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w.archive org/details/journalofexperim27broo

THE JOURNAL

OF

EXPERIMENTAL ZOOLOGY

EDITED BY

WILLIAM E. Caste Jacques LoEB
Harvard University The Rockefeller Institute

Epmunp B. WILSON

Columbia University

EpwIn G. CoNnkKLIN
Princeton University
THoomas H. Moraan

Cuar.es B. DAVENPORT ‘
Columbia University

Carnegie Institution
GEORGE H. PARKER
HERBERT S. JENNINGS Tenrerec) Unie ors by
Johns Hopkins University
RAYMOND PEARL

FRANK R. LILuis Maine Agricultural
University of Chicago Experiment Station

and

Ross G. HARRISON, Yale University

Managing Editor

VOLUME 27 “ol
1918-1919

THE WISTAR INSTITUTE OF ANATOMY AND BIOLOGY
PHILADELPHIA, PA.

CONTENTS
No. 1. OCTOBER, 1918

Heten Dean Kinc. Studies on inbreeding. III. The effects of inbreeding,

with selection, on the sex ratio of the albino rat. One figure.......... 1
Surntcut Matsumoto. Demonstration of epithelial movement by the use
of vital staining, with observations on phagocytosis in the corneal epithe-
“Une Ruey GLUT TE TV eee ele Sgn cr en Es AC Re a em ae aa 37
WriiuraMm B. KirkHam. Observations on the relation between suckling and
the rate of embryonic development in mice.....:...........0. 00. . 6205s 49
Peter Scumipr. Anabhiosis of the earthworms...........................- Yb
H. H. Couurns. Studies of normal moult and of artificially induced regen-
eration of pelage in Peromyscus. Fifteen figures...................... 73
No. 2. NOVEMBER, 1918
FE. R. Hoskins anp M. M. Hoskins. The reaction of Selachii to injections of
various non-toxi¢ solutions and suspensions (including vital dyes), and
to excretory toxins. Twenty-seven figures (six plates)................ 101
Etmer Roserts. Fluctuations in a recessive Mendelian character and
selection. Two plates and three text-figures.............:....-..0--5- 157
CuHarLes Haruan Asporr. Reactions of land isopods to light. Fourteen
TCADA SS a7 een O ebb oi Gic RE LED cia, oes ta ard ERM A APS es“ RAPE Sa sree Pr 193
W. J. Crozter. Assortive mating in a nudibranch Chromodoris zebra
Heilprin,. “Ewenty-three figures and charts: 5.5: 7cguc- oe. 0). a es ee 247
No. 3. JANUARY, 1919
Gary N. Caixins. Uroleptus mobilis, Engelm. I. History of the nuclei
during division and conjugation. Ninety-five text figures............. 293
W. J. Croztmr. On the use of the foot in some mollusks. One figure...... 359
S. O. Masr. Reversion in the sense of orientation to light in the colonial
forms, Volvox globator and Pandorina morum. ‘Two figures........... 367
ANDREW JOHNSON BiaNry. The effect of adrenin on the pigment migration
in the melanophores of the skin and in the pigment cells of the retina of
W. W. Swinete. Studies on the relation of iodin to the thyroid. I. The
effects of feeding iodin to normal and thyroidectomized tadpoles... .. 397
W.W.Swincie. Studies on the relation of iodin to the thyroid. II. Com-
parison of the thyroid glands of iodin-fed and normal frog larvae...... AIT
M.H.Jacons. Acclimatization as a factor affecting the upper thermal death
POMUS OMOUCAMISIOS se cee ao an. - ee Ss oe ee 427

ill

lv CONTENTS

No. 4. FEBRUARY, 1919

GERTRUDE Marean Waite. Association and color discrimination in mud-

minnows and sticklebacks. ‘Ten’ figures. ..............<_- eee 443
G. H. Parker. The organization of Renilla. One figure..............._.. 499
Mary B. Starx. An hereditary tumor. Twelve figures (three plates).... 507

AUTHOR'S ABSTRACT OF THIS PAPER ISSUED
BY THE BIBLIOGRAPHIC SERVICE, AuGusT 15

STUDIES ON INBREEDING

Ill. THE EFFECTS OF INBREEDING, WITH SELECTION, ON THE SEX
RATIO OF THE ALBINO RAT

HELEN DEAN KING
The Wistar Institute of Anatomy and Biology

ONE FIGURE

During the latter part of the nineteenth century it was gener-
ally believed that sex in man and in various animals is determined
mainly by the amount of nourishment that the embryos receive;
well nourished embryos were supposed to become females; those
that were poorly nourished were assumed to develop into males.
A considerable amount of evidence in favor of this view was
collected by Diising (’83, ’84, ’86), who maintained, furthermore,
that close inbreeding interferes with embryonic nutrition, by
lessening the vitality of the mother, and so produces a great
excess of male young.

