THE Vv +}

ae
*

AMERICAN NATURALIST

AN ILLUSTRATED MAGAZINE

OF ~

NATURAL HISTORY

ae VOLUME XLI

—

BOSTON, U.S. A.
GINN & COMPANY, PUBLISHERS
The Atheneum Press
1907

Mo. Bot.Garaen |
1908

l

INDEX

Acassız Centennial 1
a The problem of . . . . 332
Allen, G. M. Schwarz’s Long-

5 Mutations bad the
ueactaphio yai of
nearly related specie

Miller’s Families ae Gen:

era of Bats . 671
Ridgway’s Birds of North

and Middle Americ . 672
Amblystoma ed Breed-

ing habits of . . 381

Andrews, E, A. The attached
young of the crayfish C
barus clarkii and C. pear + 200
hain ian as planters of
441
A Be glonerctus, Silk glands
of . 567

Aquaria, Aarating device for tt
Aramides north of Panama 177
Banas, O. On the wood rails,
gen Aramides, occurring
port of Franna . a ... A
EW. yauwa notes 474
Behavior of Gonion . 683

Berry, E.W. Pie plants
from Alabama
Blarina ee ‘Habits of 495
Book revi
Baldwin’s s “Mental Develop-
719

MODE oo a e e A
Barker’s Anatomical Termin-
l ;

ONT ees . 897
Beebe’s Log of the Sun . 275
Beebe’s The Bird . 282

ology
Jenning’s Behavior of Lower
isms

PAGE
nine cen Davis’s Principles

f Bota 52

eee s Sukkulaa Euphör-

bien . . 286

Bigelow’s Spirit “of N ature
Study

Burkett iid Poe’ 8 Goito ; . 405

Cash and Hopkinson’s British
Rhizopoda i

. 125

Constantin’s Transom aas

Culin’s Games of North Amer-
ican Indians .

Dean’s Chimaeroid pihe . 132

Drew’s re Manual . 592

Folsom’s Entomology 48

Fowler’s Heterognathous
Fishes se M

Guenther’s Darwinism . . 44
Guyer’s Animal Micrology . 196
Herrick’s General Zoology. . 592

Hodge, ed, oe of Amer-

ican Indians
Hough and ER Physi-
ol 194, 721

Johnston’s Nervous is System ot
rate

i i | 785
Kidd’s Sense of Touch ; . v2
Kollmann’s Altas of Human
Embryology
Laloy’s Parksitian and Mutu-
alism 2
Lock’s Progress in the Study
of Variat
Matthew’s Continents i in "Terti:
ary Tim . 191

iv INDEX

PAGE
Miller’s SN and Genera
of Bat

Millikan ee Gale’ S Physica . Al
Molisch’s Purpurbakterien . 541
Montgomery’s Racial Descent 719
Norton’s Elements of Geology 409

Punnett’s Mendelism . . . 329

Rich’s Feathered Game . . 726

Ridgway’s Birds of North and
Middle America . BI2

Scharff’s European Annals £
Schwarz’s Longleaf Pine . . 539

Skeat and Blagden’s Pagan

Races of the Malay Penin-
BER a ee ee
de Vries’ Arten und Varietäten 189

Yerkes’ Dancing Mouse =e

Breeding habits of Amblystoma

. 381

—-— of Sanada . 467
Brown-tail moth, Netting io
of . 342

CAMBARUS, Attached young of . 253
Studies on the
Ophioglossacea: . 139
— ea studies on oes
sperm.
Capitalisation a ce: names ; 525
Cataloguing museum speciméns 77
Celastrus scandens as a food sup-

ply .3
Chaetognatha, Distribution ir, . 24

—

Chalicothere: . 733
Chrysler, M. ve ‘Hee > Jetirey, E.
en : . 355
Chube’ n 323, 468
Cilia, ee of . $45
Color vision, The RER A . 365

Courtis, S. A. Response of toads
o soun a a a 677
Crayfish, Attached young of
Cushman, J. A racoda from
southeastern Massachusetts . 35

Dane, J. M. The problem of
color vision .

Davenport, C. B. “Moderuised
Darwinism

. 253°

PAGE

Dirk W: T. Hyla PE
and Rana virgatipes in New
Jersey .

Dearborn, G. V. N. T ‘ond
Sedgwick’s Physiology . .
Dillingham, F. T. The stafi-

tree, Celastrus scandens
former ae supply of er
Indian
len of velated coin
207, 241, 653
. 477

. 194

is beetles .
rnford, C. B. The fying-
fish problem ;

EARTHWORMS as planters of trees 711
Eigenmann, H. r’
“ Heterognathous Fishes” with
a note on the Stethaprioninae .
Eliot, C. W. Agassiz Centen-
ar

767

5) RER een in. . 589
= cra Notes on
532, 597, 727, 798
Molisch’s Pur-

Ernst, H. C.

puimeniena:, ©: 40.0, ee
Exhibits at the 7th Int. Zool.
Congress

Fierasfer affinis, Habits of . . 1
Flying-fish problem 65, 347
Fowler, . W. Records of

Pennsylvania fishes
pater abi re vari-

—— en =; dia i in
Geographic distribution of dose-
ly related species 207, 241, 653
Gill, T. Stone-gathering fishes 468
Gonionemus, Behavior of . . 683
Goodale, G. L. Burkett and
Poe’s Cotton .
Grabau, A. W. AR
variation in Gastropoda . 607
Graphie method of correlating
fish environment and distri-
bution . . an BR

INDEX v

PAGE
Guyer, M. F. Method for re-
moving gelatinous coats of

Be ia er
Gymnosperms, Recent studies on 801

Gynandromorphism in inseets . 715

Harris, J. A. Constantin’s
Transformisme
coe i Vries’ Arten and Vatis-
täte BE messe yk OO
ey and mutation . 403
—— Search for mutations . . 470
—— Fungi of termite nests . . 536
—— Plant geography Ban
Lock’s Study of Variation . 603
—— Floral ecology . 673

813

Xerophily in gynnas
Heterogenesis . . 396
Hoffmann, R. Beebe’s The
Bird see ee ee
Holder, ©. F. Nest of the kelp
Dah E E a kG
Hrdlička, A. Quaternary re-
mains of man in central Eu-

rope, and other notes 127
—— Hodge’s Handbook of

American Indians . 529
Hus, H. Winter rest . . 344
Hyla andersonii .
eng en of 335,788 |
Inheritan . 184 |
Insects, Note on RA en

o s > 532; 597, T2 T98

Gynandromorphiem i in . 715

Instincts in birds

JEFFREY, E. C., and Chrysler, M
A. microgametophyte
of the Podocarpineae .

ry D. W. River terraces

—— Flying-fish problem

KanGARoo, The young of the .
Kingsley, J. S. anne wou
ogies in vertebrates .
—— Zoological aa 132, 197, jói
—— Guyer’s Animal Micrology 196
Kofoid, C. A. The coincident
distribution of related species
of pelagic organisms as illus-
trated by the Chaetognatha . 241
Jenning’s Lower Organ-
isms .
Cash and Hopkinson’ s Bni-
ish Rhizopoda .

o.

pe

Leaves, Development of

431, 701, 817
Leavitt, R. G. The geographic
ee of closely related
species o u ie ee

7 | Lewis, F. T. Studies of leaf

. 431, 701, 817

| —— Problem of ts
| ones

| — Palms a , 123
| —— Nettling hairs of the brown-

tail mot š . 342

|

395, 595
. 396

i

Barker’s PERRE y

molor =- <;

Instincts in birds .

Agassiz Centennial
reservation of native ani-

mals and plants .

—— Problem of life. ‘

eg of specific

nam
— Specific tens in em-

.126 | bryos . 589
a ead a no 192, 277 | a RR af the Tth int.
—— Norton’s rS of Geol- . Zool. Congress i
ca ro aa a 3 | e Ris Ponthaied Game . 726
—— Recession of Niagara Falls 541 | —— Inheritance of disease . . 784

Jordan, D. S.

Ichthyological
notes io acs 02 Bu 188

—— Scharff’s European Animals 785
—— Yerkes’ The Dancing Mouse 786

vi INDEX

PAGE
Linton, E. Habits of Fierasfer
afınis . re et a
Loomis, F. B. A note of the
prairie-dog owl resembling the
rattlesnake’s rattle

Lucas, F. A. Mönnum in
VON o ee a

Matueson, R., and Ruggles, A.
The = eg of Apan-
teles glome
Mating habit ai: Rivellia basen
Mendelism
ei homologies in oe

. 567
. 465
329

. 103
Miergameton of the Pods:
arpin . 35

ine Be 333, 781

Morgan, T. H. "The cause of
gynandromorphism in insects 715

Morrill, A. W. Description of a
new species of Telenomus with
observations on its habits and

Murbach, L. An Kalorasiie
aerating device for aquaria . 61
Murray, J. Some South Ameri-
can Rotifers . . . 97
Mutants, Pink insect is . 773
Mutation ae 403, 470, 653

Necturus maculosus, Specific
name o : 23
Needham, J. G. Entomological

notes
—— and ‘Williamson. H. V. ide
servations on the natural his-

tory of diving beetles . . . 477
Nest of the kelp fish . . . . 587
of the chub > . 328, 468
Nichols, J. F. Star nosed mole
on Long Island < - %0]
Noturus, Poison glands of . . 553

OPHIOGLOSSACEAE, Studieson . 139

Orthogenetic variation in Gastro-
poda
Ortmann, i E. Matthew A de
tinents in Tertiary Times. . 191
Osteology of the Tubinares 109, 281
Ostracoda from köuihenetten
‘Massachusetts

Pans and soles . 334, 723
Parker, G. H. Zoologia notes 51
Montgomery’s Racial De-
scent ‘
d ahnen s Neewveds System 722
Penhallow, D. P. Contributions
to the Pleistocene flora of
. 443

Canada ;
Pennsylvania habeas:
Peterson, O. A. Notes on some

American Chalicotheres . 733
Piersol, W. H. Mating habit of

the fly Rivellia boscii . 465
Pike, F. H. A critical ind sth

tistical study of the determi- `

nation of sex, particularly in

human offspri eo ak 308
Pink insect mutants

Pleistocene flora, of ER . 689
— an . 443
Podocarpineae, neo:
hyte of .
Poison glands of Noturuk and
Schilbeodes . 553
Polygamy and viher iodi si
mating among bir i 61
Polyodon spathula, The natural
istory o 753
Prairie-dog owi, A vols of 125
Rarts (Aramides) north of Pan-
ama
Rana virguipe:
Rand, H. W. The dunedtone of
the spiracle of the skate . . 287

Reed, H. D. The poison glands
of Noturus and Schilbeodes . 553
Riley, W. A. Folsom’s ento-
mology . . 48
—— Notes on sicpottiral: aio-
mology . . . 532, 597, 727, 798

Ritter, W. E. The significant
results of a decade’s study of

_ the Tunicata .

Rivellia boscii, Making habit ee;

Rotifers, South American . .

Ruggles, A. G. See Matheson,

R. and SP E
Ruthven, G. Note on the
variation of scutellation in
garter sn N ae nee ae

Large frogs from west
AMDA e

SCHILBEODES, Poison glands of .
.4

Seutellation in garter snakes .
Sex determination . 303,
Sheak, W. H. Chanvitioos on
the young of the red kangaroo
Shrew, Habits of the Short-tailed

Shufeldt, R. W. Osteology of
i 1

the Tubinares

Polygamy and ee NE
of mating among birds . .

Shull, A.F. Habits of the short:
tailed shrew, Blarina brevi-

Silk glands of Apanteles glom-
FRE nee are

Skate, Functions of the spiracle
of a Ee uc ee

Smith, B. G. Volvox for labo-
ratory use

Hreeding habits et Ambiy-

punctatum

Spiracle, ee i ee ee

_Staff-tree as a food supply bee

ar-nosed mole on Long Island

St
Stejneger, L. en posi-
. 28

tion of the Tubinares
Stethaprioninae . . E

tockard, C. R. The natural

history of Polyodon spathula

PAGE

. 753

INDEX

|

vil
AGE
TELENOMUs, New species Or 417
Termite nests, Fungi of . 536-
Thompson, C.H. Benger’ s Suk-
kulente Euphorbien 5
Toads, Response to sound ; ae
Trelease, W. Bergen and Davis’s
re ;
RER B, 344, 405
Palta Osteology of . 109
—— Systematic position of . . 281
Tunicata, Results of a decade’s
VARIATION, Momentum in 46.
Vertebrates, Meristic homolo-

OO Gee . 103
Volvox for laboratory use 31
WAITE, F. C. Specific name of

Necturus maculosus 23.

Walton, L. B. Cealsguingi mu-
seum specimens 77
Wheeler, W. M. Pink ask
mutants 773
Williams, L. W The irasu
of cilia, especially in gastro-
pods o

<< Boolönicnl text booki i : 592
Williamson, H. V. See Need-
ham, J. G. and —— . 477

Wilson, A. W.G. Chubs’ ‘vents 323
Wright, A. H. A graphic
method of correlating fish en-

vironment and distribution . 351
XENIA in wheat . 47
YERKES, R. M. Baldwin’s

Mental Development . 719

VOL. XLI, NO. 481 = JANUARY, 1907 —

= THE
AMERICAN |

A MONTHLY JOURNAL =
DEVOTED TO THE NATURAL SCIENCES è ——
IN THEIR WIDEST SENSE = —

The American Naturalist

ASSOCIATE EDITORS

J. A. ALLEN, Pu.D., American Museum of Natural History, New York
E. A. ANDREWS, Pu.D., Johns Hopkins University, Baltimore
WILLIAM S. BAYLEY, Pu.D., Colby University, Waterville
DOUGLAS H. CAMPBELL, Pu.D., Stanford University
J. H. COMSTOCK, S.B., Cornell University, Ithaca.
WILLIAM M. DAVIS, M. E., Harvard University, Cambridge
ALES HRDLICKA, M.D., U. S. National 2 useum, Washington
D. S. JORDAN, LL.D. ‚ Stanford Universit
CHARLES A. KOFOID, Pr.D., University <= se Berkeley
J. G. NEEDHAM, P».D., Lake Forest Universit
ARNOLD E. ORTMANN, Px.D., Carnegie M aa Pittsburg
D. P. PENHALLOW, D.Sc., F.R.S.C., McGill University, Montreal
H. M. RICHARDS, S.D., Columbia University, New York
W. E. RITTER, Pu.D., University of California, Berkeley
ERWIN F. SMITH, S.D., U. S. Department of Agriculture, Washington
LEONHARD STEJNEGER, LL.D., Smithsonian Institution, Washington
W. TRELEASE, S.D., Missouri Botanical Garden, St. Louis
HENRY B. WARD, Pr. D., University of Nebraska, Lincoln
M. WHEELER, Pn.D., American Museum of Natural History,
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THE
AMERICAN NATURALIST

Vor. XLI January, 1907 No. 481

NOTE ON THE HABITS OF FIERASFER AFFINIS
EDWIN LINTON

On the 18th of June, 1906, at the Tortugas Laboratory of the
Carnegie Institution I had the opportunity of watching an evicted
Fierasfer in the act of returning to his lodging-place in a holo-
thurian (Stichopus mebit).

A record of this event, while perhaps not contributing anything
new to science, will, it is hoped, be useful to teachers of zoölogy.

Perhaps as good a way as any of making this communication
will be to narrate in order the series of events by which the knowl-
edge came to the writer and at the same time to his associates in
the laboratory, all of whom were interested witnesses.

The holothurian in question was found in a fish-trap and taken
to the laboratory where it was placed in a large dish filled with sea
water. Incidentally it may be remarked that the holothurian
had been out of the water fully half an hour. It should also be
stated that the holothurian was taken to the laboratory rather in
response to the instinct of collecting than for the purpose of carry-
ing on any experimental work.

The specimen was placed on my table and in the intervals of
other work I placed various objects on it for the purpose of finding
out whether it would get rid of them or not. é

The holothurian was very contractile and varied in length from
150 millimeters, or less, up to the diameter of the dish, 300 milli-
meters.

It appeared to be indifferent to the presence of such objects as
small glass dishes, allowing them to settle slowly into the yielding
mass of its body wall. At length a finger-bowl, 115 millimeters

1

2 THE AMERICAN NATURALIST [Vor. XLI

in diameter, was inverted over the animal, the edges resting on the
dorsal side and about 30 millimeters from ‘each end: ` Instead of
making any effort to escape the animal retreated beneath the finger-
bowl and at the expiration of 30 minutes had made no effort to
escape.

At this point in the experiment, my patience proved inferior to
that of the holothurian’ and I lifted the finger-bowl. When this
was done a specimen of the interesting genus Fierasfer, which I
have identified as F. affinis, was found. Evidently it had been
driven to leave its host on account of the deficient supply of oxygen.
The fish. which was nearly transparent, measured 124 millimeters
in length, and was very slender, tapering almost uniformly from
the head to the tip of the long and whip-like tail.

As soon as the finger-bowl was removed the fish began to swim

Fig. 1.— The figures represent the holothurian ern to the greatest length
one-third natural size an atic.
a. Position of fich during its progress toward the iieii end of its hos
b. Fish at een of movement which results in the insertion of the ns in
the cloacal apertu

actively about in the dish. It kept its nose close to the surface of
the water, and at times even thrust its head above the surface in
its eagerness to get oxygen.

After a few minutes it ceased to swim at the surface but appeared
to be still uneasy. No test was made to prove what seemed to be
indicated by its actions, viz., that its sense of sight is defective.
Judging from its subsequent behavior it was even then trying to
find its customary quarters, but, to those of us who were watching,
its movements began to be somewhat aimless.

No. 481] HABITS OF FIERASFER 3

At last, and, so far as I was able to judge, by accident, its nose
came in contact with the holothurian near the anterior end. Imme-
diately the fish appeared to become excited and began to feel its.
way back toward the posterior end of the holothurian. In its.
progress it bumped its nose rapidly against the side of the passive
holothurian, and, as if following a scent, proceeded without any
. pause or regression toward the cloacal aperture. ‘The instant
that the nose of the fish touched the edge of the aperture, which
was rather tightly closed, the slender tail was brought around with
a very rapid whip-like movement, which terminated in a thrust
whereby about 5 millimeters of the tip were darted into the narrow
slit between the apposed lips of the cloaca. ‘This movement was

Maen

EUER OME ee iien ae

Fic. 2—c. The fish has straightened and is beginning to insinuate itself into
the body of its host.

effected while the nose of the fish was still touching the cloacal
region.

Up to this time the fish had exhibited + more or less excitement
but as soon as the tip of its tail had been inserted it straightened
itself and began leisurely to insinuate its body tail first into its
host, In this process the fish appeared to be making some use of
the spines of the dorsal and ventral fins. ‘The motion was a slow,
gliding one and was not dependent on the relaxing of the cloacal.
sphincter of the holothurian.

The lips of the cloacal aperture remained Mead during the
ingress except so far as they were forced apart by the body of the

4 THE AMERICAN NATURALIST [Vor. XLI

The time occupied by the fish in entering the holothurian was
not taken, but in my notes which I made immediately after my
observations, I find that I estimated the time to be probably not
more than half a minute.

In order to give some of the workers in the laboratory, who had
not seen all of the events described above, an opportunity to view
this interesting instance of animal behavior, the experiment was
repeated.

When the finger-bowl had been removed from the holothurian
a second time the fish was found to be again in the water.

Then were repeated in minutest detail the actions which I have
described above. ‘The fish swam actively at the surface of the
water — part of the time with its mouth above the surface. Then it
began to move in a more or less aimless fashion. Finally it touched
the holothurian with its nose, this time about the middle of the
length. Then followed in exact order the reactions which had
been observed before, viz., the rapid bumping of its nose against
the side of the holothurian, the undeviating progress towards the
posterior end, the whip-like motion and insertion of the tail while |
the nose was still in contact with the margin of the cloacal aperture,
the leisurely straightening of the body, and the gradual retreat into
the resisting, at least not assisting, holothurian.

It should be added that the above account is made up from
notes which I wrote down immediately after the observations were
made. Except in one or two details they are confirmed by Dr.
Ulric Dahlgren who has kindly placed his notes at my disposal.

The above account is the story of the way one Fierasfer gained
entrance to its host. Whether every individual Fierasfer would
behave exactly the same, under similar circumstances, perhaps
does not necessarily follow.

I am indebted to Professor Cornelia M. Clapp for reference to
an excellent article on the habits, anatomy, etc., of Fierasfer by
Dr. Carlo Emery, (Fauna und Flora des Golfes von Neapel, vol. 1,
1880). Dr. Emery notes that Fierasfer enters its host tail first.

A somewhat similar habit is indicated for the common eel b
what the veteran and accurate observer, Vinal N. Edwards, tells
me, viz., that eels go into holes tail first.

RECORDS OF PENNSYLVANIA FISHES

HENRY W. FOWLER

Two complete accounts of the fishes of Pennsylvania have
appeared, one by Cope in 1881, and the other by Dr. Bean in 1892.
The first of these is of a rather general nature, though based on the
author’s studies while collecting about the State, and the other is
to a large extent little more than an elaborated compilation of the
first. In view of the desideratum, of definite records for the dis-
tribution of the different species in the various streams, lakes, etc.,
I have collected at a number of localities, and thus am able to
offer nearly complete notes for some districts. This, and an
examination of the fine collection of Pennsylvania fishes in the
Academy of Natural Sciences of Philadelphia will complete my
records. It may be understood that no species is here included
unless known to me from the examination of a Pennsylvania
specimen. Further exploration will undoubtedly extend the dis-
tribution of many species, besides resulting in the acquisition of
some others not now known from within our limits.

The collections in the Academy embrace chiefly those made by
E. D. Cope and J. H. Slack, together with others made by T. D.
Keim, B. W. Griffiths, P. Lorrilliere, W. S. Sutch, S. P. G. Lindsay,
D. McCadden, H. T. Wolff, Alfred Satterthwait, J. S. Witmer,
W. Stone, and myself. In this connection the writer wishes to
thank Mr. Wm. E. Meehan of the State Fish Commission for
permission to collect fishes in Pennsylvania with nets.

PETROMYZONIDÆ

Petromyzon marinus Linnæus. LAMPREY.— Delaware River,
in the Brandywine tributaries in the Delaware basin at Stock
Grange, Chester Co. (W. Stone); at Holmesburg, Philadelphia
Co., Cornwells, Bucks Co., Dingmans Ferry, Pike Co. (H. T.
Wolff); apparently less frequent in the Delaware than formerly.

Ichthyomyzon concolor (Kirtland). SILVER LAMPREY.— Alle-
gheny River at Port Allegany, McKean Co.

5

6 THE AMERICAN NATURALIST [Vor. XLI

Lampetra wilderi Jordan and Evermann. Brook LAMPREY.
— Kiskiminitas River (E. D. Cope); Allegheny River at Port
Allegany, McKean Co.; Susquehanna tributaries at Emporium,
Cameron Co. ;

ACIPENSERIDE

Acipenser sturio Linnsus. STURGEON.— Delaware River at
Holmesburg, Tacony, Bridesburg, and Torresdale, in Philadelphia
Co., and Cornwells, Bristol, and Tullytown in Bucks Co. I have
found it fairly abundant at times and seen some large examples.

PoOLYODONTIDE

Polyodon spathula (Walbaum). PADDLE Fisu.— Reported as
occurring occasionally in the Allegheny River below Corydon,
Warren Co., which it has been known to ascend as far as Sala-
manca and Olean in Cattaraugus Co., N. Y.

PSALLISOSTOMATIDÆ

Psallisostomus osseus (Linnæus). GAR PIKE.— Small exam-
ples occur in the lower Delaware River as far as Morrisville,
Bucks Co., and occasionally a large one is noted.

AMIID -

Amia calva Linneus. Bow Fın.— An example from Lake
Erie, obtained by Dr. Watson, may have been taken within our
limits.

GLOSSODONTID

Glossodon harengoides Rafinesque. Moon Eyr.— Beaver River
(E. D. Cope); Youghiogheny River (E. D. Cope).

CLUPEIDE

Pomolobus pseudoharengus (Wilson). ALEWIFE.— Delaware
River at Tinicum, Delaware Co., Holmesburg, Tacony, and
Torresdale, Philadelphia Co., and Cornwells, Croydon, Bristol,
-Tullytown, and Morrisville, Bucks Co. Abundant in the spring.

No. 481] PENNSYLVANIA FISHES fi

Alosa sapidissima (Wilson). SHAap.— Delaware River at Tini-
cum, Delaware Co., League Island, Frankford, Tacony, Holmes-
burg, and Torresdale, Philadelphia Co., Cornwells, Eddington,
Croydon, Bristol, Tullytown, and Morrisville, Bucks Co., and
Dingmans Ferry, Pike Co. (H. T. Wolff). Some seasons .more
abundant than others. In the Susquehanna they are taken about
Peach Bottom and McCall’s Ferry, Lancaster Co.

DOROSOMATIDE

Dorosoma cepedianum (Le Sueur). Mwup SHap.— Delaware
River at Torresdale, Philadelphia Co. (Dr. H. D. Senior), and
Cornwells, Bristol, and Tullytown, Bucks Co. Apparently less
abundant than formerly, though even in midwinter a few have
been hauled out of the mud.

ENGRAULIDIDE

Anchovia mitchilli (Valenciennes). AncHovy.— Many exam-
ples were obtained many years ago below Philadelphia, some
most likely within our limits, by Dr. Colin Arrott. They occur
in the lower Delaware and are more a feature of the marine fauna.

SALMONIDE

Salvelinus fontinalis (Mitchill). Brook Trour.— Brandywine
tributaries in Chester Co., and those of the Schuylkill near Port
Kennedy, Montgomery Co. (D. MeCadden), all in the Delaware
basin; the Susquehanna basin in the Loyalsock near Lopez,
Sullivan Co., and near Galeton, Potter Co.; the Allegheny basin
above Port Allegheny in McKean Co., and Seven Bridges in
Potter Co.; the Genesee basin about Gold in Potter Co.

ARGENTINID

Osmerus mordax (Mitchill). SmeLr.— I have seen a number
of examples taken from the Schuylkill and Delaware near Phila-
delphia.

8 THE AMERICAN NATURALIST [Vor. XL1

ANGUILLIDE

Anguilla chrisypa Rafinesque. ErL.— Delaware River at Tini-
cum and Darby Creek, Delaware Co., League Island, Frankford,
Tacony, Holmesburg, Torresdale, with the Pennypack Creek basin
at Bustleton, in Philadelphia Co.. Cornwells, Croydon, Bristol,
Tullytown, and Morrisville, with the Neshaminy Creek basin at
Hulmeville and Newtown, Bucks Co., and Dingmans Ferry, Pike
Co. (H. T. Wolff); Susquehanna basin at Galeton, Potter Co. I
did not meet with eels over the Allegheny divide in Potter and
McKean Counties, and the impression is prevalent that they do
not occur in the upper tributaries of either the Allegheny or the
Genesee.

CYPRINIDE

Campostoma anomalum (Rafinesque). STONE RoLLER.— Alle-
gheny River at Port Allegany, McKean Co., in June, 1906,
where I found entirely tuberculated males; Kiskiminitas River
(E. D. Cope).

Chrosomus erythrogaster eos (Cope). RED-BELLIED DAcE.—
Cotypes of ©. eos Cope examined.

Hybognathus nuchalis Agassiz. SILVERY Minnow.— Kiskimin-
itas River (E. D. Cope).

Hybognathus nuchalis regius (Girard). EASTERN SILVERY MIN-
Now.— Delaware River at Tacony, Holmesburg, and Torresdale,
Philadelphia Co., and Cornwells and Bristol, also the Neshaminy
Creek basin at Hulmeville and Neshaminy Falls, in Bucks Co.
Many examples were examined.

Pimephales notatus (Rafinesque). BLUNT-NOSED MInNow. —
Kiskiminitas River (E. D. Cope) and the Allegheny River at Port
Allegany, McKean Co., June, 1906.

Semotilus bullaris (Rafinesque). Fart Fisu.— Delaware River
basin in the Brandywine Creek basin at Kennett Square, Menden-
hall, Willistown Barrens, and opposite Chadds Ford, Chester
Co.; Darby Creek basin, Delaware Co.; Tacony, the Penny-
pack Creek basin at Holmesburg and Bustleton, the Poquessing
Creek basin opposite Cornwells and Torresdale, Philadelphia

No. 481] PENNSYLVANIA FISHES 9

Co.; the Neshaminy Creek basin at Croydon, Hulmeville, Nesha-
miny Falls, and Newtown, Mill Creek basin about Bristol, and
Tullytown Creek basin about Tullytown, Bucks Co.; Delaware
Water Gap, Monroe Co. (E. D. Cope); Dingmans Ferry, Pike
Co. (H. T. Wolff). In the Susquehanna basin I have it from the
Northeast Creek at Nottingham, Chester Co., and the Cone-
stoga Creek, Lancaster Co. (E. D. Cope).

Semotilus atromaculatus (Mitchill). CHus.— Delaware River
basin in the Brandywine Creek basin at Kennett Square, Menden-
hall, and opposite Chadds Ford, Chester Co.; Cobb’s Creek (E.
D. Cope) and Darby Creek, Delaware Co.; Tacony Creek, the
Pennypack Creek at Holmesburg and Bustleton, the Poquessing
Creek at Torresdale and opposite Cornwells, Philadelphia Co.;
the Neshaminy Creek at Croydon, Hulmeville, Neshaminy Falls,
and Newtown, Mill Creek at Bristol, Tullytown Creek at Tully-
town, and Morrisville, Bucks Co.; Dingmans Ferry, Pike Co.
(H. T. Wolff). The Susquehanna basin in the Octoraro near
Nottingham, Chester Co., and Muncy, Lycoming Co. Beaver
River (E. D. Cope); Warren Co. (Dr. J. H. Slack); Kiskiminitas
River (E. D. Cope); the Allegheny River at Raymonds, Potter
Co. Ihave also found it in the headwaters of the Genesee around
Gold, Potter Co.

Leuciscus vandoisulus Valenciennes. Rosy Dacr.— Octoraro
Creek, in the Susquehanna basin, near Nottingham, Chester Co.

Leuciscus elongatus (Kirtland). Rep-sıpep Dacr.— Allegheny
River at Port Allegany, McKean Co., in June, 1906.

Brama crysoleucas (Mitchill). RoacH.— Delaware basin in the
Brandywine Creek basin at Kennett Square, Mendenhall, and
opposite Chadds Ford, Chester Co.; Tinicum and Darby Creek,
Delaware Co.; Tacony Creek, the Pennypack at Holmesburg, and
Bustleton, and the Poquessing at Torresdale and opposite Corn-
wells, Philadelphia Co.; Neshaminy Creek at Croydon, Hulme-
ville, Neshaminy Falls, and Newtown, Mill Creek at Bristol,
Tullytown Creek at Tullytown, and Morrisville, Bucks Co.;
Pennypack at Hatboro, Montgomery Co.; Daleville, Lackawanna |
Co.; Dingmans Ferry, Pike Co. (H. T. Wolff), and in the Susque-
hanna basin from the Loyalsock Creek near Lopez, Sullivan Co.

. Notropis bifrenatus (Cope). Briptep MINNOW. — Delaware

10 THE AMERICAN NATURALIST [Vor. XLI

River in the Brandywine at Chadds Ford, Delaware Co.; the
Pennypack at Holmesburg and Bustleton in Philadelphia Co.,
and Hatboro in Montgomery Co.; the Poquessing at Cornwells,
the. Neshaminy at Croydon, Hulmeville, Neshaminy Falls, and
Newtown, and Mill Creek at Bristol, Bucks Co. Abundant and
rather local.

Notropis cayuga Meek. Cayuca Minnow.—I have already
recorded the only example seen, which was taken near Port Alle-
gany in 1904.

Notropis procne (Cope). SwALLow Mınnow.— Cotypes of
Hybognathus proene Cope examined. I have examples also from
the Delaware basin taken in the Schuylkill (E. D. Cope) and the
Pennypack Creek near Holmesburg, Philadelphia. A small
minnow was taken on one occasion, which may be this species,
in the headwaters of Northeast Creek, near Nottingham, Chester
Co., in the Susquehanna basin.

Notropis hudsonius amarus (Girard). EASTERN GUDGEON.—
Susquehanna basin at Paradise, Lancaster Co. (J. S. Witmer).
Delaware basin in the Brandywine Creek at Chadds Ford, Dela-
ware Co.; open river and Pennypack Creek at Holmesburg, and
the Poquessing at Torresdale, Philadelphia Co.; Neshaminy
Creek at Croydon, Hulmeville, and Neshaminy Falls, and Mill
Creek at Bristol, Bucks Co. More abundant in the larger streams.

Notropis whipplii (Girard). SILvEer Fin.— Youghiogheny River
(E. D. Cope) and Kiskiminitas River (E. D. Cope).

Notropis whipplii analostanus (Girard). EASTERN SILVER FIN.
— Delaware River basin in the Brandywine Creek at Chadds
Ford, and Darby Creek, Delaware Co.; Wissahickon Creek near
Barren Hill, and Pennypack Creek near Hatboro, Montgomery
Co.; Tacony Creek, Pennypack at Holmesburg and Bustleton,
and Poquessing Creek at Torresdale and opposite Cornwells,
Philadelphia Co.; the Neshaminy Creek at Croydon, Hulmeville,
Neshaminy Falls, Frog Hollow, and Newtown, Mill Creek at
Bristol, Tullytown Creek at Tullytown and Morrisville, Bucks
Co.; Dingmans Ferry, Pike Co. (H. T. Wolff). It is also abun-
dant in the Susquehanna basin where I received it from Paradise,
Lancaster Co. (J. S. Witmer), and the Northeast Creek at N =
ham, Chester Co.

No. 481] PENNSYLVANIA FISHES 11

Notropis cornutus (Mitchill). Rep Fın.— Delaware River basin
in the Brandywine Creek at Kennett Square, Mendenhall, and
opposite. Chadds Ford, Chester Co.; Darby Creek and Ridley
Creek near Willistown Barrens, Delaware Co.; Wissahickon Creek
near Barren Hill, and the Pennypack at Hatboro, Montgomery
Co.; Tacony Creek, Pennypack at Holmesburg and Bustleton,
Poquessing Creek at Torresdale and opposite Cornwells, Phila-
delphia Co.; Neshaminy Creek at Croydon, Hulmeville, Nesha-
miny Falls, Newtown, Frog Hollow, and Chalfont, Mill Creek at
Bristol, Tullytown Creek at Tullytown, and Morrisville, Bucks
Co. In the Susquehanna basin in Northeast Creek at Notting-
ham, Chester Co.; Conestoga Creek (E. D. Cope) and Paradise,
Lancaster Co. (J. S. Witmer), and Meshoppen, Elk Co. (E. D.
Cope). In the Allegheny from near Croydon, Warren Co., and
it also occurs farther up. Kiskiminitas River (E. D. Cope).

Notropis chalybeus (Cope). IRON-COLORED Minnow.— Nesha-
miny Creek near Newton, and Mill Creek, Bristol, both in the
Delaware basin, Bucks Co.

Notropis atherinoides Bithia EMERALD Mopo- Beaver
River (E. D. Cope).

Notropis rubrifrons (Cope). RosY-FACED. Minnow.— Cotypes
of Alburnus rubrifrons Cope examined.

Notropis photogenis (Cope). WHITE-EYED Minnow: — Cotypes

of Squalius photogenis Cope examined.

' Notropis photogenis amenus (Abbott). ATTRACTIVE Minnow.
— Hulmeville, in the Neshaminy Creek, Bucks Co.

Ericymba buccata Cope. SILVER-MOUTHED Mınnow.— Cotypes
of the species examined.

Rhinichthys cataracte Vale, LonG-NosED DAcE.—
Delaware River basin in the Brandywine tributaries near Kennett
Square and Mendenhall, Chester Co. In the Susquehanna at
Paradise, Lancaster Co. (J. S. Witmer)... Beaver River (E. D
Cope): ..

Rhinichthys atronasus (Mitchill). BLAcK-NOsED Dacr.—Del-
aware River basin in the Brandywine Creek basin at Kennett
Square, Mendenhall, opposite Chadds Ford, Chester Co.; Darby,
Ridley, and Cobb’s Creeks, Delaware Co.; Schuylkill River,
Tacony Creek, Pennypack Creek at Holmesburg, and Bustleton,

12 THE AMERICAN NATURALIST [Vor. XLI

and Poquessing Creek at Torresdale, and opposite Cornwells,
Philadelphia Co.; Wisahickon Creek near Barren Hill and Penny-
pack at Hatboro, Montgomery Co.; Neshaminy Creek at Croydon,
Hulmeville, Neshaminy Falls, Frog Hollow, Chalfont, and New-
town, Mill Creek at Bristol, Tullytown Creek at 'Tullytown,
Morrisville, Bucks Co.; Dingmans Ferry, Pike Co. (H. T. Wolff);
Daleville, Lackawanna Co. In the Susquehanna basin it occurs
in the Octoraro and Northeast Creeks near Nottingham, Chester
Co.; Paradise in Lancaster Co. (J. S. Witmer); the Loyalsock
Creek near Lopez, Sullivan Co., and Pine Creek at Galeton and
above, Potter Co. In the Allegheny River it is abundant at
Coudersport and Raymonds, Potter Co. Kiskiminitas River (E.
D. Cope). Youghiogheny River (E. D. Cope). Genesee basin
near Gold, Potter Co. Potomac drainage of Fulton Co., (W.
Stone).

Hybopsis kentuckiensis (Rafinesque). Hornep CHUB.— Sus-
quehanna basin in Elk Creek, Chester Co. (E. D. Cope); Conestoga
Creek, Lancaster Co. (E. D. Cope). Beaver River (E. D. Cope);
Youghiogheny River (E. D. Cope); Kiskiminitas River (E. D.
Cope); Warren Co. (Dr. J. H. Slack); Allegheny River at Port
Allegany, McKean Co.

Exoglossum maxillingua (Le Sueur). Cur-Lıprs Minnow.— Alle-
gheny River at Port Allegany, McKean Co.

CATOSTOMATID.E

Carpiodes cyprinus (Le Sueur). EASTERN Carp SUCKER.—
Conestoga Creek, in the Susquehanna basin, Lancaster Co. (E.
D. Cope).

Cycleptus elongatus (Le Sueur). Brack Horse.— Kiskimini-
tas River (E. D. Cope).

Catostomus commersonnii (Lacépède). Common SUCKER.— Del-
aware River in the Brandywine tributaries at Kennett Square,
Mendenhall and opposite Chadds Ford, Chester Co.; Tinicum,
Ridley, Cobb’s and Darby Creeks, Delaware Co.; Pennypack
Creek at Hatboro, Montgomery Co.; Tacony Creek, Pennypack
Creek at Holmesburg and Bustleton, Poquessing Creek at Torres-
dale and opposite Cornwells, Philadelphia Co.; Neshaminy Creek

No. 481] PENNSYLVANIA FISHES 13

at Croydon, Hulmeville, Chalfont, Frog Hollow, Neshaminy Falls,
and Newtown, Mill Creek at Bristol, Tullytown Creek at Tully-
town, and Morrisville, Bucks Co.; Delaware Water Gap, Monroe
Co. (E. D. Cope); Dingmans Ferry, Pike Co. (H. T. Wolff).
In the Susquehanna basin in the Northeast and Octoraro Creeks
near Nottingham, Chester Co.; Conestoga Creek (E. D. Cope)
and Paradise, Lancaster Co. (J. S. Witmer). In the Allegheny
River it occurs at Port Allegany in McKean Co.

Catostomus nigricans Le Sueur. BLACK SUCKER.— In the
Susquehanna basin in the Conestoga Creek (J. Stauffer) and at
Paradise, Lancaster Co. (J. S. Witmer); Octoraro Creek near
Nottingham, Chester Co. Kiskiminitas River (E. D. Cope). I
have not positively identified this from the Delaware basin.

Erimyzon sucetta oblongus (Mitchill). MULLET. — Delaware
River basin in the Brandywine tributaries at Kennett Square and
Mendenhall, Chester Co.; Brandywine at Chadds Ford, Ridley
and Darby Creeks, Delaware Co.; Tacony Creek, river and Penny-
pack Creek at Holmesburg and Bustleton, Poquessing Creek at
Torresdale, and opposite Cornwells, Philadelphia Co.; Nesh-
aminy Creek at Croydon, Hulmeville, Neshaminy Falls, and New-
town, Mill Creek at Bristol, Tullytown Creek at Tullytown, and
Morrisville, Bucks Co. In the Susquehanna basin from Center
Co. (Dr. H. Allport). Genesee River at Gold, Potter Co.

Moxostoma anisurum (Rafinesque). WHITE-NOSED SUCKER.—
Beaver River (E. D. Cope) and Youghiogheny River (E. D. Cope).

Moxostoma aureolum (Le Sueur). GoLtpEN Rep Horse. —
Beaver River (E. D. Cope) and Youghiogheny River (E. D. Cope).

Moxostoma macrolepidotum (Le Sueur). Rep HorsE.— Cone-
stoga Creek, Lancaster Co. (E. D. Cope).

Moxostoma breviceps (Cope). LONG-TAILED Rep HoRsE.—
Type of Ptychostomus breviceps Cope examined.

Placopharynx duquesnii (Le Sueur). BIG-JAWED SUCKER. —
Beaver River (E. D. Cope).

SILURIDÆ
Ictalurus punctatus (Rafinesque). Brue CAT. — Beaver River

(E. D. Cope).
Ameiurus catus (Linneus). WHITE CatT.— Delaware River

14 THE AMERICAN NATURALIST [Vor. KEI

basin in tributaries in Chester Co. (V. Bernard); Holmesburg
and Torresdale, Philadelphia Co.; Bristol, Bucks Co.; Susque-
hanna River (E. D. Cope).

Ameiurus nebulosus (Le Sueur). YeLLow Car. — Delaware
River basin in the Brandywine tributaries at Kennett Square and
Mendenhall, Chester Co.; 'Tinicum, Brandywine at Chadds
Ford, Darby, Ridley, and Cobb’s Creeks, Delaware Co.; Jenkin-
town, Montgomery Co. (H. Crawley); Falls of Schuylkill (Dr.
Uhler), Tacony Creek, river and Pennypack at Holmesburg and
Bustleton, Poquessing Creek at ‘Torresdale, and opposite Corn-
wells, Philadelphia Co.; Neshaminy Creek at Croydon, Hulme-
ville, Neshaminy Falls, Chalfont, and Newtown, Mill Creek at
Bristol, Tullytown Creek at Tullytown, and Morrisville, Bucks
Co.; Dingmans Ferry, Pike Co. (H. T. Wolff); Susquehanna
River (E. D. Cope); Northeast Creek near Nottingham, Chester
Co.; Conestoga Creek, Lancaster ‘Co. (E. D. Cope); Allegheny
River at Coudersport and Perryville, Potter Co.

Gronias a Cope. Brinp Car.— Cotypes of the species
examined.

Leptops olivaris Pitio: Mup Car.— Youghiogheny
River (E. D. Cope).

Schilbeodes gyrinus (Mitchill). TADPOLE Stone Car.— Dela-
ware River at Holmesburg, Philadelphia Co.; Mill Creek at
Bristol, and Tullytown, Bucks Co.; Delaware Water Gap, Monroe
Co. (E. D. Cope); Dingmans Ferry, Pike Co. (H. T. Wolff). In
the Susquehanna from the Loyalsock Creek near Lopez, Sullivan
Co. In the Genesee below Gold, Potter Co.

Schilbeodes insignis (Richardson). MARGINED STONE CAT.—
Delaware River in the Schuylkill and at Holmesburg, Philadel-
phia Co.; Susquehanna basin at Carlisle, Cumberland Co. (S. F.
Baird); Conestoga Creek (J. Stauffer) and Paradise, Lancaster
Co. (J. S. Witmer).

Esocip 4

Esox americanus (Gmelin). BANDED PICKEREL.— Delaware
River basin in the Brandywine tributaries at Kennett Square and
Mendenhall, Chester Co.; Tinicum and Darby Creek, Delaware
Co.; Tacony Creek, Pennypack Creek at Holmesburg, and Po-
quessing Creek at Torresdale and opposite Cornwells, Philadel-

No. 481] PENNSYLVANIA FISHES 15

phia Co.; Neshaminy Creek at Neshaminy Falls and Newtown,
Mill Creek at Bristol, Tullytown, and Morrisville, Bucks Co. In
the Octoraro Creek of the Susquehanna basin near Nottingham,
Chester Co.

Esox vermiculatus Le Sueur. WESTERN PICKEREL.— Allegheny
River in Potter County.

Esox reticulatus Le Sueur. CuHain Pıke.— Rock Hill Pond
and Dingmans Ferry, in the Delaware Basin, Pike Co. (H. T.
Wolff).

Esox lucius Linneus. Pixe.— Although I did not secure any
examples of this species in the Allegheny River while at Port
Allegany, in McKean Co., in 1904, it was reported as occurring
farther down stream. One from Lake Erie may have been from
within our limits (Dr. Watson).

Esox masquinongy ohiensis (Kirtland). Osio River Musk-
ALLUNGE.— Reported to occur in the Allegheny as far as Corydon,
Warren Co., and in New York to Olean. Warren Co. (Dr. J. H.
Slack).

UMBRIDE

Umbra limi pygmea (De Kay). Mup Minnow.— Delaware
River at Philadelphia and Holmesburg, Philadelphia Co.; Bristol
and Tullytown, Bucks Co.; Schuylkill River (Dr. Harlan).

P&cıLuD&

Fundulus heteroclitus macrolepidotus (Walbaum). MummıcHoc.
— Delaware River in tide-water, at Tinicum, Delaware Co.;
League Island, Tacony, Holmesburg, and Torresdale, Philadel-
phia Co.; Cornwells, Croydon, Bristol, Tullytown, and Morrisville,
Bucks Co.

Fundulus diaphanus (Le Sueur). Barrep KiLiirisn.— Dela-
ware River in tide-water and above, Brandywine basin in Chester
Co. at Kennett Square; Brandywine at Chadds Ford, Darby and
Ridley Creeks, Delaware Co.; Tacony Creek, Pennypack Creek
at Holmesburg and Bustleton, Poquessing Creek at Torresdale
and opposite Cornwells, Philadelphia Co.; Neshaminy Creek at
Croydon, Hulmeville, Neshaminy Falls, and Newtown, Mill

16 THE AMERICAN NATURALIST [Vor. XLI

Creek at Bristol, Tullytown Creek at Tullytown, and Morrisville,
Bucks Co.; Montgomery Co.; the Susquehanna basin at Paradise
(J. S. Witmer) and Lancaster Co. (E. D. Cope); Warren County
(Dr. J. H. Slack).

MASTACCEMBELIDE

Tylosurus marinus (Walbaum). GREEN Gar.— Delaware River
(Dr. Uhler), at Bristol, Bucks Co.; Susquehanna River (E. D.
Cope).

ÄTHERINIDE

Labidesthes sicculus (Cope). Brook SILVERSIDE.— Youghi-
ogheny River (E. D. Cope).

(GASTEROSTERIDE

Eucalia inconstans (Kirtland). Brook STICKLEBACK.— Erie,
Erie Co.

Apeltes quadracus (Mitchill). FOUR-SPINED STICKLEBACK.—
Delaware River, in tide-water, at Tinicum, Delaware Co.; Tacony,
Holmesburg, and Torresdale, Philadelphia Co.; Cornwells, Croy- —
don, Bristol, Tullytown, and Morrisville, Bucks Co.

ÄAPHREDODERIDE

Aphredoderus sayanus (Gilliams). PIRATE PERcH.— Delaware
River at Tinicum, Delaware Co.; League Island, Tacony, Holmes-
burg, and Torresdale, Philadelphia Co.; Mill Creek and the river
at Bristol, Bucks Co.

CENTRARCHIDÆ

Pomoxis annularis Rafinesque. CRAPPIE.— Kiskiminitas River
(E. D. Cope). I have an example from the Delaware at Browns-
ville, Bucks Co. (J. G. Dillin).

Ambloplites rupestris (Rafinesque). Rock Bass.— Beaver River
(E. D. Cope), Warren Co. (Dr. J. H. Slack), and Kiskiminitas
River (E. D. Cope).

No. 481] PENNSYLVANIA FISHES 17

Enneacanthus gloriosus (Holbrook). BLUE-SPOTTED SUNFISH.
— Delaware River at League Island (Professor Wm. M. Gabb),
and Holmesburg, Philadelphia Co.; river and Mill Creek at Bristol,
Bucks Co. In the Susquehanna from the Conestoga Creek, Lan-
caster Co.

Enneacanthus obesus (Girard). SPHAGNUM SuNFISH.—Found
only in the ditches of the lower part of Philadelphia along the
Delaware. i

Mesogonistius chetodon (Baird). BANDED SunrısH.— Dela-
ware River at Holmesburg, Philadelphia Co., and Bristol, Bucks
Co.

Lepomis auritus (Linnæus). RED-BREASTED SUNFISH.— Dela-
ware River basin in the Brandywine tributaries (Dr. H. Allen),
Londongrove (E. D. Cope); Chadds Ford on the Brandywine,
Darby, Ridley, and Cobb’s Creeks, Delaware Co.; Montgomery
Co. (W. Cassin), and Pennypack at Hatboro; Tacony Creek,
Pennypack at Holmesburg and Bustleton, Poquessing at Torres-
dale and opposite Cornwells, Philadelphia Co.; Neshaminy Creek
at Croydon, Hulmeville, Neshaminy Falls, and Newtown, Mill
Creek at Bristol, Tullytown and Morrisville, Bucks Co.; Ding-
mans Ferry, Pike Co. (H. T. Wolff). In the Susquehanna basin
from the Octoraro Creek (E. D. Cope) and Conestoga Creek,
Lancaster Co. (E. D. Cope), and Paradise, Lancaster Co. (J. S.
Witmer).

Lepomis megalotis (Rafinesque). LONG-EARED SUNFISH.—
Kiskiminitas River (E. D. Cope).

Lepomis macrochirus Rafinesque. LARGE-FINNED SUNFISH.
— Cotypes of Lepomotis nephelus Cope examined.

Lepomis palladus (Mitchill). BLuE-GILL SuUNFIsH.— Warren
Co. (Dr. J. H. Slack); Kiskiminitas River (E. D. Cope).

Eupomotis gibbosus (Linnæus). Common SunrisH.— Dela-
ware River basin in tributaries of Brandywine near Kennett
Square, Chester Co. (E. D. Cope and H. Allen); Brandywine at
Chadds Ford, Ridley, Darby, and Cobb’s Creek, and Tinicum,
Delaware Co.; Jenkintown and Hatboro, Montgomery Co.;
Tacony Creek, Pennypack Creek at Holmesburg and Bustleton,
Poquessing at Torresdale and opposite Cornwells, Philadelphia
Co.; Neshaminy Creek at Croydon, Hulmeville, Neshaminy Falls,

18 THE AMERICAN NATURALIST [Vòn XLI

and Newtown, Bristol, and Mill Creek, Tullytown and Tullytown
Creek, and Morrisville, Bucks Co.; Dingmans Ferry, Pike Co.
(H. T. Wolff). In the Susquehanna from the Conestoga Creek,
Lancaster Co. (E. D. Cope); the Loyalsock near Lopez, Sullivan
Co.; Octoraro Creek (E. D. Cope). Erie, Erie Co. (C. Rutter).

Micropterus dolomieu Lacépède. SMALL-MOUTHED BAss.—
Youghiogheny River (E. D. Cope) and the Allegheny at Corydon,
Warren Co., and met with as far as Olean, N. Y.

Micropterus salmoides (Lacépède). LARGE-MOUTHED Bass.—
Warren Co.

PERCIDÆ

Stizostedion vitreum salmoneum (Rafinesque). BLuE PIKE.—
Warren Co. (Dr. J. H. Slack), Beaver River (E. D. Cope), and
Youghiogheny River (E. D. Cope).

Stizostedion canadense griseum (De Kay). SAUGER.— Warren
Co. (Dr. J. H. Slack), Beaver River (E. D. ene) and Youghi-
ogheny River (E. D. Cope).

Perca flavescens (Mitchill). YELLow PERCH.— Delaware River
in Darby Creek, Delaware Co.; river and Pennypack Creek at
Holmesburg, and Poquessing Creek at Torresdale, Philadelphia
Co.; Neshaminy Creek at Croydon, Hulmeville, Neshaminy
Falls and Newtown, Mill Creek at Bristol, Tullytown Creek at
Tullytown and Morrisville, Bucks Co. In the Susquehanna basin
from the Conestoga Creek in Lancaster Co. (E. D. Cope).

Percina caprodes (Rafinesque). Loe Percu.— Type of Perca
nebulosa Haldeman examined. Youghiogheny River (E. D. Cope)
and Kiskiminitas River.

Hadropterus macrocephalus (Cope). LoNG-HEADED DARTER.
— Cotype of Etheostoma macrocephalum Cope examined.

Hadropterus peltatus (Cope). SHIELDED DARTER.— Type of
Etheostoma peltatum Stauffer, in Cope, examined.

Diplesion blennioides (Rafinesque). GREEN-SIDED DARTER.—
Beaver River (E. D. Cope)

Boleosoma nigrum (Rafinesque). JOHNNY DARTER.— Cotypes
of B. olmstedi brevipinnis Cope examined.

Boleosoma nigrum olmstedi (Storer). "T'ESSELLATED DARTER.
— Delaware River basin in the Brandywine tributaries at Kennett

No. 481] PENNSYLVANIA FISHES 19

Square, Mendenhall and opposite Chadds Ford, Chester Co.;
Brandywine at Chadds Ford, Ridley, Darby, and Cobb’s Creek,

and Tinicum, Delaware
Co.; Pennypack at Hat-
boro, and Jenkintown,
Montgomery Co.; League
Island, Tacony Creek,
Frankford Creek, Penny-
pack Creek at Holmes-
burg and Bustleton, and
Poquessing Creek at
Torresdale, and opposite
Cornwells, Philadelphia
Co.; Neshaminy Creek
at Croydon, Newportville,
Hulmeville, Neshaminy
Falls, Frog Hollow, and
Newtown, Mill Creek at
Bristol, Tullytown Creek
at Tullytown, and Morris-
ville, Bucks Co.; Ding-
mans Ferry, Pike Co. (H.
T. Wolff). In the Sus-
quehanna basin I have it
from the Octoraro Creek

at Nottingham in Chester —

Co., the Loyalsock near
Lopez, Sullivan Co., and
the Pequea at Paradise,
Lancaster Co. (J. S. Wit-
mer), besides the type of
Percina minima Halde-
man. The accompany-
ing figure represents a
remarkable variation of

y j a
f er /
& Ži

a

Fie. 1.— Variation of Boleosoma nigrum olmstedi

(Storer).

fin-rays seen in an example I secured at Holmesburg, Phila-
delphia, September 11th, 1898. Although I have not seen the
type of Boleosoma esopus Cope my Loyalsock examples go far to
establish it as a pure synonym of this fish.

20 THE AMERICAN NATURALIST [Vor. XLI

Etheostoma ceruleum Storer. BLUE Darrer.— Kiskiminitas
River (E. D. Cope).

Etheostoma flabellare Rafinesque. FANn-TAILED DARTER.— Kis-
kiminitas River (E. D. Cope); Youghiogheny River (E. D.
Cope); Pittsburgh (Jacob Green); Allegheny River at Port Alle-
. gany in McKean Co. during July and August of 1904 and June
of 1906, where it is abundant.

Boleichthys fusiformis erochrous (Cope). SPHAGNUM DARTER.
— Delaware basin in Mill Creek near Bristol, Bucks Co.

SERRANIDE

Roccus lineatus (Bloch). Srripep Bass.— Delaware River
basin at Tinicum, Delaware Co.; League Island, ‘Tacony, Holmes-
burg, and Torresdale, Philadelphia Co.; Cornwells, Bristol, Tully-
town, and Morrisville, Bucks Co. In the Susquehanna basin I
have it from the Conestoga in Lancaster Co. (E. D. Cope).

Roccus chrysops (Rafinesque). Warre Bass.— Reported from
just below the headwaters of the Genesee in Potter Co. near Gold.

Morone americana (Gmelin). WHITE Percu.— Delaware River
at League Island, Tacony, Holmesburg, and Torresdale, Phila-
delphia Co., Cornwells, Bristol, Croydon, Tullytown, and Morris-
ville, Bucks Co.

SCLENIDE

Aplodinotus grunniens Rafinesque. FRESH-WATER DRUM.—
One from Lake Erie (Dr. Watson) may have been taken in our
limits.

COTTIDÆ

Uranidea gracilis viscosa (Haldeman). Miırrer’s THUMB.—
The Delaware basin in the Brandywine tributaries near West
Chester, Chester Co.; in the Schuylkill basin near Port Kennedy,
Montgomery Co. (D. McCadden), and Douglassville, Berks Co.
(S. N. Rhoads); in the Neshaminy basin near New Britain, Bucks
Co. (Dr. C. C. Abbott). In the Susquehanna basin in Spruce
Creek, Huntingdon Co. In the Genesee basin at Gold, Potter
Co., also other examples from the same County (E. Harris).

No. 481] PENNSYLVANIA FISHES 21

SOLEIDE

Achirus fasciatus Lacépède. SoLE.— Schuylkill River in the
Delaware basin (Dr. Harlan) and Bristol, Bucks Co. (Dr. J. De B.
Abbott).

GADID

Lota maculosa (Le Sueur). Line.— Erie, Erie Co.; Susque-
hanna basin at Muncy, Lycoming Co. (E. D. Cope).

SPECIFIC NAME OF NECTURUS MACULOSUS
F. C. WAITE

In view of the fact that this animal is now extensively used in
research and teaching, and since the majority of teachers and
writers follow Cope (’89) and erroneously use the name Necturus
maculatus, it seems worth while to call attention to the correct ter-
minology.

There has been considerable confusion in the nomenclature of
this form since it was first described. Minor variations have in
several cases received specific names, and in the earlier literature
it was frequently confused with Cryptobranchus allegheniensis of
which it was for a time considered the larva.

The first scientific description of this animal was by Schneider
in 1799 from a single specimen in the museum at Brunswick. This
specimen came from Lake Champlain. Schneider did not consider
it a new genus but put it under the European genus Salamandra
without appending any specific name.!

Lacépède (’07) described a museum specimen, saying that it had
never been before described, evidently not knowing of Schneider’s
description. He recognized that it differed from Salamandra and
therefore referred it to the genus Proteus, naming it Proteus tetra-
dactyle with the provision that if it were found to be a larva, it
should be called Salamandra tetradactyle.

Barton (’07, pp. 196-7), describes “a large species of Salaman-
dra” which he proposes to call S. horrida, or maxima, or gigantea. —
It is evident from a reading of his paper that he has confused
Necturus and Cryptobranchus, and the general inaccuracy of his
description makes his contribution of little value.

Rafinesque (’18, p. 40), gave a brief preliminary description of
this salamander under the name Sirena maculosa. He, however,
recognized, as the following quotation shows, that it might repre-
sent a new genus (p. 40): “In Zoology my discoveries are par-

1 The original paper is not available. I quote from Holbrook (’42).

23

24 THE AMERICAN NATURALIST [Vor. XLI

ticularly important consisting of about 25 new undescribed
quadrupeds, 30 new birds and about 32 new reptiles” * * * *
“Among so many undescribed things it must follow that several
may constitute new genera. ...I propose to select 8 N. G. and 10
N. Sp. in order to convey an idea of the whole.

(p. 41) I. N. Sp. Sirena maculosa, (A Reptile). Body oliva-
` ceous brown, covered with large unequal blackish spots * * * *
“ This spotted siren bears the generic name Water Puppet along
with S. lutea and S. fusca.”

A year later, after he had been able to study his collections,
Rafinesque (719) erected the new genus Necturus to include this
form. I quote part of his description, (p. 418): “IIIe Classe.
Reptiles * * * * 7. Necturus (Batracien) Different des genres
Salamandra, Triturus (Triton, Laur.), Larvarius (Proteus, Aurt.),
par queue comprimée 4 doigts séparés a tous les 4 pieds, branchies
extérieures persistent communement jusqu’ à la vieillesse. ....
Especes: N. maculatus, N. lutescens, N. fuscus, N. marginatus,
N. axolotes?, N. anguillaris, N. operculatus, ete.”

A year later Rafinesque (’20) again describes this form, (p. 4):
“III Class. Erpetiá — the Reptiles....17. Necturus macu-
losus, olive brown covered with large unequal black spots....
My genus Necturus (70 N. G. An.) is distinguished from Triturus
by having teeth, four toes to all the feet and external gills present
to a late period....18. Necturus luteus....19. Necturus phos-

horeus” * + *,

Mitchill (21, p. 183) says in regard to this form: “From such
survey as I have been capable of making I am inclined to consider
him a Proteus; but of a species different to that known to European
naturalists.” Later, in a very extensive description with good
plate, (Mitchill, ’24) he describes a specimen from Lake Erie and
recognizes that it differs from the genus Proteus, but is “averse to
unnecessary multiplication of genera.”’

In 1823 Say (James, ’23, vol. 1, p. 5, footnote) describes speci-
mens from the Allegheny River, with permanent branchiz. He says
that it is caught at Pittsburg but is not so abundant as S. alleghe-
niensis. He gives the new name Triton lateralis.

Harlan (’24, p. 233, pl. 16), evidently unaware of the papers of
Rafinesque, erected the new genus Menobranchus. “ The Am-

No. 481] NAME OF NECTURUS 25

phiuma, the Siren, the Proteus and the Salamandra will be acknowl-
edged by all to constitute separate genera. The lateralis and
allegheniensis not belonging to any of these will require appropriate
generic names....As the most prominent feature distinguishing
the T. lateralis from the Salamandra is its persistent branchie,
we have preferred a name significant of this fact. Menobranchus.
Generic characters. Persistent branchis, two rows of teeth in the
upper and one row in the lower jaw; four footed, four toes to each
foot, clawless.” He describes two species, M. lateralis and M.
tetradactylus. Since these were found to be but variations of the
same species and since the term tetradactylus described a generic
character, the first species, only, held.

Harlan erected the genus Abranchus to include the alleghenien-
sis, but in a note a few months later (same journal and volume, p-
270) he changed this to Menopoma having learned that the name
Abranchus was preëmpted for a genus of nudibranch molluscs.

Barnes (’26) calls it Proteus lateralis and says (p. 287) that “the
first specific name given was by Mr. Say who called it lateralis in
allusion to the black lateral line. 'The discoveries already made
....show that the character from which he derived this is
variable.” He dissents from Harlan and does not think that a
new genus should be established. He evidently knew nothing
of Rafinesque’s description. |

In a later note (Barnes, ’27, p. 68), he says: “Dr. Mitchill has.
laterly called it Proteus maculatus, which as it isa good descriptive:
name. ...I am disposed to adopt.” Mitchill had evidently gotten
the maculatus from Rafinesque’s second paper (719) but had not
seen the first (718) or third (’20) papers.

Fitzinger (’26, p. 43) gave a new name to the genus. “Genus.
Phaenerobranchus. Aus Lacépéde’s Proteus tetradactylus, Say’s.
Triton lateralis, aus Nord Amerika, schuf ich die Gattung Phae-
nerobranchus (Menobranchus, Harlan; Necturus, Rafinesque).”
Under the list of reptiles in the Zoological Museum at Vienna
he includes (p. 66) “Phaenerobranchus cepedii (=Proteus tetra-
dactylus, La Cepede).”

Harlan (’27) in his synopsis includes (p. 323) “ Menobranchus
ateralis” and this name was followed by many writers.

Wagler (’30, p. 210) returns to the generic name of Necturus,.

26 THE AMERICAN NATURALIST [Vor. XLI

and quotes as synonyms, Proteus tetradactylus Lacépède, Triton
lateralis Say, and Menobranchus lateralis Harlan.

Tschudi (’38, p. 97) adopts Menobranchus lateralis.

Holbrook (’42, vol. 5) describes two species of Menobranchus:
(p. 111) M. maculatus (Barnes) in which he makes no reference to
Rafinesque, and (p. 115) M. lateralis (Say). He states that the
two species may be only geographical varieties.

DeKay (’42, p. 87, pl. 18, fig. 45) uses Menobranchus lateralis
and does not refer to Rafinesque.

Baird (’50), in his “ Revision of the Tailed-Batrachia” gives cor-
rect references to Rafinesque’s three papers and while adopting
his generic name, adheres to Say’s specific name (which was given
five years later) giving the name of the form as Necturus lateralis
1823, which was the date of Say’s description, although Say did
not use the term Necturus.

Gray (’50) gives the reference to Rafinesque’s three papers and
is the first to adopt the correct name Necturus maculosus. How-
ever, in the second edition of this work (Boulenger, ’82, p. 84)
reference is made only to Rafinesque’s second (19) paper and the
term Necturus maculatus is taken.

Dumeril and Bibron (54, p. 183) use Harlan’s term Meno-
branchus lateralis.

Finally, Cope (’89, p. 23) aden the name Necturus. maculatus
in spite of the fact that his references to synonyms shows that he
had consulted all of Rafinesque’s papers.

The following are part of the Laws, of priority as published in
the International Rules of Nomenclature (:05):—

(p. 35) “Art 25. The valid name of a genus or species can be
only that under which it was first designated on the condition: (a)
That this name was published and accompanied by an indication
or a definition or a description and (b) That the author applied
the principles of binary nomenclature.”

(p. 36) “ Art. 28... A genus formed by the union of two or more
genera or subgenera takes the oldest valid generic or subgeneric
name of its components. The same rule obtains when two or
more species or subspecies are united to form a single species or
subspecies.

(p. 37) “Art. 32. A generic or a specific name once published

No. 481] NAME OF NECTURUS 27

cannot be rejected even by its author because of inappropriate-
ness.”

Although Schneider gave the first description of this form he
did not follow the binary system nor did he recognize it as a sepa-
rate genus.

There can be no question that Rafinesque (19) was the first
to erect and name a new genus to receive this form.

The specific name tetradactylus given by Lacépède (’07) cannot
hold because it describes a generic character (“4 doigts séparés à
tous les 4 pieds”’) in the new genus Necturus of Rafinesque.

The description by Barton (07), is certainly so inaccurate,
including his hesitation between three specific names, that his
paper can have little weight.

The first scientific description with the use of a binary nomen-
clature is that of Rafinesque (18). Here the specific name is
maculosa. According to Art. 32 of the rules on priority this term
could not have been changed by Rafinesque if he had wished to do
so. The term maculatus used in his 1819 paper is either an unin-
tentional slip on his part or a typographical error. At any rate the
use of the term maculosus in his ’20 paper, which was published
under his immediate direction with opportunity to correct proof,
shows that he preferred the original adjective form maculosus to
the participial form maculatus. Such is certainly the better gram-
matical usage.

The confusion has arisen from the fact that the first (’18) paper
was printed in a rather obscure literary periodical where scientific
men were unlikely to see it. Likewise the third paper (’20) was
published in an obscure private publication, a serial which did not
continue and so was easily lost sight of. The second paper (’19) in
which the error occurred was in a prominent scientific journal and
thus came to be generally known.

In the past ten years although many papers have been written
on Necturus, two only have, as far as I know, used the correct
nomenclature. These are Eycleshymer (:06) and Waite (’97).

I believe that it is clear from the foreoging that the correct name
is Necturus maculosus and I hope that this may come into general
use.

WESTERN RESERVE UNIVERSITY.

28 THE AMERICAN NATURALIST [Vor. XLI

LITERATURE.

05. International Rules of Nomenclature, adopted by the Inter-

national Congress of Zodlogy, Paris,
Barrp, S. F.

60. Revision of the North American Tailed-Batrachia with Descrip-
tions of a New Genus and Species. Journ. Acad. Nat. Sci.,
Philadelphia, ser. 2, vol. I, pp. 281-294.

Barnes, D.

26. An Ababa of the Genera of the Batracian Animals with a
Description of the more Remarkable Species including a mono-
graph of the Doubtful Reptiles. Amer. Journ. Sct. and Arts,
ser. 1, vol. 11, pp. 268-297.

Barnes, D.

’27. Note on "the Doubtful Reptils. Amer. Journ. Sci. and Arts, ser. 1,

vol. 13, pp. 66-70.
Barton, B. S.

’07. [Scientific Notes]. Phila. Med. and Physical Journ., suppl. 2,

sect. 2.
BOULENGER, G. A.

’82. Catalogue of the Batrachia Gradientia, s. Caudata and Batrachia
Apoda in the Collection of the British Museum. London, 1882.
Seo edition of Gray, ’50).

Corr, E. D.
’89. The Batrachia of North America. Bull. 34, U. S. Nat. Mus.,
Was ington.
DeKar, J. E.

’42. RB of New York. Part III. Reptiles and Amphibia.
DumÉRIL, A. M. C. er BIBRON, G.
’54. Erpetologié générale ou histoire naturelle complète des Reptiles.
Tome 9, Paris.
EYCLESHYMER, A. C.
06. The Habits of Necturus maculosus. Amer. Nat., vol. 40, pp-
123-136

FITZINGER, L. I.
26. Neue Classification der Reptilien. Wien.
Gray; J. E.
’50. Catalogue of the Specimens of Amphibia in the Collection of the
British Museum. Part II. Batrachia Gradientia etc. London.

No. 481] NAME OF NECTURUS 29

HARLAN, R.
’24. Observations on the Genus Salamandra with the Anatomy of
the Salamandra gigantea (Barton) or S. allegheniensis (Michaux)
and two New Genera proposed. Ann. Lyc. Nat. Hist., vol. 1,
pt. 2, pp. 222-234.
Haran, R.
’27. Genera of North American Reptilia and a Synopsis of the Species.
Journ. Acad. Nat. Sci. Philadelphia, vol. 5, pt. 2
HoLBROOK, J.
’42. North Autor Herpetology. Ed. 2, 5 vols., Philadelphia.
James, Epwin, (editor).
ceount of an Expedition from Pittsburg to the Rocky Mountains
in 1819 and 1820 under the command of Major S. H. Long. 2
vols., Philadelphia, and 3 vols., London.
Lackyena, M. DE
Sur une peptic de quadrupéde ovipare non encore décrite. Ann.
Mus. Hist. Nat. Paris, vol. 10, pp. 230-235, pl. 17.
MıtcHiuı, S. L.
’21. The Proteus of the North American Lakes. Amer. Journ. Sci.
and Arts, ser. 1, vol. 4, pp. 181-183
Mircuit1, 8. L.
24. Observations on Several Reptiles of North America which seem
to belong to the family Proteus. Amer. Journ, Sci. and Arts,
ser. 1, vol. 7, pp. 63-69, pl. 2.
RAFINESQUE, C. 8.
118. Purther Accounts of Discoveries in Natural History in the West-
ern States. Amer. Month. Mag. and Crit. Rev., vol. 4, pp. 39-42,
New York, Nov. 1818.
RaFINESQUE, C. 8.
19. Prodrome de 70 nouveaux Genres d’animaux découverts dans
Vinterieur des Etats-Unis d’Amérique durant l’année 1818.
Journ. Physique, Chemie, et Hist. Nat., vol. 88, pp. 417-429,
June 1819.
RAFINESQUE, C. S.
Annals of Nature or Annual Synopsis of new Genera of Plants and
Animals. First Annual Number, pp. 1-16, Transylvania Univer-
sity, Lexington, Ky., Mch. 1820

Say.
23. Vide James, Edwin (editor).
SCHNEIDER, J. G.
1799. Historiæ Amphibiorum Naturalis et Litterariae, Jena.
Tacnupr, J. J.
Classification der Batrachier mit Berucksichtigung der fossilen
Thiere dieser Abtheilung der Reptilien. Mem. Soc. Sci. Nat. de
Neuchatel, vol. 2.

30 THE AMERICAN NATURALIST [Vor. XLI

WAGLER, Jou.

’30. Natürliches System der Amphibien mit vorgehenden Classifica-
tion der Säugethiere und Vögel. München, Stuttgart und
Tübingen. .

Warre, F. C.

’97. Variations in the Brachial and Lumbo-sacral Plex (uses) of
Necturus maculosus PATA: Bull. Mus. Comp. Zoöl., vol. 31,
pp. 69-92.

VOLVOX FOR LABORATORY USE
BERTRAM G. SMITH

In providing a supply of Volvox for class use late in the fall,
difficulty has been experienced in two respects: in keeping the
material alive in the laboratory as long as desired, and in getting
specimens containing sperm and ova. Inquiry reveals the fact
that others have had the same trouble. I have recently been able
to overcome both these difficulties, and at the suggestion of Dr.
H. H. Newman have recorded the method in some brief notes.

Species.--So far as known, the only species of Volvox that has
been found in the vicinity of Ann Arbor during the late autumn is
Volvox aureus Ehrenb. It is not very abundant, and I have never
found it in the sexual stage at the time it was collected. It occurs
in small glacial pools containing Riccia and duckweed.

During the early spring Volvox globator Linn., and no other
species, occurs in great abundance in the same pools that later con-
tain Volvox aureus. I have occasionally found it in the sexual
stage when collected.

By the latter part of June Volvox globator has become quite
scarce, and V. aureus has begun to appear. During the early
part of July the two species exist in the same habitats, but neither
is very abundant.

Since Volvox is so widely used for laboratory work by beginning
classes, the marked specific differences are matters of importance.
Volvox globator is the form described in text-books, but the de-
scription is far from being applicable to V. aureus. Since the latter
may at times be the only species available, it may be profitable to
call attention to the differences between the two species, for it is to
be suspected that Volvox aureus is sometimes used without its
species being recognized.

Volvox globator is considerably larger than V. aureus; its somatic
cells are more numerous and compactly arranged. ‘The somatic
cells of globator are angular and connected by very stout proto-
plasmic strands; the somatic cells of awreus are round when seen

31

32 THE AMERICAN NATURALIST [Vor. XLI

from the surface, and connected by very slender protoplasmic
strands, difficult for students to make out under the microscope.
Volvox globator is moncecious: in the sexual stage both sperm
bundles and eggs may be found in the same colony at the same
time. The number of sperm bundles in a single colony is small.
Volvox aureus is either dicecious or monoecious proterogynous:
sperm and eggs are never found together in a single colony at the
same time, but the colony may contain one or the other exclusively.
However, I have found daughter colonies, some of which contained
bundles of sperms, others ova, within the same parent colony.
The number of sperm bundles in a single colony is very large.
Spherosira volvox Ehrenb. is an old name for the male colony of
Volvox aureus.

Kofoid (99) gives the following key for the determination of
the two species:

Cells about 10,000 (minimum 1,500, maximum 22,000), angular with
stout connecting protoplasmic processes into which the chromato-
phore may enter. Diameter of colony about 700 (minimum 400,
maximum 1,200); diameter of cell body 3-5 yp. V. globator L.

Cells 500-1000 (minimum 200, maximum 4,400) ; rounded, with slender
connecting protoplasmic processes into which the chromatophore

oes not enter. Diameter of colony 170-180 #; diameter of cell
body 5-80 u. Volvox aureus Ehrenb.

Klein (’99) gives illustrations of the general appearance of the
two species, including reproductive stages. Meyer (’96) gives
details of cell structure, with illustrations.

Volvox globator is probably a better form for laboratory work
than V. aureus, and can be obtained in greater abundance if
secured early in the spring. Hence if Volvox is to be studied in the
fall by large classes it is well to preserve this species in 4% formalin
in the spring; for many purposes the preserved material, if not
kept too long, is as good as the living. ‘The study of preserved
specimens of V. globator can then be supplemented by the living
V. aureus.

Keeping Volvox alive in the Laboratory.— Terry (:06) in experi-
menting on the galvanotropism of Volvox met with the usual
difficulty in keeping it alive in the laboratory, and concluded that
the organisms died of insufficient nourishment caused by improper

No. 481] VOLOX FOR LABORATORY USE 33

food supply and poor light, but found it impossible to regulate
either so that they would live for more than four days. My own
experience has convinced me that in our laboratory one of the
principal causes of the death of the organism has been injurious
mineral substances in the p water in which the specimens were
kept.

In collecting Volvox for our EE it has been customary to
bring in considerable quantities of vegetable material (duckweed,
Riccia, etc.) from the ponds in which Volvox occurred, along with
a little water, and place this material in shallow glass dishes filled
with tap water. As fast as the organisms gathered on the lighted
side of the dish they were picked off and removed to a dish of clean
tap water, it being deemed unsafe to leave them in the original
dish exposed to the attacks of crustaceans. Suspecting that
deleterious substances in the tap water, as well as the lack of a
proper food supply, caused the death of the organisms, I made an
attempt to reproduce the natural conditions. Water containing
Volvox was brought in in considerable quantities, together with a
small amount of the vegetable material, and placed in shallow
glass dishes without the addition of tap water. The dishes were
placed near windows and covered with glass plates to prevent
loss of water by evaporation and to keep out bacteria and fungi,
except that when exposed to direct sunlight it was found advisable
to leave room for circulation of air between the cover and the dish
to prevent a rise of temperature beyond the optimum. ‘The water
was not changed at any time during the course of the experiment.
In the majority of the aquaria thus prepared, Volvox flourished for
several weeks; in the fall of 1905, Volvox aureus was kept alive in
several aquaria for from four to eight weeks; less success was
attained with Volvox globator in the spring, but it was kept alive
in most cases for about two weeks.

It was noted that Volvox globator clusters about decaying insect
larvee, perhaps on account of the presence of carbon dioxide.
A moderate amount of decaying plant or animal material in the
water seems to be one of the essential conditions for its existence.
In its natural environment, Volvox is often found in decidedly
stagnant water.

‘Temperature is an important factor to be considered in caring

34 THE AMERICAN NATURALIST [Vor. XLI

for Volvox. It is more difficult to keep the material alive in the
laboratory during warm weather because, in exposing the dishes to
sunlight, the water is likely to become warmer than that of the
ponds in which Volvox lives. ‘This difficulty might be overcome
by placing the dishes where they will be partly immersed in the
running water of a shallow aquarium, and at the same time receive
an abundance of sunlight.

In case organisms that feed upon Volvox are too abundant, the
latter may be freed from its enemies by removing it with a pipette
when clustered at the lighted side of the dish, to a dish of pond -
water strained through bolting cloth to remove crustaceans, etc.

Obtaining Volvox in the Sexual Stage.— Both in the fall and
in the spring, material in the sexual stage was obtained in abun-
dance merely by keeping the organisms alive in the laboratory.
Several aquaria should be set up, and in some of them, specimens
in the sexual stage will usually be found in the course of one or two
weeks. It was noted by Dr. H. H. Newman that they often remain
hidden in the ooze at the bottom of the dish. When they reach the
sexual stage they seem to become less motile and consequently
drop to the bottom. ‘This is especially true of sperm colonies in
V. aureus.

UNIVERSITY oF MICHIGAN
ZOOLOGICAL LABORATORY
Ann ARBOR, MICHIGAN

LITERATURE

Kreis, L.
’99. Morphologisehe und biologische Studien über die Gattung Vol-
vox. Jahrb. f. wiss. Bot., vol. 20.
Koror, C. A.
’99. Plankton Studies, ete. Bull. IU. State Lab. Nat. Hist., vol. 5.
MEYER, ARTHUR.
’96. Die Plasmaverbindungen und die Membranen von Volvox globa-
tor, aureus, und tertius, mit Rücksicht auf die thierischen Zellen. |
Bot. Zeit. vol. 54, pp. 187-217.
Terry, O: P.
roe Galvanotropism in Volvox. Am. Journ. Physiol., vol. 15, No. 3.

OSTRACODA FROM ‘SOUTHEASTERN MASSACHU-
SETTS

JOSEPH A. CUSHMAN

Tuar the Ostracoda of New England have been greatly neglected
may at once be seen by a reference to Miss Rathbun’s list of the
New England Crustacea. At the time of its publication there
was a single species reported from New England and that from
but one locality. With a view to supplying this lack of records
in a slight measure, some collecting has been done in our ponds,
mainly about Boston. Several persons have kindly supplied
material which has now been placed in the collections of the Boston
Society of Natural History. Seven species are reported here,
making the number of species now known from the fresh water
of New England, nine instead of one. All of the records so far,
however, are from Massachusetts.

It has been a matter of interest to find the local distribution of
the species. Where a species is found at all it is usually abundant.
Of the three species of Cypris reported, all were found in ponds
in the vicinity of Boston and but a short distance apart, yet no one
collection contained more than a single species.

A number of other species have been collected but in immature
condition or in insufficient numbers for complete diagnosis.

The measurements given are average ones for the material
examined. Asa rule, if adults alone are taken there is a noticeable
constancy in measurements but in cases where the collection con-
tains the young also, the range in measurements is considerably
greater.

It is to be hoped that more collecting will be done in the near
future and over a much broader region. By this means a con-
siderable addition to the present list should be made. The seven
species representing five genera are given below.

35

36 THE AMERICAN NATURALIST [Vor. XLI

Family Cypridide
Subfamily Cypridinze
Genus SPIROCYPRIS Sharpe, 1903
1. Spirocypris passaica Sharpe
Length 1.54 mm., height 0.76 mm., breadth 0.78 mm.

Spirocypris passaica Sharpe, Proc. U. S. Nat. Mus., vol. 26, 1903, p. 982,
pl. 66, figs

This species and genus were described as new from material
in the U. S. National Museum, collected at Passaic, New Jersey.
There is no other record for it, as far as I know, up to the present.
It is especially interesting, therefore, to be able to record this spe-
cies from Massachusetts. Several specimens were obtained from
Wellesley, Mass., April 20, 1905, collected by Mr. Irving L. Shaw.

The Massachusetts specimens were very slightly smaller than
the types but otherwise the specimens agreed very well. The
peculiar arrangement of the testes in concentric circles is very
apparent and striking. The original description gives the furca
as 23 times as long as wide. In the specimen measured from
Massachusetts the length was 0.486 mm. and the breadth 0.021
mm. A closer ratio of 23:1 could hardly be obtained in such a
structure. Further collecting may show this species to be widely
distributed in New England.

Genus Cyprıs O. F. Müller, 1792
2. Cypris virens (Jurine)
Monoculus virens Jurine, Histoire des Monocles, qui se trouvent aux
Environs de Genève, 1820, p. 174, pl. 18, figs. 15-16.

Cypris virens Zaddach, Synopseos Crustaceorum Prussicorum Pro-
dromus, 1844, p. 35.

Length 1.70 mm., height 0.97 mm., breadth 0.90 mm.

Arlington, Mass. May 7, 1905. A. S. Pearse, coll.

This is a very widely distributed species and should be found
throughout New England as collecting is extended. It was repre-
sented in considerable numbers in the material examined.

No. 481] MASSACHUSETTS OSTRACODES 37

3. Cypris fuscata (Jurine)

Monoculus fuscatus Jurine, l. c., 1820, p. 174, pl. 19, figs. 1, 2.

Cypris fuscata Zaddach, l. c., 1844, p. 32.

Length 1.36 mm., height 0.81 mm., breadth 0.75 mm.

Near Fresh Pond, Cambridge, Mass. April 30, 1905. J. A. C.,
coll.

In a very shallow pond-hole this species was very abundant on
the date given. As in the case of the preceding species, this is
very widely distributed and should be found throughout New
England.

4. Cypris reticulata Zaddach
Cypris reticulata Zaddach, l. c., 1844, p. 34.

Length 1.20 mm., height 0.70 mm., breadth 0.60 mm.

Brookline, Mass. April 10, 1905. Irving L. Shaw, coll.

Although this species is a very characteristic one and is widely
distributed in Europe, its occurrence in this country has hitherto
rested upon the single record of Dr. Sharpe. He found it in great
numbers at Normal, Ill., in a small grassy pool. It seems to
prefer such a habitat and therefore may be looked for in New
England in such places. The species was abundant in the col-
lection from Brookline.

Subfamily Cypridopsinz
Genus Cyprıporsıs Brady, 1868
5. Cypridopsis vidua (O. F. Müller)

Cypris vidua O. F. Müller, Entomostraca seu Insecta testacea, quae in
aquis Daniae et Norvegiae reperit, descripsit et iconibus illustravit,
1792. p. 55, tab. 4, figs. 7-9.

Cypridopsis vidua Brady, “A Monograph of the Recent British Ostra-
coda,” Trans. Linn. Soc. London, vol. 26, pt. 2, 1868, p. 375, pl. 24,
figs. 27-30, 46.

Length 0.64-0.75 mm., height 0.38-0.42 mm., breadth 0.42-

0.47 mm.

Small pond, West Cambridge, Mass. April 30,1905. J. A. C.,

coll.

38 THE AMERICAN NATURALIST [Vor. XLI

In tap water from Fresh Pond, Cambridge, Mass. Aug. 12,
1905. A.S. Pearse, coll.

Cohasset, Mass. Oct. 22, 1906. Owen Bryant, coll.

This species should be found everywhere in all kinds of fresh
water. It is probably the most abundant and one of the most
widely distributed of our fresh-water ostracods. It may be over-
looked on account of its small size.

Subfamily Cyclocypridinee
Genus CYPRIA Zenker, 1854
6. Cypria exsculpta (Fischer)

Cypris exsculpta Fischer, “Beitrag zur Kenntniss der Ostracoden,”
Abhandl. math. phys. Klasse k. bayr. Akad. d. Wiss., vol. 7, 1855,
p. 18, pl. 19, figs. 36-38.

Cypria exsculpta Brady and Norman, “Monograph of the Marine and
Freshwater Ostracoda, Sec. I,” Trans. Roy. Dublin Soc., ser. 2, vol. 4,
1889, p. 68, pl. 11, figs. 1-4. 4

Length 0.68 mm., height 0.44 mm., breadth 0.28 mm.

Woods Hole, Mass. Abundant in fresh-water pond, June 25,
1905, A. S. Pearse, coll. July 15, 1906, J. A. C., coll. Auburn-
dale, Mass., Oct. 28, 1906, C. W. Johnson, coll.

This species is almost as widely distributed and abundant as
the preceding. It should be found throughout New England.

Subfamily Candonins
Genus CANDONA Baird, 1850
7. Candona candida (O. F. Miiller)

Cypris candida O. F. Müller, l. c., 1792, p. 62, tab. 6, figs. 7-9.
Candona candida Lilljeborg, De Crustaceis ex ordinibus Tribus, 1853,
p. 127, pl. 11, figs. 19-20, pl. 25, figs. 13-15.

Length 0.86-1.39 mm., height 0.45-0.66 mm.

Arlington, Mass., May 7, 1905, A. S. Pearse, coll.; Auburndale,
Mass., Oct. 28, 1906, C. W. Johnson, coll.

This species has not been reported from America as far as I
am aware. ‘The specimens seem to agree well with the European

No. 481] MASSACHUSETTS OSTRACODES 39

figures and descriptions and seem to be that species without doubt.
There is a very considerable range in the measurements given as
many young specimens and both sexes were in the lot measured.
An average measurement would be close to the maximum given
here, if adults alone were taken.

This species, like the others of its genus, has a crawling habit
and may be in this way overlooked in collecting and in the exami-
nation of fresh material. It was not abundant in either of the
two collections in which it was found.

Boston Society or NarturaL History, November, 1906.

NOTES AND LITERATURE.
PHYSICS.

A First Course in Physics.'— These two books outline a thor-
oughly substantial course in elementary physics. They are obviously
intended to be used together, but each is complete in itself and either
(preferably the laboratory manual, as the authors themselves say
in their preface) could be used alone as the basis of a shorter course.

The essential feature of these books is their emphasis on the necessity
of showing a student “the hows and whys of the physical world in
which he lives” as well as the “how much” to which the reaction
from “the superficial, descriptive physics of thirty years ago” has led
us. For this reason, a great number of devices which are in common
use are explained with the help, in many cases, of admirable diagrams
of actual machines; as examples we may mention platform scales
for wagons, gas meters, two kinds of hydraulic elevators, the
engine, the railroad locomotive, hydraulic and steam turbines and gas
engines, artificial-ice and liquid-air machines, an excellent discussion
of the modern methods of heating and ventilating houses, a full descrip-
tion not only of the instruments used in telegraphy and telephony,
including the carbon transmitter, but also of the circuits themselves,
including even the new Bell central-battery system of telephony, auto-
matic signals and all, three pages of musical instruments, the Zeiss
binocular and, of course, wireless telegraphy. In the present instance,
the introduction of these illustrative digressions is governed by so just a
sense of proportion, and they are handled so well and are backed by
so much thoroughly good physics of a more quantitative sort, that the
result is much to be commended. It should always be remembered,
however,— this is to be taken not as a criticism but as a warning —
that this sort of thing may very easily become, in the hands of authors
and especially of teachers less scholarly than Professor Millikan
and Dr. Gale, an unfortunate return to the old-fashioned superficial,
descriptive “natural philosophy” which they themselves so definitely
deplore.

1 Millikan, Robert Andrews and Gale, Henry Gordon, A First Course in
Physics. Boston, Ginn & Co., 1906. 8vo, viii+488 pp.

Millikan, R. A. and Gale H. G., A Laboratory Course in Physics, for Sec-
ondary Schools. Boston, Ginn & Co., 1906. 8vo, x +134 pp.

41

42 THE AMERICAN NATURALIST [Vor. XLI

Another interesting feature of these books is the free use which is
made in qualitative explanations of such conceptions as the kinetic
theory of gases, the ionic theory of electrolytic conduction, and the
wave front in geometrical optics. Whether or not it pays, for instance,
to displace the old ray-optics, which must, of course, be properly
interpreted, by the more valuable but also more difficult notion of
the wave front, is a question of pedagogy which each teacher must
decide for himself. Fortunately the treatment of the most danger-
ously spectacular part of our modern physics is confined to the last
twelve pages of the text-book, where there is an account, admirable
as regards both interest and conservatism, of vacuum tube phenomena
and of radio-activity, including some of the evidence for the existence
of electrons, together with brief statements of the corpuscular theory
of matter and of the disintegration theory of radio-activity.

Many other features, while not unique, are nevertheless worthy of
much praise. For instance, the experiments, both for the laboratory
and for the lecture room, are ingeniously simple and yet, so far as one
can judge without trying them, entirely effective.

The typography is good, and the illustrations are most excellent,
both in technique and in conception; and the sixteen full-page half-
tones of eminent physicists, each with a short paragraph describing
the man’s life and work, are a notable addition not only to the attrac-
tiveness but to the real value of the books.

H. ND,

BIOLOGY.

Jennings’ Behavior of the Lower Organisms.'— It is now nearly
a decade since Professor Jennings published his first brochure on
the reactions to stimuli in unicellular organisms. The intervening
period has been one of continuous activity on his part in the study
of animal behavior, especially among the lower organisms. His
investigations have not been strictly confined to the Protozoa for
among the score or more of titles of important contributions from his

$ H. 8. Jennings, Behavior of the Lower Organisms. Columbia University.
Biological Series, New York, The Macmillan Co., 1906, 8vo, xiv+366 pp.,
illus. $3.00.

4

No. 481] NOTES AND LITERATURE 43

pen are studies of the reactions of Metridium and of rotifers. Nor
have his investigations been limited to the animal world alone for
groups on the border lines such as the flagellates and bacteria have
also been included. All students of these groups and especially
investigators of animal behavior and workers in the field of compara-
tive psychology will find cause for congratulation in the fact that
Professor Jennings has taken this opportunity to resurvey the whole
field of his experimental work and to summarize and restate his con-
clusions in this most important field of research. While many studies
in this field have been made primarily from the standpoint of the
psychologist, or have been of a desultory character, or are but partial
in scope, the work summarized in this book has been dominated by
the broadest scientific spirit, has been conducted with the greatest
care and thoroughness, has included in its scope all possible avenues
of approach to the analysis of animal behavior, as exemplified in the
simplest organisms, and has been carried through to a stage of com-
pletion where fundamental generalizations are possible. The work
of others in this field whether in agreement or not, with the author’s
conclusions, is treated with fullness and fairness. e thus
becomes an exemplification of the value of intensive research, an
indispensable authority for any who wish to become familiar with the
latest results in the field of animal psychology. As illustrative of the
thoroughness with which the analysis has been carried out we

that in Paramecium the structure and the normal movements are
described and correlated, and the reactions to chemical and mechanical
stimuli of various sorts determined, the absence of reaction to light
but the sensitiveness to the ultra-violet rays noted, as are also the
reactions to heat and cold, to induction shocks and a constant current
of electricity, to water currents, gravity, and centrifugal force. The
relation of these actions of orientation to other reactions is carefully
analyzed. The behavior of Paramecium in daily life in the aquarium,
in fission and conjugation, under two or more stimuli, are all passed
in review and the variability and modifiability of reactions is deter-
mined. The author concludes from observations on the differences
in behavior of individuals that we find in Paramecium slight beginnings
of the modification of behavior through the previous experiences of
the organism. In the case of Stentor the same individual does not
always behave in the same way under the same external conditions,
but the behavior depends upon the physiological condition of the
animal. The reaction to any given stimulus is modified by the past
experience of the animal, and the modifications are regulatory, not

4h THE AMERICAN NATURALIST [Vor. XLI

haphazard, in character. The phenomena are thus similar to those
shown in the “learning” of higher organisms, save that the modifica-
tions depend upon less complex relations and last a shorter time.

Each organism is found to exhibit a set of actions made up, in the
case of the lower organisms, of a few factors combined in various ways
in a coördinated system which Professor Jennings designates as “the
action system.” For the term “motor reaction” employed in his
earlier papers the phrase “avoiding reaction” is now used to designate
the stereotyped method of reaction of Infusoria to most stimuli. The
author rejects the local action theory of tropisms as a “more or less
artificial coristruction, made by combining certain elements of behavior
and omitting others that are of most essential significance.” In its
place he proposes the method of “trial and error” as an explanation
of behavior. The stimulus interferes with definite internal processes _
occurring in the organism and this interference causes a change in
behavior and varied movements which subject the organism indis-
criminately to many different conditions. It merely acts in all sorts
of ways possible to it. When one of these new conditions thus met
relieves the organism from the existing interference with its life proc-
esses, the trials cease. .

As a second cornerstone in the formulation of behavior we find the
law of “resolution of physiological states” thus stated: ‘‘The resolu-
tion of one physiological state into another becomes easier and more
rapid after it has taken place a number of times.” It appears that
even in Stentor and Vorticella repetition of an action brings the second
step in a sequence in behavior more quickly upon the first. Here lie
the foundations of the phenomena which are usually designated as
habit formations, memory and learning, and the question may well
be asked whether they are not coéxtensive with life and based funda-
mentally on the physical and chemical structure of colloids.

Modernized Darwinism.! — Professor Guenther has written a very
readable book on Darwinism and allied biological problems which
the tyro will find quite intelligible. The translation seems
and the publishers have done their part well. The treatment of
the subject is rather novel, most of the chapters being divided tax-

*C. Guenther. Darwinism and the Problems of Life. Translated from the
third edition by Joseph McCabe. London: A. Brown & Co., 1906, Dutton
& Co., New York, American agents. 8vo, 439 pp

No. 481] NOTES AND LITERATURE 45

inomically under the headings mammals, birds, reptiles, and amphi-
bians, ete. The group names, however, merely serve as hooks on
which to hang certain biological discussions. Thus, under mammals
are considered: protective coloration of hairy coats, hibernation, play
of animals; under birds, sexual selection and migration; under
reptiles and amphibians, the death of species and the origin of aérial
life; under fishes, the origin of terrestrial vertebrates, rudimentary
organs, and the biogenetic law; under insects, mimicry, instincts,
inheritance of acquired characters; under crustaceans and molluscs
biochemistry, parthenogenesis, and the meaning of sexual reproduc-
tion; under worms and ccelenterates, the descent of animals, parasitic
life and symbiosis; under Protozoa, the principle of division of labor,
the origin of the germ cells, and outlines of a theory of heredity. This
arrangement does not lend itself to a systematic and logical develop-
ment of the subject but the result is easy and delightful reading.

Not only is the book interestingly written but it is also a perfectly
safe one. No evolutionary heresies tarnish its pages; nothing but
simon-pure, orthodox natural selection is permitted here. Of course,
as befits a scientific book, reference is made to de Vries’s mutation
theory and that of orthogenesis. The former is quickly disposed of
in a couple of pages by stating first, that it cannot account for adapta-
tions because with each mutation many or all parts change and all the
changes cannot be adaptive. Secondly, an arising mutation will be
swamped by intercrossing with the original stock. “Hence the multi-
plicity of our actual species cannot be due to mutations.” Now that
we know that species cannot be due to mutations it is to be hoped that
people will please stop speaking about them. Similarly in regard to
orthogenesis the theory is stated in one paragraph and then — “we
need not delay long with this theory, because we know that the foun-
dation of it is unsound.” Thus authority speaks and an obedient
scientific world will quickly forget that the theory was ever held by
anyone. The folly of any other theory of evolution than Darwinism
of the Weismannian brand is overwhelmingly demonstrated in every
chapter by persuasive arguments and appealing examples. ‘The nec-
essary limitations of natural processes are so clearly set forth that
the investigator has only himself to blame if he wastes time investigat-
ing any other theories of evolution; for, has not the author shown

that they are all impossible?
C. B. D.

46 THE AMERICAN NATURALIST [Vor. XLI

Momentum in Variation. — It is a little late to criticize an article
that appeared in November, 1905, nevertheless I should like to say a
word or two in regard to the paper by Mr. F. B. Loomis entitled
“Momentum in Variation.” The conclusion is reached that a varia-
tion started along any line tends to carry that line of development to
its ultimate, being driven by momentum. If the feature is detrimen-
tal, the group dies out. If, however, it is merely a minor feature, it
makes a handicap.

No one doubts that in the course of evolution, specialization goes
so far as to carry a given species or group out of existence, but that
this is of such widespread occurrence as Mr. Loomis implies, is open
to doubt. Certainly the statements which he adduces to support
‘this theory, are in many cases erroneous and in other instances open
to quite other deductions than are placed upon them.

The few comments here given, are not at all in the line of captious
criticisms, but are merely intended as a protest against any such
short-cut to a solution of important problems as that taken in the
paper in question.

If we begin with the Saber-toothed Tigers, which are cited as
examples of extinction due to overdevelopment, we may go back
about twenty years to the time when Professor Cope reached a similar `
conclusion, saying in the course of some discussion that Smilodon
undoubtedly became extinct because it could not obtain food, where-
upon someone present arose and said: “Mr. Cope, what did the
Smilodon feed on”? In connection with this Dr. Matthew has
recently brought forward some facts tending to show that the long
tusks of Smilodon were of service in cutting through the long hair and
thick hide of some of the contemporary ground sloths. Certainly if
the tusks of Smilodon caused its extinction, why does not the Walrus
die out for a similar cause? The Mammoth with its extreme develop-
ment of tusks is also cited to illustrate the principle of momentum in
variation, leading to extermination, but the great Gangetic elephant
which shows the most enormous development of tusks, became extinct
long ago, while other members of the race whose tusks were far more
recurved lived on. Nor did those mastodons in which the tusks were
greatly curved, come to an untimely end one whit sooner than their
contemporaries with fairly straight tusks. The African Elephant,
which is much the most primitive in structure of existing species, and
more nearly resembles E. ganesa in tusk development, is the species.
that has thrived best. Moreover, the African elephant is the one in
which tusks are present in both sexes while a large proportion of the

No. 481] NOTES AND LITERATURE 47

females of Asiatic Elephants are tuskless, so that here we have a case
in which tusk development has gone beyond sex differentiation.

If Babirussa seems to be handicapped by its teeth, though there is
another side to the case, how about Mesoplodon, in one species of
which the teeth lock over the beak so that the animal can open its
mouth for a short distance only and yet shows no signs of passing out
of existence.

The elongation of the snout of Teleosaurus is cited as another dis-
advantageous character but the Gangetic Gavial in which the snout
is nearly as long, finds this of great service in catching fish, as un-
doubtedly Teleosaurus did, and Dr. Abel gives elongation of snout
as characteristic of fresh-water cetaceans.

Stegosaurus did not come to an end on account of its heavy armor
but from some other cause, for the active predatory dinosaurs, such
as Allosaurus, that were unincumbered by any defensive armor, died
out just as did their heavier-plated contemporaries. The male
Narwhal which has a single long tusk lives in the same sea and just
as long and happily as his tuskless spouse, and many similar instances.
might be cited. The problem of the extinction of animals is far too
complicated to be decided in haste and few of the examples cited by

r. Loomis seem to be conclusive.

F. A. Lucas

Xenia in Wheat.'— As everyone has noticed, when white sweet
corn is pollinated with red corn the outer part of the grains, although
not truly part of the embryo, is red. This is a case of so called xenia.
Xenia has been observed in other cases also, notably in beans and
in wheat. Tschermak has recently studied xenia in wheat in more
detail. He experimented with two races — the Hanna wheat and the
Petkus wheat. Both kinds of wheat when in bud yield both green
and yellow seeds; but yellow Hanna wheat gives 80% of yellow grains.
and green Petkus wheat breeds almost pure (95% of green seeds).
The green Hanna and the yellow Petkus wheats when inbred yield
only about half of their own kind respectively. Tschermak finds.
that when green and yellow Hanna wheats are cross-bred the seeds
resulting show the color of the mother stock, whichever is so used.
Likewise when the green and the yellow Petkus wheats are crossed

1Tschermak, E., “Ueber Züchtung neuer Getreiderassen mittels Künst-

licher Kreuzung, II.” Zeitschr. f. d. landw. Versuchswesen in (Esterreich, 45.

pp., Feb., 1906.

48 THE AMERICAN NATURALIST [ Vor. XLI

the seeds have only the maternal color. On the other hand, when the
opposite colors are derived from different races, and, especially, when
the father is either yellow Hanna or green Petkus, the paternal char-
acter shows strongly on the seeds. Consequently, xenia is better
manifested in wheats that are not very closely related than in those
that are.

C.B.D.

ZOOLOGY

Folsom’s Entomology.'— Dr. Folsom’s new work occupies a
unique place among entomological text-books. As stated in the
preface, “the book was written in an effort to meet the growing
demand for a biological treatment of entomology.” To this end the
systematic side of the subject has been confined to a mere outline of
the orders, following essentially the system of Brauer. The external
anatomy, too, has been very briefly touched upon as that has been
emphasized by the current texts.

On the other hand, there is an admirably clear-cut discussion of
the elements of internal anatomy and of physiology. The value of
this chapter lies not only in the careful organization of the material
presented but in the omission of a vast amount of detail. The author
has followed a common error in stating that the alary muscles are
unstriated. He speaks of the follicular cells of the ovary as derived
from the primitive germ cells, — a view which is not held by recent
investigators of this subject. In view of the decisive work of Petrunke-
witsch and other of Weismann’s ‘students one is surprised to see, p.
145, the statement that “males may, of course, result from fertilized
eggs, as in the honey-bee, according to Dickel.”

The chapter on development likewise shows the virtue of vigorous
pruning. There is a very brief but excellent outline of the embryo-
logical development, while the greater portion of the chapter is devoted
to the postembryonie development.

: Folsom, J. W. Entomology, with Special Reference to its Biological and
Economic Aspects. Philadelphia, Blakiston’s Son & Co., 1906. 8vo, vii +
485 pp., with 1 col. pl. and 300 illustrations.

No. 481] NOTES AND LITERATURE 49

The remainder of the text is largely devoted to biological phases of
the subject. Much material which is not accessible in any other text
is here brought together and is treated from a broad biological view-
point. The subjects of color and coloration; the origin of adaptations
and of species, distribution; the relation of insects to plants and to
other animals; their interrelations and their behavior, are treated in
a concise but most readable and interesting manner.

Though the method of treatment is professedly economic as well as

biologic, the practical aspect of the subject receives but scant attention.
The relations of insects to plants, and to other animals, are discussed
from the view-point of the biologist. Six pages are devoted to an
excellent summary of the important subject of the transmission of
disease by insects. The sixteen pages on insects in relation to man
are largely given over to a statement of the importance of the subject
and to an historical sketch of the progress of economic entomology in
America.
The illustrations are excellent and, in many cases, new and prepared
by the author. Such as have been copied are very carefully credited.
An extensive and carefully arranged bibliography will be very helpful
to the student.

Dr. Folsom is to be congratulated on the clear, concise, and interest-
ing presentation of his material. The book is one which is bound to
prove stimulating, and which every worker in the field of entomology
and every teacher of zoölogy will want in his own library. Whether
it will meet the present day demands for an entomological text-book
is a question. `

WAR.

Additional Observations on Hyla andersonii and Rana virgatipes
in New Jersey. — An effort was made this past summer to add to the
observations on Hyla andersonii and Rana virgatipes published in
two previous numbers of the American Naturalist.

It was observed in June at Lakehurst that the males of Hyla ander-
sonii were attracted to a few small pools in particular, several of which
were only a yard or two in diameter. On July 21st, with Mr. James
Chapin, I made search in these pools for the tadpoles, and was fortu-
nate in finding a number in one pool, though they appeared to be
absent from another and similar locality about a mile distant where the
adult frogs had been and were still most numerous. The tadpoles col-
lected were in all stages from a few millimeters long to those just leav-
ing the water as little frogs. The mature tadpoles are from 35 to 40
mm. long and of the usual tadpole color, that is, of the color of the

50 THE AMERICAN NATURALIST [Vor. XLI

muddy bottom of a pool. The under parts are lighter and show a
golden sheen, which sometimes extends up the sides. ‘The small hind
legs show early on the ends of the toes the disks that are so conspicu-
ous in the mature Hyla. The tail is spotted, and there is usually a dark
irregular marginal band. The maculations sometimes become irreg-
ular blotches as on the tails of the tadpoles of Hyla versicolor. When
the tail is nearly absorbed, and they leave the water, they are about
25 mm. long and of a dull olive green. They grow lighter, that is,
brighter green in hue with the disappearance of the tail, until the
little frogs, which in length of body are 15 mm., resemble the mature
individuals. The white that margins the green of the back and ex-
tremities is not so conspicuous as in the adults, and the saffron of the
under parts is wanting in those that I have examined. ‘The narrow
band of purplish brown that commences at the nose and extends
through the eyes and so down the sides is conspicuous in the little
frogs before the last remnant of the tail has disappeared.

The adult Hyla andersonii is amusingly active at night and jumps
about the lower limbs of the trees and on to the bushes with much
agility. They seem rarely to climb over five or six feet from the ground.
They sit upright and look pert, and if interrupted in the midst of their
song they leave their bubbles blown up until such time as the intruder
goes away or stands still. In the day time they are usually quiet and
for the most part hide in the damp moss and leaves lying on the ground.

On the warm cloudy evening of August 10th, Hyla andersonii was
heard near some pools a short distance north of the village of Farm-
ingdale, N. J. This locality is 15 miles northeast of Lakehurst,
which has been the most northern locality for the frog heretofore
recorded.

Rana virgatipes may be called the Carpenter Frog, for its note
sounds much like the blow of a hammer on a board. It is a quickly
uttered chuck-up, chuck-up, and the frog usually hammers from three
to four times. For a time I was not sure of the singer, but some
captive individuals under the influence of good living have uttered
this call-note in my room while I sat by. These frogs domineer over
one another to some extent, and when insects were placed in the cage
as food, it was common for the more active individual, failing in the
attempt to catch a fly, to turn on his companion and butt him until
he retreated into the pool or into a corner. The butted individual
would hold his head down in the meekest manner, and he became so
cowed that if I touched him at any time with my finger, he assumed
the humble position. Miss Dickerson in The Frog Book says that

No. 481] NOTES AND LITERATURE öl

Rana pipiens and Rana onca will snap at the head of a companion
frog that has taken a worm that he was trying to capture, but she
thinks it is probably not an exhibition of anger, but a desire to secure
the disappearing worm. However this may be, it is certain that
the butting Rana virgatipes in the above-mentioned case secured a
great advantage over the other frog, for after “settling” his companion,
he captured all of the insects.
Wittram T. Davis

Zoölogical Laboratory Notes.— In the form of loose leaves bound
together so that they can be individually removed, T. H. Sheffer?
has prepared a set of laboratory notes on about two dozen common
animals. Such notes are usually so arranged as to excite in the
student a desire to study the material before him; this set described
rather fully what he “ought” to see and is well calculated to kill any
real growing interest he may have. The author thinks the notes
should commend themselves to teachers “by reason of certain special
advantages and a simple and rational treatment in general.”

Notes.— Circulatory Organs of Diotocardian Gastropods. The
study of the heart of the diotocardians by Spillmann (“Zur Anatomie
und Histologie des Herzens und der Hauptarterien der Diotocardier.”
Jen. Zeitschr. f}. Naturwiss., vol. 40, pp. 537-538, pls. 19-21) justifies
the separation of the Rhipidoglossa from the Docoglossa. In the
Rhipidoglossa the pericardial chamber is penetrated by the intestine,
and there are two auricles. While the auricles are thin-walled and
deficient in muscle, the ventricle has a thick muscular wall of three
layers. The openings from the auricles to the ventricle are guarded
by lamellar valves. In the Docoglossa the intestine does not penetrate
the pericardial chamber, and only the left auricle is present. This
has the same structure as in the Rhipidoglossa, but the ventricle of
the Docoglossa shows only two of the three layers seen in the Rhipido-
glossa. In the Docoglossa the opening from the auricle into the
ventricle is provided with a tubular valve. Nerita forms an interesting
transition between these two groups so far as the structure of its heart
is concerned. It may be called a docoglossan with a penetrated
pericardial chamber or a rhipidoglossan with lamellar valves.

Goblet Cells in the Epidermis of Fishes. According to Oxner

‘Scheffer, T. H. The Loose Leaf System of Laboratory Notes. P. Blakis-
ton’s Son & Co., Philada., 1906, 112 pp.

52 THE AMERICAN NATURALIST [Vor. XLI

(“Ueber die Kolbenzellen in der Epidermis der Fische.” Jen.
‚Zeitschr. f. Naturwiss., vol. 40, pp. 589-646, pls. 22-26) goblet cells
occur in the epidermis of cyclostomes and most physostomous teleosts.
All goblet cells are modified epithelial cells from the deepest or germinal
layer of the epidermis. ‘They are undoubtedly specialized unicellular
glands which may have in addition some supporting function.

The Selachian Eye. From a study of the eyes of some eighteen
species of sharks and rays Franz (‘‘Zur Anatomie, Histologie, und
functionellen Gestaltung des Selachierauges.’ Jen. Zeitschr. f. Natur-
wiss., vol. 40, pp. 697-840, pl. 29), has shown that while there are
many specific differences, the eyes of this group as a whole are clearly
distinguishable from those of other vertebrates. What is especially
peculiar in them is the tapetum lucidum, an epithelial musculature in
the iris instead of the usual mesodermal one, a specialized zonula
zinnii, and the absence of a falciform process characteristic of other
fishes. The adaptations shown by the eyes of different species are
discussed at some length.

G HT.

BOTANY

Bergen and Davis’s Principles of Botany.' — One of the most
successful American elementary botanical text-books has been Bergen’s
Foundations of Botany. With its author, Dr. Davis has been asso-
ciated in the preparation of the present book, which is certain to find
favor with the users of its predecessor and to win many new friends
since in addition to what was best in the earlier text there is now
given a consecutive series of studies of representative spore plants
so treated as to outline the evolutionary history of the plant world.
Both authors are experienced teachers, and also familiar with research
problems at first hand, and they have brought to their task unusual
care in grouping and handling the subject matter and in well illus-
trating it.

The book is said to furnish material for a full year’s work. It
contains, indeed, enough to occupy considerably more than this time,

* Bergen, J. Y., and Davis, B. M. Principles of Botany. Boston, Ginn
& Co., 1906. 12mo, ix+555 pp., 14 pl., 402 figs. `

No. 481] NOTES AND LITERATURE 53

if all of its topics were thoroughly worked over; but the purpose of
its authors has been to present somewhat more than is likely to be
used, so that individual teachers may find it comprehensive enough
to base on it courses adapted to their several needs. It is safe to say
that it will be a much consulted book even in laboratories where other
manuals are used to outline the courses given.

Wit.

Rydberg’s Flora of Colorado.‘ As a precursor to his flora of the
entire Rocky Mountain region, Dr. Rydberg has prepared a manual
of the Pteridophytes and Spermatophytes of Colorado, which, for
extent and carefulness of work stands well to the front among our
State floras. Forty-nine orders, 134 families, 702 genera, and 2912
species find representation in it. "The nomenclature used is essentially
after the Philadelphia Code. Generic limits are confessedly rather
radically close, and the same may be said of the limitation of species.
Apparently good keys are given for the higher groups, genera, and
species; but descriptions are limited to these, though ample data are
given as to habitat, distribution, ete., and considerable synonymy is
added.

Wat.

Notes:— The recently issued fifth volume on the Congress of Arts
and Science, held in connection with the Louisiana Purchase Expo-
sition of 1904, (Boston and New York, Houghton, Mifflin & Co.,
1906) deals with Biology, Anthropology, Psychology and Sociology,
and contains the following addresses of botanical interest: — Coulter,
“Development of Morphological Conceptions”; Loeb, “The Recent
Development of Biology”; De Vries, “A Comparison between Arti-
ficial and Natural Selection”; Bower, “Plant Morphology”; Goebel,
“The Fundamental Problems of Present Day Plant Morphology”;
Wiesner, “The Development of Plant Physiology under the Influence
of the Other Sciences”; Duggar, “Plant Physiology — Present Prob-
lems”; Arthur, “The History and Scope of Plant Pathology”; Waite,
“Vegetable Pathology an Economic Science”; Drude, “The Position
of Ecology in Modern Science”; Robinson, “The Problems of
Ecology”; Jordan, “Relations of Bacteriology to Other Sciences” ;
Smith, “Some Problems in the Life History of Pathogenic Micro-
` Organisms.”

‘Rydberg, P. A. “Flora of Colorado.” Bulletin 100, Agricultural
Experiment Station of the Colorado Agricultural College, Fort Collins, Col.,
1906. 8vo, xxii + 447 pp.

54 THE AMERICAN NATURALIST [Vor. XLI

The second volume of Postelsia, the Yearbook of the Minnesota
Seaside Station, issued from the Pioneer Press of St. Paul, contains
the following papers: — Rosendahl, “Observations on Plant Dis-
tribution in Renfrew District of Vancouver Island”; Butters, “ The
Conifers of Vancouver Island”; Evans, ‘““Hepatic of Vancouver”;
Hone, “Some Western Helvellinee”; Griggs, “Renjrewia parvula,
a New Kelp from Vancouver Island”; Henkel, “A Study of Tide-
pools on the West Coast of Vancouver Island”; and Hall, “Some
Geological Features of the Minnesota Seaside Station.”

The weaving of stem and branches into a pseudo-trunk, by their
aérial roots, is described and figured for Hemitelia by Schoute in vol.
20, part 2, of the Annales du Jardin Botanique de Buitenzorg.

An illustrated paper on the medullary rays of Conifers, by Tassi,
forms part of the recently issued vol. 8, fasc. 1-4, of the Bullettino
del Laboratorio ed Orto Botanico of the University of Siena.

An illustrated paper on the leaf structure of certain New Zealand
plants, by Miss Herriott, is published in vol. 38 of the Transactions
and Proceedings of the New Zealand Institute, which also contains
other papers of botanical interest.

A study of unlignified cellulose in certain wood cells, and of the
cellulose skeleton remaining after the delignification of others, is
separately issued by Spaulding from the 17th Annual Report of the
Missouri Botanical Garden.

Non-nitrogenous food reserves, and irritability, occupy a large part
respectively of the recently issued first and sixth volumes of the Recueil
del’ Institut Botanique Leo Errera, of the Brussels University.

Part 11 of Koorders & Valeton’s “ Additamenta ad Cognitionem
Flore Arboree Javanice” has recently been issued at Batavia as no.
2 of the M ededeelingen uitgaande van het Departemente van Landbouw.

An account of the botany of Christmas Island, by Ridley, is contained
in the recently issued no. 45 of the Journal of the Straits Branch of
the Royal Asiatic Society.

Considerable attention is given to Natural History in Sir Harry
Johnston’s book on Liberia (London, Hutchinson & Co., 1906, 2 vols.),
an appendix on the flora being contributed by Stapf.

A number of generic segregates are published by Greene in the
signature of his Leaflets issued on September 8th.

No. 481] NOTES AND LITERATURE 55

A considerable part of the June number of the Revista de la Facultad
de Agronomia y Veterinaria of the La Plata University is occupied
by an illustrated account of Ilex paraguayensis and its commercial
preparation, by Uzal.

Ribes viburnifolium is figured in Curtis’s Botanical Magazinefor
September.

A further discussion of Primula obconica and its poison, with figures
of the glandular hairs, is contributed by Weydahl to Gartenflora of
Sept. 1

An illustrated monograph of the typical varieties of Nicotiana
tabacum by Anastasia, has been issued from the R. Instituto Speri-
mentale Tabacchi, of Scafati, Italy.

Sprenger briefly describes his hybrids of Yucca aloifolia in the
Bullettino della R. Società Toscana di Ortieultura for August.

A fine flowering mass of Yucca recurvijolia, as grown at Kew, is
figured in the Gardeners’ Chronicle of August 18.

A sumptuous quarto volume on American fossil Cycads, by Wieland,
has been issued as Publication no. 34 of the Carnegie Institution of
Washington.

A paper on the cytology of Entomophthoracee, by Riddle, forming
no. 63 of the “Contributions from the Cryptogamie Laboratory of
Harvard University,” occupies vol. 42, no. 10, of the Proceedings of
the American Academy of Arts and Sciences.

A number of new Philippine ferns are described and figured by
Copeland in vol. 1, supplement 2, of The Philippine Journal of
Science, issued on June 15.

Palmer contributes a paper on the nature of Diatom motion to vol.
1, no. 4, of the Proceedings of the Delaware County Institute of Science,
of Media, Pa

Papers on chromogenic fungi which discolor wood, and the zonation
of artificial cultures of certain moulds, by Hedgecock, have been sepa-
rately issued from the 17th Annual Report of the Missouri Botanical
Garden.

An illustrated synopsis of Portuguese galls is given by Tavares in
roteria, vol. 4.

56 THE AMERICAN NATURALIST [Vor. XLI

The dune-fixing planting of Cape Cod is illustrated by Birge in

The American Inventor for September.

An illustrated forestal account of Sequoia is given by Sterling in
School Science and Mathematics for October.

A series of “Botaniker Porträts,” each accompanied by a short
but comprehensive biographic sketch, is being issued in quarto fascicles
by Dörfler of Vienna. Judging from the two fascicles thus far issued,
the quality of execution and accuracy of text are unimpeachable.

Kellogg contributes a paper on the scientific aspects of Luther
Burbank’s work to The Popular Science Monthly for October.

PUBLICATIONS RECEIVED
(Regular exchanges are not included)

Bergen, J. Y., ano Davis, B. M. Principles of Botany. Boston and New
York, Ginn and Co., 1906. 12mo, ix + 555 pp., illus. $1.50.— GUENTHER,
C. Darwinism and the Problems of Life. A study of Familiar Animal Life.
London, A. Owen and Co., 1906. 8vo, 426 pp.— Horver, C. F. Halj Hours
with Fishes, Reptiles, ond Birds. New York, American Book Co., 1906.
12mo, 255 pp., 244 figs. 60 cts.— Hoven, T., AND ee W. T. The
Human Mechanism, its Physiology and Hygiene and the Sanitation of its Sur-
roundings. Boston, Ginn and Co., 1906. 12mo, ix + 564 pp., illus.—
Howe, R. H., JR., AnD M. A. Common and Conspicuous Lichens of New
England. A Fieldbook for Beginners. Part IV. Boston, W. B. Clarke and
Co., 1906. 16mo, pp. 57-71, illus. 50 ets.— INGERSOLL, Ernest. The
Life of Animals. The Mammals. New York, the Macmillan Co., 1906.
8vo, xi + 555 pp., illus.— Jennines, H. S. Behavior of the Lower Organisms.
New York, The Macmillan Co., 1906. 8vo, xiv + 366 pp., illus. $3.00.—
Linvitte, H. R., anb Ketiy, H. A. A Text-book in General Zoölogy. Boston,
Ginn and Co., 1906. ne x + 462 pp., 233 text-figs. $1.50.— MILLIKAN,
R. A., AnD Gare, H. G. boratory Course in Physics for Secondary Schools..
Boston, Ginn and Co., peony 12mo, viii + 134 pp., illus.— MONTGOMERY,
T. H. The Analysis of Racial Descent in Animals. New York, Henry Holt.
and Co., 1906. 8vo, xi + 311 pp.— Seat, Wm. W., anb Braanen, C. O..
Pagan Robes of the Malay Peninsula. New York, The Macmillan Co., 1906.
8vo, 2 vols., xl + 724, x + 775 pp., illus. $13.00.— Wricur, C. T. Field,
Labcratory, and Library Manual in Physical Geography. Boston and New
York, Ginn and Co., 1906. 8vo, xii + 178 pp. + 164 pp. of ruled sheets.
$1.00.

Apams, G. E., anD WHEELER, H. J. Continuous Corn Culture. R. I.
Agric. College, bull. 113, pp. 99-114.— Barger, H. G. Hemiptera from

no. 9, pp. 255-289.— Barrscu, P. The Urocoptid Mollusks from the Main-
land of America in the Collection of the United States National Museum.
Proc. U. S. Nat. Mus., vol. 31, pp. 109-160, pls. 3-5.— Barner, F. A. The
Species of Botryocrinis: Ottawa Nat., vol. 20, pp. 93-104.— Bran, T. H.
A Catalogue of the Fishes of RE with Notes on a Colleetion made in

Illinois. IU. State Geol. Surv., bull. 2, 109 pp., 6 pls.— Bouvier, E. L. Sur
les Gennadas ou Pénéides bathypélagiques. Bull. Mus. Océanogr. de Monaco,
no. 80, 13 pp.— Bouvier, E. L. Observations sur les Pénéides du genre
Halinorss Sp. Bate. Bull. Mus. Océanogr. de Monaco, no. 81, 11 pp.—
BOWNOCKER s er Salt Deposits and the Salt erg in Ohio. Geol.
Surv. Ohio, se 4, bull. 8, xv + 42 pp., 6 figs.— Ca Yy, M. On the Diurnal.
Lepidoptera of thè Athabaska and Mackenzie Ragen. British America.

57

58 THE AMERICAN NATURALIST [Vor. XLI

Proc. U. S. Nat. Mus., vol. 31, pp. 425-457.— Cons, J. N. The Commercial
Fisheries of Alaska in 1905. U.S. Bureau Fisheries, doc. 603, 46 pp.— COBB,
N. A. Methods of Using the Microscope, Camera-Lucida and Solar Projector
for Purposes of Examination and the Production of Illustrations. Ist Ann.
Rept. Div. Path. Phys., Exp. Sta. Hawaiian Sugar Planters’ Assn., 29 pp.—
Combre, J. Observations sur la périodicité du développement de ıa flore
algologique dans la région toulousame. Bull. Soc. Bot. France, ser. 4, vol. 6,
pp. 390-407.— DELLINGER, O. P. Locomotion of Amcebe and Allied Forms.
Journ. Exp. Zoöl., vol. 3, pp. 337-358, pls. 1-2.— Evans, A. W. Notes on.
Japanese Hepaticæ. Proc. Washington Acad. Sci., vol. 8, pp. 141-166, pls.
6-8.— EvERMANN, B. W., AND SEALE, A. Fishes Collected in the Philippine
Islands by Maj. Edgar A. Mearns, Surgeon, U. S. Army. Proc. U. S. Nat
Mus., vol. 31, pp. 505-512.— Farrman, C. E. New or Rare Pyrenadiyieteie
from Western New York. Proc. Rochester Acad. Sci., vol. 4, pp. 215-224,
pls. 20-22.— Farrineton, O. C. Zoisite from Lower California. Field
Columbian Mus., geol. ser., vol. 3, no. 4, pp. 55-57, pl. 28.— Fawcert, H. S.
Variation in Ray Flowers of Anthemis cotula and Other Composites. Proc.
Iowa Acad. Sci., 1905, pp. 55-59, pls. 12-20.— Fısuer, W. K. New Star-
fishes from the Pacific Coast of North America. Proc. Washington Acad. Sct.,
vol. 8, pp. 111-139.— Fer, E. P. The Gipsy and Brown Tail Moths. N.Y.
State Mus., bull. 103, 42 pp., 10 pls.— Ferr, E. P. Twenty-first Report of
the State Entomologist on Injurious and Other Insects of the State of New
York. N. Y. State Mus., bull. 104, 186 pp., 10 pls— Frernatp, H. T. The
Digger Wasps of North America and the West Indies belonging to the Sub-
family Chlorionine. Proc. U. S. Nat. Mus., vol. 31, pp. 291-423, pls. 6-10.—
Garcia, F. European Grapes. N. Mex. Coll. Agric. and Mech. Arts, Agric.
Exp. Sta., bull. 58, 32 pp.— GARDNER, N. L. Cytological Studies in Cyano-
phycee. Univ. of Calif. Publ., bot., vol. 2, pp. 237-296, pls. 21-26.— GIL-
MORE, C. W. Notes on a Newly Mounted Skeleton of Merycoidodon, a Fossil
Mammal. Proc. U. S. Nat. Mus., vol. 31, pp. 513-514, pl. 12.— Herrera,
A.L. Invasion de gusanos en los estados del centro de la Republica. Com.
Parasitol. Agric., circ. 45, 14 pp.— Herrera, A. L. Destruccion de los
mosquitos en las habitaciones con el polvo de crisantema. Com. Parasitol.
Agric., circ. 48, 5 pp.— Hrpricka, A. Anatomical Observations on a Collec-
tion of Orang Skulls from Western Borneo; with a Bibliography. Proc. U. 8.
Nat. Mus., vol. 31, pp. 539-568.— Inpa, J. R. Una plaga de insectos llama-
dos “fraileeillos” en el valle de Mexico. Com. Parasitol. Agric., cire. 46, 8 pp.
— Inpa, J. R. EI tabaco como insecticida. Com. Parasitol. A „ cire

dactyloptera. Bull. Mus. Océanogr. de Monaco, no. 79, 6 pp , 1 pl.— JORDAN,
D. S. AND Snyper, J. O. A Review of the Peeciliide or Killifishes of Japan.
Proc. U. S. Nat. Mus., vol. 31, pp. 287-290.— Jorpan, D. S., AND STARKS,
E.C. A Review of the Flounders and Soles of Japan. Proc. U. 8S. Nat. Mus.,
vol. 31, pp. 161-246.— Jorpan, D. S., ann Starks, E. ©. Notes on a Collec-
tion of Fishes from Port Arthur, Manchuria, Obtained by James Francis
Abbott. Proc. U. S. Nat. Mus., vol. 31, pp. 516-526.— Jousın, L. Descrip-
tion des némertiens batho pélaginiaes capturés au cours des derniéres cam-
pagnes du Prince de Monaco (1890-1905). Bull. Mus. Océanogr. de Monaco,
no. 78, 25 pp.— Karprnsky, A. Die Trochilisken. Mém. Comité Géol. St.

No. 481] PUBLICATIONS RECEIVED 59

Pétersb., n. s., livr. 27, viii + 166 pp., 3 pls.— Kniıs#t, H. G., Hepner, F. E.,
AND NELSON, A. Wyoming Forage Plants and their Chemical Composition —
Studies No. 2. Wyo. Exp. Sta., bull. 70, 75 pp., 31 figs.— Lyon, M. W., Jr.
Notes on the Slow Lemurs. Proc. U. S. Nat. Mus., vol. 31, pp. 527-538, pl.
13.— Lyon, M. W., Jr. N: of a Sew Species of Great Ant-eater
from Central America. Proc. U. S. Nat. Mus., vol. 31, pp. 569-571, pl. 14.—
Macıas, C. La destruccion de las ratas y In ratones del campo. Com. de
Parasitol. Agric., cire. 41, 25 pp.— Mancın, M. L. Cours d’océanographie
fondé à Paris par S. A. S. le Prince Albert de Monaco. (Deuxième année.)
Distribution des algues: algues fixées, algues du — Bull. Mus.
Océanogr. de Monaco, no. 82, 32 pp., 3 pls.— Merk, S. E. Description of
Three New Species of Fishes from Middle America. Op ield Columbian Mus.,
zoöl. ser., vol. 7, no. 3, pp. 93-95.— MILLER, G. S., Jr. The Mammals col-
lected by Dr. W. L. Abbott in the Rhio-Linga Archipelago. Proc. U. S. Nat.
Mus., vol. 31, pp. 247-286, map.— Moore, J. P. Hirudinea and Oligochæta
collected in the Great Lakes Region. Bull. U. S. Bur. Fisheries, vol. 25, pp.
153-171, pl. 32.— NıcHnoss, H. W. New Forms of Concretions. Field
Columbian Mus., geol. ser., vol. 3, no. 3, pp. 25-54, pls. 19-27.— Nıcoras,
F. J. Catalogue of Publications of the Geological Survey of Canada. Geol,
Surv. Canada, publ. no. 956, 129 pp.— Orton, E., JR., AND PEPPEL, S. V.
The Limestone Resources and the Lime Industry in Ohio. Geol. Surv. Ohio,
ser. 4, bull. 4, xv + 361 pp., 53 figs.— PEPPEL, S. V. The Manufacture of
Artificial Sand Stone or Sand-lime Brick. Geol. Surv. Ohio, ser. 4, bull. 5,
79 pp., 8 figs.— Ramarey, F. Plants of the Florissant Region in Colorado.
Univ. of Colorado Studies, vol. 3, pp. 177-185, 1 pl.— Ramarey, F. The
Seed and Seedling of the Mountain Globe-flower. Univ. of Colorado Studies,
vol. 3, pp. 93-95, 1 pl.— Sarte, C. J. Arthropycus and Dædalus of Burrow
Origin. Preliminary Note on the Nature of Taonurus. Proc. Rochester
Acad. Sci., vol. 4, pp. 203-214.— SCHAEFFER, C. On New and Known Genera
and Species of the Family, Chrysomelide. Sei. Bull. Mus. Brooklyn Inst.
Arts and Sci., vol. 1, no. 9, pp. 221-253.— Stocom, A. W. A List of Devonian
Fossils Collected in Western New York, with Notes on their Stratigraphic
Distribution. Field Columbian Mus., geol. ser., vol. 2, no. 8, pp. 257-265,
pls. 79-80.— Smirn, H. M., ann Pore, T. E. B. List of Fishes Collected in
Japan in 1903, with Descriptions of New Genera and Species. Proc. U. S.
Nat. Mus., vol. 31, pp. 459-499.— SPRINGER, Frank. Discovery of the
Disk of Onyctigeritins and further Remarks on the Crinoidea Flexibilia.
Journ. of Geol., vol. 14, pp. 467-523, pls. 4-7.— SPRINGER, F., AND SLocoM,
A wW. ypsocrinus, a New Genus of Crinoids from the Devoniat.
Columbian Mus., geol. ser., vol. 2, no. 9, pp. 267-271, pl. 81.— StEBBING,
TRR AN Costa Rican Amphipod. Proc. U. S. Nat. Mus., vol. 31,
pp. 501-504, pl. 11.— Tassın, W. Note on an Occurrence of Graphitie Iron
in a Meteorite. Proc. U. S. Nat. Mus., vol. 31, pp. 573-574. 7 B, S. BUREAU

Scorr, J. M. The Duty of Well Water and the Cost and Profit on Irrigated
Crops in the Rio Grande Valley. N. Mex. Coll. Agric. and Mech. Arts, Agric.
Exp. Sta., bull. 56, 52 PP-— Votapora, A. EI chapulin, chocho 6 langosta.
Com. Parasitol. Agrie. ., circ. 47, 7 pp— Warp, H. A. Three New Chilian

60 THE AMERICAN NATURALIST [Vor. XLI

Meteorites. Proc. Rochester Acad. Sci., vol. 4, pp. 225-231, pls. N
WELLER, S. The Geological Map of Illinois. Ill. Geol. Surv., bull. 1, 26 pp.,
map.— WHEELER, H. J., AND HARTWELL, B. L. RER u
R. I. Agric. Exp. Sta., bull. 115, 114 pp.— WHEELER, H. J., HARTWELL, B. L.,

Wesseıs, P. H., AnD Gray, J. P. Commercial Feeding-stuffs. R. I. Aade
Exp . Sta. „ bull. 112, pp. 77-96.— Wuirman, C. O. The Problem of the
Origin of Species. Congr. Arts and Sci., Universal Exposition, St. Louis,

p.

Conpor, vol. 8, no. 5.— Economic GEoLoGY, vol. 1, nos. 6, 7.— ELTKA,
vol. 7, no. arg en SCHOOL JOURNAL, vol. 6, no. 10.— JOURNAL OF GEOG-

RAPHY, vol. 5 . 7.— JOURNAL OF GEOLOGY, vol. 14, no. 6.— KENTUCKY
AGRICULTURAL ae Sration. Report on the Enforcement of the
Pure Food Law. 197 pp.— Le Mots SCIENTIFIQUE, vol. 8, no. 10.— Missouri

BOTANICAL GARDEN. Seventeenth Annual Report, 1906, 181 pp., pls.—
Museu Geetpr. Boletim, vol. 4, no. 4.— NATURE NOVITATES, vol. 28, nos.
12-15.— NATURE-Stupy Review, vol. 2, no. 6.— La Nuova NOTARISIA,
ser. 17, Oct., 1906.— ROCHESTER ACADEMY OF SCIENCE. Proceedings, pp-
231-344.— St. Lours Mepicau REVIEW, vol. 54, nos. 9, 10, 12.— UNIVERSITY
OF COLORADO STUDIES, vol. 3, no. 4

(No. 480 was issued December 19, 1906)

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THE JOURNAL OF EXPERIMENTAL ZOOLOGY

EDIT
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CONTENTS OF VOLUME

UARY
Studies on Chromosomes. > The Sexual rences n the Chromosome-
ge in Hemiptera, with Some Considerations of the Determination of
ie B. Wilson
An Examination ‘of the Effe cts of Mechanical Shocks and viru Upon the
Ra Development of Fertilized Eggs eg D. Whitney
Re of the Parthenogenetic Der ent of Amphitrit sea W. Scott
The gg men t of Fundulus Heteroclitus in Solutions = Lithi m Chlorid,
iih Ap xon its Development in Fresh Water, Charles R. ‘Stockard
ial PEE En of the TEET E in Crayfish.
Experimental —— of Light as a Factor in the Regeneration Be, tara,

Goldfarb
No, 2 ULY, 1906
Experiments on the — ior = Tubicolous eea 5 Cc. argitt
Inheritance of Dichromatism in Lina and Gastroidea "Isabel ai
The Elementary Phadomena > Embryonic ie in Chetopterns.
oy Frank R. Lillie
The Rögenannitien “ot sites Pieces in Planarians. ey ` Lilian V. Morgan

POTAS, 1906
Locomotion of Amoebae d er Form ris P. Dellinger
The Influence = an and ers on the rim of the Chromatophore ves

me ecially = Liza A George H. Par

Light Rea n Low one isms. = "Stentor Coeruleus. soe © ice
Some cs x Sareri a Mot ,

Gen G. Mayer and Caroline G. Soul
Modifiability in Behavior. JE Factors Determining Direction and eier

rms, H. 5. Jennings

A Study of the Spermatogenesis of Cop tocyels Aurichalcea. and Coptocycla Gut-
tata, with nn Reference to Abe Problem of Sex Determination.

; W. N. Nowlin

. .

No. 4— IN Pre
The — of Gases and ee on theo Cardiac and erg Move-
E.

of the porous A. Walling

The Prey of Reg T. H. Morgan

Tors = ka Other Transitional Phenomena in “the Regeneration of the Cheliped
ictor

è Lobster (Homarus Ameri
The ae Between Portions lee and Form Wagidatton. C. M. Child
Studies on the Development of the pe Egg.
D. H. Tennent =. z4 J. Hogue
Hydranth Formation and Polarity in “Tubularia. H. Morgan

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VOL. XLI, NO, 482 FEBRUARY, 1907

THE
AMERICAN
NATURALIST

A MONTHLY JOURNAL
DEVOTED TO THE NATURAL SCIENCES
IN THEIR WIDEST SENSE

CONTENTS

Page
I, An automatic Aerating device for ee ‘ . DR. LOUIS MURBACH 61
II. The Flying-Fish Problem . . ,LIEUT.-COL. C. D. DURNFORD 65
III. Cataloguing Museum EEE PRO OR L. B. WALTON 77
IV. Some South American Rotifers ; . Y 97
V. Meristic Homologies in ts secre fe sent a dei AINGELENF 108
VI. On the Osteology of the Tubin . „DR. R. W. SHUFELDT 109

VII. Notes and Literature: ee Mae. ner and Agriculture,

a Analysis; Geology, River Terraces at Brattleboro, Vt.; Anthropology,
Quaternary Remains of Man in Central Euro n Races of

Malay Peninsula, Growth of Parisian Children, Autliropensbtzie Data
on the Norwegians, Population of Tripoli; Zoö/ogy, Dean’s Chimzroid
Fishes, Development of the Mammalian Lung, Half Hours with Fishes,

Reptiles and Birds, Notes; Botany, The Journals 125
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THE
AMERICAN NATURALIST

Vor. XLI February, 1907 No. 482

AN AUTOMATIC AERATING DEVICE FOR AQUARIA
LOUIS MURBACH

THE use of the water blast as a means of aérating is well enough
known to need no more than passing mention. Its cost is prohi-
bitive for smaller schools and its use limited to laboratories where
noise would not be a disturbing factor. Furthermore it may be
desirable to have an aquarium under observation in different rooms.
Some time ago a simple device was described (Amer. Nat., vol. 38,
no. 453, 1904, pp. 655-661, 2 figs.) which, however, necessitates
the exchange of the water in the aquarium. This might involve
the loss of organisms if the flow were continuous as from a tap, or
it would necessitate lifting the water periodically.

These were some of the difficulties I encountered when about a
year ago I wished to aérate some small aquaria containing sea
water, in a class room where fresh water was available, but a flow
of sea water could not be had. An ordinary filter or vacuum
pump was fitted into a calcium-chloride jar about 45 cm. tall.
The accumulating air in the jar was carried through the stopper
by a small tube to the aquarium. A ball valve of paraffin held
against the lower opening of the jar by a lever and weight was to
regulate the outflow of water. This and similar devices tried,
failed to regulate the varying pressure in the supply pipes, and was
not satisfactory. If regulated for the day when more taps were in
use, the pressure increased during the night, with few or no other
taps on, so that the fresh water overflowed through the air tube
and diluted the sea water.

The above obstacles were entirely overcome in a device that I
hit upon the past summer at the Marine Biological Laboratory

61

62 THE AMERICAN NATURALIST [Vor. XLI

Woods Hole, in attempting to a@rate the sea water in which Gonio-
nemus was kept, rather than to use the water from the pipe.
Other workers have carried water daily from the end{of the/pier
to get more favorable results than with the water from the pipes.

It remains to be seen whether aération and cooling will answer

From

d 3
NEED EEE PPA
2. 3
x a

IZZZZZZZIZIY,

il
I)
T miN

KKWv An
Air U

Air-Water
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Counterpoise

Valve

_ Nil
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these and other purposes. While I got very satisfactory results, .
yet my observations this season were not numerous enough to
warrant any general claim for all-around usefulness.

A general idea of the apparatus may be gained from the. agii
The things needed are a glass filter pump, two wide-mouth bottles,
about 8 X 15 cm., and 6 X 12 cm., a cork stopper to fit the larger

No. 482] AERATING DEVICE FOR AQUARIA 63

bottle, a stand with balance beam, glass and rubber tubing. The
stopper is bored with three holes, 5 mm., 8 mm., and 11 mm. in
diameter. Into the smaller holes are fitted a 24 em. long tube for
the air outflow and a 15 em. long tube for carrying the water from
the filter pump. ‘The 11 mm. hole is for a wooden rod, 15 mm. in
diameter and about 15 em. long. This is cut down tapering
abruptly from 15 mm. to 8 mm. the rest of its length. The larger
end of this rod serves as a valve in the 11 mm. hole in the stopper
being placed vertically’so that the stopper can glide freely along
the rod when placed in the inverted bottle.

A few details will be desirable for those who wish to try the appa-
ratus. After inserting the glass tubes as shown in the figure, the
wooden rod is inserted through the stopper from the side that goes
into the bottle. Then the small end of the rod is attached to a
block. Now the larger bottle is suspended in inverted position
from one end of the balance beam of the stand, the stopper is
inserted and the smaller bottle nearly filled with water is hung on
the opposite end of the beam for counter-poise. The block carry-
ing the wooden rod is moved about on the base of the stand until
the stopper moves easily up and down the rod, and is then fastened
in this position with a wood screw. ‘The length of the cord sup-
porting the inverted bottle should be so adjusted that the beam
on this side is a little higher than on the opposite side when the
stopper is drawn up against the head of the wooden rod as far as it
will easily go. If the head of the rod fits the hole in the stopper
accurately no water will escape when it is turned on until the
weight of water in the inverted bottle exceeds that of the counter-
poise. Now the weight of the counterpoise may be adjusted so
that it will keep the larger bottle about $ full of water, thus pre-
venting the escape of air except through the proper outlet. The
water and air should not discharge alternately and if this does take
place, a longitudinal groove may be cut into one side of the head
in the stopper until enough water escapes to balance the inflow
when the water pressure is at its lowest. From this on it will
work automatically. Several other forms of valves may be used
but I have found the one described the simplest.

If it is desired, more than one aquarium may be aérated with
the same apparatus by dividing the air with T-tubes and using

64 THE AMERICAN NATURALIST [Vor.. XLI

pinch cocks until the desired flow is obtained in each, necessitating,
however, more attention than the simpler form. ‘The main features
of this apparatus are: its automaticity, its noiseless action making
it suitable for the class room or laboratory table, its simplieity and
inexpensiveness.

Derrorr, Mica.

THE FLYING-FISH PROBLEM!

LIEUT.-COLONEL C. D. DURNFORD

In a paper published in the Annals and Magazine of Natural
History for January, 1906, the impossibility, from a mechanical
point of view, of a flying-fish accomplishing sailing flight was
shown. The argument was based upon the fact that as a flying
animal the flying-fish is equipped with wings of a fractional sail-
ing value compared with those of a sailing bird. Also that if the
wings were many times larger, so as to bring the fish on an equality
with the bird in this respect, it could only sail with the bird’s
limitations as regards direction of the wind, and with the bird’s
frequent assistance from rowing flight. Also that if the figures
(which can be easily verified or, if wrong, refuted) are correctly
given in the article, the accepted aeroplane flight is miraculous,
unless a new law of Nature be discovered.

It is, then, perhaps advisable, if the present curious condition
of the question is to be understood, to examine how it has come
about.

The flying-fish problem is a very odd one in many ways, of which
the most striking is the unexplained power therein of the negative
to quench the positive. Throughout we find the aeroplanist’s
“I cannot see the wing-movement” smothering a fairly equal
bulk of “I can, and have, and do see it.”

Let us create a parallel instance, for a real parallel does not
perhaps exist:— Many people can see bullets in their flight.
Many others with equally good, or even better, sight cannot pick
up the flying bullets. Now if those who fail to see them said, and
if all books and papers on shooting supported them in so saying,

1 This article was intended to appear simultaneously in the American
Naturalist and in the Annals and Magazine of Natural History but delays
in the mail prevented. The subject however is of such interest that its later
publication here may be pardoned.— Eprror.

65

66 THE AMERICAN NATURALIST [Vor. XLI

“I cannot see the bullets, therefore you, and all those who do see
them, do not see them,” we should have a parallel to the current
odd mode of conducting the flying-fish problem.

It is in consequence of this supremacy of the negative that the
flying-fish problem has earned for itself the name of “eternal,”
for as soon as one new witness can see the flight, either another
new one fails to do so, or a reference is made to some observer who
has formerly so failed; and this is equally satisfactory, for, in the
problem, even an old “I did not” is better than a new “I do.”

It might naturally be supposed that there must be an overwhelm-
ing backing of probability, both mechanical and natural, to the
negative evidence in order to justify such dogged denial to the
affirmative of its common value. So far, however, from this
being the case, it is a second odd fact that but one seemingly practi
cal effort at proof has been made, and with this one exception
aeroplane flight rests wholly upon the flat negative.

Let us examine this solitary attempt at proof.

‘I requote from an article, which may be taken as typical of the
system, in the ‘Annual Report of the Smithsonian Institution,’
1904, p. 498, by Dr. Theodore Gill, an emphatic aeroplanist: —
“ Möbius (1878, 1885) contended that ‘Flying-fish are incapable
of flying [the italics are his], for the simple reason that the muscles
of the pectoral fins are not large enough to bear the weight of their
body aloft in the air.’” If undisputed that is, without doubt, a
most powerful argument — decisive, in fact. But mark! almost
immediately Prof. Whitman, a high authority, denies its accuracy.
In the same article we find that this statement is “vigorously
objected to by C. O. Whitman (1880), who urged, ‘Admitting
that in form, size, length, and structure the pectoral fins of Exo-
cætus are less well adapted to flight than the wings of most birds,
there is still ample room to beliève, on anatomical and physiological
grounds alone, that they are capable of executing true flight.?”
This is a plain statement moderately worded by a distinguished
physiologist and naturalist, and it is interesting to note that it is
answered, as though by convincing argument, by the old irritating
impasse — the reference to views of distinguished naturalists as
to whether flying-fish fly or do not fly, and entirely ignoring the
new muscle aspect opened by Whitman.

No. 482] THE FLYING-FISH PROBLEM 67

Among the distinguished naturalists thus referred to in support
of Möbius’s theory, Prof. Moseley, as being of the “Challenger’
Expedition, and Mr. Boulenger are prominently mentioned. But
Moseley, who cannot see the Exocetus flapping, can see the Dac-
tylopterids doing so (p. 512): the possibility of which act is denied
by Möbius from personal observation as strongly as in the case of
Exocetus! Whilst Boulenger merely quoted the verdict of others,
he himself retained, then as now, as he informs me, an open mind
upon the question.

It is surprising how largely this ‘ ae verdict” is influenced
by the researches of Möbius, the very Professor whose solitary
so-called proof is questioned by Whitman; so we will examine
more closely what he says about the muscles. ‘The quotation is
continued from ‘‘‘aloft in the air,’” above.

““ The pectoral muscles of birds depressing their wings weigh,
on an average, one sixth of the total weight of the body, the pectoral
muscles of bats one thirteenth, the muscles of the pectoral fins of
flying-fish only one thirty-second.’”

If this proves anything — which to the purpose it does not —
it may prove that, as flying-fish have somewhat less than half the
comparative muscle of bats, and (according to aeroplanists) cannot,
for this reason, fly, therefore bats, which have somewhat less than
half the comparative muscle of birds, cannot fly.

Or, the other way about: — Birds can fly. Bats, having rather
less than half the comparative muscle of birds, can fly; therefore
flying-fish having rather less than half the comparative muscle
of bats, may fly.

Those are reasonable deductions, but “therefore flying-fish can-
not fly” is an unreasonable one. :

It is quite clearly a question of degree, and the true deduction
is that bats, if they can fly, cannot be expected to fly like birds, and
flying-fish, if they can fly, cannot be expected to fly like either
bats or birds; and, I may add, no one thinks or claims that they
do so fly.

But an even greater claim is made by aeroplanists. It is recog-
nized that there are two kinds of bird-flight, “sailing” and “ row-
ing,” the sailing being greatly the superior form. Sailers can always
row, but rowers cannot properly sail on account of their low wing

68 THE AMERICAN NATURALIST [Vor. XLI

to weight ratio.‘ Now flying-fish have a ratio of the lowest class
in comparison with birds (see ‘Annals,’ Jan. 1906, p. 162); yet
they are credited by aeroplanists with sailing of a higher form than
that of the best-equipped sailing birds — sailing, without even
occasional rowing assistance, at a slow speed, regardless of the
direction of the wind ! Such a feat — one utterly impossible for
an albatross, an eagle, a vulture, kings of flight — is given to
this last poor dabbler in the art upon persistently contradicted
negative evidence, two impossible parallels, and the one discredited
proof.

I have endeavored in the foregoing to show how observers have
been weighted and clogged by the unique system of handling an
admittedly difficult question — how a very able man, Prof. Möbius,
years ago undertook a research which required a very special knack
of eyesight in the observer. Probably the majority of men are
without this knack, and do not know it. Firmly believing what
I have endeavored to show must have been the false view pre-
sented to his retina, to be a true view, he wrote, with the cleverness.
that belonged to him and the dogmatism of the believer, the text
of the faith which has guided and misguided scientists for over a
quarter of a century. His reputation was, and is, deservedly
great — so great that his word was practically law, and it came
about that if other scientists possessed the knack of sight and
differed from him so much the worse for them; they must be either
ignored, or explained away, any or no explanation being sufficient
for such a proper purpose. ‘This is not a hard judgment. Any-
one, who is free from the superstition, on reading an ordinary
aeroplane article will recognize its justice.

\/wing-surface in sq. cm.
-iT

1 Harting’s formula , which governs this ratio

vV weight in grammes.
in birds, is impugned by R. von Lendenfeld in the volume that we have been
quoting from (Ann. Rep. Smith. Inst. 1904, p. 129). The figures of his ex-
ample in proof will not, however, bear examination. Correctly calculated
sian

they strongly support Harting (ae = 2°68, and not 4'03 as given by

Von Lendenfeld as the ratio of the partridge }.

? Some notes by Prof. Moseley (“Notes by a Naturalist on the ‘Challenger,’
p. 571, 1874) upon the small amount of true soaring performed even by the
albatross are instructive. Our eyesight misleads us again in this matter.

No. 482] THE FLYING-FISH PROBLEM 69

Take a quite typical example of the common aeroplane blind-
fold acceptance from writer to writer of palpable impossibilities
as guiding facts. In the article that we have been quoting from
we may note the following (p. 500): “The best estimate has been
that an ordinary flight may extend from 30 to 50 yards in less than
twenty seconds.” In order to get working figures we may call
“30 to 50 yards” 40 yards, and “less than twenty seconds” 15
seconds. ‘This gives a rate of 54 miles an hour!

Note this, you who watch the fish fleeing before a 14-knot
steamer.

Such statements are the habit of the problem. Just in the
same way is it its recognized habit to quote, unquestioned, as “ sail-
ing” parallels to the heavy small-winged fish, the ł-oz. large-
winged swallow, and the parachute whose work is falling only;
or, again, to faithfully reproduce over and over again pictures of
impossible air-currents performing feats also impossible; or to
continue to ascribe the frantic efforts at flight of a fish fallen on
deck to natural spasms, although it is not credited with active use

`

i
SCALE zZ

f

WING AREA

WING AREA

4O09 SMOTTWMS

of its wings either in air or sea; and so on. It is the way of the
problem, and no one is to blame.

Perhaps the odd unsuitability of the swallow comparison may
be brought more fully home by a sketch.

The ratio (Harting’s formula) of a swallow (house-martin) is
4.2, and its wing-area 120 sq. em. The flying-fish ratio is 2.6.
If we reduce the swallow to a 2.6 ratio, its wing-area becomes about
47 sq. cm.

This reduction to flying-fish ratio is shown by the shaded parts
of the sketch.

70 THE AMERICAN NATURALIST [Vor. XLI

Could anyone contend that a swallow could sail even in its pres-
ent poor and much-assisted way (for it is far from being a first-
class sailer) if the unshaded parts of the wing-areas were removed ?

Opinion is, however, undoubtedly changing. Many of the old
shibboleths are fast becoming discredited. ‘The great distances
that the fish, under favoring conditions, fly clear of the water *—
the fact that they fly in calms as in winds — that they come on
board ships from lee and weather sides indifferently — that they
can and do turn in air ? — that they often lose and often gain speed,
both from simple causes, on meeting a wave or on tail-dipping —
that they can and do at times gain speed whilst still in air — that
they make for lights deliberately — that they rise and fall of set
purpose while in the air: all these and much more that has been
under the ban are being witnessed and certified to so incessantly
that soon only the high-priests of aeroplane will be left contra-
dicting them.

. G. Aflalo (‘Natural Hist. of Anua: Macmillan & Co.,
1896) writes: “I have watched these beautiful creatures by the
hour and in all weathers, ....but after having closely watched
thousands of them through strong glasses, I cannot give as emphatic

‘It is difficult to judge distance at sea. The tendency is to underestimate
it. Many observers testify to having seen flights of more than a quarter of a
mile. Frank Bullen, in his article upon flying-fish in ‘Creatures of the Sea,’
insists that he has seen flights of over a mile. - He has had exceptional oppor-
tunities for observing them, and I see no reason for thinking that he is mistaken.

2 With reference to their turning powers. I mentioned in the former paper
a fish which'I had seen to turn back in air. I then restricted myself to the
bare facts required for the argument. It had interested me, however, much
at the time, not only because it was, to me, a rare occurrence, but also because
the controlling cause of the fish’s remaining and turning in air was quite
evident. The sea was rather calm and the ship was throwing out, with each
gentle roll and dip, those broad hissing tables of white foam which spread
away for many feet from her sides, and die in a mass of struggling bubbles,
to reappear as the white broad rushing table of the next dip. The fish had
risen independently of the ship, and was flying towards us at full speed, when
a sudden slow down marked its perception of the advancing monster. There
was no time, however, for it to decide whether water or air was the less perilous
before it was over an unusually broad table of boiling foam. The hidden and
fearful possibilities of this evidently decided it, and then ensued its slow but
successful struggle to turn and get clear of the concealed horrors. This it
did with what must have been a terrific effort, but it got quite round and
well away out into the blue water before it dived

No. 482] THE FLYING-FISH PROBLEM ei

an opinion as I should like on the oft-discussed question of whether
the wings vibrate like those of birds.... If the pectoral fins are
so constituted as to be capable of vibration, then I would say as
the result of my own observations that to some slight extent they
do flap, not like those of birds, perhaps, certainly not like those of
the bat.”

I have quoted the above as it expresses markedly two common
difficulties: (1) the real difficulty in discerning the movements;
(2) the pre-acquired idea that the wings are not fitted for flapping,
an idea which naturally greatly increases difficulty (1). Had Mr.
Aflalo been certain of the two facts that the wings were fitted for
flapping and that “sailing” was for the fish ordinarily impossible,
it cannot be doubted that his views would have been stronger and
expressed very differently.

Among quite recent papers upon this question, two should be
especially noted. Lionel E. Adams, B. A., writes in the ‘Zoologist’
(April 4th, 1906) an article interesting throughout. I quote from
p. 146: “.... I was often able to see them against the sky.... I
could see quite distinctly that their tails were vibrating very rapidly
from side to side during the whole flight, and that the wings would
vibrate with an intensely rapid shivering motion for a second, then
remain outspread motionless for one or two seconds, and then
vibrate again. ‘This vibration of the wings is not up and down as
in the case when birds fly, but in an almost horizontal direction.”

That is a quite possible explanation of the mode of flight, pro-
vided that a sufficient speed be acquired in the intermediate flap-
pings, but this the known speed of the fish shows to be not com-
monly the case.

Again, on p. 148: “I am perfectly well aware that a casual
glance at flying-fish from the lofty deck of a liner gives the impres-
sion that they soar like birds with motionless wings, but watch
them at close quarters from the deck of a low-waisted tramp and
the vibratory motion of the tail and fins will be quite plain.”

Interesting as is Mr. Adams’s paper, I cannot but think that he
is partly mistaken in his views, and that the wing-vibration which
he discerned was really less rapid than the movement in the period
following which he believed to be one of stillness, just as the line-
passengers ‘mistook his vibrations for stillness. I do not say that

72 THE AMERICAN NATURALIST ` [Vor. XLI

the fish could never arrive at a speed by which a very short aero-
plane flight could be attained even with their low ratio; but I do
say that such is not their common speed, and that in any case their
disregard of wind-direction disproves such flight.

Therefore another way must be looked for, and we are driven
‘back, perforce, to continuous wing-action, the manner of which
may be here examined as carefully as our information allows.

Premising that the flight varies greatly on different days and
under different conditions, the following is probably a fair aie A
tion of their methods in an ordinary flight :—

1. The tail-impelled, visibly (to many) wingsasäisted . jump
from the water to a height where the wings can work freely.

2. The flight continued by an intensely rapid and labored
wing-movement — one easily mistaken for stillness, and usually
seen, if at all, as blur.

3. Short periods of slowing down of wing-speed, during which
the wing-movement becomes again visible. (These are the “ vibra- -
tion” periods, representing to aeroplanists loose wing-trailing,
or dragging like a flapping flag—an impossibility; and, to Mr.
Adams, periods of wing-assistance — with limitations a possibility.)
These periods often precede a special spurt such as is required to
lift the fish over an oncoming wave.

4. Either sudden cessation of wing-movement and consequent
immediate drop into the sea or a short slow down into visibility
(No. 3) previous to such drop.

It is to be noted that this vibration so often seen before the fish
enters the water is one of the many pointers to continuous wing-
movement, for such a time is a proper one for slowing down, but an
absurd one for renewal of wing-effort.

To return to Mr. Adams’s paper. He notes, as have others,
the vibration of the wings as being in “an almost horizontal direc-
tion.” This horizontal movement, if it exists, as is probable,
may afford, as I hope to show, a looked for key to the fish’s action.

According to Pettigrew, it is a necessity of flight, where wing-
beats are in a more or less vertical direction, that the up-beat should
meet with little and the down-beat with much resistance from the
air. This is arranged for in the case of bats, birds, and certain
insects by means of special muscles and ligaments which automat-

No. 482] THE FLYING-FISH PROBLEM 73

ically flex the wing for or during the up-stroke, and extend it for
or during the down. (Pettigrew, ‘Animal Locomotion,’ Int.
Science Series, vol. vii. pp. 122, 182, 194, &c.: 1891.)

Marey (‘Animal Mechanism,’ p. 263 &c.: Int. Science Series,
1893) equally recognizes the necessity for a diminished wing-area
in the up-stroke, but believes it to be obtained in birds through the
natural elasticity of the feathers, which enables them to return to
their ordinary position when the resistance of the air in the down-
stroke ceases to raise them.

The flying-fish’s wing, as is known, is formed on quite a different
principle from that of a bird or bat. It opens and closes some-
what like a fan. A partial automatic closing of this fan at the foot
of the downward stroke in flight and opening at the top of the
rising stroke would both give the appearance of horizontal vibra-
tion when seen either from above or below, and would turn a sume-
what difficult question of the mechanics of the flight into a verv
simple one. Indeed we have here flying action on the same general
principle as that shown by Pettigrew and Marey to be necessarily
provided for in the case of bats and birds, but the working details
of which are different and simpler, as becomes a simpler form of
wing.

Perhaps that is the explanation. ‘There must, of course, be
some explanation, and that is not only the natural deduction from
the peculiar formation of the wing, but it also fits everything in.

The known (but indistinct) visibility of the larger rays of the
wings at times during flight points, perhaps, to a comparative
pause with wings full open before beginning the down-stroke.
Such pause would give the open position, and with it the wing-
tracery prominence.

The form of these fishes’ wings points to this fan-action rather
than to other known horizontal wing-actions of the nature of that
of certain insects — the common fly, for instance (Marey, loc. cit.
pp. 204, 206).

The second quite recent and very important observer and writer
on this subject is convinced of the flight-action. He writes also
from personal observation, and is as free from proper mechanical
bias as from the improper follow-my-leader habit. One of his
remarks, “It is by no means impossible that flying-fish may soar,

74 THE AMERICAN NATURALIST [Vor. XLI

as even [my italics] birds do this,” shows his mechanical freedom.
In a paper dated Oct. 28th, 1905, Brig ‘Galilee,’ North Pacific
Ocean, Dr. J. Hobart Egbert, Carnegie Expedition, writes (‘ Forest
and Stream,’ Jan. 27th, 1906): “Though still denied by some
observers, the power of propulsion through the air by means of
its fin-wings is generally accorded the flying-fish.t During months
at sea in the tropics the writer has almost daily watched the flying-
fishes and studied their flight through the air.... The difficul-
ties of assuring oneself that the flying-fish moves its wings during
its flight through the air are well understood, and also the fact
that these difficulties are generally removed when opportunity
is afforded of observing the flight of certain of the larger species
under favorable conditions. That flying-fishes use their wings
after the manner of birds, at least upon emerging from the water,
can hardly be denied, since from the fo’c’s’le head of a ship plying
the waters of the lower latitudes this wide bird-like motion of the
fin-wings may be easily observed as the large flying-fishes break
water almost under the vessel’s bow. This flapping motion of the
fin-wings is not, however, long maintained, but as soon as the fish
is well started in the air apparently passes into a vibratory motion
of the appendages so rapid as to be almost beyond human visual
perception.”

Quite so. That is the to-be-expected flight of an exceptionally
low-ratio flyer having special added natural disabilities. Before
long it will be the accepted one for flying-fish.

More about the Pectoral M uscles.

Since writing the foregoing I have received a communication
from Prof. C. Stewart, F. R. S., Conservator of the Museum of
the Royal College of Surgeons, who kindly gives me permission
to use the results of a dissection made at the Museum for the pur-
pose of comparing the pectoral muscles of the flying-fish with
those of a nearly related non-flying fish.

I quote from the letter of Mr. a who made the dissection :—

1A little nan if Natural Histories and Encyclopædias are any indi-
cation of general ac DD,

No. 482] THE FLYING-FISH PROBLEM 75

“Royal College of Surgeons of England,
incoln’s Inn Fields,
London, W. C., 18th June, 1906.

“Dear Sır, .... I have made a dissection of the pectoral
muscles of a flying-fish (Exocetus sp.) and of a nearly related fish
of much the same build, but without the enlarged pectoral fins
(Hemiramphus). Both were specimens from our store-room,
and although in pretty good condition had evidently been in spirit
for a considerable time. I enclose you tracings of the drawings I

S u
F
$ È
W

as
es
ae
NaS
xD
Wo

“~*~ Shoulder girdle.

INTERNAL
SURFACE.

INTERNAL
SURFACE

-

"Er
EN
Se
Rs
R S
ExocÆæTus _ HEMIRAMPHUS

made. The two of the external view were drawn with a camera,
and the Hemiramphus, which was rather less in girth than the
Exocætus, was so much enlarged as to have the same girth about
an inch behind the pectorals. I thought that body-girth sufficiently
far behind the fins not to be influenced by their degree of develop-

76 THE AMERICAN NATURALIST [Vor. XLI

ment was the best standard of size to take — better than length,
for instance. As a matter of fact, the fish were very much the
same length; the Exocetus being rather the longer.

“The drawings, I think, explain themselves. The flying-fish
muscles were, as you see, considerably larger, both in area and in
thickness, than in Hemiramphus, and the same was the case with
the muscles on the deep surface of the fin. In their arrangement
they were much the same in both fish and the same as in other
bony fishes (the cod, for instance). The numbers on the surface
of the fins are the points where I took the thickness of the muscles
by plunging a needle into it and measuring the depth to which the
needle entered. You will notice the great length of the muscles
in Exocetus: a long muscle means a proportionate length of con-
traction.

“.... there is a very marked difference in the size of the muscles
of these two fishes... .

“Believe me, yours faithfully,
R. H. BURNE

(Assistant in Museum).

The above tracing seems to give, roughly, about 4$ times greater
bulk of muscle to the Exocætus than to the Hemiramphus. With
this light it will not be out of place to requote and amplify the one
“proof,” distinguishing the addition by italics: — “'The pectoral
muscles of birds depressing their wings weigh on an average one
sixth the total weight of their body, the pectoral muscles of bats one
thirteenth, the muscles of the pectoral fins of flying-fish.... one
thirty-second,” and the muscles of a nearly related non-flying fish
only one hundred and fifty-fourth.

As before, it does not prove that bats or flying-fish flap or do
not flap their wings, but it gives a different and, I hope, a proper
aspect to the figures which have done duty — of a kind — for so
many years.

CONTRIBUTIONS TO MUSEUM TECHNIQUE
I. CATALOGUING MUSEUM SPECIMENS!

L. B. WALTON

AN essential feature in connection with a museum, is the main-
tenance of a careful record or history of the objects forming the
various collections, since a specimen deficient in data referring
to the locality, date and conditions under which it was obtained,
is practically valueless in comparison with one correctly catalogued.?

The inadequacy of the systems commonly employed, even in
prominent museums of America and Europe,’ by which rarely
more than a number, name, and locality of uncertain value, are
more or less heterogeneously arranged in cumbersome and often
inaccessible volumes,‘ is apparent to any one who has attempted
‘to locate a desired spegimen, or when fortunate enough to ascer-
' tain the location, to obtain concise information concerning it.
This condition of affairs is particularly obvious to the systematist
wishing to study the material belonging to a certain group or
from a definite area in a museum, for he may indeed be considered

1 Contributions from the Biological Laboratory of Kenyon College, No. 5.

? I have merely given expression to the principle laid down by Goode in
his admirable paper on museum administration (Annual Report of the Mu-
seums Association, 1895, also republished in the Annual Report of the Smith-
sonian Institution, 1897) where he says, “A museum specimen without a
history is practically without value and had much better be destroyed than
preserved.”

3 The museums as well as many other institutions abroad, are subservient
to precedents which, under the changing conditions, have too often outlived
their usefulness. The remarks of Dr. Meyer in a note on a succeeding page
(unintentionally on his part) furnish excellent evidence in corroboration of
the above statement.

* Both the Field Museum of Chicago and the Carnegie Museum of Pittsburg
make use to a limited extent of card or slip catalogues in connection with the
book system. From their form and size (34 X 9} in the former, 53 X 8
inches in the latter museum) method of filing, and arrangement of data how-
ever, it is questionable whether a decided advance has been made over the
old book catalogue.

B THE AMERICAN NATURALIST [Vor. XLI

a fortunate individual if, after the loss of much time examining
the collections on exhibition and in storage, both catalogued and
uncatalogued, and in consulting the various volumes in which the.
data are supposed to be kept, he obtains the data which he wishes.’

Consequently the following suggestions in respect to the cata-
loguing (often spoken of as ‘registering’ or ‘recording’’) of
specimens have been brought together primarily with a view
toward facilitating the maintenance of such records in museums
of Natural History, although it is hoped that they may prove of
practical advantage in connection with other institutions of a sim-
ilar nature. The paper was outlined and partially written while
engaged in the rearrangement of certain collections in the American
Museum of Natural History, New York, during the summer of
1901. The completion, however, although a brief review was pub-
lished in the Ohio Naturalist for 1904, has been delayed in order
to make further inquiries concerning the systems of cataloguing
used in various museums, as well as for the purpose of profiting by a
more extended practical application of the method. ‘This latter
result has been accomplished in the cataloguing of specimens dur-
ing the last three years for a foundation of a small museum at
Kenyon College. . It may be noted that very few changes from the
plan first proposed have been rendered necessary.

The literature relating to the subject of cataloguing museum
specimens is chiefly conspicuous by its absence, notwithstanding
the mass of information in regard to museums and museum admin-
istration which has been brought together in the Museum Journal
and a few other periodicals devoted to the interests of such insti-
tutions, and. in the papers by Meyer :00-03, Gratacap :02-03,

"In a vigorous article by. Bather (How may Museums best retard the
Advance of Science, Annual Report of the Museums Association, p. 90-105,
1896) some of the difficulties of locating museum specimens are described as
follows. “Many years ago I journeyed to Strassburg on purpose to examine
certain specimens that had been described by Mr. de Loriol. The various
curators whom I met at the Museum assisted me very willingly throughout
three days searching for these specimens, but they could not be found, and I
went on my way sorrowing. Arrived at Freiburg, I mentioned the fact to
my friend, Professor Steinmann, who suggested that possibly the specimens
might have been overlooked as being in the Cartier collection. At consider-
able expense and inconvenience I therefore returned to Strassburg, and sure
enough, there were the specimens carefully obscured.”

No. 482] CATALOGUING MUSEUM SPECIMENS 79

Murray :04, ete. Meyer (p. 419) briefly outlines the method used
in the Field Columbian Museum, while Murray (v. l. p. 264) some-
what naively suggests that “As a rule it is of importance that the
exact locality from which each specimen has been obtained
should be recorded....This does not apply to archaeological
objects alone....The date of finding or acquisition is often like-
wise of importance.”

There are nevertheless a few papers which should be mentioned.

Hoyle, ’91, described the cataloguing of specimens in the Man-
chester Museum and formulated a system of ‘registration’ in book
form, and of ‘cataloguing’ through the use of cards. His regis-
tration catalogue corresponded to that designated in the succeed-
ing pages as The Department Catalogue. It consisted of four-
teen volumes bearing reference letters A-O, beginning with A-
Mammals, B-Aves, etc., and ending with N-Mineralogy, and O-
Anthropology. Each volume contained space for 12500 speci-
mens and was ruled in perpendicular columns so that space for
data concerning ‘date,’ ‘name,’ ‘locality,’ and ‘remarks,’ was
afforded. When a specimen arrived at the museum, the first
vacant number in the volume corresponding to the group to which
the specimen belonged, was affixed to it and the data concerning
it noted in the appropriate column. After the specimen was thus
‘registered’ (i. e., our Department Catalogue) it was farther cata-
logued in what Hoyle described as the “Curators Catalogue”
(i. e., our Reference Catalogue) by means of which an official
record of the contents of the museum arranged according to a
natural classification, was maintained. This is very similar to
that which I have termed The Reference Catalogue. It con-
sisted of a buff ‘family-card’ 5 x 3 $ inches, on which the name
of the family (e. g. CIDARIDAE) was written, a gray ‘genus card’
containing the generic name (e. g. Cidaris), and a white ‘species
card’ having the specific name (e. g. hystrix) and the mode of
preservation, the register number (i. e. department number), and
locality.

The method of registration presents, in comparison with a
card system, the usual disadvantages of the book catalogue as
noted on a succeeding page. The absence of a practical means
of cross indexing the various volumes by tabs and colored cards

80 THE AMERICAN NATURALIST [Vor. XLI

representing systematic divisions, geographical distribution, type
specimens, etc., is at once manifest. Furthermore no space is
given for noting the authority for identification, date collected,
etc., name of collector, etc., for all of which data provision should
be made.

The “Curators Catalogue” may be criticized on this same
basis. Moreover in a catalogue, the chief purpose of which is
that of a reference or finding catalogue, there seems every reason
for arranging the cards in alphabetical order in preference to
classifying on a systematic basis. Hoyle, himself, in noting some
objections to the decimal system proposed by Petrie in Nature,
mentions the fact that “no specialist is ever satisfied with any other
specialist’s work.” Furthermore unless arranged according to
the alphabet as suggested under the Reference Catalogue, it would
be of no value to the public. The cards adopted should naturally
be of a standard size since odd sizes cannot be perfectly cut by
reason of the expensive machinery used. Ordinary ‘guide cards’
would be much better than the ‘genus’ and ‘family cards.’

Dorsey, ’99, reviewed the method of cataloguing used in the
Field Columbian Museum of Chicago. As suggested in a preced-
ing footnote, this appears to be more or less of an heterogeneous
arrangement of cards, books, and manilla envelopes, which could
be much simplified.

Walton, :04, published a brief outline of the present paper noting
the division into (a) The Accession Catalogue, (b) The Depart-
ment Catalogue, and (c) The Reference Catalogue, as well as
suggesting the general scope and methods of filing the cards
employed in each.

Wray, :05, called attention to the adoption of the card system
in the Perak Museum of the Federated Malay States, a result
brought about by the unsatisfactory nature of the book method
of cataloguing. A single type of card (3 X 5 inch) was used.
This contained the following data: ‘Accession No.,’ ‘Date when
received,’ ‘Place in Museum,’ ‘Description of Specimen,’ ‘Where
procured,’ ‘How obtained,’ ‘Presented by,’ ‘Bequeathed by,’
‘Purchased from,’ and ‘Collected by.’ Duplicate cards were
made out, one set being filed numerically as a ‘Register,’ the
other according to the arrangement of the specimens in the museum

No. 482] CATALOGUING MUSEUM SPECIMENS SI

(each museum case being given a number, and each gallery a letter,
e. g. 17 F) as a ‘Catalogue.’ The ‘Register’ evidently corre-
sponds to that which I have designated the ‘Department Cata-
logue,’ lacking the method of cross indexing by departments,
marginal tabs, and colored cards (when desirable). ‘The 3 x 5
inch cards used by Wray are too small, while the writing of two
sets for each specimen nearly doubles the clerical work involved
in the use of an Accession, Department, and Reference catalogue
as noted in the following pages, since by the latter method a large
number of specimens are usually transcribed on a single depart-
ment and reference card. Space for certain valuable data is like-
wise omitted by Wray, something unavoidable however with the
small card.

From the first it seemed evident that the mal catalogue arranged
in unit cabinet sections would furnish the most satisfactory solu-
tion of the problem. ‘The value of such a system had long ago
been recognized in connection with library and general business
methods, where it rapidly displaced the bulky volumes formerly
considered necessary to contain various records. ‘The advan-
tages resulting from the use of the card system are obvious, since
(1) the required data are presented in a compact and easily acces-
- sible form; (2) the capacity is unlimited, useless records can be
taken out or new ones added; (3) by varying the position of the
tab * on the upper margin of the card, as well as by using cards
of different colors, a variety of cross reference systems may be
employed; furthermore, (4) the form of the card allows the con-
densation of matter which would extend across one or more pages
in a catalogue.

The standard sizes of cards’ manufactured in America, are 3X5,
4 X 6, and 5 X 8, inches, and although other sizes could be made
and used, it is well to adopt one of these, inasmuch as the regular —
card cabinet section can thus be employed as a unit and the special
machinery used is particularly adapted for the three sizes. The
3 X 5 inch cards are too small, and for general purposes the 5 x 8

1 The word ‘ on is the term applied to the projecting portion of the upper
margin a the e

* The Re size ’ (No. 33), adopted by the erg Library Asso-
ciation in pea for library use, is 125X75 mm. (2¢} X 43% in.).

82 THE AMERICAN NATURALIST [Vor. XLI

inch cards are too large and unwieldy. The 4 X 6 inch card,
however, is of sufficient size to contain all necessary data, without
being cumbersome in manipulation.

Card cabinets to contain the catalogues may be obtained in
various sizes, but by the adoption of the ‘unit’ card index section
containing six drawers adopted for the 4 X 6 in. card, future
units may be added as occasion demands, and the cabinet is thus
always complete.

Following a chronological order, the data which should be
rendered accessible in an adequately catalogued collection, can be
separated into three divisions. These are: (A) The Accession
Catalogue, containing a general record of all material received
by the museum. (B) The Department Catalogue, giving a com-
plete history of each specimen or group of specimens, (a single
species, acquired by each department. (C) The Reference Cata-
logue, having the names of all specimens belonging to each depart-
ment, arranged alphabetically so that the final disposition of any
desired specimen can at once be ascertained.

Of these, the Accession and Department catalogues are essen-
tial from a business as well as a scientific standpoint, while the
Reference catalogue, although not a necessary requisite, will be
found advantageous as a reference index to the specimens, particu-
larly in the larger museums. With the exception of the one per-
taining to accessions, which should be in charge of the director of
the museum, each catalogue should be controlled by the head of
the particular department with which it deals.

While the records considered necessary vary more or less in
connection with the needs of the institution and department con-
cerned, they can in general be reduced to the following tabular
form, covering the data which may be required in Museums of
Natural History.

A. Accession Catalogue (arranged numerically).

1. Accession number.
2. Date received.

3. Description.

4. How obtained.

a. Purchase (cost ).
b. Gift.
c. Exchange.

No. 482] CATALOGUING MUSEUM SPECIMENS 83

d. In trust.
e. Museum collectors.
5. From whom received.
6. Address.
7. ‘Transportation number.
8. Collector.
9. Locality where collected.
10. Date when collected (approximate).
11. Correspondence filed under.
12. Remarks.
13. Date of entry.
B. Department Catalogue (arranged numerically)
1. Department number.
2. Accession number.
3. Original number.
4. Number of specimens.
5. Sex.
6. Stage of growth.
7. Scientific name.
8. Authority for identification.
9. Date of identification.
10. Locality where collected.
11. Name of collector.
12. Correspondence.
13. Date when collected.
14. Character of specimens.
15. Remarks.
16. Date of entry.
C. Reference Catalogue (arranged alphabetically)
1. Name of specimen (common name and scientific
name,— genus, species,— listed on separate cards).
Department number.
3. Character of specimen.
Location.
a. On exhibition. Case No.
b. In storage. Drawer No.
5. Number of specimens.
The following suggestions have been found valuable in regard
to the data and their arrangement on the cards.

>

84 THE AMERICAN NATURALIST [Vor. XLI

A. ACCESSION CATALOGUE.

In this catalogue, all material * received or collected at a partic-
ular time from a particular source, (an accession), is placed under
a single accession number. ‘Thus the catalogue will contain a
record of each group of specimens coming into the possession of
the different departments in the museums, and by means of a
series of cross references, consisting of tabs arranged as indicated

Ja
voran N numo Y E W
ACCESSION CATALOGUE
seen wo 294 KENYON COLLEGE MUSEUM Gg Xi "OL
escarion OL mmol collictiow of fide, ee do
25 mounlucd, 15 Exchange
shins page lectors
anen 32 Kar TRANSPORTATION ur
ADDRESS Wuwvv, Obur.
COLLECTOR. sane ae re
WHEN COLLECTED Ong, Spk or

Bm a 1962, sory eae ;

A

or Enry \O-XT-O%

Kenyon College Museum

Fia. 1.— Cards (4 X6 in.) from Accession Catalogue. The position of the nee nn
a the various ‘departments’ into which it is convenient tos ot > “see
en nis of data is here uniform for each depar
ser yet eg d year card are represented. The ee Es ae ro
guide lines is not ns wg

in the accompanying illustration (Fig. 1), it will be possible to
ascertain at any period the data concerning the accessions acquired

! While it is equally the same whether one specimen or one million specimens.
are received, the terms ‘particular time’ and ‘particular place’ are Swen
subject to eonsiderable latitude in their interpretation. If cert

several different accession numbers. For example, if cards of various colors.
eigen geographical distribution (e. g. Nearctic, ete.), it would be necessary
t many accession cards as there were regions represented in the par-
ticular aie

No. 482] CATALOGUING MUSEUM SPECIMENS 85

by each department, whether they have been obtained by pur-
chase, gift, exchange, through museum collectors, or in trust,
and if by purchase, their cost, as well as the particular fund made
use of in connection with their acquisition.

The disposition of each item on the card should correspond to
its relative importance. In the following diagram (Fig. 1) a
convenient arrangement is suggested.

Classification by Departments.— A classification by departments
can be conveniently maintained by having tabs arranged on the
cards in as many different positions as there are departments.
Thus with ? inch tabs as in Fig. 1, eight departments may be
tabulated.

Accession number.— This should occupy a prominent place, pref-
erably the upper left hand corner, and in order that it may be
easily noted, should be written in a large plain figure with black
orred ink.” ‘The numbers should be serially arranged in accordance
with the date of arrival of the accession, and at intervals of one
hundred cards, a numbered guide card of a particular color (e. g.
dark blue) may be inserted. Where no previous catalogue of
this nature has been kept, it may be well to have new accessions
commence with a number sufficiently large (e. g. 1001) to allow
the eventual cataloguing of former collections which have come
into the possession of the museum ° in a manner as nearly chrono-
logical as possible.

Date received.— The most convenient formula for expressing
the date on which an accession is received, is the use of an Arabic
numeral for the day of the month and a Roman numeral for the
month, followed by the year (e. g., 6-IX-1898= September 6,
1898). The usual place for the date is the upper right hand mar-
gin. At the end of every year, a card can be inserted, on the tab
of which the particular year is indicated (Fig. 1). Thus the mate-

‘It is perhaps unnecessary to remark that in records of this nature india
ink should always be employed and cards of the best quality be used. Inks
made of aniline colors will fade within a few years.

2 When accession catalogues have been maintained separately by the
departments, the numbers in the new catalogue must be of a higher order
than the sum of the previous ones used, provided it is desired to maintain
the approximate chronological order.

86 THE AMERICAN NATURALIST [Vor. XLI

rial obtained by the museum during any particular period is at all
times readily ascertained.

Description of material— The general nature of the consign-
ment should be indicated, (e. g. archeological material, mammal
skeletons, fishes) as well as the manner in which it is packed (num-
ber of packages, boxes, ete.). In this connection a record should
also be kept as to whether the accession is received as a ‘purchase,’
‘exchange,’ ‘gift,’ ‘in trust,’ or through ‘museum collectors.’
This can be readily accomplished by having the above words
written on the card and placing a cross in the proper space at the
time of cataloguing. When procured by purchase, the price
should also be indicated.

From whom received.— The name and permanent address of
the person sending the specimens, is to be noted here.

Transportation number.— It is often convenient to have a rec-
ord of the number or numbers placed upon the consignment by
the transportation companies, particularly in the event of break-
age or loss of any of the contents of a package or box.

Name of collector. Many collections are deficient in labels
bearing accurate information, consequently it is advisable to ascer-
tain the names of individuals concerned in collecting the speci-
mens, so that if desirable, further data may be obtained. ‘The
address of the collector is to be noted, provided it differs from that
of the locality where the collection was made.

General locality.— When the collection is a small one nn a
restricted locality, this can be readily indicated. If, however,
a large amount of material is represented, the principal region or
regions should be given.

Date when collected— It is necessary to indicate merely the
approximate time.

Correspondence.— In order to readily refer to correspondence,
invoices, bills, and other memoranda relating to the accession, it
is well to indicate the initial name or number, together with the
year, under which they are filed.’

Remarks.— Under this heading can be noted the condition of

‘Madeley :04 presents an elaborate arrangement for the classification of

office papers in Museums based upon a provisional decimal system. It seems
unfortunate that the standard decimal system (Dewey) was not utilized.

No. 482) CATALOGUING MUSEUM SPECIMENS 87

the specimens whether or not the collection contains any forms of
particular value (types, cotypes, etc.), as well as other general
information.

General suggestions.— In order to record small collections,
which may come directly to a department, blank cards may be
provided for those in charge, and upon the arrival of such an
accession, these should be immediately filled out and handed to
the person keeping the Accession Catalogue. Blank cards to be
similarly filled out and returned, can be sent to a person from whom
an accession deficient in data.is received. ‘The system of cross
references can be arranged to meet any demand. ‘The method
employed as noted above, appears adequate for ordinary purposes.
Thus the name of each department is placed on a tab assigned to
a particular position, and when the cards are filed, the accessions
of a department will be indicated by the corresponding row of
tabs. A further subdivision which may be applied to each depart-
ment is in the use of colored cards. se for prampie' the department
of anthropology , possesses tl upon which
to draw for as many purposes, e. gå r Explorations on the North
Pacific Coast. (b) The purchase of Michigan Antiquities, and
(c) Collections illustrating the life of the Aztecs; all accessions in
Anthropology of (a) obtained by purchase, or at the expense of
the museum from the one fund, can be placed on salmon colored
cards, while similarly all accessions of (b) and (c) obtained from
the corresponding appropriations can be placed on buff and blue
cards, respectively. Thus at any time the general condition of
the various funds of the department can be readily ascertained.
Geographical Distribution (e. g. nearctic, neotropical, etc. may be
represented in a similar manner.

Placing numerical guide cards at intervals of every hundred
cards, will greatly facilitate finding any desired accession number.
In a catalogue where the width of the tabs makes it possible to
have an area at the right from which no tabs project, it is con-
venient to place the numerical tab as in Fig. 1.

Inasmuch as the majority of accessions cover a quantity of
specimens, such a catalogue as the one described can be easily
maintained, and the advantages which result through always
having correctly classified data accessible are an important item
in the making up of reports. |

88 THE AMERICAN NATURALIST [Vor. XLI

B. DEPARTMENT CATALOGUE.

The department catalogue has the cards arranged numerically
in chronological order and should contain concise information
concerning each specimen, or group of specimens belonging to
the same species which were obtained at a definite time and place.
In the smaller museums the material may be grouped under depart-
ments of Zoology, Botany, Palzeontology, etc. as represented by

Number of

ZOOLOGY
DEPARTMENT CATALOGUE

Specimens =
Acc’n KENYON COLLEGE MUSEUM
Fa n e ee EA >
rg.
No. 17.18.19 Growth Oda Lt

“WANE Salvelinus fontinalis (mitend

IDENTIFIED DATE OF
BY

W. Other. IDENTIFICATION 21 -vi -< 1903
WHERE COLLECTED Salw Tupigow, Comado.
eorecron W. Onnbtar, Cland , Ohio , COLLECTED 21 -vu-03

CHARACTER OF

“SPECIMEN 24°, Ferma Ada Ah Twawsfornd to Torma tuw- Mh
CORRESPONDENCE ORR “24% “od. Snake W2, 03.
REMARKS "17218 Lak ew a Mownal Hy. iq ew ov Parwnroshense

Gell: CMe mind, $to.

DATE OF ENTRY Lb IX-03
1903-3

Fic. 2. Department Catalogue, Zoology, cards (4 X6 in.), en arrangement of däta,
and method of systematic cross index tind 27 position of small marginal tabs (e. g.
Fishes, Amphibians, Birds, etc.). The color of the card ae a second system
of cross er illustrating m geographical ern (e. g. white= Knox Co.
Ohio; salmon=Ohio exclusive of Knox Co. all territory ale of Ohio.
Numerical En year ee mide are da bank

the Accession Catalogue (Fig. 1) each with its separate depart-
ment catalogue. In the larger museums, however, it will often
be advisable for each department to have several sub-depart-
ments or group catalogues having the rank of departments. For
example the department of Zoology may maintain catalogues of
Vertebrate and Invertebrate Zoology, or of Pathological prepara-
tions, Neurological specimens, etc., or on a systematic basis it
may have a catalogue for each phylum or branch of the animal
and plant kingdoms. ‘The cross-reference classification by means

No. 482] CATALOGUING MUSEUM SPECIMENS 89

of tabs, however, as represented in the department catalogue
(Fig. 2) will usually be sufficient in the smaller museums.

Here the arrangement of data will meet the needs of the average
department. Near the middle of the upper margin of the card
should be placed the name of the particular department to which
it refers, together with the name of the institution. If the depart-
ment is large so that group catalogues are necessary, this should
also appear, e. g. Zoology Department Catalogue, South African
Museum, Birds.

Systematic cross reference classification by tabs. — The classifi-
cation adopted will depend on the nature of the catalogue. If
half-inch tabs are used on a 6 inch card twelve divisions are possible
which in the zoological department cards above consist of 1.
Mammals, 2. Birds, 3. Reptiles, 4. Amphibians, 5. Fishes, ete.
6. Tunicates, 7. Echinoderms, 8. Articulates, 9. Mollusca, 10.
Vermes, 11. Coelenterates and Sponges, and 12. Protozoa. For
certain reasons an arrangement in the reverse order would be
more logical. In a botanical catalogue one could choose between
the older classification of Eichler, 1883, where a somewhat arbitrary
grouping gives us the 1. Algae, etc., 2. Lichens, 3. Bryophytes,
5. Ferns, 6. Gymnosperms, and 7. Angiosperms, and the recent
one of Engler,' 1904, with thirteen groups and 35-40 classes. The
classification adopted in the other department catalogues, Paleon-
tology, Anthropology, ete., will in a similar manner represent to
a more or less extent the personal equation of the curator under
whose supervision they are maintained.

Geographical cross reference classification by colors.— Geograph-
ical distribution may easily be indicated by having cards of
a particular color represent definite areas. Such an arrange-
ment does not appear to render the card system so complex that it
is disadvantageous, although over-systematizing is a danger which
confronts any general method.

If the collection is local in its character, the majority of speci-
mens being obtained from a given state, an excellent arrangement
is that of having all specimens from the county in which the col-
lection is located, catalogued on white cards; all specimens from

1 Engler, A. 1904. Syllabus der Pflanzenfamilien, 4th edition, Berlin.

90 THE AMERICAN NATURALIST [Vor. XLI

the state excluding the county, catalogued on buff colored cards
while other specimens from localities outside of the state would
be catalogued on salmon * colored cards. In the larger museums
where collections are made up of specimens from different parts
of the world, certain colors can be used to represent various regions,
(nearctic, neotropical, palsarctic, etc.). Types, cotypes, ete.
could be catalogued on cards having the right half red, the left
half in accordance with the color representing the een geo-
graphical distribution.

Department number. — A single department number will cover
a series of specimens of the same species, which have been obtained
at the same time in a particular locality. ‘This method is more
satisfactory than assigning a number to each individual specimen
inasmuch as time would be lost by such a method and no particu-
lar benefits result. Should the occasion arise at a later period,
a separate number may be assigned to any specimen.

Accession number. — ‘This should be indicated on the card, in
order that general information regarding the collection may be
obtained at any time. The accession number and department
number may be indicated in connection with the specimens as a
fraction (e. g. 32+) whose numerator represents the accession num-
ber, and denominator the department number, or as a decimal
(294.896), or the accession number may be entirely omitted from
the specimens, since a reference to the department card will fur-
nish it when desired.

Original number.— ‘This is the number which a specimen may
possess on its arrival. Often times it will be the field number
placed on it at the time when it was collected or it may refer to a
number assigned in a previous collection.

Number of Specimens.— This is essential in order to know the
amount of material in any collection. When duplicates are used
for exchange, the former number should be crossed out and the
new one substituted, while, at the same time, a reference number
referring to the exchange may be added.

Sex.— The sex can be designated by the conventional signs,
oS, 2, 9, representing, male, female, and hermaphrodite forms.

1 These colors are suggested inasmuch as the majority of manufacturers

of cards in the United States make them in four standard colors, white, buff,
salmon, and blue.

No. 482] CATALOGUING MUSEUM SPECIMENS 91

Growth. — Embryo, young, adult. Measurements, weight, etc.

Scientific name.— In systematic work of this nature the generic
followed by the specific name must be used.

Authority for identification— This is an important item which
is too .often omitted from the average museum catalogue. If a
specialist subsequently verifies a name previously given, this
should also be noted. In case the name is found incorrect a new
card is to be written.

Date of identification.— It is well to have this information avail-
able.

Locality where collected.— Too much care cannot be exercised
in accurately indicating the locality from which specimens are
obtained. It is safe to say that every museum has among its col-
lections material which would be of the utmost value, provide the
locality, even within a few hundred miles, could alone be ascer-
tained. Unfortunately in most cases of this kind, it is the collector
who is at fault. The cataloguer must rely on his data.

Name of collector.— Inasmuch as the ‘personal equation’ must
be taken into consideration, the name of the collector is indispens-
able. Furthermore it often furnishes a clue to the history of a
specimen when all other means have failed.

Correspondence.— Letters, etc., pertaining to the particular
specimens can be indicated as suggested in the accession cata-
logue. eles

Date when collected.— This can be indicated as in the accession
catalogue.

Character of specimen.— The nature of a specimen, whether a
skeleton, an anatomical preparation, a mounted skin, ete., should
be given. If preserved in a special manner it is well to indicate
the formula, e. g. 5% formalin; 70% alcohol; killed and hard-
ened in chromosmic 3 hours, preserved in 95% alcohol, ete.
Explicit notes here will in the end well repay the time spent in
making them. The back of the card will afford additional space,
if needed.

Remarks.— This space is only to be filled out when there is
something of particular importance to be noted concerning the
specimen, and of a nature which cannot be covered under the
other records.

92 - THE AMERICAN NATURALIST [Vor. XLI

General suggestions.— The data, as well as their arrangement
on the cards, are naturally subject to various changes, in order to
conform to the requirements in different museums. It is well
to have a blank space for each item of information concerning
the specimen, although often unnecessary, or even inadvisable,
provided there is reason to doubt its accuracy, to fill it out. Asin
the Accession Catalogue numerical guides should be placed at
intervals of one hundred cards, while ‘side locking cards’ are
recommended.

C. REFERENCE CATALOGUE.

The Reference Catalogue may with equal propriety be termed
a finding list, since its purpose is that of indicating the location of

REFERENCE CATALOGUE
KENYON COLLEGE MUSEUM
um: Oryptobranchus altegheniensis Dud
Exhibition ae Exhibition Storage
Department ee No.of Case [No.of Draw'r} Totaj | Department Character f| Case | No. of Draw'r| Total.
Number of $ ce {| No. c. | No» Number of Specimens Spec. | No. | Spec.| No,
415 at 333 |v]: 3
49% Termakın 34, 1.1973
507 ” * 4 |21] 4
|

Fig 3.— Reference en card (4X5 in.). One card will usually contain data refer-
ring to 50-100 specimens. The cards er be arranged an the scientific and
‘common’ names to be on separat An alcove or hall letter may be added to
the case number. The permanent position of the card in the vol may be assured
by use ofa central rod.

each specimen which belongs to the particular department in the
museum. The cards are arranged in alphabetical order, both
the scientific name (generic followed by specific name in the case
of biological specimens), and the common name having a place
on separate cards, the latter, however, referring to the former,

No. 482] CATALOGUING MUSEUM SPECIMENS 93

(e. g. opossum, see Didelphys. Furthermore, the reference card
indicates the number of specimens of each species on exhibition,
or in storage, giving the number of the case or storage drawer in
which they are to be found.

A single card will usually contain the data concerning all mate-
rial belonging to a particular species, consequently the time involved
in maintaining a Reference Catalogue is an unimportant item, the
data (except location of specimens) being readily obtainable at
any time from the Department Catalogue. |

The Reference Catalogue should be located in the principal
room containing the collections to which it refers, where it will
be readily accessible to each of the three classes of people for which
a museum primarily exists: (a) the specialist, (b) the amateur,
and (c) the general public.'

One method for arranging the data for a reference catalogue,
is shown below (Fig. 3).

Systematic Cross Reference Classification by means of Tabs.—
An excellent method which meets the usual requirements, is that
of having the tabs arranged as in the Department Catalogue.
Geographical cross reference by colors cannot be used inasmuch
as one card will often contain specimens from widely separated
localities.

Name of specimens.— Both the scientific name and the common
name should be given, the former on the card containing the data,
the latter on a separate card referring to the generic or specific
name of the particular species. (e. g. Brook Trout, see Salvelinus
fontinalis, Pickerel, see Esox, various species). By placing the
common name on cards having a particular color they may be
readily distinguished.

Department numbers.— Inasmuch as the department numbers
will be placed on all material, this will serve to establish the identity
of the specimen sought, and in case further data is required, the
corresponding number in the Department Catalogue can be con-
sulted.

Character of Specimens.— In alcohol, mounted, skeleton, skin,
etc.

‘See Bather, F. 1904. The Functions of a Museum; a Re-Survey. Pop.
Sci. Mo., v. 64, p. 210-218.

94 THE AMERICAN NATURALIST [Vor. XLI

Exhibition, Storage, etc— The location of a specimen is indi-
cated by the particular column under which it is placed. If on
exhibition, the number or letter of the case! will be given. Al-
coves or galleries may be designated by letters. If on storage,
the location will be similarly designated.?

Total number of specimens.— These columns will indicate the
total number of specimens of a given species ® belonging to the
museum. If customary for the institution to make many exchanges
a balance column may be added, which will show the material
on hand as well as that exchanged.

The necessary steps incident to the cataloguing of a collection
which has been received may now be outlined as follows.

a. Catalogued as an Accession.

b. Placed in charge of a department.

c. Catalogued in a Department Catalogue and given a
department number.

d. Identified and labelled. ‘This data then added to the
department card.

e. Placed on exhibition or in storage.

f. Reference Catalogue filled out from data on department
card.

The first three items should be attended to at once. A consid-
erable interval will often elapse however before final desposition
of the specimen is made.

It would seem that only two general objections can be urged
against any system similar to the one proposed, namely; (1) The
plea that too much time will be occupied in the preparation of such
a catalogue, and (2) a certain inherent condition which precludes
the adoption of new ideas. The only answer that need be given

‘ If the case is a large one and contains a quantity of specimens, it may be
convenient to indicate the number of the shelf, ete. w

? The practice of having separate department catalogues for the exhibition
and storage series, is to be criticised. Different species thus possess identical
numbers, and when it becomes necessary to transfer a specimen which has
outlived its usefulness for exhibition purposes, to the storage collection,
complications at once ensue

3 When it becomes desirable to include a collection in a guide book to the
museum or to issue a general catalogue of the specimens, the question involved
is merely that of selecting the data here classified.

No. 482) CATALOGUING MUSEUM SPECIMENS 95

to the former is that the space occupied by a specimen unworthy
of being properly recorded, is more valuable than the specimen -
itself, while to the latter no reply is needed.

It is unnecessary and often inadvisable to at once reduce former
catalogues to a card system. Incoming material can be cata-
logued on the cards, and as the opportunity allows, data from the
previous records can be transferred to cards.

Conservatism * is a valuable factor in connection with all scien-
tific work. It has its limitations however, and in order to make
definite progress in any direction, old methods must give place to
new ones — the fittest will survive.

Kenyon COLLEGE, GAMBIER, Omio. Dec. 1, 1906

‘Meyer, (:00-01) in his excellent review of the museums of the eastern
United States depreciates the lack of uniformity among the various American
museums in respect to the installation of the collections. In reply to this
criticism however it might well be suggested that to a certain extent at least
this lack of uniformity is an indication of healthy activity. It is not considered
necessary in this country to cling to traditional ideas which are too often
brought to the attention of one visiting European museums. New methods
of dealing with well known problems are sought and evolved — and if their
value is proven — they are adopted.

Since the above paragraph was first written (Aug. 1901) Dr. Jordan in his
presidential address before the members of Sigma Xi (Dec. 31, 1903) expressed
similar ideas regarding this tendency which he had noted. “In France, in
Germany, even in England, the tradition of great names, the customs of great
museums, largely outweigh the testimony of the things themselves. — The
willingness to adopt new ideas is, broadly speaking, in proportion to the
spirit of democracy by which a worker is surrounded.”

96 THE AMERICAN NATURALIST [Vor. XLI

BIBLIOGRAPHY

Dorsey, G.
99. (The aa of Museum Specimens), American Anthropolo-
gist, n. s., 1, p. 473.
Meyer, A. B.
: 00-01. Ueber Museen des Ostens der vereinigten Staaten von Amerika.
R. Friedlander und Sohn, Berlin. (Also see translation in Report
of the U. S. National Museum for 1903, p. 311-808 with 40 plates).
Hoyts, W. E.
’91. The Registration and Cataloguing of Museum Specimens. An-
nual Report of The Museums Association, Cambridge, England.
MADELEY, CHAS.
04. The Classification of Office Papers. Mus. Jour., v. 4, no. 3, p.
73-95.
Murray, Davip.
:04. Museums, Their History and their Use. 3 vols., J. MacLehose
and Sons, Glasgow, Scotland.
WALTON, L.
The Cataloguing of Museum Collections. Ohio Naturalist,
v. 4, no. 3, p. 62.
Wray, L.
:05. A System for the Registration of the Contents of Museums.
Museums Journal, June, p. 407-412.

SOME SOUTH AMERICAN ROTIFERS
JAMES MURRAY

THE undernoted rotifers were obtained from moss kindly sent
to me by Mr. N. D. F. Pearce, of Cambridge, England, in the
early summer of 1906. The moss was sent from British Guiana.
The locality from which it came was unknown, but it was some-
where in the interior.

A portion of the moss was still moist, but most of it had been
dried. ‘The majority of the species were got from the dried moss.

As is usual when dried moss is examined after a lapse of some
time, most of the rotifers found belonged to the order Bdelloida.
Of this order 13 species were distinguished; 11 of the species were
already known, most of them being common and widely distributed
species. One, Callidina perforata,’ was only recently discovered
in India, and a very distinct variety occurred more abundantly
than the type. C. multispinosa was represented by a variety,
probably of specific value. Two new species are here described.

Four species of the order Ploima were also found,— one Colurus,
two Monostyla,— and one Diglena. I was unable to determine
any of these.

ORDER BDELLOIDA

Callidina angusticollis Murray (:05).— Very abundant. All the
examples belonged to the type, or to a small variety. The Indian
variety attenuata did not occur.

C. perforata Murray.— The most abundant species in as col-
lection. The type (Fig. 1) was fairly plentiful, but a variety,
described below, was much more so.

C. p. var. americana var. nov. (Figs. 2-3).— Case smaller than
in the type, length 106 » (type about 136 ~). Posterior process

"Murray, James, “Some Rotifera of the Sikkim Himalaya.” Journ. Roy.
Mir. Soc., 1906.

98 THE AMERICAN NATURALIST [Vor. XLI

sharply marked off by abrupt constriction, not turned to dorsal
side as in the type, but in line with the axis of the case; — perfora-
tion towards ventral side (dorsal in type). Dorsal plicee of the
case not distinct, but an obscure tesselation or coarse stippling
instead. As in Indian examples, empty cases usually lacked the
ventral wall, as though some enemy had found this part vulnerable.

C. constricta Duj. (’41).— Plentiful.

C. aspera Bryce (’92).— A few examples.

C. habita Bryce (’94).— One example, living.

C. quadricornifera Milne (’85—’86).— One small hyaline example.

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ij
N Need
Fig. 1. Fig. 2. Fig. 3.

. Callidina perforata Murray.

C. multispinosa Thompson (’92).— In Britain I have found
this species variable only within narrow limits. In various warm
countries I find many forms related to this species, sufficiently
distinct and apparently constant, which are probably distinct
species. ‘They are so numerous that I think it would be well to
make further comparisons of them before deciding how many
of these forms are good species, and I make all provisionally sub-
ordinate to C. multispinosa. In British Guiana the type was not
found, but two varieties were frequent. One variety has all the
spines very short. It has a superficial resemblance to C. papillosa,

No. 482] SOUTH AMERICAN ROTIFERS 99

but the arrangement of the spines shows that it belongs to this
species. ‘This variety is also found in India and Africa.

C. m. var. crassispinosa var.
nov. (Fig. 4).—Long ante-
rior spines few, usually 4 on
each side, the 2d and 4th of
these much thicker than the
others. ‘The lateral spine of
the anterior row on the central
segments of the trunk large
and very thick. Skin strongly
stippled or papillose.

Other smaller differences
from the type will be better
understood from the figure.
There was no variation from
this arrangement of spines in
all the examples seen. The
variety is much smaller than

Fig. 4.
the type. About 6 examples caniai sitesi ak dentition.

seen.
C. ehrenbergi Janson (’93).— One living example.

C. tripus n. sp. (Figs. 5-7)

Specific characters — Small, 240 » long, hyaline or whitish,
with pale yellow stomach, food not moulded into pellets. Head
small, corona 40 » wide, less than collar and about half diameter
of central trunk, discs touching, central process of upper lip
single, truncate. Length of antenna $ diameter of neck. Jaws
18 » long, teeth 2/2, very thin. Foot 4-jointed, spurs narrow, taper-
ing, divergent; toes large and long, the two ventral put out and
drawn in, in the usual manner, when making the step, the dorsal
kept always extended and forming with the spurs a tripod. Dorsal
skin folds faint, few, lateral deeper. ‘The striking peculiarity is
the tripod, which is unique in the order. Otherwise the animal
comes nearest C. ehrenbergi Janson, from which it is distinguished
by the smaller head, closer discs, and truncate upper lip. Abun-
dant. '

100° THE AMERICAN NATURALIST [Vor. XLI

C. speciosa n: sp. (Figs. 8-10)

Specific characters.— Very small, 163 » feeding to 238 1 creeping.
Head very small, diameter of corona 26 x, of prominent collar 38 x.
Food not moulded into pellets. Teeth 2/2. Anal segment with
lateral prominences. Foot 3-jointed, first joint with lateral proc-
esses, spurs small, tapering, divergent. Toes three. Dorsal
longitudinal and ventral transverse skinfolds forming symmetrical
pattern, which is constant. Length of antenna half diameter of
neck.

The most distinctive character is the pattern formed by the

mii

A

Fig. 6.

Fig. 5. Fig.7. .8, Fig. 9.
Callidina tripus n. sp. Callidina speciosa n, sp.

skinfolds. Many species have a similar pattern formed by the
dorsal wrinkles, but no other species has the ventral surface so
ornate. Apart from this character it has no close resemblance

No. 482] SOUTH AMERICAN ROTIFERS 101

to any other species. ‘Those which approach it in general form
and dorsal wrinkling have larger heads with separated discs.

Not abundant, about a dozen examples seen.

Rotifer longirostris (Janson) (’93).—Several examples of the type
were found, but none of the Indian varieties occurred.

Adineta gracilis Janson (’93).— Not plentiful.

A. vaga Davis (’73).— Rare.

LITERATURE
Brycr, D.
792. On the Macrotrachelous Callidine. Journ. Quekett Micr. Club,
ser. 2, vol. 5, p. 15.
Bryce, D.
’94. Further Notes on Macrotrachelous Callidine. Journ. Quekett
Micr. Club, ser. 2, vol. 5, p. 436.
Davis, H.
73. A New Callidina. Month. Micr. Journ., p. 201.
DuJarpın, F.
41. Zoophytes Infusoires, p. 658. Paris.

Janson, O.
93. Rotatorien-Familie der Philodinzen, Marburg.
Ming, W.
’*85-’86. Defectiveness of the Eye-spot, ete. Proc. Phil. Soc. Glasgow,
vol. 17, p. 134.
Murray, J.

705. A New Family, ete. Trans. Roy. Soc. Edinb., vol. 41, p. 367.
TxHompson, P. G.
’92. Moss-haunting Rotifers. Science Gossip, p. 56.

MERISTIC HOMOLOGIES IN VERTEBRATES
J. S. KINGSLEY

One of the most difficult problems in vertebrate morphology

is to explain the serial homologies between the different groups.
In the lower segmented animals these difficulties, although they
exist, are far more simple and are far more easily explained. Thus
no one has any doubt that the tenth or the fifteenth somite of
Homarus is the exact equivalent of the serially homologous somite
of Cancer. Between the larger Arthropodan divisions the task
of comparisons of somites is possibly not so easy yet all attempts
at drawing homologies between, say, a hexapod, an arachnid and a
crustacean, are based upon the assumption of exact serial equiv-
alency. It is true that one author or another has at times sug-
gested the possibility of intercalation or elision of a somite, but
these have been mere suggestions and have usually been discarded
in the discussions.
__ In the vertebrates this comparison is more complicated. We
are forced to assume that the shoulder girdle and fore limb of the
frog are the homologues of those of man, although their connec-
tions are with entirely different somites when serial position is
taken into account. In the case of the pelvic arch the numeri-
cal disparity of the corresponding somites is even greater, but in
either case the identity of structure of arch and limb is so great
that doubt of homology is practically impossible. How then has
it come about that say the twelfth somite of the Amphibian is not
homologue of the twelfth but of more nearly the twentieth of
man ?

In Gegenbaur’s hypothesis that the girdles are derived from
branchial arches and that these have migrated backwards over
the post-cranial somites we have a possible explanation of these
problems of the relations of girdles to body segments. ‘The back-
ward migration has been arrested at different points in thg various

103

104 THE AMERICAN NATURALIST [Vor. XLI

groups. But this explanation will not suffice for other cases,
hence the probability that it is true for none.

In the frog as in all Ichthyopsida, there are but ten cranial
nerves, while in the mammals there are twelve. ‘There is no
doubt that as far back as the tenth the nerves are exactly homol-
ogous in Amphibia and in the mammals. Relations to brain and
to points of distribution place this beyond question, but what
shall be said of the mammalian eleventh and twelfth? Are both
of these nerves from the post-cranial region which have been
transferred to the skull? If so, does it not follow that the cranium
in the higher vertebrates is not the exact equivalent of that in the
lower? and that the differences have been brought about by the
transformation of cervical into occipital vertebra. If this, in
turn, be so, are the occipital bones of the frog homologous with
those of the mammal? Or are the basi-, ex- and supra-occipitals
of the one merely analogous of those of the other? Is Huxley’s
argument for the derivation of the mammals from the Amphibia
because of the double occipital condyles in the two groups based
upon analogies rather than on true homologies? Are the condyles
in Amphibia and Mammals not homologous but rather homo-
plastic formations ?

Carrying this matter further back in the body, how are we to
explain that apparent shifting of the pelvis in such a form as
Necturus as described by Bumpus, Parker and others? Are
somites ten, twenty and the like exactly equivalent in the normal
and aberrant forms? And has there been an actual shifting of
the pelvic girdle from one somite to the next in some individual ?
Or has there been an actual intercalation of vertebrae, the one to
which the ilium is attached being constantly the same morpho-
logically if not serially? Or, lastly, have the limbs and their
arches arisen from a continuous fin fold and has every somite
which contributes to that fold the potentiality of limb formation
with all that this implies?

To take another case. In Amphioxus there are a large number
of gill slits, a number which is doubled during development by the
formation of the ‘tongue bar.’ Right behind the last gill slit
comes the entrance of the hepatic duct into the alimentary tract,
there thus being no cesophagus nor stomach intervening between

No. 482] MERISTIC HOMOLOGIES IN VERTEBRATES 105

.
the pharynx and the liver. Is this to be explained by saying that
in the vertebrates the posterior gill elefts of Amphioxus have closed
and that the space which they occupy has become converted into
stomach and cesophagus? In other words are these formations
of the vertebrate tube the homologues of a part of the gill region
of the acraniate ?

Then, too, what are to be done with cases of increased numbers
of gill slits; the Notidanids with six or seven, the Californian
Bdellostoma with its variable number, and Amphioxus itself?
This question is wholly apart from that which discusses the rela-
tions between metamerism and branchiomerism.

Numerous other similar questions will readily suggest them-
selves to all. There is no reason for enumerating them here.
The problem is, how are they to be explained. Must we find a
separate explanation for each or can we find some one principle
which will account for all?

This article is to be regarded in the light of a suggestion rather
than a full reply with demonstrations of validity. I have no
proof, other than analogies and the fact that the hypothesis here
presented answers all the demands of the problem, that the expla-
natıon here advanced is the true one. It must be tested and the
tests are not easily made.

In the invertebrate segmented animals there is, at the beginning,
no metamerism. It appears later during growth, and in numbers
of forms it is found that the segmenting tissues are produced by
budding from groups of cells at the posterior end of the embryo.
These are most familiar in the annelid teloblast and are scarcely
less well known in the Insects and Crustacea. Their number
varies between wide limits, but for the present purposes the most
important points concerning them, aside from their budding
capacities, are their position in a more or less plainly marked
transverse band and their situation at the extreme posterior limit
of the growing embryo. Extensive examination of the literature
has not shown similar budding cells in the Cuvierian group of
Articulata in other places than the tip of the growing embryo,
with the exceptions noted below.

It follows then that in these teloblasts and their equivalents are
the full potentialities of the future somites. From them arise

106 THE AMERICAN NATURALIST [Vor XLI

a
all the cells which are utilized in every structure which is meta-
merically repeated, the material for the new somite not being
budded from any pre-existing somite, but always just in front of
the hinder end of the body.

This applies strictly to all cases which are known to me in: the
arthropods as well as to most of the annelids; but in a few of the
latter group modifications occur in the process which have great
interest for us. As is well known in a number of annelids asex-
ual reproduction by transverse division occurs. At one or more
points in the body a new head may develop with the eyes, append-
ages, etc., characteristic of the anterior end of the worm, these
features arising from a somite which in its earlier stages is appar-
ently normal and like its fellows on either side. ‘Then, just in
front of this new head the worm divides and two worms, each
with fewer somites than the original one, are produced and from
this time onward lead an independent existence.

Of these only the anterior worm need now be considered. After
the separation the segment which was just in front of the new head
of course becomes the terminal somite of the new worm. ‘The
worm now increases in length and the new somites are formed by
material cut off from the terminal somite which thus must have
within it the equivalent of the teloblasts of the embryo.

From these facts it seems logically to follow that at least certain
somites in the body have the potentialities of forming material
for additional somites and must contain within them the same
physiological possibilities as the original teloblasts from which
they arise. In other words, in the annelid before the beginning
of the transverse division the capacity for producing new tissues
was located at more than one point in the body, but it was not
exercised until after the asexual reproduction was well advanced.

In the case of the Naides the somites thus produced are all
similar in character but in such instances as Protula, where heter-
onomous somites occur, the division of the worm is accompanied
by the formation of new somites which differ in kind.

The application of these facts to the various types of meristic
variation which occur in annelids need not be discussed here, but
I think it is apparent that they will in part explain some of them.
I do not mean to say that they reveal first causes but they do point

No. 482] MERISTIC HOMOLOGIES IN VERTEBRATES 107

out the mechanism involved and may be used to reduce all to a
common rule.

In the same way the assumption that there are similar budding
zones at various points in the vertebrate body will explain the
various conditions outlined in the statement of the problem. In
the vertebrates there is a continuous addition of new somites at
the posterior end of the body as in the arthropods and annelids,
implying the existence of the equivalents of teloblasts at the pos-
terior end. The assumption of budding zones at other points
will explain the other features noted. Such a zone in the occipital
region will allow us to explain the difference in the number of
cranial nerves in the mammals and in the Ichthyopsida and yet
allow us to accept the homology of the occipital bones throughout
the vertebrate series. The additional nerves are thus to be re-
garded not as transferred from the neck but as new or intercalated
structures. In the same way we may explain the varying number
of vertebree in the different regions and allow at least one of the
pelvic vertebre to be regarded as a fixed point and may be relieved
of any assumption of a shifting of the girdles. It will also explain
many anomalies such as the attachment of the two halves of the
pelvis to different vertebrae and the increased number of lumbar
or thoracic vertebree in man.

This is to be regarded solely as an hypothesis. So far as I am
aware no one has seen such budding zones in any vertebrate. In
fact it is extremely probable that there is no such well defined zone
as is found in the band of teloblasts of the crustacean. It is to be
regarded rather as a series of assumptions, based in part upon
analogies, which, if true, would explain the questions with which
the present note began. The hypothesis is presented as a sug-
gestion to stimulate investigation and criticism upon an interesting
and difficult subject.

ON THE OSTEOLOGY OF THE TUBINARES.
R. W. SHUFELDT.
I. HISTORICAL.

Few of the groups of Birds have a more interesting literature
than this Suborder.

As early as 1827 M. 1. Biainnister placed the Tubinares together
in a family of birds (28th) and classified them upon the characters
of their sterna, assigning them to three sections; (1) the smaller
Petrels in which the xiphoidal end of the sternum was entire or
nearly so; (2) the Albatrosses, where it presented a shallow notch
upon either side of the carina; (3) those Petrels in which two
well-marked notches occurred on either side of the sternal keel.’

M. M. Hombron and Jacquinot in the year 1844, added some-
thing to our knowledge of the Tubinares,’ and they classified the
group upon the morphology of their palates, tongues, and beaks.
In one genus they placed the three genera Diomedea, Puffinus
and Priofinus, in another, the genus Prion, and finally, in their
third genus,— Procellaria. By them Pelecanoides was removed
from the Procellaride, and placed in the Alc near Alle, which
they considered its nearest relative (A. nigricans). Five years
later Gray and Mitchell (1849) divide the Procellaridz into the
Diomedeinz and the Procellariin®, and the last named into 5
genera (Prion, Pelecanoides, Thalassidroma, Procellaria, and
Puffinus), the group constituting the fourth family of their Anseres.°
In his Conspectus, Bonaparte divides the Procellaridz into the
Diomedeine, Procellariine, and the Halodromine; the second

1 Recherches sur l’appareil sternal des Oiseaux, pp. 79-81. v. iv. Paris,
182

3 Baa sur quelques points de l’anatomie et de la. physiologie des
Procellarides, et essai d’une nouvelle classification des ces oiseaux, Compt.
Rend. de l’Acad. Sei. xviii, 1844, pp. 353-358

? The Genera of Birds, iii, pp. 646-650.

109

110 THE AMERICAN NATURALIST [Vor. XLI

subfamily being subdivided into five lesser groups." But a few
years later (1864-66) this constitution was followed by the far
more accurate work of Coues, though that distinguished ornithol-
ogist complains of “having suffered not a little from imprudence
in believing Bonaparte,” whom to some extent he followed, but
upon the whole has given us a more natural classification of the
Tubinares.?

Both Bonaparte and Coues based their classification upon
the topographical anatomy of the birds of the suborder we are now
considering, but this was not the case with Eyton nor with Milne-
Edwards; nor with Huxley who followed them.” All these
distinguished authors dealt more or less thoroughly with the
osteology of many of the Tubinares, as well as with such char-
acters as procellarine species presented externally. Eyton fig-
ured the bones of the skeleton of several varieties of Albatrosses,
and forms related to them. Milne-Edwards pointed out the
relations existing among Petrels, Gulls, and the Steganopodes;
showing that the first two were more or less closely akin, and both
more remotely related to the last-named group of Birds. Huxley
in one of his groups of Schizognathous forms, the Cecomorph,
in his celebrated paper, placed the Divers, the Auks, the Gulls,
and the Petrels in a group by themselves, and of the Procellaridae
says that they “are aberrant forms, inclining towards the Cor-
morants and Pelicans among the Desmognathe”’ (loc. cit., p.

Next of importance we find Professor Reinhardt in 1873, touch-
ing upon certain anatomical characters of Petrels, Albatrosses,
and Puffins, and presenting his classification of the Group, and
to his paper the reader is referred, inasmuch as his results are

1 Conspectus generum avium, 1857, tom ii, pp. 184-206.

? Coues, E. Critical Review of the Family Procellariide. Proc. Acad.
Nat. Sci. Phila. pt. 1, (pp. 72-91); pt. 2, (pp. 116-144); pt. 3, (pp. 25-33);
pts. 4 and 5 (pp. 134-197). Parts 1 and 2 appeared in 1864, and the remaining
parts in 1866.

3 Eyton, T. C. Osteologia Avium, Lond. 1867, pp. 221-225.

MıLne-Epwarps, M. Ar. Recherches anatomiques et paleontologiques
pour servir a l’histoire des oiseaux fossils de la France. Paris, 1867-68.

Huxley, Thos. H. On the Classification of Birds, ete. P. Z. S. 1867, pp-
415-472.

No. 482] OSTEOLOGY OF THE TUBINARES 111

too extensive to present in this connection.‘ That same year
likewise saw Garrod’s studies of the Petrels appear, and finding
them ‘holorhinal,’ he parted them from the ‘schizorhinal’ Gulls
and related forms exhibiting a similar character.

Other papers and works of minor taxonomic importance con-
tinued to be put forth, when in 1882 appeared the very extensive
and meritorious work of Forbes dealing with the entire anatomy
of many forms of the Tubinares, and a thorough study of their
probable affinities.’

Forbes divided the Tubinares into two families, the Oceanitidee
and the Procellariide, which last was subdivided into the two
subfamilies — Diomedein® and the Procellariine. Osteology of
the Petrels and their allies filled a prominent place in this able
production, and I shall frequently have occasion in the present
brief article to refer to it, especially in instances where its author
had skeletons of species which the writer has not been able to
secure.

Another classification is seen in that of Dr. Stejneger which
was published in the Standard Natural History (Boston) in 1885.
The following selected from his scheme will show where he places

the Tubinares: —

Subclass IV. Super-Order III. Order VI. Superfam. V.
Eurhipidure { Euornithes } Cecomorph® { Procellaroidex.

In the Procellaroide are arrayed the three families Diomedidee,
Procellariide, and the Pelecanoidide. ‘This writer places in his
scheme the Tubinares widely removed from the Steganopodes,
which I believe to be a mistake, and a non-appreciation of the
morphological characters of the latter group of Birds.

In his great work upon the anatomy and taxonomy of birds,
Fürbringer makes the Procellariiformes an ‘ Intermediate Suborder’

! Reinhardt, J. Om Vingens anatomiske Bygning hos Stormfugle-Familien.
Viden. Medd. Naturh. For. Kjöbenhaon, 1873, pp. 123-138.

? Garrod, A. H. Collected Papers, p. 128.

orbes, W. A. Report on the Anatomy of the Petrels (Tubinares) Col-

lected during the Voyage of H. M. S. Challenger. (Zool. Chall. Exp. vol. iv,
pt. xi, pp. 1-64. Pls. i-vii (1882).)

[“ This contribution will be found a most valuable addition to the literature
on this remarkable order of pelagic birds.” John Murray.]

112 THE AMERICAN NATURALIST [Vou XLI

between his Orders Pelargonithes and Charadriornithes. He
considers the Procellariiformes to contain the Procellarie or
Tubinares to which group he gives the name of ‘Gens.’ The
Gens Procellarise according to him contains but the single family
— Procellaride. Above the Procellariiformes in the Order
Pelargornithes we find the Gens Steganopodes.

In 1890 Mr. H. Seebohm in his “Classification of Birds,” —
the “alternative scheme” makes an Order of the Tubinares,
placing them in his subclass Ciconiiformes, between the Stegan-
opodes and Impennes. Thus his third subclass of birds is ar-
ranged as follows: —

SUBCLASS. ORDER. . SUBORDER.
| Psittaci. Psittaci.
e Striges.
|

n
>

Raptores. 16. Accipitres.

17. Serpentarii.

3. Ciconiiformes. { (18. Plataleze.

Pelecano-Herodiones { 19. Herodiones.
20. Steganopodes.

Tubinares. 21. Tubinares.

| Impennes. 22. Impennes.

Professor Hans Gadow regards the Tubinares much in the same
light as they are by Fürbringer, placing them as an Order Procel-
lariiformes, (9), between the orders Sphenisciformes (8) and
Ardeiformes (10), the first suborder of the latter being the
Steganopodes.*

The ‘Procellariiformes’ constitute Order XV of Dr. Sharpe’s
classification, and it is subdivided into a suborder — Tubinares,
which latter is made to contain the three Families: (1) Diome-
deidze, (2) Procellariide, and (3) Pelecanoide. Of this author’s
scheme, Order XIV contains the Sphenisciformes, and Order
XVI, the Alciformes.” This authority likewise widely separates
the Tubinares and the Steganopodes, the last being included in
his Order XXIII or the Pelecaniformes (loc. cit. p. 76). In

1 On the Classification of Birds, P. Z. S. 1892, pp. 229-256. [An able and

? Sharpe, R. Bowdler. A Review of the Recent Attempts to Classif
Birds. Budapest 1891, pp. 71, 72. .

No. 482] OSTEOLOGY OF THE TUBINARES 113

1899 Dr. Sharpe changed this arrangement entirely as will be seen
by the following scheme which represents I believe his latest
opinions upon this subject.‘ He now places the Procellariiformes
between the Sphenisciformes and the Alciformes.

No. of
OrpeEr (XII). FAMILY. SUBFAMILY. GENERA. SPECIES.
[ f [ Procellaria. 2
A I Procellariinæ. | Halocyptena. 1
Y \ Oceanodroma. 13
2 | Oceanites. 2
> Garrodia. 1
of II Oceanitine. { Pelagodroma. 1
=
8 Pealea. 1
| \ Fregetta. 4
; Puffinus. 24
a: Priofinus. 1
Q Thalassoeca. 1
& .
Be I Puffinine. | ae r
= w jaqueres.
S y (Estrelata. 31
Z z% Pagodroma. 1
o Z. | Bulweria. 2
8 | Ossifraga. 1
Fulmarus. 4
II Fulmarine. Daption. 1
| Halobæna. 1
| Prion. 4
III Pelecanoididæ. Pelecanoides. 3
[ Diomedea. 10
IV Diomedeide. en 6
Phoebetria. 1

s

This scheme does not enumerate the fossil or subfossil forms
given by Dr. Sharpe in the Hand-List, of which not a few have
been discovered and described. There are abòut 120 species of
Tubinares known to science, and this scheme is very useful in
exhibiting at a glance their distribution into genera.

- 1! Hand-List of Birds. Vol. I, pp. 120-129. Lond. 1899.

114 THE AMERICAN NATURALIST [Vor. XLI

Cope essentially agrees with Stejneger as given above, with the
exception that the Superfamilies of the latter are equal to the
families of the former. Thus Cope makes the Cecomorphe
contain the families Colymbide, Heliornithide, Alcidee, Laridæ,
and Procellariidee.*

The writer of the present memoir added his own studies to the
literature of this subject in a paper published in 1889, which ap-
peared in the Proceedings of the United States National Museum,
it being, in its aim, more descriptive of material then in the col-
lections of that institution, rather than an attempt to classify the
Tubinares. In that paper the skeleton of Oceanodroma furcata
is fully described and figured, also the skeletons of Fulmarus
glacialis and F. rodgersii, ten figures being devoted to the bones
of the latter species.

A section is also devoted to the ‘Osteological points wherein
Oceanodroma furcata and Fulmarus rodgersii differ,” and this
is followed by some notes on the osteology of Puffinus tenuirostris
and other material. Finally, a very complete account is given
of the skeleton of Diomedea albatrus, it being illustrated by twelve
figures (nat. size), giving the skull (four views), the vomer (two
views), the mandible (two figures), the hyoid arches, the sternum
(two figures), and the shoulder-girdle.? "Taken in connection
with my examinations of additional material since that paper
was published, and a study of the foregoing works of other authors,
the present brief memoir aims simply to bring this subject up to
date. I have never been able to get the skeletons of a great many
species of procellarine birds, a number of which have been de-
scribed by Forbes in his above cited work, and the student may
readily consult these in the volume of his collected scientific
Memoirs published by the Zoological Society of London (R.
H. Porter). Either wholly or in part, Forbes examined skeletons
of Diomedea albatrus, Thalassogeron culminatus, Phebetria fuligi-
nosa, Ossifraga gigantea, Fulmarus glacialis, F. glacialoides, Dap-

1! Cope, E. D. Synopsis of the Families of the Vertebrata. The Amer.
Nat. XXIII, Phil. Oct. 1889, p. 849 et seq.
? Shufeldt, R. W. Observations upon the Osteology of the Orders Tubi-
nares and Steganopodes. Proc. U. S. Nat. Mus., Vol. XI, Washington, 1889,
pp. 253-315. %

No. 482] OSTEOLOGY OF. THE TUBINARES 115

tion capensis, Oceanodroma leucorhoa, Oceanites oceanicus, and
Pelagodroma marina. The skeletons of a number of these have
also been examined by me, and in addition thereto I have stu-
died complete skeletons of Puffinus borealis, P. major, P. griseus
(2), P. ereatopus, Oceanodroma furcata and others. We also both
examined a skeleton of Puffinus obscurus, and he also a skeleton
of Bulweria columbina.

Considering the rarity in collections of the skeletons of tubi-
narine birds, the ground is pretty well covered by our united
examinations, though it is highly desirable that many or all of the
others be in time anatomically examined and compared.

II. Some GENERAL NOTES ON THE OSTEOLOGY OF THE
TUBINARES.

Bearing in mind what Forbes has recorded in his papers on the
palate of the Tubinares (Coll. Sci. Mem. p. 416), I would say in
addition thereto that I find in a skull of Puffinus borealis before
me, that the inner ends of the maxillo-palatines abut against,
on either side, the nearly vertical and lofty scroll of the corre-
sponding palatine. The. meeting is quite extensive and‘ codssi-
fication appears almost to have taken place at the point of contact.
The fenestration in them is hardly evident. We likewise find in
the skull of P. borealis that the descending plates of the palatines
are quite as prominent and well developed as the ascending ones
just referred to, while the pterygoidal heads of these bones (pala-
tines) in this shearwater are notably long, and closely applied
to each other in the middle line, and to the sphenoidal rostrum.
In it, too, the os uncinatum is well seen, being a distinct spine of
bone, articulating, upon either side, with the infero-internal border
of the lacrymal with its free apex pointing downwards and inwards
towards the ascending plate of the palatine. In this shearwater
the lacrymal is large and pneumatic. It articulates extensively,
but does not anchylose with the corresponding frontal and nasal
bones, and internally with the broad outer end of the pars plana.
Its descending end is bifid and comes in contact with the zygoma,
while superiorly its anterior apex is finely pointed, but posteriorly

116 THE AMERICAN NATURALIST [Vor. XLI

is blunt and juts backwards and slightly outwards, being found
just at the point where the deeply sculptured supra-orbital gland-
ular depression terminates in front. Contrary to Forbes’ state-
ment that “well-developed basipterygoid facets are present in all

_

Fic. 1. Right lateral view of pe evi abe a Shearwater (Puffinus borealis). Coll,
J. S. Nat. Museum, No. (From a photograph by Prof. T. W. Smillie,
atin reduced.)

the forms, except the Diomedine, the Oceanitide, Procellaria,
and Cymochorea,” (p. 416), I find them but rudimentary in this
specimen of Puffinus borealis (No. 17776. Smithsonian Collec-
tions), though they are well-developed and functional in a specimen
of Puffinus creatopus (No. 18,773, Smithn. Coll.). In this last-

No. 482] OSTEOLOGY OF THE TUBINARES 117

named species, too, the maxillo-palatines are well-anterior to the
ascending plates of the palatine; moreover, its vomer is notched
at its apex, and is not especially curved downward anteriorly.
These are three well-marked differences in Puffinus borealis and
P. creatopus, and go to prove, what I have always held, that we
can never have too much material before as when comparing the
skulls or any other part of the anatomy of birds.

So far as my observation goes I find that Forbes’s description
of the quadrate bone for the Tubinares agrees with what I found
in other species of the group not examined or seen by him. But
my material does not bear him out so well in his description of the
foramen magnum of the Tubinares, and he says that that opening
“is more or less reniform, with the major axis transverse, in the
small species, whereas in the biggest it is oval, especially in Ossi-
fraga, with the long axis vertical. ‘The moderately sized species
are here again intermediate in structure” (p. 417). Of the two
shearwaters (Puffinus) before me, birds nearly of a size, and both
above the ‘‘small-sized species” of the group, it is found to be
oval in Puffinus borealis, with its major axis vertical, while in
Puffinus creatopus the foramen magnum is subcircular with the
major axis transverse.

The mandible of Puffinus borealis has the articular ends some-
what massive, truncated posteriorly, with very deep ramal sides
for its hinder half, and very shallow ones anteriorly. Apically it
is decurved, and there are lacking recurved angular processes and
ramal vacuities. The articular ends are pneumatic, with the
facets for the quadrate, of course, the reverse in form to those
found on the last-named bone.

The distal elements of the greater cornua of the hyoidean appa-
ratus are much flattened from above downwards, and, as in the
Albatrosses, the parts anterior to the basibranchials are not per-
formed in bone. The first basibranchial is subcircular in form,
and anchyloses with a short urohyal or second basibranchial
(Puffinus).

The sclerotic plates in an eye of P. borealis are small, and some-
what numerous; they are disposed as we usually find them among
birds.

Axial Skeleton: — In the skeleton of Puffinus borealis at hand,

118 THE AMERICAN NATURALIST (Vor: XLI

I find twenty-one free vertebræ between the skull and sacrum.
Of these the thirteenth, fourteenth and fifteenth support a free
pair of ribs; they being quite rudimentary upon the first two, but
are long and slender on the fifteenth vertebra, and are without
unciform appendages. The following six vertebræ have ribs
that connect with the sternum by costal hæmapophysis. ‘There
is also a pair of sacral or pelvic ribs, but their hæmapophyses
fail to reach the sternum, and their lower ends make extensive
articulation with the last pair of true costal ribs, at some distance
above the costal border of the sternum. The pelvis very much
resembles the pelvis of Rodger’s Fulmar figured by me in the Pro-
ceedings of the U. S. National Museum (cited above), and there
are eight free caudal vertebræ plus a somewhat elongated pygo-
style.

The costal border of the sternum is characteristically wide
from side to side, and the pits between the six facettes, unmarked
by pneumatic openings, are very shallow. ‘The sternums of these
shearwaters agree in their general characters with those of the
fulmars.

In P. borealis the xiphoidal extremity is doubly notched upon
either side of the sternal keel, and the form of the bone is there
symmetrical. This is not the case with the xiphoidal extremity
of the sternum of my specimen of Puffinus creatopus. In it, not
only is the left side of the bone somewhat longer than the right,
but instead of showing the two usual notches of the right, it has
three, which appears to have been caused by a bifurcation of the
inner xiphoidal process. These inner xiphoidal processes in P.
obscurus are wonderfully slender.

The shoulder-girdle is much like that of Daption capensis, and
in Figure 1 I present those parts in that species articulated in
situ with the sternum. This figure originally illustrated a paper
of mine which appeared in the Proceedings of the U. S. National
Museum for 1887 (fig. 1, v. X. p. 379), where the skull is likewise
described in connection with other observations upon the osteology
of the Tubinares, and these should be read in connection with the
present memoir.

Returning to the shearwaters, I may say that the arrangement
of the bones of the shoulder-girdle in some of them is as we find

No. 482] OSTEOLOGY OF THE TUBINARES 119

it in Daption, and this is the case with Puffinus obseurus. The
sternum of the former, however, is non-pneumatic, a condition
not found in Puffinus.

Forbes in his work presents a careful and somewhat lengthy
description of the Pectoral arch in general for the Tubinares,
and it agrees very closely with my own observations upon that
bone. I have at present nothing to add to it.

In a specimen of Puffinus borealis I find the humerus to measure
in length 135 millimetres. The bone is non-pneumatic, and is

" Girdle in oil, (Drawn by the author from a specimen in his own collection).
remarkable especially for the prominence of its jutting, papilliform
ulnar crest, and conspicuous triangular radial crest. Its shaft
is quite straight, and at its distal end, proximal, to the external
condyle, we find a strongly developed epicondylar process. At-
tached to this by ligament is an ossicle of some considerable size,
being 14 millimetres long, and of an L-form, with the short arm
of the L bent to an obtuse angle. A rather deep, well-defined
fossa exists immediately above the oblique tubercle, while the
olecranon fossa on the opposite side of the bone is decidedly
shallow. “In the Oceanitide the humerus is conspicuously a
stouter and shorter bone, with its shaft evidently curved instead

120 THE AMERICAN NATURALIST [Vor. XLI

of being almost straight [as it is in Puffinus]. ‘The epicondylar
process projects much less forwards, and is continued down by
an elevated ridge to the surface of the condyle itself.” (Forbes,
p. 422). |

Both radius and ulna in Puffinus are comparatively very slender
bones, the former, measuring 125 mm., is straight, and presents
a well-marked tendinal groove at its disto-superior aspect, over
the carpal enlargement. The ulna is likewise a very straight
bone in the shearwaters, with the elevations for the quill-butts of
the secondary remiges absent from the shaft. Its ends are but
very slightly enlarged, as they are in some birds.

The skeleton of the hand has a length almost equaling the length
of the radius. ‘The terminal finger-points are long, slender, and
pointed distally. Claws are absent. The proximal phalanx of
index digit is very long and narrow; its blade not being fenestrated
as in the Laride. Large and small shafts of the carpo-metacarpus
are rather close together and markedly straight. Above its prox-
imal end is a spindle-shaped, free ossicle of some considerable
size. Possibly it occurs in the tendon of the tensor patagii longus
close to its insertional extremity, but it exhibits no articular facette
for the wrist, as does the os prominens of the Owls and others.

The small phalanx of the medius digit is notably free, and
develops a tendinal tubercle upon its posterior border. Forbes
describes the pectoral limb as it exists in the Oceanitidee, in Ada-
mastor, in Majaqueus, and in Ossifraga of the Procellariin®, and
compares the same as the skeleton of this limb is found iv the
Diomedeinæ (loc. cit. pp. 422, 423).

Puffinus borealis has a femur that in length hardly equals half
that of the tibio-tarsus; it is somewhat antero-posteriorly arched,
the convexity being along the anterior border. Its upper end is
also antero-posteriorly flattened, with the trochanterian crest
about absent, and the pit for the ligamentum teres much scooped
out. A small free patella exists. In the tibio-tarsus the strikirg
feature is the enormous development of its procnemial crest with
a corresponding sub-suppression of the ectocnemial one. ‘This
is even still more marked in Puffinus creatopus, where upon the
posterior aspect of the common prominence, a well-marked,
transverse groove exists, apparently for the accommodation of the

No. 482] OSTEOLOGY OF THE TUBINARES 121

lower margin of the patella. The remaining characters of the
balance of the pelvic limb of Puffinus have already been correctly
described by Forbes, and consequently it will-not be necessary to
reproduce his description in this place. He has also compared
those characters with those found in various other representatives
of this group of birds including Diomedea, Pelecanoides, the
Oceanitide, and the Petrels. (loc. cit., pp. 424, 425.)

In examining the skeleton in the Oceanitide I found among
other things that they lack in the skull the basipterygoid processes,
and that in them the uncinate bones, found in the skulls of other
Tubinares are also absent. ‘The posterior margin of the xiphoidal
extremity of the sternum, is usually quite entire; and they have
but twenty-one cervico-dorsal vertebree. ‘These birds also possess,
in contradistinction to the Procellariid&, short and stout humeri,
a character which is also seen in the long bones of the fore-arm.

Ill. On THE Taxonomy AND AFFINITIES OF THE TUBINARES.

There is a combination of a few marked osteological characters
which will serve to distinguish any member of the present suborder
from any other existing avian group. The Tubinares all have
their skulls characterized by the presence of conspicuous supra-
orbital glandular depressions, which are large and generally deeply
sculpt.

They are likewise all holorhinal, as well as schizognathous
birds, wherein the vomer is usually of considerable size, being
more or less broad, pointed anteriorly, and often depressed and
arched antero-posteriorly. Combined with these characters we
find that in them the hallux of pes to be either absent or else
rudimentary in that it is reduced to a single joint. Not more
than twenty-three cervico-dorsal vertebrae, nor less than twenty-
one are seen to exist. The sternum is short and broad, with its
posterior border either entire, or regularly 4-notched, or of au
asymmetrical pattern, or even jagged. ‘The patella, when present,
is free and small, articulating high up on the posterior aspect of
the much-produced procnemial crest of the tibio-tarsus. ‘The
sternal extremity of a coracoid is of remarkable width, being
nearly as wide there as the bone is long from summit to midpoint

122 THE AMERICAN NATURALIST [Vor. XLI

of base. The superior mandible of the skull is conspicuously
decurved apically, and very sharp-pointed; symphysis of mandible
also more or less decurved, and the articular ends of this bone,
truncated posteriorly.

When the skeleton of any bird ad associated in it all the osteo-
logical characters here enumerated, they are sufficient to indicate
that the species belongs to the suborder Tubinares. ‘These char-
acters are thoroughly diagnostic, and typical tubinarine forms
possess them in the avifauna in any part of the world.

I am of the opinion that the natural classification of the Tubi-
nares is as follows: —

SUBORDER. FAMILIES. SUBFAMILIES.
1. Procellariide. 1. Procellariinse.
2. Oceanitine.
‘ 3. Puffinine.
} 2. Puffinidee. :
TUBINARES. serene: P Fulmarinæ.
3. Pelecanoididæ. :
| 4. Diomedeidee.

This arrangement does not include the extinct forms of this
suborder, but nevertheless the characters presented on the part
of these have been taken into consideration in connection with
taxonomical affinities.

When Mr. Forbes came to sum up his conclusions in regard to
this group of birds, at the close of his extensive paper, cited above,
he said that L’Herminier, A. Milne-Edwards, and Huxley have
all, in describing various points in the osteology of the Tubinares,
pointed out similarities of various kinds between their osseous
structure and that of various forms of Steganopodes, though they
still kept them close to the Laride. Eyton, on the other hand,
places the various petrels he describes in the family ‘Pelecanidee,’
and gulls forming a separate family by themselves.”

“But no one will be prepared, I think, to dispute that the
Steganopodes are allied to the Herodiones, including under that
name the Storks and Herons, with Scopus only.”

“Thus, on osteological grounds alone, there is sufficient ground
for placing the Tubinares in the vicinity of the Steganopodes and
Herodines. And, in fact, neglecting the desmognathous structure
of the palate — the taxonomic value of which, per se, is becoming

No. 482] OSTEOLOGY OF THE TUBINARES 123

more and more dubious as our knowledge of the structure of birds
increases — there is little in the character assigned to the groups
Pelargomorph® and Dysporomorphe by Professor Huxley that
is not applicable to the general Petrel type.” (loc. cit. p. 434.)

In this connection it is interesting to observe that the Tubinares
possess, in common with the Cathartide, the Steganopodes, and
the Ciconiide, a deep-keeled, broad and well-developed sternum;
external osseous nares holorhinal; articular ends of mandible
posteriorly truncated; an evident tendency of the palatine bones
to unite with each other for their posterior moieties; powerfully
developed clavicles, which are strongly curved,— and these
osteological characters co-exist with other similarities to be found
in other parts of the morphological organizations of the respective
groups mentioned.

Structurally, the Cathartide are of great interest, and the
anatomy of those peculiar terrestrial scavengers must be still better
known to us than it is, before we can hope to trace their probable
ancestry.

Remotely akin to the Steganopodes, the Falconidz, or more
generally, the Accipitres, also are linked with these more lowly
avian groups,— as are also the Ardeide, through Scopus.

During the ages past, it is quite evident that hosts of intermediate
forms linking these families and groups have perished and become
extinct. This, taken in connection with the very marked speciali-
zation of the remaining genera, goes far towards proving the great
antiquity of the entire group, and how vast that extinction of the
less specialized forms must have been.

My impression is that perhaps the Tubinares on the one hand
see their nearest relatives in the Steganopodes, in fact there can
now hardly be any doubt upon this point,— while upon the other
hand I am inclined to think that the penguins (Impennes) might
be with truth placed next below them, as Fiirbringer has done.
But such questions as these I will take up more thoroughly later
on, when I come, in another connection, to draw up my scheme
of classification for the Class Aves, and after I have paid further
attention to the osteology of other existing groups.

Nore: — In closing this Memoir I would say that since it was
written there has appeared in the American Naturalist my con-

124 THE AMERICAN NATURALIST [Vor. XLI

tribution entitled “An Arrangement of the Families and the
Higher Groups of Birds (Vol. XXX VIII, Nos. 455-456 Nov-Dec.
1904, pp. 833-857), and, in so far as the taxonomy of the Tubi-
nares is concerned, it sustains what is set forth above; in other
words my opinion in the matter remains the same as it was six

years ago.

NOTES AND LITERATURE

GENERAL BIOLOGY

Transmutation and Agriculture— Much of the evidence upon
which the evolution theory rests has been derived from the experi-
ments of practical breeders. It is doubtful, however, whether practi-
cal workers have ever greatly profited by the incorporation of the
results of their experience into general theories of evolution. The
present volume * seems to be intended as a general and popular review
of the evidence which cultivated plants afford the student of the origin
of species, rather than as a guide or handbook for those engaged in
plant breeding. Naturally many facts of interest to the breeder are
to be found in the discussions of the wide range of material treated,
but there is. no attempt to formulate rules to be followed in any par-
ticular class of practical work or to emphasize the significance of any
particular theory of evolution for agriculturists. ‘The arrangement of
the material under two main divisions, “Minor Species and Mutation,”
and “The Factors of Variation,’ might suggest that the author is
inclined to attach much significance to the views of de Vries and to
the Lamarckian factors. The source of material is not limited to the
results obtained by commercial breeders or agricultural experiment
stations, but recent experimental work of all kinds and especially that
of de Vries and his followers is quite fully treated. In fact, the volume
furnishes a rather interesting index to recent literature bearing on the
evolution theory. It must be said, however, that it is not easy to grasp
the author’s own point of view. 'The-work gives somewhat the impres-
sion of a series of reviews, and while it is desirable that evolutionary
writings should contain less of theory and more of fact than has fre-
quently been the case, a work loses much in interest if it is not written
in support of definite theses which are kept constantly and clearly
in view. Wanting, as it does, an obvious central purpose, the book
is not one of the kind to found a school and it will probably not in-
fluence evolutionary literature materially, but it does furnish a very
readable presentation of the results of much recent work and will
doubtless be of real service to many to whom the more fundamental

works are quite inaccessible.
J. A. Harris

‘Constantin, J. Le Transjormisme appliqué à l’Agriculture. Paris, Félix
Alcan. 1906. 8vo, 300 pp., 105 figs.

125

126 THE AMERICAN NATURALIST [Vor. XUI

Form Analysis —Slowly but surely the necessity of applying pre-
cise mathematical methods to the solution of many biological prob-
lems is becoming apparent to workers in both fields. The chief
application of mathematical methods has been in the study of varia-
tion and heredity, but the problems of leaf form, arrangement of leaves
on the stem, and the convolutions of the shells of gastropods may be
mentioned as having attracted the attention of mathematical workers.
In an address before the American Philosophical Society, Michelson *
emphasizes the importance of the problems of symmetry and suggests
a Classification of symmetrical and unsymmetrical forms.

J. A. HARRIS

GEOLOGY

River terraces at Brattleboro, Vt.— Professor Fisher? has tested
the theory that the river terraces of New England may be accounted
for by the behavior of meandering and swinging streams slowly
degrading previously aggraded valleys without necessary change in
volume and by the control exerted here and there over the lateral
swinging of the streams through the discovery of rock ledges, by apply-
ing the theory to the explanation of the terraces of the West River
near its junction with the Connecticut. It is found that this theory,
elaborated by Davis some years ago, is the only one which will ade-
quately account for the features presented in the district under study.

e lateral swinging of rivers by meanders, cut-offs, and short-
cuts is considered, and the evidence in favor of a fourth process
presented. This latter, called the ‘partition process,’ results when a
sudden withdrawal of the current from banks of erosion is effected,
the stream then forming a sand bar which is not continuous with the
former banks, and the sand bar grows to an island which parts the
stream. Eventually the deeper channel acquires the entire stream, the
deserted channel and former island being thus added to the flood
plain. The West River, swinging by these various processes, and at

; Michelson, A. A. “Form Analysis.” Proc. Amer. Phil. Soc., vol. 45,
pp. 110-116, 1906.

? Terraces of the West River, Brattleboro, Vermont. By E. F. Fisher.
Proc. Bost. Soc. Nat. Hist., Vol. 33, pp. 9-42, pls. 1-11. 1906.

No. 482] NOTES AND LITERATURE 127

the same time slowly degrading its previously aggraded valley, has
encountered numerous rock barriers in its down-cutting, these barriers
controlling the extent and character of the lateral swinging, and thus
determining the variety of terrace pattern described.
The paper is abundantly illustrated by block diagrams, engravings,
and by maps and sections based on a careful survey of the region.
D.

We ee

ANTHROPOLOGY

Quaternary Remains of Man in Central Europe. By Hugues
Obermaier. The presence of man in central Europe in the Quater-
nary no longer admits of doubt. The finds of archeological and skele-
tal human remains dating back to that period, have been numerous.
and well authenticated. They have, in fact, become so numerous and
publications concerning them are so scattered, that a good grasp of
the whole subject is at present a matter of difficulty. Under these
circumstances, Obermaier’s effort to establish “a list of all the quater-
nary anthropological discoveries, discarding those the antiquity of
which is disputable,” is much to be commended. This is especially
the case when we learn that the author endeavored to form his opinions
by visiting the localities where the finds have been made, by personally
examining the collections, and by consulting the men who made =
discoveries.

The following succession of stages and substages during which man
existed in Europe is admitted:

I. 2nd interglacial stage

Substages: Chellean (fauna of a hot climate)
Acheulean (fauna of a hot temperate climate)
The Micoque phase (fauna of the steppes)
II. 3rd glacial stage
Mousterian (fauna of cold climate)
III. 3rd interglacial stage
Tousterian (fauna of temperate, then of hot
climate
Solutrean (fauna of temperate and finally of
cold climate)

1 Les restes humaines quaternaires dans l’Europe centrale. L’Anthropol-

ogie, XVI, 1905, pp. 385-410, XVII, 1906, 55-80.

128

THE AMERICAN NATURALIST

IV. 4th glacial stage, and retreat of the glaciers

agdalenian (fauna of cold climate)
Last quaternary industries
The finds that M. Obermaier considers as indubitably of quater-

[Vor. XLI

nary age can be conveniently arranged into a table. They are as
follows:
Discovered or
first reported Period from which
Country Locality y Nature of the Find it dates
Moravia | Cave Spika Maska Paleoliths. A fragment | Mousterian (fauna
of human lower jaw of cold climate);
yon layers more
rec
Pfedmost Wankel, Maš- | Over 25,000 er. re nding to
ka, KYiz Objects from ge Solutrean
os wood
O
Brno (Brünn) | Makovský use skelet Ob- | Same as preceding
jects of sea bone,
ivor
Croatia Cave Krapina Gorjanovic- Human bones. Stone geringen (with
Kramberger | objects fauna of hot cli-
Austria Willendorf Fischer iece of human femur, “Palsolithir supé-
Woldrich gents aax implements | rieur” correspond-
of stone. Objects of ing a “that f
, horn and bone Předm
Cave Gude- | Hacker 1300 stone implements, Aare
nushöhle Woldřich bjects of horn and
near Krems bone, a human tooth
Germany | Taubach near | Porti, Nehring pone trag Hu- | Mousterian (hot)
Weimar
Andernach Schaafhausen Pat implements, ob- | Magdalenian (cold)
near Coblenz jects of bon ood.
Human teeth Ans parts
f bone:
Switzer- | Cave at Freu- | Karsten Implements. Human | Magdalenian
land dental ones
Cave of Kes- | Merk, Numerous stone imple- | Solutrean
och Nuesch, coe and objects of
Heierli bone ood

Among the ‘doubtful,’ the author places the skulls of most (Briix),
Podbaba, Canstatt, Egisheim, and Neanderthal.
The whole paper is concise, easily read, and furnished with numer-
ous bibliographical references. It is to be hoped the author will fol-
low up the subject and outline in the near future the really ancient and

the doubtful human remains in France, and other parts o

Europe.
HRDLIČKA

No. 482] NOTES AND LITERATURE 129

Pagan Races of the Malay Peninsula.'—T'he two handsome volumes
of over 1500 pages constitute unquestionably the most important con-
tribution to the knowledge of the less civilized peoples of southeastern
Asia. The work, according to the authors (p. VII et seq.) claims to
belong to the scope of “descriptive ethnography,” but this is rather an
unfortunate term because of its redundancy; the text, with the excep-
tion of somatological notes, comes wholly under ‘ethnology,’ as under-
stood in this country. It is “essentially a compilation from many
sources, but differs from most books of that kind, first, in being based
to a very large extent on materials hitherto unpublished, and accessible
only through private channels of information; and secondly, in having
been constructed with special knowledge of the subject and in a critical
spirit.” Itis a work of “many facts, but few hypotheses,” and should
be regarded not solely as a monograph on the tribes dealt with, “but
also as a necessary preliminary to a general scientific survey of the races
of southern Indo-China and the Malay Peninsula” — which survey
is strongly advocated. The objectionable term “pagan,” used in the
title as a discriminative of races is justified by the opinion that “the
point of religion (as between Mohammedan and non-Mohammedan)
was perhaps a better dividing line, on account of its definiteness,
than the vague, indefinite, and perhaps undefinable, quality of wild-
ness.” The bulk of the book was written by Skeat, the attention of
Blagden being confined to language.

The contents of the two volumes, besides preface, bibliography, and
introduction, are, vol. I: Racial characters and affinities; Notes on
diseases; food, stimulants, narcotics; dress; habitations; hunting,
trapping, and fishing, barter; weapons and implements; cultivation;
arts and crafts; decorative art; social order; dealings with other races;
and place and personal names. Vol. II: Birth-customs and beliefs;
maturity customs and beliefs; marriage customs and beliefs; burial
customs and beliefs; music, songs, and feasts; natural religion and
folk-lore; and language. Both volumes are provided with abundant
illustrations, nearly all of which are photographs.

The reading of the book reveals a mass of details such as has been
brought together in few other works, and which will be of great utility
in further studies of the peoples of the Malay Peninsula, as well as
that from the mainland further north and the islands to the south-
ward.

Three distinct racial types are recognized, namely the Semang, or

*Skeat, W. W., and Chas. O. Blagden. Pagan Races of sy .. Penin-
sula. 2 vols., Svó, London (Macmillan & Co.), 1906. 42/ne

130 THE AMERICAN NATURALIST [Vor. XLI

Negrito, the Sakai, of suggested Dravidian ancestry, and the Jakun,
or aboriginal Malay. They differ principally in head form, physiog-
nomy, and nature of the hair. The Semang are meso- to brachy-
cephalic, with woolly hair, and features approaching, in a number of
particulars, the negro; the Sakai are dolichocephalic, with wavy hair
and finer features; the Jakun are brachycephalic, with straight hair
and with the features of the Malay in general. All are short in stature,
but the Semang are the smallest. In color the Semang are chocolate-
brown to black, the Sakai and Jakun ranging from brown to yellowish.
Both the Sakai and Jakun show numerous instances of admixture with
the Negrito.

The chapters on the foods and mode of life of the individual
tribes are valuable; but the diseases of the people, their environment,
and especially their physiology are far from being treated adequately.
The total number of the ‘pagan’ aboriginies of the Malay Peninsula
appears to be no more than 35,000 or 40,000.

For the mass of details concerning the habits, religion, folk-lore and
language of the tribes the reader must be referred to the original.

The book as a whole will not be found easy reading. This is partly
due to its plan, including several appendices, partly to the many native
names, and in some degree to the style of the authors. More tabula-
tion would have been of help. However, the work must be regarded
not as a narrative, but more as a reference hand-book of the tribes
of the Malay Peninsula, and as such it will be highly appreciated by
every student of that region. For this purpose, however, a more
copious index, and page references instead of the occasional ‘‘will be
found in another part of the work,” would have been desirable.

The illustrations are not always satisfactory. There are a number
of photographs that show but little, and a few (e. g. the ‘‘Kedah-
Raman,” “Kedah,” superior plane of the Semang skull, the “Semang
of Grit,” the “Sakai at G. Kerbu,” the “Group of Ulu Jelai Sakai”)
which are wholly useless, being out of focus. It is not easy to see what
was the object of the authors or publishers in including these pictures
with the many others which are of real value.

A. HRDLIČKA

Growth of Parisian Children.'— The paper presents the results of
the determinations of height and weight of 4400 children from various

1 Tables de croissance des enfants Parisiens de I a 16 ans. Par MM. Variot
et Chaumet. Bull. & Mém. Soc. d’Anthrop. Paris, Vme Sér., VII, No. 2, pp.
51-65.

No. 482] NOTES AND LITERATURE 131

Parisian nurseries and schools. The series includes at least 100 sub-
jects of each sex for every year of life, which insures the value of the
averages. The study is the first of its nature made in France; Godin’s
well known observations were made on older individuals.

The results agree in the main with those of measurements of white
children in other countries. Up to the end of their eleventh year the
girls are shorter than the boys; between their eleventh and twelfth
years they pass the boys in this regard, and continue taller until after
their fourteenth year, after which they are definitely passed by the
boys. In weight the physiological excess of the female children
becomes marked even earlier and they exceed the boys from the end
of the ninth to a little beyond their fifteeth year.

A comparison of these data with those obtained by Professor C. P.
Bowditch on Boston children shows that between the ages of thirteen
and sixteen the Parisians slightly exceed the Americans in height.
This can very likely be attributed to earlier puberty in the French

adolescents.
A... BD,

Anthropometric data on the Norwegians.— Messrs. Daae report? the
results of measurements, by military surgeons, of 3,955 recruits of
between 22 and 23 years of age.

The data show that the average stature of the Norwegians of that
age is 172.1 cm. The tallest men are in the district of Jarlsberg-Larvik
(173.4 cm.), the shortest in the district of Finmarken (168.5 cm.).

The mean arm-spread amounts to 178.2 cm., and is to stature as
103.55 to 100. . It is relatively shortest (102.2 to 100) in the Bergenhus-
Sud district, peopled by fishermen who all the year around work with
oars.

Height sitting was found to average 91.2 cm., bearing a relation to
stature as 52.98 to 100. The proportion is smaller (52.46) among the
tallest men, and larger (53.61) among those of the shortest stature.

The mean circumference of the chest is 87.3 cm., ranging in the dis-
tricts from 86.2 to 89.6. The relation it bears to stature is as 51.04 to
100. ws

A.H.

‘See the American Naturalist, XX XIII, July, 1899, p. 605 et seq.

? Sur la taille, ’envergure, le périmètre thoracique et la hauteur du buste
chez les populations de l'intérieur et de cotes de la Norvège. Par M. A.
Daae et le Dr. H. Daae. Bull. & Mém: Soc. d’Anthrop. Paris, Vme Ser.,
VII, No. 3, 1906, pp. 158-164.

132 THE AMERICAN NATURALIST [Vor. XLI

The population of Tripoli, according to the latest official data,’
amounts to 711,242. Among this are 16,670 Jews. ‘The most south-
ern point at which the latter are found is Orfella. They live an ex-
tremely miserable life and in places suffer even partial slavery. “They
do not emigrate because they know not where to go.

A. H.

ZOOLOGY

Dean’s Chimeroid Fishes” is one of the most strikingly illustrated
works yet issued by the Carnegie Institution. Any adequate sum-
mary of its contents is impossible here; all that can be attempted is
an enumeration of its contents. For several years Dr. Dean has
labored indefatigably in obtaining embryos of this group of rare
Selachians. The work is based on the eggs of the Pacific Chimera
collei, the eggs of which were obtained from the gravid females and then
incubated in floating boxes, but unfortunately these often broke adrift
and about 150 eggs have been lost in this way.

After an introductory chapter on methods and the like Dr. Dean
first describes the appearance, habits, etc., of the fish and then proceeds
to a study of the development. The egg-capsule is beautifully figured
and described in detail, this part of the work being made more valuable
by figures of the egg-capsules of other chimeeroids, both recent and
fossil. The egg is fertilized before oviposition and Dr. Dean was
fortunate enough to get specimens showing various phases of the proc-
ess of fusion of the male and female pronuclei. Polyspemy is appar-
ently the usual condition. ‘The segmentation is in general of the usual
Selachian discoidal type but is accompanied by a fragmentation of
the yolk. A single early stage of gastrulation is described in detail, the
striking feature being that the blastopore is not, as in other elasmo-
branchs, at the edge of the blastoderm but inside its rim, a condition
which throws much light on gastrulation in other forms, conclusions
which are supported by two other stages.

1 Méhier de Mathuisieulx, L’Anthropologie, XVII, 1906, Nos. 1-2, pp. 237-
239

2 Dean, Bashford: Chimsroid Fishes and their development. Carnegie
Institution, Publication 32, Washington, 1906, pp. 194, 11 plates.

No. 482] NOTES AND LITERATURE 133

Of the stages after the closure of the medullary folds the accounts
are far less detailed than we could wish and there are many gaps in
the organogeny which remain to be filled but which cannot at present
be described on account of lack of material. Especially interesting
are the figures given of a reconstruction of the skull of a well advanced
embryo in which the pterygoquadrate bar is not completely fused
with the cranium. Other features of organogeny given are concerned
with (1) the integument and dentition in which embryos and larve of
other chimeeroids are considered and the conclusion is reached that
the dental plates represent fused denticles. (2) The skeleton which is
largely based on the work of Schauinsland. (3) The viscera. ere
is, even in early stages, no continuous mesentery. A few words are
devoted to gut, gills and nephridial structures.

The third section, one of the most valuable of the work, is a discus-
sion of the fossil chimeroids. The existence of Silurian members of
the group is more than doubted, but, as shown by the Ptyctodonts,
they probably occurred in the Devonian. The definite knowledge of
the group began with the lower Jurassic, since which time numerous
undoubted chimeroids have occurred, the group attaining its maxi-
mum development in the cretaceous. These fossils and the structure
and embryology of the existing species are invoked to show that the
chimeeroids are not a primitive group but are a modified and specialized
development from forms more like the normal Selachians. An exten-

sive bibliography closes the volume.
J.S. K.

Development of the Mammalian Lung. Flint (Am. Journ. Anat.
6, 1906) describes in a long paper the development of the lung and
associated structures in the pig. The anlage is asymmetrical, and its
origin, below the level of the gill pouches is an argument against any
phylogenetic connection between lungs and gill pouches. The develop-
ment of the bronchi is followed in detail and many variations noted, the
complete series including sixteen on one side and seventeen on the
other, a condition rarely occurring. AEby’s conclusion that the pul-
monary artery differentiates two lung regions of different morphologi-
cal significance is not supported. The pulmonary veins arise as an
outgrowth from the undivided portion of the sinus venosus, the veins
to the right and left lungs developing by specialization in the capillary
plexus. In the earlier history the division of the respiratory ducts is
monopodial in character as in the lower pulmonate vertebrates and it
is only in the other stages that dichotomous division, characteristic

134 THE AMERICAN NATURALIST [Vor. XLI

of the mammals, sets in. The histogenesis and the development of
the lymphatic system are also traced. The early stages were studied
by Born reconstruction methods, the later by digsedtion and by corro-
sive preparations.

Half Hours with Fishes, Reptiles and Birds‘ is the second in the
series of books by C. F. Holder, designed as supplementary readers
for children in the grammar grades. The section devoted to birds
suffers from the same defects in the arrangement of material that were
pointed out in the review of the earlier volume (American Naturalist,
40, p. 140, 1906). The part dealing with fishes is full of interesting
information vividly presented. -

ReH:

Notes.— In the Proceedings of the Indiana Academy of Science for
1905 (1906) Dennis and Petry give an interesting series of photographs
of the young of the turkey buzzard showing the changes in the plumage
from the tenth to the seventy-fourth day after hatching.

Zeleny (Proc. Acad. Sciences Indiana [for 1905] 1906) describes
the regeneration of an antenna-like appendage in the place of an
excised eye in the blind crayfish. The new organ has the appearance of
a functional tactile organ and the experiment has especial interest in
that a functional organ has developed in place of the functionless eye.

Martin describes (Proc. Indiana Acad. Sci. [for 1905] 1906) a handy
clamp by which the blades of ‘safety razors’ may be used for section
cutting, thus materially reducing the cost, confusion, etc., of supplying
section knives to large classes.

Madison Grant publishes some “Notes on Adirondack Mammals”
in the Eighth and Ninth Report of the Forest Fish and Game Commis-
sion of New York. The paper, which supplements Dr. Merriam’s
well known work on the same region, is illustrated with some fine half
tones, some taken in the forest, others in the New York Zoological

Gardens.

C. W. Johnson has collected all the references to the appearance and
distribution of the English garden snail, Helix hortensis, in America
and is inclined to think (Nautilus, 20, p. 73, 1906) that it has not been

! Half Hours with Fishes, Reptiles and Birds. By Charles Frederick Holder.
N. Y. American Book Company. pp. 255. Illustrated.

No. 482] NOTES AND LITERATURE 135

introduced by man within comparatively recent years nor by the
“vikings” but is a much older inhabitant of this continent.

Lönnberg (Arkiv för Zoologi, 3, 1906) discusses the systematic posi-
tion of the extinct Irish Elk. This is usually closely associated with
the common fallow deer. Lönnberg thinks that this association
rests almost exclusively upon the somewhat similar palmated antlers
but that in other and more important features there is more affinity
with the reindeer than with any other cervicorn, although it presents
considerable specialization in its own line.

Froriep gives (Verhandl. Anatom. Gesellschaft, XX, 1906) a detailed
comparison of the eyes of vertebrates and tunicates and concludes
that both are derivable from a common ancestral condition which is
closer to the optic pit of the vertebrate than to the eye of the ascidian
larva. Two weeks later comes the Anatomischer Anzeiger (xxix, p.
526 Nov. 24, 1906) in which Metcalf discusses the relation of the ver-
tebrate eye to that of Salpa suggested by Redikorzew, and holds that
the views of the latter are untenable but he says “It may not unlikely
be true that the condition with a single anterior enlargement of the
central nerve tube is ancestral (cf. Amphioxus and the tunicate tad-
pole).”

BOTANY

The Journals: — The American Botanist, September: — Saunders,
“Under Sierra Pines”; Bailey, “The Leaf Alert or Drowsy”; Dobbin,
“A Word Concerning Trees”; Blanchard, “A New Dewberry.”

The Bryologist, September:— Haynes, “Some Characteristics of
Lophozia inflata and Cephalozia fluitans”; Evans, “ Lepidozia
sylvatica” ; Best, “Ptychomitrium leibergü”; Howe, “Some Addi-
tions to the Flora of Middlesex County, Mass.”; Nayler, “ Micro-
scopical Technique”; Merrill, “Lichen Notes no. 4, — A Study of
Umbilicaria vellea and U. spadochroa.”

The Botanical Gazette, August:— Ganong, “The Nascent Forest of
the Miscou Beach Plain”; Shreve, “The Development and Anatomy
of Sarracenia”; Osterhout, “Physiologically Balanced Solutions for
Plants”; Hasselbring, “The Appressoria of the Anthracnoses”; Frye,

136 THE AMERICAN NATURALIST [Vor. XLI

“ Nereocystis luetkeana”; Greenman, “Two New Species from North-
eastern America.”

The Botanical Gazette, September :— Blakeslee, “ Differentiation of
Sex in Thallus Gametophyte and Sporophyte”’; Shantz, “A Study
of the Vegetation of the Mesa Region East of Pike’s Peak: The
Bouteloua Formation — II”; Kauffman, “Cortinarius as a Myco-
rhiza-producing Fungus”; Smith and Smith, “A New Fungus of
Economic Importance” [Pythiacystis citriophthora,— forming a
transition from Pythium to Phytophthora].

The Botanical Gazette, October:— Atkinson, ‘The Development
of Agaricus campestris”; Crocker, “Rôle of Seed Coats in Delayed
Germination”; J. D. Smith, “Undescribed Plants from Guatemala
and Other Central American Republics”; C. O. Smith, “A Bacterial
Disease of Oleander.”

Bulletin of the Torrey Botanical Club, August:— Arthur and Kern,
“North American Species of Peridermium”; MacKenzie, ‘‘ Notes on
Carex — I”; Abrams, “Two New Southwestern Species of Pent-
stemon.”

Bulletin of the Torrey Botanical Club, September :— Eaton, “ Pteri-
dophytes Observed during three Excursions into Southern Florida” ;
Mathewson, “ The Behavior of the Pollen-tube in Houstonia cerulea” ;
House, ‘‘ Studies in the North American Convolvulaceee — II. The
Genus Operculina.”

Bulletin of the Southern California Academy of Sciences, June:—
Hasse, “Contributions to the Lichen Flora of Southern California” ;
Parish, “Additions and Corrections,” and “A Preliminary en |
of the Southern California Cyperacex — XII.”

Journal of Mycology, July:— Kellerman, “Mycological Expedition
to Guatemala”; Charles, ‘Occurrence of Lasiodiplodia on Theobroma
cacao and Mangijera indica”; Hedgecock and Spaulding, ™ A New
Method of Mounting Fungi Grown in Cultures for the Herbarium” ;
Peck, “A New Species of Galera”; Arthur, “Reasons for Desiring a
Better Classification of the Uredinales”; Morgan, “North American
Species of Lepiota; [I.] Descriptive Synopses of Morgan’s North
American Species of Marasiums’’; and “Synopsis to North American
Species of Heliomyces”; Garrett, “Field Notes on the Uredinee”’;
Kellerman, “Notes from Mycological Literature — XX.”

Journal of the New York Botanical Garden, September:— Murrill,
“Further Remarks on a Serious Chestnut Disease”; Rusby, ‘‘Obser-

No. 482] NOTES AND LITERATURE 137

vations in Economic Botany Made at Oscoda, Mich.” Gager, “Sym-
biosis in Gunnera manicata.”

Journal of the New York Botanical Garden, October:— Murrill,
“A Summer in Europe: Some Foreign Botanists and Botanical
Institutions.”

The Plant World, August:— Fink, “The Gynecocentric Theory
and the Sexes in Plants”; Rusby, “An Historical Sketch of the Devel-
opment of Botany in New York City” (concluded); Cook, “ Tropical
Epiphytes.” :

The Plant World, September:— Shreve, “The Hope Botanical
Gardens”; Gager, “Outline Study of Seeds and Seedlings’; Robin-
son, ‘“ The Filmy Ferns.”

Rhodora, August :— Lamson-Scribner, “ The Genus Sphenopholis” ;
Blanchard, “Some Maine Rubi. The Blackberries of the Kenne-
bunks and Wells — I”; Collins, “Notes on Algee — VIII”; Fernald,
“Some New or Little Known Cyperacez of Eastern North America.”

Rhodora, September:— Blanchard, “Some Maine Rubi. The
Blackberries of the Kennebunks and Wells — II”; Fernald, “Some
New or Little Known Cyperacee of Eastern North America” (con-
tinued); Knight, “A New Variety of Carex trisperma”; Hill, “ The
Perianth of Rynchospora capillacea var. leviseta”; Knight, “ Ha-

ria macrophylla in Maine.”

Rhodora, October:— Collins, ‘‘Acrochetium and Chantransia in
North America”; Robinson, ‘The Nomenclature of the New England
Lauraceæ”; Fernald, “Some New or Little Known Cyperacee of
Eastern North America”; Robinson, “Filipendula rubra, a new
Binomial.”

The fourth annual volume of the International Catalogue of Scien-
tific Literature, M, Botany, is dated in July, 1906, and forms an octavo
of nearly 1000 pages.

Torreya, September:— Gager, ‘‘Tuber-Formation in Solanum
tuberosum in Daylight,” Murrill, “A New Chestnut Disease” [Dia-
porthe parasitica]; Bailey, “A Newly Introduced Plant in Rhode
Island”; Hollick, “ An Addition to the Flora of Block Island”; Rob-
bins, ‘Tubular Ray-Flowers in Gaillardia aristata”; Wilson, “ My-
cological Notes from Indiana”; Harper, “A hitherto Unnoticed
Relation Between Viola pedata and Iris verna”; Bruckman, “ Fasci-
ations in Arisema, Rudbeckia, and Viola.”

138 THE AMERICAN NATURALIST [Vor. XLI

Torreya, October:— Harper, “Midwinter Observations in South-
eastern Mississippi and Eastern Louisiana”; Dowell, ““Observations
on the Occurrence of Boott’s Fern”; Farwell; “ Note on the Identity
of Trillium obovatum Pursh”; MacKenzie, “Lespedega simulata in
New Jersey”; Gager, “Further Note on the Formation of Aérial
Tubers in Solanum.”

Vol. 7, part 4, of the current botanical series of Transactions of the
Linnean Society of London is devoted to an account of Sutclifha,
representing a new type of Medullosez from the lower Coal Meas-
ures, by Scott.

Zoe, September :— Brandegee, “ Plants of California,” “New Species
of Mexican Plants Collected by Dr. C. A. Purpus,” and “Plants of
Sinaloa.

The following papers of botanical interest occur in the recently
issued second volume of Proceedings of the American Breeders’ Asso-
ciation :— Shamel, “Tobacco Breeding”; Montgomery, “The Corn
Plant as Affected by Rate of Planting”; Lyon, “Some Correlated
Characters in Wheat and Their Transmission”; Ten Eyck, “Plant
Adaptation”; Freeman, “The Use of the Seed Plant in the Prevention
of Diseases in Wheat”; Ward, “Economic Value of Plant Breeding” ;
Westgate, “A Method of Breeding a Strain of Alfalfa from a Single
Individual” ; Webber, “Correlation of Characters in Plant Breeding” ;
Keyser, “Variation in Wheat Hybrids”; Funk, “Practical Corn
Breeding on a Large Scale”; Hopkins, “Breeding Timothy” ; Emer-
son, “Laboratory Work in Plant Breeding”; Gauss, ‘‘ Breeding
Drought-Resistant Crops”; Bessey, ‘‘Crop Improvement by Utilizing
Wild Species”; Zavitz, “Breeding Cereals”; Hansen, “Breeding
Hardy Raspberries for the Northwest”; Carleton, “Fundamental
Requirements for Grain Breeding”; Hartley, “Value of Corn Pollen
from Suckers vs. from Main Stalks”; Stockdale, “Improvement of
Sugar Cane by Selection and Hybridization”; Hays, “ American
Work in Breeding Plants and Animals” ; Hansen, ‘‘ Methods of Breed-
ing Hardy Fruits”; Williams, “Methods and Results of Hybridiz-
ing Fruits”; Keyser, “ Methods in Wheat Breeding”; Beach, ‘Grape
Breeding”; Fruwirth, ‘Enclosing Single Plants, and its Effect on a
Large N nase of Important Agrieultural Species”; Camp, ‘Breeding
Grapes”; Patten, “Results from Work in Diving Hardy Fruits.”

(No. 481 was issued January 8, 1907)

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THE
AMERICAN
NATURALI

The American Naturalist
ASSOCIATE EDITORS = ae

_ J. A. ALLEN, Px.D., American Museum of Natural History, New York
E. A. ANDREWS, PaD., Johns Hopkins University, Baltimore

_ WILLIAM S. BAYLEY, Pu.D., Colby University, Waterville’
DOUGLAS H. CAMPBELL, Pu.D., Stanford University

_ J. H. COMSTOCK, S.B., Cornell University, Ithaca.

: WILLIAM M. DAVIS, M. E., Harvard University, Cambridge

_ ALES HRDLICKA, M.D., U.S. — er Washington
D. S. JORDAN, LL.D. | Stanford U

CHARLES A. KOFOID, Pu.D., Ove = Calijornia, Berkeley

Cornel LU

ARNOLD E. ORTMANN, Pa.D er ns Pittsburg
DE PENHALLOW, D.Sc., F. R. S.Ç., McGill University, M aed
$ En . . = k

ALL. ake ashington
DSTI LINEGER, LGD. Siniihaontan Institution, Washington
Ss. .D., Missouri Bolanceal Cordes St. Louis

RD, Pr.D., aati of Nebraska, Lincoln
WHEELER, | en American. Museum .of Natural History,

ies of pl
I be briefer articles on various
on scientific ee of the
‘a aod a ‚record of

g interesting to say are ied ; =
but the editors will endeavor to select =

THE
AMERICAN NATURALIST

Vor. XLI March, 1907 No. 483

STUDIES ON THE OPHIOGLOSSACER

DOUGLAS HOUGHTON CAMPBELL

THE family of the Ophioglossaceze comprises the three genera—
Ophioglossum, Botrychium and Helminthostachys, which are all
evidently related, but whose affinities with the other Pteridophytes
are not so clear, and there is a good deal of difference of opinion as
to where they should be placed. Most botanists agree that the
Ophioglossacez are related to the true ferns, but this view is not
universally accepted, although the results of the more recent in-
vestigations tend to strengthen this conclusion.

The most marked feature of the family is the peculiar fertile
leaf segment or spike; and the present paper is mainly concerned
with the question of the morphologic nature of this sporophyll.

During the past year the writer had an opportunity of collect-
ing a large amount of material of the Ophioglossacee in Ceylon,
Singapore and Java. This included several species of Ophio-
glossum, one of Botrychium, and the monotypic Helmintho-
stachys,— so that it has been possible to make a first-hand study
of all the genera belonging to the family. The following account
of the morphology of the leaf is based mainly upon a study of
this material.

THE MORPHOLOGY OF THE SPOROPHYLL.
In all of the Ophioglossacex the sporophyll consists of a fertile
and a sterile segment. ‘The former (Figs. 1, 3, 4, 6, 7) is a stalked
structure, the peduncle being often very long. The sporangia

are in two rows in Ophioglossum, but in the other genera the
fertile portion of the spike is more or less extensively branched,

139

140 THE AMERICAN NATURALIST [Vor. XLI

this being very marked in the larger species of Botrychium. The
two segments of the sporophyll may be almost entirely separate,
e. g., Ophioglossum bergianum, Botrychium ternatum, or the fertile
segment may be apparently an outgrowth of the base of the sterile
segment or from above its base.

The earlier views of the morphologic value of the fertile leaf
segment were strongly influenced by the prevailing theory that
the fertile portion was a secondary development of originally
sterile leaf tissue, and therefore must be homologized with some
portion of the sterile leaf. The belief more generally current
at present that the fertile structures of the sporophyll are older
than the sterile ones, inclines toward a different interpretation
of the real nature of the fertile segment.

Bower (Studies in the Morphology of Spore-producing Mem-
bers, II, Ophioglossacee. London, 1896) has given a very com-
plete account of the different theories that have been advanced
to explain the morphology of the fertile spike in the Ophioglos-
saceze, and we shall merely give here a brief summary of the more
important of these. Mettenius (Farne des Bot. Garten zu Leip-
zig. 1856, p. 119) regarded the two parts of the leaf as of equal
importance, but gives no data as to their method of origin,—-
whether by the equal branching of a common primordium or
otherwise. Later writers, e. g., Holle (Bot. Zeit. 1875, p. 271)
and Goebel (Schenk’s Handbuch, vol. 3, p. 111) consider the
fertile spike as the equivalent of the fertile pinnæ of such a fern
as Aneimia. The former considers the single median spike to
be the result of the coalescence of two lateral pinnze; the latter
as a single pinna which arises in a median position.

Bower himself has made the most complete study of the develop-
ment of the spore-bearing parts of the Ophioglossacez that has
ever been made. He concludes that the spike of Ophioglossum
is morphologically equivalent to the single sporangium of Lycopo-
dium. In this view he has the support of Strasburger (Bot.
Zeit., 1873) and Celakovsky (Pringsheim’s Jahrb., 1884, vol. 14).
Bower has, however, more recently described a most remarkable
species of Ophioglossum (Ann. of Bot. 18, p. 205, 1904) O. simplex
Ridley, which makes possible another interpretation of the nature
of the spike, 7. e., that it is a terminal and not a lateral organ.
The writer (Mosses & Ferns, 2d edit., p. 600) in view of the dis-

No. 483] STUDIES OF THE OPHIOGLOSSACEE 141

covery of this remarkable form, has ventured the hypothesis
that in O. pendulum the sporangiophore may also be terminal.
In order to make a thorough investigation of the question, the
collections of material already referred to were made and the
results of this study and the conclusions to be drawn from it are
given in the present paper.

THE GENERAL MORPHOLOGY OF THE SPOROPHYLL.
ÜPHIOGLOSSUM.

The genus Ophioglossum com-
prises, according to Bitter (Engle-
& Prantl, Die Naturlichen Pflanzen-
familien, 1 Theil. Abt. 4, p. 466)
about thirty species, but it is prob-
able that the number is much great-
er, as the species have not been
critically studied in some regions
where the genus is well represent-
ed. Bitter recognizes three sections
of the genus, Euophioglossum Prantl,
including most of the terrestrial spe-
cies; Ophioderma Presl, with O.
pendulum L. and O. intermedium
Hooker; and Cheiroglossa Presl.
with the single species, O. palma-
tum. The subgenus, Rhizoglossum
Presl, is also sometimes recognized
to include the single species O.
bergianum.

The great majority of the species
belong to the first section, Euophio-
glossum. The writer collected a
number of species in Ceylon and
Java, but it was found very difficult
to identify them, as in neither the : ae oor rein pie Ve
collections at Peradeniya nor Buiten- Be size; S By Smali form oi
zorg was the genus well represented, ee
and there is evidently very much confusion as to the species.

142 THE AMERICAN NATURALIST [Vor. XLI

Raciborski, who has published a list of Javanese Pteridophytes
(Die Pteridophyten der Flora von Buitenzorg, Leiden, 1898) gives
only one terrestrial species, O. moluccanum Schlecht.; but it is
evident from the writer’s collections that there are at least four spe-
cies belonging to Euophioglossum in western
Java and possibly more.

What seems to be the typical O. moluccanum
(fig. 1, A) is a species of moderate size. ‘The
specimen shown has a sterile leaf somewhat
smaller than usual, but otherwise is typical.
One of the smaller forms of the same (?) spe-
cies is shown in fig. 1, B. In both of these
the sterile lamina is small, while the peduncle of
the spike is. very long and not very much infe-
rior in thickness to petiole below the junction
of the spike and the sterile lamina. Most of
the other species of the section, e. g., O. vul-
gatum L., O. californicum Prantl, O. reticulatum
L., etc., agree in the main with O. moluccanum,
and in none of these is there anything in the
external morphology of the adult sporophyll to
forbid the assumption that the sterile lamina
is a lateral appendage of the spike.

The second section of the genus, Ophio-
derma, comprises O. pendulum L., O. interme-
dium Hook. and probably also O. simplex
Ridley. In the latter species (fig. 2), which
was discovered by Ridley in Sumatra, the fer-
tile leaf consists of a narrow basal part without
any lamina, terminated by a spike similar to
that in O. pendulum, and it was assumed to be
the nearest relative of this species. ‘There is,
however, no peduncle developed as is the case
in O. pendulum and O. intermedium. It is well
(after Bower). known that in O. pendulum (see Fig. 3) the
| short peduncle of the spike which apparently

arises from the lamina itself, is continued into a sort of thickened
mid-rib which is not developed above the insertion of the peduncle

No. 483] STUDIES OF THE OPHIOGLOSSACEE 143

of the spike, and the latter may very well be interpreted as the
apex of the leaf, the lamina being lateral and closely coherent with
its basal portion.

In all the species of Ophioglossum the growth of the basal part
of the young sporophyll is very much more active than that of the
lamina which remains relatively small, although the young spike
is conspicuous in the early stages. This is especially marked in O.

Fig. 3.— A, Young sporophyll of nei ey (Ophioderma) pendulum L.. X 2;
B, an older En epee size a still older stage; D, base of a large spike,
natural size; E, mall en in which the sterile lamina, L, is very
greatly en: ke size,

pendulum (Fig. 3). This is the largest of the genus, and is’a
striking epiphyte of the moist tropies of the old world, extending,
however, to the Hawaiian Islands. The specimens figured were
collected in the botanical garden at Singapore.

In the youngest specimen shown (Fig. 3, A), the thick fleshy

144 -.. THE AMERICAN NATURALIST [Vor. XLI

leaf base terminates in a very small pointed lamina that is usually
bent over, suggesting the circinate vernation of the true ferns. In
most of the terrestrial species of Ophioglossum the young leaf is
folded straight in the bud. Under the arched hood formed by the
lamina is the young spike (Sp.) which almost equals the lamina in
length.

Fig. 3, B, shows a somewhat older stage. The leaf has now
become somewhat flattened, but there is no clear demarkation
between the petiole and the small lamina. ‘The fertile segment,
which shows as yet no differentiation of the peduncle and spike,
is conspicuous, and merges gradually into the thick petiole of the
leaf whose margins are more or less distinctly winged and pass
imperceptibly into the lamina above the insertion of the fertile
segment. The interpretation of the latter as terminal and the
sterile portion as a lateral appendage coherent with it would seem
entirely plausible. An interesting case is shown in Fig. 3, E,
where the lamina is almost entirely suppressed, and the terminal
character of the spike is very evident.

As the leaf develops there is a very great increase in size of the
lamina, which, in some of the largest individuals collected in Cey-
lon and Java, reached a length of one and one-half metres, or even
more. These large leaves usually have the lamina dichotomously
divided, and strikingly resemble the long drooping leaves of some
species of Platycerium. Nevertheless even in these larger leaves
the segments are quite destitute of a mid-rib. This stops at the
base of the peduncle of the spike into which it is continued. ‘The
spike in these large specimens is correspondingly large, and some-
times attains a length of 25 to 30 centimetres, with a breadth of
more than a centimeter (Fig. 3, D).

Undoubtedly allied to O. pendulum is the rare O. intermedium
Hook. (Fig. 4). This is also perhaps the nearest ally of O. sim-
plex. In the ordinary form (Fig. 4, A, B) this is not unlike a
small specimen of O. pendulum, but it is rigidly upright instead
of lax and drooping, the peduncle is longer and the lamina of the
leaf much smaller and more sharply separated from the petiole.
As in O. pendulum, however, the petiole is prolonged into the
peduncle of the spike with the same mid-rib like thickening,
caused by the coherence of the basal part of the peduncle with
the lamina.

No. 483] STUDIES OF THE OPHIOGLOSSACEE 145

Even in the small number of specimens collected (the plant is
an extremely rare one) a number of very interesting variations
were found, some of which approximated quite closely the condi-
tion found in O. simplex. In these the lamina was greatly reduced,
and in one case (Fig. 4, E) formed merely the narrow wing along
the margin of the petiole and peduncle of the spike. In the other

os
——

Fig, ne — Ophioglossum (Ophioderma) intermedium Hook. several plants reduced
bout 4, showing variation in form; K, root-bud.

cases the lamina was wider and its apex free, but even in these the

‘lamina was very small, and the terminal position of the spike

extremely evident (C, D).

In both O. pendulum and O. intermedium the spike is more
flattened than in the section Euophioglossum, and the central
sterile portion wider in proportion. Stomata are almost entirely
absent from the spike of O. pendulum, and the few that are occa-
sionally found are confined to the central part. In O. intermedium
the stomata are more numerous than in O. pendulum, but much
less numerous than in O. moluccanum, for example, where they
also occur upon the epidermis of the wall of the sporangium.

146 THE AMERICAN NATURALIST [Vor. XLI

The third section, Cheiroglossa, represented by the monotypic
O. palmatum L. of the American tropics differs from the others of
the genus in having, usually, several spikes which are not generally
borne in the median plane of the leaf, but are inserted near the
margin. Bower (loc. cit., figs. 116-117) has shown that there
may occasionally be a single spike which is then borne in the
same position as in O. pendulum. He supposes that O. palmatum
has been derived from the form with a single median spike like
that of O. pendulum by branching of the spike, which not infre-
quently occurs in the latter species as well as in some others. ‘The
separation of the originally connected spikes he assumes has been
the result of the great expansion of the lamina, which is much
broader in O. palmatum than in any other species. Unfortunately
the developmental history of the sporophyll in O. palmatum is
quite unknown.

THE YouNG SPOROPHYLL.

The differentiation of the two parts of the sporophyll takes

Fic. 5.— A, Nearly median section of a very young sporophyll of O. pendulum, X
about 90; B, section of an older sporophyll, X 50; Sp. the apex of the spike;
L, the sterile leaf-segment.

No. 483] STUDIES OF THE OPHIOGLOSSACEE 147

place at a very early period, and at this time the fertile spike is
already evident as a conspicuous protuberance on the adaxial
side of the leaf rudiment not far from its apex. Both divisions
of the young sporophyll terminate in an apical cell, and both
apparently grow in the same way.

Fig. 5, A, shows a nearly median section of a very young
sporophyll of O. pendulum. This is a broadly conical body upon
whose inner (adaxial) face there is a slight prominence (Sp.) the
apex of the young spike. Fig. 5, B,
shows an older, but still very early 4 $
stage, in which it is evident that the
spike rudiment extends completely to
the base of the young leaf, with which
it is adherent except at the extreme
tip. The apex of the young spike is
directed upward and its axis is almost
parallel with that of the sterile leaf
segment. From Bower’s figures of
corresponding stages in O. vulgatum
it is clear that a very similar condition
of things prevails in that species. In
such a stage as that shown in Fig 5,
B, the relation of the fertile and sterile
segments is not unlike that of a stem |
apex and leaf, and the condition of
things here present would very well
lend itself to the interpretation of a
terminal spike with á subtending ster-
. . : i}
ilelamina. At this stage the vascular
bundles are not yet differentiated, and |
the arrangement of these in the young
leaf still remains to be made out.

En.

BOTRYCHIUM.

In the second genus, Botrychium,
most of whose species are plants of
the temperate zones, both the fertile
and sterile segments of the leaf as is well known, expat in some

lanuginosum Wall., slightly en-

148 THE AMERICAN NATURALIST [Vor. XLI

simple forms of B. simplex, are more or less extensively branched.
This is especially marked in such large species as B. virginianum
and B. lanuginosum.

The relation of the fertile and sterile periods is essentially the
same as in Ophioglossum, and there is the same variation in the
point of divergence of the two leaf segments. Thus in O. obli-
quum Muhl. the two are separated almost to the base. In O. vir-
ginianum and O. lanuginosum (Fig. 6, B) the spike appears to arise
close to the lamina of the leaf or even above its base. No material
was available for a critical study of this point in B. virginianum,
but in O. lanuginosum Wall. where (see Engler & Prantl, loc.
cit., p. 471) it is stated that the spike arises from the base of the
sterile segment; even a casual examination will show that this is
more apparent than real (see Fig. 6, B). If the leaf be looked at
from in front it is very evident that the peduncle can be traced
for a long distance below the bases of the sterile leaf segments,
although only the anterior face is free, the inner face and sides
being completely adherent to the base of the sterile segments.

HELMINTHOSTACHYS.

A similar condition to that found in Botrychium lanuginosum
prevails in the third genus, Helminthostachys (Fig. 7), a mono-
typic genus of the Indo-Malayan region. ‘This is much nearer to
Botrychium, in its general morphology, than it is to Ophioglossum,
although, in the character of both the prothallium and fertile
spike, it is to some extent intermediate in character between the
two genera.

In Helminthostachys the sterile segment, as in most species
of Botrychium, is ternately divided, and the anterior margins
of the stalks of the two lateral leaf segments are continued as
more or less conspicuous wings enclosing the adherent base of

the peduncle.

DISTRIBUTION OF THE VASCULAR BUNDLES.

A careful study of distribution of the vascular bundles of the
leaf was made in most of the species that were available, to see

No. 483] STUDIES OF THE OPHIOGLOSSACEE 149

how far this harmonized with the theory of the terminal nature
of the fertile spike. The arrangement of the bundles has already

Fig. 7.— A, Sporophyll of a small specimen of Helminthostachys zeylanica Hook.,
X 4; B, base of the spike, natural size.

been studied in the commoner. European species, O. vulgatum,
O. lusitanieum and B. lunaria. Bower has also investigated
this in O. bergianum, and more recently in O. simplex, O. pen-
dulum and O. palmatum (loc. cit. 1904). Of these forms the writer
has examined O. pendulum, and in addition to this a number of
other species which have not been hitherto studied.

In all of the species belonging to the section Euophioglossum
that have been examined, there is given off from the vascular
system of the rhizome a single leaf trace which divides at the base
of the leaf into two strands. This is probably the case also in all
the forms associated with O. moluccanum (see Fig. 8). Accord-
ing to Prantl, in O. lusitanicum each of these two bundles gives
off a branch toward the adaxial side of the petiole which unite and

150 THE AMERICAN NATURALIST [Vor. XLI

pass into the spike, the main
trunks passing upward into the
lamina. In the specimen shown
in Fig. 8, which probably was not
the typical O. moluccanum, while
the leaf trace divides into two

branches, as in O. lusitanicum,
only one of these divided at the
base of the leaf, so that at a point
some distance above the base
there are only three bundles, two
of which are destined for the
spike. The single bundle which
is to supply the lamina is the
result of the division of one of the
two primary strands, the other half
Fig. 8.—Three cross-sections of the lower of which forms one of the adaxial

part of the petiole of Ophioglossum sp., b .
A, B, at the base; C,higherup. bundles belonging to the spike.

O. MOLUCCANUM SCHLECHT.

A transverse section of the petiole in the typical O. moluccanum,
made some distance below the point of separation of the two
parts of the sporophyll (Fig. 9, A), shows four nearly equal vascular
bundles, of which one is on the outer (abaxial) side, the other
three on the adaxial side. As in all other species of Euophio-
glossum, these bundles are markedly collateral in structure. It
is probable that the central adaxial bundle is due to the branching
of one of the two adaxial bundles found near the base of the
petiole.

If a section be made just below the point where the two parts
of the leaf separate (Fig. 9, B), the three adaxial bundles are still
recognizable, but the abaxial one has divided into several, which
are evidently destined to supply the sterile leaf segment. A section
taken a little higher up (C) shows plainly the bases of the two
parts of the leaf. In the adaxial part, the peduncle of the spike,
the original three adaxial bundles, are clearly evident, while in
the lamina may be seen an increased number of bundles due to

No. 483] STUDIES OF THE OPHIOGLOSSACEE 151

the further ramifications
of the abaxial bundles to
form the reticulum of
veins in the leaf segment.
It is clear that in this
species three of the four
bundles of the petiole are
continued unbroken into
the spike, while only one
of these contributes to the
sterileleaf segment. This
would certainly tend to
confirm the view that the
spike is the principal part
of the leaf, and the lamina
is secondary.

The base of the spike
(Fig. 9, C, D) shows the
three bundles, but above
the base (E) these bundles
may branch, so that a sec-
tion higher up shows five 9.— Five sections of the sporophyll of O.

Fig.
bundles. The ramifica- moluccanum; A, the petiole; B, C, intermediate:
. ‘ E, the peduncle of the spike; l, lacune; X 20.
tions of the veins of the

fertile part of the spike were not studied in detail.

OpHIOGLOSSUM SP.

Fig. 10 shows sections of a second form of Ophioglossum,
collected at Buitenzorg, evidently specifically distinct from O.
moluccanum. It was a plant of about the same size, but it differed
both in the cordate sterile leaf and in the size and other characters
of the spores. It is probable that Fig. 8, which shows the extreme
lower part of the petiole, also belongs to this species. The lower
part of the petiole in cross section shows but three bundles instead
of four, the middle adaxial bundle being absent. In a section
taken near the junction of the spike and lamina there were four
abaxial bundles and five adaxial ones. It is not exactly clear
as to the relation of the latter to the ramification of the two pri-

152

THE AMERICAN NATURALIST

[Vor. XLI

mary adaxial bundles, whose identity is not so clearly maintained
as in O. moluccanum. In a section at the base of the lamina the

FıG. 10.— Four sections at ee heights of the nen de of Ophioglossum
sp.; A, ol x

petiole; B, C, intermediat

te; D, pedun

arrangement of the bundles is very much the same as in O. moluc-

canum, and the three bundles of the spike are very similar.

The

triple arrangement continues into the spike, and a section made
well above the base shows practically the same appearance.

Fic. 11.—Ophioglossum californicum Prantl.;

A-C, three sections of the sporophyll of
a medium sized specimen; D, section of
the peduncle from a larger specimen; X
0.

O. CALIFORNICUM PRANTL.

O. californicum is a small
species from southern Cali-
fornia. In the anatomy of
the leaf it seems to follow
pretty closely the description
given by Prantl for O. lusita-
nicum. A section of the petiole
(Fig. 11, A) shows four adaxial
bundles, and a single abaxial
one. If the section be made
through the base of the pedun-
cle and lamina (Fig. 11, B) the
spike shows in some cases but
a single large bundle, evidently

formed by the coalescence of the adaxial bundles. There are five

No. 483] STUDIES OF THE OPHIOGLOSSACEE 153

bundles belonging to the lamina, of which. the posterior one is
apparently the original abaxial bundle, while the others are de-
rived from the two outer of the four adaxial bundles. A large
specimen which was examined showed three bundles in a trans-

verse section of the peduncle (Fig. 11, D). ;

OPHIODERMA.

Bower has shown that in O. pendulum, O. simplex and O. pal-
matum there is not a single leaf trace, but the individual strands
of the petiole join the vascular system of the rhizome directly.
He also showed that the adaxial bundles which supply the spike
in the fertile leaf of O. pendulum are quite absent from the petiole
of the sterile leaf, which in section shows no bundles at all on the
adaxial side. In the section Ophioderma the upper part only of

the peduncle is free, the lower
portion, as we have seen,
being adherent to the lamina

and merging insensibly into the A

common petiole of the sporo-

phyll. Fig. 12 shows four sec-

tions at different heights from

a leaf of O. intermedium. e
Near the base of the petiole

there are five vascular bun- ms ;
dles, of which the two on the SE ā go oo

adaxial . side are noticeably | ee

larger than the three abaxial Pie, 12- Orten wtermatn: de,
bundles. Somewhat higher up part of lamina, X 6; D, section of free
there are four adaxial bundles, eo

evidently the result of a bifurcation of the two which are seen lower
down. The three abaxial bundles remain unchanged except that
they are somewhat further apart, corresponding to the broadening
of the petiole at this point. Still higher up, where the base of the
peduncle is coherent with the lamina, the former may be seen
projecting somewhat from the leaf and containing three bundles,
and the same number occurs in the free portion of the pedun-

cle (Fig. 12, C & D).

154 THE AMERICAN NATURALIST [Vor. XLI

The very much larger leaves of O. pendulum show a corre-
spondingly larger number of vascular strands. Fig. 13, A to D,
shows sections through the petiole, base of lamina, and spike of a
medium size specimen. In the former eighteen bundles could be
seen, of which probably seven or eight are destined to supply the
spike. In the basal part of the lamina six or seven adaxial bundles
are plainly visible below the slightly projecting region which marks
the coherent portion of the peduncle. In both this species and
O. intermedium the free portion of the peduncle is comparatively
slender, and the number of
bundles less than in the broad-
er basal part. In the speci-
men figured there were three
bundles, of which the middle
one was evidently doubled,
and was clearly formed by the

ee coalescence of some of the
~L o on, bundles before they left the

ET NEN ee As wk adherent part of the peduncle.

tion of the petiole of the sporophyll; B, Higher up there were five
bundles arranged in a semi-

of the free portion of the p eduncle; E, sec- circle. The same arrange-

tion of the peduncle from a larger speci- A

men; all figures X 4. ment was found in the peduncle

of a larger specimen (Fig. 13,

E) taken from the spike which is shown in Fig. 3, D

The complete absence of the adaxial strands in the petiole of
the sterile leaf, even at its base, is a strong confirmation of the view
suggested by both the older leaf and the younger stages that the
peduncle really extends to the extreme base of the petiole and is
joined directly to the rhizome.

BOTRYCHIUM.

The only species of Botrychium available for study was O.
lanuginosum Wall. collected at Horton Plains in the uplands of
Ceylon. "The arrangement of the bundles in the leaf of this species
agrees in the main with that of the other species that have been
studied (see Bitter, loc. cit., p. 458). The leaf trace divides into

No. 483] STUDIES OF THE OPHIOGLOSSACEE 155

two at the base of the petiole, and these branches divide again
somewhat higher up (Figs. 14, A to C). Of the four bundles thus
formed, the two larger adaxial ones are those which supply the
spike, the smaller abaxial ones supplying the lamina. In larger

Fig. 14.— Botrychium lanuginosum; A, B, C, Sections through the base of the
petiole; in C, the position is reversed from that of the others; D-G, sections
of the petiole and upper part of the sporophyll of another specimen; X 4.

specimens of this species (Fig. 14, D), and the same is true in B.
virginianum, there may be a subsequent branching of some of the
bundles, so that a cross section of a stout petiole shows a larger
number of bundles, sometimes as many as ten.

Sections made at the junction of the spike and lamina (Fig. 14,
E) show anastomoses of some of the bundles which appear elon-
gated in section, but there seems to be no regular rule governing
the fusion of these. It is not quite clear whether any branches
are given off from the spike bundles into the lamina, but this is
probably the case in regard to the two lateral segments of the
lamina. Within the peduncle of the spike in the larger speci-
mens (Fig. 11, G) the two original bundles are again clearly
defined, but in some of the smaller specimens these may be com-
pletely united into a single central bundle.

156 THE AMERICAN NATURALIST ` [Vou. XLI

HELMINTHOSTACHYS.

Farmer & Freeman (On the Structure and Affinities of Hel-
minthostachys zeylanica, Ann. of Bot. 17, p. 421, 1899) state that
in Helminthostachys there is, as in Euophioglossum and Botry-
chium, a single leaf trace which afterwards divides into several,
usually seven or eight, within the petiole. As we have already
seen, although the spike in Helminthostachys arises apparently
from the base of the lamina, in reality its origin is lower down, and
it may be traced for a long distance below the insertion of the
sterile segments.

In a section made near the base of the petiole, it appears almost
circular in outline with a ring of separate bundles. On the adaxial
side, however, there are two other bundles within the outer circle.
The number of bundles in the larger specimens collected by the
writer was decidedly greater than that given by Farmer & Freeman
(see Fig. 15, A). Higher
up the section is no longer
round, but slightly lobed,
indicating the bases of the
three branches of the ter-
nately divided lamina, and
on the adaxial side can be
plainly seen a fourth lobe,
which marks the position of
the spike. This is bound-
ed by two more or less
conspicuous bodies, the

sections of the wings that

Fic. 15.— Helminthostachys zeylanica; A, section .
of the petiole of a large specimen, near the base; extend down the petiole
C; sections higher up, of the petiole of a from the lateral leaf lobes
PETE specimen; D, section of the peduncle; ( Fig. 15,B & ©). th the
region the separate bundles
of the basal part of the petiole are more or less coalescent, but the
two adaxial bundles remain separate and are those which later
extend into the spike. Still higher up the spike becomes more evi-
dent, and the two bundles belonging to it still more clearly separated.
In the free portion of the peduncle the two crescent shaped bundle

No. 483] STUDIES OF THE OPHIOGLOSSACEE 157

sections are seen (Fig. 15, D), but it is evident that they are really
composed of several coalescent bundles. A slight indication of
this can be seen also in the adherent basal portion of the peduncle.

CONCLUSIONS.

From a study of the distribution of the bundles in the leaf it is
evident that the bundles which supply the spike are not second-
arily given off from the main bundles of the petiole, but are them-
selves the adaxial bundles which can be traced
from the base of the petiole into the spike.
This would indicate that the spike is not a
secondary development upon the leaf, but is a
primary portion of it. From a study of the
earlier stages of the young sporophyll as well
as from the conditions shown in O. simplex
and certain forms of O. pendulum and O.
intermedium, there seems to be little question
that the spike is really a terminal structure,
and the writer is inclined to believe that in all
cases the spike may be regarded as the apex of
the leaf structure and the lamina as lateral with
regard to it. If this view be not accepted, it
would seem necessary to return to the old view
of Mettenius, that the leaf is divided into two
equal branches.

. In connection with the question of the termi-
rn Pras nal position of the sporophyll, the position of
young sporo- the leaf in the embryo may be cited. In O.

oo ee moluccanum — and the same is true in O.

the latter consists pedunculosum described fifty years ago by

minal leaf, Z, and Mettenius—the young sporophyte (Fig. 16)

"4 Siege root, develops at first only a leaf and root, the defini-

tive sporophyte arising later as an endogenous
bud from the primary root. The first leaf must be considered a
strictly terminal organ. ‘This embryo corresponds exactly to what
might be expected if the hypothesis advanced by the writer — that
Ophioglossum probably arose from some form resembling Antho-

158 THE AMERICAN NATURALIST [Vor. XLI

ceros — be true. This hypothesis assumes that, by the develop-
ment of a root from the lower part of the sporophyte and a
complete septation of the sporogenous tissue of the sporogonium
so that something resembling the spike of an Ophioglossum
resulted, there would be formed a plant not very unlike O. sim-
plex. We actually have in the embryo sporophyte of O. moluc-
canum a plant which consists simply of leaf and root. Of course
the leaf is not sporogenous, but the ancestral form must have
developed a sporogenous structure comparable to the spike before
the foliage leaf arose. ‘The latter presumably was formed as a
lateral outgrowth of the sporogenous portion, as there seems to
be some evidence is the case in the young sporophyll of the living
species.

THE AFFINITIES OF O. INTERMEDIUM HOOKER.

Ophioglossum (Ophioderma) intermedium Hook. is apparently
a very rare plant. It was originally described by Hooker from

Pots
E RZ.
P al
Were
Fig. 17.— A, Spore of Ophioglossum pendulum, X 500; B, optical section of the
wall of the spore, more highly magnified; C, surface view of the markings of
the spore-membrane; D, three spores of O. intermedium, X 500; E, mark-
ings of the surface of the spore.

No. 483] STUDIES OF THE OPHIOGLOSSACEE 159

material collected in Sarawak in Borneo. When the writer was
in Singapore inquiries were made at the botanical gardens as
to the possibility of obtaining material of this species, but it was
found that the original locality was lost, and the plant had not
apparently been collected since it was first sent to Hooker.

The writer, however, found that this species had been collected
near Buitenzorg by Mr. J. J. Smith, of the herbarium of the gar-
den there. He was kind enough to accompany the writer to the
place where it had been collected, and it was thus possible to
obtain a fair amount of material which was enough to show that
the plant is certainly quite distinct from O. pendulum, of which
it has been supposed (Bitter, loc. cit., p. 469) that it was a mere
form, perhaps due to its terrestrial habit. In Buitenzorg it grew
in a plantation of bamboo — usually in the accumulation of
humus and earth about the roots of the clumps of bamboo. It
is a small plant (see Fig. 4) and in its stiff upright habit and much
longer peduncle presents a very different appearance from any
form of O. pendulum — although it is evident that it belongs to
the same section of the genus. The plants grew from a small
tuberous body apparently developed as a root bud (Fig. 4, B, E)
and in this respect as well as in the occurrence of such forms as
that shown in Fig. 4, E, where the lamina is almost wanting,
it approaches O. simplex, with which it may be pretty closely allied.
It differs, however, in other respects than that of its habit, from
O. pendulum. The spores (Fig. 17, D) are decidedly smaller
than those of O. pendulum, and the delicate reticulate markings
of the epispore (Fig. 17, E) are very different from the markings
in the latter species.

STANFORD UNIVERSITY
Jan.,

POLYGAMY AND OTHER MODES OF MATING AMONG
BIRDS

R. W. SHUFELDT

For several years I have devoted much time to a study of the
phenomena of sex in vertebrates, comparing those of the lower
forms with the features presented by man. Much of the matter
thus obtained is now in the publisher’s hands but some of it is
presented here.

The nature of man, .his customs, habits, and institutions, his
mental and physical characteristics cannot be fully and intelli-
gently understood unless all of our stock of accumulated facts are
studied in the light of what we know to obtain along the corre-
sponding lines among all animals below man. ‘That is to say, it
is simply impossible to comprehend the morphology of man, unless
our studies of it are made comparative with our knowledge of the
anatomy of all other animals. So too with all else manifested
on the part of our species;— to get at the origin of all things in `
man and his customs, his crimes, and his passions, we are obliged
to trace them down through the scale of living forms below him.
It holds in our researches into the science of society, and it was
Letourneau who said “When once it is established that man is a
mammal like any other, and only distinguished from the animals
of this class by a greater cerebral development, all study of human
sociology must logically be preceded by a corresponding study
of animal sociology. Moreover, as sociology finally depends on
biology, it will be necessary to seek in physiological conditions
themselves the origin of great sociological manifestations.” *

It has been recently, with such thoughts as these in mind, that
I have been making some comparisons of the various forms of
marriage as we find it among different races of mankind; the
question of divorce; and the part played in the marital relations
by sexuality. Following the biological methods of comparison

‘The Evolution of Marriage, p. 2, 1900.

161

162 THE AMERICAN NATURALIST [Vor. XLI

and derivation, I attempted to bring together what I knew of the
matter of mating among animals generally, carrying my investi-
gations into the various groups of fishes, reptiles, birds and mam-
mals. It is a very well known fact that with respect to our own
species, we meet in one part of the world or another, people who
practice every form of sexual relation, to say nothing of what is
met with along the lines of pervertism in such matters. Even in
the United States, we meet with any number of cases of marriage
devoid of all ceremony (anarchists); of free love; of monogamy;
of promiscuity; of polygamy and bigamy; of legalized concu-
binage (South Carolina); and of the divers unnatural relations
of the sexual perverts and inverts. Polyandry, that rare and
exceptional conjugal form, where the one wife has two or more
husbands, has never been instanced among us, so far as I am
aware. No such sexual association is met with among mammals
below man, and never among birds.

It is in this latter class of vertebrates that we meet with some
of the purest types of, as well as some of the most interesting
examples of the conjugal relation, and it is to a comparative con-
sideration of some of these that the present article will be devoted.

In reviewing the material for this purpose at hand, I have
drawn largely upon my own ornithological observations and
studies extending over a period of forty or more years. Then I
have consulted such works upon ornithology as I find in my
private library. With respect to the latter, I am obliged to con-
fess my surprise at the inadequacy of the accounts, and the marked
variance often exemplified in the statements of different authors
of recognized standing and reputation on the subject. Very few
books at my command pretend to make any comparisons between
the mating habits of birds and the marriage customs of various
peoples, but there are a few.

Beyond the matter of the different procedures of courtship in
the case of birds, there are no further ceremonials with them as
in the case of many, indeed, the majority of the races of mankind.
So that, in the abstract, polygamy in birds means exactly the
same thing as human polygamy, and so on for monogamy, pro-
miscuity and other practices. ‘Taken in the abstract, and barring
opinions to the contrary, many believe in the case of man, that

No. 483] MATING AMONG BIRDS 163

in prehistoric time, when he was first differentiated from simian
stock, he, wherever existing, was given over to unmixed pro-
miscuity; that this was soon followed in many regions by some
form of polygamy, and polyandry where women were scarce (rare);
as promiscuity disappeared, and polygamy became far less preva-
lent, some mode of monogamy appeared, and this, at the present
time is the form of marriage adopted by nearly all civilized races.
In other words these various customs have shaded into each other,
—that is, in the main, promiscuity for the wild, prehistoric people;
followed by polygamy for ancient times, with monogamy now
ever on the increase. Still we must bear well in mind that we have
polygamy now openly followed in the United States, and some
of the lowest existing races of the world are monogamous.

These facts are thus briefly presented in that we may contrast
them with what occurs in the class of birds. Theoretically, in
one way, the lowest forms of existing birds should in their
mating be given over to promiscuity; those higher in the scale
should be polygamous; and, finally the most specialized types,
as the Passeres, be monogamous. ‘This, however, is by no
means the case, and agreeing with our own species, some of the
existing groups of birds most nearly related to extinct types,
closely associated with reptilian stock, are strictly monogamous,
while others perhaps, are promiscuous (no birds being poly-
androus); and still others affording examples of polygamy. So
it is too, higher up in the scale, just as it is, as before remarked,
with the human species.

Tracing birds back through geologic time as best we can by
means of the material at hand there is no question but what in
their morphology they approached nearer and nearer the archaic
types of reptiles. Avian and reptilian osteology especially em-
phasizes this fact, and it is well known that some of the existing
families of birds from various parts of the world exhibit in their
skeletons characters that were more or less common to the entire
class Aves as represented in that age of the Earth’s history when
birds had first become more or less differentiated from their repti-
lian ancestry. This by no means implies, however, that the pres-
ent day existing families of birds, in the osseous systems of which
still are to be met with those more pronounced evidences (in the

164 THE AMERICAN NATURALIST [Vor. XLI

way of characters) of their reptilian relationships, are distinctly
more closely allied upon that account. Many taxonomers, how-
ever, have thought so; and have endeavored to show that all
existing true ostrich forms, the Kiwis, and tinanous are a sort of
modern affined struthious types. On the other hand a Kiwi
(Apteryx) is no nearer an ostrich, and an ostrich to a tinamou,
than a limpkin (Aramus) is to a bustard, and a bustard (Otis)
to a quail (Colinus). Therefore it need not surprise us, in view
of all that has been set forth above, that the various modes of mat-
ing of any of these birds should be entirely different, or that these
modes should fail to throw any light upon their affinities. For
a moment then let us see what some authors have to say in regard
to the mating of ostriches and their allies.

Professor Newton, quoting Lichtenstein, says: “Though some-
times assembling with Zebras or with some of the larger antelopes,
ostrichs commonly, and especially in the breeding season, live in
companies of not more than four or five, one of which is a cock
and the rest are hens. All the latter lay their eggs in one and the
same nest, a shallow pit scraped out by their feet, with the earth
heaped around to form a kind of wall against which the outermost
circle of eggs rest. As soon as ten or a dozen eggs are laid, the
cock begins to brood, always taking his place on them at night-
fall surrounded by his wives, while by day they relieve one another,
more it would seem to guard their common treasure from jackals
and small beasts-of-prey than directly to forward the process of
hatching, for that is often left wholly to the sun.” * From this
it is clear that the African Ostrich is a polygamous bird by nature.

The Rhea or South American ostrich (Rhea darwini, americana,
etc.) is also undoubtedly polygamous in nature, while the emeus
of Australia are said to be monogamous, though neither Newton
or Pycraft °? say anything on this point. Neither do they give us
any information on this point in regard to the cassowaries, birds

1 Newton, Alfred. A. Dictionary of Birds. Part III, Art. “Ostrich,”
pp. 664-665, 1894, quoted from M. H. K. Lichtenstein, Reise im südlichen
Africa, ii, pp. 42-45 (Berlin: 1812.). The fact that the sun assists in hatch-
ing the eggs of the African ostrich ‚is disputed, but it is doubtless true. Cap-
tive ostriches are usually enforced to lead a life of obligatory monogamy.

2 Pycraft, W. P. The Living Animals of the World. Vol. II, p. 394, London
(no date).

No. 483] MATING AMONG BIRDS 165

more or less closely allied to the emeus. Indeed, I am unable to
state whether a cassowary is, by nature, polygamous or monoga-
mous. ‘Their eggs have been described but apparently not their
mating habits. None of the above-named writers describe the
breeding habits of the kiwis (Apteryx oweni, mantelli and aus-
tralis) and I am unable from personal observation to state whether
they are by habit monogamous or polygamous (see Sir Walter
Buller, Newton, Pycraft, and other writers). These curious birds,
now being rapidly exterminated, are probably monogamous, as Dr.
Claus says of them, “The kiwis are nocturnal birds, which by day
remain concealed in holes in the earth and go out at night to seek
their food. ‘They feed on insect-larve and worms, live in pairs,
and at the breeding time, which seems to come twice in the year,
they lay, in holes scraped in the earth, a strikingly large egg,
which, according to some, is incubated by the female, and accord-
ing to others by the male and female in turn.” *

So far as I have been able to ascertain, the tinamous (Cryp-
turide) are monogamous birds, while they associate together in
flocks during those times of the year when they are not breeding.
Newton does not mention this in the “Dictionary,” and at this
writing I do not happen to have Bartlett’s paper at hand (P. Z.
S. 1868, p. 115, pl. xii). In fact there are but very few good
accounts of the breeding habits of these very interesting birds.
Their wonderfully beautiful eggs are well-known to naturalists,

All water birds of the main groups appear to be monogamous
in the matter of their mating. There appear to be no exceptions
to this rule to be met with among the several suborders of the
Pygopodes, Impennes, Tubinares, Steganopodes, Longipennes,
Alc, and the Chionides. As we know, these groups contain
the divers, the penguins, the petrels, the pelicans and various
allies, the gulls, and the auk tribe. Nearly all these forms are
low in the scale, and in all we meet with near relatives among
birds that are extinct and certain fossil types. Yet, as I say,
they are all monogamous so far as my knowledge carries me.
Passing next to the great limicoline assemblage (Limicole), it is
to be observed that it contains, with their numerous allies, the

1 Claus, Dr. ©. Elementary Text-book of Zoology. Translated by Sedg-
wick and Heathcote. Pt. ii, p. 272, 1885.

166 THE AMERICAN NTURALIST [Vor. XLI

plovers, the turnstones, the surf birds, the snipes, the phalaropes,
the avocets, and the jacanas, the entire host being monogamous
by habit, with but one famous exception, namely, the truly polyg-
amous ruff (Machetes pugnax). ‘The peculiar habits of courtship
and breeding practiced by this species have been well-described
by a number of continental naturalists... Among the Limicolee
there ‘appears to be, among existing birds, but one other species
suspected of being a polygamist, and this is the double or solitary
snipe (Scolopax major) of Europe. Newton does not mention the
fact in the “Dictionary,” but Darwin remarks in “The Descent
of Man,” that “some of the above birds,— the black-cock, caper-
cailzie, pheasant-grouse, ruff, solitary snipe, and perhaps others,
are, as is believed, polygamists.” (p. 406.) From all that I can
gather, it would seem that the question has not yet been decided.
Coming to the Cursore, the group contains but few species that
I know of, that have been suspected of being polygamists and
among these is the great bustard (Otis tarda),— and with it
most of the evidence seems rather to point to the fact, that such
is the case. Whether any other representatives of this somewhat
numerous group (Europe, Africa, Asia, and Australia) are polyg-
amous by habit, I am unable at present to say. However, the
birds called ‘floricans’ of India, closely allied species to the
bustards, are reported as practising polygamy. ‘There seem to
be two known species of these, — the Bengal (Sypheotides ben-
galensis) and the lesser florican (S. aurita). During pairing
season the two sexes live apart in groups, and in mating come
together, and “when a male wishes to attract a temporary part-
ner, he does so by going through an elaborate series of perform-
ances.”” It is possible that all the true bustards possess strong
inclinations in this direction, even if they are not actually polyg-
amists. Not so, however, with the stone curlew (Œ. crepitans)
a species I have relegated to the Cursor, although, I by no
means consider it to be very closely allied to the Otidide.*

1 See A. Newton, art. “Ruff.” Diet. Birds, Darwin, “The Descent of
Man,” p. 219, Montagu (Suppl. Orn. Dict. 1813); Pennant, Daniel, Graves,
Collett, Lubbock, Southwell, Stevenson and others.

? Lydekker, R. The Royal Nat. Hist. p. 458.

*Shufeldt, R. W. “An Arrangement of the Families and the Higher
Groups of Birds.” The Amer. Nat., Vol. 38, Nov., Dec., 1904, pp. 833-857.

No. 483] MATING AMONG BIRDS 167

Monogamous matings seem to be the rule with all the cranes
and rails, with their allies, near and remote.!

Probably no group of birds in the world’s entire avifauna have
been more closely studied or had more written about them than
the great gallinaceous group of fowls, including among them not
a few other such familiar birds as the turkeys, the guinea fowls,
quails, partridges, grouse, pheasants, and their various allies,
near and remote. Good and sufhcient reasons there are for this,
as a very large number of them are, and have been, long domes-
ticated, as the chickens and turkeys. All of them constitute
game in every part of the world; while many of them are kept
in zoological gardens and private preserves, as the pheasants
and others. None of the Galliformes, I believe, are polyandrous,
though many of the families are curiously divided up between
polygamy and monogamy, some being strong adherents of the
first-named practice, while others, under no circumstances, depart
from the latter mode of mating.

Captivity sometimes influences these habits, and birds that are
polygamous in nature become monogamous when their domesti-
cation is undertaken, and vice versa. Beautiful accounts have
been given us by different naturalists of the often extraordinary
courtships to be seen in the case of many of the representatives
of this suborder of birds, while in other cases there habits are.
still quite unknown to science. Whether the Hemipodes or button
quails (Hemipodide) are polygamous or not, I cannot at this
writing say, but it is a well known fact that with them the females
are brighter plumaged while the males, resembling the subadult
specimens, perform all the duties of incubation. All this is

! Loc. cit. pp. 851, 852. It is here intended to include the supersuborders
Gruiformes and Ralliformes. Curious and puzzling forms of birds occur in
the first assemblage (Grues) such as the trumpeters (Psophia), the seriema
(Cariama), the sun-bitterns (Eurypyga), the kagu (Rhinochetus), and the
Mesitidse of Madagascar. Although many of these have been long known to
ornithologists, and much written about them, it is by no means certain that
they are all monogamous species in nature, as I believe the finfoot (Heliornis)
among the Ralliformes to be. Several of those named have been kept in
zoölogical gardens, where they have reared their young, but a bird may be
monogamous in captivity and polygamous in nature. Both the sun-bitterns
and the kagu practice a show-off, but it does not appear to be confined to
the breeding season or to their modes of courtship.

168 THE AMERICAN NATURALIST [Von XLI

reversed in the little common quail of the old world (Corturnix
communis), a well-known polygamous species, where the males
are both larger and handsomer than the females.

As to the Megapodes or brush turkeys (Megapodide) of the
East Indies and Australia, none of the writers at hand state whether
they are polygamous or otherwise.

The habits of these birds are pretty well known, especially their
burying their eggs in immense mounds which they build, or con-
cealing them in sand-holes and burrows, in either situation they
hatch out by the sun and the heat of the fermenting vegetable
matter in the mounds. The young fly an hour after they are
hatched. Wallace describes several species of them in his “ Malay
Archepelago,” but does not state whether they are polygamous
or not, and neither Newton or Pycraft have anything to say upon
that point.’

Most ornithological writers lay it down as a rule that among
the Gallinz generally, where the cock bird is evidently larger than
the hen and its plumage is remarkably conspicuous, the hen,
being more or less plain in this particular, the species is polyga-
mous, whereas, when the sexes are nearly alike in point of size,
and but little difference in plumage, they are almost certain to be
monogamous in their mating. There are, however, a few excep-
tions to this rule.

Personally, I have never studied the curassows and guans
(Cracide) in their native haunts, and therefore cannot say, from
my own experience, anything in regard to their mating habits.
In this group, I take it, the curassows of South America are prob-
ably monogamous, as is likewise our Chachalaca (Ortalis v. mac-
calli), though in the case of the latter species, where the sexes
are nearly alike, few American ornithologists describe its court-
ship and mating, notably Bendire, Coues, Ridgway (Manual),
and others, while continental writers rarely refer to it. Neither
Audubon or Wilson ever saw the bird.

Finally, the suborder Gallinz is seen to contain five very ele-

1 Loc. cit. Art. “Megapode” Pt. ii, p. 539, and Pyeraft, “Living Animals
of the World” Lond. p. 411. One writer states that several hen megapodes
may bury their eggs in the same mound, but does not say whether the birds
all belonged to the harem of one male.

No. 483] MATING AMONG BIRDS 169

gant families of birds, representatives of which, in more or fewer
species, are found in all parts of the world. These are the pheas-
ants (Phasianidee), the grouse (Tetraonide), the American Par-
tridges (Odontophoride), the Guinea fowl (Numididee), and the
Turkeys (Meleagridee). Great is the wealth of species in the most
of these several families, and while some of them are polygamous,
others are strictly monogamous, and the habits of any of them
may be changed through domestication, and they sometimes
infringe upon, or even break, some of the rules given in fore-
going paragraphs. Included in their ranks are all of our common
domesticated gallinaceous fowl, and occasionally the habits of
some of these are very remarkable.

Very much do I regret that I cannot give more space to this
group as it is both an interesting as well as an important one;
moreover, authors are by no means unanimous in their opinions
in regard to the modes of mating, and in the case of some species
we have apparently no data at all. Considerable part of the
literature has been carefully looked up by me. No one seems to
question but what such species as the capercailie and black grouse
of northern Europe are polygamous. Pheasants and their near
allies are likewise so, and I believe the famous Argus pheasant is,
but in this I may be wrong. The wild turkeys of North America
are also polygamists, though it is said that the old males generally
have a favorite hen,while the other females he favors are but his
concubines. Peacocks are polygamous but the various species
of Guinea fowl are eminently monogamous. When the latter
are domesticated, however, as vast numbers of them are, I have
personally known a male Guinea fowl to take charge of six or
seven hens, and the latter would all lay the usual number of eggs
and bring forth their young. From all I can gather, it has been
found that all the species of ptarmigan wherever they occur are
monogamous. ‘This seems to be the case too, with the birds we
call quail (American partridges: Odontophoridee), though I am
not so sure about the species of the genus Cyrtonyx. ‘The com-
mon partridge of Europe is monogamous, as are the majority of
our typical grouse (Canada, dusky, Franklin’s and others), the
sage cock, however, is polygamous (Centrocercus).

Audubon, whose life-histories of our game birds are so thorough-

170 THE AMERICAN NATURALIST [Vor. XLI

ly unsatisfactory, in his account of the mating of the pinnated
grouse (Tympanuchus) gives one the impression that he believes
the bird to be monogamous, while in his account of the ruffed
grouse (Bonasa) he states in referring to the latter species, that
“The males have the liberty of promiscuous concubinage, although
not to such an extent as those of the pinnated grouse.”* Bendire,
on the other hand when describing the habits of the ruffed grouse
(B. umbellus) says, “By many persons the ruffed grouse is consid-
ered polygamous, and while I can not actually disprove that
assertion, I doubt it very much.” ?

Again authors are at variance in their opinions with respect
to the several species of the sharp-tailed grouse (Pediocetes)
and E. T. Seton, quoted by Bendire, says of the prairie sharp-
tailed grouse in describing the remarkable dance of the males, “Its
erratic character can hardly be questioned.... The whole affair
bears a close resemblance to the manceuvring of the European
ruff, and from this and other reasons I am inclined to suspect
the sharp-tail of polygamy.’”

The curious hoatzin of tropical South America (Opisthocomus)
in a way related to the Galline, is said to be polygamous, but as
yet we stand quite in ignorance of some of the habits of this inter-
esting form in nature.

Sand-grouse (Syrrhaptes) and their kin I believe are monoga-
mous, and I do not at this writing recall any species of wild pigeon
(Columbiformes) that has any other form of mating in the breeding

1 Audubon, J. J. Birds of America, Vol. V, pp. 78 and 93-105, 1839.

? Bendire, Chas. E. Life Hists. Amer. Birds, p. 61. In the same work
(p. 90), and quoting Judge John Dean Caton, he evidently believes the pin-
nated grouse to be monogamous, when it is stated that “It is toward the
latter part of the love season that the fighting takes place among the cocks,
probably by two who have fallen in love with the same sweetheart, whose
modesty prevents her from selecting between them.”

3? Loc. cit. p. 105. I am of the opinion that this question has by no means
been definitely settled yet, except perhaps in the case of the ruffed grouse
which has been kept and reared in confinement by Mr. C. F. Hodge who says
“The cocks of the ruffed grouse are evidently polygamous. I observed the
“wild” cock mate with the two “wild” hens. The hens, however, permitted
mating but once, and after mating, if left together, the cock will pick the
hen to death.” (Rep. of the Comm. on Fisheries and Game. Dec. 31, 1905
Mere Pub. Doc. No. 25, pp. 66, 67.

No. 483] MATING AMONG BIRDS 171

season, though to me pigeons are by no means always so. Those
birds known as screamers (Palamedæ) also appear to be mo-
nogamous, and I believe the entire swan, goose and duck tribe
(Anseriformes) are,— at least in nature, although there may be
exceptions to this that I either do not recall for the moment, or
have not come to my notice. When domesticated, however,
ducks may become highly polygamous, and it is a well-known
fact that in this state it is not difficult to cross various species and
rear interesting hybrids. Cases of this character are reported
by Darwin, who states with respect to birds that “In several
groups I have not been able to discover whether the species are
polygamous or monogamous.” '

“Very peculiar fancies,’ says Letourneau, “sometimes arise
in the brains of certain birds. Thus we see birds of distinct spe-
cies pairing, and this even in a wild state. These illegitimate
unions have been observed between geese and barnacle geese,
and between black grouse and pheasants,” and further, when
quoting Hewitt from Darwin as to how a common tame mallard
duck threw over the male of own species and deliberately courted
a male pintail that had been placed in the water with her, mated,
and would have nothing further to do with the mallard, he says
“that conjugal fidelity does not always resist a strong impression
arising from a chance encounter; that novelty has a disturbing
effect; and, finally, that indifference and coldness can rarely hold
out against the persistent advances of one who loves ardently
enough not to yield to discouragement. Dante has already made
this last reflection in his celebrated line —

‘Amor ch’a null’ amato amar perdona.’

To quote Dante à propos of the illicit amours of a pintail and
a wild duck may shock the learned, but the aptness of the quota-
tion proves once more the essential identity of the animal and
human organisms.”?

Polygamy is not practiced, so far as I am aware, by any of the
flamingoes (Pheenicopteri), or representatives of the crane-stork
assemblage (Herodiones), or the diurnal Raptores including
all the vultures (Accipitres), or the parrot group (Psittaci), or

! Loc. cit. pp. 219, 218.

? [otouma Ch. "The Evolution of Marriage. London, 1900, pp. 28, 29.

172 THE AMERICAN NATURALIST [Vor. XLI

the owls (Striges), the Caprimulgine forms (Caprimulgiformes).
None of the Coraciz (rollers, etc.) I believe are polygamous, or
the kingfishers (Haleyoniformes), or the Bucerotes, or representa-
tives of such suborders as the Upupe, the Meropes, the Momoti,
or the Todi, but when we come to the humming-birds (Trochili)
some authorities still seem to be in doubt, and no less a distinguished
ornithologist than Mr. Salvin told Darwin that he was “led to
believe that humming-birds are polygamous,” * but, the present
writer by no means entertains any such an opinion.

Comparatively speaking, very little is known of the courtships
and matings of the Jacamariformes (jacamars and _puff-birds)
and the Trogoniformes (trogons), but I believe none of them to
be polygamous in their habits, although if found to be so it would
in no way surprise me, on account of the relations of the latter to
the cuckoos.

When I say this I do not mean to imply that any of the cuckoos
are strictly polygamous, and no writer seems to be perfectly cer-
tain on that point. What the mating habits of the touracos (Muso-
phagidee) is like, I am, at this writing unable to say, but it is very
interesting and important for us to know. ‘Those who have had
opportunity to study them have, as in so many instances in or-
nithological history, overlooked all this. The literature upon the
nidification of the cuckoos (Cuculide) would make many volumes
so it is quite unnecessary to dwell upon it here. Their depositing
their eggs in the nest of other birds is simply parasitism, and for
all I know to the contrary, the European cuckoo may be the
veriest polygamist in the world’s avifauna, and the same is true
of others of his kin that follow the same practice. It is not likely
that these birds are monogamous, it being far more probable that
they follow some form of promiscuity, or where there is a scarcity
of males, even polyandry? All these remarks likewise apply
to our cowbirds (Molothrus) of the Passeriformes, birds which I
am quite sure from personal observation may be either polygamous,
monogamous, promiscuous, or have recourse to concubinage,
or perchance in some instances, may even be polyandrous, though |

1 Loc. cit. p. 219. I have never seen any evidence of this in an common

eastern form, the ruby-throat, nor in any of those I have had the opportunity
to study in the west.

No. 483] MATING AMONG BIRDS 173

it is only through the force of circumstances that birds are ever
the latter, as some seem to contend.

Some of the breeding habits of Cuckoos in various parts of the
world are truly remarkable, as witness those of this country
(Crotophaga, Geococeyx and Coccyzus). It would appear, from
what we know of its habits, that our Anis may be strietly polyg-
amous (Crotophaga), inasmuch as several females of this species
all lay their eggs in the same nest,— but even so, they may be the
mates of different males.

There are some wonderfully interesting questions that arise,
when we come to study the courtships, mating, and nidification
of the cuckoos, cuckoo-like birds, and the cowbirds, and especially
when we apply this knowledge, in a comparative way, with the
customs followed by our own species. Space, or rather its limi-
tations, will not admit of my discussing any such matter here.
Furthermore, the author is at present engaged upon a volume
that will take fully into considerations all such questions, and
where sufficient data is available, endeavor to throw some light
upon their significance. Right here I may say, however, that the
reader cannot be too strongly commended to read in the present
connection all that Darwin has to say with respect to birds in The
Descent of Man (pp. 219-221 and 358-499); also Letourneau on
the Evolution of Marriage.

Returning to the cuckoos for a moment, I find Dr. R. Bowdler
Sharp has said of the common European species (C. canorus),
“There can scarcely be any doubt that the number of males con-
siderably exceeds that of the females and some naturalists not
only speak of the species as polyandrous but declare that the
female bird does all the courting.” They are said to lay twenty
eggs in one season."

Other than those referred to above, I know of few other birds
in the world that are given to polygamy, though I expect the breed-
ing habits of some of them are wonderfully interesting, not to say
curious. Little or no information is before me on such subjects
with respect to some of the following suborders, namely the Pam-
prodactyle, Capitones, Rhamphastides, Indicatores, „Piciformes,

1 Cuckoos, Royal Nat. Hist. Lond., R. Lydekker, Editor. This work con-
tains some excellent general accounts of birds and their habits.

174 THE AMERICAN NATURALIST [Vor. XLI

Cypseliformes, and the Euryleemiformes, although I know of no
species or family among these several groups that are not strictly
monogamous by nature, while they may differ very widely in
their habits of nidification. Unfortunately, we still know very
little about the life-histories of the lyre-birds of Australia (Me-
nura), and some naturalists believe them to be polygamous.
Again, Darwin quoting Lesson says “that birds of paradise, so
remarkable for their sexual differences, are polygamous, but
Mr. Wallace doubts whether he had sufficient evidence.’

In closing this article it is well to note that what I have set forth
in it has probably long been known to the majority of general
and observing naturalists of each generation, but not so to the
average reading public, and, unfortunately not to a great many
people to whom the knowledge would be of considerable interest
if not of positive value.

It is clearly shown that birds, as a Class among Vertebrates, in
nature may, in mating, be polygamists, monogamists, or under
certain conditions given to practices simulating polyandry, or,
as some claim, actual polyandry. At present we have no knowl-
edge of the origin, causes, and in the majority of cases, the needs
of these various habits. The radical changes that birds, in most
instances make in these particulars under domestication are often
more easily explained. ‘That the satisfaction of the sexual instinct
and the equally imperative demand, on the part of nature, that
the species be perpetuated, if possible, is the essential part of the
explanation, there can be no question. No one in any way famil-
iar with general biology, and the past and present life histories of
animals on this planet, would for an instant claim that any of these
mating habits in birds were of a criminal nature. It is only the

1 Loc. cit. p. 219. The fact of the matter is the so-called birds of paradise
differ widely among themselves in structure appearance and in habits; so it
may be that some of them are polygamists and others monogamists,— and
this is possibly, indeed, probably the case. On the same page as quoted
above, Darwin remarks that the male widow-bird, remarkable for his caudal
plumes, certainly seems to be a polygamist,” and Lydekker in the Royal

Jatural History, quoting Mr. Bowker (p. 366 of Vol. iii), says of the paradise
whydahs (Vidua), an African genus of birds the same to which Darwin refers,
that one male not unusually mates with at least fifteen females. This species
is frequently seen in captivity.

No. 483] MATING AMONG BIRDS 175
ignorant, the superstitious and narrow-minded who entertain such
views. We have plenty of storks, black grouse, and even Euro-
pean cuckoos and American cow-birds among our own species,
but the significance of all this, and its biological importance to
our kind, I shall endeavor to point out in another connection

later on.

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ON THE WOOD RAILS, GENUS ARAMIDES, OCCUR-
RING NORTH OF PANAMA

OUTRAM BANGS

For many years I have been gathering all specimens I could
of the splendid, great Wood Rails of the genus Aramides with the
hope of some day monographing the group. Unfortunately I
have as yet been unable to bring together sufficient material from
South America to attempt to include in review the forms of that
country. I now have, however, a complete set of the species and
subspecies of Middle America from Panama north to the northern
limit of the genus in southern Mexico. A critical study of this
material together with a number of skins kindly lent me by the
United States National Museum, the American Museum of
Natural History, and the Bureau of Biological Survey of Washing-
ton, which include the types of Aramides plumbeicollis Zeledon,
A. axillaris Lawr. and A. albiventris Lawr. has induced me to
publish now a short synopsis of the forms of Aramides occurring
north of Panama.

My views expressed in the following pages will be found to differ
a little from those of recent authors, such as Sharpe in Vol. XXIII
Catalogue of Birds in British Museum 1894 and Biologia Centrali-
Americana, Aves, 3, 1897-1904, and I describe as new one form
from Mexico, allowing to the region here treated three species
and two additional subspecies.

In all species of Aramides the sexes are alike in color and there
are but slight individual or seasonal differences, apart from those
caused of the wholly mechanical processes of fading and wear.
Some species have a juvenile plumage, still worn when the bird is
nearly full grown, that is quite different in color from the livery
of the adults — A. axillaris and its allies. Other species, appar-
ently (I have seen but one young individual of A. albiventris
plumbeicollis, and none at all of the other subspecies of albiventris
or of A. cajanea) do not have a young plumage that is very dis-
tinctly different in color from that of the adults.

177

178 THE AMERICAN NATURALIST [Vor. XLI

If the specimens examined by me are correctly sexed, there
is also no average difference in size between the sexes in any of
the species or subspecies. All, however, vary much in size indi-
vidually, in fact to a degree I am wholly unable to account for.

KEY TO THE SPECIES AND SUBSPECIES OF ARAMIDES OCCUR-
RING NORTH OF PANAMA

A. Sexes alike in color.
1. Under wing-coverts banded black and white
A. axillaris Lawr.
1. Under wing-coverts banded black and cinnamon-rufous or
hazel

2. Back of head, Ds gray | ad gray neck not
distinctly chestnut, but grayish-brown or brownish-gray

A. cajanea (Miill.).

2. Back of head distinctly chestnut . Ä i ; 3.

3. Back concolor, olive . 4.

3. Back not concolor; cas away steno. ae pos-

teriorly . . . 4A. albiventris plumbeicollis (Zeledon).

4. General color paler; light colored crescent around the black
belly patch, very wide, white
A. albiventris albiventris Lawr.
4. General color darker; light colored crescent around the
black belly patch, narrow, fulvous
A. albiventris mexicanus nobis.

ARAMIDES AXILLARIS Lawrence

Aramides axillaris Lawr. Proc. Phil. Acad. p. 107, 1863. Sharpe
Cat. Birds Br. Mus. 23, p. 56, 1894. Biol. Cent. Am., Aves vol.
3, p. 318, pl. LXXVII, 1897-1904.

Tyre Locauımy. Barranquilla, Colombia. Type, now No.
45655, American Museum of Nat. Hist., New York, examined.

(GEOGRAPHIC DISTRIBUTION. British Guiana, Trinidad, and
northward through Venezuela and Colombia to southern Mexico.

It has been supposed that there was a break in the range of
this species and that it did not occur in southern Central America
south of Honduras. There is, however, in the Underwood collec-
tion, lately purchased by John E. Thayer Esq., a young example

No. 483] WOOD RAILS NORTH OF PANAMA 179

of A. axillaris, nearly full grown but with the under parts still
brownish slate-color, from Costa Rica. Unfortunately the label
bears nothing more definite than “Costa Rica.” While certainly
very rare in southern Central America, I still believe A. axillaris
has a continuous range. It is a rare species in northern South
America, and seems to be nowhere so plentiful as in the region
lying between southern Mexico and Honduras. At all events I
can detect no difference between northern and southern speci-
mens.

CHARACTERS. Size small; bill short; under wing-coverts
banded blackish and white; neck and head, except throat, ru-
fous-chestnut; a conspicuous gray patch occupying upper inter-
scapular region and lower hind neck.

Coror. Adult plumage. Throat white; head, neck and
breast bright rufous-chestnut; upper interscapular region and
lower hind neck gray (about slate gray); back, wing-coverts
and wings except primaries and secondaries, olive; rump brown-
ish black; tail and upper and under tail-coverts, black; belly
and thighs slate-color; primaries hazel; secondaries also hazel
but duller, more dusky toward tips; under wing coverts and
axillars banded black and white; bend of wing and tips of axillars
usually banded black and hazel; “tarsus vermilion; beak green,
basal portion yellow; iris brown.

Young differ from adults in having the neck and under parts
dull slate-color, and the characteristic gray patch on lower hind
neck and upper back less distinct though still evident.

MEASUREMENTS.
ex Tar- Cul
No. & Age Loc ing. Tail sus, men
45655° Type — Colombia, Ten 171 60. 57.5 44.
6159 dad. Colombia, Chirua. 166. 57. 57. 43.
167364 Gad. Yucatan, Mujeres Isl. 165. 58. 54. 41.

141535 ad. Mexico, Guerreo, Acapulco. 168. 54. 56. 43.

157363 iad. _ Mexico, Tepic, San Blas. 169. 60. 60. 45.
508715 Z'yg. ad. E T A 166. — 57. 42.5

Mexico, Mazatlan. 170. 585 046 425

1 From notes made from fresh specimen by W. W. Brown Jr.
? Coll. of American Museum of Nat. Hist., New York.

3 Coll. of E. A. & O. Bangs, Boston.

t Coll. of Bureau of Biological Survey, u.

5 Coll. of U. S. National Museum, Washing

180 THE AMERICAN NATURALIST [Vor. XLI

Sex Tar- Cul-
No. & Age Locality. Wing. Tail. sus. men.
105554 yg. British Guiana. 168. 53. 5L 39.
16375! yg. Costa Rica. 156. 50. Bl. 40.5

Remarks. A. axillaris is a small species with a short bill,
related to A. mangle (Spix) of Brazil of which it is the northern
representative. Judged by the few specimens I have been able
to examine I should think the two were specifically distinct.

A. axillaris is very different from any species occurring in the
same region with it, being at once distinguished by its small size,
black and white under wing-coverts and red-brown neck. It
does not appear to be subject to any geographic variation —
southern and northern examples being, so far as I can see, quite
alike.

‘
ARAMIDES CAJANEA (Miiller).

Fulica cajanea Miill., Syst. Nat. Suppl., p. 119, 1776, based on
Daubent. Pl. Eul. pl. 352.

Rallus chiricote Vieill., N. Dict. d’ Hist. Nat., 28, p. 551, 1789.

Aramides cayanea Sharpe, Cat. Birds Br. Mus. Vol. 23, pp. 57-
58, 1894.

Aramides cayanea subsp. A. Aramides chiricote Sharpe, Cat.
Birds Br. Mus. Vol. 23, pp. 58-59, 1894.

Aramides chiricote Biol. Cent. Am. Aves, Vol. 3, p. 318, 1897-
1904.

Type Locauıty: Cayenne.

Geographie Distribution: ‘Tropical America in general from
northern Brazil north through Panama and Chiriqui to the Pacific
slope of Costa Rica.

CHARACTERS: Size large (in point of size A. cajanea and its
allies occupy an intermediate position in the genus, being much
larger than A. axillaris and allied species, but inferior to the
gigantic A. ypacaha (Vieill.) of southern South America); bill
long; under wing-coverts banded blackish and hazel; neck and
head gray, duller, browner on occiput; back concolor, olive;
breast, concolor bright, deep, reddish tawny.

Cotor: Throat dull grayish white; rest of head and neck
gray (nearest slate-gray) this color sometimes extending a little

1 Coll. of E. A. & O. Bangs, Boston.

No. 483] WOOD RAILS NORTH OF PANAMA 181

onto mantle, darkest on forehead and palest on cheeks, the occi-
put darker, duller, often brownish — grayish-brown, brownish-
gray or grayish-olive; back and wings, except primaries and sec-
ondaries greenish-olive; primaries and secondaries hazel, darker,
dusky olive toward tips, the outer secondaries olive on outer
edges, and inner secondaries mostly olive; rump black, often
‘suffused posteriorly with deep reddish olive; upper tail coverts
and tail black; breast deep reddish tawny, varying slightly in
tone (with season or age?), sometimes toward hazel sometimes
toward orange-rufous; belly and under tail coverts black; thighs
slate color; under wing coverts and axillars banded black and
hazel; “tarsus poppy-red; terminal part of bill green, basal part
yellow; obital ring red; iris red, soon after death changing to

MEASUREMENTS.
Se Tar- Cul-
No. & Age ocality. Wing. Tail sus. men.
11398 — Brazil, Santarem 180. 56.5 69. 61.
121110? Ọ ad. Brazil, Diamantina ur Gi 68.5 50.
15408 — Brazil. 168. 58. 68. 52.5
16586 — s: 185. 70 68. 57.
9942? Qad. Surinam, Paramaribo. 176. 61. 70. 57.
9943 Qad er M 168 58. 68. 52
17940 — Darien, Atrata. 177. — 69. —-
148191 -— Panama. 17/5. 99. TA, 52
7060? dad. Panama, Loma del Leon. 173. 65. 69. 55.
7650 Q ad. Chiriqui, Divala. mi ti: 72. 53.5
7649 gad s s 135. 6l- 73, 565
40386? — Chiriqui, David. 176. 60. 54.
40392 — z 2 172. 66. 72 55.5
132265 gad. Costa Rica. 190. 65. ak. 54.
64997 — Costa Rica, Talamanca Dist. 182. 66. 6s... 87
64998 — oe “ im s T u
67900 — n 25 378: ol. 69. 54.5
67905 — ii ie 189. 54. 69. 50.5
163732 Qad. Costa Rica, Pozo Azul. 184. 59. q1: 53.5
16374 gad 3 “ 180 63 72. 57
14297 Qad. Panama, San Miguel Isl. 163. 58.5 67.5 52.
14298 Qad a ” 170. 64. 66. 52
14299 g'ad. n ” 165. 59. 67. 52.
40343? dad. be er 109. — 67. 53.

1 Notes made from freshly killed examples by W. W. Brown, Jr.
? Coll. of E. A. and O. Bangs.

3 Coll. of United States National Museum.

t Coll. of Museum of Comparative Zoology.

182 THE AMERICAN NATURALIST [Vor. XLI

REMARKS. After very careful comparison of a large number
of specimens I fail altogether to make out a subspecies, chiricote.
I can find no constant differences whatever between skins from
Brazil and Surinam on the one hand and the most northern exam-
ples from Chiriqui and Costa Rica on the other. Indeed Sharpe
in Catalogue of Birds in the British Museum (Vol. 23, pp. 57-59)
does not assign any well defined geographic distribution to the
two subspecies he recognizes. ‘The patch of a duller color on the
occiput varies considerably in shade — with season I think, that
is with the condition of the plumage, whether fresh or much worn.
Different examples from Panama and Costa Rica differ quite as
much in respect to the shade of color and distinctness of this mark-
ing as do any two that can be picked out from the northern and
southern parts of the range of the species.

Inhabiting the Pearl Islands in the Bay of Panama is a slightly
paler and slightly smaller race of this rail. The four examples
taken there by Mr. Brown cannot quite be matched by continental
specimens, but the differences are too slight and in this genus of
two unimportant a nature to base a subspecies upon.

There appears, however, to be in Brazil a well marked sub-
species, the exact range of which I am through want of sufficient
material unable to define. Skin “f” of Sharpe’s list in Catalogue
of Birds, belongs to this form (see footnote, p. 58) and there is one
skin in the National Museum, No. 24124 from (St. Catharines ?)
Brazil collected by Lemuel Wells, that appears to agree exactly
with Sharpe’s Rio de Boraxudo specimen, differing from A. caja-
nea in being mostly gray above, the gray of the upper neck per-
vading the entire mantle, the wing coverts alone being olive and
these paler and decidedly more grayish olive than in A. cajanea;
the rufous color of under parts, as pointed out by Sharpe in his
specimen too, is also paler. This bird is not Gallinula ruficeps
Spix, which, judged by the plate, is true A. cajanea, and un-
doubtedly represents a valid form.

Another peculiar individual is a very old skin in the National
Museum, no. 15407, labeled ‘‘ Buenos Ayres, J. K. Townsend 3.”
In color this example agrees with true A. cajanea except in having
the rump nearly wholly dark reddish olive. It is, however, very
much larger with proportionally shorter tarsus and bill, the wings,

No. 483] WOOD RAILS NORTH OF PANAMA 183

considerably worn at that, measuring, 200, tail 86, tarsus 73,
culmen 55. It may represent still another subspecies.

Thus while in the northern part of its range from northern
Brazil north, this rail does not vary to any extent with geographic
areas, there seem to be in southern South America several geo-
graphic forms.

Aramides cajanea is another very distinet species, nearly allied
only to A. albiventris Lawr. From that bird it can always be
distinguished by its shorter, thicker bill, and duller color of the
occipital region, which in A. albiventris is always bright chestnut.

ARAMIDES ALBIVENTRIS ALBIVENTRIS Lawr.

Aramides albiventris Lawr. Proc. Phila. Acad., p. 234, 1867.

Aramides cayanea, subsp. B. Aramides albiventris Sharpe, Cat.
Birds. Br. Mus. Vol. 23, 1894, pp. 59-60.

Aramides albiventris Biol. Cent. Am., Aves, Vol. 3, p. 319, 1897-
1904.

Type Locauity; British Honduras, Type, now 45656, Ameri-
can Museum of Natural History, examined.

GEOGRAPHIC Distripution: British Honduras and Yucatan,
and parts of Guatemala. Exact limits of range not known.

CHARACTERS: About the size of A. cajanea or slightly larger;
bill longer and more slender than in that species; all the colors
pale; a large, conspicuous patch of bright chestnut extending
from between eyes over occiput to upper surface of neck; white
throat patch large, extending well down neck; black of belly
surrounded by a wide crescent shaped marking of white; under
wing coverts banded black and pale hazel.

Cotor: Throat dull white, this color extending well down
under surface of neck; on the occiput, extending backward to
upper neck and forward to between eyes, a conspicuous patch of
chestnut; rest of neck and head gray (about Gray No. 6 of Ridg-
way); back pale greenish olive; scapulars and sometimes outer
interscapulars as well ochraceous-rufous more or less mixed with
olive, this marking usually very conspicuous, though never form-
ing a complete mantle across back as in the southern subspecies
plumbeicollis; primaries and secondaries, light, bright hazel;

184 THE AMERICAN NATURALIST [Vor. XLI

rump black, somewhat dusky olive anteriorly; upper tail coverts
and tail black; breast pale tawny-ochraceous becoming ochra-
ceous-buff posteriorly; a wide crescent shaped marking of white
or sometimes cream-buff, around upper part of black belly patch;
belly and under tail coverts black; thighs slate color; under
wing coverts and axillars banded black and pale hazel, the tips
of the feathers sometimes buff.

MEASUREMENTS
i Sex Tar- Cul-
No. & Age. Locality. Wing. Tail. sus. men.
45656' Type British Honduras. 186. 62.5 80. 63.5
_—’ — Belize, British Honduras. 180. 65. 74.5 60.
130325 — Yucatan 236. oi. 74. 60.5
130326 — = 177. D9 76 64
130327 — ca 177. 58. 80. 65.
148192 — t; i 184. 62. 273 —
15246° Gad. Yucatan, Rio Lagartos 171..: 6305 f; 62.5
33668? — Guatemala, Chiapam 187. 62. 78. 66.
42777 — Central Guatemala 176. 98. 75.5 66.

Remarks. ‘Typical A. albiventris occurs only, so far as I know,
in the coast region of British Honduras and Yucatan, and in its
very pale coloration parallels other bird forms of the same region
such as the clapper rail, lately named Rallus pallidus by Nelson.

Two specimens from Guatemala I refer here, though they are
intermediates, between A. albiventris albiventris and A. albiventris
mexicanus, the one from central Guatemala being nearer to
Yucatan and British Honduras examples, the other from Chiapam
on the Pacific coast being more like the Mexican bird. To the
northward true A. albiventris is replaced by a darker form with
less distinct and more fulvous crescentic marking on the belly,
that occupies southern Mexico and that I have named below as a
new subspecies. Farther south in Central America A. albiventris
is represented by a form— A. plumbeicollis — quite different
in some details of coloration, and somewhat smaller, but still so
like it in general that I have no hesitation in regarding the south-
ern form as a subspecies rather than a segregate species.

1 Coll. American Museum of Natural History.

? Coll. United States National Museum.
3 Coll. E. A. and O. Bangs.

No. 483] WOOD RAILS NORTH OF PANAMA 185

I find no indication of intergradation between A. cajanea and
A. albiventris and must regard them as distinct species. The
much longer more slender bill of A. albiventris and the conspic-
uous chestnut patch on the back of the head, always serve to dis-
tinguish it in all its subspecies from A. cajanea.

ARAMIDES ALBIVENTRIS MEXICANUS sub. sp. nov.

Type: from Buena Vista, Vera Cruz, Mexico, adult 9, no.
2281 Coll. of E. A. and O. Bangs. Collected June 4, 1901, by
A. E. Colburn and P. W. Shufeldt.

GEOGRAPHIC DISTRIBUTION: Southern Mexico, in States of
Vera Cruz, Tabasco, Oaxaca and Chiapas, north to Hidalgo (one
skin from Orizava no. 29231, U. S. Nat. Mus.) and on the coast
at least to Tampico.

CHARACTERS: Very similar to true A. albiventris, but pale
crescentic marking on belly, surrounding black belly patch much
narrower and less distinct, strong buff in color, not white or cream
buff; all the colors darker — gray of head and neck, greenish
olive of back, and tawny of breast; much less suffused with
ochraceous or tawny on scapulars and outer interscapulars though
this marking is often indicated; throat less purely white, more
grayish and this marking more confined, extending less onto-
under surface of neck.

MEASUREMENTS
No. Pi Loca Wing. Tail.

lity. 3
2281! Type Q ad. Mexico, Vera Cruz, Buena Vista. 177. 54. 74. 64.
g'ad. o P sy 180. 56.5 76. 63.

22
141536? Qad. Mexico, Vera Cruz, Tlacotalpam. 179. 59. 74. 63.
141537 Gad. i me 3 185. 5. 73. 61.
141539 ad. a “ ® 178. 58. 77. 94.
58966 — Isthmus of Tehuantepec. 189. 60. 83. 73.
76990 — a“ 185. 67. 78. 66.
29231 — Mexico, Hidalgo, Orizava. 188. 04. 79. 67,
141541? Qad. Mexico, Oaxaca, Guichicovi. m m 73. 81.8
11012! Q ad. Mexico, Tabasco 104 060. T0. 62.
11013 gad. i n 184. 62. 80. 66

1 Coll. of E. A. and O. Bangs.
? Coll. of Bureau of Biological Survey, Washington.
3 Coll. of U. S. National Museum.

186 -THE AMERICAN NATURALIST [Vor. XLI

REMARKS: Aramides albiventris mexicanus is the northern
representative of this group of the genus, occupying the southern
- tier of states of the Republic of Mexico and southeastward passing
gradually into true A. albiventris of Yucatan and British Honduras.
Though well characterized subspecifically it is in general much
like true A. albiventris. It can, however, always be told from that
form by the characters pointed out above.

ARAMIDES ALBIVENTRIS PLUMBEICOLLIS (Zeledon)

Aramides plumbeicollis Zeledon Anales. Mus. Nac. Costa Rica,
1, p. 131, 1887. Biol. Cent. Am. Aves, Vol. 3, p. 320, 1897-1904.

Type Locauiry: Jiménez, Costa Rica. Type now no. 113603,
U. S. National Museum, examined.

GEOGRAPHIC DISTRIBUTION: Costa Rica, specimens exam-
ined from Jiménez, Carrillo, and Cariblanco de Sarapiqui, north
at least to Segovia River, Honduras.

CHARACTERS: Similar to A. albiventris mexicanus, but slightly
smaller; bill actually shorter, though relatively of about the same
length; differing in color principally in having a complete mantle
across upper back of olivaceous-tawny — the back thus bicolor,
olivaceous — tawny anteriorly, greenish olive posteriorly; breast
rather darker than in the other two subspecies more nearly as in
A. cajanea; crescentic marking made by paler feathers around
black belly patch, when present, narrow and buff in color (in two
skins, one from Carrillo and one from Cariblanco de Sarapiqui
this marking shows very distinctly; in the type and one other
skin from type locality it is barely indicated).

MEASUREMENTS.

Tar- Cul-
No. Wing. Tail. sus. men.
113603' Sad. dee em enge Jiménez 273. 5L H. OI.
115045 Q ad. 170. oa m —

1637r 9ad. Costa iis Cariblanco de Sara-
piqui. 1:72 09. 15. 08.
16372 Q ad. Costa Rica, Carrillo. 175..:005 fe: Bl.
112254 yg. Honduras, Segovia River. 1755 38. 78: 88

1 Coll. of United States National Museum.
? Coll. of E. A. and O. Bangs

No. 483] WOOD RAILS NORTH OF PANAMA 187

Remarks: I feel confident that I am right in placing this bird
among the subspecies of A. albiventris, rather than to allow it
specific rank. In all essential points — the long slender bill and
chestnut color of the occiput and crown it agrees with A. albiven-
tris albiventris and A. albiventris mexicanus. The brown mantle
strikes one at first as a very strong point of difference, but this
is in reality only a difference of degree, many northern skins
showing a very decided approach to it, though it is in them never
quite complete all across the back as it invariably is in the Costa
Rican bird. The southern form is also somewhat smaller and
darker in color below than either of the other two races, but every
indication, in my opinion, points to its being a representative
geographic form — subspecies — of the A. albiventris type.

The specimen from Segovia River, Honduras, unquestionably
belongs here, as first pointed out by Richmond (Proc. U. S. Nat.
Mus. 16, p. 528, 1894). It is young, and as it happens is the
only young example of any of these rails, except A. azillaris,
that I have seen. The feathers of the underparts, especially
the belly, are more fluffy than in the adults and in color it
differs in the belly (black in the adult plumage) being black only
at the base of the feathers which are externally tipped and suf-
fused with the tawny color of the breast and in the rump, also
clothed in fluffy feathers, being decidedly paler and browner.
Though badly shot in the back and neck with many feathers
from these parts lacking, the complete mantle of olivaceous-
tawny is plainly to be seen. The bill is not full grown and is
very immature in appearance. Judging from this skin it appears
that the species of Aramides of this group do not have a brownish
gray breasted juvenile plumage as does A. axillaris and its allies.

NOTES AND LITERATURE
BIOLOGY

The Reception of the Mutation Theory.— When the first Lieferung
of “Die Mutationstheorie” appeared in 1901 a frequent question was
whether the work would be made available for a larger audience
by the preparation of an English translation. That the interest
of Americans in this subject is very real was soon evidenced by an
invitation extended to Professor de Vries to deliver a series of lectures
at the University of California. A second edition of the thick volume
containing these published lectures was necessary in a few months.
Besides a French translation of the American lectures we now wel-
come an attractive German edition by Klebahn.!

Species and Varieties was reviewed in the pages of this journal
(Am. Nat. 39: 747-751, 1905) and it seems unnecessary to discuss
the scope or contents of the work. The translator had the benefit
of the corrections prepared by Professor de Vries so that the transla-
tion is comparable with the second American edition. An especially
commendable feature of the present volume is a fine series of over
fifty illustrations. These are drawn in part from the larger work of
the author, in part from his unpublished drawings or photographs,
and in part from living material or other sources.

It must be gratifying to all serious students of evolution to see the
widespread interest in these works. Whether or not they admit
the general applicability. of de Vries’s theory, they must at least
realize that after long years of marking time students of evolution
have at last begun to march. No one should scorn the results of
comparative studies, but their limitations should always be kept
clearly in mind. The spirit of experimental work is in the air and
let us hope that there will be no turning back because of difficulties
encountered in the way. Just here a word of warning may not be
out of place. In experimental physiology and morphology it is con-
sidered essential that the factors involved and the results secured
be quantitatively expressed. In ecology and evolution the impor-

1 deVries, H. Arten und Varietäten und ihre Entstehung durch Mutation.
Ins Deutche übertragen von H. Klebahn. Berlin. Gebrüder Borntraeger,
1906. Q. xii + 530 pp.

189

190 THE AMERICAN NATURALIST [Vor. XEL

tance of quantitative methods is just as great. While de Vries was
making the now celebrated experiments upon which his theory’ is
based Pearson and his associates were developing the methods of
quantitative investigation in variation and heredity. It will be unfor-
tunate indeed if present day workers neglect this new and power-
ful instrument of research. But with a proper combination of ex-
perimental and biometric methods it should be possible to gain a
very precise knowledge of the processes involved in species formation.
J. A. Harris.

A Monument to Theodor Schwann.— Theodor Schwann was born
at Neuss on the Rhine, December 7, 1810. On the centennial of
that date it is proposed to unveil a monument to his memory in his
native town. A considerable sum is already in hand and a committee
representing all countries has issued an appeal for subscriptions for
the memorial. As is well known, he with Schleiden, placed the cell-
theory on a substantial basis sixty-five years ago; while his later work
was almost equally valuable though not so startling in character. He
became an authority on fermentation, decomposition, digestion and
spontaneous generation, and, not least, was the discoverer of pepsin.
A monument to his associate has been erected in Jena while his master
Johannus Miiller has a bronze memorial in his native town, Coblenz.
Contributions may be sent direct to the ‘Städtische Sparkasse, Neuss
am Rhein, Germany’ marked ‘Schwanndenkmal’ or probably to the
American members of the Committee, Prof. C. S. Minot of Boston
and Prof. R. Ramsay Wright of Toronto.

Fitch’s Basis of Mind and Morals.'— This book is a brief exposi-
tion of the principles of evolution as stated by Darwin and Spencer,
together with a discussion of the evolution of mind and of the nat-
ural code of ethics. The point of view of the book is phenomenal-
istic; the style is simple, clear and direct. For those who have
thought seriously about the problems of evolution the work has little
value; for those who wish to be stimulated to such thought it may
prove profitable.

The author contends that there should be a natural code of ethics.
He does not attempt to construct such a code, but, instead states
that it should be the result of man’s knowledge of natural causes and

! Fitch, M. H. The Physical Basis of Mind and Morals. Chicago, Charles
"H. Kerr and Company. 1906. 266 pp.

No. 483] NOTES AND LITERATURE 191

effects. “But I repeat, he says that until men come to comprehend
a natural cause for every natural effect they should be controlled
in their attitude toward environment, including their brother men,
y some code that will have the proper effect, however based that
code may be.” (p. 255.)

GEOLOGY.

The reconstruction of the Continents of Tertiary times is the
topic discussed in a paper by W. D. Matthew.’ Using the evidence
furnished by the distribution of fossil and recent Mammals, he tries
to reconstruct the outlines of the old land-masses, and illustrates
his results by seven maps, which represent the geographical conditions
of the earth’s surface in Postcretaceous time (immediately after the
close of the Cretaceous), in the middle Eocene, in the middle Oligo-
cene, in the Miocene, in the Pliocene, in the early Pleistocene, and
in recent times.

This paper undoubtedly marks an important progress in this branch
of research. Comparing it with the last attempt to reconstruct the
old continents, made by Ortmann in 1902 (Pr. Amer. Philos. Soc. 41),
we see that here only two maps were given, for the lower and for the
upper Tertiary period. Neither agrees entirely with any one of
Matthew’s maps, although the one for the lower Tertiary corresponds
rather closely to the middle Eocene map, and the one for the upper
Tertiary to that of the Miocene. But complete agreement cannot
be expected, considering the extreme difficulties with which such
investigations are connected. Indeed, it is rather surprising that
Matthew’s studies, in many points, have led to results, which largely
indorse the views held by Ortmann, and furnish additional support
for many of the accepted features of ancient geography

Studies of this kind are often regarded as rather phantastic and
without sufficient support to render the conclusions trustworthy
enough to give them universal recognition. But Matthew’s paper
again demonstrates that it is possible to express definite views as to
the shape, the connections and disconnections of the continents,

1 Matthew, W. D. Hypothetical Outlines of the Continents in Tertiary
times. (Bull. Amer. Mus. Nat. Hist., 22, 1906, p. 353-383. 7 maps)

192 THE AMERICAN NATURALIST [Vor. XLI

chiefly in Tertiary times, and the agreement of the zoogeographical
facts with paleontology and geology tends to show, that these recon-
structions of the old continents are not merely wild speculations.
However, the results cannot yet be accepted as final, and although
some of the major features of old geography must be regarded as well
established, much remains to be done in detail. Chief of all, additional
groups of animals should be studied, and an attempt should be made -
to correlate the results obtained by them with those of Ortmann and
Matthew; and further, attention should also be paid to the Mesozoic,
and if possible, Paleozoic times. It is to be hoped that, for instance,
the distribution of certain molluscs and lower vertebrates may fur-
nish evidence with regard to these ages, although it is only natural
that this task will be much more difficult, since the facts are very
scanty, and their meaning is largely obscured by the changes in
subsequent times.

ARO.

The Mountains of Cape Colony.— In the Cape Colony, southern
Africa, are ranges of folded mountains very similar to the Alleghenies
of the eastern United States. During the summer of 1905 Professor
Davis had an opportunity to study the Cape Colony ranges while a
guest of the British Association for the Advancement of Science dur-
ing its South African meeting, and in this paper’ has given a most
interesting account of the ranges, comparing them with the Allegheny
type. The paper will be of more than usual interest to American
geologists and geographers, because of the striking similarity, in
practically all essential features, of the two widely separated moun-
tain groups, whether compared as to structure, the relation of folded
areas to undisturbed plateaus, the erosion history and development
of drainage adjustments, or the control exerted by the physiographic
features upon transportation, etc. In climate, however, a marke
contrast between the two localities exists. The paper is illustrated
by a number of drawings and photographs. °

DWG

Natural Mounds.’ — During the last two years a number of papers
have been published deseribing and attempting to explain the origin
of the natural mounds occurring in different parts of the country.

1 The Mountains of Southernmost Africa. By W. M. Davis. Bulletin
American Geographical Society, Vol. 38, 593-623, 1906.

2 Natural Mounds. By Marius R. Campbell. Journal of Geology, Vol.
14, 708-717, 1906.

No. 483] NOTES AND LITERATURE 193

Mr. Campbell figures and briefly describes the mounds, reviews the
various theories of origin, some ten in number, which have been
advanced by various writers, and concludes from his own studies
of the subject that the mounds have been built up by ants or small
rodents, more probably by ants. A bibliography of the subject is
appended to the paper.

DW.

Ancient Glacial Periods— During recent years the evidences of
repeated glacial periods during ancient geological time have been
accumulating so rapidly that whereas much doubt was cast upon the
earlier reports of such glaciation, it is no longer possible for the unpre-
judiced student to doubt the conclusions which the evidence forces
upon us. The famous Dwyka glacial formation of South Africa is
now well known, and its equivalent in India, the Talchir. I. C.
White and David White have recently reached the conclusion, inde-
pendently, that the equivalent of these Permian or Permo-Carbon-
iferous glacial deposits occurs in southern Brazil in what is called the
Orleans conglomerate. Glacial deposits in Australia are rn
from both the Permian and the Cambrian or older beds.
Coleman has recently reported evidence of a lower Huronian ice age
in Canada. Mr. Schwarz! discusses three glacial periods in South
Africa, those in addition to the Permian Dwyka being most probably,
according to the author, of Devonian and Archaean age. The relation
of the glacial beds to other members of the general stratigraphic series
is pointed out, and the evidence of the glacial origin considered. It
is this last point which in every case is critical. The fact that a large
number of reports of ancient glaciation are being published does not
strengthen the evidence in favor of ancient glaciation in any particular
case. Each reported instance must be critically examined as to the

value of the evidence supporting it.
D Wd.

! The Three Paleozoic Ice-Ages of South Africa. By Ernest H. L. Schwarz,
Journal of Geology, Vol. 14, 683-691, 1

194 THE AMERICAN NATURALIST [Vor. XLI

PHYSIOLOGY

Hough and Sedgwick’s Physiology.'— “The authors of this work
believe that extensive and fundamental changes must be made in the
elementary teaching of physiology, hygiene, and sanitation, if these
subjects are ever to occupy in the curriculum of education the place
which their intrinsic importance requires.” This sentence from the
Preface to this new book by two well-known professors of biology is
the key-note to its importance, for their intention in this respect cer-
tainly has been fulfilled. Not only the students of high schools,
academies, and colleges actually need to know the facts and principles
set forth here, but so also does the long-graduated ‘average man’ if
he would live well. Especially is it one more step towards the recog-
nition educational theory is certainly about to make, that in education
every part of a boy’s body one is educating at the same time and in
the most real manner also the capability of his whole mind.

The book is divided into two nearly equal parts: ‘Physiology,’
and ‘The Hygiene of the Human Mechanism and the Sanitation
of its Surroundings,’ respectively. The latter half is subdivided into
accounts of personal hygiene, domestic hygiene, and public hygiene
and sanitation, with an important introductory chapter in addition.

The matter of the first part of the book is better than its arrange-
ment in chapters, for the nervous system is placed last and the mus-
cular mechanism early in the list. For the learner the much more
preferable order is just the reverse, it being certainly difficult really to
understand any one of the great organic functions until the coördi-
nating purpose of the nervous system is mastered. One deplores
too the omission of at least a brief discussion of protoplasm in general
as an introduction to its differentiated natures.

A far more serious omission (but one more easily defensible) is
that of the basal principles of reproduction. When all is said, at
whatever length, one can but deplore the fashionable prudery of our
times which keeps from youth the true and useful knowledge of their
own real nature in this respect. With a decreasing birth-rate and an
ever increasing ‘social evil,’ the information both sexes most crave
is, above all others, most hard for them to obtain. The book is surely

1 The Human Mechanism: its Physiology and Hygiene and the Sanitation

of its Surroundings,” Theodore Hough and William T. Sedgwick. Boston,
Ginn & Company, [1907]. Pp. ix + 564. Illustrated.

No. 483] NOTES AND LITERATURE 195

not intended for grammar schools nor for the first years of the high
school even, but for schools whose students might soon aspire to be
husbands and wives.

The chapter on muscular activity is uniquely fine in its discussion
of the necessity for physical exercise, and in combination with previous
chapters on muscle-function and neural coördination almost meets
the insistent demand pedagogy is beginning to make for bodily skill
as a basis for learning. One misses, perhaps, an adequate descrip-
tion of the kinesthetic mechanism for muscular control, as well as.
sufficient information as to habit and the emotional reactions. On
the other hand, ‘rhythmic segmentation’ is allowed far more promi-
nence than the doubts as to its existence warrant.

The hygienic portion of the book is rich in clear and precise infor-
mation of really great importance to everyone. Moreover it is set
forth in a manner as scientific and up-to-date as could be desired.
Could an enlarged wall-copy of figure 116 (“A domestic well badly
situated in a farmyard”), be distributed broadcast by the state boards
of health, our city hospitals would soon cease to be over-filled with
typhoid patients in October and our farm-houses would be less sad-
dened by cholera infantum in the summer.

The account of personal hygiene is at once eminently practical and
entirely scientific — a needful combination seldom attained. More-
over it is more complete than is common in text-books of this sort.
It seems as if too little emphasis perhaps, were placed on the impor-
tance of moisture in the air of dwellings, this need being met by con-
tinually open windows. It is the throat-specialists who best realize
the general lack of moisture in the atmosphere of our houses, but
there are of course other reasons (such as that moist warm air feels
warmer than does dry warm air) which are important in the theory of
ventilation.

Few but physiologists familiar with the required falsities as to
alcohol and tobacco which reek in certain states, especially westward,
will realize how excellent is the discussion of these very important
topics in this book. The facts are clearly stated and the principles
laid down,— their dangers in overuse any student in a school
for normal persons may certainly see and be warned by for himself.

The 147 often familiar illustrations of the work are adequate and
for the most part well executed.

Altogether this is an important text-book, not only in itself as a
source of vital information for a host of young men and women, but.
as a prophecy of the present excellent trend of general education.

GEORGE V. N. DEARBORN.

196 THE AMERICAN NATURALIST [Vor. XLI

ZOOLOGY

Guyer’s Animal Micrology,' though burdened with a horrible
name, is one of the best and most practical works upon microscopic
technique with which we are acquainted, ranking, in this respect with
Böhm and Oppel’s well-known “Taschenbuch” which, by the way,
is not referred to in the list of works cited on p. vi.

The especial merit of the work lies in its great practicability. It.
does not burden the beginner with a large number of alternatives;
but starts him ‘at once with a few reagents of almost universal avail-
ability and sets him at work with his specimens. Only when these
have been carried through and converted into slides are other methods
and other objects considered.

In the Appendix are given an account of the microscope and its
accessories, a list of further tried and proved reagents and a table of
tissues and organs with methods of preparation which will doubtless
prove of value to instructors as well as to students. The list which
is given embraces over 250 objects and is more than ample to illustrate
any practicable course in normal histology. The final chapter of the
Appendix deals with methods preparatory to microscopic preparation
and study of a series of animals which are frequently used in the
Zoölogical Laboratory.

Omissions of what we would like to see in such a work are few. We
have found no mention of Cox’s Golgi method which presents certain
advantages over the silver impregnation; the Golgi method for dis-
tinguishing bile capillaries is not referred to, nor is the value of Lyons
blue for differentiating cartilage. The method of rolling wax plates
for reconstruction, credited to Huber (p. 128), has been in use for
many years. In the ‘Memoranda’ on p. 30 it is stated that material
which is to be kept indefinitely should be put in tightly stoppered
bottles, but there is no hint as to the injurious effects of the extracts
of cork and that some other method of closure should be adopted.
But why find any more fault with such a useful and excellent work?

D. K

‘Animal Micrology. Practical Exercises in Microscopical Methods by
Michel F. Guyer, Chicago, University of Chicago Press, 1906, pp. ix + 240.
$1.75 net.

No. 483] NOTES AND LITERATURE 197

Mollusca of Illinois and Michigan.—F. C. Baker has recently
catalogued! the Mollusca of Illinois, enumerating in all 332 species of
which 91 are terrestrial and 240 are aquatic (the figures are the
author’s, the discrepancy is not explained). The Unionidae number
89. The list gives localities with considerable detail; no new species
are described. Bryant Walker's catalogue of the terrestrial Pulmonata
of Michigan? is more elaborate, giving descriptions and in most cases
figures, with an outline of the synonymy of the 79 species recorded
from the state. In the Introduction, besides general notes on dis-
tribution, adequate directions are given for the collection and prep-
aration of specimens.

A monograph on Anurida.— Those in charge of the Liverpool
Biological Society have, for several years past, been issuing a series
of short Memoirs on the morphology, life history, and cecology of
various typical animals and plants found in that region. The thir-
teenth of the series appears in volume 20 of the Proceedings and
Transactions of the society. It deals with the interesting Collem-
bolan, Anurida and is by A. D. Imms. The habits and structure
are described from original observations; the account of the develop-
ment is summarized from American writers. A bibliography of 102
articles is given and the whole is illustrated by four figures in the
text and by seven plates.

Reichensperger describes (Bull. Mus. Comp. Zoöl., 43, Dee. 1906)
a new species of Myzostoma (M. vincentinum) found parasitic on
Pentacrinus decorus from St. Vincent.

BOTANY

A popular book on Canadian wild flowers.— In 1885 the venerable
Mrs. Catherine Parr Traill was among the leaders in popularizing a
knowledge of American wild flowers by presenting them untechni-
cally and attractively to those who could or would not make their ac-
quaintance through keys and manuals. Her pioneer course has been

1 Bulletin Ill. State Lat. Nat. Hist. 7, 1907.
? Published by the State Board of Geological Survey, as a part of the Report
for 1905, Lansing 1906.

198 THE AMERICAN NATURALIST [Vor. XLI

successfully followed in this country by many and excellent works
of the same character. A new and revised edition of her book has
now made its appearance.’ Like the original, it has passed through
the hands of Macoun and Fletcher, for the determination of the plants
included; it should stimulate in many people of the present day that
love for plants and their ways which comes through knowing what
they are,and toward which the first edition did such good service two

decades ago.
WE

Notes.— An interesting and appreciative sketch of de Vries, by a
former ee Henri Hus, has been separately issued from The
Open Cou

A handsomely printed volume of botanical studies presented to
Kjellman on his 60th birthday has been distributed by the University
library of Upsala.

A detailed account of the history of natural science in the Aberdeen
Universities has been reprinted by Professor Trail from “Aberdeen
University Studies.”

Semon’s terminology, “‘equally applicable to the movements of a
plant or the thoughts of a man,” is used by Francis Darwin in a lecture
on associated stimuli, printed in The New Phytologist of November
30.

A lecture on ““Mendelism and Microscopy” is published by Scour-
field in the Journal of the Quekett Microscopical Club of November.

The viability of old seeds has been tested recently by Becquerel,
as reported in the Comptes Rendus of June 25 last, and abstracted
in the Gardeners’ Chronicle of November 24. |

A concrete presentation of the results of local ecological study of
the modern sort is afforded by Woodhead’s Huddersfield paper occupy-
ing no. 261 of the Journal of the Linnean Society, Botany.

Strasburger contributes an illustrated paper on the thickening of
palm and screwpine trunks, to vol. 43, Heft 4 of the Jahrbücher für
wissenschajtliche Botanik.

! Traill, Mrs. C. P. Studies of Plant Life in Canada. Toronto, William
Briggs, 1906. 8vo. xvii + 227 pp., with 8 reproductions in natural colors
and 12 half-tone engravings, from drawings by Mrs. Agnes D. Chamberlin.

No. 483] NOTES AND LITERATURE 199

Habit illustrations of a number of the economic plants of West
Africa occupy Heft 5, Vierte Reihe of Karsten and Schenck’s “ Vege-
tationsbilder.”

South American botany continues to receive important attention
in the Arkiv jör Botanik of Stockholm.

A morphological and anatomical study of Ceanothus americanus
and C. ovatus is published by Holm in The American Journal of
Science for December.

An extensive segregation of the components of Rhus glabra is
effected by Greene in the Proceedings of the Washington Academy of
Sciences of December 18th.

Agnes Chase publishes on Panicex in the Proceedings of the Bio-
logical Society of Washington of December 8.

An interesting study of the Euglenoid genus Dunaliella is published
by Teodoresco in the Revue Générale de Botanique of September 15.

Pithyum de Baryanum is said by Raffill, in The Gardeners’ Chronicle
of November 10, to have proved a serious enemy of the Victoria, at
Kew.

An illustrated monograph of Ravenelia is published by Dietel in
vol. 20, Abt. 2, Heft 3 of the Beihefte zum Botanischen Centralblatt.

A practical account of the fungous diseases of tulips and their
treatment is contributed by Klebahn to Gartenflora of November 1.

A small text book of fungi, including morphology, peel
pathology, classification, ete., by Massee has been issued from the
Duckworth Press of London.

A biographic sketch of Mitten, with portrait, is published in The
Journal of Botany for October.

A new “Manual of the New Zealand Flora,” conformed to the
Colonial flora plan of the elder Hooker, and prepared by Mr. T. F.
Cheeseman, has recently been published by the Government of New
Zealand. The species that are admitted number 156 vascular crypto-
gams and 1415 phenogams, representing 382 genera and pertaining
to 97 orders. Of the total, 1143 are peculiar to New Zealand; 366
also occur in Australia; and 108 in South America. Naturalized
species have been excluded from the work; but over 600 such species
are said to occur in the colony.

200 THE AMERICAN NATURALIST [Vor. XLI

An excellent, conservatively handled, local flora, of a very rich region,
is that of the State of Washington, by Professor Piper, recently pub-
lished as vol. 11 of Contributions from the U. S. National Herbarium,
an illustrated volume of 637 pages.

In contrast with the highly diversified flora of Washington, is the
homogeneous flora of the Altamaha grit region of the coastal plain of
Georgia, to which is devoted a volume of 357 pages, by R. M. Harper,
forming vol. 17, part 1 of the Annals of the New York Academy of
Sciences. In this region, comprising about 11000 square miles, only
814 species or varieties of vascular plants are recognized, and 75 of
these are weeds. Mr. Harper’s study has been carried out on the lines
of ecological analysis with special reference to geographic distribution,
and his paper is illustrated by a map and 28 half-tone plates which
form one of the best series of such illustrations yet published.

Habit illustrations of antarctic vegetation are given by Skottsberg
in Reihe 4, Heft 3-4 of Karsten and Schenck’s Vegetationsbilder.

Further “Contributions to Canadian Botany” are being published
by Macoun in current numbers of The Ottawa Naturalist.

The official precedings of the International Botanical Congress
held at Vienna in 1905 have recently been issued from the Fischer
press of Jena, in the form of a quarto brochure of vi + 262 pages:
the scientific papers presented before the Congress form a similar
quarto of vi+446 pages, freely illustrated, and published by the
same house.

A polyglot code of the rules of botanical nomenclature adopted by
the 1905 International Botanical Congress of Vienna, has been sepa-
rately issued from the Fischer press of Jena. The pamphlet is indis-
pensable for every phanerogamic herbarium. One of the most debated
acts of the Congress was the adoption of a list of several hundred
generic names which were considered so thoroughly established as to
be exempted from supersession by earlier names which have failed to
come into general use. This list is included in the pamphlet.

Raunkiaer discusses the biological types to be recognized in botani-
cal geography, in a paper separately issued from the Oversigt over det
Kgl. Danske Videnskabernes Selskabs Förhandlinger for 1905.

Professor Bray’s “Vegetation of the Sotol Country in Texas,”

elsewhere published, is also printed in vol. 7 of the Transactions of
the Texas Academy of Sciences.

No. 483] NOTES AND LITERATURE 201

For Juliana and Orthopterygium, Mr. Hemsley proposes a new
Order, Julianaceæ, to go between Juglandacee and Cupulifere,—
in The Journal of Botany for November.

Brand describes and figures under the name Trifolium pratense
Joliosum, a glabrous clover recently introduced into American culti-
vation from Orel, Russia. (Bulletin no. 95, Bureau of Plant Industry,
U. S. Department of Agriculture).

A considerable number of new species of the orchid genus Acovi-
dium are described by Ames in the Proceedings of the Biological
Society of Washington of September 25.

The Department of Agriculture in India has begun the publication
of an important series of botanical memoirs, from the Agricultural
Research Institute at Pusa. The three numbers thus far received
refer to “Fungus Diseases of Sugar Cane in Bengal,” “The Hau-
storium of Santalum album,” and “Indian Wheat Rusts.” A fourth
paper, on “Gossypium obtusifolium,” and a fifth, “An Account of
the Genus Pythium and some Chytridiacex,” are also announced.

An account of Crategus, as richly represented in the vieinty of
Albany, has been separately issued by Sargent and Peck from Bulletin
105 of the New York State Museum.

A colored plate of Ribes cruentum is given in Curtis's Botanical
Magazine for November.

The first issue of The Bulletin of the Pictou Academy Scientific
Association contains an account of the Myxomycetes of Pictou County,
Nova Scotia, by C. L. Moore.

Huber publishes a synopsis of 18 recognized species of Hevea in
vol. 4, no. 4, of the Boletim do Museu Goeldi, of Para.

The fondness of cats for Actinidia polygama is re-recorded by Fair-
child in Science of October 19.

Several new Cuban grasses are described by Hackel in the first
Informe Anual de la Estación Central Agronómica de Cuba, issued in
June.

Among other papers on island botany, Supplement 4 of the current
volume of The Philippine Journal of Science contains a list of known
Philippine fungi, by Ricker.

Adams, in The Irish Naturalist for November, notes that a mold
of fermenting hay thrives at an induced temperature as high as 135.5°
F.

202 THE AMERICAN NATURALIST [Vor. XL1

Magnus has separately issued from vol. 21 of the Naturwissen-
schaftliche Rundschau an account of the destructive mushroom para-
site, Mycogone perniciosa.

An exhaustive account of a Sclerotinia-rot of apples is given by
Molz in the Centralblatt für Bakteriologie, etc., Abteilung 2, of October
27.

A study of the influence of selected yeasts upon fermentation, with
reference to cider making, by Moncure, Davidson and Ellett, forms
Bulletin 160 of the Virginia Agricultural Experiment Station.

The Ustilaginales of North America are revised by Clinton in the
recently issued vol. 7, part 1, of “North American Flora,” under the
editorship of Professors Underwood and Britton.

A descriptive account of the economic plants of the world and of
their commercial uses, by Freeman and Chandler, is being issued in
fortnightly parts by Pitman and Sons, of London, under the title
“The World’s Commercial Products.”

Brief descriptions, with 3-color illustrations, of the most noxious
weeds or “proclaimed plants” of Victoria are being published by
Ewart and Tovey in The Journal of the Department of Agriculture of
Victoria.

An illustrated account of the seed of red clover, and its impurities,
by Brown and Hillman, forms Farmers’ Bulletin no. 260, of the U. S.
Department of Agriculture.

Laubert gives an account of Ambrosia artemisiefolia as a German
weed in vol. 35, no. 5, of Landwirtschaftliche Jahrbücher.

Stockberger gives an economic account of Spigelia marilandica and
its surrogates in Bulletin 100, part 5, of the Bureau of Plant Industry,
U. S. Department of Agriculture.

A portrait of Lord Avebury forms the frontispiece to Nature Notes
for October.

An account of the varieties of dates grown in the Figuig region is
being published by Paris in current numbers of the Revue Horticole
de l Algérie.

“Date varieties and date culture in Tunis” is the title of Bulletin
no. 92 of the Bureau of Plant Industry, U. S. Department of Agri-
culture, by Kearney.

No. 483] NOTES AND LITERATURE 203

An illustrated practical guide to judging and selecting corn is given
by Shoesmith in Bulletin no. 139 of the Kansas Agricultural Experi-
ment Station.

An economic account of the cultivation of Agave cantula in the
Philippines is given by Edwards in Farmers’ Bulletin no. 13 of the
Insular Bureau of Agriculture.

Gomolla gives an interesting account of vanilla cultivation and
preparation in Africa, in Der Tropenpflanzer for October.

Chemical studies of Althusa, Grindelia and Pittosporum, by Power
and Tutin, have recently been distributed as papers from the Well-
come Research Laboratories of London.

An interesting account of the use of tree bark etc. for bread making
is given by Dillingham in the recently issued vol. 3, part 5, of the
Bulletin of the Bussey Institution of Harvard University.

Some good root-habit photographs of Ficus are reproduced in
Arboriculture, for October.

Biffen analyzes Mendel’s laws of inheritance with reference to
wheat breeding, and the inheritance of sterility in barley, in the recently
issued Cambridge volume of reprints from vol. 1 of the Journal of
Agricultural Science.

A second edition of De Vries’ “Species and Varieties: their Origin
by Mutation,” corrected and revised under the editorship of Dr.
MacDougal, has been issued by The Open Court Publishing Com-
pany. The frontispiece is an excellent but somewhat informal por-
trait of the author, at work.

Further evidence of the germicidal effects of copper is given, in
official orthography, by Kellerman and Beckwith in Bulletin no. 100,
part 7, of the Bureau of Plant Industry, U. S. Department of Agri-
culture.

Livingston publishes an important study of the relation of desert
plants to soil moisture and to evaporation as Publication no. 50 of The
Carnegie Institution of Washington.

A paper on the effect of tension upon the development of mechanical
tissues in plants, by Ball, is contained in vol. 7 of the Transactions of
the Texas Academy of Science.

From a study of the strength of the bands which Thyridopteryx
fastens about twigs, the results of which are published in vol. 17 of the

204 THE AMERICAN NATURALIST [Vor. XLI

Report of the Missouri Botanical Garden, von Schrenk concludes that
the radial force of twig growth may equal a pressure of 40 or more
atmospheres.

A biographie sketch of C. B. Clarke, with portrait, appears in the
November Journal of Botany.

A short account of the McKinley or Dinkey grove of big-trees is
given by Guthrie in Forestry and Irrigation for October.

The Journals.— Botanical Gazette, November:— Chamberlain,
“The Ovule and Female Gametophyte of Dioon”; Brooks, “Tem-
perature and Toxic Action”; Cook, “The Embryogeny of some Cuban
Nympheeaceee.”’

The Fern Bulletin, October :— Fellows, ‘“ The Fern Flora of Maine’ ;
Gilbert, “ Polypodium vulgare var. alato- multifidum, var. nov.” ; Clute,
“The Genus Oleandra”; Negley, “Where Florida Ferns Grow”;
Palmer, Asplenium eg in Chester Valley, Pa.”; Ferriss, “On
Cultivating our Ferns”; Clute, “Rare Forms of Ferns,—I”; Squires,

“A New Station for Selaginella douglasii”; Puffer, “The Rusty
Woodsia in Cultivation.”

Torreya, December :— Harper, “Some Hitherto Undescribed Out-
crops of Altamaha Grit and their Vegetation”; Berry, “Leaf Rafts
and Fossil Leaves”; Sheldon, “A Rare Uromyces.”

Rhodora, November:— Hitchcock, “ Notes on Grasses”; Blanchard,
“Some Maine Rubi. The Blackberries of the Kennebunks and Wells
— III”; Fernald, “Twelve Additions to the Flora of Rhode Island”;
Leavitt, “Regeneration in the Leaf of Aristolochia sipho”; Fernald,
“ Potamogeton spatheformis a probable Hybrid in Mystic Pond.”

Torreya, November:— Howe, “Some Photographs of the Silk
Cotton Tree (Ceiba pentandra), with Remarks on the Early Records
of its Occurrence in America”; Hill, “A Mississippi Aletris and
Some Associated Plants”; Shafer, “ Hibiscus oculiroseus”; Murrill,
“How Bresadola Became a Mycologist”; Burnham, “A New Species
of Monotropsis”; Blanchard, “A New Dwarf Blackberry.”

Journal of Mycology, November:— Long, “Notes on New or Rare
Species of Ravenelia”; Atkinson, “A New Entoloma from Central
Ohio”; Kellerman, “Fungi Selecti Guatemalenses Exsiccati, Decade
1” [label data]; Morgan, ‘‘North American Species of Lepiota”
(continued); Kelierman, “Index to North American Mycology”
(continued).

No. 483] NOTES AND LITERATURE 205

The Ohio Naturalist, November:— Schaffner, Mabel, ‘The
Embryology of the Shepherd’s Purse”; Hambleton, “Key to the
Families of Ohio Lichens”; McCleery, ‘‘Pubescence and other
External Peculiarities of Ohio Plants.”

The Plant World, October:— Arthur, “ The Paired Seeds of Cockle-
bur”; Tullsen, “The Probable Origin of Key-Fruits”; Parsons,
“Children’s Gardens and Their Value to Teachers of Botany and
Nature Study”; Blumer, ‘Wild Fruits and Shrubs of the Priest
River Valley”; Taylor, “The Germination of the Morning Glory.”

The Bryologist, November:— Fink, “Further Notes on Cladonias
— VIII”; Hagen, “A Study of Tetraplodon australis”; Bailey, “ Van-
couver Island Bryology—.I”; Lorenz, “Notes on the Mosses of
Waterville, N. H.”; erg “Ten Lophozias”; Collins, ‘Notes
on Polytrichum commune.”

Bulletin of the Torrey Botanical Club, October:— Arthur, “New
Species of Uredinee—V”; Harper, “Notes on the Distribution of
some Alabama Plants”; Piper, “Notes on Calochortus.”

Journal of the New York Botanical Garden, November:— Britton,
“Recent Explorations in Jamaica”; Underwood, “Report on the
Condition of the Tropical Laboratory”; Taylor, “Collecting in the
Mountains West of Santiago, Cuba.”

Journal of Mycology, September :— Kellerman, “ A New Plowrightia
from Guatemala”; Arthur, “A New Classification of the Uredinee” ;
Bain and Essary, “A New Anthracnose of Alfalfa and Red Clover” ;
Atkinson, ‘Two New Species belonging to Naucoria and Stropharia” ;
Morgan, “North American Species of Lepiota (continued)”; Hedg-
cock, “Some Wood-Staining Fungi from Various Localities in the
United States”; Kellerman, “Notes from Mycological Literature —
XXI,” and “Index to North American Mycology (continued).”

Of Mr. Elmer’s Leaflets on Philippine Botany the following articles
have been issued:— Elmer, ‘Philippine Rubiacex,” “A Fascicle of
Benguet Figs,” “Additional New Species of Rubiacez,” and “ Pan-
dans of East Leyte”; and Copeland, “A New Polypodium and Two
Varieties.”

(No. 482 was issued February 16, 1907).

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traverse in the time indicated, _ ... vine those topics which are
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It differs from the earlier editio ons of pony “Fle ments” mainly in the
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histological w ork o eed plants,
and in the greatly -n quality of the diuetexsions: Sine changes
ery page.

will be found on almost ev:
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By the natural ee wie of rain d en the pupil first, as Professor won
ecomme! t

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for the k of brevity af
By the treatment of the structures and ‘the functions of plants consecutively, not in
widely separate Teuton of the boo!
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eral effects, mever ag nute ns or struct
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BOTANY NOTEBOOK
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Volume I, containing 616 pages, 5 plates, and 478 text illustrations, and Volum
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CONTE Se OF VOLU HI
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Studies on Seen III. The Sex Differences of the Chromosome-
ao ps in Santee: with Some ee of the Determination of
Edmund B. Wilson
An een of the Effects of Mechanical Shocks and Vibrations Upon the
Rate of Development of Fertilized David D. zen
Morphology of the Parthenogenetie Developm ment of Amphitrite er W. Scott
us. Hetero

u 3
with Appendix on its Develo.ment in Fresh Water. ee R. Stockard
Partial Regeneration of the Sp erm-Receptacle in Crayfish. E. A. Andrews
are a of ae: as a Factor in the Regeneration of tiaras,
Goldfarb

; — June, 1008
Experiments on the Behavior = es Annelids Pe c. W. Hargitt
‘Inheritance of Dickcomatism in Lina and Gastroidea Is sa McCracken
The Elementary Phenomena of Embryonic Development in Chætopterus.
x ei R. Lillie
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Light Reactions in Lower Organisms. i "Stentor Coeruleus. th
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Modifiability in Beha. vior. II. Factors Determining Dioten and Bere
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RE New York

= Tue AMERICAN NATURALIST is an uted monti z 2 :

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THE
AMERICAN NATURALIST

Vor. XLI April, 1907 No. 484

THE GEOGRAPHIC DISTRIBUTION OF CLOSELY
RELATED SPECIES.:

BY ROBERT GREENLEAF LEAVITT.

Tae botanical researches of the members of the New England
Botanical Club are largely taxonomic and floristic. With some
of us this is vocation, with others avocation. The majority per-
haps pursue the study of plants in the field and make collections
of them in herbaria for their own personal satisfaction. Floristic
studies may properly be an end in themselves, whether followed
as a business or only for recreation. In the latter case they
need no further justification than the fine and pure pleasure they
afford to those who love them for themselves. But the results
of these studies, for whatever conscious motive pursued, may have
an application and a destination far beyond our private aims.
Collections of specimens and reports of distribution recorded
in accessible journals by well-informed non-professional as well as
professional botanists, may help materially in answering some of
the largest questions of biological science. In this paper I hope
to make it clear that refined taxonomy and most thorough-going
plant geography may have a direct relation to the enormously
difficult problem of evolution.

Organic geography has, indeed, already served the cause of
evolution,— in aiding to secure general acceptation of the Descent
Theory. Darwin and Wallace, drawing upon the works of tax-
onomers, were able to point to features in the distribution of

1 A paper read before the New England Botanical Club at the meeting of
Feb. 1, 1907. Published as Contribution from the Ames Botanical Laboratory,
no. 6.

207

208 THE AMERICAN NATURALIST [Vor. XLI

species which support the notion of common descent. Plants
and animals, they said, occur upon the surface of the globe just
as if they had originated by evolution, and in a manner unintel-
ligible on the assumption of special creation. Species are uni-
versally found in the neighborhood of other species which they
resemble; or to put this generalization in evolutionary phrase,
species arise in geographic proximity to the species from which
they may be supposed to have sprung. The geographic evidence
was an important part of the testimony accumulated by Darwin
(’59), to which he gives two of the fifteen chapters of the “Origin
of Species.” Wallace (’55) had already published an essay
arguing for the evolutionary conception of organic history, the
main thesis being this: “Every species has come into existence
coincident both in time and space with a pre-existing closely
allied species.” Thus the evolutionist has been under deep
obligation to the taxonomer from the beginning.

The obligation is likely to be much increased with the lapse
of time. I do not agree with D. H. Scott, that the determination
of the actual course of descent is the ultimate, or chief, object
of the scientific systematist.' The fact of evolution being ad-
mitted, and the course of evolution having been ascertained,
there still remains the question, “By what methods have new
forms emerged from old ones?” — a subject not less interesting
or important than the others, from any point of view. It seems
to me, furthermore, that the final goal of phytogeography is not
reached in the reconstruction of the continents and islands of
former epochs, and the reviving of ancient states and changes
of climate, through the study of the history of the vegetation of
the earth; nor is its purpose satisfied in teaching us through
its ecological aspects, that plants are marvellously and multi-
fariously adapted to their environments. Biologically considered,
there is a still more valuable product yet to be yielded by these
sciences. Organic geography will, I believe, unite with syste-
matic botany and zoölogy and with experimental morphology
in composing the solid basis of an adequate theory of evolution.

1 The present Position of Paleozoic Botany, Lotsy’s Progressus Rei Botan-
ice, 1: 139 (1907).

No. 484] CLOSELY RELATED SPECIES 209

The finely discriminative work of modern taxonomers, much
as it confuses and discourages students of other aspects of bio-
logic science, is necessary for several reasons but especially is
it necessary from the point of view of the evolution problem.
Doubtless systematic and experimental work will be more fre-
quently coöperative henceforth, and such studies as those of
Alexis Jordan, de Bary, Rosen and Wittrock will be repeated
with many of the so-called polymorphic plant groups by students
of the greater problem.

This view is apparently opposed to that lately expressed by a
prominent worker in experimental evolution, who seems to deny
this applicability. “The underlying fault,” he says, ‘consists
in the fact that taxonomic and geographic methods are not in
themselves, or conjointly, adequate for the analysis, or solution,
of genetic problems. ‘The inventor did not reach the solution
of the problem of the construction of a typesetting machine by
studying the structure of the printed page, but by actual experi-
mentation with mechanisms, using printed pages only as a record
of his success. Likewise no amount of consideration of fossils,
herbarium specimens, dried skins, skulls, or fish in aleohol may
give any actual proof as to the mechanism and action of heredity
in transmitting qualities and characters from generation to gen-
eration, although from such historical data the general trend
or direction of succession may be traced.” — MacDougal (:06,

Nevertheless, it may be shown that, while such studies are
not in themselves adequate to the solution of genetic problems
they have a very high corrective and evaluatory worth.

Geographic studies founded on an exact taxonomy have a
corrective function. It is axiomatic that no theory having its
origin in experiment can be accepted if it seems to be in funda-
mental discord with what we know of the present disposition
of the organic world. For example, the theory of Mutation as
developed by de Vries cannot be accepted for the animal king-
dom, if, as seems to certain zoölogists, it is irreconcilable with
the facts of the distribution of animals. And even if an hypoth-
esis is not positively excluded by the facts, it may be weakened
or practically nullified by comparison with large bodies of facts

210 THE AMERICAN NATURALIST [Vor. XLI

gathered broadly; so that we may fairly ask the experimental
school to admit that results, however well proved for the condi-
tions established by the experimenter, ought to be assigned little
worth if they find only a trivial correspondence in nature at large.
We make the same demand of the physiologist with respect to
such a phenomenon as geotropism, for instance. ‘The extended
study of this form of irritability has its justification only in the
fact that plants in nature so widely show the effects of geotropism
in their forms; the value of the experimental results is great
because the phenomenon is manifestly widespread in free nature,
being observable in the erect attitude of countless main axes
in field and forest, in the fixed angles of side stems, the vertical
descent of tap-roots, etc., etc. In like manner a true theory of
specific origins should find strong confirmation in the study of
the broadest aspects of plant and animal life. Every grand
agent of specific modification should leave its distinctive mark
upon the character of life as a whole, and if we rightly apprehend
the nature of the agent we may expect to be able to distinguish
its special mark or effect when we know plants and animals
thoroughly. I think that it will appear from considerations
which I now bring before you that the distribution of species
must have peculiarities corresponding to the particular class of
evolutionary forces which have been at work. If this be so, suit-
able studies in geographic taxonomy must possess high evalua-
tory worth when we wish to estimate theories of evolution.

THe EFFECTS oF DIFFERENT EVOLUTIONARY AGENCIES UPON
SPECIFIC DISTRIBUTION

Let us examine the necessary effects of the chief supposed
evolutionary agencies upon the character of specific distribution;
and first contrast Natural Selection in Darwin’s stricter sense
with Mutation, in this regard. Natural Selection works within
specific limits. Its materials are the small, or individual, varia-
tions within the species. By the accumulation of these variations
as they occur from generation to generation new characters are
built up. The change in a species is slow and the whole species
within a given competitive area moves along together. When

No. 484] CLOSELY RELATED SPECIES 211

we consider that sufficient change has occurred to warrant the
epithet ‘new,’ as applied to the condition of the group, we find
that the new species has risen upon stepping stones of its dead
self, since the survival of the fittest has had its converse in the
extinction of the unfit — that is, the ‘old’ species —; and in
the given area only a single new species is found replacing the
vanished old one. For any given area of competition the trans-
forming effect of Natural Selection then, is monotypic. Romanes
(:06, ch. I.) clearly states the truth that Natural Selection with-
out isolation effects monotypic evolution, and only by the aid of
isolating factors of some kind results in polytypic evolution.
Nägeli’s earlier exposition of the monotypic effect of Natural
Selection was explicit (Nägeli, ’73).

On the other hand Mutation breaks the species and momenta-
rily at least, must give a polytypic aspect to the group within a
specific area. The parent species is contemporaneous with the
new species to which it gives rise. ‘The new and the old stand
side by side for a time, without geographic isolation and in general
without isolation of any sort. This is the primary condition.
Subsequently competition may leave only one of the several
original forms in an area. In some instances topographic (eco-
logical) separation of the mutants, or chronal isolation in respect
to flowering or breeding time, a physiological isolation may be
the immediate result of Mutation. But asa rule the first effect
of Mutation must certainly be the allocation of closely related
species, or kinds, in the same area without any sorting or sepa-
ration. :

If we compare Orthogenesis, acting under guidance of the
environment, with Natural Selection on the one hand and Muta-
tion on the other, we see that Orthogenesis must in many respects
agree with Natural Selection rather than with Mutation as con-
cerns the distribution of its products — species. ‘Throughout a
single region of uniform ecological character the effect of environ-
mental moulding, so-called, upon a given organic stock must be
monotypic. But if the ecological conditions are diverse in a
geographic district, as they always are when the surface is varied,
we may expect to find as many kinds of plants or animals derived
from a single stock as there are ecologically different environ-

`

212 THE AMERICAN NATURALIST [Vor. XLi

ments in the district; or, if interbreeding suffices to reduce the
diversity in some degree, at least several kinds perferring different
habitats. While in the broader geographic sense this effect
would be polytypic, in that any geographic district might have
several different closely allied types, each type would fit a partic-
ular set of conditions; there would be definite allotment and
topographical separation of the derivative species, and each
ecological field would present a monotypic aspect. A distribu-
tion quite distinct from that due to recent Mutation would be
found.

Thus while the geography of species may or may not be deci-
sive as between the evolutionary theories known by the names
Natural Selection and Orthogenesis, both these modes are dis-
tinguished from Mutation in the immediate effects which they
have upon distribution. Such specific distribution as Moritz
Wagner asserted to be universal or almost universal, if it could
be proved, would be practically fatal to the Mutation Theory
regarded as a general explanation of specific evolution.’

It is hard to see on what ground the experimentalists can deny
the competence of geographic evidence. Indeed they appear
at times to recognize the propriety of the appeal to nature; De
Vries refers to Draba, Viola and similar groups, and MacDougal
in the paper already cited alludes to studies of plant distribution
and adduces the case of closely related Opuntias in the Arizona
desert. The distinguished zoölogist who recently assumed to
pass upon the merits of the Mutation Theory, evidently without

1 Yet Darwin (Orig. Sp., ch. IV.) in his theory of Divergence of Character,
seems to allow polytypic evolution within an area by means = erage Se-
lection. He thinks geographic isolation unnecessary. Weismann (:04, 2:
338) argues against the necessity of isolation and for a ee condition
as possibly arising by Natural Selection, alleging in support of this view
sexual dimorphism, and polymorphism in species of animals. To which it
may be replied that we do not know whether the diverse forms in the same
species of animals have arisen by Natural Selection. In the absence of evi-
dence, the contention becomes a theoretical one, in which Romanes (’86,
pp. 343, 386), Gulick (’88, pp. 202-206) and Nägeli seem to have the clearer
views, and I have accepted their opinion. Whichever side is taken, it has
to be allowed that a uniformly monotypic geographic distribution excludes Muta-
tion.

No. 484] CLOSELY RELATED SPECIES 213

much knowledge of De Vries’s work and apparently after a read-
ing of only the popular lectures published in this country,’ was
at least thus far right, that he searched for indications of muta-
tion in the distribution of animals. ‘The evidences should be
found even in museums, providing the museums are representative,
and providing mutation is a sufficient explanation of the origin of
species.

THE NECESSITY oF ISOLATION: MENDELIAN INHERITANCE

Before coming to an examination of the facts as they are repre-
sented by writers, it will be well to consider for a moment a the-
oretical side of the subject, namely the supposed necessity of
isolation as a factor in the evolutionary process. Granting that
new forms may appear upon the scene by Mutation, what is to
become of them? How can Mutation be said to originate new
species — that is, stable groups — if through interbreeding the
mutants are at once swallowed up by the parent species with which
they grow commingled? ‘The opponents of the Mutation Theory
hold that the isolation which the experimenter practices in his
garden by means of paper bags, etc., is lacking in nature and
that this difference between the garden and free nature vitiates
the experiments.

The need of isolation is well, and for the present sufficiently,
discussed in the writings of Romanes and Gulick; the latter has
treated every form of isolation in an exhaustive fashion, chiefly
from the theoretical standpoint and upon the basis of the very
limited knowledge of heredity of a few years ago. The conclu-
sion of these authors is that some kind of segregation or isolation
is necessary for the success of a new race. While Wagner (’89)
saw only spatial isolation as giving the needful security, Romanes
(:06) and Gulick (05), have shown, as well as can be shown
deductively, that other forms of isolation may suffice, such as

‘Is it too much to ask ‚that those who undertake to discuss deVries’s
theories shall read his evidence? The lectures in English (Species and Varie-
ties, Chicago, 1905), doubtless serve a useful purpose in popularizing, but
incidentally have done some harm in leading certain critics to suppose that
they may find therein an adequate exposition of principles and evidence.

214 THE AMERICAN NATURALIST [Vor. XLI

difference of breeding time, difference of local habitat, and phy-
siological properties precluding inter-breeding. The clear dis-
cussions of Romanes and Gulick have rendered superfluous
much in recent disputes on Isolation and Evolution.

Lately new conceptions in the theory of heredity have materi-
ally changed the conditions of the argument. Experiment has
shown that new characters may not be immediately swamped
by promiscuous breeding, but may on the contrary, in the fusion
of new and old races, predominate in full force over old characters
which they sometimes have the power of entirely subduing.’
While this result is very suggestive, too little is as yet positively
known to make an extended discussion at all profitable. ‘Those
who are inclined to argue the matter may well take caution from
Davenport’s opinion on the integrity of unit characters. “While
admitting, thus, the reality of unit characters, the further study
of the evidence of hybridization in poultry has led me away from
the conception that they are rigid and immutable as atoms are,
which may be combined and recombined in various ways and
always come out of the process in their pristine purity. This
is by no means the case. Very frequently, if not always, the
character that has been once crossed has been affected by its
opposite with which it was mated and whose place it has taken
in the hybrid. It may be extracted therefrom to use in a new
combination, but it will be found to be altered. ‘This we have
seen to be true for almost every characteristic sufficiently studied
—for the comb form, the nostril form, cerebral hernia, crest,
muff, tail length, vulture hock, foot feathering, foot color, ear
lobe, and both general and special plumage color. Everywhere
unit characters are changed by hybridizing.

“How does this fact bear on the rival theories of evolution?
It has an important bearing on them. It is not in accord with
the statements of de Vries quoted above: ‘The characteristics
of organisms are built up of units that are sharply separable one
from another,’ and ‘Transitions exist between the units as little
as between the molecules.’ Single comb is one unit and pea

1 Besides the Mendelian results see also de Vries (: 03, 2, p. 396 et seq.) on
the crossing of mutants with the parent species.

No. 484] CLOSELY RELATED SPECIES 215

comb is a different unit, but they are not sharply separable. Crest
and no crest are units, but they run into each other in hybridizing.
Unit characters may show transitions, and, if so, they may have
originated gradually, so far as I see. It does not follow that
they must have originated gradually’? — Davenport (:06, p. 80).

Castle and Forbes’s results with guinea pigs indicate the‘
same modifiability of unit characters. These authors (:06, p.
13) say: “From the foregoing observations it is clear that, while
the long-haired and short-haired conditions are sharply alterna-
tive to each other in heredity, the gametes formed by cross-breds
are not in all cases pure. Frequently they consist of a blend
or a mixture of the two alternative conditions, constituting in
effect a new condition intermediate between the other two. A
study of other characters alternative in heredity yields results
somewhat similar.

“ Albinism is, in heredity, the most sharply alternative of char-
acters, yet cross-breeding between albino and pigmented guinea-
pigs may modify the character both of the albino race and of the
pigmented one. ‘This modification may take on a variety of
forms, as has elsewhere been pointed out (Castle, :05). It may
result in the production of mosaics (pigmented animals spotted
with white), or of albinos with a modified peripheral pigmenta-
tion, or of albinos visibly like their ancestors but transmitting a
different set of latent characters. Again, the rough or rosetted
coat of certain races of guinea-pigs is sharply alternative to smooth
coat, yet cross-breeding of rough with smooth races may induce
curious modifications of the rough character or produce smooth
individuals bearing the merest trace of the rough character.

“All these facts are in harmony with the hypothesis, for which
there is strong evidence on the cytological side, that each sepa-
rately heritable character is represented by a different structural
element in the germ (egg or spermatozoon). In fertilization
the paternal and maternal representatives of a character become
more or less closely united, this union persisting through all
subsequent cell-generations until the new individual forms its
sexual elements. At that time the paternal and maternal repre-
sentatives of a character separate from each other and pass into
different cells.

216 THE AMERICAN NATURALIST [Vor. XLI

“But the paternal and maternal representatives of a character
may in the meantime have exercised on each other a considerable
influence. In the case of some characters, as ear-length in rab-
bits (Castle, :05a), they completely blend and intermingle, so
that a new character is produced strietly intermediate between
the conditions found in the respective parents.

“In other cases the modification may be slight, as if the pater-
nal and maternal representatives of a character had been scarcely
more than approximated. Sometimes in cases of alternative
inheritance no influence of the cross is observable in certain of
the ‘extracted’ individuals, but if any considerable number of
individuals is examined, others will be found in which the cross-
breeding manifests its influence. From this we conclude that
gametic purity is not absolute, even in sharply alternative inheri-
tance.”

These are very interesting qualifications of the Mendelian
principle of gametic purity. They suggest that new characters
might be swamped by repeated crossing, unless they were of
such overwhelming importance that they quickly won out in the
struggle for existence, to the immediate extinction of the bearers
of the older alternative characters. However, discussion may
here well wait upon further discovery.

But this may be said: If characters are gradually modifiable,
time becomes a necessary element in experiments on evolution and
possibly long periods of time may be needed for the demonstra-
tion of certain slow natural processes. For the present we may
well hesitate to accept the conclusion that Mutation is the sole
and only possible mode of evolution. Refreshing as the new
method of research is, in the midst of oceans of tiresome specula-
tions, and most valuable and even absolutely indispensable as
the results already are, the latter are certainly small compared
to the bulk of our ignorance regarding morphogenetic processes.
Those who are free from inexpugnable prejudice on the one hand
and from infatuation with new ideas on the other, will look for
some independent means of estimating the probable significance
of the new theories. It is the chief object of this paper to suggest
that such estimation may be rested upon the evidence of organic
geography when the evidence is available in sufficient body.

No. 484] CLOSELY RELATED SPECIES 217

If we were right in what was said above about the specific
effects of different modes of evolution upon distribution, the
first question to be asked of the geographer is this: Are species
universally so distributed that each one occupies a region of its
own, or a habitat of its own; so that even the nearest related
species are strictly separated in space, either in the broad geo-
graphic sense, or at least topographically ?

It is to be noted that the inquiry has two steps, or stages. The
first relates to the distribution of organisms in the broader sense,
and it is inquired whether closely related species are found in
identical districts, or have largely coincident ranges, in many
cases. ‘The adherents of the Mutation Theory expect to find a
considerable proportion of such instances. Certain of its oppo-
nents have believed that the advance of the theory might be blocked
on this first level. But if their efforts fail here they are prepared
to fall back upon the second line of defence. ‘The second stage
of the inquiry relates to topographical distribution, or distribution
in relation to ecological conditions, and asks whether any of the
allocated forms — if some are found — exist side by side with-
out even local segregation. Disciples of de Vries expect that
instances will occur in such numbers as to satisfy the demands
of their theory; while the opposite party thinks that practically
no instances will be discovered giving countenance to the idea
of Mutation. They expect that all cases of general geographic
coincidence of range will be accounted for by ecological segrega-
tion, affording practical isolation; and so hope to withstand the
final assault of the Mutationists.

The application of the botanical evidence presented in this
paper is to the first stage of the inquiry. Some of it is manifestiy
applicable to the second stage also.

SPECIFIC DISTRIBUTION IN THE ANIMAL KINGDOM

We may briefly review some of the chief contributions to our
knowledge of the distribution of animal species. Moritz Wagner,
Professor of Zoölogy in Munich, perceived the close relation
which distribution may have to the problem of evolution and
began to publish upon this subject very shortly after the appear-

218 THE AMERICAN NATURALIST ` [Vo XLI

ance of Darwin’s Origin of Species, first as an advocate of the
theory of Natural Selection, but shortly as its opponent. Through
twenty years of controversy he insisted upon the inadequacy of
Natural Selection, and as the prime factor in the diversification
of species sought to substitute Spatial Separation and to estab-
lish his own Law of Migration and Colony-formation. He sup-
posed a new species to arise by the migration or escape of a single
individual or of a pair from the domain of the old species into
new territory, where in geographic isolation and freedom from
the influence of the old stock a new race might be founded. The
divergence of the race from the old type he supposed to result
(Wagner, ’89, pp. 286-295, 401) (1) from the individual peculiari-
ties of the parental pair or individual, which peculiarities in the
absence of the normalizing influence of interbreeding with the
whole body of the old stock would necessarily become accen-
tuated; and, (2) from the new environment. His theoretical
views, which throughout are questionable, are of less consequence
than the facts which he adduced in their support; the facts indeed
upon which he first formed these views. Wagner himself was a
traveler, observer, and collector in several parts of the world and
continually recurs in his writing to his experience in the field with
regard to endemic, narrowly restricted species-forms and con-
tant local varieties occurring in overwhelming numbers. His
illustrations are drawn from all classes of animals and to some
extent also from plants. He represents specific distribution as
having a strictly mosaic or chain-like character. Everywhere we
find vicarious species and local races in separate habitats. ‘The
facts are presented at great length and with careful detail, and
seem to form a consistent body of knowledge, which impresses one
as being pregnant with a rational principle of wide import.

Mr. C. H. Merriam about a year ago addressed the zoölogical
section of the American Association for the Advancement of
Science on the topie, “Is Mutation a factor in the evolution of
the higher vertebrates ?’— (Merriam, :06). While many of the
arguments and conclusions regarding evolutionary processes be-
long, to my mind, too largely in the conjectural category, and
while this author’s grasp upon the real character of de Vries’s
work and upon his theory seems comparatively feeble, the data

No. 484] CLOSELY RELATED SPECIES 219

of distribution brought forward for several groups of mammals
are valuable. Dr. Merriam considers the geographic relations
of certain American rats, chipmunks, and ground squirrels; and
refers besides to other groups. His representation of specific
distribution agrees with that held by Wagner, with a qualification.
Merriam shows that the mammals in question occupy distinct
areas with very little exception, but that the areas often overlap,
and that the overlaps are likely to constitute narrow transition
zones characterized by the presence of intergrades. Actual phy-
sical barriers are often wanting.

President David Starr Jordan has also discussed the Mutation
question from the standpoint of organic geography and assembled
from his own experience and that of others a considerable body
of evidence regarding birds, while he himself speaks for fishes
(Jordan, :05). His paper, which appeared in Science a little
more than a year ago, contains some extraordinarily sweeping
assertions. He says: “....Moritz Wagner (1868) first made
it clear that geographical isolation (räumliche Sonderung) was a
factor or condition in the formation of every species, race, or
tribe of animal or plant we know on the face of the earth.” The
principles set forth by Wagner “have never been confuted,*
scarcely even attacked, so far as the present writer remembers,
but in the literature of the present day they have been almost
universally ignored.” ‘The question is much discussed whether
minute variations may serve to establish a new species in the
presence of a parent species, or whether wide fluctuation or muta-
tion may do so. “In theory either of these conditions might
exist. In fact both of them are virtually unknown. In nature
a closely related distinct species is not often found quite side by
side with the old. It is simply next to it, geographically or geolog-
ically speaking, and the degree of distinction almost always bears
a relation to the importance or the permanence of the barrier
separating the supposed new stock from the parent stock.” “ The
contention is not that species are occasionally associated with

1 See the works of Darwin (’72), Romanes, Weismann (’72), and fg tin ro
in the Bibliography. Weismann’s paper relying upon the case of Pla
multiformis in the Steinheim chalk should be considered in connection ath
Hyatt’s Memoir on the same form (’80).

220 THE AMERICAN NATURALIST [Vor. XLI

physical barriers, which determine their range, and which have
been factors in their formation. It may be claimed that such
conditions are virtually universal. Ina few cases, a species ranges
widely over the earth, showing little change in varying conditions
and little susceptibility to the results of isolation. In other cases,
there is some possibility that saltations, or suddenly appearing
characters, may give rise to a new species within the territory
already occupied by the parent form. But these cases are so
rare that in ornithology, mammalogy, herpetology, conchology
and entomology, they are treated as negligible quantities. In
the distribution of fishes the same rules hold good, but as the
material for study is relatively far less extensive and less perfectly
preserved than with birds and insects, we have correspondingly
less certainty as to the actual traits of species and subspecies,
and the actual relation of these to the intervening barriers.”

President Jordan summarizes the distribution of species in a
law, as follows: ‘‘Given any species in any region, the nearest
related species is not likely to be found in the same region nor
in a remote region, but in a neighboring district separated from
the first by a barrier of some sort.” That the intent of the law
involves both animal and vegetable kingdoms seems clear from
the context.

President Jordan says that his conclusions, much as they differ
from a priori judgments or the results of experiment, are the
unavoidable outcome of the study of distribution, and that they
are as a matter of fact “accepted as self-evident by every com-
petent — of species or of the geographical distribution of
species.”

nn the facts of animal geography as they appear in these
several essays, typical of a larger number which might be cited,
we may say that as a whole they militate against the operation -
of Mutation in any wide sense in the animal kingdom. ‘This
conclusion is not prompted by the attitude of certain of the zoölo-
gists mentioned, who seem to have made but a cursory study of

In a later note in Science (N. S., 22, p. 873) Pres. Jordan modifies his position
somewhat, as regards the exclusive agency of spatial isolation and the nee
of actual physical barriers; but his representation of specific distribution in
the animal kingdom is not recast.

No. 484] CLOSELY RELATED SPECIES 221

the Mutation Theory, but is drawn from the geographic evidence.
It is, however, true that the evidence is rather scanty. More-
over there are some exceptions to the general law of distribution,
and if these exceptions should, upon further research become
very numerous, the prejudicial force of the law would be much
diminished. But from the evidence at hand we may infer the
very general truth that animal species are distributed according
to Jordan’s law of geographic isolation; that when exceptions
occur, the exceptional species are taken over into some other
category of isolation. The nearly universal patch-work char-
acter of specific chorology — as at present depicted in the works
of zoölogists — strongly suggests the gradual spreading out of
individuals over the surface of the earth, their settlement here
and there in isolated districts or topographically distinct stations,
where shielded from promiscuous intercrossing they have under-
gone transformations, which have been different in the different
areas; transformations which, advancing by whatever forces or
conditions, whether those of Natural Selection or of orthogenesis,
or what-not, have advanced with even front. ‘This suppositious
history is that which forms itself in the imagination of most students
of animal geography and has appealed most strongly to me as I
have reviewed the literature of the subject.

THE DISTRIBUTION OF PLANTS.

Turning now to the vegetable kingdom we find, first, that
there have been few or no exhaustive essays dealing with the
question of specific distribution in relation to the theory of evolu-
tion. In the second place, it may be said at once that when
botanists have turned their attention in this direction their views
` generally do not coincide with those of the zoologists as to the
nature of the facts.

Nägeli (’73) opposed Wagner in a paper of which the purport
is succinctly expressed in the title, “ Die gesellschaftliche Entsteh-
ung neuer Spezies,” — the social origin of new species. ‘This
eminent botanist stoutly opposed Wagner as to the general char-
acter of specific distribution, to the study of which he gave much
time in the field for several years. He calls particular attention

222 THE AMERICAN NATURALIST [Vor. XLI

to the association of species of plants and their varieties upon the
Same ground, and states that when one form replaces another in
consequence of change of ecological conditions within the same
district, the replacing form is not related to the other in the closest
grade of affinity, but in some degree more remote. He clearly
recognizes the intimate relation of distributional studies to the
question of evolution.

There is a little bit of evidence from Wallace (:00, p. 391).
He says he made inquiries of two experienced English botanists
to find whether well-defined varieties occupy areas to the exclusion
of the type and do not occupy the area or only a very small one
with the type. Only one such case was found in England. Wal-
lace’s conclusion is that such varieties of plants occupying consider-
able areas to the exclusion of the type are not common.

Asa Gray (’59, p. 193) expressed the following opinion:
“Whether capable of scientific explanation or not it is certain that
related species of phzenogamous plants are commonly associated
in the same region or are found in comparatively approximate
areas, however large, of similar climate.”

The. case of Draba verna L., is most interesting. As is well
known, about two hundred distinct species, or at least kinds, of
Draba have been distinguished within the limits of the original
Linnean species Draba verna. These numerous forms were
studied in cultivation by A. Jordan, and later by De Bary and
F. Rosen. They are found to come true to seed, and for this
reason are by these authorities spoken of as species. ‘Their geo-
graphic distribution is discussed by both Jordan (’73) and Rosen
(89, p. 613). The conclusion is that as a rule the forms which
resemble each other most are found in the same stations. ‘The
joint occurrence of next related species is indeed a fact which
particularly impressed both of these writers. Rosen thinks that
it is very unlikely that these closely related species originated
separately and by chance came to be associated in the fashion in
which they are now found. Such an explanation might serve, he
says, if one or two cases only were to be explained; but it becomes
absurd when we consider that the concomitance of next related
forms is wide-spread. Rosen ends his account of this group of
Draba species with a very clear statement of the mutative origin

No. 484] CLOSELY RELATED SPECIES 223

which he is obliged to assign to these forms; without, of course,
using the terms of the Mutation Theory, which he partially antici-
pates by several years. “The Erophila [Draba] species owe
their existence to the free variation of their forefathers. This
consists not in a mere heightening or further development of single
characters, but variation fashions new characters and combines
old characters in new ways. Therefore the forms which arise
from species do not intergrade.”’

He says that, while Selection plays no part in the origin of these
forms it operates upon them after they appear. And of the laws
which must control this sort of variation he speaks as follows:
“Variation is not blind, vaguely working in all directions, but is
obviously determined by laws unknown to us: for we are obliged
to assume that the same or similar combinations of next-related
forms have arisen in different places. But what can these laws
be?” It is most interesting and significant that Rosen is led to
these de Vriesian conclusions through floristic and geographic
studies.

The following excerpt from A. Jordan (’73, p. 4) has so direct
a bearing upon our argument that I give it entire: “ Ayant observé
dans leurs stations diverses, pendant plus de trente années, une
foule de végétaux de toutes les familles et de toutes les catégories,
des plantes annuelles ou vivaces, bulbeuses ou aquatiques, des
arbres ou des arbustes, j’ai pu constater presque partout que
lorsqu’un type linnéen, vraiment indigéne dans une contrée, y
était commun à ce point qu’on pouvait le citer parmi les plantes
caracteristiques de la végétation d’une certaine étendue du terri-
toire, ce type y était presque toujours representé par des formes
diverses, plus ou moins nombreuses, croissant en société et pêle-
mêle [ital. mine]. L’observateur superficiel, qui parcourt le terrain,
n’est frappé que des ressemblances de ces diverses formes; il
n’apercoit pas leurs différences, ou, n’y attachant aucune impor-
tance, il ne s’arréte pas à les considérer attentivement; il croit
n’avoir affaire quà un type unique, susceptible de quelques
modifications accidentelles et sans valeur. Tandis que celui
qui observe avec attention peut aisément se convaincre, sur les
lieux, que ces modifications apparentes se retrouvent sur des
individus divers, tous parfaitement semblables entre eux. Si,

224 THE AMERICAN NATURALIST [Vor. XLI

pour pouvoir continuer et completer son observation, il arrache
des pieds vivants de chacune des formes qu’il a pu distinguer
et les replante ensuite, dans un méme lieu, afin de les suivre dans
tous leurs développements, il se convaincra bientôt qu’elles pré-
sentent des différences appréciables, dans tous leurs organes
S’il seme leurs graines, il les verra se reproduire avec une parfaite
identité de caractéres.

“Voila le fait que j’ai pu constater moi-méme mille fois, que
j'ai fait constater dans les lieux que je ne pouvais visiter, en France,
en Corse et en Algérie ou ailleurs, par divers botanists qui m’ont
envoyé soit des graines, soit des pieds vivants de formes nom-
breuses, recueillis dans les mémes station et appartenant aux
memes types linnéens. Je ne dis pas que les plants communes
soient toutes également et partout diversifiées. Il y a, sous ce
rapport, de grandes differences entre elles. Je dis seulement
que le cas oü elles présentent diverses formes croissant en société
est le cas le plus ordinaire [ital. mine], et je crois que ce fait pa-
raitra clair, patent, indiscutable, & quiconque prendra la peine
de le vérifier sérieusement.”

In the literature of this subject, as far as I have read it,
essentially the only writers who insist on the isolation of nearly
related kinds of plants are the zoologists. Their assertions
are not, however, supported by evidence from the vegetable
realm.

I have examined the distribution of North American Orchi-
dacez from the standpoint of this paper. Furthermore, I have
consulted with several specialists in different groups as occasion
offered. Several members of this club have given me information
with permission to publish it along with the evidence gathered
by myself. I may take the groups in sequence.

For Alge, Mr. F. S. Collins speaks as follows in regard to their
general distribution and in particular the distribution of nearest
related species: “As regards fresh water algee, it almost seems
as if geographical limitations did not exist. Of course this is
not entirely true, but the area of distribution in the case of the
great majority of fresh water alge is vastly greater than in the

No. 484] CLOSELY RELATED SPECIES 225

case of most flowering plants.' The limitations seem to be those
of temperature, exposure, character of attachment, and to a less
degree, geological characters. Take the genus Vaucheria, for
instance. ‘The last serious work is by Götz; a study of the species
of Vaucheria in the neighborhood of Basel, Switzerland. There
are 12 species there; 8 of them occur in England, 6 in the New
England States, 7 in California. Only three other fresh water
species are recorded for North America; one is a European species,
found in the West Indies but not elsewhere so far on this continent;
the other two are from California. Now these two species, grow-
ing together, belong to the same subgenus, and I know of no
described species that I should say belonged in between them.
Take the genus Spirogyra. The best book on this is that of
Petit, Spirogyres des Environs de Paris. He includes 37 species;
of these 34 have been found in North America. We have also
five other species; three of them are European, though not found
about Paris; the two others are from Greenland and Florida
respectively. It is much the same with all the fresh water alge;
of the very inconspicuous species, the records from distant stations
are not so abundant, but that is largely because these minute
forms have been little studied outside of Europe.

“As to the marine alge, the difference geographically is much
greater. It would seem strange that marine alge on the two
sides of the Atlantic, should differ much more than the fresh
water alge of the two continents, but such is the fact. Still the
resemblances are much greater than with flowering plants.
And there are many instances where closely allied species or
varieties have practically the same range. I will give a few such
pairs, and in each case there seems to be no species or variety
anywhere else that would stand between the two in question.

“Cladostephus verticillatus and C. spongiosus have the same
range, in temperate waters on both sides of the Atlantic. ‘They
are the only species of the genus in that range. Fucus edentatus
and F. evanescens have their headquarters in high arctic regions,

1 Compare Alph. De Candolle, Geographie Botanique, 1, p. 499: “Nous
arrivons ainsi à une loi importante, savoir que l’aire moyenne des espèces est
d'autant plus petite que la classe dont elles font par ie a une organisation plus
complète, plus développée, ou, selon l’expression usitée, plus parfaite.”

226 THE AMERICAN NATURALIST [Vor. XLI

extending to Great Britain, New Jersey and California. Myrio-
trichia filiformis and M. claveformis have practically the same
range as the Cladostephus species. Ralfsia borneti and R. ver-
rucosa have a slightly more northern range on both sides of the
Atlantic. Phyllophora brodiei and P. membranifolia range from
France and New Jersey to Norway and Labrador. Polysiphonia
violacea and P. fibrillosa from Virginia ‘to Maine, from the Med-
iterranean to Scotland. P. harveyi and P. olneyi are American
species, or possibly varieties of the same species; they have the
same range as P. violacea and P. fibrillosa; wherever I found
one, I should expect to find the other.

“T could keep on for some time in this way, but will give only
one more instance; that is a group of species in the genus Anti-
thamnion, one of the most beautiful of the red alge. On the
European coast A. plumula ranges from Morocco to Great Britain;
A. cruciata about the same; A. floccosa from the English channel
to high arctic regions; A. boreale from the Faroes north; A.
pylaisei from Norway north. On the American coast A. plumula
and A. cruciatum range from New Jersey to Cape Cod; A. floc-
cosum and A. boreale from Cape Cod to Greenland; A. pylaisei
from Long Island Sound to Greenland; A. americanum from
New Jersey to Portland, Maine. On our Pacific coast A. floc-
cosum ranges from California to Alaska; A. boreale from south-
ern Alaska to high arctic regions; A. pylaisei from Washington
north. Now these are all so closely allied that Rosenvinge some
time ago proposed to unite them all under the older name, A.
plumula. He is a man with a strong tendency toward uniting,
it is true, and has since concluded that A. erueiatum, and possibly
A. floccosum are distinct; but at any rate, this shows how closely
allied they are.

“Some things about alge seem very much like supporting the
mutation theory; when the same species occurs in widely distant
stations, we sometimes find with the type exactly the same varie-
ties and forms.”

Dr. Evans, while lacking the opportunity to pay very extended
attention to the subject, has given me the following indication
of the distributional conditions in Hepatice. “One of the best

examples of a cognate pair of species is Leptolejeunea elliptica

No. 484] CLOSELY RELATED SPECIES 227

and L. exocellata. The first of these species is very widely dis-
tributed in tropical America, growing on the upper surface of
thick and glossy leaves. The second species is less abundant
but nearly always occurs mixed with the first.

“Among northern species Lophozia barbata and L. lyoni are
closely related and often grow together, although each retains
its distinctive characteristics. The same is true of Gymnomitrium
concinnatum and the much rarer G. corolloides; of Sphenolobus
exsectus and S. easecteformis; of Anthoceros levis and A. punctatus.

“As a group of related species I might mention the ventricosa-
group of the genus Lophozia. This contains about half a dozen
closely related species, most of which are circumpolar in their
distribution. L. ventricosa, L. alpestris, L. porphyroleuca, L.
longidens and L. confertifolia are all known from New England,
being most abundant in mountainous regions. Of these L. por-
phyroleuca and L. longidens grow on rotten logs, and the others
on moist rocks, although L. longidens is equally at home on either
substratum. Although I have no definite data that these species
actually grow mixed in North America, their ranges coincide to a
greater or less extent with some overlapping.

“Unfortunately our information is not very full at present
about the distribution of many species. Only a few regions have
been at all accurately studied, and I feel sure that further study
would considerably lengthen the short list I have given.”

Mr. A. A. Eaton has given me several examples from Equisetum
and Isoetes. “Equisetum fluviatile is circumboreal in its distri-
bution. No third form stands between this and E. palustre, yet
the latter has practically the same range. E. scirpoides and E.
variegatum are a cognate pair, and yet both have in general the
same range throughout the northern part of both hemispheres.
E. variegatum has a variety, E. variegatum jessupi, distinguished
by anatomical characters. Its range, Vermont to Minnesota,
is quite covered by that of the species. E. lævigatum has a near
relation, without an intermediate, in E. hiemale intermedium,
and this on the other side is next to the variety affine. The last
of the trio is wide-spread in northern North America and overlies
the other varieties, which also essentially coincide in their ranges.
_ E. arvense is found in Europe, Asia, N. America to Virginia and

228 THE AMERICAN NATURALIST [Vor. XLI

southern California. Its near of kin (without intermediate), E.
telmateia, is found with it (broadly speaking) in Europe and
California. Starting with E. pratense a next-related species is
E. sylvaticum. 'The former belongs to northern Europe, Siberia,
Alaska, Canada, the Rocky Mountains, Labrador, and south-
ward to Massachusetts and New Jersey. ‘The other is circum-
boreal, covers the range of the first and with us goes somewhat
further south to Virginia.

“In Isoetes we find the following coincident ranges of close
relatives. Isoetes tuckermanni is found quite plentifully in New
England and completely overlies the range of its varieties harveyi
and borealis. I. Engelmanni is found plentifully throughout the
region east of the Appalachian range, from New Hampshire and
Vermont to Pennsylvania, extending sparingly to Georgia. It
overlies the ranges of its varieties caroliniana, fontana and valida.
I. canadensis is found from Pennsylvania to Maine and Quebec,
appearing again in British Columbia. Its next of kin in the genus
is I. engelmanni, whose range for the most part it covers, and the
two species are not rarely found commingled in the same pond.
I. bolanderi is found from Wyoming to California and Washing-
ton. Its next of kin would appear to be J. pygmea of the Mono
Lake region of California, and the two species were found by
members of the King Expedition in contiguous areas. It may
be supposed that I. pygmea is an abnormal form of I. bolanderi
and hence not competent in this relation, but the next of kin of
bolanderi is I. echinospora var. braunii, which overlies the range
of bolanderi, but is widely distributed otherwise in North America.”

I have inquired of President Brainerd about the conditions in
Viola, and particularly whether pairs of closely related species
are found within the same ranges. He answers: “ Many pairs
of species in Viola closely allied and nearly co-extensive in range
are to be found.” He mentions six of them; viz. (1) V. fimbriatula
and sagitata, (2) V. palmata and papilionacea, (3) V. septemloba
and emarginata, (4) V. lanceolata and primulefolia, (5) V.
ranifolia and incognita, (6) V. arenaria and conspersa. ‘These
are without intermediate species says President Brainerd, but they
- have intermediates resulting from hybridization, found in the
- same localities with the species.

No. 484] CLOSELY RELATED SPECIES 229

To Professor Charles Sprague Sargent I am indebted for inter-
esting information as to the distribution of North American
Crategus. As is well known, numerous species have been dis-
tinguished within the last few years, of which some five hundred
have been named. ‘These species are readily and unmistakably
recognized by special students of the genus, by means of floral
characters such as number of stamens, color of anthers, form of
inflorescence, etc.; by fruit characters, configuration of nutlet,
time of blooming and fruiting, character of foliage, veining, pres-
ence or absence of hairs, etc.; traits which appear to be constant
and reliable as shown by extended observation in the field and
by cultures of seedlings carried on now for a number of years at
the Arnold Arboretum. In these cultures, the sowings from the
several species result in crops of seedlings of remarkable uni-
formity within the limits of each species, and in the instances in
which the seedlings have flowered and fruited, of notable con-
formity to parental type. This result must certainly diminish
the scepticism with which the proposal of such a vast number of
species within the one genus has rather naturally been met in some
quarters.

In answer to the question whether the nearest related species
are separated, as the law of D. S. Jordan and of Wagner would
require, Professor Sargent replies in the negative.

In the genus as it is represented in North America several
groups are distinguished, which in part correspond to the species
of the older writers, and which may be readily recognized by
anyone with a little attention’ such are Crus-galli, Punctate,
Astivales, Tenuifoliz, Pruinosz, Intricate, Flabellate, Anomale,
Molles, Tomentosz, etc. These groups are in general fairly
-well restricted to particular geographic sections. For example,
the Tenuifoliz, the largest group in the northeast, do not extend
west of the Mississippi river, or go southward except along the
mountains. The Flave are found only in the southeast. The
Intricate are most numerous in eastern Pennsylvania, extending
along the mountains southward to the end of the Alleghanies,
northward into Vermont, and westward through New York and
Ontario to southern Michigan, within which distributional area they
mingle with all the other northern groups. In some cases a group

230 THE AMERICAN NATURALIST [Vor. XLI

predominates in a region, in other regions several groups are
nearly equally represented. Within each group, divisions can
be made; but in the case of these divisions geographic sepa-
ration does not obtain, since species of all the divisions of a group
are likely to occur in any part of the general territory proper to
the whole group. Regarding the ultimate units, or species, those
which are most closely allied are likely to be found promiscuously
associated in the same distriet and without the semblance of isola-
tion. For example species of the Pruinos® or of the Intricatse
with 10, or with 20 stamens, or with rose-colored, or with yellow
anthers are found growing within a few feet of one another, and
may cover common districts of several hundred square miles.
In these cases, while it is the number of stamens or color of anther
which first attracts attention, other specific characters exist which
adequately distinguish the species. As an example of promiscuous
association, the vicinity of Albany may be pointed out, where
the five species of Intricate heretofore found in New York state
grow in a small area. In Ontario we find twenty-five species of
Tomentose, many of them growing very close together. In the
distinctly southern group Microcarpe we find the two species,
C. apiijolia and C. spathulata, growing over the same areas, while
the third and more distantly related species, C. cordata has a some-
what more northern range. In general, the reverse of Jordan’s
law would more nearly represent the distribution of American
species of Crategus.

Coming now to Orchidacez, I may say that I adopted the line
of examination suggested by the form of Jordan’s law; that is,
I looked for pairs of kinds. I say kinds instead of species in-
tentionally. The main problem should not be confused by the
difficulty of agreeing upon a definition of species. What the evo-
lutionist has to account for is not the definitions of systematists,
but the multiplicity of hereditary types; he has to explain the
antithesis between the uniformity which heredity seems at first
to promise, and the diversity which actually prevails among
organic things. A definition of species is demanded in taxonomy,
but is somewhat less necessary in studies like the present. We
do not require that the forms be related in some particular taxo-
nomic sense; but only that they have different hereditary charac-

No. 484] CLOSELY RELATED SPECIES 231

ters. In order to avoid complications I have used the word kind
to designate such different types, instead of the words species,
variety, etc., which have restricted technical senses. -

I have sought for closely related pairs of kinds so made up that
in each case no third kind stands between the members of the
pair in resemblance. Such pairs I may call immediately cognate
pairs, or for short, cognate pairs. A pair may consist of two
species, two varieties, two subspecies, a species and a subspecies,
a species and a variety, etc. It is assumed that such cognate
pairs represent recent forkings of the phylogenetic tree; and that
if we could collect all such cognate pairs in the vegetable kingdom
we should have a representation of all the youngest forkings.
Evidently their distribution would be very illuminating, for the
youngest branches are on the average the least disturbed geo-
graphically, and the distribution of the members of these pairs
would represent as accurately as we could ever discover it, the
position of things at the moment when forking takes place. ‘That
is, we should have a geographic chart, more or less distorted it
is true, of the origin of kinds. If the members of the pairs are
universally, in the vegetable kingdom, separated from each other,
then — as already explained — Mutation is excluded as a true
cause of diversification of hereditary types in plants. For among
several forms of isolation to which Mutation may conceivably
give rise, and which are, therefore, not inconsistent with the mu-
tational assumption, the one form of isolation to which it could
never give rise is geographic isolation.

I repeat that I have examined only the broad geographical
aspect of distribution and not at all the topographical, for which
exact data are wanting. Let the reader recall the two stages of
this general inquiry: my evidence belongs to the first of these.
I present the following facts as a contribution towards an answer
to the question, Is Mutation instantly excluded from a place among
the considerable powers in evolution, by the broad aspects of specific
distribution in plants? I have taken only one step. But this
may be of some little importance, especially in view of the asser-
tions concerning the distribution of plants which have been made,
and in view of the lack of even broadly geographical statistics.

232 THE AMERICAN NATURALIST [Vor. XLI

EVIDENCE FROM THE FAMILY ORCHIDACEX IN NORTH AMERICA

The American Habenarias have been given careful study in
our laboratory. In addition to our own collections, those from
several of the largest herbaria in the United States have been
brought together. ‘The species have been delimited with minute
attention and then the distribution of each species, represented
by the large amount of material assembled, has been recorded.
Thus exceptionally full and reliable returns have been secured,
which are available for the present paper.

H. ciliaris R. Br., and H. blephariglottis Torr., are a pair of
perfectly distinct, yet extremely similar species. While instantly
distinguishable in the field by their colors — the flowers of the
former being yellow or orange, those of H. blephariglottis pure
white — the dried specimens are separated only upon close inspec-
tion. The best distinguishing character is then the degree of
fimbriation of the lip, which is considerably greater in H. ciliaris
than in H. blephariglottis. No third species stands between
them. ‘They are spread together through the eastern United
States. H. ciliaris is found in Massachusetts, Connecticut, New
York, Ontario, Michigan, New Jersey, Pennsylvania, Ohio,
Indiana, Delaware, Maryland, District of Columbia, Virginia,
Kentucky, North Carolina, Tennessee, Missouri, Arkansas, S.
Carolina, Georgia, Florida, Alabama, Mississippi, Louisiana,
Texas. H. blephariglottis is found in Newfoundland, Nova
Scotia, New Brunswick, all New England, New York, Ontario,
Michigan, New Jersey, Pennsylvania, Ohio, Virginia and North
Carolina; and if we include the southern form which may possibly
be distinguished, the range is extended to South Carolina, Georgia,
Alabama, and Mississippi. Whether we allow that the southern
form is distinct or not is immaterial, since it does not stand between
H. blephariglottis and H. ciliaris, and the latter species covers the
range of both the northern and the southern forms of the other.

H. cristata R. Br., H. chapmanii Ames, and H. ciliaris R.
Br., form a group of very closely related kinds. H. cristata is
like a very small H. ciliaris, with a broader and un-clawed lip,
petals oblong or somewhat obovate instead of linear, and a spur

No. 484] CLOSELY RELATED SPECIES 233

shorter than the ovary instead of longer. H. chapmanii is inter-
mediate between the others in perhaps every respect, and this fact,
with the absence of any new character of its own, makes this
species appear very like a hybrid. Its apparently local occur-
rence is in favor of hybridity. But allowing it to be independent,
it forms a pair with H. cristata on one side, and with H. ciliaris
on the other. On the other hand, removing the plants now
grouped as H. chapmanii, because of suspected hybrid origin,
we have left a very close pair in the two supposed parental types.
On any disposition of the matter, the geographical ranges of the
three kinds are found to coincide widely. The range of H.
ciliaris, as above shown, extends from New England to middle
Florida and Texas, and inland to Michigan, Missouri and Arkan-
sas. That of H. cristata includes all the Atlantic states from
New Jersey to Louisiana, with Pennsylvania, Tennessee and
Arkansas added. Specimens of H. chapmani have been seen
only from northern Florida.

Habenaria psycodes Gray, and H. eudeiuta R. Br. are a very
close pair, with no intermediary. ‘They are with some difficulty
distinguished, yet statistical studies that I made upon them some
time since convinced me that authors, including the most reliable
authorities, are right in considering them specifically distinct.
No one character can be relied upon to separate them invariably
but all characters of each species fluctuate, so that any given
part in one may run into the form characteristic of the other species.
The balance of characters, however, is almost always decisive.
The geographic ranges are very largely the same. Both are
found in Newfoundland, Nova Scotia, New Brunswick, Quebec,
all New England, New York, New Jersey, Pennsylvania, and
North Carolina. H. psycodes extends further west, and H.
fimbriata a little further south, as represented in the collections
before me.

H. peramena Gray, has for its probably nearest relative H.
fimbriata — or possibly H. psycodes — with no species between.
The three species mentioned, with H. leucophea, form a group of
close affinity. While H. peramena is more widely. distributed
westward and southward (Ill., Mo., Ala.), and H. fimbriata much
further northward, they occupy extensive territory together; viz.,

234 THE AMERICAN NATURALIST [Vor. XLI

Pennsylvania, West Virginia, North Carolina, and Tennessee.
If H. psycodes is substituted for H. fimbriata in the comparison,
the geographic result has the same influence on the discussion.

H. orbiculata Torr. and H. macrophylla Goldie are so close
that the plants of the two kinds have long been accepted by col-
lectors and described by authors as of one species. The differ-
ences are at first sight slight, but are apparently constant and
sufficient for distinction. The former species has a much greater
range, which completely covers that of the latter. H. orbiculata
extends from Labrador and Newfoundland westward through
Michigan, and Minnesota, to British Columbia and Washington;
and southward through New England, New York, and Pennsyl-
vania to South Carolina and Tennessee. It is found in every
district where H. macrophylla is found; viz., Newfoundland,
New Brunswick, Ontario, Michigan, New England, and New
York. The status of these two species is discussed by Ames in

Rhodora for January, 1906, with illustrations of the flowers.
` The difficult genus Spiranthes has lately been thoroughly
studied by Ames, who has given the results in Orchidacez, Fasc.
I, pp. 113-154. The abundance of material examined may be
seen from the citations of specimens in the detailed statement of
the distribution of each species.

S. cernua Rich. has for nearest allies, first, the variety (which
some authors regard as a species), S. cernua var. ochroleuca Ames,
and secondly the species S. odorata Lindl. S. cernua may be paired
with either of them. S. cernua and S. cernua orchroleuca in the
dried state can be separated with certainty by no macroscopic
character. They may be distinguished by the seeds, however,
S. cernua being polyembryonie.! Unfruited specimens being
indistinguishable in the dry state, the exact distribution of each
form may not be very precisely defined, but Rydberg in Britton’s
Manual gives the range of var. ochroleuca as from New Hampshire
and Massachusetts to Pennsylvania and North Carolina. I
myself have identified, as being unmistakably typical S. cernua,
ae from Massachusetts, Ontario, Iowa, and Georgia.

my notes on the embryology of the two forms in Rhodora 2, p. 227
es and shy p. 61 (1901). In S. cernua embryo formation takes place without
llinatio

No. 484] CLOSELY RELATED SPECIES 235

Thus the range of the species overlies that of the variety. Geo-
graphic isolation is wanting.

When we compare S. cernua with S. odorata we find again a
very strong likeness. S. odorata is usually much larger in all
parts than the former. The length of the scape relative to
that of the leaves is greater in S. odorata, and its leaves are less
strictly radical. ‘Those not expert in the genus Spiranthes would
often distinguish the two species with difficulty. They might be
regarded as elementary species in de Vries’s sense. S. odorata
has been found in Virginia, Georgia, Florida, Alabama, Louisiana,
and ‘Texas, and its range thus coincides widely with that of S.
cernua.

S. romanzoffiana Cham. and S. porrifolia Lindl. are very closely
related species, which no other species approaches. 'The former
is by very much the more widely dispersed, since it crosses the
continent, while S. porrifolia is confined — according to speci-
mens seen — within the states of Washington, Oregon, and
California. S. romanzoffiana is represented in our records by
many specimens from these same states, and there is therefore no
general geographic separation in this case.

S. laciniata Ames and 8S. vernalis Engelm. and Gray are ex-
tremely similar but distinct species. The former is confined to
Georgia, Florida, Alabama, Louisiana and Texas. 8. vernalis
occurs in all these states, but reaches far beyond this area.

S. beckii Lindl. and S. gracilis Beck are an immediately cognate
pair of near affinity. The former grows in the Atlantic states
from Massachusetts to Texas. S. gracilis covers the same range,
but is also to be found further north and further inland. ‘There
is no geographic isolation.

Cypripedium pubescens Willd. and C. parviflorum Salisb. have
had attention at this laboratory for several years, observations
having been made in the field and in the herbarium, and collec-
tions of dried specimens having been received from many sources.
Measurements indicate that there are two pronounced tendencies
as regards size of flower. In life, the plants generally have an
appearance of distinctness, and most field naturalists whose
opinions have been asked, have maintained that the two kinds are
specifically different. The manuals treat them so. Yet they

236. THE AMERICAN NATURALIST (Vou XLi

occasionally intergrade and perhaps can be regarded merely as
subspecies. I have found them growing together in closest
proximity. We have specimens of C. parviflorum from Ontario,
British Columbia, New England, New York, New Jersey, Penn-
sylvania, Ohio, Indiana, Michigan, Wisconsin, Washington;
and of C. pubescens from New England, New York, Pennsylvania,
Ohio, Illinois, Wisconsin and Minnesota. ‘The manuals extend
the reported occurrence of both plants to Georgia. Thus the
ranges of these two very closely allied kinds coincide over a very
wide extent of territory. No other form in the world stands
between them.

The genus Calopogon is confined to the eastern half of the
United States (if we except the occurrence of C. pulchellus in
Cuba), and comprises four close species and a variety, or five
species. ‘These species all come together and overlap in Florida.
One, C. pulchellus R. Br., ranges from Newfoundland to Florida,
Cuba, and Missouri, and geographically includes all the rest. C.
pallidus Chapm. ranges from North Carolina to Florida and
Alabama; C. parviflorus Lindl. from North Carolina to Florida;
©. multiflorus Lindl. is confined to Florida. Here, therefore, are
several pairs of cognate species not geographically separated.

Pogonia verticillata Nutt. and P. affinis Austin make a pair
of very nearly related yet distinct species. The former extends
from New England to Florida and west to Wisconsin and quite
surrounds the other, a very rare species occurring sporadically
in Vermont, Massachusetts, Connecticut, New York and New
Jersey. Here again geographic isolation is wanting.

The conclusion from this examination of North American
Orchidacez is that cognate pairs of kinds with uniform or widely
coincident ranges are too numerous to leave any force at all in
Jordan’s law in its broad sense as regards this family in our flora.
If one member of each pair was derived from the other member,
or both were derived from a parent species, then, as far as the
geographic evidence goes, the new species may have originated
in the same district with the old one; i. e. without geographic isola-
tion.

No. 484] CLOSELY RELATED SPECIES 237

CONCLUDING REMARKS.

In concluding this paper I may make some remarks of a general
character touching the whole problem.

First, we note that zoologists and botanists are rather distinctly
opposed to each other in their views of the actual state of specific
distribution. ‘The suggestion is offered that zoologists may best
discover the condition and interpret its meaning among animals,
and botanists among plants. In no case is it safe to reason deduc-
tively from one kingdom to the other. In the factors affecting
their evolution plants and animals differ vastly.

Secondly, in seeking for the laws of specific distribution we
should first take the facts as we find them. We should agree
to consider that in the absence of explicit evidence to the contrary,
kinds now found in coincident ranges have been so situated from
the beginning. In any given cases this assumption may or may
not represent the truth, but we have no right to postulate move-
ments in the past, of which there is no certain evidence, in order
to save a preconceived theory. We may call such hypothetical
migrations into being, in a strictly limited number of cases, upon
a reconsideration, if from a first examination of the unmodified
facts some law emerges so strong and compulsory that the few
exceptional instances must somehow be brought into accord with
it.

In the third place, if I may express my personal impression of
the matter with regard to plants, it seems to me that the study of
specific distribution in the vegetable kingdom is not likely to be
unfavorable to Mutation, regarded as a method, but perhaps
not the sole method, of evolution. It is true that in examining
the distribution of species of plants, one encounters an effect
which seems to be connected with geographical distance. We often
find that a species of wide distribution exhibits slightly different
phases in different divisions of its range. ‘These phases are some-
times too subtle for definition and pass into one another by degrees,
yet are evident to students of particular groups. Such cases do
not look like the work of Mutation. They exemplify that which,
to conceal ignorance of causes, may be termed a geographic effect.

238 THE AMERICAN NATURALIST [Vor. XLI

But this aside, the indications seem to me to be that a good many
instances sustaining the notion of mutative origin will be found
among plants. It is not to be expected that the number of such
cases will be relatively large. On the assumption of periodie
Mutation as the origin of species, with competition between
associated mutants and the survival of those mutants best fitted
for existence in the original habitat, and the spread of mutants
with new capacities into areas or habitats not open to the parental
species, we should expect to find as a rule a single species occupy-
ing a given territory or ecological footing, and related species in
separate, neighboring areas or habitats; though it is evident
that mutants instantly endowed by Mutation with physiological
or chronal isolation might continue to exist side by side with the
parental species or with sister mutants if there were no active
vegetative competition between the associated stocks. As a
matter of fact, in many species of plants competition for sub-
sistence between individuals of the same parentage is practically
absent. Unification of congenital mutants may be brought about
by continued interbreeding. ‘This would eventually destroy the
geographic evidence of Mutation in any given case. But in such
amalgamation the effects of Mutation may not be destroyed; for
new characters may during amalgamation be perpetuated in full
force. It is single characters, rather than constellations of charac-
ters, with which the Mutation Theory is primarily concerned
The number of cases of association of closely related species
resembling recent mutants, in proportion to the number of cases
of geographic or topographic segregation of closely related species
would depend upon the balance between the activity of Mutation
on the one hand and the operation of the forces tending to isolate
or to amalgamate the products of Mutation on the other. If
mutative periods are far apart in most species — and stability
of the organic world may preclude great frequence — while the
segregating or amalgamating powers are constantly at work,
then the occurrence of the social condition indicative of Mutation
may be expected to be relatively infrequent.

In order to use geographical evidence effectively against the
Mutation Theory, its opponents must show that the social con-
dition of closely related forms is, to use President Jordan’s words,

No. 484] CLOSELY RELATED SPECIES 239

“virtually unknown.” In the vegetable kingdom this is likely
to be an arduous task. The indications are that the adherents
of Mutation will be able to bring forward enough cases of social
distribution to render phytogeographic weapons useless in the
attack upon this Theory.

THE Ames BOTANICAL LABORATORY,
Norta Easton, Mass.

LITERATURE

CASTLE, W. E., AND FORBES, ALEXANDER.

1906. Heredity of Hair-length in Guinea-pigs and its bearing on the
theory -of pure gametes. Published by the Carnegie Institution
of Washington, D. C.

DARWIN, CHARLES.

1859. The Origin of Species, apra 11 and 12, on Geographical
Distribution.

1872. The Origin of Species, 6th Edition, wer 4, as far as it relates
to Isolation and to Divergence of Characte

Davenport, C. B.
1906. Inheritance in i Pauley Published by the Carnegie Institution
of Washington, D. C.
De Vaiss, H.
1903. Die Mutationstheorie, 2, pp. 396-457 (dieMutationskreuzungen). |
GvuLick, Rev. J. T.

1887. Divergent evolution u cumulative segregation. Jour.
Linn. Soc., Zool., 20, p. 1

1905. Kouan, Fan and Aue ay Published by the Carnegie
Institution of Washington, D.

HYATT, ALPHEUS.

1880. The genesis of the tertiary species of Planorbis at Steinheim.

Anniversary Mem. Boston Soc. Nat. Hist. 1880.
JORDAN, ALEXIS.

1873. Remarques sur le fait de lexistence en société, a l’état sauvage
des espèces végétales affines et sur d’autres faits relatifs a la
question de Vespéce. Lyon, Pitrat Ainé (pp. 23).

JORDAN, PRESIDENT DAVID STARR.

1 The Origin of species through isolation. Science, N. S., 22,
p. 545. In the same volume, p. 873, appears a note modifying
some statements of the above paper.

240 THE AMERICAN NATURALIST [Vor. XLI

MacDovaat, D. T

1906. Discontinuous variations in pedigree cultures. Pop. Sci.
Monthly, Sept., 1906.

>~ Merriam, C. Harr.

1906. Is Mutation a factor in the evolution of the higher vertebrates?
Proc. A. A. A. S., New Orleans, 1906, p. 383. Also Science, N. S.,
23, p. 241 (1906).

Nacer, C.
1873. Die gesellschaftliche Entstehung neuer Spezies. Sitzungsb.
d. math.-phys. Klasse d. k. b. Akad. München, 3, p. 305 (1872-3).
Romanes, G. J.
1886. Physiological Selection. Jour. Linn. Soc., Zool., 19, p. 337.
~ 1906. Darwin and after Darwin. Vol. 3, Isolation and physiological
selection. Opinions on isolation [with clues to valuable data of
distribution]. The appendices contain important matter.
Rosen, F.

1889. Systematische und biologische Beobachtungen über Erophila

[Draba] verna. Bot. Zeit., 47, pp. 565, 581, 597, 613.
WAGNER, MORITZ.

1889. Die Entstehung der.Arten durch räumliche Sonderung. Gesam-
melte Aufsätze. Basel. This edition contains the following pa-
pers of importance: Die Darwin’sche Theorie und das Migra-
tionsgesetz der Organismen. Leipzig, 1868.— Ueber den Einfluss
der geographischen Isolirung und Kolonienbildung auf die morph-
ologischen Veränderung der Organism. München, 1870, Sitzungsb.
d. k. bayer. Akad. Wiss. 2 July (1870).— Ueber die Entstehung
der Arten durch Absonderung. Kosmos, Hfe. 1, 2, 3, (1880).—
Darwinistiche Streitfragen [5 papers]. Kosmos (1882, 1884).

WALLACE, ALFRED RUSSELL
On the law which his regulated the introduction of new species.
Annals and Magazine of Nat. History, September, 1855. Also
in his Contributions to Natural Selection, London, 1875, p. 5.
1900. Studies, scientific and social, 2, p. 391.
WEISMANN, AUGUST.

1872. Ueber den Einfluss der Isolirung auf die Artbildung. Leipzig,
Engelmann.

1904. The Evolution Theory. Tr. by Thomson. London, E.
Arnold. Vol. 2, ch. 32, Influence of isolation on the formation
of species. Also 2, p. 350.

THE COINCIDENT DISTRIBUTION OF RELATED
SPECIES OF PELAGIC ORGANISMS AS ILLUS-
TRATED BY THE CHETOGNATHA.

CHARLES ATWOOD KOFOID

No small part of the diversification of the organic world has
taken place in the open sea. Whether we accept the view that the
littoral and abyssal faunas are derivatives of the pelagic, or regard
the latter as secondarily derived along many lines from the organ-
isms of the shore and bottom, the fact remains that many groups
have undergone great diversification both in the specific and in
higher categories in the pelagic habitat. Illustrations of this
process are to be found in the diatoms, the Protozoa (notably
the Foraminifera, Radiolaria, Dinoflagellata and Tintinnoina),
in the Scyphomeduse, Siphonophora, and Ctenophora, Ostra-
coda, Schizopoda, Amphipoda, Decapoda, Heteropoda, Ptero-
poda, Cephalopoda, and Tunicata and certain families of fishes.
The Nemertini, Annelida, Rotifera, Holothuroidea and the Hem-
iptera are sparingly represented. One class, the Cheetognatha,
are exclusively marine and pelagic, and their affinities are with
the more primitive types of invertebrates. It seems probable
that their entire evolution, or at least their generic and specific
differentiation has taken place in the marine habitat. Their
present distribution is therefore of prime interest because of its .
bearing on the relation of isolation to the origin and preservation
of species.

Barriers are far less in evidence in the environment of the pelagic
fauna than in that of the shore or of the land. A few instances in
limited regions along the margins of great ocean currents as, for
example, along the edges of the Gulf Stream or in horizontally
stratified waters, there are abrupt transitions in temperature,
but in the main the changes in temperature, illumination, density,
and substances in solution or suspension, are so gradual that
zoological provinces are delimited with difficulty and mainly in
terms of temperature, on the high seas away from the influence of

241

242 THE AMERICAN NATURALIST [Vor. XLI

shore conditions. In a large and somewhat vague way isotherms
and isothermobaths constitute the barriers of the sea. Many,
and in some groups, most of the pelagic species are wide-ranging,
found in most seas, through a greater or less range of temperature.
The pelagic fauna has thus a considerable cosmopolitan element
and part of the differences which result in the contrasted poverty
and richness of pelagic fauna are due to changes in the numbers
of individuals and in the proportionate representation of the
various components, as much as, or even more, than to restrictions
in the distribution of species. In so far as the species of any group
of related organisms establish themselves throughout a wide,
coincident or overlapping range, in like degree isolation becomes
problematical as a factor in the origin of new or preservation of
old species.

Our knowledge of the horizontal and vertical distribution of
pelagic organisms is lamentably incomplete and partial, and no
less so of the Chetognatha than of other groups. Fowler (:06)
calls attention to the fact that he finds no published record of a
single species of that group between 160° E and 80° W, nearly the
whole of the Pacific Ocean! Unfortunately no report was pub-
lished on the Chetognatha of the Challenger Expedition and
the results of later surveys have not yet appeared. We find,
however, an excellent summary of the known distribution in
Fowler’s (:06) report on the ‘Siboga’ collections, based largely
on his Biscayan investigations, Fowler (:05), and the work of
Doncaster (:03) on the Maldive and Laccadive fauna, of Aida
(’97) on that of Japanese waters, of Steinhaus (’96) and Strodt-
mann (92) on collections from the Atlantic, and of various re-
corders in the lists of the Conseil permanent pour l’ exploration
de la Mer, from the waters of Northern Europe. The data thus
assembled by one whose critical knowledge of the species has
enabled him to sift out synonyms and eliminate probable errors,
are far from being adequate to give a complete or satisfactory pre-
sentation of the distribution of Cheetognatha in the seas named.
They are, nevertheless, of sufficient fulness to afford a basis for
the consideration of the extent to which isolation of species prevails
in this typical pelagic group of organisms and to mark out clearly
the necessity for additional data on vertical distribution and
breeding seasons for a critical and final analysis of the problem.

No. 484] DISTRIBUTION OF CHETOGNATHS 243

It is the purpose of the present note to call attention to the
important contributions which investigators of pelagic life might
make to the discussion of this phase of the problems of evolution
especially since monographers of pelagic groups are best qualified
to judge of the degrees of affinity between the species of the genus
and can determine whether the most closely related ones have a
coincident or contiguous distribution. It is exceedingly desirable
that future expeditions investigating the life of the high seas be
equipped for a fuller analysis of the details of vertical distribution
and that data on breeding seasons of pelagic species be included
in monographs whenever available.

GENUS KROHNIA

This genus includes three species, K. hamata, K. subtilis, and
K. pacifica. ‘The first are two oceanic species of wide distribution,
the last an Indo-Austral species of surface neritic distribution.
The horizontal area of distribution of the first two species is largely
coincident, K. hamata being known to extend to higher latitudes
(81° N., 52° S.) than K. subtilis (60° N., 29° S.). As might be
expected from its temperature relations, K. hamata is recorded
from lower levels in the tropics than is K. subtilis. Data on this
point are not very complete as K. subtilis is not an abundant
= species. The closing net catches of the Plankton Expedition
indicate a maximum depth of 1500 m. for K. hamata and 850 m.
for K. subtilis. The two occur together between 300 and 500 m.
(37° N). The extent to which the vertical distribution of the
two species overlaps cannot be determined from the available
data. Fowler (:05) shows that the size of the individual of K.
hamata increases with the depth in the Biscayan region. The
young, that is, only small specimens, were taken above 500 fathoms
and large ones with occasional small ones below that level. The
sexual condition at different levels was not noted. ‘The possibility
of overlapping distribution is certainly present but contiguous
distribution is by no means excluded.

Krohnia hamata is found in the mesoplankton of the Indo-
Austral region, where K. pacifica is also found, but in surface
waters exclusively. These two species were thus contiguous

244 THE AMERICAN NATURALIST [Vor. XLI

rather than coincident in their distribution. There is thus little
conclusive evidence of coincident distribution in the few species
of Krohnia.

GENUS SPADELLA

The case of the two species of Spadella, S. cephaloptera and
S. draco the area of distribution of the latter, which is a wide one,
includes that of the former which is a neritic species from the
northwestern coasts of Europe and the Mediterranean. ‘They are
both surface forms and their distribution is of the coincident type.

GENUS SAGITTA

The genus Sagitta as revised by Fowler (:06) includes twenty-
one species. Their general horizontal and vertical distribution
is shown in the accompanying table taken from Fowler’s (:06)

EPIPLANKTON MESOPLANKTON
Atlantic Ocean rennen i è Atlantic Ocean ung
TE
5j 2
A 3 $ Š 2 2 g < ro s s 8
sHEIEIZIET Ela T eV lelel Rigel ela
- $ £ 8 £ a É 4 2 8 £ “ 2 £
zZ “lo § j Zz a || à
ARCTICA +++ > . . . .
Bepori +]. i x í 5 En BY T ; .
BIPUNCTATA -H £ +/+!+!1+1+1+!+ B za + .
DECIPI: j . |+ 4 4 s ‘ á .
ELEGANS + “ + b " ‘ . . . .
—" = -+ . i+ ++ t +h. . . .
FURCATA + + ; + ? ; ; . : ` i + ? :
+ ++ +++ +++ + +
MACROCEPHALA . t+ 4 š 5 « y è % +it+ ` +
MINIMA +]. +). . + . . . .
GLECTA r è ‘ 5 En `; . +; i
PLANCTONIS + + » + 4 ` .
LCHRA $ š i ; = . .
REGULARIS +i]. ; x . $ + . . >
ROBUSTA $ . . x x + $ . .
poem a + i++ + +++ . |+ £
WHARTONI i 1 + i i ö ; ; 2 š . .
ZETESIOS -j+ š . . #1.
HAMATA Haa aT eaa p a +++ t
PACIFICA +]. R ‘ ’ . +i. . . è >
SURTILIS + t+ +|+|+]+ TiTi: +|+ +
CEPHALOPTERA I > P ` . è . . . . .
+ +++

Fie. 1.— Geographic Distribution of Chetognatha, after Fowler (: 06).

(Siboga) report. S. bipunctata is omitted by him from the Indo-
Austral region in his text because of the uncertainty of its identifica-

tion since it is quite similar to the young of several other species.
in the list. Of the twenty-one species, eleven, including S. bipune-

No. 484] DISTRIBUTION OF CHETOGNATHS 245

tata, occur in the Atlantic, ten in the Indo-Austral, eight in Jap-
anese waters, and two in the subantarctic, in the epiplankton. In
the mesoplankton of the Atlantic eight species are found, and
three in the Indo-Austral. In the larger geographical regions.
of the Atlantic we find coincidently in the epiplankton, in the
Arctic, three species, in the subarctic five, in the north temperate,
eight, in the tropical, five, in the south temperate, four; in the

SPECIES TEMPERATURE IN DEGREES CENTIGRADE

my 9 2345 6 7 8 9 10 If 12 13 14 15 16 17 18 19 20 21 22 23 2425 26 27 28 29 30 3 32

ARCTICA, 2

<S

-1 0 3456789 1 it 1213 14 15 16 17 18 19 20 21 22 23 2425 26 27 28 29 30 31 32

Fig. 2.— Distribution of Chætognatha with reference to temperature,

mesoplankton, two, eight and two species respectively in the
subarctic, north temperate and tropical regions. In the Indo-
Austral there are three species in the south temperate and ten in
the tropical, with three in the mesoplankton of the latter.

The distribution of the species with reference to the temperatures
at which they have been recorded is shown in the accompanying
table from Fowler’s (:06) report.

246 THE AMERICAN NATURALIST [Vorn XLI

In the case of Sagitta the distribution is as follows:

--1° to 4° — 3 species

5° to 10° — 7
11° to 15°.— 6
16° to 20° — 6
21° to 25° — 8
26° to 32° — 11

This, in conjunction with the fact that some of the low tempera-
ture species belong to the mesoplankton of the tropics, indicates
that the center of radiation of the genus has been in the tropics,
or that specific differentiation has been relatively more rapid in
that region than at the lower temperatures toward the poles.

These broader outlines of the distribution of the species of
Sagitta are suggestive of a considerable degree of coincidence of
distribution of species, it may be of closely related ones, and
prompts to a closer analysis of their relationships and distribution.

The determination of degrees of relationship among species of a
genus is a matter of inference from structural details for whose
relative values we have no absolute standard. One’s judgment is
guided by the selection of characters on which classification is
based, by experience in dealing with the specific analysis of the
material, and subjectively, by the conception of species which one
entertains. It is obvious that species differentiated by the slow
accumulation of minute fluctuating variations would offer in their
modified structures, some clue to the distance of their removal
from the parent stock, or from each other. On the other hand
the elementary species arising by mutation from (Enothera lamarck-
iana may be regarded as genetically equally related to each other
or to the parent stock, but if we base our judgment of the degrees
of the relationship which they exhibit solely on the structural
characters which distinguish them, we would be forced to conclude
that there was considerable disparity of relationship among them.
The mutation theory admits a wider latitude in estimating the
relationship of species than does the unmodified Darwinian point
of view.

We have, however, in Sagitta only the result, and not the process
of specific differentiation with which to deal, and are therefore

No. 484] DISTRIBUTION OF CHETOGNATHS 247

forced to depend solely upon structural resemblances for the
determination of specific relationships.

The species of Sagitta are distinguished, among other less
quantitatively expressed characters, by (1) size, (2) ratio of tail to
total length, (3) number of jaws, (4) number of anterior and (5)
posterior teeth. An analysis of Fowler’s (06) specific diagnoses
reveals three groups of related species within which couplets of
most closely related species may be noted.

The first of these, the serratodentata group, includes five species:
S. serratodentata, a eurythermal cosmopolitan species with little
tendency to sink to deeper waters in the tropics; S. bedoti, a
neritic surface species from Indo-Austral waters; S. jerox and
S. robusta, neritic and surface species from the Malay and Maldive
Archipelagos; and S. siboge, taken only in hauls from deep water
in the Malay Archipelago.

The following table of quantitative characters of the species
taken from Fowler’s records serves rather to indicate their close
resemblance than to differentiate them. Other characters such
as proportions, form of the eyes and teeth, assist in diagnosis.

Serratodentata Group.

Length in Tail in % of Anterior Posterior
pecie H "total length Jaws teeth teeth
serratodentata 5-14 28-36 5-7 8-9 16-22
bedoti 13-20 21-28 6-7 8-10 17-29
siboge 9-20 21-33 5-7 7-10 16-22
ferox 10-20 29-36 5-6 6-10 9-14
robusta 10-14 25-33 5-7 6-9 10-15

The quantitative characters of the table in conjunction with
others not included, suggest that the wide ranging S. serratodentata
may be the ancestral stock of the couplets bedoti - siboge and
ferox - robusta, or more nearly related to that stock than the
couplets named.

The ‘Siboga’ lists indicate that these five species occur in the
waters of the Malay Archipelago, but S. siboge@ only in collections
from the deeper waters. The other four, however, are found
together repeatedly in collections from the surface. In the 65
collections in which Sagitta occurs all four species appear in 27,
three of them in 27, two in 9, and one in but 2, the average percent-

248 THE AMERICAN NATURALIST [Vor. XLI

age of coincidence 80%. Of the 65 collections 55 were made at
the surface. Four of the five species thus have a coincident dis-
tribution, including the mostly closely related couplet ferox-
robusta and the very closely related S. bedoti and S. serratodentata.
The bedoti-siboge couplet appear to have a contiguous distribution
in the upper and lower levels, respectively, in this region.

A second group of species which show considerable resemblances
to each other are S. hexaptera, an oceanic, stenohyaline, eury-
bathic, and eurythermal form; S. enflata, a warm water form of
wide distribution in the epiplankton of warm-temperate and
tropical seas; and S. pulchra, a neritic surface form from the
Malay and Maldive Archipelagos.

The accompanying table indicates the relationships of the
three species of the hexaptera group as suggested by the quantita-
tive characters.

Hexaptera Group.
Length in Tailin % of Anterior Posterior
Species t total length Jaws teeth teeth
hexaptera 15-70 20-25 6-8 3-4 2-7
pulchra 9-22 18-27 5-7 6-9 10-15
| euflata 22-26 16-22 79 7-10 12-17

An examination of the ‘Siboga’ lists shows that the three species
occur together in 24 catches, two in 26, and but a single one in 26,
the percentage of coincident occurrence being 66%. ‘The most
closely related couplet in this group is pulchra-enflata, the former
a neritic, the latter an oceanic species. ‘These two occur together
in the Maldives and also in the ‘Siboga’ collections, where S.
enflata is one of the most abundant species. It is found in every
one of the 34 collections in which S. pulchra appears. Of the 34
coincident occurrences 29 are in surface collections. ‘These three
related species have here a coincident distribution and S. hexaptera
and S. enflata have a common distribution over a much wider area.

A third group of related species includes S. bipunctata, and two
couplets of most closely related species, furcata- planctonis and
neglecta—regularis. Published records indicate that the first
named species is a cosmopolitan one of wide range. Difficulties
attend its specific determination so that Fowler is of the opinion
that it is possibly only an Atlantic neritic form not occurring in
Indo-Pacific waters.

No. 484] DISTRIBUTION OF CHETOGNATHS 249

The members of the first couplet, furcata- planctonis, are Atlantic
species, the former of wide distribution, 51° N. to 7° S., in the
epiplankton of colder waters (17°) and the mesoplankton of the
tropics. ‘The latter occurs only in the epiplankton of the tropics.
This couplet of most closely related species has a contiguous
rather than a coincident distribution. The distribution of both,
however, is overlapped by that of the very closely related S. bi-
punctata. ‘The degrees of relationship as suggested by quantita-
tive characters may be inferred from the accompanying table.

Bipunctata group.

Tail in % of Anterior Posterior
Species Length total length Jaws teeth teeth
bipunctata 12-20 21-25 8-10 4-7 8-18
Jurcata 21-27 22-24 6-7 4-6 9-10
planctonis 17-23 23-26 7-9 6-8 9-10
neglecta 5-10 26-40 5-8 4-6 9-12
regularis 4.5-7 28—40 5-7 2-4 4-6

The members of the second couplet of most closely related
species, S. regularis and S. neglecta, are both surface neritic forms.
of the Malay Archipelago and Japanese waters. S. regularis is
neritic also about the Maldives and it may be that Doncaster (:03).
overlooked the very similar S. neglecta in the collections from
these waters. The distribution of these two most closely related
species is thus widely overlapping, if not indeed coincident.

The distribution of pelagic organisms, as illustrated by the
Cheetognatha thus affords several probable instances of the isola-
tion of the members of couplets of most closely related species by
isotherms or isothermobaths. This isolation is similar in many
of its aspects to that so often found between terrestrial species.
It may well be that isolation has been an essential factor in the
differentiation of the members of these couplets. Even more
general, however, in the pelagic world and among the species of
this same group is the phenomenon of the coincident occurrence:
of couplets, and of larger groups, of most closely related species.
We have now no evidence of differential seasons, temperatures,
or levels at which breeding might occur in these closely related
species. Should these differentials ultimately prove to be absent:

250 THE AMERICAN NATURALIST [Vor. XLI

we would be forced to conclude that isolation has had no part in
the origin, differentiation, and continuance of these related species.

In Dagitta bipunctata Miss Stevens (:03) has described a method
of close fertilization. As yet we have no light on the extent of its
occurrence in other species where the presence of enlarged seminal
vesicles and external male parts affords suggestive though not con-
clusive evidence of external and presumably of cross fertilization.
Should all species of Cheetognatha prove ultimately to have close
fertilization we would have in this a most effective means of isola-
tion.

The apparently wide-spread phenomenon of coincident dis-
tribution of related species among pelagic organisms appears to
cast some doubt upon the universality of the operation of isolation
in the evolution of species as originally maintained by Moritz
Wagner (’68) and recently revived by President Jordan (:05).

The contrast here afforded also raises the question whether the
two types of ‘species’ really belong fundamentally to the same
category or not. Are those with contiguous distribution, and also
many of the geographical species and subspecies of land verte-
brates, of a standing exactly equivalent to that of those having a
coincident distribution? Are, for example, S. furcata and S.
planctonis merely the extremes of an environmental series begin-
ning in the warm surface waters and ending in deep waters of
lower temperature? In other words are they the result, in part
at least, of the pressure of the environment? A statistical study
of the distribution and variation of such a pelagic couplet and a
comparison with a similar study of a couplet having a coincident
distribution would be most instructive in indicating whether or
not any distinction exists between ‘isolation-environmental’ spe-
cies on the one hand and ‘selection-mutation (?)’ species on
the other. Are intermediate forms equally absent in both types of
couplets? Is variation similar in kind and in distribution among
the individuals of the two types? Above all will the individuals of
the isolated couplets maintain their specific integrity if their envi-
ronments are transposed? And finally will the species with coin-
cident distribution exhibit any greater specific stability under
environmental changes than will those produced by the agency
of isolation ?

Investigators of pelagic organisms have been morphologists so

No. 484] DISTRIBUTION OF CHETOGNATHS 251

generally, rather than primarily systematists, that the bearing of
the data of the geographical distribution of the organisms with
which they have been dealing, upon the broader problems of
evolution has been somewhat neglected. It is greatly to be hoped
that the life of the sea, primitive, ancient, diversified as it is, may
yet shed some light upon the problems which this brief paper can
do little more than suggest.

ZOOLOGICAL LABORATORY
UNIVERSITY OF CALIFORNIA
D 6

BIBLIOGRAPHY
Arpa, T.
97. Chetognaths of Misaki Harbor. Annot. Zool. Jap., Vol. I,

pp. 13-21. Tab. III.

DONCASTER, L
Chætognatha, with a note on the variation and distribution
of the group. Fauna and Geog. of the Maldive and Laccadive
Archipelago. Vol. I, pp. 209-218, pl. 13, text figures 39, 40.
FowLer, G. H.

:05. Biscayan Plankton collected during a cruise of H. M. 8. ‘Re-
search,’ 1900, Part III.— The Chetognatha. Trans. Linn. Soc.
London, Zool. Ser. 2, Vol. X, pp. 55-87, Pls. 4-7.

:06. The Chetognatha of the Siboga Biondition with a discussion
of the synonymy and distribution of the group. Siboga Exped.,
Monogr. XXI, 85 pp., 3 Pls., 6 Charts.

JoRDAN, D. S.

:05. The origin of species through isolation. Science, N. S. Vol.

XXII, pp. 545-562.
STEINHAUS, O.
’96. Die Verbreitung der Chætognathen im sudatlantischen und
indischen Ozean. Inaug. Diss., Kiel, 49 pp., 1 Taf., 2 Karten.
Stenns, N. M
On the oogenesis and spermatogenesis of Sagitta bipunctata.
Zool. Jahrb. Abth. f. Anat., 18, 227-241, Pl. 20-21.
STRODTMANN,
’92. Die Systematik der Chætognathen. Arch. f. Naturg., Jahrg.
LVIII, pp. 333-377, Taf. 17-18
WAGNER, Morirz.
. Ueber die Darwinsche Theorie in Bezug auf die geographische
Verbreitung der Organismen. Sitzber. d. bayer. Akad. d. Wiss.
Miinchen, Bd. 1, pp. 359-395.

THE ATTACHED YOUNG OF THE CRAYFISH CAM-
BARUS CLARKII AND CAMBARUS DIOGENES

E. A. ANDREWS.

A REMARKABLE fact in the life history of the crayfish is that the
young associate with the mother for many days after leaving the
egg, being at first firmly fastened to her and later going back to her
for protection until finally quite independent.

As pointed out in The American Naturalist, March, 1904,
Cambarus affinis molts twice while fast to the mother and leaves
her only in the third stage. Some facts as to the character of this
incipient family life in an American Astacus from Oregon will be
given in another communication. ‘The object of the present note
is to describe the association of parent and offspring in two more
species of Cambarus and to compare this with what is found in
C. affinis and in Astacus. The illustrations are all of C. clarkii.

The young of C. clarkii were obtained from eggs laid in con-
finement by adults shipped from New Orleans, November 18,
1904; some 18 out of 61 surviving the journey. ‘Two of these
active, prawn-like and brilliant red crayfish, one male and one
female lived in a shallow sink of warmish water during the
winter and by March 25, 1905, the single female had the abdominal
basket full of many very small and very dark-colored eggs. ‘These
eggs were already in the stage H of Reichenbach but differed from
that in having the abdomen larger. Each egg was about 13 mm.
in diameter and partook of the exceptionally vivid coloring of the
adult, the large oil-like yolk drops being wine colored instead of
yellow as in Cambarus affinis.

When received in November, three of the females examined
had only minute yellow eggs in the ovaries and no sperm in the
annuli, while the males had small testes but yet mature sperm in
the vasa deferentia. It would thus appear that the season of
conjugation may be late autumn or winter, and that of laying
early spring, but this can be determined only by observations in
the field.

253

254 THE AMERICAN NATURALIST [Vor. XLI

By April 17 the eggs had become coated over with a dark deposit,
but the embryo within was far advanced and easily escaped when
pressure caused the egg case to spring open. With Zeiss 2. A. it
was evident that the embryo was clothed in a loose cuticle, or cast
off shell, which loosely invested the tips of the first and second
antennz, the chelæ, the walking-legs, the abdomen and thorax as
well as the ends of the gills when torn out of the gill chamber.

These embryos were now essentially the same as when they
hatched three days later. The eyes were almost sessile and with
the pigment restricted to a narrow crescent and this pigment
reflected yellow light but appeared black by transmitted light.
The yolk was still a large dark mass of saddle-bag shape. ‘The
tips of the fourth and fifth legs were strangely bent back like
hooks while the tips of the claws of the chelz did not as yet seem
to be recurved. All over the body the extremely dark crimson
pigment cells again emphasized the agreement of embryo and .
parent in intensity of coloration.

But the detail of anatomy of the telson was the most important
character for understanding the subsequent attachment of the
young to the parent. The abdomen ended in a simple, flat,
rounded telson that bore a row of simple spines along its posterior
edge as seen with 2. D. in figure 3. The spines were fourteen or
fifteen on each side symmetrically placed right and left, and a
group of seven or eight of them on each side, near the median
plane, seemed to push off the loose cuticle, which on the middle
plane, was close to the body. The spines, or better, papillæ,
were highly refractive and clear except that some showed granules
and some vacuoles in their homogeneous contents. Some of them
had small protrusions at the tips as if paste-like material had
extruded from within.

The spines in the special group, right and left, converged,
arched over, met and seemed grown together. On the animal’s
left the spines 7 and 11 were grown together at their tips while 8
and 10 seemed fused together at the tips into one continuous arch
and the same was true of 9 and 12. With higher power, 4 mm.
4.45 comp. oc., tufts of fine threads, or fibrils were seen diverging
from the tips of many spines to pass, posteriorly, often beyond
the tips of other spines. Some of these threads passed out to the

No. 484] ATTACHED YOUNG OF CRAYFISH 255

loosened cuticle and seemed fastened to it. On the right of the
specimen fine wavy lines suggested secreted films rather than fibrils.

As will be seen later these specialized spines are glandular
structures that make the telson adhere firmly to the cast-off cuticle
and thus make possible the “telson thread” of the hatching larva.

The small number of spines so grouped, together with the fact
that the telson of earlier embryonic stages is incised on the middle
of the posterior edge suggests that these 7 or 8 spines may be
comparable to the 7 or 8 spines seen on each side of the incised
telson of the lobster embryo (Fig. 72; Herrick; The American
Lobster) before it molts at the time of hatching and is in a stage
which Herrick compared to a protozoea, or other early larva.
On this basis a very remote ancestral state has been retained to
the extent that its spines have been applied to the new use of
attaching the larva to its cast cuticle.

Before speaking of the hatching larve it must be recalled that
all crayfish eggs are fastened to the pleopods of the mother by a
hardening mass whose origin is somewhat in dispute. In ©.
clarkii the pleopods of the mother were so translucent that the
transverse striation of the muscles was seen through the exoskeleton
and with 2. D. the gland cells that are supposed to take part in
fixing the eggs to the pleopods were seen as polygonal areas of
secretion droplets separated by clear lines.

All over the bases of the pleopods these areas were massed
together but the terminal part had them arranged in transverse
bands that crossed the anterior face and extended into the sides
but left the posterior face without glands. On the bands anteriorly
were small tubercles each with a number of tubes passing from
the glands to the surface and near these were some short, sharp
sete which occurred again at the tips of the pleopods.

While it is possible that these sharp sete act in pricking the
eggs and liberating an adhesive material as claimed by Williamson
for crab’s eggs, and that the glands of the pleopods have nothing
to do with fastening the eggs, yet this seems very improbable, as
the eggs are fastened to a large mass of material similar to the egg
case and stalk and which binds all the long plumose setæ together
and is most probably the product of the pleopod glands.

The small first pleopods also had glands and setæ like the others
but were more colored with large, arborescent, red cells.

256 THE AMERICAN NATURALIST [Vor. XLI

When fastened to the mother each egg was in a remarkably
elastic case which had a rough, dirty outside layer and a clear
inner layer containing the same microscopic droplets seen in C.
affinis and similar to the droplets coming from the pleopod glands.
Each case was continued on one side as a long stalk that in turn
was continuous with the hardened secretion binding together the
plumose setæ along the edges of the pleopods. ‘The stalk was
hollow though flat-and wide and was a continuation of the dirty
outer layer of the egg case, separating from the inner layer on one
side to form a large hollow bell or tent.

Between the egg and the egg case was a variable amount of
coagulum showing fibrils in it.

By April 17th some of the larvee had hatched while others were
not yet out of the egg cases. The young, figure 1, had the usual
embryonic look of crayfish at hatching; a huge swelling of the
head region owning to the presence of much yolk there; a weak
development of the locomotor part of the head-thorax so that the
five pairs of weak legs all arose posterior to the middle of the head-
thorax; a weak, down-bent abdomen of little use in locomotion;
eyes almost sessile and of little size or perfection. These larvee
were transparent and showed the heart beating rapidly and the
scaphognathites rapidly baling the water out of the gill chambers.
The dark area in figure 7 represents the dark red yolk mass;
and the scattered dots, the aborescent pigment cells that were
thickly scattered over the head-thorax and abdomen with but few
upon the third maxilliped, base of antenna, three basal segments
of the antennule and some few segments of the periopods.

Normally the larvæ remained upon the mother and did not
move about, and when pulled off and put on the bottom of the
dish they could not stand up but could progress by lying upon
the side and flapping the abdomen.

At hatching, figure 1, the young were so weak they would
have dropped to the bottom but for the “telson-thread” which
is the cast off cuticle pulled out into a thread or band and fastened
at one end to the telson of the larva by the special telson spines
described above and at the other end to the inside of the egg case.
As the egg case still remains fast by its stalk to the mother the
larva is hung suspended from the mother till able to use its claws

No. 484] ATTACHED YOUNG OF CRAYFISH 257

and obtain a hold by them to the egg stalk or to parts of the material
covering the plumes of the pleopods.

In hatching the larva escapes not only from the egg case but
from its loose cuticle and this cuticle, where it covers the abdomen,
is pulled inside out, but leaves the telson spines fast as before to
the inside of the cuticle over the tip of the telson. The cuticle is
so strong that larvee may be picked up by the telson thread and
their weight does not break it even when hanging in the air.

The attachment of the cast cuticle to the inside of the egg case
seems to be an indirect one; apparently the larval cast cuticle is in
some way fast to the egg membrane and that in turn adherent to
the inner of the two layers that makes the egg case, but this was
not definitely seen. In many eggs the embryo when young lies
upon the side of the egg near the stalk and we suspect some re-
lation between the region of fertilization and of stalk formation.
Later, when the embryo hatches, it goes out back foremost through
a crack in the case opposite to the stalk. In the old embryos the
tip of the telson is carried forward to near the eyes and not far
from the stalk of the egg case and in that same region of the egg is
found the connection of egg case to embryonic cuticle. Possibly
there may be some common factor, as gravitation, that determines
at fertilization the position of the embryo, the place for formation
of the egg stalk and the connection of egg case and larval cuticle.

The part played by the special telson spines in holding the larva `
fast to the telson thread is shown in figures 2 and 4, which show
how the wrinkled telson thread is connected to fibrillar material,
fastened to and interlocked with the long, curved and arched
spines. In passing from the condition shown in figure 3 to that in
figure 4 the cuticle over the abdomen has been pulled off and
turned inside out and is now free from the larva except where
held by the material furnished by the glandular spines.

When the young get hold of the mother pleopods with their
claws they soon break the telson thread, but a short end of it long
remains fast to the telson and the main mass still recognizable is
fastened to the egg case.

In this first larval stage these young crayfish were about 45 mm,
long from tip of telson to a point between the eyes where the
rostrum turned down close against the head and was concealed
between the eyes. ‘The antennæ were 1} mm. long.

258 THE AMERICAN NATURALIST [Vor. XLI

The accompanying camera sketches from specimens hardened
in Worcester’s liquid show the generally imperfect state of the
appendages of the first larva, which lived for a few days an inert
embryo-like existence fastened to the mother and not eating but
only rapidly aerating and circulating its blood as the yolk was
being transformed. ‘The first antenna, figure 8, has only four
segments in its exopodite and in its endopodite and agrees with
most of the other appendages in being devoid of sete. ‘This bare-
ness of the appendages of the first larval stage was first pointed
out in the English Astacus by Huxley and seems common to all
crayfish larvee in their first stage. In place of sete there are but a
few spinules at the tips of the first antenna and on the basal seg-
ment there is a small ear-pit; but as yet the entire appendage
would seem of no use as a sense organ.

The second antenna, figure 9, has only 24 segments in the slender
part of its filament, beyond the three large broad segments, and the
exopodite scale bears a blunt process and a row of few, sharp
spines. ‘The tubercle upon which the nephridial canal opens is,
as in all young crayfish, proportionally very large.

The mandible, figure 10, has a smooth edge with no teeth and
is probably not used. The first maxilla also, figure 11, is very
simple and probably of no use.

The second maxilla, on the other hand, figure 12, bears the
large scaphognathite which is very active in removing water from
the gill chamber. The setæ along the edges of the scaphognathite,
though represented in the figure as smooth, were in reality, under
2. D., set with five side branches so that in this only actively moy-
ing appendage the setz are present as plumes that would seem to
be of use in striking against the water and in making the appendage
fit more closely into the passage leading out of the gill chamber.

The three maxillipeds, figures 13, 14, 15, are strangely lacking
in setæ except upon exopodite of the first where there is a row of
sparsely plumose sete. The gills begin as a large podobranch
and a slender anterior arthrobranch on the second, figure 14, and
on the third, figure 15, there are two arthrobranchs. The project-
ing lobe at the base of the epipodite, or lamina bearing the fila-
ments of the podobranch, is conspicuously large in all larval
crayfish and here bears a few, acicular sete. Probably these

No. 484] ATTACHED YOUNG OF CRAYFISH 259

lobes and sete aid respiration in making the inlet water more
free from dirt.

The chele, figure 16, are long and strong but as yet not special-
ized as cutting organs. The tips of the claws are recurved as
Huxley first found them to be in the English Astacus so that once
shut upon a penetrable mass they could scarcely be loosened by
the larva, figure 17. By means of these locking tips the young
become fastened to the egg stalks and to the hardened secretion
on the mother’s pleopod sete so that they probably remain fixed
in one spot all the time they live in the first stage. The simple,
acicular sete seen along the edge of the claw, figure 17, may pos-
sibly aid in tactual reflexes to enable the larva to shut its claw on
suitable substances.

The next two pairs of legs are very like the chelæ, but more
slender, short and weak.

The fourth leg, figure 18, with no claw, has its arthrobranchs
much reduced, the anterior having but slight protuberances to
represent lateral filaments and the posterior being quite smooth.

The fifth leg has no gills at all associated with it; the pleuro-
branch of Astacus being absent not only in the adult Cambarus
but in the earliest larva here as well as in C. affinis and, as long ago
determined by Faxon, in C. rusticus. The branchial formula is
thus the same in the larv as in the adults.

On the abdomen the appendages have the incompleteness of all
crayfish larve. The first pair are not begun and the sixth pair
are forming under the exoskeleton within the base of the telson.
The other four pairs are very small and apparently quite useless
structures each projecting towards its fellow crosswise under the
abdomen and with the endopodite more anterior and the exopodite
more posterior. As seen in figure 19, the endopodite is somewhat
the larger and both endopodite and exopodite are very simple and
show but slight suggestions of spines at their tips.

The telson, figure 2, is a simple, elongated, flat plate showing
within its clear substance radiating lines ending at the marginal
spines and also the outlines of the long exopodites of the sixth
pleopods lying along on each side of the rectum and anus. On
the ventral side, figure 1, the base of the telson is quite protuberant
over the part of the enclosed pleopod that will be the exopodite.

260 THE AMERICAN NATURALIST [Vor. XLI

In larvee that have been in the first stage a few days and are
about ready to molt it is obvious that the radiating lines in the
posterior part of the telson are the glands secreting the set which
will replace the marginal spines at the next molt. In a prepared
section of the posterior part of the telson of such a larva, figure 5,
the old cuticle is separated from the epidermis by a space across
which the tips of the forming sets pass toward the hollow bases
of the old spines. Each old spine has a new seta beneath it but
as there are also other set the second larvee will have more sete
than the first had spines; the long plumes, however, figure 7, are
slightly fewer in the second larvee than the spines in the first.

Each developing plumose seta seems a flat plate ending in a
fine central thread and with its edges frayed out in short fine
threads. ‘The base of each is deep within the epidermal ingrowth
that forms the secreting gland. Each gland seems a row or rod of
cells, indicated by large nuclei in a common protoplasm in which
no cell walls were seen. The longitudinally striated base of the
plumose seta forms the axis of the rod of cells. The space between
the radiating glands was in part occupied by blood, staining,
like the setze, yellow, while the nuclei were red in borax carmine
and orange G.

Similar, but less developed rods of cells were also seen in sections
of the internal buds of the sixth pleopods where they were forming
plumose set that projected into a bag surrounding the pleopod.

By April 24th, when some of the larvæ had begun to molt, it
was evident that something was abnormal, as some larvee in both
the first and the second stages fell away from the mother and
died. The mother also died, April 28th. The hatching was pro-
longed more than is probably normal so that many first and sec-
ond stage larvee were found side by side for a few days. Some
of the young in the second stage remained with the mother for a
few days but made excursions away from her and again returned
as was the habit for the second stage in Astacus leniusculus, but it
is not certain that this was normal in C. clarkii. While upon the
mother these young held firmly with their chele, but they let go
when the dead female was lifted out of the water. When upon
the bottom of a dish they were able to stand up and walk feebly,
and after a day, they swam backwards on their sides by flapping

No. 484] ATTACHED YOUNG OF CRAYFISH 261

the abdomen. ‘They tended to climb over one another and one
held so fast to a dead fellow that it could be shaken loose only
with difficulty. They also climbed up on to the dead female and
on to a piece of Canton flannel where they held fast by their chelee
for a time and then got down and swam actively if disturbed by a
pipette.

Though the larva in the second stage may thus go away from
the mother it doubtless returns even into the third stage as Faxon
records finding upon the abdomen of museum specimens larvee
with characters evidently of the third stage.

The second stage young, figure 6, were still so translucent that
in the abdomen the digestive tract and the ventral ganglia could
be plainly seen.

In C. affinis it was noticed that the young, in passing from the
second to the third stage, was suspended from its cast cuticle by an
anal thread which bound its anus to that of the cast off cuticle
and as the claws of that cuticle still held fast to the mother the
young was prevented from dropping away from the mother till
able to take hold again with its new claws. In C. clarkii the same
arrangement may prevail though it was noticed only in two larve
that died just after molting. In these there was a long thread
that issued from the anus and, passing down through the hollow
cast off cuticle of the abdomen, was fastened at the bottom of it to
the flat telson. By the strain of the anal thread the cast off ab-
dominal cuticle had been telescoped; the old telson being dragged
up against the collapsing rings of the cast cuticle. As in C. affinis
this anal thread was only the cuticular lining of the intestine not
cast off entirely at the same time with the external cuticle and thus
serviceable in binding the larva to its old shell. If this tardiness in
casting the lining of the intestine is normal in C. clarkii it would
seem a useful means of holding the young to the mother when soft
and helpless at molting time, provided the young molts while
upon the mother, which is probably the case even if it has some
freedom of motion in the second stage.

In contrasting the second stage, figure 6, with the first, figure 1,
we find an increase in size, the body being now 53 mm. long with
antenne 3 mm. long, and some advance in the proportions of the

body and in the perfection of the limbs. While the head-thorax

262 THE AMERICAN NATURALIST (Von KLI

still contains much yolk it is less swollen and more elongated while
the abdomen is relatively larger and it is more useful as its telson
bears a fringe of setæ.

The limbs are changed but little, yet they now bear some setæ
though these are too small to show under low magnifications,
figure 6. The rostrum is still triangular, but sharp, and though it
is still bent down between the eyes it can be seen from a dorsal
view and also from a side view, figure 6, where its base is visible
near the eyes which are now decidedly stalked.

The first antenna had six segments in its exopodite and in its
endopodite and the former bore five sense setæ, three on the
terminal and two on the fifth segment. The ear was a wide open
cavity with three or four finely barbed sete along its external
border.

The second antenna now had a long spine and a row of 19 or 20
plumose setze on its scale and its filament contained 34 segments
some of which seemed to be dividing.

The mandible edge was now no longer smooth but had six or
seven teeth on its free edge and three above the palpus.

The spines at the tips of the chele, figure 20, stood at about
right angles and were but slightly recurved. Along each edge of
the claws was a row of peculiar spines having a thick edge and a
narrow blade, figure 20, which tended to be cracked or striated
across its length. ‘These cutting or rasping spines are a speciali-
zation not found in the first stage when the claws are used only
as hold-fasts.

On the abdomen no new appendages were found but the four
pleopods present were now well provided with plumose sete.
The telson of the second stage, figure 7, compared with the first
stage, figure 2, shows a great increase in size and the addition of a
row of barbed setze in place of the simple marginal spines. The
sides of the telson protrude so much where the enclosed sixth
pleopods have enlarged that its margin is somewhat three lobed;
all the set are upon the middle or posterior lobe, and are sym-
metrically placed right and left. In the middle line there are no
sete; and right and left they begin short and suddenly reach
the greatest length and then, as seen in figure 7, are long enough
to make an efficient increase in the length and area of the telson
as an organ for striking against the water in swimming.

No. 484] ATTACHED YOUNG OF CRAYFISH 263

In the figure the dotted lines represent the enclosed pleopods
and in them the radiating sete glands in which are forming the
plumes to be expanded at the next molt. Studied in life with
Zeiss 2. D. these glands were long tubes from each of which pro-
jected a plume, the tip of which turned to one side in the space
between the edge of the pleopod and the enveloping sac. In the
same way the posterior end of the telson showed long tubular
glands forming a set of plumose setz to replace those already
present. ‘The tip of each new plume projected slightly from its
gland into the hollow base of the existing plume, which would be
cast off with the cuticle of which it is a part, at the next molting.
All these sete seen in formation in long tubes are richly barbed
plumes that later come into use when suddenly exposed to the
water at the next molt.

Only some five or six of these specimens of C. clarkii survived
to change into a third stage, April 29 to May 1st, but these agreed
with all known crayfish of the third stage in having a complete
tail-fan, with both telson and widely expanded sixth pleopods
together forming a very large area for resistance to the water and
set all along the combined edges with the above long plumose sete.

Though these few individuals seemed weak they both walked
and swam easily. The color had now become a darker flesh-color
from the crowding of red pigment cells, but the area about the
stomach was lighter and on each side of the stomach there was
a small, narrow, dark band representing the yolk.

As above stated it is probable that in nature the larve in the
third stage remain with the mother for a time, and then gradually
become entirely independent.

While the conditions seem to have been so unfavorable for C.
clarkii that the young were weak and probably somewhat abnor-
mal in their actions this was not the case with the young of another
crayfish, C. diogenes Girard as kindly determined by Walter
Faxon. April 8, 1906, ten females with eggs in late stages, three
females without eggs and twenty-two males were obtained from
Talbot Co., Maryland, by a collector who stated that they usually
breed in May and are caught walking about in ditches.

The eggs were nearly black, or upon a few females dark brown,
and of great size, being 2} to 3 mm. in diameter, while in C. affinis
they are 1ł to 2 mm. and in C. clarkii only 14 mm.

264 THE AMERICAN NATURALIST [Vor. XLI

The young were hatching upon six of these females May 22nd
and just before this an examination of the embryos showed a
delicate loose cuticle over each tip of the chela, over the abdomen,
and over the body, and an egg opened in strong sugar solution,
and then put into water showed a cuticle swelling up all over the
antennze, the chelz and the abdomen. But when carefully dis-
sected it seemed that this cuticle was not a case over each append-
age but rather that it was a large bag over the thorax, a side pouch
over the abdomen, a large side pouch over all the pereiopods and
a side pouch over all the gills. Probably, however, there are two
thin membranes, an outer vitelline membrane of irregular form
when stretched over the protuberant regions of the animal and an
inner, real cast-off cuticle, that goes over each appendage; for
some dissections showed the embryo inside a delicate spherical
bag fastened to the inside of the egg case, and observations upon
‘the hatching larvee seemed to show them drawing out the limbs
from separate envelopes.

At the end of the telson there were groups of spines fastened to
the cuticle by refractive fibrillar coagulum. On each side a group
of six spines arched over and connected very much as in C. clarkii,
figure 3, and here the cuticle was thrust off further, while on the
middle line it was close to the telson.

In one individual the actual hatching lasted forty-five minutes;
the egg case cracked open opposite to the stalk and the embryo
slowly “oozed” out back forward. During this process some
movements of the legs were seen as well as a rhythmic pulsation
of the lateral lobe of the liver lying close to the yolk mass on each
side of the body, and swaying movements of the yolk mass. This
tube was filled with yellow liquid for ten or twelve seconds and
then grew narrow and white for about two seconds and again filled.
It seemed as if the tube were contractile itself, but the yellow liquid —
may have been forced into it and so have caused it to distend.
In either case the rhythmic filling would seem useful in aiding in
digestion of the yolk, which was the only available food so far.
Should it prove that the adult liver also rhythmically fills and
empties it would be an interesting addition to the anatomical and
physiological evidence advanced by H. Jordan (Pflüger’s Archiv,
1904,) to show that the ‘liver’ is the chief organ for absorption
as well as secretion.

No. 484] ATTACHED YOUNG OF CRAYFISH 265

As soon as out of the egg case the larva began to kick its legs
and in a few minutes the scaphognathite slowly moved, stopped
and began again, finally establishing a rapid rhythm. On adding
carmine, the currents made by the scaphognathite were visible
and its movement seemed comparable to a scooping motion of a
hollowed hand, the fingers downward, thus forcing the water
through the dorsal part of the respiratory passage as the fingers
closed the lower part and then rising up to close the upper part.
and prevent a back set of water into the passage way.

Once out of the egg case the larva was still fastened to it by a
telson thread consisting of a short string from the telson spines to a
large crumpled mass that seemed a cast off cuticle and lay just
within the gaping egg case and was fastened to it, inside, by the
intervention of an expanded membrane which may possibly have-
been the old vitelline membrane. This membrane was bound to
the inside of the egg case by a few short fibrils over a round area.
smaller than the base of the egg stalk and often near it. Thus
suspended the larva moved its legs weakly and now and then shut
its claws and violently flapped its abdomen without breaking
loose from the telson thread. Soon the larvee became fast by their-
claws to the egg stalks or to the material on the plumose sete of
the mother’s pleopods.

In this first stage the larvae remained cowered down close to the
pleopods and were so firmly fastened to the mother by their claws.
that they did not break loose when the pleopod was thrown into
Worcester’s liquid, though they jerked their legs and powerfully
and violently flapped their abdomens. ‘Those left locked to the-
pleopods of the mother lived three to four days and then molted
into a second stage, May 26.

They were very large, 5 to 6 mm. long when stretched out and —
4% mm. as they lay with the weak abdomen carried forward under
the thorax and were very attractive objects because of the swaying
of the dark red and golden yolk mass, the contractions and change
in color of the lobes of the liver spread like the fingers of a hand
deep in over the back, and of the fiery, ruby-red, neuron-like,
branching pigment cells spangled over a body so translucent as to
show the white blood corpuscles hurried along the vessels over the-
red yolk, along the sinus at the edge of the carapace and out and
in through the legs and antenne like shuttles.

266 THE AMERICAN NATURALIST [Vor. XLI

Camera lucida sketches of the first larva of C. diogenes showed
it larger than even the second stage of C. clarkii but in simplicity
and proportions essentially like the first stage. As usual in hatch-
ing crayfish the appendages were almost all bare of setae; the eyes
were nearly sessile; the rostrum a small triangle close to the body
and between the eyes. The yolk far forward in the head-thorax
distended that region and left the region for the gills and pereiopods
of less extent.

In the first antenne there were four segments in the larger, club-
like exopodite and also in the slender, nuie endopodite and
there were no sensory setæ.

The second antennæ were carried curved backward and down-
ward but not close against the thorax as in C. affinis and each had
only spines upon its scale and 35 segments on the slender part of
the filament.

The mandible had no teeth but its edge was very slightly waved
where the epidermal cells seemed about to secrete slight thicken-
ings.

The scaphognathite used as a baling organ also was exceptional
amongst the appendages in bearing plumose setee which formed
a row along the edge and were longer and more easily seen than in
C. clarkii.

The gills were larger and with more side filaments than in C.
clarkii but were suddenly reduced upon the fourth pereiopod so
that the anterior arthrobranch had but a few filaments and the
posterior none. On the last thoracic somite there were no gills,
- as is the case in all the young of Cambarus thus far studied.

The four pairs of pleopods had the endopodites slightly longer
than the exopodites and the entire appendage was very much
longer than in C. clarkii and with evident spines on both tips.

The telson with its enclosed pleopods was very much like that
of C. clarkii and bore on its posterior edge the same kind of spines,
about 14 on each side, six of which were specialized gland ducts
arched over and joined together and bound to the telson string
very much as in C. clarkii, figure 4. Inside the telson there were
again the radiating glands making the plumose setæ of the second
stage and a day before molting, the tips of the plumose setæ
extended from their glands so far along, posteriorly, between the

No. 484] ATTACHED YOUNG OF CRAYFISH 267

epidermis and the loosened cuticle as to pass by several spines.
Each new seta had its lateral barbs closely appressed against its
axis. Moreover the new cuticle extended inward to line part of
the seta gland so that in macerated specimens these cuticularized
tubes ending abruptly, strongly recalled the like tubes that go in
along the sete of the earth worm. Probably at molting these
sleeves become everted and so allow the sudden extension of the
setee to a length equal to the length of those tubes added to the
length of setee already lying between the old and new cuticles.

Molted into a second stage the young C. diogenes were 8} mm.
long, 14 wide and 2 deep and had antenne 5 mm. long. Until the
next molt — some five days, May 26th to 31st,— they remained
upon the mother’s pleopods, but were not so firmly fixed as before
as they fell off when put into Worcester’s liquid.

While in most respects the larva was essentially like the second
larva of C. clarkii a number of differences were noted.

The rostrum was less bent down than in C. clarkii and was long
and pointed and visible from the side as its tip extended out beyond
the eyes; its sides moreover were not straight as in C. affinis but
arched so that something of the adult character was already
expressed.

The first antenna was yet concave on the upper side of its base
to fit against the eye and had in it a large open ear pit bordered
externally by a few small spines and one very imperfect plumose
seta. Beneath these spines the plumose sete of the third stage
were seen in formation. The exopodite bore seven sense set,
three on the sixth and two on the fifth and on the fourth segments.
The exopodites and endopodites were each divided into six seg-
ments.

The second antenna had some 13 to 15 plumose setze on its scale
and 38-42 segments on its filament.

The tips of the chele were still slightly recurved but as above
noted the larvæ did not seem very firmly fastened by them.

Though the telson was larger than in C. clarkii its fringe of
sparsely plumose setz were noticeably shorter. ‘There were about
twenty on each side. In the base of the telson the large sixth
pleopods showed a long exopodite, with a transverse joint, suggest-
ing an index finger lying along the side of the telson while the
endopodite was bent crosswise like a thumb.

268 THE AMERICAN NATURALIST [Vor. XLI

A dissection of one of these second larve revealed a mass of
membranous material and both simple and plumose setze in the
intestine suggesting that these larve may eat the egg cases and
setze from the mother’s pleopods.

The creature was still translucent enough to show the ventral
ganglia through the exoskeleton of the abdomen and was dotted
over with pigment cells of stellate form, which when expanded were
light red and when contracted very dark, while deeper in were
diffuse and indefinite blue cells. In the antenne and legs as well
as in the antennal artery the corpuscles were going outward rapidly
and returning somewhat more slowly in wider vessels.

Two days before molting into the third stage the new inner
cuticle was already formed and the new sete projected into the
bases of the old. The yolk had become reduced to a small dark
remnant on either side and even to the naked eye the gastroliths
were conspicuous as two pink-white opaque areas, one on each
side of the stomach enveloped in a clear glassy coat.

The third stage began by June 1st and had the adult character
of a tail-fan made of the telson and the fully expanded sixth pleo-
pods all fringed with perfect plumose sete. These larvee were
103 to 11 mm. long, 3 wide and 24 deep and expanded the tail-fan
about 4 mm. while the antenn® were 6 mm. long.

These third stage larvee when recently molted were still some-
what translucent and of a faint pink color with red-tipped claws
and though the stomach was plainly visible the gastroliths were
lacking on the outside. But within the actively moving stomach
was a brownish liquid containing white particles or in some cases
whole gastroliths moved about actively. In some cases the intes-
tine contained colored material in its anterior part.

The specific gravity of the larvee had so changed that they now
floated in Worcester’s liquid though the first and second stages
sank; they were also less resistant to this fluid and died more
quickly than when younger.

When the larve had changed into the third stage it was noted
that the six mothers no longer had egg cases and cast cuticles upon
their pleopods and as their fæces contained parts of plumose sets
of adult size it may be that they aided in cleaning off their pleopods
though there is some evidence that the second larvee may eat off

No. 484] ATTACHED YOUNG OF CRAYFISH 269

that material and Soubeiran stated that the young of an Astacus
ate the egg cases and larval skins.

The third stage larvæ stayed near the mother some ten days or
more, often, when disturbed, climbing on one another and crowd-
ing under and upon the mother, but after that they were quite
independent and seemed to have no association with the mother
though kept in the same small aquarium.

Walking and swimming the young sought food over the bottom
of the aquarium and in a day cleaned off all the brown deposit
from a spray of Myriophyllum and when another piece was given
them ravenously set about tearing off and eating the bacterial
slime and algal growths. When given Chara they seized an
internode with their mouth parts and pushed it with their feet
somewhat as a dog gnaws a bone, but when pieces of internode
were cut off for them they seized them by one end and walked
about sucking the contents out. Such a larva holding its head
high and supporting a stick longer than its body, held by its
mouth parts straight out in front of it, ludicrously suggested the
enjoyment of a huge stick of candy. Animal food in the shape of a
dead comrade was eagerly seized and pulled to pieces and a small
earthworm was eaten up in a few hours.

Living thus, at a temperature of 85° F., the young were very
active and darted away from the shadow of an object outside the
water. After two weeks some molted without much change
of size but by July 3rd some were 13 to 15 mm. long and the only
survivor, July 15th, 18 or 19 mm. long.

From the above account it appears that the young of Cambarus
clarkii and Cambarus diogenes associate with the parent in the
first and second stages and in part of the third and this sort of
family life is aided both by special recurved tips on the chele and
by a peculiar telson thread; and as this is true also in C. affinis as
well as in an Astacus of France and one in Oregon it is probably a
general fact for all species of these two genera. Moreover all these
crayfish show in the young structural characters and habits that
make them unfit for free life like that of their marine relatives,
the lobsters, and better fit them for a life of protected association
with the mother with whom they live as in a kind of elementary
family.

270 THE AMERICAN NATURALIST [Vorn XLI

In this departure from ancestral conditions C. affinis has gone
farther than Astacus in the following respects. In the first stage
and in the second stage the telson is more reduced and both pairs
of antennæ are more simple and to some extent this is also true in
the other species of Cambarus here described. Thus in the first
stage, Astacus has 50 to 66 spines along both the posterior and
lateral edges of the telson while the three species of Cambarus
have spines only upon the posterior edge and they are less than 30.
Astacus also has in the first stage five segments in endopodite and
exopodite of the first antenna and 50 in the filament of the second
antenna while the three species of Cambarus have but four in the
first case and 25 to 35 in the last.

In the first larval stage the three species of Cambarus thus
agree amongst themselves and depart from Astacus in the direction
of simplicity which is presumed to be a secondary reduction in
connection with protected life upon the mother.

In the second larval stage C. affinis alone has spines merely
and no plumose setæ upon its telson and is thus most remote from
fitness for the active life of its ancestors. In the second stage
Astacus is most like a free form in having its telson fringed with
much more perfect and numerous plumose setæ than are found in
C. clarkii or C. diogenes. In Astacus also the first antenna has its
ear-pit well overarched by a row of plumose setze but in C. clarkii
there are only 3 or 4 plumes, in C. diogenes but one plume and in
C. affinis only minute spines and no plumes. In Astacus the
second antenna has 54 segments, in C. diogenes about 40, in C.
clarkii 34 and in C. affinis 39. In C. affinis alone is there a reten-
tion of simple spines such as occur in the first larval stage, so
that the scale of the second antenna here still bears no plumes.

Thus in the second stage C. affinis is most removed from Astacus
but C. diogenes and C. clarkii depart less from the ancestral Asta-
cus-like form.

Likewise in habit the three species of Cambarus agree in remain-
ing attached to the parent during the second stage but in Astacus,
however, as far as known, the larvæ become free in the second
stage.

Apparently also Cambarus is more fitted to family life than is
Astacus by having the anal thread at the time of passing from the
first into the second stage.

No. 484] ATTACHED YOUNG OF CRAYFISH 271

From consideration of the larval life we come to the same
general conclusion as that generally drawn from study of adult
anatomy and geographical distribution, namely that Cambarus
is a more highly evolved form than Astacus and that C. affinis is
one of the higher, more specialized forms of the genus.

As to the relative position of C. clarkii and C. diogenes there is,
however, doubt and discrepency. The adult characters seem to
leave no doubt that C. clarkii is much the more primitive, less
specialized and more like Astacus of the two. But in the adjust-
ment of the larva to family life C. diogenes would seem to have
progressed less far than C. clarkii, at least in the first stage C.
diogenes has more segments in its second antenna and in the second
stage more, sense sete in the first antenna as well as more segments
in the second antenna. On the other hand C. clarkii would be
more primitive in having more sete over the ear-pit and if in
nature the young actually get loose from the mother in the second
stage they would be more like Astacus.

Yet in future study of crayfish it would seem that regard should
be paid to the first three larval stages as aids in determining the
relative positions of the species and their probable derivation
from ancestral forms.

From a thorough study of larvæ of many species and from experi-
ments in cross breeding some idea might be got as to the nature
of the causes that seem to be leading some of the more evolved
crayfishes to develop further that association of parent and off-
spring which forms in the crayfish a simple stage in family life.

December 20th, 1906

EXPLANATION OF PLATES.

All the figures were drawn with camera lucida and the Zeiss lenses indicated and
were reduced to one third in diameter. nde represent the first and second stages of
Cambarus clarkii. Figures 1, 3, 6, 17 are from living and the rest from preserved
specimens, fixed in Worcester’s liquid.

Fig. 1. Larva just hatched f gg with which iti ted by the telson-

thread: 2.90

Fig. 2. Dorsal face ee telson of bs larva with attachment of telson thread and
internal opods,

Fic. 3. Dorsal mt a a Be aor teased out from ed STE to hatch, showing
investing cuticle over the glandular mar, en. BD,

Fie. 4. Enlargement of part of an a Beste rans ne pores attachment of
e. an‘

nes. re D.
Fie. 5. Com arg o: ee views z sections of part of margin of telson of
first sta
Fic. 6. Right. uae of] oat larva in second stage. 2.90 mm, aa,

Fig. 8. Dorsal face of left antennule of first stage. 2 Pes
Fia. 9. Sues face of left antenna of first stage.

Fie. 10. Outer face of left mandible of first stage. is ve
Fie. 11. Outer face of left first maxilla of first stage. 2. A

eQ
Fig. 13. ing face of left first eta of first stage.

% ter face of lef ped of ont stage,
Fig. 15. _ reste! face of left third cig mooie first re 2:
Fie. 16. Posterior face of left chela of first stage.
Fig. 17. Dorsal view of tip of chela of first stage ur DD
Fic. 18. Posterior face of left fourth pereiopod = stage, 2 A;
Fig. 19. Anterior face of a left pleopod P first WP
Fie. 20. Tips of chela of second stage. i,

me
WEITER

SS
ay tas

NOTES AND LITERATURE
BIOLOGY

Beebe’s Log of the Sun.'— Merely to turn over the pages of this
beautiful book dispels all desire for captious criticism. The pub-
lishers have done everything to present it to the public in the best
shape while the fifty-two full page plates in color by Walter King Stone
and the numerous text figures from photographs and from wash and
charcoal drawings make the work a delight unto the eye. Each of
the fifty-two weeks of the year has its chapter; in some cases chosen
with a full appreciation of the fitness of things, in others placed in
position because one week would do as well as another. Some of
these chapters have previously appeared, without illustration, in
other places, while others were prepared expressly for this volume.
Naturally the birds attract the most attention, with the mammals a
close second, but other chapters deal with reptiles, fishes and insects,
while the invertebrates of the sea are not neglected and even those
marvels of crystallography, the snow flakes, have their allotted space.

The text itself is written in an easy, graceful manner with a full
appreciation of the wonders of nature and with the most sympathetic
spirit. Here and there, perhaps, ‘a statement is exaggerated or, may
be, a slight mistake is made but these are but’ slight blemishes and
they shall not be detailed here. Read the book, look upon the living
world about you — sea, shore — plain or forest — with the open eyes
of the author and you will see the marvels he has seen and a myria
others of which he tells you nothing.

Laloy’s Parasitism and Mutualism.— Dr. Laloy devotes an intro-
ductory chapter of his recent work? to a consideration of the various
reciprocal relations between living things of which series parasitism
and mutualism are the opposite extremes. Following this the first
part deals with parasitism under seven chapter headings: generalities,

‘The Log of the Sun; a chronicle of Nature’s Year. By C. William
Beebe. New York, Henry Holt & Co., 1906, pp. xii + 345, $6

*Parasitisme et Mutualisme dans la Nature, par le Dr. L. Laloy, biblio-
thécaire de l’Académie de Médecine. Préface de M. A. Giard, professeur à
la Sorbonne. 1 vol. Bibliotheque Scientifique internationale; 82 text fig-
ures, 6 fr, Félix Alcan, éditeur, Paris 1906.

275

276 THE AMERICAN NATURALIST [Vor. XLI

plant parasitism, plants parasitic on animals, animals parasitic on
plants, animal parasitism, the röle of parasites in pathology, and
finally parasitism in the evolution of species. This last chapter
presents in striking fashion an opinion previously advanced by this
author regarding embryonic and sexual parasitism.

In the second part, devoted to mutualism, are grouped under separate
chapters discussions of social life among plants, mutualism between
plants and animals, social life among animals, and mimicry. Under
these headings are discussed many interesting questions of an unusual
sort. ‘The author has selected instances of an illustrative type and
presents them clearly and attractively.

he scope of the work is uncommonly large, embracing as it does
both plants and animals and scant 300 pages are narrow limits in
which to present such discussions in a form to escape criticism. To
a zoologist it appears as if on the whole too great space had been given
to the plant side and yet this may be distorted perspective on the part
of the reviewer. The figures deal almost exclusively with plants and
insects, with the former largely in the majority.

In many respects the work hardly represents present knowledge
on the subjects discussed. Thus, in speaking of the hookworm, to
which the author devotes a considerable section, the statements that
this parasite sucks blood is perhaps excusable, though in 1903 Looss
showed it to be incorrect, and this work has been much commented
upon and quoted, as well as confirmed, since then. However to
outline the life history with the larva encysted in a resistant envelope
and infection taking place by the mouth is astonishing in view of the
experimentation and discussion in this field for the past three years or
more. Other statements are open to the criticism at least of serious
exaggeration, such as that Yellow Fever caused one hundred deaths
per annum in Havana under Spanish rule, or that in the Tæniæ
one finds only internal autofecundation.

On the other hand the accounts of malarial organisms, of yellow
fever and of trypanosomes are as good as could be given in the space
at command. In the latter cases use was made of the admirable
work of Blanchard, Laveran and Mesnil, while in the former the
authority cited was not so trustworthy. In fact the author does not
seem to know the literature of his subject thoroughly. He cites almost
alone the French authors and does not differentiate clearly their work.
Where his selection is happy the text is admirable, but at times the
choice of an authority is less fortunate and the text suffers.

Some lack of knowledge shows itself also in the use of such long

No. 484] NOTES AND LITERATURE arr

since abandoned names as Tenia cucumerina and Distomum hepati-
cum. Better figures could have been found almost anywhere than
those he gives of Tenia solium and tapeworm embryos; that of
Cerurus cerebralis is clearly wrong and the cut of a liver fluke is little
more than a blotch of ink. On the other hand many of the botanical
illustrations are excellent, and none are really poor. Neither author-
ity nor credit is given for any figure, though many, if not most of them, _
are copied from other authors.

Despite these criticisms and an evident lack of control of his field
in some places, Dr. Laloy has produced an usable work. e
material brought together here is scattered widely and both unknown
and inaccessible save to the specialist. The order is logical, the
presentation clear and the author manifests the characteristic French
ability to secure and hold the attention and interest of his readers.

GEOLOGY

Relative Geological Importance of Continental, Littoral, and Marine
Sedimentation. — Professor Joseph Barrell has given us! a critical
discussion of the conditions under which continental, littoral, and
marine sedimentation take place, the classification of the three types
of deposits, the evidence upon which they may be discriminated, and
the probable areal and vertical extent of the deposits of each class
now found in the geological column. It is shown that the littoral
zone is of exceedingly small extent, its deposits less likely to be pre-
served than the deposits of the other two zones, and that unless a
given formation is undoubtedly of littoral origin it is more likely to
be either marine or continental. The regions of continental sedimen-
tation are shown to be far more extensive than generally believed,
the chances for the preservation of continental deposits often very
good, and that therefore a much greater proportion of ancient sedi-
ments is likely to be found of continental origin than is generally
conceded. ‘The last part of the essay deals with the origin and pre-
servation of mud cracks, and their value as a criterion of continental
rather than of littoral sedimentation. It is shown that contrary to the
usual interpretation, mud cracks generally furnish one of the surest

1 Journal of Geology, 14, pp. 316-356, 430-457, 524-568, 1906.

278 THE AMERICAN NATURALIST [Vor. XLI

indications of the continental origin of a given formation. Applying
the results of his studies to specific portions of the geological column,
the author concludes that certain important formations, heretofore gen-
erally referred to a marine origin, are most poopy continental
deposits.

Professor Barrell’s paper is an important contribution to a series
of studies which are resulting in-a very manifest movement away
from the former tendency to regard all sediments as marine unless
definitely proved of some other origin, toward a fuller recognition
of the importance of continental sedimentation, and a more open
attitude of mind to such an alternative interpretation.

BW J

Observations in South Africa.— Professor W. M. Davis presents!
a variety of geological and geographical observations made during
his visit to the Colonies of South Africa in the summer of 1905.
After a brief introduction, in which the going and return journeys
are sketched, the physiographic provinces of South Africa are out-
lined, and the problems to be considered briefly stated. The next
twenty pages are mainly concerned with a study of the Cape Colony
ranges considered with special regard to their resemblance to the
Allegheny mountains of our own country, both groups belonging
to the class of much dissected folded mountains. ‘The famous
Dwyka glacial formation of Permian age is next discussed in some
detail, some twenty pages dealing with the character of the evidence
upon which reference to a glacial origin is based, the topography
of South Africa during Dwyka time, and the possible causes of the
Dwyka glacial period. The third portion of the paper deals with
the peneplain of the Veld or interior highland, and the conditions
of its origin, the evidence being weighed with a desire to discriminate
if possible between normal peneplanation as one alternative, and arid
leveling without baseleveling as the other. Other problems of interest,
such as the origin of the zig-zag gorge below the Victoria falls of the
Zambesi, and the probable greater extent of South Africa in former
times, are considered. Eight plates and a number of drawings serve
to illustrate the paper.

DI Ws

Geology of the Big Horn Mountains.’— The results of five seasons’

field work in the Big Horn Mountains of Wyoming and Montana

! Bulletin Geol. Society of America, 17, pp. 377-450, 1906.
2 U. S. Geological Survey, Professional Paper No. 51, 1906, 128 pp.

No. 484] NOTES AND LITERATURE 279

are embodied in this splendidly illustrated report by Mr. N. H. Darton.
After a preliminary consideration of the geography of the region,
an extended and detailed account of the various types of rocks repre-
sented in the range is given. The glacial geology is discussed by
Professor R. D. Salisbury on the basis of work done by several assist-
ants. The results of glacial erosion are very pronounced, splendid
examples of cirques, U-shaped valleys, and glacial lakes being found,
the amount of valley-deepening due to glacial scour being placed as
high as 700 feet or possibly more in cases. The structure of the
range is next considered, the uplift being in the nature of a great
anticline with a somewhat prominent local dome toward the southern
end, while minor flexures and faults occur. The general geologic
history of the region is traced, and in conclusion the mineral resources,
water supply and timber are described. Some years ago Mr. F. E.
Matthes prepared an unusually valuable contour map of the central
portion of the range and discussed the feature due to glacial sculpture
Mr. Darton’s report gives a comprehensive account of the general
geology, adding much to our knowledge of this interesting region.
D. W

Weds

A Glacial Lake in Tibet.— Mr. Huntington has spent several seasons
in the study of geological and geographical features in central Asia,
and presents in this paper’ an account of a lake which seems to owe
its origin to glacial erosion, and which closely resembles the famous
valley lakes of Switzerland. According to previous observers the
lake has been formed by the damming of an old outlet by fans spread
out across the valley by tributary streams; but Mr. Huntington
presents pretty clear evidence that the basin is terminated by a rock
lip rising well above the present level of the lake, and of course much
_ farther above the lake bottom, the lake being 142 feet deep according
to F. Drew. There seems to be no evidence of warping or faulting,
while the evidence of strong glaciation is abundant. The features
observed would seem to indicate a true rock basin of appreciable
depth scoured out by the valley glacier. Fluctuations of climate are
recorded by a number of elevated beaches marking oscillations of
lake level. The paper is illustrated with a map and numerous draw-
ings and photographs.

D W. J.

1 Pangong: A Glacial Lake in the Tibetan Plateau. By Ellsworth Hunt-
ington. Journal of Geology, Vol. 14, 599-617, 1906.

280 THE AMERICAN NATURALIST [Vorn XLI

ZOOLOGY

A Statue of Lamarck.— As yet there is no memorial to this emi-
nent naturalist but now it is proposed to erect one in the Jardin des
Plantes in Paris. The matter is in charge of a committee of the
Museum d’Historie Naturelle in Paris; subscriptions may be sent
to Professor Joubin, the secretary, 55, Rue de Buffon, Paris, France.

Gardiner’s Maldive and Laccadive Archipelagoes,' parts of which
have been noticed in these pages as they have appeared, has now
been completed. The whole makes two quarto volumes of 1079
pages and 100 plates. In this concluding part is an account of the
Myriapoda collected by R. I. Pocock enumerating eight species, and
some supplementary remarks upon geographical distribution and
comments upon the coral reefs, apropos of Mr. Agassiz’s work in the
same region.

Kollmann’s Atlas of Human Embryology.” — This is, as its name
implies, an atlas of development. There is no true text, merely
descriptions of the three hundred and forty figures which are intended
to illustrate the features of human embryology. These figures,
which are in part printed in tint,in part in color, are of varying degrees.
of artistic excellence and have been taken from various sources, a
goodly proportion of them being original. ‘Those in half-tone made
from wash drawings are with few exceptions excellent, while those
made by the zinc process are usually more crude. In a few cases
other animals than man have been called upon to supply the illus-
trations. Thus the early phases of the mammalian orums are based
upon Sobotta’s well known figures of the egg of the white mouse;
Bonnet’s work upon the dog and Selenka’s upon the apes are called
in to illustrate other early features; while chick and fish furnish illus-

1 The Fauna and Geography of the Maldive and Laccadive Archipelagoes
edited by J. Stanley Gardiner, Volume 2, Supplement 2, Cambridge [England]
1906. 3s, 6d.

2 Handatlas der Entwicklungsgeschichte des Menschen von Dr. Julius:
Kollmann, Erster theil; Progenie, Blastogenie, Adnexa Embryorum, Em-
bryologia Osseum, Embryologia musculorum. Jena, Gustav Fischer, 1907.
Mk. 15, Gebunden.

No. 484] NOTES AND LITERATURE 281

trations of monstrosities, and the development of the skull is intro-
duced by Schauinsland’s figures of Callorhynchus, and Stöhr’s of the
salmon.

While the work has considerable value for the medical student
in that the illustrations supplement those of the usual text book,
the morphologist finds the volume less adapted to his needs. One
might wish figures showing the early stages of the vertebral column,
more details regarding the development of the lower jaw, better
illustrations of the embryonic adnexa, and some connection between
the figures of the head cavities and the definitive eye muscles which
develop from them. Three figures illustrate the development of
the diaphragm. In two only the septum transversum is shown;
in the third the diaphragm has nearly its definitive condition, but
there is nothing to show the origin of the ‘pleural portion.

The Systematic Position of the Tubinares— In a recent number:
of this journal (41, p. 111, 1907), Dr. Shufeldt in the historical intro-
duction to his paper ‘On the osteology of the Tubinares,’ has this to.
say about my treatment of these birds in the Standard Natural His-
tory, vol. IV, pp. 84, seq., (Boston, 1885): “ This writer places in his
scheme the Tubinares widely removed from the Steganopodes, which
I believe to be a mistake, and a non-appreciation of the morphological
characters of the latter group of Birds.”

If the main object of the bird volume of the Standard Natural
History had been to present a new classification which in all details
should represent my own ideas, the position of the Tubinares would
have been a different one. That I fully indicated their proper place
and also fully appreciated their ‘morphological characters’ will be
apparent from a perusal of the following quotations from my work:
“The arrangement may not be regarded as final, however, for there
are reasons to suspect that it will be necessary, ere long, to divide the
schizognathous swimmers into three orders, Eretmopodes for the
first two superfamilies of the present arrangement, Tubinares for-
the superfamily Procellaroideze, and Pluviales for the rest.” (P. 65.)

“It has already been hinted at, on a previous page, that the super-
family Procellaroidese might perhaps better constitute a separate
order, Tubinares. Their differences from all the foregoing birds
are many and important, and their affinities seem to be more with
the Steganopodes and Herodiones than with the gulls or the auks,
to some of which many of the petrels show a remarkable external
and superficial resemblance.” (P. 84.)

282 THE AMERICAN NATURALIST [Vor. XLI

And finally, on page 85, I again emphasized the true position of
these birds by reiterating that it is “rather probable that the Tubi-
nares should be placed in the neighborhood of the Steganopodes and
Herodii.”

Professor Fiirbringer, in his last review of this subject (Jena.
Zeitschr. Naturw., 36, pp. 644-646, 1902), does full justice to the
subject as follows: “Stejneger-Cope (85/89) follow Huxley in
the rather unfortunate establishment of the Cecomorph#, but Stej-
neger mentions particularly that the Tubinares perhaps are better
regarded as a special ordo with nearer relation to the Steganopodes
and Herodii....On the strength of later considerations I still adhere
essentially to the opinion expressed by me in 1888, but I am inclined
to place their relationship to the Ciconiiformes more in the foreground
and that to the Laro-Limicolse more in the background than then....
On the other hand, I cannot follow those authors who argue for
placing them too far from the Laro-Limicole,” the group called
Pluviales by me in my first quotation above from the Standard
Natural History.

LEONHARD STEJNEGER.

Beebe’s The Bird’ in the American Nature Series is easily one
of the most useful as well as one of the most interesting books which
this epoch of bird books has produced. It marks, we hope, the begin-
ning of a new period in amateur bird study, a period when many of
those who now keep bird lists as a pastime will take up the serious
study of the bird itself. The book contains seventeen chapters, the
titles of some of which are as follows,— The Framework of the Bird,
The Skull, The Food of Birds, The Senses, Beaks and Bills, The
Eggs of Birds, ete.

Mr. Beebe is curator of birds in the New York Zoological Park.
His position has enabled him to observe at close range the habits of a
great variety of birds, and also to discover the needs of an inquiring
public. Mr. Beebe is, however, much more than a keeper of animals;
he is a trained scientist and a skilful lecturer. He has succeeded in
this book in arranging a large amount of accurate information clearly
and forcibly, and to present it in such a way as to arouse and hold
the reader's interest.

The value of enlarging the amateur student’s horizon is constantly

1 Beebe, C. William. The Bird. Its Form and Function. New York,
Henry Holt & Co. x + 496 pp. 371 figures.

No. 484] NOTES AND LITERATURE 283

in the author’s mind. The first chapter, therefore, presents the
essential facts which paleontology contributes to our knowledge of
the bird, and throughout the book there are frequent and illuminating
references to homologies or analogies in the kindred classes. ‘The
delicate balance of Nature and the complex interrelations of all
organic life are well illustrated in the chapter on food.

Where a large number of forms are discussed it is difficult to avoid
the appearance of a mere catalogue of compiled facts. Evans’ Dic-
_tionary of Birds is a noticeable example of work of this kind. Mr.
Beebe has avoided this danger by a happy introduction from time to
time of bits of personal observation, or by enlarging on some excep-
tionally interesting habit or structure. The reference to a flamingo
observed by Mr. Beebe, weeping from terror because a condor was
playfully “galloping” around it, illustrates also the author’s happy
choice of words.

The suggestion of problems to the solution of which careful observ-
ers can bring assistance, the frequent references to Nature’s evasions
of our pet theories, and the conservative position taken on disputed
points, begets in the reader a strong and deserved feeling of confi-
dence that Mr. Beebe possesses together with his power of picturesque
presentation the wide knowledge and sound judgment of a trained
scientist. Mr. Beebe is evidently a strong believer in sexual selection,
but he puts forth (p. 318) an interesting suggestion that the display
of the male bird instead of affecting the æsthetic sense of the female
may induce some sort of hypnotic condition. In the chapter on The
Body of the Bird (pp. 292-295) there are some interesting observa-
tions on color changes due directly to environment or food. White-
throated sparrows and wood thrushes turned almost black when
confined in a bird house where the air was constantly moist.

The book is extremely rich in illustrations, chiefly photographs
of great clearness and beauty taken from life by the author. Their
excellence adds much to the attractiveness of the work, and the skill
with which they have been selected and arranged is evidence of the
author’s gift as a teacher. There is an excellent index, and a brief
list of useful books.

Though primarily intended for the instruction of amateurs, Mr.
Beebe’s book is one that will at once win an honorable place in the
library of every teacher of natural history. No public library or
school should be without it. It will be the hope of all who use this
manual, that Mr. Beebe will follow it by a similar treatment of the
intelligence of birds.

R H.

284 THE AMERICAN NATURALIST [Vor. XLI

The Conus Arteriosus in Teleosts.— One of the characters which
have been relied upon to distinguish Ganoids from Teleosts has been
the presence in all Ganoids and, with the exception of Butirinus,
its absence from all of the other group. H. D. Senior now shows!
that the tarpon of our southern waters has a conus with two rows
of valves.

Does half of an Ascidian Egg give rise to a whole Larva?— In
reply to criticisms of Driesch, Conklin returns to this question which
was discussed in his earlier papers and maintains (Archiv f. Entwick-
lungsmechanik, 21, 1906) the general correctness of his former account.
The half blastomere cleaves as if it were still part of the entire egg;
correspondingly the resulting gastrule are half gastrule and are in
no wise bilaterally symmetrical and the anlagen of muscles and
mesenchyman unilateral in position. Similarly the larve up to the
time of metamorphosis are half larvee, having only the parts belonging
to one side—right or left—represented. ‘They “are such as would
result if a fully formed larva were cut in the median plane and the
cut edges of each half then came together, the dorsal and ventral
mid-lines joining. These results follow from the early differentia-
tion of the organ-forming substances in the egg.

Digestive processes in Collembola.— Dr. J. W. Folsom and Miss
M. U. Welles have studied the digestive processes in the mid-gut of
Tomocerus and other Collembola? They deny the existence of
Malpighian tubules in these insects and note the fact that they molt
throughout life. In connection with each ecdysis there is a degenera-
tion of the inner half of the intestinal epithelium, the degenerate
portion being cast out soon after the molt, carrying with it a part of
the nuclei which are replaced mitotically from those which persist.
In this degenerating mass is contained sodic urate as well as gre-
garine so that this is an excretory process. Adult specimens molt
every six or eight days; the cast skin is devoured.

Fresh Water Amphipods of North America.— Miss Ada Weckel
furnishes a valuable synopsis? of these forms. In all eighteen species
are described, two (Gammarus ramellus from California and
cecus from Cuba) being new. The author seems to have overlooked

! Biological Bulletin, 12, 1907.
a EET [of R steppes Pa no. 2, 1906.
s t. Mus., 32,

No. 484] NOTES AND LITERATURE 285

the description of Crangonyx knoxensis by O. P. Hay printed (June
27, 1878) on the extras of Dr. Hay’s reprint of his “Description of
a new species of Asellus” from the Bulletin of the Illinois State Labo-
ratory of Natural History, No. 2. This reprint, by the way, possesses
a plate, illustrating Asellus militaris, Crangonyx knoxensis and C.
gracilis Smith, which does not appear in the Bulletin.

‘Some Problematic Worms.— Schepotieff has a valuable systematic
paper! on the interesting worms of uncertain affinities grouped as
Desmoscolicidee, Echinoderide, Cheetosomatide, and Rhabdogaster
and Trichoderma. The article begins with some interesting con-
clusions as to geographic and bathymetric distribution and then
proceeds to the description of the species, illustrated by good figures,
in which numerous new forms are recognized.

C. Davidoff thinks’ that he has found evidences of a true mesoderm
in the larva of the Narcomedusan jelly fish Solmundella. Photo-
graphs of sections which he gives show a distinct cell-layer between
ectoderm and entoderm, not the structureless mesogloea usual in that
position. If this interpretation be correct, it will, as Davidoff remarks,
remove one of the objections to a close association of Ctenophores
with the Cnidaria.

Leisenitz has studied? the chitinose spines occurring on a number
of insect larve which serve as organs of locomotion. Numerous
zine etchings illustrate the kinds of spines and their arrangement.
The results are not readily summarized and have little systematic
importance.

Forbes’ Keys to Lepidoptera and Caterpillars* will doubtless
prove of value to beginners in the study of the butterflies of New
England, while others will find the keys to the larve of use. First
in order is a list of butterflies and larger moths with size and color
markings, food plants of the larvee, dates of imago, number of broods
and haunts; next a key based upon color of the species of large Lepi-

x Zoologischer Anzieger, 31, p. 132, 1907.

? Zoologischer Anzeiger, 31, p. 119, 1907.

4 une chitinöse Fortbewegungs — Apparate einiger Insektenlarven. Mün-
chen, 1906.
, Jsu Tables of Lepidoptera by Ww. T. M. Forbes, Worcester, Mass., 1906,
pp. 1

286 THE AMERICAN NATURALIST [Vor. XLI

doptera found in New England. The second portion (over half)
is given to a key to the caterpillars of all but the smaller Lepidoptera
of the same region.

J. F. McClendon has described four new species of Myzostoma
(Proc. U. S. Nat. Mus., 32, 1907, obtained from the collection of
crinoids in the Niassa! Museum.

BOTANY

Sukkulente Euphorbien.!—This is the first of a series of illustrated
handbooks of succulent plants designed by the author to meet the
_ demand that the scattered literature should be brought together in a `
form accessible to the many cultivators of this group of plants. The
aim is to give both a scientific classification and cultural hints on
those species now in cultivation and this work has been admirably
done, both in the text and in the numerous half-tone illustrations.

One hundred and nine species and eight varieties of Euphorbias
are treated, nine species and two varieties being new to science and
three species have been renamed. ‘The species listed are for the most
part natives of Africa, though a few are from the adjacent islands and
from India, and three are American. A good working key is given
to the twelve sections under which the species are arranged and the
sections again are each provided with good comprehensive keys so’
that a species may be readily determined. The descriptions are full
and clear, supplemented by full synonymy and by additional notes on
habitats and comparisons between species, ending in a short note on
the culture required for the species. Following the treatment of spe-
cies a chapter is devoted to the general culture required for this group
of succulents and the text ends in a full index to the literature bearing
on the group.

In view of the fact that several new species appear in the publica-
tion it may be well to state that, though the title page bears the date
of 1907, copies have been distributed in December 1906.

C. H. Tompson.

1 Berger, Alwin. Sukkulente Euphorbien. Stuttgart, 1907. 12 mo. v +
135 pp. 33 Abb,

(No. 483 was issued March 29, 1907)

The first of a series of Colored| —
Plates of the 2 2 2 2 æ =

THRUSHES

>> | Ae

NORTH AMERICA | —

By FUERTES & HORSFALL,

was published in BIRD-LORE for - =
February. 2 2 8 rE ae | 2
The series will be concluded this year _

20 CENTS A COPY. $100 A YEAR | __

Englis
o Magazines

O YOU know them—know what they are publishing—
read them— subscribe for them? There are THE
EDINBURGH REVIEW and the QUARTERLY; the
CONTEMPORARY, FORTNIGHTLY, MONTHLY,
I , WESTMINSTER, and NINETEENTH

SATURDAY
he OUTLOOR, PUNCH and

THE |
AMERICAN
NATURALIST

A MONTHLY JOURNAL
DEVOTED TO THE NATURAL SCIENCES
IN THEIR WIDEST SENSE

CONTENTS

I. The Functions of the Spiracle of the Skate fen HERBERT W. RAND

Il. A ia and Statistical Beaty x of the Determination of si, particularly in z
uman Offspring F. H. PIKE 303

II. Chubs’ Nests . . . . Bs ALFRED W. 6. WILSON

IV. Notes and Literature: Genera/ bales: Mendelism, — The. problem of age =

‚growth and death. The hypothesis of minie. Zoology; Palms and

moth. —_Divided Si of insects. —No tes. Botany; Winter Test
Notes s : [eee oy = :
V, Correspondence: The Fiying Fish Problem en pies ei z
At Publications Received are a Bee

: "BOSTON, ws Ba ee
INN. & oeann, POR = see

e ®
The American Naturalist
EDITOR
FREDERIC T. LEWIS, M. D., Harvard Medical School, Boston, Mass.
ASSOCIATE EDITORS
- JA ALLEN, Pa.D., American Museum of Natural History, = York
_E. A. ANDREWS, Pu. D., Johns Hopkins University, Baltimor
_ WILLIAM S. BAYLEY, Pr. D., Colby University, Waterville
_ DOUGLAS H. CAMPBELL, Pr. D., Stanford University
_ J. H. COMSTOCK, S.B., Cornell Putoetsity: Ithaca
_ WILLIAM M. DAVIS, ME, Harvard University, Cambridge
- ALES HRDLICKA, M.D., U. S. National Museum, Washington
_ D. 8. JORDAN, LL.D., Stanford University
CHARLES A. KOFOID, Pu.D., University of California, Berkeley
, J. G. NEEDHAM, Pr.D., Cornell University, Ithaca
` ARNOLD E. ORTMANN, Pu.D., Carnegie Museum, Pittsburg
=D; F PENHALLOW, D.Sc., F.R.S. C., McGill University, Montreal

ment of
, LL.D., Smithsonian Institution, Washington.
3.D., , Missouri ee Garden, St. u

3 M M. \ WHERLER, PaD., sae TER of : Natural History,

HE Sa NATAT is an illustrated monthly magazine
al History, and will aim to present to its readers the leading
discoveries in General al brane en Ze

> : wheal : ;

> critical summaries of progress in some line; in addition to these

re will be briefer articles on various points of interest, editorial

ote Her eg — of the day, and critical reviews
—

peditions, biogr

thing interesting ‘to say are el
ates for the hig = scientific degrees

he special literature

ill endeavor to select = —
ientifie c — and at =

THE
AMERICAN NATURALIST

Vor. XLI May, 1907 No. 485

CONTRIBUTIONS FROM THE ZOÖLOGICAL LABORATORY OF
THE MUSEUM OF COMPARATIVE ZOOLOGY AT HARVARD
COLLEGE. E. L MARK, Drrecror. No. 189.

THE FUNCTIONS OF THE SPIRACLE OF THE SKATE
HERBERT W. RAND

In the latter part of September, 1904, I spent a few days at the
Woods Hole laboratory of the United States Bureau of Fisheries
for the purpose of making a study of certain blood vessels of the
skate. At that late season the Fisheries laboratory had abandoned
its fish traps and I was supplied with material through kindness
of officials of the Marine Biological Laboratory, which was still
maintaining a trap in Vineyard Sound. One afternoon this trap
was hauled and some seven or eight common skates (Raja erinacea)
were taken. ‘The skates were thrown with numerous other fish
into the bottom of a skiff which was towed back to the laboratory
by the steam launch,— a distance of about a mile. Arrived at the
laboratory, I picked out the skates and threw them into a large
shallow tank for the purpose of washing from them the sand and
debris which had become attached to them in transit. In view
of the fact that the fish had been out of the water nearly an hour
and had been subjected to no very careful treatment, it did not
occur to me but that they were dead, or at least beyond the possi-
bility of reviving. By means of a hose I turned upon them a
copious stream of cold sea water and then I noticed, for the first
time, that feeble respiratory motions were in progress. As I
continued to play the water over the fish the respiratory motions
became stronger. Shortly one skate slid over the opening of the

287

288 THE AMERICAN NATURALIST [Vor XLI

outlet of the tank, closing it, and in a few moments a half inch of
water had accumulated over the bottom of the tank. ‘Thereupon
the skates set up an energetic spouting of water from the spiracles,
— a mode of behavior which had never before come to my notice.
At frequent intervals a large stream of water was ejected from each
spiracle, rising vertically to a height of one or two inches. (The
fish were of uniform size, — about a foot in width across the pectoral
fins.) ‘The animals were not submerged, it should be remembered,
but were less than half covered with water, most of the dorsal
surface, including the spiracular region, being well out. ‘The
vigor and frequency of the spouting and the fact that so many
skates were doing it at the same time produced an effect striking
enough to compel attention. No doubt this behavior has been
observed previously by others. A “Spritzloch” is certainly a
spout-hole. But I could recall having met only the briefest
reference to the use of the elasmobranch spiracle in respiration,
so I postponed the fate of some of the skates and placed them in an
aquarium supplied with running sea water, with a view to watching
their respiratory movements. During the next few days I observed
the fish as I could, but other work had precedence, so that I was
unable to carry on any systematic study of their behavior. How-
ever, my impromptu experiments brought to light one or two
facts which seem to me worthy of mention.

As must be well known, the modified first visceral cleft (spiracle)
serves in the skate chiefly as an incurrent opening for the respira-
tory stream. So far as this function is concerned, as pointed out
by Garman (’74), the spiracle is probably of greater importance
in the rays than in the sharks, owing to the fact that the rays, for
the most part, lie flat upon the bottom of the sea, and this habit
places the mouth at a disadvantage as an incurrent respiratory
opening, while in the perpetually roving sharks such is not the case.
These facts are very likely connected with the fact that the spiracles
occur as large openings in all the rays while in many of the sharks
they are either very small or completely closed.

Many writers make the statement that water may pass either
into or out from the-mouth by way of the spiracle. Garman (’74)
notes that, whereas the sting-rays have in the spiracular passage a
valvular fold preventing outflow, in the common skate no such

No. 485] THE FUNCTIONS OF THE SPIRACLE 289

structure is present, so that water may pass either way. Dumeril
(65-70, tome 1, p. 210) states that water usually enters the mouth
through the spiracle, but less frequently passes in the reverse
direction.

While at rest on the bottom of an aquarium, the skate slightly
elevates the head above the surface of the bottom in the manner
described in Brehm’s 'Thierleben (Brehm, ’79, p. 387), which may
well be quoted : “Abweichend von anderen Bodenfischen liegen
sie mit dem Vordertheile ihres Leibes niemals fest auf, sondern
stützen sich so auf ihre Brustflossen, dass in der Mitte ein Hohlraum
bleibt.” Continuing, Brehm’s account says, “Um die Kiemen
mit Wasser zu versorgen, öffnen sie ihre Athemlöcher, indem sie
den Kolben zurückziehen, füllen die Kiemensäcke, schliessen die
Athemlöcher und treiben das verbrauchte Wasser durch die
Kiemenspalten nach aussen.” According to my observations the
skate takes in water not only by the spiracle but also through the
mouth, although considerably more water enters through the
spiracle than through the mouth.

When fully open the external aperture of the spiracle in the
common skate is nearly elliptical in outline, but the curvature of
its anterior margin is much greater than that of its posterior margin.
The anterior lip of the opening bears the rudimentary gill and
the closing of the spiracle is effected mainly by the contraction of
this gilled lip, while the posterior lip, being nearly straight when
relaxed, contracts but little.

In ordinary respiration the spiracle opens and closes with
pendulum-like regularity. During one of the prolonged resting
periods of the fish, the interval between successive openings is
longer than when the fish is active, and the spiracle is not opened
wide,— indeed, the opening may be only a narrow slit. During
more active respiration the anterior lip of the spiracle moves back
and forth with a quick decisive motion and the spiracle is opened
to its utmost width. As the spiracular valve opens, the branchial
region is expanded and a strong current of water is drawn in through
the spiracle, the external branchial apertures meanwhile being
tightly closed. At the same time that the spiracle is open, the
mouth also is opened more or less and a certain quantity of water
enters. I satisfied myself as to the inward current at the mouth

290 THE AMERICAN NATURALIST [Vor. XLI

by watching the movement of solid particles suspended in the
water in the vieinity of the mouth. Much the greater volume of
water, however, appears to enter through the spiracle.‘ During
an expiration the spiracle is shut, while the mouth tends to close
but does not close tightly. The mouth action was always a little
sluggish as compared with the action of the spiracle, especially
in opening. As nearly as I could determine, mouth and spiracle
closed together, but the opening of the mouth was slightly later
than that of the spiracle. As spiracle and mouth close, the bran-
chial region is contracted and the water contained in the gill
chambers is forced out through the gill clefts.

That water does not flow out through the mouth as well as
through the gill clefts during an expiration is probably due to the
action of a well developed respiratory valve similar to those de-
scribed for teleosts by Dahlgren (’99). The dorsal flap of the
valve (Figures 1 and 3, vlv. d.) is a conspicuous bilobed fold of the
oral membrane, while the ventral or mandibular flap — a less
extensive fold — is broadest in the median region of the lower jaw
and becomes much narrower towards the sides of the mouth.
Judging from the relative widths and the positions of the two parts
of the valve, it appears that the prevention of outflow through the
mouth must depend mainly upon the action of the dorsal flap.
Garman (’74) mentions only the dorsal one of these two folds.

The elevation of the forward end of the fish above the surface
on which it rests would seem to facilitate the respiratory process.

1 To observe these respiratory movements I put a fish in a large rectangular
flat-bottomed glass vessel. The vessel was placed upon a high table so that
one end projected some distance beyond the edge of the table. The fish was
induced to lie with its head in the overhanging part of the vessel. I found that
an object held just underneath the mouth could be seen directly through the
head of the fish by looking, at the proper angle, into the spiracle as it opened,
and, similarly, an object held just above the spiracle could be seen by looking
upward into the mouth as it opened. This was sufficient proof that mouth
and spiracle were open at the same time. In order to see the dorsal and ven-
tral surfaces of the head at the same time so that the action of spiracle, mouth
and gill clefts could be observed simultaneously, I viewed the spiracle by
total reflection from the surface of the water. Having the water at a certain
depth and looking upward from underneath the overhanging vessel at just
the proper angle, I could see by reflection the dorsal surface of the head with
sufficient clearness, while at the same time I had a direct view of the ventral
surface of the head.

No. 485] THE FUNCTIONS OF THE SPIRACLE 291

Is the spiracular current ever reversed — that is, does the
spouting occur — in normal respiration? ‘To answer this question

R-----cri.md.

RESPIRATORY VALVE OF Raja erinacea.

IG. 1.— l f the head of e lower jaw and floor of mouth
haying been removed so as to show the roof of the mouth and the dorsal flap
e e (vlv. d. a stril; spr., oral aperture of spiracle.
je 2.— Low ver jaw and anterior part o oor of mouth, showing the ventral or
andibular flap of the respiratory care (vlv. v.). crt. md., cut end of mandi-

soles cartilage.

Fig. 0 = ee section of the jaws at the position of the line x . Figure
je moutl cavity: crt, m andibular cartilage; crt. pal-qd., pala-
to-q pants u eth. or., oral al epithelium; vlv. d., dorsal flap, aroa rey v;
ventral flap, of respiratory valve

292 THE AMERICAN NATURALIST [Vor. XLI

I watched the respiration of skates in aquaria supplied with running
water, observing’ the fish at times when they had not been dis-
turbed in any way for several hours. At such times the rate of
respiration was always slow,— usually from 22 to 30 inspirations
per minute. At fairly regular but long intervals there occurred
a break in the regular alternation of inspiration and expiration.
This break was brought about in the following way. Immediately
after an inspiration (and therefore in a period ordinarily marked
by a contraction of the pharynx with closed spiracle and open
gill clefts) the spiracle remained open and the gill clefts remained
tightly closed while a particularly vigorous contraction of the
pharynx caused the contained water to be ejected forcibly from
the spiracle. It is apparently by muscular action that the gills
are kept closed during the spouting, since the pressure of the
water in the gill chambers would tend to force open the external
valves. During the spouting the mouth was open, as it is during
inspiration, and some water escaped from it, but very little as
compared with the amount ejected from the spiracle. It is doubt-
less due to the respiratory valve that the outflow from the mouth is
not greater. The contraction which caused the spouting was
immediately followed by an expansion of the pharynx, the spiracle
still remaining open and the gill clefts closed, and respiration
then proceeded in the usual way. In animals which had been at
rest for several hours, the rate of respiration being then at its
lowest, the spouting occurred at intervals of five to ten minutes.

Having found that spouting is a feature of normal respiration
in a resting fish, I next sought to discover what part the spouting
plays in the respiratory process. With this end in view, I observed
the fish under other conditions than rest.

Effects of Exercise—— The rate of respiration in a fish varies
with the degree of activity. To induce rapid respiration I caused
the fish to take exercise. This was effectively done by grasping
and holding the skate firmly by the tail. The most violent efforts
are made to swim away from the detaining grasp. Following
are accounts of several experiments in which the rate of respiration
was caused to vary.

(1) A skate had been undisturbed over night in an aquarium
supplied with running sea water. When first observed in the

No. 485] THE FUNCTIONS OF THE SPIRACLE 293

morning the fish was at rest, the respiration being very slow and
the spouting infrequent, as described above for the resting condi-
tion. I have no record of the precise rates in this case. The
fish was then exercised and immediately removed to a shallow
tray of water for easier observation. ‘The rate of respiration was
markedly increased, rising to 47 inspirations per minute, dnd a
spouting occurred on the average after every nineteenth inspira-
tion, that is, a little oftener than twice a minute. This average
was obtained by counting the number of inspirations within a
period covered by eleven successive spouts. The actual number
of inspirations between two successive spouts varied from 15
to 23.

In a similar case the rate of respiration while at rest was 22
inspirations per minute, with spouting at intervals of several
minutes. After exercise the rate of respiration was 39.5 per
minute, with a spouting after every seventeenth inspiration, or at
the rate of 2.3 spouts per minute.

(2) A skate which had been undisturbed, so far as I know, for
two days was found resting quietly against the side of the aquarium.
‘The rate of respiration and the frequency of spouting were deter-
mined. ‘Then the-fish was exercised vigorously for five minutes,
after which it was given five minutes to become quiet so that
observations could be made. Following are the results of the
experiment.

o. of No. of . of
Inspirations Inspirations Spoutings
per tween per
Minute Spouts Minute!
Resting 30 246 0.12
After exercise 47.5 67 0.71
‘Increase 58% 500%

(3) A skate which had been under experiment was allowed
to rest for about.an hour. At the end of that time the rates of
respiration and spouting were determined. ‘Then during the next
half hour the fish was subjected to some annoyance by irritation

1 The rate of spouting is thus expressed for the sake of ready comparison
with the rate of respiration (first column). Thus, a spouting rate of 0.12
means that the spouting occurred at intervals of about eight minutes.

294 THE AMERICAN NATURALIST [Vor. XLI

of the spiracle and neighboring parts (see page 299). After these
experiments the fish was exercised vigorously for a minute or so,
after which the rates were again observed. Following are the
results of the experiment.

No. of No. of No. of
Inspirations Inspirations Spoutings
per n per
Minute Spouts Minute
Immediately after one hour’s rest 47 55 0.85
After a half hour’s annoyance, fol-
lowed by brief violent exercise, 63 42 1.5
Increase 34% 77%

The high respiratory rate (47) immediately after the hour’s
rest apparently means that the fish had not recovered from the
effects of the experiments which preceded that hour, a rate as high
as 57 having been induced in the course of these experiments.

(4) In a skate immediately after exercise, conditions were as
shown in the following table.

of No. of No. of
Inspirations Inspirations Spoutings
per etween per
Minute _ Spouts Minute
(a) 49.5 9 1.0

This skate was then left undisturbed about three hours in a
small vessel of water, which was not changed during that time.
At the end of the three hours the rates were as follows.

No. of No. of No. of
Inspirations Inspirations Spoutings
per per
Minute Spouts Minute
(b) 39 78 0.5
Decrease in rates, compar-
ing (b) with (a) 21% 50%

Immediately after the record (b) was obtained, the fish was
exercised and put into well aerated water. After five minutes
(to allow the fish to become quiet enough for observation) the
conditions were: —

No. 485] THE FUNCTIONS OF THE SPIRACLE 295

0. No. of No. of
Inspirations Inspirations Spoutings
r r

pe tween pe
Minute Spouts Minute
(c) 49 22.5 2.2
Increase in rates, comparing
(c) with (b) 26% 340%

In this experiment the rates of respiration and spouting are in-
fluenced by two factors, exercise and the quality of the water,
and the effects of these two factors can not be separated in the
results. The experiment is cited because it shows strikingly,
and in accord with other experiments, that, as the rate of respira-
tion rises and falls, the rate of spouting likewise rises and falls,
but in much greater proportion.

(5) Another observation shows the effect of quiescence. A
skate immediately after exercise breathed 40 times per minute
and spouted twice per minute. After three hours’ quiescence
(during the first hour of which the fish was extremely restless),
the frequency of breathing had decreased 44%, while the frequency
of spouting had decreased 68%.

In several other experiments similar to those just described the
same general results were obtained. Fish which had been resting
quietly for several hours were found to breathe from 22 to 30 times
per minute, while the spouting occurred at intervals of several
minutes. After vigorous exercise the frequency of breathing
was always increased to a rate between 40 and 60 per minute and
the spouting occurred once per minute or oftener. Thus, when
the rate of respiration becomes more rapid as the result of exercise
following a period of rest, the frequency of spouting is increased
also, but in much greater proportion. A very rough average, from
all of the observations taken together, shows that, whereas the
rate of respiration is increased about 100%, the rate of spouting
is increased at least 500%.

With quiescence, the rates of respiration and spouting drop
towards the low resting rates, but the spouting rate falls off rela-
tively much more rapidly than the rate of breathing.

Effects of Partial Asphyxiation.— Is the frequency of spouting
affected by partial asphyxiation? ‘The behavior of the fish when
first brought into the laboratory suggests this question. The fol-
lowing experiments were made.

296 THE AMERICAN NATURALIST [Vor. XLI

(1) A skate was put into a rectangular glass vessel measuring
about 12 by 18 inches, containing sea water to the depth of about
3 inches. The fish was allowed to become quiet and then was left
undisturbed for two hours, during which time a copious stream
of water was flowing into the vessel. At the end of this period
the animal was found resting quietly, respiration being at the rate
of 22 per minute, while spouting occurred at very irregular intervals
averaging about 14 minutes.

The stream of running water was now shut off and the fish was
left in the vessel without change of water for about three hours.
During the earlier part of this time there were alternate periods
of quiet and unrest. In one of the periods of quiet, the respiration
was slow and the spiracle was only slightly opened. But after a
minute or two of these resting conditions, respiration became
markedly quickened, the spiracle being opened wide at each
inspiration, and shortly the fish raised its head and began to swim
about, usually trying to swim up the low vertical side of the aqua-
rium so that the head was thrust out of the water. This activity
lasted usually less than a minute, after which the fish dropped to
the bottom of the aquarium and became quiet, the respiration at
once slowing down to the normal resting rate. Sometimes the
performance was varied in that the quickened respiration which
marked the close of an interval of rest was followed, not by the
swimming activity, but by a vigorous spouting, after which slow
respiration was resumed. At still other times the period of unrest
was marked by both the swimming and the spouting. Occasion-
ally the spouting occurred also in the resting intervals.

During the second hour after the incurrent stream of water
was shut off the alternate periods of rest and unrest continued.
The rate of respiration, however, gradually increased, reaching
a maximum at the end of the second hour when the fish was
breathing 59 times per minute and spouting about once per min-
ute. Respiration was equally rapid during rest and unrest. ‘The
activity was often much more violent than in the first hour of the
experiment.

In the third hour of the experiment the rate of respiration
diminished with increasing rapidity. Following is the record
(the running water having been shut off at 1.00 P. M.).

No. 485] THE FUNCTIONS OF THE SPIRACLE 297

3.00 P. M. Rate of respiration 59 per minute

ER wo 3% G H

345°" it ee = 88: 7

400 “ a z 40 “ =
The spouting continued at the rate of about once per minute.
The resting periods were considerably longer than in the pre-
ceding hours and the activity was less violent. The fish evidently
was becoming sluggish. Returning at 4.10 to observe the fish,
I found the respiration obviously much slower and rapidly dimin-
ishing in frequency. Before I could determine the rate the
respiratory motions suddenly became very irregular and spasmodic
and then the action of the spiracle abruptly stopped. I waited,
perhaps half a minute, and then, fearing a premature end to the
experiment, I turned into the aquarium a stream of water, washing
it about the head of the fish. Within a minute feeble and slow
respiratory movements began, shortly followed by four vigorous
spoutings in rapid succession. Respiration quickly became stronger
and its rate increased rapidly, reaching 48 per minute at 4.22 o’clock.
The rate of spouting, at the same time, was 1.5 per minute, an
increase of about 50% over the rate at 4.00 o’clock.

At 4.29 the fish was taken out of the water and left lying on the
table top. For several minutes it struggled vigorously, but at
the end of eight minutes the respiratory motions had ceased and
there was little muscular reaction anywhere— the fish was quite
limp. The heart, however, was beating strongly. Then the
animal was put into well aerated sea water. At first no sign of
returning activity appeared. The spiracle was wide open and
motionless. I therefore began kneading the gills and directed a
stream of water into the spiracle. Almost immediately very weak,
slow and irregular spiracular motions began, and in the course
of two minutes regular respiratory movements were in progress,
although still weak and very slow. The spiracle did not close
tightly, so that some water escaped from it at each expiration.
This was not regarded as spouting. ‘The action of the spiracle
rapidly quickened and strengthened, and about four minutes
after the fish was returned to water I began to count the rate of
spouting which was then occurring frequently. The count was
made through three successive minutes. During the first minute

298 THE AMERICAN NATURALIST [Vor. XLI

the spouting occurred five times, while for the entire period of
three minutes there were, on the average, four spoutings per
minute. At the end of the three minutes the rate of respiration
was found to be 41 per minute.
(2) Following is the record of another experiment.
10.00 A. M. A skate was removed from the water.
11.15 A. M. Feeble respiratory motions of gill chambers
and spiracles still in progress at the rate of 28 per minute.
The spiracle is continuously wide open, its anterior lip
contracting very slightly at each expiratory movement.
The mouth is continuously shut.
11.20 A. M. ‘The skate is put into well aerated sea water.
11.21 A. M. The spiracular action is stronger and weak
mouth action begins.
11.25 A. M. The spiracle closes completely at each expira-
tory movement.

Inspirations Inspirations Rate
per etween
Minute Spouts Spouting

11.30 A. M. 35 25 1.4
11.39 a 39 1.0
11.47 47.5
11.48 (The first swimming motions occurred.)
12.12 F. M. 57 76 0.75

47 55 0.85

These experiments, then, so far as they go, indicate that, under
conditions of gradual approach toward asphyxia (as when a fish
is left in a small volume of unchanged water), there is for a time
increasing restlessness attended by a rising rate of respiration and
greater frequency of spouting. In the cases closely followed,
there were, early in the experiment, alternate periods of rest with
slow respiration, and periods of activity with rapid respiration
and frequent spouting. This behavior suggests that, as the fish
rests normally for a time, it begins to suffer discomfort because
of the deterioration of the water. There ensues, then, a brief
period of moving about and rapid breathing and spouting. ‘The
momentary quickening of the respiration restores comfort and
the fish sinks to rest again, soon to repeat the whole performance.

No. 485] THE FUNCTIONS OF THE SPIRACLE 299

Later in the experiment the rate of respiration was continuously
high, with frequent spouting.

At the near approach of asphyxia the rate of respiration grad-
ually diminishes, but spouting continues to occur with greater
frequency than under normal resting conditions.

In recovery from asphyxia respiration was at first weak and
slow, but during the first few minutes of the period of recovery
spouting occurred with very marked frequency,— up to five times
in one minute. Within the first hour or two of the period of
recovery the rate of respiration gradually rose and attained a
maximum far above the normal rate in a resting skate, while the
rate of spouting, after the first few minutes of excessive frequency,
gradually fell, as the rate of respiration became higher. But so
long as respiration continued at a high rate, spouting occurred
with much greater frequency than under normal resting conditions.

Spouting Induced by Tactile Stimulation. Some chance obser-
vations led me to try the effect of tactile stimulation of the skin
in the vicinity of the external spiracular aperture. When the
margin of the spiracle was gently touched with the end of a glass
rod or with a stiff bit of eel-grass there usually resulted imme-
diately a spouting from both spiracles at once. But a sharper
stimulation, or persistent annoyance of one spiracle, often resulted
in a vigorous spouting from that spiracle only. When a spouting
had once been provoked by tactile stimulation, the immediate
repetition of the stimulation usually failed to produce a second
spouting. But after an interval of several seconds had elapsed,
renewed stimulation usually brought again the spouting response.

One skate was especially lively and responded to stimulation
much more promptly and energetically than the others. ‘This
animal was experimented with for a brief time in a small tank
containing so little water that the external aperture of the spiracle
was submerged only about an inch. A fairly vigorous prodding
of the skin at the margin of the spiracle by means of the sharp-
pointed end of a bit of glass tubing resulted, in some twelve trials,
in an extremely energetic spouting from the stimulated spiracle
only. ‘This one-sided spouting was provoked first from one spiracle
and then from the other, in fairly rapid succession, by rather sharp
stimulation of the spiracles alternately. The column of water

300 THE AMERICAN NATURALIST [Vor. XLI

was squirted from the spiracle with such energy as to rise through
an inch of water and some seven or eight inches vertically upward
into the air. Frequently the stimulation was followed, not only
by the spouting, but by a sudden dash to another part of the tank,
as if to get away from the annoyance.

Tactile stimulation of the skin in the region of the eye also
usually caused spouting. A gentle touch upon the outer corneal
surface of the eyeball almost invariably provoked a particularly
vigorous spouting from the corresponding spiracle. Indeed, stimu-
lation of the cornea was found to be a more certain way of pro-
voking spouting than stimulation of the spiracle itself. The
response was always immediate and definite and in nearly every
instance unilateral.

I tried also the introduction of solid materials of one sort and
another into the gill chambers. I first tried sand, allowing a little
to sift into the spiracle when it opened for an inspiration. Some-
times a spouting resulted, but equally often, even though a con-
siderable quantity of sand was introduced, no response whatever
followed.

Experimenting in a similar way with another fish, I found in the
aquarium some shreds of filmy substance of doubtful nature.
They appeared like bits of sloughed-off skin. It well exemplifies
the impromptu character of all of these experiments that, making
trial of whatever happened to be suggested by the materials at
hand, I caused some of this doubtful filmy substance to be sucked
into the spiracle at an inspiration. Invariably material of this
sort was promptly expelled by spouting. Often one or two in-
spirations intervened between the one by which the foreign material
was drawn in and the spouting by which it was expelled. Usually
the spouting occurred from both spiracles at once,— rarely from
only the one at which the foreign material was introduced. The
material was always ejected by the same spiracle at which it
entered.

In the one-sided spouting the action of the unstimulated spiracle
appeared to be uninterrupted. The stimulated spiracle simply
remained open during one closing of the other.

Summarizing the foregoing account, it appears that the spiracle
of the common skate serves chiefly as an in-take for the respiratory

No. 485] THE FUNCTIONS OF THE SPIRACLE 301

stream, but at somewhat regular intervals the stream is reversed
and an expiration takes place via the spiracle, which thereby
becomes a spout-hole. With quickened respiration due to exer-
cise, the spouting occurs much more frequently than in the resting
fish. Also, when a skate is confined in a small volume of water
which is not changed, respiration is quickened and spouting occurs
much oftener than under normal resting conditions. Whether
in this case the higher rate of respiration is due directly to the con-
dition of the water, or to the activity caused by the unfavorable
quality of the water, I am unable to say. M’Kendrick (’79) states
that, in the presence of an insufficient supply of oxygen the fish
“breathes hurriedly.” Finally, spouting occurs with excessive
frequency in skates which are just beginning to recover from an
advanced stage of asphyxiation. What, in view of these facts,
is the probable réle of the spouting, so far as it is a respiratory act?
May it not be roughly analogous to “ taking a deep breath”? An
occasional reversal of the respiratory stream may serve to clear
out the gill chambers, resulting in a more nearly complete change
of water in them. ‘The greater frequency of the spouting when
respiration is.quickened, by whatever cause, and its excessive
frequency in recovery from asphyxia indicate, I think, that it has
some importance in the way of increasing the efficiency of the
respiratory process.

Spouting in response to tactile stimulation in the vicinity of the
spiracle indicates that the fish may, under natural conditions, em--
ploy the spout-hole as a means of expelling foreign solid materials
from the gill chambers, or of dislodging objects from the surface
of the body in the region of the spiracles and eyes. The behavior
in respect to sand puzzled me at first. Skates when resting on
the sea-bottom have a habit of settling themselves into the sand
and washing it over their backs in such a way that sand would,
apparently, be very likely to sift into the spiracles, and one might
suppose that sand would be particularly irritating. But in my
experiments the skates were indifferent to the introduction of con-
siderable quantities of sand, while soft filmy materials were
promptly spouted out. On further consideration, it occurred to
me that sand, being a finely divided substance, would easily wash
out through the gill clefts, whereas, being heavy, it could not so-

302 THE AMERICAN NATURALIST [Vor. XLI

readily be forced up through the spiracles. But the larger frag-
ments of soft material (such as bits of sea-weed) are likely to be
caught on the gill-rakers, tending to clog the branchial passages,
and could best be dislodged and expelled by a reversal of the cur-
rents.

The prompt, vigorous, and almost unfailing response to a touch
upon the cornea suggests that the fish regularly employs spouting
as a means of keeping the eyes unobstructed. ‘The external
opening of the spiracle is so near the eye that a stream spurted
from the spiracle would readily wash away foreign objects which
settle upon the eye.

Regarding the spiracle as one of a series of visceral clefts which
were primitively similar in structural relations and in function, it
is evident that, serving as it does such a diversity of uses, it has
come to differ from the more posterior visceral clefts quite as
markedly in its function as in its structural conditions.

BIBLIOGRAPHY.
BREHM, A. C.
’79. Thierleben. Band 8, Die Fische. Leipzig. xvi + 426 pp.,
11 Taf., 145 Textfig.
DAHLGREN, U.
’99. The Maxillary and Mandibular Breathing Valves of Teleost
Fishes. Zool. Bull., Vol. 2, pp. 117-124, 3 figs. in text.
Dumért, A.
65-70. Histoire Naturelle des Poissons. Paris. Tome 1, 720 pp.,
Tome 2, 624 pp.; 26 pl.
GARMAN, 8. W.
74. On the Skates (Raj) of the Eastern Coast of the United States.
Proc. Boston Soc. Nat. Hist., vol. 17, pp. 170-181, 1 fig. in text.
M’KEnDeıck, J. G.
79. On the Respiratory Movements of Fishes. Journ. Anat. and
Physiol., Vol. 14, pp. 461-466, pl. 28

A CRITICAL AND STATISTICAL STUDY OF THE
DETERMINATION OF SEX, PARTICULARLY
IN HUMAN OFFSPRING.’

F. DH. PIKE.
I. INTRODUCTION.

Cutnor (99) and Strasburger (:00) summarized the evidence
in favor of the heredity of sex in animals and plants, respectively.
Rauber (:00) in the same year as Strasburger, declared for the
heredity of sex in man.

Bateson in 1902 suggested that the Mendelian law might apply
to the heredity of sex. Castle (:03), accepting Cuénot’s and
Strasburger’s views without question, formulated an hypothesis
to account for the heredity of sex in accordance with Mendel’s
law. Weldon (:01) had already shown that Mendel’s original
results with cotyledon color in peas differed from the theoretical
numbers by something less than the limits of error. At the time
Castle’s theory appeared, it occurred to me to gather statistics
of births in order to determine in a similar way the probability
that the actual numbers of male and female births would be the
numbers demanded by the hypothesis.

Il. Review or Previous WORK.

The idea that the sex of the offspring could be influenced by
changing the environment of the parents or of the very young
embryo has long been current. Yung’s (’83) experiments on
tadpoles, in which he was apparently able to control the sex by

1 This study was begun under the direction of Professor C. H. Eigenmann
of the Department of Zoology of Indiana University and was completed in
the Hull Physiological Laboratory of the University of Chicago. The author
desires to express his obligations to the health officers and registrars who
have supplied him with statistics; to his colleagues in the Hull Laboratory for
criticism of the manuscript; and to Professor Eigenmann for encouragement
and assistance.

303

304 THE AMERICAN NATURALIST [Vor. XLI

changing the nutrition, have been cited as a demonstration of
this point. Statistics of human births have been judged in such a
way as to lend some support to this view. A good review of this
aspect of the question has been given by Geddes and ‘Thompson
(:01). The validity of such conclusions has been well discussed
by Newcomb (:04), who has made a statistical inquiry into the
probable causes of sex in the human subject. Newcomb concludes
that the causes of sex are beyond voluntary control.

Cuénot repeated Yung’s experiments on tadpoles with contrary
results. Eggs from the same mother, but of different layings,
gave a more constant proportion of males to females than Yung
obtained. The ratio of males to females in the young (54.85%
females) did not differ materially from the ratio (61.5% females)
existing among the metamorphosed tadpoles found in a state of
nature in the vicinity of Nancy. Born (’81) found 52 per cent
of females in the metamorphosed tadpoles near Breslau. Gries-
heim (’81) found 63.63 per cent of females in young Rana tempo-
raria in the vicinity of Bonn. Pflüger (81) found 64.5 per cent of
females in the same vicinity, and 86.8 per cent near Utrecht. The
percentage of old females in the latter vicinity he found to be 51.2.
Pfliiger concluded that the sex was determined in the egg. From
his results on tadpoles and other animals, Cuénot likewise con-
cluded that sex was not influenced by the conditions of develop-
ment. He decided further that there was a certain sexual ratio
common to the frogs of any particular vicinity, and that this ratio
might vary among frogs of different localities. In view of the
comparatively small number of frogs observed, the last conclusion
may possibly be open to question.

Von Malsen (:06) and Issakowitsch (:06), the former for the
worm Dinophilis apatris and the latter for Daphnia, have recently
reaffirmed the statement that an abundance of food and a low
temperature cause a greater number of eggs to develop into females,
while a higher temperature and a scarcity of food result in the
development of a greater number of males. The food supply,
according to them, is the main factor in this process, and the
temperature acts only indirectly by influencing the nutrition.
It is to be remembered, however, that in experiments dealing with
a whole animal, it is difficult to exclude all causes except food and
temperature.

No. 485] THE DETERMINATION OF SEX 305

Strasburger (:00) made many experiments with diecious plants,
growing them on various kinds of soil and under various condi-
tions, in the attempt to modify the sexual ratio. The following
results with Melandrium album may be cited as an example:

TABLE Í.

Females

Kind oj soil Males Females to 100 males.
Fertilized garden soil 410 562 137.0
Unfertilized garden soil 235 282 120.0
Fertilized field soil 384 479 124.4
Unfertilized field soil 254 307 120.8
Sand 321 411 128.0
Totals . 1604 2041 Mean 127.2

Thus sexual ratios for groups of plants grown under the most
diverse nutritive conditions did not differ greatly from the mean.
Strasburger concluded that an arbitrary determination of sex in
dioecious phanerogams has never been accomplished, and he is
inclined to apply this conclusion to all plants.

Rauber (:00) studied statistically the distribution of sex in man.
He found everywhere an excess of male births, but this early excess
in the young was changed, because of the greater mortality of
the males,’ to an excess of females in later life, and particularly
in old age. He showed that the sexual ratio for Europe was 1000
female to 1060 male births, and that this mean ratio was fairly
constant in the different parts of Europe. Reasoning on the basis
that, if sex was determined by environment, the great diversity
of external conditions in the different parts of Europe should
cause a considerable difference in the sexual ratios for the differ-
ent countries, he concluded that sex is hereditary in man.

According to Rauber, there is normally an excess of female
births in horses, sheep and certain other domestic animals.

Punnett (:04a) has made a statistical study of the distribution

1 The relative death rates per million infants of each sex, as determined from
Tatham’s English Life Tables is 161,036 males and 131,126 females during the
first year after birth. The excess of male deaths is 29,910 per million infants
of each sex, or approximately 1.57%. (Cited by Punnett, :04a, p. 265)

306 THE AMERICAN NATURALIST [Vor. XLI

of male and female births in London, in order to determine whether
or not the sexual ratio is affected by the nutrition of the parents.
For this purpose he divides London society into three groups,
following Rowntree’s (:02) division of the society of York. These
groups are (1) the servant keeping class, (2) the artisan class in
which the family earnings are in excess of 26 shillings a week,
and (3) the laboring class in which the family earnings fall below
26 shillings a week. Rowntree found that, compared with a
standard dietary containing 125 grams of proteid and possessing
a total energy content of 3500 calories, the first group has a dietary
containing more food than is necessary for the maintenance of
health; that the second class has, in general, a sufficient diet,
although the family must practice strict economy in order to pro-
cure it; the third class is, as a rule, seriously underfed, the average
deficiency in proteids amounting to as much as 29 percent. Assum-
ing that these considerations apply to London as well as to York,
Punnett finds that there is either no effect upon the sexual ratio
which can be attributed to parental nutrition, or, at most only a
very small effect. He finds also that the statement of Diising as
to the greater proportion of males among the first born children
is supported by the statistics of the English lying-in hospitals.

urthermore, mothers whose first birth occurs between the ages
of nineteen and twenty-three years bear a larger proportion of
males at this birth than mothers whose first birth occurs either
earlier or later in life.

III. Sratisticat Data.

On the fundamental errors in the statistics—— Rauber (:00) has
considered the errors in even the best statistics, and only a
brief discussion of them will be given here. In order to compute
the exact sexual ratio, it is necessary to obtain statistics of all
births, both premature and full term, living or still born. The
effect upon the sexual ratio of disregarding the premature and
still births will be pointed out below. For purposes of heredity,
homologous or duplicate twins, developed from a single ovum,
and invariably of the same sex, should be counted as a single
birth. The author has at hand no sufficient data upon which to
base an idea of the magnitude of the error which might be intro-

No. 485] THE DETERMINATION OF SEX 307

duced by counting such twins as two births. Of the eighteen
cases of twins and triplets considered by Wilder (:04), twelve
pairs of duplicate twins were females. If such a large proportion
of all duplicate twins should be females, the error introduced
would be considerable, and the preponderance of male births
increased. ‘The number of cases given, however, is too small to
warrant drawing conclusions as to the relative frequency of male
and female duplicate twins.

The sexual ratio— The sexual ratios for eleven European
countries, as they existed sometime during the latter part of the
nineteenth century, have been taken from the twenty-eighth annual
report of the Massachusetts State Board of Health through the
courtesy of the late Dr. Samuel W. Abbott. ‘The figure for Eng-
land from 1628 to 1642 is that given by Lexis (’92). The ratio
for the United States was computed from 2,021,955 births —
1,038,432 males and 983,523 females — the statistics for which
were furnished by the health officers of the various states having
reliable statistics of births.

TABLE II.

Number of males

to 1000 females
German ri (1871- ie i ; ; ; 1062
Switzerland. : ; : i 1063
Austria . ‘ i x : i : i : 1067
Italy : : ; ; i i x i ; 1071
France . ; : ; : ; ; : i 1063
Belgium . . o ey i a.
Holland . | : ; ; : i ; i 1063
Denmark . ; . ; : : 1058
England (modera times. ‘tive births only) ; 1038
England ee ; : i ‘ ‘ \ 1068
Sweden } ; Í : ; : 1060
Noms a a, ra
Massachusetts (1876-1896) still births included . 1066
Massachusetts ( ~ ie births nn - . 1088
United States : . 1056

Mean of all ratios A i ; i ; 1060

308 THE AMERICAN NATURALIST [Vor. XLI

A considerable increase in the sexual ratio occurs when still
births are included. The sexual ratio for the city of Chicago,
based upon all births reported in the years 1898 to 1902 inclusive,
(141,233), is 1065. During this period 4828 males and 3554
females were prematurely or still-born. If these premature and
still-births are deducted from the total number reported, the
number of males to 1000 females is 1035. It becomes necessary,
then, to decide whether or not still-births shall be counted. Still-
births must be reported under penalty. Since the living children
are the ones voluntarily reported, their record is not complete;
but we may suppose that the parents are as apt to report a birth
of one sex as of the other. The statistics of living births, there-
fore, in localities where birth registration is not compulsory,
probably approach more nearly to the true ratio than the ratio
based upon both still- and living births. If birth registration is
compulsory, the ratio should be computed on a basis of all births
reported. ‘The ratio for Chicago computed on the basis of living
births only is very nearly the same as the ratio for England. ‘The
ratio for Massachusetts, computed from living births only, is less
than that based upon both living and still births. It is probable,
therefore, that the incompleteness of the statistics is the most
serious source of error.

The constancy of the sexual ratio.— An examination of the sta-
tistics shows a remarkable constancy of the sexual ratio in all
parts of Europe and in the United States, for a period ranging
from 1856 in Massachusetts, through 1871-1880 in the German
Empire, to the year 1902 in Chicago. During these years and in
the various countries, there were periods of war and peace, of
famine and plenty, beside a great variety of racial and climatic
conditions. Yet the greatest variation from the mean, exclusive
of England, is only eleven in 1000 — a difference of one per cent.

In the same country for a period of years, the ratio is approxi-
mately constant. As an example, we may take the statistics for
England (Table III) during the twelve years from 1888 to 1899,
inclusive.

No. 485] THE DETERMINATION OF SEX 309

Taste III.
(Taken from Sessional Papers of the House of Lords)

"Year Total Births Males Females 1000 Females
1899 928646 473172 455474 1039
1898 923265 468920 454345 1032
1897 921693 469180 452513 1037
1896 915331 465660 449671 1035
1895 922291 468886 453405 1034
1894 890289 453016 437273 1036
1893 914572 465711 448861 1037
1892 897957 456622 441335 1034-5
1891 914157 465660 448497 1038
1890 869937 442070 427867 1033
1889 879868 447172 423696 1033
1888 885944 451218 434726 1037
10,864,950 5,527,287 5,336,663 1036

It will be seen that the ratio for any one year does not differ by
more than four in one thousand from the mean calculated from
more than ten million births. As a further example, the sexual
ratio in Massachusetts, based upon living births only, for the years

1856 to 1875 inclusive is 1059. The ratio for the years 1876 to
1896 inclusive, based upon a considerably greater number of births,
is 1053. ‘The mean for the two periods is 1055. ‘The sexual ratio
for the period in which the Civil War occurred differed by approxi-
mately one half of one per cent from the later period of peace,
and by less than one half of one per cent from the mean of the
two periods. If external conditions exerted any effect upon the
parents in such a way as to change the sex of the offspring, the
change due to such influences was not greater than one in two
hundred.

- Social, political and material conditions in England during the
years 1628 to 1642 were vastly different from those during the
years 1888 to 1899, but the difference between the sexual ratios
for the two periods — 1068 to 1000, and 1036 to 1000 respectively
— is not greater than the difference between the ratios for the city

310 THE AMERICAN NATURALIST [Vor. XLI

of Chicago computed upon the living births only for a given
period, and upon all births for the same period. It does not,
therefore, appear necessary to assume with Strasburger that the
sexual ratio for England has changed to any considerable extent
in two hundred years.

The effect of a war upon the sexual ratio.— It has long been a
current belief that more males were born in a period following a
war than in a similar period of peace. Newcomb considers this
‚statement unworthy of serious consideration. It may be said
that, so far as the United States is concerned, such statements are
based upon an insufficient number of births, and that the statisties
are for the most part worthless. I have many letters from state
health officers to the effect that there are now no reliable statistics
of births in their respective states.

The sexual ratio independent of external conditions.— In view
of the remarkable constancy of the sexual ratio under diverse
social, political and material conditions and for long periods of
time in different races, it seems incredible that the determination
of sex should be dependent upon external conditions.

If the sex of the offspring is independent of external conditions,
what is the determining factor? Two general explanations are
open. ‘There is first the possibility that sex is determined by a
series of accidents, as Newcomb suggests, and second, the possi-
bility that sex is hereditary.

The possibility that sex is determined by a series of accidents —
Newcomb likens the sex of a child to a particle floating on a
stream of water. In the early part of its course the stream is
single, but an obstacle divides it into two at the lower part. A
particle entering the stream at the upper part may pass on either
side of the obstacle, the exact course depending upon a multitude
of accidental causes up to a certain point, after which its course
on one side of the barrier or the other is fixed. So with an ovum.
In its early development, there is the possibility of developing into
either a male or a female, the sex depending upon a series of acci-
dents.

Newcomb showed from statistics that the probability that twins
will be of the same sex is .77, and the probability that they will be
of opposite sexes is .23. It is impossible to tell from Newcomb’s

No. 485] THE DETERMINATION OF SEX 3ll

tables whether duplicate twins were excluded, as they should have
been, since but one ovum is involved. If duplicate twins had
been excluded, the probability that ordinary twins would be of
the same sex might have been even less than .77; for duplicate
twins are invariably of the same sex.

Sex determined before the first cleavage of the ovum.— Let us
now examine into the bearing of these considerations upon New-
comb’s hypothesis. ‘To continue his simile, two particles starting
together will have a greater chance of remaining together and
passing on the same side of the barrier than two particles somewhat
removed from each other. Similarly, two ova developing together
(in the same environment) will have a greater chance of producing
ofispring of the same sex than two ova developing at different
times, but neither the two particles nor the two ova invariably
follow the same course. If any series of accidents acting upon the
ovum after fertilization is to determine the sex of the twins, it is.
incredible that it should always produce the same result in both.
Since, however, duplicate twins are always of the same sex, this.
view becomes untenable, and we must limit the action of a series
of accidents to the period preceding and possibly including fertili-
zation. The conclusion that at or immediately after fertilization,
the sex of the offspring is determined once for all seems inevitable.
The effect upon the ovum of any series of accidents must cease
before the first cleavage is accomplished.

Is sex determined by either parent alone?— Having concluded
that- the sex of the offspring is determined at or before the time
of fertilization, we may inquire further whether the sex of the
offspring may not be determined by the ovum alone, or by the
spermatozoon alone. First, the ovum may have the potentiality
of developing into either a male or a female embryo. During
maturation the chromatic material necessary for the development
of an embryo of one sex is cast off in the polar bodies, and that
necessary for an embryo of the other sex is retained. ‘The sperma-
tozoon thus plays a purely asexual rôle. This hypothesis postu-
lates a qualitative reduction of the chromatin in maturation.
According to another variety of this hypothesis the ovum assumes.
the asexual réle, and the sex of the embryo is determined solely
by the spermatozoon. Since all spermatozoa do not produce-

312 THE AMERICAN NATURALIST [Vor. XLI

embryos of the same sex, there must have been, at some period in
the development of the spermatozoon, a qualitative reduction of
the chromosomes, those necessary for a male going into one
spermatozoon, and those necessary for a female into another.
If we accept this hypothesis, we must show why a constant and
unequal proportion of all ova or of all spermatozoa have chromo-
somes, e. g. the accessory chromosome, which will produce an
embryo of a certain sex. As an alternative hypothesis we may
suppose that both ovum and spermatozoon play a sexual röle,
and that the sex of the embryo, in common with other character-
istics, is determined by both sexual elements. This view, as I
shall show subsequently, is the more probable.

If we cannot explain the cause of sex by postulating a series
of accidents of unknown nature occurring after fertilization, can
we explain it on the second possibility,— heredity? And if so,
which of the two great laws of heredity are applicable to the case?
The first question I shall answer in the affirmative, and proceed
to the discussion of the second.

The application of Mendel’s law.— On the basis of Mendel’s
law we must suppose that each ovum has equal chances of develop-
ing into a male or into a female embryo. Given two thousand
ova, chosen at random, the chances are even that a thousand of
them will develop into males and one thousand into females. We
might reasonably expect also that in some groups we would find
an excess of males, and in others an excess of females, but the
mean of all groups would be 1000 each of males and females. '

Punnett (:04b) in order to test Bateson’s suggestion, attempted
an enumeration of the sexes in Carcinus menas. He found an
excess of females in groups of individuals of the same size, but
this excess decreased in groups of younger individuals and there
were indications of an approximately equal distribution of the
sexes at the time of hatching. The exact proportion of the sexes
at the time of hatching could not, however, be determined.

McIntosh (’04,) from a study of the Norway lobster, concluded
that the young were hatched in about equal proportions of the
sexes, but was not able to determine the exact proportion.

Taking the English statistics given in Table III as a basis, we
may compute the probability that the actual distribution of males

No. 485] THE DETERMINATION OF SEX 313

and females would be obtained by such a random choice. Instead
of the theoretical distribution of 1000 males and 1000 females,
the actual numbers of males and females in 2000 births are 1017.6
and 982.4 respectively, or, for convenience in calculation, 1018
males and 982 females. The probability that, in choosing at
random, we should obtain such a distribution is .60984 x 1020,
The probability that in eleven such choices, we would always
obtain the same distribution is infinitesimal. The probability
that, in every case where the births are numerous enough to be
representative of the actual conditions, we should always obtain
practically the same distribution is practically zero. There is
about the same probability that Mendel’s law holds for all these
cases.

A single concrete example taken from organic chemistry will
serve to emphasize this point and perhaps to make this mathemati-
cal abstraction clearer. In the transformation of acetaldehyde to
lactic acid by the addition of hydrocyanic acid, saponification and
oxidation, each of two isomeric forms of lactic acid is, on the
theory of probability, equally likely to be produced. The two

forms differ in optical activity, one being dextro-rotatory and the
~ other laevo-rotatory. Experimentally, it is found that the two
forms are actually produced in exactly equal amounts, and the
mixture of the two is optically inactive. A variation of from
three to seven per cent from the theoretical yield would be fatal
to the theory of probability. In general, in the synthesis of organic
bodies in which two isomeric forms are possible and theoretically
equally probable, the experimental results agree much more closely
with the theory than do the statistical resuits of human births.

Neither ovum nor spermatozoon play asexual roles.— It is evi-
dent that these considerations apply also to the hypothesis that
either the ovum or the spermatozoon play a purely asexual röle.
If we suppose that, in the qualitative reduction of the chromo-
somes, male and female chromosomes are equally likely to be
extruded in the polar bodies, there is practically no probability
at all that we would obtain the actual distribution of males and
females. If the hypothesis is correct, there must be some defi-
nite regulative mechanism of unknown nature which determines
the extrusion of the chromosomes. It is incumbent upon those

314 THE AMERICAN NATURALIST [Vor. XLI

who maintain the truth of such a hypothesis to explain the
nature of this unknown mechanism.

In the case of the accessory chromosome (McClung, :02), the
statement is made that it occurs in one half of the spermatozoa of
Orthoptera and Hemiptera. If we are to suppose that the acces-
sory chromosome acts as a sex determinant, and that sex characters
are to be treated as if they were Mendelian alternates (Wilson,
’07), we should find a sexual ratio equal to unity or differing from
unity by an extremely small per cent. We cannot, however,
account for the determination of sex in the human subject on any
basis of an equal division of spermatozoa into male and female
producing sperms, unless we suppose, as Wilson concedes for the
sake of argument, that sex may be modified by external condi-
tions. The statistical evidence is strongly against this alternative.
If it can be shown that the accessory chromosome occurs in the
spermatozoa of a species in the same proportion as the sex to which
it gives rise occurs in the young of that species, the statistical
evidence in its favor will be increased. At present, there is no
such evidence in its favor, as we do not know the exact sexual
ratio of the species in which the accessory chromosome has been
observed.

The strongest evidence known to the author in favor of the
Mendelian theory of dominance in the determination of sex is
that cited by Harper (:07) in regard to plants. ‘That the stamens
should develop and the pistil be suppressed in the fungus-infected
female plants of the campion is strongly suggestive of the recessive-
ness of the stamens under ordinary conditions.

The application of Galton’s law.— To explain the remarkable
constancy of the sexual ratio by Galton’s law, we have only to
assume that sex, in common with other physical characteristics,
is inherited equally from the paternal and maternal ancestry;
and to explain the preponderance of males in the present genera-
tion, we assume that in this ancestry for five or six generations back,
there has been a preponderance of males. In this we are justi-
fied since there is direct statistical evidence that, for more than
two hundred years, there has been an excess of male births in
England. Accepting the statistics as being reasonably accurate,
the accordance with Galton’s law of ancestral inheritance is much
closer than with Mendel’s law.

No. 485] THE DETERMINATION OF SEX 315

IV. Tae BIOLOGICAL SIGNIFICANCE OF THE SEXUAL RATIO.

Rauber, apparently taking the view that an excess of females is
the normal condition, explains the present preponderance of male
births in man by supposing that those tribes or families which,
in primitive times, had the greatest proportion of males would
possess a certain advantage in warfare and thus be enabled to
overpower those in which there was a larger proportion of females.
‘The male preponderance, once established, would be perpetuated
by heredity. This ingenious explanation, does not, however,
account for the excess of females among the domestic animals.
What the sexual ratio was in primitive man we have no means of
knowing. Neither do we know what the sexual ratio was in horses
and sheep before they were domesticated. One would expect
that the sexual ratio in wild animals would depend somewhat
upon the mating and breeding habits of a species. In those species
of birds, in which one male mates with one female for a season or
for life, we might expect that the sexual ratio would be nearly
unity, the excess of one sex or the other depending on which one
was exposed to the greater dangers and had the less chance of
growing to maturity. In herds of wild horses, cattle and bison,
there are many females to one male. All but the strongest males
are killed off by the others and the number of adult males is thus
kept down to the needs of the herd. Those individuals which
are most likely to produce males are not always the ones likely
to reproduce. In the dairy industry, females are of more value
than males, and it is possible, in fact more than probable, that man
has unconsciously, by selection in breeding, increased the pro-
portion of female births.

No one sexual ratio may be taken as the standard.— If sex is
hereditary, we might reasonably expect that the relative numbers
of male and female births in any species would be those which,
after deducting the early deaths, would confer upon the species
at the period of sexual maturity of its individuals the greatest
advantage in the struggle for existence so far as the production of
young is concerned. ‘This would mean that the species would
enjoy the maximum reproductive power, and this condition would
be fulfilled when there were no superfluous, sexually mature males
or females.

316 THE AMERICAN NATURALIST [Vor. XLI

Let us suppose that a species possesses the maximum reproduc-
tive power when there are x males to n females, the relative magni-
tudes of x and n depending upon the breeding habits of the species.
Let us suppose also that a males and b females die before reaching
sexual maturity. The number of males born will therefore be
a + x, and the number of females b + n. The sexual ratio will

a+ +2 R :
be Scar ae A 1000 if we wish to express the number of

male births to 1000 female births.

In a monogamous species, such as the American robin, the repro-
ductive power of the species would be at a maximum when there
were equal numbers of sexually mature males and females. If
the males are more likely to be killed off than the females, a would
be greater than b, and the sexual ratio would be greater than unity.
Surplus males or females would die off without reproducing. In
a polygamous species, such as the ox, it is not necessary that there
be equal numbers of sexually mature males and females to give
the species its maximum reproductive power, and a + x might
well be less than b + n. The sexual ratio would in this instance
be less than unity. The relative proportions of the sexes in any
species may, therefore, be looked upon as one of the physiological
adaptations of the species, determined by the conditions of its
existence.

V. THE EXPERIMENTAL POINT OF ATTACK.

If sex is inherited according to Galton’s law it should be possible,
by suitable selection of the parents, to establish a strain of animals
or plants in which males or females occur with any desired degree
of frequency compatible with perpetuation of the species. The
practical benefits of the favorable results of such an experiment
to the dairy and grazing interests of the country would be difficult
to estimate. Castle has recently published some experiments on
the effects of inbreeding, cross-breeding, and selection upon the
fertility of flies (Drosophila) in which he found no marked change
in the sexual ratio. Other experiments are now in progress.

There is, however, a second point of attack which is more dis-
tinctly within the province of the physiologist. As previously
pointed out, it is difficult to imagine why ordinary twins should

No. 485] THE DETERMINATION OF SEX 317

often be of different sexes while duplicate twins are invariably of
the same sex if nutritive or any other conditions outside of the
ovum itself are responsible for the sex of the offspring. It is per-
haps conceivable that, in the case of ordinary twins, the placental
circulation may be more highly developed, and the nutrition con-
sequently better, for one twin than for the other, or that some
peculiar local characteristic of the uterine wall may affect one
twin more than the other. The probability of any such dissimi-
larity of conditions in the case of duplicate twins, where the same
placenta supplies both with nutriment, and any local peculiarity
of the uterine wall affects them equally, is very small. It must
therefore be admitted that ordinary twins may be subjected to
more diverse conditions during development than duplicate twins,
and it is conceivable that the latter might sometimes be of opposite
sexes if we could vary the conditions during development. This
would manifestly be a matter of great difficulty in mammals, but
a simpler method of attack is open.

Roux (’85) and others have shown that the individual blasto-
meres of a frog’s egg will, when separated from the others, develop
into complete embryos. Such embryos are presumably compara-
ble in all respects to duplicate twins, and if by any means we might
cause two blastomeres from the same ovum of any animal nor-
mally reproducing sexually to develop into embryos of opposite
sexes, we would have a demonstration that sex was not determined
at the time of fertilization of the egg. Failure to produce from
the same egg two embryos of opposite sex would be evidence that
we have, at present, no known means of changing the sex of the
embryo after fertilization of the egg. It is incumbent upon those
who maintain that sex is determined by the environment to show
that two embryos of opposite sexes can be produced from the
same ovum. ‘The experimental solution of the problem of the
causes which influence the sex of the offspring, as well as the
significance of sex itself, is to be sought in the simple cell whose
environment can be varied in a known way and to a known extent.
. It is obvious, also, that the problem of sex determination is but a
particular phase of the much wider problem of the extent to which
the ovum may be modified by a change in the external environ-
ment. Furthermore, if we acquire experimental data on the deter-

318 THE AMERICAN NATURALIST [Vor. XLI

mination of sex, we will at the same time acquire experimental
data on the question of a period of sexual indifference in the devel-
opment of the individual. If sex is determined, as appears prob-
able from the statistical data, at the time of fertilization, it is
difficult to conceive of a period of real sexual indifference in the
history of the individual. But if we can influence the sex of an
individual after fertilization of the ovum, we will at the same time
demonstrate a period of sexual indifference in development.

The bearing of artificial parthenogenesis on the problem of sex.
— In.a personal communication to the writer, Dr. Woelfel has
suggested that if, by any means other than fertilization by a sperma-
tozoon, we are able to cause an ovum of an animal which normally
reproduces bisexually to develop to sexual maturity, we will have a
demonstration that one parent plays a purely asexual röle in the
production of sex. This conclusion, however, does not follow
necessarily. Moreover no individual arising by artificial partheno-
genesis has as yet grown to sexual maturity. Whether this failure
of normal development is due to improper nutrition of the young
or toa lack of some essential detail in fertilization cannot, perhaps,
be stated at present. One is inclined to regard the production of
a sexually mature individual, which may in its turn reproduce, and
the transmission of certain hereditary characteristics to the off-
spring as two essential details of fertilization. Until these phe-
nomena have been imitated by artificial means, one is loath to
believe that normal fertilization is imitated in all essential details
by artificial parthenogenesis (Loeb :06). The study to artificial
parthenogenesis may have an important bearing upon the deter-
mination of sex, but the true significance of the work already done
is not apparent.

VI. SUMMARY AND CONCLUSIONS.

The statistical study of the distribution of sex in man shows
that there is a slight but constant excess of male births. The
greater mortality of the males leads to a preponderance of females
in old age.

There are certain unavoidable errors in the statistics, the two
most serious being (1) incompleteness, and (2) disregard of dupli-

No. 485] THE DETERMINATION OF SEX 319

cate twins. It is not probable, however, that these errors are in
such a direction as would change the sexual proportion if we
could get absolutely correct statistics.

The sexual ratio is remarkably constant in widely different
localities and at widely different times; in a given locality the ratio
is not altered by the varying social and material conditions of the
parents, as indicated by statistics.

The study of duplicate twins shows that if sex is determined
by a series of accidental causes, such causes cannot be operative
after the fertilization and first segmentation of the ovum.

The logical conclusion from the statistical data is that sex is
hereditary. Mendel’s law does not apply. The constancy of the
sexual ratio for more than two hundred years may best be ex-
plained by supposing that sex follows Galton’s law of ancestral
inheritance.

If sex is hereditary, we may explain the significance of the sexual
ratio on the basis of natural selection by supposing that the pro-
portion of the sexes in any species is such as will give that species
the maximum reproductive power at the time of sexual maturity
of its individual members. ‘The sexual ratio may be expected to
vary for different species, depending upon the mating and breed-
ing habits of any particular species. ‘The sexual proportion may
be considered as one of the physiological adaptations of a species.

The conclusions drawn from statistical data should be tested
experimentally. ‘There are two experimental points of attack:
(1) Breeding experiments to determine whether the sexual pro-
portion can be altered by selection. (2) Experiments on the
separate blastomeres from one ovum to determine whether two
embryos of different sexes can be reared from the same egg, and
whether there is a period of sexual indifference in the development
of an individual.

HULL PHYSIOLOGICAL LABORATORY
CHICAGO

320 THE AMERICAN NATURALIST [Vor XLI

BIBLIOGRAPHY.

Only a partial bibliography is given here. Cuénot and Düsing (’84)
give all the literature for animals up to 1899. Strasburger and Gregory
give the botanical literature. A less complete review is given by Loeb.
(06).

BATEson, W. and SAUNDERS, E. R.
:02. Experimental studies in the physiology of heredity. Reports
to the Evolution Committee, No. 1, London.
Born, G.

’81. Experimentelle Untersuchungen über die Entstehung der Ge-

schlechtsunterschiede. Breslauer ärtzliche Zeitschrift, 3, p. 25.
CASTLE, W. E.

:03. The Heredity of Sex. Bull. Mus. Comp. Zool., 40, pp. 189-218.

CASTLE, W. E. , CARPENTER, F. W., CLARK, A. H. Muse; S. O., and BAR- |
ROWS,

:06. The effete of Inbreeding, Cross-breeding and Selection upon
the Fertility and Variability of Drosophila. Proc. Amer. Acad.
Arts and Sciences, 41, pp. 729-786.

Cu£nor, L.

99. Sur la determination du sexe chez les animaux. Bull. scientif.

de la France et de la Belgique, 32, pp. 462-535.
Düsıns, C.

’84. Die Regulierung des Geschlechtsverhältnisses bei der Vermehrung
der Menschen, Thieren und Pflanzen. Jenaische Zeitsch. f.
Naturwissenschaft. 17, p. 593.

Düsıng, C.
’85. Der Experimentelle Prüfung der Theorie von der Regulierung
der Geschlechtsverhältnisses. ee rit supp. Heft 2, p. 108.
GEDDES, PATRICK, and THOMPSON, J. ARTH
:01. The Evolution of Sex, Chapter IV, od. wi: London.
GREGORY, R. P.
Some observations on the determination of sex in plants. Proc.
Cambridge Phil. Soc., 12, pp. 430-440.
GRIESHEIM, A.

’81. Ueber die Zahlenverhältnisse der Geschlechter bei Rana fusca.

Arch. f. d. ges. Physiol., 26, p. 237.
Harper, R. V.

:07 Sex Determining Factors in Plants. Science, N. S. 25, pp. 379-

382.

ISSAKOWITSCH, A.
Geschlechtsbestimmende Ursachen bei den Daphniden. Arch.
f. mikr. Anat., 69, p. 223.

No. 485] THE DETERMINATION OF SEX 321

Lexis.
"92. Geschlechtsverhältniss der Geborenen und der Gestorbenen.
Handwörterbuch der Staatswissenschaften, 3, p. 816: new edition
1900, 4, p. 177, cited by Strasburger (:00).

Logs, J.
:06. The dynamics of living matter. N. Y. and London. Chapters
IX and X.
McCune, C. E.
:02. The corer chromosome — sex determinant? Biol. Bull.
3, ki
von MALs

iR
N Einflüsse und Eibildung bei Dinophilus
apatris. Arch. f. mikr. Anat. 69, p. 63.

MclIntosn, D.

:04. On the variation in the number and arrangement of the male
genital apertures and on the proportion of the sexes in the Nor-
way lobster. Proc. Cambridge Philos. Soc., 12, pp. 441-444.

NeEwcoms, S.

:04. A Statistical Inquiry into the Probability of Causes of Sex in
Human Offspring. Carnegie Institution, Publication No. 11,
pp. 1-34.

PFLüÜGER, E.
’81. Einige Beobachtungen zur Frage über die das geschlechts-
.. bestimmenden Ursachen. Arch. f. d. ges. Physiol. 26, p. 243.

’82a. Hat die Concentration des Samens einer Einfluss auf das Gesch-
lecht? Idem, 29, p. 1. (Has no effect.)

’82b. Ueber die das geschlechtsbestimmende Ursachen und die ges-
chlechtsverhältnisse der Frosche. Idem, 29, p. 13.

Punnett, R.

:04a. On nutrition and sex determination in man. Proc. Cambridge
Phil. Soc., 12, pp. 262-276.

:04b. Note on the PEOPEEROR of the sexes in Carcinus menas, Idem,
pp. 293-296.

RAUBER, A.

:00. Der Ueberschuss an Knabengeburten und seine biologische
Bedeutung. Leipzig. (Abstract by R. F. Fruchs in Biol. Cen-
tralbl., 21, p. 833, 1901)

ROWNTREE, B. S.
:02. Poverty, a study of town life. Second edition.
Rovx,

’85. Usher die Bestimmung der Hauptrichtungen des Frosch-embryos
im Ei, und über die erste Teilung des Froscheies. Breslauer
ärtzliche Zeitsch. [The literature is given by Wilson (1900)].

STRASBURGER, E.
:00. Versuche mit diöcischen Pflanzen in Rücksicht auf Geschlechts-

322 THE AMERICAN NATURALIST [Vor. XLI
en ; Biol. Centralbl., 20, pp. 657-65, 689-98, 721-31,

WELDON, W. F.
:01—: 02. Mendel’ s Laws of Alternative Inheritance in Peas. Biome-
trika, 1, pp. 228-254
Wiper, H. H.
: ne ae Twins and Double Monsters. Amer. Journ. of Anat.,

WiıLson, E B.
:00. The Cell in Development and Inheritance. 2nd ed. New York,
p. 408 et se

:07. Sex deine in relation to fertilization and parthenogenesis.

Science, N. S. 25, pp. 376-379.
Yung, EMILE.

’83. Contributions à Phistoire de l’influence des milieu physico-
chimiques sur les étres vivants. Arch. de Zool. experimental,
2e serie, 1, p. 31.

’85. Influence des variations du milieu physico-chimiques sur le
développement des animaux. Arch. des Sciences Phys. et Natur-
elles, 14, p. 502.

CHUBS’ NESTS
ALFRED W. G. WILSON

During late summer, at times of low water on almost any one
of the numerous small streams tributary to the Upper Ottawa
River, the passing voyageur cannot fail in having his attention
drawn to curious conical piles of coarse gravel and pebbles which
occur along the river shores. Locally these piles of stones are
called “Chubs’ Nests.” The following notes are published in
the hope that they may prove of interest to American Naturalists.

The accompanying plates will give a general idea of the shape
and character of these heaps of stones. They are conical in form,
with a circular or oval base. The volume of the gravel of which
they are built will vary from a good sized wheelbarrow load to
about a cart load. ‘The individual pebbles vary in size; the great
majority would readily pass through a two inch ring. In a few
cases oblong pieces of schist about three inches in length were
noted but their cross section would not be more than one square
inch. The largest pebbles used in the construction of the heaps
would weigh at least half a pound each; most of the pebbles would
weigh less than four ounces each. The rock material from which
the pebbles have been derived is often quite different from the
rock of the immediate vicinity, showing that the pebbles have been
transported some distance to their present resting place. In a
number of instances it was found that the interior of the heap
consists almost entirely of small pebbles less than an inch in the
maximum dimension, the larger ones forming only an outer layer
over the whole cone.

The dimensions of two of these heaps of stones were as follows: —
No. 1. Base, length 6.5 feet, width 5 feet at one end (left of figure
1), and 4 feet at the other, height 21 inches, angular slope of the
side of the cone about 48° to the vertical. This pile was built of
mixed pebbles, chiefly granite and schist. (See figure 1.)

No. 2. Base, nearly circular and four feet in diameter, height
22 inches, angular slope 49° 45’. (See figure 2.)

323

324 THE AMERICAN NATURALIST [Vor. XLI

In a very large number of cases examined the stones were found
to be piled quite loosely so that the slightest jar set them sliding
down into a position of more stable equlibrium.

Along the larger streams and rivers the heaps are usually found
in small bays off the main stream or on bars and ridges on the
sides of the main channel, in quiet but never in dead water. In
some places near the watersheds they occur in midstream, and
occasionally they are sufficiently numerous to hinder and partly
obstruct canoe navigation, where the water is shallow and the
stream narrow.

Bye. 1.

In the early spring when the waters are high and usually more
or less turbid the cones are not in sight; but as the waters recede
the apices of the cones gradually appear above the surface and
late in the season the water may have receded so that the whole
cone together with the bar on which it was built comes into view.
The tops of the “nests” shown in figures 2 and 3 were fully five
feet above the surface of the water when the pictures were taken
in August. In early June the water was probably six feet higher
and the tops would have been under at least a foot of water.

As to the origin of these curious heaps of pebbles, the Indians

No. 485] CHUBS’ NESTS 325

and Bushmen all attribute them to small fish — called Chub by
the whites and Awadosi (stone carriers) by the Indians.’ Per-
sonally I have made numerous inquiries but I have not been able
to find any one who will say he has actually seen the fish at work,
still they all insist that it is the fish who make them. A careful
examination of over one hundred heaps, scattered along a line of
gravel more than three hundred miles in length has convinced the
writer that the cones are of animal origin, that the materials have
been assembled by some intelligent agent, not by stream action.

iG. 2,

These heaps of stones are said to be built in the early spring
and are presumably used for spawning purposes. They are
always in places where the water is smooth but still flowing.
Except in the very beds of the rivers of this north country, pebble
and gravel beds and bars are not found. The shores of the
streams are almost universally clay. At high water the rivers
expand and invade the woods so that, as one of my canoemen
expressed it “The pike go into the bush to hunt.” In midstream
the water is usually flowing very swiftly at high water and along

1 Bell, Robert. Recent Explorations to the South of Hudson Bay. The
Geographical Journal, July, 1897, p. 16.

326 THE AMERICAN NATURALIST [Von XLI

the shores the ground is covered with logs and bushes. Ground
suitable for spawning covered by a moderate depth of water is
rare. In nearly every case where the nests were seen the bottom
consisted either of large boulders and cobbles, or of soft materials
and sand with a certain admixture of partly decayed logs and
lower types of plant life, chiefly alge. On this bottom the conical
heaps of stones were built up. It seems not unnatural to suppose
that they serve the dual purpose of offering a clean gravel surface
for the deposition of the eggs, and at the same time raise these
eggs nearer the surface of the water and thus into a zone of more

Fig. 3.

light and warmth than if they were deposited directly upon the
bottom.

The fish which are said to be the architects of these curious
nests vary in size up to about 18 inches in length, and in weight
up to about two pounds or a little over. Their ventral aspect is
white, the dorsal dark gray-black, and the broad sides are silver
white. The cycloid scales are large and thick, and the body is
about three times as deep as wide. The third plate shows a
specimen about 14 inches in length which was captured and laid
upon the nest before making the picture. President David S.
Jordan to whom these data have been submitted considers that

No. 485] CHUBS’ NESTS 327

the fish is “probably the Silver Chub or Fall Fish, Semnotilus
corporalis Mitchell.” It may be interesting to sportsmen to know
that the fish rise readily to the fly, occasionally can be caught with
a troll, and are easily captured with an ordinary hook baited with a
piece of bacon rind. The flesh is coarse and the bones are few
and large, reminding one of mullet.

In 1844 Chubs’ nests were found in the Magalloway River,
Maine, by Dr. Jeffries Wyman. He described them to the Boston
Society of Natural History (Proceedings, Vol. 1, p. 196) as “mounds
of pebbles, two or three feet in diameter, which he was told were
heaped up by a fish called the Chub, at its breeding season, and
that its eggs were deposited among the stones.” He referred to a
similar habit attributed to the lamprey eel and remarked that he
was not aware of any other instance of the kind.! Dr. Robert
Bell, in the report of his explorations referred to above, has pub-
lished a figure of a characteristic nest. He states that a varying
number of chubs work together in building a mound, bringing
the stones in their mouths, one at a time, from far and near.

In considering the relative sizes of the pebbles and the fish that
move them, it must be remembered that under water the weight
of the stones will be from one quarter to one third less than the
weight in air. In the cases of the larger heaps of stones it is often
found that there is an area greater than the base of the cone over
which the stones are scattered. In one case we found what ap-
peared to be the base of an old cone and the inference seems to be
that in the rebuilding every spring they repair the old nests, shift
them at times, and utilize materials from abandoned nests to
construct new ones or to enlarge the old. ‘The larger nests are
probably the work of several seasons.

MontrEAL, January, 1907

1 The nests of the lamprey are “ gravel filled pockets.” ‘‘The central part
is usually 15 to 20 ems. deeper than the edges, so that the whole is dish-like
in appearance; at the lower edge there is always a pile of stones.” The
stone carrying habit of the lamprey has been described by S. H. Gage, by

an and Sumner, and by Young and Cole (American Naturalist, 1900, vol.
34, pp. 617-620). In an interesting and comprehensive account of parental
care among fresh water fishes (Rep. of the Smithsonian Inst., 1905, pp. 402-
531) Theodore Gill does not include either the lamprey or the chub, the
pao presumably not being considered a fish. The cat-fish is described as

ing stones away from its nest; no stone gatherer like the chub is men-
honed,

NOTES AND LITERATURE
GENERAL BIOLOGY

Mendelism.' — In a well printed booklet of eighty-five 4 X 54 inch
pages, R. C. Punnett of Cambridge, England, has presented an ad-
mirably clear and concise account of Mendelism. After reviewing
the simple and fundamental experiments of the Abbot of Brünn, the
writer describes the more recent discoveries to which they have led,
and in conclusion shows them to be of the highest practical and
scientific importance. Although the mendelian principles of heredity
are well known in America through the publications of Castle, Daven-
port, and others, a brief review of them as presented by Punnett may
still be of interest. :

It is found by experiment that when a certain pure bred tall variety
of plant is crossed with a dwarf, the resulting hybrid contains both
the factors for tallness and shortness. If A represents the tall factor
of one parent and a the short factor of the other the hybrid which
contains both is Aa. It is not of medium height, but is like its tall
parent. A character such as tallness in peas which is retained by
the hybrid is called dominant: one like dwarfness which is latent in
the hybrid is named recessive.

When hybrids Aa are bred together, they produce in the next gen-
eration 25% of pure tall forms, AA; 50% of tall hybrids, Aa; and
25% of dwarfs, aa. The familiar formula may be written thus:

Parents AA aa
Ist generation Aa
2nd generation AA 2Aa aa

The tall hybrids Aa, and the pure tall plants AA, are indistinguish-
able except by further breeding. Then it appears that one in every
three contains only the factors for tallness. Such plants, like the
dwarfs, breed as true as if derived from an unbroken ancestry of pure
forms.

It is not always the case that the hybrid resembles one of its parents.

1 Punnett, R. ©. Mendelism. Second Edition. Cambridge, MacMillan
and Bowes, 1907. 16mo. vii + 85 pp.

329

330 THE AMERICAN NATURALIST [Vor. XLI

The blue Andalusian fowl is a race which in breeding produces 25%
of black offspring, 50% of blue, and 25% of white splashed with
black. It is evident from these proportions that the blue race desired
by fanciers is essentially mongrel, and can never be made to breed
true. The black race and the splashed whites remain true when each
is mated with its own kind, but when crossed they produce the blue
Andalusian.

The fixed proportion of pure and mongrel forms in the offspring
of hybrids may be readily explained. The factors A and a, derived
by the hybrid from its parents respectively, are transmitted through
its germ cells in equal abundance. The factors become segregated,
so that one half of the germ cells contains only A, and the other half
a. In the process of fertilization an A will unite with a as often as
with A; and an a will join A as often as a. Thus there will be 2
Aa for each aa and AA.

When two different inheritable factors occur in each parent the
number of combinations in the offspring is much greater. Mendel
found, with peas, that the height of the plant (tall or dwarf) and the
color of the seeds (green or yellow) were transmitted independently
of one another. A and B may represent respectively the factors for
tallness and greenness which are dominant; a and b the factors for
shortness and yellowness which are recessive. If a tall green-seeded
plant AB, is crossed with a dwarf yellow ab, tall green-seeded hybrids
containing the factors AaBb result. Every germ cell of such a hybrid
contains one factor for height and one for color; they are equally
distributed in the four possible combinations AB, Ab, aB, and ab.
When such a group of germ cells fertilizes a similar group, the follow-
ing combinations are to be expected:

AA BB AA bb aa BB aabb
2AA Bb 2Aa bb 2aa Bb
24a BB
4Aa Bb

Thus among sixteen individuals nine contain both dominant factors
and in the case of the peas are tall green-seeded plants. Three con-
tain only the dominant A, and are tall yellow-seeded forms; three
contain only the dominant B and are green-seeded dwarfs. One
contains neither dominant and is a yellow-seeded dwarf. This ratio,
9:3:3:1 Mendel verified by experiment.

The sweet pea known as the ‘Painted Lady’ has a bright pink color
due to its sap, and this is dominant over the absence of such sap color

No. 485] NOTES AND LITERATURE 331

in which case the flower is white. In the cream sweet pea there is no
sap color, the tint being due to pigmented chromoplasts. The yellow
chromoplasts are recessive to colorless ones. ‘Therefore when a
Painted Lady is crossed with a cream, the hybrids are all Painted
Ladies; in the next generation four classes are found,— Painted Ladies,
cream Painted Ladies, whites, and creams, in the proportion 9:3:3:1.

A similar result has been observed in breeding fowls. The rose
comb of the Wyandotte type and the pea comb of the Indian game
are both dominant over the single comb of the Leghorn type. When
a rose comb is crossed with a pea comb a new type results, described
as the “walnut” comb. It resembles that of the Malay breed. When
such hybrids are bred together four types of comb appear in the next
generation, namely the walnut, rose, pea, and single in the proportion
of 9:3:3:1.

In rabbits the gray color of the wild animal is dominant over albin-
ism. When a gray is crossed with an albino, gray hybrids result which
produce young in the proportion of 9 grays, 3 blacks, and 4 whites.
The factors involved are pigmentation, A, dominant over albinism,
a; and grayness, B, dominant over blackness, b. The four white
animals which appear identical include three forms, namely aa BB,
2 aa Bb, and aa bb, all of which lack the pigmentation factor A. From
this it appears that the wild gray color consists of a factor for pigmen-
tation and another for grayness. By loss of the former a white rabbit
results, and by loss of the latter, a black one. In the offspring of
such a white and black, reversion occurs to the original gray form.
Similarly white pea blossoms may each contain one of the two factors
for pigmentation, and by crossing such whites, reversion to a wild
colored type has been observed. Thus reversion has been defined
as a union of complementary factors which have become separated
in the course of phylogenetic development.

From these and many other observations, the author concludes
that no horticulturalist can propose to raise a tall pea from a dwarf
by a process of manuring, nor by selecting minute fluctuations, but
only by obtaining new aggregations of unit characters through breed-
ing. He infers that ‘‘education is to man what manure is to the pea.”
— “Permanent progress is a question of breeding rather than of
hygiene and pedagogics” for “the creature is not made but born.”

` In Mr. Punnett’s book no reference is made to ‘mixed inheritance’
whereby the parental characters are blended in the offspring. It must
be remembered, however, that rabbits with ears of medium length are
obtained by crossing short-eared with lop-eared forms; and that the

332 THE AMERICAN NATURALIST [Vor. XLI

crossing of some tall and dwarf plants produces those of intermediate
height. The omission of such limitations may cause a student to
believe that Mendelism is the universal law of inheritance.

Bide

The Problem of Age, Growth, and Death.— In a series of six
public lectures Professor Charles S. Minot has made known the results
of his studies, now in progress, concerning the essential nature of
senescence. Rejecting such criteria of old age as a halting gait or
arterio-sclerosis, which pertain chiefly to man, he has sought those
features which apply as well to the aged frog or fish, and even to still
lower forms. Such characteristics are found in the decreasing rate
of cell division, the increase of protoplasm at the expense of the
nucleus, and the progressive differentiation of the protoplasm. Old
age is therefore essentially a cytomorphic phase.

The rate of cell division is expressed by the “mitotic index” which
is the average number of mitotic figures found, in sections, among a
thousand nuclei. The mitotic index falls from 18 to 13 in rabbit
embryos of 74 and 13 days respectively. Drawings, on the same scale,
of nuclei of the various tissues in rabbit embryos of 74 to 164 days
show a striking reduction in the actual size of the nucleus, except in
the case of the nervous tissue. Even there, in relation to the proto-
plasmic mass, the nucleus may be relatively small.

The rate of growth begins to decline before birth, and this rate of
decline rapidly decreases until old age, when growth is at its minimum.
The uninterrupted process of senescence was demonstrated by weigh-
ings of rabbit embryos of various ages, and of individual guinea pigs,
rabbits and chickens, from birth until death. The same law was
held to apply to man, both in physical development as shown by
statistics of weight, and in mental development as determined by
psychologists. During the first months after birth, progress in
acquiring concepts of time, space, the ego, and the external world is
more rapid than in later years. As with weight, the rate of decline
is most abrupt at the outset, becoming gradual as age advances.

- The study leads to the paradoxical conclusion that the changes of
senescence are most marked in the years of infancy, for the popular
idea of maximum efficiency as the mark of maturity is set aside.
The embryo in adding an ounce to its weight is rated as advancing
more rapidly than the child in gaining a pound; the insect which leaps
many times its own length would be regarded as more successful in
jumping than the mammal which can far outdistance it.

No. 485] NOTES AND LITERATURE 333

Because of the rapid early decline in the rate of development
Professor Minot believes that the age of college entrance should be _
lowered, and that professional studies should be entered upon at a
younger age. A final publication of these researches, which have
extended through many years, is in preparation.

| aad ba x

The Hypothesis of Mimicry.— Dr. Franz Werner of the University
of Vienna is a skeptical critic of the Mimikrylehre which he regards.
as due to a rather crude anthropomorphic point of view (Biol. Cen-
tralbl., 27, pp. 174-185). He considers first the non-poisonous.
snakes which are supposed to have acquired a protective resem-
blance to the poisonous forms of other genera inhabiting the same
locality. Since no snake-eating animal is known which makes a dis-
tinction between poisonous and non-poisonous forms, the latter can-
not be protected by the similarity of pattern. Moreover in some cases.
there is reason to believe that the non-poisonous snake is the older
type and that the venomous Elaps or Vipera is the “imitator.” The
stingless insects which deceptively resemble bees and wasps fare no-
better than the harmless snakes, for stinging forms are “not in the
least protected from their natural enemies; they fall a prey to many
birds as well as to lizards, frogs, toads, and spiders.” Finn is cited:
in evidence that the poisonous Danais is as eagerly devoured in India
by lizards of the genus Calotes as are its mimics. Poisonous forms.
which often exhibit bright warning colors “to signalize their unpalata-
bility to enemies in good season” are not secure.

The similar patterns and colors of various snakes in a given locality
may be due to similar climatic conditions and food supply, the pig-
ments involved being physiological by-products. Color photography
is invoked to account for the correspondence in color between an
animal and its habitat. A physiological rather than a teleological
explanation is desired. In other words, it is believed that similar
causes produce both the forms which mimic and those which are
imitated, and that there is no other relation between the two. From
the reports of field observers the number of instances of effective-
mimicry has been so reduced that “as good as nothing remains.”
Dr. Werner believes that man alone has been seriously deceived.

x FELLE

334 THE AMERICAN NATURALIST [Vor. XLI

ZOOLOGY

Palms and Soles.— Dr. Schlaginhaufen of Dresden has written a
brief description of the palms and soles of man and the apes, based
upon a literature of one hundred and fourteen publications. ‘The
volar surface of the hand and fingers, and the plantar surface of the
foot and toes are thickly covered with slender ridges, the cristae cutis,
separated from one another by depressions, the sulci cutis. ong
the summit of a ridge, a row of sweat glands opens. A primitive stage
in the formation of the ridges is seen in the Prosimiae, which have
small round elevations (insulae primariae) surrounding single sweat
pores. Besides these primary islands there are larger elliptical forms
on which several sweat pores may be arranged in a circle or ellipse,
surrounding a central depression. These lenticular islands are due
to the coalescence of primary islands radially arranged. A crista
is formed by the coalescence of a linear series. The minutiae of the
cristae, upon which personal identification depends, consist in the
branches of the ridges, which may end blindly or anastomose; in
detached ridges; and in the ridge patterns. The two principal
patterns are the more or less concentric tactile figures, and the Y shaped
groups called triradii.

Besides the bas-relief of cristae, palms and soles present the high
relief of tactile cushions, toruli tactiles. For each extremity there are
typically five digital cushions at the tips of the fingers or toes; four
interdigital cushions near the metacarpo- or metatarso-phalangeal
joints; and two or three proximal cushions,— a tibial and an elongated
fibular, or a radial and two ulnar, one behind the other. This ar-
rangement is typical for pentadactylous mammals and the cushions
are well developed in marsupials, rodents, the insectivora and pri-
mates. Often the interdigital cushions fuse, as in the cat, and that
between the thumb and fingers may be suppressed. Secondary
cushions are not infrequent — such as a central cushion found in
Cebus — but none occur in the anthropoid apes or in man. Cushions
are accumulations of connective tissue and are not to be confounded
with eminences due to underlying muscles. On the summits of the

1 Schlaginhaufen, O. Über das Leistenrelief der Hohlhand- und Fusssohlen-
Fläche der Halbaffen, Affen und Menschenrassen. Ergebn. d. Anat, u. Entw.,
vol. 15, pp. 628-662. Since writing this review, the editor has received the
announcement of the following book. Kidd, W. The sense of touch in mam-
mals and birds wıth special en to the papillary ridges. London, A. and
C. Black, 1907. 8vo., 174 figs. 5s

No. 485] NOTES AND LITERATURE 335

cushions the complex tactile figures occur, and between them are
the triradii and imperfectly formed cristae. The distribution of the
triradii in the monkeys and various races of men has been elaborately
plotted, showing among other things, the shifting which accompanies
the altered function of the foot.

According to Whipple the cushions are essentially walking pads
which are secondarily tactile. The cristae have been designated
“friction ridges’ since they have been supposed to allow a firmer
grasp. An area of furrowed skin has been found on the prehensile
tail of Alouatta (Mycetes). The German writers, however, including
Schlaginhaufen, regard the cushions as primarily tactile. The most
highly developed pads (the digitals) are the most sensitive; the inter-
digitals are less sensitive; and the low tarsal and carpal cushions
least of all. The sensory functions of the toruli, whether primary or
secondary, have been demonstrated by various experiments with
compass points.

ge bee

Literature of Ichthyology. In the Proceedings of the United
States National Museum for 1906, (vol. XXXI) are numerous papers
on fishes, most of them relating to the fauna of Japan. Jordan and
Starks give an elaborate review of the Japanese flounders and soles,
60 species in all. Jordan and Herre discuss the herring-like fishes,
and Jordan and Snyder the killifishes. Jordan and Starks give a
record of the fishes collected by Prof. J. F. Abbott at Port Arthur,
and Hugh M. Smith and Thomas E. B. Pope record the fishes obtained
in Japan by Dr. Hugh M. Smith in 1903. Among these are four new
genera, Tosana, Satswma, Lysodermus, and Lambdopsetta.

Evermann and Goldsborough describe a new rock-fish, Sebastodes
alexandri, from California; Evermann and Kendall, a collection of
fishes from Argentina; and Evermann and Seale, a collection from
the Philippines made by Major Edgar S. Mearns.

In the Proceedings of the United States National Museum for 1907,
(vol. XXXII), Jordan and Starks describe a collection of fishes from
Santa Catalina Island, California.

Among these are Germo macropterus, the yellow-fin Albacore, here-
tofore known from Japan and Hawaii; Tetrapterus mitsukurii, the
Marlin-spike fish, heretofore known from Japan; Lepidopus xantusi,
known from Cape San Lucas; Chenopsis alepidota, known from the
Gulf of California; and Luvarus imperialis, known from the Mediter-
ranean. New species are Starksia holderi and Antennarius avalonis.

336 THE AMERICAN NATURALIST [Vor. XLI

Otohime, a new genus of gurnards (O. hemisticta) is described in
the same proceedings by Jordan and Starks, from Japan.

In the same Proceedings, Professor John O. Snyder gives a review
of the Mullide or Surmullets of Japan.

In the Bulletin of the Bureau of Fisheries, vol. XXV, 1905 (issued
1906), are several important papers on the fish-fauna of our island
possessions.

The “Fishes of Samoa” by Jordan and Seale contains a list of the
species collected on the American island of Tutuila and the German
island of Upolu by David Starr Jordan and Vernon Lyman Kellogg
in 1902. About 500 species were obtained, 92 of them new to science.
Most of the latter are small fishes taken through the use of poison
(chloride of lime) in the pools of the reefs. The reef fauna of the
islands of Samoa is remarkable for the number of brilliantly colored
species. In this paper are twenty-six colored plates of the most strik-
ingly colored of these small reef-fishes, noted since the days of Captain

ook. These plates are from water color sketches by Kako Morita.
The origin and purpose of these brilliant hues of coral-reef fishes is
one of the most difficult problems in evolution. It is to be noted that
these colors are not.confined to any one family, but that more than a
dozen families of fishes participate in them.

With this paper is a check list of all the species, 1704 in number,
now known from the region called Oceania, which includes Hawaii,
Polynesia, Micronesia, and Melanesia. In all this region the fauna
is essentially continuous, except as regards Hawaii. In this separated
island group, the genera remain the same as in Polynesia, but the
species as a rule are different. This difference is clearly due to the
operation of isolation and segregation.

In the same paper is a valuable discussion of the Samoan names of
fishes, and the root-words composing them, by Mr. W. E. Safford.

Almost simultaneous with this paper, but apparently with a few
weeks priority, is a memoir “Zur Fischfauna der Samoa-Inseln” by
Dr. Franz Steindachner, in the “Sitzungsberichte der Kaiserliche
Akademie” (1906) in Vienna. Dr. Steindachner describes the spe-
cies of fishes collected at Apia in Upolu, by Dr. Rechinger. This
collection contains 120 species, of which 20 are new. Only one of
the new species is contained in the series described by Jordan and
Seale. This is Salarias rechingert Steindachner, called Salarias
garmani by Jordan and Seale. A new genus, Kremeria, is added
to the rare family of Trichonotide.

In the next volume of the Bulletin of the Bureau of Fisheries,

No. 485] NOTES AND LITERATURE 337

(XXVI), Jordan and Seale discuss the ‘ Fishes of the Islands of Luzon
and Panay” as represented in a collection made in 1900 by Dr. George
A. Lung, Surgeon in the United States Navy. Dr. Lung obtained
at Manila and Iloilo, 249 species, of which eighteen are described as
new. One of these species, Rhinogobius lungi proves identical with
an older species Rhinogobius nebulosus (Forskäl), and Petroscirtes
vulsus is the young of Petroscirtes eretes.

The same rich fauna is discussed in a similar paper which imme-
diately follows the other in the same Bulletin, “ Fishes of the Philippine
Islands” by Evermann and Seale. ‘This treats of the collection exhib-
ited at the Louisiana Purchase Exhibition, most of it being obtained
by Mr. Charles J. Pierson, formerly of Stanford University. In this
collection are 296 species, of which 22 are new.

One of these, Platophrys palad, should have been referred to the
genus Pseudorhombus of Bleeker, of which the American genus
Cencylopsetta seems to be a synonym. ‘Three other species of Pseu-
dorhombus are by some slip of the pen referred to Platophrys. It
may be noted also that Amia jasciata (white) is a species quite different
from Amia novemjasciata.

Under the title of ‘Fishes of Australia (Sydney, 1906), Mr. David
G. Stead, naturalist to the Board of Fisheries for New South Wales,
gives a convenient popular account of the food-fishes of Australia,
with a useful record of the vernacular names applied to them. This
book is very well written, and contains much unpublished material.
It should lead to a general descriptive catalogue of the vast fish-fauna
of the Australian continent.

In the Bulletin of the Museum of Comparative Zoology, vol. L,
1906, Dr. Charles R. Eastman describes numerous shark’s teeth and
cetacean bones found in deep sea dredgings of the Albatross.

In the same bulletin (vol. XLVI, 1906), Dr. Charles H. Gilbert
describes certain lantern-fishes in the Museum at Cambridge. Dia-
phus nocturnus Poey is described and figured from the type. A
new species, Diaphus garmani, is described from Cuba.

In the same bulletin (vol. L, 1906), L. J. Cole and Thomas Barbour
describe a collection of vertebrates from Yucatan.

There are 45 fishes, Rhamdia depressa and Rhamdia sacrifieii being
new. Jordanella florida, a characteristic species of the Florida ever-
glades, is reported from near Progreso, and the rare species, Emble-
maria atlantica and Corvula sancte-lucie, from the sea near the same
town.

In the Anales del Museo Nacional de Buenos Aires, Dr. Fernando

338 THE AMERICAN NATURALIST [Vor. XLI

Lahille describes a remarkable new genus of mackerel-like. fishes
from Argentina under the name of Chenogaster holmbergi. The
dorsal and anal fins are provided with finlets; the mouth is very large,
and the body is covered with large scales. An allied fish is described
by Dr. Lahille from Port Lyttelton, New Zealand, under the name
of Lepidothynnus huttoni. Both of these are regarded, probably
correctly, as related to Gasterochisma melampus of New Zealand.
Figures of all three of these species are given by Lahille.

In Volume III, of Marine Investigations of South Africa (1905),
Dr. J. D. F. Gilchrist, Government Biologist of Cape Colony, describes
seventeen new species of fishes found in rather deep water off the
Cape of Good Hope. Several of these are most interesting additions
to our knowledge of fish-forms.

The Biennial Report of the State Board of Fish Commissioners
of California for 1906 contains useful accounts of the trout of Cali-
fornia, those of the Sierras by Dr. B. W. Evermann, the others by
Dr. D. S. Jordan. The report is edited by Charles A. Vogelsang.

One of the most valuable monographs of a single type of fishes is
the magnificent paper entitled, “‘Chimeroid Fishes and Their Devel-
= opment,” by Bashford Dean, published by the Carnegie Institution.

This paper treats especially of the anatomy and development of
the California Chimera called Rat-fish or Elephant-fish, Chimera
colliei, as studied in the Hopkins Seaside Laboratory at Pacific Grove
in California. The paper contains a record of the other living. and
fossil species. The final conclusion is that the Chimeeroids constitute
a highly modified and specialized offshoot from the group of primitive
sharks.

In the Transactions of the Zoological Society of London, 1906,
Dr. G. A. Boulenger continues his papers on the fresh water fishes
of Africa with a memoir on the fishes of Lake Tanganyika.

In the Proceedings of the Royal Academy of Amsterdam, Professor
Max Weber discusses the fresh water fauna of New Guinea. He
divides these fishes into two groups. The fluviomarine group is
derived from the marine fauna of the East Indies. The fluviatile
group is derived from the river fauna of Northern Australia. In his
view, New Guinea was joined to Australia at a time not later than the
Pliocene.

In the Biologia Centrali Americana, published in London (October,
1906), Mr. C. Tate Regan gives an account of the fresh water fishes
of Mexico and Central America, a group generously represented in
the British Museum. According to Regan, Eleotris equidens, from

No. 485] NOTES AND LITERATURE 339

Mazatlan, is the same as Eleotris picta from farther south. Dormitator
latifrons, of the Pacific slope, is regarded as different from Dormitator
maculatus of the Atlantic. The name, Chonophorus banana, is used
instead of the doubtfully identifiable Chonophorus (or Awaous)
taiasica. Gobius guentheri is shown to be the same as Chonophorus
transandeanus and Awaous nelsoni may be the same species. Sicy-
dium multipunctatum is a new species from Oaxaca. Excellent
figures are given of many of the species. In the Annals and Maga-
zine of Natural History, XVIII, 1906, Mr. Regan has numerous
papers on fishes. In “Descriptions of Some New Sharks in the
British Museum Collection,” the Japanese Orectolobus is separated
from O. barbatus, as Orectolobus japonicus, and the Japanese Monk-
fish as Squatina nebulosa. This had, however, been earlier named
Squatina japonica by Bleeker. In another paper in the Proc. Zool.
Soc. London for 1906, Mr. Regan discusses the classification of the
sharks and rays, proposing a new classification.
The following is Regan’s arrangement of the families;
Subclass Selachii,
Series 1. Tremato
Order 1. Pleuropierygii _
Families, Cladoselachid
Order 2. Acanthodii ER
Families, Acanthoesside,
Diplacanthıde.
Order 3. Ichthyotoma veo et
Families, Pleuracanthü
Order 4. Euselachii.
Suborder, Pleurotremata,
Division, N otodanoidea.
Families, Chlamydoselachide,
Hexanchide.
Division, Galeoidea,
Families, Odontaspidide,

Seylliorhinide,
Carcharüde.
Division, Squaloidet,
Families, Cochliodontide (extinct)
odontide (extinct)
Cestraciontide,

340 THE AMERICAN NATURALIST [Vor. XLI

(Heterodontide)
Squalide,
Squatinide.
Suborder 2, Hypotrema
Division, Narcobatoidei
Family, Torpedinide
Division, Batoidei
Families, Rhinobatide,
aude,
Dasybatide.
Series II. Chasmatopnea,
Order, Holocephali,

Family, Pyctodontide (extinct)
Squaloratide (extinct)
Myriacanthide (extinct)
Chimeride

The principal feature of this arrangement is the grouping together
of the Cestraciont and Squaloid sharks as a division corresponding
to the Galeoidea. Except for the reduction of some families to a
lower rank, and a few changes in names of groups, this corresponds
fairly with that adopted by recent American writers.

Under Diagnoses of New Central American Fresh Water Fishes,
Mr. Regan describes Rivulus flabellicauda, from Costa Rica, Rivulus
godmanni, from Guatemala, Pacilia salvatoris, from San Salvador,
Xiphophorus strigatus, from Vera Cruz and Oaxaca, X. brevis, from
Honduras, Agonostomus macracanthus and A. salvini, from Guate-
mala.

In the Anatomischer Anzeiger, Dr. Ulric Dahlgren describes the
anatomy of the electric organs on the top of the head in the Electric
stargazer, Astroscopus y-grecum.

These very interesting organs constitute a new type of electric
organs, quite different from those of the torpedoes and other electric
fishes.
- In the Proceedings of the Academy of Natural Sciences of Phila-

delphia, Henry W. Fowler describes Centropomus gabbi as a new species
from San Domingo, and C. heringi, from Surinam. He gives a list
of the cold-blooded vertebrates obtained about the Florida Keys.
Eighty-six species of fishes are recorded, one of them regarded as
new. This is Congrammus moorei, which seems to the writer a spe-
cies of Dactyloscopus, not evidently different from Dactyloscopus tri-
digitatus, found by him at Key West.

No. 485] NOTES AND LITERATURE 341

In a paper on “Rare or little known Scombroids, No. 3,” Mr.
Fowler proposes the new subgenus Pampanoa for Trachinotus glaucus,
distinguished by the falcate fins. Stromateus brasiliensis is described,
as new from Brazil, and Psenes chapmani, from the Sargasso Sea.

Mr. Fowler in this and other papers adopts the generic names of
Klein, published about 1740, and pre-Linnzean as well as non-binomial.

hese names, in his view, become available, because Walbaum in 1792
reprinted them all with their diagnoses, although not adopting them
or in any way reinforcing them. In the judgment of most writers,
a name published before Linnæus does not acquire validity by a reprint
without acceptance. This is a matter on which some definite ruling
should be made.

If we adopt these names of Klein, Psallisostomus will replace Lepi-
sosteus or Lepidosteus, Brama will replace Abramis, and Glaucus
Lichia.

A review of various genera of South American Characins is given
by Mr. Fowler, as also series of useful notes on fishes of Pennsylvania.

In the Bulletin of George Washington University, vol. I, 1906, Dr.
Theodore Gill tells “the remarkable story of a Greek fish, the Glanis,”’
(Parasilurus aristotelis). This species was known to Aristotle, but
modern authors have, with a few exceptions, overlooked its existence.

In the Smithsonian Report for 1905, Dr. Theodore Gill gives an
interesting review of our knowledge of ‘Parental Care among Fresh
Water Fishes.” The literature of this subject is fully discussed.

In the Zoologischer Anzeiger, Dr. L. S. Berg discusses the fishes
of Lake Baikal and those of the Amur Basin. He considers Cotto-
comephorus as the type of a distinct family. This is based mainly on
the peculiar structure of the caudal vertebrae. ‘The fishes of Turkestan
are also listed by the same author.

In the Bulletin of the Académie Impériale des Sciences, L. Berg
discusses the lampreys of the Russian Empire.

The species of Lampetra or river lamprey in this vast region he
reduces to two, L. fluviatilis and L. planeri. To the former he refers
Lampetra aurea of Alaska, L. japonica of Japan, L. camtchatica of
Kamchatka and other nominal species.

Lampetra planeri, according to Berg, includes L. mitsukurii of Japan
and L. wilderi of the Eastern United States. This last determination
is certainly doubtful. |

In the Proc. Zool. Soc. London, Prof. W. B. Benham and W. J.
Dunbar describe the skull of a young Ribbon-fish, Regalecus, from
New Zealand.

342 THE AMERICAN NATURALIST [Vor. XLI

In the 24th Annual Report of the Fishery Board for Scotland, Dr.

. C. Williamson describes the small cod-fish, Gadus minutus and
Gadus esmarki, and records two cases of hermaphroditism in the
common cod-fish.

The fourth part of the Fishes of Japan by Otaki, Fujita and Higur-

ashi appears with descriptions in English and Japanese and with
excellent colored figures of the common ‘Tai,’ the “national fish” of
Japan, (Pagrus major), of the Ayu (Plecoglosmus altivelis), next to-
the American Eulachon, the finest of all food-fishes, and other spe-
cies of interest.

In the Zoological Series of the Field Columbian Museum, Dr. T.
H. Bean publishes a catalogue of the Fishes of Bermuda. ` 261 species.
are recorded, many of the more rare forms being figured. The new
species, previously described in the Proceedings of the Biological
Society of Washington, vol. XIX, for 1906, are the following: Hippo-
campus brunneus, (= H. hudsonius Jordan & Evermann, not of
DeKay), Holocentrus meeki, Eupomacentrus chrysus, Iridio decoratus,
Iridio meyeri, Iridio microstomus, Cryptotomus crassiceps, Mona--
canthus tuckeri, Rhinogobius mowbrayi, Labrisomus lentiginosus,
Antennarius Verrucosus.

In the series of Occasional Papers of the Bernice Pauahi Museum
at Honolulu Alvin Seale gives a list of “Fishes of the South Pacific”
collected by him in the Marquesas, Tahiti, Solomon Islands, and
elsewhere in the South Seas. Numerous new species are described,
and illustrated in not very satisfactory fashion by photographs.

In the same series, William A. Bryan describes a few new or rare
fishes from Honolulu.

In the Records of the Australian Museum, VI, 1906, Edgar R.
Waite gives descriptions of Australian and Tasmanian fishes, and’
studies in Australian Sharks, with photographs of the egg cases of
certain species.

In the Proceedings of the Biological Society of Washington, Hugh
M. Smith and Alvin Seale describe a number of species from the-
Philippines, four species being new.

In the Bulletin of the Michigan Fish Commission, No. 8, Mr. Ellis.
L. Michael catalogs the fishes of Michigan, with reference to all
Michigan notices of each species.

DAVID Starr JORDAN.

Nettling Hairs of the Brown-tail Moth.' — It is well known that

1 Tyzzer, E. E. The pathology of the brown-tail moth dermatitis. Journ.
of Med. Res., vol. 16, pp. 43-64.

No. 485] NOTES AND LITERATURE 343.

certain barbed hairs from caterpillars of the brown-tail moth, when
applied to the skin, may cause a severe inflammation. Dr. Tyzzer
has found that these hairs occur over “two velvety brown spots which
appear on the dorsal aspect of the fifth and sixth segments after the
first molt.” Similar spots are found after each succeeding molt up.
to the last two spring molts, when they appear on all segments from
the fifth to the twelfth inclusive. At this time they occur also in
relation with the lateral tubercles of the same segments, so that the
caterpillar becomes much more poisonous than in its young stages.
The tapering nettling hairs are inserted by their pointed ends into-
elevations upon the caterpillar; the barbs, which at intervals tend to.
encircle the hair, point outward. If these hairs, which are easily
detached, are rubbed upon the skin they work their way inward,
pointed end foremost. It was supposed that the irritation which
followed was purely mechanical. Dr. Tyzzer has demonstrated a
chemical poison in the following manner. If the hairs are placed in
a drop of blood between a slide and cover glass, a modification of
the red corpuscles takes place at the apex of the hair. There the
rouleaux are broken up; the corpuscles shrink and become at first
spiny, and then spherical. That this is not a physical phenomenon
is shown by substituting hairs of similar shape from the tussock moth,
when no reaction occurs. It is believed that a poisonous substance is.
emitted from the apex of the hair, although no pore is visible. If the
hair is broken the reaction occurs about the fracture, but otherwise only
at the pointed extremity. The poisonous substance is not destroyed
by baking the hairs for one hour at 110° C, but is destroyed at 115°.

In the latter case the hairs produce no dermatitis when applied to the
skin, and no reaction in the drop of blood. ‘The poison is insoluble
in alcohol, acetone, chloroform, ether, acetic acid, and dilute hydro-
chloric acid. It appears, however, to dissolve in distilled water at 60°
C, and a further chemical study is in progress.

In regard to animal coloration it may be noted that the cater-
pillars of the tussock moth, said to present ‘warning colors,’ have
non-poisonous hairs; those of the Io moth, with a green ‘protective
coloration’ are somewhat poisonous; and the poisonous brown-tail
caterpillars have neither a warning nor a protective color. All three
forms, moreover, are eaten by birds.

IL

Divided Eyes of Insects.— G. D. Shafer has studied the divided
eyes in certain Odonata and Diptera ! and has followed the late stages.

1 Proc. Washington Academy of Science, 8, 1907.

344 THE AMERICAN NATURALIST [Vor. XLI

of their development in two species. The modifications are introduced
in the nymph stage and are almost complete in the subimago, though
the eyes rapidly increase in size at the time of the final molt. Shafer
thinks that the two divisions of the eye are for vision in different kind
of light the regions with larger elements and less dense pigmentation
being available in twilight or in the darker hours.

Notes.— Dr. Lawrence E. Griffin has published in the Missouri
Valley College Quarterly Bulletin, (6, No. 4, 1907) a handy guide to
the dissection of the dogfish (Acanthias & Galius). Copies may be
had from the author at Marshall, Missouri, at 25 cents each.

BOTANY

Winter Rest.— In a very comprehensive series of experiments,’
in one of which as many as 283 species were used, Dr. Walter L.
Howard, of Columbia, Mo., has studied the effect of increase of
temperature, narcotics, lack of light, and dehydrating agents upon
plants in the resting condition. He comes to the conclusion that
the resting period is due to external influences, which also determine
its duration and intensity. It may be interrupted by the use of the
above mentioned agents. Though the results they produce are identi-
cal, their action is different. An ample citation of literature enhances
the value of this paper.

Henri Hus.

Notes.— A quarto of 340 pages, devoted to a revision of the genus
Lepidium by Thellung, has been separately issued from vol. 41 of
the Neue Denkschrijten der Allgem. Schweizerischen Gesellschaft
j. d. Gesamten Naturwissenschaften, as a contribution from the Zürich
Botanical Museum.

Some of the difficulties of cactus study are pointed out by Griffiths
and Hare in an economic leaflet issued as Bulletin no. 102, part 1, of
the Bureau of Plant Industry, U. S. Department of Agriculture.

Observations on Sarracenia are published by Macfarlane in The
Journal of Botany for January.

ı Howard, Walter L. Untersuchung ueber = Pe saclay ay der
Pflanzen. Inaugural-dissertation, Halle, 1906.

No. 485] NOTES AND LITERATURE 345

Opuntia pusilla as a Cape weed is discussed by Nobbs in The
Agricultural Journal of the Cape of Good Hope for December.

Illustrations of the celebrated cypress of Tule are given in Forest
Leaves for December.

Notes on rare ferns about Media, Pa., and especially Asplenium
ebenoides, are given by Palmer in vol. 2, no. 1 of the Proceedings of
the Delaware County Institute of Science.

From notes in Nature of December 13 and January 10, it appears
a subject of debate whether Spherotheca mors-wve is a new pest in
England or one of 30 years’ standing.

Berghs gives an account of the nuclear phenomena of Spirogyra
in vol. 23, fascicle 1 of La Cellule.

Cruchet publishes on Labiate rusts in the Centralblatt für Bak-
teriologie &c., Abteilung II., of Dec. 28.

The biology of the sand areas of Illinois is the subject of vol. 7,
article 7, of the Bulletin of the Illinois State Laboratory of Natural
History, by Hart and Gleason.

A short readable exposition of his views on evolution and mutation
is given by DeVries in The Monist for January.

An illustrated handbook of ‘‘The Microscopy of Vegetable Foods”
with special reference to the detection of adulteration and the diagnosis
of mixtures, by Winton and Moeller, has recently been issued by
John Wiley and Sons of New York and Chapman and Hall of London.

The flora of the Cuban ‘Sierra Maestra’ is considered in a forestry
study reported by Fernow and Taylor in the Forestry Quarterly of
December.

Tobacco-culture experiments, by Hunger, occupy part 3 of the cur-
rent volume of Archives du Musée Teyler.

_ Guayule (Parthenium) rubber is the subject of a statistical note
in Tropical Life for December.

The Christmas number of The Southern Lumberman contains a
number of well illustrated articles on native trees.

The activities of the Desert Laboratory at Tucson are outlined by
MacDougal in the recently issued Year Book, No. 5, of the Carnegie
Institution of Washington.

346 THE AMERICAN NATURALIST [Vor. XLI

Vol. 5, no. 16 of the Bulletin of the New York Botanical Garden
forms a general descriptive guide to the grounds, buildings and
collections.

The Report of the Michigan Academy of Science, vol. 8, contains
the following papers of botanical interest: — Kauffman, ‘Unreported
Michigan Fungi....’; Beal, ‘A Study of Rudbeckia hirta,’ and ‘Some
Botanical Errors Found in Agricultural and Botanical Text-Books.’
Dandeno, ‘A Stimulus to the Production of Cellulose and Starch,’
‘A Fungus Disease of Greenhouse Lettuce,’ and ‘The Aerating Sys-
tems of Plant Tissues’; Pennington, ‘Plant Distribution at Mu
Lake’; Smith, ‘Some Notes on Nodules’; and Sackett, ‘The Asso-
ciation of Pseudomonas radicicola with Bacillus ramosus.’

Wek:

CORRESPONDENCE

Editor of the American Naturalist:

The Flying Fish problem, discussed by Lieut. Col. C. D. Durnford
in the American Naturalist for February (page 65), seems to be now
reduced to a question of keenness of eyesight. Do the wings or pectoral
fins of this fish in flight move so swiftly that the motion cannot be seen ?
or do they not move at all?

The initial start of the fish on leaving the water is clearly due to
the swift motion of the tail. When the tail is moving, either at the
initial leap from the water, or when by skimming along the surface
the tail touches the water, the wings are seen to be in rapid vibration.
When the tail is free from the water, the wings are outspread fan-
fashion and seem to be held firmly and at rest without vibration, to be
folded when the fish drops into the water. It takes strong muscles
to hold the wings taut; we may admit that the fish has these; it would
take stronger muscles to cause the fish to move through the flapping
of the wings.

The problem is this: Does the fish flap its fins? In the view of
Col. Durnford it does. In his view the vibrations are so rapid that
to most observers they cannot be seen, except at the beginning or end
of the flight, when the tail is in the water.

In the view of others, the wings are not flapped at all. When the
fish rises from the body the tail is flapped, which flaps the body and
causes the wings to vibrate up and down as the body itself is agitated.

The writer has watched many. hundreds of flying fishes. His best
opportunity has been in a small boat in the Santa Catalina Channel,
where the largest of the known species, Cypselurus californicus, over
a foot long, flies by the hundred in March. He is reasonably sure,
so far as any man can trust his own eye, that the wings do not move
when the fish is sailing, and that that portion of the fish’s flight is on
the principle of the aeroplane.

The following note was made by the writer in 1880:

“Their movements in the water are extremely rapid; the sole
source of motive power is the action of the strong tail while in the water.
No force is acquired while the fish is in the air. On rising from the
water, the movements of the tail are continued until the whole body
is out of the water. While the tail is in motion, the pectorals seem to

347

348 THE AMERICAN NATURALIST [Vor. XLI

be in a state of rapid vibration, but this is apparent only, due to the
resistance of the air to the motions of the animal. While the tail is
in the water, the ventrals are folded. When the action of the tail
ceases, the pectorals and ventrals are spread and heldat rest. They
are not used as wings, but act rather as parachutes to hold the body
in the air. When the fish begins to fall, the tail touches the water,
when its motion begins again, and with it the apparent motion of the
pectorals. It is thus enabled to resume its flight, which it finishes
with a splash. While in the air it resembles a large dragon-fly. The
motion is very swift, at first in a straight line, but later deflected into
a curve. The motion has no relation to the direction of the wind.

When a vessel is passing through a school of these fishes, they spring
up before it, moving in all directions, as grasshoppers in a meadow.

Very truly yours,

DAVID STARR JORDAN
February 23, 1907

PUBLICATIONS RECEIVED.
(Regular exchanges are not included)

Hawkes, C. The Trail to the Woods. New York, American Book Co.,
1907. 12mo, 176 pp., illus. 40 ets.— Kerrer, C. A. Nature Studies on the
Farm. New York, American Book Co., 1907. 12mo, 154 pp., illus. 40 cts.—
Le Dantec, F. Elements de Philosophie biologique. Paris, Felix Aloin. 1907.
8vo, vi + 297 pp. 3 fr. 50.— Linvitiez, H. R., anp KeLLY, H. A. A Guide
for Laboratory and Field Work in Zoölogy. Boston; Ginn & Company, 1907.
12vo, vi + 104 pp., illus. 45 ects —— McPHeErson, W., AND HENDERSoN, W. E.
Exercises in Chemistry. Boston, Ginn & Compaiy, 1907. 12vo, xii + 69,
pp., illus. 45 ets.— pr Nussac, L. Les débuts d'un savant naturaliste, le prince

Ventomologie, Pierre-André Latreille, à Brive de 1762 à 1798. Paris, G.
gras: 1907. 8vo, 264 pp., 2 pls.

LBERT I, PRINCE DE Monaco. Sur la huitième campagne de la Princesse-
Alice 1. Bull de U Inst. Océanog. de Monaco. No. 95, 4 pp. — ALLEMANDET,
G.-H. Analyse de quelques échantillons de Pélagosite recueillis dans le port
de Monaco. Bull. de Inst. Océanogr, de Monaco, no. 91, 11 pp. — Barrscu,

A new mollusk of the genus Macromphalina from the west coast of Amer-
ica. Proc. U. S. Nat. Mus., vol. 32, p. 233.— BELL, A. G. Aerial locomo-
tion. ha! Washington Acad. Bet., vol. 8, PP- iota, pls. 9-20.— BouvIER,
E.-L. au cours d’une campagne scienti-
fique P 8 X S. hiore de Monaco (1905). Bull. de U’ Inst. Océanogr. de
Monaco, no. 93, 9 figs— BUREAU OF FISHERIES. Statistics of the
middle Atlantic rsh he 1904. Document No. 609. The distribution of
food fishes during the fiscal year 1906. Document No. 613.— Carp, F. W.
Corn selection. R. I. Agric. Exp. Sta., bull. 116. 35 pp., 9 figs.— Cops, N. A.
Fungus maladies of the sugar cane, with notes on associated inseets and
nematodes. Rep. of the Exp. Sta. of the Hawaiian Sugar Planters’ Assoc.,
bull. 5, 2nd ed., 254 pp., 101 figs., 7 pls.— Epwarps, H. T. The cultivation
of Maguey in the Philippine Islands. Dept. of the Int., Bur. of Agric., Farm
Bull. 13, 25 pp., 9 pls.— Eıgenmann, C. H. Ona collection of fishes oak

Euuiot, D. G. A catalogue of the collection of mammals in the Field Colum-
ay Museum. Field Columbian Mus., zoöl. ser., vol. 8, pub. 115, pp. 1-694,
2 figs— GÁNDARA, G. = suzuilde del calato. Com. Parasitol. Agric.,
Mien eirc. 51, 7 pp. > 6 figs.— GREENMAN, J. M. Studies in the genus
Citharexylum. Field C! Mus., bot. ser., vol. 2, pub. 117, pp. 185-190.
ia TWELL, B. L. Analyses of commercial fertilizers. R. I. Agric. Exp.
Sta., bull. 117, pp. 39-52.— HRDLIČKA, A. Measurements of the cranial
f Proc. U. S. Nat. Mus., vol. 32, pp. 177-232, pls. een J. R.
Las mantas 6 campamochas. Com. Parasitol. Agric., México, circ. 54, 14
2 figs.— Jorpan, D. S. A review of the fishes of the er Histiopterides,
found in the waters of Japan; with a note on Tephritis Günther. Proc. U. 8.
Nat. Mus., vol. 32, pp. 235-239.— Jounin, L. La Presqu’ile de Quiberon.

349

350 THE AMERICAN NATURALIST [Vor. XLI

Bull. de U’ Inst. Océanog. de Monaco, no. 92, 24 pp., 19 figs., 4 pls.— Jupay, C.
‘Ostracoda of the San Diego region. II. Littoral forms. Univ. of Cal. Publ.,
Zool., vol. 3, pp. 135-150, pls. 18-20.— Jupay,C. Cladocera of the San Diego
region. Univ. of Cal. Publ., Zool., vol. 3, pp. 157-158, 1 fig.— MILLSPAUGH,
C. F. Flora of the sand hie of Florida. Field Columbian Mus., bot. ser.,
vol. 2, pub. 118, pp. 191-243, 19 maps.— Moore, H. F. Survey of oyster
bottoms in Matagorda Bay, Texas. Bureau of Fisheries, doc. 610, 86 pp., 13
pls., 1 map.— Netson, A. Some potato diseases; their cause and control.
Wyoming Exp. Sta., bull. 71, 39 pp., 11 figs — Noweıı, H. T. Duty of water
on field pease. Wyoming Exp. Sta., bull. 72, 16 pp., 4 figs.— SCHAEFFER, C.
‘Seve Bruchide, with notes on ken species and list of species known to occur
at Brownsville, Texas, and in the Huachuca Mts., Arizona. Brook lyn Inst.
of Arts and Sci., vol. 1, pp. 291-306.— SCHLAGINHAUFEN, O. Uber das
Laitan dal der Hohlhand und Fusssohlen-Flächen der Halbaffen, Affen, und
Menschenrassen. Ergebn. d. Anat. u. Entw., vol. 15, pp. 628-662, 14 figs.—
SCHLAGINHAUFEN, O. Beschreibung und Handhabung von Rudolf Martins
diagraphentechnischen Apparaten. Korrespondenzbl. d. Deutsch. Gesellsch.
i Anthr. Ethn. u. Urgeschichte, vol. 38, pp. 1-6, 4 figs.— SCHLAGINHAUFEN,
O. Ein Canalis craniopharyngeus persistens an einem Menschenschädel und
sein Vorkommen bei den Anthropoiden. Anat. Anz., vol. 30, pp. 1-8, 5 figs
— SHAFER, G. D. Histology and development of the divided eyes of orten
insects. Proc. Washington Ac aa eS vol. 8, pp. 459-486, pls. 24-27.—
SPRINGFIELD MUSEUM or Natu gene Bird migration; dates of
arrival of birds within ten miles = Springfield, Mass., from 1901 to 1906.—
Vrès F. Sur l’existence de la Mye dans la Méditerranée. Bull. de VInst.
Océanog. de Monaco, no. 94, 2 pp.— Wırcox, W. A. The commercial fisheries
of the Pacific Coast States in 1904. Bureau of Fisheries, doc. 612, 74 pp.
Bo. E

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NATURAL

A MONTHLY JOURNAL — č
DEVOTED TO THE NATURAL SCIENCES a
CONTENTS
I. A Graphic Method of Correlating Fish Environment and Distribution

ALBERT E. WRIGHT :
II. The Microgametophyte of the Podoearpinen
= oo ee ee

III. The Problem of Color V

The American Naturalist

EDITOR
FREDERIC T. LEWIS, M. D., Harvard Medical School, Boston, Mass.
ASSOCIATE EDITORS

4. À. ALLEN, Pu.D., American Museum of Natural History, New York
_ E. A. ANDREWS, Pa.D., Johns Hopkins University, Baltimore
= y * * t ll

ID: S. JORDAN, LL.D., Stanford University

CHARLES A. KOFOID, Pu.D., University of California, Berkeley.
SEG. NEEDHAM, Pa.D., Cornel University, Ithaca

_ ARNOLD E. ORTMANN, Pa useum, Pittsburg

SE P. PENHALLOW, D.Sc., BER: MeGill University, Montreal

H

7
ER
= LEONHARD STEINE STEJNEGER, LL.D., Smithsonian Ins titution, Washington.
a

x

in some line; in addition to these
rial

aments on en mn
ents on of y, an un

her scientific

THE |
AMERICAN NATURALIST

Vor. XLI June, 1907 No. 486

A GRAPHIC METHOD OF CORRELATING FISH
ENVIRONMENT AND DISTRIBUTION

ALBERT HAZEN WRIGHT

Ir is some years since ornithologists saw the advantages of a
graphic means of representing complex bird waves and their
coincident relation to physical conditions. In ichthyology a
schematic method whereby fish distribution and environment
can be correlated is not less valuable.

The study of a stream and its fishes involves the consideration
of factors so numerous and so diverse, and accumulates such a
mass of data, that one is impelled to adopt some graphic method
to make results appear quickly and clearly.

The chart to be described presently (Fig. 1) is of a hypothetic
stream, including a variety of possible conditions. ‘The first con-
tinuous vertical line to the right of the list of species represents
the mouth of the stream, and the corresponding vertical on the
right of the chart is its source. ‘The dotted verticals numbered
below (1-8) mark mile points. Beneath the “Misc. Data” space,
these mile lines are not dotted but continuous.

The heavy horizontal opposite each species indicates the range
of that species in the stream. Wherever the horizontal is broken, -
it indicates the occasional occurrence of the species. Whenever
a species gains entrance to a stream from two or more points an
arrow tip at the end of each of its range lines indicates the direction
of its migration; e. g., in our hypothetic stream the carp, Cyprinus
carpio enters from the mouth and from canal overflows.

The continuous horizontal above the first species in the list,
represents the surface of the water. The bottom is shown by the
curved line labeled “Bottom of Stream.” The average depth

351

352 THE AMERICAN NATURALIST [Vor. XLI

at any given point is, therefore, the vertical between these two
lines, read from the scale at the extreme right of the chart.

The continuous horizontal immediately below the last species
enumerated, represents the altitude of the mouth above sea-level.
The profile line indicates the drop in the stream. The approxi-
mate altitude of any given point along the stream is shown by the
vertical between the two above mentioned lines, and read from
the scale at the right.

The continuous horizontal in “Valley Cross Sections” repre-
sents the stream, on either side of which is shown a section of the
country for one and a quarter miles. In these cross sections at
every mile point the geologie formation can be indicated.

The current, width and bottom data are self explanatory. In
the “Miscellaneous Data,” bridges, marshy regions, dams, etc.,
are represented so far as possible, by the conventional signs

employed by the U. S. Geological Survey, thus:

Briggs na 8; (A) e.g., below the one mile mark, at the
two mile mark, etc.

Woodlands......... (B) “ at the one mile mark.

SWAMPS ocd NG. (C) “ between the one and two mile
marks.

Important Tributary (D) represented by a forked wavy line.
The position of the tributary line
in the upper or lower part of the
“Mise. Data” space indicates
that the tributary enters the stream
from the right or left side respec-
tively.

“ at the 1.25 mile mark. (Enters
from the left side.)
“ at the 2.6 mile mark. (Enters
from the right side.)

ig Weep rears ce (Œ) “ oneither side of the four mile mark.

Daws ee Ae. (F) “ at the 5.6 mile mark.

Remains of a Dam..(G) “ at the seven mile mark.

Small Tributary.... (H) represented by an unforked wavy

line.

at the 5.8 mile mark. (Enters

from the right side.)

A
kad

Name of Stream

Nature of Bottom
= ae
Species Mud Gravel Rock Gravel Mua Clay | Gravel Feet
Sur fa ce of _ water
Catostomus H T ë
commersonii H 1 nay i e i t
Cato ste mus ' m = , —
re. TR a | 2
al meturas a `
nebulosus > el aaa S { á
Nolurus
flavus ee KERRY | 4
Aramis A
crysoleucas 5
Notropis j
yuga | Š
Boleosema l i E
FETTE H -
l'abella re B I 700
Cyprinus = ; (0U
Mr Ende > i — BE
Rhinichlhys i + eres
alronesus vs nA
oo DAA | re ER er
Ums t +
E mi i à Yun Pe: i ROO
Zuealia i m
„= = fants E4 -
le 7 |
Miceropferu : ug
le Means °
Exeglessum a
E pia “ua i
Bape mis Tis 300
i m mi 7 - i
Semolilus L
NN 4
Sche Toa — 200
ws ‘game J
‚Schr Tareas
roan Sander
Level of mehth en
Mi 1 es ® 3 5 8 8 BEN
Current | Percentidle | Swift a BaT E Swift \Sill | Gentle | LS weft
Mi Se. fa ee if t P | / ß
Data vice | | 1 | ps WAJ |
. A De N D E 5 F H HUI
Width ae
N
ese m 24
a Me
x on.
ä -5280
x &
\ ` -28640
Ñ :
r ï Pr
Valley S 1320
2 R aE 660
Cross- à i
Sections À ¥
: k
» '-
$ :
| 3

Fic. 1.— A Hypothetic Chart Correlating Fish Environment and Distribution,
Explanation of Miscellaneous Data,

Bridge,
Roum

Q 'z

|

s.....

Dam
nr Remains of a Dam,

. Small Tributary.

. Canal

354 THE AMERICAN NATURALIST [Vor. XLI

e. g., at the 7.25 mile mark. (Enters
from the left side.) |
Canak aom or (I) “ at the 7.5 mile mark.

Taking the common bullhead, Ameiurus nebulosus, as an
example, one is able to read from the chart, concerning its distri-
bution, etc., the following: it is common in the lower two miles
of the stream, gradually decreasing in abundance at the end of the
second mile. Throughout the middle course where rock or
gravel bottoms and swift water or rapids occur this species is
absent. In the upper course where the current and bottom are -
influenced by the dam, located 5.5 miles from the mouth, it re-
appears. In the latter instance, its presence so near the head-
waters is due to canal overflows at the 7.5 mile point. It seldom
frequents water less than 4 feet deep. In both ranges, the drop
in the stream is slight, so that the current is just perceptible at
the mouth, and imperceptible at the dam. At these two points
the stream’s width is respectively 27 and 32 feet. In both places
a muddy bottom obtains. In the lower course the stream lies
on a delta formation while in the upper course the underlying
stratum is glacial drift.

The Johnny darter, Boleosoma nigrum, occurs at the source
of the creek, due to a contribution at floodtime from another
stream across the divide, the two sources being on the same level
and continuous at some seasons. The falls on either side of the
4 mile point would preclude its reaching the source from the mouth.

One objection to the chart, which appears serious at first, is
its failure to show migration within the stream. If a stream,
however, be charted in this way in the spring, summer and autumn
and a comparison of the three charts be made, many interesting
deductions might be drawn. Should it seem desirable to make
the work more intensive, to restrict it to a limited portion of a
stream and to a single species, daily surveys might be made and
the results embodied in one chart. The date of each daily survey
could be placed in the spaces now occupied by the specific names
and the range line for the day constructed opposite the date.

CORNELL UNIVERSITY
Ithaca, N. Y.

.

THE MICROGAMETOPHYTE OF THE PODO-
CARPINE/!

E. C. JEFFREY AND M. A. CHRYSLER

ALTHOUGH at the present time the views in regard to the rela-
tionships of the Coniferales depend very largely on the study of
their gametophytic or sexual generation, our knowledge in regard
to the gametophyte of the coniferous families is often very meager.
The two families concerning which information is actually most
needed are the Podocarpineae and the Araucarineae, exotics con-
fined chiefly to the southern hemisphere. ‘There is a prospect that
our ignorance in regard to the Araucarineae will soon be less dense
than it is at present, a consummation devoutly to be desired on
account of the prevailing views, which make them the most ancient
of the Coniferales. It is proposed in the present article to describe
certain features of the male sexual generation of the Podocarpineae
observed in material which we owe to the kindness of Dr. Cockayne
of Christchurch, New Zealand, and Dr. Treub, Director of the
Royal Gardens at Buitenzorg, Java. ‘To both of these we tender
our very warm thanks for the unfailing good nature which has
made it possible for us to study some of the Australasian genera
of the Podocarpineae. The material at our disposal was fixed
in formaline or alcohol and consequently leaves something to be
desired in the preservation of cytological details. As we shall
however confine ourselves to the gross features of nuclear structure
which do not suffer seriously by the methods of preservation de-
scribed, this will not be a serious disadvantage.

The first species to be considered is Podocarpus polystachya,
material of which we owe to Dr. Treub, Director of the Botanic
Gardens at Buitenzorg. The male cones in our possession are
in various stages of anthesis; but some of them show quite young
anthers or microsporophylls in the upper region of the axis. This
feature has made it possible for us to follow step by step the
development of the male gametophyte up to the time of the shed-

‘Contributions from the Phanerogamic Laboratories of Harvard University.
0.8.

355

356 THE AMERICAN NATURALIST [Vor. XLI

ding of the pollen or microspores, in spite of the fact that the
material represents a single collection. A figure 1, represents
the first mitosis in the microspore, which it will be observed is
well advanced toward completion. ‘The state of preservation of
this material is remarkable in view of the fact that it was fixed
in strong alcohol. In b figure 1, is to be seen the first prothallial
cell fully formed and lying over against the upper or posterior side
of the microspore. Beneath it, is the residual nucleus surrounded
by vacuolated protoplasm. In c figure 1, is to be seen the mitosis
which precedes the formation of the second prothallial cell. Ind

Fig. 1.— Podocarpus polystachya. a, First division of microspore. b, First pro-
thallial cell cut off. c, Cutting off of second prothallial cell. d, Two prothal-
lial cells cut off. X 925. The lateral air chambers, completely shown in
a, are one of the numerous features of resemblance between the pollen of the
Podocarpinee and that of the Abietinee.

figure 1, the second prothallial cell is complete and lies against the
first. At about this time the strongly thickened posterior wall of
the microspore, which seems to be a peculiar feature of podocar-
pineous pollen, becomes markedly sculptured as is shown ind. In
a figure 2, is shown a still later phase where the so-called genera-
tive cell has become added to the prothallial cells, which lie on the
posterior wall of the microspore; it arises from another division of
the residual nucleus. The contents of the pollen grain at this stage
resemble in detail the conditions to be found in the abietineous
microspore before the prothallial cells have begun to degenerate.

No. 486] PODOCARPINEE 357

In Podocarpus however there is no atrophy of the prothallial
rudiments at this stage, but they undergo further changes of a sur-
prising character, comparable only to those recently described by
"Thomson in the genus Araucaria. In b figure 2, a later stage of
development is shown, in which each of the prothallial cells has
undergone transverse or anticlinal division. Division generally
takes place first in the outer prothallial cell lying next the wall

Fie Posi — Bg oti polystachya. a, Generative cell cut off. b, Anticlinal divi-
s of the two Dee proth allial cells. c, Mitosia i in the _ a coe -

scr wear cell. d, ei of prothallial

the pollen grain.
of the microspore and subsequently in the second prothallial
cell. Contrary to the statements of Coker? in regard to P. coriacea,
where a similar but less well marked condition has been described
as a probable abnormality due to artificial conditions, anticlinal
divisions of the prothallial cells are not initiated by direct divi-
sion of the nucleus but by true mitosis. In the cells derived from

‘Thomson, R. B. The Araucariee — a ‘Proto-Siphonogamic’ method
of Fertilization. Science N. S. 25: 271, 272. 1907.

? Coker, W. C. Notes on the organ ty and embryo of Podocarpus.
Botan. Gazette 33: 89-107. pls. 5-7.

358 THE AMERICAN NATURALIST [Vor. XLI

the second prothallial cell in b figure 2, the nuclei are still in the
spireme condition. Occasionally anticlinal divisions occur in the
generative cell as in the prothallial rudiments. One such case is
represented in c figure 2, which is an obvious and clear mitosis.
Usually however in P. polystachya such divisions of the generative
cell do not occur, although they are exceedingly common in some
of the other species which we have had the opportunity of study-
ing. At about this time the prothallial cells lose their walls; and
their nuclei, floating freely in the cavity of the microspore, are no

Fie. 3.— Podocarpus ferrugine ‚Two erg cells and ge cells
formed. b, Anticlinal pestis of second prothallial cell. c, Tangential
view of prothallial end of the oona “a Anticlinal divisions oe both

e, nerati 1 X 925.

prothallial cells.

longer enclosed by cytoplasmic bodies. The nuclei, however,
persist indefinitely and pass out as a swarm into the pollen tube.
Among the unusually numerous free nuclei present in the micro-
spore at this stage, the residual or tube nucleus can be distinguished
readily by its large size, as is shown in figure 2 d; the generative
cell, or the central cell derived from it in case it has undergone

No. 486] PODOCARPINEE 359

anticlinal divisions previous to being set free from the prothallial
complex, always retains its protoplasmic body as is generally the
case in other Gymnosperms, and thus cannot be confused with
any of the other contents of the microspore in the condition which
immediately precedes anthesis.

In Podocarpus ferruginea from New Zealand, material of which
we owe to the kindness of Dr. Cockayne, the earlier stages are
not so well represented as in the species described above, but so
far as they have been followed they present no essential deviation
from the course of events in P. polystachya. A figure 3, represents
the abietineous stage of development in this species. The preser-
vation is even less good than that of the Podocarpus already de-
scribed, and the protoplasm has shrunken from the microspore
membrane. In b figure 3, is shown a fully developed grain, in
which only one of the prothallial cells has undergone division.
The generative cell in this case is also free from divisions, although
it has rounded off and is almost ready to be set free from the
cavity of the microspore. C figure 3, presents a tangential view of
the first prothallial rudiment, which in this case has undergone
two anticlinal divisions, so that four cells have resulted. D figure
3, presents a longitudinal section through the air chambers and
shows anticlinal divisions in both of the prothallial cells. Æ figure
3, shows a similar condition’ in the prothallial rudiments; but in
this case there are two lateral derivatives of the generative cell.
The latter are very small in size compared with the central cell of
the generative complex and with the derivatives of the prothallial
rudiments.

As is represented in figures 3 and 4, starch is commonly found
in the pollen grains, especially in the younger stages, though its
presence is by no means constant. A similar feature has been
noticed by Coker in the article cited above.

A figure 4, shows the structure of a ripe pollen grain in P.
dacrydioides, from material sent us by Dr. Cockayne. ‘The con-
ditions are identical with those shown in e figure 3, representing

. ferruginea.

B figure 4, shows the gametophytic development in a probably
mature microspore of Dacrydium Bidwillii, another representa-
tive of the Podocarpineze. ‘The material in this case proved to be

360 THE AMERICAN NATURALIST [Vor. XLI

very badly preserved. Dacrydium is distinguished from Podo-
carpus by the transverse striations of the thickened posterior wall
of its microspore. In the species of Dacrydium which we have
examined more than two prothallial cells are present, but the
derivatives of the prothallial rudiments do not seem to be as
numerous as they are in Podocarpus, where there may apparently
be as many as eight present (P. ferruginea).

Through the kindness of Dr. Cockayne we have had the op-
portunity of comparing the microgametophytic development of
Podocarpus and Dacrydium with that presented in Agathis,
probably the more ancient of the two living genera of the Arau-

Fig. 4.— a Podocarpus dacrydioides. Divisions of prothallial and generative cells,
b, Dacrydium Bidwillii. The second prothallial cell has divided. X 925.

carinee. In our material of Agathis the protoplasm is unfortu-
nately very much shrunken, possibly on account of the small
amount of alcohol in which it was preserved, but this fortunately
does not interfere with the understanding of the general conditions
present in the microgametophyte. In b figure 5, is shown an
apparently mature microspore. We cannot however speak with
certainty on this point, since none of the microsporophylls in our
possession have shed their pollen. It is to be noted that the
conditions present in this figure closely resemble those depicted
in b figure 2, and d figure 3. In other words there are sub-
sequent anticlinal divisions present in the two prothallial rudiments
which are originally laid down as they are in the Abietinew. A
figure 5, resembles b closely and differs in the fact that only one
of the prothallial rudiments has become divided. In c figure 5,
is shown a tangential view of one of the prothallial cells. There
have obviously been two anticlinal divisions in this case.

No. 486] PODOCARPINEE 361

It is apparent from the foregoing paragraphs that in two genera
of the Podocarpinez there are unusually numerous prothallial
cells present in the microspore, which are derived by the subsequent
anticlinal divisions of the two primitive prothallial cells. That
these features are perfectly normal ones in the Podocarpinez is
made clear by the fact that all our material is from plants grown
in their native habitat and presumably under natural conditions.

C
FıG. 5.— Agathis australis. a, The divided first prothallial cell, undivided second
protha llial cell generative ce b, The same, but the seconi
PeO cell has also a: c, Tangential view of the prothallial end of
e gametophyte.

These features are further paralleled by the conditions presented
by the microspore of the araucarian genus Agathis. The question
here arises if we are to regard the rich prothallial endowment of
the Podocarpinex as the retention of a feature possessed by the
ancestral Coniferales or as a recent cenogenetic adaptation, which
has arisen at a later stage of evolution. ‘This question can only
be answered by a consideration of the microgametophytic condi-
tions found in the Gymnosperms in general, particularly the
more ancient of those still living. In the primitive zoidogamous

362 THE AMERICAN NATURALIST [Vor. XLI

Cycads and Ginkgo there are one or two prothallial cells present.
The generative cell undergoes only a tangential or periclinal
division in connection with the formation of the stalk cell and
antheridial cell. The antheridial cell in both the Cycadales and
Ginkgoales gives rise to two spermatocytes, the mother cells of
antherozoids. In the Abietinex, which we know from the
evidence of the fossil remains extend very far back geologically .
in forms allied to Pinus, there are two evanescent prothallial cells
present in the mature microgametophyte, and a generative cell
which as in the zoidogamous Gymnosperms gives rise to stalk and
antheridial cells by periclinal division. The antheridial cell in turn
gives rise to two cells which are to be regarded as the homologues
of the two spermatocytes of the Cycadales and Ginkgoales. In
the Araucarinez, so far as our knowledge goes, there are formed at
first two prothallial cells, which may subsequently undergo more or
less numerous anticlinal and possibly also periclinal divisions.
The final history of the generative cell is obscure, but it is to be
inferred from the brief summary of Thomson (loc. cit.) that the
antheridial cell of the Araucarinez does not divide into two as in
the Abietinee and the ancient zoidogamous Gymnosperms. In
the Araucarinex there is a further remarkable feature in that the
pollen grain does not reach the micropyle of the ovule as in the
other Coniferales and all other known Gymnosperms living or
fossil; but is deposited on some part of the ovuliferous scale or
megasporophyll (on the ‘ligule’ in Araucaria) thence sending a
pollen tube down to the ovule, in a manner analogous to that
obtaining in the Angiosperms. ‘Thomson, adopting the prevailing
hypothesis that the Araucarinez are the most primitive Coniferales,
designates this peculiar mode of fertilization as primitive or ‘ pro-
tosiphonogamic.’ :

This view presents some difficulties, for if the quasi-angiosperm-
ous method of fertilization found in the Araucarinez is ‘primitive’
it is difficult to see why such a method is entirely absent in the
older gymnospermous series, the Pteridospermz, Cordaitales
and Ginkgoales, or being ancestral for the Coniferales is entirely
lost in the coniferous families other than the Araucarinez, which
have moreover a method of pollination resembling closely that
of the older Gymnosperms in that the microspores are received
through the micropyle. The reported presence of only a single

No. 486] PODOCARPINEE 363

sperm-cell in the Araucarinese supplies another argument against
their being more primitive than the other Coniferales. Their su-
perior antiquity further does not rest on any sound palsonto-
logical basis, for so competent an authority as Schenk (Zittel’s
Handbuch) remarks that if more abundant and more ancient
geological occurrence were to be considered as a criterion of anti-
quity, the Araucarineze must yield place to the Taxodinex. It
appears not unlikely, especially in view of observations made by
one of us on Mesozoic Coniferales, shortly to be published, that
the ‘protosiphonogamic’ method of fertilization which is the inter-
esting discovery of Mr. Thomson, is correlated with the prolifera-
tion of the prothallial cells in the Araucarinez, since the greater
length of pollen tube, in the absence of any special conductive
tissue such as is found in the Angiosperms, calls for a greater
development of prothallial tissue. The failure of the pollen to
reach the micropyle, on the other hand, may have been due to the
unfavorable influence of drought upon the fluid secretion which in
other Conifers floats the pollen to the micropyle.

Turning from the Araucarines to the Podocarpinex, we find
very similar conditions in regard to the prothallial proliferations.
The plan of prothallial development here as in the Abietinez and
Araucarinee involves two prothallial cells, but as in the Arau-
carinee these have apparently undergone cenogenetic prolifera-
tion. ‘That this is the true view of the matter is rendered more
probable by the fact that even the generative cell may be affected
by the process of proliferation, as in Podocarpus polystachya, P.
ferruginea and P. dacrydioides, described above. There is cer-
tainly no reason from our knowledge of the older and zoido-
gamous Gymnosperms to regard the anticlinal proliferation of
the antheridial cell as a primitive feature, since so far as our present
information goes such a phenomenon is quite absent here. Further
whatever prejudice there may exist in favor of the Araucarinee
being a primitive family of Conifers, there can be none in favor
of a like view in the case of the Podocarpinee. The develop-
ment of the microgametophyte in the case of the Podocarpines
as here described only serves to strengthen the opinion already
expressed by Coker (op. cit.) and Thomson‘ that they are not

‘Thomson, R. B. The megaspore-membrane of the Gymnosperms, Univ.
of Toronto Studies, Biological Series No. 4. 1905.

364 THE AMERICAN NATURALIST [Vor. XLI

very remotely connected with the Abietinex. Their peculiar pro-
thallial developments represent an apparently cenogenetic super-
addition to the primitive type of coniferous microgametophyte
found in the Abietinez. If this view be taken of the position
of the Podocarpinex, it may well be extended to the Araucari-
nes which present a similar microgametophytic development,
although it would take us too far afield and would involve the
discussion of yet unpublished data in regard to living and fossil
Coniferales, to defend that proposition in the present connection.

SUMMARY

1. The Podocarpinez as represented by the genera Podocarpus
and Dacrydium are characterized by a proliferation of the two
original prothallial cells through more or less numerous anticlinal
divisions.

2. The anticlinal proliferation of the prothallial cells in some
cases is accompanied by a similar proliferation of the generative
cell, an abnormality which appears to have been described in no
other Gymnosperms.

3. Similar proliferation of the two original prothallial cells
has been observed in the araucarian genus Agathis.

4. The proliferation of the two prothallial cells in the Podocar-
pinese and Araucarinez and the proliferation of the generative
cell in certain species of Podocarpus, cannot be regarded as a
primitive feature.

5. The ground plan of microgametophytic development found
in the Podocarpinex and Araucarinese points to their derivation
from an ancestral stock allied to the Abietineze.

6. Since the Podocarpinee and Araucarinee present many
features of similarity in general habit, in geographical distribution,
in the organization of their megasporophylls, and the development
of their microgametophytes, it seems not improbable that they
are somewhat more nearly allied than has been supposed

HARVARD UNIVERSITY.

THE PROBLEM OF COLOR VISION

JOHN M. DANE

THE problem of color vision is one of the most intricate which
the biologist is asked to solve. The following paragraphs are
intended to indicate the several methods which are being employed
for its solution, together with some of the results thus far obtained.
The anatomy of color vision will be considered first; then in turn
its physiology and its development; and finally, the abnormal
conditions of color blindness, together with the thogar of normal
vision to which they have given rise.

Anatomy. The mechanism of color vision is lodged i in the rod
and the cone cells. A ray of light, after passing through the
lens of the eye and its vitreous body, penetrates several layers of
the retina, thus arriving at the proximal ends of the elongated
rod and cone cells. These cells are arranged in a single row.
The light traverses the length of the cells to their distal ends which
it stimulates. The rod and cone cells project against a single
layer of heavily pigmented cells, the stratum pigmenti retinae
(Fig. 1, S. P.). These have non-retractile processes which are
found between the rods and the cones. The pigment fuscin, in
the form of elongated or crystalloid granules, migrates into these
processes when the eye is illuminated; in the dark it is withdrawn
into the cell body. |

Every rod cell consists of a rod, a rod fiber, and a nucleus,
arranged as shown in Fig. 1, A. A rod, which is from 40 to 50 u
long and 1.5 to 2 x in diameter, consists of a doubly refractive,
lustrous outer segment, and a singly refractive, finely granular
inner segment. In serum or dilute osmic acid the outer segment
breaks into a series of regular transverse discs which are believed
to indicate a stratified structure in the living rods. Visual purple
is a pigment which occurs only in the outer segments of the rods.

365

366 THE AMERICAN NATURALIST [Vor. XLI

It bleaches rapidly in the light, but (unless the pigmented stratum
has been removed experimentally) it is soon restored in the dark.
Light thus appears to incite chemical processes in the outer seg-
ments of the rods. The inner segments are sometimes described
as having a longitudinally fibrillar structure in their outer portions.
The opposite ends pass rather abruptly into the very slender rod
fibers. Each fiber somewhere in its course expands to enclose
the nucleus, and finally terminates in a pyriform enlargement.
The nucleus in preserved specimens may have its chromatin
arranged in a few broad transverse bands.

Every cone cell consists of a cone, a cone fiber, and a nucleus.
The cones like the rods are divisible into outer and inner segments.
The outer segment is usually shorter than that of the rod (12 x)
and tapers somewhat to its rounded extremity. It never contains
visual purple, but otherwise, as for example in breaking into trans-
verse discs, it resembles the outer segment of the rod. ‘The inner
cone segment bulges like the body of a flask. It is divided into
an outer, longitudinally fibrillar, ellipsoid portion, and an inner
contractile myoid portion. The non-contractile ellipsoid is said
to become strongly eosinophilic in the dark. Because of the myoid
substance the cones, unlike the rods, may alter their length. ‘The
contractility is said to be less in man than in the pig, and less in
the latter than in some amphibia and fishes where the myoid
segment is reported to shorten from 50 a to 5 y. The nuclei are
found in a mass of protoplasm near the base of the cone; beyond
the nucleus the protoplasm forms a cone fiber which is thicker
than that of a rod and which ends in a branched and expanded
base.

The stimuli received by the outer segments of the rods and
cones are transmitted through their fibers to the nerve cells of the
retina, and thence to the brain. A single retinal nerve cell receives
the stimuli from several rods and cones.

Since rods and cones are believed to have different relations to
the perception of color their distribution in man and other animals
should be significant. In the peripheral portion of the human
retina rods are in excess, so that in sections three or four rods
appear between every two cones. Near the depression or fovea
where vision is most acute, rods and cones are equally abundant,

No. 486] THE PROBLEM OF COLOR VISION 367

and in the fovea itself only cones are found. These cones, how-
ever, are strikingly rod-like in form, and greatly exceed the rods
in length (Fig. 1, B). Slender cones are also found in the thick-
ened area centralis which in many mammals replaces the human
fovea.

In the ape, horse, pig, cow, sheep, and dog the rods and cones
are similar to those of man. In rodents which avoid the light
the cones are “very small and hard to detect since their inner
segments scarcely differ from those of the rods, from which they
may be distinguished by their much shorter outer segment. M.

Fia. 1.— A, diagram of human rod cells and cone cells from the fr ge ogg part
of the retina. B, cone cells from the fovea, drawn on the s cale,
Schultze at first questioned the existence of cones in the mouse,
guinea pig, mole, hedgehog, and bat. The cat undoubtedly has
cones but they are small, slender, and except in the area, infre-
quent.’ Birds have a single or double fovea, like that of man.
Cones are small but very numerous, and in their inner segments
they often contain a drop of oily substance, either colorless or
various shades of yellow, green or red. Presumably these drops
which are absent from the rods and some of the cones, exert an
important influence upon color perception. In owls the bright
colored drops are lacking and the cones are said to be fewer.
Some reptiles have fovex; two kinds of visual cells are reported,
neither of which resembles the mammalian rods. M. Schultze
1 The quotation, and much of this account of the retina, is from von Ebner’s
resumé in Koelliker’s Handbuch der Gewebelehre, 1902, vol. 3, p. 818-832.

368 THE AMERICAN NATURALIST [Vor. XLI

believed that reptiles have only cones. In fishes and amphibia,
both rods and cones occur; in some sharks, rays, and eels, however,
the cones so resemble rods that they may be overlooked. Whether
or not deep sea fishes are without cones is apparently unknown.
In the various groups of animals the rods and the cones each
present modifications of structure, with which as yet physiological
observations have not been correlated.

Physiology. ‘The physiology of color vision is the study of the
functions of the rod and the cone cells. In passing from a bright
to a very dim illumination one experiences a momentary blindness;
after becoming accustomed to the darkness, a modified form of
vision is regained. In this twilight vision the fovea is far less
sensitive to light than the more peripheral parts of the retina.
Moreover all objects appear in shades of gray. The spectrum is
bright but colorless, and its brightest part has shifted from the
yellow portion toward the blue. Von Kries has explained these
facts by assuming that the cones are the agents of day vision, and
the rods of twilight vision." Cones, exclusively, occur in the fovea
where day vision is most acute; and rods predominate where
twilight vision is at its best. The fluctuations in the visual purple
of the rods show that they respond to the varying intensities of
dim light, and this purple is known to desintegrate most rapidly
in green light which appears brightest in twilight vision. Whether
or not the bleached rods are active in day vision has not been
determined.

It is probable that all cones do not respond to color stimuli.
In the peripheral portion of the retina there is a partially color-
blind region where red and green cannot be distinguished from
one another; and the outermost portion of the retina is always
totally color blind. Since cones occur in these areas they also
must be color blind. From these considerations it is reasonably
assumed that, in human vision, the ability to perceive colors
depends upon the differentiation of certain of the cones.

Since at the present time the nature of vision cannot be deter-
mined by the microscopic examination of the retina, and since
a very efficient vision may exist without color perception, it may

* Von Kries presents this Duplizitätstheorie in Nagel’s Handbuch der Physiol-
ogie, 1904, vol. 3, p. 168-193.

No. 486] THE PROBLEM OF COLOR VISION 369

fairly be questioned whether the lower animals are capable of
color vision. The biological importance of this problem is very
great, since prevalent theories of the development of the colors
of flowers, and the bright plumage of male birds, assume a color
perception in insects and female birds essentially like that in man.
To learn what a bee actually sees has been thought impossible
since it requires that one should possess the nervous system of
an insect and still remain a man.

There is a large literature dealing with the distinctions which
the lower animals make between various colors, but the factor of
intensity or brightness has seldom been satisfactorily eliminated.
The trout fisherman is confident that one fish, at least, discrimi-
nates colors with precision. Careful experiments with the chub,
by feeding it from colored forceps and taking certain precautions
to eliminate brightness, indicate that the chub distinguishes red
from green and from blue.*

Nagel, who is convinced that the phenomena of mimicry and
warning colors demand color vision in animals, experimented
with the dog. After taking precautions to eliminate brightness,
he proved that the dog perceived the difference between red and
blue, blue and green, and red and green.”

Kinnaman tested the monkey, Macacus rhesus. Its food was
placed in one of six receptacles, precisely alike except that each
was of a different color. When the monkey had learned to choose
correctly the food-containing glass, a different color was selected.
Thus the monkey learned to proceed at once to the receptacle
with food, whether it was blue, yellow, red or green. It was
tested also with a black and light gray glass. Having learned
that the food was in the former, successively darker grays were
substituted for the:empty one. The percentage of wrong choices
increased and it was found that grays were confused which the
human eye can distinguish with perfect ease and certainty. Kinna-
man concludes that “there can be no doubt that monkeys per-

‘Washburn, M. F. and Bentley, I. M. The establishment of an associa-
tion involving color discrimination in the creek chub. Journ. of Comp.
Neur., 1906, vol. 16, p. 113-125.

* Himstedt, F., and Nagel, W. Versuche über die Reizwirkung verschiede-
ner Strahlarten auf Menschen- und Tieraugen, Festschrijt der Albert-Ludwigs-
Universität in Freiburg, 1902.

370 THE AMERICAN NATURALIST [Vor. XLI

ceive colors.” Two colors of equal brightness are distinguished
better than two grays of equal brightness; and though the bright-
nesses are the same, colors may be distinguished from grays. '

In the dancing mouse, however, the cones of which are at least
very rod-like, Yerkes has recently found that color vision is ex-
tremely poor. There is some evidence of discrimination of red
and green, and of red and blue, but none whatever of blue and
green. Apparently such visual guidance as is received results
from differences in brightness. ‘The mouse discriminates blacks
grays, and whites.’

Because of the inherent difficulties in the investigation of color
vision in the lower animals, comprehensive results have not
yet been obtained, but the newer methods promise notable
discoveries.

Development. Since color vision is a complex differentiation,
it might be expected that in the course of development, an individ-
ual should successively pass through the simpler stages by which
it was acquired. Anatomically it has been shown that the retinal
layers first become distinct at the center of the retinal cup, and
that the differentiation of the retinal cells decreases from the
center toward the periphery. In the chick it is said that the cone
nuclei may be identified at an earlier stage than the rod nuclei,’
but it is not generally recognized that one form of visual cell pre-
cedes the other.

The development of color vision has been theoretically consid-
ered by Mrs. Ladd Franklin.‘ Her theory assumes that the color-
less sensations, white, gray and black, are caused by a primitive
photo-chemical substance called the gray substance, which is com-
posed of numerous gray molecules.

These gray molecules, which persist in their primitive state only
in the rods, upon disassociation furnish us with the gray sensa-

‘ Kinnaman, A. J. Mental life of two Macacus rhesus monkeys in captivity.
Amer. Journ. of Psych., 1902, vol. 13, p. 98-14
2? Yerkes, R. M. The sense of vision in the dancing mouse. Journ. of
is Neur., 1907, vol. 17, p. 194.
3 Weysse, A. W., and Burgess, W. S. Histogenesis of the retina. Am.
Nat., 1906, vol. 40, p. 611-634.
* Franklin, C. L. On theories of light sensation. Mind, 1893, N. S. vol. 2,
p. 473-489.

No. 486] THE PROBLEM OF COLOR VISION art

tions. In the cones the gray molecules have undergone a devel-
opment such that a certain portion only of the molecule becomes
disassociated by the action of light of a given color.
The differentiation of the primitive gray molecule is supposed
to have taken place in three stages (Fig. 2). The first stage is
represented by the simple,
primitive gray molecule, so
constructed that it is disin-
tegrated by light of any color,
Stage 1 thus produeing a gray or
white sensation. In the sec-
ond stage the molecule is
more complex and contains
two groupings, the disasso-
ciation of one of which gives
the sensation of yellow and
the disassociation of the other
gives blue. ‘The simultaneous
disassociation of both gives
white. ‘This stage persists in
the peripheral portion of the
retina where neither green
nor red can be perceived
Stage 8 as such. In the third stage
the yellow grouping is divided
to form two new combina-
tions, the disassociation of
— Diagram to sagen aid the Franklin one of which produces the
circle of dots respectively. Disassociated Sensation of green and the
en other the sensation of red.
If the red and green groupings are disassociated together the
resulting sensation is yellow; whereas the simultaneous disassocia-
tion of the red, green, and blue groupings produces the white
sensation.
Schenck ' has EN extended this theory by describing
the development of the primitive gray molecule. Since in twilight

‘Schenck, F. Über die physiologischen Grundlagen des Farbensinns.
Sitz.-ber. d. Gesell. d. ges. Naturw. z. Marburg. 1907. Jahrg. 1906, p. 133-164.

372 THE AMERICAN NATURALIST [Vor. XLI

vision the red end of the spectrum is lost, and the green-blue por-
tion is its brightest part, he considers that the photo-chemical
substance of the rods is attuned only to the green-blue light, which
"is perceived as colorless. Later this photo-chemical substance be-
comes sensitized in two stages, first to include the green-yellow,
and then the yellow-red, which however are still perceived as
colorless light. ‘Thus a gray molecule like that of Mrs. Franklin’s
first stage is constructed. It occurs in the color blind peripheral
cones. ‘The formation of color-reacting groupings in the partly
sensitized gray molecule leads, according to Schenck, to those
forms of human vision in which the red end of the spectrum is
shortened.

Observations upon the color perception of young children do
not support these developmental theories. Holden and Bosse '
tested two hundred children by placing before them square pieces
of colored paper attached to a gray background of similar bright-
ness. If the child made an effort to grasp the square, its color
must have been perceived. It was found that the average child
would react to all colors by the tenth month, the red end of the
spectrum causing response a little earlier than the violet end.
When ribbons of six spectral colors were placed before children
of from seven to twenty-four months, red was selected first; orange
or yellow second and third; and green, blue and violet last of all.
Nagel? showed his child of twenty-eight months each of the spectral
colors in varying degrees of brightness, at the same time teaching
him their names. Red and green were learned easily, but blue
was acquired with greater difficulty than any other color, includ-
ing violet. Green, violet, and red were preferred; black, yellow,
white, gray, and blue had secondary rank. Other experiments
with the color perception of children have given different results.
It is clear, however, that children are not known to pass from a
color blind stage, through one of yellow-blue vision, to a discrimi-
nation of all the spectral colors. No race of men now exists in

‘Holden, W. A. and Bosse, K. K. The order of development of color
perception and color preference in the child. Arch. of Ophth., 1900, vol. 29,
p. 261-277.

2 Nagel, W. A. Observations on the color sense of a child. Journ. of
Comp. Neur., 1906, vol. 16, p. 217-

No. 486] THE PROBLEM OF COLOR VISION 318

which any of the colors is unknown; and the notion derived from
studying the color terms. and references in ancient literature,
that man in historic times had a deficient color sense, is not sub-
stantiated. It may be that as in children, the red portion of the
spectrum was preferred to the blue, but even this is not estab-
lished.

Color blindness. All the colors which are normally perceived
may be produced by combinations of the spectral red, green, and
blue. Normal vision is therefore trichromatic. Sometimes in
trichromatic vision the red end of the spectrum is shortened; in
other cases a mixture of red and green, which to normal persons
appears pure yellow, may seem tinged with red or green. Thus
there are variations in trichromatic vision. Greater abnormalities
may take the form of dichromatic and monochromatic vision. ‘The
latter is a rare pathological condition in which all colors are per-
ceived as shades of one; vision therefore is essentially colorless
(achromatic), the images obtained being comparable with photo-
graphs. In dichromatic vision color perception is so limited that
all of the shades perceived may be made by combining two of the
spectral colors red, green, and blue; blindness to the third of these
colors may be partial or complete. The ordinary color blindness
is dichromatic. Forty men and four women per thousand are
either wholly unable to perceive certain colors or can recognize
them only with difficulty. This defect is usually congenital and
hereditary. It may cause so little trouble as to pass undetected
until the age of seventy. All attempts to overcome the color
blindness by educating the color sense in various ways, have failed.

Since dichromatic color blindness plays so large a part in the
theories of normal vision, a portion of Dr. Pole’s description of his
own case is here inserted. He says,’ “In the first place we see
white and black and their intermediate gray, provided they are
free from alloy with other colors, precisely as others do. (Such
statements are confirmed by those who are color blind in one eye,
the other being normal.) Secondly there are two colors, namely
yellow and blue, which also if unalloyed we see, so far as can be
ascertained, in the normal manner. But these two are the only

‘Pole, W. Colour blindness in relation to the Homeric expressions for
colour. Nature, 1878, vol. 18, p. 676-679.

374 THE AMERICAN NATURALIST [Vor. XLI

colors of which we have any sensation. It may naturally be asked:
Do we not see objects of other colors such as roses, grass, violets,
oranges, and so on? The answer is that we do see all these things
but that they do not give us the color sensation correctly belonging
to them; their colors appear to us as varieties of the other color
sensations which we are able to receive. ‘Take for example the
color red. A soldier’s coat or a stick of sealing wax conveys
to me a very positive sensation of color, by which I am perfectly
able to identify, in a great number of instances, bodies of this hue.
But when I examine more closely what I really see, I am obliged
to conclude that it is simply a modification of one of my other
sensations, namely yellow. It is in fact a yellow shaded with
black or gray, a darkened yellow or yellow brown.” I

Dichromatic vision occurs in three forms, in two of which red
and green are not differentiated from one another. The three
forms are named protanopia, deuteranopia, and tritanopia respec-
tively. In protanopia the red end of the spectrum is shortened;
that is, a portion which to the normal person is red, appears black.
The remainder of the red, the orange, the yellow, and the green
appear as successively lighter shades of yellow which, toward the
blue, becomes gray or white. This white shades into blue which
deepens toward the violet end of the spectrum. In deuteranopia,
which is the normal condition of a peripheral zone of the retina,
the red of the spectrum is not shortened. Red, orange, yellow
and green appear as lighter shades of one color, called red or
yellow, and shade into a white or gray band which is a little nearer
the red end of the spectrum than the corresponding band of protan-
opia. Blue is perceived normally. 'Tritanopia is a rare form in
which yellow and blue are not recognized. The spectrum presents
red and green portions, separated by a white band in place of the
yellow. A dark green is seen in place of blue and the violet end
of the spectrum is shortened.

Theories of Color Vision. Certain features of color blindness
are ingeniously explained by Hering’s theory, illustrated in figure
3. It is supposed that the cones contain a photo-chemical sub-
stance which is disassociated by red rays but which is built up by
the green rays, giving rise respectively to the sensations of red and
green. A second substance is broken down by yellow and built

No. 486] THE PROBLEM OF COLOR VISION 375

up by blue light. As shown in the figure, orange is a mixed sensa-
tion due to the simultaneous partial destruction of the red-green
and the yellow-blue substances. Yellowish green and greenish
blue are likewise mixtures, and violet is supposed to combine the
partial construction of the yellow-blue with the destruction of
the red-green, the latter being indicated by the broken line. There
are four pure sensations, red, yellow, green, and blue. Color
blindness may be due to the absence or deficiency of the red-green
substance (protanopia and deuteranopia, the two forms being
varieties of a single type), or to lack of the yellow-blue substance
(tritanopia). Hering further considered that there was a white-
black substance, built up in darkness to give rise to the sensation

i

Me yb w

R O 2 G B 4
MG. ibstanes Ty; io vertically shadei; and the yellow-blue substance, 9b, is
treme? ersely shaded.
of black, but destroyed in varying degree by different colored
lights, thus giving white. In monochromatic vision the retina
contains only this white-black substance. ‘The curve w of figure
3 shows that the maximum stimulation of white is in the yellow
portion of the spectrum. Without considering the difficulties
concerning the white-black hypothesis, it may be questioned
whether both constructive and destructive chemical processes
can produce color sensations of similar nature. Mrs. Franklin
considered that her theory was supported by the fact that the
color sensations were all chemically destructive. Hering’s theory,
moreover, calls for four primary color sensations, whereas physi-

376 THE AMERICAN NATURALIST [Vor. XLI

cists recognize that only three are necessary. Accordingly the
physicist Young proposed a simpler theory antedating that of
Hering. It was advocated by Helmholtz, and is generally known
as the Young-Helmholtz theory.

According to the Young-Helmholtz theory there are three photo-
chemical substances, red, green, and blue respectively, which are
stimulated by the various rays of the spectrum as shown in figure
4. Absence of stimulation produces black, and the simultaneous
disassociation of all three yields white. Protanopia is interpreted
as red blindness, due to deficiency of the red perceiving substance.
Deuteranopia is green blindness, and tritanopia is blue blindness.
Since it would appear that the perception of white must be lost

ii<-_ iii

| so rE
| onli

R UE
Fig, 4.— Diagram to illustrate the Yoe annota Ba r, g, b, red, green,
and blue perceiving substances, respecti

with the disappearance of one of the three elements, the theory
has been variously modified. In protanopia the red and the green
substances may be so altered that each responds both to red and
green light (Fick), or the red and the green substances may be
imperfectly segregated, as assumed by Mrs. Franklin’s theory.
The close relation between the red and green substances is shown
in Koenigs presentation of the Young-Helmholtz theory (Fig. 5).
The absence of either would give rise to somewhat similar condi-
tions, such as occur in protanopia and deuteranopia. The figure
indicates that in trichromatic vision, the colors from yellow to
blue affect all three substances to a certain extent, thus adding a
small amount of white to the color sensation. In dichromatic
vision the mixing of the two elements yields white. In case the
red substance is absent, this white will appear nearer the blue
than in case the green is absent; its position is indicated by the

No. 486] THE PROBLEM OF COLOR VISION 377

intersection of the blue with the green and red curves respectively.
In the absence of the blue substance, the white band is near the
yellow. ‘This accords with the observations upon the color blind.
The absence of the green substance would not shorten the spec-
trum, but the lack of the red or blue would cut off their respective
ends. All of these features are equally well explained if, instead
of the absence of one of the three substances, such a modification
of its reaction is assumed as would be illustrated by a lateral
shifting of its curve in the diagram. ‘Thus in red blindness the
red curve is shifted to cover more closely the territory of the green;
in green blindness the green is shifted toward the red; and in blue
blindness the blue and green curves are brought together. Thus

Fic. 5.— A modified diagram of the Young-Helmholtz theory, after Koenig.

in the color blind all three substances are present but in modified
form. Since this modified Young-Helmholtz theory accords so
well with observations on color blindness, it is generally considered
as the most satisfactory explanation of color vision.

An interesting attempt has been made by Patten to bring this
theory into relation with structural elements in the cones.’ He
believes that the*visual cells of invertebrates are characterized by
a fibrillation which is transverse to the direction of the incident
light waves, and that the tendency of the vertebrate rods and
cones to separate into transverse discs is evidence of a similar
structure. Many hundreds of such fibrils may exist in a rod
or cone, They are not supposed to vibrate like tense strings, but

‘Patten, W. A basis for a theory of color vision. Am. Nat., 1898, vol. 32,
p. 833-837.

378 THE AMERICAN NATURALIST [Vor. XLI

to act as ‘conductors or resonators,’ a fact which would not exclude
chemical changes resulting in fatigue. The long fibrils respond
to the red end of the spectrum and the short ones to the blue. In
rods the fibers are of equal length and only monochromatic vision
is possible, but in the cones their varying length allows a range of
color perception. Any variation in the form or dimensions of
the cones would bring about cor-
responding changes in vision.
a The increased length of the

cones at the fovea provides for
a greater power of color discrim-
ination. If the base of a cone
were absent or cylindrical it would
be red blind.

This theory is illustrated in fig-
ure 6. On the right is the dia-
gram of a cone and its fibrils;
the latter radiate from an axial
filament, the existence of which
has been discussed and denied
by other investigators. The fi-
brils in the right half of the cone
are drawn as responding to red, -
yellowish green, and violet light;
the Young-Helmholtz curves are
shown on the left. In nonpolar-
ized light all of the fibrils in a
Fic. 6.— Diagram to illustrate the sup- transverse section of a cone re-

posed fibrillar structure of human š . .

cones, and the way in which various spond uniformly, but in polarized

light waves affect them. (Patten.) light only such are effected as are
indicated in the cross sections on the left of the figure. Thus the
dullness of polarized light is explained. The correctness of this
supposition, as Dr. Patten states, will be determined by extensive
measurements, much more accurate and detailed than any here-
tofore made, of the visual elements in all classes of animals.

It will be noted that according to Patten’s and Mrs. Franklin’s
theories the mechanism for reaction to all the colors may exist in
a single cone. The Hering theory calls for the reaction to at least

Fe
Cay

No. 486] THE PROBLEM OF COLOR VISION 379

two colors in one cone; but according to the Young-Helmholtz
theory, although the three substances could exist in a single cone,
each is declared to exist in a cone by itself. This is considered
to be strongly in favor of the validity of the Young-Helmholtz
theory. Since physiologists find no instance in which different
sorts of impulses are conveyed over a given nerve fiber, it is believed
that a single cone fiber can transmit only one sort of color sensation.
The stimuli of the red, green, and blue cones respectively are
supposed to be gathered by separate nerve cells of the retina, and
the optic nerve consequently contains certain fibers transmitting
only red, green, and blue sensations respectively. The mixing of
the sensations, giving rise to the perception of shades and tints, is
therefore accomplished in the brain and not in the cones. In an
attempt to test this supposition, attention has been called to the
perception of the colors of stars. The image of the star is so
minute that it would cover but a single cone, but the conclusion
that one cone perceives its color is invalidated by the fact that the
retina is not sufficiently stationary; the image of the star falls in
rapid succession upon several cones which may unite in giving the
color perception. ‘Those who believe in the specific energy of the
rod and cone fibers dismiss at once several of the theories of color
vision. It must be remembered, however, that the separation of
the cones into forms responding to red, blue, and green light,
with three corresponding sets of nerve cells and fibers to convey
these separate stimuli to the brain, does not rest upon anatomical
evidence.

PHYSIOLOGICAL LABORATORY
Harvard University

THE BREEDING HABITS OF AMBLYSTOMA PUNC-
TATUM LINN'

BERTRAM G. SMITH

On April 9, 1906, in some small ponds in a wood in the vicinity
of Ann Arbor, Michigan, Prof. Jacob Reighard discovered what
he surmised to be spermatophores of Amblystoma. At his sug-
gestion and under his direction, I undertook the identification and
study of these structures.

I. OBSERVATIONS

A. The Spermatophores. The spermatophores look like bunches
or tufts of snowy-white fungus growing on leaves, twigs, or stalks
of grass lying on the bottom of the pond. They invariably occur
on a horizontal surface, and are never attached to an erect twig
or stalk as is often the case with the eggs of Amblystoma. They
are found in water from 6 to 10 inches deep, and 5 to 10 feet from
the shore. ‘The spermatophores usually occur in groups of about
40 or 50, but the number is extremely variable, ranging from 1 to
100. Isolated spermatophores are rarely found, though a single
one is conspicuous enough to be readily discovered. The sperma-
tophores of each group are scattered over an area of rather more
than one square foot. Along the shores of an elliptical pond about
125 feet in length, 25 groups of spermatophores were counted;
they were less numerous in three other ponds examined.

The spermatophores (Fig. 1.) resemble those of Triton (Diemyc-
tylus) viridescens as described by Jordan (’91 and ’93) rather than
the more complicated structures produced by some European
forms (Zeller, 05). Each consists of a base and a stalk of clear
gelatinous material almost invisible in the water, having the gen-
eral form of the stump of a tree, this structure is surmounted by a
slightly broader cap or tuft of snowy-white felt-like material con-
sisting of spermatozoa with no visible matrix. The material con-

‘Contributions from the Zoological Laboratory of the University of Mich-
igan, No.

381

382 THE AMERICAN NATURALIST [Vor. XLI

stituting the base must be strongly adhesive when fresh, for the
spermatophore is firmly attached to the objeet on which it is de-
posited. ‘The cap is usually hemispherical in form, with the con-
vex surface upward; but the material of which it consists often
runs down the side of the stalk, or is found projecting in downy
tufts like the cotton from an open cotton-boll. In many cases
the caps have a frayed appearance, as if they had been disturbed;
in occasional specimens the cap of spermatozoa is partly or almost
wholly absent. ‘The appearance in the latter case is like that of
a spermatophore of Triton viridescens from which I have seen the
ball of spermatozoa taken up into the cloaca of a female. The
dimensions of the complete spermatophore are about as follows:

Height... ne. mm

Breadth of base... —....; 6-8 mm.

Diameter of stalk near top. ..2.5-3 mm.
E an ce, 3-4 mm.

As compared with some spermatophores of Triton viridescens
obtained from specimens in captivity, these under discussion are
slightly taller, with a smaller base and a stalk of much larger
diameter, surmounted by a larger mass of spermatozoa. The
spermatophore of Triton viridescens has a broad flattened base
from the center of which rises a distinctly conical stalk tapering
to a very slender spine, at the top of which is attached a small ball
of spermatozoa; the spermatophores attributed to Amblystoma
are more massive and more nearly cylindrical.

When found on April 9 and 10 the spermatophores were all in
good condition, with some slight differences in the freshness of
their appearance. In two or three days they became infested
with fungus, disintegrated quite rapidly, and in a week very few
few of them could be found. Had new ones been deposited in the
interval, they could readily have been distinguished from the
old ones; but no more spermatophores were deposited. Hence
it is scarcely possible that the period during which spermatophores
are deposited lasts longer than two or three days.

The spermatophores shown in the figure had been attacked by
fungus and were beginning to disintegrate when photographed.
The base is therefore no longer clear, but on the contrary the
whole spermatophore appears white.

a

No. 486] HABITS OF AMBLYSTOMA 383

Identification. In order to identify the spermatophores, search
was made for the parent animals. This resulted in the capture
on April 11, of three specimens of Amblystoma punctatum Linn.
which were found embedded in rotten wood under a stump at the
edge of the water of one of the ponds where the spermatophores
were numerous. From two of these specimens a few drops of
seminal fluid, containing an abundance of spermatozoa, were
obtained by stripping; from the third, which proved to be a female,

Fig, 1.— SI top! f Amblystoma punctatum. Two-
thirds natural size, linear reduction.

comparatively few. spermatozoa were obtained. The sperma-
tozoa were mounted, stained, and compared with some taken from
spermatophores and similarly treated. In structure, size, and
staining reactions the two were identical.

Another species, A. tigrinum Green, also occurs in the vicinity

384 THE AMERICAN NATURALIST [Vor. XLI

of Ann Arbor, and a single example was taken on April 9, in a
field several hundred yards distant from the nearest pond where
spermatophores were found; but the eggs of the two species are
easily distinguishable, and in the case of A. punctatum were iden-
tified by means of eggs laid in the laboratory. With the exception
of one bunch of eggs of A. tigrinum, all the eggs found in the pond
where spermatophores were observed, were those of A. punctatum.
With the single exception above noted, the two species have not
been known to breed in the same ponds in the vicinity of Ann
Arbor.

B. The Spermatozoa. ‘The spermatozoon of Amblystoma punc-
tatum is extremely long and slender. The head stains well with
Delafields’ haemotoxylin, the middle-piece less deeply. The tail-
piece is bordered on one side by a very delicate undulating mem-
brane. Some of the dimensions are as follows:

Length of acrosome. +... 00... 08 20 u
= MBI ae, 106 u
a ~ middlepiece n> 14 u
z "F tailpiece. o i a 480 u

Total length, ooo co sity so 620

The spermatozoon resembles in size and form that of Triton
viridescens, with which it was compared, but the latter has a
middle-piece twice as long, and a more conspicuous undulating
membrane.

As compared with the spermatozoon of Crytobranchus alleghe-
niensis (Smith ’06) the sperm of Amblystoma punctatum is nearly
three times as long, with a proportionally much longer middle-
piece; the entire structure is much more slender and thread-like.

In freshly mounted seminal fluid the spermatozoa were seen in
active motion. They tend to cling together parallel to each other
to form bundles or ringlets, revolving with a circular motion;
when so clustered they retain their vitality much longer than when
separated. In a dying spermatozoon, long after the shaft has
ceased to move, the activity of the undulating membrane continues.
It gradually becomes slower until with a high magnification it is
possible to follow a trough or a crest without interruption or change
of form across the entire field of the microscope. The undulating
membrane does not wind about the shaft as in Cryptobranchus,
but continues on one side of it. When dead, the sperms are usually

No. 486] HABITS OF AMBLYSTOMA 385

found much convoluted, indicating a greater degree of flexibility
than is the case with stouter spermatozoa like those of Crypto-
branchus.

Experiments were performed to determine the length of time
the spermatophores would retain their vitality in water, hence the
interval within which they would have to be taken up by the female.
In all the spermatophores examined the spermatozoa were motion- _
less; but since the examination was not made until the evening
of April 10, probably the spermatophores had been in the water
for many hours. The effect of the cloacal secretion of the living
female was then tried, to see if it would revive these spermatozoa;
no such result was produced. Freshly obtained seminal fluid
mounted in water retained its vitality for many hours; but as this
experiment was not performed until April 18, only a small amount
of seminal fluid could be obtained, and in this the sperms were not
in a vigorous condition. If fresh seminal fluid were taken in the
proper season and mounted in quantities to correspond with that
deposited in a spermatophore, it might retain its vitality much
longer. The viscous liquid in which the spermatozoa occur does
not readily mix with water.

A freshly deposited spermatophore of Triton viridescens was
obtained and kept in water; from time to time small portions of
the ball of spermatozoa were teased apart and examined under
the microscope. Eleven hours from the time the spermatophore
was deposited, many active spermatozoa were found; an hour
later all were motionless. Probably in an undisturbed sperma-
tophore their vitality would be retained longer than twelve hours.

C. The Eggs. Those of A. punctatum have been described
and figured by Clark (’80). The eggs, with their individual
gelatinous envelopes, occur in compact bunches, surrounded by
a very thick jelly mass. The entire structure is usually of an oval
shape, often nearly as large as one’s fist. The eggs of A. tigrinum
are more loosely aggregated in a thinner jelly mass, and the cluster
resembles a bunch of grapes. The clusters of eggs of A. punctatum
are as a rule larger than those of A. tigrinum, and the number of
eggs in a bunch is usually greater.

At the time of the discovery of the spermatophores, very few
bunches of eggs could be found. The number steadily increased
for a week; at the end of that time eggs were found in early seg-

386 THE AMERICAN NATURALIST [Vor. XLI

mentation stages, showing that they had been quite recently laid.
The egg-laying season follows immediately after the deposition of
spermatophores, and lasts six or seven days. Nearly every bunch
of eggs found on April 10 was close to a group of spermatophores.

On April 16, in the pond where 25 groups of spermatophores
had been counted nearly a week before, about 55 bunches of eggs
were found. Of these, many bunches were deposited in groups of
two to four, probably by the same female. ‘The number of aggre-
gations of eggs very nearly equalled the number of groups of
spermatophores.

The Adults. Secondary Sexual Characteristics. During
the breeding season, at least, the cloacal region of the male is quite
prominent; that of the single female examined was much less
swollen, and the orifice was smaller. The cloaca of the male is
lined with fine parallel papillated ridges, extending inward for a
few millimeters; between these ridges are deep grooves, lined with
cilia whose beat is outward. ‘These ridges and grooves were not
found in the single female examined. According to Kingsbury
(95) the female Amblystoma, as well as the male, has cilia in the
cloaca but the tract is less extensive. The urogenital sinus of
the male is larger than that of the female, probably to hold a con-
siderable supply of seminal fluid preliminary to the deposition of a
spermatophore. No secondary sexual characters to indicate the
clasping of the female by the male were found.

II. Discussion.

Andrews (’97) described the structure and distribution of some
spermatophores which he attributed to Amblystoma punctatum, but
without positive identification. He states that these spermato-
phores were more slender and higher than those of Triton virid-
escens, and were distributed, at intervals of a few inches, in lines
of several to a dozen. I find it difficult to reconcile his account
with my own observations.’

1 Professor Andrews, to whom the manuscript of this paper was submitted, writes, —
“ The spermatophores vary in size, arrangement and form here (about Baltimore) in

tions — despite some differences in descriptions — refer to Amblystoma punctatum.”

No. 486] HABITS OF AMBLYSTOMA 387

On account of the late season at which my investigation was
begun, no direct observations of the process of fertilization were
possible. Clark (’79) says of some specimens of A. punctatum
in confinement: ‘‘The males showed no inclination to clasp the
females, but quietly deposited quite large masses of an apparently
rather thick liquid, opaque white, on the bottom of the dish in
which they were kept. Upon examination this was found to con-
sist of spermatozoa moving actively in a liquid.” The manner in
which the spermatozoa reached the eggs was not observed.

Fertilization is undoubtedly internal. Of this the evidence |
adduced by Kingsbury (’95), and the presence of spermatozoa
in the cloaca of the female as described above, furnish sufficient
proof. It remains to consider how the transfer of spermatozoa
is effected by the spermatophores.

The number of spermatophores is evidently very much greater
than the number of females; and unless there exists an enormous
disproportion between the sexes, each male must deposit a large
number of spermatophores. Their abundance and the manner
of their distribution, render it a very easy matter for the female
to find enough of them for purposes of fertilization. In some
portions of the pond it would seem scarcely possible for a female
to move about in the water for any length of time without brushing
against some of these spermatophores; hence there is the possi-
bility of finding them by chance contact.

In the cases of those Urodela in which, as in Triton viridescens
(Jordan ’91 and ’93; Hilton ’02) and Axolotl (Gasco ’81) the
number of spermatophores deposited by a single male is small,
particular safeguards are needed in order to facilitate their delivery
to the cloaca of the female. In these forms the physiological
necessity which requires the co-operation of the female in order
that spermatophores may be deposited insures the presence of the
female at the right time; subsequent reactions safeguard the
reception of at least one of these spermatophores by the female
cloaca. In Triton viridescens, according to my own observations,
in some cases the female seems to make a definite attempt to get
the spermatophore. The complicated behavior of the adults in
these cases finds its biological significance not only in the increasing
certainty of the process, but in a corresponding economy in the

388 THE AMERICAN NATURALIST [Vor. XLI

number of spermatophores that must be deposited. With Ambly-
stoma punctatum, on account of the very large number of sperma-
tophores, there is the probability of a simpler mode of behavior,
and the spermatophores may be found largely by chance. ‘The
wastefulness of the method is obvious. In Amblystoma as in
Axolotl there is evidently no clasping of the female by the male,
such as occurs in Triton.

The result of the experimental work on the vitality of the seminal
fluid in water indicates that the spermatophore is not necessarily
taken up by the female immediately after it is deposited; probably
it is capable of effecting fertilization after exposure to the water for
many hours.

On account of the shortness of the breeding season, the sperma-
tozoa can be retained in the cloaca of the female for only a few
days at most, before fertilization is effected. The position with
respect to the spermatophores, of the earlier eggs found, suggests
that in some cases the eggs are deposited immediately after the
spermatophores are picked up.

The extreme flexibility of the sperm is doublless correlated with
the process of internal fertilization. In Cryptobranchus, in which
fertilization is external (Smith ’07), the egg envelopes must be
penetrated after a brief exposure to the hardening effect of the
water, and a much more rigid spermatozoon is required.

In the evolution of terrestrial from aquatic vertebrate life, a
transition from external to internal fertilization takes place.
External fertilization is not adapted to terrestrial conditions,
hence in the land-living vertebrates it occurs only in some of the
forms that revert to the water during the breeding season — i. e. in
the Amphibia. Internal fertilization is an adaptation to terres-
trial life in the sense that it is a condition antecedent to that life,
not a result brought about by it; it may occur in purely aquatic
vertebrates, as in the Elasmobranchs and a few Teleosts. Internal
fertilization by means of spermatophores is a method still adapted
_ to aquatic rather than to terrestrial conditions. It is a method
intermediate between external fertilization on the one hand and
internal fertilization without spermatophores on the other. Viewed
in the light of the habits of the higher vertebrates, the occurrence
of any method of internal fertilization in a form that breeds in the

No. 486] HABITS OF AMBLYSTOMA 389

water represents an advance upon the habit of external fertiliza-
tion, and a stage in the evolution of habits that are to make possible
the invasion and permanent occupation of the land.

Internal fertilization also finds a biological significance in the
fact that in the course of its development there is gradually effected
an economy in the amount of seminal fluid required for fertiliza-
tion. This factor may account for the persistent development of
the habit under aquatic conditions, where external fertilization
is still possible; the incidental result is a preparation for terrestrial
life. |

In existing Amphibia we may find illustrations of various stages
in this evolution of the breeding habits correlated with a transition
from the water to the land. In Cryptobranchus, one of the lowest
of the Urodela, leading an aquatic life and showing only in its
methods of respiration and locomotion an advance toward terres-
trial conditions, external fertilization takes place. ‘This is evi-
dently the primitive condition for the Urodela. In Amblystoma,
a urodele living partly upon the land but returning to the water
to breed, we see developed the peculiar habit of fertilization by
means of spermatophores — a mode of internal fertilization favored
by aquatic conditions. In Triton viridescens an economy of
seminal fluid through a reduction in the number of spermatophores
is made possible by definite reactions on the part of the adults,
which insure fertilization. In the urodeles Megapterna montana
Savi., Molge aspera Dugès and Glossoliga Hagenmulleri Lataste,
according to Bedriaga (’82 and ’95) the male emits spermatophores
while still clasping the female; in Triton torosus Esch. (Ritter ’99)
it is probable that a very similar process occurs; in none of these
cases, with the possible exception of Molge aspera, is there direct
cloacal contact. Finally in the Apoda (the Sarasins ’87-’93;
Brauer ’97) we find the establishment of a method of internal
fertilization by direct cloacal contact, thus fulfilling the require-
ments for continuous residence upon the land.

UNIVERSITY or MICHIGAN ZOOLOGICAL LABORATORY
ANN ARBOR, MICHIGAN

390 THE AMERICAN NATURALIST [Vor. XLI

LITERATURE CITED.

ANDREWS, E. A.

1897. Breeding Habits of the Spotted Salamander (Amblystoma

punctatum). Amer. Nat., Vol. 31, pp. 635-7.
DE BEDRIAGA, J.

1882. Ueber die Begattung bei einigen geschwänzten Amphibien.
Zool. Anz., Bd. V, pp. 265-268, 357-359.

1895. On the Pyrenean Newt, Molge aspera Dugés. Proc. Zool. Soe.
1895, p. 150.

BRAUER, AUGUST.

1897. Beiträge zur Kenntniss der Entwicklungsgeschichte und der

Anatomie der Gymnophionen. Zool. Jahrb. Anat., X, p. 389.
CLARKE, S. F.
1880. Development of Amblystoma punctatum. Studies from Biol.
Lab. of Johns Hopkins Univ., No. II.
Gasco, P.
1881. Les Amours des Axolotls. Zool. Anz., IV, pp. 313, 328.
Hırton, WILLIAM A.

1902. A Structural Feature Connected with the Mating of Diemycty-

lus viridescens. Amer. Nat., Vol. 36, pp. 643-51.
JORDAN, EDWIN

1891. The ETE of Diemyctylus. Journ. Morphol., Vol.
X, No.

1893. The Habits and Development of the Newt (Diemyetylus
viridescens) Journ. Morphol., Vol. VIII, No. 2.

Kınasgury, B. F.

895. The Spermathecæ and Methods of Fertilization in Some Ameri-
can Newts and Salamanders. Trans. Am. Micr. Soc., Vol. 17,
PP- t

Rırrer, W. E.

1897. Diemyctylus torosus Esch. The Life History and Habits of
the Pacific Coast Newt. Proc. Cal. Acad. Se., Third Series, Zool-
ogy, Vol. I, No. 2, 1897.

Sarasin, P. B. ann C. F.

1887- Zur Entwicklungsgeschichte und Anatomie der Ceyloni-
schen Blindwühlen, Ichthyophis glutinosus. Ergebnisse natur-
wissenschaftlicher Forschungen auf Ceylon, II

SMITH, BERTRAM G.

1 Preliminary Report on the er ial of Cryptobranchus
allegheniensis. Biol. Bull., Aug. 1
. The Life History and Habits of Ck allegheniensis.
Biol. Bull. (In press.)

ZELLER, E. v.

1905. Untersuchungen über die Samenträger ve die Kloakenwulst
der Tritonen. Zeitschr. wiss. Zool., Bd.

THE STAFF-TREE, CELASTRUS SCANDENS, AS
A FORMER FOOD SUPPLY OF
STARVING INDIANS

FRANK T. DILLINGHAM

In many kinds of hard and horny seeds there is present, as a
reserve material, a carbohydrate which upon hydrolysis yields
mannose (a simple sugar closely related to glucose). ‘This carbo-
hydrate has been named mannan. It is one of the hemi-celluloses,
a group of substances closely resembling in appearance the true
celluloses, but easily resolved into simpler carbohydrates by the
hydrolytic action of enzymes or of dilute acids. There is no lack
of evidence that mannan which occurs abundantly in the so-called
vegetable ivory, Phytelephas macrocarpa, and in the seeds of many
other palms, as well as in the wood of coniferous trees, is in spite
of its hardness, fit food for camels, neat cattle, sheep, and various
rodents. This is illustrated in the girdling of pine trees by mice,
as recorded by Thoreau in “Walden.” * He says:— “There
were scores of pitch-pines around my house, from one to four
inches in diameter, which had been gnawed by mice the previous
winter, — a Norwegian winter for them, for the snow lay long and
deep, and they were obliged to mix a large proportion of pine
bark with their other diet. These trees were alive and apparently
flourishing at mid-summer, and many of them had grown a foot,
though completely girdled; but after another winter such were
without exception dead. It is remarkable that a single mouse
should thus be allowed a whole pine tree for its dinner, gnawing
round instead of up and down it; but perhaps it is necessary in
order to thin these trees, which are wont to grow up densely.”

It is known that the root of a Japanese plant, Conophallus
konnjaku, rich in mannan is used as human food, and the question
may fairly be asked whether the former use of bark bread by the
inhabitants of Scandinavia might not have been dependent upon
the mannan in the bark. After discussing this matter in the

‘Walden, p. 300. Jas. R. Osgood & Co. Boston, 1876.
391

392 THE AMERICAN NATURALIST [Vor. XLI

Bulletin of the Bussey Institution (1906, Vol. 3, pp. 120-128),
the writer learned that some tribes of North American Indians in
times of extreme dearth were accustomed to keep body and soul
together by boiling and eating the bark of the Staff-tree, Celastrus
scandens. The Staff-tree is also called the staff-vine; false,
climbing or shrubby bittersweet; wax-work, fever-twig, yellow-
root, climbing orange-root and Jacob’s ladder.

Radisson, wintering near the outlet of Lake Superior about
the year 1658, found the Indians suffering greatly from starvation
He writes: — “Those that have any life seeketh out for roots,
which could not be done without great difficulty, the earth being
frozen 2 or 3 feet deep, and the snow 5 or 6 aboveit. The greatest
subsistence that we can have is of rind tree which grows like ivy
about the trees; but to swallow it, we cut the stick some 2 foot
long, tying it in fagot, and boil it, and when it boils one hour or
two the rind or skin comes off with ease, we take and dry it in
the smoke and then reduce it into powder betwixt two grain stones,
and putting the kettle with the same water upon the fire, we make
it a kind of broth which nourishes us, but become thirstier and
drier than the wood we ate.”

In the Report of the U. S. Commissioner of Agriculture for 1870,
(p. 422), there is the following statement:— “The Chippewa
Indians use as food the tender branches of the Staff tree (Celastrus
scandens). This climbing shrub, the bois retors of the French,
or twisted wood, is sometimes called bitter sweet. It has a thick
bark and is sweetish and palatable when boiled.”

In view of the above statements, specimens of both the bark and
the wood of the Staff-tree were tested for mannan. On the
grounds of the Bussey Institution, on Jan. 24th, 1907, branches of
the Staff-tree were cut in pieces about one foot in length. Both
the inner and outer bark were removed together, no attempt
being made to separate them. The outer bark was thin, but the
inner bark was thick and fleshy. The material was carefully
dried, ground to a fine meal, and a weighed quantity of it was
boiled with dilute hydrochloric acid for three hours. A small
portion of the liquor thus obtained was neutralized with sodium
hydroxide and examined for mannose by the addition of a few

* Voyages of P. E. Radisson, p. 204, Prince Society Edition, Boston, 1885.

No. 486] THE STAFF-TREE AS A FOOD SUPPLY 393

drops of phenylhydrazine acetate. No mannose hydrazone crys-
tals formed at this point. The remainder of the liquor, after be-
ing similarly neutralized, was evaporated to dryness; the residue
was treated with a small quantity of water; and the concentrated
liquor thus obtained was tested for mannose by adding a few drops
of phenylhydrazine acetate. With the aid of the microscope,
the formation of characteristic crystals of mannose hydrazone
was observed.‘ The wood proper (including the pith) was re-
duced to a fine meal and then treated in precisely the same manner
as was the bark.

From these tests it appears that unlike the bark of most decidu-
ous trees, that of the Staff-tree contains an abundance of mannan.
The bark of the Staff-tree, moreover, contains a larger quantity
of mannan than does the wood proper.

To confirm Radisson’s statement as to the effect of boiling, a
few branches of the Staff-tree were boiled with water for about
one hour. At the end of this time the bark was found to peel off
with great ease. It was seen to be thick, pulpy, and very mucilagi-
nous, and it had a rather agreeable taste.

It is evident from these experiments that a part, at least, of the
physiological value of the bark of the Staff-tree may be justly
attributed to the presence of mannan.

Bussey INSTITUTION or HARVARD UNIVERSITY

Jamaica Plain, Mass.

‘This method has been explained in detail in the Bulletin of the Bussey

Institution. 1902, 3, p. 30. 1903, 3, p. 47.

NOTES AND LITERATURE
GENERAL BIOLOGY

The Spirit of Nature Study.'— Nature may be approached in a
very unscientific spirit. Thus Emerson was led to dedicate to the
Botanist the following quatrain:

Go thou to thy learned task,

I stay with the flowers of Spring:
Do thou of the Ages ask

What me the Hours will bring.

What the hours brought he so expressed that the Rhodora has become
a universal type of botanie beauty. In a different spirit the New
England botanists named their journal Rhodora, for they profess
to have been uninfluenced by Emerson’s familiar lines; they sought
a characteristic local plant with a short name which would commend
itself to bibliographers. The spirit of nature study, according to Dr.
Bigelow’s interpretation, combines the sentimental and the scientific,
with its emphasis upon the former. This appears in such advice as,—
“Take frequent rambles into the country; associate with natural
objects, love them, take them into your nature, and treasure the
remembrances of them.... Subsequent years of trouble cannot oblit-
erate the charmed impressions.” “‘At the next stopping place there
will be no fairer landscapes, nor more beautiful skies, no statelier
trees, more joyous songsters, nor brighter flowers; more cheerful

um of insects, more invigorating air, no more happiness, no better
friends, and no better God.”

Therefore more time should be given to nature study in the schools,
and many educators are quoted to this effect. School children should
be taken to the country and should have plants and animals at home;
rabbits and gourds are particularly recommended since the former
are reasonably small and the latter grow upward ‘where land is cheap.’
College methods of instruction should not be extended to elementary
schools. Of the sixteen half-tones which illustrate the book, twelve
are photographs of boys and girls out in the country.

The nature student, as Burroughs has said, does not regard birds

1 Bigelow, Edward F, The spirt of nature study. New York, A. S. Barnes
& Company, 1907. 12m0, 222 pp.

395

396 THE AMERICAN NATURALIST [Vor. XLI

as ornithological specimens, nor wild flowers as material for herbaria.
Dr. Bigelow’s expeditions are not for “what one can get.’ It is ap-
parent that within the present century the destruction of such irre-
placable plants and animals as remain will not be tolerated, either for
sport, for food, or for amateur collections. Since nature study in the
schools should save the swallows’ banks from the small boy and
protect native plants from bouquet gatherers, it may prove of great
value to the community. This, however, is not strongly presented in
Dr. Bigelow’s book, which includes a photograph of eleven women
gathering bunches of violets, and recounts, as one of the author’s
pleasurable reminiscences, the bloody death of a woodchuck.

Dr. Bigelow’s twenty-three informal essays are enlivened by many
quotations and anecdotes; their author appreciates the “fun of being
a naturalist” and his good natured humor is all at the expense of the
“bug-hunter’s” critics. He is at home with boys and girls for whom
he edits each month an excellent department of Nature and Science
in St. Nicholas, but the book here considered is addressed to parents
and to teachers of nature study.

Heterogenesis.— The idea that eggs of one species may give rise
to adults of other species still finds an occasional advocate undismayed
by overwhelming evidence to the contrary. A contribution recently
submitted to the Naturalist set forth breeding experiments in which
several species of insects hatched from a single batch of eggs, and none
were parasites. The suggestion of a distinguished entomologist that
in these days of the multiplicity of species, several might readily arise
from one lot of eggs, was here inapplicable, for different genera were
involved. The probable explanation is that the technique of the
experiments was faulty. Dr. H. Carlton Bastian continues to believe
in heterogenesis, upon which he has published voluminously, but a
skeptical critic of his latest book concludes with the following anecdote.
“On one occasion, Dr. John Rennie, lecturer on parasitology in the
University of Aberdeen and an expert investigator, observed two
infusorians moving inside a rotifer’s egg, but he did not regard the
phenomenon as a proof of heterogenesis. As a matter of fact the
egg envelope showed a small split through which the infusorians soon
passed out, doubtless following the path by which they formerly
entered.”

RB. 3. L.

‘Bastian, H.C. The evolution of hfe. Reviewed in Nature, May 2, 1907 i
vol, 76, p. 1.

No. 486] NOTES AND LITERATURE 397

ZOOLOGY

Anatomical Terminology.' — In descriptive anatomy, as in syste-
matic zoology, synonymy has been a heavy burden. In a current
text book a paragraph of five lines begins with “ The Corium, Cutis
vera, Dermis, or True Skin”; and another, which is not exceptional,
announces “ The Simple Follicles, Intestinal Glands, Crypts, or Glands
of Lieberkühn, glandule intestinales [Lieberkuehni].” In America.
since 1871, Professor Burt G. Wilder has been active in reform with
the following results. In 1889 the Association of American Anatomists
voted to employ the adjectives anterior, posterior, dorsal and ventral,.
in the sense of toward the head, tail, back, and abdomen respectively.
They substituted thoracic vertebra for dorsal vertebra, and approved
the terms calcar, hippocampus, pons, insula, pia, and dura. In 1896-
the Neurological Association adopted forty terms pertaining to the
nervous system. The Association for the Advancement of Science
went so far as to sanction the most unfortunate principle of Professor
Wilder’s system, namely that terms should be single words rather
than descriptive phrases. This principle leads (1) to the introduction
of shorter new names to replace more familiar older ones; (2) to the
omission of nouns, making the descriptive adjective the complete
term; and (3) to the fusion of two words in one, often combined with
the elimination of certain syllables. The omission of mater from
dura mater, and of tunica from tunica muscularis is common and
desirable in the laboratory, but the noun is understood and is an
essential portion of the name. Nothing is gained by ruling it out of
existence. The following are examples of fused words,— transection
for transverse section; postcava for vena cava posterior; alinjected
for injected with alcohol; terma for lamina terminalis. In this sys-
tem the elimination of synonyms becomes secondary to a kind of
anatomical spelling reform.

n 1889 the Anatomische Gesellschaft appointed a committee of
nine eminent anatomists to revise anatomical nomenclature, and after
six years’ labor it reported a list of about forty-five hundred Latin
terms. An even larger number of synonyms was rejected. Un-
fortunately anterior is used as equivalent to ventral, superior is some-

! Barker, Lewellys F., Anatomical terminology. Philadelphia, P. Blakiston’s.
Son & Co., 1907. 8vo, ix+ 103 pp., 5 figs.

398 THE AMERICAN NATURALIST [Vor. XLI

times employed for anterior, and in some other instances, as in naming
the dorsal pancreas accessory pancreas, the bias of human anatomy is
apparent. In this respect Professor Wilder’s rejected principle ought
not to be abandoned. ‘The German committee has adopted thirty-
four of the forty terms sanctioned by the American Neurological
Association; in ten of these, however, nouns which had been dropped
as superfluous are retained. In general, the committee declined to
introduce new terms, to combine nouns and adjectives, or to eliminate
syllables or letters for brevity. It followed Professor Wilder’s advice
in preferring descriptive to personal names, definitely retaining only
two of the latter, Wolffian and Muellerian. Intestinal glands, parotid
duct, splenic nodule, and renal corpuscle replace glands of Lieber-
kuehn, Stenson’s duct, and Malpighian corpuscle, the last term having
been applied to radically different parts of the spleen and kidney.

After a trial of more than ten years this anatomical nomenclature
adopted at Basle, and known consequently as the BNA, has become
the standard terminology. The writer has found it necessary to have
the report of the German committee always at hand. This report
has been made easily available by Professor Barker of Johns Hopkins
University. In a preface of twelve pages he describes the origin of
the Basle nomenclature. On the left hand pages of his book are the
Latin terms in two columns, reprinted in full and without modification
from the German report. On the right hand pages there are two
corresponding columns of English translations of the terms, together
with some of the current rejected names. He says, on page 1, “The
English vocabulary is simply explanatory; in’many instances it would
be unwise to use the English synonyms given, and in many more
instances anatomists would differ as to the most suitable English
equivalent to be chosen. Each anatomist is of course at liberty to
use whatever English equivalent he desires for the official Latin terms.
Students are strongly advised, however, to use the original Latin
terms as English words. The Latin terms are the only authorized
ones.” We agree with Professor Barker that “the sooner a general
decision to adopt these terms is reached, the better it will be of ana-
tomical instruction and research, and the easier it will be for teacher
and taught.”

PEL

The Blending and Overlap of Instincts in Birds.! — Wild birds are
described as passing annually through a cycle of instinctive activities

1 Herrick, F. H. Analysis of the cyclical instincts of birds.— The blending
and overlap of inst'nets. Journ. of Comp. Neur., 1907, vol. 17, pp. 194-197.

No. 486] NOTES AND LITERATURE 399

including (1) spring migration; (2) courtship and mating; (3) nest
building; (4) egg laying and incubation; (5) care of young; and (6)
fall migration. Some birds, like the robin and blue bird, pass through
two or three reproductive cycles before the fall migration. The fish
hawks and eagles which repair their old nests in the autumn do not
act in “anticipation of spring” but exhibit a recurrence of the nesting
instinct, due to beginning a new cycle which is never finished. Young
birds may be abandoned in the fall when the migratory impulse over-
laps the parental instinct. ‘‘An adult robin has been seen to offer a
string to its fully grown young, and try to cram it down the throat of

ling. Later the old bird flew with the string into a tree. This
was the result of the overlapping of two reproductive cycles. The
bird was alternately swayed by opposing impulses, now being impelled
to gather nesting material when she picked up the string, now by
parental instinct to feed her young when she tried to serve it, and
again possibly by the instinct of building when she flew with the string
into a tree.”

When a vireo’s nest contains a cowbird’s egg and a new story is
added to the nest by the vireo, it is not for the purpose of eliminating
the cowbird’s egg, which it does so perfectly. It indicates rather that
the reproductive cycle has been broken by fear, and a new one is
begun, in these rare cases the old nest being retained as a site to build
upon. The herring gull also will bury its eggs when its cycle has been
interrupted through fear.

This interesting interpretation of anomalous actions in birds is
followed in the Journal of Comparative Neurology by an extraordinary
explanation of the brooding habit of the male salamander, Crypto-
branchus allegheniensis.‘ It states that “after the eggs are deposited
they are usually guarded for a time by the male, who fights and drives
away other hellbenders which attempt to eat the eggs. The male
himself eats some of the eggs, but on account of the slowness of his
digestion is unable to eat more than a small proportion, hence his
presence is in the main protective. In defending the eggs the male
is only guarding his own food supply: the origin of the brooding
habit in this case seems to be the feeding habit.” If one doubts that
the perpetuation of this species depends upon a providential slowness
of digestion, a blending of the feeding and brooding instincts may

be substituted.
ine tae

1 Smith, B.G. The habits and life history of cerium allegheniensis.
Journ. of Comp. Neur., 1907, vol. 27, pp. 197-1

- 400 THE AMERICAN NATURALIST [Vor. XLI

A Preliminary Note on the Variation of Scutellation in the Garter
Snakes. — Three years ago the writer began an investigation into the
relationships of the different races of garter snakes (Thannophis) in
an attempt to determine the laws involved in the differentiation of
the genus. The results of this work are being included in a mono-
graph of the genus, but as it will be several months before this work
can be completed it has been thought best to publish a brief outline
of some of the conclusions.

In the progress of this investigation it was seen very early that before
a serious attempt could be made to determine the affinities of the
different races, the significance of the variations in scale arrangement
or scutellation must be determined. This was attempted with the
following results:

1) The number of dorsal scale rows on an individual snake
decreases posteriorly by the elimination of certain rows, and
the series eliminated are always the same for snakes with the
same number of rows, as for example T. sirtalis and T. saurita.

(2) The rows dropped posteriorly in individual snakes are those
which have — disappeared in races with a fewer number
of scale ro

(3) The a in the number of dorsal scale rows is generally
accompanied by a reduction in the number of labial, ventral,
and subcaudal scales (gastrosteges and urosteges).

(4) There is considerable evidence that the reduction in scutella-
tion is directly or indirectly associated with a diminution in size.

The general reduction in scutellation described above is exhibited
by each of the several (natural?) groups into which the genus can be
divided. These groups all occur together only in northern Mexico,
which may be considered the center of origin for the genus. The
races that occur in this region all exhibit the maximum scutellation
for their respective groups, the dwarfing in size and scutellation
taking place at points away from the center of origin. The dis-
covery of these methods of variation in the different series of scales
has been an indispensable aid in determining the affinities of the dif-
ferent races.

ALEXANDER G. RUTHVEN

A Simple Method for removing the Gelatinous Coats of Eggs.—
In the course of work in which it was necessary to handle a number
of amphibian eggs the writer hit upon a simple and rapid method of
freeing them from their gelatinous envelopes. While, because of its

No. 486] NOTES AND LITERATURE 401

very simplicity, it seems impossible that other workers have not used
the method, still the writer has been able to find no reference to it in
embryological literature and he records it here, therefore, because he
feels that it will be very serviceable to workers who have to handle
such material.

The method consists simply in placing the egg on a bit of blotting
paper and then rolling it over and over, thus reversing the small boy’s
method of rolling up a large snow ball. Either fresh or preserved
eggs may in this way be rapidly removed from their envelopes and
transferred by means of a spear-headed needle or a paper spatula to
the fixing reagent. The method worked well on frog and salamander
eggs that had been preserved in formalin for two years, and on milli-
pede eggs which had been similarly preserved for over three years.

When using the method with certain kinds of fresh material, the
eggs may be so soft that when finally unrolled from their coats they
are drawn down so as to adhere tightly to the blotting paper. To
avoid this, (1) roll them off onto a paper of harder texture just before
the last trace of gelatinous film has been removed from their surfaces,
or (2) first fix them (e. g., in Gilson’s mercuro-nitrie mixture) and
then, before further hardening in alcohol, roll them out of their en-
velopes on the blotter.

MicHAEL F. GUYER

The Star-nosed Mole on Long Island, N. Y.— In a recent (1902)
list of the mammals of Long Island, Arthur H. Helme states that the
only evidence of the presence of the star-nosed mole (Condylura cris-
tata) on the island that has come to his knowledge is the finding of a
` single dead specimen. It seems then worth recording that on April
18 a star-nosed mole, which had been caught by a cat, was sent me
from Great Neck, Long Island, by Miss Elise Gignoux.

JoHN TREADWELL NICHOLS

Notes.— Under the name Cirrodrilus cirratus U. Pierantoni has
described' a peculiar-looking worm, about 3 mm. long, found as a
parasite on the crayfish of Japan. It is cylindrical, and consists of a
large head and following this eight body segments, the anterior six
having short fleshy finger-like processes arranged in a transverse line
on the ventral surface. The mouth is nearly surrounded by a ring
of similar longer processes, whence the name cirratus. The mouth
is armed with a pair of horny jaws like those of certain Branchiob-

! Bolletino Societid di Naturalisti in Napoli, 19, 1905.

402 THE AMERICAN NATURALIST [Vor. XLI

dellids with which group (or the Histriodrilids) the author is inclined
to place it. The internal structure was not studied.

The Systematic Position of Trichoplax. Ever since its discovery
Trichoplax has been one of the zoological problems, and now Thilo
Krumbach of Breslau offers evidence’ to show that it may be the
planula of the hydroid Eleutheria. His proof is not conclusive but is
based upon the histological similarities between the planula and
Trichoplax, and upon the fact that Trichoplax appeared suddenly in
great numbers in a tank where the nudusa Eleutheria krohni occurred.
He suggests also that Monticellis Treptoplax reptans belongs to
Eleutheria claparedi.

Caesar Böttger reports? Petricola pholadiformis from the North
Frisian Islands, and quotes also its presence from the East Frisian
Islands. It has previously only been known from the Atlantic coast
of America. It is now distributed over quite a territory and the prob-
lem is how and when did it reach the old world?

Kofoid points out? that the genus Polykrikos which occurs abund-
antly at San Diego, California, is really a colonial infusorian consisting
of two, four or rarely eight zooids and that its place is in the family
Gymnodinide of the Dinoflagellates. Apparently the same species,
Polykrikos schwartzi occurs on the Californian and European coasts.
P. auricularia of Bergh is regarded as a synonym.

Haswell‘ repeats his observation of Euglena-like organisms as `
intracellular parasites in rhabdocoele turbellarian worms.

The Museum at Bergen, Norway, has begun the publication of a
series of monographs dealing with the marine fauna of the vicinity.
The second and third Hefte issued last year, but only now received,
deal with the Bryozoa by O. Nordgaard and the Decapod Crustacea
by A. Appellöf.

J. S. KINGSLEY.

1 Zool. Anzeiger, 31, p. 450, 1907.
? Zool. Anzeiger, 31, p. 268, 1907.
3 Zool. Anzeiger, 31, p. 291, 1907.
‘Zool. Anzeiger, 31, p. 296, 1907.

No. 486] NOTES AND LITERATURE 403.

BOTANY

Cytology and Mutation.— Immediately after the rediscovery of
Mendel’s law and the publication of DeVries’s great work on mutation,
cytologists began seeking for some basis for these phenomena in the
organization of the germ cells. The most recent contribution to the
literature of this subject is a paper by Gates! on (Enothera Lamarckiana
and O. lata.

The author finds that the regular abortion of the pollen in (Enothera
lata is not due to the filling of the anther cavity or loculus by an in-
growth of its lining (the tapetum) as described by Pohl, but to some
other agency the nature of which is not yet explained. Pollen devel-
opment may proceed to the formation of the tetrads, but degeneration
of both the mother cells and the tapetum frequently begins in the
resting stage or in the prophase of the first mitosis. If the tapetal
cells always degenerated before the pollen mother cells, we might
conclude that the failure of the former to secrete nutriment for the
pollen was the immediate cause of sterility. But this is not always
the case for the degeneration of the pollen mother cells may precede
that of the tapetum. The writer is inclined to accept the hypothesis.
that the maternal and the paternal chromatin remain separate in the
somatic cells, and also in the germ cells until maturation approaches.
' Then the intimate union which occurs during synapsis may lead to
incompatibilities between the plasms and to the more or less com-
plete failure of further development.

A second point of interest is the demonstration of peculiar chro-
mosomes, called ‘‘heterochromosomes.” "They arise in O. lata in the
prophase after synapsis by the cutting off of a portion or loop of the
spireme thread before the remainder breaks up into chromosomes.
A cell may contain one or two of these bodies which appear as large
rings, usually seen in the cytoplasm near the spindle. They do not
divide but become smaller and probably disappear at the end of the
first mitosis. In the O. Lamarckiana hybrid these bodies also occur.
The author thinks that they represent discarded chromosomes and are,
perhaps, a means of lessening the number of chromosomes in certain

! Gates, R. R. Pollen development in hybrids of (Enothera lata
marckiana, and its relation to mutation. Bot. Gaz., 1907, vol. 43, pp. ee 115,
2-4.

pl.

404 THE AMERICAN NATURALIST [Vor. XLI

germ cells. Some mother cells do not contain them, but it could not
be demonstrated that these have fewer ordinary chromosomes than
the others. The number of chromosomes in O. lata is fourteen; in
the hybrid with O. Lamarckiana it is “probably twenty”; and in pure
O. Lamarckiana the number, as yet undetermined, is thought to vary.
Since a different number of chromosomes in closely related species
has apparently never before been recorded, these observations if they
are verified by further investigations are of great interest. The author
dismisses the idea that O. Lamarckiana is itself a hybrid, but this also
is an important subject for further study. He concludes that the
mutations of O. Lamarckiana probably arise during the reduction
divisions, and that the pollen grains which give rise to mutants may
differ in their chromatin morphology from the ordinary pollen of the
plant.
J. A. HARRIS

Variation and Differentiation— Dr. Pearl has recently published
an exhaustive study of the intra-individual variation and differentiation
in Ceratophyllum.' The purpose of the author was “to work out as
exactly and completely as possible for a particular organism the laws
according to which post-embryonic differentiation and growth occur.”
The characters considered are (a) the number of leaves per whorl;
(b) the position of the whorl on the plant; (c) the size of the various
divisions of the plant; and (d) the position of the branches. It is
found that the mean number of leaves per whorl is greatest on the
main stem and decreases on the primary, secondary, tertiary and
quaternary branches. The variability — measured by both the
standard deviation and the coefficient of variation, on the other hand,
increases on the branches of the first and second order to fall again
on those of the third and fourth order. The skewness also seems to
increase in the negative direction from the main stem outward but the
shortness of the material does not permit of the determination of this
point by analytical methods beyond the secondary branches. A
marked correlation is found between the position of the whorl on the
stem and the number of leaves. The number of leaves increases
from the base to the tip of the axis but the increase cannot be repre-
sented by the slope of a straight line —in biometric terminology,
regression is not linear — or by a parabola. The increase is, however,

ı Pearl, R. Variation and Differentiation in Ceratophyllum. Carnegie
Institution of Washington, 1907, Publ. 58, 136 pp., 26 figs., 2 pl.

No. 486] NOTES AND LITERATURE 405

well represented by a logarithmic curve. This is the first law of growth
in Ceratophyllum and may be stated as follows: ‘On any axial
division of the plant the mean number of leaves per whorl increases
with each successive whorl in sucha way that both the absolute incre-
ment and the rate of increase diminish as the distance (in units of nodes)
of the whorl from a fixed point increases.”

The second law of growth is that of diminishing variability. The
whorls of leaves produced by a growing point are formed with ever
increasing fidelity to type. “The growing point appears to be in-
fluenced in its morphogenetic activity by its previous experience.”

To the students of evolution, who are now concerning themselves
primarily with experimental and statistical investigations of variation
and heredity, the importance of such a detailed study of intra-indi-
vidual variation, correlation and differentiation will be apparent. In
the original paper they will find a wealth of analyzed material.

J. A. HARRIS

Cotton.— Its Cultivation, Marketing, Manufacture, and the Prob-
lems of the Cotton World. By Charles William Burkett, Professor of
Agriculture, North Carolina College of Agriculture and Mechanic
Arts, and Clarence Hamilton Poe.'— This volume of over three hun-
dred pages is interesting from many points of view. Its illustrations
are reproductions in a sepia tone of much effectiveness and the con-
trasts, especially in the case of white cotton bolls are very pleasin
Moreover many of the sketches are likely to be of permanent interest
as matters of record, notably those which give some notion of fast-
vanishing methods of carding, spinning, and weaving cotton by hand.
The authors have spared no pains to make the illustrations attractive
and useful, and they have succeeded admirably. The text is clearly
written, throughout, and it is well-arranged with respect to convenience
of reference. Moreover, the facts as regards the botany, the agricul-
ture, and the commercial relations of the cotton-plant, are carefully
stated in such a manner as to be quite within the reach of the general
reader, but we miss what ought never to be lacking in any book of
reference,— an index. The value of this useful treatise would be
enhanced tenfold by a copious alphabetical and subject index.

G. L. GOODALE

Notes. — Three new species of Dendromecon are described by
Fedde in Repertorium Novarum Specierum of Jan. 15.

1 New York, Doubleday, Page & Company.

406 THE AMERICAN NATURALIST [Vor. XLI

Notes and illustrations concerning Robinia N eo-Mexicana are pub-
lished by Phillips in Forestry and Irrigation for February.

An illustrated economic account of Nyssa aquatica, by von Schrenk,
has been reprinted from the “Silver anniversary edition” of The
Southern Lumberman.

Vaccinium Dobbini is the name proposed by Burnham in The
American Botanist of February for a New York relative of V. vacillans.

A revision of Spilanthes, by A. H. Moore, constituting no. 33 of the
new series of ‘‘Contributions from the Gray Herbarium of Harvard
University,” is published as vol. 42, no. 20 of the Proceedings of the
American Academy of Arts and Denice.

A paper on Citharexylum, by Greenman, forms Publication 117 of
the Field Columbian Museum.

On Pringle’s Santa Catalina Mountain material of 1881, Dode
bases a new Juglans eleopyren in the Bulletin de ? Herbier Boissier
of February 28.

An economic account of the walnut in Oregon is published by
Lewis in Bulletin no. 92 of the Agricultural ee, Station of that.
State.

A new Californian oak, Quercus Pricei, is described by Sudworth
in Forestry and Irrigation for March.

Several new aloids and other succulents are described by Berger in
vol. 4, no. 38 of the Notizblatt des K. Botanischen Gartens und Muse-
ums zu Berlin.

Agave deserti is figured in detail in Icones Selecte Horti Thenensis,
vol. 6, fase. 1.

A series of notes on Abietinez, by Hickel, are appearing in the
Bulletin de la Société Dendrologique de France.

Cardot and Thériot report on a collection of 63 Alaskan mosses in
vol. 2, no. 13 of the University of California Publications, Botany.

Vol. 7, part 2, of North American Flora is occupied with a part of
the Uredinales, by Arthur.

An extensive and well illustrated paper by Lyman on “Culture
Studies on Polymorphism of Hymenomycetes,” constituting no. 64
of the ‘Contributions from the Cryptogamic Laboratory of Harvard
University,” forms vol. 33, no. 4 of the Proceedings of the Boston
Society of Natural History.

No. 486] NOTES AND LITERATURE 407

An enumeration of the fungi collected by Simmons on the second
Norwegian Polar expedition, by Rostrup, was published in no. 9 of
the Report on the Expedition shortly before the death of the author,
which occurred in January.

Several quite distinct puff balls and phalloids of Argentina are
described and figured by Spegazzini in a paper recently distributed
from vol. 16 of the Anales del Museo Nacional de Buenos Aires.

A flora of Central Europe, with text cuts and colored plates, by
Hegi and Dunzinger, is being issued in 70 monthly parts from the
Lehmann Press of Munich.

With vol. 3, fase. 7, issued in December, Coste’s “Flore Descriptive
et Illustrée de la France” etc. was brought to a conclusion, the final
signatures dealing with Pteridophytes.

An ecological systematic account of the flora of Columbia, Missouri,
by F. P. Daniels, forms vol. 1, no. 2 of the Scientific Series of The-
University of Missouri Studies. Twelve new species or varieties and
26 new names occur in the list, which includes 13 genera, with 19
species, of Pteridophytes and 422 genera, with 1039 species, of
Spermatophytes.

A general biological study of the sand areas of Illinois, by Hart and
Gleason, forms vol. 7, article 7 of the Bulletin of the Illinois State-
Laboratory of Natural History.

The distribution and adaptation of the vegetation of Texas are
discussed by Bray in Bulletin no. 82 (Scientific Series no. 10) of the
University of Texas.

A study of the flora of the Sand Keys of Florida, by Millspaugh,
forms Publication 118 of the Field Columbian Museum.

A further paper on the grasses of Argentina has been published by
Stuckert in vol. 13 of the Anales del Museo Nacional de Buenos Aires.

The first fascicle of vol. 3 of Arechavaleta’s “Flora Uruguaya” has
recently been issued as a part of vol. 6 of the Anales del Museo Nacional
de Montevideo.

Mr. Cook’s concept of “Kinetic Evolution” is set forth in extenso
in a large brochure of vol. 8 of the Proceedings of the Washington
Academy of Sciences, issued on February 13th.

Separates of Dr. Robinson’s paper on “The Problems of Ecology”
have been distributed from vol. 5 of ‘ Congress of Arts and Seiences,.
Universal Exposition, St. Louis, 1904.

408 THE AMERICAN NATURALIST [Vor. XLI

Studies on the pollination of Wisconsin flowers are being published
by Graenicher in current numbers of the Bulletin of the Wisconsin
Natural History Society.

Von Ihering contributes an illustrated account of the myrmeco-
philous Cecropias to recent numbers of Engler’s Botanische Jahrbiicher.

Dissemination by the aid of ants is the subject of a well illustrated
memoir by Sernander, forming vol. 41, no. 7 of the K. Svenska Veten-
skapsakademiens Handlingar.

A large preliminary paper on the fungi of certain termite nests, by
Petch, is published, with illustrations, in vol. 3, part 2 of the Annals
of the Royal Botanic Gardens, Peradeniya.

A comprehensive bibliographic, botanical and physiological memoir
on tannoids, by Dekker, forms no. 35 of the Bulletin van het Kolo-
niaal Museum te Haarlem, printed in December last.

A long list of plants known to contain prussic acid is separately
distributed by Greshoff from the 1906 Report of the British Associa-
tion for the Advancement of Science.

Studies on the influence of spectral colors on the sporulation of
Saccharomyces are reported by Purvis and Warwick in vol. 14, part
1 of the Proceedings of the Cambridge Philosophical Society.

The root-knees of Sonneratia are well figured in the Annual Report
of the Director of Forestry of the Philippine Islands for the Period
July, 1905 to June 30, 1906.

A rope-like tumor of Betula populifolia is described and figured
by Penhallow in a separate from vol. 12 of the Transactions of the
Royal Society of Canada.

An illustrated account of commercial seeds of brome grass and blue
grass and their adulterants, by Roberts and Freeman, forms Bulletin
141 of the Kansas Agricultural Experiment Station.

Tobacco breeding is considered by Shamel and Cobey in Bulletin
no. 96 of the Bureau of Plant Industry, U. S. Department of Agri-
culture.

An illustrated editorial account of the Mexican “guayule” is being
published in current numbers of The India Rubber World.

A discussion of timber under conditions of modern demand and
growth, by von Schrenk and others before the New England Railroad
Club, has been distributed in pamphlet form by the Rand Avery
Supply Company of Boston.

No. 486] NOTES AND LITERATURE 409

A series of “Forest Planting Leaflets,” each dealing with a single
species, is being published as Circulars of the Forest Service of the
United States Department of Agriculture.

Studies of the wood of Javan trees, by Moll and Janssonius, are
being published by the Brill Press of Leiden.

A second edition of the useful “Key to the Genera of Woody Plants
in Winter,” by Wiegand and Foxworthy, has been issued by the
authors, whose address is Ithaca, N. Y.

A portrait, with short biographic sketch, of the late Sir Thomas
Hanbury is given in The Gardeners’ Chronicle of March 16th.

A portrait of H. N. Ridley is given in Tropical Life for January.

An appreciative notice of Marshall Ward, by the late Director of
Kew Gardens, appears in The New Phytologist of January 31.

Fascicle 4 of de Wildeman’s “Enum6ration des Plantes Récoltées
par Emile Laurent,” issued in February, contains a portrait and
biographic sketch of Laurent.

Further articles on Burbank and his work, by DeVries, appear in
the Biologisches Centralblatt for September, The Open Court for

November, and The Century Magazine for March.
We E

GEOLOGY.

The Elements of Geology.'— Professor Norton of Cornell College,
Iowa, has sought to present to the public an elementary textbook on
geology “in which causes and their consequences should be knit
together as closely as possible.” He accordingly departs from the
usual three-fold division into dynamical, structural, and historical
geology, treating geological processes and the forms or structures
which they produce in immediate connection, under the headings
“External Geological Agencies” and “Internal Geological Agencies.”
A third part of the book treats of Historical Geology.

Under the heading “External Geological Agencies” the work of

1 Norton, William Harmon, The Elements of Geology. Boston, Ginn &
Company. x+462 pp., 374 illustrations.

410 THE AMERICAN NATURALIST [Von XLI

the weather and the work of ground water are first considered, after
which the work of rivers, glaciers, winds, and the sea are considered
in the order indicated. A final chapter in this part of the book dis-
cusses off-shore and deep-sea deposits. Under the heading ‘Internal
Geological Agencies” the following chapters appear: Movements
of the Earth’s Crust, Earthquakes, Voleanoes, Underground Struc-
tures of Igneous Origin, Metamorphism and Mineral Veins. Histori-
cal Geology is treated in the usual manner, the principal systems and
some of their characteristic fossils being described in order, beginning
with the Pre-Cambrian. Special emphasis is laid upon the evolution
of the North American continent and the evolution of life upon the
planet.

It is probable that many will doubt the wisdom of dropping out
structural geology as a special subject and treating it only in connec-
tion with geological processes. There are difficulties in the way of
such a treatment, one being the danger that the elementary student
will not discriminate sufficiently between the process, the structures.
due to the process, and the structures which merely affect the operation
of the process, all of which are treated under a single tite. In the
present text this danger is minimized by a clear presentation of the
different factors involved, although in places a stronger discrimination
between structures due to the process under discussion and structures
controlling the operation of that process might profitably have been

made.

The illustrations are well chosen and remarkably good. Indeed,
Professor Norton’s book is one of the best illustrated elementary texts.
on geology which the reviewer has seen. The book is thus made
attractive to the student, and at the same time the subjects treated
are made more real to him than is possible with inferior illustrations.
In view of the fact that contour maps are used for some of the figures,
it would doubtless increase the efficiency of the book to have the -
printed explanation of contours on page 69 supplemented by such
illustrations as would aid the student to a better understanding of
that subject than the brief printed text is apt to impart

As is the case with every text, there are points in Professor Norton’s
book which one would prefer to see changed. But after a careful
reading the reviewer is convinced that the author has succeeded in his
endeavor to present a text which will rank as one of the best elementary
treatises on geology. The mechanical work on the book is excellent.

D. W. JoHnson.

PUBLICATIONS RECEIVED

From April 1 to May 1, regular exchanges not included
The year of publication, when not otherwise noted, is 1907.

BERGEN, J. Y. and Davıs, B. M. Laboratory and Field Manual of Botany.
Boston, Ginn & Company, 1907. 12mo, 257 pp. 90 cents.— BıGELow, E. F.
The Spirit of Nature Study. New York, A. S. Barnes & Company, 1907.
222 pp., illus.

APPELLÖF, A., editor. Meeresfauna von Bergen, parts 2 and 3 (Bryozoa
and dacapod Grostacés), p pp. 76-233, 4 pls., 3 maps. Publ. of the Bergen
Museum, 1906.— CHEVREUX, Eb. Dromos wpm nouvelle espèce
d’Amphipode des régions arctiques. Bull. de U’Ins de Monaco
no. 96, 6 pp., 3 figs—Coss, N. A. Some ee of plant pathology:
Rep. of the Exp. Sta. of the Hawaiian Sugar Planters’ Assoc., dw. of path. and
p ys., bull. 4, 46 pp., 32 illus. — CouTI&rE, H. Questi onnaire relatif aux
espèces comestibles de Crustacés. Bull. de l’ Inst. Oceanog. de Monaco, no.
98, 8 pp.— Frernatp, H. T. The San José scale and experiments tor its
control. Mass. Agric. Exp. Sta., bull. 116, 22 pp.— Forses, S. A. On =
local distribution of certain Illinois fishes. ~ of Ill. State Lab., vol.
art. 8, pp. 273-303, pls. 24-32, 15 maps.— Forses, S. A. An fone bore.
cross-section of Illinois in autumn. Bull. of Ill. ee Lab., vol. 7, art. 9, pp.
305-335.— FRANKLIN, H. J. Preliminary report on abaty insects.
Mass. Agric. Exp. Sta., bull. 115, 15 pp.— GRINNELL, J. and H. W. Reptiles
of Los Angeles County, ee Throop Inst. Bull., no. 35, 60 pp., 23 figs

Hoper, F. W., oo of American Indians north of Mexico
part 1. Smitinion Inst., of Amer. Ethn., bull. 30, 972 pp., illus.—
JOHANNSEN, W. le o" Laniskaller. K. D. Vid.

Selsk. Overs., no. = 72 pp.— JoRDAN, D. S. A review of the fishes of the
family Gerridae found in the waters of Japan. Proc. U. S. Nat. Mus., vol.
32, pp. 245-248, 2 figs.— Korom, C. A. Dinoflagellata of the San Diego
region, III. Descriptions of new species. Univ. of Cal. Publ., Zool., vol. 3,
no. 13, pp. 299-340, pls. 22-33.— Mearns, E. A. Mammals of the Mexican
boundary of the United des part 1. Smithsonian Inst., U. S. Nat. Mus.,
bull. 56, 501 pp., 126 figs., 1 map.— Merritt, G. P., and Tassın, W. On the
meteorite from Rich Mountain, Jackson County, North Carolina. Proc.
U. S. Nat. Mus., vol. 32, pp. 241-244, pl. 16.— Porter, P., and Ricuarp, J.
Sur une méthode de prélèvement de l’eau de mer destinée aux études bac-
tériologiques. Bull. de VU Inst. Oceanog. de Monaco, no. 97, 4 pp., 4 figs.—
Sars, G. O. An account of the Crustacea of Norway, vol. 5, parts 13-16
(Copepoda: Diosaceide and Canthocamptide), pp. 157-196, 32 pls.) Publ.
of the Bergen Museum, 1906.— Starks, E. C. and Morris, E. L. The marine
fishes of southern California. Univ. of Cal. Publ., Zool., vol. 3, no. 11, pp.

Somaliland, East Africa, collected by Dr. Charles Gravier. Proc. U. S. Nat.
Mus., vol. 32, pp. 249-266, pl. 17-28.— Vernon, J. J. Dry farming in New
Mexico. N. M. Agric. Exp. Sta., bull. 61, 54 pp., 30 pls.— Wıruıams, H. S.

411

412 THE AMERICAN NATURALIST [Vor. XLI

A new Brachiopod, Rensseleria mainensis, from the Devonian of Maine.
Proc. U. S. Nat. Mus., vol. 32, pp. 267-269

ANNALES DE LA SocIÉTÉ BELGE DE MICROSCOPIE, vol. 27, no. 2, 1906; vol.
28,no.1. ANNUAL ANNOUNCEMENT OF THE MARINE BIOLOGICAL Lisoaaseur,
Woops Hore, Mass. ERGENS MUSEUM AARBOG 1906, nos. 1 and 2. BuL-
LETIN OF THE CHARLESTON MUSEUM, vol. 3, no. 3. BULLETIN OF THE TORREY
ue Sn vol. 34, no. 2. JOURNAL OF GEOGRAPHY, vol. 6, no.
Naturæ ates, vol. 29, nos. 1-3. Onto STATE UNIVERSITY BULLETIN,
vol. 11, no. 5 supplement B. PRESIDENT’S REPORT OF THE UNIVERSITY
or MONTANA, 1905-1906. PROCEEDINGS OF THE WASHINGTON ACADEMY
OF SCIENCES, vol. 8, pp. E 487-491. STATEN ISLAND ASSOCIATION OF
ARTS AND SCIENCES, vol. 1, part 3, 1906, and memorial number, 1907. UNI-
VERSITY OF COLORADO, ois. vol. 4, no. 2.

(No. 485 was issued May 21, 1907)

The first of a series of Colored
Plates of the 2 2 æ æ &

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By FUERTES & HORSFALL,

was published in BIRD-LORE for

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BERGEN’S
ELEMENTS OF BOTANY

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Including Key and Flora for Northern and Central ee ı2mo. Cloth. 283 + 257
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RGEN’S “ Elements of Botany,” Revised Edition, is designed to
furnish a half- a u in ee subject for pitty in atone
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traverse in the time fadicated, and presents d thee vent Ee Olah a are
essential to an elementary course in the
It differs from the earlier editio ons of “the « “Ble ments” mainly in the
greater stress laid on the topics of ecology and ur ni ee botany, i in
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and in ri greatly weh quality of the illustrations, “Minor changes
will be found on almost every page.

THE BOOK IS ae ERIZED

y the natural method of presentation, introducing the pupil first, as Professor Huxley
recommended, to the com tivel uk forms pee processes of plant life.
By the sparin w of technical terms, emplo g these only when they are i indispensable

for the sake of clearness or of brevi
rc of the structures and ae functions of plants consecutively, not in
s of the book.

wid
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r

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By the rer
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By mbar that at fours sites | keys floras rg ode n pre ared to accompany the text.

udent in ney ge of en pe ry
nation of fg ay of phanerogams, and to get a practical idea oh their Ge namen. and
classification by means of asi mply wri and inexpensive flora of his o

To accompany Bergen’s Text-Books on Botany, and for rer use in Botanical
Laboratories or for ondary Schools. Square 4to. Cloth. 144 pages. List price,
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The American Naturalist
EDITOR
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ASSOCIATE EDITORS
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didat
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THE
AMERICAN NATURALIST

Vor. XLI July, 1907 No. 487

AGASSIZ CENTENNIAL
REMARKS OF
CHARLES WILLIAM ELIOT

Lapıes and Gentlemen: Mr. Dana in opening this meeting
spoke of the Saturday Club and of Agassiz as a member. His
words reminded me of the only occasion when I ever heard a speech
made at that Club. I have been a member of it now about thirty-
five years, and only on this one occasion did I ever hear a speech
made there. It was when Agassiz, who at that time always sat
at the foot of the table, was going away on that long voyage of the
Hassler round Cape Horn. At the head of the table sat Long-
fellow, as usual, and along the sides sat many of the men just men-
tioned by Mr. Dana. Near the close of the dinner Longfellow
suddenly rose, and to our great astonishment said,— “Our dear
friend Agassiz is going away; he is going on a long voyage in the
hope of recovering his health; we shall miss him grievously; we
shall welcome him back most thankfully, restored to health. Let
us drink his health now.” And we all got up except Agassiz, and
drank his health; and then he rose and struggled to say something,
and could not; and finally the tears rolled down his cheeks and
he sat down speechless. It was a vivid instance of a characteristic
quality in Agassiz, namely, the strength of his emotions. He was
a man of strong and deep emotions, and his influence over us
restrained, reserved Americans was largely due to the intensity
of his feelings, and to the way in which his face and body expressed
those feelings.

He was, as has been repeatedly said here this evening, a born

413

414 THE AMERICAN NATURALIST [Vor. XLI

teacher and expositor. He expounded clearly and sympathetically
before any audience the fundamental principles of his science, and
gave examples illustrating the principles with both hands, and
with shining, smiling face. He was just that,—a teacher by
nature, an enthusiastic, earnest, moving teacher.

As Professor Gray has just said, he came into this Puritan
society like a warm glow into a chilly room. He was a revolution-
ary spirit in Harvard College, an exception to all our rules. He
welcomed special students, for instance, who could not possibly
pass the examinations for admission to Harvard College. He
kept them for years in his laboratory, training them in his obser-
vational method,— quite a new introduction among us. Many
of our best people disapproved of that method! ‘The son of one
of our most distinguished surgeons submitted himself to the teach-
ing of Agassiz in the crude zoölogical laboratory, and received
several trilobites upon which he was expected to spend weeks,—
examining them, seeing what he could discover in them, and mak-
ing a record of his discoveries. He was kept at this sort of work
for weeks without a book, and without plates. He was to make
his own plates. At last the son described this process to the
father as novel and interesting, but difficult. Now that father
was at bottom a naturalist, like every physician or surgeon, and
yet he said,— “ What! no book, no plates, no guidance from the
wisdom of all preceding generations! Set just to use your own
senses on those fossils!” “Yes,” said the son, “that was the
whole of it.” “ Well,” said the father, “that is exactly the way a
puppy has to learn everything.” ‘The criticism was a real one;
the father thought that Agassiz was neglecting all the natural and
proper aids which past time had placed at the service of human
youth.

And then, what a new kind of professor Agassiz was in this old
town! He had none of the regular habits of the traditional Har-
vard professor. He did not even wear the characteristic black
clothes. He would cross the College Yard any day of the week,
at any hour of the day, in a soft, grey felt hat, smoking a cigar
when to smoke in the College Yard was a grave offence. He
never went to church. Sunday was his day of rest, but he did not
take it in the New England fashion. His mode of lecturing was

No. 487] AGASSIZ CENTENNIAL 415

unexampled among us. His conception of the duty of a professor
to investigate, to discover, to collect, we had only noticed faintly
in a few exceptional American teachers. ‘Those methods had been
introduced in small measure among us; but those were the prime
ideas of Agassiz as a professor and a teacher.

There were but two pitiful little collections in the possession of
the University when Agassiz first came here,— a collection of
minerals, imperfect, small, and never properly arranged, and the
beginnings of a botanic garden and herbarium. The idea of mak-
ing great collections of natural history objects hardly existed
among us; we had hardly aspired to such collections.

And then, he raised such astonishing sums of money for these
new subjects of zodlogy and geology. A good deal of jealousy
about this extraordinary money-raising was felt by members of
other departments long established in Cambridge for the traditional
subjects of collegiate instruction. I remember one night at my
uncle Mr. George Ticknor’s, hearing this jealousy expressed by
one of Professor Agassiz’s colleagues in Harvard University. But
Mr. Ticknor said,— “Don’t be alarmed; Agassiz will get more
money out of the Commonwealth of Massachusetts for his subjects
than any of you have dreamed of getting, than any of you could
possibly get; but he will so equip his subject, he will set such a
standard for collections in all subjects, that every department
of learning in the University will profit by his achievements.”
That is just what has turned out to be the truth.

Agassiz founded here an institution; and he has had this un-
usual felicity,— that his son, an extraordinary naturalist and an
extraordinary man of business, has built up with prodigious skill
and liberality the institution which his father founded. That, I
say, is a rare felicity.

Every teacher who is eminently successful as teacher, inspirer,
and enthusiast, wins another sort of felicity in time. He brings
up a group of disciples, and these disciples carry their master’s
teaching beyond their master’s own range, and adapt his teachings
to the new conditions which rapidly come about in science,— in-
deed, in all kinds of learning and working, and in modern society
as a whole. That felicity Agassiz has enjoyed,— a beautiful
felicity, a rare reward.

416 THE AMERICAN NATURALIST [Vor. XLI

So we welcome this commemoration of a great teacher and a
noble friend, and we say with Longfellow at the Saturday Club, —
We miss him greatly, but we rejoice in his coming back to us in
durable memory, and in the infinite ramifications of his personal
influence.

CAMBRIDGE. 27 Mar ’07

DESCRIPTION OF A NEW SPECIES OF TELENOMUS
WITH OBSERVATIONS ON ITS HABITS AND
LIFE HISTORY

A. W. MORRILL

MINUTE egg parasites belonging to the hymenopterous family
Proctotrypide are known to play an important role in checking
the multiplication of certain insects, fluctuations in the numbers of
the parasites and hosts usually being intimately associated and re-
sulting in a corresponding benefit or injury to the crops attacked
by the latter. Notwithstanding the economic importance of the
proctotrypids our knowledge of their life histories is very meager,
and the incidental and more or less fragmentary notes upon which
this contribution is based seem to point to a fruitful field for the
investigator.

The data here presented were obtained in 1905 in connection
with the investigation of heteropterous pests of cotton, alfalfa
and other crops. ‘The principal insect (Fig. 1, a) affected by the
parasite here discussed, is a member of the stink-bug family or
Pentatomide, and is commonly known in Mexico by the name
“Conchuela.” Only five North American species of proctotry-
pids known to attack the eggs of these bugs have heretofore been
described, but many undescribed forms doubtless exist. All
of these five species were described by Ashmead (’93), one belong-
ing to the genus Telenomus and four to Trissolcus.

H. A. Morgan (’97) records that in Louisiana in August, 1896,
the eggs of the Harlequin Cabbage Bug, Murgantia histrionica,
were parasitized by proctotrypids (Trissoleus murgantie and
Trissoleus podisi) to the extent of over 60%. The writer has
noted (’07) that of 211 pentatomid eggs collected at Barstow,
Texas, in September 1905, 148 or 70% produced adult specimens
of Telenomus ashmeadi, the species hereafter described. During
July 1905, 22 batches including 794 eggs were collected in cotton
and alfalfa fields at Tlahualilo, Dgo., Mexico. Of these, 18
batches were parasitized and from their 638 eggs, 468 adult speci-

417

418 THE AMERICAN NATURALIST [Vor. XLI

mens of Telenomus ashmeadi were produced. The remaining
eggs, amounting to 27%, failed to produce adult parasites or to
hatch; they were presumably destroyed by parasites which failed
to mature or to emerge, for from the four non-parasitized egg
batches 155 bug nymphs hatched from 156 eggs. In the case of
every parasitized pentatomid egg batch collected at Barstow,
Texas, or at Tlahualilo, Mexico, no nymphs hatched, showing
that in the majority of cases complete destruction results when-
ever an egg batch of a host species is discovered by its tiny
enemies. Of 41 batches collected, 36 or 88% were parasitized
by Telenomus ashmeadi. This probably represents more closely

. 1l.—a, an adult conchuela, Pentatoma ligata Say, en I a er
a an ik female specimen of Telenomus ashmeadi N. Sp., enlarged abou

20 diameters. From the author’s illustrations in Bull, 64 of fer Bur, of can A
U.S. Dept. of Agriculture,

the economie usefulness of this species than do figures based upon
the individual eggs. Although the multiplication of the host
species appears to be effectively checked by these beneficial insects
by midsummer, the pentatomid bugs affected have already had an
opportunity to show the extent of their destructive capabilites.
In the case of a large plantation in northern Mexico which com-
prises some twenty-seven thousand acres of cultivated land mostly
devoted to cotton, the damage from the host species, the conchuela,
is estimated at from twenty to sixty thousand dollars in single
seasons. Without the natural check afforded by these parasites
this destruction would doubtless be increased five or six times.

No. 487] A NEW SPECIES OF TELENOMUS 419

DESCRIPTION AND RECORDS OF BREEDING AND COLLECTION.

This parasite having been pronounced a new species of the
genus Telenomus by Dr. W. H. Ashmead, the writer takes pleasure
in dedicating it to this eminent authority on the parasitic Hy-
menoptera who has described more than 500 North American
representatives of the family Proctotrypide.

Telenomus ashmeadi, N. Sp. 2 (Fig. 1, b). Length 1.08-1.15
mm. Black with fine pale pubescence.

Head.— Width, .56 mm., scarcely wider than thorax, marked
with impressed reticulations; mandibles black. Antenne clothed
with pale pubescence, dark brown to blackish in color, except
pedicel the color of which gradually changes to light brown at
distal end. ii eigen dimensions of antennal segments (Fig.
2, B) are as follows:'

— daear Segments of Flagellum

eee eo Re 1

Length 105 28 oo: 18 12 n 17..38. 75 36:99: TH
Greatest width 16 2: 131 13 15. 18 8.12 16 B —

Thorax. — Width .55 mm., length .48 mm. Dorsum marked
with impressed reticulations, pubescent; mesoscutum rather
roughly longitudinally grooved posteriorly; scutellum smooth
and shining with a few pale hairs arising from minute punctures.
Legs clothed with moderately dense pale pubescence; cox
black; trochanters, tibie and tarse light brown by reflected
light, yellowish brown by transmitted light; tarsal segments
successively darker to the last; femora dark brown or brownish
black by reflected light, dark brown by transmitted light. Pro-
portionate length of segments of hind tarse not including tarsal
claws, as follows:® $, 3, 3, $, 3. Wings hyaline, iridescent;
venation brownish; length of fore wing 1 mm., greatest width,
46 mm.

Abdomen.— Length .532 mm., width .518 mm.; basal two
thirds of first segment striate above; basal two thirds of second

1 Measurements made with 1 in. eye piece and } in. obj.; tube length 160
mm. To obtain dimensions in mm, multiply by .003.

? Measurements made with 1 in. eye piece and 4 in. obj., tube length 160
mm. To obtain true lengths in mm. multiply by .0148.

420 THE AMERICAN NATURALIST [Vorn XL1

segment striate above except laterally, elsewhere smooth and shin-
ing; third to fifth segments punctate. Length of second segment
.3 mm., greatest width .518 mm. Second, third and fourth seg-
ments fringed with sparse pale hairs posteriorly. Fifth segment
finely pubescent. Ventral plates finely punctate and pubescent.
Sheath of ovipositor about .044 mm. in length. Ovipositor when
fully extended about .1 mm. in length.

S.— Length .8-1.13 mm. Differs in form from the female
principally in the moniliform twelve segmented antennz and the
more abruptly truncate abdomen. Head, .44-.62 mm. wide.
Thorax, .38-.55 mm. wide. Length of abdomen .32-.44 mm.,
greatest width .38-.46 mm. Proportionate dimensions of anten-
nal segments (Fig. 2, A) are as follows:'

Scape Pedicel Segments of Flagellum
ee ees é 6. t 9 101-10
Length 100. 25 31 24 25 20 19 19 19 19 2 30 226
Greatest, width I7: 15 H-U 2 un EU BB nu m =
The constrieted basal portion of the scape is dark brown; the
outer three-fourths is light
brown. Pedicel light brown,
darker on outer side. Fla-
gellum light brown basally,
changing to dark brown dis-
tally. Legs except the coxee
light brown in color by re-
flected light, by transmitted
light pale brown to honey
yellow.

Described from numerous.
specimens of both sexes.
Cotypes deposited in the U.
10. 2.— Antennae of Telenomus ashmeadi, en- S National Museum; Type
larged 70 diameters, A, male. B, female. No. 10364. Type locality

Barstow, Texas; also collected at Tlahualilo, Dgo., Mexico.

1 Measurements with same combination as used for measurements of the
segments of the antenn® in the female. Multiplying the figures by .003
will give dimensions in mm. of average specimens bred from eggs of Pentatoma

No. 487] A NEW SPECIES OF TELENOMUS 421

All of the females were bred from eggs of Pentatoma ligata
collected at Barstow, Texas, Sept. 12th, 1905. Three of the
males were bred from eggs of Thyanta custator Fabr. In the
foregoing description of the male, the smaller series of dimen-
sions refers to the specimens bred from Thyanta custator, and
the larger series of dimensions to specimens bred from the eggs
of Pentatoma ligata. It is probable that this parasite will readily
attack the eggs of most or all of the species of pentatomid bugs.
In addition to the eggs of Pentatoma ligata they have been bred
from the eggs of Pentatoma sayi Stal collected at Barstow and
in the laboratory showed no hesitation in attacking the eggs of
Euschistus servus Say and Thyanta custator. The size of the
adult parasites corresponds directly with the size of the respective
host eggs. The following table showing the relationship between
the size of the host eggs and of the adult parasites is based on
five male specimens bred from eggs of each of the three host species:

Host species Pentatoma Euschistus eh
ligata servus tator
Host egg, ee length 1.33 1:11 “90
erage diameter 1.01 88 -15
I - paraste average width .60 .53 45
aximum width .62 .54 AT
pes hh A TER width .56 .52 .44

The parasitizing of eggs of pentatomid species representing
more than one genus by a proctotrypid was recorded in 1897 by
Prof. H. A. Morgan who bred Trissoleus podisi from the eggs of
Murgantia histrionica, the Harlequin Cabbage Bug. The para-
site in this case had previously been recorded as having been bred
from the eggs of Podisus maculiventris Say (= spinosus Dal).

Hasits AND Lire HISTORY.

Emergence of adults. The adult parasites use their mandibles
to make exit holes for themselves at the top of the eggs, i. e., at
the end through which the nymphs normally emerge (Fig. 3).
When mature, the parasite completely fills the host egg and so
far as observed always develops with its head at the end from
which the pentatomid nymphs normally hatch. In one instance,
one egg of a batch of 28 was deposited wrong side up by the parent

422 THE AMERICAN NATURALIST [Von XL1

pentatomid (P. ligata) and after the batch was subsequently
parasitized the adult proctotrypid emerged from the top side of
the misplaced egg, ?. e., the under side of the egg batch.
Oviposition. On one occasion it was observed that four adult
parasites, which had previously been rather quiet at the top of a
cage, became very much excited immediately upon the introduction
of empty egg shells of Thyanta custator and an unhatched egg
batch of Euschistus servus.’ The insects were not ordinarily dis-

PE TERTA

Fic. 3.— Egg batch of conchuela, Pentatoma ligata, from which 32 parasites,
Pech us ashmeadi, have emerged. Enlarged 63 diameters. The illus-
+ amg shows three paresites, inc anit ling male and fe male, ready to emerge;
also an egg destroyed, probably by an ant. Morrill, Bull. 64 of the Bureau

of Arch Bu United States Department of Agriculture

turbed by such a slight movement of the cage as was necessary
to introduce these eggs and egg shells, but in this case they dropped
almost at once to the bottom and carefully examined the empty
egg shells, after which the eggs of Euschistus servus were found,
and oviposition in these began almost immediately. At another
time thirteen parasites, presumably all females, showed similar
excitement upon the introduction of eggs of Pentatoma ligata.

No. 487] A NEW SPECIES OF TELENOMUS 208

No attempt was made to ascertain the nature of the tropism or
sense which leads to the discovery of host eggs by the adult para-
sites, but it appears that the attraction is as great for empty egg
shells of Thyanta custator as for unhatched eggs of Euschistus
servus in a suitable stage of development for successful parasitism.

When the pentatomid egg batch is found, the adult parasite
carefully examines it with her antenne. If the eggs are satisfac-
tory she sets to work industriously and oviposits in one egg after
the other. ‘The process of oviposition in a single host egg requires
from two and one quarter to three minutes. The body of the
female during this operation is held rigidly by the legs in a position
nearly perpendicular to the surface of the host egg at the point of
introduction of the ovipositor. The puncture may be made
through the egg cap or top end of the egg, or it may be through
the side of the egg. The latter is more frequently the case with
eggs located on the outside of the batch.

Before leaving the egg the female scrapes it for a few seconds
with the tip of the ovipositor, usually moving it around the point .
of insertion making a nearly complete circle, then reversing and
with a shorter radius passing around to or beyond the starting
point, then perhaps reversing again and with a still shorter radius
making a nearly complete circle. Sometimes a much more irregu-
lar figure is traced but it is always curved for the most part, and
so far as observed the direction of the movement is abruptly
reversed from one to three times. It is difficult to imagine any
useful purpose of this instinctive act except to mark the para-
sitized egg so that it can be detected as unsuitable for further
attack by parasites of its own and probably other species.

Egg laying capacity. The largest number of pentatomid eggs
positively known to have been successfully parasitized by a single
female of the species here considered is 27. ‘The total number
of eggs which a female parasite may deposit appears not to be
necessarily indicated by the number of adult parasites which may
result. In many cases it has been found that the parasite for
some reason failed to emerge even after reaching full maturity.
In other cases the larve of the parasites appear to die when quite
young, although accomplishing the destruction of the host egg.
The data at hand on the number of eggs deposited by a single
female parasite of this species are given in the following table:

424 THE AMERICAN NATURALIST [Vor. XLI

NUMBER OF PENTATOMID Eces PARASITIZED BY SINGLE SPECI-
MENS OF Telenomus ashmeadi.

No. failing to hatch or

No. of eggs ae which to produce adult para-
Date No. of eggs adult parasites i
1905 accessible were need parasitized
July 17 28 27 1
= 42 21 7
Sept. 16 127 13 34
830 13 13 0
al 10 10 0
et, ae 22 0

Developmental period of the parasite compared with the incu-
bation period of the host. The parasite requires for its complete
development about twice the normal incubation period of the
host egg at any given temperature. The following table sum-
marizes the data at hand which bear on this point:

DEVELOPMENTAL PERIOD OF PARASITES AND INCUBATION
PERIOD or Eces or THE Host SPECIES.
Incubation pe-

Developmental es daily riod of non-
period of par- ean tem- parasitized
site pe atu ost eggs

rature h
When parasitized Locality days. hrs. days. hrs.
July 17, 6 P. M. Tlahualilo, Mexico 10 23 80.2 6 i
Sept. 16, 10 A. M. Dallas, Texas 11 76. 5 n
Sept. 24, 10 A. M.-5 P. M. " eas 1 P 74. 6 —
Sept. 28-29, 4 P. M.-4 P. M. g “ 6 — -— - —
Sept. 30, 4 P. M. iy “o T 69.8 7
Sept. 30-Oct. 1, 10 A. M.-4 P. M. “ RA — Bs

In the case of the first, second and fifth records the exact time
of the beginning of oviposition is given to the nearest hour. In
the remaining records no note was made. as to the exact time at
which oviposition began. ‘The last five records, although made
at Dallas, Texas, refer to specimens of host and parasite originally
from Barstow, Texas. The short incubation period in the record
in Mexico as compared with subsequent records in Texas is prob-
ably due to the natural adaptation of the species to climatic con-
ditions within its range. The parasite seems to be equally well
adapted to its different environments inasmuch as the relation
of its developmental stages to the normal incubation period of

No. 487] A NEW SPECIES OF TELENOMUS 425

the eggs of the host species remains quite constant as shown in
the table.

Condition of host eggs necessary for successful parasitism.
In the many cases in which definite records have been made,
parasitism by Telenomus ashmeadi has been successful with the
majority of the eggs of a batch up to the time that the embryos
have gone through one half of their development. ‘The failure
to produce adult parasites from the remaining eggs in such cases
is probably due to some other factor than the developmental
condition of the host egg.

In one instance a batch of twenty-two eggs of Pentatoma ligata
deposited on the morning of September 26th was parasitized by a
female Telenomus on the morning of September 30th. ‘The normal
incubation period of the eggs of the host species at this season was
about six and one half or seven days, the embryos therefore at the
time of oviposition were slightly more than one half developed.
Twenty-one of a total of twenty-two of the bug eggs hatched in a
normal manner and the remaining egg failed to produce either a
nymph or an adult parasite. A similar experiment with the eggs
of Euschistus servus deposited four days previously and at a time
when the normal incubation period was about seven days resulted
in four eggs of a batch of ten producing adult parasites. ‘The
remaining six eggs contained parasites which failed to emerge,
perhaps as a result of an attempt to delay their emergence by
placing the egg batch for a few days in an ice box.

Changes in the appearance of parasitized eggs. During the
course of two or three days following oviposition by the parasite
the eggs of Pentatoma ligata, Pentatoma sayi, and Thyanta custator
became slightly darker, but as they are subject to a variation in
their color during normal development, parasitism cannot be
said to produce any characteristic changes in appearance up to
the time the adult parasites emerge. In the case of Euschistus
servus, however, parasitism produces a marked change in color,
since the egg membrane in this case is more translucent than with
the other species mentioned, and the young nymphs are normally
paler in color. Ten eggs of this host species were parasitized on
October Ist, beginning at 3:00 P. m. On October 5th at 9:00
p. M. it was noted that seven of the ten were very dark in color,
six being very dark gray and one slate gray; the three others had

426 THE AMERICAN NATURALIST [Vor. XLI

changed color only slightly if at all. Two days later the eggs
which had changed but little up to the time of the previous exami-
nation were as dark as the rest and indistinguishable from them
as far as appearance was concerned. Parasites developed to
maturity in each of these ten eggs and the first one was noted to
have emerged at noon on October 16th.

Development in infertile host eggs. It is the writer’s observation
that shriveling of the eggs of pentatomid bugs indicates infertility
although in some species, as in that of the Harlequin Cabbage
Bug (Murgantia histrionica), a slight shrinking normally occurs
just before hatching. With this as guide for the experiment, a
batch of ten eggs was selected, which had been deposited by a
specimen of Euschistus servus which previously had deposited a
batch of infertile eggs. Four of these eggs were reserved as con-
trols and a female parasite was given access to the remaining six;
after having made the usual examination she was observed to
begin oviposition. The four control eggs shrivelled in the course
of a few days, but the six eggs into which the parasite had ovi-
posited became dark in color and to all appearances promised to
produce adult parasites. None appeared however nor did shrink-
ing occur, and several weeks later when the eggs were opened
their contents was found to consist of a very dark colored vitelline
membrane together with a small shrivelled blackish mass on one
side, which was unrecognizable as insect remains. A similar
condition was found occasionally in parasitized eggs believed to
be fertile and belonging to a batch from which many adult para-
sites appeared. The failure to produce adult parasites from the
eggs used in the above experiment is therefore not positive evi-
dence that this was due to infertility of the host eggs. The experi-
ment shows however in a fairly conclusive manner that adult
females of the species of proctotrypid here considered will readily
parasitize infertile pentatomid eggs, and that the resulting larval
parasites will develop sufficiently to cause the host eggs to take on
the characteristic color of parasitized fertile eggs.

Parthenogenesis and its relation to sex of offspring. No absolute
proof of parthenogenetic development of the eggs of Telenomus
ashmeadi was obtained, but the contributary evidence from the
few breeding experiments undertaken furnishes a good basis for
the supposition that parthenogenetic development occurs and

No. 487] A NEW SPECIES OF TELENOMUS 427

moreover has a marked influence on the sex of the offspring. The
following diagram shows the history of the offspring of a single
female, which was one of a lot of 120 females and 19 males bred
from eggs of pentatomids collected at Barstow, September 12,
1905:

2 (probably fertilized)

E Q Q (females probably fertilized)
er 9 8 9 9 9 9 (probably not
~~ fertilized)

FERNE N RER a
122,12 41296? 205909,12 3o F

The specimens recorded in the diagram by a “ ?” escaped or
were otherwise lost so that their sex is unknown. The last genera-
tion included eighteen specimens which are not indicated in the
diagram, since they came from eggs laid before the individuals
of the preceding generation had been separated from one another.
Of these eighteen, fourteen were males, and the others escaped
before their sex had been determined. Two females bred to
maturity in the laboratory under conditions which allowed of
less doubt concerning their supposed infertility, oviposited in eggs
of Pentatoma ligata and produced 27 and 21 adult parasites respec-
tively; of these 17 and 15 respectively were males and the remain-.
der escaped before their sex was determined. To summarize: —
The offspring of the probably fertile females numbered 10 females,
1 male, and 5 undetermined; the offspring of the probably infertile
females numbered 93 males, 2 females,’ and 26 undetermined.

Proportion of sexes in nature. This subject furnishes addi--
tional and probably the strongest evidence that the fertility or
infertility of the eggs of the parasite determines to a great extent
the sex of the offspring. Sixteen females and 8 males were bred
from a batch of eggs of Pentatoma ligata collected in a cotton field at.
Tlahualilo, in July, 1905. Another batch yielded 20 females and
2 males. Pentatomid eggs collected at Barstow in the months.
of August and September, 1905, produced 125 females and 19
males. In all, of 190 adult parasites bred from pentatomid eggs.
collected in the field, 161 or 85% were females, and 15% males.

‘The writer has followed his original notes closely, although at present
inclined to doubt that the two females referred to above were actually bred
from the same egg batches with the males. Owing to their minute size and
consequent difficulties met with in handling them it seems not impossible-
that the two specimens were in some way misplaced,

428 THE AMERICAN NATURALIST [Vor. XLI -

In the laboratory, where the chances of the females becoming
fertilized were much less than in nature, the sex of 106 specimens
was determined as above stated; of these 11 % were females and
89% males.

Longevity and Food Requirements. Under laboratory condi-
tions, confined in glass tubes, pill boxes and insect cages, the adult
parasites under observation had an average life of 3.8 days. The
maximum longevity under these conditions was 8 days. The
following table shows the various records in their relation to the
season of the vear:

LONGEVITY oF ADULTS or T elenomus ashmeadi IN THE

LABORATORY.
No. of adult Approximate totai Average longevity
Period parasites .no, of days lived per specimen

uly 17-20 1 3 3

“ 28-31 19 47 2.4
Sept. 14-16 1 2 2

m OTO. A 3 12 4

N AA 3 15 5

er D H 5.9 5.5
Oct. D= ~ TƏ 38 165 4.3

An attempt to produce artificial hibernating conditions in an
ice box was unsuccessful although the adult life of each of the
25 parasites used in the experiment was very much prolonged.
When subjected to an average and only slightly varying tempera-
ture of 48.6° F., one adult lived 22 days, another 21 days, and the
remainder between 12 and 20 days. At the temperature mentioned
the adults appeared to be entirely inactive.

Adults of Telenomus ashmeadi have never been observed to
feed. Those upon which the observations recorded in this paper
were made had no access to anything that might have been used
as food except pentatomid eggs and egg shells, fragments of
more or less dried cotton leaves to which such egg batches were
attached, and dry cotton lint or cloth which was used to close the
tubes or cages in which the parasites were confined. No moisture
was accessible to any of those which were used in the breeding
experiments. In biting the exit holes from the host eggs the
fragments of the egg shells are not eaten by the parasites. The
evidence indicates that the parasites are sufficiently nourished

No. 487] A NEW SPECIES OF TELENOMUS 429

during their larval existence to require no food for carrying on,
at least to a certain extent, their reproductive functions. It is
not unlikely, however, that their longevity and reproductive
capacity is increased by such food as they might obtain under
natural conditions.

SUMMARY AND CONCLUSIONS.

1. A species of the proctotrypid genus Telenomus, believed
to be new, is described under the name Telenomus ashmeadi.

2. The species, although originally bred from the eggs of
pentatomid bugs of the genus Pentatoma, readily attacks the eggs
of species of the genera Thyanta and Euschistus and such eggs
ordinarily produce adult parasites differing in size from the parent
in direct correspondence with the size of the host eggs.

3. The developing parasite invariably occupies a fixed position
in relation to the embryo of the host, and emerges from the egg
through the end from which the bug nymph normally hatches.

4. Adult female parasites are capable of detecting the presence
of pentatomid eggs at some distance; four specimens were as
strongly attracted by empty egg shells as by the unhatched eggs
suitable for parasitizing.

. Between two and three minutes are required for oviposition,
after which the surface of the host egg is marked by the ovipositor
in a characteristic manner, presumably for aiding in its subse-
quent detection as unsuitable for attack by other parasites.

. The maximum number of pentatomid eggs known to have
been successfully parasitized by a single specimen of Telenomus
ashmeadi is 27; but there is evidence that this number may be
greatly exceeded.

The entire developmental period of the proctotrypid para-
site here considered is approximately twice the normal incubation
period of the eggs of the host species, in Texas and northern
Mexico during the summer months of 1905 varying approximately
from 11 to 15 days.

8. Pentatomid eggs may be parasitized successfully by Tele-
nomus ashmeadi up to the time that the host embryos have passed
through one half of their incubation period. After this time the
results are uncertain.

430 THE AMERICAN NATURALIST [Vor. XLI

9. Pentatomid eggs with translucent membranes containing
developing nymphs of a pale color undergo a characteristic darken-
ing as a result of the parasitism. Other eggs with more opaque
membranes and dark colored developing nymphs do not exhibit
characteristic changes in external appearance.

Females of Telenomus ashmeadi show no hesitation in
ovipositing in infertile pentatomid eggs, and such eggs when
parasitized do not show the shrinkage which is usual in infertile
eggs. In the case of Euschistus servus they undergo the changes
in color characteristic of the parasitized fertile eggs of this species.
Although no adults have thus far been bred from parasitized in-
fertile eggs, the development of the parasite is at least partial, and
the observations here recorded furnish only slight evidence that
complete development in infertile host eggs is impossible.

11. Sex of the offspring seems to be controlled to a great extent,
if not absolutely, by fertilization. In nature where the chance
for a female parent to be fertilized is at a maximum the female
sex greatly predominates, whereas under laboratory conditions
which artificially reduce the chances for mating of the adults,
the male sex predominates in an even greater proportion.

12. In confinement in the laboratory, adult life under ordinary
temperature conditions lasts but a few days. The maximum
period recorded during the month of July is three days, during
September four days, and during October eight days.

13. The adults of Telenomus ashmeadi have not been observed
to feed and apparently this is not necessary for carrying on repro-
ductive functions.

WASHINGTON, D. C.

BIBLIOGRAPHY.
AsuMeap, W. H.
893. A monograph of the North American Proctotrypidæ. U. 8.
Nat. re bull. 45.

Morgan, H
1897. as of the entomologist. Louisiana Agric. Exp. Station
bull. 48.

MORRILL, A.W.
& 1907. The Mexican conchuela in western Texas in 1905. U.S. Dep.

of Agric., Bur. of Ent., bull. 64, pt. 1.

THE DEVELOPMENT OF PINNATE LEAVES
FREDERIC T. LEWIS

BETWEEN 1837 and 1861 the development of leaves occasioned
a lively controversy among botanists. Schleiden’s school main-
tained that a leaf grows at its base,— not at its tip, and that this
is the fundamental distinction between leaf and branch. Basal
growth was demonstrated by painting the outer half of a young
leaf and observing the diminishing proportion of the painted area
as the leaf grew; it was also observed that many actively growing
leaves of monocotyledons were dead and withered at their distal
ends. The leaflets of compound leaves were thought to arise at
the base and to be pushed outward so that the stipules and basal
leaflets of the mature leaf were the last of all parts to appear. Con-
trary to all this Nägeli declared that the stipules are formed first,
and that lateral leaflets are cut off from the terminal leaflet so that
the apical lateral leaflets are the youngest. Since the basal part
of the leaf forms first and grows longest it becomes the broadest
part, but the growing tip remains slender. In 1861 Eichler intro-
duced his thorough study of leaf development with the statement,
“The nature and development of leaves have been a subject of
controversy among botanists until recent times, and the issue is
still undecided.” Since then, however, the attention of investi-
gators has been directed chiefly to newer problems, and the subject
remains about as Eichler left it. Ten years ago, quite unaware of
this controversy, the writer gathered and sketched a selection of
mature rose, blackberry, and sumac leaves which presented the
problem in very clear terms. In the present paper some of these
leaves are to be described, after which the embryological inter-
pretation of their peculiarities will be considered, and finally their
evolutionary significance will be noted. |

Mature Leaves.— The group of rose leaves (Fig. 1) was gathered
from different bushes and from various parts of the stem. Although
they all probably came from Rosa lucida Ehrh., other species of
wild rose may be included. The arrangement of the leaves is

431

432 THE AMERICAN NATURALIST [Vor. XLI

purely arbitrary, but it indicates a possible mode of development.
The lower pair of leaflets in b is close to the stipules; in ¢ and d
the length of petiole separating them from the stipules is succes-
sively greater. In e one stipule is enlarged and leaf-like at its tip,
having a coarsely serrate upper margin and containing a mid-rib;
in f there is a complete leaflet close to the stipule. @, h and t
show an imperfeetly developed pair of leaflets in relation with the
stipules. J and k have a perfect pair close to the stipules, and in
l and m this third pair is more distally placed since the petiole is
longer. Thus the series suggests that the third pair of leaflets
is developed from the outer portion of the stipules. Forms show-
ing the similar addition of a fourth pair of leaflets may easily be
obtained, together with those which present the first and second
pairs in relation with the stipules. In the leaf a there is an un-
paired fourth leaflet on the right, but the stipule on the left is
distinctly longer than its mate.

From the examination of mature rose leaves it appears, there-
fore, that leaflets are added from the stipules. It would be in-
ferred that the basal leaflets are the last to develop, but that the
stipules arise before the first pair of lateral leaflets. In the rose
neither the terminal nor the basal leaflets show lobation or other
evidence of leaflet production.

In the “high-bush” blackberry, Rubus sp.?, there is a different
process of leaflet formation as shown in Figure 2. A is a simple
leaf with stipules. In b, c, and d, by the lobation of the basal
portion of the leaf blade, the first pair of leaflets is produced. ‘The
stipules are not involved in their formation. In e, f, g and h, a
second pair of leaflets appears by the lobation of the basal leaflets.
Thus the mature blackberry leaves suggest that leaflets arise, not
from the stipules, but from the basal leaflets.

The sumac, Rhus copallina L., presents a third type as seen in
Figure 3. The leaf a has five pairs of leaflets together with an
undivided terminal leaflet; b, c, and d also have five pairs, but the
terminal leaflet is lobed or divided and suggests the origin of the
sixth pair of leaflets shown in e. In the sumac the addition of
new leaflets is from the terminal leaflet, and never from the basal
as in the blackberry. There are no stipules.

Leaves of the sumac type are generally called basijugal (Goebel

433

THE DEVELOPMENT OF LEAVES

No. 487]

434 THE AMERICAN NATURALIST Vor. XLI

prefers akropetal). Nägeli who believed that all leaves grew
near their apices, studied particularly the leaf development in
Aralia spinosa L. which is of the basifugal type.* At the distal
ends of its chief subdivisions there are lobed leaflets like those of
the sumac. Steinheil’ who believed that leaf-growth was generally
basal, considered that compound leaves were an exception in that
their outermost leaflets were the youngest.. Trécul? recognized
both the basifugal type of compound leaf and the basipetal which
would include both the blackberry and rose. He distinguished
also a mixed and a parallel type. ‘These are discussed and rear-
ranged by Eichler‘ (pp. 16-21). In addition to basifugal and
basipetal he recognizes six types, namely divergent, convergent,
simultaneous, ternary, cyclical, and parallel (but the last is not
in Trécul’s sense). In the divergent form, the leaflets develop
from the center toward both ends of the leaf; in convergent leaves
they develop from both ends toward the center; and in the simul-
taneous type all the leaflets arise at one time. When a single
leaflet divides to make three, the distinction between basifugal
and basipetal can scarcely be made since the next pair of leaflets
may arise from the terminal leaflet as in the sumac, or from
the basal leaflets as in the blackberry; but these ternary leaves are
usually counted as basipetal. Cyclical leaves may be either basi-
petal or basifugal; the two lateral basal portions of the blade
become connected around the petiole in peltate form, as in Ricinus,
Lupinus and others. In the parallel type, on both sides of the
median line vertical divisions arise, parallel with the periphery
of the leaf. This occurs in Foeniculum and others. In the paral-
lel form the divisions may be basipetal or basifugal. Eichler states
(p. 18) that “Other developmental types have never been observed
either by me or by earlier investigators; but considering the mani-
fold forms of leaf development doubtless other types exist.”

1 Nägeli, C. Wachsthumsgeschichte des Blattes von Aralia spinosa Lin.
Pflanzenphysiologische Untersuchungen, Heft 1, Zürich, 1855.

2 Steinheil, Ad. Observations sur le mode d’accroissement des feuilles.
Ann. des gs Nat., Partie Bot., 1837, ser. 2, vol. 8, pp. 257-307.

3 Trécul, Mänoire sur la gg des feuilles. Ann. des Sci. Nat
Partie Bot., oie ser. 3, vol. 20, pp. 2 4,

* Eichler, A. W. Zur en ET des Blattes. Marburg,

1861, 60 pp.

No. 487] THE DEVELOPMENT OF LEAVES 435

In Eichler’s tables Rhus typhina is with the basifugal leaves;
“Rosa canina, tomentosa, arvensis, etc.” are with the basipetal.

Fic. 2.— Leaves of the high bush blackberry, Rubus sp.? 4 natural size.

Rubus is not included, but the similar Potentilla is classed with
the rose. Goebel! likewise places “all digitate leaves” with the

1 Goebel, K. Organographie der Pflanzen, Part 2, Heft 2, Jena, 1900.

436 THE AMERICAN NATURALIST [Vor. XLI

rose and calls them basipetal (p. 525). There are two serious
objections to grouping the rose leaf with that of the blackberry or
potentilla. Neither the terminal nor the basal leaflets of the rose
are ever lobed to produce new leaflets as in the blackberry; and
in the blackberry the stipules are not involved in leaflet production
as in the rose. If the term basipetal is to be retained for the
blackberry and potentilla type, the leaf formation in the rose may
be described as stipular.

Embryonic Leaves.— The interpretation of series of leaves such
as those shown in Figures 1-3 depends upon the study of their em-
bryonic development, for they are mature leaves and can never add
to their lobes or leaflets. The number of these parts is determined
before the leaf expands.

According to Eichler (loc. cit.) a leaf may begin in two ways.
In some cases, immediately below the tip of the axis, there arises
simultaneously in all its parts, a wall-like proliferation of cambial
tissue corresponding to the entire insertion of the future leaf to-
gether with its stipules, if it is to have any. In other cases, beneath
the growing tip of the axis a low papilla or conical proliferation
appears, which quickly spreads laterally so that more and more
of the circumference of the stem is involved in the leaf formation.
This spreading ends before the leaf begins to be subdivided into
lobes. In one of these two ways the primordial leaf is formed,
from which (and never from the stem) all parts of the mature leaf
develop. They are not pushed out from the stem. ‘The pri-
mordial leaf forms from the stem; after that, all growth of the
leaf is only an elaboration of the primordial leaf.

After its formation, the primordial leaf begins to differentiate a.
stationary basal zone, which is concerned only with the formation
of stipules, and a vegetative outer zone which produces the petiole
and blade. Petiole formation always follows blade formation;
the expansion is at least indicated before the stalk begins. In
palmate and pinnate leaves all of the main subdivisions are gener-
ally mapped out before the appearance of the petiole. The mid-rib
may be present before the blade expands, as is true especially of
simple, feather-veined leaves and some compound, pinnate forms;
or the expansion of the blade is primary and the formation of the
chief veins secondary, as in many three-parted, pinnate, and.
palmate leaves.

438 THE AMERICAN NATURALIST [Vor. XLI

The development of a leaf to this point is characterized by seg-
mentation of its parts, accompanied by relatively little increase
in volume. This is its embryonie stage. It is followed by the
stage of expansion in which there is a great increase in volume
without the addition of lobes or leaflets. The recognition of these
two fundamental stages in leaf development is essential in inter-
preting mature leaves.

The embryonic development of the rose leaf is shown in Figure
4 a, b, and c. A is from Sir John Lubbock’s drawing of the
growing point, with side views of two primordial leaves in succes-
sive stages of development. He states’ that the leaf “commences
as a small knob at the side of, and immediately below the growing-
point. When this knob has reached a certain length it presents
two lobes (as on the left of the drawing). .... The lower lobe is
one of the stipules, which according to Schacht appear M..
The stipule appears almost simultaneously with the first and
upper leaflet, before any of the lower and later ones. ‘These
originate close above the stipules.” On the right of Figure 4 a,
the leaf presents lower lobes for the stipules, middle lobes for a
pair of leaflets, and an upper lobe for the terminal leaflet. If
by an arrest of development the stage of expansion should begin’
at this time, we should expect such a mature leaf as in Fig. 4 d.
Expansion at the younger stage shown in a would produce a leaf
like e; and at a still earlier stage, when the primordial leaf was
but slightly indented, the stipules and blade would be scarcely
separable, as in f.

Later stages in the embryonic development of the rose leaf are
presented in b and c, after Trecul. They show the addition of
the second and third pairs of leaflets respectively. It may be
noted that in Eichler’s opinion Trécul was misled by the early
large size of the stipules into believing that they formed before
the leaflets. Eichler finds that in various types of leaves the
stipules may arise either as the first or the last of the primary
divisions of the leaf blade, or at some intermediate time. In the
rose they form last (loe. cit. pp. 26-27). If this were true, however,
one might expect to find certain mature leaves without stipules,
but such do not occur. The fact that if a mature leaf shows only

1 Lubbock, J. On Buds and Stipules. London, 1899, 233 pp.

No. 487] THE DEVELOPMENT OF LEAVES 439

two divisions they will be terminal leaflet and stipules is in har-
mony with the early origin of the stipules as stated by Trecul and
Lubbock.

The embryology of a basifugal leaf is shown in Fig. 4 g. Since
drawings of the sumac are not available, Trécul’s figure of Gledit-
schia ferox has been substituted. The youngest leaf, l’, is without
lobes; in the older leaf, /”, the stipules (s) have appeared; and in
the oldest leaf a succession of leaflets is forming from the base

g h i 3

Fig, 4.— Embryonic leaves, and mature sang showing an arrest of re
development. a,b, ande, embryonic ro rey ves, a after Lubbock, band
after Trecul. d, e, and fî, mature rose lea g, embryonic eaves. of Godik:
schia ferox, after Trécul. A,i, and j, ea leaves of Gleditschia
The embryonic leaves are ‘considerably magnified; the mature eig are
reduced,

toward the apex (the lowest leaflet is marked U). An arrest of
development at this stage may produce such a leaf as h. The
forms i and j may be compared with Į”. In mature leaves of
Gleditschia triacanthos the stipules, if retained, are very small
and they do not appear in those figured

From the consideration of the embryology of rose and honey
locust leaves it appears that the developmental history may be

440 THE AMERICAN NATURALIST [Vor. XLI

approximately inferred from the variations in mature leaves.
The study of the mature leaves is therefore significant, but it ought
to be confirmed by embryological examinations.

Evolutionary Significance A knowledge of leaf development
is of great importance to the paleontologist, and in a paper entitled
“Localized Stages in Development in Plants and Animals” J ack-
son presents a study of mature leaves from a geological and evolu-
tionary point of view.’ His conclusions are stated to be in the
direct line and the natural outcome of Hyatt’s principles of develop-
ment. Professor Jackson’s work upon leaves was continued by
Cushman who published three papers on localized stages in this
journal? The leaves at either end of a branch which terminates.
in a flower are’well known to be simpler than those along its mid-
dle portion. Simple leaves are expected near the bud scales,
the sepals, and the cotyledons. St. Hilaire (quoted by Trécul)
sought to explain this arrangement by nutritive conditions; the
simple leaves in the young plant or near the flower are due to weak-
ness and exhaustion. In full vigor leaves tend to become com-
pound, and there are some instances in which cultivation in rich
soil has favored the production of compound leaves. This expla-
nation is not satisfactory, however, and Jackson proposes another.
The early leaves are said to represent the adult types of ancestral
forms; and the successive leaves between the cotyledons and the
most complex forms which the plant produces record the evolu-
tionary history of the species. The simplification of leaves toward
the flower is considered a senile repetition, in reverse order, of the
developmental series. In localized parts of the adult, as at the
base of vigorous shoots, stages of leaf development may be found
similar to those of young plants; their equivalents are to be sought
in the adults of ancestral groups.

The nature of ancestral forms is for the geologist to decide; it

1 Jackson, R. T. Localized Stages in Development in Plants and Animals.
Mem. of the Boston Soc. of Nat. Hist., 1899, vol. 5, no. 4, pp. 89-1

2 Cushman, J. A. Studies of Localized Stages of Growth in Some Common
New England Plants. Amer. Nat., 1902, vol. 36, pp. 865-885.

Studies of Localized Stages in Some Plants of the Botanic Gardens of Har-
vard University. Amer. Nat., 1903, vol. 37, pp. 243-259.

Localized Stages in Common Roadside Plants. Amer. Nat., 1904, vol. 38,
pp. 819-832.

No. 487] THE DEVELOPMENT OF LEAVES 441

is generally assumed that their leaves were simpler in outline than
those of existing species. If, however, it is true that the plant is
recording its history in producing these simpler leaves, the reason
why they occur in.the places named remains as much a mystery
as ever. The plant just before producing a flower can scarcely
be regarded as weak, exhausted, or senile. The embryologist is
content to find that the diverse forms of mature leaves arise from
papillae which become characteristically lobed and molded before
they expand. If expansion occurs before the modelling is com-
plete, a simple form of leaf results. A more accurate account
of the development of the papillae in various plants ought, however,
to be obtained.

SUMMARY.

Certain features of leaf development which were established
some fifty years ago, should not be overlooked. These are pri-
marily the basipetal and basifugal types of growth, which may be
verified by collecting mature leaves, and which can profitably
be taught to students of elementary botany.

Among the basipetal leaves of the earlier writers there are two
radically different types, represented by the rose and blackberry
respectively. The rose should be separated from this class and
its leaf development may be described as stipular. Mature leaves
indicate that the rose stipules are formed before the lateral leaf-
lets, as observed by Trécul and Lubbock but denied by Eichler.

The formation of relatively simple leaves in plants which bear
lobed or compound forms may be described embryologically, as
an arrest of development in the primordial leaf followed by a stage
of expansion, or by expansion before the embryological stage has
been completed. Rapidity of growth may account for the con-
stant location of the simpler leaves near the cotyledons, bud scales
and sepals.

CAMBRIDGE, Mass.

CONTRIBUTIONS TO THE PLEISTOCENE FLORA
OF CANADA

D. P. PENHALLOW

EARLY in the present year I received from Professor A. P. Cole-
man of Toronto University, a very fine collection of leaves from
the Interglacial deposits of the Don Valley, Toronto. With them
there was one small but rather well preserved fragment of a woody
branch which it was possible to identify with accuracy. "These
specimens prove to be important since they serve to confirm in
rather striking ways, conclusions already reached through previous
studies of the Don material, and they furthermore afford addi-
tional evidence bearing upon the preglacial existence of types
now unknown in the living state. It is therefore thought desirable
to place on record such facts as are revealed by a study of this
collection.

The last previous record of the Don plants was made by me in
1904 (’04) when thirteen species were passed in review. Since
then both Berry (06) and Hollick (06) have added to our knowl-
edge of the Pleistocene of Virginia and Maryland, and the evidence
they bring forward goes to show that essentially the same flora
characterized the entire region between Virginia and Ontario. in
Pleistocene time. The following species are included in the
present studies :—

Acer pleistocenicum Penh.— This species appears for the fourth
time in collections from the Don Valley, and in the present instance
it forms a large percentage of the entire material. Most of the
specimens are in fragments, but one or two are nearly perfect.
One of the best of these is reproduced here on a diminished scale
(Fig. 1), as it is more complete than that employed for the original
description (790, 327).

In the last enumeration of Canadian Pleistocene plants (’04, 72),
attention was directed to the very close resemblance between Acer
pleistocenicum Penh., and A. lesquereuxii Knowlton (’98) and the
opinion was then expressed that the two are undoubtedly the

443

444 THE AMERICAN NATURALIST [Vor. XLI

same. With the possibilities arising from more extended com-
parison of material representing a wider range of variations, the
conviction becomes stronger that the opinion so stated is a tenable
one.

Acer torontoniensis n. sp.— The Don collection embraces a
number of specimens, some of them fairly perfect, representing
_ a species of maple altogether unknown, either in the fossil or the
living state. ‘This leaf appears to present two principal variations
which depend in part upon the relative depths of the principal
sinuses and the character of the minor lobes or teeth, but chiefly
upon the fact that in one form the base of the leaf is only slightly
if at all lobed, while in the other case two large lobes extend down-
ward from the insertion of the blade on the petiole and enclose
the latter. Two principal veins extend from the base of the mid-
rib to the corresponding principal lobes, and two subordinate veins
of varying prominence extend diagonally downward from near
the same point, into the two minor and variable lobes which form
the base of the leaf blade. From this description, as also from
the two specimens shown in Fig. 2 it will be seen that this leaf
belongs to the same group with our common hard maples. Com-
parison with these latter also shows that its nearest representative
among existing species is the common rock or sugar maple, Acer
saccharinum Wang. Comparing the upper fossil of Fig. 2 with
one of the more ordinary types of leaf of the sugar maple, it appears
that the chief points of difference are to be found in the form of
the sinuses and in the character of the large teeth or smaller lobes.
If again we compare the lower fossil leaf in Fig. 2 with the cor-
responding type of leaf of the sugar maple, the resemblance be-
comes much stronger by reason of the similar basal lobes, which
have unfortunately been much broken away in the fossil. "The
differences noted are such as might well result from changes inci-
dent to natural development, whereby the more simple tends in
the direetion of the more compound, and when to this there are
joined the actual resemblances, they suggest a very intimate rela-
tion between the existing sugar maple and the fossil, of such a
character as to indicate that the latter may be the ancestral form
of the former.

A comparison of leaves of the sugar maple with those of the

No. 487] PLEISTOCENE FLORA OF CANADA 445

Norway maple will show that although they differ materially with
respect to venation, they resemble one another in a very remark-
able manner as to the form of the sinuses and the detailed con-
figuration of the lobes. ‘These resemblances between two such
well defined species, are precisely of the same order as those which
are recognized in a comparison of the fossil with the sugar maple.
It therefore becomes obvious that in the absence of flowers and
fruit, it is not possible to effect a satisfactory specific differentiation

Fig. 1. Acer pleistocenicum Penh. X 0.55.

on the basis of leaf form only, but upon this basis the form now
under discussion must be regarded as altogether different from
any previously recognized fossil or recent species. ‘The diagnosis
of this leaf may be stated as follows:—

Leaves strongly and palmately veined; two principal veins aris-
ing at the base of the midrib and traversing the principal lobes;
two inferior veins of varying prominence arising from near the
same position but extending diagonally downward into the inferior
lobes. Leaves three to five lobed; the two basal lobes variable,

446 THE AMERICAN NATURALIST [Vor. XL}

sometimes small and inconspicuous, or prominent and extending
downward so as to enclose the petiole as in Acer saccharinum
Wang.; the sinuses broad and shallow; the terminal lobe with
two large, lateral teeth; the lateral lobes with one or two large
teeth on the lower side; the teeth acute, rarely somewhat acumi-
nate toward the summit.

Hollick (06, 234) has recently observed the occurrence of maple
fruits in the Pleistocene of Maryland, but it is at present impos-
sible to connect them definitely with any of the recognized leaves
or wood so far studied.

Carya alba Nutt.— Although never abundant, the leaves of the
hickory have been noted in three former collections from the Don.
Their form and venation are so characteristic as to leave little
room for doubt as to their true character.

Hollick (06, 221, 222) now records the occurrence of three
species, one from the Talbot and two from the Sunderland For-
mation of Maryland. Only one of these is specifically recogniz-
able, and to this the name Hicoria pseudo-glabra, Hollick, is
assigned.

Cercis canadensis L.— The red-bud, an altogether new constitu-
ent of the Don flora, is represented in the present collection by a
few leaf fragments which are nevertheless sufficient to establish
the identity of the species.

Cyperus sp.— Fragments of jointed stems showing a finely
- striated surface are referable to the genus Cyperus without specific
differentiation. Such fragments are of common occurrence in
material from the Pleistocene, and they possess little or no signi-
ficance with respect to a knowledge of climatic conditions.

Gleditschia donensis n. sp.— One or two leaflets are clearly
comparable with those of the genus Gleditschia to which they are
referred under the name of G. donensis.

The genus is at present represented in North America by two.
species (’02, 76) of which the common three-thorned acacia, G.
triacanthos, seems to be more nearly related to the fossil, and
presents the closer resemblance with respect to geographical loca-
tion.

Maclura aurantiaca Nutt.— One imperfect leaf is referable to
the osage orange. Although not now growing in the same region,

No. 487] PLEISTOCENE FLORA OF CANADA 447

this species has been recorded on previous occasions as occurring
in the Don deposits of which it is a recognized feature.

Picea nigra Link.— This species is a constant constituent of the
Don flora and has been recognized in nearly all previous collec-

Fig. 2. Acer torontoniensis n. sp. X 0.55.

tions. As now, it is always represented by fragments of wood,
usually small branches in a more or less altered condition.
Ostrya virginica Willd.— Although not recorded as embraced in

448 THE AMERICAN NATURALIST [Vor. XLI

any previous collection from the Don, the leaves contained in the
present one are sufficiently characteristic to make the determin-
ation reliable. :

Platanus occidentalis L.— One small and imperfect leaf shows
the characteristic venation of the sycamore. Although not often
represented, this tree has nevertheless been found in a previous
collection representing two localities, and it is a recognized con-
stituent of the Don flora.

Hollick (’06, 231, 232) has shown the occurrence of P. aceroides
Goepp., together with another large leaved but unnamed species,
in the Sunderland Formation of Maryland.

Populus grandidentata Michx.— This well known but sparingly
represented species is a well recognized element of the Don flora,
and it once more appears in the present collection.

Prunus sp.— The genus is represented in the present instance by
a single drupe of an oblong form. A similar but somewhat shorter
fruit has been found on one previous occasion.

Quercus alba L.— The white oak is represented in the present
collection by fragmented but well characterized leaves. ‘This
species has been observed previously in only one collection. The
specimens obtained from Gaol Hill were so imperfect as to make
the determination open to some question, but the present material
is sufficiently perfect to remove all doubt.

Other oak leaves are also embraced in the 1906 collection, but
the fragments are too incomplete to justify reference to a particu-
lar species. It is quite probable that they may represent the
white oak, but this cannot be stated with any degree of certainty
since the Don flora embraces no less than seven recognized species,
any one of which they may be.

Under the name of Quercus pseudo-alba, Hollick (06, 227)
describes an oak from the Sunderland Formation of Maryland. .
The leaves which he figures bear a very close resemblance to those
from the Don, and it is not unlikely that they may be the same,
but a close comparison of more perfect specimens should be made
before final decision is reached.

Robinia pseudacacia L.— A few. leaflets of the common locust
are found in the present collection. ‘This species appears to be
rather sparingly represented in the Don flora, since this is only
the second time it has been found.

No. 487] PLEISTOCENE FLORA OF CANADA 449

According to Hollick (’06, 234) this species occurs in the Talbot
Formation of Maryland, and the leaflets figured by him are iden-
tical with those from the Don.

Tilia americana L.— The exceedingly well characterized leaves
of the common linden or basswood, occur in the present collection
in rather large numbers, some of them being fairly perfect. ‘The
species is sparingly represented in the Don Pleistocene, since it
has been recognized in only one other collection.

A recent note by E. W. Berry, (’07, 80) directs attention to the
occurrence of either T. americana or T. heterophylla in the Pleisto-
cene clays at Fish House, New Jersey. ‘The imperfect condition
of the fossils makes it impossible to determine their correlation
with one of the existing species, and in this emergency the specific
name T. dubium originally assigned by Newberry to the leaves,
is now retained but transferred from the. genus Tilliephyllum,
and the citation therefore becomes Tilia dubia (Newb.) Berry.

Ulmus americana L.— The common American or white elm
has been identified on former occasions as a prominent constituent
of the Don flora, and it is once more represented in the present
collection from the same locality.

Lesquereux (’83, pl. LIV, f. 10) has figured under the name of
U. pseudo-americana, a specimen from the John Day Basin of
Oregon (Upper Miocene) which very closely resembles the exist-
ing species and may well be regarded as its progenitor.

In a report upon Tertiary plants from the region of the Interna-
tional Boundary in British Columbia, collected by Prof. R. A. Daly
in connection with the International Boundary Commission, and
now in course of publication, certain elms are described on the
basis of their wood structure, and it is seen that they differ but
little from some existing species. Among them there is one
which differs from the wood of the white elm to about the same
extent that the leaf of U. speciosa Newb. differs from its more
modern representative, U. americana. In a collection of woods
from the Pleistocene of Elmira, N. Y., now being studied, either
this or a closely related species is found, and the evidence there-
fore tends to show that Ulmus americana may be definitely traced
back into Miocene time.

Ulmus pseudo-racemosa Hollick, has been found by Hollick
in the Sunderland Formation of Maryland (06, 228), and this

450 THE AMERICAN NATURALIST [Vor. XLI

gives one more proof of the wide extension of the same flora,
since the Elmira woods contain an elm which will be designated
as U. proto-racemosa.

BIOLOGICAL CONSIDERATIONS

The present determinations lend emphasis to previous conclu-
sions respecting the character of the Dcn- flora, its relation to
existing vegetation in the same region, and its indications of the
existence of a climate warmer than at present and comparable
with that of the middle and southern United States.

With four exceptions, Ostrya, Gleditschia, Cercis and Acer
torontoniensis, the flora indicated by the present studies is identical
with that previously determined to be characteristic of the Don
Period or Warm Climate Period of the Pleistocene. But an
examination of these four new elements, shows that they also,
are quite consistent factors in the warm climate flora.

Gleditschia triacanthos L. which is undoubtedly the nearest living
representative of the fossil, finds its northern limit of distribution
according to Macoun (’83), in Ontario, and it occurs on the sand
dunes of Pelee Point to which the seeds appear to have been carried
across the Lake from Ohio. But according to Sargent (’02, III,
75) this species appears on the western slope of the Alleghany
Mountains whence it extends westward as far as longitude 96°, and
southward to Alabama, Mississippi and the Brazos River in Texas,
from which it would appear that it is distinctly characteristic of a
climate warmer than that now known in the region’ of ‘Toronto,
and comparable with that of the Don Period in Pleistocene time.

Cercis canadensis is practically unknown in Canada, although
Britton (’97, II, 257) records it as occurring in southern Ontario.
Sargent on the other hand (’02, III) gives its northern limit as New
Jersey, whence it extends southward to Tampa Bay and westward
to the Brazos River in Texas. The evidence which it affords of a
warm climate is even more conclusive than in the previous case.

Ostrya virginica ranges from Cape Breton westward through
the Valley of the St. Lawrence to Lake of the Woods and Rat
Portage, northern Minnesota and the Black Hills of Dakota, and
southward to northern Florida and eastern Texas. Although
the tree is very common throughout all this region, Sargent (02,

No. 487] PLEISTOCEHE FLORA OF CANADA 451

IX, 35) states that it is most abundant and of largest size in south-
ern Arkansas and adjacent parts of Texas. It is therefore evi-
dent that in spite of its wide distribution and high northern range,
it is essentially a southern type, and the evidence it affords is
therefore in direct accord with that offered by those other repre-
sentatives of the Don flora now recognized for the first time.

With respect to Acer pleistocenicum, very little of a definite
character can be said since we know nothing of it except through
its occurrence in the Don clays; but its very definite association
with a warm climate flora leads to the conclusion that it also
must bear the same relations to meteorological conditions, and
that it must of necessity be a southern type.

Acer torontoniensis is similarly unknown beyond the Don clays,
but the same evidence which applies to A. pleistocenieum must
lead to similar conclusions with respect to its climatic relations.
If this species is to be regarded as the actual progenitor of the
sugar maple, it is perhaps somewhat difficult to explain satis-
factorily how a southern type, or at least a type with a far southern
extension, can have become so altered as to constitute an exclu-
sively northern type, since the converse would be susceptible of a
more ready explanation. If on the contrary, this be regarded
as a distinct species with adaptation to a more southern climate,
it becomes quite easy to understand how it was obliterated from
the Toronto region by the southward movement of the ice sheet,
in precisely the same manner that other species were driven out
of the same area and ultimately confined to more southern localities.

The present studies serve to give renewed emphasis to the idea
which has now passed beyond the limits of a working hypothesis,
that successive northerly and southerly movements of the con-
tinental ice sheet, involving corresponding movements in vegeta-
tion, were productive not merely of plant migrations from north
to south and vice versa, but that they established conditions which
permanently “eliminated those species which, we may suppose,
occupied a somewhat unstable position in the flora and were there-
fore susceptible to a relatively slight change of surroundings.
This conception is in exact accord with the present status of the
genus Sequoia which, from a very wide distribution extending
over the entire northern half of the continent as far as Alaska and
Greenland, has become restricted to a very limited area on the

452 THE AMERICAN NATURALIST [Vor. XLI

western slopes of the Sierra Nevada Mountains where, according
to Gray (’89, II, 147) the two species now occupy an unstable
position of such character that “a little further drying of the
climate would precipitate their doom.”

The evidence afforded by the Pleistocene clays of Toronto is
therefore in accord, in this respect, with that furnished by certain
Pleistocene deposits at Elmira, New York, and by the conclusions
elsewhere stated with respect to the recession of Sequoia, Taxo-
dium, and probably also Pseudotsuga, from the present Great
Plains region of Saskatchewan and Alberta (’04, 64-65).

McGILL UNIVERSITY
MONTREAL

LITERATURE.
Berry, Epwarp W.
06. Pleistocene Plants from Virginia. Torreya, VI, 1906. pp. 88-90.
07. A Tilia from the New Jersey Pleistocene. Torreya, VII, 1907.
p- 80.
Britton, N. L. Aanb Brown, A.
’97. Flora of the Northern States and Canada. II, 1897.
Gray, ASA
89. Baqada and Its History. Scientific Papers, II, 1889.
HOLLICK, ARTHUR
’06 Hyktehhatie Paleontology of the Pleistocene Deposits of
Maryland.
Cont. from the N. Y. Bot. Gard., No. 85, 1906. pp. 217-237,
Pl. LXVII-LXXV.
Knowrron, F. H.
’98. Catalogue of the Cretaceous and Tertiary Plants of North America.
U. S. Geol. Surv., Bull. 152, 1898.
LESQUEREUX, LEO.
’83. Cretaceous and Tertiary Flora of the United States. U. S. Geol.
Surv. of the Terr. VIII, 1883. Pl. LIV, f. 10.
Macoun, JoHN.
’83. Catalogue of Canadian Plants. Geol. Surv. Can., 1883.
PrENHALLOW, D
’90. The Pleistocene Flora of Canada. Bull. Geol. Soc. Amer., I,
1890. p. 327.
’04. Notes on Tertiary Plants. Trans. R. S. C., X, iv, 1904. pp. 57-

SARGENT, C. S.
’02. Silva of North America. III & IX. 1902.

THE SIGNIFICANT RESULTS OF A DECADE’S
STUDY OF THE TUNICATA

WILLIAM E. RITTER

In any mass of detailed knowledge of organic phenomena, there
is sure to be something of general significance for philosophical
biology. Under the guidance of this principle I have tried to
skim the cream from the results of the last ten years’ researches
“ on the Tunicata. These skimmings I present under the follow-
ing captions:— 1, Taxonomy and Affinities; 2, Distribution; 3,
Morphology; 4, Embryology; 5, Physiology.

1. Taxonomy and Affinities.— There are several questions of
general interest that naturally arise under this head. ‘The Tuni-
cata being a comparatively small class of animals, does the prog-
ress made in getting hold of he new kinds indicate that we are
approaching completeness in this direction? ‘The class being as
thoroughly pelagic at one extreme of its habitat, as thoroughly
littoral at another, and as thoroughly abyssal at still another as
any class of animals, what is being revealed as to the dependence
of number of kinds upon environment? Is the progress of knowl-
edge bringing out anything conclusive as to the greater success of
certain types of organization over others because of better adapta-
tion to environment?

Herdman’s “Revised Classification of the Tunicata,” published
in 1891, contains a total of 538 species. This list supposedly
includes all the species known at that time. By a reasonably
careful enumeration, those described since that year number 521,
making a total of 1069 species now known. The better explored
portions of the sea, such as the Atlantic about the British Islands,
the coasts of Continental Europe, and the Mediterannean, have
yielded very few of the new ones, probably not more than half a
dozen. The regions that have contributed most are the Australian
waters (Herdman and Sluiter); the seas traversed by the Siboga
Expedition (Sluiter); the Ceylon region (Herdman); the southern
South American region (Michelsen); the Japanese coasts (Oka
and Hartmeyer); the Pacific North American region (Ritter);

453

454 THE AMERICAN NATURALIST [Vor. XLI

the west African coast (Sluiter); the Arctic (Hartmeyer); the
Antarctic (Sluiter and Herdman); the western tropical Atlantic
(Sluiter and Van Name); and the western central Pacific (Sluiter).

As regards the sedentary Tunicata the general statement seems
justifiable that every portion of the sea at moderate depths, when
first invaded by the collector, yields a considerable number of new
species. The further conclusion seems warranted that a few
more decades of exploration, as active as the last three or four
have been, would put us in sight of nearly the whole existing tuni-
cate fauna so far as the open sea and shallower waters are con-
cerned. Experience seems to indicate that here as perhaps in
other branches of systematic natural history, after a particular
locality has been explored with reasonable care, further collecting
does not greatly alter the total number of recognized species. ‘The
new ones later brought to light are approximately offset by the
elimination of spurious ones from the earlier lists. The slaughter
of supposed species of Botryllus by Bancroft should be noted in
this connection. Almost certainly the same sort of thing would
happen in several other genera, were they to be studied with equal
care. This suggestion relative to the rounding out of knowledge
of the number of kinds of living tunicates does not touch the ques-
tion of how in the future it may be found best to classify them.

As to the deployment of the species with respect to the extremes
of habitat, of the 521 described since 1892 only about 40 are pelagic.
Of these, 10 belong to the Thaliacea, 27 to the Larvacea, and the
others to the Pyrosome. This is the result in spite of the fact
that exploration has been prosecuted little if at all less vigorously
in the pelagic than in the littoral realm. This is surely true as
regards the Thaliacea and the Pyrosome. As to the Larvacea,
the minuteness of the animals and difficulty of handling them
results in their receiving somewhat less attention than the other
groups. There can be no doubt that the living pelagic tunicates
are much less abundant in kinds than the sedentary ones. Is
this due to the fact that they are subject to less diversity of environ-
ment? This explanation is not of necessity the only one. It is
possible that the small number of kinds is due to the fact that the
group is waning or senescent. I am inclined to think a good case
could be made for this hypothesis, at least as regards the Thalia-

No. 487] ‘STUDY OF THE TUNICATA 455

cea. It is by no means impossible that could paleontology give its
testimony on the history of this group, as it does for the Cephalo-
poda and the Foraminifera, for instance it might reveal a richness
of ancestral kinds far greater than that presented by the modern
fauna.

A matter of prime interest from its bearing on the problem of
fitness to survive is the large number of kinds (species ?) belonging
to a few of the genera, or sets of illy separated genera, of sedentary
ascidians. The most conspicuous groups from this standpoint
are 1 Ascidia; 2, Molgula; 3, Cynthia with its close ally Rhab-
docynthia; 4, Styela with the scarcely distinguishable Polycarpa;
5, Botryllus and its close congener Botrylloides; 6, Amaroucium
with its near relative Aplidium; and 7, Leptoclinum. These
seven groups contain more than 600 of the approximately 1000
species of simple and compound ascidians now described. There
are recognized at least 80 genera in these two tunicate sections.
In other words, as our scheme of classification now stands less
than 14% of the genera contain fully 60% of all the species. It
will be observed that these few prolific groups present all the lead-
ing types of sedentary ascidian organization. An analysis of the
species in these groups with reference to the character of their
environments would certainly not show that some of the types
tend to be restricted to one set of external conditions while others
are restricted to different conditions. I do not believe there is
anything in our present knowledge of ascidian structure, function,
or distribution, to warrant the conclusion that the groups most
abundant in kinds are so because of their greater fitness to survive,
or their relative adaptability to external conditions.

Little headway has been made toward determining the extrinsic
affinities of tunicates. Indeed although nothing has turned up
to shake confidence in their chordate nature, some of the newer
results are puzzling rather than enlightening. ‘Thus Goldschmidt
reports the embryology of Appendicularia (strictly Oikopleura)
to be so similar to that of the typical ascidian that little hope
can be entertained of further light on the problem from this
direction. He confirms the contention of Seeliger and others
that there is no real metamerism in the tail of this animal. I have
examined a number of stages in the larval life of a species of Oiko-

456 THE AMERICAN NATURALIST [Vor. XLI

pleura and am able so far to testify to the correctness of Gold-
schmidt’s observations. On the other hand Metcalf finds some
evidence of metamerism in the rapheal nerve of the Molgulide.
Perhaps these facts slightly support Perrier’s view that the adult
sedentary simple ascidian is nearest to the vertebrate ancestor
and that consequently Appendicularia is a modified ascidian larva.

Seeliger and Metcalf doubt that there is a true homology between
the tunicate and vertebrate hypophysis. Neither does Seeliger
believe the vertebrate thyroid to be related genetically to the tuni-
cate endostyle.

Largely from the character of the stigmata and the absence of
an epicardium, Julin holds a Mediterannean species called by him
Archiascidia to be the most primitive ascidian.

As to intra-class kinships, perhaps nothing of greater general
interest has come to light during the decade than that Octacnemus
is an ascidian proper and has nothing to do with the Salpide.
Metcalf and Ritter have made this positive.

The polyphyletic character of the compound ascidians is now
admitted by probably all students of the class.

2. Distribution. — Some of the most interesting questions
under this head are presented by the abyssal fauna. We now
know at least 25 species that belong here and about half of these
come from depths of 2000 fathoms, more or less. Some of the
genera represented in this deep-sea fauna, though widely separated
systematically, still present a common trait in the tendency to
retrogression of the branchial apparatus. This is distinctly seen
in genera so far asunder as Culeolus, Octacnemus, and Hypoby-
thius. On the other hand species of familiar littoral genera are
coming up from time to time from great depths, having no marks
whatever that can be regarded as impressed upon them by their
peculiar environment. For example I have now in manuscript
the description of a Styela from 2200 fathoms off the California
coast, which does not differ from several shore species more than
these latter differ from one another; neither do its specific marks
betray anything of the peculiarities of its habitat. No aspect of
observational as contrasted with experimental natural history
promises more light on the nature of species, so it seems to me,
than do faunas of the profound ocean depths. `

No. 487] STUDY OF THE TUNICATA 457

The cosmopolitanism of some of the pelagie species, notably
Salpa runcinata fusiformis, is significant. It appears as if there
is no part of any sea in which this animal does not flourish. Per-
haps the data yet in hand do not warrant quite so sweeping a
statement, but it is borne out by material now in my possession
from many parts of the Pacific, and by already published data
from other oceans. This Salpa is a close rival of some species of
Sagitta and of Eucalanus finmarkicus in this regard.

We now have sufficient information about Arctic ascidians
(Bonnevie, Kiear, Huitfeldt-Kas, Hartmeyer), and about those of
the Antarctic (Herdman, Sluiter), to make it clear that this group
lends little support to the “bipolar” theory of distribution. Fif-
teen years ago Herdman concluded that sedentary tunicates are
more numerous in species, and are in general of larger size in
higher latitudes than in the tropics and subtropics. In spite of
some rather rich collections recently described from tropical waters,
notably from Bermuda and the East Indies, it seems as though the
generalization will stand. My own somewhat extensive experience
with Pacific Ocean ascidian faunas appears to support it.

3. Morphology.— Knowledge of the adult anatomy of the
group has been enriched in many directions. ‘The structure of
the appendicularian “haus” has revealed, particularly through
the patient labors of Lohmann, an elaborateness that puts it along
side the sting of the honey-bee as a puzzle to the student of adapta-
tions. For one thing the apparatus turns out to be a strainer of
the most exquisite fineness.

One of the most interesting results of Salensky’s extensive
studies on the anatomy of appendicularians is that the heart of
these animals is far more simple than was supposed, and that it
is probably homologous with the procardial organ of the ascidian

per.

Branching of the nuclei of some of the ectodermal secretory
cells of Oikopleura occurs to such an extent that it may well attract
the attention of those interested in general problems of cell struc-
ture and activity

Metcalf’s findings relative to the fusion or intergradation of
nervous and glandular tissues in the neuro-glandular complex of
several ascidians is noteworthy. Of general significance also may

458 THE AMERICAN NATURALIST [Vor. XLI

be mentioned the tendency to multiplication of ganglionie out-
growths observed by Metcalf in Salpa.

4. Embryology.— Knowledge of tunicate development has prog-
ressed in numerous ways during the decade. According to my
judgment two of these are particularly significant to the general
biologist. They pertain to the very early embryonic life and to
the multiplication of branchial stigmata. Among the investiga-
tions of the early embryo those by Conklin easily hold first place.
To the embryologist, one set of facts brought out by Conklin
stands with special prominence in the midst of many that are
important. These relate to the question of organization in the
unsegmented egg. Conklin’s figures seem to furnish strong sup-
port for his statement that “it is doubtful whether any other case
of cytoplasmic localization hitherto reported is more remarkable
than that which has been described in the preceding pages for the
ascidian egg.”

Important as are these particular truths of ascidian develop-
ment emphasized by Conklin’s observations, there are other as-
pects of his work which appeal particularly to the general zoologist.
In a résumé of what is known about cytoplasmic localization
the author says:— “The annelids do not approach the chor-
dates nor the echinoderms in the earliest stages of localization
any more closely than in their cleavage stages or later development.
In short there is no convergence toward a common type of localization
as one goes back to earlier and earlier stages in the ontogeny.” In
another connection Conklin points out that the pigmentation of
the ovum which has served him so admirably in making out the
“specification” in the development of Cynthia “may differ most
remarkably in different genera of ascidians”; and, that “the
same may also be said of the yolk.” Of the pigment he says,
“this inert substance is not in itself of differential value, but it.
lies in a definite region of the egg and probably in a particular
kind of protoplasm.” The general zoologist, particularly the
taxonomist, must inquire in the presence of these facts, Where
is this sort of discovery going to lead us? If, viewing developing
animals broadly, we find types of presegmental localization or in
ordinary terms, types of egg structure that do not converge to a
common type; and if eggs from genera so closely related as Cyn-

No. 487] STUDY OF THE TUNICATA 459

thia* and Molgula differ remarkably in “ kinds of protoplasm,”
does it mean that by and by we are going to find specific characters
in the eggs of aminals as well as in their adult condition? For
my own part, speaking as a systematist, I am fully prepared to
accept the full consequences of just this outcome. Furthermore
I see something of the reach of such consequences.

The fact about the development of branchial stigmata which
seems to me second in significance only to cytoplasmic localization,
is that the origin of the epithelium of new stigmata is always
dependent on that of preceding ones. The general question of
how repetitive parts arise is basal. These results on the branchial
stigmata of ascidians seem to be decisive so far. Selys-Long-
champs, Dumas and Julin are specially to be mentioned in these
investigations.

The somewhat bizarre notions which gained currency some
time ago about the origin and fate of the follicle cells of the ascidian
ovum seem to have been pretty nearly disposed of during the
decade, thanks to Floderus, Bancroft, Todaro, and Korotneff.

Origin of the heart from the ectoderm is affirmed by Salensky.
He treats this along with other instances of ontogenic origin of
ascidian parts in defiance of rigid germ layer tenets, under the
term “ heteroblasty.” This general subject, important as it is,
has received no thorough investigation during the decade.

The regular succession of generations of ascidiozoids in the
Botryllus colony observed by Pizon and Bancroft is a significant
enlargement of our knowledge of development on the plane of
organic animal societies.

5. Physiology.— Studies of the degeneration and rejuvenation
of colonies of compound ascidians (Pizon, Caullery, Bancroft)
have yielded significant results. For one thing the dying down
of the colonies seems to be at least partly a normal senescent
phenomenon and not due to the direct influence of environment.

Colonial as contrasted with zooidal individuality is suggested
particularly by studies on growth and blood circulation in the
Botryllus colony. The interesting fact is brought out by Ban-

1 Attention should be called to the fact that if Conklin’s eggs were from the
Halocynthia partita of Verrill, he was really dealing with a Styela and not.
with the genus Cynthia at all.

460 THE AMERICAN NATURALIST [Vor. XLI

croft that the ectodermal ampulls in the test substance of the
Botryllus colony are rhythmically contractile and have a regular
circulatory office. There is coordinated activity among large
numbers of ampulle in the same colony and this seems to be
without the intermediation of the nervous system.

The unique form of tunicate heart action has continued to
attract attention. The most comprehensive study of it is by L.
Schultze on Salpa. “The heart of Salpa is an example of purely
muscular self-regulation in a highly coordinated mechanism of
motion.” This sentence summarizes Schultze’s positive results.
Neither cerebral influence nor blood pressure play a causal part
in the phenomena. Of similar general import Bancroft and
Esterly find proof of polarization through its own activity in the
heart of Ciona. On the other hand Magnus, Hunter and Fröh-
lich bring forward rather strong evidence of the dependence of
heart action in Ciona on ganglia and to some extent on the brain.

UNIVERSITY OF CALIFORNIA
BERKELEY, Cat,

NOTES AND LITERATURE
GENERAL BIOLOGY

The Agassiz Centennial— On May twenty-seventh the one hun-
‘dredth anniversary of the birth of Louis Agassiz was observed in
Sanders Theatre, Cambridge, by a public reunion of his pupils.
President Dana of the Cambridge Historical Society made the opening
remarks and presented Colonel Thomas Wentworth Higginson, the
chairman of the meeting. Letters were read from Professors Dall,
Verrill, Wilder, Holland, Brooks, Ehlers and Bouvier. Professor A.
L. Lowell spoke of the coming of Agassiz to America at the invitation
of the Lowell Institute of Boston. Professors Niles and Gray told of
his influence upon his pupils and over the community. Two poems,
“The fiftieth birthday of Agassiz” by Longfellow, and “The prayer
of Agassiz” by Whittier were read by Professor Winter. The meeting
closed with the short address by President Eliot which is printed in
full in this number of the Naturalist.

Commemorative meetings were held in other places. At Barnes
Hall, Cornell University, Professor Burt G. Wilder delivered an
address on ‘‘What we owe to Agassiz,” a portion of which is printed
in the Cornell Era (vol. 39, pp. 441-446).

To the younger generation of scientists the attractive and impressive
personality of Agassiz belongs essentially with the past. Some
children are still led by an inborn love of nature to hunt the fields and
ponds for strange creatures, and to bring home small fishes to the
watering trough. Sometimes they are later found at a school of
medicine where parental warnings fail to keep their interests within
the presumably lucrative bounds. Occasionally while quite young
they are entrusted with important scientific work,— but they do not
become naturalists.

It is said that Agassiz’s first essay in natural history was a catalogue
of the plants of the Jura Vaudois; later he was professor both of geology
and zoology. ‘The plan of creation” was not too large a subject for
a lecture course. The laboratory and the teacher’s desk were attractive
as a means to make known what was gathered from the sea or observed
on the mountains. At the inauguration of Cornell University in 1868
Agassiz said,— “I am full of recollections of the Rocky Mountains.
I wish this were a fitting time and place to speak of nature, its beauties

461

462 THE AMERICAN NATURALIST [Vor. XLI

and its instruction, for I should know then that I was upon my own
ground.” Nature was studied in a large way, and directly, without
the intervention of collectors and preparators. In this far-reaching
knowledge and discerning love of nature, unlimited by class or king-
dom, Agassiz was a naturalist. But the minute, laboratory method
of study which he advocated has ended the succession. Given fishes
to study and one is busy for life; the interest in glaciers, flowers, and
the plan of creation are lost in the intensive activity of the ichthyologist.
The love of nature may indeed remain, but the knowledge of nature
must be narrow or superficial; and the scientist of to-day is far removed
from the naturalist of the past.

To retain something of the broader interest has been the purpose of
this journal. Through its pages many of Agassiz’s pupils have cir-
culated the teachings of natural history, and to spread such knowledge
was their master’s delight. The number for March 1898, contains
seven articles commemorating the beginning of Agassiz’s Harvar
professorship which “‘marked a new era in the history of zoology in
America.” To these tributes it is a pleasure to add that of President

Eliot.

The Preservation of Native Animals and Plants.— Both in America
and in Europe the destructive effects of the growth of cities and
spread of monotonously cultivated areas are receiving earnest at-
tention. There is also widespread protest against every form of wil-
ful and needless destruction of animals or plants. ‘Those who feel
some resentment that the portion of the world in which they live is
not as attractive as their grandfathers found it, will find signs of
better times in current literature and activities, a few of which will be
cited. Beginning with the preservation of mammals we quote as fol-
lows from H. H. Johnston, in Nature (1907, vol. 76, p. 34).

“So far back as 1890 a movement began in Great Britain in favour
of preserving wild life in lands under British control rather than allow-
ing it to be exterminated by ruthless shooters. To some extent this
movement was inspired from the United States. The creation of the
National Park of the Yellowstone district, which was to lead to the
formation of a ‘paradise’ for the nearly extinct bison, bears, prongbuck,
deer, and wolves of central North America, suggested to several sports-
men-naturalists of Great Britain similar preserves in tropical lands,
especially in Africa. Of course, long antecedent to that, British
naturalists had at last induced the State to legislate for the preservation
of the scanty remains of the British fauna, and although our measures

No. 487] NOTES AND LITERATURE 463

in this respect are still woefully inadequate, and a limited and old-
fashioned class is allowed to push certain forms of sport at the expense
of the wild fauna of these islands, still we have saved much; and in
some distriets of Great Britain birds and the smaller mammals really
form constant and charming features in the landscape.

“The great invasion of Africa which began in earnest in 1890,
directed public attention to the coincident slaughter of big game
which everywhere accompanied the pioneering parties of the British.
Just as Great Britain. ...has gone far beyond any other nationality
in the destruction of wild beasts and birds, her people are now fore-
most (though the United States is running almost neck and neck) in
the world-movement for the preservation from extinction of all but the
most harmful animals. We cannot be contented aesthetically with
beef, mutton, poultry and pheasants, but to complete the interest of
our lives we must have beautiful wild things around us to admire and
study; there must be a place in our society for the rhinoceros, the lion,
tiger, and even the wolf.”

In southern New England only the weaker mammals remain.
Attempts are made to introduce woodchucks, muskrats, and squirrels
in the city parks where it is a crime to molest them, but in the country
districts where these animals are much more attractive, bounties are
offered for their destruction in case their skins are not sufficient lure.
The wearing of furs is largely needless,— the lack of “buffalo robes”
is not felt though the loss of the bison remains. A protest against
the wearing of furs has recently appeared in Life.

The greatest interest in animal preservation attaches to the birds.
Present legislation does not prevent the unnecessary decrease of many

inds. Brewster notes that “the Solitary Sandpiper i is one of the few
waders that have not diminished perceptibly in numbers within the
past thirty years” (The Birds of the Cambridge Region, p. 165). There
seems to be no good reason why the pleasure a few in shooting shore
birds should continue at the expense of ma

The scientific value of egg and skin ‘alle is relatively slight.
Bird Lore and The Condor have recently been at odds whether oology
is a science at all. It is clear that the deepest science is often the least
destructive to nature. Embryologists have learned the development
of birds by studying domesticated forms,— the chick more than all
others together. The position of birds in the animal series is and
will be based upon thorough anatomical and physiological study of
these forms. Under the name of science, however, many a superficial
collector has sought refuge.

464 THE AMERICAN NATURALIST [Vor. XLI

In a neighboring town a beautiful museum has been erected, devoted
exclusively to birds. It contains a specimen of the great auk. For
scientific purposes, a synoptic collection of equal size, similar to that
in Cambridge planned by Agassiz, would be of more value to the
town. In the same village and quite as attractive, there is a long low
barn with overhanging eaves under which there are some forty popu-
lous nests of the eave swallow. The owner has left out a few panes
of glass from an upper window so that barn swallows are there also,
and the two forms of birds can scarcely be confused after a visit to
his place. The town ought to recognize its indebtedness to such a
citizen as it does to the donor of a museum. How desirable he is as
compared with the owner of the last large colony in the Cambridge
region! Of that colony Brewster records that in 1869 “there were
sixty or seventy occupied nests strung in a long row along the western
side of a large barn. The owner of the place destroyed them all soon
afterwards and they did not return. He objected to the presence of
the swallows because their droppings disfigured his barn.” Mr.
Brewster’s volume contains many such unpleasant memoranda. A
great gray owl had the misfortune to visit Cambridge where it was
observed by a woman who asked a certain Mr. Malone to shoot it.
“Tt stared at him fixedly with its yellow eyes wide open, but showed
no alarm at his presence although he went almost directly under the
branch on which it was sitting. After watching it for a few moments,
he fired at it but missed. At his second shot the bird flew across the
paddock and alighted on the end of a spruce limb. It proved to be
badly wounded and soon fluttered down to the ground where it stood
on the defensive, presenting so menacing an appearance that he did
not venture to touch it for several minutes. It died a few hours later.”

A bill to protect these birds failed to be passed in Massachusetts
but justice demands that they should be the property of all and not
of the first selfish observer. All forms of native animals which are
readily seen should be protected; if they are required in large numbers
they should be reared for the purpose. The first remark of a systema-
tist who was asked to identify a lot of turtles for dissection was,—
“Some place is being depopulated of its tortoises!” Children should
be taught to rear insects rather than to destroy all available Lepidop-
tera. In these days of inexpensive and quite accurate pictures, col-
lections are not necessary for identification, and science is advanced
by detailed studies of common forms,— the brown-tail caterpillar
and the Colorado potato beetle — rather than by collecting luna and
imperial mot

No. 487] NOTES AND LITERATURE 465

Similar problems confront the botanist. Just as boys gather eggs
and butterflies, girls make large bouquets of wild flowers and are often
encouraged by the advice that ‘the more they pick, the more there
will be.’ There is a mercenary motive also, for the arbutus, fringed
gentian and sabbatia among others are tied in compact bunches and
sold in the cities,— a practice which might properly be prevented by
law. The mayflower is so protected in Connecticut. To prevent
thoughtless and wilful destruction there are at least two important
organizations, The Wild Flower Preservation Society of America, and
the Society jor the Protection of Native Plants. 'The officers of the
latter are among the most eminent botanists of New England and its
membership is about seventeen hundred. ‘The Naturalist has received
copies of its leaflets which are widely circulated without charge.
They urge that the roots of plants shall not be disturbed, and protest
particularly against the destruction of arbutus, gentians, Christmas
evergreens,— mountain laurel and ground pine, various orchids, and
all the rarer flowers, even by botanists. For decorative purposes
daisies and buttercups may be gathered indiscriminately. Asters
and goldenrod may be taken freely, except that flowers by the road-
side should be left for general enjoyment. ‘They quote Ruskin,—
“Flowers seem intended for the solace of ordinary humanity; children
love them; quiet contented ordinary people love them as they grow;
luxurious and disorderly people rejoice in them gathered... .”

All of these efforts for the preservation of native plants and animals
indicate the progress of natural science. They are based, not upon
sentiment, but upon a more intelligent appreciation of nature; and
they deserve success.

ETR

ZOOLOGY

The Curious Mating Habit of the Fly Rivellia boscii.— The following
observations were made near Toronto in the latter part of June. The
flies were found in bright sunlight about noon on leaves of bushes
and flowers in a garden border. The behavior of four pairs only
will be described for though other pairs were seen going through
similar movements, only four were watched from their first meeting
until separation. In all cases the female runs about on the leaves in
small circles and spirals varied by an occasional straight course. The
wings are extended and moved slowly up and down; at intervals

466 THE AMERICAN NATURALIST [Vor. XLI

she stops for a second or two and then goes on. The male who is
much smaller follows closely and when the pace admits touches her
abdomen with his proboscis or with one of his anterior pair of legs.
Sooner or later he mounts the back of the female, the penis is extended
and taps the abdomen of the female two or three times when the latter
also becomes extended and copulation begins. This extension of the
female’s abdomen is necessary to connection and seems purely auto-
matic, for it invariably occurs even when her previous and subsequent
actions show that the male’s attentions are not acceptable.

Pair I. In copula the wings keep in constant motion, while at
intervals of three or four minutes a period of greater excitement arrives
during which the wings of both are moved more rapidly and their
probosces are alternately extended and retracted. After a few seconds
of this excitement a droplet of colorless fluid appears at the end of the
proboscis of the male and rapidly increases in size until from one-half
to two-thirds of a millimeter in diameter. This is not a bubble but a
solid globule. The male now raises his proboscis as high as possible
and lurching forward with his body, brings it down with a sweep and
transfers the globule to the proboscis of the female which she elevates
to receive it. The movement is rapid and very deft. Under move-
ments of the female’s proboscis the globule now dwindles and dis-
appears; evidently she eats it. This transference of a globule is
repeated many times before the pair separate. ‘The male maintains
his position chiefly by grasping the abdomen of the female with the
second pair of legs, the first pair resting either on abdomen or thorax.

Pair II. The male succeeded several times in mounting but each
time was dislodged by the female by movements of her legs and whole
body. Male number two appeared on the scene and mounting was
allowed to remain. Male number one endeavored to displace him
but failing several times, soon went off. After the first globule had
been handed over by male number two he dismounted of his own
accord and went off.

Pair III. After handing over the globule the male would dismount
of his own choice and run in circles around the female who remained
almost stationary. After three or four minutes he would mount, the
globule would appear at once and be handed over as usual. This
occurred many times in succession.

Pair IV. The globule would appear as usual but with less excite-
ment on the part of the male, as shown by sluggish movements or
none at all, of wings, legs, and proboscis. After appearing and increas-
ing to the usual size it would decrease, evidently being consumed by

No. 487] NOTES AND LITERATURE 467

the male himself. This occurred five times in succession. At inter-
vals the female struggled to rid herself of him but did not succeed.
The sixth time that the globule appeared was immediately after one
of these struggles; this time the globule was handed over but the
male dismounted at once of his own accord and went off.

The habit itself is curious enough, but no less interesting are the
variations noted and the decided imperfection of instinct in the male
of pair number four. The apparent choice exerted by the female of
pair number two, and the whole behavior of the pairs gave an impres-
sion that could not be harmonized with any theory of insect behavior
that considered insects pure automata.

Another point of interest is the possible connection between these
globules and those referred to by J. M. Aldrich and L. A. Turley in
an article entitled “ A balloon-making fly” (Amer. Nat., 1899, vol. 33,
pp. 809-812). The balloons are described as hollow, elliptical
structures “composed entirely of a single layer of minute bubbles,”
and it is said that they are probably produced by the anal organs as
in the leaf-hoppers “but no positive observations on this point could be

ade.” The authors do not state plainly that the bubbles contain
air; in the present case, however, there are certainly no bubbles, but
solid droplets probably of salivary secretion.

The behavior of these flies suggests that of the pigeon as described
by Dr. E. H. Harper (Amer. Journ. of Anat., 1904, vol. 3, p. 354).
He says,— ‘There is an act which regularly precedes copulation, in
which there is an apparent regurgitation of some secretion by the male
which is taken from his throat by the bill of the female, in somewhat
the same manner as the young birds take their food. It is a less violent
manifestation than the feeding of the young however. It is easy to see
that here may be one of the sources of indirect stimulation to the
female reproductive organs.” (Compare with the stroking of the
salamander recorded in the following note.)

Specimens of the fly were preserved and through the kindness of
Dr. L. O. Howard, identified as Rivellia boseii (Desv.).

W. H. Pıersor.

The Spermatophores of Salamandra.— In connection with Dr.
Smith’s account of the spermatophores of Amblystoma published in
the last number of the Naturalist, the recent paper by W. Docters
van Leeuwen is of special interest (Über die Aufnahme der Spermato-
phoren bei Salamandra maculosa Laur., Zool. Anz., 1907, vol. 31,
pp. 649-653). The animals observed were in confinement but the

468 THE AMERICAN NATURALIST [Vor. XLL

conditions were believed to be natural. At twilight the salamanders
come out from the mossy logs, and the male having found a mate
crawls under her body, working his way forward. His front legs are
swung around those of the female and he strokes the under side of
her head with his nose. After a time a spermatophore is deposited
on the moss. It is a pyramidal structure 8-10 mm. high and 4-6-
mm. wide, sharply pointed with the apex upward. After its deposi-
tion the male swings his body 90 degrees to one side, but retains his.
grasp, and his head remains beneath that of the female. The cloaca
of the female is thus brought over the spermatophore which is taken
up before the pair separates. Mating occurs from July to September
or October, and the spermatophores are always deposited on land.
The eggs are fertilized and in the following spring or early summer
the young are laid. A new set of eggs is then mature and ready for
fertilization.

EDL

Stone-gathering Fishes. — In the American Naturalist for May
(pages 323-327 of the current volume), Dr. Alfred W. G. Wilson has
given important information and excellent illustrations of so-called.
“Chubs’ Nests.” Although, as stated in a foot-note, no account of
these nests is included in my article on “Parental care among fresh
water fishes,” it is recorded (p. 436) that several American cyprinids.
“also take care of their eggs, especially the Horned Dace (Semotilus
atromaculatus), the Black-headed Dace (Pimephales promelas), and.
the Stone-roller (Campostoma anomalum).” I did not give any fur-
ther information for two reasons; the data in the books were unsat-
isfactory, and Professor Jacob Reighard had informed me that he
would soon publish an account of the habits of these fishes.

The evidence as to the exact species that heaps the stones in question.
needs confirmation. Dr. C. C. Abbott, in “A naturalist’s rambles
about home” (1884, p. 408) positively declares that Semotilus corporalis-
(called by him bullaris) ‘‘differs materially from the birds and even
many fish” in that “it does not concern itself with the care of its off-
spring. Once the eggs are laid upon their bed of sand, all care as to-
their future vanishes”; he says nothing about the oviposition of
Semotilus atromaculatus noticed on page 409 and called by him S.
corporalis (p. 479).

Semotilus atromaculatus occurs in Canada as well as S. corporalis;
it is known not only as Dace but as Chub, both English terms being-
applied to this American fish which is no nearer one than the other..

No. 487] NOTES AND LITERATURE 469:

The question thus arises whether the fish which prepared the chubs’
nests observed by Dr. Wilson was Semotilus corporalis' or S. atroma-

culatus; the former has been declared not to be a nest-maker and the
latter is known to be such.

ur own common catfish does indeed carry “‘stones away from its.

nest” but the following instance of the contrary habit has been de-
scribed in my article (p. 453). The Australian catfish (Arius australis)
according to Professor Richard Semon resorts to flat, sandy, and
stony parts of the river under a rapidly passing current to spawn.
“When depositing its eggs and building its nest the fish goes to work
in the following way. It begins by preparing a bedding about half
a yard in area, consisting of gravel and small pebbles among which
it deposits the spawn which is instantly milted by the male. After-
this it covers the eggs by several layers of bigger stones, thereby pre-
venting them from being washed away by the stream, or carried off
by water birds ....or by marauding little fishes. The material for
this defensive structure is derived from the above mentioned ring
(surrounding the nest) which thereby becomes devoid of all stones
and gleams brightly in its smooth garb of white sand. It is wonder-
ful to observe the accuracy of the fish’s handiwork and the perfect
circle described by the ring. So far as I could see the fish moved the
bigger stones by pushing them along with its tail. The whole affair
shows a very clever arrangement, the eggs being well shielded from
enemies, well ventilated by the current, and even protected against
being mud-stifled (save in case of a downright flood).”

I may add that the earliest detailed notice of a stone-gathering
cyprinid that I know of, was communicated by Dr. W. H. Gregg to
the American Naturalist in 1879 (vol. 13, p. 321); the fish was identi-
fied by him as Rhinichthys atronasus.

THEODORE GILL

‘In Dr. Wilson’s paper (p. 327) Semnotilus corporalis Mitchell should read
Semotilus corporalis (Mitchill).

470 THE AMERICAN NATURALIST [Vor. XLI

BOTANY

The Search for Mutations.— Few are inclined to doubt the reality
of the mutations observed by DeVries in the cultivated evening prim-
rose, but many have questioned whether these changes occur at all
frequently in nature. The search for them has been active since the
publication of Die Mutationstheorie.

Cockyane (New Phyt., 6: 43-46, 1907) describes pink, rose pink,
and even bright rose forms of Leptospermum scoparium. So far as
he was able to determine these color varieties must have originated
in single individuals by discontinuous variation.

Cockerell (Bot. Gaz., 43: 283-284, 1907) reports that near Boulder,
Colorado, Euphorbia corollata has only four glands instead of the five
normal to the species. No plants with five were seen.

Rehder (Bot. Gaz., 43: 281-282, 1907) records the discovery in
British Columbia of a fine specimen of Rhododendron albiflorum with
double flowers. There was: petalody of the stamens and carpels,
with a considerable increase in their number. Only a single, imper-
fectly developed anther was found. Wild rhododendrons with double
flowers are rare; in the Alps R. jerrugineum with double flowers has
been observed at least twice.

Focke (Abh. naturw. Ver., Bremen, 19: 74-75, 1907) announces
the gradual change of Datura ‘abla to D. stramonium. The offspring
of typical D. tatula became weaker and paler from year to year until
finally vigorous D. stramonium plants were produced from the seed
of the weaklings. Since the methods of culture and pollination are
not given in detail these results cannot be accepted without verifica-
tion. The author records also a number of variations which some
might class as mutations.

In connection with the recent discussions of geographic isolation
in the American Naturalist, the observations of Schaffner are of inter-
est (Ohio Naturalist, 7: 41-44, 1906). He discovered a new variety
of Verbena stricta growing in Clay County, Kansas, distributed over
somewhat more than a square mile of territory and represented by
thousands of specimens. The new form is characterized by a pinkish
white corolla, and among many thousands of specimens no transitional
forms were found. In some spots the new form was more abundant;
in others the parent species predominated; and elsewhere the two

a

No. 487] NOTES AND LITERATURE 471

forms were about equally represented. Schaffner considered this
unquestionably a mutation, and points to the significance of the fact
that it has been able to persist and spread without any geographic
isolation whatever.

The observations of Druery (Journ. Roy. Hort. Soc., 31: 77-83,
1906) on the wild sports of British ferns are also pertinent. He
records a case in which the cristate form of Pteris aquilina was found
covering an area of several acres, having apparently superseded the
normal form in this one locality. Druery has devoted much attention
to the collection and cultivation of the wild sports of British ferns.
The British Isles are particularly rich in these sports of extremely
divergent character and often of great beauty. About 1200 wild forms
have been catalogued as distinct although only some 40 species are
listed for the flora, and the majority of these have sported only rarely.
Most of the ornamental forms cultivated in gardens have originated
in nature and not under the influence of cultural conditions. The
spores collected from wild plants yield the anomaly in its full develop-
ment, or in three generations at the most, so that there can be no
suggestion of a gradual development by the selection of minute varia-
tions. In nature the aberrant and the typical forms are found grow-
ing together but no intermediates are to be seen.

Shull (Science, n. s. 25: 590-591, 1907) has been occupied for some
time with pedigree experiments on the common shepherd’s purse and
now announces results of great interest based upon the examination
of over 20,000 pedigreed individuals. Four elementary forms have
been discovered which breed true when self fertilized or crossed within
the limits of the same elementary species. Upon crossing, these forms
hybridize in strictly Mendelian fashion. Other atypic forms which
appeared in the cultures breed true to their characteristics and do not
show Mendelian segregation, but Dr. Shull is unwilling to advance
them as mutants since they were not produced from the seed of guarded
flowers. Shull (loc. cit.) and Transeau (Science, n. s. 25: 269-270,
1907) both point out the significance of Mendelian hybridization in
the persistence and migration of a newly arisen type. e recessive
form is at no disadvantage from crossing with ibe parent in these cases
but sometimes probably has the advantage.

Zoologists are more cautious than botanists in accepting the muta-
tion theory. Whitman has recently criticized it (Bull. Wise. Nat.
Hist. Soc., n. s. 5: 6-14, 1907). Duerden (Rec. Albany Mus., 2:
65-96, 1907) in his studies of the genesis of color patterns in tortoises
concludes that the color patterns must have arisen by gradual modi-
fication and not by sudden transformation. Ortmann (Mem. of the

472 THE AMERICAN NATURALIST [Vor. XLI

Carnegie Mus., 2 :343-524, 1906) studied the crawfishes of Pennsyl-
vania and states that “anything that looks like a ‘mutation’ in de
Vries’s sense is entirely unknown.” Closely allied species either have
distinct geographical distributions or if found jn one locality they pre-
fer different habitats.

ower is of the opinion that “the evolution of the genus
Leptinotarsa and of animals in general has been continuous and
direct, developing new species in migrating races by ‘direct response
to the conditions of existence” (Carnegie Inst., Publ. 48). He states
that “there is not at present evidence to show the origin of any heritable
variations in the soma”; and that “in these beetles we can get new
permanent variations by stimulating the germ cells and in no other
way.” Such an inheritable character he produced artificially by sub-
jecting adult beetles to abnormal conditions of temperature, moisture,
and barometric pressure. The eggs produced and developing under
these conditions give rise to new forms which breed true even under
normal conditions. But the parent beetles when restored to normal
conditions produce offspring of the original type. The new forms are
therefore believed to be due to influences of environmental conditions
on the germ plasm. F. E. Lutz of the Cold Spring Harbor Station
has reviewed Dr. Tower’s work from the mutationist’s point of view,
as follows (Canadian Ent., 39: 176-179, 1907),—

“The author maintains that ‘mutation is not a special kind of varia-
bility different from that of ordinary fluctuating variation, but it is a
part of the normal variability, and the direct response of the germ
plasm to stimuli.’ He finds that ‘extreme variates’ are rare, occurring
only once in 6,000 cases; and they breed true, a thing which ordinary
variates do not do. This is my idea of a mutant.... The fact is,
Tower has given us one of the strongest arguments for the importance
of mutations that has ever been presented. He says,— “The breed-
ing ‘mutants’ in our gardens and laboratories cannot tell us how they
would succeed in nature; my experience with these beetles is that they
fare badly, and, as far as I can discover, that they play a minor role
in the evolution of species.’ However, he had already stated that not
only did pallida, one of the ‘mutants,’ breed absolutely true for six
generations in the laboratory with ‘no tendency to revert to the parental
species’ (decemlineata), but that from 14 males and 15 females allowed
to shift for themselves in nature, 1,580 pallida offspring of the 6th
generation were found, and he ‘felt that further experiment with this
form unconfined in nature was neither safe nor desirable, and exter-
minated the entire lot.’ It is true that 29 pallida are more than he
ever found in nature at one time and place, but he did find 6 at Clifton,

No. 487] NOTES AND LITERATURE 473

Ohio, and he noted that occasionally, as at Cabin John Bridge, Md.,
in 1900, sports are relatively very abundant....If I had been so fortu-
nate as to obtain his results, I would have drawn quite the opposite
conclusions, and would have supported the mutation theory most
loyally....”

Aigner-Abafi (Ann. Hist.-Nat. Mus. Nat. Hung., 4: 484-531, 1906)
describes aberrations or varieties of 113 forms of Lepidoptera, many
of which are figured. He aims to include only such as may be of
interest to the student of evolution, but offers no suggestions as to their
phylogeny which, he believes, should follow experimental researches.
He considers that a knowledge of these forms collected in nature will
be of great interest in connection with their production by experimental
means.

Melanism has received particular attention among mutationists.
Porritt (Rep. Brit. Ass., 76: 316-332, 1907) has given a detailed
account of the increase of melanism in Yorkshire Lepidoptera. ‘The
author confines himself strictly to recording the facts, some of which
seem to support the mutation theory although others do not.

In all these cases it is observed that zoologists are cautious about
applying the term mutant to variations found in nature. Although
the teratological studies so popular a few years ago have gained a new
significance through the discoveries of De Vries, real progress lies
only in the cultivation of these aberrant forms and the recording of
their behavior in successive generations under guarded conditions.

J. A. Harris.

Biology in the Journal of Agricultural Science.— Although the real
progress of science cannot be properly estimated by the counting of
titles of journals, some notion of the interest which is being shown in
scientific matters and of the degree to which specialization has extended
may be had from this very source. The appearance of the new Jour-
nal of Agricultural Science indicates that another field of research
has become enlarged, and that this division of applied science acquires
a more direct means of spreading its benefits.

The purpose of the journal is to afford a “general channel for the
publication and discussion of papers bearing on agriculture.” Papers
on zoology, botany, bacteriology, chemistry physics or geology are
accepted if they have a bearing upon the definitely scientific problems
of agriculture, but no papers dealing with matters of an ordinary
commercial or farming character as distinct from agricultural science
are to be admitted. The first six numbers of the journal, fine speci-
mens of the product of the Cambridge press, are now at hand.

474 THE AMERICAN NATURALIST [Von XLI

The name of W. Bateson on the editorial staff is an assurance that
the pages will contain much of interest to students of Mendelism.
As a matter of fact, of the forty-seven signed papers ten are devoted
mainly to discussions of this new field of experimental work. Biffin
has a paper on Mendel’s laws of inheritance in wheat breeding, and a
supplementary note on the same subject. He discusses also the hybrid-
ization of the barleys, the inheritance of sterility in the barleys, and the
inheritance of disease resistance. Butler contributes a paper on

the bearing of Mendelism on the susceptibility of wheat to rust. ‘The
problem of disease resistance is taken up from the histological side
by Marryat. Under the title “Hybridization of Cereals,” Wilson
reports Mendelian studies of oats and barley. Ball presents a note
on Mendelian heredity in cotton. Humphries and Biffin discuss
the improvement of English wheat. It will be noted that the Mende-
lian investigations reported are almost exclusively on cereals,— the
group of agricultural plants where the results may be expected to have
the highest economic importance. An exception is a paper by Wood
on the inheritance of horns and face color in sheep.

Other papers of interest to botanists are an article on the influence
of pollination in the development of the hop, by Howard; papers on
the chemical composition of the swede and mangels, and a paper
discussing the law of sequence in the yield of wheat.

A journal of this type should contribute greatly to agricultural
progress; moreover it promises to be a mine of facts for the student
of pure science.

J. A. Harris.

Notes.— A new flora of Louisiana. Students interested in the
flora of Louisiana must often have regretted the very incomplete
publications upon this subject. e “Florula Ludoviciana” of
Rafinesque, and the books of Darby and Chapman all fall far short
of treating it satisfactorily.

It wi good news that the newly formed Museum Commission
of the State of Louisiana, which is charged with the duty of creating
a State Museum in New Orleans, contemplates publishing every six
months a volume dealing with the history and resources of the state,
and that the first volume will be a Flora of Louisiana by Prof. Reginald
S. Cocks. This gentleman has given many years of study and active
personal research to the work, which would have been published
some years since but for an unfortunate fire which destroyed a part of
his material.

Wiliam BEER.

PUBLICATIONS RECEIVED

From May 1 to June 1, regular exchanges not included
The year of publication, when not otherwise noted, is 1907

Burkett, C. W., D Por Cotton. Its Cultivation, Marketing,
M Unklochire, and the Problems F the oik World. New York, Doubleday,
Page & Company, 1906. 8vo, IX + 331 pp., illus. $2.00.— Schwarz, G.

The Longleaf Pine in Virgin Forest. er York, John Wiley & Sons, 1907.
12mo, X + 135 pp., illus. $1.25.— Smith, E. A. The Underground Water
Resources of Alabama. Geological eu of Alabama, Montgomery, The
Brown Printing Company, 1907.

ALBERT I, Prince or Monaco. Meteorological researches in the high
atmosphere. Scottish Geog. Mag., Mar., pp. 113-122, illus.— Bere, L.
review of the cobitoid fishes of u bean of the Amur. Proc. U. S. Nat. Mus.,
vol. 32, pp. 435-438. A review of the species of the Be rar
or Pygosteus from East Asia. Proc. U. S. Nat. Mus., vol. 3
CaupELL, A. N. The Decticinae (a group of Orthoptera) d en America.
Proc. U. S. Nat. Mus., vol. 32, pp. 285-410, 94 figs— CırErA, R. Notice
sur l’observatoire et sur quelques Ghesryntdons de Véclipse. Mémoires de
l’Observatoire de l'Ebre, 1906, no. 1, pp. 1-56, pls. 1-12.— Coser, J. N. and
Kourcuin, H. M. Report on ties fisheries of Alaska. Report on inspection
of the salmon fisheries. Bureau of Fisheries, doc. 618, 70 pp.— EIGENMANN,
C. H. The poeciliid fishes of Rio Grande do Sul and the La Plata basin
Proc. U. S. Nat. Mus., vol. 32, pp. 425-433, 11 figs— Farrineton, O. C.
en of en meteorites compiled and classified. Field Columbian Mus.
geol. ser., vol. 3, pub. 5, pp. 59-110.— Grirritus, D., and Hare, R. F.
Prickly pear oe aces cacti as food for stock II. N. M. ex. Agric. Exp. Sta.,
1906, bull. 60, 134 pp., 7 pls.— Hay, O. P. A new fossil stickleback fish
from Nevada. Proc. U. S. Nat. Mus., vol. 32, pp. 271-273, 3 figs.— JUDAY,
C. Notes on Lake Tahoe, its trout and trout-fishing. Bull. of Bur. Fisheries,
vol. 25, pp. 133-146.— Kerross, R. S. The timber supply of the United
States. U.S. Dep’t of Agric., forest service, cire. 97, 16 pp.— KOEHLER, R.
Note préliminaire sur quelques Astéries et Ophiures PEA des cam
de la Princesse-Alice. Bull. de lInst. Océanogr. de Monaco, no. 99, 47 pp.

Bur. Fisheries, vol. 26, 1906, pp. 111-132, pl. I and II.— Linton, E. "Notes
on Calyptrobothrium, a cestode genus found in the torpedo. Proc. U. S.
Nat. Mus., vol. 32, pp. 275-284, 8 figs. — Lyon, M. W. Remarks on the giant
squirrels of Sumatra, with descriptions of two new species. Proc. U. S. Nat.
Mus., vol. 32, pp. 439-445, pl. 33.— Martarp, L. L’Industrie des Salines
côtières, Bull. de l Inst. Océanogr. de Monaco, no. 100, pp. 43, 13 pls.— Nesom,
G. E. Bureau of agriculture districts of the Philippines. Control of rinder-
pest. Carolina golden rice. Notes. Dept. of the Int., Bur. of Agric., P. L.,
Press bull. no. 9, 11 pp.— Rıcmarpson, H. A new terrestrial Isopod from
Guatemala, the type of a new genus. Proc. U. S. Nat. Mus., vol. 32, pp. 447-
450, 1 fig.— Sars, G. O. Notes supplémentaires sur les Calanoïdés de la

475

476 THE AMERICAN NATURALIST [Vor. XLI

Princesse-Alice. Bull. de Inst. Oceanogr. de Monaco, no, 101, 27 pp.— SKIFF,
F. J. Annual report of the director to the board of trustees for the year,
1906. Field Mus. of Nat. Hist., report ser., vol. 3, no. 1, 108 pp., 17 pls.
— SHIMEK, B. Botany in its tation to good citizenship. Proc. Jo. en
Sci., 1905, vol. 12, 6 pp., 4 pls.— Sumek, B. Flora of Winneshiek Coun
Io. Goi. Kur., 1906, vol. 16, pp. 147-211.— Wırson, C. B. Additional ne
on the development of the Argulidae, with peh of a new species. Proc.
U.S vol. 32, pp. 411-424, pls. 2

TTI DEL Saad INTERNAZIONALE DI a STORICHE, vol. 1.—
BOLETÍN DE LA SOCIEDAD ARAGONESA DE CIENCIAS NATURALES, vol. 6, nos.
2,3 and 4.— BULLETIN OF THE CHARLESTON MUSEUM, vol. 3, nos. 4 and 5.—

AGRICULTURE, bull. 8.— PROCEEDINGS OF THE [INNEAN Society oF NEw
Sours WALES FOR 1906, vol. 31, part 4.— ScHooL Review, vol. 14, no. 5.—
THIRTY-FIFTH ANNUAL REPORT OF THE BOARD OF DIRECTORS OF THE ZOOLOGI-
CAL SOCIETY OF PHILADELPHIA.— THIRTY-SEVENTH ANNUAL REPORT OF THE
EENTOMOLOGICAL SOCIETY OF ONTARIO.— UNIVERSITY OF COLORADO STUDIES,
vol. 4, no. 3

(No. 486 was issued June 22, 1907).

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ASSOCIATE EDITORS
J. A. ALLEN, Pic; Ameren Museum of Natural History, New York
=E. A. ANDREWS, Pa.D., Johns Hopkins University, Baltimore
S. BAYLEY, Pa.D,, Colby Universüy, Waterville
= ‘DOUGLAS H. CAMPBELL, Pu. Da Stanjord University
J.H. COMSTOCK, S.B., Cornell University, Ithaca
WILLIAM M. DAVIS, M. E., Harvard — Sie
ALES HRDLI CKA, M.D., U. 8. National Mus m, Washingt
D. S. JORDAN, LL.D., Stanford U versity
‘CHARLES A. KOFOID, Pa.D., University of California, Berkeley.
=> J. G. NEEDHAM, Pr.D., Cornell Sen, Ithaca
_ ARNOLD E. ORTMANN, Pa.D., C 5
D. P. PENHALLOW, D.Sc., F.R.S. C., a Una: Montreal
EM = k

*

ERWIN F. SMITH, S.D., U. S. Department of en Washington.
. LEONHARD STEJ ‚GER, LL.D., Smithsonian Institution, Washington
Wz TRELEASE, = Missouri ; Botanical Garden, St. Louis

, Lincoln
LER, PaD, RER Museum of ren History

Tue Auerıcan N ns is an ‘Mlstrated monthly magazine
of at oe and will aim reser a, ee

n rn and the Sn; ee s a
h will anne ob ending ea a Er
3 of new disco

veries, reports of =

es on various points of interest, oral: Aas
emis of Tee day iad ee

THE
AMERICAN NATURALIST

Vor. XLI August, 1907 No. 488

OBSERVATIONS ON THE NATURAL HISTORY OF
DIVING BEETLES

JAMES G. NEEDHAM AND HELEN V. WILLIAMSON

Our predacious diving beetles of the family Dytiscide are
fairly well known as museum species, but the study of their life
histories and habits has been singularly neglected. A number
of our genera and a few of our species occur also in Europe, and
the natural history of some of these has been studied there; but
practically nothing has been done in this line in our own country.
Therefore the following observations on the habits and adapta-
tions of the group may serve to direct attention to an unworked
but interesting field.

Dytiscidee are very common at Lake Forest, and are very access-
ible in a campus pond that lies almost under the windows of the
biological laboratory. They illustrate very well the more obvious
phenomena of adaptation, and have been much used by the senior
author for that purpose with classes for a number of years. The
material incidentally accumulated in that work, combined with
special studies of life histories and habits made by the junior
author during the academic year 1905-6, will constitute this paper.

The campus pond (locally known as the “Gym Pond”) from
which our material has mainly been obtained, is an artificial one,
made by damming a short, spring-fed branch of one of the ravines
that bound the campus. It has been in existence for many years,
and conditions in it are now quite natural. It is some sixty meters
long and about half as wide, and it attains a depth of four and a
half meters in its deepest part, near the dam. ‘Toward the other
end it becomes shallow, and is filled with a dense and clear growth

477

478 THE AMERICAN NATURALIST [Vor. XLI

of cat-tails (Typha). There is very little other vegetation in it
anywhere, but the hollows of its shores become filled in autumn
with oak leaves from the surrounding forest trees.

It is in the typha beds of the upper end of the pond, extending
from the shore outward into water of about a meter in depth, that
the diving beetles are commonly found. These beds cover an
area of but little more than a square decameter, but in them we
have found twenty-nine species of Dytiscidæ, as follows, —

*Laccophilus maculosus Germar Hydroporus modestus Aubé
Laccophilus fasciatus Aubé Hydroporus dichrous Melsh.
Laccophilus proximus Say Ilybius confusus Aubé
Hydrovatus cuspidatus Germar *Coptotomus interrogatus Say

*Bidessus lacustris Say Agabus subfuscatus Sharp
Bidessus flavicollis Lec. Agabus disintegratus Cr.
Bidessus affinis Say Rhantus notatus Fabr.

*Celambus inequalis Fabr. Colymbetes sculptilis Harr.
Cælambus punctatus Say Hydaticus piceus Lec.
Cælambus dispar *Acilius semisulcatus Aubé
Cælambus acaroides Lec. Acilius fraternus Harr.
Cælambus nubilus Lec. *Dytiscus hybridus Aubé
Cælambus impresso-punctatus Sch. Thermonectes basilaris Harr.
Deronectes catascopium Say Graphoderes cinereus Linn.

*Hydroporus undulatus Say

No other Dytiscidæ have been found at Lake Forest, except two
that are occasionally cast up on the beach of Lake Michigan and
that we have picked up from the drift line, — Agabus semipunctatus
Kirby and Cybister fimbriolatus Say.

Distribution by Size and Depth of Water.— The seven species of
the above list that are marked with a * are very common and
easily obtained; and being fairly representative of the family,
these were made the basis for the observations which follow.
These fairly represent the striking difference in size that is found
in this family coupled with an almost unparalleled uniformity of
shape (Fig. 1.)

The shoreward distribution of these beetles corresponds roughly
with their size: the largest are found in the deepest water, the
smallest nearest shore. Dytiscus is usually found in the more
open places between the outposts of the typha beds in the deepest

€

No. 488] DIVING BEETLES 479

water, and Acilius is adjacent to it on the shoreward side, although
both (as well as the following species) may range shoreward
foraging. Coptotomus abounds in water about a third of a meter
in depth, and loves to disport itself in the narrow aisles between
the typha clumps. Laccophilus dwells amid the fallen stems and
trashy accumulations nearer shore, and is less in evidence in open
water. Hydroporus and Coelambus love the shoals into which
one can look down while sitting on the bank, while Bidessus clings
to the very shore line: it has nearly always been found by us within
a few inches of dry land.

The larve of these forms show, likewise, a general distribution
in depth corresponding to their size although the larvee keep more

Fia. 1.— Silhouette print of seven adult diving beetles, illustrating the uniformity
of mai and disparity of size agri er in the family Dytiscide: natural size.

, Dytiscus hybridus dag cilit ue semisulcatus pie 3, Coptotomus
ee Fabr hil Germ. ‚ Hydroporus undulatus
Say. 6, Colambus ineauiits Fabr. 7 Bidessus liiir Say.

-

closely to cover of vegetation than do the adults. Dytiscus larvee
are found chiefly in the more open vegetation in the deeper water:
Bidessus larvee, at the shore line: and the others ranged between.
It must not be understood that there is any such definite and
sharply limited zonal distribution as aquatic plants on such a
sloping shore often exhibit: that is not to be expected in animals
possessed of such excellent powers of locomotion: we have meant
to indicate merely the favorite haunts of each species, and the
general correspondence between size of beetle and depth of water.

The accompanying table gives a more precise statement of the
difference in size of the seven common forms of adult beetles
already mentioned. The length was measured with a metric

480 THE AMERICAN NATURALIST [Vor. XLI

caliper rule. Weight was determined with a chemical balance.
Live beetles were weighed inclosed in envelopes of absorbent
paper to remove the excess of moisture; then the weight of the
paper with its contained water was deducted, and the remainder
was divided by the number of the beetles used. By this means
fairly accurate average weights were secured. In the other
columns of the table are expressed with much less accuracy the
comparative excellence of these seven beetles with respect to their
different modes of locomotion.
Order of excellence in

Name Length Weight Swimming Walking Jumping
Dytiscus hybridus 27.6 mm. 1.303 grams 1 7 5
Acilius semisulcatus 14.1 2 6 2
Coptotomus interrogatus 7.9 .033 3 5 3
Laccophilus maculosus 5.5 .0142 4 4 1
Hydroporus undulatus 4.0 .010 5 3 4
Coelambus nubilus 2.9 .0032 6 2 6
Bidessus lacustris 2.0 .0005 € 1 *

The Activities of the Adult Beetles.— There is a very marked
difference in the swimming powers of these beetles. Such forms
as Cybister probably manifest the highest efficiency in the family.
The long beautifully fringed hind legs are moved synchronously;
the flattened and fringed tarsi and the blade-like lower tibial spur
meet the water squarely, and each stroke sends the body forward
several times its own length; whereas the rapid strokes of the
scantily fringed feet of some of the lower members of the family,
little modified in their motion from that employed in walking,
produce individually but little result in forward progress. In
arriving at an estimate of the swimming capacity of the seven
forms listed in the above table the actual distance traversed per
second was determined, and also the distance for each stroke of
the swimming legs. In order to make just allowance for differ-
ences of size, this distance was expressed in terms of length of body.
There was some difficulty in making these measurements, owing
to the extreme rapidity of movement of the legs in the case of some
of the smaller beetles, and owing also to the irregularity of their
movements. In general, the ability to hold a straight course, to
control equilibrium in turning, and to economize effort by elimina-

* Could not be induced to jump at all.

No. 488] DIVING BEETLES 481

tion of useless motions of the fore legs was also taken into account
and the estimated average is expressed in the table. Beetles fresh
from the pond were used in every case.

Walking was compared by turning the beetles out upon a long
sheet of blotting paper before a window, and allowing them to
run toward the light. Excellence at walking was estimated not
so much by speed as by ability to support and propel the body
upon all of the feet. The greatest speed across the paper was
occasionally attained by Dytiscus but it was not walking: it slid
along on its belly, with its hind feet high in air, its front feet reaching
forward, catching the hooked claws and drawing the body after.
Bidessus, however, gets up on its feet and runs like a ground
beetle, freely using all its tarsi. There is in Bidessus none of that
flopping and floundering that characterizes the progression of the
more specialized forms when out of water.

Jumping, in this table, covers any sort of sudden springing
forward in air. The hind feet alone may be used very effectively,
as in Laccophilus which is by far the best jumper of the lot, but
they may also be assisted by the wings. It is not an uncommon
thing to see at the pond a Laccophilus suddenly emerge from some
trash floating on the surface and instantly spring into the air,
using its wings as well as its legs, and then drop on the water and
disappear instantly beneath it: for Laccophilus can take flight
very quickly. The slow and lumbering start of most members of
the family, is not at all characteristic of this beetle. The superior
jumping powers of Laccophilus are explained in large part by the
structure of its legs; especially their equipment of tarsal spines
(Fig. 2 A).

The order of excellence in swimming and walking in this series
of beetles has been determined by classes of students at Lake
Forest for a number of years, and it has always been found as it
stands in our table. ‘The suspicious regularity of the figures raised
some doubts in our minds as to their correctness: so the junior
author went over the work of determining them carefully anew,
with the result that they appear to be entirely confirmed. Doubt-
less such close correlation between size and excellence of swimming
would not hold everywhere among the Dytiscide. Some of the
smaller, more convex forms are very highly specialized. Our

482 THE AMERICAN NATURALIST [Vor. XLI

series of seven selected at first solely on account of availability
and abundance happened to be a most excellent one for illustrating
the law of specialization. Nothing could be clearer than that,
in this series, increasing fitness for locomotion in water accom-
panies increasing unfitness for locomotion on land.

FıG. 2.— A, Ventral view of the hind leg of Se maculosus. r, trochanter.

s, femur, and 2, its prolonged ende angle. t, tibia, and z,itsspurs. 1,2,
3, 4, 5, en segments. ar vn es < rudimentary claw. v,v, v, swimming
fringes. 6,36; 056,6, U

ump
B, Ventral Tini of Coptotomus ELEREN a, antenna, b, mouth. c, c, fore and
iddle coxal cavities. d, labial palpi. e, eye. f, maxillary palpi. g, lateral
margin of pronotum. h, epipleuron. 7, prosternal process. j, bifurcated
intercoxal process of the un in which is st the anterior end of
the en gg groo k, A hind e ; Z, inner a Og PE
laminæ of s ‚m,m, Par of the three erbte segmen
epimera of a ax ee mesothorax. p, the coxal process, and q, m coxa
notch in the right coxal process. g trochanter. s, femur. st!, st2, st3, stern
of the prosternum, m and metasternum respectively. #, oie.
u, tarsus. w, wing ot ee premier trans 1, 2, 3, 4, 6, 6, ventral abdominal
ents,

The Structural Adaptations of the Beetles for Aquatic Life.—
The ancestors of the Dytiscide were doubtless terrestrial, and
probably they were not very different from ground beetles of the
family Carabidae. Coleopterists agree that the association between
these two families is a very close one. If we compare any ground

No. 488] DIVING BEETLES 483

beetle (as, for example, Calosoma) with any of the higher Dytiscidee
(such as Dytiscus) we shall see some marked contrasts in appear-
ance, and some indications of the main lines that have been fol-
lowed in the adaptation of the latter to aquatic life. The body of
Calosoma is loosely jointed; its surface is provided with sensory
hairs and is sculptured; its antenne are prominent and hairy,
and its feet are long and adjustable to every inequality of its path.
Dytiscus on the contrary is compact of body and evenly contoured,
pointed at both ends and naked, with slender hairless reversible
antenne, and stiff oar-like hind feet. ‘There are three main features
of this adaptation, namely an increased rigidity of the body,
diminished resistance to the water, and an increased swimming
efficiency of the hind legs.

The increase in the rigidty of the body has been accomplished
by the compacting and coadaptation of the parts of the external
skeleton. Close conjunction has been effected between the head
and prothorax (through immersion of the head into the front of the
latter); between the several segments of the thorax; between the
elytra and the sides of the abdomen; between the front margin of
the elytra and the prothorax; and between the two elytra along
the dorsal suture: this and the joining with the sides of the abdo-
men combine to make the air chamber inclosed beneath the elytra
water tight. These coadaptations which distinguish the Dytis-
cidæ from terrestrial Coleoptera have been well recognized by
systematists, and are especially well discussed in Sharp’s great
monograph of the family Dytiscide.’ Rigidity is demanded in
the body of a diving beetle as in the hull of a boat. The means
of securing it are most noteworthy in those parts where in other
beetles we find great flexibility, as between the first two segments
of the thorax. This particular articulation can be fully seen and
appreciated only in a disarticulated beetle, some of the coadaptive
structures being more or less concealed by parts external to them.
It is technically described by Dr. Sharp (l. c. p. 219) as follows:

“The coadaptation of the various parts of the posterior aspect of the pro-
thorax, to corresponding parts of the after-body and base of the wing cases is
extremely perfect and very complicated; proceeding from below upward, we
have first, the prosternal proces (Fig. 2 B, i) stretching beyond the meso-

1 On Aquatic Carnivorous Coleoptera or Dytiscidæ. Trans. Roy. Dublin
Soc. for 1882.

484 THE AMERICAN NATURALIST [Vor. XLI

sternum to be received in a metasternal groove; directly above the prosternal
process we see a considerable protuberance or prominence which fits into the
fork of the mesosternum; then come the posterior aspects of the coxæ, which
fit into facets on the face of the mesosternum, and on a still higher level we
have the transverse bridge closing the coxal cavities which fits into the in-
terior of the mesosternum, while on the upper surface we find that the base of
the mesothorax and scutellum are shaped so as to allow the hind margin
of the pronotum to overlap and accurately fit them, while the shoulders of
the wing cases are prominent, and rest on an expansion of the posterior face
of the pronotum which is beautifully sinuate and emarginate to facilitate the
coadaptation. This joining is so perfect in the higher forms, such as Cybister,
that if after the prothorax has been detached from the after-body an attempt
be made to replace it in its natural position, this is very easily effected; and
it will then be found that the prothorax retains its position in spite of con-
siderable efforts being made to dislodge it.”

A diminished resistance to the water has been brought about in
many ways,’ notably by the rounding of the contours of the body
especially at the neck and shoulders, so that it assumes a boat
shaped form}; by the depression of the eyes}; by the loss of hair f
and sculpture; by reversal of the antennæ; by recession of the fore
and middle legs into the concavities beneath the thorax at the sides;
and by the flattening of the hind legs in the horizontal planet.

The increased swimming efficiency of the hind legs has also been
brought about in many ways, the seven most striking of which
are as follows,— the flattening down and soldering fast of the hind
coxæ (Fig. 2 B, k k) to the ventral surface of the metasternum,
transforming what is in other beetles a movable joint into a remark-
ably rigid supporting base; the bringing of the basal joints of the
leg into one plane of action, limiting their movements, but increas-
ing the range of motion in the one horizontal plane; the develop-
ment of braces at the joints to further limit motion to one plane,
making the leg more rigid and oar-like; the shortening of the prox-
imal joints of the leg +; the lengthening of the joints of the tarsus}
accompanied by the flattening of these joints and occasionally
of the tibial spurs as well; the development of swimming fringes

1 The features atc by a dagger in this and the following paragraph
appear to be exact parallels of aquatic adaptations in in mammals, as stated in
Dr. Osburn’s ee article in the American Naturalist for October, 1903
(vol. 37, pp. 651-665). In many other respects it appears that by diverse
means analogous results have been attained. That the changes in body are
not more directly comparable in the two groups is due to the very great dif-
ferences in the nature of the supporting skeleton.

No. 488] DIVING BEETLES 485

in the thin lateral margins of the tarsus; the recurvature of the
tarsi to a more dorsal position, in line with the motion of the center
of gravity of the body +; and finally the loss of the hind clawst.

The modifications having to do with the taking and storage
of air are much less obvious. They consist in the adjustments
of the margins of the elytra (already mentioned for their compacting
and strengthening function) which tend to make a water tight
air-compartment; and in the slight modification of the tracheal
system in a few members of the family (Dytiscus, etc.) manifest
in the enlargement of the hindmost abdominal spiracles to several
times the diameter of the other spiracles. The respiratory appar-
atus of terrestrial beetles has been evidently fairly adequate, and
the main problem has been that of getting through the water with
sufficient ease and speed to capture prey and to escape from ene-
mies.

The Larve Studied.— Five species of larvee of Dytiscidee were
kept under observation. Unfortunately but one of these (Hydro-
porus undulatus Say) was reared to the adult beetle. The others
are here named tentatively, it being possible to make a supposition
as to the genera to which they belong, based on the known fauna
of the Gym pond, on their size, and on their likeness to known
European forms. The largest larvee encountered (41 mm. long)
were those of Dytiscus. ‘These are of the sinuous spindle-shaped
form, well known from being figured in every entomological text
book. We found them in May in great numbers, feeding on
Corethra pupz in the deep narrow straits of open water between
standing aquatics, but they are so well known and they require
such quantities of live food daily, that we did not attempt to rear
them. Of still more snaky form and with an equally good devel-
opment of swimming fringes on legs and the sides of terminal
abdominal segments is the agile larva of Acilius. It is an exceed-
ingly graceful creature, and has a remarkable capacity for dodging
quickly when approached. Our specimens of this form were young
(15.5 mm. long) and their nurture had to be abandoned before any
of them had transformed.

The larvee which we have referred tentatively to Coptotomus
interrogatus (Fig. 3) are but poorly adapted for aquatic life: they
are much more like primitive ground beetle larvee of the family

486 THE AMERICAN NATURALIST [Vor. XLI

Carabide. We obtained numerous specimens in the fall of 1905
when our cages were first started, and these furnished our early
experience. The first lot collected, kept over night in a small
vessel, ate each other; in the morning but one remained. ‘The
second lot, kept over night in a large vessel with plenty of proper
food, did exactly the same. Then we made a screen cage with
separate compartments, set it in an aquarium and put our third
lot into it, one larva in each compartment. These then climbed
out of the water and over the partitions
and ate each other as the others had
done. They did not mind a little ramble
in the open air at all. By this time we
had learned the necessity of covering
the top as well as the bottom of each
compartment: but unfortunately we
were not then able to find any more
larve. This is the more regrettable
because no larve in this endemic
American genus have been made
_known. A description of the larva is
appended to this paper.

We were fortunate in finding in the
spring of 1906 grown larvee of Hydro-
porus undulatus Say (Fig. 4), and in
rearing them. ‘These were taken from
the pond May 20th and were kept in
shallow water in a flat bottomed white

= dish containing a few dead leaves and
A N bits of typha stems. Showing nothing

ede a er ne of the disposition of the larger larvee to
eat each other, we left them together in

the dish and fed them with small fresh pieces of damselfly larvee.
On May 29th four of the larvee were found inactive and curled up
on their backs on the bottom of the dish. These were placed on
damp sand in a dish covered so as to be perfectly dark. ‘They did
not spin, nor make a cell, nor even move from the positions in
which we placed them, but on June 2nd, two of them were found
transformed to soft white pupe of the form shown in Fig. 5 and two

No. 488] DIVING BEETLES 487

days later the other two had transformed. On June 8th, the first
one transformed to the adult beetle. A little later adults of the
same species could be collected commonly from the edges of the
pond.

The minute larvee of Bidessus, apparently grown, were found
so near the close of our

work that there was no
time for attempting to
rear them. They are
here referred to the
commonest species of
the genus from the
same habitat, Bidessus
lacustris.

Habits of the Larve.— The larve, like the adults, are all carni-
vorous. ‘The larger ones are all cannibals: only Hydroporus
and Bidessus among those we have taken, when kept together
refrain from eating each other. We fed the largest larvee on
damselfly and mayfly nymphs, and those of medium size on
Corethra larvee, these being the most
abundant forage available. For all but
the smallest species the manner of feed-
ing is much the same. The prey is
seized alive by the fore legs and the
mandibles are instantly thrust into it
deeply, and it is sucked until nothing
remains but the empty skin. For the
small Hydroporus larvee we were unable
to supply living prey of suitably small
~ size: so, pieces of damselfly larvæ freshly

Fic. 5.— Pupa of Hydropo- cut up for the purpose, were used. ‘These

rus undulatus. .

were seized between the long frontal horn
(Fig. 6) and the upeurved mandibles, sucked for a little while,
then dropped, to be returned to at intervals and seized and sucked
again.

The swimming habits of the different larvee are remarkably
different. Coptotomus (Fig. 3), having little development of
swimming fringes, makes very violent and inefficient movements

Fig. 4.— Larva of Hydroporus undulatus.

488 THE AMERICAN NATURALIST [Vor. XLI

of the legs and abdomen in swimming. When approaching the
surface of the water the head is upward and the body advances
by a succession of irregular shifts (Fig. 7 A, s). It rarely takes a
direct course to the surface, and in water of more than a few inches
depth, it has great difficulty in reaching the surface by swimming.
It can remain below for a considerable time. Of half a dozen
specimens transferred to a fresh aquarium and watched, the first
to reach the surface came up in about four minutes, but went
down again at once: the first to remain at the surface taking air,
rose after twelve minutes: several did not rise for at least seventeen
minutes. In taking air this species hangs vertically from the
surface with legs N extended, and with caudal cerci outspread
upon the surface film
(Fig. 7 A, t). When
it leaves the surface, it
swims downward head
first in an indirect sin-
uous course. ‘The tail
appears not to be used
at all as a fin in swim-
ming. The larve of
Dytiscus are possessed
Fic. Head of larva of Hydroporus undulatus of an excellent swim-
pe ‘from the side. ming fringe along
either side of the terminal abdominal segments, and they use their
tails continually in swimming, lashing them violently back and
forth, up and down. They swim to the surface head upward
(Fig. 7 B, v), but quite as often they float slowly upward with
both head and tail elevated, the former a little in advance, and
with the body bent in a wide U-shaped curve. Usually when
floating thus, bubbles of air may be seen sticking to their bodies.
While taking air they retain this curved position (Fig 7 B, w),
the top of the head as well as the caudal cerci resting in the sur-
face film. These larvee are powerful members of the natural
society in which they live, and are much less easily frightened
than other species. One of them that had been fed regularly for
a few days would allow its back to be stroked gently with a pencil,
and not until poked violently would it swim away: then it would

No. 488] DIVING BEETLES 489

swim very rapidly, as if in sudden alarm, with quick wriggling
movements of its body and tail.

The larva of Acilius although much like that of Dytiscus in
general appearance and in the possession of excellent swimming
fringes, is very different in its habits. It has a peculiar way of
swimming toward the surface tail upward, in a sinuous course as
indicated in the diagram (Fig. 7 C, a) its progress being accom-
plished by very slight movements of its legs. Often one will
start from the bottom swimming forward, then circle about hori-
zontally once or twice, and finally rise to the surface, tail upward,
as just described. This species swims very rapidly, twisting and
turning its long slender body like a snake. When disturbed it

a BN 0
ee z 5 >:

s k ine a Boru
epn o o ?

Fie. 7.— Diagram of swimming habits and attitudes of dytiscid larve. A, Coptoto-
mus interrogatus B, Dytiscus hybridus. C, Acilius sp.? D, Hydroporus undulatus.

darts with a peculiar indescribable motion of the whole body
away from the point of disturbance. Sometimes it makes just
one quick dodge, and sometimes it goes through a series of wrig-
gling movements so swiftly executed that the eye cannot follow
them. This dodging feat must be of great advantage in avoiding
enemies.

The larva of Hydroporus (Fig. 4) has only a scanty develop-
ment of swimming fringes on its legs, and its tail is used merely as
a rudder. It crawls much and swims little. It has a boomerang-
shaped body, which when projected through the water, has a
corresponding motion. It circles about in a vertical plane, its
back to the outside of the curve, as indicated in the diagram

490 THE AMERICAN NATURALIST [Vor. XLI

(Fig. 7 D). Placed in a deep vessel of clear water the Hydro-
porus larvee spend much time swimming about in this manner,
very rarely rising to the surface. During various periods of
observation, none were seen.to remain at the surface taking air:
and during about an hour and a half of continuous observation of
half a dozen specimens together in a large beaker, not one of them
rose to the surface. When kept in a shallow dish of water with
plant fragments, they spent much time crawling about on the
bottom, creeping beneath dead leaves, or hiding in the hollows of
the typha stems.

Supplemental descriptions of hitherto unknown larve of Dytiscide

. Coptotomus interrogatus Fabr. (supposition). Length of larva:
17-18 mm., cerci 2 mm. additional, greatest breadth 2.5-3.0 mm.

Body elongate, rather stout anteriorly: head narrower than the pro-
thorax, which equals the other thoracic and the first four abdominal
segments in breadth: terminal segments of the abdomen tapering.
General color brown above and on legs; below, paler.

Head depressed, the sides parallel for more than half its length, from
the eyes to the spinous margined hind angles, behind which it is con-
stricted to a short neck. Mandibles stout, prominent, channeled nearly
to the base (Fig. 8, g and i). Maxilla with two curved spines upon the
inner face (Fig. 8, a) in a close fringe of short hairs, a sub-cylindric end
segment, a four-jointed palpus and single terminal and dorsal set».
Labium (Fig. 8, e) simple, its body trapezoidal, the anterior margin
double-edged and the edges beset with fine short spinules, the second
joint of the palpus bearing internally a long fine seta. Antenna (Fig. 8,
d) four jointed, simple.

The general color of the head above is brown, with a pair of obliquely
placed transverse pale marks between the bases of the antenne; behind
these, two small clusters of pale dots with yellow ( marks between them
and a pair of larger yellow dots behind them. On the occiput, a pair of
larger ff. marks more or less confluent with the yellow of the hind margin
stands between two more scattered clusters of pale dots, which extend im
a line forward and outward to the eyes: outside these lines of dots is a
yellow oblique stripe on each side above the spinous margined hind angles.

The prothorax is but little longer than broad, its sides are broadly
rounded and its anterior end is constricted to form a short neck. In
coloration it is brown above, with a median double row of more or less
confluent pale dots abbreviated before and behind and not reaching the
ends of the segment, and with a few widely separated, elongate hiero-

No. 488] DIVING BEETLES 491

h
Fie. 8.— Structures of larve of Dytiscide. a, maxilla of Coptotomus interrogatus ?~
, maxilla of Acilius sp.? c, maxilla of Coptotomus us? d, antenna and e,
labium of Coptotomus maxilla of Hydro ndulatus.

interrogatus ? f, 9
inner aspect of mandible, h, fore leg and 7, outer aspect of the mandible of Copto-
tomus interrogatus?

492 THE AMERICAN NATURALIST [Vor. XLI

glyphics on the disc each side. On the succeeding segments, which are
about two thirds as long, there is only one pair of pale submedian dots
and these are placed close behind the anterior transverse carina: and
there are a few pale markings outside these on each segment, the inner-
most one of which each side becomes resolved into a single longitudinal
dash on the abdominal segments. All these markings disappear on the
hindmost segments, which are uniformly deeper brown. The legs are
brown with narrow darker lines across the tips of femora and tibie. The
spiracles are set in the uninterrupted lateral margin of the dorsal shields
on the middle abdominal segments.

The basal abdominal segments are of nearly equal length. The length
increases slightly successively on segments 4, 5 and 6 and rapidly on 7
and 8, each being one half longer than the segment preceding it.
There are a few slender set about the lateral margins of all the body
segments except the hindmost, and that segment is thickly beset all
over its dorsum with short stout spinules. The respiratory tubercle is
short and obtusely truncated: viewed from the side it is conspicuously
and obliquely prolonged over the bases of the cerci. The cerci are about
as long as segments 7 and 8 together, two jointed, the second joint being
about three times the length of the basal one: at the tip of the basal
segment are two or three slender sets, and at the tip of the terminal one
four more.

2. Coptotomus longulus Lec. (supposition). While this study was in
progress the larvze of a second species, so closely similar that it probably
belongs in the same genus, were received from Professor T. D. A. Cock-
erell, collected by him from the Gallinas River, Las Vegas, N. Mexico on
the 12th of Jan. 1902. These are like the ones just described in size, and
in general coloration, though the color pattern is less sharply defined. .
They differ in lacking the curved spines from the inner face of the maxilla
(Fig. 8, c) and in the relative length of the segments of the cerci, the
second being hardly twice the length of the first.

3. droporus undulatus Say. Length 6 mm.; cerci, 1 mm. addi-
tional; greatest width about 1 mm.

Color brown above, whitish beneath. A narrow middorsal line of pale
yellow extends from the middle of the head backward the length of the
body: it is somewhat interrupted by the dark brown posterior margins
of the middle abdominal segments. On the front of the head this pale
line is dilated to inelude three brown spots: a pair of U-shaped spots
between the eyes, the arms of the U’s extended backward, and a median
spot on the base of the rostrum, There is a lateral row of large pale spots
beginning on the side of the head, where it encircles the eye, and ending
on the eighth abdominal segment. These spots are elongate and jagged
on the inner margin on the thoracic segments but rounded and diminish-
ing in size posteriorly on the abdominal segments. The antenne and
legs are pale. In the brown of the rear of the head between the median

No. 488] DIVING BEETLES 493

and lateral spots are three minute yellow dots each side: these are often
confluent.

The dorsal plates of all the body segments are thinly clad with slender
fragile sete: the hind margin of each abdominal segment bears a fringe
of stouter setæ: the fringe is much shorter than the length of the seg-
ment.

The cerci are slender, tapering, longer than the seventh and eighth
abdominal segments taken together: they are studded externally with
thin and scattering set and bear at the tip a little cluster of a few sete,
the central one of which is much stouter than the others and appears as a
prolongation, or as a second tapering cercal segment.

The rostrum (Fig. 6) is as long as the head, broad and obtusely
rounded at the tip, indented just beyond the middle of each lateral margin,
with the broader more flaring edge behind the indentation fringed with
excessively minute and slender setz of which there are several transverse
rows that extend across the dorsal surface.

The coxæ are somewhat longer than the femora. The femora, tibie
and tarsi are armed with stout spinules beneath, and tibiz and tarsi bear
also scanty fringes of longer hairs externally.

The mandibles are long and sickle shaped, and are perforated nearly to
the upturned tips, which rest just beneath the tip of the rostrum. Max-
ille greatly reduced, lacinie and galex being wholly wanting (fig. 8 f).
Labium projecting, mentum narrow, trapezoidal, widened anteriorly, the
slender nearly naked two-jointed palpi arising from the square cut front
border near the outer angles: at the middle of the terminal joint of
palpus are two slender set and four or five arise about the base of the
first joint.

4. Bidessus lacustris. Length 3.5 mm: width .6 mm.

Color grayish brown, faintly marked with grayish yellow, the latter
color predominating on the head and on the hinder abdominal segments.
Body beneath and all appendages pale. The brown of the head and pro-
thorax forms a large dorsal X whose anterior arms end between and close
to the eyes, whose large posterior arms reach backward beyond the middle
of the prothorax and are incurved at their tips. Between them arises
the stem of a T-mark whose top bar occupies the hind margin of the pro-
thorax. Meso- and meta-thorax with an obscure brown mark each side.
Abdominal segments suffused with brownish, and having an indistinct
divided pale transverse bar across each except the last.

The respiratory tubercle of the eighth abdominal segment is triangular
pyramidal, and continues the slope of the sides of the segment to a sub-
acute tip, and is about half as long as the body of the segment. The
cerci are slender and tapering. They are armed with a pair of long sete
externally at one third their length, opposite the tip of the respiratory
tubercle, another single external seta at two thirds their length, and at
the tip is another external one close beside two internally placed and

494 THE AMERICAN NATURALIST [Vor. XLI

similar ones, and a central stouter seta that continues the taper of the
appendage and is attenuate to an excessively slender tip.

The general pubescence of the body is short, dense and seurfy: that of
the legs is shorter and stouter. On the hind borders of the abdominal
segments there is hardly any differentiation of apical fringes.

The rostrum is longer than the head, broad and obtusely rounded at
its tip, where it bears a fringe of very fine close-set set, suddenly broad-
ened opposite the bases of the antenne where the heavy pubescence of
the body begins, and toothed beneath at midway the length of its lateral
margins. The mandibles are somewhat constricted just before the tip
and bear a ring of scattered sete about the constriction.

This larva differs from that of Hydroporus most markedly in the dense
pubescence of its body, in the possession of longer tarsal claws — claws
as long as the tarsus itself, and in the continuity of outline of the sides
of the eighth abdominal segment with the respiratory tubercle, there
being no constriction setting off the latter at its base.

BIOLOGICAL LABORATORY
LAKE Forest COLLEGE

HABITS OF THE SHORT-TAILED SHREW, BLARINA
BREVICAUDA (SAY)!

A. FRANKLIN SHULL
INTRODUCTION.

In January, 1906, in a low tract of land near Ann Arbor, Pro-
fessor Jacob Reighard found upon the snow a number of heaps
of snails of several species of the genus Polygyra (Fig. 1). At his
suggestion and under his supervision I undertook to find what had
heaped these shells and to pursue any further studies suggested by
the discovery. I am also indebted to Mr. Bryant Walker for
identifying a number of snails.

The heaps contained from two or three to more than a hundred
shells. During the whole period of observation five species were
found represented,— Polygyra albolabris, P. multilineata, P.
profunda, P. thyroides, and P. fraterna, in the approximate ratio
of 300: 250:30:1:8. On several successive excursions the num-
ber of shells in individual heaps was counted, and it was found to
vary; shells had either been taken away or added. No marks
were visible in the snow to tell how the shells had been moved,
but there was invariably the opening of a small burrow near the
heap. My problem was to discover what animal was moving the
snails, and also something of its habits.

FINDING THE SHREW.

The presence of a burrow at each heap and the absence of
marks in the snow suggested that the occupant of the burrows was
moving the shells. To determine this point, bacteria dishes were
inverted over each of several of the heaps of snails together with
the adjacent burrow. The snails were found to be moved just as
before. A further test was made as follows: —A heavy wire

x _— from the Zoologieai Laboratory of the University of Michi-

gan No. 1
495

496 THE AMERICAN NATURALIST [Vor. XLI

was passed through a spool and bent down at the ends in the form
of an inverted U. The sharpened ends of the wire were thrust
into the ground. The spool was held in such a position that a
thread unwound from it could easily pass into the burrow. On
the reel thus formed were wound several yards of carpet thread,
to the end of which a snail was tied by means of a hole pierced
through its shell just back of the lip. The shell was then placed
near the opening of the burrow. The thread was marked at
intervals so that it would be possible, without first finding the shell,
to determine how much had been reeled off. At the next visit to
the heaps the thread was found extending into the burrow for
about a foot. The shell was still fast to the string, but had been
broken open and the snail was gone.

Now that I knew where to look for the animal, I began to set
traps. At one place there were two large heaps of shells about a
meter apart, each near a burrow descending abruptly into the
ground. Between these was a well worn path in the snow at the
surface of the ground. Into this path a steel wire trap was sunk
by digging out a bit of the earth, so that the trigger of the trap was
on a level with the bottom of the trail. No bait was used. At
my next visit the trap contained a short-tailed shrew, Blarina
brevicauda. Many of the snails had been removed, showing either
that the animal had for some time escaped the trap, or that another
shrew had carried on the work after the first had been captured.

My work was then ordered according to the following plan:
(1) To discover as many heaps of snails as possible in different
situations, and to record minutely the changes in location of the
shells above ground; (2) As soon as the frost had thawed out of
the ground, to excavate the burrows and search for nests; (3) To
capture in the meantime one or more shrews and confine them in
the laboratory; and (4) To make various psychological studies
in the laboratory and in the field.

OBSERVATIONS ON THE HEAPS OF SNAIL SHELLS.

All my field observations were made in Steere’s swamp, a tract
four miles south of Ann Arbor. It was here alone that the heaps
of snails were found, though search was made for them at other

No. 488] HABITS OF THE SHREW 497

places where the shrew had been taken. The soil of this region
is rich black peat, at many places in a rather early stage of decom-
position. The groundwater level in spring occurs at a depth of
only 15 to 20 cm., so that after even moderate rains the water
stands at the surface in places for several days. Several ditches
have been dug through the swamp. Near these the groundwater
level sinks gradually to the level of the water in the ditch, which
was usually 60 to 70 cm. below the surface at the season when my
observations were made. According to old settlers, the region

Fie. 1.— A he ap of 19 snail shells near the opening of a burrow of Blarina brevicauda.

This ban? is not visible, the large one beyond the heap belonging to another ani-

l. The shells are in a slight depression where the snow has not melted,

was formerly occupied by tamaracks, black ash, and willows.
Since it was cleared a few years ago, nettles, goldenrod, and sumac,
with here and there a thicket of black ash, willows, elder, and
raspberry, have taken the swamp

Apparently the region favors the growth of snails, for they are
abundant. Many live ones were found after warm weather had
set in, and large numbers of empty shells were scattered over the
surface. Within two areas containing the principal thickets and
goldenrod patches of the swamp, each less than 150 meters in
radius, there were found, by careful search, a total of over forty
heaps of shells. The larger portion of these was being moved.
Of those shells that were not being moved, a number were cracked.

498 THE AMERICAN NATURALIST [Vor. XLI

They may have been broken before the shrews began collecting
them; they may have been accidentally cracked in transportation;
or the shrews may have broken them purposely, to render the
snails immobile. This effect was produced by compressing some
snails in a vise until their shells were cracked much like those in
the field. ‘These snails were placed with uninjured ones on moist
earth in a warm situation; the latter were soon crawling about.
Those with broken shells never came out although for three weeks
they contracted in response to thrusts with a stick, showing that
they were still alive.

The shells at the various heaps were either occupied or empty.
The number of both sorts was being increased in certain heaps
which were receiving additions. When, at another time, shells
were being removed from these heaps, only the number of occu-
pied shells was diminished, whereas that of the empty shells re-
mained the same. 'To determine whether this distinction occurred
regularly, a considerable portion of the shells was numbered.
The figures were placed near the base of the columella, since in all
the broken shells that had been observed up to that time this portion
remained intact. At each visit, the numbers of the shells at
individual heaps were recorded, and when they were not too nu-
merous, their relative position was carefully mapped. A record was
kept of the condition of the shells, whether they were occupied or
empty, entire or broken, at the time of numbering. As new shells
were added to the heaps, they were numbered.

From Feb. 15 to Apr. 7, 144 shells found in the field were num-
bered. Of these, 99 were occupied, and 45 were empty, most of
the latter being unbroken. ‘To increase the number under observa-
tion, 25 snails that had been killed in formalin and then transferred
to alcohol were added to the various heaps where the number
of shells was found to vary. At the end of this period of more
than seven weeks, the records showed that the following disposi-
tion had been made of the shells:

No. 488] HABITS OF THE SHREW 499

TABLE I. Showing the number of occupied and empty shells, also snails
killed in formalin, which were removed from the surface. and the
number left at the surface.

Condition of Number of Number of shells Number of shells
shells. shells. removed. left.
Occupied 99 76 23
45 2 43
Formalin 25 7 18

It is seen that most of the occupied shells were removed, although
but few of the empty ones were ever taken away. The formalin
snails show neither extreme, though the majority were untouched.
Apparently the shrews have some method of distinguishing between
an empty shell, a normally occupied one, and a snail killed in forma-
lin. Experiments to determine the basis of this distinction are
described under the head of Psychology.

The numbering of the shells served also to show the relation
between the activities of the shrews and climatic conditions. The
climatic data are from the Observatory of the University of Michi-
gan. Humidity was not recorded but it seems hardly probable
that the absolute humidities possible at the low temperatures that
prevailed would have any marked effect. The temperature
readings on days when field trips were made, and the observations
on the shells for a period of seven weeks are given in Table II.
The shells here included were brought to the surface of the ground
at 21 different points on an area not more than 8 meters in diameter.
Two shrews were eventually captured at this place, and subsequent
excavation of the burrows within this area revealed but one nest.
I have concluded, therefore, that the heaping up and removal
of all these shells was probably the work of a single pair of shrews.
My field trips were made sometimes in the forenoon, sometimes
in the afternoon. I nearly always visited this small area first,
since it lay on that side of the swamp nearest Ann Arbor. I then
passed on to the more distant parts of the swamp, and returned
to the same area some three hours later, again carefully noting
the arrangement of the shells. In only one instance did I find
that any shells had been moved during the three hours, and then
three shells were brought to the surface in the forenoon. From
these facts I have concluded that most of the shells are moved at
night. In the table, therefore, I have given the minimum tempera-

500 THE AMERICAN NATURALIST [Vor. XLI

ture of the night, rather than the maximum or the average. ‘The

Fahrenheit scale is retained as given in the weather records.

The snails killed in formalin which were placed at the burrows in

this area are not included in the counts.

TABLE II. Showing the number of shells at the surface in an area 8 m.
in diameter, and the minimum nightly temperature, for a period of

over seven weeks.
Change in total Change in min-

Minimum Number of shells at number o imum temper-
tempera. surface. shells since ature since
Date. ture°F Occupied Empty Total last visit. last visit.
Feb. 15 2 1 13 74 pay pase
20 30 32 17 49 — 25 +32
22 29 28 18 46 — 3 — 1
24 38 33 18 51 + 5 +9
27 14 146 23 169 +118 —24
Mar. 1 23 118 24 142 — 27 +9
2 26
3 31
4 25
5 23 pa S pai
6 19 72 25 97 — 45 — 4
8 32 52 25 77 — 20 +13
10 25 59 25 84 + 7 — 7
13 16 56 25 81 — 3 —9
15 14 57 25 82 + 1 — 2
20 16 60 25 85 + 3 + 2
24 8 59 27 86 + 1 —8
27 35 29 32 61 — 25 +27
31 25 26 32 58 — 3 —10
Apr. 3 35 24 32 56 — 2 +10
7 37 16 32 48 — 8 + 2

As in Table I it is seen that the number of empty shells was:
never diminished, showing that once the empty shells were brought
to the surface they were not ordinarily moved again. Throughout
the seven weeks there is a steady increase in the number of empty
shells. If the last two columns be compared, it is observed that
on ten of the sixteen days the change in temperature and the
change in the number of shells are of opposite sign, — that is,
with a rise in temperature shells are removed and vice versa.
These ten days include all the most marked temperature changes,
namely, those on Feb. 20, Feb. 27, Mar. 8, and Mar. 27. Similar
to these are the changes for Mar. 1 and Apr. 3. The conspicuous.
exceptions are Feb. 24 and Mar. 31, when, though the temperature:

No. 488] HABITS OF THE SHREW 501

changes are marked, the change in the number of shells is of the
same sign as the temperature change. Further, with the one
exception of Mar. 6, all the considerable changes in the number of
shells occurred at times when the temperature changes were of
opposite sign. On this date there seemed to have been a marked
removal of shells into the burrows, while at the same time the
temperature had fallen. However, five days had elapsed since
the last preceding visit. In this time there had not been a steady
decline of the temperature; but the temperature had risen 8°
between Mar. 1 and Mar. 3, and then fallen 12° from Mar. 3 to
Mar. 6. Had I observed the shells on Mar. 3, the number of
shells might have been much smaller than for Mar. 1, and then
increased to Mar. 6. This seems especially probable since some
of the individual heaps showed an increase on Mar. 6, and others
a decrease. The decreasing effect of the rise of temperature
prevailed.

NESTS AND BURROWS

The Burrows.— The record of the snails was closed Apr. 7.
Though a few occupied shells were still above ground, the weather
was then so warm that several of the snails were found crawling
about. Records of their transportation were untrustworthy after
that time, and were discontinued. By this time the frost was in
large measure out of the ground, and excavation of the burrows
was begun. Two methods were employed. Where the ground
was not very wet, flour was sometimes blown into the burrows with
a small hand bellows. The burrow was then carefully opened as
far as the walls were whitened, and more flour was blown in. If
the ground were wet, the flour soon became moistened and lost
much of its whiteness. A more successful method was to pass a.
rather stiff rubber tube into the burrow to keep it open while the
spade was being used.

Some difficulty was experienced at first in determining which
burrows were those of the shrew. The runs at the surface in
which the shrew was trapped looked exactly like those of the
meadow vole, or field mouse, Microtus pennsylvanicus. More-
over, I have seen Microtus enter burrows that descended abruptly

502 THE AMERICAN NATURALIST [Vorn XLI

into the ground, so that it could not be said with certainty that
even the underground burrows were those of the shrew. Further,
I have found underground nests used by Microtus, notwithstand-
ing the emphasis which Rhoads (1903, p. 100) places on the state-
ment that the nests of this species are built “at the surface.” ‘The
position of any nests that might be found could not then be used
as a safe criterion. Some of the burrows had heaps of shells near
them, which could serve as the criterion if it were known that
Microtus never used snails for food. To determine this point,
two meadow voles were confined in iron cages in the laboratory.
Each was given a vessel of water, and equal care was taken to keep
each cage clean and dry. One Microtus was given corn, wheat,

FıG. 2.— Diagram of a typical burrow of Blarina brevicauda, showing Matribugion
of snail shells; and The
upper figure is a horizontal projection; the lower an ideal vertical section,
The black circles in the upper diagram are points where the burrow descended
abruptly into the ground

crackers, bread crumbs, etc., the other only a few live snails. At
the end of 30 hours the latter Microtus was dead, but the former
lived for several days, when it was removed from the cage. Fearing
that such an early death might have been due to injuries received
in capture, I confined two other voles in similar cages. Each
was given only water and snails. One died in 48 hours, the other
in 56. Later eight voles were captured and kept i in confinement
for a week to insure that they had not suffered injury while being
captured. They were all in excellent condition at the end of this
time. They were then confined in pairs successively, one of each
pair being given its common food (grains, crackers, etc.), the other

No. 488] HABITSOF THE SHREW 503

only water and snails. In each case the one confined with snails
died in less than 48 hours, the other remained in good condition.
From these experiments I have concluded that all burrows with
snail shells in or beside them were at one time used by the shrew.
Taking this as the only criterion at first, I found other features
later which distinguished the burrows of the two animals.

The burrows used by Blarina were usually 25 to 30 mm. in diam-
eter. Those at the surface were exactly like those of Microtus,
running in zigzag fashion under weeds and grasses, often pushing
the latter aside, sometimes crushing them down, crossing and re-

Fic. 3.— Diagrams of two nests of Blarina brevicauda and the burrows near
them, showing po ath ee of snail shells. The upper figure in each case is
a horizontal view; the lower an ideal vertical section.

crossing to form a complex network which in several cases was
easily traced for 30 meters. When the burrows entered the ground,
they did so at a steep angle, as Kennicott (1857, p. 94) has described.
After descending 15 or 20 cm. they became more nearly horizontal,
and passed along between 3 or 4 and 40 cm. below the surface.
Branches were frequently sent off, at almost any angle. There
was no ridge of earth above the burrow, even when the latter came
near the surface, though Stone and Cram (1902, p. 181) mention
such ridges. A typical burrow is represented in horizontal view
and in ideal section in Fig. 2. Usually the burrows returned to

504 THE AMERICAN NATURALIST [Vor. XLI

the surface, rising as abruptly at one end as they had descended
at the other. The two openings of a single burrow were never
found closer together than a meter, and they were occasionally
four meters apart. This fact gives another means of distinguish-
ing the burrows of Blarina from those of Microtus. As far as I
have observed, the openings of an individual underground burrow
of Microtus were never as far apart as a meter, usually not more
than 35 or 40 cm. Microtus burrows, moreover, were not found
to extend as deep into the soil as those of Blarina.

Nests and the Burrows Near Them.— Nests are found along the
course of the burrows. In digging out the burrows some sixteen
nests were unearthed. Some of these were along ditch banks where
the groundwater level was lower than elsewhere. All the others
were in small elevations such as mounds where celery had been
buried or hills thrown up by roots of fallen trees. ‘The nests were
found at depths of 15 to 40 cm. ‘They were
12 to 15 cm. in diameter, and slightly de-

pressed from the spherical form. They were
Barina brevica Excrement of usually made of grass, sedge, and leaves of

nettle, goldenrod or ash, arranged in the form
of a hollow ball, the shell of which was 1 to 3 cm. thick. One
was composed entirely of hair which microscopic examination
showed to be that of the meadow vole. When plant materials
were used, the plants furnishing them were invariably found
immediately adjoining the nest. If grass was near the nest, it
was used almost to the exclusion of other leaves. Coarse mate-
rials were used without being shredded or torn into smaller
pieces. This constitutes an easy distinction between the nests
of Blarina and such nests of Microtus as are constructed of any-
thing larger than grass. In all the nests of Microtus which I
observed, coarse materials were torn apart; sedge leaves 6 to 8
mm. wide were shredded into three or four strips, and corn blades
and leaves of trees were torn into irregular pieces of any size less
than about 2 cm. When the same kinds of material were used in
Blarina nests they were in no way subdivided.

Very rarely, in the vicinity of nests, the excrement of Blarina
was found. In the laboratory, the excrement was piled up in the
corners of the cage, but the only deposits found in the field occurred

No. 488] HABITS OF THE SHREW 505

singly. The excrement was greenish black when fresh, slightly
brownish when dry. It was voided in spindle-shaped portions
25 to 30 mm. long, coiled in various ways, as in Fig. 4. Very differ-
ent is the excrement of Microtus, which is found in black or brown
spindles only 5 to 8 mm. long.

Usually two, three, or four burrows radiated from the nest. At
one nest, however, no burrows could be found. I had followed
an ordinary burrow with a rubber tube until the burrow seemed
to come to a blind end; the tube could be pushed no further in
any direction. Another burrow running obliquely to this one was
then excavated. When I had approached within about 35 cm.
of the place where the first burrow had been abandoned, the second
burrow also was closed. A third burrow approaching the same
spot was next dug open, and it likewise ended blindly. A spade
was set in at the point toward which the three burrows converged,
and at the first spadeful a nest was turned out. The partly eaten
body of a meadow vole near by showed that the nest was then being
used, and was not a relic of the preceding year. Careful search
all round the nest failed to reveal a burrow leading to it. ‘The soft,
loose soil was then carefully dug up to a distance of 40 cm. around
the nest and 20 cm. below it and examined as it was thrown out
to discover the shrew. None was found, so the soil was thrown
back and stamped down. At my next visit a burrow opened to the
surface directly over the former location of the nest, showing
where the shrew had escaped. It had evidently been present when
I dug up the nest, but had escaped my spade. In this case I have
concluded that the shrew was obliged to force its way through
the mass of loose soil for a distance of about 40 cm. every time it
entered or left the nest.

At one nest, in addition to three horizontal burrows radiating
from it, a fourth was traced obliquely downward from the bottom
of the nest, at an angle of about 40° with the horizontal. At a
distance of about 60 cm. from the nest it terminated blindly.

At all but one of the sixteen nests unearthed, snail shells were
found stored beneath and at the sides of the nest. All the shells
at the nests were empty at the time of excavation, between Apr. 10
and June 10. Their number varied from two or three dozen to
166. Empty shells were also scattered at irregular intervals along

506 THE AMERICAN NATURALIST [Vor. XLI

the burrows. Sometimes they were thrust into the soil at the sides
of the burrow in groups of 2 to 10. At other places short branches
led either downward or laterally from the main burrows, and then
expanded into chambers filled with shells, mingled with loose soil.
Such chambers contained in some cases as many as 80 shells.
Generally, all the shells were empty, but one such chamber con-
tained 69 shells, of which 54 were still occupied the last week in
April. In several instances when such a chamber was located
beneath the main burrow, the branch burrow leading to it was
spiral in form, like a winding staircase. One of these is illustrated
in Fig. 2. In two instances empty shells, broken exactly like those
found elsewhere, were found inside nests which, from their com-
position of shredded material and position at the surface of the
ground, must have been Microtus nests.

Method of Burrowing.— The method of burrowing was phactved
and experimented on in the laboratory, where a shrew captured
by hand was kept for some time. When it was first confined,
loose black soil was placed in the cage to a depth of about 10 cm.
Into this soft soil the shrew at once thrust its nose, and by violent
backward and outward strokes of its forefeet, forced its way
through the soil like a wedge. No difficulty was experienced in
burrowing 20 or 30 em. in a minute. ‘The movements underground
were evidenced by the movement of the soil at the surface; but
no ridge was formed above the burrow. When clods were en-
countered, they were readily moved, even if fifteen or twenty times
as large as the shrew and proportionately much heavier.

During the first night a rather elaborate system of burrows
opening to the surface at seven or eight points was worked out.
The aggregate length of burrow was not known, as I did not dig
out the soil, but it included the whole cage which measured 35 by
48 cm.

Some time later the shrew was put into another cage in which
sandy soil had been placed. The same method of procedure was
followed in attempting to make burrows, but small headway was
made. I watched the shrew for half an hour, during which time
it had not succeeded in getting under the surface. The next
morning a burrow 15 em. long open at both ends was found. At
the end of a week there was an aggregate of 55 cm. of burrow

No. 488] HABITS OF THE SHREW 507

with three openings. An extension of 40 cm. had been made from
one of the former openings. ‘This sandy soil had not been packed.
Hence the difficulty in burrowing in it must have been due to its
weight, not to its hardness. In neither the black nor sandy soil
did the shrew loosen the soil with its teeth as Kennicott (1857, p.
94) has conjectured. Neither then nor at any other time during
the confinement of the shrew did I observe any marked surface
runs which the animal was in the habit of following. Instead, it
ran about anywhere in the cage.

Foo».

Dietary of Blarina.— Two articles of food of Blarina have been
so far mentioned, namely, snails and voles. A fair idea of the
extent to which snails are used as food may be gathered from the
data presented in Table II. On Feb. 27, there were at the partic-
ular series of burrows represented in this table 146 occupied shells.
On Mar. 1, one of the two shrews which were found in possession
of the burrows was captured, so that the succeeding work was
that of one shrew. By Apr. 7, all but 16 of these snails, that is,
130 in all, had been removed underground. When the final
excavation of the burrows was made at the end of April, all these
shells were empty. One shrew must, therefore, have eaten 130
snails between Mar. 1 and the last of April.

The only quantitative evidence obtained in the field in regard
to the vole diet was found at the nest mentioned above as having
been made exclusively of the hair of this animal. Beside this
nest, thrust into the loose peat, were the bodies of two freshly
killed meadow voles and that of a third half eaten. In addition
to these there were several handfuls of hair in which were mixed
legs and tails enough for about twenty voles. I could not know
how long it had taken to accumulate this mass. The hair was still
moist, but was packed so close that moisture would be retained a
long time even in the dry soil in which the nest was located.

To determine more accurately the quantity of mice and other
foods eaten by the shrew, experiments were made in the laboratory.
A shrew was kept in confinement for over five weeks, in a wire

508 THE AMERICAN NATURALIST [Von XLI

covered cage in which earth was placed to a depth of about 10 cm.
When practicable, live food was furnished. Among the various
foods tried were meadow voles and house mice (Mus musculus),
May beetles (Lachnosterna) and their grubs, moth larvae, other
insects and pupae, earthworms, snails, sowbugs, carrots, crackers,
roots of grasses and other plants. None of the last three articles
were ever touched as food. If any article proved especially ac-
ceptable to the shrew, that food was furnished exclusively for
several days, and the quantity consumed was noted. From these
figures the average per day was computed. The result in each
of the foods thus tested is given in Table III.

TABLE III. Showing the quantities of various foods consumed by an indi-
vidual of Blarina brevicauda when a single article of food was furnished.
Number of days on
which this food

Number was exclusively Average diet

Article of food. consumed. urnished per day.
Meadow voles 4 6
House mice 3 3 1
May beetles (adult) 77 5 15
May Be ue (larvae) s 2 13
Earthw cm.

shy Peer 142 4 35

Other articles of food were furnished at other times, and some
proved favorites; but owing to the difficulty in securing the food
no quantitative data were secured. Other insects, such as various
ground beetles, giant water bugs (Benacus), and Hydrophilus
triangularis, were furnished. All were eaten, but the ground
beetles were the favorite. Other larvae of insects besides Lach-
nosterna were readily taken, even the “woolly bear” of Pyrrharctia
isabella. Sowbugs were eagerly devoured. When live food was
not to be had, beef was furnished, and was eaten readily. I made
only two stomach examinations. One stomach contained an insect
larva mutilated beyond recognition; the other the remains of a
medior age recognizable by the hairs swallowed with the flesh.
Veg iably rejected, though Professor Reighard
. has captured the shrew in traps baited with nut meats scented with

* Proved insufficient; all were consumed by 11 a. m. on second day.

No. 488] HABITS OF THE SHREW 509

anise oil, and the specimens taken still had fragments of the nut
meats in their teeth.

Method of Capturing Food.— On several occasions I witnessed
the capture of prey. In the case of the voles and the mice, the
attack was essentially the same as described by Merriam (1886,
pp- 166-168) and Morden (1883, p. 283). The house mouse,
being very agile, was not taken in the open, but only when it entered
the shrew’s burrows. I observed this twice. The clumsy vole,
on the other hand, was pursued above ground, cornered in the cage,
and caught. In each case the shrew seized the animal’s ear in its
teeth. After the shrew had been dragged around the cage until its
victim was almost exhausted, it quickly loosed its hold on the
ear, seized the head in the parietal region, and pierced the skull
with its teeth. In two cases the prey was dragged part way into
a burrow after it had been killed. In the third case it was eaten
at once at the surface. The brain and cranium were eaten first,
then the neck and shoulders. The skin was closely cleaned and
rolled back till the tail was reached. The snout, legs, skin, and
tail were left.

Some difficulty was experienced in making observations on the
eating of snails. When beef or mice were furnished, snails were
not touched. Finally, when all other foods were excluded, snails
put in the cage of a morning were devoured before the following
morning, though they remained untouched during the day. Learn-
ing by this means that the shrew would eat snails at that time of
year (early in June), I starved it for a day, then in order to keep
it at the surface put it into a cage with sandy soil, and gave it a
few snails. The snails were large and their shells were hard.
The shrew put its lower jaw into the aperture in an attempt to
reach the snail. Once its forefoot was thrust in. Failing to get
the snail in this way, it set its teeth across the outer turn of the
shell and tried to break it. This it failed to do in my presence,
but later the same shells were found broken. It seems from these
observations that in the case of large shells, breaking is a last
resort. A group of empty shells taken from one of the under-
ground chambers in the series of burrows in which this same cap-
tive shrew was taken is shown in Fig. 5. The group on the left
contains all the unbroken shells. ‘Those on the right were broken,

510 THE AMERICAN NATURALIST [Vor. XLI

being mostly small and immature shells of the same species as
those on the left. These small shells were of course much more
fragile than the mature ones.

From the way in which the attempt to get the snails was begun,
it appears that when the shells are not broken the snails are dragged
out through the aperture. I did not see this done. To determine
whether it could be successfully accomplished, I seized an extended
snail with a heavy forceps and pulled upon it strongly. With
a steady pull the attachments to the shell slowly yielded and the
snail was removed almost entire.

PSYCHOLOGY.

I have described reels which were set at several of the burrows
to determine whether the animal that was moving the snails occu-
pied the burrows. The same reels were used to determine how
the occupied shells were distinguished from the empty ones. The
possible means that suggested themselves were the weight of the
snail, and the senses of touch, sight, and smell.

Muscular Sense.— To learn whether weight was the criterion,
an empty shell was stuffed with sandy soil till it was about as.
heavy as an occupied one. This, with an empty shell and an
occupied one, was placed near one of the burrows. Each shell
was tied to a reel, and all were placed at equally accessible points.
The occupied shell was drawn into the burrow at the time of the
first decided rise of temperature, while the other two were left
indefinitely. The experiment was repeated, but the occupied
shell was so placed that the shrew would have to go round the
empty and stuffed shells and under the reel in order to get it.
The occupied shell was again removed and the other two left.
The experiment was twice repeated at another burrow, with the
same results. Evidently weight of shell is not the determining
feature. It seemed possible that the center of gravity might not
be at the same point in a stuffed shell as in an occupied one, and
that the shrew could detect this difference. Therefore the position
of the center of gravity in a stuffed and an occupied shell was
determined by balancing on a knife edge and by suspension;
it was found to be the same in the two shells.

No. 488] HABITS OF THE SHREW oll

Tactile Sense.—It might be supposed that the shrew would
reach into a shell with its feet and feel whether the snail was there.
I found later that the tactile sense was acute. When the shrew
was running at full speed in its cage and came upon an obstacle,
it invariably stopped short before touching it except with its
vibrissae. ‘The most common obstacle was its water dish, which
was frequently moved about to different places in the cage. I am
not certain that I ever observed the shrew run against the water
dish even immediately after it had been moved. I have seen the
shrew run past masses of such favorite food as earthworms without

Fie. 5.— The mitted en en from a single — storage opps of
Blarina brevicauda. P pneis on the left were en those on right
broken, ein’ mostly i ls of the those on he left.

noticing them, but when a worm in its wriggling touched the tactile
hairs, the shrew turned at once and seized it. To learn whether
the tactile sense was used to determine the presence of a snail in
its shell, I stuffed the apertures of several occupied shells with soil
firmly, so that the snails were out of sight and reach. ‘The external
appearance of one of these shells was to a human observer precisely
like that of a stuffed one, unless it was held up to the light. Then
the central turns of the unoccupied shell into which it was impossible
to force the soil appeared lighter than in the shells containing
snails. The shells with apertures closed with dirt were placed,

512 THE AMERICAN NATURALIST [Vor. XLI

along with stuffed and empty shells, at several burrows. ‘The
occupied shells were again removed, to the exclusion of the others.
Sight.— Blarina has not been accredited with acute vision,
the principal function of its eyes being, as Merriam (1886, p.
165) has supposed, to distinguish light from shadow. ‘To deter-
mine this point at first hand, various tests were made on the shrew
in the laboratory. Objects varying in size from a lead pencil to a
book were waved before the shrew, first at a distance of a foot or
more. No notice was taken of them. The distance was gradually
shortened until the objects almost touched the shrew’s vibrissae,
but still the animal was not disturbed. Once when a cigar box
was thrust violently toward the shrew, the latter shrank back
and immediately turned to face the object. Thinking that the
response might have been due to air currents, I moved various
objects, as cards, boxes, or books, toward or past the shrew in an
oblique position so as to produce currents. ‘The shrew invariably
noticed these although its head was sometimes turned away from
the object. I then blew lightly upon the animal and it turned
toward me and chattered vehemently. I have concluded that, in
the above case where notice was taken of the cigar box, the response
was due to air currents, and that the box had not been seen.
The above experiments were all performed with the cage between
the moving objects and the window. When similar movements
were made on the opposite side of the cage so as to throw a shadow
over the shrew, the animal was at once disturbed. If a large object,
as a book, were used to cast the shadow, the shrew frequently
hurried into one of its burrows. Sight, then, can hardly serve
to distinguish occupied from empty or stuffed snail shells in cases
where a human observer could not discern a difference. The
remaining possible means of distinguishing them is by their odor.
Smell.— When mice or beef were placed in the cage the shrew
almost invariably came out of its burrows in a short time. It
rarely did so when the lid was merely raised and lowered, or when
other objects, as the water dish, were put in. In the case of the
mouse, the response may have been due either to the trembling
of the soil as the mouse ran about, or to the odor of the mouse; but
with the beef, the disturbance of the ground was eliminated.
When the shrew was above ground, it was always going about

No. 488] HABITS OF THE SHREW 513

with its nose slightly elevated and its nostrils dilating and con-
tracting rapidly in unison with movements of the sides of the body,
as if sniffing the air. It is further noted (Table I) that only 7 of
the 25 snails killed in formalin were ever moved from their places
at the burrows in the field. I have concluded from all these observa-
tions that the distinction between empty and occupied shells is
due chiefly to the odor of the snail. Possibly weight is another
factor, for although the experiments showed that weight was not
effective apart from odor, no experiments were performed with

odor apart from weight.

Hearing.— It has been pointed out by both Merriam (1886, p.
165) and Kennicott (1857, p. 95) that the hearing of the shrew is
acute. This was not at once apparent from the shrew that had
been for some time in confinement. It was oblivious to sounds
that were often repeated. It took no notice of footsteps, and con-
versation did not disturb it. Even the slamming of the door did
not at the last appear to be perceived, but slight sounds that I
produced for the first time made the shrew start. Plucking a
taut string within a foot of the shrew produced this result. A
shrill whistle caused it to run into the corner of its cage, though
I was careful not to blow upon it. It started violently when a
strip of metal was drawn across the lip of a tin can near the cage.
Each of these noises when repeated a number of times at various
intervals ceased to produce any effect, even when several days had
elapsed since last producing them. The flutter of wings of a
pigeon kept in the same vivarium, on the other hand, always sent
the shrew scurrying into its burrows. I observed this more than
twenty times, at intervals throughout the five weeks of the shrew’s
captivity, and the last flutter produced as much disturbance as the
first. This particular sound must have been heard hundreds of
times during that period, yet even at the last could not be heard
with equanimity by the shrew.

Effect of Light and Heat.— Sufficient evidence has been offered
that most of the shrew’s work on snails is done at night. Eight
of eleven voles and mice put into the cage of the shrew were killed
at night. Most of the food which was small enough was dragged
into the burrows to be eaten. In my field work I twice saw a
shrew come momentarily to the surface, once in March and once

514 THE AMERICAN NATURALIST. [Vou. XLI

in April. Both days were rather cool, though the sun was shin-
ing brightly. Still more conclusive, at least in regard to heat,
was the behavior of the shrew when brought out to be photo-
graphed in a dish lined with white paper. ‘The animal was exposed
to direct sunlight when the temperature was about 30° C. It
tried at every point to get under the paper lining of the dish, while
its breathing rapidly increased. After some 8 minutes of exposure
it was evidently overcome by heat, and after dancing wildly about
a short time on all fours, lay motionless. Long continued bathing
with cold water was necessary to restore it. It is evident that times
of daylight and even ordinary summer heat are not selected by
the shrew for its greatest activity. On the other hand, even if
there were no direct evidence of daylight activity, the capture of
shrews by hawks (Fisher, 1893) shows that the animals occasion-
ally come out upon the surface by day.

Summary oF PRINCIPAL RESULTS.

1. Blarina brevicauda preys upon various snails of the genus
Polygyra, at least in winter.

2. These snails are hoarded, and are in general moved to the
surface of the ground as the temperature falls and into the burrows
as it rises.

3. Empty shells which are brought to the surface are not moved
back into the burrows. The basis of distinction between empty
and occupied shells is the odor of the snail, or possibly the odor
combined with the weight.

4. Empty shells not left at the surface are stored about the
nests, along the burrows, or in special chambers.

5. Other principal foods are voles, mice, insects, and earth-
worms. Vegetable foods, except nuts, are not employed.

6. The burrows of Blarina brevicauda are similar to those of
Microtus pennsylvanicus, but may be distinguished by the follow-
ing features:

a. The runs of Blarina, when underground, open to the surface
at points more than 1 meter apart; those of Microtus have openings -
less than 1 meter apart. Burrows of Blarina often extend as deep
as 40 cm. into the soil; those of Microtus rarely more than 15 cm.

No. 488] A HABITS OF THE SHREW 515

b. The nests of Blarina are always underground; those of
Microtus are more usually at the surface.

c. Blarina uses all its nesting materials unaltered; Microtus
shreds or tears coarse material.

d. The excrement of Blarina is greenish black, coiled spindle-
shaped, about 25 mm. long; that of Microtus is black or brown,
spindle-shaped, 5 to 8 mm. long.

7. The smell, hearing, and tactile sense of Blarina are acute;
its sight serves merely to distinguish light from shadow.

DISCUSSION.

The short-tailed shrew is easily recognized. It differs from other
shrews by its large size, having a total length of 120-124 mm., by
its short tail (23 mm.), and relatively small feet (hind foot, 15 mm.).
From the common mole and Brewer’s mole, it is distinguished by
its smaller size, and by the absence of digging forefeet; from the
starnosed mole it is further separable by the absence of tentacles
around the snout.

In the field, the work of Blarina is readily distinguishable from
that of either the common or starnosed mole by the smaller burrows,
and the absence of humps of earth which are so characteristically
heaped up by both moles. A further distinction is the ridge of
earth over the burrows of the moles, especially the common mole.
Blarina does not make such a ridge, at least in soft ground.

It has been noted that the runs used by Blarina at the surface of
the ground are precisely like those of Microtus but that the
burrows as a whole differ in several respects. ‘The most interesting
of these differences concerns the material of which the nests are
composed. Shredding or tearing it into pieces would perhaps
make the nest more comfortable and the shrew is fully capable of
thus altering its material. But the shrew is carnivorous and
Microtus is a rodent. To the latter, with its gnawing incisors,
accustomed to dividing and tearing roots of grasses and the bark
of trees, the shredding of nesting material is a natural process.

The collecting of empty shells around the nest of the shrew
seems significant in relation to the origin of the nesting habit.
One nest which I have described was made entirely of the hair

516 THE AMERICAN NATURALIST [Vor. XLI

of the vole, rejected parts of its food. Microtus nests are commonly
made of the husks, leaves, and silk of the corn, or of the chaff
and leaves of the wheat which it devours. It is easy to conceive
that in this way the nesting habit of the shrews also originated.
If this be true, the use of grass, leaves, and sedge, now so common
among the shrews, must be a secondary modification, since these
articles are not rejected food materials.

The fact that in the laboratory the shrew did not make any
defined runs at the surface, suggests that it may not make any in
the field. If this is true, the runs which it occupies were probably
made by Microtus. They may have been entered in pursuit of
game, and when the original owners were captured, their burrows
were appropriated. The finding of broken snail shells in Microtus
nests seems to support this view, since Microtus does not eat snails.
The shells must have been carried thither on a foraging expedition,
and devoured in the nest of the vole. To what extent the runs used
by Blarina have been appropriated by it has not been determined.

Many of the shells found around the nests of Blarina, in under-
ground chambers, and in the burrows, were shown by the numbers
painted upon them to be those which were previously heaped at
the surface. The snails, therefore, were being hoarded, and
used gradually. Bachman (1837, p. 370) mentions that beetles
are hoarded by shrews of the genus Sorex, and Merriam (1886, p.
169) thinks it probable that Blarina stores food. Dahl (1891)
has found masses of earthworms, having their anterior segments
injured, in the burrows of the European mole; but Adams (1903,
p. 14) thinks they merely fell in and could not get out,— he does
not explain the injury of the anterior segments. ‘There is no
mention of hoarding among shrews on as large a scale as this of the
snails seems to be. It has been noted that the snails were carried
out on top of the ground in considerable numbers when the
temperature fell markedly, and were taken back in equally
large numbers when there was a marked rise in temperature.
The snails seem to be kept in the coldest place available. In
cold weather this is above ground; in warm weather, in the bur-
rows. ‘Though the temperature in February and March never
rose high enough to render the snails active, yet some of the snails
at the burrows referred to in Table II were still at the surface

No. 488] HABITS OF THE SHREW 517

early in April when it was warm enough for them to crawl. This
may have been due to the fact that my first shrew was captured
at this set of burrows, so that only one shrew was left to devour
the snails originally intended for two. Bodies of Microtus were
hoarded but were not transferred to the surface. This again
indicates that the cold storage serves to keep the snails immobile
rather than to prevent decomposition.

Too little has heretofore been known of the short-tailed shrew
to make an estimate of its economic importance practicable.
Stomach examinations are almost wanting, my own work including
but two. However, from data concerning the quantities of food
in laboratory and field, I have attempted an estimate of the eco-
nomic importance of Blarina. ;

Three principal elements determine the economic value of a
species, namely its range, its abundance, and the character and
quantity of its food. Of the range of Blarina, Rhoads says (1903,
p- 192): “Atlantic Ocean to Nebraska and Manitoba; Quebec
to Virginia.” ‘This is practically the northeastern quarter of the
United States. Of its abundance, the same author says (p. 193):
“This species stands preeminent above all others of our mammals
in its combined abundance and universality of distribution in all
conceivable situations. Not a place have I trapped over in the
two states but what it was among the first species to be caught.
It is found in our deepest, coldest mountain ravines, on the stormy,
barren mountain top, in the banks and valleys of low tidewater
streams and maritime marshes, and delights in roving from the
cool sphagnum bogs of the N. J. cedar swamps where the temper-
ature may be below 60° to the hot sand barrens of the adjoining
fields with a mid-day heat of 110.° Forest and plain, sand and
clay, barren or fruitful field, back woods or door yard, heat and
cold, wet and dry, day and night, have common charms for this
cosmopolite.” It is difficult to conceive of the shrew in some of
these situations after having observed its almost futile attempts
to burrow in heavy, sandy soil that was not even compacted.
Yet numerous records attest its presence in these situations.

Montgomery (1899, p. 572) has used the number of skulls of
different mammals found in the pellets of owls to determine the
relative abundance of the animals. Shrews necessarily came far

518 THE AMERICAN NATURALIST [Vor. XLI

down the list, because few were captured; and he found that
Blarina parva is more abundant than B. brevicauda. It seems to
me that the small number captured is due to the fact that they are
underground most of the time, rather than to their rarity. From
my own observations, assuming that a pair was present at each
nest that was being used, as I found to be the case in two instances,
there were at least two pairs to the acre over the region studied.
This number should be easily maintained for, according to Rhoads
(1903, p. 195), they produce four to six young at a litter, and
breed the year round.

The quantity of food eaten in a month has been estimated as
follows: From Table III was computed the quantity of each item
which would have been consumed in a month had that article
alone been furnished. For example, one month’s rations of voles
alone would be 20; of house mice, 30; of adult May beetles, 450;
and so on. It has already been stated that 130 snails were eaten
by one shrew between Mar. 1 and Apr. 31. However, since the
moving of the snails by the shrew had practically ceased by Apr. 7,
it seems probable that the snails were eaten in a little over one
month. Moreover such other foods as insects, earthworms, and
voles were available at the same time, so that the snail diet was not
the total. It seems reasonable to assume that 120 snails alone
would make one month’s rations, since that is more nearly the
equivalent of 20 voles.

The distribution of the dietary among the different articles is
largely a matter of judgment, and in Table IV the quantities are
based on the relative abundance of the various items in the swamp
region studied. For example, voles were abundant, and have
been allowed to constitute 40% of the diet. Earthworms, on the
other hand, were comparatively rare in the peat of the swamp,
and have been allowed but 5%. The table of course represents `
only a sort of average for the year. Snails are evidently eaten in
much greater numbers during several months of the winter, when
the insect diet is necessarily limited. The snail diet is probably
less in upland situations, though Charles A. Shull, of Kentucky
University, tells me he has found the characteristic heaps of snail
shells, all Polygyra thyroides, about the openings of small burrows
in high land near Lexington, Ky. This was probably the work

No. 488] HABITS OF THE SHREW 519

of Blarina. In other situations than the peaty swamp, the earth-
worm diet is probably greater than I have estimated. In pro-
portion as other foods not here included are employed, the
quantities in the table will be diminished.

TABLE IV. Showing estimated quantities of various staple foods devoured
by a single Blarina brevicauda in one mont

Per cent.

Estimated num- of total

Article of Food. er eaten. rations.
Meadow voles (or equivalent in mice) 8 40
Adult insects (of the size of oe 90 20
Insect larvae (of the size of Lachnosterna) 78 20
Earthworms (4 em. long in praia condition) 53 5
Snails 18 15

Estimating the number of shrews as I have done at four per
acre, it appears that the number of meadow voles devoured by
them on a farm of 100 acres in a year is 100 x 4x 12 x 8 =38400.
Since this number can scarcely be supplied, the capacity of the
shrews for keeping the voles in check is not strained. Where
this quantity of voles can not be found, either other foods must
be eaten in equivalent amounts, or the shrew is capable of sub-
sisting on shorter rations, or the estimated four shrews per acre.
can not exist. Farmers should take note of the economic value
of Blarina. In their zeal to rid their premises of noxious animals,
they sometimes kill indiscriminately anything that looks like a
mouse. One of these animals evidently kills many more voles in
a year than the farmer himself. The shrew even compares
favorably, from the economic standpoint, with the common owls.
Montgomery (1899) examined the pellets of four long-eared owls
for a period of two months, and found that these birds had de-
voured 347 small mammals, mostly Microtus. This is an average
of 43 per month for each owl. Blarina devours 20 voles per
month, or an equivalent in insects, most of which are even more
destructive than the voles.

With abundance of food, it might be expected that the race of
short-tailed shrews would become very numerous. But other
forces are at work maintaining the balance of nature. The in-
vestigations of Fisher (1893) show that six species of hawk and six
species of owl capture the short-tailed shrew. Two other species

520 THE AMERICAN NATURALIST [Vor. XLI

of owl capture shrews but the species of shrew is not stated. Mont-
gomery (1899) found the skulls of shrews in the pellets of the long-
eared and the short-eared owl. ‘The number of shrews taken,
however, is relatively small. For example, Fisher (1893, p. 53)
found in 562 stomachs of the red-tailed hawk 45 specimens of
shrews. Of these one third were short-tailed shrews, taken in
10 individual stomachs. In 39 stomachs of the barn owl (p. 139)
5 specimens of shrews were found, among which was Blarina.
Montgomery (1899, p. 566-567) found that out of 347 skulls of
mammals taken from the pellets of the long-eared owl, only one
belonged to Blarina. ‘These figures show that the item of shrews
does not count very heavily against the hawks and owls in esti-
mating the economic value of these birds.

The subject of bird enemies of the shrew recalls the disturb-
ance produced in the laboratory by the fluttering of the pigeon’s
wings. The sound was probably recognized as a familiar one by
the shrew. This accounts for the fact that the animal never
became oblivious to this particular sound.

Surface (1906, pp. 155, 160, 189, 197) has found shrews in the
stomachs of four species of snake, though in small numbers. In
at least one case he was able to identify the specimen as Blarina.
Rhoads (1903) and Stone and Cram (1902) state that small mam-
mals are captured by foxes, minks, weasels, and skunks. In
several instances they mention shrews among the number, but in
no case is specific mention made of Blarina brevicauda. Dicker-
son (1907, p. 356) records that three specimens of Blarina brevi-
cauda were found dead in the fallen nest of a red squirrel. She
believed them to have been killed and stored there by the white-
footed mouse. This mouse is well known to utilize deserted nests,
among others that of the red squirrel, but whether it kills shrews
is doubtful. It appears to me more probable that the shrews had
been killed by larger beasts of prey and rejected, possibly on ac-
count of their odor (Rhoads, 1903, p. 193; Stone and Cram,
1902, p. 182), and had then been picked up by the whitefooted
mouse. This mouse is said by Stone and Cram (1902, p. 132)
to glean after other hunters.

From bird enemies the shrew can escape to its burrows. From
those enemies that can pursue it in its burrows, some other means of

No. 488] HABITS OF THE SHREW 521

escape must be employed; perhaps it pushes out into the loose
soil. ‘The instance of the obliquely descending burrow at one nest
suggests the “bolt run” by which the European mole is said to
escape when its fortress is attacked (Adams, 1903, p. 13). This
burrow, however, was probably not a back door escape, since it
ended blindly and the shrew did not enter it at this time of attack.

The short-tailed shrew is so well protected from its enemies that
no animals appear to depend upon it for food. It is abundant
and widely distributed. In security it devours such quantities
of voles and insects that its economic importance is considerable;
and since, unlike the other common shrew, Sorex personatus, it is
almost exclusively carnivorous, there is little to detract from its
economic value. i

UNIVERSITY OF MICHIGAN
Ann ARBOR, MICHIGAN

LITERATURE CITED

BacHMAN, J.
1837. Journ. oj the Acad. of Nat. Sci. of Philadelphia. Vol. 7, pt. 2.
Kennicort, Rost.

1857. The Quadrupeds of Illinois Injurious and Beneficial to the
Farmer. Rep. of the Commissioner of Patents for 1857. Agricul-
ture.

Morpen, J.

1883. Canadian Sportsman and Naturalist. Vol. 3, p. 283.
Merriam, C. H.

1886. The Mammals of the Adirondack Region. Henry Holt. 316 pp.
Dant, Fr.

1891. Die Nahrungsvorräthe des Maulwurfs. Zool. Anz. Bd. 14,
pp. 9-11.

Fisuer, A. K.

1893. The Hawks and Owls of the United States in their Relation to
Agriculture. U.S. Dept. of Agric., Div. of Ornith. and Mammal.,
Bull. No. 3.

Montcom_ery, T. H., Jr.

1899. Observations on Owls with Particular Regard to their Feeding

Habits. Amer. Nat. Vol. 33, pp. 563-572.

922 THE AMERICAN NATURALIST [Vor. XLI

STONE, W., AND Cram, W. E.
American Animals. Doubleday, Page and Co. xxiii + 318 pp.
Apams, L. E. -
1903. A Contribution to our Knowledge of the Mole (Talpa europæa).
Mem. and Proc. of the Manchester Lit. and Phil. Soc. Vol. 47,
No. 4.
Ruoaps, 8. N.
. Mammals of Pennsylvania and New Jersey. Philadelphia.
Published privately. 266 pp.
Surrace, H. A.
1 The Serpents of Pennsylvania. Pennsylvania State Dept. of
Agric., Monthly Bull. of the Div. of Zool., vol. 4, nos. 4 and 5.
Dickerson, Mary C.
1907. The Pageant of Nature. Country Life in America. Vol. 11,
p. 356.

NOTES AND LITERATURE
GENERAL BIOLOGY -

The Philosophical Problem of Life Dr. Verworn, Professor of
Physiology at Göttingen, has recently published a lecture upon the
investigation of life, delivered before the society of political science
at Berlin. At the outset he states that the search for a cause in
biology is unfruitful and unscientific. ‘There is no process in the
world which is determined by a single cause. Every process is always
dependent upon a number of other processes and it is unjustifiably
arbitrary to select one of these and to account it the first cause....
A scientific investigator can only establish the several conditions
which are necessary for the occurrence of a process. If these are
known, the process is accounted for,— explained. The process is
nothing more than the expression of the sum of the concomitant con-
ditions. The conception of cause becomes therefore superfluous and
worthless

Accordingly one must regard as superficial such affirmations as.
that an insect is colored green because it is thereby protected, or
that a mammalian embryo has gill clefts because its ancestors did.

From the study of the conditions of life Professor Verworn concludes.
that,— “ To produce life artificially we must know completely all
the elements of the living substance. We must know the relative
amounts. We must understand their arrangement in the cell body.
If we could construct such a system, fulfilling all the conditions of life,
the artificial cell would at once live. It would certainly be extremely
interesting to see how the artificial organism would live, reproduce,
and transmit its qualities— but the prospect of producing life is.
a complete Utopia. We have not learned to approach the complex
conditions involved in a living organism....The chemical fabric of
a cell should first be so understood that it could be imagined as a great
machine shop, in which the mechanism of life could be observed by
wandering among the atoms as among wheels and cylinders.’

Consciousness also is held to be a product of these conditions. If,
according to DuBois-Reymond, we could bring together at once and
in their proper relations all the atoms of which Cesar was composed

1 Verworn, M. Die Erforschung des Lebens. Gustav Fischer, Jena, 1907.

PE,

45 pp. 1Mk. 80
523

524 THE AMERICAN NATURALIST [Vor. XLI

when he crossed the Rubicon, we should have reconstructed Cesar,
body and soul. The artificial Caesar would have the same sensations,
aspirations, and ideas as his predecessor at the Rubicon. Both con-
sciousness and life, therefore, are the expression of definite conditions to
determine which is the object of scientific investigation.

Professor Verworn here ascribes as a cause of consciousness an
unknown arrangement of atoms. A more conservative opinion has
been expressed by an American biologist, as follows,’ — “The work
of physiologists has been so devoted to the physical and chemical
phenomena of life that the conviction is widespread that all vital
phenomena are capable of a physical explanation. ...Let us give up
the ineffectual struggle to discover the essential nature of consciousness
until we can renew it with much larger resources of knowledge.

In regarding the construction of a living cell as a complete Utopia,
Professor Verworn differs from Professors Le Dantec and Cresson.
The former writes,” — “‘Our knowledge of colloids is still so recent
and rudimentary, that we ought not to expect to see the making of a
cell accomplished soon; but it will come some day by careful analysis,
permitting a rational synthesis....The scientific world today is so
prepared for the discovery that the premature announcement of spon-
taneous generation in gelatine submitted to the action of radium
surprised no one. . . . It is not necessary for an enlightened mind to see
protoplasm badi to be convinced of the absence of any essential
difference, — any real discontinuity, between living and dead matter.”

Professor Cresson,’ after quoting Büchner that “doubtless some
day it will be possible to form living protoplasm artificially,” adds, —
“Such a hope is at least somewhat reasonable and probable.” When,
however, it is considered that nowhere in nature are such conditions
known to be realized at present, and that the conditions in the past
when life arose are equally unknown, one is inclined to accept Professor
Verworn’s characterization, — a complete Utopia.

It is unnecessary to refer further to Dr. Le Dantec’s volume, which

was published some months ago in English, and has been frequently
reviewed. Dr. Cresson’s more recent volume is a simple introduction
to naturalistic philosophy. The author describes the development

1 Minot, C. S. The problem of consciousness in its biological aspects.
Science, N. S. vol. 16, 1902. pp. 1-12.
2 Le Dantec, Félix. Éléments de philosophie biologique. Félix Alcan, Paris,

i r. 50.
‘ Cresson, André. Les bases de la philosophie naturaliste. Félix Alcan, Paris,
1907. 179 pp. 2 fr. 50.

No. 488] NOTES AND LITERATURE © 525

of natural science and its conflict with the “old geocentric and anthro-
pocentrie philosophy which seduced and satisfied our ancestors... .
Science has descended upon this philosophy like a tempest and nothing
is left. The earth is not the center of creation. Man is not an excep-
tion in the universe. ‘The adaptation between living things and their
environment is explained by evolutionary principles without supposing
an intelligent creator.” In the preface, philosophy is said to be a
matter of temperament. “For some, naturalism is the final word of
true metaphysics; for others, it is devoid of all truth.” In this way,
perhaps, the author acknowledges, that there are many who see in
evolutionary principles the manifestation of an intelligent creator;
and who find in man, though one animal among many, much that is
exceptional. It is stated by Professor Cresson that naturalistic
philosophy is not science, though suggested by it. The determination
of the conditions of life, as described by Verworn, is science itself.

Te ka

The Capitalization of Specific Names.— It is agreed that the name
of a genus shall always begin with a capital letter and that the specific
name shall usually begin with a small letter. Zoologists are inclined
to begin specific names invariably with small letters, but botanists
employ capitals for a variety of purposes as shown in the following
examples:

Zoological Names. Botanical Names.
a. Sitta canadensis Juncus Ca
b. Lampetra wilderi Smilax Walteri
c. Gastropacha ilicifolia Lythrum Hyssopijolia
d. Bernornis isabellae Rosa Beatricis

Whatever reasons exist for beginning these botanical names with
capitals apply with equal force to the zoological names; and the advan-
tages of the invariable rule for lower case letters are no greater in zool-
ogy than in botany. Moreover, as expressed by the Vienna Congress
of botanists, — ‘The principles and forms of nomenclature should
be as similar as possible in botany and in zoology.” In the matter
of capitalization of specific names, one rule should apply to both. In
order to determine upon a uniform practice for the Naturalist (in
which botanical and zoological names should appear with equal fre-
quency) the editor examined the following codes.

1842. A committee of the British Association, appointed “to con-
sider of the rules by which the Nomenclature of Zoology may be
established on a uniform and permanent basis,” presented various

526 _ THE AMERICAN NATURALIST [Vor. XLI

“Recommendations for improving the nomenclature in future.”
Among theseis § C. “Specific names should always be written with a
small initial letter, even when derived from persons or places, and
generic names should always be written with a capital.”

1865. The British Association code was revised, and although the
rule for small letters had been very generally adopted, the section relat-
ing to it was omitted. ‘The revised code stated that “It is not a matter
of great importance and may be safely left to naturalists to deal with
as they see fit.”

1881. The Société Zoologique de France stated,— ‘‘ Every one
agrees that the name of the genus should be written first and begin
with a capital letter. For the specific names, there is also unanimity if
they are common nouns or adjectives, —a small letter is used. Should
proper nouns and adjectives be treated in the same way? Some per-
sons adopt and recommend the practice. Your committee considers
that the question is of very minor importance. It believes that it
conforms to the most generally established usage in recommending
the capital, which is not inconvenient, and may in fact, in certain
cases, be a useful distinctive mark.”

1881. The rules of the International Geological Congress at
Boulogne, in regard to the nomenclature of species, merely state that
“the rules of Latin orthography are to be followed.”

1886. In the code of nomenclature adopted by the American
Ornithologists Union, Canon VIII states that “proper names of
species, and of subspecies or ‘varieties, are single words, simple or
compound, .... written with a small initial letter.”

1893. The Deutsche Zoologische Gesellschaft adopted a code
containing the following note to § 10. “It is very desirable to write
not merely all adjective but also all substantive specific names inva-
riably with small letters.”

A committee of the International Zoological Congress
framed a code containing Art. 13.— ‘‘While specific and substantive
names derived from names of persons may be written with a capital
initial letter, all other specific names are to be written with a small
initial letter.

1905. At Vienna the International Botanical Congress adopted
the following recommendation. Chap. III., Sect. 4. Recommenda-
tions. X. ‘‘Specifie names begin with a small letter except those
taken from names of persons (substantives or adjectives) or those
which are taken from generic names (substantives or adjectives).”’

1907. The nomenclature commission of the Botanical Club of the

No. 488] NOTES AND LITERATURE 527

American Association for the Advancement of Sciences rejected
various fundamental principles of the Vienna code and framed an
‘American code’. Part 3, § 1, art. 3 reads,— “If capital letters are to
be used for specific names they should be employed only for substan-
tives and for adjectives derived from personal names. his is
followed by the curious example Uromyces Trijolii, and in another
place the specific name Tulipifera is capitalized.

The examination of these codes shows that the most radical rule
was that of the British Association in 1842, and that this was subse-
quently cancelled. Nevertheless the progress toward its adoption
seems constant. The botanists have ruled against capitals for nouns
and adjectives denoting places (example a in the list). Since a very
large number of botanical names are of this sort, the progress toward
decapitalization is considerable. Capitals for personal names are
recommended by the botanists, small letters by the German zoologists
and American ornithologists, and both forms are sanctioned by the
international code of the zoologists. The botanists are alone in recom-
mending capitals for specific names derived from those of genera
(example ce). Under this rule a person unfamiliar with the genera
of plants must refer to an authoritative botany to ascertain the capitali-
zation,— thus a zoologist would not expect to find Datura Stramonium
and D. Tatula capitalized. Should a botanist desire to refer to a
zoological species, however, a check list need not be consulted regard-
ing the capitalization. Since no single practice can conform with all
the codes and yet a uniform rule is obviously desirable, the Naturalist
will capitalize specific names only at the request of a contributor;
the invariable use of small letters is recommended. It is to be noted
that the Vienna code allows choice in this matter. Chapter I, Art. 3,
states that ‘‘the rules of nomenclature should be neither arbitrary nor
imposed by authority,— they must be simple and founded on con-
siderations clear and forcible enough for every one to comprehend and
be disposed to accept.” !

1 Since this was written the University of Missouri has issued The Flora of
Columbia Missouri. The specific names derived from places are capitalized
contrary to the Vienna code. The confusing nature of the capitalization is
apparent from the following examples,— Leonurus Cardiaca, Apocynum hyper-
icifolivm, Robinia Pseudacacıa, Vernonia pseudobaldwinii. The corrigenda
inelude,— for Achillea millefohum, read A. Millefolium. Potentilla Norvegica
of the text is indexed as P. norvegica. In Dr. Cockerell’s Bees of Boulder
County, Colorado, also just received, all specific names of plants visited by the
bees are written with small letters, e. g. (p. 243) Linum lewisii. This is the
practice which the Naturalist adopts.

528 THE AMERICAN NATURALIST [Vor. XLI

The opinions of the botanists who are associate editors of the
Naturalist, upon the capitalization question are as follows:

“] shall be very glad to follow the practice of lower case spelling
for specific names in conformity with zoological usage.”

“I am not very positive in my opinions of right and wrong on
the capitalization question. I am going to try to follow the Vienna
practice as consistently as possible. The zoological decapitalization
has some valid arguments against it. In its favor is the fact that no
knowledge is required on the part of those who adopt it, other than
that the specific name chosen is to be used. I should suppose that
for the Naturalist a uniform practice for the different departments of
biology would be adopted, and the line of least resistance would be
uniform decapitalization. Any proof-reader is then competent to
correct all deviations.”

c. “I have no decided opinion on the subject. My instinct is to
use capitals for adjectives derived from proper nouns, as it somehow
does not look right to me to see them spelled with small letters. I have
no objection to offer if it seems best to adopt the uniform rule of small
letters for specific names.”

“Botanists should follow the international code. Personally
I come near it, that is, I write names derived from persons with capi-
tals, e. g., Goldoni Lewisi, and names derived from other proper nouns
with small letters, e. g., Goldoni pennsylvanica. American scientific
men (some of them) seem never satisfied to do things in nomenclature
the way the rest of the world does. Really we ought to write G.
Lewisi, and G. Pennsylvanica following the genius of the Latin lan-
guage.”

In order to know whether. Latin usage had any bearing upon the
question at issue, the last sentence in this quotation was referred to
Dr. A. A. Howard, Professor of Latin at Harvard College, who wrote,
— “There are no ancient rules whatever for the use of capital letters
in Classical Latin. Our earliest manuscripts are written throughout
in capitals, and so are all inscriptions. When the minuscule letters
were introduced, the capitals were sometimes, but not always, used to
begin a sentence or paragraph, apparently only as a sort of embellish-
ment. Proper names are written in small letters down to the time
of the introduction of printing. Therefore it is absurd to talk about
the genius of the Latin language in this connection. All rules for
capitalization are of modern origin, necessitated by the invention of
printing. It is customary for each country to follow, in writing Latin,
the rules governing the language of the country, though German
writers not infrequently begin Latin sentences with small letters.”

No. 488] NOTES AND LITERATURE 529

e. “The question of capitalization of specific names has given me
much concern, and I should be very glad were it possible to reach
some practice which would be acceptable to all zoologists and botanists.
At the present moment no less than three rules are in use by botanists.
Personally I see no good reason for capitalizing any specific names.
and my preference is decidedly in favor of following the practice of
the zoologists. Some botanists consistently adhere to the rule of no
capitals and they are right. In adopting this rule, you would make
the Naturalist the exponent of a uniform practice for all biologists,
and would, I feel sure, gain the support of many botanists.”

da

ANTHROPOLOGY

Handbook of American Indians North of Mexico.'— The volume
at hand is the first of the two parts of a most important and generally
useful work, dealing with the North American Indian and prepared
under the auspices of the Bureau of American Ethnology. The work
is an encyclopedia of the Indian, dealing in alphabetical order, with
every phase of his life as well as with his anatomical, physiological,
and indirectly also with his mental characteristics. Preparations:
for this publication have been carried on since 1873, and since 1902
the task has been in the hands of a special editor. The second volume
will probably appear in the course of the coming winter.

The work is the result of contributions of forty-six authors, special-
ists in various branches of anthropology throughout this country.
Every article in it has not only been carefully supervised by the able
official editor of the book, Mr. Hodge, but has also been sent for read-
ing and suggestions to all the contributors. Moreover, there were
held at the Bureau of American Ethnology, under the chairmanship.
of Professor W. H. Holmes, for many months, regular meetings
three times a week, to which all the authors were invited, and where
all the more important papers were read and freely discussed. The
result, great credit for which is due to Professor Holmes, the Chief of

1 Hodge, Frederick W., editor. Handbook of American Indians north of
Mexico. Part 1. Bur. of Amer. Ethn., bull. 30, Washington, 1907. 972 pp.,
with a map and numerous illustrations.

530 THE AMERICAN NATURALIST [Vor. XLI

the Bureau of Ethnology, besides to the editor, is a compilation of brief
but comprehensive, simply worded and well illustrated, authoritative
articles, which represent the substance of our actual knowledge of
the Indian. A further perfection and possibly extension of the subject
matter will be attended to in future editions.

The work will prove in general a satisfactory reference book on the
North American aborigines, and a valuable handbook on the subject
in higher schools and colleges. It has, with its other merits, the dis-
tinction of being the first work of its nature in existence. The bib-
liography, though mostly restrieted to synonymy, according to the
original plans of the work, is nevertheless ample and will facilitate the
researches of special students.

Among the authors contributing to this work are Miss Fletcher,
Chamberlain, Fewkes, Kroeber, Gatschet, Cyrus, Thomas, Hewett,
Boas, Cushing, Colville, Hodge, Hrdlicka, Hough, Dorsey, Mason,
McGuire, Mooney, Swanton, Dixon, Culin, Matthews, Hewitt,
Grinnell, Henshaw and others.

Among the individual articles may be mentioned Abnaki, Acoma,
Adoption, Adornment, Agency System, Agriculture, Anatomy, Anti-
quity, Architecture, Arrows, Bows & Quivers, Art, Atlantis, Axes,
e

tC.
The first volume embraces the letters A to M inclusive.
. A. HRDLICKA.

Games of the North American Indians.— In a large volume *
Stewart Culin presents “a classified and illustrated list of practically
all the American Indian gaming implements in American and European
museums, together with a more or less exhaustive summary of the
entire literature of the subject.” The many amusements of Indian
children, such as “tag,” which are played without implements are not
within the scope of his compilation, and dolls are not included. None
of the games described as Indian were imported into America; on
the other hand “we have taken their lacrosse in the north, and racket
in the south, and the Mexicans on the Rio Grande play all the old
Indian games under Spanish names.” Certain games, however,
strikingly resemble those of the Europeans, and with various modifi- —
cations the same game is played throughout the continent, by tribes
belonging to unrelated linguistic stocks.

_ 1Culin, Stewart. Games of the North American Indians. Bur. of Amer.
Ethn., 24th Ann. Rep., Washington, 1907. ` pp. 1-846, 1112 figs., 21 pls.

No. 488] NOTES AND LITERATURE 531

Games of chance are described first. Dice in the form of banded
sticks, plum stones, small bones, or ivory figures of birds or mammals
(which count for the player whom they face after being thrown) were
widely used. A second class of games of chance includes those in
which a small stone or other object is hidden in moccasins or under
wooden cups, suggesting the illicit “shell game.” Forfeits ranged
from arrows to horses, and the games were sometimes played far into
the night.

Games of skill include archery, various ball games in some of which
racing is involved, and the game of sliding darts along the hard ground
or ice toward a mark. Like the dice game, hoop and pole with many
variations was played throughout the continent north of Mexico. A
hoop twined with a network like a spider’s web was rolled along the
ground and darts were thrown at it, the count being determined by the
hole penetrated. It was played by men only, but the lighter game of
ring and pin was played also by women and girls. A perforated or
penetrable object, such as a rodent’s skull, attached to a cord was
swung in the air and caught upon a pin or dart fastened to the other
end of the cord. The most elaborate of the games of skill is that
which resembles lacrosse. It was sometimes played between the
young men of different villages, there being thirty or more players on
a side. Among the many training regulations there is one which for-
bids the eating of hares since they are timid creatures. Ceremonial
dances precede the game; each side has its conjurer and the spectators
are numerous. The players are dressed only in girdles and ornamental
tails of hair or feathers. ‘They are armed only with rackets but in the
scrimmages of the game bones are occasionally broken.

“Games of pure skill and calculation such as chess are entirely
absent.” The minor amusements, briefly described in this volume,
include whip tops, cat’s cradles, bull roarers, swings, stilts, and others.
The author concludes that the games are “instruments of rites or have
descended from ceremonial observances of a religious character.”
The myths with which they are associated are as widespread as the
corresponding games, which are not only for amusement but to drive
away sickness and avert evil. The book is admirably arranged for
reference. With the picture of each implement there is generally a
vivid account of its use by an eye-witness. The author has written
only the necessary introductory passages and summarizes the conclu-
sions of his eight hundred pages in eighteen lines.

FFE

532 THE AMERICAN NATURALIST- [Vor. XU

ZOOLOGY

Oogenesis in Insects— It is a much debated question whether
the sex or germ cells are set apart at the outset of embryonie
development or arise later by modification of certain of the somatic
or body cells. The continuation of Marshall’s studies on the anatomy
and embryology of the wasp Polistes pallipes* treats of the early
history of the cellular elements of the ovary. The author finds that
in the embryos and very early larvee, each undifferentiated ovary is a
syncytium with a number of nuclei similar in structure. In the course
of development oocytes, primitive nurse-cells, and follicular epithelial
cells are developed from the undifferentiated cells of the distal end of
the egg tube. In a similar study of a Phryganid ? he found that the
first differentiation had taken place in a fairly old larva. At this
stage the cells may be either “1st, undifferentiated or, 2d, passing
through the first stages in the development which is to result in the
further differentiation of oocytes or nurse-cells. Cells of the first
group may either remain unchanged and become the epithelial cells-
or they may pass through the same stages as those of group two.”
Thus Marshall believes that the sex cells arise late and have a common
origin with certain other cells in the ovary.

These results agree essentially with those of the earlier workers,.
notably Korschelt, ’86, on the history of the germ cells of insects, but
are in sharp contrast to the results of Heymons ’95, Lecaillon ’00-01,
and many other recent workers who contend that the germ cells are im
origin perfectly distinct from the follicular epithelium.

W. A. RLEY.

Parthenogenesis of Bacillus rossii.—The theory that each body cell
contained both male and female constituents, and that the egg cell in
becoming mature gave off its male elements in the second polar body
has also been much discussed. This idea was supported by finding
that the second polar body was not given off from certain eggs which

1 Marshall, Wm. S. ’07. Contributions towards the embryology and ana-
tomy of Polistes pallipes. II. The early history of the cellular elements of
the ovary. Zeitschr. wiss. Zool. Ixxxv; pp. 173-213, pls. 12-14.

2 The early history of the cellular elements of the ovary of a Phryganid,.
Platyphylax designatus Walk. 1. c. pp. 214-237, pls. 15-16.

No. 488] NOTES AND LITERATURE 533

developed parthenogenetically. According to Baehr, the walking
stick Bacillus rossii must be added to the list of parthenogenetic species
in the development of which the second polar body is formed, and the
first divides in two. ‘There is no evidence of their functioning further
for they apparently degenerate and disappear.

Contrary to a generally accepted belief that parthenogenesis in this.
species quickly leads to degeneration, the author reared perfectly

ealthy females from at least the ninth parthenogenetic generation.
Apparently only females are produced,— it is a case of normal thely-
toky.
WA E

Phagocytosis.— By means of a clever technique Mercier? has been
able to throw new light upon the much debated question as to the
nature of the phagocytes in the batrachians and the insects. On
injecting sterilized, powdered carmine before the beginning of meta-
morphosis he found that it was taken up by the leucocytes and that
leucocytes thus marked were yet capable of phagocytosis. ‘Through
this method he was able to demonstrate beyond a doubt the active
participation of the leucocytes in the degeneration of the muscle
fibers. In the case of the batrachians the muscles exhibited signs of‘
degeneration at the time that the leucocytes entered but in the case of
the fly Calliphora such signs were not to be detected microscopically.

e fiber becomes broken up into sarcolytes which are engulfed by the-
phagocytes. There is no such phenomenon as the formation of
myoclasts and consequent autophagocytosis. The author was able
to demonstrate with equal clearness the active participation of the
leucocytes in the destruction of the fat body of Calliphora and to dis--
tinguish them from the so-called “pseudonuclei”’ of Berlese.

WAR:

Histolysis in Queen Ants.— Janet? has studied in queen ants, the
degeneration of the wing muscles, which begins very soon after the-

! Baehr, W. B. v. 07. Uber die Zahl der Richtungskörper in partheno-
genetisch sich entwickelnden Eiern von Bacillus rossii. Zool. Jahrb, Anat.
xxiv pp. 174-192. Pl. 16.

2 Mercier, L. 06. Les processus phagocytaires pendant la metamorphose -
des batraciens anoures et des insectes. Arch. Zool. exp. et gen., 4e ser., t. v
pp. 1-151, pls. 1-4.

® Janet, Ch. Histolyse, sans phagocytose, des muscles vibrateurs du vol,.
chez les reines des Fourmis. C. R. Acad. Sci. Paris. exliv, 1907, pp. 393-196.

534 THE AMERICAN NATURALIST [Vor. XLI

nuptial flight. This histolysis does not begin simultaneously or
advance with equal rapidity in all of these muscles and hence among
fasicles apparently intact may be found those in which the degener-
ation is in various degrees of completeness or even terminated. Janet
states that throughout the process there is no phagocytosis, or ingesting
of solid particles by leucocytes. The wing muscles are finally com-
pletely replaced by adipocytes which, he believes, arise from leucocytes.

Notes on Entomological Literature— The Green Pigment of
Locustide.— Podiapolsky * has studied both the chemical and the
spectroscopic peculiarities of the green pigment extracted from the
w me of Locusta viridissima. He was able to separate a yellow and

reen pigment completely parallel to, if not identical with, the xan-
thophyil and the chlorophyllan of plant-green. The paper is very
suggestive as regards methods.

W. AUR.

Inner Metamorphosis of the Trichoptera—— Much as the caddis
flies have been studied from the biological and the systematic view
point, comparatively little is known regarding their histologic struc-
ture, and practically nothing concerning their inner metamorphosis.
Lubben’s extended contribution? is therefore especially welcome.
The author discusses the changes in the respiratory system, the sexual
organs, and the alimentary canal. e work has not been limited
to a single species but treats of a wide series and brings together many
interesting details.

W.AH.

Starving out the Codling Moth.— Under this caption Fabian Garcia
of the New Mexico Agricultural Experiment Station issues a call to
fruit growers to exterminate the codling moth in a single season!
The late frosts of last April left little pome fruit in the territory: if
fruit growers will but cooperate in the destruction of what little re-
mains (which will all be worthless anyway because all will be wormy)
and will destroy also all wild rosaceous fruit and walnuts, the codling
moth, being deprived of its food, will be eradicated. The optimism

a Podiapolsky, P. ’07. Uber das grüne Pigment bei Locustiden. Zool.
Anz. xxxi pp. 362

? Lubben, H. ’07. Über die innere —— der Trichopteren. Zool.
Jahrb. Anat. xxiv, pp. 71-128, pls. 11-1

No. 488] NOTES AND LITERATURE 535

of the plan, its faith in the applicability of laboratory results by the
public, undaunted by the contemplation of the inertia of the human
species, is delightful.

ox Ate N

Fossil Insects — The four parts of Handlirsch’s Die Fossile Insec-
ten* now at hand (640 pages and 36 double plates) suffice to show
that this is a work of first importance to every student of fossil insects.
In bringing together and making accessible descriptions and figures of
practically all the known fossils (at least, in the older strata, thus far
treated), and in correlating the fragmentary knowledge of them with
keen morphological insight, the author is rendering good service.
Though not all his more radical changes in groupings are likely to
prove acceptable, and though the multiplicity of new groups of all
` grades will seem at first confusing, all will agree that the collective
result of the work is substantial progress. Hitherto few monographers
of insect orders have noticed the fossil representatives of the orders.
There will be less excuse for the neglect of the paleontological evidence
in the future.

J. Go N;

A Catalogue that is in part a Monograph.— The sons of the late
Baron de Selys Longschamps of Liege are building a worthy monu-
ment to the memory of their father in the issuance of a catalogue of
his zoological collections. The first number that comes to hand (Fas-
cicle xvii, Cordulines, by M. R. Martin) shows that this, for the Odon-
ata at least, is to be a great monograph. This small subfamily of
dragonflies containing fewer than 140 species, is described on 94
quarto pages, illustrated by 99 (mostly multiple) text figures and three
colored plates. The text figures are admirably executed and are
sufficient for all practical purposes. The colored plates add little of
real value, although they greatly increase the cost of the work. To
every special student of the dragon-flies, this work will be indispen-
sable because of its comprehensive character and its general
excellence.

d. G. N.

1! Handlirsch, A. Die Fossile Insekten, und die Phylogenie der rezenten
Formen. Leipzig. Wilh. Engelmann.

536 THE AMERICAN NATURALIST [Vor. XLI

Berlese’s Entomology.— Fascicles 21-22 (pp. 585-648) of Berlese’s
magnificent work? are just at hand. They conclude the discussion
of the nervous system and begin that of the organs of special sense.
Like the preceding fascicles these are not mere compilations but are
rich in new facts for the student of insect morphology.

W. A: R.

BOTANY

The Fungi of Termite Nests.— We are accustomed to think of
Belt’s classic observations on the leaf cutting ants of South America
as the beginning of our knowledge of the relationships between ants
and fungi, but Petch ? assures us that Sweathman in 1781, nearly a cen-
tury before Belt’s discoveries, stated that in tropical Africa some species
of termites had chambers in their nests in which grew a kind of fungus
used by the ants as food. Although the “fungus gardens” of the true
ants of tropical America have been quite fully described, we have had
until the present time no comprehensive treatment of the similar habits
in the termites of the Eastern Hemisphere. Petch brings together
and tests by his own extensive studies of the Ceylonese species, the
scattered observations on this subject.

Ceylon does not afford such variety of form and size of termites as
Australia and Africa, but the nests of Termes redmanni and T. obscuri-
ceps, the only two species which Petch studied, are abundant every-
where except in the highest districts. 'The ant hills, roughly conical
in form, are only about six feet high. Their upper portion is con-
tinued into one or more hollow conical structures called chimneys.
The form of the nests varies greatly; they may slope gradually to the
top of the chimneys, they may branch into several chimneys or they
may have a solid apex and bear the chimneys at the side. They are
built of earth and grains of sand brought up from the interior of the
nest and cemented together by a secretion of the termites. A large
portion of every nest is underground. In the early stages of develop-
ment the presence of a nest is usually indicated by three or four chim-

1 Berlese, A. Gli insetti, loro organizzazione, sviluppo, abitudini e rapporte
coll, uomo. vol. 1. Milan. Societá Editrice Libraria.

2 Petch, T. The Fungi of Certain Termite Nests. Ann. Roy. Bot. Gard.
Peradeniya, 3: 185-270, pl. 5-21. 1906.

No. 488] NOTES AND LITERATURE 537

neys 10 —20 cm. high, surrounded by the scattered earth brought up
in excavating the underground chambers. In fact in some cases the
nest is entirely under ground and the chimneys are wanting. Reasons
for the differences have not been found.

Internally the nest is composed of numerous chambers roughly
oval in shape, 5-25 cm. in diameter and 5-15 cm. in height, connected
by numerous galleries sometimes as much as 1 cm. in diameter but
generally only large enough to permit of the passage of two or three
insects at once. Similar galleries connect the chambers with the chim-
ney. For a discussion of the purposes of this structure the original
paper must be consulted. Some idea of the extent of the underground
system of these nests may be gained from ‘experiments which Petch
made; in one case water was run in for two hours from a pipe deliver-
ing 15 gallons per minute but this was quite fruitless so far as filling
the opening was concerned.

The chambers, except the royal cell, are generally nearly filled
with a structure designated as the comb. This is a grayish or brown-
ish mass, traversed in all directions by a labyrinth of anastomosing
galleries, and closely resembling in general appearance a coarse bath
_ sponge. The combs lie free in the chambers, leaving a clear space of
2 to 3 cm. between them and the roof and the sides. ‘The comb sub-
stance is built up of closely packed balls of about 0.75 mm. in diameter,
composed of finely divided vegetable substance. Under the micro-
scope irregular pieces of ringed and pitted vessels, up to 250 microns
in length, may be seen, as well as tracheids, sclerenchymatous cells,
and the hyphae and spores of Halminthosporium, Diplodia, etc., all
imbedded in a ground substance from- which all structural detail
has disappeared. The fact that the same substance is found in the
intestines of the workers and soldiers, taken in connection with the
regularity of formation of the comb from the small pellets, shows that
this is made up of the excreta of the termites. It will thus be seen that
the comb itself is not of fungus origin.

The surface of the comb is given a grayish or glaucous appearance
by the presence of a thickly woven mat of fungus hyphe. From this
mass of hyphz small stalked spheres arise by the combination of
several threads into an upright stalk; these hyphe branch repeatedly
above and finally give rise to conidia. ‘These are the “conidial forma-
ations” which have been described by all students of the fungi of termite
nests. Injured spheres or stalks from which the conidia have fallen
are never found on the comb, and it would seem that the termites in
eating them must consume them at a single bite.

538 THE AMERICAN NATURALIST [Vor. XLI

Some have suggested that this fungus is one which is found in the
neighborhood of the nests on decaying wood and that it is introduced
into the nest accidentally by the termites, but in an extensive investi-
gation of the fungi of Ceylon in which large quantities of dead wood
passed through his hands, Petch was never able to find any form at
all similar to that in the nests.

Occasionally an agaric also develops from the comb. This species
is the chief edible form of Ceylon and so generally is it esteemed that
it is difficult to obtain perfect specimens, for the natives who collect
them for food do not secure the long stipe intact and unfortunately
they do not overlook many examples. This fungus has never been
found growing from the hill itself but is always produced from the
underground portions of the nest. ‘The comb from which it develops
may be as much as four feet underground but the most of Petch’s
specimens were found to grow from combs nearer the surface. The
connection of the agaric with the hyphe described above has not been
demonstrated. Efforts to germinate the spores or to grow the sphere-
producing mycelium from the tissue of the agaric have proven unsuc-
cessful. It is not improbable, however, that they are stages of the
same species. At first the agaric forms brownish-white, somewhat
conical, tomentose columns 3 to 5 mm. in diameter and 1 to 2 cm. in
height; in some cases Petch found as many as fifty of these on a single
comb. All the developing agarics reach this stage but only one forms
a Pluteus; the others cease growth before they reach the roof of the
chamber and it has been found impossible to cause them to develop
farther by experimental methods. This peculiarity of the species
renders it almost impossible to obtain other than the mature and the
very earliest stages. It has not been found possible to cause a normal
comb to produce the agaric by artificial treatment, and after it has
borne one, another will not be produced. No results have ever been
obtained by digging in the nests at random in search of the intermediate
stages; when the mature fruiting body has appeared on the surface
no more may be expected from the same comb and it does not indicate
that the other combs of the same nest are in a state in which they may
be expected to produce agarics. The termites have been known to
consume the stipe up to the surface of the ground and then to stop the

opening. This agaric has been assigned to several genera, Lentinus,
Collybia, Pluteus, Pholiota, and Flammula; Petch considers it a
modified Volvaria. It has never been found when it could not be
traced to the termite nests.

A second agaric seems sometimes to develop from the termite comb,

No. 488] NOTES AND LITERATURE 539

but probably only in wet weather. In this species a number of stipes
may develop from the same comb.

If a piece of fresh comb be removed from the nest and placed under

a bell jar the spheres will decay if the insects have been removed but
both spheres and external hyphe will be eaten if the termites remain.
In the course of two or three days after the surface of the comb has
been freed from these, small groups of erect hyphee, indistinguishable
from those which give rise to the agaric, but apparently derived from
the interior of the comb-substance, appear and grow rapidly into tall
thin structures resembling the conidial forms of Xylaria. Petch has
carried on a large series of cultural experiments with this form and
concludes that it is probably X. nigripes. The termites eat this too
as it develops. After continued rain X. nigripes grows from deserted
nests.
Besides these forms, Mucor, Thamnidium, Cephalosporium, and
Peziza sometimes grow on combs removed from the nests. Since none
of these are found in the nests, though some of them are capable of
growing underground, it seems probable that the insects “weed out”
undesirable fungi as they develop.

Although it is known that the termites will eat the fungi it is not
definitely proved that they form the food of the insects. The two
species studied prefer fungi, or wood which has been attacked by
fungi. Whether a difference in food is a factor in the differentiation
of the termites into workers, soldiers and sexed insects is not decided.

The author observes that the mycelium of Entoloma microcarpum
is composed of spheres of swollen cells which in detail resemble the
termite spheres but are not so highly developed. He thinks that the
spheres of the termite nests and the “Kohlrabihäufchen” of the
leaf-cutting ants investigated by Möller are parts of a normal mycelium
and that their form has been little, if at all, modified by the insects.

J. ARTHUR HARRIS.

The Longleaf Pine.— Schwarz’s The Longleaf Pine * is an attractive
little volume, describing in a popular style the silvics of Pinus palustris,
the valuable hard pine of the Southern States. The subject matter
is considered under nine main headings which cover the character
of the virgin forests of this tree and their natural rotation, the tolerance
of the species, its relation to injuries by fire, insects, cattle, and swine,
its rate of growth, and its technical forest management.

1 Schwarz, G. Frederick. The Longleaf Pine in Virgin Forest, a Silvical
Study. New York, John Wiley & Sons, 1907. 12mo, xii+135 pp., illustr.

540 THE AMERICAN NATURALIST [Vor. XLI

The longleaf pine is characteristic of the so called Southern Pine
Forest, and occurs principally in a belt some 125 miles broad, from
Virginia south and west along the coast to within a short distance of
the Mississippi River, and in southeastern Texas. The chief type
is that of a pure forest. Owing to various destructive causes, these
forests are largely in groups of different ages. A second, mixed type
is found farther inland, and is largely determined by differences in the
composition of the soil. Here the longleaf pines occur on the hilltops
while farther down, on the richer or damper slopes are the oaks,
hickories, and other deciduous species, with shortleaf and loblolly
pines.

The natural course of evolution of the longleaf pine forest and its
method of reproduction are briefly sketched. The species is intolerant
of shade and requires direct overhead light, since the dense terminal
clusters of leaves shade the buds from side light.

The chief danger to which the southern forests are subject, is doubt-
less fire, hence this is treated at considerable length. ‘The fires in
longleaf pine forests are exclusively surface fires, which not only
destroy the young seedlings in the grass, but injure the butts of the
older trees, causing often considerable damage. The frequency of
fires, set either accidentally or purposely for burning over grass lands,
makes imperative the employment of rangers and the construction of
fire lanes about commercial forests. As a rule, seedlings of one or
two years’ growth are destroyed by surface fires, but older plants
usually escape total destruction by virtue of their thick bark and the
dense head of long needles that not only protect the terminal bud but
form a miniature fire screen by hanging down about the short stem
to the ground. Frequent fires will, however, kill even these older
seedlings, to say nothing of their destructive action on the humus.

The future silvicultural treatment of these forests is considered in
Chapter 8. The forest must be perpetuated as well as exploited.
Cutting to a diameter limit of 16 inches has been recommended.
In some cases, a method of clear cutting with reserve trees left for
seeding the cut over area will probably be found good. The aim of
future management will also be partly to bring these forests into a
more uniform condition instead of their present great irregularity.

Although more extended tables as to rates of growth and volumes
might have been added, this little book will no doubt serve its purpose
in helping the lumberman and the general reader to a better under-
standing of the proper study and treatment of our southern pine
forests. The volume is handsomely printed and fully illustrated.

G. M. ALLEN.

No. 488] NOTES AND LITERATURE 541

Purple-producing Bacteria.'— ‘The Purpurbacteria’ make an inter-
esting group with certain characteristics differing from the majority
of these plants. Many bacteria, in fact most of them, grow best in
the absence of light, but the group of the Purpurbacteria grow best
or as well in its presence. Most pigment-producing bacteria show
color production best or only in the free access of oxygen — the group
under consideration have the opposite characteristic that they produce
their color best or only in the absence or in a diminished supply of
oxygen. The color of most bacteria is outside of the cell, but with
this group it is in the bacterial cell for the most part.

The author has brought together the known facts in regard to this
group, has added some new methods of cultivation, and has contributed
descriptions of a number of new varieties isolated by himself. He has
furthermore studied more fully the action of light and other conditions
on their growth and pigment-producing powers, so that the physiologi-
cal characteristics of the group are clearly presented in detail. The
plates include two of photomicrographs of some of the new varieties
described in the text, a presentation of the appearance of bacteriopurp-
urin crystals from one of them, the color scheme of bacteriochlorin
and bacteriopurpurin — the first in alcohol and the second in bisul-
phuret of carbon — and a number of absorption spectra of the pig-
ments from different members of the group. The book is an interesting
and important contribution to the study of the subject.

H. C. Ernst.

GEOLOGY

Rate of Recession of Niagara Falls.— Bulletin 306 of the United
States Geological Survey, which has recently been issued,’ is of much
interest to the layman as well as to the student of geology. G. K.
Gilbert traces the early development of the ideas that the falls are

! Die Purpurbakterien nach neuen untersuchungen. Eine mikrobiologische
studie von Prof. Dr. Hans Molisch: Direktor des pflanzenphysiologischen
institutes der K. K, Deutschen Universität in Prag. Mit 4 tafeln. Jena, Ver-
lag von Gustav Fischer. 1907. pp. vii, 95, Octavo.

? Gilbert, W. K. and Hall, W. C. Rate of Recession of Niagara Falls (by
G. K. Gilbert) accompanied by a report on the survey of the crest (by W.
Carvel Hall). Bull, U. S. Geol. Sur. No. 306, 1907. pp. 1-31, 11 plates, 8
figures,

942 THE AMERICAN NATURALIST [Vor. XLI

receding upstream, that the gorge below the falls is the result of this
recession, and that it would be possible, by sufficiently accurate obser-
vations, to determine the rate of recession. He then discusses the data
upon which computations of the rate of recession must be based, con-
sisting of surveys of the crest-line of the falls made in 1842, 1875, 1886,
1890, and in 1905; and camera-lucida sketches made in 1827. After
considering the relative accuracy of the different surveys and sketches,
and platting the results together, the author concludes that a gradual
recession of the Horseshoe Falls is demonstrated, while a much slower
rate of recession is indicated for the American Falls. These changes
are strikingly represented by contrasted photographs and sketches
made from the same view-point, but many years apart.

Concerning quantitative results of the study, the author points out
that the available data may be treated in a variety of ways, and made
to yield widely divergent results. The lack of harmony is due in
part to inaccuracies in the surveys, some of which are unavoidable;
and in part to the fact that the rate at which the limestone crest breaks
away is necessarily irregular. Too much confidence should not,
therefore, be placed in exact mathematical expressions of the rate of
recession. In general, however, the evidence proves a recession of
about 5 feet a year with a possible error of not more than 1 foot, for
the Horseshoe Falls, in the sixty-three years from 1842 to 1905; and
a recession of less than 3 inches a year for the American Falls, in the
seventy-eight years from 1827 to 1905.

The time consumed in the total recession of the falls from their
former position near Lewiston is not considered in this report, except
that the author briefly notes some of the many variable factors which
must be taken into account in estimating such time. A short report
by W. Carvel Hall on the latest survey of the crest line of the falls is
appended to the paper.

A sprinkling of “reformed” (one is tempted to say “deformed’”)
spelling throughout the paper occasionally distracts the reader’s
attention from the matter itself to the manner in which it is presented.

D, W. JoHnson.

PUBLICATIONS RECEIVED

From June 1 to July 1, regular exchanges not included
The year of publication, when not otherwise noted, is 1907

Cresson, A, Les Bases de la Philosophie Naturaliste. Paris, Felix Alcan,
1907. 178 pp. 2 fr. 50.— Horper, C. F. Half Hours with Mammals. New
York, American Book Company, 1907. 12mo, 253 pp., illus. 60 cents.—
KoRScHaLT, E. Regeneration und Transplantation. Jena, Gustav Fischer,
1907. 286 pp., 144 figs. : "Mk. — MorıscH, H. Die Purpurbakterien. Jen
Gustav Fischer, 1907. 95 pp., 4 pls. 5 Mk.— Verworn, M. Erforschung
des Lebens, 1907. Naturwiss. Wochenschrift, ba 22, no. 18; printed sepa-
rately si Gustav Fischer, Jena, 1907. 45 80 Pf.

New and characteristic species a fossil mollusks from the
pen Tertiary pee of southern California. Proc. U. S. Nat. Mus.,
vol. 32, pp. 525-546, pls. 3 See Bartscu, P. A new parasitic mollusk of
the genus Eulima. Proc. s S. Nat. Mus., vol. 32, pp. 555-556, pl. 53.—
CLARK, A. H. A new species of crinoid (Ptilocrinus pinnatus) from the
Pacific . with a note on Bathycrinus. Proc. U. S. Nat. Mus., vol. 32, pp.
551-554.— CLARK, A. H. Eighteen new species and one new genus of birds
from 2 Asia ‘end the Aleutian Islands. Proc. U. 8. Nat. Mus., vol. 32,
pp. 467-475.— CLARK, A. H. Ona collection of erinoids of the genus Eudio-
erinus from Japan, with description of a new species. Proc. U. S. Nat. Mus.,
vol. 32, pp. 569-574.— CLARK, A. H. Two new crinoids from the North
Pacific Ocean. Proc. U. S. Nat. Mus., vol. 32, pp. 507-512.— Dyar, H. G.
Descriptions of new species of moths of the family Cochlidiidae. Proc. U. 8.
Nat. Mus., vol. 32, pp. 565-567. Haun, W. L. Notes on mammals of the
Kankakee Valley. Proc. U. S. Nat. Mus., vol. 32, pp. 455-464.— JORDAN,
D. S. and Herre, A.C. A review of the lizard-fishes or Synodontid of the
waters of Japan. Proc. U. S. Nat. Mus., vol. 32, pp. 513-524.— JORDAN,
D. S. and Starks, E. ©. List of fishes recorded from ee or the Riu Kiu
Islands of Japan. Proc. U. S. Nat. Mus., vol. 32, pp. 491-504.— Jupay, C.
A study of Twin Lakes, Colorado, with especial eonaiderstion of the food of
the trouts. Bull. U. S. Bur. Fisheries, vol. 26, pp. 147-178, pl. 3.— LAMBE,
L. M. Notes on the fossil corals collected by Mr. A. P. Low in 1904. Geol.
Sur. of Canada, 9 pp. — Lamsr, L. M. Note on the occurrence of a super-
numerary tooth in a dog. Ottawa Nat., vol. 21, pp. 25-26, 1 fig. — LAMBE, L.

Ottawa Nat., vol. 21, pp. 15-18, pl. 1.— Lewron-Brain, L. A lecture on
rind disease of the sugar-cane. Div. Path. and Phys., Exp. Sta. Hawaiian
Sugar Planters’ Assn., bull. 7, 38 pp., 16 illus.— Merritt, G. P. On a pecu-
liar form of metamorphism in siliceous sandstone. Proc. U. S. Nat. Mus.,
vol. 32, pp. 547-550, pl. 52.— Perkins, J. The Leguminose of Porto Rico,
C

The Fecal service. U. S. Dept. Agric., For. Ser., cir. 36, 38 pp.— Pont, O.
543

544 THE AMERICAN NATURALIST [Vor. XLI

Basaltische Ergussgesteine vom Tepler Hochland. Arch. f. naturwiss. Land-
esdurchforschung v. Böhmen, 1905, vol. 13, no. 3, 72 pp., 2 pls. — Rurrner, F.
Die Mikroflora der Prager Wasserleitung. Arch. f. naturwiss. Lahidesdurch-
forschung v. Böhmen, 1906, vol. 13, no. 4, 46 pp., 6 figs. — Smrra, E. H. The
blossom end rot of tomatoes. Mass. Agric. Exp. Sta., bull. 3, 19 pp.— STEJ-
NEGER, L. A new Gerrhonotine lizard from Costa ey Proc. U: Nat
Mus., vol. 32, pp. 505-506.— STEINEGER, L. A new salamander from Nica-
ragua, Proc. U. S. Nat. Mus., vol. 32, pp. 465-466.— Warp, H. B. Icono-
graphia parasitorum hominis. Stud. Zool. Lab., Univ. of Neb., no. 70, 20 pls.
— Wetter, S. Descriptions of new species of Ordovician fol from China.
Proc. U. S. Nat. Mus., vol. 32, pp. 557-563.— WıLver, B. G.. What Agassiz
did for Cornell University. Cornell Era, vol. 39.— Wıruiston, 8. W. The
skull of Brachauchenius, with observations on the nn of the Plesiv-
saurs. Proc. U. S. Nat. Mus., vol. 32, pp. 447-489, pls. 34-37.— WOoHnIG,
K. Trachytische und kidanki nn vom ein ges
Arch. 2 naturwiss. Landesdurchforschung v. Böhmen, 1904, vol. 13, no. 1. 24
pp., 1 pl.— Woopkurr, F. M. The birds of the chia area. Chic. a
of Sei., Nat. Hist. Sur., bull. 6, 221 pp., 11 pls.

BOLETIM MENSAL DO OBSERVATORIO DO Rio DE JANEIRO, Jan., Feb., Mar.,
1906.— FORTY-NINTH ANNUAL REPORT OF THE HORTICULTURAL SOCIETY OF
MISSOURI.— NINETEENTH ANNUAL REPORT OF THE RHODE IsLAND EXPERI-
MENT STATION.— NINTH ANNUAL ANNOUNCEMENT OF THE UNIVERSITY OF
Montana BIOLOGICAL STATION.— RECORDS OF THE CANTERBURY MUSEUM,
vol. 1, no. 1.— TIJDSCHRIFT DER NEDERLANDSCHE DIERKUNDIGE VEREENIG-
ING, 2nd series, vol. 10, no. 3.— WISCONSIN GEOLOGICAL AND NATURAL His-
TORY SURVEY, bull. 15.

(No. 487 was issued July 17, 1907).

To Zoologists and Museums
he F. H. ROSENBERG
IMPORTER OF XOTIC ZOOLOCICAL en
57 ee HILL, LONDON, N. W., ENGLA
Holds the largest stock in the world of specimens in ir sn of

Just published, my new Price List of Bird-skins, containing over 4,300
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AMERICAN NATURALIST

Vor. XLI September, 1907 No. 489

THE STRUCTURE OF CILIA, ESPECIALLY IN
GASTROPODS

LEONARD W. WILLIAMS

WE venture to present the following incomplete observations in
the hope that they may contribute to the solution of the difficult
problem of the structure of cilia.

While looking over fresh marine plankton from Narragansett
Bay, we came upon an unidentified but common larva of a proto-
branch mollusk whose velar cilia were so large that they were excep-
tionally favorable for study. With a cover glass upon the larva,
we were able to watch with increasing ease the successive ciliary
waves which gradually became less frequent and rapid as the ani-
mal died; and consequently we were able to study the individual
cilia in detail. A groove with overhanging edges follows the rim
of the velum, and the large preoral cilia are arranged in a row along
the posterior edge of this groove. Each cilium is large and some-
what curved, being concave on the side toward which the effective
stroke is directed. It tapers evenly from its basal body to its
apex. The protoplasm at the base of the cilium was seen to con-
tract alternately on the opposite sides of the basal body and, corre-
spondingly, to move the base of the cilium back and forth. In
contracting, the protoplasm draws the cuticula downward.

As already stated, the cilia are arranged in a row along the edge
of a groove. The contraction of the protoplasm upon the lower
side of the cilium draws its base into the groove while the lower
portion of the cilium is bent so as to fit into the groove and the upper
portion is carried backward a few degrees (Fig. 1, a and b). The
convex side of the cilium is thus drawn into the groove. The

545

546 THE AMERICAN NATURALIST [Vol. XLI

contraction of the protoplasm above the cilium carries its base up-
ward, and cramps the cilium against the overhanging edge of the
groove until the lower portion of the cilium is bent into an S-shaped
curve (Fig. 1, c and d). The contraction continuing, the cilium is
forced past the edge of the groove and flies out and back with a
very rapid stroke — the effective stroke of the cilium (Fig. 1, e).
It is carried by the force of its stroke far beyond its position of
rest to which its elasticity brings it back in position for another
stroke. There seems no doubt that these cilia are elastic rods.
(Fig. 2, g) which are moved by the contraction of the protoplasm at
their bases. The cuticula around the base of the cilium rises and
falls with the movement of the cilium as though it formed a plate
into which the cilium is set. Consequently it appears that the
contractile fibrillae of the protoplasm are inserted in the cuticula.
and not directly in the base of the cilium. We do not know what
part the basal body plays in this movement but we believe that
it forms a pivot upon which the cilium turns somewhat as an
echinoderm spine turns upon its base.

The cramping and subsequent escape of the cilium account for
the rapidity and force of the effective stroke and also explain the well
known fact that the cilia of rotifers and veligers always seem to move
only in the opposite direction to that which is necessary, since the
effective stroke is too rapid to be visible. We do not believe that
the groove is a common ciliary structure,— on the contrary it is.
probably present only in cilia like those mentioned, whose effective:
stroke is invisible. However, we should call attention to the pits,.
collars, and ridges at the bases of the flagella and cilia of Protozoa,.
Porifera, and spermatozoa to which as yet no function has been
ascribed

Almost every cilium whose structure has been made out consists
of an axial rod or canal filled with cell sap or protoplasm, and a
sheath consisting of cuticle or protoplasm. In the velar cilium
described above, we have no doubt that the elastic rod is surrounded
by a protoplasmic or cuticular sheath.

The large swimming plates of ctenophores, which are formed by
the fusion of a number of cilia, have been carefully studied by
Verworn.' In the position of rest, the plate is parallel to the sur-

1 Verworn, M. Studien zur Physiologie der Flimmerbewegung. Arch. f.
d. g. Physiol., 1891, 48, p. 149-180.

No. 489] THE STRUCTURE OF CILIA 547

face of the body and points toward the aboral pole of the animal.
Its base is sharply bent toward the aboral pole and its distal por-
tion is concave outward. The contraction of the oral side of the
base of the plate first straightens out the basal curve and then
bends the base of the cilium over toward the mouth. While the
contraction of the base is taking place the distal portion of the plate
is first flattened by the resistance of the water and then is bent into
a curve of shorter radius by the contraction of its oral side. At
the end of the stroke, the cilium is again parallel to the surface

AKG c d è

Fie. 1.— Diagram showing successive stages in the stroke of a cilium in the
velum of a gastropod larva.

of the animal but it points toward the mouth and its single concavity
is directed inward. Smooth muscle fibers pass from the gastric
canal, which underlies each row of cilia, to the rib which carries
the swimming plates; by their contraction they draw the rib into
the gelatinous tissue of the body. Verworn believes that the sole
function of these muscle cells is to draw the plates from the surface
for the protection of the plates, and also that the movement of the
cilium is caused chiefly by the contraction of its base. He does not
suggest the existence of an axial supporting rod. It is possible,
however, that the muscles underlying the plates may assist in the
movements of the cilium and that it is really quite similar function-
ally to the velar cilia.

The tails or flagella of spermatozoa undoubtedly consist of an

548 l THE AMERICAN NATURALIST [Vol. XLI

axial rod with a protoplasmic sheath which often bears undulatory
membranes. The tails of the vast majority of spermatozoa seem
to lack the power of movement when separated from the basal body
and cell protoplasm, and we believe that this indicates a dependence
of the cilium upon a muscle-like structure around the basal body.
In Salamandra, as reported by Meves,' and in many protozoa a

Fig. 2.— Diagram showing the hypothetical structure cilia.
a, primitive cilium with fluid core and contractile sheath.
b, cross section of a.
c cross section of a cilium according to Schäfer’s theory of ciliary structure.
d, more highly developed cilium with basal body and elastic axial rod.
e, cross section of an irreversible cilium.
f, cross section of a reversible cilium.
g, cilium in which the contractile portion is confined to its base.

flagellum or cilium separated from the basal body and the cell
protoplasm is capable of motion. In these cases doubtless the
contractile substance is not confined to the base of the flagellum
but extends into, perhaps throughout, the sheath (Fig. 2, d).
The vast majority of cilia and flagella, however, can move only
while in connection with protoplasm and the basal body. A differ-
ent interpretation has been given to these facts by Pütter? and
ı Meves, F. Über Struetur und Histogenese der Samenfäden des Meer-
schweinehen. Arch. f. mikr. Anat., 1899, 54, p. 329-402, vide p. 382.
? Pütter, A. Die Flimmerbewegung. Erg. Physiol., 1902, 2, Abth. 2, p.
1-102,

No. 489] THE STRUCTURE OF CILIA 549

others who consider that the isolated cilium is capable of motion
but lacks only the necessary stimulus.

That the core or axis of the cilium is always solid is rendered
improbable by the fact that many pseudopodia and the tentacles
of the Suctoria, which are admittedly homologous with cilia, clearly
have a central canal or a fluid core (Fig. 2, a). Moreover the
experiments of Zacharias! who caused the spermatozoa of Poly-
phemus to produce slender cilia-like pseudopodia by immersing
them in a 5 per cent. solution of sodium phosphate, and of Pro-
wazek ? who saw the retracting protoplasm of an injured cell thread
of Siphonaea bryopsis produce in five minutes cilia which beat at
the rate of 40 strokes a minute, and who? also found in Chilomonas
cilia appearing as small processes which in 8 minutes attained
half their normal size and beat 19 times in 20 seconds, show that
certain cilia must consist of but slightly modified protoplasm.
These experiments also indicate that a solid or a permanent core
is not always formed, for in the first two cases the cilia were quickly
destroyed. It is clear that a tube containing a fluid which cannot
escape either because of the cell turgor or because enclosed in the
tube, will act precisely as an elastic solid. In this connection
Gurwitsch’s' discovery that a marked increase in cell turgor accom-
panies the formation of cilia, and the cases of contraction of the cell
or movements of the nucleus indicating such contraction, syn-
chronously with the stroke of the cilia of the cell, all suggest that
the turgor holds in, or the contraction of the cell forces into, the
cilium the fluid which forms its support. This consideration in
turn suggests a function for the ciliary roots which may increase
the turgor of the cell by drawing its walls together.

These various considerations have been utilized in the current
theories of ciliary action and structure, especially in the most
generally accepted theory which is supported with various modi-

! Zacharias, O. Über die Amöboiden Bewegungen der Spermatozoen von
Polyphemus pediculus. Zeit. f. wiss. Zool., 1885, 41, p. 252-258.

2 Prowazek. Protozoenstudien II. Arb. a. d. Zool. Inst. Univ. Wien,
1900, 12, p. 243-300.

3 Prowazek. Protistenstudien III. Arb. a. d. Zool. Inst. Univ. Wien,
1902, 14, p. 81-88. i

4 Gurwitsch, A. Studien uber Flimmerzellen. I. Histogenese der Flimmer-
zeller, Arch. f. mikr. Anat., 1901, 57, p. 184-229.

550 THE AMERICAN NATURALIST [Vol. XLI

fications by Engelmann,’ Pütter, Parker? and Gurwitsch.” Ac-
cording to this theory, the cilium consists of an axial support and a
contractile protoplasmic sheath. The nature of the axis has been
less the subject of discussion than that of the sheath which Engel-
mann regards as fibrillar, Piitter as protoplasm with temporary
fibrillar arrangements, and Gurwitsch as protoplasm of changing
surface tension. As stated above, Verworn thinks that the cilium
of ctenophores is formed of two columns of contractile protoplasm
whose differential contraction moves the cilium, and Engelmann
seems to lean toward this view.

Less generally accepted theories are those of Benda and Schäfer.
Benda‘ believes that the cilium is passive and is operated by a
mechanism at its base, but the cases cited above of the movement of
cilia entirely separated from the basal body and the cytoplasm,
and the failure with few exceptions to find such a mechanism,
make this view unacceptable. The velar cilia above described,
the existence in some cells of the hypobasal layer which seems to
consist of contractile protoplasm, and the partial agreement of
Verworn’s observations upon ctenophore cilia suggest, however,
that although this theory will not apply to all cilia, it is the only
theory which explains the action and structure of certain cilia.

Schiifer® regards the cilium as an elastic tube (Fig. 2, c), one
side of which is less elastic than the rest, into which fluid flows or is
forced causing the cilium to bend over toward its less elastic side.

This theory is plausible and the structure is mechanically
possible but it fails to explain some points, as, for example, the
reversal of ciliary action and the presence of axial rods in sperma-
tozoan flagella. It seems, however, that the action of the suctorian
tentacles which are evaginated and invaginated like the finger of a
glove can only be explained by this theory.

1 Engelmann, T. W. Cils Vibratils, in Richet’s Dictionaire de Physiologie,
Tome 3, 1898, p. 785-799. See also older works by the same author.

? Parker, G. H. The eae of Ciliary Movement in Metazoans. Am.

Journ. Physiol., 1905, 13, p. 1-16. ;
3 Gurwitsch, A. Morphologie und Biologie der Zelle. Jena, 1904, vide

6 ff.
4Benda, C. Über neuer Darstellungsmethoden der Centralkörperchen.
1901, Arch. j. Anat. und Physiol., Physiol. abth., 1901, p. 147-157.

5 Schäfer, E. A. Theories of ciliary movement. Anat. Anz., 1904, 24, p.
497-511. See also Anat. Anz., 1905, 26, 517-521, and Proc. Royal Soc. Lon-
don, 1891, 41, 193-198.

No. 489] THE STRUCTURE OF CILIA 551

The generally accepted theory is undoubtedly correct but it can
now be stated more fully than heretofore and can be, in a measure,
harmonized with the less acceptable theories. All protoplasmic
processes, cilia, flagella, pseudopodia, and suctorian tentacles, are
of essentially the same structure and consist of a contractile pro-
toplasmic sheath which encloses a solid or fluid supporting core.
Primitively the sheath (Fig. 2, a) is contractile throughout and is
not marked off structurally or functionally from the remainder
of the ectoplasm. Secondarily the sheath becomes differentiated
into contractile and noncontractile portions, the relations of which
are shown in the following examples. ‘The contractile protoplasm
(Fig. 2, g) of velar cilia and ctenophore plates is practically
confined to the base of the cilium. Parker has shown that in
reversible cilia (Fig. 2, f) the contractile substance must occur in
two opposite bands which in Metridium are on the oral and aboral
sides of the supporting axis. Ordinarily the aboral band contracts
more strongly than the other and drives water away from the mouth
but certain organic and inorganic substances cause the oral band
to contract more strongly and so to reverse the direction of the
effective stroke and of the currents caused by it. Parker shows
also that irreversible cilia (Fig. 2, e) probably have but one band
of contractile material. Ballowitz' has shown that spermatozoan
flagella have a fibrillar axial structure surrounded by a sheath of
uneven thickness and Pütter with others have shown that the axial
rod supports the irregular contractile protoplasmic sheath.

The core of the pseudopodium, which is to be regarded as the
simplest cilium, is fluid. In higher stages of ciliary development
a solid, which is elastic in cilia and flagella and inelastic in pendu-
lous pseudopodia, replaces the fluid core.

Harvard MEDICAL SCHOOL
Boston, Mass.

! Ballowitz, B. Untersuchungen über die Structur der Spermatozoen,
zugleich ein Beitrag zur Lehre vom feineren Bau der kontractilen Elemente.
Arch. f. mikr. Anat., 1888, 32, p. 401-473.

THE POISON GLANDS OF NOTURUS AND
SCHILBEODES

HUGH DANIEL REED

THE eleven species of Noturus and Schilbeodes are popularly
known as “stone cats” and “mad toms.” They are small catfishes
found in the lesser streams from New York and New Jersey west
to Wyoming and Montana, and south to Georgia, Alabama and
Texas, being most abundant in the Great Lake, Ohio and Upper
Mississippi regions. ‘They may be distinguished from other cat-
fishes by the presence of a keel-like adipose fin joined to the back
and more or less continuous with the caudal fin. The two genera,
which appear very much alike, may be distinguished from each
other by means of the pad of villiform teeth on the upper jaw. In
Noturus this pad of teeth, at each outer caudal angle, possesses
a backward extension which is absent in Schilbeodes.

It has long been known that the mad toms can inflict a painful
wound with their pectoral spines. The sensations produced by
the wounds, and the presence of a pore in the axilla, have led to
much speculation respecting the presence of a poison-secreting
gland which anoints the spine. Some take it for granted that such
an organ exists, others are doubtful, and recently the presence of
poison glands in these fishes has been denied altogether.

Giinther (’80 b) recognized the existence of a sac in the axilla
of certain catfishes and says,— “It does not seem improbable that
it contains a fluid which may be introduced into a wound by means
of the pectoral spine.... However, whether this secretion is
equally poisonous in all the species provided with that axillary sac,
or whether it has poisonous qualities at all, is a question which
can be decided by experiments only made with the living fishes.”

Jordan and Gilbert (’82) under the description of the genus
Noturus' say,— “In or above the axil of the pectoral fins is an
orifice, which is the opening of the duct of a poison gland.” ‘To

t now constitute the pan E and Schilbeodes were ther
included under the generic term Notu

553

554 THE AMERICAN NATURALIST [Vol. XLI

this is added a quotation from Cope,— “From it [the pore] may
frequently be drawn a solid gelatinous style ending in a tripod,
each limb of which is dichotomously divided into short branches of
regular length.” Jordan and Evermann (’96) make a similar
statement and add,— “ The sting from the pectoral spine is very
painful, resembling the sting of a bee, but worse.” Again, Jordan
(04) writes the following footnote,— “The wounds produced by
the sting of their sharp pectoral spines are excessively painful. In
the axil is usually a pore, probably the opening of a duct from a
poison gland. This matter deserves investigation.” Finally
(05) he writes,— “In two genera, Noturus and Schilbeodes, a
poison gland exists at the base of the pectoral spine, and the wound
gives a sharp pain like the sting of a hornet and almost exactly
like the sting of a scorpion-fish.”’ 3

Boulenger (’04) does not consider this axillary sac a poison
gland. In this connection he says,— “I think this condition of
things has nothing to do with a poison organ, and is merely a
repetition of what is observed in loaches and in the characinid
Xenocharax, where I have found a gelatinous substance filling the
short duct by which the membrane of the air bladder is placed in
communication with the skin and the sensory organ of the lateral
line.”

Poison organs in connection with various spines have been
found in several different groups of fishes. Günther (’69) has
described a poison apparatus in Thalassophryne reticulata which
inflicts a wound followed by poisonous symptoms. At the base
of the dorsal and opercular spines in this species he found a sac
connected with a canal passing through the whole length of the
spine and opening through a slit at its distal extremity. Thus the
spine resembles the fang of a poisonous snake. Günther con-
cluded by saying, “ Nobody will suppose that a complicated appa-
ratus like the one described can be intended for conveying an
innocuous substance and therefore I have not hesitated to desig-
nate it as poisonous; and Capt. Dow informs me in a letter lately
received, that ‘the natives of Panama seemed quite familiar with
the existence of the spines and of the emission from them of a
poison which, when introduced into a wound, caused fever, an
effect somewhat similar to that produced by the sting of a scorpion;

No. 489] POISON GLANDS 555

but in no case was a wound caused by one of them known to result
seriously. The slightest pressure of the finger at the base of the
spine caused the poison to jet a foot or more from the opening of
the spine’.”

The weever fishes (Trachinus) found along the coast of Europe
inflict very severe wounds with their dorsal and opercular spines.
‘This was so well known that in some towns, at one time, there
were regulations providing for the removal of the spines before
the fishes were displayed in the markets. Schmidt (’75) and
Parker (’88) independently found well developed glands about
the dorsal and opercular spines. ‘There are numerous references
to the poisonous nature of the weever fishes, but the two authors
mentioned are the only ones, so far as I know, who have described
the structure of the glands.

Wallace (’93) in the toadfish, Opsanus (Batrachus) tau, dis-
covered glands in connection with pores in the axilla, on the dorsal
portion of the operculum and on the surface of the pectoral fin.
This author does not consider them as poison glands although
the spines of this species give a “slightly painful sting” and the
glands apparently are of the same type as those of the weever
fishes described by Schmidt and Parker, and those of the mad
toms to be described presently.

With the above facts and views in mind and a desire to know
more of the action and structure of the supposed poison glands,
all the known species’ of Noturus and Schilbeodes, except S.
funebris, have been examined. The sting will be described first,
and then the structure of the glands.

The Sting.— The sting of the mad toms has been described as
like that of a bee. In Schilbeodes gyrinus the sensations produced
do not differ materially from those of a bee but as a rule the pain
is not so intense and is usually confined to the wounded region.
Frequently a very severe sting upon the end of the finger caused
pain throughout the hand and wrist. In several cases after receiv-
ing deep punctures on the end of the finger, sharp pains which
continued for several hours, were experienced to the elbow. Dr.

1 The author ishes t k led his indebted to Dr.C. H. Eigenmann,

Dr. B. W. Evermann and the authorities of the National Museum for the
generous loan of specimens for study.

556 THE AMERICAN NATURALIST [Vol. XLI

Evermann (MS.) describes the pain as, “A very stinging sensa-
tion, more like that which would result from a severe nettle sting.’
This describes precisely the majority of stings, for in handling
live specimens ordinarily only the tip of the spine enters the flesh.
The mechanical injury is so slight that it frequently is impossible
to locate the wound except for the stinging sensation. From an
ordinary sting, such as is received in handling the live fishes, the
pain continues from one to several hours, depending probably
upon the amount of poison entering the wound. Both in sensation
and duration these wounds differ from those made by the prick
or puncture of a sharply pointed instrument. ‘The swelling is
hardly perceptible,’ except in cases of very severe punctures, in
which event the flesh about the wound becomes distinctly swollen

Fic. 1.— The head of Noturus flavus. P, axillary pore or opening of axillary
gland. Sp, pectoral spine.
and slightly discolored. Similar results, but more marked, are
produced by introducing a portion of a fresh gland underneath
the skin. .

The Poison Glands.— All the species of Noturus and Schilbeodes
possess axillary glands which open through a pore situated in the
axilla just below the post humeral process (Fig. 1, P). The
position of the pore with reference to the base of the fin and the
humeral process varies somewhat in different species. In all,
the pore is more or less slit-like and is situated so that when the
fin is adducted the spine lies either directly across or parallel with
it. Thus the transfer of secretions to the spine may be accom-

1 Schilbeodes gyrinus was the only species available > ge
Some other species of the genus are said to be more vir

No. 489] POISON GLANDS 557

plished during adduction but it is doubtful if this is the usual
method of anointing the spines. In most of the species the pore
is opened widely when the fin is abducted. In Schilbeodes insignis
the lips of the pore, if anything, are drawn closer together by the
abduction of the fin. In approaching each other, however, the
lips of the pore are continued to the base of the spine as two slight
folds with a groove between them. ‘Thus the secretions would find
a safe conduit from the pore to
the spine.

The glands are pear-shaped,
with the apex toward the axil- ps.
lary pore (Fig. 2, p. g: and p. a
0.). In most species examined,
the gland is inclined backwards
and lies just beneath the skin
and entad of the posthumeral
process (Fig. 2, h). It is sur-
rounded by loose connective
and adipose tissue. In S. gy-
rinus the gland extends farther
towards the head than in some
other species. In all species
the gland, though small, is
macroscopic. In a specimen
of Noturus flavus 17 cm. long

at.

HA
TA

De an 6 :
NASN SONS i
EIER:
7) TEN

>

EL
oF
“
In

nar
Asse
T
LA
sà
(S

the greatest diameter of the Fig. 2.— Section through the axillary
land and pectoral spine of Schil-

gland was 5 mm. Beodes miurus. a. t, adipose
, mee . tissue. g., axillary poison

The glands are divided into gland. d., corium. ep., epider-
RER cells. "X, poet- komersil process.

; ‘ cells. h., S.

three TD lo r each of which c. ¢., Clavate cells of the epider-
is subdivided into lobules. The ie Se ee

° r
cretion,

. ”
sp., pectoral agit
fin-ray. l., she
m,, muscle.

to! S T.,
lumen of the gland is extremely Re isd coo
narrow except near the pore

where it is comparatively wide. It can be traced in sections how-
ever, through the main lobes and for a short distance into the
. subdivisions. The tripod style which Cope withdrew from the
pore was probably the hardened secretion of the gland, each of
the three legs of the style corresponding to the lumen of the three

main divisions of the duct and the dichotomous branches repre-

558 THE AMERICAN NATURALIST [Vol. XLI

senting the lumens of further subdivisions. I have frequently
found globular masses of the secretion filling and depending
from the pore (Fig. 2, s) but have been unable to withdraw one
with the branches intact. The secreting cells are granular and
very large. They range between 80 and 200 microns in their
greatest diameter, and vary in shape due to compression with
neighboring cells. Most of the cells contain two large nuclei. As
a rule the two nuclei are separated by a short space, but fre-
quently they are found very close together or apparently joined.
This may indicate recent division as Parker has suggested in con-

Fic. 3.— Transection of the dorsal spine of raters gyrinus. pg, poison
aad: ep, epidermis. sp, dorsal spine. r, fin-ra

nection with similar phenomena in the poison glands of the weever
fishes. Further evidence of division has not been apparent.

The entire gland is surrounded by a sheath which reaches the
bottom of the fissures between the primary and secondary lobes.
(Fig. 2, 1). Every secreting cell is lodged in a loose network of
elongated spindle-shaped cells which Schmidt has named support-
ing cells. Each has a nucleus in its central part. The gland is
richly supplied with blood vessels which are lodged in its sheath
and between its lobes.

No. 489] POISON GLANDS 559

Besides the axillary glands, two species, Schilbeodes gyrinus and
S. nocturnus, each possess
glands beneath the skin

projects slightly. In pre-
served specimens it is not
unusual to find a globular
mass or a long filament of
the hardened secretion at-
tached to the end of these X
spines. The sting of the ANSAN
dorsal spine in Schilbeodes ; j
gyrinus is precisely like
that of the pectoral. The wu?

which covers the dorsal and E
pectoral spines. Both spines 5
are situated in front of and | | S
are shorter than the first HA || $
. r A y ry ;
soft rays of their respective AA 3
fins. Both are grooved, as ois S E
: : FI a
shown in the transection INS 5
. f age LSA 3
Fig. 3, sp. Near the base HWM ET a,
of the spines the grooves ay = š
N Sa
are more complex. If an DX aes d
uninjured specimen be ex- =o Se =
amined, at the middle of a NS E
the extent of these spines ag W 3
F j ADNANA T
there will be noticed a CAZAS S
swelling which tapers to- 4 ö Za e
wards either end. The nee ARA
gland (Fig. 4, pg) is coex- r Y EN ye be
tensive with this swelling = | i z
and occupies nearly all of- A| W silo a
the space between the skin x di \ = $
and the spine which it sur- | salt AMY 3
rounds (Fig. 3, pg). At Or N E
> ES
the end of the spine there |: |
i it i Sa deh
is a slit in the epidermis EN
through which the spine eG Ne

Abductor profundus
Fig, 4.— Longitudinal section of the pectoral spine of Sehilbeodes gyrinus.

Clavicle

560 THE AMERICAN NATURALIST [Vol. XL.

same will probably be found true of S. nocturnus for the dorsal
spine gland is here as well developed as the pectoral. The
presence of spine glands may be determined by carefully slit-
ting the overlying skin and scraping the spine with a needle.
If the gland is present, the scrapings when stained and
mounted show the typical gland structure almost as clearly as
sections. Sometimes the structure can be made out with a
dissecting lens without either staining or scraping the tissue from
the spine. In the fresh condition the glands are of a translucent
jelly-like consistency and appearance. There is no difference in
structure between the axillary and spine glands.

It appears from the figures and descriptions of Schmidt and
Parker that the poison organs of the mad toms and the weever
fishes are identical in structure. In the latter group the glands
are found only in connection with the opercular and dorsal spines
which they surround in precisely the same manner as do the pectoral
and dorsal glands of Schilbeodes gyrinus and S. nocturnus.

Differential stains fail to reveal the presence of any muscular
fibers which might by their contraction exert pressure upon the
cells and force their secretions to the exterior. The same is true
according to Schmidt and Parker of the weever fishes. The
latter (’88) writes,— “No special muscles are present in connection
with the glands. ...I am inclined to think that in the discharge of
their secretions the cells simply burst.” Schmidt (’75) observes
that “Along the ventral side of the upper gland are found a few
bundles of the extensor muscle of the gill cover but they could
hardly produce any pressure on the gland, and moreover, no
organ, adapted for active ejection of the secretion, is found.”
It appears that the cells are destroyed when the secretions are
released, for in no case has a natural opening been found in the
cells, and the secretions when stained are found to contain rup-
tured and ragged cells in many of which the nucleus can still be
made out. Frequently uninjured cells are found floating in the
secretions along with the ruptured ones. Usually these are small
cells, probably immature ones, which have been torn away with
the others.

The relation of the fin and body muscles to the gland is such
that no amount of contraction can produce any pressure upon it.

No. 489] POISON GLANDS 561

It is improbable that the glands depend upon the application of
external pressüre, such as would result if the fish were seized in
the axillary region by another animal. ‘It is doubtful whether,
in those species which possess spine glands, the spines are ever
inserted far enough into the flesh of the victim to produce pressure
as a result of the slipping of the skin away from the tip and towards
the base of the spine. Such was Byerley’s (’49) explanation of
the ejection of the poison from the glands of the weever fishes
but it was not accepted later by Schmidt and Parker. Judging
from the size of the wound inflicted by these forms which possess
spine glands, the exposed portion of the spine is probably as much
as is usually inserted into the flesh. It seems probable that the
cells of both axillary and spine glands are ruptured from the out-
ward pressure exerted by their own contents. ‘The ruptured cells
are not found in one place but are scattered through the gland,
and the secretion may be seen streaming through the lumen and
pore, out along the folds of skin on the dorsal surface of the spine
toward its tip. In specimens which have been carefully handled
a globule will be found depending from the axillary pore or a
stream of the secretion extending from it to the pectoral spine.
The end of the pectoral and dorsal spines in Schilbeodes gyrinus
is usually found with a globule or wavy filament of the poison.
Thus always supplied with poison at its very tip it can be readily
understood how the slightest prick produces results.

It is worthy of note that spine glands are found only in those
species where serrae upon the spines are absent or very few and
weak. A serrate dorsal spine without a gland apparently cannot
inflict a stinging wound, but the non-glandular serrate pectoral
spines are supplied with poison from the axillary glands. Although
no difference in the relative size or specialization of the axillary
glands in the two groups has been noted, the species with serrae are
considered more poisonous than those without. The presence
of serrae makes possible the infliction of a large number of wounds
and consequently the introduction of a large amount of poison at
one and the same time. This would render such species more
formidable although the poison is secreted in smaller quantities
and is no more virulent. Certainly spines without serrae can
inflict wounds from the tip end only and being some distance from

562 THE AMERICAN NATURALIST [Vol. XLL

the axillary pore would most likely be poorly provided with poison
except for the presence of a gland opening at the very end. It
seems plausible, therefore, that the absence of serrae is correlated
with the presence of glands developed about the spines, as in
Schilbeodes gyrinus and S. nocturnus and as probably will be found
in S. leptacanthus * when an uninjured individual is examined.
The Origin of the Gland Cells.— Cutaneous glands are generally
to be regarded as invaginations or proliferations of the epidermis,
certain cells of which become transformed into the secreting cells,
Wallace (93) has shown that in the axillary glands of the toadfish
the clavate cells of the epidermis become the secreting cells, whereas

P. g. C. €. p. 6. sp. ee

Sn
pap AS
Ba 20
©

o's
Se op ego
SED = = Pes

©
o
ee BOS
©

— oo
ae oS
© er
o2 d. ep.
Fic. 5.— Longitudinal section of the end of the postern anne of Schilbeodes
gyrinus. p. g., poison gland. c. c., clavate Ener ‚layer of pigment

cells. sp., Sea spine. d., corium. ep., epi

the smaller cells become the supporting elements. Similarly, in
writing of the weever fishes, Schmidt says,— “ After a comparison
of the contents of the gland sac and the adjacent epidermis it
seems clear that in the gland tissue the secreting cells replace the
clavate cells and that the ordinary epidermal cells are gradually
transformed into the supporting plexus.” Parker calls attention
to the lack of well defined ducts in the glands of the weever fish.
He says,— “There can be little doubt that the gland is developed
as an epidermic involution the whole of which gives rise to secre-

! The only specimen available was a very small one, the spines of which
had been denuded of all tissue whatsoever.

No. 489] POISON GLANDS 563

tory cells, so that there is no marked differentiation into gland and
duct.”

The glands in Noturus and Schilbeodes are likewise invagina-
tions of the epidermis. They are surrounded by a sheath of corium
pushed inward by the developing gland. As shown in Fig. 2,
d and J, the sheath is thinner and denser than the rest of the corium,
with which it is continuous around the neck of the gland. Be-
tween the corium and epidermis in most regions of the body there
is a layer of pigment cells (Fig. 2, p. c.) which is frequently found
to extend about the gland between the sheath and the gland tissue,
thus occupying the same relative position as in the skin. The
arrangement of the pigment layer in relation to the spine glands
shows that they are invaginated from near the tip of the spine.
Near the tip, the pigment layer (Fig. 5, p. c.) turns upon itself and
passes over the gland to its base, toward the root of the spine.
Thus the gland is invested by two layers of pigment cells with
corium between them (Fig. 5, d). The clavate cells of the skin
and the secreting cells of the gland form an uninterrupted series
(Fig. 5, c. c. and p. g.), the former gradually increasing in size so
that in sections it is sometimes impossible to draw the line between
the two. The other cells of the epidermis as the gland is ap-
proached, gradually assume an irregular shape, then becoming
more elongated they are finally transformed into the extremely
slender cells which constitute the supporting tissue.

The invagination is much more extensive and the specialization
of elements proceeds much further in the mad toms than in the
toadfish. In the glands of the latter the epidermal character of
the cells is barely lost. Thus the slime cells, which in the mad
toms are apparent only in the skin, according to Wallace’s figures
are perfectly distinct in the glands of the toadfish, and project into
the gland cavity.

SUMMARY

1. All of the species of Noturus and Schilbeodes, except 8.
junebris, have been examined; they are found to possess an
axillary pore which is the opening of a gland.

2. Experiments with Schilbeodes gyrinus indicate that the
secretions of the glands are poisonous.

564 THE AMERICAN NATURALIST [Vol. XLI

3. In addition to the axillary glands Schilbeodes gyrinus and
S. nocturnus possess glands developed about the pectoral and
dorsal spines. These are of the same type and structure as the
axillary glands. The end of such a gland-bearing spine projects
‘slightly through a slit in the epidermis.

4. Spine glands are not found in those species which possess
well developed serrae upon the spines.

5. Schilbeodes leptacanthus, because of its close relation to S.
gyrinus, would be expected to possess spine aeg in addition to
the axillary glands.

6. A study of the mature glands tends to justify the following
conclusions:

a. The glands are of epidermal origin; those in the axilla
invaginate from the pore, and those in the spines from
the slits near the tips of the spines.

b. The gland sheath is modified corium.

©

The clavate cells of the skin become the secreting cells
of the gland.

d. The ordinary epidermal cells become elongated, forming
the supporting network of the secreting cells.
e. The glands of the mad toms are essentially like those

of the weever fishes.

The glands of the toadfish, although of the same type,
are intermediate in structure between the glands of the
mad toms and unmodified epidermis.

There are no muscles for rupturing the cells and forcing
out the secretion. The cell walls are evidently ruptured
by the pressure of their contents. In this way the spines
are constantly anointed with the poisonous secretion as
may be seen by examining uninjured specimens.

eh

gs

CoRNELL UNIVERSITY
ON. 3.

No. 489] POISON GLANDS 565

LITERATURE.
ALLMAN, G. J.
’41. On the Stinging Property of the Lesser Weever. (Trachinus).
Ann. Nat. Hist. 1841, vol. 6, p. 161.
BOULENGER, G.
'04. The Cenbrides Natural History, Fishes, Ascidians, etc., 1904,
vol. 7, p. 590. . Macmillan Co., N. Y.
Briva, T. W.
04. The Cambridge Natural History, Fishes, Ascidians, etc., 1904,
vol. 7, p. 177. Macmillan Co., N. Y:
BYERLEY.
’49. Poison of Weever Fishes. Proc. Literary and Philosophical
Soc., Liverpool, 1849, p. 156.
merle i H.
Notice on Professor W. Newton Parker’s Communication, “On
the Poison Organs of Trachinus.” Anat. Anz., 1888, k
Cuvier. [Remarks upon the poison of the weever Sohasi. Hist. Nat.
des Poissons. T. 3, p. 184
Day. [Remarks upon the poison of the weever fishes].
’80-’84. The Fishes of Great Britain and Ireland, vol. 1, pp. 78-82.
London.
GessIn, LEON.
’84. Contributions A l'étude de l’appareil a venin chez les poissons du
genre “vive” (Trachinus). Thèse de Paris. 1884.
GÜNTHER, A.
64 On a Poison Organ in a genus of Batrachoid Fishes. Proc. Zool.
Soc. Lon., 1864, p. 157.
69. An account of the Fishes of the States of Central America Based
on Collections made by Capt. J. M. Dowe, F. Godman Esq., and
O. Salvin Esq., Trans. Zool. Soc. Lon., 1869, vol. 6, p. 439.
’80 a. Article on “Ichthyology” in Ency. Brit., 1880, vol. 12, p. 190.
’80 b. An Introduction to the Study of Fishes. Edin., 1880. p. 192.
SKEN, Sır Wm.
British Fishes, pt. 1. . Naturalists Library, 1843, vol. 4 (Ichthy-
ology), pp. 135-137.
Jordan, D. S.
04. Manual of Vertebrates. 1904, p. 41, McClurg & Co., Chicago.
’05. A Guide to rn en of Fishes. 1905, vol. 2, p. 177. Henry
Holt & Co.,
JORDAN, D. S. AND Bes GH.
’82. Synopsis of the Fishes of North America. U. S. Nat. Mus.,
1882, bull. 16, p. 98.

566 THE AMERICAN NATURALIST [Vol. XLI

JORDAN, D. S. AnD Evermann, B. W.
’96. The Fishes of North and Middle America. U. S. Nat. Mus.,
1896, hes = p. 145.
Kent, W. Savit
83. British ER & Fresh Water Fishes. Fisheries Exhibition
Handbook, 1883, p. 29. London.
PARKER, W. N.
’88. On the Poison Organs of Trachinus, Proc. Zool. Soc. London,
1888, p. 359.
SACCHI, MARIE.
’95. Aiti. Soc. Ligust., 1895, vol. 6, p. 89.
Scumipt, F.
15. Om Fj eg Stik og Giftredskaber. Nord. Med. Arkiv.,
1875, vol.
TYBRING, OSCAR.
’86, Poisonous Fishes. (Translated from the Danish by Hermann
a Bull. U. S. F. C., 1886, vol. 6, p. 148.
WALLACE, Louis
-e OS The ante and Development of the Axillary Glands of Batra-
c Journ. Morph., 1893, vol. 8, p. 563, pl. 27.
WIEDERSHEIM, R.
06, Vergleichende Anatomie der Wirbelthiere. 1906, Jena.
WRIGHT, R.
84. Proc. De Inst., 1884, vol. 2, p. 252.

THE STRUCTURE OF THE SILK GLANDS OF
APANTELES GLOMERATUS L.!

ROBERT MATHESON AND A. G. RUGGLES.

Apanteles glomeratus is a hymenopterous social parasite of the
larvae of Pieris rapae, the common cabbage worm. The adult
females deposit at each oviposition from fifteen to thirty-five eggs
in the young larvae of Pieris. ‘The parasites on hatching, feed upon
the lymph and fatty tissue of their host and grow very rapidly,
becoming full grown at about the end of the larval life of the
caterpillar. They then penetrate through the skin of their host
and, while emerging, spin their characteristic sulphur-yellow co-
coons. The silk glands, as seen in sections of the mature larvae,
are enormously developed. Although the silk glands of lepidop-
terous and trichopterous larvae have been the objects of detailed
study by Helm, Gilson, and others, very little is known concerning
these glands in the Hymenoptera. As regards histological struc-
ture the only works of importance are those of Cholodkovsky,
his student Pikel, and Bordas; and, excepting the latter who
gives a brief discussion of these glands in the aculeate Hymenop-
tera, these writers have confined themselves to the study of the
larvae of various Tenthredinidae. Therefore at the suggestion
of Professor Riley we were led to investigate more fully the silk
glands of Apanteles.

The work was carried on in the Entomological Laboratory of
Cornell University. We wish to extend our thanks to Professors
Comstock, Riley and MacGillivray, for their constant aid and
advice.

Anatomical Disposition of the Silk Glands.— The silk glands
of Apanteles glomeratus arise near the base of the labium and
extend through the body cavity to the antepenultimate segment
of the abdomen. In the abdominal region of mature larvae they
consist of two pairs of thin-walled, much convoluted, cylindrical
tubes (Pl. 1, fig. 3) which completely surround the alimentary

1 Contributions from the Entomological Laboratory of Cornell University.

567

~“

568 THE AMERICAN NATURALIST [Vol. XLI

canal. Each pair of tubes unites in the first abdominal segment
to form a common thoracic division. ‘These common tubes, extend-
ing forwards with many convolutions in the thorax, turn ventrad
just behind the developing head and passing on each side of the
sub-oesophageal ganglion, end in short ducts. These ducts unite
in the labial region to form the press which occupies more than
half of the common duct.

In young larvae just hatched, and for several days rs the
glands show no convolutions whatever. They lie as straight
tubes, two on each side of the alimentary canal and extend caudad
to the antepenultimate segment (Pl. 1, fig. 1). Moreover the
structure is the same throughout their entire length, no regional
differences occurring. Their walls are thick and their lumina
very small. Later they become much convoluted, and their
lumina are greatly distended, till in the mature larvae at time of
emergence from the host, the abdominal division has practically
ceased to secrete, becoming simply a reservoir for the already
accumulated product.

The silk glands may be divided into two general ne i
Secretory. 2. Conducting.

The Secretory Division.— The secreting division may be con-
veniently divided into two portions, abdominal and thoracic.

The abdominal portion comprises that part of the gland extend-
ing caudad from the point of juncture of the glandular tubes in
the first abdominal segment.

In the freshly hatched and young larvae this portion consists
of two pairs of straight glandular tubes, one pair situated on each
side of the alimentary canal (Pl. 1, fig. 1). On each side the tubes
lie directly one above the other. No difference in structure between —
the dorsal and ventral tubes could be detected. In cross section
the gland is seen to be composed of two large cells surrounding
a very small lumen (Pl. 1, fig. 9). Each cell is almost completely
filled by alarge unbranched nucleus. Externally lies the basement
membrane (b. m.), a delicate structureless sheath surrounding the
gland. On the inner surface lies a delicate, thin membrane, the
structure of which we were unable to make out under the highest
powers of the microscope. It appears as a thin, resistent, struc-
tureless membrane. Gilson, 90, has worked out in detail its struc-

No. 489] SILK GLANDS OF APANTELES 569

ture in the larvae of Bombyx mori. He concludes his study by
stating that the producing portion is clothed by an extremely
fine resistent cuticula, in which are found spiral filaments of
various’ thicknesses, united to one another by delicate transverse
or oblique trabeculae. He does not consider that these meshes
are closed by a structureless lamella but refrains from a positive
statement.

As the larvae feed and grow, this portion, during the third
and fourth days, commences to become convoluted; the nuclei
are larger and somewhat branched; the lumen slightly increases.
in size. Gradually, as the cells begin to secrete actively, the glan-
dular tubes become more and more convoluted until, at the time
of emergence of the parasite from the host, they almost completely
fill and greatly distend the perivisceral cavity. These changes are
brought out in the longitudinal sections of young and mature larvae
respectively, Pl. 1, figs. 2 and 4, and in corresponding cross sections,
Pl. 2, figs. 7 and 8.

Along with the great increase in length of the glandular tubes
goes a corresponding increase in size. The cells necessarily
become larger, but their radial diameter diminishes. The lumen
gradually becomes distended by the accumulated product, till,
at the time of the spinning of the cocoon, the walls are reduced to a.
very thin layer (Pl. 1, fig. 11). The figures 9, 10, and 11 show
the enormous increase in the size of the lumen during the very
short larval life. So great is this increase that either cross or longi-
tudinal sections of an adult larva present a very striking appearance,
practically the whole body cavity being monopolized by the silk
gland.

The nuclei in the glands of the young larvae are round or oval
in shape and fill the greater part of the cells (Pl. 1, fig. 9). As
these cells commence actively secreting the nuclei become more
and more branched. ‘The shape of the nuclei at nearly four days
is shown in Pl. 3, fig. 31; during the latter part of the larval life
they appear as if fragmented (Pl. 3, fig. 34). Gilson records com-
plete fragmentation of the nuclei in certain cells of the larger part
of the glandular tubes in Bombyx and Trichoptera. Marshall
and Vorhies, ’06, could not confirm this in the case of Platphylax
designatus and they also deny the anastomosing of the branches..

570 THE AMERICAN NATURALIST [Vol. XLI

In Apanteles glomeratus, owing to the thinness of the glandular
walls, it was impossible to secure tangential sections which would
give surface views of the nuclei. As the nuclei do not stain deeply
at this stage, they are rather difficult to differentiate, although we
secured fairly good results by staining with Grenacher’s borax
carmine, as shown in figure 34.

The cytoplasm is dense, granular, and vacuolated, especially
during the latter part of the larval life when the glands are at the
height of their activity (Pl. 1, figs. 10 and 12). Through the
cytoplasm run trabeculae, extending in many cases from the exter-
nal border to the inner margin of the cell. These trabeculae
appear as fine radiating lines, but later, with the thinning of the
glandular walls, they disappear.

Gilson, ’90, performed some interesting experiments in order
to determine the method of secretion. He ligated the entire liv-
ing larvae, disposing the ligatures in two pairs, the two threads of
each pair being close together. He then divided the larva into
three sections by cutting between each pair of ligatures. Treat-
ing the cut surfaces with mercuric chloride and collodion he secured
living isolated portions of the caterpillar, in each of which the
silk glands, especially near the ligatures, continued to secrete.
In such isolated portions he found vacuoles present in the cytoplasm
and even in the nuclei of the silk glands. These vacuoles he con-
sidered as the silk secretion. He did not succeed in establishing
whether they lay between the radiating trabeculae or not. In
the case of Apanteles glomeratus the condition which Gilson sought
to obtain by mechanical means is the normal one since none of
the secreted product is used till at the time of emergence from the
host. Numerous vacuoles are present in the cytoplasm, becom-
ing most abundant during the time of the greatest glandular activ-
ity. The contents of these vacuoles remain unstained by any of
the coloring agents used, but the secreted product is sometimes
stained as is noted later. Whether the presence of these vacuoles
in the cells is due to the retention of the secreted product in the
lumina of the glands remains an open question.

The thoracic portion of the secretory division of the gland con-
sists of but two secreting tubes, lying one on each side of the ali-
mentary canal (Pl. 1, fig. 1). Each is formed by the union of the

No. 489] SILK GLANDS OF APANTELES 571

two tubes of the abdominal division in the first abdominal segment
and extends cephalad to the short duct which begins just in front
of the sub-oesophageal ganglion. The thoracic portion may be
divided into three well defined parts,— the 1st, or anterior thoracic;
the 2nd, or middle thoracic; and the 3rd, or posterior thoracic
divisions.

The 3rd, or posterior thoracic, division during the first half of
larval life consists of an almost straight cylindrical tube. Later
it becomes much convoluted and its walls become thinner so that
in every way it markedly resembles the abdominal portion. The
cytoplasm is densely granular, deeply staining, and much vacuo-
lated, especially near the periphery of the cells (Pl. 2, figs. 14 and
16).

The 2nd, or middle thoracic division, is quite short and straight.
It extends from the beginning of the second thoracic segment to
the first division. The cells of this portion of the gland have a
greater radial diameter than in any other part. The layer of
“ores” or “gum,” so prominent in the 1st division, is very thin
and in some places difficult to distinguish. ‘The cells are character-
ized by a faintly staining, loosely granular cytoplasm, which near
the periphery of the cells, is much vacuolated (Pl. 1, figs. 19 and
20

The Ist, or anterior thoracic division, is also short and straight.
It extends from the beginning of the first thoracic segment to the
duct. This portion of the gland is characterized by a thick dense
layer of “gres” or “gum” adhering closely to the inner surface of
the secreting cells (Pl. 1, fig. 23; pl. 3, figs. 24 and 30). The
cytoplasm of these cells is dense, granular, and deeply staining,
contrasting strongly with that of the middle or 2nd thoracic divi-
sion as shown in Pl. 3, fig. 24.

The nuclei of these divisions differ mainly in the extent of their
branching. In the Ist they are not so markedly branched as in
the 2nd, and in the 3rd, or posterior division, they are yet more
ramifying. The basement membrane is of the same character as
in the abdominal divisions. The internal lining of the lumen is
more distinct. It appears as a thin, elastic, structureless, cuticular
membrane.

A fact worthy of note is the absence of the glands of Philippi.

572 THE AMERICAN NATURALIST [Vol. XLI

There is no indication of a vestige of these glands, such as Gilson
found in Limnophilus rhombicus, one of the Trichoptera.

The Conducting Division. — The conducting portion of the silk
glands is Y-shaped, with a median stem and branches pointing
caudad; each branch joins the thoracie portion on its respective
side of the body. ‘The press commences at the juncture of the
two branches. ‘The entire conducting portion is very short, being
wholly confined to the labium. In cross section the branches are
seen to be composed of a number of cells surrounding a small lumen
(Pl. 3, fig. 25). The nuclei are oval to rounded in shape,— never
branched. Posteriorly the cells are columnar and contain elongated
nuclei, but anteriorly the cells become flattened (Pl. 3, fig. 30).
There is thus formed an enlarged lumen at the anterior end of
each branch of the conducting tube. Also by the increased radial
diameter of the posterior cells the amount of “gres” or “gum”
that can pass forward is regulated (Pl. 3, fig. 30).

The cuticular lining of these branches forms chitinous folds.
or ridges which are not perfect spirals but appear as incomplete
rings. (Pl. 3, figs. 25, 29 and 30, 7).

The Press.— Although the internal disposition of the silk glands
was familar to the earlier anatomists, nothing was known regard-
ing the mechanism by which the silk thread was formed and
regulated until the time of Lyonet. He designated the entire
labium as the “‘filiere,’’ because it was the instrument which had
been given to the caterpillar for spinning. He was the first to
demonstrate the presence of the press with its attached pyramidal
muscles, but he did not succeed in working out its structure. He
concluded by supposing that this organ acted as a pump to draw
up the silk from the glandular tubes and to force it to the exterior.

Dr. Azoux, ’49, in his classic model of the silk worm, represents.
with exactness these pyramidal muscles of the press.

Helm, ’76, was the next worker who added anything new
regarding this organ. His figures and descriptions of its structure
are not at all exact yet he arrives at correct conclusions regarding
its function. He considered it to act simply as a press in the
formation of the silk thread. It was not till the important works
of Gilson and Blanc that the minute structure of this organ in Lep-
idoptera and Trichoptera was known and its functions clearly

enned. ;

No. 489] SILK GLANDS OF APANTELES 573

Berlese, ’06, denies the presence of a press in the silk glands of
the larvae of Hymenoptera, Diptera, and Coleoptera. He figures
a sagittal section of the head of the larva of Xylotoma rosae but
does not represent muscles as present in the region of the con-
ducting tube. On the other hand the presence of a press in hymen-
opterous larvae has been recorded by Eckstein, ’90, in Lyda
pratensis, and Pikel, ’96, in Lophyrus pini. Both of these workers
figure this organ as present but give no definite details regarding
its structure. Pikel states that in structure it is similar to that
described by Tichomirow for Bombyx mori.

Structure of the Press.— In the case of Apanteles glomeratus the
press is highly developed. It commences at the union of the two
conducting tubes in the region of the labium and occupies more
than half of the common duct. Dorsally the press is concave,
traversed by a longitudinal furrow into which pass the dorsal pair
of muscles as shown in cross and longitudinal sections in Pl. 3,
figs. 27,29 and 30. The ventral surface is convex (Figs. 27 and 30);
its cells are somewhat elongated and secrete the thicker chitinous
layer of the common duct. The dorsal muscles consist of numer-
ous fibers which are attached directly to the chitin along the longi-
tudinal median furrow as shown in figures 27 and 29. Emerging
from this furrow the muscles separate laterally and, passing dorso-
caudad, are inserted on the chitinous layer of the floor of the
buccal cavity (Fig. 27). The ventral muscles are each composed
of several fibers. ‘They are located as shown in cross section in Fig.
27. They are inserted on opposite sides of the press and, passing
almost directly ventrad, have their origin on the ventral body wall,
being attached directly to the chitin. »

The lumen of the press, as seen in cross section (Fig. 27), is horse-
shoe-like in form. When the muscles are relaxed this lumen is prac-
‘tically closed, thus preventing the further egress of the thread. The
lumen is lined with a thick chitinous layer which is more strongly
developed on the ventral side. This chitinous layer is directly
continuous with that of the ducts. In Fig. 27 the dorsal portion of
this layer appears thick, but this is due to the obliquity of the section
which was necessary in order to show the muscles in one section.

In very young larvae the press is not yet developed. The dorsal
- median furrow and the attached muscles cannot be distinguished

574 THE AMERICAN NATURALIST [Vol. XLI

and it is not till about three days after hatching that the furrow
and attached muscles become clearly differentiated. Being func-
tional for such a short time its complete development does not
take place till late in the larval life. It is not till shortly before
emerging from its host that the press becomes completely developed
as it is not necessary that it should be fitted for spinning during the
entire lifetime of the larvae but only for the very short time occupied
in the building of its cocoon.

In structure the press differs from that described for Lepidop-
tera in that the lateral pair of muscles is not present, and from
that of the Trichoptera in that each dorsal muscle is single and not
divided into two distinct bundles as figured by Gilson.

Functions of the Press.— The functions of the press in the Lepi-
doptera have been carefully worked out by Gilson and Blanc and
there is no doubt that the functions of this structure in the Hymen-
optera are similar. These functions may be summed up as fol-
lows, — .

1. The press modifies and regulates the form and diameter of
the two threads. |

2. It regulates the layer of “gres” or “gum” which surrounds
these threads.

3. By the relaxation of the muscles the chitinous walls, on
account of their elasticity, contract and hold the thread immovable
as in a vise.

Gilson attributes to the press another function, that of forcing the
thread to the exterior when by accident or voluntarily the thread
is broken in the spinneret. This is denied by Blanc who holds
that the contraction of the-muscles of the press, distending its
lumen to the fullest extent, together with the pressure upon the
contents of the gland due to the elasticity of its walls, and the general
muscular contractions of the body, serve to force the thread to the
exterior when broken in the spinneret or even in the conducting
tube.

In the case of Apanteles glomeratus we do not think the press
possesses the latter function attributed to it by Gilson, inasmuch
as the pressure exerted by the elastic walls of the abdominal portion
and the general contractions of the somatic muscles along with
that of the muscles of the press, seem to us a more correct explana-

No. 489] SILK GLANDS OF APANTELES 575

tion of how the thread is first forced to the exterior and also how it
is extruded when broken.

It is not necessary for us to describe the mechanism of spinning
as that has been fully done by Blanc and Gilson for the Lepidop-
tera and their descriptions serve equally well for the hymenopterous
larvae. The method of spinning the cocoon in Apanteles glomera-
tus has been well described and figured by Reaumur.

The Spinneret.— From the press a short chitinous tube leads to
the spinneret (sp. Figs. 28, 29 and 30). The lumen of this tube
gradually widens as it approaches the exterior (Figs. 29 and 30).
The entire length of the common duct is .875 mm., of which the
press occupies .4 mm. ‘The spinneret is situated just beneath the
buccal cavity and consists of two small chitinous projections
directed cephalo-dorsad (Fig. 28, sp.).

Functions of the Different Parts of the Silk Gland— Abdominal
Division. As previously pointed out the abdominal division of
the silk glands consists, in the young larvae, of two pairs of straight
cylindrical tubes lying on each side of the alimentary canal. As
the larvae grow these parts become active, their lumina become
gradually distended with the secreted product till, in the mature
forms, the glandular walls are so thin as to warrant the assertion
that they have practically ceased to secrete and are meny reservoirs
for the accumulated product.

The question as to whether the “gres” or “um” is secreted
by one particular region of the gland and the silk by another is still
unsettled. Gilson in 1890 and again in 1894 came to the conclu-
sion that both are secreted throughout the gland; and that the
silk, properly speaking, is the result of a selection effected in the
layer of secreted product lying next the internal face of the cells.
Whether this process of selection is a chemical phenomenon or
merely a physical separation, he does not attempt to decide. From
a study of several series of sections he concludes that the outer or
cortical layer of the secretion is granular in appearance and has
special affinity for coloring agents. Neither of these conclusions is
absolute since he did not find them to hold true in all cases.

Blanc, ’89, p. 24, states that “ The silk secreted in the posterior
part of the gland is discharged continuously into the reservoir and,
on its arrival there, it is surrounded by a new material which is

-

576 THE AMERICAN NATURALIST [Vol. XLI
formed in this region. This substance is the ‘gres.’” He con-
siders (pp. 27-28) the “ gres” as nothing more than the peripheral
layer of silk oxidized in the reservoir, the oxidation being due to
the presence of a large number of tracheae in this region.

In the abdominal portion of the silk glands of Apanteles glomera-
tus the secretion appears as a hyaline, faintly staining product.
Fixation in Flemming’s solution and staining with iron haematoxy-
lin gives it a greenish color, the peripheral portion often being
black. In the anterior part of the abdominal portion the peripheral
layer is always stained black. Safranin colors the entire secretion
salmon color, the peripheral layer always more deeply, especially
in the anterior part of the abdominal portion. Mayer’s acid
haemalum and eosin do not color it at all.

Judging from the staining properties of the secretion the conclu-
sion that there is a differentiation between the peripheral layer and
the central column appears justified. Whether this peripheral layer
is the “ gres” or not is a question which we do not pretend to answer.

Thoracic Division. ‘This portion of the gland remains actively
secreting much longer than the abdominal division. . The char-
acteristic appearance of an actively secreting portion is shown in Pl.
2, fig. 16. The peripheral area often appears less deeply stained
and numerous vacuoles are always present.

The character of the secretion in the posterior thoracic division
appears similar to that of the abdominal portion except that the
peripheral layer has a greater radial diameter and that vacuoles
are generally more numerous. It also takes the same character-
istic colorations. |

The anterior and middle thoracic portions secrete a somewhat
different product. The character of the cells of the middle portion
would indicate that such is the case here at least. Fixation in
Fleming’s solution and staining with iron haematoxylin gives to
this division a very characteristic appearance. The cytoplasm
is filled with rather large rounded black granules thus easily differ-
entiating this portion from the other two thoracic divisions. ‘The
nature and function of these granules we were unable to determine.
In similarly treated glands many identical black granules are seen
near the internal surface of the cells just within the internal mem-
brane. ‘These granules are present in all parts of the gland except
the first thoracic division (Pl. 1, figs. 10 and 12).

No. 489] SILK GLANDS OF APANTELES 577

The dense secretion covering the inner surface of the 1st thoracic
portion indicates that this is its own peculiar product and not that
of the following division. This secretion appears closely striate
in a radial manner. Acid haemalum and eosin do not color it;
iron haematoxylin, safranin, and Grenacher’s borax carmine stain
it but slightly. The central column of silk, however, is more
densely stained with iron haematoxylin and safranin.

As the glands of Philippi are not present it is only speculation
to suppose that the secretion of the second thoracic portion may be
of a nature similar to that of these glands in the Lepidoptera. The
function of the product of the glands of Philippi is not definitely
known. Nearly all workers differ in their conclusions in regard
to this question. The conclusion of Blanc, ’91, and Berlese, ’06,
based upon the experiments of Robinet, ’39, seems the most logical.
These authors consider its function that of lubricating the thread
which is to pass through the press.

The fact that the thread, in Apanteles glomeratus, begins to take
on its definite form at the posterior end of the 1st thoracic portion
might indicate that the secretion of the 2nd division had a coagu-
lating effect upon the silk and “gres.”

SUMMARY

1. The silk glands of Apanteles glomeratus differ from those
in the Lepidoptera and Trichoptera in that there are four tubes
in the abdominal region. Their histological structure is similar
to that of Lepidoptera and on but differs markedly from
that described for the tenthredinid larv

2. In immature larvae the epithelial cell of the whole produc- _
ing region are actively secreting. Numerous vacuoles are present
in these secreting cells, especially near the periphery.

3. In glands fixed in Flemming’s solution and stained with iron
haematoxylin there are present, near the inner margin of the
secreting cells, many black rounded granules. ‘These are very
abundant in the 2nd thoracic portion and absent in the 1st thoracic
portion. Their nature and function we were unable to determine.

4. In mature larvae the abdominal division becomes greatly

578 THE AMERICAN NATURALIST [Vol. XLI

distended and nearly fills the entire body cavity. It is probable
that this portion now acts merely as a reservoir and that its cells.
have ceased secreting.
5. The glands of Philippi are absent and it is probable that
the second thoracic portion performs the functions of these glands.
6. The press is well developed. It differs from that of the
Lepidoptera in that the lateral pair of muscles is absent, and from.
that of the Trichoptera in that there is a single pair of dorsal
muscles rather than two distinct pairs.
_ 7. The product of the gland is a double thread as in the Lepidop-
tera and Trichoptera.

CoRNELL UNIVERSITY
Ithaca, N. Y

BIBLIOGRAPHY

BERLESE, ANTONIO.

1907. Gli Insetti, loro organizzazione, sviluppo, abitudini e rapporti

coll’uomo. 1907, vol. 1, pp. 521-523
Borpas, L.

1895. Appareil ee des Hymenopteres. Ann. Sei. Nat. Zool.,

1895, vol. 19, pp. 12-2
CARRIERE AND BÜRGER.

1897. Die Entwicklungsgeschichte der Mauerbiene (Chalicodoma.
muraria Fabr.) im Ei. Nova Acta Acad. Leop. Car., 1897,
vol. 69, No. 2, pp. 342-350.

CHOLODKOVSKY, N.

1895. Eintomotonilache Misceller, I. Ueber die Spinndrüsen der
Tenthredinidenlarven. Horae Soc. Ent. Ross., 1895, vol. 29, pp.
145-149, pl. 2.

1901. Ueber den Spinnapparat der Lyda-Larven. Allgem. Zeit. f.
Ent., 1901, vol. 6, pp. 17-19.

Eckstein, K.

1890. Zur Biologie der Gattung Lyda. Zool. Jahrb., 1890, Abth. f.

Sys. 5, p. 427, pl. XXXV.
DE GEER, K.
1762-78. Memoirs pour servir a l’histoire des Insectes. Stockholm.
GILSON, G.

1893. On Cytological Differences in Homologous Organs. 63rd Rept.
Brit. Ass. Adv. Sci., 1893, pp. 813-816.

No. 489] SILK GLANDS OF APANTELES 579

Hennecvy, L. F
1904. Les Insectes, 1904, p. 466.
KIRBY AND SPENCE.
1828. An Introduction to Entomology. 1828, vol. 3; p. 125.
KoLßge, H. J.
1893, nn in die Kentniss der Insekten. 1893, p. 623.
NEWPOR
1852. heats and Development of Certain Chalcididae and Ichneu-
monidae, compared with their special economy and instincts.
Trans. Linn. Soc. Lond., 1852, vol. 22, pp. 61-67.
PIKE, V.
1896. Zur Frage iiber die Spinndriisen der Tenthrediniden-larven.
Horae Soc. Ent. Ross., 1896, vol. 30, pp. 122-128, Taf. VIII.
POLETAJEW, N.
1885. Ueber die Spinndrüsen der Blattwespen. Zool. Anz., 1885, pp.
22-23.

RAMDOHR, K. A.
1811. Abhandlung über Verdauungswerkzeuge der Insecten. 1811,
p. 58-65 and p. 143.
SEURAT, L. G.
1899. Etude des Hyménoptéres Entomophages. Ann. Sci. Nat., 1899,
(8) 10, p. 62.
Westwoop, J. O.
1840. Classification of Insects. 1840, vol. 2, p. 78.
Perez, C.
1901. Histolyse des tubes de Malpighi et les glandes nn chez
la Fourmi rousse. Bull. Soc. Ent. Fr., 1901, pp.
WHEELER, W.M.
1898. The Embryonic Development of the Wall Bee (Chalicodoma
; muraria Fab.). Am. Nat., 1898, vol. 32, pp. 794-798. A review
of Carrière and Bürger’s work.

580 THE AMERICAN NATURALIST [Vol. XLI

EXPLANATION OF THE FIGURES.

"Fig. 1, pl. 1.— Optical section of a young larva shortly after hatching, show-
ing the arrangement of the silk glands. (s. g

Fig. 2, pl. 1.— Longitudinal section of a young A about six days old.
The silk glands have not yet become much convoluted.

Fig. 3, pl. 1.— Mature a aae the enormous increase in the size of
the silk glands (s. 2.5.

Fig. 4, pl. 1.— Longitudinal PETER ve a mature larva. X 12.5.

Fig. 5, pl. 2.— Cross section of a young larva (about one day old) in the
thoracie region. 130.

Fig. 6, pl. 2.— Cross section of a mature larva in the thoracic region. X 37.5.

Fig. 7, pl. 2.— Cross section of a young larva (shortly after hatching) in
the abdominal region.

Fig. 8, pl. 2.— Cross section of a mature | the abdomi egion. X 37.5.

Fig. 9, pl. 1.— Cross section of the posterior end of one of the tubes of the
er division of the silk glands. From a larva just hatched.

267.5.

Fig. 10, $f 1.— Cross section of the same portion of the gland as in Fig. 9 but
at a later period of the larval life. X 267.5.

Fig. 11, pl. 1— Cross section of the same portion as shown in Figs. 9 and
10 but from a mature larva. .5.

Fig. 12, pl. 1.— Section of a portion of the glandular wall of the abdominal
division showing presence of vacuoles (v) and radiating trabeculae
in the cytoplasm. X 260.

Figs. 13, 14, and 15, pl. 2.— Cross sections of the third thoracic portion
at different periods of the larval life; Fig. 13 shortly e ae
Fig. 14 at a later period, Fig. 15 from a mature larva. ;

Fig. 16, pl. 2.— Section of a portion of the 3rd thoracic Helden arme
numerous eg E near the periphery of the cells. From an
immature larva 260.

Fig. 17, pl. 2.— Section b portion of the 3rd thoracic division in a mature
larva, showing the great thinning of the glandular walls.

Fig. 18, pl. 1.— Cross section in the region of the 2nd thoracic portion. From
a larva about two days old. 0

Fig. 19, pl. 1.— Cross section of the 2nd thoracic portion from a nearly mature
larva. X 260.

Fig. 20, pl. 1.— Section of a portion of the 2nd thoracic portion, showing

numerous vacuoles (v) near the periphery of the cells. x 260.

Fig. 21, pl. 1.— Union of the 2nd and 3rd thoracic divisions. 260.

Fig.'22, pl. 1.— Buriace vi view of the cells of the 2nd thoracic portion. 260.

Fig. 23, pl. 1 of the Ist thoracic division immediately behind
the conducting portion.

Fig. 24, pl. 3.— Longitudinal section of the point of union of the 1st and
2nd thoracic portions. X 2

Fig. 25, pl. 3.— Cross section of one ot the conducting branches. X 260.

Fig. 26, pl. 3.— Cross section of the common duct just behind the press. X

-

No. 489] SILK GLANDS OF APANTELES 581

Fig. 27, pl. 3.— Cross section of the press, showing the muscular attachment;
d. m., dorsal muscles; v. m., ventral muscles. X 260.

Fig. 28, pl. 3.— Lon gitudinal section of the press, showing the position of,
the dorsal and ventral muscles, s. t., silk thread passing through the
press to the spinneret.

Fig. 29, pl. 3.— Same as Fig. 28, but ähowink the attachment of the muscles
‘iecetty to the chitin of the conducting tube. X 267

Fig. 30, pl. 3.— Longitudinal section of the press, of one ot the PRR
branches, and of the beginning of the 1st thoracic portion. a., poin
of union with the conducting branch of the opposite side. X 267. ns

Fig. 31, pl. 3.— Surface view of a cell and its nucleus, from the abdominal
portion. From a larva nearly four days old. 2

Fig. 32, pl. 3.— Surface view of a cell and its nucleus, from the anterior end
of the 2nd thoracic portion of a mature larva. X

Fig. 33, pl. 3.— Surface view of a cell and its oe nucleus, from the
posterior portion of the 3rd thoracic division x 260.

Fig. 34, pl. 3.— Portion of a cell and its nucleus, lia the abdeminel division
of the glands of a nearly mature larva. X

List of Abbreviations

a. Ci, ee canal. m., musel

b. c., buccal ca m. t., Malpighian tube.
b. Ma a ne n. c€., nerve cord.

br., brain nu., nucleus.

Š: rs common conducting tube. ov., ovary

ch., thitin. s om

co. l., cortical layer.
d. m., dorsal muscle.

`e. d., conducting tube. bp., pioni.
f. b., fat body. s. t., silk thread.
“ gres” or “gum.” tr., trachea
ht., heart. v., vacuole.
in., intima. v. m., ventral musel

int., intestine. i ;
yp., hypodermis. 2nd. t., 2nd or middle thoracic.

l., lumen. 3rd. t., 3rd or posterior thoracic.

PLATE 1

PLATE 2

ir

NG SEEEN
tt EN
er vn Ya

ZOEK or
G A RREN 5 f
KSS

- PLATE 3

THE NEST OF THE KELP FISH
CHARLES F. HOLDER

One of the most interesting fishes found in the great kelp beds
along the shores of Southern California is the so-called kelp fish,
Heterostichus rostrata Girard. In color it closely resembles the
sea weed in which it habitually lives. During the past year two
adult kelp fishes and a smailer fish of another kind occupied one
of the tanks in the Santa Catalina Island Aquarium. ‘The larger
kelp fish, a female, was about nine inches in length; the male
measured about five inches. I was attracted to them by the savage
attacks of the male on the stranger, and investigation showed that
he was in nuptial colors and was attending the female. The
offending fish was removed giving the kelp fishes the entire tank.

All the colors of the male kelp fish were highly accentuated and
brilliant. What had been white was now lavender and silver;
the dark angles of the zig-zag barring took on darker tints and were
emphasized by countless lines of lavender, yellow, blue and gold;
patches of silver, old rose, lavender and white appeared here and
there the entire length of the fish, making it a most gorgeous crea-
ture. The long vibrating dorsal fin was erect, and the fish was un-
usually alert as if sensible of the importance of the situation and
its responsibilities. |

In the tank were several small bunches of a deep maroon sea-
weed four or five inches high; and as I watched the female, large
and heavy with spawn, she approached the weed and appeared to
examine it, passing around it several times. Then I saw that her
ventral surface was pressed against the weed and that its branches
were being caught together by a viscid pure white cord having
the diameter of a thick thread. It clung tenaciously to every branch
it touched. Along the cord were large numbers of small eggs.
When four or five inches of the cord had been attached, the fish
would rest, the male taking her place and hovering over the eggs
which he guarded with a viciousness altogether unexpected in so
small a fish. He withdrew when his mate resumed egg-laying.

587

588 THE AMERICAN NATURALIST [Vol. XLI

She frequently pushed her way through the clump of weed but more
often passed around it, the silken tenacious cord binding it together
in a globular or oval mass about the size of a hen’s egg. The
entire nest shown in the photograph was formed in about two hours,
the fish dropping to the bottom of the tank after each effort and lying
there for ten or twenty minutes.

The accompanying photograph of probably the first nest of
Heterostichus to be recorded was made under my direction by

y

Charles Ironmonger, of Avalon, Cal. It was necessarily taken
under cover and through glass and water, all efforts being directed
toward having the nest in focus. The head of the female fish
shows indistinctly below. Although the photograph was so success-
ful that the eggs within the strands could easily be seen with a hand
lens, there was no indication of the beauty of the pure white nest
among the rich purple and lavender weeds.

PASADENA, CAL.

NOTES AND LITERATURE
GENERAL BIOLOGY

Specific Characters in Early Embryos.— In a recent contribution
to the Naturalist it is asked if “by and by we are going to find specific
characters in the eggs of animals as well as in their adult condition.”
In the seventeenth century this was believed to be true, since the egg
was supposed to contain in miniature the adult form to which it should
give rise. Early in the nineteenth century, however, it was thought
that the embryos of the higher animals passed successively through
stages corresponding with the adults of lower forms. With the theory
of evolution, it began to be considered that the early embryos in dif-
ferent groups of animals were identical and that specific characters
were late acquisitions. A few interesting expressions of this opinion
are as follows:

“Embryology has revealed the strange resemblance which exists,
at the beginning of their formation, between the embryos of different
vertebrates; it has shown how each embryo before taking its final
form hesitates, so to speak, between different specific forms.

“Take, for example, the case of the highest organism, Man....
When his animality becomes established, he exhibits the fundamental
anatomical qualities which characterize such lowly animals as polyps
and jelly fish. And even when he is marked off as a vertebrate it can-
not be said whether he is to be a fish, a reptile, a bird, or a beast.
Later it becomes evident that he is to be a mammal; but not till later
can it be said to which order of mammals he belongs.’”?

“The embryo of a mammal at the stage which represents a gill-
bearing vertebrate, in all cases which I have examined, ranges from
one third of an inch to an inch in length; the former size belongs to
the smaller kinds, the latter to the larger. Know one, know all; one
diagram would represent all, one description serve for all.”

“The careful investigation and comparison of embryos of man and

‘Cresson, A. Les bases de la philosophie naturaliste. Paris, Félix Alcan,
1907. p. 64.
? Romanes, ze ` Darwin, and after Darwin. Chicago, Open Court Publ.
Co., 1892. p.
. ‘Parker, W. k On mammalian descent. London, Charles Griffin Co.,
1885. p.
589

590 THE AMERICAN NATURALIST [Vol. XLI

other vertebrates... .is highly instructive and discloses to the thought-
ful person deeper and weightier secrets than are to be found in the
so-called ‘‘revelations” of all the religions of the earth. Compare
attentively the successive stages of the chick, pig, rabbit, and man
shown in the accompanying figure. In the first stage (the upper row),
in which the head with the five cerebral vesicles and the gill arches are
clearly marked out but the limbs are still wholly absent, the embryos
of all vertebrates from fishes to man differ from one another either
unessentially or not at all. In the second stage (the lower row), in
which the limbs have begun to develop, distinctions between the
embryos of lower and higher vertebrates have begun to appear; yet
the human embryo even now is scarcely to be distinguished from those
of the higher mammals... . These are facts the significance of which
cannot be overestimated.”

As drawings of embryos, the well known figures of Haeckel here
reproduced are totally valueless. The front limbs have been trans-
ferred to the neck, and the characteristic features by which any one
familiar with embryos can distinguish a pig from a rabbit have been
wholly overlooked. Although Parker declared that ‘one diagram
would represent all,’ his figure of the embryo mole could not possibly
be mistaken for a pig. Moreover the pig at this stage could be dis-
tinguished from the rabbit or man by its pancreas alone. The com-
parative study of embryos to detect generic and specific differences
has not been carried far, but from such publications as Keibel’s Nor-
mentafeln of the pig and rabbit it is evident that at no stage in their
development is there a confusing similarity in external form.

In place of Haeckel’s upper row of figures, those of still younger
stages may be substituted, in which the differences are more obvious.
The spherical yolk of the hen’s egg, the elongated vesicle of the sheep
(that of the pig being quite as long but not so slender), the round
smooth vesicle of the rabbit and the villous human vesicle are radically
different from each other. Since these membranous structures are
parts of the embryo they must be regarded as expressions of differences
existing at an early stage. Since a given egg cell can produce only
one species of animal it must, according to current embryological
belief, contain specific characteristics, and if an inheritable peculiarity
appears in any adult animal it will modify to some extent the egg cell
and every succeeding stage of development. Thus, according to

1! Haeckel, E. Anthropogenie. 3rd ed. Leipzig, W. Engelmann, 1877,
p. 288-289.

No. 489] NOTES AND LITERATURE 591

from Romanes’ copy of Haeckel’s figures. The — a, sheep, 12
days 2} hours, $ nat. size (Bonnet); b, chick, Te hot ours , incubation, 3
nat. size; c, rabbit, 7 days, X 2; d, man, 12-13 days X 2 (Reichert); e,
chick, 5 days, 8.5 mm.: f, pig, 20 days, (?), 9.0 mm.; g, rabbit, 12}
days, 8

Hertwig, there are as many kinds of egg cells as there are species or
kinds of animals or plants. Morgan, after an interesting historical
consideration of the question, says,— “I should not expect to find
the embryos of any two species identical at any stage in their develop-
ment, but at most there might be a close resemblance between them.”!

1 Morgan, T. H. Evolution and adaptation. New York, The Macmillan
Co., 1903, p. 74.

592 THE AMERICAN NATURALIST [Vol. XLI

Montgomery states that two species are as distinct in the egg-cell stage
as in any later one, “‘no matter whether the differences are as percepti-
ble or not.” Such a statement, however, evades the question whether
or not embryos of related species can actually be distinguished from.
one another.

The four suborders of rodents, represented by the squirrel, mouse,
guinea pig, and rabbit respectively, according to Lee may be distin-
guished at very early stages. His studies do not enable him as yet to
recognize the genera of one suborder,— namely the gophers, prairie
dogs, squirrels, and chipmunks — until the embryos are far advanced.
Differences in tunicate eggs of closely related genera have, however,
been recorded by Conklin, and McClung can distinguish several
species in one genus of grasshoppers by the chromosomes of their
germ cells.

FELL

ZOOLOGY

New Text Books of Zoology.— The most important service that
biology can render to students is to train their reason and their power
of observation, and to free them from a too deep reverence for authority.
This service can also be performed by the other natural sciences,
physics and chemistry, which are commonly included in the curricula
of high schools but which require expensive apparatus beyond the
reach of many schools. Biology, however, can profitably taught
with so slight an equipment that every school can afford to undertake
to teach botany or zoology, or both. The teaching of biology has
often failed to yield the results that educators have expected. This
is so because teachers too often yield to the temptation to tell the
students the facts and theories which they ought to learn by their own
efforts, instead of ~ them how to discover, to ni: and to
draw proper conclusio

Professor Glenn W. Herrick, of the Mississippi Agricultural College
has endeavored to meet the needs of the high school of limited means
whose students will, as a whole, have no further instruction in biology.
He presents to such students a laboratory guide containing directions
for the examination (we can scarcely say for the dissection) of some-

1 Montgomery, T. H. The pone of racial descent in animals. New
York, Henry Holt and Co., 1906. 192.

No. 489] NOTES AND LITERATURE 593

thing more than twenty species of vertebrates and invertebrates,
together with questions, the majority of which appear to be answered

by the context, the remainder by the companion text book.! This
method seems to us unwise and the book is apparently less useful than
Kingsley’s Elements of Comparative Zoology (2nd. ed., Henry Holt
and Co., 1904). The latter is a cheaper book which gives facts that
are otherwise inaccessible to the student and asks questions which
can be answered without appeal to costly apparatus, about easily
obtained and inexpensive animals. The answers, the student must
gather while learning both to find and arrange facts and to draw right
conclusions. A more extensive work is that of Linville and Kelly;
their Text Book in General Zoology and Guide for Laboratory and Field
Work in Zoology (Ginn. and Co., 1906) give facts and suggestions,
especially for the reading of original articles, together with necessary
deductions; and ask most interesting and suggestive questions which
the student must answer from his own work. The conscientious use
of any of these books will give the student about the same facts, but
Kingsley, and Linville and Kelly, compel the student so far as a book
can do so, to observe and think, which is the most desirable service
to the memory-laden youth. It really makes little difference how
many facts are given to a student, whatever his future may be; the
method of study is of primary importance.

Some of Professor Herrick’s diagrams are not wholly correct. For
example Fig. 70, which is very much like the excellent figure of a male
crayfish in McMurrich’s Invertebrate Morphology (Fig. 168), is labelled
as a female. It is the sperm duct, and not the oviduct as in Herrick’s
figure, which opens at the base of the last thoracic limb. The follow-
ing statement from page 33 of the text book is an example of defective
fact and theory,— “ It may seem strange that the oldest animals (Pro-
tozoa) are the simplest, but it is true. It is probably due to the fact
that these animals have always lived in the water and the water is
probably not very different today from what it was ages ago. Hence
there has been nothing to bring about change in these animals, and
they have remained much the same.” It is needless to say that Pro-
tozoa or even Amoebae are not confined to the water and that very
many highly developed animals have been evolved in water.

For more advanced students Dr. Gilman A. Drew, Professor of

‘Herrick, G. W. Laboratory Exercises fe General ite New York,
American Book Company, 1907. 12mo., 110 pp.

Herrick, G. W. Text Book in Dania En Rew “York, American
Book Company, 1907. 12mo., 386 pp. $1.2

594 THE AMERICAN NATURALIST [Vol. XLI

Biology at the University of Maine, has written a Laboratory Manual
of Invertebrate Zoology.’ This book is essentially like Bumpus’ Labora-
tory Course in Invertebrate Zoology, the first edition of which appeared
fifteen years ago, and both are the result of the teaching of zoology
at the Marine Biological Laboratory at Woods Hole. The later book,
however, differs from the earlier in the addition of tables of classifi-
cation, an index and a glossary, as well as in the number and length
of the directions for dissection.

The second edition of Bumpus’ book (1893) gives directions for the
dissection of 31 species in 141 pages, while Drew deals with 90 species
in 174 pages or, if we exclude the 16 pages devoted to classification,
in 158 pages.

This large increase in the number of species without a corresponding
increase in the size of the book does not indicate superficiality, as might
reasonably be inferred, but is due to the desire to show the student
something of the range of modifications in structure and of the marvel-
lous adaptation to environment found among invertebrates. A good
example of this is seen in the treatment of the annelids. Nereis and
Lumbricus are each given a moderately full description: the speciali-
zation of the swimming and sensory organs are emphasized in the
former; the nephridia, reproductive organs and musculature in the
latter. Other genera show budding; the formation of scales, tubes
and shells of various form and material; types of gill; and the dif-
ferentiation of the body into two or three regions. This is really
splendid and we hope that our fear is unwarranted that internal
anatomy is given too small a place. This fear is in a measure justified
by the fact that the coelom of echinoderms is not mentioned, that of
mollusks is indicated only by references to the pericardium and, in
the squid, to the ovary “inclosed in a capsule from which the oviduct

eads.’

The wealth of living material demanded by the book ought to limit
its use to marine stations or to schools near the ocean. The glossary
is not perfect but is useful. The term nephridium is not defined and
the excretory organ of molluscs, which is a nephridium, is called in the
text a kidney; and the definition of the kidney is,— “Frequently
applied to the excretory organ of an invertebrate.” The hypophysis
is defined as “a ventral projection from the brain of Chordata.”

The book has excellent features and in the second edition which
will be demanded soon, minor faults will be eliminated. The boo

! Drew, G. A. A Laboratory Manual of Invertebrate Zoology. Philadelphia,
W. B. Saunders Co., 1907. 12mo., 201 pp.

No. 489] NOTES AND LITERATURE 595

will probably serve another decade as well as Bumpus’ book has
served students of zoology for the past ten years.
Leonarp W. WILLIAMS

Books of Nature Study.— The American Book Company is issuing
a series of ‘‘Eclectic Readers” for lower grammar school grades.
These include The Trail to the Woods! by Clarence Hawkes, and
Half Hours with Mammals,? by Charles F. Holder. The former is
chiefly a collection of hunting stories. It tells of foxes who “stop a
moment to consider” and who have learned to place a wounded foot
in cold water ‘to draw out fever and pain.” With the humanizing
of the foxes there is a cold-blooded account of their destruction — “‘ As
the club said, ‘They were just old enough to play nicely.’ By seven
o'clock the pelts of two of them were dangling from the pockets of
lucky hunters.” This is not good reading for children.

The book by Dr. Holder in some respects suggests Wood’s Natural
History. It is intended for intermediate grades. The student is
advised not to accept the reports of “honest men and women” who
impart to animals such traits as “would astonish the bear, fox and
others could they read the English language”; but the author states
that animal intelligence differs from human intelligence only in degree.
His frequent references to his own observations, particularly of Cali-
fornian animals, form a considerable part of the book. Of the gopher
he says,— ‘I have seen my favorite carnations waving wildly as
though an earthquake was shaking them. Then the stalk and flower
would disappear, being hauled down into the burrow and eaten.”
The Reader is fully and attractively illustrated.

Pictures from Nature’s Garden’ is an English book comparable with
Bigelow’s Spirit of Nature Study. It contains reminiscences and
stories about children and butterflies, the author being very fond of

oth. Several of the photographic illustrations refer to mimicry and
protective adaptations, which the reviewer believes are interpreted
with the simplicity which led Topsy, as described on page 38, to con-
found frogs’ eggs with tapioca pudding. To justify the child’s mistake
the author presents a photograph of both. After an interesting descrip-

1 Hawkes, Clarence. The Trail to the Woods. New York, American Book
Company, 1907. 12mo, 176 pp., illus

? Holder, Charles F. Half Hours with Mammals. New York, American
Book Company, 1907. 12mo, 253 pp., illus.

*Shepheard—Walwyn, H. W. Pictures from Nature’s Garden. London,
John Long, 1907. 8vo, 311 pp., illus. s

596 THE AMERICAN NATURALIST [Vol. XLI

tion of his butterfly-house, a green-house devoted to rearing plants and
insects together, he writes as follows ;— ‘‘In my younger days I myself
amassed an extensive collection of butterflies and moths....I have
the collection still, and never look upon it without pride. Friends love
to gaze upon the Scarlet Tigers, Clouded Yellows and mammoth
Death’s Heads; white bearded fossils come down from afar and beam
upon it — but when all’s said and done what else is it but a collection
of corpses? Beautiful though they may be to look upon, arranged
systematically with pinions outstretched upon the clean white paper —
how much more beautiful to gaze upon the living form flashing its
gorgeous wings in sunlight, throbbing with the exuberance of life!”
This is a frank statement from a collector, but one which is character-
istic of the times; interest is being transferred from collections to nature
itself.
FD ds

Birds of Labrador and of the Chicago Area.— The Birds of Labrador
are well presented by Dr. Charles W. Townsend and Glover M. Allen
(Proc. of the Boston Soc. of Nat. Hist., vol. 33, pp. 277-428). In the
introduction the authors describe first their visit to Labrador in the sum-
mer of 1906; then the topography, the faunal areas, paths of migra-
tion, and ornithological history of the region; and finally the bird and
egg destruction which in 1833 filled Audubon with “horror and dis-
gust.” “Where fishermen are numerous sea birds are very scarce”
and the authors hope that “the wonderful nursery for water birds in
Labrador will not be entirely depopulated but that sufficient protection
for the breeding birds will be given and that speedily, before it is too
late.”

The introduction is followed by an annotated list of all Labrador
birds, and the book concludes with a table showing the approximate
number of each species observed by the authors, a bibliography, and
a map. This publication (which is sold separately) will be of interest
to the large number of students of local birds in eastern United States,
for Labrador is the destination of many familiar migrants. It is
unusually well written.

The Birds of the Chicago Area are similarly treated by Frank M.
Woodruff (Bull. 6 of the Nat. Hist. Survey, Chicago Acad. of Sci., 221
pp.). The introduction contains notes on the favorable localities for
studying birds, their migration, the rapacity of collectors, ete. The
catalogue of species brings together a large body of facts covering a
long period of observation. Sometimes, however, the list of synonyms

No. 489] NOTES AND LITERATURE 597

occupies more lines than the account of the bird, as with the savanna
sparrow and purple martin. An amusing feature of the extensive
bibliography is the translation of the titles of newspaper articles into
intelligible form, for example,— Linger in Winter’s Lap. (An account
of birds which delayed their migration.)— Birds of Mystery at Lake
Forest. (Notes on evening grosbeaks.)— The twelve half-tones of birds
or bird haunts include a photograph of a colony of great blue herons,
twenty miles north of Chicago.
ERE

The Excess of Male Births.— In the May Naturalist (vol. 41, p.
303) A. H. Pike discussed the significance of the excess of male births
in human offspring, extensive statistics indicating that 106 males are
born for every 100 females. In the June issue of the Proc. of the
Cambridge Phil. Soc. (vol. 14, p. 122) Walter Heape presents the
best available statistics for dogs. Among 36,867 pups of registered
stock there are 117 males for every 100 females. Of some twenty
breeds considered, all showed an excess of males except two, the
figures for which were based on limited returns. 'The excess of males
is apparently greater in large breeds of dogs than in small ones. Mr.
Heape believes that the latest moment at which sex of offspring can
be determined is the time of fertilization. However, since nutrition
of the parents may alter the sex-determining factors in their sperma-
tozoa or ova, he thinks it possible that the sex of offspring may be con-
trolled, at least to some extent.

T.I i

Recent Publications Concerning the Structure of Insects.— The
Wing Rudiments of the Sheep Tick— That the wings of the adult
insect are present in the larva in the form of disk-like rudiments
is a well known fact. Even wingless species, excepting the Thysanura,
possess these so-called “imaginal disks” in the larvae, thus indicating
descent from winged ancestors. Extending the work of Pratt, ’00,
Stange,’ ’07, has traced the development and the degeneration of the
rudiments of the wings and halteres in the sheeptick, Melophagus
ovinus.

He finds that in the earlier stages the disks of the wings and the
halteres are identical in appearance except that from the first the

1 Stange, P. Über die Rückbildung der Flügel und Halterenscheiben
bei Melophagus ovinus. Zool. Jahrb. Anat., 1907, 24, pp. 295-322. Pls.
27-28.

598 THE AMERICAN NATURALIST [Vol. XLI

wing rudiments are the larger. The wings continue to develop until
in the late pupal stages they are provided with a chitinous covering
bearing bristles. They then degenerate so that there are left in the
adult only peg-like vestiges well supplied with nerves, and possibly
sensory in function. Previous workers have mistaken these structures
for vestiges of the halteres. The latter, however, completely disappear
and are replaced by a spiracle.

The Physiology of Metamorphosis— An important contribution
on the subject of the changes which initiate metamorphosis in insects
is a brief article by Metalnikoff.' Utilizing the method of marking
the leucocytes by means of carmine injections he was able to establish
beyond question their active participation in the histolytic changes.

The most interesting feature of his work is the discovery that at the
beginning of metamorphosis there appear in the blood of the larva
specific toxines which apparently poison definite tissues and cells, and
thus render them liable to the attacks of the phagocytes. Blood of
mature larvae of Galleria melonella was injected into young larvae of
the same species and led to almost immediate paralysis. For a half
hour or longer, depending upon the quantity of blood injected, the
subject lay as though dead, and then gradually recovered. Check
experiments showed that injection of the blood of young individuals
is perfectly innocuous. The toxicity of the blood is manifest two or
three days before pupation and disappears about the third day of
pupal life, as soon as the course of histolytic change is run, and the
building up of new tissues is well under way.

Similar results were obtained from experiments on the silk-worm,
but there is brought out the interesting fact that injections of blood of
Galleria has no effect on Bombyx and vice versa.

Regeneration in Insects.— Przibram? has succeeded in the difficult
task of rearing to maturity the common European Praying Mantis,
and has studied their color variations and their power of regeneration.

He found that this species which in nature is usually green or brown
in captivity produced solely brown nymphs and yellow imagos. The
number of molts is seven or eight. The color may vary during the
nymphal period but this is apparently independent of their surround-
ings, degree of moisture, or temperature.

x zuge S. Zur Verwandlung der Insekten. Biol. Centralbl., 1907,
27, pp. 3

ue "eh Aufzucht, Farbwechsel, und Regeneration unsrer euro-
päischen Gottesanbeterin (Mantis religiosa L.). Arch. f. Entwicklungsme-
chanik, 1907, 23, pp. 600-614.

No. 489] NOTES AND LITERATURE 599

The grasping leg is capable of regeneration but on account of the
great mortality among the nymphs this is seldom to be observed.

The same investigator, assisted by Werber,* has carried on a series
of experiments on the power of regeneration in the bristle-tails (Lepis-
matidae) which on account of the generalized condition of this group
are of especial significance.

The authors find that the Lepismatidae show a marked power of
regeneration, since antennae, palpi, anal stylets, and legs may be
replaced after mutilation. This capability was to be noted even in
sexually mature individuals

In molting, growth TPE and power of regeneration the
forms studied display a generalized condition in keeping with their
low systematic rank, and comparable to what has already been re-
ported for the myriapods and crustaceans.

The Post-embryonic Development of the Mid-intestine in Trichoptera.
— The changes undergone by the mid-intestinal epithelium of insects
at the time of metamorphosis have been the subject of considerable
study during recent years, but in a preliminary paper Russ? has
brought to light some entirely new facts regarding epithelial replace-
ment in the pupa of the caddice-fly, Anabolia laevis.

In the first day of the prepupal stage there begins an active division
of the cells in the regenerative centers of the mid-intestine. The new
cells extend out under the old larval epithelium which is soon entirely
cast off and forms in the lumen of the intestine the so-called larval
“yellow body.” Meanwhile the new cells have completely clothed
the intestine and now through their activity hasten the dissolution of
the mass of old tissue.

Thus far the conditions are similar to what have been observed in
other insects. The new epithelium, however, does not in toto become
the definitive lining of the intestine of the adult. By a contraction
of the muscles of the mid-intestine and a consequent formation of a
ring-like thickening within its lumen its two ends are brought into
proximity. The ring of epithelium and muscle is then constricted off,
and now forms a second “yellow body” within the definitive mid-
intestine which has been formed from only a small portion of the pre-
pupal tissues.

! Przibram, H. und E. I. Werber. Regenerationsversuche allgemeinerer
een. bei Borstenschwanzen (Lepismatidae) 1. c. pp. 615-631

? Russ ber die postembryonale Entwicklung des Mitteldarmes bei den
Trichopteren (Anabolia laevis Zett.) Zool. Anz., 1907, 31, pp. 708-710.

600 THE AMERICAN NATURALIST [Vol. XLI

The Suboesophageal Body of Insect Embryos.— The question as to-
the origin and the morphological significance of the suboesophageal
body which has been found in certain insect embryos is an open one.
Hirschler! has studied this structure in embryos of Donacia and has.
added much to our knowledge of its nature. He finds that it is ento-
dermal in origin and that from an unpaired rudiment at the end of
the stomadeal invagination there arise four rounded, paired masses
which finally communicate directly with the lumen of the mid-intestine.
These persist until at least the third day of larval life,— their further
fate has not been studied.

Hirschler’s results apparently confirm the theory of Nusbaum and
Fulinski, ’06, that the suboesophageal body is to be homologized with
the hepatopancreas, or glandular diverticula of the mid-intestine, of
the Crustacea.

W. A. RILEY.

Stridulation Rhythm of Crickets.— According to A. F. Shull (Can.
Ent., vol. 39, p. 213), in the chirping of the snowy cricket “exact
synchronism is comparatively rare” and exists only between two or
three neighboring individuals. Thus two crickets five feet apart were
observed to time their chirps in unison as if they heard each other.
The rate of stridulation is independent of wing length; in general it
increases with rise in temperature, but Dolbear’s and Bessey’s formulae
to express this relation are only approximately correct. Under the
same conditions the rate in different individuals varied from 93 to 110
chirps per minute. Except on cool nights, from 600 to 800 chirps.
are usually performed continuously; one cricket was found to chirp.
2,640 times without interruption.

Notes.— Bull. 110 of the N. Y. State Museum, preparatory to a
monograph of the Cecidomyiidae, presents descriptions of 203 new
species belonging to this group. The Cecidomyiidae, or gall gnats,
are dipterous insects from 0.5 to 3.0 mm. in length which produce
various leafy galls including the “willow cones.” Bull. 109 of the
N. Y. State Museum is devoted to the tussock moth and elm leaf beetle,
presenting a colored plate of each, and six photographs showing their
destructive effects. The gypsy moth and brown tail have not yet
invaded New York.

1 Hirschler, J. Über leberartige Mitteldarmdrusen und ihre embryonale
Entwicklung bei Donacia. Zool. Anz., 1907, 31, pp. 766-770.

No. 489] NOTES AND LITERATURE < pOL

BOTANY

Plant Geography.— The Scandinavian flora. Several naturalists.
have considered the origin of the biota of the Scandinavian peninsula.
During the glacial period most of the higher forms of life must have
disappeared, leaving the peninsula to be repopulated by immigrants
from other regions as the ice receded. This immigration was early
thought to have had two sources: the central European lowlands and
the Russo-Siberian region. The biota of the former is supposed to
have come in by way of one or more Baltic land connections, and that
of the latter is thought to have gained access by way of Finland and
northwestern Russia. But besides these a third element, called by
Blytt “the Atlantic group” of plants, was discerned, as the flora, especi-
ally of the western part, became better known.

This so-called “ Altantic” element is discussed by Stejneger (Smith.
Misc. Coll., quart. iss., 3:458-513. 1907) from both the zoological and
botanical sides. The term “Atlantic” he considers an unfortunate
designation for those members of the fauna and flora which occur
nowhere in Norway except along the coast between Stavanger and
Kristianssund or where they may be shown to have been derived from
this secondary center of distribution. This association shows a strong
resemblance to the biota of Scotland and northwestern Ireland, and
Stejneger thinks that the similarity is not due to parallel development
but that it indicates a direct genetic connection between the two. The
possibility of the immigration of this element from Scotland across the
present expanse of water is considered and the author concludes that
in addition to the arguments against this hypothesis offered by plants
and lower animals, the presence of mammals offers a finally conclusive
proof of a prior land connection between northern Scotland and
western Norway. He thinks that certain geological considerations
support this theory.

Endemic plants in Ceylon. Willis publishes important contributions
to our knowledge of endemism (Ann. Roy. Bot. Gard. Peradeniya
3:271-302. 1906; 4:1-15. 1907). Ritigala is an isolated mountain
in the north-central province of Ceylon, which, although of no great
height, arises abruptly from the plains and forms the highest ground
between the central mass of the Ceylon mountain system and the very
similar hills of southern India. 'The nearest hills are forty miles to the-

602 THE AMERICAN NATURALIST [Vol. XLI

south and the intervening region is dry, and judging from the configura-
tion of the region must always have been so for at least 25 miles of the
distance. It is almost rainless except during the season of the eastern
monsoon from September to December. The summit of the moun-
tain, however, is bathed in mist and consequently affords an isolated
“moist region” vegetation, practically confined to a few acres within
100 vertical feet of the summit which it must have reached by leaping
at one bound over the intervening 40 miles of dry lowland that separate
it from the Matale hills to the south or over the 280 miles that separate
it from the hills of southern India.

A flora of 144 flowering plants and ferns is found at or near the
summit. Of these, 41 belong to the dry region and consequently have
not had to be transported forty miles to reach the summit. Of the
103 remaining species, 24 have in all probability been introduced by
birds; and 49, of which 24 are ferns or lycopods, have evidently been
brought by the wind. Thus only 30 remain whose method of intro-
duction is doubtful; these Dr. Willis discusses in detail.

Bearing these facts in mind, we may now turn to the question of
endemism. Of the 144 species and varieties of the flora of the summit,
13 are strictly endemic so far as is now known, and 1 other which
may perhaps occur in the mountains of southern India, is provisionally
added to the list. The distribution of these plants in the groups recog-
nized above is as follows:

Total Endemic
“a

Dry Zone Plants : : ER

Carried by Birds . s í a! 1

Carried by Wind . . 49 3

Doubtful . , ; i i : et 9
144 cH

The conclusion to be drawn from these figures is that: ‘‘ Endemism,
other things being equal, goes in general with difficulty of distribution
and with rare arrival at one spot.” The author adduces arguments
to show that the introduction of seed by birds would be much more
common than that by wind, and that the arrival of seed of those forms
which have been classed as doubtful would be the least likely of all. A
new form arising from a stock which had reached the summit will be
less likely to be swamped by crossing with the parent species if the
latter arrives very infrequently. Among the dry zone plants the only
endemic form belongs to a genus in which the seeds are extremely ill
adapted to transportation over long distances. If difficulty of arrival
be one of the conditions of endemism, one would expect to find the

No. 489] NOTES AND LITERATURE 603

greatest number of endemic forms related to species which are rare
elsewhere, and this seems to be true in the case of this flora. Indeed
it would seem that the endemic forms belong chiefly to families which
show the largest number of endemics elsewhere in Ceylon.

In his second paper, Dr. Willis attempts to show that the differentia-
tion of endemic species cannot be due to the action of natural selection
on infinitesimal variations. The arguments are:—

The distinguishing characteristics cannot be shown to have any
adaptive value. The endemic forms are often associated with the
species from which they have probably been derived. They have not
supplanted them as they would if evolved by the selection of special
adaptations. he distribution of endemics is narrower than that
demanded by their environmental conditions, and corresponds rather
with that resulting from an origin by mutation.

In conclusion the author remarks:— ‘‘The evidence is not so abso-
lutely in favor of mutation as it is against selection of infinitesimal
variations, but at present the mutation theory is the only one in the
field which can be invoked to explain the facts.”

J. ARTHUR Harris

Lock on Progress in the Study of Variation, Heredity and Evolution.’
— This attractive little volume contains two introductory chapters on
the general conceptions of evolution, one on the theory of natural
selection, one on biometry and one on the theory of mutation. The
three chapters following these are devoted to a discussion of the results
from investigations of hybridization. One of these is essentially an
historical sketch of the work of the older hybridists. The two succeed-
ing chapters treat of Mendelism, to the literature of which the author
has already made valuable contributions. In chapter ten he discusses
the bearing of recent cytological investigations upon the problems of
heredity. A final chapter sums up and discusses the general bearing
of the subjects treated.

That the author is a mutationist appears from even a casual reading
of a few pages. The style is simple and for the most part very clear
as are also the diagrams which serve as illustrations. A few excellent
half tones, particularly the portraits of Darwin, Galton, DeVries,
Kölreuter, and Mendel, add much to the attractiveness of the book.
Possibly the author might have found a much more weighty quotation
for his closing pages than one from Bernard Shaw.

1 Lock, R. H. Recent Progress in the Study of Variation. Heredity and
Evolution. London, John Murry, 1906. xiii + 299 pp.

604 THE AMERICAN NATURALIST [Vol. XLI

The work can be regarded only as an introduction to the modern
experimental and biometric study of evolution, since much space is
devoted to elementary principles, but it is a commendable effort to bring
the newer work before a wide circle of readers.

Jo A. H.

Notes.— The origin of the cow-pea has been investigated by Wight
(U. S. Dept. of Agric., Bur. of Pl. Ind., Bull. 102. 1907.) who con-
cludes that this legume is a native of India and the region northwest-
ward to the trans-Caspian district. Its cultivation in that region is
very ancient and it also extended to China at an early period. As
early as the beginning of the Christian era it was known in Arabia and '
Asia Minor and was cultivated in at least one of the countries of
southern Europe at about the same time. Its introduction into cen-
tral Europe occurred much later and independently. It seems to
have been introduced into the West Indies in the latter half of the
seventeenth century and probably reached the mainland during the
first half of the eighteenth century.

Statistical Methods.— Elderton! has published a small volume
treating in detail some of the less generally known biometric methods.
Biologists working with the more refined statistical methods will find
it very helpful.

The presidential address before the section of Economic Science
and Statistics of the British Association (Rep. Brit. Ass., 76: 629-642.
York, 1906.) is a plea for scientific method in statistical research.
While primarily of interest to students of social problems, statistical
biologists will be interested in some of the arguments.

Totes on Economie Botany.— The second volume of the handbook
of sugar cane culture and cane sugar manufacture for Java (Hand-
boek ten Dienste van de Suikerriet-Cultuur en de Rietsuiker-Fabricage
op Java. Amsterdam. 1906) published by the associated sugar
experiment stations of east and west Java, has just appeared. This.
elegantly illustrated volume is devoted to the animal enemies of the
sugar cane and their parasites.

Takeushi (Bull. Coll. Ag. Imp. Univ. Tokyo. 7:465-468. 1907)

discusses the chemical composition of the shoots of Aralia cordata,

1Elderton, W. P. Frequency Curves o Correlation. 1907. London.
Charles and Edwin Layton. xiii + 172

No. 489] NOTES AND LITERATURE 605

extensively used as food in Japan and now being introduced into the
United States. Funatsu (l. c., 469) gives the composition of a chrysan-
themum flower used as food. Albahary (Compt. Rend., 145:131-133.
1907) publishes analyses of the fruit of the tomato. Jaffa (Yearb.
U Dep. Ag. 1906; 295-312. 1907) considers the value of nuts
as food.

Ybarra (Smith. Misc. Coll., quart. iss. 3:428-457. 1907) has done
a service to those interested in the natural history of America by pub-
lishing an annotated translation of a letter by Dr. Diego Alvarez
Chanca, physician to the fleet of Columbus, dated 1494, relating to
the second voyage of Columbus. The letter embraces observations
made between November 4, 1493, and the last week in January 1494.
Of course but little space could be devoted to botanical matters but
several of the references to economic plants are of considerable interest.

J.A. B.

The difficulties of botanists in capitalizing specific names are illus-
trated in “ The Flora of the Gulf Biologic Station,” recently issued
by the Louisiana Board of Agriculture. It refers to Verbesina Vir-
ginica, Commelina virginica, Lycium Vulgare, Eleocharis Mutata, ete.
Cassia Chamaecrista of Gray’s Manual is written Cassia chamaecrista.
Ipomoea pes-caprae may be compared with Panicum Crus-galli. Uni-
form decapitalization would prevent such confusion. This “ Flora,”
which records some twenty-six phanerogams not previously reported
in Louisiana — a state which “ is to-day almost unknown botanically ”
— is to be supplemented by further publications. Its author, R. S.
Cocks, refrains from naming prematurely several new forms.

PUBLICATIONS RECEIVED

From July to August 1, regular exchanges not goon
The year a ann when not otherwise noted, is 1907

Drew, G. A. A Laboratory Manual of Invertebrate Zoology. Philadelphia
and London, W. B. Saunders Company, 1907. 12 pp. 81.
Herrick, G. W. Laboratory Exercises in General Zoology. New a
American Book Company, 1907. 12mo, 110 pp. 60 e — Herrick, G.
W. Text-Book in Busi New York, ache Book a are
1907. ER 386 $1.

Banks, N. Ac az i the Acarina, or mites, of the United States.
Proc. U. s. Nat. Mus., vol. 32, pp. 595-625.— Danrets, F. P. The flora of
Columbia Missouri and vicinity. Univ. of Missouri Studies, sci. ser., vol.
1, no. 2, 318 pp., pl. 1.— FisHer, W. K. The holothurians of the ia vation
RER Proc. U. S. Nat. Mus., vol. 32, pp. 637-744, pls. 66-82. GIDLEY,
J. N new horned rodent from the Miocene of Kansas. Proc. U. S. Nat.
Mus., vol. 32, pp. 627-636, pls. 58-65.— Guzman, D. J. La enfermedad
del café en el Salvador. Com. Parasitol. Agric., cire. 60, 24 pp., 6 pls.— INDA,
J El gorgojo de las Semillas. Com. Parasitol. Agric., circ. 59, 21 pp.,
8 figs.— Inpa, J. R. EI gorgojo de los plantios de Chile, llamado Barrenillo.
Com. Parasitol. Agric., circ. 58, 11 pp., 5 figs.— Lyon, M. W. Notes on the
porcupines of the Malay Peninsula and Archipelago. Proc. U. S. Nat. Mus.,
vol. 32, pp. 575-594, pls. 54-57.— Morton, G. E. Ration experiments with
lambs. Wyo. Exp. Sta., bull. 73, 18 pp., 12 figs.— Newranp, D. H. The
mining and quarry industry of New York State. N. Y. State Mus., bull.
112, economic geol. 16, 80 pp.— Pirspry, H. A. Hawaiian Cirripedia. Bull.
U. S. Bur. Fisheries, vol. 26, pp. 179-204, pls. 4-11.— Tenney, A. A. Social
democracy and population. Studies in History, Economics and Public Law,
vol. 26, no. 4, 89 pp.

LELAND STANFORD JUNIOR UNIVERSITY, REGISTER FOR 1906-1907.— NINE-
TEENTH ANNUAL REPORT OF THE MASSACHUSETTS AGRICULTURAL EXPERI-
MENT StTatTion.— NINETEENTH ANNUAL REPORT OF THE RHODE ISLAND
EXPERIMENT STATION.— TRANSACTIONS OF THE AMERICAN MICROSCOPICAL
Society, vol. 27.— UNIVERSITY OF COLORADO STUDIES, vol. 4, no. 4.—
University oF Montana REGISTER, 1906-7.

(No. 488 was issued August 26, 1907.)

THE JOURNAL OF EXPERIMENTAL ZOOLOGY

EDITED BY
WILLIAM K. Bro Ks HERBERT 8. stage, Tuomas H, MORGAN
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CHARLES B, DAVENPORT Epmunn B. WILSON

Ross G. Harrison, Managing Editor

CONTENTS OF VOLUME IV

NO. 1, FEBRUARY, 1907
Abnormal Development of Toad a. Fertilized by Spermatozoa

Exposed to the Roentgen Ra Charles R. Bardeen
An Ecological and Experimental Rudy of Sarcophagdae with Re-

lation to Lake Debris Wiliam B. Herm

venescence as the Result of Conjugat h ; ? . Sara White Cull
Artificial Parthenogenesis in Thalm messema Mellita : g è peen Lefevre
Concerning the Theory of Tropisms Jacques Loeb
The Mechanism of the Galvanotropic Orientation in Volv ox Frank Ww. Basta

NO. 2, MAY, 1907
The por aes of rn Pa y ro. Tin and EN ge! on the

ana it of Fu Heteroclitu Charles R. Stockard
The Energy of Segmenta ais ‘ oe a Spaulding
Movement and Problem Eini in ı Ophuria Brevispin o C. Glaser
The y ruia of a Sport in Lina Lappomica and its Behari ior in
edity . Isabel McCracken
T Besi in Tr ansplanting Limbs and Their Bearing upon the
Problems of the Development of Nerves oss G. Harrison

Factors in = a o a nanpa wiih droid, Eudendrium
ramo . A.J. Goldfarb

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THE
AMERICAN NATURALIST

Vor. XLI October, 1907 No. 490

STUDIES OF GASTROPODA
III. On ÖRTHOGENETIC VARIATION IN GASTROPODA!
AMADEUS W. GRABAU?

ORTHOGENETIC variation may be defined as progressive variation
along definite or determinate lines, whether such variation is along
the line of increasing or decreasing complexity; i. e., aggradational
or degradational. In the first place orthogenetic variation is
ontogenetic; i. e., the successive changes which the individual
undergoes in its transformation from embryo to adult follow each
other in definite succession, the changes appearing step by step.
When we are convinced that the changes seen in the development
of the individual are reminiscent of the changes passed through by
its successive ancestors, it becomes apparent that phylogenetic
variation is also orthogenetic, or along definitely determinable lines.

It has been the general custom to test the validity of the reca-
pitulation theory by the embryological method; i. e., the compar-
ableness of the changes which the individual undergoes during its
embryonic period, to the adults of more primitive types. Usually
the comparison has been with adults of existing types, since in
most cases these alone were available for comparison. It is no
wonder, then, that such comparisons have led to innumerable
errors, if not absurdities, which have placed the recapitulation

! The previous numbers of these “studies” appeared in the American
/aturalist as follows: No. I, vol. XXXVI, no. 432, pp. 917-945, Dec. 1902;
No. II, Fulgur and Sycotypus, vol. XXX VII, no. 440, pp. 515-539, Aug. 1903.
? Investigations carried on by the aid of a grant from the Hermann Fund
of the council of the Scientific Alliance of the city of New York.

607

608 | THE AMERICAN NATURALIST [Vor. XLI

theory in an evil light, and awakened in the minds of many serious.
investigators doubts as to the validity of the deductions based upon
this doctrine. When, however, the entire life history of the indi-
vidual is considered, instead of only the embryonic period, and when
the successive stages of epembryonic development are compared
with the adult characters of related types in immediately preceding
geologic periods, it will be found that the fundamental principle of
recapitulation is sound, and that the individuals do repeat in their
own epembryonic development the characters of their immediate
ancestors.

One of the great mistakes made by the majority of systematists.
is the disregard of the immature stages of development; i. e., the
stages between the embryonic and adult. ‘This is notably the case
among writers on recent mollusks, who either ignore the early
stages entirely in their specific description or give them the briefest.
notice. And yet it is in these early stages that we find the key to
the affinities of a given species with others of its kind, in the present
and in past faunas, more often and more surely than in the adult
characters. To classify by adult characters only is to neglect the
nearest and most obvious method for the ascertainment of the line
of descent of the species in question; and, further, it is to leave out
of consideration the inevitable similarity produced in the aspect of
adult types of different origins, by a loss of the characters distinc-
tive of their respective ancestors and of their younger stages. The
classification into one family of all bald headed men of the same
age would not be more illogical than some of the classifications of
phylogerontic mollusks in vogue today,— classifications based
wholly on adult characters. Agassiz long ago called attention to
the need of considering the stages between the embryo and adult,
as the following extracts will show.

“Embryologists have generally considered their work as com-
pleted when they have traced the new being to a point at which it
resembles somewhat any of the members of the natural group to
which it belongs. The process by which the gradual completion
of the whole frame is attained has been assumed to be of little
interest, hardly deserving the careful scrutiny of the embryologist;
while the zoologist has also overlooked, or regarded as of little
importance, the differences which still distinguish the young from

No. 490] ORTHOGENETIC VARIATION 609
the adult, even after its typical characters are perfectly distinct.” !
And again: “‘....I would say to all young students of Embryology
that their next aim should be to study those intermediate phases in
the life of a young animal, when, having already acquired inde-
pendent existence, it has not yet reached the condition of the adult.
Here lies an inexhaustible mine of valuable information unappre-
ciated, from which. ...may be gathered the evidence for the solu-
tion of the most perplexing problems of our science.” ?

AVAILABILITY OF THE MOLLUSCA FOR THE STUDY OF
DEVELOPMEN TAL STAGES

Of all classes of organisms, the mollusks are perhaps the best
adapted for the study of ontogenetic stages between the embryo
and the adult, since all these stages are preserved as a permanent
record in the form of the shell. Such a record cannot, of course, be
obtained from the soft parts, where a number of individuals are
necessary to represent the principal stages. Moreover, a certain
step in development may be very definitely indicated in the form
and sculpture of the shell, and yet be entirely unrecognizable in
the soft parts. Not only, then, is the shell a permanent record
of the changes, but it is also a more delicate register of advance-
ment than is afforded by the soft parts. In other groups of organ-
isms, the record is seldom so compiete, though brachiopods and
corals retain, in, perfect specimens, all the earlier stages. Other
organisms, however, such as the echinoderms and vertebrates,
preserve in their hard parts only the record of the stage at which
the animals die, since these hard parts undergo individually con-
stant changes from youth to maturity.

Among the mollusks, the gastropods and cephalopods are the
most satisfactory for ontogenetic investigations, since in them the
early stages are not only well preserved, but there are also a large
number of characters the progressive variations of which may be
studied. In many respects gastropod shells are the simpler to
study, because the greater parts of the whorls are freely exposed

! Agassiz, Methods of Study in Natural History, Chapter XVI.
? Ibid., Chapter XV.

610 THE AMERICAN NATURALIST [Vor. XLI

and open to observation, whereas in the coiled cephalopod shells
the outer whorls must be removed before a satisfactory view of the
inner ones can be obtained. Despite this fact, the study of shell
ontogeny has been mostly confined to the cephalopods, especially
to the highly complex and often richly ornamented ammonite shells;
and this can hardly be wondered at, when we consider their
number, and, the high degree of diversity found in this group of
organisms.

ORTHOGENESIS IN THE ONTOGENETIC DEVELOPMENT OF
GASTROPODS

The individual development of gastropod shells always follows
one of a small number of lines of variation. Leaving aside color
markings, which have been somewhat fully discussed by the Count-
ess von Linden,’ we may devote this discussion to the changes in
form and ornamentation. At the outset, however, we must note
that in every perfect shell there are two parts to consider; namely,
the protoconch and the conch. ‘These may be continuous with
each other, in which case the features of the protoconch merge into
those of the conch; or they may be discontinuous, when the proto-
conch features end abruptly and the conch features begin as
abruptly. (See Studies of Gastropoda, I, fig 5.)

The form of the gastropod shell is manifold, but the types are
few. Primitive types always begin with rounded whorls free from
all ornamentation. The coiling of the whorls at first is in a suffi-
ciently loose manner to produce a hollow axis, opening below in
an umbilicus. Even in types in which the anterior end of the
adult is produced into a canal — as in Fulgur, Buceinum, Fascio-
laria, etc.— the earliest protoconch stage has been found to show
the umbilicated round-whorled condition (Studies of Gastropoda
I, fig. 3). This condition may be accompanied by various modi-
fications in the amount of embracing of the succeeding whorls.
In all cases a moderate amount of embracing by the succeeding
whorls seems to be the simplest condition, although it must be borne

1 Die Entwickelung der Skulptur und der Zeichnung bei = Gehäuse-
schnecken des Meeres. Zeitschr. f. wissensch. Zoologie, LXI, p

No. 490] ORTHOGENETIC VARIATION 611

in mind that a difference may here be found between protoconch
and conch. When the whorls embrace but slightly, a deep suture
is produced between them. In this case the spire also is a slender
one, as is shown in so many primitive fusoid shells (Studies I,
fig. 6). As the amount of embracing increases, the suture becomes
less strongly depressed, and the spire takes on an ever greater apical
angle. The amount of embracing may increase until the suture
is found at the ambitus of the preceding whorl (Studies II, fig. 13).
Beyond this, the embracing is only carried in the old age of the
individual of normal types or in specialized types, generally the
members of a phylogerontic series.’

In a large number of types, the amount of embracing by the
whorl remains practically the same throughout life, thus giving
the spire a uniform angle. In others, again, and perhaps in the
majority of specialized types, the embracing is at first less, but
slowly increases in amount with each succeeding whorl in the later
stages (Fig. 1).

Even in degradational types, where the embracing of the adult
shell is in extreme excess of that of the normal adult type, the
amount of embracing increases regularly from its first appearance
to the completion of the growth

There is another extreme found in phylogerontie members of a
certain group of Gastropoda and so far observed in the non-cana-
liculate types only; namely, the loss of the power to coil, due to the
equalization of the rate of increase in all portions of the shell
(Studies I, figs. 14 and 15). This results in a looser coiling or
complete straightness of the final portion of the last whorl, and
may or may not be accomplished by an increase in the diameter
of the whorl. Ontogenetically this is often expressed by a progres-
sive loosening of the coil, though there are various degrees of
abruptness, some coils becoming gradually straightened, while in
other types this straightening appears very abruptly. As will be
shown presently, the loss of power to coil and the excessive spread-

1 The nomenclature of stages in development, devised by Hyatt, Buchmann,
Bather and others, is for ontogenetic stages as follows: nepionic, babyhood;
neanic, youthful or adolescent; ephebic, adult; gerontic, old age or senile.
Corresponding stages in phylogenesis are designated by the prefix ~ but
the term phylogerontic, or racial old age, is the only one in common

612 THE AMERICAN NATURALIST [Vor. XLI

ing of the whorl are generally accompanied by the loss, or at least
a modification, of the ornamentation.

A second important type of modification of form in ontogeny
is the angulation of the whorls. ‘This begins as a slight depression
_ in the curvature of the upper or shoulder portion of the whorl, and
a similar depression of the lower or body portion. ‘Thus a faint
angulation appears in the ambital portion of the whorl, which
usually occurs where the whorl is marked by the first or most
pronounced of the spirals. From a faint beginning, the angle
increases in sharpness, and the depression of the shoulder surface
and body surface increases, until the whorl consists of two perfectly
flat or even slightly concave surfaces separated by a sharp angle
(Fig. 2). Where the angulation appears late in the ontogeny,
generally about an equal flat space is shown above and below the
angle (Fig. 8). When it appears early, the later whorls generally
embrace the preceding more strongly, thus decreasing the space
below the angle, until in extreme cases this lower space has entirely
disappeared, the suture of the succeeding whorl being at the angle
(compare Fig. 5 with the younger portion of another individual
enlarged in Fig. 2). This produces a continuous slope of the spire,
which may vary, in different types, from nearly horizontal as in
Conus, where the shoulder makes a right angle with the axis of coil-
ing of the shell, to nearly vertical as in some Turritellas and Ceri-
thium, where the shoulder makes a very acute angle with the axis
of coiling, and the ambital angulation is far down on the shell.
In all such cases, however, it is the rule that the earlier whorls are
less closely coiled, so that in the young spire the flattened body
of the whorl, below the angulation, becomes visible (Fig. 2).
This is true even of such highly specialized types as Conus, where
the shoulders alone of all the later whorls are visible; for the young
whorls here project commonly above the general surface, showing
a more steeply sloping shoulder, and generally exhibiting a portion
of the whorl below the angulation, though this portion may be the
merest fraction of the whorl. Rarely has acceleration gone so
far that the shell begins with an angle and the whorls embrace up
to the angle. The norm of the embracing, as in the slope of the
shoulder, seems to be that which approaches most nearly to the
round-whorled condition; i. e., an equal exhibition of flattened

No. 490] ORTHOGENETIC VARIATION 613

shoulder and body, and approximately an angle of 45° between
the shoulder and the axis of coiling. From this the progressive
change is to a steeper shoulder in one series and to a flatter shoulder
in the other. Similarly, the partial embrace of the whorls seems
to be the norm, from which variation on one hand is in the direction
of more pronounced embracing, carried to excess in phylogerontie

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Cy 85 80 76 70 65 60 55 BR 465 0

Trochonema vagrans

Diagram 1.—To illustrate the development of various types of gastropod shells,
as explained in the text.
types, and in the other to a gradual loss of power to coil, which
also terminates in a phylogerontic condition. ‘These relationships
may be represented in the following manner (Diagram 1).

The ambitus of the whorl, or the point of greatest convexity,
is taken as the center of the whorl. The line O — A represents
progressive increase in embracing, from zero at O to 50% at the
ambitus, and to complete overlapping and concealing of the pre-

614 THE AMERICAN NATURALIST [Vor. XLI

ceding whorl at A (100%). O— B represents progressive loss
of coiling power to straight conditions at B; O-—C, increasing
horizontality of shoulder from round at O to 45° and thence to
horizontal or 90° with reference to the axis of coiling. O—D
in the same way represents increasing verticality from 45° to 0°,
or parallelism with reference to the axis of coiling, at D.

A simple round whorled shell in which the whorls do not em-
brace throughout life (primitive Fusus) would be represented by
the point O. One in which a slight amount of embracing occurs,
but no change in outline of whorl, is represented by a line on O -—A,
the length of which marks the percentage of embracing up to 50
at the ambitus or more if the whorls overlap. The line may not
start. at O but higher up, the earlier whorls showing some embrac-
ing. The line O —a represents the life of a shell in which the
whorls gradually change to angular (45°) and the embracing
increases up to 25% or half way to the ambitus.

O — b represents a shell with gradual increase of embracing
of whorls to ambitus, and flattening to 75° with reference to the
axis of coiling, as in some Fulgurs. O — c represents a more
rapid flattening than increase in embracing, as in Conus; O — d
a gradual increase in embracing to below the ambitus, while at the
same time the whorls are flattened to a shoulder of 45°. Then
the embracing continues to the ambitus, beyond which, with in-
creasing embracing, the whorls lose their angularity. This is seen
in Melongena. In Clavilithes, represented by O — f, embracing
increases to the ambitus, after which the whorls become quickly
flattened vertically to 0°. Vermetus is represented by O — g, in
which increasing embracing and flattening to 10° or less represents
the Turritella stage, after which a loss of the embracing finally brings
us to the loose coiling type with a return to round whorled condi-
tion. Similar changes are seen in Trohonema vagrans (Studies
I, fig. 15) where angular embracing whorls are succeeded by loose
rounded ones.

ORNAMENTATION OF THE WHORLS.

As already shown in the first of these studies (Am. Nat., XXXVI,
p- 930) the ornamentation of the whorl consists of ribs, spirals,

No. 490] ORTHOGENETIC VARIATION 615

tubercular keel, and spines. Of these, so far as ascertained, the
ribs generally appear first, though in a group of early gastropods
in which ribs are never developed in the adult, spirals may be
well developed. The point of importance, however, is not the
relative time of appearance, but the mode of development of each,
and their influence upon each other when they occur together.
Where the development is complete, the ribs are.at first faint
vertical ridges upon a rounded whorl, enlarging gradually until
they are strong, rounded, elevated ridges extending from suture to
suture, with their greatest prominence at the ambitus of the
whorl (Figs. 16-17). From being at first rather distant, they may
increase in breadth until they are separated only by a depressed
line. With the appearance of the ambital angulation, the ribs
become fainter towards the sutures, while at the same time they
become more pronounced upon the ambitus. Eventually the ribs
disappear entirely from the shoulders, disappearing at the same
time or somewhat later from the body of the whorl below the shoul-
der angle. Then only a regular row of tubercles remains behind,
each tubercle being the concentrated essence of the ribs of the
earlier stages (Studies II, fig. 10). Throughout, this process of
metamorphosis is a regular progression, though in some (i. e.,
accelerated) shells it occupies a smaller number of whorls than in
others. Up to this point there is uniformity in development of all
ribbed shells with angular whorls following upon rounded ones.
Beyond this point there is a divergence; along one line the tubercles
gradually broaden and become confluent into a keel (Studies II,
fig. 12) which forms a prominent and persistent character, dis-
appearing only in old age types when the shell becomes rounded;
along another line the keel, if it comes into existence quickly dis-
appears, when the shell becomes rounded in outline. Upon this
a new type of ornamentation, the spine, appears. This will be
more fully discussed below.

The spirals — These are continuous and persistent folds in the
shell substance, caused by a slight emargination in the lip of the
shell. This emargination corresponds to a faint wrinkle in the
mantle when withdrawn, the growth of that organ being a more
rapid one than is commensurate with the increase in diameter of .
the whorl. Thus while when expanded, the mantle is smooth,

616 THE AMERICAN NATURALIST [Vor. XLI

when withdrawn it must be folded into minute wrinkles to be-
come accommodated to the smaller space. That these spirals
are generally visible only as emarginations on the margin of the
lip, indicates that only the outer portion of the mantle is affected
by this excess of growth. If other parts of the mantle are affected,
lirae result on the inside of the outer lip and plications on the
columellar lip.

The order of appearance of the spirals is a very regular and prog-
ressive one. In simple or primitive shells a single spiral makes
its appearance at the ambitus, followed in most cases successively
by spirals above and below. A partial exception to this rule is
found in types in which a certain number of stages have been
dropped out between the protoconch and conch and hence the
conch does not begin at the beginning (Studies I, fig. 5) but at a
stage normally belonging later in the ontogeny. ‘Thus in Fusus,
Latirus, Semifusus and certain Murices the conch begins abruptly
with rounded ribs and three or more spirals. Such dropping out
of early stages is however entirely in conformity with the general
progress of development and is itself progressive, or orthogenetic.
It belongs however in the category of phyletic orthogenesis.

At whatever stage of development the shell begins, that develop-
ment is thereafter progressive. ‘Thus in a large number of forms,
if the shell begins with three spirals, the fourth, fifth and later
spirals appear progressively above the upper, and below the lower
one. If the whorls become asymmetrical, with continued growth,
as is the case in the majority of shells where the lower (anterior)
portion is either drawn out into a spindle and canal, or is flattened
and depressed, the development of the spirals will be unequally
distributed. Thus in shells with a spindle, three or four spirals
may appear successively below, while only one appears above the
ambitus.

In some cases as in Goniobasis, certain Melanias ete., the third
and later spirals appear as intercalations between the first two.
In this respect they resemble the secondary spirals to which indeed
they may be closely allied. "They however quickly reach the size
and other characters of the two first spirals with which they appear
to form the primary series (Figs. 13 and 18). Additional inter-
calated spirals with the habitat of the secondary spirals appear

between them at a later period.

No. 490] ORTHOGENETIC VARIATION 617

The manner of appearance of the spirals must be regarded as a
consequence of the rate of growth of the mantle. Considering
that the first two spirals are the result of the first two folds into
which the mantle border is thrown on retraction, and assuming
that the position of these folds is a permanent one as appears
indeed to be unquestionable from the continuity and regularity of
the spirals, we perceive that if the mantle border grows more
rapidly above and below the original folds than between them, the
new spirals will appear respectively above and below the first two.
If on the other hand the mantle grows fastest between the two
original folds, the corresponding spirals will diverge and new ones
appear between them. ‘This is the case in the formation of the
secondary spirals in the Fusidae and other forms. The question
may well be asked if these two modes of appearance of the early
spirals do not represent two lines of development originating in-
dependently in various genetic series and producing end-members,
which, within the same series, are indistinguishable in their adult
characters. If, on the other hand, we regard intercalation as the
method of appearance of secondary and later spirals, then Gonio-
basis and the Melanias and other types which show intercalation
after the appearance of the first two spirals, must be considered as
highly specialized and accelerated types.

When the full number of primary spirals has appeared, or in
accelerated shells at an earlier period, intercalated spirals appear,
beginning in the broadest interspaces. In fusoid shells this inter-
calation begins on the spindle, where expansion is most pronounced.
Secondary spirals are followed by tertiary ones, and sometimes by
spirals of a higher order, all being intercalations between the
primary ones. ‘The first spiral generally marks the point at which
the ambital angulation occurs. A strengthening of this spiral is,
indeed, often the first indication of approaching angularity, and in
some cases the change of whorl does not progress beyond this point.
When the central spiral continues to increase in size, after the ribs
have been reduced to nodules, the form of these nodules will be
influenced by the spiral, so that instead of knobs they will be
elongated, rounded, and flattened nodes. Such a condition is well
shown in Fusus distans. This condition often ends in complete
confluence and the formation of a keel (Sycotypus canaliculatus).

618 THE AMERICAN NATURALIST [Vor. XLI

Spines.— These are of two kinds in gastropods. In a number
of phylogerontic platyceroids they consist of tubular prolongations
from the surface of the shell at irregular intervals, and appear to be
of little phyletic significance. The other, more important type
represents a periodic emargination in the lip of the shell (Figs. 3-4,
7-8). That the periodicity of this spine formation is connected
with the regular recurrence of the reproductive period, may be
assumed for types in which these spines appear late in the ontog-
eny; but not for those in-which they appear early. Direct obser-
vations in this field seem to be wanting, however. The rate of
growth of the shell during the interval between such periods of
spine formation determines the number of spines upon a volution.
As has been shown for Fulgur (Studies II, p. 534) the number of
periods in progressive types decreases as the shell increases in size,
thus showing that the amount of growth between resting stages
(i. e., spine forming stages) increases at a rate faster than the rate
of increase in the size of the shell. This may of course also be
interpreted as a lengthening of the time interval between resting
stages, or possibly between the reproductive periods. In some
forms the decrease in the number of spine periods to the whorl is
a rapid one, as in Fulgur eliceans, where it is 12, 9, and 6 respectively
for the 5th, 6th, and 7th whorl, whereas the decrease is 14, 13, 12,
or 13, 12, 11 for the same whorls in F. carica. In Murex (Rhino-
canthus) brandaris, on the other hand, it is 6, 6, and 7 for the 5th, 6th
and 7th whorl respectively, thus showing a shortening of the growth
periods. In the majority of Murices, however, the number of
periods has been reduced to three for all whorls. In Ranella the
number of resting stages as expressed by the varices has been
reduced to two for each whorl.

The simplest spine is that found in Fulgur. It has been quite
fully described in a preceding number of these “Studies” (II)
and the only point that needs to be emphasized in this connection
is the gradual appearance of the spine in the ontogeny of the indi-
vidual. This is not noticeable in Fulgur carica or other accelerated
types of Fulgur, as fully discussed in the papers referred to, but is
well shown in the more primitive Miocene types (e. g., F. tritonis,
fig. 7). Here the spines appear on a faintly keeled or smooth shell,
and at first are in the form of the merest faint spinelet, scarcely

No. 490] ORTHOGENETIC VARIATION 619

noticeable, though recognizable to the touch as a faint protuber-
ance. From this beginning the spine grows, period by period, until
it has become of the normal adult dimensions. In some forms
the spine continues to grow throughout life, giving us the enor-
mous spines of Fulgur candelabrum.

Where a second row of spines appears this always comes in later
than the first, though acceleration may tend to shorten up the inter-
val, or even by dropping out the earliest stages produce a type
in which more than one spine appears at the beginning of the
conch stage. Tudicula is a good example of normal succession
in the appearance of spine rows. In the Miocene T. rusticula,
only a single row of fulguroid spines appears on the ambital angu-
lation (Fig. 3). In T. bispinosa sp. nov.* (Figs. 1, 3 and 4) the
spines of the first row increase in size, progressively though slowly
while a second row of spines makes its appearance lower down on
the body whorl, after the first has been in existence for a consider-
able number of volutions. This second row begins with the merest
elevation, scarcely visible though noticeable to the touch (Figs. 1 and
3). From this beginning the size of the spine increases period by
period, until the spines of the second row are equal in size to those
of the first (Fig. 4). In accelerated types, the second row is already
well developed in the young individuals (Fig. 1)” In the modern
Tudieula spirillus, a beginning of the second row of spines is indi-
cated by a succession of faint elevations, each later one stronger
than the preceding, but none reaching the dignity of true spines.
When more than two spines occur, these follow the same rule,
as may be seen in Murex brandaris, M. tenuispina, ete.

In all cases the spines appear on the spirals, representing periodic
outgrowths of the emargination which originally formed the spiral.
As already noted, the first spine occurs on the spiral occupying

1 I have been unable to find that a specific or varietal name has been
proposed for the forms with a double row of spines, and hence propose to
use the above name for them. I am well aware that intermediate forms be-
tween those with single spinous keel and those with double spinous keel exist,
but I do not consider that this militates against the specific standing of the

S.

2 For a full illustration of the principal mutations of the Miocene Tudicu-
las, see Hörnes und Partsch,—Die fossilen Mollusken des ns von
Wien. Abh. d. k. k. geol. Reichsanstalt,1856, Bd. 3, Taf. 2

620 THE AMERICAN NATURALIST [Vor. XLI

the summit of the ambital angulation. The second row of spines
generally forms on the spiral which separates the body of the whorl
from the spindle. The larger spines are formed on the primary
spirals, the smaller intermediate ones on the intercalated secondary
and tertiary spirals. In a number of types these spines are inde-
pendent (Murex tenuispina) while in others they become com-
pounded. ‘Thus in the majority of Murices, the spines of the later
cycles do not become independent of those of the earlier cycles,
since these earlier ones grow to such an extent that the independence
of the smaller spines is impossible. Hence they become modifi-
cations upon the sides of the larger spines, and thus is produced
the wonderful complexity of spine in such forms as Murex
palmarosae and others. Here, too, as has already been shown
(I, p. 934) the increase in complexity is progressive from period to
period, the first formed spine on the ambitus (or shoulder angle)
always leading the others. The degree of advance of the first
over the second spine varies in amount in differently accelerated
types; this variation is, however, phyletic and as such also progres-
sive. In some types the second spine always has the complexity of
the first spine in the preceding period, in others its complexity is
comparable only with that of the primary spine in a still earlier

riod.

Columellar plications and lirae—'The development of these feat-
ures also follows the law of progressive appearance and progres-
sive intensification. Those types like Fasciolaria, Rhopalithes,
Latirus, ete., which in the adult have several plications, are as a
rule, free from these in the earliest stages. ‘The only exception is
in the case of accelerated types, which start conch-life already
equipped with plications, as many of them start equipped with
costae and spirals. In the more primitive types, however, the
plications appear in succession, the first while the shell is still
young, the others successively. In some cases the second plica-
tion has only reached half the size of the first in the adult shell.
In types with numerous columellar plications, intercalated ones
appear between the older ones. ‘These begin chiefly in later stages
of development, being absent or at least weak in the younger stages.
This is well seen in the young of certain volutes, such as Voluta
musica and V. polyzonalis, where the intercalated plications in

No. 490] ORTHOGENETIC VARIATION 621

half grown shells are absent or much more weakly developed,
than in the adult.

In the same way lirae appear later in the life of individuals,
being absent from the earlier stages. ‘They are furthermore often
complicated by intercalations, which like the primary ones appear
progressively.

SUMMARY -OF APPEARANCE OF SHELL CHARACTERS.

Summarizing the results so far obtained, we note that all the
characters of the shell appear in.a definite order, and develop by
a process of progressive intensification or growth. ‘This law holds.
good in the most diverse types of gastropods as will be more fully
apparent from the examples cited below as illustrations. Even
where at first glance the order of development seems to be abnormal,
it is seen on closer inspection sig Mis apparent abnormality is due
either to normal prog falling as such under the
type of variation ine in the next section, or to pathologic con-
ditions, which cause a temporary, or sometimes permanent devel-
opment of senile characters which in the normal course of the
ontogeny would appear only towards the end of life.

Phyletic acceleration, or the condensation and elimination of
stages normal to the ontogeny is one of the chief sources of anoma-
lies in the ontogeny. When the elimination is at the beginning of
the conch stage, the shell may be looked upon in the same light as
a more primitive type in which the apical portion has been broken
away. In both cases the available part begins some stages along
the road of progress but in both cases the stages subsequently
passed are the same, though one may go at express rate and the-
other at a slow pace. When however later stages are telescoped,
as is the case in many accelerated forms (Fulgur carica, F. eliceans,
Fusus longicaudus, several species of Semifusus, Pugilina, etc.) the
recognition of the normal line of progress is not so easy. Never-
theless it becomes apparent that up to the point of telescoping,
and from that point onward, the progress is a normal one. Merely-
an original detour has been cut off as a river in the course of its.
development cuts off a large meander, and so two points, originally

ar apart on the river’s course are brought close together.

622 THE AMERICAN NATURALIST [Von XLI

Many other characters of the shell, such as the outline of the
spindle, and the formation of anterior and posterior canals, and
the development of the color pattern, have not been touched upon,
but they all proceed according to a uniform law of change. The
Countess von Linden has endeavored to show that the transfor-
mation of the color pattern in marine gastropods follows Eimer’s
law, viz: longitudinal Br spots, cross-stripings and uniform
color.

ORTHOGENESIS IN PHYLETIC DEVELOPMENT OF GASTROPODA.

The protoconch, the last of the embryonic stages, is far less
satisfactory for purposes of tracing phyletic relationship, than is the
conch. Nevertheless, up to a certain point, it may, I believe, be
confidently relied upon. That an early stage of the protoconch
in the majority of gastropods is of the form of a simple naticoid coil
with a well-marked umbilicus, has already been noted (Studies I).
As stated in the first of these studies this form of the protoconch
recalls the character of the earliest known coiled gastropod, i. e.,
Stroparollina remota of the lower Cambric of the Atlantic coast
province. Still earlier stages in the development of the protoconch
show a capuloid form, which recalls the adult character of many
of the early Cambric shells described under various names. That
all of these are not primitive but that some are phylogerontic, is
shown by the fact that the earliest stages are enrolled while the
later stages are non-coiling. Sardeson' has indeed insisted that
my interpretation of such forms as Platyceras primaevum etc.
as phylogerontic is erroneous, and he has attempted to show that
the forms with slightly coiled apex are more advanced than those
in which the apex is not coiled at all, and that the progress of
development is from forms without any coiling through those with
enrolled apex, to the close coiled types. That this is a complete
inversion of the mode of coiling, must be apparent when we con-
sider that the animal has no more power to enroll its apex, than it
has to unroll it, and that, since the apical part is the first-built

1 The Phylogenic Stage of the Cambrian Gastropoda. Journal of Geology,
Vol. XI, p. 470-482.

No. 490] ORTHOGENETIC VARIATION 623

portion of the shell, it represents the primitive condition and the
straightened part represents the later condition. ‘Thus the prog-
ress of ontogenetic development is from close-coiled to non-coiled,
from which we are justified in deducing that the ancestor of the
type with the enrolled apex was a closely coiled type, and that the
loss of power to coil, shown in the adult, is a sign of old age of the
branch which that individual represents. That the earliest types
were non-coiling shells cannot be doubted: there is every reason
for believing that they were patelloid in form, though modern
Patella is a phylogerontie type, which in its adult characters has
returned to the condition of its forefathers. This is clearly shown
by the presence of the coiled protoconch which at once stamps this
form as derived from a coiled ancestor. All deductions then
based on the anatomy of the soft parts of Patella, which leave this
fact out of consideration are necessarily faulty, since it is hardly
conceivable that in all its characters this animal has either remained
primitive, while the shell passed through a tremendous series of
metamorphoses, or that the soft parts have likewise degenerated to
such an extent that they have reached in all characters the condi-
tion of the primitive ancestor of the gastropods.

Another relationship that may be deduced from the structure
of the protoconch of many highly ornamented types of shells, is
that they were derived from an ancestor with simple ribs on rounded
whorls. Thus the ancestors of Fusus, certain Murices, Latirus,
Tudicula and other types were fusoid shells with simple ribs on
smooth rounded whorls, if the structure of the protoconch of these
types can be regarded as an indication of ancestral conditions.
For in these types the last portion of the protoconch is ribbed with
delicate vertical ribs but without spirals. While the community
of descent of the genera cited from some early Mesozoic ancestor
is probable, it does not follow that all ribbed protoconchs indicate
a common ancestry. For when it is recalled that ribs appear
independently in the most divergent types of shells, it need not
surprise us to find that this primitive ribbed character has been
pushed back into the protoconch stage in a number of different lines
of descent.

There are, of course, not wanting those who deny that the char-
acters of the protoconch can be regarded as indicative of phyletic

624 THE AMERICAN NATURALIST [Vor. XLI

relationships. Indeed the common practice of classifying largely
or wholly by adult characters has almost of necessity led to a mini-
mizing of the value of protoconchial characters when they are recog-
nized at all. When differences of protoconch features were found
in types classed together as related from adult characters it was
explained as the result of the influence of different physical condi-
tions acting upon the embryo. ‘This heterostylism as it has been
called by Boettger,’ is explained by him as probably having one of
two causes — either it is developed through a process of selection,
to give the animal a lighter shell, to enable the animal occupying
it to change its location more easily and quickly — or it has the
object to prevent the creature from sinking into the soft ooze of the
deep sea bottom, in which for lack of food or for other reasons it
would perish. ‘This of course refers only to the young shell, for the
size of the initial protoconch whorl can have little significance in
the adult.

Heterostylism, or a difference in the character of the protoconch
in individuals living under different conditions, has been shown
to exist in Murex tribulus L., where Sturany found that the deep
sea form differs from the littoral form in an embryonic end or
protoconch with more strongly swollen apical whorl, and with an
extra volution. Fusus bifrons and F. paucicostatus are also dis-
tinguished at an early age by the relatively more swollen proto-
conch of the latter, which is at home in deeper water (490-876
meters).

These two cases were used by Boettger ? to illustrate his hetero-
stylism and to establish the non-validity of my contention that the
character of the protoconch of Fusus, of Clavilithes, Rhopalithes,
etc., are not only distinctive, but due to diversity of descent.*

! Boettger, O. Ueber H lie bei Schnecl hal d Erklärung.
N: ha der Br M RER EN ey 1905, Heft 1.

? Sturany. Expeditionen S. M. Schiff Pola in das Rote Meer. Zoologische
Ergebnisse, XXIII. Gastropoden des Roten Meeres. Denkschr. Math. Nat.
Cl. K. Akad. d. Wiss. Wien., 1903, Bd. 74.

8 loc. cit
*Grabau, A. W. Phylogeny of Fusus and its Allies. Smithsonian Mis-
cellaneous Collections. Vol. XLIV, no. 1417, 1904.

No. 490] ORTHOGENETIC VARIATION 625

A similar position with reference to my work is taken by Coss-
mann! whose criticisms are more fully considered beyond.

Referring again to the Red Sea shells cited by Sturany, and used
by Boettger and by Giard? as illustrations of heterostylism in
Gastropods due to diverse physical conditions, we note on reference
to Sturany’s illustrations that the difference between the proto-
conchs of F. bifrons, and F. paucicosta is one of degree and not of
kind. Both protoconchs are of the same type, the true Fusus
type; but that of F. paucicosta has a somewhat larger initial whorl. °
This species is a highly accelerated type, as compared with F.
bifrons, and hence it is not surprising to find the protoconch par-
taking of this acceleration. Besides the initial larger whorl, the
number of whorls appears to be less than in F. bifrons where 1}
smooth volutions, followed by a delicately ribbed portion constitute
the protoconch. Reference to my figures and descriptions of pro-
toconchs of Fusus will show many such variations, (see pl. xvii,
figs. 1-4) all of which are mere modifications due to greater or less
acceleration, but do not constitute an essentially different type of
protoconch. Such a difference of type does however exist between
the protoconchs of Fusus and Falsifusus and Fulgurofusus, and
between Clavilithes and Rhopalithes as a critical study of these
will no doubt convince anyone. Where in Fusus of the Red Sea,
the deep sea form has a larger initial and fewer subsequent whorls
in the protoconch than is found in the littoral species, the deep-
sea form of Murex tribulus combines according to Sturany a large
initial with more numerous subsequent whorls when compared
with the littoral type. In the absence of figures and detailed
description such as one has a right to expect in a work of the kind
presented by Sturany, it is impossible to judge in what this differ-
ence really consists. Moreover, one is led to doubt the accuracy
of Sturany’s generalizations quoted with approval by Boettger,
when the statement, “It appears from these tabulations that the
deep-sea examples have a proportionally higher spire, due to the
increase in the number of volutions,” is compared with the table

* Revue Critique de Palaezoologie Oct. 1904, p. 233, and Essais de Paleo-
conchologie comparée, liv. 7, p. 225, 1906.

? Giard, Alfred. La Poecilogenie. Bulletin Scientifique de la France et
de la Belgique, 1905, T. XX XIX, p. 160.

626 THE AMERICAN NATURALIST [Vor. XLI

of measurements to which it refers. For here we find that the
smallest number of whorls (6) is found in shells from the greatest
depth (920 m.) while a littoral specimen has the largest number
(9) except one which has ten volutions and was obtained from a
depth of 740 meters. Judging by the actual number of whorls,
there appears to be nearly a steady increase in the number from
920 meters to shallow water. Moreover, it does not appear from
Sturany’s table how he eliminates differences in age in the individ-
ual measured. ‘Taking shells of the same number of volutions (8)
and therefore presumably of the same age, we have for

920 meters in depth — a length of 73 mm.

920 oe [2 ee “ce ‘“ oe

605 “

612 “cc c “ “ “ “ 41! “
2

212 “ “ ‘cc 66 ‘cc “ 57 “

Subtracting the length of the spindle we have in the same speci-
mens the following height of spire of 8 volutions.
920 meters in depth a length of spire of 35 mm.

5 o o E T o a u a

ME To ee Oo ee
the greatest variation being within the same depth. Since the
number of volutions is here the same, this difference in height can
only be ascribed to a difference of embracing in the earlier whorls.
A detailed description of this difference would have been of extreme
interest, and as a record of variation would have been far more
valuable than the tabulation of lengths and numbers of volutions,
which without further discussion are of very little significance and
value.

So long as the difference of protoconchial characters lies in the
somewhat larger size of the initial whorl, or the relative number of
whorls, this difference may very well be regarded as due to the
difference of environment. That the environment may influence
the development by retarding or accelerating it, seems hardly
questionable, and that as the result of such retardation or accelera-
tion the circumferential growth of the original shell may increase
proportionately more rapidly than the spiral growth, thus pro-
ducing a larger initial whorl, is also comprehensible. As is shown
by studies of the embryonic development of Fulgur carica and

No. 490] ORTHOGENETIC VARIATION 627

Sycotypus canaliculatus the size of the initial whorl is determined
by the size of the embryo long before it leaves the egg-case, and in
fact the whole protoconch is formed and the animal has begun the
building of the conch before it becomes free. "The same thing is
true of Fasciolaria gigantea and Buccinum undatum (see Studies
II, p. 535). To what extent this intracapsular development is
carried on in the species of Fusus and Murex cited, I have not
been able to ascertain, but it is most probably the case that the
protoconch stage is far advanced if not completed before the animal
becomes free. The size of the initial whorl of the protoconch i is
then probably to be regarded as an expression of the size of the
embryo, its rapidity of growth during the period of formation of
the hyaline primitive shell, and the size it has reached before the
deposition of the calcareous matter begins. The size of the yolk
of the eggs, i. e., the initial food supply may, in turn, be con-
sidered as at least a partial factor influencing this rate of growth.
The factors advocated by Boettger are thus secondary factors
which may or may not determine ‘survival. ‘They may indeed
have no significance whatever, for swollen initial whorls are found
in Fusus colus which lives in from 10 to 20 fathoms and F. mamora-
tus which lives in even shallower water. Among the Volutes, too,
which are comparatively shallow water forms, species like V.
musica have a minute apical whorl while V. rupestris Gmelin,
probably belonging to a separate line of development, has a
large initial whorl. The initial whorl of the shallow water Fulgurs,
is much larger than that of many deep water species of other genera.

Aside from the size of the initial whorl of the protoconch, its
obliquity to the axis of coiling of the other whorls is a significant
feature. This is found in shells with an emargination or canal,
that is fusoid shells, and can be traced back to the beginning of
this canal. If the initial emargination, however, forms some dis-
tance from the umbilicus toward the periphery of the whorl, the
later whorls will coil on a different plane from the first, which is
often partially embraced by or becomes sunken into the second
whorl (Fig. 6). This early rotation of the first whorl, occurring
as it does in the capsular period of development, must be due to
characters inherent in the embryo — at any rate it is difficult to
conceive how it can be a product of environmental influence on the

628 THE AMERICAN NATURALIST [Vor. XLI

animal after emergence from the capsule. It is of course possible
that this rotation of the axis of the initial whorl may be a result of
the rapid increase in size of this whorl since it nearly always accom-
panies such rapid increase, in which case it is a secondary feature.

I have elsewhere’ described in detail the protoconchs of Rhopa-
lithes and Clavilithes from the Calcaire grossier of the Paris Basin,
and shown their great distinctiveness, the species classed under
Rhopalithes having a fusoid protoconch with few riblets, while
typical Clavilithes has a papillose one of numerous whorls, with
other distinctive characters. I also showed that each genus em-
braced a series of species which in their stages of development
paralleled each other and ranged from the round whorled, ribbed
and fusiform type through a number of progressive changes, to an
extreme old age or phylogerontic condition. I further pointed out
that in spite of this remarkably close parallelism, the generic char-
acters remained constant, the protoconchs of the two series remained
distinct and Rhopalithes was throughout marked by the presence
of columellar plaits (not always visible in old shells unless the lip
has been broken back) which never occurred in Clavilithes. More-
over, the other shell characters are such that any one familiar with
these shells can separate the members of the two series almost at a
glance and without reference to the protoconch or columellar plaits.
In spite of this Cossmann? insists, and Boettger follows him,—
that my distinction is based solely on the difference in protoconchs;
and that I carry my faith in the essential constancy of the characters
of the protoconch and their phyletic value so far, that I have
allowed myself to separate into two genera what M. Cossmann,
and others who are accustomed to collect and study these shells
in their type-localities, consider to be varieties of one species only.
This arraignment might be more serious were M. Cossmann and
other high authorities on the shells of the Paris Basin accustomed
to study their species serially, and to give due attention to the
early conch stages. M. Cossmann has recently taken to a recog-
nition of the diverse characters of protoconchs, and in his valuable
“Essais” has illustrated many of them. Unfortunately these
illustrations are extremely crude,— often merely a spiral line —

1 Phylogeny of Fusus, etc.

?Cossmann. loc. cit.

No. 490] ORTHOGENETIC VARIATION 629

and the wonderful detail shown by many protoconchs is wholly
unrecognizable. As for the characters of the early whorls, and
their progressive changes, M. Cossmann, like most conchologists,
either deems them of minor importance or of none at all, and
does not grant them the space they deserve in his descriptions.
No wonder then that he should be horrified at my audacity in
making a new genus, where he sees only a variety. I was well
aware that the species separated by me under the genus Clavello-
fusus were classed by French conchologists as varieties of Clavilithes
parisiensis (which M. Cossmann still insists upon uniting with the
British C. solanderi under the name C. deformis coined by Brander
for the young of that or a related species) for I had specimens
labelled thus, presumably by M. Cossmann’s own hand; yet I
found, and continue to find whenever a new specimen of this series
comes under my observation, that the section denominated by me
Clavellofusus with the rank of a genus, is wholly distinct from,
and has its own series of mutations parallel to those of Clavilithes.
Moreover, if Deshayes is to be believed, this series belongs to the
Sables inférieurs, while Clavilithes belongs to the middle Calcaire
Grossier (though one species has been recorded from the Sables
moyens) except the most specialized terminal member of the group
C. scalaris which is confined to the Sables moyens or lower Upper
Eocene. All my material has shown, and I believe that a careful
and unbiased study of other material will show that the Clavello-
fusus series is distinct from Clavilithes of the Calcaire Grossier,
that it runs through its own series of modifications, some accelerated
or tachygenetic, other retarded or bradygenetic, and that- these
various mutations’ are derived from a Fusus-like ancestor, possibly
a Fusus itself, and not from Clavilithes parisiensis,—a species
appearing much later and belonging to a distinct genetic series.
The Clavilithes series is also derived from a fusoid ancestor but a
very different one from that which gave rise to the Clavellofusus
series. If M. Cossmann will admit that my Clavellofusus series
is a distinct series, — no matter what its origin,— and I do not see
how he can do otherwise unless he abjures all regard for phyletic
principles — I care not whether he joins me in calling it a distinct

1 I shall throughout use the term mutation in the earlier sense of Waagen.

630 THE AMERICAN NATURALIST [Vor. XLI

genus with species each showing a distinet step in progressive
development, or whether he makes the whole series a variety of
something and calls my species subvarieties. But he cannot make
the series a variety of Clavilithes parisiensis, any more than he
can make the uncle the son of the nephew.

Professor Boettger will probably find it difficult to point out that
the difference between the protoconch of Clavilithes and that of
Rhopalithes is due to any difference in physical environment, as the
fusoid members of the series, C. rugosus and R. rugoides occur
side by side, the same being true of other members of the same
series as well. Moreover, if he agrees with Cossmann, that Rho-
palithes and Clavilithes are generically identical, he will have to
show why the series with the Fusus-like protoconch has columel-
lar plaits and why these are wanting in the series with a papillose
protoconch.

Finally I may again call attention to the fact that I have de-
scribed in detail the variation in the protoconchs of Fusus and that
I have readily admitted the possibility of the existence of larger
and smaller initial whorls, of an increase or decrease in the number
of whorls in the protoconch, and of the variation in the number
of riblets on the protoconch. In fact I have illustrated such varia-
tions but I am not ready to admit that there is ever a difference of
type in the protoconch in what can otherwise be referred to the
same genus. I have repeatedly shown, that the so-called species
of Fusus from the American Eocene strata not only disagree
utterly as regards the type of the protoconch with true Fusus, but
that the young stages as well show much more acceleration than
is found in the young of even modern Fusus. “Fusus apicalis”
and “Fusus houstonensis” are an exception to this and it is not
impossible, that in spite of the remarkable protoconch, these may
be more nearly related to true Fusi, than is either Falsifusus
meyeri or Fulgurofusus quereollis.

Fusus acieulatus and “ Fusus” serratus occur side by side in the
Calcaire Grossier of the Paris Basin, yet the first retains its normal
Fusus protoconch while the second has a widely different type of
protoconch, like that of many Pleurotomas. It will be difficult
to explain on the hypothesis of any local cause of variation why
F. aciculatus retains the early Fusus whorls, common to all true

No. 490] ORTHOGENETIC VARIATION 631

Fusus, and always associated with the Fusus protoconch, while
“Fusus serratus” with a distinct protoconch has whorls more
specialized than those of any other true Fusus, even those of the
present day. Why do the fusoid shells in which the normal post-
embryonic developmental stages of Fusus occur, always have a
Fusus protoconch, while those fusoid shells which do not show the
true Fusus protoconch do not show the normal ontogenetic stages
of true Fusus, if this is not an expression of inheritance, and of
more fundamental significance than Cossmann, Boettger, or Giard
are welling to admit? It is high time that we cease making gen-
eralizations and tracing relationship by a superficial study of shell
characters. Such superficial study has deservedly brought the‘
whole subject of conchology into disrepute, so that morphologists
have come to look upon shell characters as the least reliable indices
of genetic relationships, whereas they are really the most reliable
and delicate of such indices, if subjected to a critical study.

ELIMINATION OF EARLY ConcH CHARACTERS BY ACCELERATION.

It not infrequently happens that the protoconch stops abruptly,
and the conch begins as abruptly. In fact, it may be said that this
is normal for such specialized types as the fusoid shells (Studies I,
figs. 1 and 5). In normal primitive types the protoconch char-
acters may be expected to merge by slow degrees into those of the
conch. Such is the case even in types specialized along one direc-
tion or another. In highly specialized types, however, we often
find an abrupt transition from the characters of the protoconch
to those of the conch, these latter beginning suddenly with a num-
ber of special characters. Thus in Fusus, the protoconch ends
abruptly with a strong varix, and the conch begins with round
whorls, ribs and spirals. Here protoconch and conch have been
telescoped, so that the transitional characters undoubtedly pos-
sessed by the ancestors of this genus were dropped out. Con-
ditions of this kind exist in a number of types which may or may
not be related to Fusus. Such relationship of protoconch and
conch cannot of course be regarded as indicating consanguinity
wherever it occurs, for it is clearly a stage in development, and
therefore a condition, which may appear in the specialized terminal

632 THE AMERICAN NATURALIST [Vor. XLI

members of any number of divergent genetic series. Conversely,
however, the want of such accelerated conditions in members of
the same genetic series may well be regarded as sufficient for
generic distinction, though this is largely a matter of personal
opinion regarding the elasticity of the generic boundaries. Even
greater acceleration than this is shown by many genera. ‘Thus
certain species of Semifusus have dropped out the round-whorled
ribbed stage, the conch beginning with the angular stage (Studies
I, Fig. 5).

In many cases the early characters appear not to have been wholly
dropped, but greatly condensed, so that the protoconch quickly
merges into a highly specialized conch, the transitional stages
being extremely short and often scarcely recognizable. ‘Then, too,
some of the early stages may drop out without the abrupt change
seen in Fusus, ete. Thus characters which in the phylogeny of
the group were developed only at a relatively late period after
other characters had come into existence, may in the specialized
members of this series appear immediately after the protoconch,
the earlier characters being dropped out of the ontogeny. On the
other hand, certain persistent characters may be pushed far back
into the ontogeny, and appear even in the protoconch stage. This
is seen in the riblets of the last whorls of many protoconchs (Fusus)
and in the appearance of an angulation or carina in others (certain
Murices, ete.).

Not only is acceleration by condensation and elimination active
in the earliest conch stage, but it is often found at a later period,
where some shell character, not strongly fixed in the organization,
may be eliminated to make room for a later and more prominent
one. This condition has already been briefly described for Fulgur
and Semifusus (Studies I, p. 932) and more fully for Fulgur in a
later paper (Studies II, p. 528). It may be briefly reviewed here.

In both genera, and in the case of Pugilina in what are com-
monly regarded as varieties of the same species, the tubercles are
normally developed as a result of the concentration of the ribs
upon the shoulder angle. This is characteristic of the earliest
Miocene Fulgurs as well as the ancestral forms of Semifusus and
Pugilina. With further development the tubercles grade into a keel
and this into a smooth rounded and ribless whorl, differing from the

No. 490] ORTHOGENETIC VARIATION 633

primitive rounded and ribless whorl in the presence of compound
spirals. This is the condition of adult Fulgur maximum and
certain forms of F. rapum of the Miocene. In more specialized
types a series of spines appears at periodic intervals on the primary
spiral which originally marked the angulation of the shell (Fig. 7).
These spines at first small, increase in size progressively up to a
certain point. They are simple triangular emarginations of the
outer lip and often are abruptly abandoned, so that they remain
open forward, though in other cases they are closed in front show-
ing a more progressive abandonment of the spine. ‘This diminu-
tion of the spine-forming emargination, is generally more rapid
than its development. This condition of newly added spines
following in the last whorl upon a smoothly rounded or slightly
keeled, non-tuberculate whorl is characteristic of Fulgur tritonis
(Fig. 7), F. pilosum, and others where a fraction of one whorl to
several whorls without tubercles or spines separate the primitive
tuberculate, from the last spinose whorls (Fig. 7). The same is
true of varieties of Semifusus colosseus and Pugilina pugilina
of the modern fauna (Fig. 8). Finally in the most specialized
types, such as Fulgur carica, eliceans, etc., and the accelerated
varieties of Pugilina pugilina, the spines have been crowded
back to such an extent that the non-spinose stages have been
dropped out. This telescoping has gone so far as to result in
partial overlapping of the spinous and tuberculose stages, as a
consequence of which the tubercles pass insensibly into the spines.
All stages of this telescoping can readily be observed in large col-
lections of the recent species of Pugilina cited.

The significance of this telescoping of characters is often not
appreciated. That it cuts out ancestral stages and shortens the
ontogeny by this elimination is evident, as is also the resulting
vitiation of the phylogenetic record in the ontogeny. Moreover
such an overlapping of characters destroys their individuality to a
certain extent and makes the later appear to be a mere accentuation
of the earlier whereas they have a distinct origin. Such telescop-
ing has apparently occurred in a great number of phyletic series.
In Eocene Columbarium, for example, the tubercles grade into
the spines in the nepionie stage of the shell. In modern Colum-
barium pagoda (Fig. 6) the tubercles and ribs have been pushed

634 THE AMERICAN NATURALIST [Vor. XLI

out of the ontogeny altogether so that the angulation of the ribless
whorls and the appearance of true spines is almost simultaneous.
Yet the Eocene species indicate that the genus passed through a
normal series of round-whorled-ribbed, and angular-whorled-tuber-
culated stages before the spines appeared. As already noted, a
second row of spines appears in several lines of radiation in this
series. In the genus Rhinocanthus, typified by Murex (Rhino-
canthus) brandaris, the principal spine likewise merges with the
tubercles which here are formed without the loss of the ribs. The
second spine has also been accelerated until it appears during
or shortly after the tubercled stage. In the more specialized
Murices, where the adult spines are compound, the early ones
have been pushed far back and are inseparable from the tuber-
cles or even from the ribs. It seems in fact that the spine-form-
ing stage has become superposed upon the rib-forming stage for the
ribs are characteristic of adult Murices of such relatively simple
types as M. brandaris and of such highly complicated types as M.
palmarosae as well.

In tracing the phylogeny of spinous gastropods it must be borne
in mind that tubercles and spines have a different origin, and that
where they appear to merge into each other this is due to accelera-
tion. It is highly probable that the ancestral forms of such
types will be found to have these two characters separated, the
spines not being found in the earlier members of the phyletic
series as has been demonstrated to be the case in Fulgur.

As has been shown above, the ontogeny of a great many widely
distinct types of gastropods is marked by a progressive increase
in the amount of embracing of the earlier by the later whorls.
This results in a change of angle of the spire from relatively acute
in young to often a rectangle or obtuse in the adult. In some
types (Conus) the change may be to 180 degrees, rarely more.
This same change is observable in the adults of the successive
members of the corresponding phyletic series. Thus the Eocene
species of Fusus are characterized by a slender spire throughout,
while the modern forms usually show the slender spire only in
the youthful stages, the adults becoming more broadly turreted.
In Tudicula, the Miocene species show a more slender spire, espe-
cially in the young, than is shown in the modern species. A similar

No. 490] ORTHOGENETIC VARIATION 635

condition is observable in Turritella, where the early species are
generally more loosely coiled. Such looser coiling is also observable
in the young of modern forms, in the adult of which the whorls
embrace up to the angulation. Here however another factor enters
in, the progressive flattening of the whorls so that the spire remains
slender even though the whorls embrace to the ambitus. Similar
conditions obtain in Nerinea, Cerithium, and others, the surface
of the whorls even becoming concave in many of these.

In its most pronounced form the progressive increase in the
* amount of embracing of the whorls is seen in phylogerontic types.
Here this increase is accompanied by a loss of ornamentation and
distinctive form. In its most striking form this excessive embrac-
ing is seen in Melongena, where the earlier whorls become to some
extent enwrapped by the later ones, the form of these later whorls
bearing no relation to that of the earlier ones, but being without
the normal ornamentation of the earlier whorls (Studies I, fig. 9).
Similar though more regular conditions are found in the clavili-
thoids for a discussion of which the reader is referred to my “ Phy-
logeny of Fusus.” Cossmann has recently reiterated his belief in
the generic relationship of Clavilithes and Cyrtulus which latter
type is a phylogerontic terminal of the modern Fusus series. This
reassertion of his former position indicates that Cossmann has
either not carefully read my arguments for the total distinctness
in origin of these types — or if he did, that he does not consider
them as valid. If this is the case I must give up all hope of con-
vincing him, for I do not see that I can state the case more fully.
If any one not biased by inherited ideas of relationship indicated
by adult characters, will carefully compare the young of Cyrtulus
serotinus Hinds with the nepionic and neanic stages of any species
of Fusus of the F. colus series, he will be impressed with the simi-
larity of these two types, a similarity which so far as the details
shown are concerned, amounts to identity. I do not believe that
any one can distinguish the young of Cyrtulus serotinus from that
of any member of the Fusus series, unless he finds some characters
not yet observed in these types. Certain it is, that the young of
this species, is more nearly identical with that of any member of the
Fusus colus series than with any other known gastropod. This
similarity can only be the result of relationship, so that the unbiased

636 THE AMERICAN NATURALIST [Vor. XLI

investigator will probably be forced to accept this evidence as
indicative of community of descent. If we now take the most
closely similar type of the Eocene clavilithoids, which I think all
will agree is found in the forms I have classed as Clavellofusus —
but which Cossmann still considers varieties of Clavilithes pari-
siensis Mayer-Eymer (Clavella deformis of Cossmann) we find
that its young leads us to some Eocene or earlier fusoid ancestor
which may or may not have been the ancestor of the modern Fusi,
including the Fusus colus series as well. Assuming, for the sake of
making the argument as favorable as possible to M. Cossmann, -
that Fusus and Clavilithes had a common ancestor,— which,
moreover, is probably the case — and allowing for the moment
that my species of Clavellofusus are varieties of Clavilithes pari-
siensis as Cossmann contends,— but which most certainly is not
the case — if we allow this, where do we land? In the first place,
if youthful characters show relationships at all,— and I doubt if
in view of all the evidence accumulated along so many and diverse
lines, even Cossmann will have the hardihood to deny this — it is
evident that all the Eocene clavilithoids are derived from an Eocene
or earlier fusoid ancestor, which we will allow was a true Fusus
and the ancestor of the modern Fusus as well. Nevertheless,
it remains true that Cyrtulus serotinus is a derivation of modern
Fusus and not of Eocene Fusus, a point established beyond ques-
tion by the character of its young.

If Cossmann were to contend that both the modern and the
Eocene clavilithoids were derived directly from a common Eocene
or earlier ancestor there would be some reason in his gathering
all these divergent lines into a common generic boundary. The
question would then.be boiled down to that of the greater or less
elasticity of the generic boundaries. But Cossmann holds that
Cyrtulus serotinus is a descendant of Clavilithes (“ quoiqu’elle
[Cyrtulus] soit le descendant immédiat des Clavilithes ”) although
the young stages show that this is not the case, as every student of
phylogeny of Mollusca as deduced from shell structure will readily
admit on comparison. Unless, then, Cossmann can prove the
direct derivation of Cyrtulus serotinus Hinds and Clavilithes

Joe. cit. 1904, p. 234.

No. 490] ORTHOGENETIC VARIATION 637

parisiensis Mayer-Eymar (or better Clavellojusus spiratus) from
a common Eocene or earlier ancestor, without the intermediation,
_ In the Cyrtulus line, of modern Fusus, his proceeding would be
almost as illogical as the classification of all ammonoids showing
a corresponding degree of involution in the same genus. ‘This
will appear more clearly from a consideration of the following
diagram.

Modern Fusus — Cyrtulus

Neocene ate

|

Eocene Fusus Clavilithes
|

ae radicle
The only other way, in which Clavilithes and Cyrtulus can be
made congeneric, is by also including Fusus in this genus, a
stretching of generic limits, to which even M. Cossmann will most
certainly object.

I have elsewhere’ outlined in detail a number of genetic series
among the Clavilithoids which, diverging probably from a com-
mon ancestor, produced. similar end forms, just as divergent am-
monite phyla often had end forms superficially alike. Whether
the series which I have outlined to the degree of detail permitted
by the available material, will be found to be complete, or will
need modification in the future, remains to be seen. That the
various series exist, is, I think, beyond cavil, and certainly cannot
be set aside by a wholesale assertion of authority even on the part
of the most veteran collector of these fossils.

It has already been outlined in the earlier part of this paper, that
old age characters in gastropod shells are also shown by the loss
of the power to coil, as is so commonly the case in cephalopods.
That such characters have been taken as distinctive of new genera
is not surprising, and indeed is desirable. Great caution however
is necessary not to make this the sole distinguishing character, and
class together terminal loose-coiling members of distinct genetic

1 Phylogeny of Fusus. Smithsonian Miscellaneous Collections, vol. XLIV,
no. 1417, 1904.

638 THE AMERICAN NATURALIST [Vor. XLI

series. That this has been done in Vermetus, admits of little
doubt. The Mesozoic and Tertiary species of this group repre-
sent phylogerontic terminals of various genetic lines of turritel-
loids, becoming extinct in these periods, just as modern species
represent terminals of one or more lines of modern turritelloids.
Even if the species of turritelloids are considered as congeneric
throughout, the terminal vermetoids cannot be congeneric but
merely represent a stage in development. Each terminal group
would of necessity represent a distinct genus unless it were united
in one genus with its corresponding ancestral turritelloid, as in
the following diagram.
I? 3.4
Vermetus stage ae ed
a bed
Turritella stage E48]
Thus if a, b, c, and d represent four diverging specific lines of Tur-
ritella and 1, 2, 3, and 4 the corresponding Vermetus form, these
latter could not be classed as one genus, Vermetus, unless a, b, c,
and d were also classed in the same genus. Each must be con-
sidered as a separate genus whether it has one or more species, but
1 and a, 2 and b, 3 and c, 4 and d, can each be classed as a dis-
tinct genus, with a turritelloid and a vermetoid species, or all
species of vermetoids may be classed as Turritella. -

This reasoning applies with equal force to the non-coiling forms
commonly classed as Platyceras, this term having the value of a
stage. A similar though very slight loosening of the last whorl is
made the basis for the separation of the genus Diastoma from
Melania, although pathologic individuals of the latter sometimes
show an identical character (Fig. 19). That in the case of this
so-called genus we really deal with a stage in development, and
therefore with terminal members of different phyletic series, which
ought to be united with their respective Melania ancestors instead
of being classed together, en more apparent as the detailed
study of these types progresse

In extremely accelerated series it often happens that the mode
of development appears to be reversed, the specialized character
appearing first, and the less specialized later. Thus in certain

No. 490] ORTHOGENETIC VARIATION 639

Melanias in Cerithium, Turritella, etc., ornamentations appear in
the young which are lost in the adult. Without departing from an
orthogenetic mode of development, the succession of characters
developed seems to be inverted. In such cases it generally appears
on study of the youngest stages that the simple characters of the
adult are similar to the most youthful characters, before the most
pronounced features appear. ‘This feature will be described later
in some detail in certain Melanias and is also seen in other special-
ized types. It is readily explained by referring it to degradational
development, where characters acquired during the aggradational
period are lost in the reverse order of their acquisition. Sometimes
differential acceleration may account in part for this. Thus in
some cases, the shell becomes carinate and only subsequently
develops ribs. These may be a later acquisition having never
before appeared in the phylogeny of this series. Whatever the
cause of such development, the method is orthogenetic, the
variation being in all cases progressive in one direction or another.

EXAMPLES ILLUSTRATING ORTHOGENESIS.

I have elsewhere described a considerable number of genetic
series among the fusoid shells‘ and have also traced in some detail
the development of the Fulgur and Sycotopus series (Studies IT).
It has there been clearly shown that the development is orthoge-
netic, both as regards phylogeny and ontogeny, and that the great
governing principle in the production of diversity is acceleration or
tachygenesis, and retardation or bradygenesis. To show more
clearly the universality of this principle of orthogenetic variation
among the Gastropoda, I will here append a somewhat detailed
discussion of several phyletic lines among the Melanias, a group as
distinct as possible from the Fusidae. Unfortunately in the speci-
mens studied, the protoconchs were not available, so that all the
deductions are based upon the characters of the conch, from its
earliest to its latest stages.

Melania is well adapted to this sort of study on account not only
of its variability, but also because it has so many characters upon

1 loc. cit.

640 THE AMERICAN NATURALIST [Vor. XLI

which we can seize for the purpose of determining the line of prog-
ress. The earliest types were undoubtedly marine giving rise on
the one hand to the fresh water Melanias and on the other hand to.
a number of marine descendants. No exhaustive discussion is
contemplated here, this and the tracing of the various genetic lines
being reserved for a future work. Only some of the more salient
features developed during the study of this group of shells will be
mentioned here as illustration of the principles discussed.

The Eocene Melanoides praecessa and M. inquinata of the Paris
basin may be taken as a starting point, though they already present
characters of considerable complexity both showing a marked series.
of changes. In the former the earliest stages observed show
rather flatly rounded whorls with distinct, narrow, rounded ribs
which are concave forward (i. e., towards the aperture). ‘These
ribs are cancellated by revolving spirals which however are faint
in the interspaces, but form pronounced nodules on the ribs. In
some specimens the earliest ribs appear to be free from these
tubercles, and the mode of appearance seems to indicate that the
ribs precede the spirals. This is the character of the early stages.
of the type specimen figured and described by Deshayes (Des.,
An. sans. vert., II, p. 452, pl. 23, figs. 31-32) these stages being
free from spirals. This character recalls the adult of Pseudome-
lania (Chemnitzia) undulata d’Orb., Ch. carusensis d’Orb., Ch.
corvaliana and Ch. periniana d’Orb., from the Middle Lias and Ch.
rhodani of the Upper Lias of France.' In later Jurassic strata of
France occur many Pseudomelanias, which show no ribs in the adult.
Some of these may however possess them in the young, as has
actually been found in the case of P. nerei d’Orb. of the Bathonien.
Such occurrences suggest that the smooth Pseudomelanias are
derived from the ribbed ones and hence in so far as they have
lost this character are phylogerontic.

n Eocene Melanoides praecessa var. spiralis var. nov. from
Noyon (C. U. coll. 30041, fig. 10) the spirals become gradually
strengthened, until they are well marked. ‘The uppermost or pos-
terior spiral becomes strongest; and gradually the space above it
develops into a concave shoulder free from ribs. On this shoulder-

`- ıD’Orbigny. Paleontologie Francaise.

No. 490] ORTHOGENETIC VARIATION 641

angle develops a series of nodular spines, as the ribs gradually
become obsolete, slightly fainter nodules being formed where the
lower spirals and ribs cross. With the complete disappearance of
the ribs, the lower spirals—of which there are four large and three
smaller more closely crowded ones in the adult -— become con-
tinuous and free from nodulations. No intercalated or secondary
spirals occur, except in accelerated types, where the shoulder and
nodules exist for only a few neanic whorls, after which they gradu-
ally disappear, only faint primary and secondary spirals remaining
on the last whorl (Mut. @ Fig. 9; C. U. coll. 30042). In the type
specimen of M. praecessa figured by Deshayes, the ribs have not
entirely disappeared in the adult. It represents a more primitive
or more retarded individual than the Noyon variety described
above, its adult features being comparable to the early neanic of
var. spiralis Grabau. Three varieties of M. inquinata (Def.)
are figured by Deshayes (Coq. foss. Em. Paris II pl. 12), of
these var. a (Desh., figs. 3 and 14, our fig. 11) is the immediate
successor of M. praecessa var. spiralis, but the tubercled character,
which in that variety occurs only in the adult, is here found in
the neanic and perhaps even in the nepionic whorls. Var. b
(Desh., figs. 15, 16) is characterized by the suppression in the adult
of all the spirals except the one on the angle, on which the tubercles
become greatly strengthened, and the spiral just above the suture
which is non-tuberculate. Both shoulder and body of the whorls
become strongly concave in the adult. The third variety (c, figs.
7 and 8 of Deshayes) has all the tubercles suppressed, while the
spirals become strong and the whorls below the shoulder rounded
(Fig. 12). The phyletie relationships of these types may be
expressed as follows, the length of line representing relative amount.
of divergence.

var. b var. a (Fig. 11) var. c (Fig. 12)

|
| M. inquinata
|
| Mut. 8
M. praecessa var. spiralis —— ——
(Fig. 10)

642 THE AMERICAN NATURALIST [Vor. XLI

M. praecessa var. spiralis
|

|
|

M. praecessa
(Desh., An. sans Vert., II, pl. 23, figs. 31-32)

Jurassic ribbed Pseudomelania
(D’Orbigny, Pal. Francaise)
|

An interesting line of departure is shown in some specimens of
M. praecessa var. spiralis. Here the second spiral from the pos-
terior suture is the strong or primary one; 7. e., early in the ontog-
eny a new spiral appears above (posterior to) the primary one.
This continues on the shoulder, and before the disappearance of
the ribs becomes somewhat tuberculose. Intercalated spirals also
appear on the adult whorl. ‘This appears to have been the lineal
ancestor of Melania asperata Lam. var. Brot, of the Philippine
Islands, a fresh water type (Figs. 14 and 15). The less accelerated
individuals of this form show the early ribbed whorls, though these
are marked by a large number of closely set extremely fine spirals
not observed in the Tertiary species. In the individual represented
by Fig. 15, a single row of spines makes its appearance after five
or six volutions. These spines appear near the center of the
exposed whorl, one on each rib, and begin shortly before the
appearance of the ribs themselves (Fig. 17). At first the spines
are very weak but gradually they increase in size, at the same
time beginning earlier and ending abruptly upon the rib. Together
the spines and their posterior prolongations produce the appearance
of spirals. The single row of spines continues for almost four
volutions the whorls gradually becoming divided into shoulder and
body with the spines on the pronounced shoulder angle. A second
row appears on the shoulder beginning as a faint elevation which
is gradually strengthened.

In a more accelerated individual (Figs. 14 and 16), the second
row of spines cr almost simultaneously with the first one
though the lower row | strongly accentuated.

No. 490] ORTHOGENETIC VARIATION 643

Strong spirals appear on the body of the whorl without the forma-
tion of spines, one or sometimes two of these spirals appearing
above the suture of the succeeding whorl. Intercalated spirals
occur on the body of the last body-whorl.*

‘These Melanias therefore seem to be extremely accelerated, the
spines appearing while the ribs are still in full force.

A type apparently retarded as far as the form is concerned is
found in M. dactylus Lea from the Philippines (Martini Chemnitz
Melania pl. 9, figs. 2 and 2a) in which two whorls of the adult are
marked by narrow crescentic ribs cancellated by numerous spirals
which appear in the earliest part of the ribbed whorls. The initial
whorl is not known but the whorls immediately succeeding are
smooth in appearance and embrace to the ambitus. Whether or
not fine spirals occur on the earliest whorls is not ascertainable.
The succeeding whorls embrace less, thus producing the slender
spire. In the adult of many individuals the ribs become obsolete
that being the usual line of development. Brot (Martini Chemnitz
I 24, pl. 9, fig. 2a) however figures a specimen which successively
acquires two rows of tubercles in the adult thus paralleling M.
asperata var. 3 of the Philippines.

While these types show aggradational progression, modified by
differential acceleration and retardation, other species referred to
Melania show degradational progression, i. e., a progressive modifi-
cation through suppression of characters. Certain Jurassic Pseu-
domelanias showing this have already been mentioned. A modern
example is Melania elevata Say from Indiana. Here the late
nepionie and neanic whorls are carinated, this carina gradually
disappearing the shell becoming smooth and with scarcely im-
pressed suture and with spirals only on the lower part of the whorl.
The aspect is that of Pseudomelania, the character being derived
through progressive reduction of features inherited from specialized
ancestors.

The same thing is true of M. deshaysiana Lea, and M. costu-
lata Lea from Tennessee. Here the order of development seems
to be entirely inverted, the earliest whorls being carinated while
the later ones show successive suppression of the carina, and the

1 See Martini und Chemnitz, Syst. Conch. Cab. I 24 pl. 8, figs. 1, 1b and 1f,

644 THE AMERICAN NATURALIST [Vor. XLI

strengthening of the ribs and spirals until in the spiral whorl the
ribs and spirals gradually disappear. So far as shown by the
specimens examined, which all lack the apical whorls, the ribs are
absent from the early carinate whorls. It is possible that the cari-
nate whorls are preceded by rounded ribbed whorls but of this
we have at present no evidence. Should this eventually prove not
to be the case, the explanation of these characters must be found
in the early acceleration of the carina, which appeared on the
smooth whorls before the ribs had appeared these latter not coming
in until the time of disappearance of the carina. In M. strigosa
Lea from the same locality, ribs seem to be wanting altogether,
the early angular whorls passing by disappearance of the keel-
and spirals into a smooth adult form. Other species having
smooth adult, and ribbed and spiralled youthful form are M. rustica
Moussen (Martini Chemnitz pl. 17; 2 a, b), M. palimpsestos Reeve
(Martini Chemnitz pl. 17; 3), and M. hastula Lea (Martini Chem-
nitz pl. 16; 3, a-d).

Claviger subauritus Brot represents the more primitive condition
of that genus, in which the whorls are ribbed, the single row of
tubercles being developed only on the last whorl (see Martini-
Chemnitz I 24, pl. 36, fig. 11a).

The extremely spinose types of Melanias such as Claviger
byronensis Gray (Martini Chemnitz pl. 36; 10a-c), and C. auritus
Müller (Martini Chemnitz pl. 36; 7a-c), represent accentuations
of one character at the expense of the others;— a one-sided
acceleration. In the latter species the nepionic whorls show ribs
and spirals the central of which become fused with two adjoining
ones. This fused series quickly becomes accentuated in a pro-
nounced tubercle, which increases in size and becomes variously
modified while the remaining portion of the shell becomes smooth.
At first the tubercles are near the middle of the whorl but gradu-
ally as they increase, the relative amount of embracing increases
until the tubercles of the adult whorl lie just above the suture.
In C. byronensis two groups of spirals become tuberculated, a third
one occurring in some varieties. :

A closely parallel series of variations is found in the modern
Potamides fuscatus of Gambia. The nepionic and early neanic
stages are identical with the adult of P. granulatus (Brug.) (P.

No. 490] ORTHOGENETIC VARIATION 645

corvenii Fer.) of the same locality. This begins with a round-
whorled ribbed stage passing into an angulated stage in which the
spirals are prominent. ‘The ribs progressively break up into tuber-
cles, those on the median spiral being more prominent. In acceler-
ated individuals (P. radula Linn.) the upper of the two median
spirals has its tubercles slightly more accentuated than the lower,
while a secondary spiral between them is also slightly tuberculated.
The young of P. fuscatus Linn. shows the bicarinate whorls, the
spirals forming the two carinae being tubercled. Somewhat later
the upper series of tubercles becomes accentuated and a second-
ary spiral appears between the two. Up to this point, perhaps one
fourth the length of the shell or less, all the stages except the
earliest of P. granulatus are repeated, so that the young of P.
juscatus is in effect a diminutive P. granulatus. The further
development of P. fuscatus is along the line of accentuation of the
tubercles of the upper spiral, until they have become pronounced,
sharp, and spine-like in the adult, all the other spirals, except the
one just above the suture, disappearing in the most specialized
examples. ‘The series in this case is as complete as is that of the
spinose Clavigers, and representative species, showing the same
stage of development so far as the surface characters are concerned
can be selected in both series.

The carinated Melanias represented by Claviger matoni Gray
(Martini Chemnitz pl. 37; 3, 3a-f; 4,4a-b) from Senegal show
another interesting type of modification. The primitive species
(C. mutans Gould, Martini Chemnitz pl. 37; 3b-e) are spiralled
and ribbed, the upper spiral being the stronger. In somewhat
more accelerated individuals the ribs are lost on the last whorl,
but the spirals continue and become stronger, especially the upper
one which begins to extend outward as a strong flange form-
ing a deep notch or sinus in the lip. Somewhat more acceler-
ated specimens show two or three final whorls in this condition,
the flange of the last one becoming extremely pronounced, while one
or in case of more loosely coiling individuals, two of the lower spirals
also begin to be strengthened. Finally in extremely accelerated
specimens, the ribbed and spiraled portion is restricted to the
apical part, and it passes almost abruptly into a smooth shell on
which the upper spiral makes a pronounced flange-like carina,

646 THE AMERICAN NATURALIST [Vor. XLI

while the one just above the suture also becomes very pronounced.
Sometimes this latter is prevented from taking part in the orna-
mentation of the shell by the close coiling of the whorls, the suc-
ceeding whorls crossing this spiral. (Martini Chemnitz, I 24, pl.
37, fig. 3-3a). Differentially accelerated specimens may have the
flange pushed back into the ribbed portion; i. e. the flange appears
before the ribs disappear. Then the flange is broken up into
blunt vertically flattened spines which unite into a keel as soon as
the ribs disappear entirely.

We have thus in the Melanias, a group of highly accelerated
gastropods in which the spines,— a specialized feature, appear-
ing late in the phylogeny of most gastropods — have become a
dominant character, appearing before the ribs have disappeared.
Many phylogerontic members of this group, forming terminals of
genetic series, retain their ornamentation only in the young, the
adults becoming smooth. In several lines extreme accentuation of
certain characters at the expense of others has resulted in grotesque
forms. All the characters, however, appear and disappear in a
regular progressive manner both in ontogeny or individual devel-
opment, and in phylogeny or the development of the genetic series.
The Melanias therefore constitute an excellent group from which
illustrations of ortho-ontogenesis and ortho-phylogenesis may be
obtained.

PALÆONTOLOGIC LABORATORY
COLUMBIA UNIVERSITY

PLATE I.
Fic. 1.— Tudicula bispinosa Grabau; young individual, showing beginnings
of second row of spines. (Col. Univ. Coll. 3
Fig. 2.— Tudicula ru iron (Basterot); early stages enlarged X 10, to show
looser coiling and gradual app (C. U. Coll.

30046.

Fic. e Tudicula bispinosa Grabau; a somewhat older individual than that
shown by fig. 1. (C. U. Coll. 3004 7) nn ae

Fie . 4 5 p y developed
(C. U. Coll. 30048.)

Fic. 5.— Tudicula rusticula (Basterot); a characteristic adult form with a
single row of spines.
All the above are from the Miocene. Fahluns de Bordea

Fie. 6.— Columbarium oda (Less.) Recent en ‘and a conch

stages enlarged X 10, showing elimination of ribbed ancestral s Cc.

U. Coll. 397

Fic. use 0 Conrad. Summit view of a characteristic specimen,
showing the smooth neanic stage and the gradual development of the spines.
(C. U. Coll. 30052.)

PLATE 2.

Fic. 8.— Pugilina pugilina sie’ f Tapez iby mutation retaining the smooth
818a.

stage in the neanic. (C. U. pas
Fig. 9.— Me pretera Grabau Mut. 8; showing disappear-
1. 30042.)

ance of nodules in later zug Sn er Eocene, Noyon. (C. U. Col
Fie. 10.— noides eos var. spiralis Grabau. Type. Lower Eocene,
1.)

(C. U. Coll.
— Melanoides proton (Def.) var. a Desh.— Copy of Deshayes figure.

Fid. 12.— Melanoides qui
en appearance of second and later spirals, partiy by intercalation.
Much enlarged. (C. U. Coll. 30054.)

in
a
4
Bi
o
F
fe
|}
>
28
©
i;
4
&
Eh
®

PLATE 3,

Fig. 14.— Melania eg Lam. var, 8 Brot. Recent, Philippines. Acceler

ated mutation with t rows of spines appearing almost ich
(See fig. 16.) npe hi Coll, eo
Fig. 15.— Melania . var. Ê Brot. Recent, ee A muta-
U

tion with a ie i ee era in the young. (See fig. 17.) (C. U. Coll.
41518.

Fig. 16.— Melania asperata Lam. var. B Brot. Enlargement of young stages
of fig. 14.
Fic. 17.— Melania asperata Lam. var. 8 Brot. Enlargement of early stages
of fig.
Fic. 18.— Me lania An unidentified species from the Tertiary of Abys-
sinia showing won of third spiral by intercalation. Much enlarged,
30053.)

Fic. 19.— Melanoides praecessa var. spiralis Grabau. A senile individual
showing loosening of last portion of whorl, a feature regarded as character-
istic of Diastoma. Enlarged x 2. Eocene, Bordeaux. (C. U, Coll. 30043.)

MUTATIONS AND THE GEOGRAPHIC DISTRIBUTION
OF NEARLY RELATED SPECIES IN PLANTS
AND ANIMALS

J. A. ALLEN.

In the American Naturalist for April, 1907 (vol. XLI, pp. 207-
. 240) Robert Greenleaf Leavitt has discussed with great clearness
and discrimination “The Geographie Distribution of Closely
Related Species,” with more special reference to plants than to
animals, and also with reference to the bearing of the facts of dis-
tribution upon the mutation theory of de Vries. After present-
ing an impressive array of facts regarding the distribution of nearly
related species, or “forms,” in several widely different groups of
plants, in part based on his own studies of the Orchidaceae, he
gives his personal impression of the matter, stating in his conclud-
ing remarks that it seems to him “that the study of specific distri-
bution in the vegetable kingdom is not likely to be unfavorable
to Mutation, regarded as a method, but perhaps not the sole
method, of evolution.” He concludes: “ The indications are
that the adherents of Mutation will be able to bring forward
enough cases of social distribution to render phytogeographic
weapons useless in the attack upon this Theory.”

Taking the facts of animal geography, as stated by a large
number of zoologists, “we may say,” says Leavitt, “that as a
whole they militate against the operation of Mutation in a wide
sense in the animal kingdom. ‘This conclusion,” he adds, “‘is
not prompted by the attitude of certain of the zoologists mentioned
. . - -but is drawn from the geographic evidence.”

In his final generalizations he offers this very judicial statement:
“First, we note that zoologists and botanists are rather distinctly
opposed to each other in their views of the actual state of specific
distribution. The suggestion is offered that zoologists may best
discover the condition and interpret its meaning among animals,
and botanists among plants. In no case is it safe to reason deduc-

653

654 THE AMERICAN NATURALIST [Vor. XLI

tively from one kingdom to the other. In the factors affecting
their evolution plants and animals differ vastly.”

Here is a concession from the side of the botanists that should
do much toward harmonizing the conflicting views of botanists
and zoologists respecting the influence of ‘mutation’ in the evolu-
tion of forms among animals and plants. In the first place the
conditions of reproduction, structure, growth, etc., in the two
kingdoms are so radically different that the methods of evolution
may also well be different; indeed, it would be surprising to find
them not so.

Mr. Leavitt’s paper is primarily a contention that President
Jordan’s law respecting the distribution of nearly related species
does not hold in the vegetable kingdom. It is assumed that Jor-
dan’s law was intended to apply equally to both animals and plants,
which interpretation seems to be supported by the context of the
paper. The law is as follows: ‘Given any species in any region,
the nearest related species is not likely to be found in the same
region nor in a remote region, but in a neighboring district sepa-
rated from the first by a barrier of some sort.” If we substitute
in this expression the word ‘kind’ or ‘form’ in place of ‘species,’
and restrict its application to animals, it will probably meet with
general approval on the part of zoologists.

In testing Jordan’s law by an examination of the facts of dis-
tribution presented by the Orchidaceae, Leavitt says he “looked
for pairs of kinds,” and adds: “I say kinds instead of species
intentionally. The main problem should not be confused by the
difficulty of agreeing upon a definition of species. What the evo-
lutionist has to account for is not the definitions of systematists,
but the multiplicity of hereditary types; he has to explain the
antithesis between the uniformity which heredity seems at first to
promise, and the diversity which actually prevails among organic
things.” It is evident, however, that in the expression “pairs of
kinds,” the term kinds is given unequal breadth of meaning in
different instances, and is not here the equivalent of “nearly related
forms,” or “ subspecies,” as these terms are employed by zoologists.
As regards the higher vertebrates, the evidence is indisputable
that two closely related forms do not occupy the same area. By
this expression the subspecies of zoologists are meant,— in other

No. 490] - MUTATIONS AND DISTRIBUTION 655

words, intergrading forms of a common stock. It is therefore
perfectly evident that botanists and zoologists are often speaking
of entirely different concepts when discussing the occurrence or
non-occurrence of species in the same area. It is also evident that
minor forms among plants bear no relation to the minor forms
among animals, either in mode of origin or in manner of distribu-
tion. In Crataegus, Rubus, Amelanchier, Viola, Aster, and -
countless other generic groups of plants, there often occur many
slightly differentiated forms growing side by side over large dis-
tricts. Among animals, at least among vertebrates, no such con-
ditions appear to obtain; the slightly differentiated forms occupy
different areas, and where the borders of their breeding ranges
approach they gradually merge the one into the other with the
gradual change in the environment. In the case of the plants
mentioned, these slight differentiations maintain themselves de-
spite similarity of environment; in the case of the animals, they
are obviously the product of environment. ‘The origin of such
plant forms may never be discovered, but to many minds their
development by mutation may seem not improbable. So long as
we do not find similar conditions among the higher animals, it
is hard to see how mutation has been active in the origination of
new forms, whether species in the usually accepted sense, or the
minor variants usually recognized as incipient species or subspecies.
With these facts and conditions in view Dr. Leavitt’s above-
quoted suggestion that “‘zoologists may best discover the condi-
tion and interpret its meaning among animals, and botanists among
plants,” is eminently worthy of serious consideration. It is “ob-
viously unsafe,” as he well says, to reason deductively from one
kingdom to the other.

A recent re-reading of the various recent papers by botanists
and zoologists on the subjects of “ mutation ” and the “distribution
of closely related forms” in animals and plants has given me the
impression that much of the opposition of views on these questions
is due in part to too sweeping assertions by both botanists and
zoologists, in part to a misunderstanding by one side of what the
other side really means, and largely to deductive reasoning from
wholly dissimilar conditions.

AMERICAN Museum or NATURAL HISTORY
New York

NOTES AND LITERATURE

SCIENTIFIC EXHIBITS AT THE SEVENTH INTERNA-
TIONAL ZOOLOGICAL CONGRESS

From the 19th to the 24th of August, American scientists were
privileged to entertain the delegates and members of the International
Zoological Congress at the Harvard Medical School, in Boston. The
congress met in ten sections, and its program announced the titles
of three hundred papers. The scientific exhibits, which were of
unusual interest, are briefly described in the following paragraphs.

Paleontology.— Professor A. W. Grabau of Columbia University
exhibited five series of spirifers of the S. mucronatus type, to show
the gradual evolution of five species along parallel lines. The most
primitive and oldest forms, from the middle Devonian (lower Ham-
ilton), are long-winged and flat. They gave rise to the five inde-
pendent series under discussion, in each of which the shells range
from long-winged flat forms to those which are short-winged and
round. Progress is always toward the rounded form, as shown both
by the dimensions of the average shell in a given group, and by the
extreme variations. Thus the most elongated shells in any group
are not as long as the extreme examples from a lower horizon, but the
most rounded forms surpass any which occur in the deeper strata.
As shown by the lines of growth on the shells, the young stages in a
given series are more elongated than the mature forms, thus resembling
the adults of the preceding type. Thus the series demonstrates a
gradual orthogenetic development of species, which, since similar
changes occur in different localities, is presumably independent of
environment.

Professor W. Patten of Dartmouth College exhibited a superb
collection of Bothriolepis from the Devonian of New Brunswick.
Bothriolepis is a fish-like invertebrate about ten inches long, consist-
ing of an oblong cephalo-thorax covered with sculptured dermal
plates, and a slender body free from scales but bearing dorsal and
caudal fins. A strong, spine-like swimming appendage projects from
either side of the thorax. Professor Patten has described and figured
Bothriolepis in the Biol. Bull., 1904, vol. 7, p. 105-124, and the
related Tremataspis in the Amer. Nat., 1903, vol. 37, p. 223-242.

657

658 THE AMERICAN NATURALIST [Vor. XLI

Bothriolepis presumably lived in fresh or brackish water, and moved
in large schools. One of the slabs showed some ten individuals
headed in the same direction. Ferns and plant stems turned in the
opposite direction showed that they were moving against the current.
Another slab contained four specimens moving in the same direction
but lying at different levels, indicating that two at least were buried
in the sand when killed. The internal structure of Bothriolepis, in-
cluding its stomach and the arrangement of its gills, was shown in
serial sections of the fossils. In studying the ancestry of vertebrates
Professor Patten desired further knowledge of Bothriolepis than could
be supplied from any existing collection, and therefore he collected for
himself the group of fossils exhibited. His theory of vertebrate devel-
opment from arthropod prototypes was illustrated by some fifty clay
models. ‘They were designed “to show how the earlier vertebrate
stages are but a further specialization of the later stages of an arach-
nid. ‘The models show the origin of the blastopore, the unfolding of
the cranial sense organs, the relation of the cranial neuromeres to the
cephalothorax, the origin of concrescence, the derivation of the oper-
culum and branchial chambers, the lateral fold, visceral arches, and
the union of the anterior visceral arches on the haemal side to form
the premaxillae, maxillae, and mandibles.” One series of models
illustrated the relation between echinoderm larvae and arthropod half-
embryos; another series showed similarities in the mode of attachment
of the larvae of cirripeds, echinoderms, and vertebrates; and a third
presented a suggestive comparison of the brains of the scorpion, horse
shoe crab, and primitive vertebrate.

Dr. C. R. Eastman of Harvard University showed specimens of
the head shields of lung fishes, so that the well known Scottish Devo-
nian form could be compared with the less known Canadian Scaumen-
acia, and also with existing lung fishes.

Mr. C. H. S. Sternberg of Lawrence, Kansas, who has collected
fossils for forty years, exhibited some tortoises from the Cretaceous
“Red Chalk” of Kansas, together with a specimen of Hesperornis
regalis. The latter does not include the skull, but the cervical verte-
brae were found, and show that the bird had a longer neck than some
have supposed. The skeleton of the feet and legs is complete and the
pelvis is well preserved. The divergent position of the legs is similar
to that seen in divers and loons. Mr. Sternberg is about to publish
a popular account of his experiences as a collector, entitled “The Life
of a Fossil Hunter,” for which Professor H. F. Osborn has written an
introduction.

No. 490] NOTES AND LITERATURE 659

Zoology.— Dr. C. F. Rousselet of London exhibited fifteen slides
of rotifers. They were remarkably fine, since by a special method
the animals An been preserved in an extended condition. They
were killed in a 7; % aqueous solution of osmic acid, and sealed in 7%
formalin on holo% ground slides. During the congress Dr. Rousselet
identified fifteen species of rotifers which he obtained in one “dip”
from the pond in the Public Garden.

Professor J. A. Thomson of the University of Aberdeen showed
new and rare forms of corals chiefly from the Indian ocean. They
included a specimen of the remarkable new genus Studeria from the
littoral region of the Andaman Islands.

Miss E. R. Gregory, professor of biology at Wells College, New
York, demonstrated the structure of the sand dollar, Echinarachinus.

Drs. F. B. Sumner and J. W. Underwood have studied “the seem-
ingly protective coloration of the gastropod Litorina palliata” at Woods
Hole, and they exhibited water color drawings, made by K. Hayashi,
of the shells and the sea weed upon which they live. The shells vary
from dark brown or black to bright yellow, and they may be either
uniform in color or striped. The sea weed also ranges from dark
brown to yellow. The snails, however, do not select appropriate
backgrounds, either experimentally or in nature. Over variously
painted sectors of a glass dish their distribution is purely by chance,
and in nature yellow shells are found on brown weed and vice versa.
As far as experiments have shown, the fish called tautog is as likely
to take shells from the surroundings which they match as from others.
It is possible, as has been suggested for other forms, that the pigment
of the shells is the assimilated pigment of the weeds and matches.
them accordingly. Dr. Sumner’s work is still in progress.

Professor W. C. Curtis of the University of Missouri demmonstiated
specimens showing the formation of segments in the tape worm
Crossobothrium laciniatum, which occurs in the sand shark. Usually
in tape worms new segments are formed near the anterior end, so that
the most anterior segment is the youngest and the most posterior is.
the oldest. This is true of C. laciniatum until about 35 segments
have been produced. Then, in the unsegmented region immediately
behind the head, a new series appears, of which the most anterior is
the oldest and the most posterior is the youngest; thus the body is
segmenting from both ends toward a middle portion. When 50
anterior segments and more than 400 posterior segments have been
formed the unsegmented middle portion is obliterated. After many
of the posterior segments have become mature and been detached,

660 THE AMERICAN NATURALIST [Vor. XLI

the neck region elongates, and a new set of segments may be produced,
consisting like the first set of an anterior and a posterior group of
segments. An account of this investigation was published in the
Biological Bulletin, 1906, vol. 11, p. 202-229

Professor R. Heymons, curator of the zoological museum in Berlin,
showed several larvae of a beetle of the genus Tenebrio which had
macroscopic rudiments of wings,—a pair on the mesothorax and
metathorax respectively. Since the larvae were not reared, the time
of the first appearance of the rudiments was not determined. It was
observed that small rudiments were shed in molting but that the
larger ones remained and finally expanded into the wings of the adult.
External wing rudiments on larvae of insects undergoing complete
metamorphosis are very rare. They have been observed in a few
other coleopterous larvae (Anthrenus varius) and are probably “in-
stances of premature development.”

Dr. F. E. Lutz of Cold Spring Harbor exhibited specimens of the

fly Drosophila, showing variations in the venation of its wings. ‘The
arrangement of the veins in wings of flies is usually quite constant.
A disturbance of the normal arrangement sometimes occurs in Dro-
sophila in nature, and by breeding selected individuals the disturbing
factor has been increased. It is inherited somewhat, but not abso-
lutely, in Mendelian fashion, and appears to be independent of environ-
ment.
Dr. S. Metalnikoff of the Imperial Academy of Science, St. Peters-
burg, showed sections illustrating the immunity of the moth Galleria
melonella to the bacilli of tuberculosis. An hour and a half after
injection, the bacilli were found within the blood corpuscles, and the
remains of bacilli were detected in the corpuscles five days after injection.
The bacilli become transformed into brown pigment. In the tissues
the bacilli were found encapsulated three days after injection; a
week later they were nearly all transformed into pigment. Finally
the brown pigment is absorbed by the pericardial cells.

Mr. J. H. Emerton of Boston exhibited a large and well mounted
collection of spiders, preserved in small vials of alcohol. The vials
containing the forms and sexes of one species were attached to a large
card, upon which were notes, drawings, and usually a photograph of
the web. Many of the notes and drawings have been published in
“The Common Spiders of the United States” (Ginn & Co., 1902),—
an attractive introduction to the study of these arachnids.

Dr. A. Petrunkevitch of Short Hills, New Jersey, demonstrated
the image-forming capacity of the lenses of spiders’ eyes. T

No. 490] NOTES AND LITERATURE 661

integument of a Lycosa nidicola was removed, carrying with it the
eight eyes. From the under surface of the preparation the retinae
and vitreous bodies were brushed away, leaving only the lenses in
position. The integument and lenses were mounted upon the stage
of a microscope, beneath which a postal card was placed upon the
table. With a % inch objective, eight magnified inverted images of
the McKinley portrait could be seen so distinctly that the surrounding
inscription was legible. The vision of the spider depends, however,
upon its retina and central nervous system. A preparation of the
retina was exhibited to show the coarseness of the rods. Since an
image which is so small that it falls upon only one rod would be per-
ceived as a point, Dr. Petrunkevitch has calculated the distance at
which a spider can possibly recognize another spider, and in other ways
has studied the nature of spiders’ vision.

Professor E. L. Mark of Harvard University exhibited live Am-
phioxus from Bermuda. They are nearly transparent creatures about
two inches in length, which remain buried in the coarse shell sand
with their anterior ends projecting slightly from the surface. If
disturbed they dart through the water with the greatest rapidity and
by a wriggling motion promptly disappear in the sand. It was noted
that about the British Isles and in the Mediterranean, Amphioxus
inhabits sand of a similarly coarse texture.

Professor H. F. Nachtrieb of the University of Minnesota demon-
strated several features of Polyodon, the spoon-bill sturgeon. The
“bill,” or flat anterior prolongation of the head, contains a central
cartilaginous axis and two layers of a network of bony spicules, the
spicules being easily separated in potash. Nerves extend along the
axis and radiate peripherally to the skin, and especially to the primitive
pores. These are clusters of pits surrounded by the patches of pigment
which give the bill a mottled appearance. Dissections of the bill and
sections of the pores and pigment cells were shown. The variations
in the lateral line were indicated in dissections and photographs, and
it was noted that the lateral line extended out on the dorsal lobe of the
tail nearly to its tip. It was formerly thought to end nearer the base
of the tail, as in other fishes. Professor Nachtrieb is studying further
the innervation of the lateral line.

Professor W. A. Locy of Northwestern University exhibited dis-
sections of Scyllium, Trygon, Raja, and Pristiurus to show the nervus
terminalis. This is a ganglionated nerve situated near the olfactory
nerve and passing to the olfactory region. It was discovered by
Professor Locy, and has been described in twenty-four genera of

662 THE AMERICAN NATURALIST [Vor. XLI

selachians and in lung fishes. It is considered to be a primitive nerve
belonging with the morphological tip of the body, which has been
replaced in the higher vertebrates by the development of adjacent
nerves.
Mr. C. W. Beebe of New York exhibited bird skins to show the
changes in color produced by exposing a bird to excessive humidity
during successive molts. The spots of a wood thrush become larger:
and darker. The breast of the white-throated sparrow becomes
slate-colored and the entire bird is abnormally dark. The feathers.
of the Inca dove become black-edged, and the bird passes through a
stage resembling the normal scaly dove to a dark condition which is
unknown in nature. It has been generally recognized that birds are
darkest in humid regions and palest in arid regions, thus forming
numerous subspecies.

Dr. J. A. Allen of New York showed a series of skulls of Sinaloa
deer collected within a radius of twenty-five miles. They presented
extraordinary variation in the premaxillary, maxillary and nasal bones,
which was not correlated with age or sex. A series of skulls of peccaries
showed variations in the orbital region believed to be due to parasitic
insect larvae. The skulls had not been examined when fresh so that
the presence of parasites was not determined. The bilateral symmetry
of the modifications of the orbit led some to question their parasitic

origin.

Professor B. G. Wilder of Cornell University exhibited photographs.
of human cerebral convolutions.

Embryology.— Dr. J. Warren of the Harvard Medical School.
showed a series of eighteen wax reconstructions of the pineal region
in Necturus, Lacerta, and Chrysemys. In all of these forms the-
paraphysis develops as a median outpocketing from the roof of the
brain, anterior to the pineal body. In the adult Necturus the para-
physis is a macroscopic gland-like organ, consisting of anastomosing‘
tubules between which are sinusoidal vessels derived from the sagittal
sinus. Dr. Warren’s models of the developing and adult paraphysis-
in Necturus have been described in the American Journal of Anatomy,
1905, vol. 5, pp. 1-28. His study of the paraphysis in reptilian
embryos is not yet complete. |

Professor R. J. Terry of Washington University, St. Louis, exhibited
a reconstruction of the pineal region in the toad fish, Opsanus (Ba-
trachus) tau. The general topography of this region corresponds.
closely with that of selachians (Squalus acanthias) but the paraphysis,
which is well developed in the latter, is indicated in Batrachus only by
a slight irregularity in the roof of the brain.

No. 490] NOTES AND LITERATURE 663

Professor Terry showed also a wax reconstruction of the skull of a
cat embryo of 23.1 mm. This model, which is beautifully constructed,
is of special interest in comparison with other similar models of chon-
drocrania,— Professor Gaupp’s model from Lacerta, Dr. Tonkoff’s
model from the chick, and Professor Hertwig’s model from a human
embryo of 8 cms.

Professor J. W. van Wijhe of the University of Groningen, Holland,
has perfected a method of making embryos transparent after a deep.
selective staining of their cartilages with methylene blue. The re-
sulting preparations show the cartilaginous skeleton as clearly as the
familiar transparent potash-glycerine preparations reveal the bony
skeleton. This new and valuable method was used in demonstrating
the development of the chondrocranium of birds, twenty specimens of
which were shown under two inch objectives.

Professor W. A. Locy showed the aortic arches in chick embryos
injected with ink while the heart still pulsated (a method devised, we
believe, by Professor Mall). The embryos were then dissected so that
the fourth and pulmonary arches were clearly shown, together with
the small subdivision of the latter, which is described as the fifth arch.
This fifth arch was the object of the demonstration. Its small size
as compared with the other arches was evident, yet in the chick it is
presumably a larger vessel than in mammals.

Professor S. H. Gage of Cornell University has obtained the glycogen
reaction to iodine in sections of the medullary plate of Amblystoma,
and also in nerve cells and in the deep layer of the retina in young
lampreys. These tissues, which were exhibited, are additional ex-
amples of the wide occurrence of glycogen, especially in embryonic
tissues, which Professor Gage has already demonstrated.

Professor Wilder showed the ““smallest known embryo of the man-
atee,” — a specimen approximately an inch and a half long.

Dr. J. L. Bremer of the Harvard Medical School exhibited recon-
structions of the brain, pharynx, and liver of a human embryo of 4.0
mm. The brain is of particular interest since the neuropore is still
widely open. In other human embryos of similar dimensions it is
nearly or quite closed. This indicates either considerable variability
in the time of closure, or that this embryo is abnormal. It presents,
however, no other evidence of abnormality so far as is known.

Dr. F. W. Thyng of the Harvard Medical School exhibited wax
reconstructions of the pharynx, stomach, pancreas, and cervical region
of a human embryo of 13.6 mm. The jugular lymph sacs were
modelled, probably for the first time in a human embryo. They

664 THE AMERICAN NATURALIST [Vor. XLI

correspond essentially with the jugular sacs of the pig, rabbit, and cat.
Each sac apparently communicates with the veins by a remarkably
small opening which was not shown in the model. Dr. Thyng ex-
hibited also models of the dorsal and the ventral pancreas in the
rabbit, cat, and pig, one model of the latter including a well developed
accessory pancreas

Professor T. G. Lee of the University of Minnesota was the first to
study the implantation and early development of the Sciuromorpha,
the suborder of rodents which includes squirrels, chipmunks, prairie
dogs, and gophers. Representatives of the other three suborders of
rodents have been studied by other investigators. The Sciuromorpha
have a characteristic early development. Before the placenta has
formed, the vesicle acquires a temporary uterine attachment by means
of a knob-like proliferation of cells on its ventral surface. Geomys
bursarius, the pocket gopher, which belongs to a distinct family,
perforates the epithelium of the uterus and develops in the uterine
connective tissue. The aperture in the epithelium does not become
closed as in the guinea pig, nor plugged as in man, so that Geomys
is said to differ “in certain respects from any other mammal yet de-
scribed.” It may be noted that in the syncytial covering of the vesicles
of all the Sciuromorpha the cells divide only by amitosis. Professor
Lee exhibited a few of the interesting sections from his extensive series.

Dr. M. Herzog of Chicago has studied a very young human embryo
in process of implantation. The sections exhibited were similar to
those figured by Dr. Peters in 1899 as “the earliest known stage of
human placentation.” Because of their good condition and the rarity
of such early stages, they are of great interest. The material is un-
questionably normal, since it was obtained from the autopsy upon an
individual who was accidentally and almost instantly killed upon the
street; for such material it is unusually well preserved. Dr. Herzog
has completed the study of the chorion and will soon finish that of the
embryonic area and its appendages. The results will probably be
published in the American Journal of Anatomy.

Cytology.— Dr. F. E. Botezat of the University of Czernowitz,
Austria, was the first to demonstrate the presence of taste buds in
birds. They were previously known in all other classes of vertebrates.
His preparations of taste buds in the hard and the soft palate of Passer
domesticus were shown by Dr. Gudernatsch. Preparations of Vater-
Pacinian and Merkel’s corpuscles from the tongue of the sparrow
were also shown, demonstrating the neurofibrillar net and the end
plates

No. 490] NOTES AND LITERATURE 665

Dr. J. F. Gudernatsch of the University of Czernowitz exhibited
sections of taste buds in the dugong. In the back part of the tongue
there are certain large glands, the ducts of which expand into cup-
shaped cavities near their outlets. In one of these cups there may be
two or three elevations pitted with taste buds. The taste buds also
occur occasionally along the deeper portion of the ducts. ‘There are
no vallate papillae, and no taste buds are found in connection with the
small form of lingual glands. In the three orders of aquatic mammals
taste buds are either absent, as in Cetacea, or they are not well devel-
oped, as in the Pinnipedia and Sirenia.

Professor S. Apäthy of the University at Klausenburg, Hungary,
showed three series of cytological preparations, and demonstrated
some ingenious devices used in making them. The perfection of his
technique, as well as the nature of the specimens, made this one of the
most notable exhibits. The first series of slides was produced by an
unintentional experiment on living muscle nuclei of the leech Pontob-
della, and showed important features of nuclear structure. The
experiment consisted in injecting corrosive sublimate between the
muscle layers of the intestine, instead of into the intestinal cavity, as
was intended. The introduction of the cannula caused the nuclei
to be compressed at one end and stretched at the other; in this con-
dition they were immediately fixed by the reagent. In the normal
nuclei the chromatin is arranged in coarse masses or knots at the
angles of the nuclear network. In the stretched nuclei the network
gave place to a series of parallel fibrils without cross connections,
suggesting those of mitosis, and indicating that the network of the
resting nucleus may consist of bundles of interlacing but unbranched
fibrils. At the same time the chromatin knots were shown to be
collections of granules rather than solid masses, for they had appar-
ently disappeared by becoming evenly distributed along the fibrils.
No nuclear membrane was seen, and Professor Apathy believes that
with few exceptions, the better preserved the specimen, the less defi-
nite is the nuclear membrane. In smears, nuclei may become dis-
torted somewhat like those exhibited.

The second series of preparations dealt with Krause’s membrane,
the narrow dark line which bisects the light band of striated muscle
fibers. Professor Prenant at one time believed that Krause’s mem-
brane occurred only in the muscles of arthropods and vertebrates;
later be found it in Pecten and Sagitta but failed, after repeat
attempts, to detect it in Salpa. Professor Apathy demonstrated it
very clearly in Salpa maxima, and showed it in the coelenterate

666 THE AMERICAN NATURALIST [Vor. XLI
Carmarina hastata. He believes that it occurs in all striated muscle

ers.

The third series of preparations was of neurofibrillae, which were
shown with astonishing clearness. The coarse fibrils of the invertebrate
nerve cells (from Pontobdella and Lumbricus), the finer fibrils of the
young dog, and the much finer fibrils of the adult suggest that a sub-
division of the fibrils accompanies the perfection of the nervous system.
The presence of neurofibrils is, for Professor Apáthy, the essential
feature of a nerve cell. All cells have the property of contraction and
of conduction, but they are not muscle cells unless they possess myo-
fibrillae, nor nerve cells unless they contain neurofibrillae. It remains
to be determined whether the development of neurofibrillae accom-
panies the outgrowth of processes from the neuroblasts.

Professor R. G. Harrison of Yale University showed drawings of
the nerve cell processes sent out by detached cells of the spinal cord
ofa tadpole. The portion removed was examined in lymph, into which
the processes grew, each having at its distal end a group of slender,
radiating, amoeboid branches. At times these changed their shape
more rapidly than could be drawn. Sections showing similar ter-
minal branches were exhibited. In embryos from which the neural
crest had been removed, nerves without sheath cells were produced,
thus proving that nerve fibers may grow without the participation of
sheath cells, and that the latter are derived chiefly from the neural
crest.

Professor H. V. Neal of Knox College, Ilinois, showed preparations
of embryos of Squalus, demonstrating the outgrowth of processes
from the neuroblasts. These processes could be traced for some
distance through the surrounding tissue which took no part in the
formation of the nerve fiber. 'The specimens showed indications of
neurofibrils at an early stage.

Professor A. Maximow of the Imperial Medical Academy of St.
Petersburg exhibited preparations of rabbit embryos to show the
formation of the blood corpuscles. In the area vasculosa of a rabbit
of 8} days, only one form of corpuscle occurs; it is known as the
primitive blood cell, and gives rise both to lymphocytes and to primary
erythrocytes. These two forms of corpuscles are all that occur in
the wall of the yolk sac at 9% days. The primary erythrocytes are
large cells derived from those which constitute the blood islands.
Their formation soon ceases, and they gradually disappear from the
circulating blood, in which only few remain at 20 days. Thus they
-are a purely embryonic type of corpuscle. The lymphocytes likewise

No. 490] NOTES AND LITERATURE 667

first appear in the yolk sac, but later they are formed from the endothe-
lium of blood vessels within the embryo. A section of the aorta of a
rabbit of 10 days and 5 hours showed a rounded mass of lymphocytes
projecting into its lumen and still connected with its endothelium.
The lymphocytes give rise to other lymphocytes and to the permanent
erythrocytes. The latter are smaller than the primary erythrocytes;
they are formed from lymphocytes throughout life, and ultimately,
by the extrusion of their nuclei, they become the red corpuscles. In
the vessels of the yolk sac at 12 days there are three kinds of corpuscles,
namely primary erythrocytes, lymphocytes, and permanent erythro-
cytes. In the mesenchyma around the medullary tube of the embryo
of 12 days, two small wandering cells were shown. These cells arise
in the mesenchyma; in the bone marrow they come from cells like
lymphocytes in the periosteal mesenchyma. The giant cells of the
marrow were classed with the lymphocyte series.

In addition to these preparations Professor Maximow showed two
others of much interest. One of these was a section of the thymus
of a rabbit embryo of 15 days. The solid epithelial masses were
being invaded by lymphocytes; the epithelial cells were not becoming
deceptively similar to lymphocytes as has recently been stated. The
other preparation was from a rabbit’s kidney which had become
atrophic, following the ligation of the renal vessels. In the kidney
calcification and bone formation had occurred, and a well defined
macroscopic area of bone marrow had developed. The remarkable
development of bone marrow in the kidney always occurred in rabbits,
but never in other animals similarly treated.

Mme. W. Dantchakoff of St. Petersburg demonstrated the forma-
tion of the blood corpuscles in the chick. A section from an embryo
incubated 68 hours, showed cells similar to lymphocytes both within
and outside the vessels overlying the yolk. The endothelium seemed
to have formed among cells of one sort; those inside the vessels become
lymphocytes and red corpuscles, and those outside become poly-
morphonuclear leucocytes. The differentiation of the cells was shown
in a specimen of 104 hours incubation, in which eosinophilic granules
were clearly seen in the cells outside of the vessel walls. A distinction
between primary and permanent erythrocytes was not established by
Dr. Dantchakoff in the chick. Other features, including the pro-
liferation of endothelial cells of the aorta (shown in a specimen of 72
hours incubation), agreed essentially with Professor Maximow’s
demonstration of the rabbit.

Miss K. Bonnevie, of Christiana, Norway, exhibited preparations

668 THE AMERICAN NATURALIST [Vor. XLI

illustrating the nature of heterotypical mitosis and showing that its
significance in reduction divisions has been overestimated. Hetero-
typical chromosomes were demonstrated in the first cleavage division
of Nereis. In the second maturation division of Amphiuma and in the
first cleavage of Thalassema, cross-shaped chromosomes were shown.
Cross-shaped chromosomes or tetrads are therefore not limited in Tha-
lassema to the first reduction division. The tetrad shape was shown
in some of the chromosomes of Nereis in metaphase fifteen hours after
fertilization. A longitudinal splitting of the daughter chromosomes
was shown in a cleavage mitosis of Nereis and also in its second matu-
ration mitosis. Other features of chromosome structure which were
demonstrated, include the spiral coiling of chromosomes in Amphiuma
and Ascaris, and a spiral chromatic thread wound around the surface
of each chromosome in the root tip of Allium. The relation of chro-
mosomes to the resting nucleus was illustrated, and new chromosomes
were said to arise within the disseminated chromatic material of the
old ones.

Miss A. M. Lutz of Cold Spring Harbor showed sections of the root
tips of Oenothera lamarckiana, its mutants and hybrids, to demon-
strate the variations in the number of somatic chromosomes. The
material appears very favorable for the counting of chromosomes,
and it was remarkably well preserved and clearly stained. Never-
theless the question of one chromosome more or less in a given count
is sometimes very difficult to determine. To the counts which have
been made and were demonstrated by Miss Lutz,. those recently
published by R. R. Gates from somatic cells of the flowers may be

ed; their counts are as follows,— Oenothera lamarckiana, pure
bred, 14 chromosomes (14, Gates); O. nanella, 14 in some plants, in
others probably 15; O. rubrinervis, open pollinated, 14; O. lata,
14 in one plant, 15 in another (14 with “no indication whatever that
the number is ever higher,” Gates); O. gigas, 28 with a suggestion
of a 29th in several instances, but 29 were never demonstrated in pure
bred tissue; O. lata (hybrid) 2 X O. gigas (pure) Q' showed 21 in
one plant, 22 or 23 in another, and 28 or 29 in a third. In the last
case, if each parent supplied one half of its normal number of chromo-
somes, 21 or 22 should occur in the hybrid and this was observed in
two of the plants. In hybrids produced by pollinating O. lata with O.
lamarckiana, Gates has found 20 or 21 chromosomes. From these
interesting studies which are still in progress it appears that O. lamarck-
tana and most of its mutants usually possess 14 somatic chromosomes;
that O gigas has double that number, suggesting a variety like Ascaris

No. 490] NOTES AND LITERATURE 669

megalocephala bivalens; and that in the hybrids there may be an
extraordinary disturbance in the number of chromosomes, the laws
and the explanation for which are not apparent.

Methods and Publications. — Dr. R. M. Yerkes of Harvard Uni-
versity exhibited apparatus for testing color vision and the delicacy
of visual discrimination in mice. Similar boxes are illuminated
either by photometered lamps of different intensity or by colored
lights. Over the floors of the boxes are wires for an interrupted
electric current whereby the animal receives slight shocks when it
enters the wrong box. The value of the apparatus is in its complete
elimination of sensations other than those which are being tested.
Under the title “The dancing mouse; a study in animal behavior,”
the MacMillan Company has in press a collected account of Dr.
Yerkes’ investigations of the mental life of a lower mammal.

Mrs. S. P. Gage of Ithaca, New York, showed her method of making
models from sheets of blotting paper instead of plates of wax. The
outline of the section is drawn upon the paper and may be cut out by
the needle punctures from an unthreaded sewing machine. The
blotting paper is then soaked in melted paraffin, and the smoothing
of the surface, after the model has been put together, is done with
paraffin. Pins are inserted, as in wax models, for stability. The
resulting model is light and less fragile than those made of wax; it is
not liable to change its shape in warm weather, or to crack by the
expansion of metal supports.

Professor G. A. Drew of the University of Maine showed a method
of making a series of anatomical drawings for reproduction by the
zine process. That part of the animal which is to appear in several
drawings is drawn first, and photographed upon renege en
The figure is then completed by using pen and ink upon the phot
Thus the organs may be drawn and photographed, and four igir
of the nerves, arteries, veins, and lymphatics respectively may be built
up upon this background. Professor Drew used the method in making
his drawings of Pecten.

Dr. H. H. Field of Zürich exhibited a complete series of the card
index to biological literature, issued by the Concilium Bibliographicum.
It was shown properly arranged in a library cabinet, and its system
was fully explained.

The Department of Comparative Anatomy at the Harvard Medical
School exhibited a portion of its collection of 1188 series of vertebrate
embryos, sectioned by the paraffin method. This collection may be
used at the school by any visiting scientist.

670 THE AMERICAN NATURALIST [Vor. XLI

The Secretary of the Universidad Nacional de Buenos Aires sent to
the congress numerous photographs of its zoological gardens.

Professor W. B. Scott of Princeton University exhibited Vols. 1, 4, 5,
and 8 of the Reports of the Princeton University Expeditions to Pata-
gonia. These volumes, which are all that are now published, are
devoted to the general narrative, botany, and paleontology. The
entire work is expected to require fifteen volumes, and the expense of
publication is met by the “J. P. Morgan Publication Fund.” The
narrative is said to compare in interest with Darwin’s account of the
voyage of the Beagle, and it may be printed in brief form for more
general distribution.

r. H. Przibram of the University of Vienna showed copies of his
Einleitung in die experimentelle Morphologie der Tiere published by
F. Deuticke, Leipzig und Wien, 1904, and the Experimental-Zoologie,
1, Embryogenese, published by the same firm in 1907.

D . C. Piepers sent to the congress a copy of his book Noch
einmal, Mimiery, Selektion, Darwinismus, published by E. J. Brill,
Leiden, 1907. His earlier publication upon the same subject contained
the theses which he presented to the Fifth International Zoological
Congress, at Berlin, 1901.

Variation and Mendelism.— Professor W. Bateson of the University
of Cambridge, England, whose address on “Facts limiting the theory
of heredity” was of unusual interest, showed the great variation
occurring in certain moths, and the results of cross-breeding in pigeons
poultry, and corn. Since this exhibit was not unpacked until the alee
of the congress, it could not receive the attention which it merited.

Professor T. Dwight of the Harvard Medical School invited the
congress to inspect his very fine collection of variations in human
bones, displayed in the Warren Museum.

Professor W. E. Castle of Harvard University exhibited live rabbits,
guinea pigs, and rats, showing in a most effective way several forms
of inheritance. The animals were exhibited in Cambridge, where
breeding experiments are still being conducted on an extensive scale.
The first series showed color varieties of the domesticated rabbit.
The wild gray rabbit bears three independent heredity units,— one
for black, one for yellow, and a third for barring (which causes the
black and yellow to be disposed in bands upon the individual hairs).
The various known color varieties result from the loss or modification
of one or more of these three units. The inheritance is Mendelian.
The unit composition of each known color variety was explained and.
in some cases demonstrated by the results of breeding experiments.

No. 490] NOTES AND LITERATURE 671

It was shown, for example, that in the absence of the barring factor,
the black and yellow factors combine to produce three color varieties,—
namely pure black, if the black factor is in excess; sooty yellow, if the
yellow is in excess; and blue, if the black factor is modified and dilute
and the yellow is scanty. Albino animals possess the color factors,
but lack an activating substance necessary for pigmentation ; the
albino form may occur in any of the color varieties.

The second series showed color varieties of the guinea pig. As in
the rabbit, the wild coat contains black, yellow, and barring factors
which are inherited as independent units. There is also a separable
brown factor which in the absence of the black and barring elements
produces chocolate colored animals.

The third of the series exhibited was from a race of guinea pigs
having four-toed hind feet. The hind feet of the guinea pig, agouti,
and capybara are normally three-toed; those of rabbits are four-toed
and of mice five-toed. By unremitting selection from the progeny
of a single four-toed ‘sport,’ through five generations, a corresponding
race of guinea pigs has become established. The effects of selection
upon the color pattern (spots) of guinea pigs and rats were demon-
strated, and the last series showed the blended inheritance of ear-
length in rabbits. The offspring of a long-eared and a short-eared
rabbit have ears of intermediate length, and breed true.

FeR L

ZOOLOGY

The Families and Genera of Bats.— One of the most important
recent contributions to the taxonomy of the Chiroptera is “The
Families and Genera of Bats,” by Gerrit S. Miller, Jr., forming Bulletin
57 of the United States National Museum. It is a volume of about
300 pages, with 14 plates and 49 text cuts, illustrating the dentition,
cranial and skeletal characters of this diversified order. The first
12 pages of the introduction are devoted to the technical history of
the group, from Linnaeus (1758) to Weber (1904). This is followed
by 30 pages on the anatomy of bats, relating especially to the structure
of the wing, the shoulder girdle, and teeth, and by a systematic review
of the genera and higher groups. The order Chiroptera is divided
into the usually recognized two suborders, Megachiroptera and
Microchiroptera, the former consisting of the single family Pteropidae,

672 THE AMERICAN NATURALIST [Vor. XLI

or Fruit Bats, with 4 subfamilies and 30 genera; the latter containing
all the others, which are here distributed among 16 families and 13
subfamilies.

This important monograph is based on the material contained in
the U. S. National Museum and other American museums, supple-
mented by the examination of that contained in the principal museums
of Europe, with the result that all but three of the 173 genera here
recognized have passed through the hands of the author. The number
of “forms” of Chiroptera at present recognized is stated to be about
900; ‘‘a number probably representing considerably less than half
of what will eventually be known.” The designation “forms”
probably includes subspecies as well as species.

The systematic part (pp. 43-261) gives the characters of all the
higher groups, from order to genus, with the geographic distribution
and probable number of forms of each, and diagnostic keys for the
suborders, families, subfamilies and genera. The divisions adopted,
from families down to genera, are greatly in excess of those recog-
nized by any previous author, but they appear to be all natural groups,
subject of course to a different valuation by different authors, according
to their points of view. No subgenera are recognized; of the 173
genera characterized, 19 have been proposed by Mr. Miller, only two
of which, however, are here first published. For each of the genera
a type species is designated, the probable number of species is stated,
and those examined by the author are enumerated. The full synonymy
is given, not only of the genera but of all the higher groups — a feature
of much importance.

In this monograph, the outcome of years of careful investigation,
Mr. Miller’s usual thoroughness and critical attention to minute details
of structure are conspicuously apparent, with the result that naturalists
are now provided with an excellent guide through the labyrinths of
this large and difficult order of mammals. The text cuts and the first
ten plates furnish excellent illustrations, all original, of the dentition
and cranial characters of about one third of the genera, thus supple-
menting in a most important way those contained in previous works,
to which, however, direct references are unfortunately wanting. The
last four plates illustrate the principal parts of the skeleton in four
diverse types — Rhinopoma microphyllum, Diclidurus virgo, Noctilio
leporinus, Molossus pretiosus.

J. A. A.

Birds of North and Middle America.— Mr. Robert Ridgway’s
“Birds of North and Middle America” is the most important syste-

No. 490] NOTES AND LITERATURE 673

matic work ever undertaken relating to American ornithology. The
original estimate for the work was a series of eight volumes, in octavo,
of about 1000 pages each. Its official designation is “Bulletin of the
United States National Museum, No. 50.” The first volume appeared
near the close of the year 1901, and included the single family Fringil-
lidae; the second was published in 1902, and covers the four families
Tanagridae, Icteridae, Coerebidae, and Mniotiltidae; the third bears
date 1904, and includes 15 of the remaining families of oscinine
Passeres; the fourth, published in July of the present year, includes
the remaining six families of the Oscines and the first four families
of the Mesomyodi. These families are: Turdidae, Zeledoniidae,
Mimidae, Sturnidae, Ploceidae, Alaudidae of the Oscines; Oxyrun-
cidae, Tyrannidae, Pipridae, Cotingidae, of the Mesomyodi. These
four volumes include “1675 species and subspecies, or somewhat
more than half the total number of North and Middle American birds,”
or those found north of the Isthmus of Panama, which forms approxi-
mately the southern boundary of the area treated. The preparation |
of Part V is well advanced.

The treatment is entirely technical; definitions are given of all the
higher groups, with keys to the minor divisions, and in the case of
genera to the species and subspecies. The latter are described in
detail, with a concise statement of their geographic ranges, followed
by full (often annotated) bibliographic tables, which often frequently
occupy the larger part of the text. But there is nothing relating to
their life histories beyond, in some instance, a brief reference under
the generic headings to the nest and eggs. The work is, however,
invaluable to the systematist, and will ever remain a monument to
the industry and painstaking accuracy of its author, and it will be
long before its usefulness will be superceded by any subsequent work.

J. A. A.

BOTANY

Floral Ecology.— In the writings of Darwin and his contemporaries
the structure and environmental relations of flowers hold a prominent
place. This is only natural when we remember that the Darwinian
theory is essentially a theory of adaptation. For a considerable time
it seemed that interest in floral adaptations was lagging, but this kind
of work is again being quite generally taken up. Possibly a reason for

674 THE AMERICAN NATURALIST [Vor. XLI

the renewal of interest is to be seen in the completion of Knuth’s
Handbuch, and certainly the popularity of this kind of investigation
is attested by the promise of a complete translation of this large work
from the Oxford press.

It is not surprising that the Italians, who until very recently have
had Delpino — a pioneer in this field — among them, should show
especial activity in studies of floral ecology. The Orto Botanico della
R. Università di Napoli is now commencing the republication (Bull.
Orto Bot. R. Univ. Napoli 2:3-65. 1904) of a portion of Delpino’s
` Ulteriori Osservazioni which first appeared in 1873-74. This is
unquestionably one of the most important treatises on floral ecology
and its republication will be welcomed by many to whom the original
is not accessible. Delpino’s elaborate classification was proposed at
a time when there was not a broad basis of observation but the con-
ception is certainly worthy of the most careful consideration and one
of the chief problems before future workers in this field is to determine
in how far floral adaptations may be thrown into real categories such
as Delpino suggests. This is to be one of the crucial tests of adapta-
tion which we need at the present stage of development of the evolution
theory.

Before passing from the work of Delpino, it may not be out of place
to mention that an appreciation of the man and a bibliography of his
writings has just been published by Briosi (Atti Ist. Bot. Univ. Pavia
II. 10: vi-xxi. 1907). Over one hundred and twenty titles are given,
a large proportion of them being on various phases of vegetable ecology.

The fifth memoir of Scotti’s series on the floral biology of the “ Per-
sonatae” may be mentioned as another large undertaking. This
number (Annali di Botanici 5: 101-227. 1907) comprises the families
Solanaceae, Scrophulariaceae, Bignoniaceae, Martyniaceae, Peda-
liaceae, Orobanchaceae, Gesneriaceae, Lentibulariaceae, Globulari-
aceae and Acanthaceae. The work is largely a review of the literature
on the floral ecology of these groups but it serves a useful purpose
in bringing together in one place a detailed discussion of a large body
of widely scattered observations.

Mattei (Bull. Orto Bot. R. Univ. Napoli 2:115-117. 1904) gives
lists of visitors of Dracunculus vulgaris. Nicotra (Bull. Soc. Bot.
Ital. 1906: 128-131) discusses the floral ecology of Urginea, Agave
and Smilax. Graenicher has published two papers (Bull. Nat. Hist.
Soc. Wise. n. s. 5: 15-45, 84-95. 1907) on the pollination of Wisconsin
flowers. In these the families Melanthaceae, Liliaceae, Convallaria-
ceae, Saxifragaceae, and Grossulariaceae are considered. The obser-

No. 490] NOTES AND LITERATURE 675

vations are very similar to those made by Müller and MacLeod in
Europe and by Robertson in our own country and it is to be hoped
that the author will continue the work with vigor.

Burck has been engaged in studies of anther dehiscence and con-
cludes (Proc. Kon. Akad. Amsterdam 1906: 390-396, and Rev. Gén.
Bot. 19: 104-111. 1905) that the opening of the anther is effected by
the withdrawal of water from the anther by sugar contained in the
filament. This permits the dehiscence of the anther in an atmos-
phere saturated with moisture.

Harms (Ber. Deutch. Bot. Ges. 25: 165-176. 1907) has investigated
cleistogamy in three species of the genus Clitoria. The studies were
made on herbarium material. The author concludes that we are
here dealing with a real cleistogamy in the sense in which Göbel uses
the term. The characteristics of the cleistogamous flowers are the
small size of the calyx, the absence of the corolla and a more or less
pronounced reduction in the androecium.

Tuzson (Bot. Jahrb. 40: 1-14. 1907) has observed cleistogamy i in
Robinia pseudacacia. Two trees were found together in the same
row of old trees along a street and he thinks it probable that one was
derived from the other by vegetative reproduction. The individuals
were about thirty to forty years old and have been under observation
since 1902; since then they have flowered in 1904 and 1906. Fertili-
zation occurs exceedingly rarely. In these forms cleistogamy must be
considered a highly disadvantageous characteristic which originated
discontinuously and which would be eliminated in the struggle for
existence. The author does not agree with all of Göbel’s views on
cleistogamy but insists on the causal rather than the teleological
attitude in the investigation of the problem.

Dop (Bull. Soc. Bot. Fr. IV. 7: 258-260. 1907) again discusses
the mechanism of movement in the stamens of the Berberidaceae.

Fritsch (Verh. K. K. Zool.-Bot. Ges. Wien 56: 135-160. 1906)
publishes list of insect visitors for about 150 species of the flora of
Steiermark. The observations were made in 1904.

J. ARTHUR Harris.

PUBLICATIONS RECEIVED

From August 1 to September 1, regular exchanges are not included
The year of publication, when not otherwise noted is 19

Hovc#, T., ann Sepewick, W. T. Elements of Physiology. Boston, Ginn
& Co., 1907. 12mo, 321 pp., illus. $1.25— Newman, H. Labora
Exercises in Elementary Physics. Boston, Ginn & Co., 1907. In four parts.

50 per dozen.

Auten, W. F. Distribution of the subcutaneous vessels in the head region
of the Ganoids, Polyodon and Lepisosteus. Proc. Washington Acad. Sci
vol. 9, pp. 79-158, pls. 1-15.— Coox, O. F. Mendelism and other methods
of descent. Proc. Washington Acad. Sci., vol. 9, pp. 189-240.— Cook, O. F.
Origin and evolution of angiosperms through apospory. Proc. Washington
Acad. Sci., vol. 9, pp. 159-178.— Dati, W. H. Linnaeus as a zoologist.
Proc. Washington Acad. Sci., vol. 9, pp. 272-274.— Davenport, C. B. Her-
edity and Mendel’s law. Prod. Washington Acad. Sci., vol. 9, pp. 179-188.—
Feit, E. P. White marked tussock moth and elm ied beetle. N. Y. State
ee bull. 109, 31 pp., 8 pls.— Greene, E. L. Linnaean memorial address.
Proc. Washington Acad. Sci., vol..9, pp. 241-271.— Mann, A. Report on
the diatoms of the Albatross voyages in the Pacific Ocean, 1888-1904. Cont.
U. S. Nat. Herbarium, vol. 9, pt. 5, pp. 221-442, pls. 44-54.— Mc Barn, J. W.
The experimental data of the quantitative measurements of electrolytic
migration. Proc. Washington Acad. Sci., vol. 9, pp. 1-78.— Merk, S. E.
peerage of the fishes of the Great Lakos ip Nicaragua. Field Columbian

zool. ser., vol. 7, no. 4, pp. 97-132.— MERRILL, G. P. Catalogue of the
a ae figured specimens of fossils, minerals, rocks, and ores. f
Nat. Mus., no. 53, pt. 2, 370 pp.— MILLER, G. S. The families and genera
of bats. U. S. Nat. Mus., bull. 57, 282 pp., 14 pls.— Rınaway, R. The
birds of North and Middle America, part IV. Bull. U. S. Nat. Mus., no. 50,
973 pp., 34 pls.— STEJNEGER, L. Herpetology of Japan and adjacent terri-
tory. U. S. Nat. Mus., bull. 58, 577 pp., 35 pls., 409 figs.— WHEELER, H.

and unlimed land with several varieties of plants. R. I. Agric. Exp. Sta., bull.
118, pp. 55-86.— WHEELER, H. J., HARTWELL, B. L., MORGAN, J. F., AND
PURRINGToN, W. F. PE of commercial feeding-stuffs. BE: Agric.
Exp. a sen 119, pp. 89-107.

F THE QUEENSLAND MUSEUM, no. 7.— New YORK STATE MUSEUM.
range ON INJURIOUS AND OTHER INSECTS.— PROCEEDINGS OF THE LINNEAN
Socrery or New Sours WALES ror 1907, part I.— ABSTRACT OF PROCEED-
INGS OF THE LINNEAN Socrery or New SouTH WALES, June 26th, 1907.

(No. 489 was issued Sept. 26, 1907).

676

THE JOURNAL OF EXPERIMENTAL ZOOLOGY

EDITED BY
WILLIAM K. Bro KS HERBERT S, zum zn =; tat
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Ross G. Harrison, Managing Editor

CONTENTS OF VOLUME IV

NO. 1, FEBRUARY, 1907
Abnormal Development of Toad eig Fertilized by Spermatozoa

Exposed to Mos Roentgen Ra Charles R. Bardeen

An a an en Study of Sarcophagdae with Re-
o Lake Debri William B. Herms
scence as the Resit of Conje igati $ į . Sara White Cull
pectin en! in Thalmessema telini : > . George Lefevre
Concerning the Theory of Tropisms Jacques Loeb
The Mechanism of the Galvanotropic Orientation in Volvox Frank W. Bancroft

NO. 2, MAY, 1907

The sg vanes ma External Fac Chemical and ern on the
lopment of Fundu wi Hetercentas 3 4 Charles R. Stockar

The Ba rgy of Batin tation % _ Edw ard G. Spau Gen
Movement and Problem Solving in i Ophuria Brevi ispin Otto C. Glaser
The Occurrence of a Sport in Lina EN and its bena ior in

Heredity . Isabel McCracken
Experiments in Transplanting Limbs and Their Bearing upon the

Problems of the Dereon of Nerve . Ross G. Harrison
Factors in = g Re Hyaroid, Eudendrium

ramosum . i ‘ A. J. Goldfarb

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THE
AMERICAN NATURALIST

Vor. XLI November, 1907 No. 491

RESPONSE OF TOADS TO SOUND STIMULI
S. A. COURTIS

THE sense of hearing in frogs has been critically studied by Dr.
R. M. Yerkes. He tested the effect of a great variety of sounds
upon frogs in their natural habitat and states that “To no sound
have I ever seen a motor response given.” ‘The sounds ranged in
pitch from a low tone in imitation of the bull frog’s croak to a shrill
whistle, and in loudness from the fali of a pebble to the report of a
pistol. He says further,— “One can approach to within a few
feet of a green frog or bull frog and make all sorts of noises without
causing it to give any signs of uneasiness. Just as soon, however,
as a quick movement is made by the observer the animal jumps.
I have repeatedly crept up very close to frogs keeping myself
screened from them by bushes or trees and made various sounds,
but have never succeeded in scaring an animal into a motor response
so long as I was invisible. Apparently they depend almost entirely
upon vision for the avoidance of dangers... Many observers have
told me that frogs could hear the human voice and that slight
sounds made by a passer-by would cause them to stop croaking.
In no case, however, have such observers been able to assert that
the animals were unaffected by visual stimuli at the same time... .
There is, however, conclusive evidence that the animals hear one
another, and the probability is very great that they hear a wide
range of sounds to which they give no motor reactions.”

In a later study,’ Dr. Yerkes found experimentally that although

1 Yerkes, R. M. The instincts, habits and reactions of the frog. Harvard
Psychological Studies, 1903, vol. 1, pp. 629-630

* Yerkes, R. M. The sense of hearing in frogs. Journ. of Comp. Neur.,
1905, vol. 15, pp. 279-304.

677

678 THE AMERICAN NATURALIST [Vor. XLI

frogs gave no motor reaction to various sounds, their response to
tactile stimuli accompanied by these sounds was greater than to
the tactile stimuli alone. He concludes that sounds varying in
pitch from those of 50 to 10,000 vibrations affect the frog. In
nature, “the sense of hearing apparently serves rather as a warning
sense which modifies reactions to other simultaneous or succeeding
stimuli than as a control for definite auditory motor reactions.”
In the spring months he found that sounds had a marked influence
upon both males and females, but during the winter there was “a
much diminished sensitiveness to auditory stimuli in both sexes,
but especially in the male.”

The description of Dr. Yerkes’ experiments given by Professor
Kirkpatrick, at Chicago University, greatly interested the writer.
Having once kept a frog through the winter and often succeeded
in making him croak by imitating his call, it seemed probable that
motor responses followed certain sounds. On July 1st I had an
opportunity of testing the response of toads to the mating call.

In the course of a walk along the shore of Lake Michigan, we
came to a shallow pool in the sand just behind a breakwater. ‘The
pool was three or four inches deep, six or eight feet wide, and
several hundred feet long. In one part of this we found nine pairs
of toads, the females laying eggs in long strings upon the bottom
of the pool. There were also two or three unpaired males. ‘The
males were much smaller than the females and much more active.
The females were of great size, their sides being puffed out with
eggs. On the sand they were too heavy to hop, and so walked on
all fours like a dog. One female had been seized by two males. —
We separated her from both, and placed them about ten feet apart.
One of the males soon uttered a shrill, trilling note,— a penetrating
sound that was well sustained for fifteen or twenty seconds. In
doing so he puffed out the skin of his under jaw into a dark gray
translucent hemisphere of large size, as is the well known habit of
toads. The female immediately swam towards him and the two
were soon mated.

After this preliminary experiment we made three others. In
the first we separated four couples, putting the females on a little
island in the middle of the pool and the males into the water about
ten feet away. In four or five minutes they were all mated in

No. 491] RESPONSE OF TOADS TO SOUND 679

response to the calls from the males. ‘The second time, we separated
all the couples in sight, nine I think, and placed the females as.
before, the males a little farther away. ‘The third time, we sepa-
rated them all, but put the males on the island where the females.
had been and carried the females at least thirty feet away towards
the side where the males had been. In fifteen minutes, in both
cases, every female was taken. In the last case one that had at
first hopped ten feet in the wrong direction turned completely
around in her tracks at the call, and at the next call, started towards.
the male.

There were many interesting things observed during the experi-
ments. For one thing the males as well as the females responded
to the call, which they could locate very accurately. At the begin-
ning of an experiment, as soon as the males were put down they
began to scatter in all directions, swimming excitedly about, now
this way, now that. When there were twelve unattached males
within four or five feet, a call by one of their number would bring
the others from all directions, and in a second or two there would
be one or two heaps of clasping, fighting, kicking males, squealing
like mice, and rolling over and over. Not all the males gave the
call — not over four or five individuals—and these were, as far as.
I could judge, the most sluggish among them. In giving the call
there was quite a marked tendency to climb out of the water up.
on to a scantling on the inner side of the breakwater. The toads.
were then two inches above the water.

Motion was evidently the stimulus that started the clasping reflex.
This was clearly shown on the sand where I saw one male overtake,
clasp, and release another male four or five times in succession
before the second succeeded in escaping. Each time the motion
of the toad in front would start the one behind. A male would
release a male almost instantly, but I did not see a single case of a
female clasped and released. How they knew the female I could
not tell, but they evidently did not recognize one until they had
clasped her. The clasping action, as already stated, seemed en-
tirely automatic.

Several of the solitary males that were sounding the call watched
the approach of the females, cocking their heads on one side and
moving their bodies so as to look down, and if the swimming

680 THE AMERICAN NATURALIST [Vor. XLI

impulse of the female had stopped so that she was carried to the
male by her inertia, he would make no response until she began
again to swim. Provided that the female is motionless a male may
remain for several minutes almost touching her, even in the water,
without apparently being aware of her presence. I saw the same
thing several times in males and females accidentally thrown
together during the fighting. In some cases the female, in respond-
ing to a call, would swim right by a male approaching from the
side, so that neither seemed to recognize the other.

The females are able to locate the exact spot from which a call
is issued. In most cases, at the first or second call, they turned
so as to face in the general direction from which it came, the effect
being most noticeable with eight or nine females on the sand to-
gether. Before the call they faced in all directions,— after the
call in one, the most sensitive animals moving two or three feet
toward the call at once. The effect was much like that of bringing
a strong magnet near a lot of small compass needles. At the next,
or some succeeding call, a start would be made, the toads swimming
vigorously for a few seconds, then floating forward on the surface
of the water until their motion was spent. Often when a female
started not more than eight or ten feet away from the calling
male, its nose would hit the scantling on the inner side of the
breakwater just underneath where the male was sitting. I feel
sure, though, that this was not because it saw the male. In one
case the calling male faced so that he could not see the approach
of the female just beneath him. An inch or two at one side was a
mated couple. The female, on reaching the spot where the male
was, would be attracted by the motions of the couple and swim
towards them, only to leave them immediately and swim across the
pool to the other side. ‘This was repeated several times in succes-
sion. As already stated, when a female had started towards a
calling male, she would pay no attention to any males coming
towards her from the side. This was so marked that the ee
appeared purely mechanical.

One peculiar thing I noticed, or fancied I noticed — for it was
hard to be sure — was that the response of a toad, either male or
female, was much more rapid and vigorous when in a crowd of its
kind than by itself. The first five or six females were mated

No. 491] RESPONSE OF TOADS TO SOUND 681

within as many minutes, but these may have been the more sensi-
tive toads as I had no means of distinguishing one from another.

From these observations I conclude that both male and female
toads can hear and locate in space the call of the male; that the
response is unintelligent and mechanical; that to the sound of the
mating call a motor response is given, which serves to bring the
sexes to the same place; that motion is the stimulus which starts
the clasping reflex; that neither sex is able to recognize the other
without actual contact; that toads do not quickly profit by experi-
ence.

In comparing the single set of observations here recorded with
the experiments of Dr. Yerkes, it will be noted that toads were
employed in the former and frogs in the latter; it is not probable,
however, that there is any considerable difference in the acoustie
sense of such closely related animals. It will also be noted that the
observations were made in the early summer, when, according to
Dr. Yerkes, the sensitiveness to sound is at its best. But even so,
the response observed was greater than the results obtained by Dr.
Yerkes seem to indicate. It is possible that the frog is capable of
hearing and responding to the call of its mate but has no response
ready for the report of a pistol or the Galton whistle. It would be
interesting to make a phonographic record of the male call, try its
effect on females, and observe the result of changing its pitch,
quality, and character. The call of the male is not a continuous
but a throbbing sound. Nerves that are just beginning to be
sensitive to sound might well need a slower rate of vibration than
that of the sound itself, and this the throbbing would supply. It
was easily perceptible to the ear, so I suppose could not have been
at the rate of more than fifteen or twenty vibrations to a second.
In Dr. Yerkes’ experiments the throbbing electric bell produced
“the most marked modification of reaction, probably because it
consists, like the induced electric shock, of a rapid succession of
stimulating changes.” He states that “the green frog is stimu-
lated by sounds as low as 50 vibrations per second; no experi-
mental tests were made with lower sounds.”

It is possible that the failure in the laboratory to obtain motor
reactions to sound was due to the character of the sound or to
other features of experimentation; on the other hand my observa-

682 _ THE AMERICAN NATURALIST [Vor. XLI

tions are concerned with a motor response to only one sound, at :
one season. The toad reacts directly to the vibrations of the Se
mating call transmitted thirty or forty feet through the Mt cog) |.

_Derrorr Home ann Day ScHooL
Detroit, Mick

FURTHER NOTES ON THE BEHAVIOR OF
GONIONEMUS

MAX MORSE

Tue following notes upon the response of this jelly-fish, Goni-
onemus, to light supplement those published by the writer in the
Journal of Comparative Neurology and Psychology in 1906 (Vol. 16,
p- 450-456). All the experiments to be described were made in a
dark-room to which sunlight was admitted by means of a porte-
lumière apparatus. The aquarium was 100 cm. long, 70 cm., wide
and 50 cm. deep.

That light has a directly orienting effect on the animal is seen
from the following experiment. The light was admitted through
the slit, Fig. 1, a, and was reflected vertically downward upon the
medusa, b, as it lay upon the bottom of the aquarium. The light
fell upon one side of the medusa only, so that unilateral stimula-
tion was produced. The cylinder of light was 5 cm. in diameter
and therefore sufficient to cover one half of the body and the ten-
tacles belonging thereto, even when extended. Owing to the
difficulty of determining definitely the reaction when the medusa
lay with its apex downward, it was in each case turned over.
After one half of the bell had been illuminated for from 5 seconds
to three minutes, the reaction occurred. ‘The first movement
carried the medusa vertically upward and it was only after it had
pulsated three or four times that its path veered from the per-.
pendicular. It might turn towards the light (Fig. 1, be) or away
from it (bd) or be so indefinite as not to be placed in either of these
categories. The results of one hundred trials, upon different indi-
viduals in the main, are appended; those marked “‘indefinite” are
the responses where the animal had not moved far enough to be-
come oriented before ceasing to pulsate: —

Towards the light . ; - „9 reactions.
Away from the light. . . 70 reactions.
Indefinite . 21 reactions.

The effect of unilateral stimulation on a swimming jelly-fish

683

684 THE AMERICAN NATURALIST [Vor. XLI

was tried. Care was taken to have the impinging ray as nearly
as possible parallel to the oral-aboral axis of the animal. When
thus illuminated, the medusa changed its course, moving away
from the axis of light so that the path formed an acute angle with.
the ray.

Attention was then directed to the movements of Gonionemus
when swimming freely in an aquarium illuminated from one
direction. Figure 2 explains the arrangement. The sunlight was
reflected through the aquarium from side to side (ay). A jelly-fish
was freed at the point a, and it at once sank to the bottom.
Within a few seconds it began to swim and finally reached the top
of the water. ‘The path, however, was not vertical, but was in-
clined away from the light as shown by the path Ab. On reaching
the surface, the ordinary reaction took place whereby it inverted
and sank in the vertical line bB. The process was repeated so that
the resultant of the whole was the direction Ah. In this way it
will be seen that the medusa ultimately reaches the farthermost
point, as a result of the light acting exactly as in the simpler experi-
ments in unilateral stimulation. In one case, that of a strong
swimmer, the path followed was not broken by frequent inversions,
inasmuch as the animal did not reach the surface until it had
passed to the opposite side of the aquarium, a distance of about
70 cm.

That it is the direction of the ray of light that is the important
factor in orientation, is made evident by the following experiment
(Fig. 3). It will be seen that the light was thrown upon the
aquarium at the angle indicated by the arrow, so that the end
abc, lying nearer the source of light, is dark, the opposite end being
illuminated. When a medusa starts at b in the light, it rises to the
top and performs the actions just described, so that it reaches
ultimately the end d. By this means we find an accumulation
of jelly-fish in the end farthest from the light. Here they will
remain until they die, or, as is often the case, they begin to swim
regardless of the direction of the light and ultimately reach the
shaded area, in which they settle down as described in my previous

paper.
Yerkes ! has described a very interesting response in Gonionemus

1 Yerkes, R. M. Concerning the Behavior of Gonionemus. Journ. Comp.
Neur., 1906, vol. 16, p. 457-463.

No. 491] BEHAVIOR OF GONIONEMUS
under unilateral stimulation, a reaction observed many times by
the writer. ‘The animal is seen to pull the bell out of the light
by means of its tentacles.

tentacles within the lighted area are not attached, but lie extended
and passive. The bell itself is likewise motionless.
different with the portion of the bell and its tentacles lying in the
shade, as these parts are generally more or less active.
improbable that there is any complex coordination here that

685

Careful observation shows that the
The case is

It is very

NEST
Fig. 2

A

Fig. 3 Fig. 4

Figs. 1-4.—Diagrams illustrating the response of Gonionemus to light.

serves to move the body away from an area of light. The action
seems to be wholly undirected. ‘This interpretation is strengthened
by the fact that, in some cases, the body has been drawn directly
into the sunlight by those tentacles belonging to the illuminated
side, the tentacles themselves being shaded. At other times the
tentacles of one side of the body were seen to be carried up over
the bell and to become attached to the underlying sand on the
opposite side of the jelly-fish, after which the animal turned a

686 THE AMERICAN NATURALIST [Vor. XLI

complete somersault by means of the tentacles. At first this was
observed in medusae resting in the sunlight; the action was like-
wise seen in animals in the shade so that it has nothing whatsoever
to do with the effect of light.

In the notes previously published, the writer made an attempt
to determine the cause of the peculiar behavior of the animal in
inverting the bell on reaching the surface of the water. The
medusa has no mechanism other than contact whereby it can
turn the bell on a transverse axis and thus invert it; it is never
observed to turn in its path abruptly. As the equilibrium of the
bell is destroyed when the animal reaches the surface and pushes
one edge of the bell through the surface film, the inversion occurs.
It frequently happens that medusae are found that will not remain
mouth down even when so placed by hand. Such individuals kept
from inverting pulsate violently for long intervals and come to
rest only when they are turned over.

In the paper just cited, the writer interpreted the accumulation
of Gonionemus in the shade as the result of trial and error. Further
work has strengthened this conclusion. Only in the special case
where the shadow will be met as the medusa moves away from
the source of light, can this be directly the result of the orienting
factor of light. This is shown in the experiment illustrated by
Fig. 4, a view of the aquarium from above. The light is sent
lengthwise through the aquarium and parallel with its base. One
side is shaded. Individuals freed at A in the sunlight, move in
their characteristic way to the farther end of the aquarium. Some,
moving irregularly, enter the shaded area and remain there. Ulti-
mately, the great majority of the animals are found in this area
as described in the previous paper.

Yerkes! has described the light reactions of this medusa in
the following words,—

“Gonionemus always settles down in a shaded region,—in other words,
it is negatively photokinetic or photopat

n a number of the medus® are placed in a glass vessel before a window
they usually collect in the darkest region of the vessel. A simple test of this
was made by putting a number of the animals in a dish having a bottom

1 Yerkes, R. M. A Contribution to the Physiology of the Nervous Sys-
~ tem of the Medusa Gonionemus murbachii. Part I. Amer. Journ. Phys.,
1902, vol. 6, p. 446.

No. 491] BEHAVIOR OF GONIONEMUS 687

16 X 10 inches and a depth of 34 inches, one-half of which was covered with
a black cloth. By way of illustration, the results of one test were as follows:
eight animals were put into the dish in the afternoon at four o’clock; within
fifteen minutes all were in the light half of the vessel, and there they remained
with some changes of position until nine o’clock in the evening. At seven
o’clock the next morning only one was in the light region, and of the others
several were attached to the sides and bottom of the dark region of the dish.
Similar results were gotten with several lots.

Again, when Gonionemi in a glass collecting pail are disturbed by agitation
of the water, they swim about rapidly and in a few minutes most of them are
found on the more intensely illuminated side of the vessel. If, now, they are
allowed to remain undisturbed for an hour, they will be found either equally
distributed throughout the vessel or collected in the darker region

There are here two questions to be answered. First, why do the animals at
first come to the light? Secondly, why is it that they are later found in the
shaded regions? The following statement of the relation of the motor reac-
tion of Gonionemus to stimulation by light accounts for the facts. In ordi-
nary daylight they are, when swimming, positively phototactic; in very weak
light, on the contrary, they are not directed by the stimulus to any consider-
able degree, and therefore appear to be indifferent. They come to rest in an
intensity of light which is below that necessary to direct their movements to
any important extent and are therefore negatively photopathic.”

In a later paper? he described, as follows, a new set of experi-
ments which corroborate his earlier conclusions.

“Eleven meduse were placed in a white earthenware dish. The dish was
illuminated by direct sunlight. After a few seconds, one-half of the dish was
covered with a piece of black card-board. Within a minute ten of the eleven
medus® were in the sunlit portion of the dish and there they remained for
about two and one-half minutes, swimming about actively but without
moving far in any direction, Then as quickly as they had gathered in the
sunlit portion they moved to the shaded portion and in less than a minute,
all but two were in the shade of the cardboard.”

In my former paper (p. 452) I stated that, by the use of a large
jar, “33 cm. high and 21 cm. in diameter,” no such reaction was
observed. I can only add that the experiments conducted during
the past summer with the aquarium 100 cm. by 70 cm. by 50 cm.
bear out this conclusion. The collecting of the medusae in the
light does not occur where large vessels are used and where reflec-
tions from the sides are eliminated. The writer believes that
Yerkes’ results were modified by the use of a small vessel with

* Yerkes, R.M. Concerning the Behavior of Gonionemus. Journ. Comp.
Neur., 1906, vol. 16, p. 459.

688 THE AMERICAN NATURALIST [Vor. XLI

highly reflecting sides. Moreover, it is not clear from Yerkes’
text that light of the same intensity was used since some of his
experiments were conducted from 4 in the afternoon until 9 at
night; at such times the light would be constantly decreasing in
intensity. Again, he obtained the reaction by agitating the water,
setting the medusae swimming in all directions. Under such con-
ditions it would be very difficult to determine how much the move-
ments of the jelly-fish were due to its own activities and how much
to the currents set up by the agitation.

The writer’s experiment described above where light was thrown
on a swimming medusa shows too, that the reaction to light is the
same in an individual swimming as in one at rest, and not different,
as Yerkes believes. Inasmuch as experiments conducted under
more normal and more carefully arranged conditions do not exhibit
the reaction, the writer believes that Gonionemus is at no time
positively phototactic.

These experiments lead, moreover, to the conclusion that the
reaction of Gonionemus to light is a tropic one, and that the
accumulation of the animals in shaded areas is referable to the
method of “trial and error.”

The thanks of the writer are due to Dr. T. H. Morgan for many
suggestions in regard to the work and to the Marine Biological
Laboratory for facilities.

CoLLEGE OF THE City or New YorK

PLEISTOCENE PLANTS FROM ALABAMA?
EDWARD W. BERRY

In the course of the cooperative study of the Atlantic coastal
plain from the Potomac river southward during the past season,
plant-bearing beds of Pleistocene age have been discovered at
various localities, more particularly in Virginia, North Carolina
and Alabama. A rather interesting and highly fossiliferous
deposit of this character occurs along the Chattahoochee river in
Russell County, Alabama, where the collections upon which the
following brief communication is based were made by Dr. L. W.
Stephenson of the Federal Survey, who also very kindly furnished
the sections here given. The locality is a few hundred yards below
Abercrombies Landing on the Alabama side of the Chattahoochee
river, and about seven and one-half miles below Columbus, Georgia.

The recognizable leaf-remains have been found at two levels:
they occur in an upper layer of hard, dark drab, rather pure clay
which dries to an ash color, and in a lower layer of very dark
impure peat. The leaf-remains found in the clay are fairly perma-
nent, but those in the peat are very perishable and have been saved
and identified by allowing the material to become thoroughly
macerated in water and then carefully floating out the larger frag-
ments; from these, sun-prints giving the exact outline are made
before the specimens become thoroughly dry. If allowed to become
too dry they crumble to powder. After the prints have been made
the specimens are mounted on small cards and coated with glue,
but even in this condition they are extremely fragile and liable to
destruction.

The following two diagrammatical sections were taken about
100 yards apart; No. 1 shows the leaf-bearing horizons, the lower
of which is partially concealed by land slips, and No. 2 shows a
complete section to the water’s edge. From the way in which the
base of the exposure is concealed in section No. 1, it is impossible

* Published by permission of the Director of the U. S. Geological Survey.

689

690 THE AMERICAN NATURALIST [Vor. XLI

to be certain that the peat is in place in the section and does not
represent more recent drift material; however, the opinion of the
collector and all of the circumstantial evidence are strongly in
favor of the view that it is a true Pleistocene deposit, somewhat
older than the overlying beds. The argument for this interpre-
tation may be briefly stated as follows:— The peat which was
uncovered over an area two by ten feet had every appearance of
forming an integral part of the section. The material itself is
very similar to the somewhat more argillaceous material occurring
at the same level, and in place, in section No. 2. Seven species
have been detected both in the peat and in the overlying clay,
the latter unquestionably Pleistocene. ‘These forms are Quercus
virginiana Mill, Quercus prinus Linné, Quercus nigra Linné,
Betula nigra Linné, Platanus occidentalis Linné, Carpinus carolini-
ana Walt., and Ulmus alata Michx.

The deposits record progressive changes in the conditions of
deposition which may be recast somewhat as follows:— The
lower gravel bed probably represents material deposited near the
mouth of a stream with considerable current, during the brief
erosion interval immediately preceding the deposition of the peat.
With the subsequent subsidence of the land the lower stream
valleys were transformed into estuaries and a barrier beach was
built by wave action, which impounded the stream or lagoon,
forming a swamp where the peaty material was accumulated.
With the continued sinking of the land the advancing shore line
spread a mantle of gravel (the upper gravel bed) over the swamp
and with the still greater depression of the region, the overlying
clays were deposited in quiet estuary waters.

With regard to the exact stage.of Pleistocene represented, it is
very probable that these Chattahoochee materials are to be cor-
related with those late Pleistocene beds which have been called
the Talbot formation in Maryland and Virginia, and which contain
numerous similar swamp deposits. ‘The species of plants repre-
sented are all forms which occur in the recent flora of Alabama,
although the present range of some of them is considerably dif-
ferent. For example, the northern limit of the live oak is about
one hundred miles due south while the southern limit of the chest-
nut oak is about forty miles due north of Abercrombies Landing.

No. 491] PLEISTOCENE PLANTS 691

The willow oak is also rare as far south as this point although it is
abundant a few miles to the northward.

The flora as a whole furnishes no evidence of climatic conditions
appreciably different from those which exist at the present time in
this region, although the grouping of species was quite different
from that which obtains along the present Gulf coast.

The presence of Tsuga canadensis (Linné) Carr., and Betula

Laon Pad Eoee e a A grad
ing down into EN iaa Ae arte A TA S ioe ee into
Gay, 13 Re a en and, 13-166
Dark Te
bearing aay Gravel, 2 ft.
13 ft.
Gravel, 2 ft. Dark peat
clay, 2-5 ft.
Im iall gael
y er Gravel, 0-3
cealed, 3 f feet.

No. lis

Fig. 1. Pleistocene sections along the Chattahoochee river in Alabama.
bout three hundred feet north of No. 2

lenta Linné in the existing flora of Alabama at an isolated locality
in Winston county, miles south of their usual range, coupled with -
the presence of the larch in the Pleistocene of Georgia, would seem
to indicate cooler conditions at some time in the Pleistocene, pre-
sumably at an earlier time than is represented by the fossils from
near Abercrombies Landing.

In addition to the species enumerated below, there are a con-

692 THE AMERICAN NATURALIST [Vor. XLI

siderable variety of small seeds, husks of Hicoria, and the cone
scales and needles of Pinus, which it has seemed best not to deter-
mine positively at the present time. Remains of the cypress
(Taxodium) and the gum (Nyssa) which are usually present in
deposits of this age have not been detected.

FAGALES

Carpinus caroliniana Walt., Fl. Car., p. 236, 1788.
Pl. 1, Figs. 8, 9.
Berry, Journ. Geol., vol. 15, p. 340, 1907.

A species of low rich woods which ranges from Canada to Florida
and Texas and is common throughout Alabama. The fossil
leaves are present in both the peat and the overlying clays. Re-
cently recorded by the writer from the Pleistocene of North
Carolina.

Betula nigra Linné, Sp. Pl, p. 982, 1753.
Pl. 2, Figs. 2-4.
Knowlton, Amer. Geol., vol. 18, p. 371, 1896.
Berry, Journ. Geol., vol. 15, p. 341, 1907.

A species which in the modern flora ranges from New England
to Texas and which is common throughout Alabama, especially
along the stream banks. Several leaves occur in both the peat and
the clays and a small fragment of the characteristic bark was also
detected in the peat. This species has been previously recorded
from the Pleistocene of North Carolina and West Virginia.

Fagus americana Sweet, Hort. Brit., p. 370, 1826.
Pl. 2, Fig. 7.
Berry, Torreya, vol. 6, p. 88, 1906; Journ. Geol., vol. 15,
p- 341, 1907.
Hollick, Maryland Geological Survey, Pliocene and Pleisto-
cene, p. 226, 1906.

Fagus ferruginea Michx., Lesquereux, Amer. Journ. Sci., vol.
27, p. 363, 1859; Geol. of Tenn., p. 427, pl. 7 (K), fig. 11, 1869.

No. 491] PLEISTOCENE PLANTS 693
Fagus ferruginea Ait., Knowlton, Amer. Geol., vol. 18, p. 371,
96.

Mercer, Journ. Phila. Acad., (ii), vol. 11, pp. 277, 281, fig.
8 (15), 1899.

In the modern flora the beech is a prominent element in the
mesophile valley forests of the Alleghenian, Carolinian and Louisi-
anian zones. It was also a very prominent Pleistocene type and
has been recorded from the Pleistocene of Pennsylvania, Maryland,
Virginia, West Virginia, North Carolina and Tennessee. Near
Abercrombies Landing it is represented in the peat by four or five
of the characteristic husks, two nuts and one imperfect leaf.

Quercus nigra Linné, Sp. Pl., p. 995, 1753.
EL 1, Figs. 3, 4.
Berry, Journ. Geol., vol. 15, p. 342, 1907.

This species ranges in the Recent from the Louisianian zone
northward as far as Delaware and is common throughout Alabama
where it inhabits low rich woods and sandy pine-barren swamps.
It is by far the most abundant leaf in the peat deposits, possibly
due to its ability to resist decay; in the clays a single impression
was found, showing the basal two thirds of a leaf. This species
has recently been recorded by the writer from the Pleistocene of
North Carolina.

Quercus virginiana Mill, Gard. Dict., Ed. 8, No. 16, 1768.
TI L Fig. 2,

The live oak is a tree of the sea-coast, and in Alabama rarely
occurs north of latitude 31°. Thus its northern limit in this state
is about one hundred miles due south of Abererombies Landing, —
collateral evidence, if such were necessary, that the Pleistocene
sea or estuaries of it reached as far north as this point in the late
Pleistocene. The species is present in both the peat and in the
overlying clays, and so far as I am aware has not previously been
recorded in the fossil state.

Quercus prinus Linné, Sp. Pl., p. 996, 1753.
Pl. 1, Fig. 5.
Berry, Journ. Geol., vol. 15, p. 342, 1907.

694 THE AMERICAN NATURALIST [Vor. XLI

The chestnut oak is a tree of the rocky woods and hillsides and
makes its best growth in Alabama on elevations exceeding eight
hundred feet. Its present southern limit coincides approximately
with the isothermal line of 60° F., which also serves to mark the
boundary between the Carolinian and the Louisianian zones.
This line crosses the Chattahoochee river near West Point, Ga.,
or about forty miles due north of Abercrombies Landing. Two
leaves were found in the peat, and one fragmentary specimen show-
ing venation but not marginal characters is from the overlying clays.
It was recently recorded by the writer from the Pleistocene of
North Carolina where it is present in considerable abundance.

Quercus phellos Linné, Sp. PL, p. 994, 1753.
PL I; Pig. 1:
Berry, Journ. Geol., vol. 15, p. 342, 1907.

The willow oak is a common element in the mesophile forests
of the northern part of Alabama; it becomes rare, however, south
of the long-leaf pine belt which stretches across the central part
of the state, its southern boundary crossing the Chattahoochee
river just north of Abercrombies Landing. The fossil leaves are
a common element in the peat but have not been detected in the
overlying clays. It was recently recorded by the writer from the
Pleistocene of North Carolina where it is very common.

Ulmus alata Michx., Fl. Am. Bor., vol. 1, p. 173, 1803.
Pl. 1, Figs. 6, 7.
Berry, Journ. Geol., vol. 15, p. 343, 1907.

The water elm is common throughout Alabama and ranges
northward as far as southern Illinois and Virginia. ‘The Pleisto-
cene material from Abercrombies Landing contained two frag-
mentary specimens, one from the peat and the other from the
overlying clays. These leaves show the characteristic serrated
margin of this genus. They are smaller and narrower than the
leaves of Ulmus pseudo-racemosa Hollick from the Pleistocene of
Maryland and the character of the marginal teeth is also somewhat
different. The state of preservation indicates that the surface was
roughened or somewhat pubescent in life. They are identical with
the more perfect leaves which I have referred to this species from

No. 491] PLEISTOCENE PLANTS 695

the Pleistocene of North Carolina, and also agree admirably with
leaves from the existing tree, so that the identification is reason-
ably sure in spite of the meager materials.

RANALES.

Liriodendron tulipifera Linné, Sp. PL., p. 535, 1753.

The tulip tree is a common mesophile type of the Alleghenian,
Carolinian and Louisianian zones, its southern limit in Alabama
being about latitude 31°. Material from Abercrombies Landing
contained two positively identified winged carpels and several more
doubtfully determined fragments all of which came from the peat.
The genus Liriodendron, which has such an extremely interesting
geological history,’ has furnished a large number of American
Cretaceous species ranging from the mid-Cretaceous onward, but
none have been found in the American Tertiary. In Europe and
the Arctic regions, however, a number of Tertiary forms have
been described, especially from the Pliocene,— the leaves of
Liriodendron procaceinii Unger from France and Italy being
scarcely distinguishable from those of the existing species. The
material from Alabama is, so far as I am aware, the first Pleisto-
cene record of Liriodendron, although Schmalhausen records
leaves which he has identified as this species from the Altai Moun-
tains of Central Asia in strata which he refers doubtfully to the
Pliocene.’

ROSALES.

Platanus occidentalis Linné, Sp. Fi., p. 999, 1753.
Pl. 2, Fig. 5.
Knowlton, Amer. Geol., vol. 18, p. 371, 1896.
Penhallow, Trans. Roy. Soe. Can., (ii), vol. 2, sec. 4, pp-
68, 72, 1896; Amer. Nat., vol. 41, p. 448, 1907.
Mercer, Journ. Phila. Acad., (ii), vol. 11, p. 277, 1899.
Berry, Journ. Geol., vol. 15, p. 344, 1907.
1 Berry, Notes on the Phylogeny of Liriodendron, Bot. Gaz., vol. 34, pp.
44-63, 1902.
? Schmalhausen, Ueber tert. Pflanzen aus dem Thale des Flusses Buchtornia
am Fusse des Altaigebirges. Palaeontographica, vol. 33, 1887.

696 THE AMERICAN NATURALIST [Vor. XLI

Platanus aceroides Göpp., Hollick, Maryland Geological Survey,
Pliocene and Pleistocene, p. 231, pl. 73, 74, 1906.

In the modern flora this species inhabits low woods and banks
from Canada to Florida and Texas. In Alabama it frequents the
bottom lands of the central part of the state and is infrequent in the
southern part. It is an abundant Pleistocene type and has been
previously recorded from Canada, Pennsylvania, Maryland, West
Virginia and North Carolina. The Abercrombies Landing remains
include the fragment of a central part of a leaf shown in the figure,
which has the characteristic venation but none of the marginal
characters and which comes from the clays; and a still smaller
fragment from the underlying peat which shows one of the marginal
points.

SAPINDALES.

Ilex opaca Ait., Hort. Kew., vol. 1, p. 169, 1789.
Pl. 2, Fig. 1.
Hollick, Bull. Torrey Club, vol. 19, p. 331, 1892.
Berry, Journ. Geol., vol. 15, p. 345, 1907.

The holly frequents damp banks and hammock lands in Alabama
and ranges northward to New York and southeastern Massachu-
setts. It has been recorded by Hollick from the supposed Miocene
at Bridgeton, N. J., and by the writer from the North Carolina
Pleistocene. A single specimen was found at Abererombies Land-
ing in the peat.

ERICALES.

Xolisma ligustrina (Linné) Britton, Mem. Torrey Club, vol. 4,

p- 135, 1894. P. 2, Fe. 6
Hollick, Maryland Geological Survey, Pliocene and Pleisto-
cene, p. 236, pl. 69, fig. 6, 1906.
Berry, Journ. Geol., vol. 15, p. 346, 1907.

In the present Alabama flora the typical forms of this species
inhabit the damp banks of small streams in the mountainous por-
tion of the state. It is of a generally more northern distribution,
having its southern limit along the southern edge of the metamor-

No. 491] PLEISTOCENE PLANTS 697

phic hills in Lee county, and is not a member of the Louisianian
flora. In a fossil state it has been previously recorded from Mary-
land and North Carolina. At Abercrombies Landing it is confined
to the peat. Xolisma foliosiflora (Michx.) Small which Mohr!
considers to be only a variety of this species, and which is common
in the Alabama coastal plain and on lowlands westward into
Louisiana and northward as far as Virginia, is apt to have leathery
leaves which are usually distinctly serrulate. It may be considered
to be the coastal plain descendant of the more ancient Xolisma
ligustrina.
Jouns HOPKINS UNIVERSITY

Baltimore, Md.

? Mohr, Bull. Torrey Club, vol. 24, p. 24, 1897.

Quercus prinus Linné .

peat.
Gr
peat.
. peat.

Fig.

Fig. 6.— Ulmus alata Michx. F,

9.—Carpinus caroliniana Walt.

9

peat»
clay,
peat.
clay-

6

PLATE 2

Fig. 1.—Ilex opaca Ait . . + + peat. Fig.5.—P
Figs. 2, 3.—Betula nigra Linné . . clay. Fig 6.—X
Britto

A FURTHER STUDY OF LEAF DEVELOPMENT
FREDERIC T. LEWIS

In a previous paper (Amer. Nat., 1907, vol. 41, p. 431-441)
the writer discussed whether certain forms of adult leaves could
be regarded as due to arrested development, so that by compar-
ing the mature leaves of a given plant something of their embryo-
logical history could be learned. It was found that where leaflets
are formed embryologically from the base toward the apex, as
in most pinnate leaves, the terminal leaflet of the mature leaf is
often lobed. Where leaflets are formed from the apex toward
the base, as in most palmate leaves, the basal leaflets are often
lobed. In the rose, in which the leaflets are also formed from
the apex toward the base, neither apical nor basal leaflets are
lobed, but new leaflets appear near the stipules to which they are
often joined. In the previous paper the sumac and honey locust
were described as basifugal forms, and the blackberry and rose
as basipetal, the latter being of the stipular type. In the follow-
ing pages it will be shown that the basipetal and basifugal direc-
tions of growth may both occur in a single leaf; and that, although
one becomes predominant, evidences of the other are apparent.
In some cases a single species presents both pinnate and palmate
leaves.

The simplest form of compound leaf is three-parted or ternate,
and is produced by the lateral lobation of a simple leaf. The
stages in this process as seen in the mature leaves of Clematis
virginiana are shown in Figs. la-ld. A ternate leaf may be
basipetal in character and pass on to digitate forms with four, five,
or more leaflets, or it may be basifugal and produce pinnate leaves.
The leaf of Clematis, Fig. 1d, exhibits both tendencies. Basi-
petal growth is manifest in the coarser teeth on the lower margins
of the lateral leaflets and in the fact that the part of each lateral
leaflet below the midrib is wider than the part above. Basifugal
growth is shown in the coarse tooth on either side of the apical
leaflet. Although Clematis virginiana stops ordinarily at this.

701

702 THE AMERICAN NATURALIST [Vor. XLI

stage, the “very similar” western Clematis ligusticifolia goes
further, and, by the deepening of the notches in the terminal
leaflet, becomes pinnate with five leaflets. Many other species
of Clematis, including some which are commonly cultivated, have
pinnate leaves.

In the poison ivy, Rhus toxicodendron, simple leaves are occasion-
ally found, but the typical form is ternate. Many leaves exhibit
both basipetal and basifugal features (Fig. 2a), and explain the
occurrence of both palmate and pinnate leaves in this —
(Figs. 2b and 2c).

An interesting comparison may be made between the leaves of
the black raspberry, Rubus occidentalis, and the wild red raspberry,
Rubus strigosus. In the former, Figs. 3a and 3b, the basipetal
tendency predominates, leading to pedate leaves; a basifugal
notching of the terminal leaflet is, however, often observed. In
the closely related red raspberry basifugal growth leads to pinnate
leaves, Figs. 4a and 4b, but basipetal lobation may be seen in the
basal leaflets.

The form of leaf shown in Figs. 1d, 2a, 3a, and 4a is seen also
in Fig. 5a from Negundo aceroides. In the pinnate leaves of this
species there may be a basal secondary leaflet, as shown in Fig.
5b. Such evidence of basipetal growth in pinnate leaves is often
found. It appears in the long leaves of Ailanthus glandulosus
(Fig. 6b). In the seedling of this species, ternate leaves with
basal notches have been drawn by Jackson,’ from whose paper
Fig. 6a has been taken. ‘Thus it is evident that the basipetal
and basifugal directions of growth are present together in a great
variety of leaves.

The relation of the basipetal secondary leaflets to twice pinnate
leaves is shown in Figs. 7, 8, and 9. In the elder, Sambucus
canadensis, the bastfugal development of primary leaflets is shown
in Fig. 7a.” The basipetal formation of secondary leaflets appears

‘ Jackson, R. T. Localized stages in development in plants and animals.
Mem. Boston Soc. Nat. Hist., 1899, vol. 5, pp. 89-153.

2 Goebel (Organographie der Pflanzen, Jena, 1900, pt. 2, vol. 2, p. 525) classes
Sambucus ebulus with the basipetal leaves and Sambucus nigra with the basi-
fugal. He states,— “Since in nearly related plants the order of development
of pinnate leaflets is sometimes basifugal and sometimes basipetal, not much
_ importance can be attached to this distinction.”

-

No. 491] LEAF DEVELOPMENT 703

704 THE AMERICAN NATURALIST [Vor. XLI

in Fig. 7b. If the process of compounding proceeds further, a
smaller secondary leaflet will be cut off opposite the one on the
lower border of the primary leaflet (Fig. 7c). Thus the basal
primary leaflet becomes pinnate and develops further in the basi-
fugal manner. ‘This order of leaflet formation is seen not only
in the elder, but in Aralia nudicaulis (Figs. 8a-Sc) and in Cicuta
maculata (Figs. 9a-9b). It is of widespread occurrence.

An unusual exception to the basal formation of secondary leaflets
is seen in many leaves of Bidens frondosa (Fig. 10). In this
species the secondary leaflets are usually on the upper margin of
the basal leaflets. They may become matched by leaflets on the
lower margin, and sometimes the leaflet on the lower side is formed
first. Frequently in Sambucus canadensis the secondary leaflets
first appear on the distal sides of the basal leaflets, as in Bidens,
but usually they develop on the basal side, both in Sambucus
and in most of the species examined.

The development of the pinnate leaves of the rose, as described
in the previous paper, is so different from that of other pinnate
leaves as to require further study. Eichler * has classed with the
rose, as basipetal in development, the leaves of Sanguisorba
officinalis, Poterium sanguisorba, Potentilla anserina, and “ probably
all potentillas with compound and divided leaves.” The basi-
petal nature of the palmate leaves of Potentilla canadensis is ob-
vious. In “Gray’s Manual” they are described as “ternate but
apparently quinate by the parting of the lateral leaflets.” Fre-
quently they develop seven leaflets without lobation of the central
leaflet. In Potentilla jruticosa, however, the central leaflet shows
various degrees of indentation, and if one may judge from mature
leaves, basifugal growth occurs. The entire leaf is pinnate.
Potentilla anserina also shows lobed terminal leaflets.? It is
possible in these forms that the proximal leaves are added basi-
petally but they are not connected with the stipules, and lobed

proximal leaflets were not observed in the plants examined.
= he same is true of agrimony leaves. Basal lobation and
fusion with stipules were not observed. Terminal lobation (Fig.
11) was shown in two leaves among four hundred and fifty.

: yes A. W. Zur Entwickelungsgeschichte des Blattes. Marburg,

1861, 60 p
2 Goebel a agrees with Eichler in considering Potentilla anserina as basipetal.

No. 491] LEAF DEVELOPMENT 705

Figs. 6a-6b, Ailanthus glandulosus Dest.; 6a, from seedting, s after Jackson; —

c, Sambucus canadensis L. 8a-8c, A nudicaulis L. 92-9, Cicuta
er 10, Bidens frondosa L.— 6a, node 6b, X 4; 9a and 9b, X 3; the
others, X Xi

706 THE AMERICAN NATURALIST [Vor. XLI

Twenty-seven hundred leaves of Rosa lucida yielded none with
a lobed terminal leaflet, but basifugal growth was suggested by
the two leaves figured as 12a and 12b. Several leaves with second-
ary leaflets attached to the distal pair of primary leaflets were
observed (Fig. 12c). In Sambucus, Aralia, and Cicuta, the oldest
leaflets are the ones which give rise to secondary leaflets, and they
are consequently found toward the base of the leaf. Their distal
position in the rose may be correlated with basipetal development.
In the celandine, however, in which growth seems clearly basifugal,
the distal leaflets produce secondary leaflets as in the rose (Figs.
13a and 13b).

Among the twenty-seven hundred rose leaves there were none
with the proximal leaflets lobed. One pedate leaf was found
(Fig. 12d) together with several forms like that in Fig. 12e. ‘These
suggest that leaflets cut off from the basal pair may be carried
down the petiole as should occur in a truly basipetal pinnate leaf.
However, lobation of the proximal leaflets of a ternate leaf leading
to the production of a pinnate leaf has never been found by the
writer, and the rose leaves in Figs. 12d and 12e may be explained
by the close approximation of the two basal pairs of leaflets.

In the previous paper it was suggested that the first notches in
the embryonic rose leaf divided the blade from the stipules, and
that the leaflets arose in connection with the latter. ‘The mature
apple leaf drawn in Fig. 14a indicates that a notch dividing the
blade from the stipule developed on one side only. In small
apple leaves the stipules are adherent to the petiole much as in the
rose; in larger leaves they are cut off as filiform appendages
attached by one end. They may still develop into leaflets as shown
in Fig. 14b. In Sanguisorba and Poterium, which sometimes
show a lobed terminal leaflet, there is evidence of stipular basi-
petal growth. Thus in Poterium canadense a single leaflet or a
pair of leaflets may be found close to the stipules and separated
by a long stretch of petiole from the more distal leaflets. Some-
times the stipules are scarcely to be distinguished from leaflets,
to which they are probably giving rise. Such a leaf is figured by
Cushman (Amer. Nat., 1903, vol. 37, p. 354) who states that the
oo lowest pair of leaflets has “ almost the character of stipules.”

b Em: cicutaefolium, which has basifugal pinnate leaves, the

No. 491] LEAF DEVELOPMENT | 707

Fies. 11, a. onia eupatoria L. 12a-12e, Rosa lucida Ehrh. 13a-13b, Cheli-
donium majus L. 14a-14b, Pyrus malus L. 15a-15e, Sium cicutaefolium
Gmelin.— 12e, natural size; 12c, 14a, and 14b, X 4; 12d, 15a, 15b, and 15c,
X 4; the others, X i.

708 THE AMERICAN NATURALIST [Vor. XLI

basal leaflets are often joined to the thin sheath-like stipules. In
fact the relation of the leaflets to the stipules is strikingly like that
in the rose, as shown in Figs. 15a-15c. In the first there is a well
developed leaflet proceeding from the stipule on one side, and there
is no corresponding opposite leaflet. In the second the stipules
are prolonged into small green leaf-like appendages, and in the
third the small pair of leaflets above and separate from the stipules
suggests a stipular origin. If this is true, leaflets in Sium are added
from both ends, and the basal pairs of leaflets are not always homol-
ogous as stated by Shull.’

Shull’s study of Sium supplies an admirably complete record
of the leaf-forms presented by a single species. ‘They are, however,
considered from the biometric rather than the embryological point
of view. Thus the early leaves are divided arbitrarily into six
groups or categories. One of these contains the ternate leaves
with basally lobed lateral leaflets and three lobed terminal leaflets,
— that is, leaves like those of the poison ivy (Fig. 2a) and Negundo
(Fig. 5a). This fundamental class which exhibits symmetrically
the basipetal and basifugal directions of growth, is described as
simply a special case of variously notched three-parted leaves
“ which was separated from the others only because it could be so
definitely characterized.” Although Shull includes only 20% of
the first leaves of Sium in this category, a large proportion of the
forms placed in the remaining five groups are but variations of this
type,— the terminal lobes may be suppressed on one or both sides,
the basal lobes may be secondarily notched, ete. The study of
Sium shows that the leaves at first exhibit both basipetal and basi-
fugal tendencies and that the latter becomes predominant.

SUMMARY.

The leaves of very diverse species show a common method of
leaf development in which the basipetal and basifugal directions
of growth are combined. This is shown by the widespread occur-
rence of the ternate leaf with the three lobed apical leaflet and

! Shull, G. H. Stages in the development of er cicutaefolium. Carnegie
Inst. of Washington: Publ. No. 30, 1905. 28

-

No. 491] LEAF DEVELOPMENT 709

basally lobed proximal leaflets. ‘This form appears with more
or less distinctness in Clematis virginiana, Rhus toxicodendron,
Rubus occidentalis, Rubus strigosus, Negundo aceroides, Ailanthus
glandulosus, and Sium cicutaefolium. By the predominance of
the basipetal or the basifugal element, palmate or pinnate leaves
are produced respectively. Twice pinnate leaves develop along
the same plan; in becoming twice pinnate a basipetal secondary
leaflet becomes matched by a smaller leaflet on the distal border
and further development of secondary leaflets in basifugal. This
is shown in‘ Sambucus, Aralia, and Cicuta, and the exceptional
nature of Bidens is recorded. __

The manner of leaf development in the rose requires further
study. ‘The formation of leaflets in connection with stipules occurs
in Poterium, Sium, and the rose, but in Sium and to a less extent
in Poterium they form also from the terminal leaflet. Lobed
leaflets in the rose were not found.

Jackson’s studies have shown that some Cretaceous leaves are
like the simpler stages in the corresponding existing species, not-
ably in the tulip trees. Shull concludes, however, that “no
satisfactory inferences can be drawn from ontogenetic leaf-char-
acters regarding the phylogenetic history of the species.” He
states that there is need of physiological interpretation, and further
biometric studies of leaves are being made. In connection with
paleontological and biometric studies it is important that the
embryology of leaves should be known, not by inference from
mature leaves but by reconstructions of the embryonic stages.

The preceding descriptions of adult leaves show that there is
a determinate evolution of leaf forms, whereby diverse species tend
to produce similar shapes. Plants with simple leaves constantly
show tendencies toward compounding. The “obscurely lobed”
leaves of Malva rotundifolia are occasionally deeply divided, and
the notches on the red maple leaf may become clefts extending to
the petiole. The persistent production of the similar forms of
compound leaves which have been described is evidence in favor
of determinate or orthogenetic evolution.

CAMBRIDGE, Mass.

EARTHWORMS AS PLANTERS OF TREES
E. A. ANDREWS

Tmar squirrels aid the forester by burying nuts, some of which
may be left to germinate and so start new trees, has long been
known; but that common earthworms play a like part in the drama
of the woods has not been suspected. ‘The following observations,
however, show that the earthworm may be of use in aiding the
germination of at least one important kind of tree and raise the
question whether they do not do the same for some other trees as
well as for many smaller plants.

The earthworm assists in planting by bringing the seeds into
close contact with the soil, even burying them. Here, as in the
case of the squirrel, the object sought by the animal is not the
germination of the seed. The squirrel is following a strong food
instinct in hiding away nuts, many of which it will find again and
eat; the earthworm is also obeying a very strong instinct, which is,
however, only in part a food instinct. This instinct expresses
itself in the somewhat mysterious habit the earthworm has of
plugging up its burrows.

As is well known, some of our common kinds of earthworms
make holes in the ground and inhabit them for long as places of
protection from dryness and from various enemies. In the night
time, however, these earthworms may leave their burrows more or
less completely, to seek on the surface of the ground various objects
to be used as food, and to associate with other earthworms. They
then seize and eat both live and dead vegetable matter, and soft
animal matter when available; and they also drag back to or into
their burrows both edible and inedible objects. At times the
materials collected at the mouths of earthworms’ burrows plug
them up most effectively, so as to suggest that the chief purpose
of this activity is to close the opening of the burrow after the worm
has gone in. Thus one may frequently see tufts of pine needles,
_ of dead brown or of fresh green deciduous leaves, or of other light

objects that may have been upon the surface, sticking up here

711

712 THE AMERICAN NATURALIST [Vor. XLI

and there over the ground, each tuft so tightly and completely
filling a burrow that one might at first suppose that children at play
had deftly thrust leaves into all the earthworms’ burrows.

It was this strong instinct to plug up its burrows which Darwin
seized upon as a means of enquiry into the mental powers of the
earthworm. Scattering triangles of paper over the ground he
judged from the way in which these triangles were used by the
worm in plugging its burrows that it distinguished between angles
of different acuteness and probably exercised something akin to
reasoning. In his classic work on the earthworm Darwin does not
refer to the possible collection of seeds, though he discusses the
plugging instinct at considerable length. He says,— “Worms
seize leaves and other objects not only to serve as food, but for
plugging up the mouths of their burrows; and this is one of their
strongest instincts. Leaves and petioles of many kinds, some
flower peduncles, often decayed twigs of trees, bits of paper,
feathers, tufts of wool, and horse hairs are dragged into their
burrows for this purpose... .They often, or generally, fill in the
interstices between the drawn-in leaves with moist, viscid earth
ejected from their bodies; and thus the mouths of their burrows
are securely plugged....When worms cannot obtain leaves,
petioles, sticks, ete., with which to plug up the mouths of their bur-
rows, they often protect them by little heaps of stones; and such
heaps of smooth, rounded pebbles may frequently be seen on
gravel walks....” Darwin was inclined to think that one advan-
tage gained by the earthworms in plugging up their burrows lay in
the protection gained from cold night air, from animal enemies,
and less probably from rain.

Whatever the utility of this instinct, it is carried out with so great
a variety of objects, that it was not surprising to find earthworms
plugging their burrows with the dry, flat fruits of the maple tree.
On May 30th the ground under several large silver maple trees in
Druid Hill Park was thickly sprinkled with the yellow key-fruit,
or samaras, that had fallen from these trees, and it was quite
noticeable that in many places these fruits were gathered together
in little heaps. Each collection of seeds contained form twelve
to fifty, some lying loose, others more or less buried in the earth.
One of the larger heaps when lifted up filled a hand nearly full.

No. 491] EARTHWORMS 713

In some places the heaps were not more than a foot apart, but
elsewhere they were more sparsely scattered. When any heap
was dug up it was found to be a mass of samaras, bound together
with earth and some few fibers, probably dead grass.

The ground about some of the collections of maple tree seeds
was markedly free from seeds and clean, so that it seemed as if the
worms had reached out of their burrows to nearly their full length
of eight or nine inches and dragged back all the seeds they could find
in a circular area of which their stretched out bodies made the
radius. All this was much more evident in the areas close to the
tree trunks where there was little or no grass, while far out from
the tree trunks, where the grass was thick, the heaps of seeds were
smaller and not so evident, both because of the grass and because
there was a more uniform distribution of seeds with a less perfect
cleaning up of the neighborhood of each heap.

The earthworms’ holes were completely closed by the samaras
and earth. When about an inch deep of earth and seeds had been
removed the open burrow was seen as a clear hole about as big as a
pencil. An imaginary section down through a heap of seeds
would show a low cone made of seeds imbedded in earth, covered
with some dry, free seeds on the surface, the whole rising an inch
or more above the normal surface of the ground and of the upper
end of the earthworms’ burrow.

It was not determined what species of earthworm made the
collections of maple seeds. The few small red earthworms found
in some cases lying in amongst the seeds and moist earth that
plugged the burrows, probably had nothing to do with the making
of the burrows or with the collecting of seeds, though they may
have profited by the moist vegetable food and other conditions
found in these heaps.

The samaras were for the most part buried so that the flat wing
was down and the thick part, containing the seed, uppermost; in
fact in many cases it was only the wing that was in the ground.
However, in some cases the seed was down and the wing upper-
most. Apparently the earthworm had as a rule taken hold of the
samara by the flat wing and dragged it with this part foremost.
While the samaras lying loose upon the ground were all intact and
not injured many of those inside the heaps were frayed and frazzled
so that the shorter side of the wing often looked like a comb.

714 THE AMERICAN NATURALIST [Vor. XLI

Probably the worms had macerated and eaten off the leaf-like part
of the samaras but left the seed end uninjured.

In every collection of seeds some three or four, or more, had
sprouted, while outside these collections none of the seeds lying
over the ground were found to have sprouted. Most of the sprout-
ing seeds showed merely a short radicle and in the many cases in
which the seed end of the samara was above ground the radicle
was growing down to enter the earth. Some of the seeds that
were well buried had advanced farther; in one case the young
stem was three inches long and bore a small expanding plumule.

Though so many young trees were thus started by the aid of
earthworms in a situation in which the seeds did not sprout at all
unless thus brought into connection with the necessary moisture,
few of these seedlings made much further progress, as the condi-
tions were too unfavorable. But even after a long dry hot period,
on June 27th, some dozens of young trees were found scattered
over the bare ground under the more densely shading parts of the
mother trees, where they were not destroyed by the lawn mowers
as completely as were any that started to grow in the grass. ‘These
little trees were three to four inches in height; the cotyledons were
shrivelled while two or three pairs of leaves of maple shape were
now in evidence. Some of the trees were in groups with remnants
of old decayed samaras about them to indicate the former mound
of earth, since washed away. The many trees standing isolated
were deeply implanted in the ground and probably stood where
earthworms’ mounds had been. A photograph taken then shows.
six or seven little trees of different sizes all rising up close together
from one old heap of samaras. Even these favored few did not
survive the increasingly adverse conditions, for on August first,
when the hard dry ground under the parent trees was marked by
radiating, branching streaks of brown grass that had died over
their old superficial roots, all the seedling trees had disappeared.

The failure of this particular planting, under such conditions,
does not, of course, invalidate the contention that in nature the
earthworms may play quite an important part in forestry. They
probably more than amend, by planting trees, the damage with
which they are credited through destroying’seedlings’ in" gardens.

Jouns HOPKINS UNIVERSITY
Baltimore, Md.

THE CAUSE OF GYNANDROMORPHISM IN. INSECTS
T. H. MORGAN.

In recent years many cases have been recorded in the group of
insects in which parts of the body show the characters of the male
and other parts those of the female. Most frequently the separa-
tion lies along the middle line of the body, so that one side is like
the male and the other like the female. About two years ago I
attempted in the case of the bee to correlate this result with the
well known frequency of dispermy of the insects’ egg.t Two
spermatozoa having entered, one fuses with the egg nucleus and
its products produce the female characters; the other develops
alone and gives the characters of the ovat to the parts of the body
it supplies with nuclei, ete.

That the latter assumption is not arbitrary is shown by experi-
` ments with the egg of the sea-urchin in which it has been possible
to fertilize a non-nucleated piece of the egg with a single sperma-
tozoon. Boveri has attempted to prove that under these condi-
tions the characters of the larvae are paternal, which is in accord
with our hypothesis for the bee. ‘The evidence however on which
Boveri’s conclusion rests has been disputed. More recently God-
lewski has succeeded in cross-fertilizing a non-nucleated fragment.
of the egg of a sea-urchin with the sperm of a crinoid. The char-
acters of the young larvae are said to be maternal, indicating that
the protoplasm rather than the nucleus is the controlling factor
in determining the characters, but Godlewski’s statements apply
only to the very earliest stages of development, where according
to Driesch’s results the maternal influences predominate.

A test of the view that I have suggested should be found for the
bee if a gynandromorph should arise in a cross between two species;
for, on my hypothesis those parts that develop from the combined
nuclei should be female and hybrid in character, while those that
come from the single nucleus of the spermatozoon should be male

* Morgan, T. H. An Alternative oe of the Origin of Gynandro-
morphous Insects. Science, 1905, vol. 21.

715

716 THE AMERICAN NATURALIST [Vor. XLI

and paternal in character. The most remarkable case of gynan-
dromorphism that has ever been described, namely, that of the
Eugster hive, resulted from a cross between two species of bees, but
it is impossible to tell from von Siebold’s description the specific
characters of the male and female parts. A test case is apparently
furnished in a recent paper by Toyama’ “On Some Silk-worm
Crosses with Special Reference to Mendel’s Law of Heredity.”
Since ‘Toyama has not attempted to draw any conclusion from
the interesting cases that he has found I venture to call attention
to their possible interpretation.

A cross was made between two races of silk-worm moths; the
female belonged to a European breed having striped caterpillars;
the male belonged to the common Japanese breed having plain,
i. e. not striped, caterpillars. Two of the hybrid caterpillars
had the left side of the body striped (maternal) and the right side
plain. Applying my hypothesis to this case we see that the striped
side is due to the combined nuclei — the striped character carried |
by the egg dominating the plain character of the sperm-nucleus;
the plain side is due to the sperm nucleus alone and is therefore
paternal.

It might possibly be objected that the striped race was not pure
but produced some plain germ cells, so that the right side is due to
this condition; but there is no evidence that the striped race is
impure in this respect and the many experiments made by ‘Toyama
with this race would have shown the impurity had it existed.’
` Moreover the striped condition of the left side shows that the egg
of this individual must have carried striped characters since this
character is not carried by the sperm.

Boveri suggested a different interpretation of gynandromorphism.
He assumed that the results are due to the single sperm, that enters,
fusing with one pole alone of the segmentation spindle derived
from the egg nucleus. ‘Toyama’s case offers an opportunity to test
whether Boveri’s or my own hypothesis applies here. For ex-

‘Toyama, K. Studies on the Hybridology of Insects. I. On Some Silk
worm Crosses, with Special Reference to Mendel’s Law of Heredity. Bull.
Col. Agric. Tokyo Imperial University, 1906, vol. 7.

* The striped race was found, however, to be impure in another. respect.
It may produce a pale form but the occurrence of the pale form has no bearing
on our conclusion.

No. 491] GYNANDROMORPHISM 711

ample, according to Boveri’s view the single nucleus (that supplies
the male parts in the bee) is derived from the egg which in the
present case contains the striped character; the other side is
derived from the combined nuclei which should also the striped in
the present case since this is the dominant; but the facts are
contradictory to the hypothesis. On the other hand the facts are
what my hypothesis calls for.

So far I have attempted to consider Toyama’s cases without
regard to the question of the sex of the right and left halves because
while this raises some even more interesting issues, the conclusions
are more problematical, since we do not know in the moth the
nature of the factors that determine sex. Several possibilities
must be considered. If however we are justified in extending the
conclusion reached above in regard to the origin of these gynan-
dromorph — a conclusion I repeat, that is reached independently
of the question of sex— to the case of the bee, where more is
known in regard to sex determination, we shall be led to some far
reaching and important considerations concerning sex determina-
tion.

The moth that emerged from 'Toyama’s gynandromorph cater-
pillar had on the left striped half of the abdomen, external female
reproductive organs; and on the right plain half, male organs. In
my view the right side has come from the single spermatozoon.
It has produced the male sex. Two interpretations are here
possible. If there exist in the silk-worm moth two kinds of sperma-
tozoa— male and female producers—as shown by Stevens and
Wilson for some other insects, the right side may be due to a
male-producing (arrhenotokous) spermatozoon; while the oppo-
site female side would be due to a female-producing (thelytokous)
spermatozoon having fused with the indifferent (?) egg nucleus.
On the other hand the results may be due to a single nucleus alone
being capable of forming the male characters only. ‘The evidence,
even for the egg is not clear for the moths, for while cases have
been described in which only females appear from unfertilized
eggs, there are other cases in which both males and females
developed. Until we know something of the behavior of the polar
bodies in these cases it is unsafe to draw any conclusion in re-
gard to the eggs, and much more so in regard to the spermatozoa.

718 THE AMERICAN NATURALIST [Vor. XLI

In the case of the bee these conditions are better understood.
It appears as a rule that all unfertilized eggs produce males, and
all fertilized eggs produce females. The latter result must be due
to all the sperm being female producers, or to only female sperm
being capable of entering the egg, or to a quantitative relation,
namely, the combined nuclei producing female characters and the
single nucleus producing male characters. If we are justified in
extending to the bee the conclusion reached above for the moth
we can decide amongst these three interpretations. If the gynan-
dromorphous bee is due to one sperm nucleus fusing with the egg
nucleus and one (or more) sperm nucleus failing to fuse but devel-
oping alone, then the sperm are not female-producing but alone
are male-producing. ‘The egg nucleus alone is also male-producing
as seen in the development of drones. Combined, however, these
two male-producing nuclei give rise to a female-producing nucleus.
If this conclusion proves to be correct it throws an interesting
light on one of the ways in which sex determination is accomplished.

Equally important is the conclusion to which we are led in regard
to the relative influence of the spermatozoon versus that of the egg-
protoplasm — a question, as we have seen, on which the experi-
mental embryological evidence is still in doubt. The sperm
supplied with egg protoplasm gives rise in the adult to paternal
characters only, even in those cases like the present one in which
the egg carries the dominant characters! If we think of the
spermatozoon as introducing a nucleus only, the paternal char-
acters may be attributed to the nucleus; if we think of the sperma-
tozoon as introducing also some cytoplasm — the centrosphere
for example — the results might be supposed to be due either to
the introduced nucleus, or to the introduced cytoplasm, or to both.
Since however the egg also supplies cytoplasm (and that of the
dominant kind in the present case) this would offset that of the
spermatozoon. It seems therefore that the nucleus is the essential
factor. Thus our analysis furnishes a clue as to what part of the
sperm carries the factors that determine the characters of the
adult organism.

COLUMBIA University, New YORK
Sept. 15, 1907

NOTES AND LITERATURE
GENERAL BIOLOGY

Mental Development in the Child and the Race.’—“ Then there
are the biologists — one almost despairs of them! Are there any
yet born to follow the two I have named (Spencer and Romanes) in
finding mind as interesting as life?” Professor Baldwin has not been
compelled to repeat in the new edition of his stimulating book the
statement which we have quoted from the preface to his first edition,
for, as he remarks, the ten years since it was written have witnessed
a remarkable change in the attitude of biologists toward psychology.
The truth is that not a few of the leaders in biological science have
read Professor Baldwin’s book and have found in it excellent reasons
for opening their minds to the results of the scientific investigation
of consciousness. It is to be hoped that many more of them will
read the new edition of ‘‘Mental Development”’ critically and with a
view to bringing the author’s facts, principles, and theories into.
relation to the pre-eminently important problems of heredity which
now occupy the attention of so many biologists.

Since, on its appearance ten years ago, “Mental Development”
received many lengthy review notices it is not fitting that we should
fully describe the content of the new edition. The author in revising
his book has introduced a number of minor changes, but the work
stands essentially as it was originally written. For the benefit of
those who may desire a more complete statement of Professor Baldwin's
views than can be obtained by a reading of the volume under consider-
ation we may say that three other books are now available: “Social
and Ethical Interpretations,” “Development and Evolution,” and
“Thought and Things.”

R. M. Yerkes.

Racial Descent in Animals.’— Since the general acceptance of the

‘Baldwin, James Mark. Mental Development in the Child and the Race:
Methods and Processes. With seventeen figures and ten tables. Third
edition, revised. New York, The Macmillan Company. 1906. Pp. xviii +
477.

? Montgomery, T. H., Jr. The Analysis of Racial Descent in Animals,
Henry Holt and Co., New York, 1906, xxi + 311 pp.

719

720 THE AMERICAN NATURALIST [Vor. XLI

theory of descent with modification, the exact genealogical relation-
ship of animals has been an ever recurring question. In one way
or another it seems to have fascinated certain workers. With the
superficial, it takes the form of arrangements of living species in what
is assumed to be a genealogical sequence without regard to the fact
that these animals are of the same generation, so to speak, and not
ancestrally related. Speculations of this kind have brought much of
this work into disrepute. With the serious-minded, attempts have
been made to ascertain the principles by which kinship among ani-
mals can be determined, and to this class belongs the volume under
consideration.

With much care and erudition Montgomery has sought for a sound
basis by which animal relationship can be ascertained. This he has
formulated in a series of principles as follows: first, evidence of kin-
ship must be sought in the physiological as well as the morphological
relations of animals, for these two provinces are in reality mutually
interdependent; secondly, all the factors concerning animal processes
must be scrutinized; thirdly, the relative value of the different kinds
of evidence must be considered; fourthly, monophyletic origins should
be assumed unless the opposite can be proved; fifthly, approximately
intermediate connectants between species should be anticipated;
sixthly, organic modification is a response on the part of the organism
to a change in the environment; seventhly, comparisons between
diverse organisms are, at best, of the nature of inexact homologies;
and finally, the unit of comparison is the individual during its whole
life and not at any arbitrarily chosen stage.

It is noteworthy that two classes of evidence much in vogue in the
discussion of questions of this kind are belittled by Montgomery.
According to him no special light is thrown by embryology on phy-
logeny, for the development of the individual does not in his opinion
recapitulate the development of the race; and the evidence brought
forward by paleontology is too fragmentary to be of any service.
While it can frankly be admitted that the eight principles enunciated
above are worthy of serious consideration in the determination of
phylogenies, it is by no means clear that they are of prime impor-
tance as compared with certain others; for, notwithstanding the
lengthy argument adduced by Montgomery, ontogeny may still vaguely
outline phylogeny. The fact that the appearance of a new character
in a species involves a change that must influence the whole life cycle
of the animal from the egg to the adult does not necessarily blot out
other more ancient characters that may appear only at certain stages

No. 491] NOTES AND LITERATURE 721

and that may recall an adult state of an early ancestor. Moreover
it cannot be denied that the fossil record, meager though it is, is the
real record, whereas any scheme evolved in accordance with the eight
principles already named must remain, if untested by the fossil record,
forever hypothetical. How little we would know of the real characters
and genetic relations of the reptiles or of the mammals if we limited
ourselves to these principles. But, it might be retorted, that granting
what has been said about reptiles and mammals what light does the
fossil series give us on the interrelations of such groups as the animal
phyla, and to this question it must be admitted that no satisfactory
reply can be made. But is it perhaps not well to confess at once com-
plete ignorance of a question which from its very nature can receive
only such an answer as will remain forever hypothetical? The re-
viewer is inclined to believe that it is.
G. H. Parker.

Hough and Sedgwick’s Physiology.'— The volume under considera-
tion is a reprint of the first half of “The Human Mechanism,” by
the same authors. The latter has been favorably reviewed in the
Naturalist for March of this year (p. 194). The “Physiology” is an
excellent text-book for high school grades, and since further editions
will undoubtedly be called for, it is perhaps desirable to suggest that
more attention might profitably be given to anatomy, upon which
physiology is to some extent founded. The authors state that “in
the present book anatomy has been reduced to its lowest terms and
microscopic anatomy or histology has been touched upon only as far
as seemed absolutely necessary.” Some of the anatomical references
which might be improved are as follows. On p. 167, “alveolus” is
used for “lobule” of the lung; and “air cell” for “alveolus.” The
thyreoid gland, a median, bilobed structure, is described as “two
small organs which lie in the neck, one on each side of the trachea”
(p. 66). The red corpuscles are said to be “biconcave disks” (p. 135)
although they are now generally considered to be cup-shaped, with a
small proportion of spherical forms; they vary in shape, but the bicon-
cave form is not characteristic of circulating blood. Occasionally an
unnecessary term is introduced,— ‘“‘sarcostyle” is not better than
muscle fibril or myofibril, and “synapse” is not, for high school schol-
ars, an improvement upon terminal branches. (Neither sarcostyle

* Hough, T. and Sedgwick, W. T. Elements of ene: Boston, Ginn
& Company, 1907. 12mo, 321 pp., illus. $1.25

TR- THE AMERICAN NATURALIST [Vor. XLI

(Schäfer) nor synapse (Foster) are in very wide use at present.) Gen-
erally, however, the book shows that the authors had in mind the
immature student, as when they state that “the surface arew of all the
red corpuscles of the blood is 3,000 sq. meters or approximately four
times the size of a baseball diamond.” On the whole it is a book
excellently adapted to its purpose, and in its present form it can be
still more widely used.
F. T. Lewis.

ZOOLOGY

The Nervous System of Vertebrates.' — Bell’s discovery that the
dorsal roots of spinal nerves in vertebrates are sensory and the ventral
roots motor in function may be said to be the first step in subdividing
the nervous organs of these animals into physiological regions. This
process has been very much extended recently especially by certain
American neurologists with the result that the nerves and central
organs of vertebrates have come to be considered as aggregations of
elementary systems of fibers essentially homogeneous from a physi-
ological standpoint. The observations upon w ich this eonception
is based are contained for the most part in special papers and have
not heretofore been collected and condensed into a single readable
account. Such an account has been attempted by Johnston in his
text-book on the vertebrate nervous system.

he introductory chapters of this work treat of the morphology,
development, and physiology of the nervous system, after which its
parts are dealt with, not as in most text-books from the topographical
standpoint, but from that of physiological components. Chapters
are devoted in sequence to the somatic afferent division as represented
by the nervous mechanism concerned with touch, the lateral line
organs, and the ear; to the visceral afferent division as represented by
the visceral sensory apparatus and the organs of taste; to the somatic
motor division controlling the skeletal musculature; and to the vis-
ceral afferent division concerned with the visceral musculature, etc.
These chapters are followed by others dealing with special centers:
the cerebellum, i diencephalon, and cerebral hemi-
spheres,

1 Johnston, J. B. The Nervous System of Vertebrates. P. Blakiston’s
Son & Co., Philadelphia, 1906, xx + 370 pp., 180 illustrations.

No. 491] NOTES AND LITERATURE : 728

Although this method of subdividing the nervous organs and classi-
fying their parts has many points of advantage over the older topo-
graphical method, it possesses as elaborated by Johnston its weaknesses
and these are most clearly seen in the way in which certain organs of
special senses are dealt with. The eye and its nervous connections
are put in the somatic afferent division not because they are concerned
with touch or any of the derived senses, but because in certain of the
lower vertebrates the spinal nerve terminals are stimulated apparently
by light. The olfactory apparatus is classed under the visceral sen-
sory division because it is concerned with the acquisition of food.
The weakness of this classification is apparent from the fact that
the reasoning by which the author is led to assign the olfactory appara-
tus to the visceral sensory division, if applied to the optic apparatus,
would bring these organs under that head instead of under the somatic
sensory. Ina similar way the organs of taste ought not to be classed
as visceral sensory organs but as a somatic sensory mechanism, for
the reason that the cutaneous sensory nerves of the lower vertebrates
are stimulated by sour and salt substances much as our organs of taste
are. In other words the classification proposed by Johnston and
others, though avowedly physiological, will not stand the test of even
the most elementary physiological facts. This state of affairs is prob-
ably due to the common practice of certain neurologists of assigning
physiological significance to a part on the basis of purely morphologi-
cal considerations and without once endeavoring to ascertain by
experiment the real function of the part concerned. A detailed
classification based upon such a method as this is bound to be erroneous
and as in this movement the classification epitomizes results, a com-
plete change of method must be inaugurated before sound conclusions
can be arrived at. Johnston’s book, though a praiseworthy effort,
is characterized rather by an enthusiasm for a novel system of classi-
fication than by an appreciation of the weaknesses of this system.

. PARKER.

The Sense of Touch in Mammals and Birds.‘— The title of this
volume is too inclusive, as is stated by its author in the introduction.
It is essentially an anatomical account of epidermal markings and
the papillae of the corium; other tactile organs are not considered.
The first part of the book discusses palms and soles macroscopically.

1 Kidd, Walter. The Sense of Touch in Mammals and Birds. London,

Adam and Charles Black, 1907. 176 pp., 164 figs. Also The Macmillan Co.,
New York. $2.00.

724 THE AMERICAN NATURALIST [Vor. LXI

Eighty-six mammals and eleven birds were examined. Cutaneous
ridges were found to reach their full development only in primates.
The coarse walking pads of the large carnivora consist of rods, a feature
found also in the marsupial wolf of Tasmania, and to some extent in
the eagle. The plantar surface of the other birds studied was merely
corrugated, like that in Ornithorhynchus, Echidna and fourteen other
mammals. Scaly palms and soles occurred in nine of the eighty-six
mammals; smooth epidermis was found only in Proteles, and a com-
plete covering of hair only in the rabbit. The palms and soles of the
primates are then described in detail, with numerous figures.

The second part of the book deals with the form and arrangement
of the papillae of the corium, and is illustrated from sections magnified
generally fifteen or twenty diameters. Since half-tone text-figures
will not print well on paper with a rough surface, such as is used in the
first part of the book, the publishers have printed pages 81-144 on
glazed paper. The volume concludes with a physiological discussion,
a summary, and an extensive bibliography.

F. T. Lewis.

Observations on the Young of the Red Kangaroo.— A red kangaroo,
Macropus rufus (Desm.), was born in the Barnum and Bailey menagerie
a short time before I became their zoologist, which was in March, 1904.
At that time it was just beginning to put its head out of the pouch.
The superintendent insisted that he had known of its presence in the
pouch for two months and thought it must have been a month old
when he first discovered it. About a month after my arrival the little
fellow began coming out. Four months seems rather long for the
young to remain in the pouch before beginning to come out, in view of
their very rapid growth, but the period cannot be less than two months,
and is probably three or even more. A month after beginning to come
out, he would still rush back on the slightest provocation, going in
head first and turning round, but leaving his tail and long hind legs
protruding eighteen or twenty inches. In this position he presented
a very comical picture.

The kangaroo, in common with other marsupials, is of a very low
order of intelligence, and yet this mother was very solicitous for the .
safety and welfare of her son. At first she gently objected to. his
coming out, holding him in the pouch with her fore paws. But his
budding curiosity and growing activity could not be suppressed and
his excursions into the outer world became more and more frequent.
At first she would restrain him with her paws from going to the far

No. 491] NOTES AND LITERATURE 725

side of the cage, keeping him close to her side. The father was per-
mitted to share the cage, but never made any attempt to harm his
offspring. On the other hand, he showed no affection for him.
From the very beginning the baby displayed the brick-dust red of the
father. As is well known, it is no unusual sight, when a herd of
kangaroos is feeding, to see the head of the baby protruding from the
mouth of the pouch, nibbling grass. I have seen the young eating in
this way in captivity.
W. H. Speak.

A Note of the Prairie-dog Owl which resembles the Rattlesnake’s
Rattle.— In the summer of-1904 a party of fossil hunters, with four
horses (two under the saddle and two hitched to the wagon), was
trailing across Wyoming, at the time following up Bridger Creek, a
tributary of Bad Water River. As they were moving along an old
fence, under and to either side of which were numerous prairie-dog
holes, mostly deserted, suddenly a “rattle” caused all four horses
to shy out of the road. The saddle horses were brought back, and
their riders searched through the low sage bushes and grass for the
rattlesnake to kill it. A second warning followed and a prairie-dog
owl rose, flying to a fence post some ten feet away, where it alighted
and began a third “rattle,” and this time all saw its stretched neck,
bulging eyes, open beak and vibrating tongue. The whole appear-
ance of the bird indicated assurance that it would thus frighten off
any enemy; and it certainly deceived the four plains-bred horses,
as well as the men, all of whom had for weeks been familiar with
rattlesnakes, and two of them for years. The writer has often been
startled by the rattle of the dry lupine pods, known as “rattle weeds,”
but horses are not so deceived. However they were clearly frightened
by the owl.

The usual note of the burrowing or prairie-dog owl, Speotyto cuni-
cularia (Mol), is generally described as a squawk, and is not unlike
qua-qua-qua-qua, with variations in the last part. Generally the bird
is silent, uttering its note only when startled. The unusual rattle of
the individual described was heard repeatedly, for we camped about a
mile above the prairie-dog holes, and each succeeding day for over a
week some or all of the party passed the spot. The owl never failed

. to warn with its rattle and the horse or horses, no matter how tired,
never failed to shy out of the road,— never having associated the rattle
with the owl. After ten days the party moved camp and no more was
seen of the owl, but it doubtless kept on rattling and deceiving animals

726 THE AMERICAN NATURALIST [Vor. XLI

and men. If it succeeds in teaching the trick to its young, a protective
habit of great value will be formed.
F. B. Loomis.

Feathered Game of the Northeast.'— In a volume of 432 pages
Walter H. Rich, “a keen sportsman,” has written of game birds for the
man “whose nature study has been conducted . . . . mostly over a gun-
barrel.” He hopes that the scientific ornithologist as well, may find
its pages of interest and profit. There are eighty original, full-page
half-tone pictures of the birds, which are unusually life-like and in
which color contrasts are well brought out. There are also a few
hunting scenes, and one drawing in color presenting a pair of wood
ducks. The descriptions of the birds are informal, and the author’s
joy in killing them is undisguised. He admires the woodcock’s
“‘lead-carrying grit,’ and a typical anecdote concludes,— “So the
war went on until a lucky shot tumbled the bird from his perch minus
half his head.” Flavors of the birds are discussed as follows,—
“The Sora Rail is usually introduced to the epicure in the form of a
pie, and it is in this stage that it makes its best showing”; of the
solitary sandpiper he says,— “I think he makes a good impression
when, after being skinned, wrapped in a thin piece of fat pork and
enclosed in a big potato, he has been well baked.” The spruce grouse
is “a pretty fowl for a dining room ‘bird piece.’” The shooting of
wfiistlers is enthusiastically described. These ducks are now pro-
tected within Boston’s limits and during the winter they give pleasure
to hundreds of people who cross the Charles River daily. Their
former destruction, as seen by the genial Autocrat, led him almost
to lose his temper, for he wrote,—

He knows you! “sportsmen” from suburban alleys,
Stretched under seaweed in the treacherous punt;
Knows every lazy, shiftless lout that sallies
Forth to waste powder — as he says, to “hunt.”

In presenting this book the publishers announce that it contains a
“timely plea for moderation in seeking game.” Brother sportsmen
are asked to paste in their hats the motto “Don’t forget to leave enough
for seed.” The author says that ‘‘the Whistlers seem to be holding
their own in the struggle for existence — a thing which can be said of
few of the duck family” and that “indeed it is a matter for wonder

1! Rich, W. H. Feathered Game of the Northeast. New York, Thomas
G. Crowell & Co., 1907. 8vo, 16 + 432 p., illus.

No. 491] NOTES AND LITERATURE 721

that the shore-birds were not exterminated long ago.” He would
stop spring shooting and close our markets to the sale of game. We
wish that the ‘great brotherhood of sportsmen’ would agree to this.
Their attempt to pose as ‘lovers of bird life,’ as ornithologists, or as
‘Roosevelt-like’ is unsuccessful; andif our author really desires to
“work loyally in an effort to save our wild life from the extermination
which threatens,” will he continue to destroy it?
F. T. Lewis.

Game Laws for 1907.— Farmers’ Bulletin 308 of the U. S. Dept. of
Agriculture presents a summary of the game laws of the United States
and Canadian Provinces. In the number of bills introduced and in the
general demand for change of some sort the record of 1907 is second
to that of no previous year, although the number of bills actually passed
was equaled by the legislation of 1905. Most of the changes were
made to secure greater protection. In several states the seasons were
closed entirely for certain kinds of game. On the other hand in many
places certain restrictions were removed. The legislation is said to be
in a transition stage; settled policies have not been determined but
various compromises are made between the sportsmen, the ornitholo-
gists’ unions, and the majority of people with whom such legislation is
by no means an issue. Thus these laws are abitrary, complex, and
difficult of enforcement. Hunting is prohibited in some Maryland
counties on election day; water-fowl are protected on Mondays in
Ohio. A Maine license which requires $5.00 ordinarily for the ship-
ment of a moose, etc., permits shipment to a hospital. Alaska allows
the sportsman 25 shore birds a day, whereas Maine permits 15 ducks
and 70 sandpipers. Such whimsical laws cannot be permanent, and
the study of the situation now being conducted should lead to their
improvement. Many measures, last year, were allowed to fail rather

than pass in an unsatisfactory form.
F. T. Lewis.

Notes on the Structure of Insects.— The Ovaries of the Hemiptera.—
In a recent review the writer referred to the two opposing views regard-
ing the development of the sex-cells in the ovaries of insects. As is
well known, each ovary consists of a variable number of egg-tubes
opening into the oviduct. Each tube is divided into three zones: 1st,
the terminal filament which, uniting with those from neighboring tubes,
forms the suspensorium of the organ; 2nd, the terminal chamber and,
3rd, the germarium or chambered egg-tube.

728 THE AMERICAN NATURALIST [Vor. XLI

According to the more generally accepted view the terminal chamber
contains the undifferentiated elements from which are derived not
only the eggs but the nutritive cells and the cells of the follieular
epithelium which surrounds the developing eggs. Korschelt, who is
widely quoted, formerly believed that these elements might be traced
back still further to indifferent elements of the terminal filament.

Sharply opposed is the view that the sex-cell is sui generis, in origin
entirely distinct from the surrounding epithelium. This interpreta-
tion has been gaining ground but is opposed by Marshall’s recent
results.

In view of the conflicting conclusions of previous investigators the
recent work of Köhler! is of much interest. The fact that the work
was done under Professor Korschelt’s supervision adds especial weight
to the author’s conclusions.

The contradictory results obtained by previous workers are due
mainly to the use of mature specimens, and to poor technique (staining,
fixation, or to thickness of sections). Köhler has studied sixteen
species of Hemiptera, of most of which he had immature as well as
mature stages. Of three species he had a series of the nymphal stages.
Fixation was by means of Hermann’s or Zenker’s fluids, as alcohol or
the much-used corrosive sublimate were wholly unreliable.

It was found that the cells of the peritoneal epithelium, the termi-
nal filament, the epithelium of the germarium and of the follicles, are
of common origin. These somatic cells are perfectly distinct from the
sex-cells and the nutritive cells which are derived from the latter.

e germarium is filled exclusively by the germ cells and is always
sharply set off from the terminal filament, usually by a distinct mem-
brane. There are no “free nuclei” present.

Köhler’s investigation was not confined to the question of the origin
of the cells but included a thorough study of the histological structure
of the ovaries, and an especial consideration of cell-division. He
found that cell-division takes place in the peritoneal epithelium,
terminal filament, egg-tube, and germarium and is always by mitosis.
On the other hand the so-called amitotie division occurring in the
follicular epithelium is confined to the nucleus and never leads to
cell-division. However, the tissue in which it occurs is not senile,
but living, and capable of growth and activity. Only after the nuclear
divisions have occurred begins the cell activity (secretion of egg-chorion)

1 Köhler, A. Untersuchungen über das Ovarium der Hemipteren. Zeit-
: schr. w. Zool. 1907, lxxxvii, pp. 337-381, pls. 19-20,

No. 491] NOTES AND LITERATURE 729

which leads to a wearing out of the tissues. Thus the so-called amito-
sis is not concerned with cell-increase but leads to increase in surface
area of the nucleus, the center of cell-activity.

The origin of the adipose tissue of the adult fly— In most insects the
larval adipose tissue persists in the imago, presenting at most slight
modifications. In the higher Diptera, however, and especially in the
Muscidae, it has been found that the larval fat-tissue disappears com-
pletely and is replaced in the adult by a new tissue. ‘This Berlese
thought to be derived from the nuclei of larval muscles, while Henneguy
regarded it as made up of metamorphosed leucocytes.

Perez,! ’07, describes a condition much more in harmony with what
is known concerning the origin of other adult organs and tissues.
According to this investigator the fatty tissue of the adult originates
from subhypodermal groups of small, compact, mesenchymatous cells
which, like all young cells, stain readily in haematoxylin. These
groups are thus the homologues of the imaginal dis

The influence of nutrition on reproduction in a spider.— Lecaillon,!
07, finds that the conditions of nutrition strikingly influence egg pro-
duction in a common spider, Agelena labyrinthica. Ordinarily this
species constructs a single cocoon, containing from 50-100 eggs.
Occasionally double cocoons are to be found, one capsule containing
a much smaller number of eggs. By overfeeding, Lecaillon obtained
from one female five cocoons in as many weeks. Four of these con-
tained respectively 78, 38, 14, and 5 eggs while the fifth cocoon was
small, irregular and empty.

W. A. REY.

Notes.— The so-called double heart of the mollusk Arca has been
made the subject of special investigation by A. Theiler (Jena. Zeitschr.
7. Naturwiss., Bd. 42, pp. 115-142, Taf. 9-10). The author points
out that it is only proper to speak of a double heart where each ventricle
has a separate aorta and acts independently of its fellow. Such a
condition occurs in Arca noae, A. barbata, A. tetragona, and A. lactea.
In A. lactea, however, there is a common pericardium for both ventricles

* Perez, Ch. Origine du tissu adipeux imaginal chez les Muscides. C.R.
Soc. Biol. Ay pp. 137-139.

1 Lecaillon, A. Influence de la nutrition sur la reproduction d’Agelena
Te Cl. C. R. Soc. Biol. 1907, lxii, pp. 334-337.

730 THE AMERICAN NATURALIST [Vor. XLI

and in A. scapha, according to Ménégaux, there is not only a common
pericardium but the two ventricles are represented by one. Thus
in different species of Arca there occurs all transitions from a single to a
double heart.

After an extended consideration of the musculature of the gorilla
in comparison with that of man and the lower apes, Dr. A. Sommer
(Jena. Zeitschr. f}. Naturwiss., Bd. 42, pp. 181-308, Taf. 25-28, 1906)
concludes, contrary to the opinion of Huxley, that the gorilla in this
part of its structure is more closely related to the lower apes than to
man. F

Two large frogs from South Kamerun, West Africa.— The Uni-
versity Museum, University of Michigan, has recently received, in a
very interesting collection made by Mr. George Schwab from the
vieinity of Efulen, Kribi, Kamerun, West Africa, a specimen each of
the Giant Frog, Rana goliath Boulenger, and the Hairy Frog, Tricho-
batrachus robustus Boulenger. Both of these specimens agree closely
with the descriptions recently published by Mr. Boulenger (T. robustus
Proc. Zool. Soc. Lond., May 8, 1900, 443; R. goliath, Ann. & Mag.
of Nat. Hist., XVII, 317-318, and Proc. Zool. Soc. Lond., I, 179).
R. goliath enjoys the distinction of being the largest frog known, and
the above mentioned specimen only slightly exceeds in size the one
described by Mr. Boulenger. From snout to vent it measures 300 mm.,
but-Mr. Schwab, the collector, states that it is only partly grown. He
writes of its habits as follows: “This frog lives only in rivers, about
the rocky shores of deep pools. On the slightest provocation it dives
away, making it difficult to secure specimens.”

ALEXANDER G. RUTHVEN.

PUBLICATIONS RECEIVED

From September 1 to October 1, te dos oe gs included
The year of publication when n s 1907

ANDREINI, A. L. Sfere Cosmografiche e loro Applicazione alla Risoluzione
di Problemi de Geografia Matematica. Milan, Ulrico Hoepli, 1907. XXX +
328 pp., 12 figs. L. 3.— Kipp, W. The Sense of Touch in Mammals and
Birds. London, Adam and Charles Black, 1907. 176 pp., 174 illus. $2.00.—
Macrını, G. P. Lo Studio Scientifico dei Laghi. Milan, Ulrico Hoepli, 1907.
XVI + 242 pp., 53 figs. L. 3.— OLcorrt, W. T. A Field Book of the Stars.
New York, G. P. Putnam’s Sons, 1907. 163 pp., 50 diagrams.— Ricu, W. H.
Feathered Game of the Northeast. New York, Thomas Y. Crowell & Company,
1907. 8vo, 450 pp., 87 illus. à

Avams, G. E. A study of Rhode Island soil requirements, X means of
field tests. R. I. Agric. Exp. Sta., bull. 121, pp. 141-175.— Bruner, H. L.
On the cephalic veins and sinuses of reptiles, with description of a nen
for raising the venous blood-pressure in the head. Amer. Jour. of Anat., vol.
7, no. 1, pp. 1-117, 17 figs., 3 pls.— CLark, A. H. Descriptions of new species
of recent unstalked crinoids from the north Pacific Ocean. Proc. U. S. Nat.
Mus., vol. 33, pp. 69-84.— CLARK, A. H. Descriptions of new species of
deceit unstalked crinoids from the coasts of northeastern Asia,— Proc.

Nat. Mus., vol. 33, pp. 127-156.— Cocks, R. S. The flora of the Gulf Biologic
Station. Gulf Biol. Sta., bull. 7, 42 pp.— Epwarps, C. L. The Holothurians
of the north Pacific coast of North America, collected by the Albatross in 1903.
Proc. U. S. Nat. Mus., vol. 33, pp. 49-68.— EIGENMANN, C. H., AND FLETCHER,
O. An annotated list of Characin fishes in the United States National Museum
and the Museum of Indiana University, with descriptions of new species.
Proc. U. S. Nat. Mus., vol. 33, pp. 1-36, 8 figs — Eror, D. G. A catalogue
of the collection of mamma} in the Field Columbian Museum. Field Colum-
bian Mus., zoöl. ser., vol. 8, 694 pp., 92 figs.— García, F. Melon Culture.
N.Mex. arte, Exp. Sta ., bull. 63, 38 pp., 10 figs — Girty,G.H. Descriptions
of new species of upper ‘Paleosaic fossils from China. Proc. U. S. Nat. Mus.,
vol. 33, pp. 37-48.— Hare, R. F., anp Grirrirus, D. The tuna as a food
for man. N. Mez. Agric. Exp. Sta., bull. 64, 88 pp., 7 pls.— Harris, J. A.
Prolification of the fruit in Capsicum and Passiflora. Rep. Mo. Bot. Gard.,

AND
Coox, C. L. Soil tests in paraffined wire baskets, compared with tests on
faima. R. I. Agric. Exp. Sta., bull. 120, pp. 111-138, 2 figs.— HARTWELL,
B. L., Moraan, J. F., Wai L. F. anb Hammonp, H. 8. Analyses of
commercial fertilizers. R. I. Agric. Exp. Sta., bull. 122, pp. 179-187.— Hus,
H. Fasciation in Oxalis crenata and experimental production of oe
Rep. Mo. Bot. Gard., vol. 17, pp. 147-152, pls. 17-19.— KrLLOGe, R. S.
Exports and imports ‘of forest products: 1906. U.S. Dept. of Aa. forest
service, circ. 110, 28 pp.— Kirxaupy, G. W. Leaf-hoppers — supplement.

731

182 THE AMERICAN NATURALIST [Vor. XLI

Div. Ento., Exp. Sta. Hawaiian Sugar Planters’ Assoc., bull. 3, 186 pp., 20 pls.
— Mann, H. H. Individual and seasonal variations in Helopeltis theivora,
with ee of a new species of Helopeltis. Mem. Dept. of Agric. in
nto. ser., vol. 1, no. 4, pp. 275-337, pl. 15.— MAxweELL-Lerroy, H.
The more important insects injurious to Indian agriculture. Mem. Dept. of
Agric. in India, ento. ser., vol. 1, no. 2, pp. 113-252, 80 figs— MAXWELL-
Lerroy, H., AnD GHosu, C. C. The Indian surface caterpillars of the genus
Agrotis. Mem. Dept. of Agric. in India, ento. ser., vol. 1, no. 3, pp. 253-274,
pl. 14— Orton, W. A. Sea Island cotton: its culture, improvement, and
diseases. U.S. Dept. of Agric., farmers’ bull. 302, 48 pp., 13 figs.— PALMER,
T. S., OLpys, H., AND BREWSTER, C. E. a ame laws for 1907. U. S. Dept.
of Agie. Gna bull. 308, 52 pp.— Ramatey, F. Trees of the pine family
in Colorado. Univ. of Colorado Studies, = 4, no. 2, pp. 109-122, 2 figs.—
Ramatey, F. The poplars, aspens and cottonwoods. Univ. of Colorado
Studies, vol. 4, no. 3, pp. 187-197, 6 figs.— Ramauny, F. The Tokyo Botani-
cal Garden. Plant World, 1906, vol. 9, no. 11, pp. 251-258, pls. 40-43.—
Swezey, O. H. The sugar cane leaf-roller. Die, Ento., Hawaiian Sugar
Planters’ Assoc., bull. 5, 60 pp., 6 pls.— Verrcs, F. P. Chemical methods
= utilizing wi U. S. Dept. of Agrit, si of chemistry, circ. 36, 47 pp.,
16 figs.— VERNON, J. J. AND Scorr, J. M. feeding. N. Mex. Agric. Exp.
Si; bull. 62, 20 pp., 4 pls.— WEBSTER, 4 eu. The spring grain-aphis or
“green bug.” U. S. Dept. of Agric., bur. of ento., circ. > 18 pp., 7 figs.
AGRICULTURAL COLLEGE, N. M., College Record, volt o. 2.— ELEVENTH
ANNUAL REPORT OF THE STATE Emromondsigr OF een 1906.— LA
CUNA DE AMERICA, vol. 2, nos. 30 and 31.— MIcHIGAN COLLEGE OF MINES,
Year Book for 1906-1907.— NATURAE NOVITATES, nos. 9, 11, 12, 14.— New
Mexico COLLEGE OF AGRICULTURE AND MECHANIC Arts, Seventeenth Annual
Report, 1905-1906.— New York ZooLocIcAL Socrery, bull. 27,— SELLING
MAGAZINE, vol. 3,.no. 5.— TecHınaL WorLp Magazine, April.—
STATES DEPARTMENT OF AGRICULTURE, Farmers’ Bulletin 305; Production of
Lumber, Laths and Shingles, by States and Species, 1906, 1905, 1904; Report
on Sanitary Milk Production.
(No. 490 was

issued Novemher 2, 1907)

By Prof. Vernon L. RpEnE the author of Arie rican Insects,” etc. 395 pp. and

A simple ay
scientie criticism of arwinian selection eono seein “with con-
cise accounts of the other more important pro T auxiliary an
= theories T ee forming. With ee notes and exact references
to sou

rmly cae and Untieraly ki indly ities An i nvestigat: = of the fi first ra rank, :

and master of a clear = forceful literary style.” 3
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f ieie et $5.00 C. E. Water’s Ferns. Spel atch net. = u
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VOL, XLI, NO. 492 DECEMBER, 1907
THE

AMERICAN
NATURALIST

A MONTHLY JOURNAL
DEVOTED TO THE NATURAL SCIENCES
IN THEIR WIDEST SENSE

CONTENTS
Page
I. Preliminary Notes on Some American Chalicotheres . . 0. A. PETERSON 733
II. Observations on the Natural History of Po/yodon spathula ria

.§
III. Fowler’s “ Heterognathous Fishes” with a Note on the Stethaprioninae
C. H. EIGENMANN 767

IV. Pink Insect Mutants WIL MMW WHEELER 773
V. Notes and Literature: General Biology: The theory of ne — The inherit-
ance of disease.— Malaria in ancient Greece and Rome.— The distribu-

tion of European animals.— The dancing mouse. Tins: Ichthyo-

logical notes.— Notes on the structure of insects.— British rhizopods,

Botany; Recent studies on gymnosperms.— Xerophily of the gymno-

— Notes on the problem of adaptation.— Plant cultivation in

md education.— Lobed terminal leaflets in the rose. . . 783

VI. re Received . = b R . 816
VII. Index to Volume XLI ;

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THE
AMERICAN NATURALIST

Vou. ALI December, 1907 No. 492

PRELIMINARY NOTES ON SOME AMERICAN
CHALICOTHERES*

O. A. PETERSON

CoMPARATIVELY little is known of the American forms of the
Chalicotherioidea;— an extinct family of mammals. Professors
Marsh,” Cope,’ Scott,‘ and Osborn® have from time to time pub-
lished brief accounts of the few fragments available, but nothing
comprehensive on the osteological structure of these unique ani-
mals has been accessible in America until quite recently.

A short time ago Dr. W. J. Holland, Director of the Carnegie
Museum, gave the writer permission to submit to the Seventh
International Zoological Congress some brief notes on the splen-
didly preserved remains of Moropus elatus Marsh which were
secured by the Carnegie Museum from the Agate Spring Fossil
Quarry in Sioux County, Nebraska.

This important fossil quarry has yielded much material which is
now being prepared for study and publication. The quarry is
located in the valley of the Niobrara River in the Lower Harrison
horizon, and was evidently the bed of a stream, or perhaps the shore
of a small lake, during a portion of the Miocene time. The bones
were imbedded in a comparatively thin stratum of soft sandstone
which was quarried out in large blocks. ‘These were properly

*Read before the Seventh International Zoological Congress, Boston, Mass.,
August 21st, 1907.
Am. Jour. Science, Vol. XIV, pp. 249-251, 1877.
® American Naturalist, Vol. XXIII, pp. 149-151, 1889,
+ American Naturalist, Vol. XX VII, pp. 659-662, 1893.
ë Bull. Mus. Comp. Zool., Vol. XX, pp. 99-100, 1890.

733

734 THE AMERICAN NATURALIST [Vor. XLI

labeled with reference to their position in the quarry, in order
to trace the different skeletal remains which may continue from
one block to another. In working out this material, we find that
there are parts of skeletons which are articulated and associated.
As there has been doubt among palaeontologists regarding
Professor Marsh’s genus Moropus, I decided to present the figures
of some casts (Figs. 1-11). These were made, by permission of
Professor Schuchert, from the types which were described as bones:
of edentates by Marsh. By permission of the Authorities of
Yale Museum, these types are here illustrated for the first time,
and they quite correctly represent the specimens. With the types
are associated such specimens of Moropus from the Agate Spring
Quarry (Figs. 12-20) as will at once show the characters which
are identical.
EXPLANATION OF FIGURES 1-20
All figures 4 natural size
Type of Moropus distans Marsh. From the John Day Formation, Oregon.
Fia. 1.— Dorsal view of first and portion of second co-ossified phalanges.
Fic. 2.— Proximal articular view of the cuboid.
Fic. 3.— Dorsal view of a second phalanx.
Fic. 4.— Plantar view of the same phalanx.
Type of Moropus senex Marsh. From the John Day Formation, Oregon.
Fia. 5. —Dorsal view of the first and portion of second co-ossified phalanges.
Type of Moropus elatus Marsh. From the Miocene of Nebraska.
Fic. 6.— Dorsal view of distal end of second metacarpal.
Fig. 7.— Tuberosity of calcaneum
Fia. 8.— Dorsal view of EEE II and III.
Fic. 9.— Dorsal view of co-ossified first and second phalanges.
Fic. 10.— Dorsal view of patella.
Fia. 11.— Dorsal view showing the proximal end of a first phalanx.
Material of Moropus elatus Marsh, from the Agate Spring Fossil Quarry.
Miocene of Nebraska.
Fig. 12.— Dorsal view of a second phalanx.
Fig. 13.— Dorsal view of patella
Fie. 14.— Dorsal view of second metacarpal.
Fie. 15.— Proximal articular view of the cuboid.
Fia. 16.— An oblique view of the astragalus.
Fic. 17.— Dorsal view of co-ossified a and second phalanges.
Fic. 18.— Dorsal view of a first phalan
Fig. 19.— Front view of calcaneum
Fic. 20.— Dorsal view of motatara II and III.

No. 492] SOME AMERICAN CHALICOTHERES 735

FIGURES 1-20.

736 THE AMERICAN NATURALIST [Vor. XLI

The skeletal structure of Moropus is a unique combination of
characters. The phalanges are highly modified, terminating in
cleft ungues which were, no doubt, covered by heavy claws; other-
wise the skeleton is distinctively of an ungulate type, most closely
resembling the Perissodactyla. The fore limbs are longer than
the hind limbs; they, together with the clawed feet, must have
given to the animal a very peculiar appearance. Some species
are as large as an African rhinoceros, or even larger. In the
American Naturalist, March 1889, p. 151, Professor Cope estab-
_ lished a separate order (Ancylopoda) for these different forms,
which in the Miocene time extended over Europe, Asia, and
America. After a study of the recently discovered remains, which
include nearly all parts of the skeleton, the present writer would
place Moropus as a distinct genus, in the Chalicotherioidea which,
he is inclined to believe, should be considered as an aberrant
superfamily of the Perissodactyla, as it was provisionally regarded
by Professor Osborn’ in a recent publication.

_ At this point it is thought best to give a short description of a
few characteristic features in the osteology of the skeleton of Moro-
pus as we know it from the material in the Carnegie Museum at

Pittsburgh.
THE SKULL

No. 1707 Carnegie Museum Catalogue of Vertebrate Fossils.

The skull, on which these brief notes are based, was found in the
Agate Spring Fossil Quarry by Mr. W. H. Utterback. It is that
of a young individual, which, when found, was disarticulated. We
have not, as yet, found a perfect skull of Moropus,’ but aside from
this our material is quite complete. The parts, associated in this
skull, but which may not belong to the same individual, are the
occipital condyle, the basioccipital (No. 1707 A), and the lower

1 The Extinct Rhinoceroses. Memoirs of the American Museum of Natural
History, Vol. I, Part III, p. 79, 1898.

2 Professor Barbour of the Nebraska State University, Lincoln, Neb., was
fortunate in securing a fairly good skull of Moropus from the same stratum
on an adjoining hill.

No. 492] SOME AMERICAN CHALICOTHERES 737

jaws (No. 1711). The latter parts are here inserted (Fig. 21)
in order to give a better idea of the cranium. Since no foot bones
were found in connection with these skulls, a positive identification
of the species as elatus Marsh can not be made.

The skull of Moropus, as a whole, is of the long and narrow
type (Figs. 22 and 23) and is in a general way similar to that of
Macrotherium of Europe.’ In this young specimen from Nebraska
there is no sagittal crest. The braincase is sub-ovate in form and
of fairly large size. ‘The parietal is present on one side and is of

Fie. 21.— Moropus elatus ? Marsh. 4 natural size. Side view of the skull
of a young individual, No. 1707; side view of the lower jaw of a young
individual, No, 1711.

considerable antero-posterior diameter. Superiorly the bone is
very gently convex from before backward, and the two parietals
together meet the frontals in a broadly open U-shaped outline.
The frontal is quite broad over the orbit as in Meniscotherium
from the lower Wasatch, and the orbital border is heavy and some-
what overhanging with a large foramen near the margin. This
is well shown in the illustrations (Figs. 21 and 22). The supra-
temporal ridge is very faint; this may be due to the immaturity of

1 See Professor Depéret’s Memoir “Faune de Mammifères Miocenes de la
Greve-St. Alban”; Arch. Muse. d’Hist. Nat. d’Lyon V, Pl. IL., 1892.

ae

‘
My

ste ae, \\

-i

Top view of the skull

Fıc. 23. — Moropus elatus ? Marsh. 4naturalsize. Palate view of the skull
of a young individual, No. 1707.

740 THE AMERICAN NATURALIST [Vor. XLI

the specimen, but it continues from the inion to the orbital bor-
der. The orbit is located well forward on the skull and is open
posteriorly in a similar manner to that of the known European
forms. ‘The maxillary bone is high and the maxillo-premaxillary
suture ascends rapidly. The premaxillary bone of Moropus is not
known, but I judge that it attained a considerable length and was
perhaps edentulous or retained small incisors.‘ The infra-orbital
foramen is large and is placed above D*. The jugal is small with a
delicate zygomatic process. The zygomatic process of the squamo-
sal is equally small so that the arch is rather more delicate than
that represented in the European genus. The glenoid process is
of fairly large size and the space between the latter process and

Fic. 24. — Moropus elatus ? Marsh. 4 natural size. Side view of maxilla
of a young individual, No. 1709, showing p4 in an unerupted stage.

the paroccipital is occupied by the external ear and the mastoid in
much the same way as in the recent horse. ‘The external auditory
meatus is of fairly large size and is directed outward and very
slightly upward, not unlike that in Equus. Whether or not there
was a tympanic bulla cannot be determined from the material at
hand. The occipital condyle is large and there is a slight acces-
sory facet on the basioccipital. "The condylar foramen is of large
‚size and is situated immediately back of the paroccipital process at
its internal angle. The latter process is much elongated and sug-
gests that of the recent horse. In fact a number of osteological
features of Moropus suggest characters in the equine family of the
Perissodactyla.

Lower jaws of adults with incisors in place always show wear on the
median pair, while the lateral teeth are almost entirely unworn.

No. 492] SOME AMERICAN CHALICOTHERES 741

The molar-premolar series of Moropus has a general similarity
to that of the Titanotheres, but a brief comparison of the more
important differences is thought to be of interest in this connection.
The external walls of the upper premolars of Titanotherium are
excavated, forming a transverse median valley on the grinding
face of the teeth, while in Moropus the walls are highest in the
middle, and this portion of the tooth is not divided by a trans-
verse valley. ‘The internal cusps of all the upper premolars in
Titanotherium have a tendency to become divided so as to form a
larger anterior and a smaller posterior tubercle. In Moropus the
single tubercle is crescentic, especially on P*. On the molars of
Titanotherium there are two distinct internal tubercles, while in

m?
Fic. 25.— Moropus elatus? Marsh. 4 natural size. Crown view of the
Same specimen as Fig. 24.

Moropus there is only one tubercle and a transverse cutting lobe
on the posterior internal angle of the tooth. This transverse lobe
which unites with the external part of the tooth has apparently
taken the place of the posterior internal tubercle (hypocone) of
Titanotherium and is similar to that of Meniscotherium as was
pointed out by Professor Osborn in comparing the latter with the
known genera of the Chalicotherioidea.' The upper molars in
Moropus are relatively longer and narrower than in the Titano-
theridae; they are also longer and narrower than the upper molars
of the best known forms of Chalicotherioidea in Europe and Asia.?

* American Naturalist, Vol. XXVII., p. 127, February, 1893.
? On Plate III., figs. 3, 4, and 5 in Depéret’s Memoir, 1. e., are figures of
upper molars which more nearly agree in diameter with those of Moropus.

742 THE AMERICAN NATURALIST [Vor. XLI

The close similarity of the lower molar-premolar series of Chali-
cotherioidea to that of Titanotherium and Palaeosyops is well
known. As in the European forms, the present genus has also
the premolars reduced to three teeth in both upper and lower jaws,
while in the Titanotheridae there are four. P, in Moropus is quite
simple in structure, while P, is more nearly like P, in Titanothe-
rium. ‘The internal tubercle of P,in Moropus is somewhat heavier
than that in Titanotherium, otherwise the tooth suggests that of
the latter genus. M, and M, in Moropus are similar to those in
Titanotherium. M, in the latter genus has a prominent posterior
heel which is lacking in Moropus. This third lobe of M, is also
lacking in the Wasatch genus Meniscotherivm.

The deciduous upper molars (No. 1709) in Moropus are more
nearly molariform than are the permanent premolar series.’
Deciduous M* (d* and dm‘ in Figs. 24 and 25 respectively) may
very easily be taken for the permanent Mt, if extreme care is not
exercised in the study of the dentition. The permanent P* cuts
the alveolar border shortly after permanent M? is entirely erupted.

MEASUREMENTS OF THE SKULL

mm
Diameter of skull, from external auditory meatus to extreme
anterior point of maxillary, 305
Diameter of skull, from external auditory meatus to anterior
border of the orbit, 160
Diameter of skull, from anterior border of the orbit to extreme
anterior point of the maxillary, 150
‘Transverse diameter of the frontals over the orbits, 160

VERTEBRAL COLUMN

No. 1604, Carnegie Mus. Cat. Vert. Foss.

The vertebral formula of Moropus is for the most part based on
a skeleton, the bones of which were found disarticulated, but

1 Hatcher has pointed out this same characteristic feature in Titanotherium,
Annals Carnegie Museum, Vol. I, pp. 259-260, 1901.

No. 492] SOME AMERICAN CHALICOTHERES 743

quite close together, in the Agate Spring Fossil Quarry. As the
vertebrae are found to fit one another in a quite perfect manner,
there is very little doubt that the cervicals and the dorsals are,
excepting the eighth and eleventh dorsals which are evidently lost,
correctly represented by this specimen. We found seven cervicals,
thirteen dorsals, and three anterior lumbars belonging to the same
individual. The cervical and dorsal regions are apparently
quite complete, while three lumbars are lacking, but judging from
other individuals found in the quarry the complete number in the
lumbar series was six. ‘There was no sacrum with this individual,
but we know that there are four sacral vertebrae. The caudal
region is not fully known, but I judge that it attained a length
about equal to that in the rhinoceroses generally.

The Cervical Vertebrae.— For an animal with a comparatively
small head, the cervical vertebrae of Moropus are quite robust.
The general structure of the cervical region suggests that of the
recent horse. With the exception of the greater angularity of the
transverse process, the different position of the arterial canal and
the open atlanteal notch, the atlas might be taken for that of a large
specimen of Equus caballus. The axis is still more suggestive of
the horse, but the inferior keel is larger and the neural’ spine
higher,’ more overhanging in front, and somewhat more robust.
The articulation for the atlas has the same spout-shaped extension
anteriorly, but with the median protuberance relatively much
enlarged, forming a curious knob which doubtless represents the
primitive odontoid process. With the exception of the more pro-
duced condition of the centra posteriorly, the more broadly devel-
oped hypapophysial keels inferiorly, the higher neural spines, the
relatively heavier neural arches, and the larger zygapophysial faces,
the general make-up of the cervicals back of the axis in Moropus
is similar to-that in Equus. There is no vertebrarterial canal in
the seventh cervical. That the animal could easily reach the
ground with his head is very evident from similarities of the
cervical articulations to those of Equus caballus.

1 The axis of Macrotherium of Europe is described and figured by Professor
Depéret and presents the same general characters as that in the American
species, The neural spine of the former is relatively higher than that in the
latter species,

744 THE AMERICAN NATURALIST [Vor. XLI

The Dorsal Vertebrae. — Although the number of the dorsal
vertebrae in Moropus is less (there are thirteen present and two—
the eighth and eleventh dorsals — lost in the specimen under con-
sideration) they are perhaps more suggestive of those of Aceratheria
or Metamynodon from the Oligocene than those of the horse. ‘The
first dorsal in Moropus has a relatively longer neural spine than
that in the horse, and in this respect it resembles more nearly some
of the more primitive perissodactyls. ‘The seventh, ninth, and
tenth dorsal vertebrae in No. 1604 have complete neural spines.
It is seen that the neural spines of the latter vertebrae are relatively
shorter and have a more backward slope than in the horse. The
thirteenth and fourteenth dorsals have wide neural spines, which
are constricted antero-posteriorly at their bases. In these verte-
brae there are strong metapophyses. The fifteenth dorsal vertebra
in Moropus is quite characteristic and is different from all preced-
ing vertebrae. ‘The posterior zygapophyses have already become
convex in the same manner as in the lumbar region.

The transverse process is pierced at the base by a large foramen
and is further characterized by having a superior and an inferior
division. ‘The superior division of the transverse process is the
larger of the two and is directed outward, while the smaller inferior
division has a downward and backward direction. Between the
two divisions there is a deeply emarginated area, which is con-
verted into a thin bony bridge bounding the foramen referred
to above. On this and the succeeding vertebra (the first lumbar)
the metapophyses are the heaviest and they rapidly decrease in
size on the succeeding lumbars, while on the dorsals there is still
a very small metapophysial protuberance left on the seventh
vertebra.

Only the first three lumbar vertebrae are present in No. 1604,
the specimen under consideration, but from other material found
in the quarry it is quite certain that the complete series is six. The
three lumbars present are very robust, and possess broad neural
spines which are enlarged and rugose at the superior end. The

-zygapophyses are simply convex and concave with no additional
superior articular faces. The transverse processes are only mod-
_ erately developed. i

The Sacrum.— The sacrum (No. 1706) is composed of four

No. 492] SOME AMERICAN CHALICOTHERES 745

vertebrae well co-ossified, with high and backwardly sloping neural
spines which are all co-ossified and increase in robustness from be-
fore backward. ‘The neurapophysis of the first sacral is very heavy
and supports the greatest weight of the ilium, though the succeed-
ing three sacrals share in the support as there is a rugose attach-
ment for the ilium throughout the entire length of the sides of the
sacrum.

A number of caudals of considerable length, found in the
quarry, may belong to Moropus but this is not fully determined
at present.

In No. 1604, Car. Mus. Cat. Vert. Foss., the best preserved
skeleton of Moropus, there are present fifteen ribs of the right and
fourteen of the left side; the first rib of the left side is lost. ‘The
ribs are of moderate length, but robust, and the anterior ones are
expanded at the lower ends, indicating a heavy sternal attachment.

LIMBS

Nos. 1604; 1706; 1710; Carnegie Mus. Cat. Vert. Foss.

The structure of the fore and hind limbs of Moropus was briefly
described in a former paper,' and I wish here only to call attention
to a few of the more important features which are shown in the
splendidly preserved material in the Carnegie Museum.

The Fore Limb.— The scapula of Moropus is quite large. It is
plainly of a perissodactyl type, and resembles most closely that of
‚Aceratherium tridactylum Osborn. As in the latter genus the spine
is prominent and overhangs the post-scapular fossa in a similar
manner. The humerus, radius, and ulna of Moropus, as a whole,
are quite like these parts in the European genera.” The humerus
of Moropus has a heavy deltoid ridge, which extends well down
on the shaft. The greater tuberosity is also quite robust and the
bicipital groove is single and moderately deep, but quite broad.
The distal end is much expanded transversely and suggests that of

1 Annals Carnegie Museum, Vol. IV, No. I, pp. 60-61, 1906.

2 In Macrotherium grande the fore limb is relatively ae than in Moropus
according to the figures and description of Professor Depéret, “La Faune de
Mammiföres de la Greve-St. Alban” Pl. IV, Figs. 2 and 9.

746 THE AMERICAN NATURALIST [Vor. XLI

Phenacodus from the Wasatch. The trochlea is broad with well
rounded articular surfaces for the radius and ulna. The anconeal
fossa is quite deep and broad, but low. In this specimen (No.
1604) the radius and ulna are entirely co-ossified. On the radius
the external articular facet for the humerus is considerably larger
than the internal, while on the ulna the internal articulation is very
extensive. On a direct front view the head of the radius lies in
front of the ulna, but immediately below the head on the external
side, the shaft of the ulna again appears. The olecranon of the

A
Fic. 26. — Moropus elatus Marsh. About } natural size A, the left fore
foot of skeleton No. 1604. B, the left hind foot, No. 1710, which

belongs with another skeleton.

ulna is rather truncated. ‘The distal end of the radius and ulna
together have a transversely broad aspect; the carpal articulation
is characteristically plain without the prominent border which sep-
arates the scaphoid and lunar facets in other Perissodactyla. The
articular surface for the cuneiform on the ulna project only very
slightly below the radius and form, with the lunar articulation on
the radius, a continuous and gently curved surface. The suture

No. 492] SOME AMERICAN CHALICOTHERES 747

between the radius and ulna is, however, well indicated on the
distal articulation of the bone.

The Manus.— The manus of Moropus has four digits, three of
which are functional and one (the fifth) rudimentary. This
rudimentary fifth metacarpal is not supported by the unciform,
but articulates with the fourth metacarpal by fairly well formed
facets. Me.V ! in No. 1700, Car. Mus. Cat. Vert. Foss., is much
slenderer and attains only three-fourths the length of me. IV. The
distal trochlea of me. V., in No. 1700 is quite imperfect and the
digit had perhaps only one phalanx. The trapezium is present
and articulates with me. II, the trapezoid, and the scaphoid, but
there is no indication of a first digit. The heavy protuberance
on the scaphoid of Moropus which reaches over the trapezoid and
articulates with the magnum may be represented by the centrale in
Meniscotherium.” The magnum has a heavy protuberance on
the anterior face which extends dorsally and forms, on the distal
face, a rough articular surface for the proximal end of me. II;
on the palmar face is a short but heavy hook, and the total vertical
diameter of the bone is much greater than is apparent on a direct
front view of the manus. The second metacarpal, though shorter
than the third and fourth, is the heaviest in the series. The third
metacarpal is the longest, consequently the second and third digits
in the manus of Moropus supported the greatest weight; therefore
the manus is more nearly mesaxonic than was anticipated. It is
different from the European genus from Sansan in which me. IV
is the longest.

In the manus of Moropus, the first and second phalanges of the
second digit are co-ossified, an important character which Professor
Marsh luckily discovered in three different individuals. This
now proves to be of perhaps a family importance.* The ungual
phalanx of the second digit is much larger than those on the third

1 In No. 1604 the fifth metacarpal is wanting, but the articular facets of me.
IV plainly indicate its presence.
Amer. Jour. Science, Vol. XLIII, p. 447, 1892. (H yracops socialis Marsh.)
* From Cope’s statement in the American Naturalist, March, 1889, Vol.
XXIII, p. 153, I infer that Lydekker has said that “ Ancylotherium ” Gaudry
has the first and second phalanx co-ossified. Good casts of the latter genus
are exhibited in the American Museum of Natural History which confirm
this statement.

748 THE AMERICAN NATURALIST [Vor. XLI

and fourth, and is more conspicuous than that of the European
form from Sansan. In Moropus as in “Ancylotherium” this
large ungual has a comparatively limited dorsal flexure, as there
is a shoulder near the dorsal border of the distal trochlea of this
duplex bone and a corresponding buttress on the articulation of
the terminal phalanx; thus furnishing additional strength in the
use of this digit.

Hind Limb.— The pelvis (No. 1706) of Moropus may be re-
garded as long and narrow. In comparing it with that of Perisso-
dactyla generally it is relatively longer in the region back of the
acetabulum, which feature is artiodactyl rather than perissodactyl.
Altogether, the pelvis of Moropus most nearly agrees with that of
Aceratherium tridactylum. As in the latter genus, the neck of the
ilium is long with a rapid expansion near the supra-iliac border,
but this border is less emarginated than in Aceratherium. In
Moropus the acetabulum is deep, and the pit for the round ligament
is of large size and is confined to the region back of the median
line. The obturator foramen is ovate in outline and of medium
large size. The pubic symphysis is quite strong anteriorly, but in
No. 1706, Carnegie Museum Cat. Vert., Foss., the ischium di-
verges outwardly more than is usual in other specimens.’ As
stated elsewhere, the femur has a strong third trochanter, which
is located above the middle of the shaft. The bone as a whole
resembles that of Titanotherium, but is relatively heavier and
shorter. The tibia is short and heavy; it is about four-fifths
the length of the femur. The articular facets for the femur are
divided by a prominent spine, the cnemial keel is heavy and extends
well down on the shaft, and the distal trochlea is characteristically
rhinocerotic. The fibula is complete, but its shaft is comparatively
delicate and has an even curvature from above downward so that
it lies close to the shaft of the tibia throughout; the distal end
extends below the external articular facet of the tibia and articu-
lates with the astragalus, but does not always touch the calcaneum.?

! The peduncle of the pubis in this specimen was badly crushed on one side
and partly lost on the opposite side which may, in part at least, account for
this difference.

? Some specimens have a minute articular facet for the fibula on the cal-
caneum,

No. 492] SOME AMERICAN CHALICOTHERES 749

The Pes.— In a general way the tarsus (No. 1710) in Moropus
is much like that of the Rhinocerotidae. There are, however,
many differences viz: the navicular is supported entirely by the
astragalus and the cuboid by the calcaneum as in Meniscotherium.
The trochlea of the astragalus is somewhat more deeply grooved,
the internal and external condyles are more even in size and the
external condyle is not interrupted as in Titanotherium, but con-
tinues below the articular facet for the navicular. The pes is tri-
dactyl; there is no indication of lateral digits. ‘The second meta-
tarsal is shorter and also somewhat lighter than the third and
fourth which are of equal size. ‘The articulation for the proximal
phalanx is confined almost entirely to the dorsal face of the
bone, while on the plantar face are deep, broad grooves, which
are divided by heavy keels. ‘The sesamoids are very heavy and in
some cases they are co-ossified, forming a broad open groove for
the tendons. As in the fore foot the claw-bearing ungulae are
deeply cleft, but of more nearly equal size.

From the study of the foot and limb structure of Moropus it is
very evident that the animal was digitigrade. Professor Osborn
has called attention to the fact that the European forms were
“ almost certainly sub-digitigrade.”’ *

The remains above described (No. 1604) belong to an individual
very nearly the size of Chalicotherium goldfussi of Europe, or the
size of a small specimen of Titanotherium from the American
Oligocene. Smaller remains are more common in the quarry,
indicating two or more species, or a great range of individual
variation. This question will be taken up in a later publication.
There are perhaps twenty individuals of Moropus represented in
the collection of the Carnegie Museum, which were secured in the
Agate Spring Fossil Quarry.

Discussion OF AFFINITY AND PHYLOGENY
In Chalicotherium goldjussi Kaup, P* has the internal face of
the ectoloph W-shaped and the internal tubercle of a different form
and more distinctly separated than in the American genus. In the

* American Naturalist, Vol. XX VII, pp. 118-119, 1893,

750 THE AMERICAN NATURALIST [Vor. XLI

latter, the ectoloph is simpler, and the internal tubercle is crescentic,
as in the Artiodactyla, the posterior and anterior horns being firmly
united with the ectoloph so as to form, of the median valley, a deep,
but rapidly sloping pit. This is best seen in an unworn tooth.
The upper molars, especially M? and M’, in Moropus are relatively
longer and narrower than in Chalicotherium goldfussi. ‘The teeth
in the latter species appear to have more nearly the same propor-
tionate diameter as in the Asiatic forms C. siense and C. sivalense.'
The more important differences between C. sivalense and C. siense
as pointed out in Professor Owen’s paper (l. c. pp. 431-432) are
as follows: “the anterior part of the interval between the post-
external (b) [b = reference to the illustrations in Owen’s paper]
and the postinternal (d) lobes is not closed by a ridge descending
from the summit of the postexternal lobe as in Chalicotherium
sivalense: nor does the inner side of the antexternal lobe terminate
in so ridge-like a way as in Chalicotherium sivalense.” ‘The con-
dition of the post-external and post-internal lobes, as well as the
‘“ridge-like” ant-external lobe of M? in Moropus agree more
closely with Owen’s statement of C. sivalense; and M, in Moropus
is very nearly of the same size and of the same general character
as that in ©. goldfussi, but the relative diameter,’ together with
other less important differences of M? in the European and Asiatic
forms, is entirely unlike those in Moropus.*

Phylogeny.— The best evidence at the present time points rather
towards a European * than an American ancestry of Moropus.

1 Quart. Jour. Geol. Society, London, Vol. XXVI, p. 431, 1870.

2 For measurements of upper teeth of Moropus see Annals Carnegie Museum,
Vol. IV, No. I, p. 63, 1906.

3 Chalicotherium (Ancylotherium) pentelici, from Pikermi, Greece, has the
upper molars longer than broad, and in some other respects most nearly agree
with the American form.

*Schizotherium Gaudry of the European Oligocene is undoubtedly an
ancestor of the family. And it is likely that some European Eocene form
allied to the early perissodactyls will be found to be the true ancestor, Some
characters of Palaeotherium are suggestive of the Chalicotherioidea.

Nore: While at the International Zoological Congress in Boston, I discussed
the phylogeny of Chalicotherioidea with Professor Depéret who kindly added
the following note: “Le plus ancien type européen des Chalicotherioidea est
le Pernatherium Gervais, du calcaire de St. Ouen près Paris: il est de l'étage
Bartonien, c’est à dire, à peu près du Bridger supérieur (voir Journal de Zool-
ogie.) ” #

No. 492] SOME AMERICAN CHALICOTHERES 751

Professor Osborn has pointed out Meniscotherium from the
American Eocene (Wasatch) as a possible ancestor of the Chali-
cotherioidea.* It would seem that when better specimens of Moro-
pus distansgare found in the John Day formation, it will become
necessary to separate, generically, Moropus elatus from Moropus
distans. ‘‘Chalicotherium bilobatum” Cope from the Oligocene
of the Swift Current Creek in Canada, if correctly identified, is
of course a much earlier form than Moropus elatus from the Mio-
cene of Nebraska. The remains which Professor Scott reports
from Montana (Deep River) may perhaps represent a transitional
form between Chalicotherium bilobatum and Moropus elatus.
These appear to be the evidence which we have of the presence of
the chalicotheres in the American Tertiary. The little known
Spenocoelus uintensis Osborn from the Uinta beds? bears some
resemblance to the Chalicotherioidea as was pointed out by Osborn
(l. e. p. 102), but the specimen (the posterior portion of the skull)
is too imperfect for accurate comparison. While Meniscotherium
may not be a true ancestor of Moropus there are in the latter cer-
tain affinities è to the former which are of much importance and
which point to the ancestral types of the stem of the Perissodactyla.

CONCLUSION

The conclusions drawn from the material studied may be summed
up as follows: (1) That Moropus is, excepting its unguiculate feet,
essentially a perissodactyl in structure. (2) That the laterally
compressed and cleft condition of the terminal phalanges is quite
distinct in some of the early Perissodactyla,* and that by adapta-
tion through geological ages the unguals as well as other parts of
Moropus were specially modified, and should not, in the mind of

* American Naturalist, February, 1893, pp. 118-133.

? Bull. American Museum of Natural History, Vol. VII, pp. 98-102, 1895.

? The absence of the 3rd lobe of M,; the 3rd trochanter of the femur, and the
navicular en proximally, only by the astragalus and the cuboid by
the calcane

“It is ee known that Euprotogonia and some species of Phenacodus have
the terminal phalanges laterally ze intermediate between hoofs and
claws. The early horses have cleft ungues

Oe THE AMERICAN NATURALIST [Vor. XLI

the writer, be regarded as of ordinal importance. (3) That Moro-
pus is generically separable from other known forms of the Chali-
cotherioidea.

The illustrations are from drawings made by Sidney Prentice
and photographs made by A. 5. Coggeshall.

CARNEGIE MUSEU
Pittsburgh, Pa., Aug. 2, 1907

OBSERVATIONS ON THE NATURAL HISTORY
OF POLYODON SPATHULA

CHARLES R. STOCKARD

During the springs of 1904 and 1905 I visited the regions in which
Polyodon attains its largest size and occurs in greatest abundance.
I had been aware for several years of the existence of this fish in
great numbers in the lakes bordering the lower Mississippi River.
On mentioning this fact to Professor Bashford Dean, he suggested
to me the desirability of visiting these lakes with the object of
obtaining the eggs and developmental stages of this peculiar fish.
My best thanks are due Professor Dean for this suggestion, and
for placing at my disposal during both years the Dyckman Fund
of the Zoological Department of Columbia University with which
to defray the expenses of the trips.

Most vertebrate embryologists and particularly those familiar
with the development of the ganoids will admit, I believe, that a
knowledge of the development of Polyodon is greatly desired.
The ganoids at present furnish an almost complete and one of the
most instructive comparative embryological series. ‘The series
is incomplete, however, in that nothing is known of the develop-
ment of either member of the order Selachostomi. ‘This order
comprises only two species, Polyodon spathula and Psephurus
gladius. ‘The former is found in the Mississippi River and its
tributaries; the latter is known only in some of the rivers of China.
Thus they have a decidedly discontinuous geographical distribution.

I spent from March first to April fifteenth, 1904, in Concordia
and Catahoula Parishes of Louisiana, and from April first until
May eighteenth, 1905, in Washington County, Mississippi, and on
the White River in Arkansas. During this entire time efforts
were made to obtain spawning Polyodon. Although unfortunately
I failed to secure any of the embryonic stages, I succeeded, during
the three months on the lakes and rivers where this fish is so
abundant, in making many observations on its habits. The
present paper contains a brief account of the behavior of the fish

753

754 THE AMERICAN NATURALIST [Vor. XLI

during the spring and early summer seasons, and conveys some
idea of the great fishing industry to which it has given rise within
the past twelve years.

DESCRIPTION OF POLYODON

Polyodon in the lakes bordering the lower Mississippi River
attains a much greater size than in the Ohio and upper Mississippi
River region. Museum specimens and those obtained in the more
northern parts of their range are rather small fishes. In the
metropolis of their distribution, however, they often attain a length
of almost six feet, the longest one observed by the writer being
five feet and nine inches from the tip of the tail to the end of the
snout. Their weight often exceeds one hundred pounds; one
hundred and forty-two pounds was the maximum record in Lake
Washington, Mississippi, where the fish were larger than in any
other lake visited. 3

The shape of Polyodon is shown in the accompanying photo-
graph, Fig. 1. Note the contrast between the slender shark-like
form of the middle individual, which is a characteristic river-fish,
and the heavily proportioned body of the lake-fish, on either side.

The color of these fishes during the spring differs only slightly
from that at other seasons. The back and dorso-lateral portions
are of a steel or slate-like hue while the ventral and ventro-lateral
parts are a glistening milk-white. The fins of most mature indi-
viduals show a delicate tinge of salmon-pink, but in others the fin
color partakes of the general slate-like appearance of the dorsal
portions. The general color of several fishes that were obtained
shortly after spawning was of a peculiar reddish tint, being several
shades lighter than the normal slate color. In two “spent” in-
dividuals this color difference was detected as they swam in the
water before being lifted from the seine. The anal region of these
fishes showed a dark purplish-red color and their ovaries gave
unmistakable evidence that spawning had occurred. No indica-
tion of sexual dimorphism could be detected, the males and females
being indistinguishable in their color, size, and shape, and in the
proportions of their external body appendages. A female with

No. 492] POLYODON SPATHULA 755

her ovaries filled with eggs of the season was usually recognized by
the distended condition of the abdomen and yet even this distinc-
tion was not always valid since the males when fat and in good con-

Fig. 1.— Three large specimens of Polyodon. The middle = from the
river, is thin and slender, showing a torn fin and scars ah pee
migratin In contrast, the ra fishes on Fran side a = t an rell
rounded, the one on the left eg an ae keiten er
although it is a male.

dition have so extensive a mass of adipose tissue about the testes
that their abdomen is almost equally swollen. The fat about the
testes of one male was found to weigh three and three-quarters

pounds.

756 THE AMERICAN NATURALIST [Vor. XLI

The larger females contain an enormous number of eggs. Six-
teen pounds of roe was the heaviest single yield observed, but the
maximum is no doubt greater; ten to twelve pounds was an average
yield. The egg resembles that of Acipenser very closely in size
and color. It is slightly oval in shape with the polar diameter
longer and measuring about 2.7 mm.; the equatorial diameter is
only about 2.2mm. Itis of a dark brown or blackish color. There
is a considerable polar differentiation, the animal pole of the egg
having a cap of lighter colored protoplasmic material with a rather
distinct dark ring about its lower border. The denser deuto-
plasmic part of the egg is gradually located about its lower, vegetal
pole.

Various measurements were made on a number of fish in the
hope of discovering some sexual difference. While making such
measurements a rather interesting ratio was found to exist between
the length of the fish and that of the snout, as will be seen by refer-
ring to the accompanying table. In the table the individuals
are arranged in the order of their lengths, the longest fish being
at the top of the column. The entire length of the fish is expressed
in inches in the first column and the length of the rostrum, from
the anterior border of the eye to the tip of the snout, in the third
column; by dividing the latter measurement by the former in any
one case, the decimal given in the fifth column is obtained. The
decimal, then, represents the fraction of the entire body length
which is formed by the snout, and it is seen by comparing the data
given for fifteen individuals selected at random, that the propor-
tionate length of the snout decreases gradually and quite regularly
as the fish increases in size. In other words a small fish, about
two feet in length, has a snout one-third of the length of its body
or eight inches Jong; and the large fishes, like the third and eighth
individuals of the table, may have snouts less than one-fourth of
their body lengths. Between these extremes one finds a regular
gradation as is shown in the fifth column of the table.

No. 492] POLYODON SPATHULA 757

TABLE I.
ne Sex et Weight rostrum length -~ Remarks
69 Q 17.87 — .258 Lake fish. 8 lbs. eggs.
67 g 17.00 43 lbs ‚253 Lake-fish
66 Q 15.10 H 238 River-fish
63 ‘ot 16.50 2 * 264 Lake-fish,
63 Q 15.75 90: .250 Lake-fish. 12 lbs. eggs.
62 Q 16.00 Bro .258 Lake-fish.
60 fot 15.90 Se .266 Lake-fish.
59 rot 14.00 w” Bat Lake-fish.
53 Q 13.590 = ‚254 River-fish.
Bl... 13.50 ae .265 Lake-fish,
49 Q 13.10 aoo .267 Lake-fish.
44 Q 12.00 25 272 Lake-fish.
36 Q 10.20 18 7” .283 Lake-fish.
30 g 9.00 —— .300 Lake-fish.
24 rot 8.00 aa 335 Lake-fish.

By means of the above proportion one may calculate approxi-
mately the size of a fish from a small drawing. To test this I
measured and calculated the proportion of length of rostrum to
length of body in the Polyodon figured in Jordan and Evermann’s.
Pl. XX, figs. 43 and 43a; the proportion found was .327 which
according to the table would indicate that the specimen was about
twenty-five or twenty-six inches long. Calculating from the inch
line which accompanied the figure I found that the specimen was.
27.2 inches in length, a very close agreement with my expectation.

From a few comparisons made between fishes living in the lakes
and those in the river, it appears that the river fish have shorter
and broader snouts in proportion to their entire body length than
those living in Lake Washington.

Haunts AND HABITS or PoLYLDoN

The lakes in which these fishes are found in great abundance are
the old “cut off” lakes of the Mississippi River. ‘These crescent
or horse-shoe shaped bodies of water were formed from time to
time as the course of the river changed. Some of them are at
present almost completely separated from the river, being con-
nected only by a long chain of bayous and lagoons, oftentimes.

758 THE AMERICAN NATURALIST [Vor. XLI

almost one hundred miles in length. Other such lakes still retain
a direct connection with the river and are termed by the fishermen
“river-lakes.” In these there is a current which often becomes
very strong during the spring freshets, when the water of the
Mississippi River rises.

Lake Louis in Catahoula Parish, Louisiana, is a very old lake,
being now only from one to three hundred yards in width and about
six miles long. During the spring floods the Ouachita River sends
a large volume of “backwater” into it, sometimes causing it to
rise as much as twenty feet. In many places the lake is from
forty to fifty feet deep. Polyodon exists in this lake in large num-
bers, but it is an undesirable place for seining and therefore offers
poor facilities for the study of the fish. Lake Washington in
Washington County, Mississippi, is by far the richest source of
Polyodon that I have been able to locate. This lake is a beautiful
body of water more than one mile across in several places, and
about twelve miles long. It connects with the Mississippi through
about seventy miles of smaller lakes and bayous. As many as
one hundred and fifty barrels of Polyodon have been caught in
this lake at one haul of the enormous seine described below.

Polyodon, like most large fish, frequents the deeper portions of
these lakes and is rarely caught in the shallower parts. It is almost
never found in lakes less than ten feet in depth. Usually it is
caught in those parts of the lakes having soft muddy bottoms,
the sections with hard sandy bottoms yielding no Polyodon when
seined. This is due to the feeding habits of the fish. The main
diet of Polyodon consists of small Crustacea, usually copepods.
These are very probably obtained by stirring the muddy bottoms
and gulping in the agitated material, which is then effectively
strained by means of the long slender gill-rakers, so that only the
small arthropods remain in the mouth to be swallowed. One may
often scrape more than a double-hand-full of these Entomostraca
from the mouth of a Polyodon freshly brought up by the seine.
The copepods were often alive, with their egg strings still intact,
and in good condition for preservation. Jordan and Evermann
state that “They (Polyodon) feed chiefly on mud and minute
organisms contained in it, stirring it up with the spatulate snout.”
One must surmise from the general structure of the mouth and

No. 492] POLYODON SPATHULA 759

gill-rakers that they feed on minute organisms, but Jordan and
Evermann are surely in error, so far as my observations on some
four hundred stomachs go, in stating that they feed chiefly upon
mud. No doubt some fine mud or silt is taken into the throat
along with the food, but it appears to be well strained out, since
scarcely any mud has been found in the many stomachs examined.

IG ntral and dorsal views of a Polyodon measuring 4 feet and 7 inches.
Fis oun had been broken off during life and the wound had healed as seen
in the photographs.

The contents of several stomachs were preserved in mass, and little
if any silt has settled out from the animal material.

The function of the peculiar long rostrum or snout has not been
definitely determined. ‘There are some reasons for believing that
the organ is used in procuring food but the following facts indicate
that it is not essential for such a purpose. During the two springs

760 THE AMERICAN NATURALIST [Vor. XLI

three specimens were found which had, through some mishap, been
left with only stumps of their snouts. Fig. 2 shows a photograph
of such a fish. In each case the fish was large, two being nearly
four feet in length and the other measuring four feet and seven
inches. In each the injured part of the snout was well healed,
but no indication of regeneration of the organ was shown. It is
evident from these individuals that this fish without the aid of
its snout is capable of procuring food enough to maintain a large
body. Moreover if the appendage was lost while they were yet
small, they had succeeded in increasing in size without their
“spatula with which to agitate the mud.”

Fishermen state that large holes are often rooted out in the lake
bottoms by the digging of Polyodon with its “paddle.” In the
bottoms of drained lakes, places resembling “ hog-wallows” are
found, which Polyodon is thought to have dug while feeding.
Such statements are difficult to substantiate and yet there is prob-
ability that they are true, for there are immense numbers of
Polyodon herded in one of these almost land-locked lakes, and
they feed over the muddy bottoms.

Observations on the general behavior of this fish lead me to a
rather skeptical position regarding the foraging value of the ros-
trum. I am inclined to regard it more as a tactile organ since
the sense of sight is of so little use to the fish while swimming
forward. Again its use for digging seems to be restricted as in-
dicated by the actions of this fish when its rostrum strikes against
any foreign object. When, for example, Polyodon is surrounded
by a seine and happens to swim against the net at any place, it
very often stops when its rostrum strikes the net; sometimes it
continues to push forward by one or two indifferent efforts, and
then gives up entirely, turning over on its back and floating along
the cork-line of the seine. In a large haul fifteen or twenty fishes
may be counted floating along the cork-line with their white ventral
surfaces turned upward. Sometimes they may float thus on the
outside of the seine and stupidly allow themselves to be picked up
by the fisherman who guards the line in a row-boat, in order to
catch the fish that float over while the seine is being hauled in.
The larger and more active fishes often strike the seine several
_ times before surrendering, but even they show but little ability

No. 492] POLYODON SPATHULA 761

to back-off when their snouts strike against the net. From such
actions one is led to think that if these fish should swim with much
force into mud of a very viscid consistency, they would oftentimes
be trapped, for from the above observations they appear too stupid
to pull back and loose themselves. Since the fish lacks the power
to turn its head from side to side, it cannot stir the mud with its
spatulate snout, as Jordan and Evermann claim, but must agitate
the silt by a general movement of its entire body. In this process
the spatula no doubt plays an important röle since it is a consider-
able portion of the anterior end of the body.

The food of Polyodon is extremely abundant in the lakes, and
they grow to be very large and heavily proportioned in such places.
One may distinguish almost at a glance between a fish that has
lived in the lakes and one from the river; the latter is poor and
slender as compared with the former. ‘The lake-fish contains a
much heavier roe, averaging ten or twelve pounds, whereas river-
fish often have only three or four pounds.

The stomach of Polyodon, in addition to its crustacean diet,
contains great numbers of a cestode parasite, Dibothrium hastatum
(Linton). Hundreds of these little yellow-headed ne
measuring three or four inches in length are often present in
single stomach.

Polyodon like Lepidosteus 1 is treciivontly seen to leap from the
water during the spring; the leaping at this season is not so com-
mon, however, as it is later in the year. During the summer months
one may often see several of these large fishes in the air at the same
time. They make a vigorous jump, usually clearing the water
entirely, and at times turning over backwards in the air so as to
enter the water either head foremost or by striking on their backs.
Apparently one fish may sometimes be seen to jump repeatedly
at short intervals near the same spot. ‘The, object of such leaping
is difficult to detect unless it be on account of the stagnant and
poorly aerated condition of the water during the dry summer,
when it becomes unusually low in these lakes.

Polyodon shows a considerable migratory tendency. During
the spring, when the water of the Mississippi River rises for several
feet and backs into the bayous, thus establishing connections with
the large lakes, Polyodon begins immediately to come into the

762 THE AMERICAN NATURALIST [Vor. XLI

lakes from the river and continues to come in large numbers so
long as a sufficient connection is maintained. ‘To do this it must
often make long journeys through rather shallow water in which
many obstructions, such as bushes and trees, are frequently met.
Thus it finally reaches the lakes in a rather emaciated condition
and with its body scarred and scratched. By referring again to
Fig. 1 the river-fish in the middle will be seen to show such marks
even in the photograph. It is equally true that the fish in the
river-lakes (those lakes more directly connected with the river)
migrate out into the river when the water begins to back in during
the spring, so that fishermen often abandon their fishing in these
places at such a season, since most of the desirable Polyodon have
made their escape.

SPAWNING HABITS

I was unable, on either of my trips, to find fishes in a “running”
condition or to locate a party in the act of spawning. By con-
stantly watching the fish and taking numbers in the seine each
day I concluded that the breeding season in this region occurs
about the middle and latter half of April. The fish seem to breed
only in running water, most probably in the bayous and small
wooded lakes connected with the Mississippi River. My reasons
for such conclusions may be gathered from the following observa-
tions. ;

During the first half of the month of April five females were
taken which had their ovaries well filled with almost mature eggs.
On April 4, 1905, three females of not unusually large size were
examined and contained respectively sixteen, thirteen, and twelve
pounds of roe. Such fish were taken in the lakes until shortly
after the first of May when the following condition was observed.
On May 5th a female five feet and nine inches in length, which
weighed eighty pounds, was found to contain only eight pounds of
eggs. Many of these eggs had taken on a whitish appearance and
were very soft, so that on attempting to strip them from the ovarian
membranes they broke and formed a milky pulp. After this time,
fish from five different lakes were examined and all were found to
be in a similar condition. Not one male Polyodon in any of the

No. 492] POLYODON SPATHULA 763

lakes was found to be “running” although I examined from ten
to twenty on almost every day from April 1st until May 13th, 1905.

A number of males and females were from time to time placed
in a large wire-netting pen, with the object of keeping them until
they reached the spawning condition. Some of these lived in the
pen for four or five days but rarely longer, although the pen was
twenty feet square and rested on the bottom of the lake. The
larger ones are especially difficult to keep in confinement. The
eggs of the confined females soon began to degenerate and soften,
like those of the lake-females mentioned above.

After April 10th, 1905, the Mississippi River began to rise and
river-fish were taken in Lake Washington after April 14th; several
of these females on dissection were found to have spawned. The
ovaries contained only a few defective eggs still attached to the
membranes of their ventral border. The anal region was inflamed
and other external appearances, such as their lighter pinkish color,
made it practically certain that these fishes had deposited their eggs
in anormal manner. I then concluded that the large fat lake-fish
was unable to spawn in the still waters, and that its eggs were
absorbed within its body after they began to degenerate. The
males also seem to fail to arrive at the “running” stage, as none
were observed in such a condition during either season.

An attempt was made to locate a spawning party in the running
bayous leading into the river. On May 16th, 1905, great numbers
of Polyodon were seen swimming and darting in all directions
near the surface of the water in a small bayou in Washington
County, Mississippi. This was the first time these fish had been
observed swimming near the surface, and their spirited actions
made one think them a spawning party. A zig-zag gill net one
mile in length was dropped in the midst of these fish and within
less than one hour one hundred and thirty-three large Polyodon
had been lifted into the flat boat. On examination they proved
to be river fish that were migrating up the bayou into the lake. All
of the mature ones had apparently spawned some time before.
They doubtless spawned near the mouth of this bayou which was
about sixty miles distant, and with the rising water they began to
swim up toward the lake. The fact that the lakes are so readily
depleted of their stock of Polyodon by seining and are not again

764 THE AMERICAN NATURALIST [Vor. XLI

able to repopulate themselves also indicates that the fish are non-
productive in such places. Lakes that have been exhausted of
Polyodon will remain so for years, unless the river rises sufficiently
to permit the immigration of more fish to restock them.

Only one man was found who had probably observed Polyodon
in the act of spawning. He related the way in which he had rowed
a boat into a party of “Spoon-bills” during April several years
before, and had succeeded in killing nine of them with an oar with-
out being able to frighten them from the place. He said that this
occurred in the edge of a wooded overflow border of a bayou,
several miles from where it ran into the river.

It is curious that Polyodon does not spawn in the large clear-
water lakes since the related Lepidosteus osseus and L. tristoechus,
both being ganoids abundant in this region, spawn in great num-
bers in these lakes. A spawning place of Lepidosteus was visited
on April Ist, 1905, though at this time only a few unhatched eggs
remained and all of the larvae had swam away. The fisherman
informed me that this party had spawned about March 15th.
“Runners” of both species of Lepidosteus were taken in the seine
until April 20th, so that their spawning season seems to continue
here for several weeks.

METHODS or CATcHING POLYODON

The commercial value of Polyodon is scarcely indicated in
Jordan and Evermann’s statement, — “the flesh [is] coarse, resem-
bling that of the larger cat-fishes, but inferior in quality.” For the
past ten or twelve years the roe of Polyodon has been used as a
commercial substitute for sturgeon caviar. Generally the Polyo-
don eggs are mixed with those of the sturgeon, so that the less
attractive flavor of the former is not so evident. The flesh of
Polyodon is shipped to the northern cities where it is dried or
smoked and sold in the markets as dried sturgeon. The rapid
decrease in the supply of sturgeon for the last ten or fifteen years
has caused a strong demand on the part of the dealers for a substi-
tute, and until now Polyodon is the only one successfully tried.
‘The demand for Polyodon has caused an extensive fishing industry

No. 492] POLYODON SPATHULA 765

to spring up in the lower Mississippi River region, until it has
become the most valuable fish of these waters. This fishing
industry is conducted in various degrees of perfection, and some
of the more intelligent fishermen have very extensive apparatus
for procuring Polyodon. On Lake Washington, Mr. McGehee,
through whose kindness I was enabled to make most of the obser-

G. — The upper photograph shows a crew of Polyodon fishermen putting out
a seine rang two miles in length; in the lower es they are winding it
inonther

vations above recorded, directs a most efficient fishery. He runs
two seines, one nearly two miles long and thirty feet deep, the other
about one mile long and fifteen feet deep, for use in shallower
water. These huge seines are wound upon a large reel which is
constructed on a heavy barge. In laying out the seine for the
catch, the barge is towed by a gas launch around a circular area

766 THE AMERICAN NATURALIST [Vor. XLI

more than a mile in circumference. The barge is then securely
anchored and a crew of about a dozen men proceed to wind in the
seine by means of the reel, as shown in the photograph, Fig. 3. It
requires usually about four hours to haul the seine. Great num-
bers of Polyodon are caught in such a manner, more than one
hundred and fifty barrels bring the record for a single haul in Lake
Washington.

The roe or caviar is much more valuable than the flesh of the
fish, and during my stay on these lakes there was an average of
one caviar fish to every twenty-four other individuals. ‘The roe
is taken from the fish enclosed in the ovarian membranes and
then strained through a screen which serves to separate the eggs.
A liberal amount of a calcium-free sodium-chlorid salt is then added,
and the eggs are packed in kegs for shipment to the markets. One
fisherman may ship as many as seventy-five of these hundred and _
fifty pound kegs in a single season, from November to April.
At such a rate one is not surprised to learn that Polyodon has.
decreased greatly in numbers since the beginning of this new
industry. At present many lakes that were formerly crowded
with these fish are completely depopulated. The methods of sein-
ing are very exhaustive and as above mentioned the lakes are only
restocked when the river rises sufficiently, which may not occur
for a period of several years. River seining is almost impossible
owing to the strong currents. This industry though in its infancy
is decidedly on the wane; many of the most prosperous fishermen
have now abandoned it entirely on account of the great decrease in
the number of fish. Such an extensive apparatus is essential
for taking the large Polyodon that the fishing is unprofitable unless.
they are caught in great numbers.

As I have stated, my attempt to secure material for a study of
the embryonic history of Polyodon was unsuccessful. "The observa-
tions presented in this paper, however, indicate when and how
such material may be obtained. I expect to visit these regions
again and to arrange with some well equipped fisherman to seine
one of the running water lakes so that fish may easily be taken
during the entire season. Thus it is hoped that the desired
material may be procured.

ZOOLOGICAL LABORATORY, COLUMBIA UNIVERSITY
New York

FOWLER’S “HETEROGNATHOUS FISHES” WITH A
NOTE ON THE STETHAPRIONINAE!

C. H. EIGENMANN

Ar divers times and places I have pointed out that the South
American heterognaths, or characins, offer us an unparalleled
opportunity for a study of divergent evolution. ‘They probably
entered South America in the early Tertiary, when the continent
was small and its river systems comparatively insignificant. They
have literally grown up with the country, keeping pace with the
development of its unrivaled freshwater system. ‘To-day there
are over one hundred genera and more then five hundred species
known, and only a few spots have been examined. For the most
part the genera represent steps along different directions of adapta-
tion.

Every one identifying miscellaneous collections of fishes or
other animals, without critical revision of the respective groups,
will make numerous mistakes in identification; he will emphasize
in his descriptions characters of no importance, and will omit or
slur others that are significant. The percentage of mistakes
made in identification and the number of unsatisfactory descrip-
tions vary with different men. A large percent is found in the
ichthyological writings of the late Professor Cope. His South
American freshwater fishes have especially been a source of tribu-
lation for recent writers. It is a thankless task for any naturalist
to go over such work and yet this is what Dr. Henry W. Fowler
has recently done for the characins.?, Dr. Fowler has redescribed
many of Cope’s species and has supplied illustrations of those not
figured or only unsatisfactorily figured before.

It is inevitable that new questions concerning the specimens
should arise as the result of Dr. Fowler’s work, and that he should

‘Contribution from the Zoological Laboratory of Indiana University No. 90.
? Further Knowledge of some Heterognathous Fishes. Proc. Acad. Nat
Sci. Phila., 1906, pp. 273-351 and 431-483, 60 figures.

767

768 THE AMERICAN NATURALIST [Vor. XLI

make new mistakes. With the limited material at his command
it is to be regretted that Dr. Fowler has not confined himself
largely to figuring and describing, instead of bestowing new
generic and subgeneric names with princely liberality and aban-
don. While he has helped by his figures and descriptions, he
has in large measure increased, rather than lightened, the burdens
of his successors.

The new genera and subgenera proposed by Dr. Fowler (24 in
number) are consecutively numbered in the following notes:

1. — Ophiocephalops. ‘This is an exact synonym of Hoplery-
thrinus of Gill.

2. — Copeina, a new name for the genus Holotaxis of Eigen-
mann, not Cope. This is probably a valid name.

3, 4, 5. — Curimata is used for Curimatus, although the latter
is the earlier form. The genus is divided into the subgenera,
(3) Cyphocharax, (4) Steindachnerina, (5) Peltapleura, and
Curimata. The known species of the genus are not distributed to
their respective subgenera and there is no evidence produced in
this paper demonstrating that these subgenera are valid or that
Dr. Fowler is able to delegate the species to their proper sub-
genera. Cyphocharax and Curimatus are probably valid. It
is to be hoped that Dr. Fowler will distribute the species for us.

6. — Eigenmannina, a new generic name for Anodus melano-
pogon is apparently valid.

7.— Chilomyzon is a new subgenus of Prochilodus, distin-
guished by having 33-38 scales in the lateral line, whereas Pro-
chilodus is said to have 40-60. This division is unfortunate
since P. humeralis has 33 scales, vimboides 35-37, oligolepis 36-38;
longirostris 38-39, magdalenae 40-41, cephalotes 41, asper and
hartii 41-42, brevis 41-43, rubrotaeniatus 44, etc., to the end of
the series. The new species, Prochilodus theraponura and amazo-
nensis are very probably two stages (2} and 4% inches long) of
the common P. insignis.

8. — Hemiodopsis, a subgenus of Hemiodus, distinguished by
having 100 scales. Since the other species of Hemiodus have
58-85 scales this division may be convenient.

9. — Pithecocharax is substituted for Anostomus because he
thinks the latter is preoccupied by Anastomus Bonnaterre 1790.

No. 492] FOWLER’S “HETEROGNATHOUS FISHES” 769

But Anostomus was proposed by Gronovius and accepted by
Scopoli in his Introduetio ad Historiam Naturalem, 1777, p. 451
There is no reason for doing away with the name Anostomus even
if it were identical with Anastomus, which it is not.

10. — Poecilosomatops is proposed for the species of Characi-
dium having 4 scales between the anal and the lateral line; the
rest have 2 or 3. The advisibility of this division may well be
questioned, but even if valid, the older name, Nanognathus
Boulenger, must be used instead of Poecilosomatops.

11.— Garmanina is a valid subgenus of Rhytiodus, there
being a difference of 30 scales in the lateral line.

12. — Abramites (type hypselonotus), a new genus, is said to
be distinguished from Leporinus by its longer anal basis, but
where are we to draw the line? There are groups of species of
Leporinus with 9, 10, 10 or 11, 11, 12, 12 or 13, 13 to 15 (hypselo-
notus), 14, and 15 or 16 rays! The name is not admissible.

Astyanax pectinatus (Cope) redescribed and figured, is the
type of a genus distinct from Astyanax, differing from all other
‘Tetragonopterinae in that the origin of the anal is under or in
advance of that of the dorsal. It may be named Phenacogaster.’
Astyanax moorii (Boulenger) is the type of a distinct genus which
may be named Astyanacinus.’ Astyanax atahualpinus does not
seem to be distinct from Moenkh agassizii, since the differences
fall within the limits of the observed variation of the latter. His
Astyanax oligolepis is very probably Astyanax steindachneri
Eigenmann; it certainly is not the oligolepis of Günther. Tetra-
‘gonopterus ovalis is probably a Moenkhausia.

13. — Coscinoxyron is probably a valid genus, differing from
Chalcinus in the increased number of gill-rakers.

‘It is very probable that Tetragonopterus bairdii and T. tabatıngae belong
to this genus

? The following description is based on the type in the British Museum.

Jaws equal, the lower not included; premaxillary with two series of teeth;
mandible without conical teeth in front; gill rakers setiform; snout and
maxillary forming more than half the length of the head; maxillary not slip-
ping under preorbital for its entire length, the preorbital notched; maxillary
with about 6 teeth; lateral line complete; maxillary-premaxillary border
without a distinct angle. Differing from Hollandichthys and Pseudochalceus
in its complete lateral line and incompletely toothed maxillary, from Creato-
chanes in its on lateral line, notched preorbital and unangulated pre-
maxillary-maxillary border

770 THE AMERICAN NATURALIST [Vor. XLI

14. — Thoracocharax, proposed as a subgenus of Gasteropele-
cus because the “Anterior profile of back [is] convex,” is a dis-
tinct genus characterized by its dentition and not by the degree
of the convexity of the back.

15. — Cyrtocharax is synonymous with Cynopotamus, a sub-
genus of Charax. The type of Cynopotamus lacks a second
row of teeth in the lower jaw.

16. — Eucynopotamus may be used for the genus hitherto
known by the name Cynopotamus, since the type of this genus
does not possess the generic characters distinguishing the other
species hitherto relegated to this genus from Charax. ‘The divi-
sion of this genus into a subgenus with less than 75 scales and
another with more is not fortunate, since the scales are 76-77, 79-
97, 110-120 and 115 respectively in gulo, knerii, magdalenae and
humeralis.

17. — Cynocharax, a new subgenus of Roeboides, I am unable
to pass judgment upon in the absence of material and through
the neglect of Dr. Fowler to state what species it includes.

18. — The subgenus Sphyraenocharax is said to be distinguished
by having the depth 3} to 4 in the length. It apparently consists
of brachycephalus and abbreviatus, with the latter the type. ‘The
teeth are too imperfectly redescribed to place them. Cope’s
figure of brachycephalus shows it to be allied to the type of Aces-
trorhamphus. The character of the teeth of abbreviatus is still
in doubt. Cope says: ‘There are two distinct large canines on
the anterior part of the maxillary bone and four smaller ones;
maxillary teeth are minute.” Presumably the first ‘‘maxillary”
is a misprint for premazillary. Fowler says: “about 6 well
developed [canines] in the upper” jaw. ‘This species is also allied
to the type of Acestrorhamphus. Now the type of Acestrorham-
phus has a depth of 34, other species of the genus have a depth
of 4 and I am unable to discover the semblance of an excuse for
the name Sphyraenocharax.

19. — Belonocharax is a new genus based on specimens from
the Truando, Rio Atrato basin. These same specimens were
referred to by Gill (in 1861 I think), as Ctenolucius. Admitting
that Gill’s name, being undefined, has no standing, there is no
excuse for passing over the Luciocharax (insculptus) of Stein-

No. 492] FOWLER’S “HETEROGNATHOUS FISHES” ja

_dachner, defined and figured in his Fischfauna des M agdalenen-
Stromes, p. 51, pl. XIII, figs. 2-2b, which is unquestionably the
genus to which Belonocharax beant belongs, beani being probably
identical with the type insculptus.

20, 21, 22.—I do not have the material to pass finally on the
status on the subgenus (20) Waiteina and the genus (21) Reganina;
both are apparently Colosoma, as (22) Starksina is probably a
Mylosoma.

24.— The genus Sealeina is probably a valid subgenus of
Metynnis.

The paper closes with descriptions and figures of Cope’s two
species of Stethaprion. The figures lack details of the predorsal
spines which are essential. No attempt is made to compare
critically these two species and pass judgment as to whether the
one is simply a younger specimen (213 in.) than the other (3,4 in.)
although no one else is in as good a position to do so.

The descriptions of Cope, pieced out with those here presented
and the numerous figures, will enable us without prejudice to
work out finally in most cases what species are really under con-
sideration.

We must feel grateful to Dr. Fowler for his labor. But it is
to be hoped that in the future he will be more conservative in
adding names to the science of ichthyology. ‘The valid names do
not compensate for the work imposed on some one else to separate
them from the synonyms.

An examination of Boulenger’s types of Brachychalcinus shows
them to belong to two distinct genera. Referring Boulenger’s
name to the species figured by him, the other species is congeneric
with Günther’s Tetragonopterus compressus and most nearly
allied to Cope’s Stethaprion. In recognition of Dr. Fowler’s
generous effort I would propose, using a form adopted by Dr.
Fowler, the name Fowlerina to distinguish the genus represented
by the Tetragonopterus compressus Günther.

The members of the Stethaprioninae mark the direct road
from the genus Tetragonopterus (Tetragonopterinae) in its nar-
rowest sense to the Myleinae and Serrasalminae. In the deep
Tetragonopterus argenteus the post-ventral region is trenchant,
the pre-ventral region flat. In Stichonodon both pre-ventral

772 THE AMERICAN NATURALIST [Vor. XLI

and post-ventral regions are trenchant. In Stethaprion, Brachy-
chalcinus and Fowlerina the post-ventral region is incipiently
serrate and there is a pre-dorsal spine. In .Mylesinus of the
Myleinae the abdomen is serrate behind the ventrals and in the
rest of the Myleinae and the Serrasalminae the ventral edge is
serrate both in front and behind the ventrals. ‘The descent is
indicated as follows
Tetragonopterus

Stichonodon

|

Stethaprion — Fowlerina — Brachychalcinus

Mylesinus
other Myleinae Sn.

The genera of Stethaprioninae are distinguished as follows.
a. No predorsal dom ; caudal scaled; origin of anal posterior
to dorsal. : : ph ae >: VOHEBOREUON.
aa. A predorsal spine.

b. Predorsal spine long, en spear-shaped, fitting into

a groove in the back; origin of anal under dorsal; scales

rather small, over 60 in the lateral line.

Stethaprion.

bb. Predorsal spine scale-like, spoon or saddle-shaped,
concave below, fitting into a notch in the back. Caudal
scaled; scales less than 40. . ; . Fowlerina.
bbb. Predorsal spine trigger or Hhaihideratiaped: its free
portion forming a longer anterior and shorter posterior
branch, both of which are ee pointed; caudal scaled;
scales large, about 40. . ; Brachychalcinus.

UNIVERSITY OF INDIANA,
Bloomington, Ind.

PINK INSECT MUTANTS
WILLIAM MORTON WHEELER

‘THE present wide-spread interest in mutation lends fresh signi-
ficance to the cases of dichromatism and trichromatism among
insects, and suggests experiments in breeding these animals under
laboratory control. ‘The sporadic occurrence of pink individuals
among our commonly leaf-green katydids (Locustidae) belonging
to the sub-families Phaneropterinae and Pseudophyllinae, and
especially in our two species of Amblycorypha, has been known for
some years. Scudder called attention to some of these individuals
in three brief papers (1878, 1897, 1901), and published a fine colored
figure of a pair of them on a spray of golden rod.‘ From time to
time other authors have recorded similar observations. Certain
Homoptera, as I shall show presently, also exhibit color aberrations
of the same kind. The following are the cases of pink Locustidae
of which I find records in the literature:

Cyrtophyllus perspicillatus L.

No. 1. A single specimen taken at Point Pleasant, N. J. Sex
and date of capture not mentioned (Lewis 1883).

C. roseus Stal.

No. 2. The type of the species from Chiriqui, Costa Rica,
cited by Scudder (1901).

Amblycorypha rotundifolia Scudder.

No. 3. Female, taken August 29, on Sharp Mountain, Schuyl-
kill County, Pa. Recorded by Scudder (1878) who received it
from Leidy.

‘Entomol. News, XII, 1901, Pl. VI. This plate is reproduced by Blatchley

(1902).
773

774 THE AMERICAN NATURALIST [Vor. XLI

No. 4. A single specimen from Pennsylvania. Date and sex
not recorded (von Wattenwyl, 1878).

A. oblongifolia DeGeer

No. 5. Female, taken by Professor G. Thurber, presumably in
New York State (Riley 1874).

No. 6. Specimen without record of date, sex or locality (John-
son 1889).

No. 7. Female, taken August 9, at Woods Hole, Mass., by
Mrs. Sidney I. Smith (Scudder 1897).

Nos. 8 and 9. A male and a female specimen taken August
29, at Woods Hole, Mass., by Mr. Richard Rathbun and Professor
A. E. Verrill (Scudder 1897, 1901).

Nos. 10 and 11. Two individuals belonging to a “number of
pink specimens” taken near Bass Lake, Starke County, Indiana,
by Mr. Frank Hay. Sex and date not recorded (Blatchley 1902).

Nos. 11 to 14. Three female specimens taken many years ago
at West Farms, now a part of New York City, by Mr. J. Angus
(American Museum of Natural History).

Nos. 15 to 17. Three specimens taken on Staten Island, N.
Y., by Mr. William T. Davis. Two of these, both females, cap-
tured during August and September, are in Mr. Davis’s collection.

No. 18. Female taken August 22, 1906, at Upper Montclair,
N. J., by Mr. C. B. Wolff (American Museum of Natural History).

Nos. 19 to 23. Five females taken during. August 1906, at
Woods Hole, Mass., by members of the Marine Biological Labora-
tory (Professor T. H. Morgan in litt.).

No. 24. Male taken August 12, 1906, on Grosse Isle near
Detroit, Mich., by Mr. A. S. Austin (Shull 1907).

No. 25. Female in the Museum of the University of Michigan.
Date and locality not recorded (Shull 1907).

No. 26. Female taken August 31, 1907, at Winslow, N. J., by
Mr. H. H. Halsted (American Museum of Natural History).

Conocephalus rosaceus Walker

No. 27. Female, the type of the species, from North China, in
the British Museum (Walker 1869).

No. 492] PINK INSECT MUTANTS 175

It will be noticed that the geographical range of the pink Ambly-
corypha oblongifolia is nearly or quite co-extensive with that of the
green form, and that the great majority of pink individuals enumer-
ated in the list are females. ‘This may be due either to the females
of the species in general being more numerous than the males, or
to the males being much shorter-lived than the females. Careful
comparison of the pink with the common green forms fails to reveal
any differences, except those of pigmentation. The color of all
the aberrant specimens of Amblycorypha oblongifolia which I have
seen, is very constant, although some of those seen by others have
been described as vermilion or crimson. ‘The exquisite tint of the
living insect changes rapidly after death and becomes a dull pink-
ish brown in the cabinet. In green individuals, however, the
post-mortem color change is less marked, so that we are justified
in saying that the pink pigment is less stable than the green.

The pink katydids which have been observed in confinement
show nothing unusual in their behavior, nor anything to suggest a
_ diseased or abnormal condition. ‘Those observed both by Scudder

(1901) and myself ate green leaves and drank water with avidity,
and eventually laid eggs of the normal form and size. Nos. 17
and 25 each lived in a jar in my laboratory for nearly six weeks.
I endeavored to mate No. 17 with a male of the green form, but
failed, perhaps because the experiment was tried too late in the
season, or because the male may have been moribund or exhausted
before it was placed in the jar with the female. The eggs laid by
this insect a few days before her death were not fertilized. No. 25
had laid a number of eggs before she was sent to me by Mr. Hal-
sted. According to Scudder (1878), specimen No. 3 oviposited
while she was still in Leidy’s possession.

It seems not to be generally known that, in addition to the green
and pink forms, both Amblycorypha rotundifolia and A. oblongi-
folia have also a brown phase. Mr. William T. Davis has gener-
ously loaned me two males of the latter species in this phase, one
taken by him July 24, at Hewitt, N. J., and the other during Sep-
tember, on Staten Island. In these I can detect no peculiarities
except those of color, the usual green being merely replaced by a
yellowish brown or tan tint, which was probably more vivid in the
living specimens. Several authors have recorded the occurrence

776 THE AMERICAN NATURALIST [Vor. XLI

of both green and brown individuals in some of our species of
cone-headed grasshoppers (Conocephalus nebrascensis Bruner, C.
robustus Scudder), which are not known to have a pink phase,
although Walker (1869) has based his C. rosaceus on a pink indi-
vidual of this genus from Northern China. In C. robustus the
brown and green colors are occasionally found in the same indi-
vidual, a condition that, to my knowledge, has never been met with
in the species of Amblycorypha.'

I find that certain green species of Homoptera belonging to the
families Jassidae and Fulgoridae occasionally present striking color
aberrations comparable to those of the Locustidae. Ball (1900)
described as var. paeta a red individual of the green Jassid Macrop-
sis laeta Uhler and noticed its resemblance to the pink phase of the
katydids. Mr. William T. Davis has loaned me series of speci-
mens of the jassid Gypona geminata Osborn, and of the fulgorid
Amphiscepa bivittata Say which are of peculiar interest in this con-
nection. ‘The Gypona series comprises three specimens of the
common green phase taken September 6, at Lakehurst, N. J., three
brown individuals taken at the same time and place, and two pink
specimens from Staten Island (September 11). There is also in the
collection of the American Museum of Natural History a pink indi-
vidual of the same species taken by Mr. J. Angus, at West Farms,
N. Y. On closer examination the ventral surface and ground color
of the pink specimens is seen to be greenish yellow (probably green
in life), with irregular crimson markings on the head and thorax,
and elytral veins of the same color. In the other specimens the
brown and green colors are more diffused over the whole surface,
especially on the dorsum, and there are no distinct markings on
the head, thorax and elytra. The common form of the well-
known Amphiscepa bivittata is pea-green, with the head, sides of
thorax and scutellum, the posterior margins of the elytra and
wings and the anterior legs, purplish brown. A single specimen
in Mr. Davis’s series has the green portions of the dorsal surface
and elytra replaced by pink, with the veins of the latter somewhat

1 Mr. Davis has shown me brown specimens of the following seven species
which also present a green phase: Conocephalus fuscostriatus Redt., ensiger
Harris, a Rehn., triops L., robustus Scud., candellianus Davis, exilis
canorus Davis

No. 492] PINK INSECT MUTANTS Tid

purplish. ‘This specimen, which is somewhat smaller than the
green ones, was taken August 9 on Staten Island, by Mr. Joutel.

What is the significance of these peculiar pink and brown forms
which appear so sporadically among our green Orthoptera and
Homoptera? As Scudder says, everyone who sees one of these
rare insects for the first time, “thinks at once of autumn leaves and
their changes from green to red, and notices that these grasshopper
cases all occur in the autumn, so far as known.” But further
reflection soon leads one to doubt a conclusion based on such a
superficial analogy, for it is evident, in the first place, that the colors
of these insects must differ greatly from chlorophyll or other plant
pigments, and, in the second place, the occurrence of the pink
individuals during late summer may have no significance, since it
is only during this season that even those of the common green
phase reach full maturity. In this connection, Scudder (1901)
also calls attention to the occurrence of Cyrtophyllus roseus in
tropical Costa Rica.

There is, however, another fact hitherto unrecorded, which
seems to me effectually to dispel the notion that the pink phase
can be the result of temperature acting on the green pigment.
Some years ago, while I was sweeping the low vegetation in the
prairies of Wisconsin and Illinois for small Diptera, I took in my
net, on one or two occasions during July, a few pink larval and
nymphal katydids. Unfortunately I did not preserve the specimens
as I was at that time collecting Diptera only, but I retain in my
memory a vivid picture of the specimens. They varied from one to
two centimeters in length, and were either wingless or had small
rudiments of wings. They were pink throughout, like the adults
which I have seen since, and occurred sporadically in the same
sweepings with many specimens of the common green form.
These larval and nymphal individuals show that the pink katydid
is pink throughout life and this is in all probability true mutatis
mutandis of brown individuals and of the pink and brown Homop-
tera also. In other words, the pinkness or brownness are, like the
greenness, congenital or germinal characters and not the result of
environmental conditions. This being the case, we must incline
to the hypothesis advocated by Scudder and Shull, that the pink,
and probably the brown individuals also, represent sports, or

778 THE AMERICAN NATURALIST [Vor. XLI

mutants, as we should now call them. ‘They have, in fact, every
appearance of belonging to a category of color forms similar to that
of the albino mammals and birds and certain kinds of white-flower-
ing plants. If there were need of coining new words, we might
call the pink individuals cases of rhodism and the brown ones
cases of phaeism.

Conclusive proof of the correctness of this view can be obtained
only by experimental breeding. On the sport or mutation hypothe-
sis we should expect pink individuals mated inter se to produce only
pink individuals, and the same should result mutatis mutandis in
the case of the brown forms. Pink or brown individuals crossed
with the common green form may be expected to give offspring
in the Mendelian proportion, with the pink and brown characters
acting as recessives. Perhaps some student at the Marine Biologi-
cal Laboratory at Woods Hole, where pink individuals of Ambly-
corypha oblongifolia seem to be less rare than in other localities,
may find it worth while to perform these and other experiments
for the purpose of determining the inheritance value of the charac-
ters above discussed.

Postscript

Since the foregoing paragraphs were sent to the “Naturalist”
two additional captures of pink Amblycorypha oblongifolia have
been recorded:

No. 28. A female taken August 15, 1907, by Dr. J. N. Rose,
in the New York Botanical Garden and presented to the National
Museum, is cited by Knab (1907), who also mentions two brown
specimens of this same species, one from Springfield, Mass., and
another from Dorsey, Md. (August 20, Miss R. Jones). Knab
calls attention to the pink and green caterpillars of the same species
as analogous to the pink and green katydids, and concludes that
the difference in pigmentation in the latter is in all probability
due to the red or green coloring matter of the leaves on which the
insects feed. Iam unable to accept this view for the following
reasons: first, red and green caterpillars are sometimes found on
the same green plant and living under precisely the same condi-
tions; second, my pink katydids in confinement ate green leaves

No. 492] PINK INSECT MUTANTS 779

for several weeks without showing the slightest change in coloration,
and third, red vegetation is not abundant early in August, and
katydids, unlike caterpillars, roam about, feeding on a variety of
plants and even on animal food.

No. 29. A pink male Amblycorypha oblongifolia was captured
by Grossbeck (1907) August 1, at Lahaway, Ocean County, N. J.
He also mentions several pink specimens taken some years ago
by Professor J. B. Smith in the pine barrens of New Jersey, and a
pink Amphiscepa bivittata taken August 23, by himself at Lake-
hurst, N. J. He says that in his experience Gypona octolineata
(perhaps identical with the species er cited as G. geminata)

“is almost as often pink as green.” The title of Grossbeck’s
paper shows that he regards the pink phases of these various
insects as sports, or mutants, and not as the result of the environ-
mental conditions (temperature, food, etc.).

LITERATURE

Bau, E. D.
1900. Notes on the species of Macropsis and Agallia of North America.
Psyche, 1900, p. 130
BLATCHLEY, W. S.
1902. The Orthoptera of Indiana. Twenty-seventh Rep. Dept. Geol.
and Nat. Resources of Indiana, 1902, pp. 351, 352. Pl.
GROSSBECK, J.
1907. Color Sporta Among the Insects. Science, N. S. XXVI, Nov.
8, 1907, pp. 639, 640.
Jounson, L. N.
1889. Color of Katydid. Science, XIII, 1889, p. 32.
Knas,
1907. ‘Cole Varieties of Locustide. Science, N. S. XXVI, Nov. 1,
1907, pp. 595-597.

Lewis.
1883. Change of Color in a Katydid. Proc. Acad. Nat. Sci. Phila.,
1883, p. 44
Rusy, ©. V.

1874. Sixth Annual Report on the Noxious, Beneficial and other
PES of Missouri, 1874, p. 169.
SCUDDER, 8.
1878. A a Grasshopper. Psyche, II, 1878, p. 189.

780 THE AMERICAN NATURALIST [Vor. XLI

SCUDDER, S. H.
1897. Pink Locustarians. Psyche, VIII, 1897, pp. 54, 55.
SCUDDER, S. H.
1901. Pink Grasshoppers. Entomol. News, XII, 1901, pp. 129-131,
lL VE

SHULL, A. F.
1907. A Color Sport among the Locustidae. Science, N. S. XXVI,
1907, pp. 218, 219.
WALKER, F.
1869. Catalogue of the Specimens of Dermaptera Saltatoria in the
Collection of the British Museum, London, 1869, pp. 321, 322.
VON WATTENWYL, BRUNNER.
1878. Monographie der Phaneropteriden 1878, p. 269.

NOTES AND LITERATURE
GENERAL BIOLOGY

The Theory of Mimicry.— In an address before the British Associa-
tion, Dr. F. A. Dixey has reviewed the history of the mimicry hypothe-
sis as an explanation of the resemblances in color pattern between
butterflies of diverse genera (Nature, 1907, vol. 76, p. 673-678).
After visiting the Amazon nearly fifty years ago, Bates suggested that
of two species of similar pattern, one was distasteful to birds, and the
other had acquired a protective resemblance to it through natural
selection. Dr. Dixey states that this was “the first really scientific
explanation of the matter” and that it “was at once, and cordially,
accepted by Darwin.” He continues,—

“Bates himself was not thoroughly happy about all the facts re-
corded. He directs attention to the circumstance that not only do
the mimics resemble their models but that the models themselves often
show an extraordinary resemblance to each other. He speaks of ‘a
minute and palpably intentional likeness which is perfectly stagger-
ing.’” It was thought that some local or climatic cause, acting
equally upon the forms of different groups, might bring about the
strange resemblance between them, and “in this supposition Bates
was for a time followed by Wallace.”

“It is not to be denied that there is a certain plausibility in this
view concerning the direct action of external conditions. It is, for
example, a striking fact that the members of a mimetic group of véry
diverse affinities will, as Bates says, every few hundred miles change
their hue and pattern together ‘as if by the touch of an enchanter’s
wand

According to Dr. Dixey the key to the puzzle why distasteful forms
resemble each other was found by Fritz Müller in 1879. Dr. Dixey
states that his suggestion rested on the assumption, since shown mainly
by Lloyd Morgan to be correct, that birds have no instinctive knowl-
edge of what forms should be avoided. Hence a certain number of
distasteful forms must be sacrificed until their enemies have learned
to leave them alone. Now if two distasteful species resemble each
other so closely that birds or other enemies do not distinguish between
them, the disagreeable experience gained by tasting an individual of

781

782 THE AMERICAN NATURALIST [Vor. XLI

one species will be applied to the benefit of the other, and so each of
the two species will need to contribute only a portion of the tax instead
of the whole. The greater the number of forms that can be got to
share the tax, the better for all, and hence the formation of large
‘inedible associations’ or Müllerian groups.

In Batesian mimicry the advantage is all on the side of the mimic.
In a Miillerian association the benefit is mutual, and Dr. Dixey cites
examples showing that two insects may each become modified to
resemble the other. He concludes that “the fertile suggestion of
Fritz Miiller went far to supply what was still wanting in Bates’s
interpretation. Expanded by Meldola and by Poulton, accepted by
travelled naturalists like Wallace and Trimen, the Miillerian generali-
zation has proved a powerful means of interpreting many complicated -
relationships.”

Thus the theory of mimicry has been extended to explain not only
resemblances between an edible and an inedible form but also between
two inedible species. 'The question arises whether the resemblances
have anything to do with edibility. Werner believes that they have
not (Amer. Nat., 1907, vol. 41, p. 333). Weismann has found it
necessary to gather evidence that any birds eat any species of butter-
flies to an important extent.! He states that in Germany Caspari
“let about a hundred butterflies (Vanessa antiopa) fly from his window,
but not ten of them reached the neighboring wood, all the rest being
eaten by swallows which congregated in numbers in front of his
window.” “Kathariner observed in the highlands of Asia Minor, a
flock of bee-eaters which caught in flight and swallowed a great many
individuals of a very beautiful diurnal butterfly (Thais cerisyi).”
Several other such reports are recorded from various parts of the
world, but they do not establish the fact that birds devour butterflies
to the extent and with the discrimination which the theory of mimicry
demands. The writer’s observations in New England lead to the
conclusion reached by Judd, that here the native birds seldom molest
butterflies. He says,2—In the eastern United States....there are
not yet any records of birds habitually preying upon butterflies. In
fact the same question has been agitated in the discussion following
the reading of Mr. Dixey’s most interesting paper at the London
Entomological Society; and it was found that comparatively few

‘Weismann, A. The Evolution Theory. Translated by J. A. and M. R.
Thompson. Vol. 1. London, Edward Arnold, 1904

2? Judd, S. D. The efficiency of some protective ‘adaptations in securing
insects from birds. Amer. Nat., 1899, vol. 33, p. 461-484.

No. 492] NOTES AND LITERATURE 783

members had ever seen birds take butterflies. In the eastern United
States there have been hardly more than a dozen published records
of birds seen in the act of taking butterflies. Birds, so far as I have
observed, seem to make no practice of giving chase to the butterflies
that float about them as they busily catch other insects. Butterflies
seem to be avoided, whether they are indifferently colored, protectively
colored or mimetic, or warningly colored. It is said by Wallace
that our milkweed butterfly is imitated by Basilarchia which thus
escapes capture; but, as none of our butterflies are persecuted, it
seems strange if mimicry has actually been aimed at. Beddard has
shown that there are difficulties in the theory of protective mimicry
from the fact that mimicking and mimicked forms are eaten, and that,
in certain cases, instances of apparently useless mimicry occur.”

In place of the theory of mimicry, a chemical theory of animal color-
ation may be substituted. Dr. Gadow has described pigments as
physiological products of the organism, liable to chemical transforma-
tions with corresponding changes in color. Autumn leaves turn from
green to yellow and red through such processes, and if a crimson leaf
of the red maple resembles one of the Japanese ivy, it is not due to
mimicry. What has occurred in Basilarchia archippus is a transforma-
tion from blue and black to a red like that of Anosia plexippus. A
comparable change is found in Semnopsyche diana; the female is blue
and black, but the male is brown and red. It may be noted also that
Speyeria idalia has red fore wings, and hind wings chiefly blue, but
that in the related genus Argynnis (in which Speyeria idalia was
formerly included) both pairs of wings are red. Indeed the resem-
blance between Basilarchia archippus and Anosia plexippus is strik-
ing, but there is a similar resemblance between the Carolina locust and
Euvanessa antiopa, and between Basilarchia astyanax and Papilio
troilus. These are not accounted for by mimicry.

If mimicry does not explain the difference in color between the male
and female of Semnopsyche diana, it may be doubted that the dark
female of the yellow Papilio turnus in the south is a mimic of Laertias
philenor. 'The latter, according to Weismann, is protected by its
unpleasant taste and odor, but the odor as described by Comstock, is
undoubtedly a perfume to attract and delight its mate. A. H. Pritchett
(Biol. Bull., 1903, vol. 5, p. 271-287) found that Laertias philenor
was eaten by the lizard Sceloporus floridanus “with evident relish”
in spite of its odor and the fact that its larva fed on the ill-tasting and
poisonous Aristolochia. The lizard devoured the presumably im-
mune Anosia plexippus also.

784 THE AMERICAN NATURALIST [Von XLI

Piepers * describes the theory of mimicry as superstition and romance
which “we still hesitate to abandon, particularly in England,— in
Nature and the Trans. of the Entom. Soc. of London it abounds.”
From the English journal Field, he cites the account of an Egyptian
butterfly, in which the hind end so resembles the head end that a bird
will be unable to know which way the insect will attempt to escape!
Similarly Bashford Dean, at the recent meeting of the American
Society of Zoologists in New Haven, ridiculed rather than discussed
the theory. He referred to the popularity of the Indian butterfly
Kallima mounted as mimic of European beech leaves.

The resemblances between butterflies of diverse genera, many of
which were known to the older naturalists, remain the interesting fea-
ture. Many American books, however, instead of describing them,
present the theory of mimicry with the Anosia-Basilarchia illustration,
and thus “touch only the fringe of a great subject.”

F. T. Lewis.

The Inheritance of Disease. — Professor Bateson, in his last lecture
before returning to England, presented a considerable list of human
abnormalities which are transmissible, perhaps in Mendelian propor-
tions. Several of these pertain to the eye. Displacement of the lens
due to an asymmetrical development of its ligament, is dominant;
and also praesenile cataract, which occurs at birth or soon after. The
largest tabulation of the transmission of abnormality through the
descendants of one individual, was a case of inability to see normally
except in bright illumination (hemeralopia). Color blindness and
eye color,— pure blue being recessive — were also discussed. ia-
grams were shown illustrating the transmission of hypertrophied skin
of palms and soles; of the tendency to blister, known as epidermolysis
bullosa; of diabetes insipidus; and of haemophilia, in which there is
extensive bleeding from slight wounds. In the last condition males
are much more often affected than females, although the apparently
unaffected females belonging to the families involved may trans-
mit the disease. This was compared with the inheritance of the
horned condition in sheep. A hornless breed crossed with a horned
form yields horned males and hornless females, these females trans-
mitting the horns to the males; by further crossing with the horned
stock, horned females occur also. Professor Bateson believes that

1 Piepers, M. C. Noch einmal: Mimicry, Selektion, Darwinismus. Leiden,
E J. Brill, 1907. 481 pp.

No. 492] NOTES AND LITERATURE 785

the results of experimental breeding will show how various human
afflictions may be eliminated.

Dr. E. E. Tyzzer (Journ. of Med. Res., 1907, vol. 17, p. 199-211)
discusses the inheritance of tumors in mice. Although “the analysis of
data derived from a large number of human cases has failed to furnish
evidence that a predisposition to cancer is inherited,” it is known
that some races of mice are susceptible to transplanted tumors and
that other races are not. In one of the susceptible races spontaneous
tumors were found in four individuals in a family of twenty-six, there
being one case in each of four generations. The data obtained are
insufficient “to prove or disprove that the development of a tumor is
dependent upon the presence of an inherited character, although they
may appear to favor this view.” Further experiments upon this vital
subject are in progress.

Malaria in Ancient Greece and Rome.'— “Modern Greece is
intensely malarious.... It has been estimated that in the unhealthy
year 1905, out of a total population of only about two and a half
millions, nearly a million people were attacked with malaria and nearly
six thousand died.” -The three authors of the little book under con-
sideration believe that malaria was introduced into Greece in the fifth
century B. C. by “soldiers, merchants or slaves coming from Africa
or Asia, the ancient homes of malaria.” In the fourth century B. C.,
it became prevalent, and it is considered to be an important cause
for the sentimentalism in art, pessimism in philosophy, and decay in
morality characteristic of that century. “By 300 B. C., the Greeks
had lost much of their manly vigor and intellectual strength... .
Malaria made the Greek weak and inefficient; it turned the sterner
Roman into a bloodthirsty brute.” It was endemic in Rome proba-
bly from the second century B. C. It is implied that the modern
atrocities of white men in tropical regions may be due in part to
malaria; and attention is called to the immunity of Japan in contrast
with the prevalence of malaria in China as an influence in modern
history. ‘The evidence for these propositions, as found in this book,
will interest students of medicine, history, and the classics.

The Distribution of European Animals. — Dr. Scharfl’s well known
History of the European Fauna, published in 1899 and critically dis-
1 Malaria. A neglected factor in the history of Greece and Rome. By W.

. 8. Jones. With an introduction by Major R. Ross and a concluding
chapter by G. G. Ellett. London, Macmillan & Co., ‚1907. 108 pp.

786 THE AMERICAN NATURALIST [Vor. XLI

cussed by Dr. Stejneger in the American Naturalist (1901, vol. 25,
p. 87-116) has been followed by another book upon the same sub-
ject... The problem of animal distribution is simply and clearly
presented by means of outline maps on which the occurrence of a
single species is plotted in black; in an unoccupied corner of each
chart a picture of the animal is inserted. In a few cases the former
land areas have also been indicated. Thus Fig. 6 shows a fresh water
lake in place of the Irish Sea, from which the fresh water herrings
(Coregonus) travelled up the streams to lakes in northern Ireland and
western England and Scotland, where they are now isolated. Some
of the charts deal with the distribution of plants, which are “subject
to the same laws of dispersal as animals.” Although “the occasional
transport of species by wind or by marine currents has probably taken
place sometimes,” Dr. Scharff believes that it does not effect the
constitution of an island fauna very materially. Twice he cites evi-
dence that birds during migration do not have seeds in their crops
or adhering to their bodies. Distribution is to be explained chiefly
by geögraphical changes, and leads to such conclusions as that the
Azores were not connected by land with America but only with Europe.
The Canary Islands, however, “must have formed part of the land
which connected Africa with America, in early Tertiary times.”

Dr. Scharff believes that there was no ‘exceptional destruction”
of the British fauna and flora during the glacial period. He is of the
a that “the whole of the existing Irish fauna is of pre-glacial
age” and that “a more uniformly humid climate of Europe may bave
favored the production of glaciers without decreasing the temperature.”
The criticisms of this hypothesis by Dr. Stejneger and others are noted
by Dr. Scharff. The book is an admirable presentation of the pur-
pose and importance of studies in animal and plant distribution.

The Dancing Mouse.’ — Current publications have been so occupied
with presenting and discussing faulty accounts of animal behavior
that the public is scarcely aware of a science dealing with this subject.
In a well written book entitled The Dancing Mouse Dr. Yerkes presents
the methods and some of the results of this study. The dancing
mouse, as described in the first chapters, is a domesticated animal of

1 Scharff, R. F. European animals: their geological history and geograph-
ical distribution. New York, E. P. Dutton & Co., 1907. xiv+258 pp., 70
figs. $2.50.

2 Yerkes, R. M. The dancing mouse. A study in animal behavior. New
York. The Macmillan Company, 1907. xxi+290 pp., 33 figs. $1.25.

No. 492] NOTES AND LITERATURE TST

unknown origin, characterized by its inability to move far in a straight
line without whirling or circling about with extreme rapidity. Its
action may be compared with that of a cat in chasing its tail and
regarded as an aimless, useless habit increased by the breeder’s selec-
tion; or it may be considered an abnormal condition. Since this
mouse cannot be made dizzy by any contrivance, it has been described
as anatomically defective, but according to Dr. Yerkes the anatomical
defects are not established and he “can see no satisfactory grounds
for considering the dancer either abnormal or pathological.”

The larger part of the book describes experiments with ingenious
apparatus devised by the author for testing hearing, vision, educability,
habit formation, efficiency of training methods, duration of habits,
individual differences in behavior, and the inheritance of behavior.
It is found that the dancing mouse, although able to squeak and
capable of ear movements as if listening, is totally deaf except, in some
instances, during the third week of life. The experiments indicate
“that brightness vision is fairly acute, that color vision is poor, that
although form is not clearly perceived, movement is readily per-
ceived.” The dancing mice learn some things of their own initiative,
as how to use a swinging door which must be pushed on one side and
pulled on the other; they are not helped by seeing other mice perform
an act, but are aided by being put through it themselves. Certain
acquired habits were remembered after from two to eight weeks of
disuse; if forgotten, re-learning was easier. Initiative did not decrease
with age up to eighteen months, the oldest studied. ‘‘ Frequently my
oldest mice have shown themselves preeminent in their ability to
adjust their behavior to new conditions.” Absolutely no evidence
was found of the inheritance of an acquired habit, which in the case
studied was beneficial to the animal.

These valuable studies in the mental life of the dancing mouse
were accomplished without resort to vivisection. In place of depriving
the mouse of its various senses, the apparatus was arranged so that
they became inoperative. In methods as in results the work is highly
commendable, and it has been awarded the Cartwright Prize of the
Alumni Association of the College of Physicians and Surgeons, New
York.

F. T. Lewis.

788 THE AMERICAN NATURALIST [Vor. XLI

ZOOLOGY

Ichthyological Notes.'— Fishes of Central America: Mr. C. Tate
Regan (in the Fauna Centrali- Americana, 1907) continues his account
of the fishes of Central America, with good descriptions and a series of
excellent figures.

He describes as new Gerres simillimus, the Pacific Coast representa-
tive of Gerres (or Xystaema) cinereum. He regards Gerres axillaris
as distinct from Gerres lineatus. Gerres embryx and Gerres brasilianus
are regarded as old examples of Gerres plumieri, a conclusion also
reached by the present writer. He regards Centropomus pedimacula
of Poey as identical with Centropomus pectinatus. ‘The fish from the
Pacific called pedimacula he identifies as C. medius. C. mexicanus,
C. gabbi, and C. heringi are identified with C. parallelus. C. argenteus
is the young of C. undecimalis. C. viridis, the Pacific representative
of C. undecimalis is shown to be a distinct species. C. affinis and C.
scaber are identical with C. ensiferus and C. brevis and C. atridorsalıs
with C. armatus. C. altus, a new species from Colon, is described as
the Atlantic representative of C. wnionensis. Syngnathus spicifer,
a species from Zanzibar and the Philippines is recorded from Tehuan-
tepec. Doryichthys brachyurus, a South Sea species, is recorded from
Tehuantepec. Siphostoma brevicaudum from Vera Cruz, is regarded
as identical with Doryichthys lineatus. Chirostoma attenuatum and
Ch. zirahuen are regarded as identical with Ch. bartoni, and Ch. maz-
quital with Ch. jordani. Chirostoma labarcae is considered identical
with Ch. breve, Ch. crystallinum with Ch. lucius, and Ch. lermae with
Ch. sphyraena. The genus Melaniris is said to be founded on dis-
colored specimens of Thyrina, and the species evermanni, crystallina
and balsanus are all referred to the synonymy of Thyrina guatemalensis.
Xenatherina, a new genus, is based on nn lisa. Neomugil
digneti is identical with Agonostomus nasutus. Joturus stipes and
Agonostomus globiceps are identical with Joturus pichardi. Mugil
gaimardianus and Mugil setosus are regarded as the young of Mugil
curema. This view may be correct, but a study of specimens in the
markets of Cuba gave me a contrary impression. 'The well defined
and thoroughly tenable genera Encinostomus and Tylosurus are not
adopted by Mr. Regan, a view for which no reasons are assigned.

1 Owing to unavoidable circumstances the proof of these notes has not
been revised by President Jordan.

No. 492] NOTES AND LITERATURE 789

Fundulus guatemalensis and F. oawacae are identified with F. puncta-
tus. Cynodonichthys is identified with Rivulus. Cyprinodon lati-
fasciatus is identified with C. boveinus, and C. elegans and C. eximius
are placed in the same synonymy. C. californiensis and C. nevadensis
are identical with C. macularius. Zoogenaticus miniatus is regarded
as identical with Z. diazi and Z. maculatus with Z. robustus. The
species dugesi and quitzoensis are referred to Zoogoneticus, while
pachycephalus and punctatus are removed from their provisional
station in Actinia. Limnurgus is unwarrantably used instead of the
much older, but unpleasant name of Girardinichthys, and Characodon
geddesi is placed in the synonymy of G. innominatus. Chapalichthys
is regarded as inseparable from Characodon.

Characodon ferrugineus and eiseni are identical with Ch. variatus.
Ch. garmani is the same as Ch. latevalis. Skiffia is made a synonym
of Goodea. Charaeodon duitpoldi and Xenendum xaliscone are referred
to the synonymy of Goodea atripinnis. Skiffia variegata is the same
as Goodea lermae. Pseudoxiphophorus is regarded as a subgenus.
of Gambusia. Gambusia affinis with its synonyms is called by the
older name of Gambusia gracilis. Pseudoxiphophorus pauciradiatus
is the same as Gambusia jonesi, and Ps. retiaulatus is Gambusia bimac-
ulata. Poecilia presidionis is placed in Girardinus, which name is
used instead of the prior Heteraudria which may be ineligible because
no known species were assigned to it. Heteraudria occidentalis is
placed in Poecilia. Poecilia sphenops is made to include mexicana,
thermalis, gillii, chisoyensis, dovii, vandepolli, arubensis, boucardi,
butleri, limantoun, nelsoni and latipunctata. Platypoecilus variegatus
is referred to Poecilia maculata; Mollienesia formora is referred to M.
latipinna; Xiphophinus jalapae is referred to X. helleri. A number
of additional South American cat-fishes are recorded from Panama.
Aelunchthys nuchalis is regarded as identical with A. panamensis, and
Ae. (or Felichthys) scutatus from Panama and Ae. isthmensis from
Colon are described as new.

Netuma vacula is referred to the synonymy of Galeichthys planiceps,
and Netuma clattena to that of G. Kessleri; G. azureus to that of G.
guatemalensis, and G. xenauchen to that of G. lentiginosus. Galeichthys
seemani is made to include G. jordani, G. gilberti and G. eigenmanni;
G. guentheri is described as new, from the Gulf of Mexico.

The name Anus is used in place of the uncertain Tachysurus,
probably with justice. Galeichthys aquaedulce is referred to Anus
melanopus, Tachysurus Steindachneri to Anus fuerthi, Tachysurus
emmelane to Anus multeradiatus and Cathorops gulorus to Anus

hypophthalmus

790 THE AMERICAN NATURALIST [Vor. XLI

The same fauna is again treated by Dr. Seth E. Meek (Publ. Field
Columbian Museum) in a Synopsis of the Fishes of the Great Lakes
of Nicaragua. Rhamdia barbata is described as new from San Fran-
cisco de Nicaragua, and Astyanax nasutus from Managua. Tetra-
gonopterus humitis is the young of Astyanax aeneus. Bramocharax
elongatus is described from Lake Managua, and Dorosome chavesi
from several localities. Poecilia dovii is the same as P. sphenops.
Melaniris sardina is described from Lake Managua, and Pomadasis
grandis from Lake Nicaragua. Erythrichthus is a new sub-genus
based on Heros citrinellus. "This name should be criticised as badly
formed, while the name properly spelled (Erythrichthys) is already
used for a genus of fishes. Dr. Meek gives an interesting account
of the phenomenon of rubrism — the prevalence of red colors in part
of the individuals of these fishes. Cichlasoma granadense is a new
species from various lakes. Cichlasoma dorsatum is another from
Lake Managua and C. nigritum from Lake Nicaragua. Heros
basilaris is the same as C. citrinellus, the type of Erythrichthus.

Fishes of California: In the University of California publications
(Marine Laboratory of San Diego) Edwin C. Starks and Earl L.
Morris of Stanford University give a list of the Marine Fishes of
Southern California. In this well considered list, the range of numer-
ous northern species is extended to the south of Point Concepcion.
The single new species is a flounder, Pleuronichthys ritteri.

Fishes of South America: In the Proceedings of the Washington
Academy of Sciences (VIII, 1907) Dr. Carl H. Eigenmann gives notes
on a Collection of Fishes from Buenos Aires. ‘The fauna is essentially
that of the Amazon, although the region is not tropical. New species
are Plecostomus laplatae, Pomolobus melanostomus, Geophagus australis
and Batrachops scotti. The use of the family name Stolephoridae is
unexplained. The type of Stolephorus is identical with that of Spratel-
loides and the genus belongs to the Dussumieriinae.

In the Annals and Magazine of Natural History (XIX, 1907) Mr.
C. Tate Regan describes Pimelodus boucardi from Yucatan; P.
brachycephalus from Guatemala; P. rogersi from Costa Rica; Gam-
busia annectens from Costa Rica; G. terrabensis from Costa Rica, and
Sicydium pittieri from Costa Rica. Mollienesia jonesi (= Pseudo-
xiphophorus pauciradiatus) is identified as Gambusia jonesi.

In the Proc. U. S. Nat. Mus. (XXXII, 1907) Dr. Eigenmann dis-

cusses the poecilioid fishes of the La Plata Basin. New genera are

No. 492] NOTES AND LITERATURE 791

Acanthophacelus (reticulatus), Ilyodon (Ilyodon paraguensis, new
species), Phalloptychus (januarius) and Phalloceros (caudomaculatus).
Jenynsia is not distinct from Fitzroya.

In Archivos do Museo Nacional (Rio de Janeiro, 1907) Dr. Alipio-
de Miranda Ribeiro begins an elaborate account of the fishes of Brazil.
The first part is devoted to morphology and physiology. The work is
well done, well printed, and with good illustrative plates.

In the Ann. Mag. Nat. Hist. (XIX, 1907) Dr. G. A. Boulenger
discusses the variations of Stercolepis gigas, “a great sea-perch from
California and Japan.” He maintains that the two essential points
of distinction, the higher spines and the larger scales in the Japanese
form, Stereolepis ischinagi, as compared with the Californian S. gigas,
are both fallacious. The spines are much higher in the young fishes,
and the scale count is deceptive.

I am still of the opinion that the two are distinct. The smallest
specimen of Stereolepis known from Japan or California was taken
by me at Santa Barbara in 1880. This has much higher spines than
the adult, but the spines are still lower than in S. ischinagi of much
larger size. In my way of counting the scales are smaller. Moreover,
the young of the Japanese species have broad lengthwise stripes of
black, while the American form is irregularly blotched. A study of
many specimens of different ages is necessary before the question can
be finally settled.

Fishes of Bermuda: In the Bulletin of the Museum of Comparative
Zoology, Thomas Barbour gives notes on Bermudian Fishes, with
numerous additions to the list. Siphostoma dendriticum, a pipe fish
covered with filamentous appendages, is described from Ireland
Island. Callionymus bermudanum is dredged off Castle and Ireland
Islands. Antennarius stellifer is described from Castle Harbor;
Teuthis helioides, a species of bright yellow color, is from Castle
Sound, and Holocentrus puncticulatus from Flate’s Inlet.

Fishes of the South Seas: In the Report of the Bernice Pauahi
Bishop Museum of Honolulu (IV, 1906), Mr. Alvin Seele records the
fishes obtained in his extensive collections in the South Seas, from
the Marquesas to the Solomon Islands. ‘The new species, 33 in num-
ber, are represented rather unsatisfactorily by photographs.

In the same report (vol. II) is a paper by William A. Bryan describ-
ing three new species of fishes from Honolulu. One of these, Zanclus

792 THE AMERICAN NATURALIST [Vol. XLI

ruthiae is distinct from Zanelus cornutus. It is, however, identical
with the original Zanclus canescens recently newly described by Mr.
Regan. The other species are Pseudoscarus heliotropinus and Pseu-
doscarus vitriolinus. Some of the parrot-fishes previously known
from Hawaii are here again described.

In Bull. Dept. Agric., Indes Neerl. (VIII, 1907) Dr. P. N. Van
Kampen describes East Indian mackerels, Scomber kanagurta, which
he identifies with S. loo, S. neglectus and S. brachysomus.

In the same bulletin, Dr. Van Kampen describes a new shark,
Galeocerdo jasciatus, from the East Indies.

In the Sitzungsberichte of the Gesellschaft Naturforschender
Freunde Dr. Erich Philippi notes that the cyprinodont Glaridichthys
is really physoclistous, not physostomus as is supposed to be the case
throughout that family. He notes also that this viviparous genus
does not have a modified anal fin in the male as has been supposed, a
fact already noted by Dr. Meek. The other articles are notes on the
genera Glaridichthys and Cnesterodon.

In the American Journal of Anatomy, 1907, Dr. Charles R. Stock-
ard notes the embryonic history of the crystalline lens of the California
hagfish Eptatretus stouti, which Mr. Stockard calls by the much later
name of Bdellostoma.

In the National Geographical Magazine for June, 1907, Dr. Hugh
M. Smith has an article on “Our Fish Immigrants” and Dr. Gill dis-
cusses Fish that Build Nests, with a series of interesting plates.

In the Pacific Fishermen for September, 1907, Mr. Henry S. Mc-
Gowan discusses the destruction of young salmon by trout. and gives
photographs of stomach contents which show that in all probability
the trout in the northwestern streams kill as many salmon as the
fishermen, taking them when very young.

Jordan and Evermann have already shown the enormous destruction
of young salmon wrought by the Dolly Varden trout (Salvelinus
malma) in Alaska. ‘These photographs show that the steelhead and
cut throat trout are also great offenders in this regard. —

Fishes of Japan: In the Proc. U. S. Nat. Mus. (XXX, 1907)
Jordan gives a review of the Japanese species of Histiopteridae or
boar-fish. New genera are Evistias (acutirostris), Zanclistius (eleva-
tus), Quinquarius (japonicus) vice Pentaceros preoccupied, Gilchristia

No. 492] NOTES AND LITERATURE 793

(richardsoni) and Quadrarius (decacanthus). The name Velifracta
is substituted for Tephritis, a genus of flounders, the latter name being
preoccupied. In the same proceedings, Jordan gives a review of the
Japanese Gerridae, and Jordan and Starks a list of the fishes of the
Riu Kiu or Lu Chu Islands, called Okinawa in Japan. One new
species, Girella mezina, is described. The genus Hierichthys is identi-
cal with Congrogadus.

Fishes of Siberia: In the Proc. U. S. Nat. Mus. (XXXII, 1907),
Dr. Leo Berg of St. Petersburg discusses the cobitoids and the stick-
lebacks of the Amur region. He regards the Asiatic loach, Misgurnus
anguillicaudatus, as a color variation of the European Misgurnus
jossilis, the former being irregularly spotted, the latter with longitudi-
nal stripes. He further regards all the Asiatic specimens, Ussuria
leptocephala Nikolsky, Misgurnus decemcirrosus Basilewaky etc. as
variants under M. anguillicaudatus.

Octonema (preoccupied) and Lefua (Herzenstein 1888) are older
names for the genus called Elxis by Jordan and Fowler, 1903. The
Japanese species is Lefua nikkonis. Elxis coreanus, Nemacheilus
dixoni and Octonema pleskei are regarded as synonyms of the Mon-
golian species Lefua costata. Orthrias oreas from Hokkaido, Berg
regards as identical with Nemacheilus toni from the Amur, and he
thinks it is not generically and scarcely specifically different from the
European N. barbatulus. Like Jordan and Fowler, Berg finds the
common loach, Cobitis taenia, identical in Europe, Siberia and Japan.

The Japanese stickleback, Pygosteus wndecimalis, is identical with
P. tymensis (Nikolsky 1889) from Sakhalin; Pygosteus seindachneri
and P. bussii, are as the present writer has already indicated, identical
with Pygosteus sinensis from China.

Mosquito-eating fishes: In the Bulletin of the Hawaii Exp. Station,
(20, 1907) Mr. D. L. Van Dine gives a valuable account of the success-
ful introduction of Texas top-minnows, as natural enemies of mosqui-
toes. This was done at the instance of the present reviewer. The
work was successfully accomplished by Mr. Alvin Seale under the
auspices of the Honolulu Board of Health and of the Territory of
Hawaii. The species secured were Gambusia gracilis, Fundulus gran-
dis and Mollienesia latipinna from Galveston, Texas. 450 fishes were
taken, 27 being lost on the way. All the species thrive in the new
locality and all are eager in the destruction of mosquitoes, the little
Gambusia perhaps most so.

794 THE AMERICAN NATURALIST [Vor. XLI

Fishes of South Africa: Dr. J. D. F. Gilchrist (Marine Investiga-
tions in South Africa, 1907) describes 15 new species of fishes, some
of them of special interest. Dr. Jacques Pellegrin (Assoc. Francaise |
Avance. Sci., 1906) notes the presence of a genus of Asiatic family
of Nandidae (Polycentropsis) in Africa (Rio Niger).

Fishes of New Guinea: In Resultät. Exp. Sci. Neérl. à la nouvelle
Guinée (Leiden, 1907) Dr. Max. Weber describes the fresh water
fishes of New Guinea with many new species. This is an excellent
paper, well illustrated.

Fishes of the Antarctic: In the Expedition Antarctique Française
(Paris, 1907) Dr. Léon Vaillant describes the fishes, with several new
species. A genus, Artedidraco, commemorates the 200th anniversary
of the birthday of the “Father of Ichthyology,” Petrus Artedi.

In Illustrations of the Zoology of the Investigator (Calcutta, 1905),
Alcock and MacGilchrist figure deep sea crustaceans and fishes
already described.

In the Sitzungsberichte of the Academy of Vienna (1907, XXVIII),
Dr. Steindachner describes a number of fishes from Jurua, Brazil,
and in two other papers, other species from streams of southern Brazil,
the greatest number being from Rio Cubatao.

Dr. Louis Dollo (Proc. Royal Soc. Edinburgh, XXVII, 1907) notes
the rediscovery of a singular pelagic fish, Prymnothonus hookeri, which
he regards as an ally of Paralepis.

Mr. J. Douglas Ogilby in the Annual Report of the Amateur Fisher-
men’s Association of Queensland (Brisbane 1907) gives a list of the
species of fishes in the collection, with new generic names, undefined,
but with indicated types as follows: Batrachomoeus (coecus DeVis)
“the Greater Frog-fish,” Brachaelurus (colcloughi, new species) the
“Blue Gray Blind-shark,” Coryzichthys (diemensis Le Sueur) the
“Banded Frog-fish.” These were described in a paper read March
23, 1907, but the accounts have not yet appeared. A number of new
species to be described are also indicated, the types being in this col-
lection.

In the Records of the Canterbury Museum (1907, I) Mr. Edgar R.
Waite gives a list of the fishes of New Zealand, 252 species are recorded.
This figure shows how far from complete is our knowledge of New
Zealand fishes. It is safe to say that a thorough survey of these waters

No. 492] NOTES AND LITERATURE 795

such as Mr. Waite contemplates will yield double this number of shore-
fishes, although the isolation of New Zealand is doubtless a reason
why the fauna is relatively scanty as compared, for example, with that

of Japan. ‘The shore-fishes of New Zealand are for the most part
_ distinct from those of Australia.

The writer has lately received through the courtesy of Mr. J. H.
Tole of Auckland, a little known volume, Handbook of the Fishes of
New Zealand, published by R. A. Sherrin, at Auckland in 1886.
This book is largely a compilation, but an intelligent one.

In Zool. Anzeiger (XXVIII, 1905), Professor Robert Collett de-
scribes a number of fishes from the Azores, one of them, Lampadena
. chavesi, being new.

Dr. F. Guitel of Rennes publishes (Archiv. Zool. Exper. 1904)
comparative descriptions of species of Lepadogaster the beginning of a
general anatomical and systematic study of the Gobiesocide, in which
he asks the cooperation of naturalists.

In the Smithsonian Miscellaneous Collections (1907) Dr. Theodore
Gill gives an elaborate account of “Noteworthy Extra-European
Cyprinids,” a comparative study of dace, minnows, roach, horny-
heads and shiners of America and Asia.

In another paper Dr. Gill gives an outline of the strange life-history
of toad-fishes, weevers and stargazers, with plates.

Classification of Fishes: In Ann, N. Y. Acad. Science (XVII,
XXIX, XXX, 1907) Dr. William K. Gregory of Columbia discusses
the orders of teleostomous fishes. This is a peculiarly wise and
temperate discussion of one of the most difficult of problems, the
arrangement of the bony-fishes in tangible, definable and natural
groups. Dr. Gregory recognizes that “degrees of blood relationship
do not exactly correspond to degrees of homological structural resem-
blances and differences nor to the divisions of classification.” He
also recognizes that distinctness in groups is often dependent on the
extinction of intermediate forms. He discusses in excellent fashion
the strength and defects of the “English and American schemes of
Classification,” and shows that these are in fact nearer to each other
than they appear. “The idea underlying the American method is
that the best way to map out the topography of this varied morphologi-
cal expanse is to assign a name to every conspicuous cluster of eleva-
tions, even if some lower elevations may connect with neighboring

796 THE AMERICAN NATURALIST [Vor. XLI

systems.” On the whole Gregory inclines to the American system
and approves of “Gill’s principle of keeping groups apart until they
are shown to belong together.” No linear series and no grouping of
these fishes into orders and suborders can ever be satisfactory to any- _
one, for the forms in question exhibit a great variety of interrelations
and divergences. The classification of Dr. Gregory is however about
as satisfactory as any one which is current, and it represents a great
amount of careful investigation and comparison.

Ecology of Fishes: In the Journal of Geology (1907) Dr. John C.
Branner discusses the coastwise streams about Monterey Bay, with
reference to present distribution of the fish fauna. He shows that
the latter is dependent on the former courses of these streams.

In the Bull. Bureau of Fisheries (XX VI for 1906) Prof. Chauncey
Juday gives an elaborate study of the Twin Lakes in Colorado, with
especial reference to the food of the trout, Salmo stomias.

In the Rept. of the Director of the New York Aquarium, Mr.
Charles H. Townsend, discusses the cultivation of fishes in ponds.

Anatomy of Fishes: In the Biological Bulletin (XII, 1907) Dr. H.
D. Senior erg: the conus arteriosus of two of the most primitive
of bony fishes, Tarpon atlanticus and Megalops cyprinoides, with
Eee a that of other related forms. In Albula, Tarpon, and
Megalops there are two rows of valves. Ordinary bony fishes have
but one, while in the ganoid fishes, there are three (Amiatus) or more.
In Elops, Chanos, Hiodon, Osteoglossum, Notopterus and Mormyrops,
but one row of valves has been found. In Dorosoma, there is a trace
of a rudimentary second row. This strengthens the suggestion that
the Megalopidae, (Megalops, Tarpon) should constitute a family
distinct from Elops.

In the Proc. Wash. Acad. Sciences, 1907, Mr. W. F. Allen of Stan-
ford University discusses very fully the distribution of the sub-cutane-
ous vessels of the head in the gar pike and paddle fish.

In the Budgett Memorial Volume (Cambridge, England), Dr. J
Graham Kew of the University of Glasglow, discusses with great com-
pleteness the embryology of the crossopterygian fish, Polypterus sene-
galus. In this paper, Dr. Kew upholds his theory as to the origin of
the vertebrate limb from modified gills rather than from a lateral fold
or from a gill septum.

No. 492] NOTES AND LITERATURE 797

In the Journal of Experimental Zoology (IV, 1907), Mr. Charles
R. Stockard discusses the influence of external factors, chemical and
physical on the development of the egg of the killifish (Fundulus).

Fossil Fishes: In the Bull. of Geology of the University of Cali-
fornia, Dr. D. S. Jordan describes the fossil fishes known from the
rocks of California, with supplemental notes on other extinct fishes.
43 species are known from California. Acrodus wempliae, Heptran-
chias andersoni, Isusus smithii, Carcharodon arnoldi, C. riversi and
C. branneri, Xenesthes velox, Etringus scintillans, Rogenio solitudinis
and R. bowersi, and Merriamella doryssa are described as new.
Xenesthes, Etringus, Rogenio and Merriamella are new genera. Ro-
genio, a new genus, doubtfully referred to the Cobitopsidae, shows a
remarkable resemblance to the New Zealand white bait, Retropinna,
and is possibly a fossil smelt. Etringus is a curious form with
enamelled ganoid scales, and the body of a herring. Merriamella
seems to be an athenoid with a small spinous dorsal fin.

The genus Knightia (K. eocaena) from the Green River Eocene is
characterized, and also a new species of sucker, Chasmistes oregonus
(Starks) from Oregon. Teeth of fossil salmon from the Quaternary
of Oregon show the extreme age of the anadromous habit of the salmon
of the Columbia.

In the Memoirs of the New York State Museum (X, 1907), Dr.
Charles R. Eastman presents an elaborate monograph of the Devonic
fishes of the New York formations, with a series of excellent plates.
Interesting discussions of the relationship of Bothriolepis and other
ostracophores is given, the author regarding these forms as a distinct
class, but not accepting the recent bold speculations of Dr. William
Patten, who compares these forms with Limulus and other spider-like
crustaceans.

Mr. George P. Merrill publishes a catalogue of the fossils, minerals
and ores in the United States National Museum (1907). This cata-
logue furnishes. a useful list of the fossil fishes. All the California
species above noted — even the abundant sharks’ teeth — seem to be
wanting in the national collection.

In the Bulletin Mus. Comp. Zool. (vol. L, 1907) Dr. Eastman dis-
cusses the dentition of the mylostomid Arthrodires, giving further
reasons for regarding the Arthrodires as specialized Dipnoans. A new
species is described from the Cleveland Slate, as Mylostoma newberryi.

798 THE AMERICAN NATURALIST [Vor. XLI

In the Bulletin Amer. Mus. Nat. Hist. (XXIII, 1907), Mr. L.
Hussakof describes a fossil surgeon-fish from Antigua Island, West
Indies, in rocks supposed to be of Eocene Age. The species, repre-
sented by a very complete skeleton is named Zebrasoma deani. This
species is the first of the family of Hepatidae (Teuthidae) found in
America, and it is the only fossil species of the genus Zebrasoma. The
pertinence of the species to the living genus Zebrasoma may be ques-
tioned. The first dorsal spine is the longest and seems semi-detached.
In Zebrasoma the first is much shorter than the others. The soft fins
in Zebrasoma are very high. In Z. deani, they are quite low. The
caudal peduncle is slenderer in Z. deani and the tail much more widely
forked than in any species of Zebrasoma. ‘The number of vertebra
(8 + 11 = 19) is fewer than in living Hepatidae (22). The caudal
spine possibly existed, but if so, it is lost in this specimen.

If the fish is to be referred to an existing genus, Callicanthus with
a slender tail and a widely forked fin, with the first of the five dorsal
spines enlarged and with the vertical fins low, is nearer to the species
than is Zebrasoma. ‘The profile in Callicanthus is curved while in Z.
deani, it is very straight.

In the Bulletin de la Societé Belge de Geologie (XXI, 1907), Dr.
Louis Dollo endeavors to show that the ptyctodont fishes, supposed to
be fossil chimaeroids, really belong to the order of Arthrodires. He
further concludes that the chimaeras are specialized cochliodonts,
changed through the necessities of deep sea life and a food of mollusks.
Dr. Dollo further adds that “the idea of the Irreversibility of Evolu-
tion which has led me to the conclusions I have just justified, has once
more shown its utility, else one would be led to maintain that specialized
organisms might become in the process of descent again primitive, in
order to become again specialized in the same or in different direction.”

Davip STARR JORDAN.

Notes on the Structure of Insects.— A Study of the Common House-
Fly. — That one need not search far for profitable objects of research
is evidenced by the mass of interesting material presented by Mr. C.
H. Hewitt’s studies of the common house-fly, Musca domestica. In
the first of a series of three papers dealing with the anatomy, develop-

- 1 Hewitt, C. G. The structure, development, and bionomics of the rona
fly, Musca domestica. Part 1.— zuen: of the fly. Quar.
Mier. Sci., 1907, li, pp. 395-448, pls. 22-26

No. 492] NOTES AND LITERATURE 799

ment, and bionomics of the species, is considered especially the ana-
tomy of the adult.

Various species are popularly confused with M. domestica and the
author therefore discusses the characters by which this — the true
“house-fly” — may be distinguished. External anatomy is then
considered and an attempt is made to homologize the various sclerites
with those already recognized in the simpler orders of insects. Most
of the terms introduced by Lowne are discarded and a number of
inaccuracies in his descriptions are corrected. In the discussion of
the wing veins the Comstock-Needham nomenclature is adopted
since, ‘‘on account of its great morphological value it will no doubt
_ in course of time replace the present confused system.” By an over-
sight the free parts of M, and of Cu, are referred to as the medio-cubital
and the cubito-anal cross-veins respectively.

Macroscopic features of the internal structure are described in
detail, though there is little discussion of the histological features.
Especially detailed are the accounts of the tracheal system, and of
the musculature. The four double plates illustrating the anatomy
are well executed, but the plate illustrating the imagos of Musca
domestica and related species is too highly colored.

The Segmentation of the Insect Head.— Holmgren’ discusses the
moot question as to the number of segments in the head of the dipter-
ous larva. In opposition to Bengtsson ’97 and ’05, he maintains that
the suboesophageal ganglion includes but three segments. In support
of his contention that the endolabium represents a separate segment,
Bengtsson has cited; 1, — an independent innervation from the sub-
oesophageal ganglia and ¢ertain suggestive structural relations of this
part; 2,—the development; and 3,— comparison with other forms.

Holmgren shows that the so-called endolabial nerves of Bengtsson
are muscles, as is most clearly brought out in thin sections treated
with iron-haematoxylin. The slight elevation which was supposed to
represent a distinct ganglion in the sub-oesophageal complex is caused
by the contraction of the muscles. Postembryonic development can-
not decide the question, for the presence of a fourth pair of imaginal
discs with peripodal cavities does not prove that these are homodynam-
ous with legs, and therefore with the mouth parts (cf. origin of eyes
or wings).

Finally, Holmgren maintains that evidence drawn from Folsom’s

1 Holmgren, N. Zur Morphologie des Insektenkopfes, Zool. Anz., 1907,
Bd. xxxii, pp. 73-97.

800 THE AMERICAN NATURALIST [Vor. XLI

discovery of a fourth segment in the suboesophageal ganglion of
Anurida is entirely useless since the endolabium of Phalacrocera
larva is not homologous with the paraglossae of the Thysanura.

The Habits and Structure of a Myriapod.— S. R. Williams! presents
many new observations on the habits and structure of the interesting
myriapod, Scutigerella immaculata. Its distribution, environment,
light and water relations, and food habits are discussed. Experi-
mental evidence favors the conclusion that the species is carnivorous.
There is also presented considerable data regarding the eggs and the
larvae. The newly-hatched larva has seven pairs of legs while the
adult has twelve pairs. The author regards it as a highly specialized
young, rather than a generalized ancestral form such as the hexapod
larva of other diplopods is considered to be.

Musical Organs of the Cicadidae— Among the most remarkable and
effective voice-organs of the entire animal kingdom are the “drums”
at the base of the abdomen of the males of the “ seventeen-year locust”
and their relatives in the family Cicadidae. It would seem that for
these insects any other musical apparatus would be superfluous but
Jacobi,” ’07, reports finding in the cicadid genus Tettigades, from
Chili, stridulating organs very similar to those already reported for
certain beetles, ants, and other forms. They consist of a pair of oval,
roughened file-like areas on the dorsal part of the prothorax, just
within and caudad of the bases of the front wings. On the caudal
angle of each front wing is a thickened flap which serves as a scraper.
Unlike the abdominal musical organs these stridulating organs are
equally developed in both sexes.

W. A. RILEY.

British Rhizopods:*— No group of organisms affords quicker or
more satisfactory returns to the amateur microscopist than do the
fresh water Rhizopoda, and few offer to the specialist greater oppor-
tunities for experimentation and investigation or more puzzling prob-
lems in the determination of species and the tracing of life histories.

ı Williams, S. R. Habits and structure of ren immaculata. Proc.
Bost. Soc. Nat. Hist., 1907, xxxiii, pp. 461-485, pl. 3

2 Jacobi, A. Ein Schrillapparat bei Singeicaden. ga Anz., 1907, xxxii,
pp. 67-70.

®The British Freshwater Rhizopoda and Heliozoa. By James Cash and
John Hopkinson. Vol. I. Rhizopoda. Part I. 150 pp. 16 Plates. London
1905.

No. 492] NOTES AND LITERATURE 801

It is therefore a matter of congratulation to all who are interested in
this inviting field to learn that Messrs. Cash and Hopkinson have
undertaken the preparation of a monograph of the Rhizopoda and
Heliozoa of the British Isles. Penard’s exhaustive treatises upon these
organisms of the Swiss lakes have provided continental Europe with a
very complete account of these protozoans and the present work aims
at a similar analysis of the British fauna. The first volume includes
the order Amoebina and a small part only of the Conchulina, proposed
by the author in place of the Testacea of M. Schultze. In all, 17
genera and 46 species are described. The work is illustrated with
well-executed lithographic plates and numerous text-figures, and is
provided with very complete bibliographic and synonymic references,
supplementing in these respects the more detailed and extensive works
of Penard. The fullness of the bibliographic lists is shown by the fact
that the references under Amoeba proteus occupy five closely set pages.

The introductory chapter discusses briefly the structure and activities
of the rhizopodan cell and the structure and method of formation of
the test. The discussion of the distribution and known habitats of
the various genera and of the best methods of collecting rhizopods is
both instructive and helpful. We note the revival of Leidy’s genus
Ouramoeba founded on individuals bearing a peculiar filamentous
appendage. Professor W. L. Poteat has shown! that these supposed
appendages are merely the mycelial hyphae of some parasitic fungus,
a view which Penard also subsequently adopted. The authors seem
not to have been aware of Poteat’s work.

C. A. Kororp.

BOTANY

Recent Studies on Gymnosperms.— Among the numerous recent
contributions to our knowledge of the gymnosperms several are of more
than usual importance. These deal with all the four orders and
include work both on living and on fossil forms.

The discovery of spermatozoids in the cycads in 1896, and of those of
Gingko at about the same time by the Japanese botanists Ikeno and
Hirase, and shortly after Webber’s studies on Zamia, gave a great
impetus to the investigations on these very important plants, and our

1 Poteat, W. L. Leidy’s Genus Ouramoeba. Science, N.S. vol. 8, p. 778-
782.

802 THE AMERICAN NATURALIST [Vor. XLI

knowledge of these forms has been very ea increased during
the past decade.

Among the most important of the more recent papers are those
of Chamberlain (The Ovule and Female Gametophyte of Dioon.
C. J. Chamberlain. Bot. Gaz., XLII, Nov. 1906, pp. 322-358. Pls.
XII-XV. Preliminary Note on Ceratozamia. Ibid., XLIII, Feb.
1907, p. 137) and that of Caldwell on Microcycas calocoma (Microcy-
cas Calocoma. O. W. Caldwell. Bot. Gaz., XLIV, Aug. 1907, pp.
118-141).

The three genera treated in these papers are all peculiar to America.
Dioon and Ceratozamia being Mexican, while Microcycas is confined
to a limited district in the western part of Cuba.

Professor Chamberlain made careful studies in the field, where he
collected a good deal of material, but his studies also included living
material sent to Chicago from the region where Dioon grows. ‘The
latter is abundant in a region about twenty-five kilometers from
Xalapa, the capital of the state of Santa Cruz. Apparently Dioon is
confined to this very limited area. The plant much resembles Cycas,
but does not attain the dimensions of C. revoluta or C. circinalis as.
these occur in their native habitats. The largest specimen seen had a
height of only three meters; but nevertheless it was estimated that.
these plants were at least one thousand years old. The growth is
excessively slow, and a careful study of the rate of growth of plants
in cultivation has led to this extraordinary estimate of the age of the
larger plants.

The plants are said to fruit freely every other year. The ovulate
cones are very large, sometimes weighing six kilograms or more, and
the large size of the sporophyll approximates that of Cycas, although
the sporophylls are arranged in a definite cone. The lower leaves of
the cone are sterile and there are intermediate forms between these
sterile leaves and those that bear the ovules. Each perfect sporophyll
bears two very large ovules, which may reach a length of four centi-
meters. The ovules do not ordinarily attain their full development
unless pollination takes place.

Full details are given of the methods used in studying the develop-
ment of the ovule and there is also a complete account of its morphol-
ogy. The question of the possible double nature of the integument
is left unsettled.

At the time of pollination there is a voidan amount of tissue
at the apex of the nucellus, above the embryo sac; but later this is
destroyed, partly by the growth of the pollen tubes and embryo sac,

No. 492] NOTES AND LITERATURE 803

and unquestionably the pollen tubes come into direct contact with
the archegonia. A pollen chamber is present as in the other cycads,
immediately after pollination. A very conspicuous jacket surrounds
the endosperm, and the megaspore membrane is easily identified.
The walls of these jacket cells are strongly suberized. The jacket
cells seem to be concerned with the nutrition of the endosperm.

Unfortunately the younger stages of the gametophyte could not be
secured. ‘The earliest ones collected in November already had the
initials of the archegonia developed. The development of the latter
is probably not essentially different from that of Cycas. The prothal-
lium is fully developed in April and at this time the archegonial cham-
ber is complete. The megaspore membrane becomes thick and shows
the clear differentiation into an endospore and exospore as in the
heterosporous pteridophytes.

The archegonia are enormously large and there may be as many
as ten present. As in the other cycads that have been investigated,
there are two neck cells. A ventral canal cell nucleus is separated
from the very large egg nucleus. The number of chromosomes was
estimated to be twelve. ‘The egg may reach a length of six millimeters,
and the nucleus is correspondingly large, in some cases being as much
as 6004. in diameter. In spite of this enormous size, the nature of its
minute structure was not satisfactorily made out.

The paper is accompanied by several excellent photographs and
by three plates.

Chamberlain’s second paper is a preliminary note on the Mexican
genus Ceratozamia. This differs much in its habitat from Dioon,
being a shade-loving form, while Dioon is markedly xerophytic. Fer-
tilization was found to occur more than a year subsequent to pollina-
tion. Motile spermatozoids resembling those of Cycas and Zamia
were seen. The seed has no resting period, but growth is continuous
from the time of fertilization to the emergence of the young sporophyte
from the seed.

Professor Caldwell’s paper on Microcycas calocoma is a very interest-
ing account of a little known cycad from the sierra of western Cuba.

In habit, the plant recalls Cycas revoluta, and like that species shows
various forms of branching. The largest specimens attained a height
of more than nine meters.

The ovulate cones are the largest yet known. One of these measured
ninety-four centimeters in length and weighed nine and five tenths
kilograms. ‘The staminate cone is much smaller.

The most important discovery made was the remarkable character

804 THE AMERICAN NATURALIST [Vor. XLI

of the male gametophyte, which is the most primitive yet discovered
among the seed bearing plants. The fully developed pollen tube
contains a prothallial cell, a tube nucleus, stalk nucleus and eight
body cells, each of which develops two large sperm cells, thus giving
rise to sixteen large spermatozoids similar to those known in several
other genera of cycads. In exceptional cases as many as ten body
cells were noted. Whether, as seems probable, the eight body cells
are formed from the division of a primary one was not determined.
The male gametophyte of Microcycas is thus seen to be less reduced
than that of some heterosporous pteridophytes, e. g. Isoetes, Salvinia,
Azolla, while no other living seed plant is known to show more than
two generative cells, unless possibly Araucaria, where a large number
of nuclei have been reported in the pollen tube, the exact nature of
which, however, is somewhat problematical.

The development of the female gametophyte was not followed in
detail, but it was found that the number of archegonia is very large,
sometimes exceeding two hundred. So far as could be determined,
the archegonium is of the same type as that of the other cycads.

The ripe seed contains a single large, straight embryo, with three
to six cotyledons. The young plant produces a tuberous stem several
centimeters in length before the first true leaf emerges. The author
concludes that Microcycas is the most primitive of all the known
cycads. The paper is illustrated by a number of excellent photo-
graphs and there are three plates showing the most important points
` in the development of the gametophyte.

The remarkable series of fossil cycads from different regions in the
United States, but especially from the Black Hills of Wyoming and
South Dakota has been exhaustively treated in the magnificent memoir —
by Wieland (American Fossil Cycads. G. R. Wieland. Carnegie
Institution of Washington, No. 34, 1906). Space will not permit a
complete review of this volume, which comprises nearly three hundred
quarto pages, with fifty plates and many text figures. The work is
mainly based upon the great collections in the museum of Yale Uni-
versity, the most important collection of fossil eycads in existence.

The introductory chapter deals with the discoveries and collections
of fossil eycads in Europe and America. The second chapter treats
of the preservation of the fossil forms and discusses at length the exter-
nal characters of living cycads. A number of admirable figures are
given, including some of the curious culture forms of Cycas revoluta,
which is a favorite with Japanese gardeners. Some of these garden
forms are curiously like many of the fossil eycad trunks. An interest-

No. 492] NOTES AND LITERATURE 805

ing account is given of the methods used in cutting sections of the
petrified trunks. Tubular drills were employed to cut out solid cores
for studying fruits, etc. These cores were then sectioned in the desired
directions. In this way the trunks could be fairly well preserved.

Chapter four is concerned with the structure of the trunk, both the
external layer, which is mainly composed of large, closely packed
scales, “‘ramentuin,” and the internal structure, which is often pre-
served in a very perfect way and makes the structure of the trunks
perfectly clear. For details the reader must be referred to the memoir.

The leaves of the fossil cycads have been preserved in many instances
in a remarkably perfect manner, even the young unfolded leaves being
clearly evident in some specimens. This is particularly the case in
one species, Cycadeoidea ingens. The young leaves were apparently
quite similar to those of Dioon or Macrozamia. As is the case with
the stem, the internal structure of the leaves is also perfectly preserved.

It is the reproductive parts of these fossil cycads, however, that are
of the greatest interest. While some of these are of the same type as
those of the living cycads, one group, sometimes separated from the
true cycads as a special order, Bennittitiales, had bisporangiate cones,
which apparently were curiously like the flowers of certain angiosperms.
Some of these have been preserved in a wonderfully perfect manner
owing to the young cones being completely protected by the armor of
scales in which they were imbedded. The “flower” consists of a
central conical receptacle which bears slender sporophylls, each one.
terminating in a single ovule. Surrounding this ovulate receptacle
was a series of pinnate microsporophylls, each one bearing a large
number of “synangia,” extraordinarily like those of the fern Marrattia.
Surrounding the whole strobilus was a series of elongated scales or
bracts very much like the floral envelopes of certain angiosperms.

The type of cone shown in these Bennettiteae is much more special-
ized than that of the living cycads, but it is questionable whether the
resemblance to the angiospermous flower is anything more than a
coincidence. Nevertheless in the search for the ancestors of the pre-
vailing type of seed plants, one is tempted to assume an actual relation-
ship between these and the Cycadeoideae.

The preservation of the seeds is also very perfect, and in some cases
dicotyledonous embryos can be recognized within the petrified seeds,
Some of the specimens of the young ovules were very perfectly preserved
and these showed what seemed to be prothallial structures suggesting
those of Gingko. More evidence, however, is necessary before it can
be certainly decided what was the process of the development of the

806 THE AMERICAN NATURALIST [Vor. XLI

prothallium and embryo. The species in which the bisporangiate
cone is best shown has been named Cycadeoidea dakotensis.

In chapter nine there is given an excellent comparison of the exist-
ing and fossil eycads. There are but one hundred and seven described.
species of living cycads, included in nine genera, of which four belong
to the New World and five to the Old World (including Australia).
As we have seen in the consideration of Chamberlain’s and Caldwell’s
papers, three of the four American genera are of very limited distribu-
tion, Zamia being the only American genus of fairly extended range.
Three of the Old World genera, i. e. Cycas, Encephalartos and Macro-
zamia, are much more widespread. As is well known, the cycads
were a predominate plant type during most of the Mesozoic, when this
type reached its culmination.

The affinities of the cycads with ferns have been long recognized
and Wieland’s work strongly confirms the view that these have arisen
from ferns of marattiaceous affinity. The extraordinarily Marattia-
like microsporangial sori of Cycadeoidea are especially striking in this
connection. Wieland discusses the question whether the Cycadeoi-
deae, that is, those forms with bisporangiate cones, should be separated
as a special order, Bennettitiales, as recognized, among other authori-
ties, by Engler and Prantl. ‘This view is not accepted by all botanists
however, some of whom, like Scott, recognize three families, Cycadeae,
Zamieae and Bennittiteae, all referable to a single order, Cycadales.
This latter view is supported by Wieland, who believes that from the
great complex of Cycadofilices or Pteridosperms (seed-bearing ferns)
a group which is now known to have been highly developed during
the Paleozoic, there arose the common ancestors of the true cycads
and Bennittiteae, the group becoming more and more divergent as
they developed through the Mesozoic. Of these two divisions, only
the true cycads have survived to the present time.

The final chapter is taken up with a discussion of the relation of the
cycads to the ferns and of the analogies exhibited between the flower
of the Cycadeoideae and those of the angiosperms. The strong
evidence that the Cycadales are descended more or less directly from
marattiaceous ancestors is summarized, and after pointing out the
numerous points of resemblance the author says: “Plainly the
preceding résumé of the principal characters of the two great cycad
groups as combined and showing their descent from marattiaceous

ferns of the Paleozoic is not merely conclusive, but one of the great
cornerstones upon which the plan of evolution can rest secure.”
It is evident that having to deal with such an enormously compli-

No. 492] NOTES AND LITERATURE 807

cated plexus of forms as the ferns and pteridosperms of the Paleozoic,
it is well nigh impossible to come to a definite conclusion as to the
question of the common origin of the cycads proper and Cycadeoideae
and the question of the possible relation of these on the one hand to
the other gymnosperms, and on the other to the angiosperms. “It is
believed in the Cycadeoideae and especially in the persistence in such
highly organized plants of the marattiaceous synangium that we get
the first unmistakable hint of the nature of angiosperm evolution and
the further view would seem to be justified that while the staminate
dise surrounding the ovulate axis of Cycadeoidea indicates primarily
an evolution terminating, so far as now possible to trace, in the gymno-
sperms, the juxtaposition of parts is exceedingly suggestive of the
possibility, if not the manner as well, of angiosperm development
directly from filicinean forms.”

The discovery that many of the supposed Marattiaceae of the Paleo-
zoic are really seed-bearing plants, Pteridosperms, emphasizes the
importance of the Marattiaceae as the ancestors of the higher seed-
bearing types. Whether or not we may agree with all of the author’s
conclusions, this magnificent memoir must remain an indispensable
source of information for every student interested in the fascinating
problems of the origin of the higher plants.

The development of the ovule and female gametophyte in Ginkgo-
are treated in a recent paper by Miss I. E. Carothers (The Develop-
ment of the Ovule and Female Gametophyte in Ginkgo. Bot. Gaz.,
43, pp. 16-130, Feb. 1907). ‘The most important point brought out
in the course of this study is the fact that a large amount of chlorophyll
is developed in the tissues of the gametophyte. This seems to be the
only instance known where the endosperm develops chlorophyll,
except in the case of Cycas, where it has been found that under certain
conditions the prothallium may grow out of the ovule and on exposure
to the light may turn green. ‘The paper is accompanied by two plates.

Among the most important of the recent papers on the development
of the Coniferae may be mentioned two by Lawson (Gametophytes,
Fertilization and Embryo of Cephalotaxus Drupacea. A. A. Lawson.
Annals of Botany, XXI, 1907. The Gametophytes and Embryo of
the Cupressinee with Special Reference to Libocedrus decurrens.
Ibid., XXI, Apl. 1907).

The first of these papers deals with Cephalotaxus drupacea. In
this species the macrospore remains undivided until a very short time
before it is shed, when it divides into two cells, the tube cell and the
generative cell. No vestigial prothallial cells are present. After the

808 THE AMERICAN NATURALIST [Vor. XLI

separation of the stalk nucleus from the antheridial cell the latter has
its nucleus divided into two equal sperm nuclei, but there is no division
wall formed between them. Both sperm nuclei enter the archegonium.
Probably only one megaspore develops a prothallium. The membrane
is almost wanting and in this respect as well as in some others the
Taxaceae are regarded as less primitive than the other conifers. The
development of the prothallial tissue follows the usual course found
in the Coniferae. The archegonia, which are usually four in number,
offer no marked peculiarities. There are two or three neck cells,
and Lawson failed to confirm the statement of Arnoldi that the nuclei
of the jacket cells pass into the egg cell, and he does not think that the
“proteid vacuoles” of the egg have any connection with the nuclei
of the jacket cells. A ventral canal cell nucleus is always found.

Of the two sperm nuclei that enter the egg only one is functional.
After fertilization the fusion nucleus divides until eight free nuclei
are formed. ‘The next divisions are accompanied by cell walls. Only
one embryo is normally formed from each archegonium. The embryo
shows a more or less clear division into four tiers, of which the lower-
most forms a cap over the apex of the embryo proper. Very long
suspensor cells develop from the tier above the embryo proper and
these push the embryo into the endosperm. Secondary suspensor
cells are later developed from the upper part of the embryo itself.

The author’s conclusions as to the systematic position of Cephalo-
taxus are as follows: “From this account of the gametophytes it
becomes obvious that Cephalotaxus cannot be regarded as a primitive
type of the Coniferae, although this is contrary to the results obtained
from certain studies on thesporophytes. .... Worsdell regards Cephalo-
taxus as the most ancient of the coniferous genera and concludes that
this genus forms in a measure the connecting link between the Cycada-
ceae and Coniferae. .... By comparing the gametophytes of Cephalo-
taxus with the Cycadales and with the Coniferales, I cannot accept
Worsdell’s view. In fact I am forced to the conclusion that this
genus represents a very recent type of conifer.”

In the study of the Cupressineae, Dr. Lawson has taken as the
principal form for study the incense cedar, Libocedrus decurrens, of
the Pacific Coast, one of the noblest members of the family. The
material was collected from the fine collection of conifers growing
upon the grounds of Stanford University.

Pollination occurs in Libocedrus decurrens as grown at Stanford
late in March or early in April. Like the other Cupressineae the
_ pollen spores are small and each contains two cells, the smaller one

No. 492] NOTES AND LITERATURE 809

being the generative cell, which afterward divides into a stalk and
body cell. The latter produces two similar male cells and this seems
to be the rule in the Cupressineae. No sterile prothallial cells such
as occur in the Abietineae and Cycas have been found in any Cupressi-
neae. ‘The other genera, in which a similar division was observed.
were Cupressus, Chamaecyparis, Thuja, Cryptomeria and Taxodium.
Both of the latter, according to Lawson, show close affinity with the
Cupressineae, with which, however, they are not usually associated.
Libocedrus, in the history of the male gametophyte, approaches most
nearly to Thuja.

Two megaspore mother cells are usually present and from each of
these four megaspores arise. Only one of the latter, however, develops
a prothallium, the others being apparently destroyed by its further
growth. The megaspore in its earlier stages of growth contains
several vacuoles which ultimately fuse into a single large central one
surrounded by a parietal layer of cytoplasm. In the latter are many
free nuclei as in other conifers. The development of the cellular
tissue from the multinucleate protoplasmic layer seems to closely
resemble what has been described in various other conifers and seems
to offer no marked peculiarities.

The archegonia in Libocedrus as in Thuja and Juniperus are in a
compact group and number from ten to fifteen. ‘There are five or six
neck cells and as in other Cupressineae and in Cephalotaxus, the
ventral canal cell is represented only by the nucleus, there being no
proper ventral canal cell. The whole group of archegonia is sur-
rounded by a layer of jacket cells, but no direct protoplasmic connec-
tion could be shown between the latter and the egg cell and it is
considered probable that the transfer of food substance takes place
through the cell walls.

The actual fertilization was observed in both Thuja and Chamae-
cyparis and in both cases it was shown that the male nucleus escapes
from the cytoplasmic envelope of the male cell, and coming into con-
tact with the egg nucleus, presses into it at one side. Finally the
fusion is complete. The fusion nucleus divides until eight free nuclei
result, a condition that seems to be universal in the Cupressineae.
The organization of the suspensor and embryo proper agrees closely
in all forms studied

Lawson considers the Cupressineae as less primitive than the Abie-
tineae, but more so than Cephalotaxus. Three excellent plates com-
plete the paper.

The Araucariaceae have naturally received less attention than the

810 THE AMERICAN NATURALIST [Vor. XLI

more accessible northern coniferous types and there is much need of a
critical study of this important family. The important memoir of
Professor Seward (The Araucarieae, Recent and Fossil. A. C.
Seward, F. R. S. and Sibille O. Ford. Phil. Trans. Royal Soc.,
series B, vol. 198, pp. 305-411, 1906) is therefore especially welcome.

he Araucariaceae are with few exceptions confined to the southern
hemisphere, and although cultivated to a limited extent in the milder
portions of Europe and in California they are not readily accessible
to most of the students of the conifers and doubtless this largely is
responsible for our imperfect knowledge of the more important points
in their development.

The genus Agathis (Dammara) is confined to tropical and sub-
tropical regions of Indo-Malaysia and Australasia. The Philippine
Islands mark the northern limit of the genus. In the northern island
of New Zealand, the home of the famous Kauri pine (Agathis australis)
the latter species is said to extend to 38° S. Except for A. robusta of
Queensland and some species from the Malay peninsula, the species of
Agathis are essentially island types.

Full diagnoses are given of the species, of which eight are recognized
in Agathis and eleven in Araucaria. Several doubtful species are
also described. A full account is given of the anatomy of the genera
and there is also included an account of the seedlings of several species
of Araucaria. |

Araucaria is confined entirely to the southern hemisphere, but while
most of the species occur in the Australasian region, no less than five
belonging to New Caledonia, there are two very distinet species in
South America, A. imbricata, in Chile and A. braziliensis in Brazil.
As the Araucariaceae are for the most part trees of warm, moist cli-
mates, it is not surprising that growth rings are very feebly marked
or may be entirely absent. It is interesting to note, however, that
Seward found in the trees of A. imbricata grown in England, well
marked annual growth rings. The strobili, both male and female,
especially in Araucaria, show very gradual transitions from the foli-
age leaves to the sporophylls. This seems to strengthen the view that
both male and female sporophylls are directly homologous with the
foliage leaves and this is the view that Seward accepts.

The male flowers of Araucaria are noticeable for their relatively
large size, much exceeding that of the other conifers. The number of
pollen sacs is large. These sporophylls of A. imbricata are 1.9 centi-
meters in length and may have as many as nineteen sporangia. T he
= sporophylls of the large female cones bear a single very large seed,

No. 492] NOTES AND LITERATURE Sit

which in Agathis is provided with a single wing. In Araucaria the
scale develops a ligulate appendage and the ovule is imbedded in the
tissue.

The ovule and embryo were only casually studied and not much is
added to what we knew before in regard to these. `

The fossil Araucariaceae are perhaps of even more interest than the
living ones. While there is some doubt of the occurrence of true
Araucariaceae in Paleozoic rocks, it is not unlikely that they already
existed during the Paleozoic. In the Mesozoic they were abundant
and widely distributed. Seward does not agree with those botanists
who would regard the Abietineae as perhaps the oldest existing mem-
bers of the Coniferae. Of Paleozoic fossils not improbably of Arau-
carian affinity, the genus Walchia shows the closest resemblance to
the living forms. In the Jurassic there are fossils which seem to be
beyond question true Araucariaceae. Such for example is Araucarites
phillipsit, and Seward concludes that the Jurassic flora of the north-
ern hemisphere was rich in Araucarian conifers. All of the fossil
forms resemble Araucaria rather than Agathis, which is as yet un-
known certainly to occur in a fossil state, although numerous fossils
have been referred to the genus.

Professor Seward’s conclusions as to the affinities of the Araucaria-
ceae and by implication of the other conifers have been strongly op-
posed, but we believe that his conclusions will be found to be correct.
He says: “We have endeavored to show that the Araucarian type
is one of the oldest, if not the oldest, of the Coniferales. .... If we have
evidence that the Araucariaceae are older than Abietineae, we may
reasonably expect to find that the morphological characters of the
older group are simpler and less specialized than those of the new
group.”

Seward also defends a view that we have long maintained, that there
is strong reason to believe that the resemblances between the lycopods
and conifers are real evidences of relationships, particularly emphasiz-
ing the resemblance between the Paleozoic Lepidocarpon and the
Araucariaceae. While he recognizes the many differences in struc-
tural details between the lycopods and Araucariaceae, he does not
believe that these are so great as to forbid the assumption of a lyco-
podineous origin for the Araucariaceae. We fully endorse his criticism
of the extreme view taken by the majority of students of gymnosperms
at the present time. He says, “We are disposed to think that the
proof of the relationships between cycads and ferns has been allowed
an undue influence in opinion regarding the ancestry of the conifers.”

812 THE AMERICAN NATURALIST [Vor. XLI

Of recent papers on the Gnetaceae, the present paper by Pearson
on Welwitschia (Some Observations on Welwitschia mirabilis, Hooker
H. H. W. Pearson, M. A., F. L. S. Phil. Trans. Royal Soc. London,
Series B. Vol. 198, pp. 265-304. Plates. 18-22. 1906.) is easily first
in point of importance.

One of the most remarkable of known plants is W. mirabilis, which
is an inhabitant of the desert strip along the coast of Portuguese and
German West Africa. In January, 1904, Professor H. H. W. Pearson
of the South African College in Cape Town made a visit to Walfisch
Bay for the purpose of studying and collecting Welwitschia and the
present memoir is a record of his observations. Owing to a native
uprising his visit was cut short, and the amount of material collected
was limited, but nevertheless a number of important facts were estab-
lished, which add materially to our knowledge of this extraordinary
plant.

The region where it grows is an almost absolutely rainless desert,
and excepting at very long intervals the only source of water is the
heavy sea fog, whose condensed moisture is sufficient to sustain life
in a few plants. It appears, however, that in some seasons, often a
good many years apart, heavy rains occur and the country may be
inundated. Pearson concludes that it is only during these rare periods
of heavy rain that the moisture is sufficient to germinate the seeds of
Welwitschia, although these are produced freely each season. The
plant does not appear to be able to exist outside the fog belt, but
Pearson believes that the main source of water supply is deep seated,
as is indicated by the very deep tap root of the plant.

The plants are dioecious, the flowering male plants being more
conspicuous than the female. Pearson believes that Hooker’s state-
ment that pollination takes place while the ovules are still very small
is incorrect and that Strasburger was right in stating that pollination
does not occur until the integument of the ovule projects above the
subtending bract. There is, however, strong evidence that the plant
is entomophilous, as the sticky pollen is not adapted to removal by the
wind and the flowers are constantly visited by insects. After pollina-
tion, fertilization and maturing of the seed seem to go on more rapidly
than in any other gymnosperms. On January 13th Pearson found
very few pollinated ovules, but he was informed that a month more
would be sufficient for the ripening of the seeds. While this state-
ment needs confirmation, it may very well be true, and if so, it is prob-

ably an adaptation connected with the desert habit of the plant.
The anther develops three loculi: In addition to the true tapetal

No. 492] NOTES AND LITERATURE 813

cells there is a breaking down of some of the sporogenous cells — a
condition of things not at all uncommon in the sporangia of certain
pteridophytes. In general there is pretty close agreement between
Ephedra and Welwitschia in the structure of the stamens. The
pollen spores possess three nuclei, one of which usually is completely
disorganized before the spores are shed. Of these three, this dis-
organized nucleus presumably represents a sterile prothallial cell, while
the others are respectively tube nucleus and generative nucleus. Pear-
son found a single archesporial cell in the megasporangium. Although
some of the stages were wanting, it was concluded that the arche-
sporial cell divides into several cells, of which one becomes the mega-
spore. While numbers of young embryo sacs with free nuclei were
observed, no dividing nuclei were seen. No vacuole was found in the
young embryo sac, a condition, by the way, which is quite similar to
what obtains in Peperomia.

The upper part of the nucellus becomes more or less disorganized,
and as the prothallium grows there is the usual. development of cell
walls between the free nuclei; but these cells later become multi-
nucleate, presumably by the division of the original nucleus. In the
lower part of the sac there may be as many as twelve nuclei, in some
of these cells. The number is less in those in the upper portion of
the embryo sac. The upper prothallial cells grow out into tubes
penetrating the nucellar cap in much the same way that the pollen
tube would do. There are several nuclei in each tube, and t
all assumed to be potentially egg cells, but this has not been
proven. These tubes are not to be looked upon as archegoni
each nucleus is considered to be an egg cell as in Gnetu

gous with the wholeifipex of the prothallium of Gnetum,- with which
genus Pearson seems inclined to connect Welwitschia, although of
course the relationship is rather a remote one. It is understood that
Professor Pearson has been engaged in further studies on this most
interesting plant and the result of these studies will be looked forward
to with much interest by all students of the gymnosperms.

Dovetas HOUGHTON CAMPBELL.

Xerophily of the Gymnosperms.— Although the foliage of the
conifers apparently presents adaptations to conditions of drought,
Stopes (New Phytologist, 6: 46-50. 1907) finds that at the present time
the conifers occupy territory in which the rainfall is, in the main,
plentiful. The generally accepted explanation of the occurrence of

814 THE AMERICAN NATURALIST [Vor. XLI

characters adapted to drought in environments in which they are
unnecessary is that the present day plants have inherited these features
from ancestral forms which grew under xerophytic conditions.‘ Miss
Stopes, however, argues that in the conifers the xerophytic character
is not to be regarded as an inherited adaptation but as correlated with
the peculiarities of the conducting system of the stem. The gymno-
sperms have a much more primitive wood structure than the angio-
sperms and a much lower capacity for the conduction of water. It is
this lower efficiency as conductors of water that necessitates the xero-
phytic character of the foliage,— not the environment. In other
words, the author regards the xerophily of this group as phylogenetic,
not adaptive.

With Miss Stope’s general conclusion that the xerophily of the
Coniferales is phylogenetic and not ecological, Moss agrees (New
Phytologist 6 : 183-185. 1906),? but he feels that there is an untenable
assumption running through the whole of her argument. This
assumption is that the conifers in question are more pronounced
xerophytes than the angiosperins with which they are ecologically
associated. The xerophily of the gymnosperms is seen in the greatly
reduced surface of the acicular leaf, whereas that of the angiosperms
takes the form of a deciduous habit by which the transpiration is
reduced to practically zero during the season of physiological dryness
of the soil. He finds that in many instances deciduous angiospermous
trees which are commonly regarded as mesophytes, extend into higher
altitudes and latitudes than conifers which are generally classed as fine
examples of xerophytes. Furthermore, he finds that among both
conifers and dicotyledons, the deciduous species are the ones which
extend the farthest north.

In view of these facts Moss would consider that the xerophily of the

1Clements (Res. Meth. Ecol. 127, 1905) has suggested that the xerophytic
characters of bog plants are not due to the “physiological dryness” of their
substratum as proposed by Schimper and generally accepted, but to the
inheritance of characters acquired when their ancestors were growing in xero-
phytic environments, He would therefore suggest the origin of stable adap-
tive structures which persist when the forms which had acquired them are
yeoman to ecological conditions of the most diverse type.

2 Moss writes: “With her general contention, that the xerophily of the
Coniferales is inherited and not acquired, I do not propose to deal, as Miss
Stopes amply proves her case.” The sentence is somewhat confusing, but by
“inherited” he evidently means phylogenetic in the sense in w iss
Stopes uses the term while “acquired” is equivalent to her “ecological” or
“inherited.”

No. 492] NOTES AND LITERATURE 815

- conifers is in no wise out of place in the environment of our mesophytic
forests, for these are ecologically xerophytic for over half the year.
He also holds that in the acicular leaf and the deciduous habit of some
of the northern conifers we have more recent ‘adaptations to the de-
mands of a xerophytic habitat, thus accounting for the present wide
distribution of this primitive group and its successful competition with
phylogenetically higher forms.

The arguments of both of these writers are suggestive, and much of
the value of such discussions lies in the emphasis which they lay upon
the necessity of approaching these problems with more precise methods
than have hitherto been employed.

J. ARTHUR Harris

Notes on the Problem of Adaptation — The Stinging Property of
the Giant Nettle tree. The giant nettle tree, Laportea gigas, a native
of Australia often attaining a height of over a hundred feet, has long
been noted for the violence of its action. Its large juicy leaves are
covered with numerous strong hairs or bristles which are filled with a
powerful stinging fluid. If the leaves be lightly brushed these hairs
penetrate and break in the skin, causing pain which gradually increases
in severity and sometimes lasts for several days. A popular name for
the Laportea is “mad tree.” Petrie (Proc. Linn. Soc. N. S. W., 31:
530-545. 1906) presents a detailed account of the chemical composi-
tion and physiological action of the juices of this tree. He suggests five
functions for the organic acids which are found in especial abundance,
and states that “after considering the various functions in which
organic acids take part, we cannot believe that the function of protec-
tion is the only one in this case.”

Assimilatory Tissue in Mangrove Seedlings. Schimper was inclined
to doubt the assimilatory function of the hypocotyl of mangrove seed-
lings but Goebel and Haberlandt acknowledge that they may perform
this function. Carson (New. Phytologist, 6:178-183. 1907) describes
the structure of the chlorophyll-eontaining tissue of the hypocotyl of
Bruguiera and Rhizophora, and thinks it safe to assume that in the
Rhizophoraceae generally the “hypocotyl is an assimilatory organ and
is definitely modified for assimilatory purposes.”

Benzoie Acid in Pinguilica. Insects which die in great numbers
on the leaves of Pinguilica vulgaris emit no putrid odor.- Experiments
performed by Loew several years ago indicated the presence of some
antiseptic substance. Loew and Asö (Bull. Coll. Agric. Imp. Univ.

816 THE AMERICAN NATURALIST [Vor. XLI

Tokyo, 7: 411-412. 1907; also Bot. Mag. Tokyo, 21: 107-109. 1907)
conclude that benzoic acid is the substance which prevents putre-
faction. Thus Pinguilica differs from Utricularia in which the cap-
tured organisms putrify.

Biologists are much less inclined than formerly to attribute adaptive
significance to the characters separating closely related species. Never-
theless Focke (Abh. Naturw. Ver. Bremen, 19:82. 1907) holds that
closely related forms are adapted to slightly different habitats. He
gives a list of several plant species which he thinks illustrates this
point.

Davidson (Agric. Journ. Cape Good Hope, 31: 175-177. 1907) calls
the attention of botanists to the interesting structural peculiarities
of the tuberous Liliaceous genus Eriospermum.

J. A. H.

Plant Cultivation in Art and Education.'— During the past few
years there has been unusual interest in the possibilities of artistic
gardening, both in the country and the city. This is evidenced by the
publication of such elegant magazines as the Country Calender, Subur-
ban Life, Country Life in America, and the Garden Magazine, as well
as by the attention which civic leagues everywhere are giving to parks
and highways. Many of the publications of the park commissioners of
our cities are prepared and published with the most fastidious care,
and in them plant cultivation has a prominent place.

The English are still much in advance of Americans in these matters.
--in interest, theory, and practice. During the last few weeks we
note the publication of such works as Kingsley’s ‘‘Eversley Garden
and Others,” Thonger’s “Book of Rock and Water Gardens,” David-
son’s “‘Unheated Greenhouse,” and the more pretentious “Art and
Craft of Garden Making” by Mawson. On this side of the water

1 Kingsley, Rose G. Eversley Garden and Others, London. George
Allen. 1907. ;

Thonger, C. The Book of Rock and Water Gardens. London & New
York. John Lane. 1907. .00.

Davidson, K. L. The Unheated Greenhouse. London. The Country
Life Co. 1907. 8s,6d.

Mawson, T. H. The Art and Craft of Garden Making. 3 ed. London,
B. T. Botsford. 1907.

Bisset, P. The Book of Water Gardening. New York. A. T. De La
Mare. 1907.

No. 492] NOTES AND LITERATURE 817

we may record Bissett’s “Book of Water Gardening.” This is not
the place to discuss the merits of these volumes as practical guides or
as teachers of art, but in all of thei the skill of the photographer has
been fully utilized in supplying illustrations, and these the systematic
botanist may find of considerable interest. Another finely illustrated
work is Perrédés’s ‘London Botanic Gardens,” 1ecently reprinted in
book form.

The interest in these matters is further evidenced by Baker’s dis-
cussion of the problems of horticultural education (Journ. Roy. Hort.
Soc., 22:152-162. 1907); True’s consideration of the advisability of
the introduction of elementary agriculture into schools (Yearb. U. S.
Dep. Agric., 1906 : 151-154. 1907); and Cook’s arguments in favor
of agriculture as the basis of education (Monist, 17: 347-364. 1907).

J. ARTHUR Harris.

Lobed Terminal Leaflets in the Rose.— In discussing the develop-
ment of pinnate leaves the writer stated that lobed terminal leaflets
were not found in the rose. It seemed probable that they would
appear, since they occur in the related agrimony, but among twenty-
seven hundred leaves of the wild Rosa lucida not a single example
was found.

Leaves of the cultivated rose. 4 natural size.

The writer is indebted to Miss Margaret W. Whitney of Pasadena,
California, for the lobed leaves of the cultivated rose shown in the
accompanying drawing. ‘They indicate that the basifugal tendency
is present in the stipular type of basipetal leaves, and that it may pre-
dominate.

F. T. Lewis.

PUBLICATIONS RECEIVED

From October 1 to December 1, regular exchanges not included
The year of publication, when not otherwise noted, is 1907

CLEMENTS, F. E. Plant Physiology and oe New York, Henry Holt.
and Company, 1907. 315 pp., 125 illus.— Curtis, C. C. Nature and Devel-
opment of Plants. New York, Henry Holt a nn 1907. 471 pp.,
342 figs. $2.50.— GAGE, A. P. Ann GooDsPEED, A.W. Principles of Physics.
Boston, Ginn and Company, 1907. 12mo, 547 pp., illus. $1.50.— GREEN,
J. R. An Introduction to Vegetable Physiology. Philadelphia, P. Blakiston’s.
Son and Co., 1907. 2nd ed., 459 pp., 182 figs., $3.00.— Hunter, G. W.
Elements of Biology, New York. American Book Company, 1907. 8vo, 445
PP» illus. $1.25.— Jones, W. H. S., Ross, R., anp ELLETT, G. G. Malaria,

neglected Factor in the History of Greice and Pipa: London, Macmillan and
ine 1907. 108 pp.— KeıLocs, V. L. Darwinism Today. New York,
Henry Holt and Company, 1907. 403 pp. $2.00.— Lamarck, J. B. Dis-
cours D’Owverture des Cours de Zoologie (An VIII, An X, An XI et 1806).
Paris, Bulletin Scientifique, 1907. 157 pp.— Mutiens, W. H. Gilbert
White of Selborne. London, Witherby & Co., 1907. 32 pp., 7 pls. 2s 6d.—
SCHARFF, R. F. European Animals, their Geological History and Geographical
Distribution. New York, E. P. Dutton and Co., 1907. 258 pp., 70 figs.
$2.50.— Stevens, W. C. Plant Anatomy. Philadelphia, P. Blakiston’s Son
& Co., 1907. 349 pp., 136 illus. $2.00.— WRIGHT, M. O. Gray Lady and
the Birds. New York, The Macmillan EEE 1907. 437 pp., illus.

7

Bartscu, P. New marine mollusks from the west coast of America. Proc.
U. S. Nat. Mus., vol. 33, pp. 177-183.— Bovarp, J. F. The structure and.
movements of Condylostoma patens. Univ. of Cal. Pub., zool., vol. 3, no.
14, pp. 343-368, pl. 34, 21 text-figs..— Burrum, B.C. The life and preserva-
tion of pitch pine fence posts. Wyo. Exp. Sta., bull. 75, 18 pp., 7 pls.—
BURCKHARDT, R. Das zentral-nervensystem der Selachier als Grundlage
für eine phylogenie des vertebratenhirus. Abh. d. kais. Leopoldinisch-Caro-
linischen deutsch. Akad. d. Naturf., W 73, pp. 241-450, 4 pls.— CARTER,
xperiments i in swine feeding. Jo. Exp. Sta., bull. 91, 17 pp.— Casey,
T. E A revision of the American ee of the Tenebrionid subfamily,.
Tentyriinae. Proc. Wash. Acad. of Sci., vol. 9, PP. 275-522.— CAUDELL,
A. On some earwigs (Forficulidae) collented in Guatemala by Messrs.
Schwarz and Barber. Proc. U.S. Nat. Mus., vol. 33, pp. 169-176.— CoUTIERE,
H. Sur quelques formes larvaires dnigtnaticques d’Eucyphotes, provenant-
des collections de S. A. S. le Prince de Monaco. Bull. Inst. Océanog., no. 1
69 pp., 22 figs.— Dati, W. H. Supplementary notes on Martyn’s Universal
Conchologist. Proc. U. S. Nat. Mus., vol. 33, pp. 185-192,— DE LA BARREDA,
L. Las plagas del algodonero. Coin: Parasitol. Agric., vol. 4, no. 2, pp. 107-
215, 24 pls.— Durrpen, J. E. Death-feigning instinct in the ostrich. Rep.
_ of So. African Assoc. for the Adv. of Sci., 1906, pp. 209-212.— Durrpen, J. E..

818

No. 492] PUBLICATIONS RECEIVED -819

Experiments with ostriches, Cape of Good H ope, Agric. Jour., nos. 11 and 12,
16 pp., 3 pls.— Durrpen, J. E. The morphology of the Madreporaria,—
The primary septa of the Rugosa. Ann. and Mag. of Nat. Hist., ser. 7, vol.
18, 1906, pp. 226-242, 21 figs.— DUERDEn, J. E. Genetics of the colour
pattern in tortoises of the genus Homopus and its allies, Rec. of the Albany
Mus., vol. 2, no. 1, pp 65-92, pls. 6-8.— Durrpen, J. E. Variations in the
geometrica-group of South African tortoises. Rep. of So. African Assoc. for
the Adv. of Sci., 1906, pp. 178-208.— Fretp, I. A. Unutilized fishes and their
relation to the fishing industries. U.S. Bur. Fisheries, doc. 622, 50 pp., 1 pl.—
García, F. Codling moth investigations during 1903 and 1904. N.M. Exp.
Sta., bull. 65, 29 pp.— GoLpr#waıT, J. W. The abandoned. shorelines of
eastern Wisconsin. Wis. Geol. and Nat. Hist. Sur., bull. 17, 134 pp., 36 pls.—
GREEN, E. E. anp Mann, H. H. The Coccidae attacking the tea plant p
India and Ceylon. Mem. Dept. of Agric. in India, ento. ser., vol. 1, no.
pp. 337-355, pls. 16-19.— Harr, W. L. The waning hardwood supply nd
the Appalachian forests. U. S. Dept. of Agric., forest service, circ. 116, 16
pp.— Harra, S. On the gastrulation in Petromyzon. Jour. College of Sci.,
Imp. Univ. of Tokyo, vol. 21, art. 2, 44 pp., 3 pls.— Herrera, A. L. El
polvo de crisantema y las plantas que lo producen. Com. Parasitol, Agric.,
circ. 61, 24 pp., 6 figs.— Herzoc, T. Studien über den formenkreis von
trichostomum mutabile.. Abh. d. kais. a ee deutsch.
Akad. d. Naturf., vol. 73, pp. 451-498, 7 pls.— Hırıman, F. H. Dodder in
relation to farm seeds. U. S. Dept. of Agric., farmers’ ball, 306, 27 pp., 10
s.— Hunter, W. D. The most important step in the control of the boll
weevil. U.S. Dept. of Agric., Bur. of Ento., circ. 95, 8 pp.— Hunter, W. D.
AND Hooker, W. A. Information concerning the North American fever
tick. U.S. Dept. of Agric., Bur. of Ento., bull. 72, 87 pp., 13 figs.— JAQUET,
Note sur une forme jeune de Trigla. Bull. Inst. Océanog., no. 102, 5 pp.,
1 pl.— Jorpan, D. S. anD Herre, A. C. A review of the Cirrhitoid fishes
of Japan. Proc. U. S. Nat. Mus., vol. 33, pp. 157-167.— Jorvan, D. S. AND
SYNDER, J. O. Notes on fishes of Hawaii, ro descriptions of new species.
Bur. of Fisheries, doc. 623, pp. 205-218, pls. 12, 13.— Jousıs, L. Note sur
les Brachiopodes recueillis au cours des dernières croisières du Prince de
Monaco. Bull. Inst. Océanog., no. 103, 9 PP-— Kennepy, W. J., ROBBINS,
E. T. anp Bouska, F. W. Tuberculosis in swine. Io. Exp Se bull. 92,
24 pp.— Lantz, D. E. An economic study of field mice. U. 5. Dept. of
Agric., biol. sur., bull. 31, 64 pp., 8 pls.— Levinsen, G.M.R. Surla régén- .
rg totale des Bryozoaires. D. K. D. Vid. Selsk. Overs., no. 4, pp. 151-159,
1 pl— Linton, E. Notes on parasites of Bermuda fishes, Proc. hte : 5. Nat,
Mus., vol. 33, pp. 85-126, pls. 1-15.— Macsring, T. H. On certain fossil
plant remains in the Iowa herbarium. Proc, Daven Acad. of sy ok 10,
pp. 153-162, 12 pls.— Macfas, C. Estudio experimental de la Nina en
la Hacienda = Zimatepec. Com. Parasitol. Agric., circ. 62, 4 pp., 5 figs.—
Mapsen, T. anp Nyman, M. Contributions aux études eo sur la
désinfection. D. K. D. Vid. Selsk. Overs., no. 3, pp. 105-126. — Mason, O. T.
Basketry bolo case from Basilan Island. Proc. U. S. Nat. Mus., vol. 33, pp.
193-16, 1 fig— Morrırz, A. W. La Conchuela Mexicana en la parte occi-
are del estado de Texas en 1905. Com. Parasitol. Agric., cir. 63, 25 pp.,
4 figs.— Morton, G. E. Ration experiments with swine. Wyo. Exp. Sta.,

820 THE AMERICAN NATURALIST [Vor. XLI

bull. 74, 18 pp., 2 figs. — ee W. J. V. On nutrient and balanced
solutions. Univ. of Cal. Pub., bot., vol. 2, no. 15, pp. 317-318.— RITTER;
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A FoNDATION NOBEL.

(No. 491 was issued December 9, 1907)

OF

EXPERIMENTAL ZOOLOGY| —

EDITED >

WILLIAM K, BROOKS HERBERT 8, JENNINGS .

E. CASTLE FRANK ILLIE x
NK JACQUES LOEB

CONIENIS

VOLUME V. NO. 1.

NOVEMBER 1907 |
DAVID D. WHITNE eS

tion of Sex in Hydatina Senta En

ARTHUR B. LAMB wenn 5
A New E pl +i a ae nie; of Mit: ;

HERBERT EUG : :

The Reactions of Planarians to Light. — — —

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