In the literature of the succeeding twenty years that deals
with the subject of sex determination, Diising’s statement regard-
ing the effect of inbreeding on the sex ratio was widely quoted
and generally credited. Those who challenged the truth of the
assertion were, in the main, advocates of the ancient theory,
generally ascribed to Hippocrates (460-377 B.C.), that sex is
determined in the ovary; eggs from the right ovary producing
males and those from the left ovary developing into females.
During this period three series of experiments were made that
give data regarding the sex-proportions in a closely inbred stock.
Huth (’87) inbred rabbits, brother and sister, for six generations
and found a relatively low sex ratio (78.8 0": 100 2) among the
ninety young in which the sex was ascertained; Copeman and
Parsons (’04) obtained a similar result in their inbreeding experi-
ments with mice. Schultze (’03) coneluded that inbreeding

1

THE JOURNAL OF EXPERIMENTAL ZOOLOGY, VOL. 27, No. 1
: OCTOBER, 1918

2 HELEN DEAN KING

has no pronounced tendency to produce an excess of male young,
although he found a high sex ratio (110.9o: 100 2) among 135
mice that were the offspring of brother and Sister matings. The
question as to whether inbreeding does or does not alter the sex
ratio was not satisfactorily answered by any of these experi-
ments, for in each case the number of animals used was small,
and there was, apparently, no selection of the best stock for breed-
ing or any way of checking the results. Moreover, none of these
investigations were continued long enough to give evidence that
could be considered as conclusive.
The effects of inbreeding on the sex ratio seemed to me to be a
problem of sufficient importance to warrant a careful and pro-
longed investigation. For if it were possible to swing the sex
ratio of any animal in a definite direction by factors that could be
controlled, one might hope to gain valuable information regard-
ing the nature of sex—a problem that has been a favorite subject
of speculation for many centuries and one that modern methods of
research have not, as yet, satisfactorily solved.

1. MATERIAL, METHOD, AND SCOPE OF THE INVESTIGATION

The albino rat (Mus norvegicus albinus) was the animal used
in this investigation, which was begun in 1909. Details regarding
the manner in which the experiments were conducted were given
in the first paper of this series (King, 718), but it has seemed ad-
visable to repeat them here in order to give a clear understanding
of the way in which the problem has been approached.

The basis of the inbred strain was a litter of four albino rats,
two males and two females, taken from the general colony of
these animals maintained at The Wistar Institute of Anatomy
and Biology in Philadelphia. The litter was selected for the
purpose in view solely because of its size, not because of the
ancestry or the vigor of the animals. One of the two females
in the litter was called ‘A’, and her descendants form the A
series of inbreds; the other female was called ‘B’, and her de-
scendants are the B series of inbreds.

Since the mating of brother and sister from the same litter is
the closest form of inbreeding possible in mammals, such matings

EFFECTS OF INBREEDING ON THE SEX RATIO 3

would be expected to be more potent than any other kind in
producing an alteration in the sex ratio. In these experiments,
therefore, brother and sister matings only were used to obtain
strictly inbred litters from which all females used for breeding
were taken. The plan of breeding that was followed through the
first twenty-five generations of these animals was this: Females
A and B, as well as all of the females in their respective lines
that were subsequently used for breeding, were paired twice with
a litter brother and then twice with an unrelated male taken
from the stock colony. Sex records for the first two litters
produced by any group of females might be expected to show
whether inbreeding had any effect on the sex ratio; sex data for
the third and for the fourth litters cast by these same females
would, it was hoped, indicate whether the male or the female
was responsible for the alteration, if any, in the sex ratio. For
convenience the litters obtained from the mating of inbred fe-
males with stock males are here designated as ‘half-inbred’
litters; no animals from such litters have ever been reared.

Emphasis should be placed on the fact that, with few exceptions,
the sex data given in this paper were obtained by examining the
litters very soon after their birth. The sexes can readily be
distinguished at this time, as Jackson (’12) has shown, and if
accurate sex data are wanted it is imperative that they be taken
as soon as possible, since the young that are stillborn, or those
that die soon after birth, are usually eaten by the mother within
a few hours.

In order to keep track of a large series of animals it was neces-
sary to find some way in which the pedigree of any particular
individual could be told by a glance at the record card. The
scheme of marking devised, which is outlined below, has proved
to be very convenient and also most satisfactory for the filing
of permanent records. The letter A or B is used to show from
which of the two females, A or B, the animal was descended, and
thus places the individual in its proper series. The serial letter
is preceded in all cases by a number which signifies the generation
to which the animal belonged. An index number, 2, 3, or 4,
following the serial letter shows in which of the mother’s litters

|

4 HELEN DEAN KING

the animal was born; if no index number is used the rat was a
member of its mother’s first litter. The subscript following the
serial letter is the number which serves to distinguish each
particular rat from the other rats belonging to the same genera-
tion and litter group. When it is desired to indicate the sex of the
individual its number is inclosed by the sex symbol. An illustra-
tion will, perhaps, render the scheme clearer. .

This symbol denotes a female rat belonging in the seventh
generation of the A series of inbreds. She was a member of the
second litter cast by her mother, and her individual number in
the series of rats belonging to the second litters of the seventh
generation was twenty.

In the early generations of both inbred series the animals
suffered severely from malnutrition which produced a marked
effect on their growth, fertility, and longevity, as previous papers
in this series have shown (King, ’18, 18a). During this period
a considerable proportion of the individuals were sterile, and it
was not possible to select animals for breeding; any rats that
would breed at all were used to continue the strain. Nutritive
conditions were improved at the time that the rats of the fourth
inbred generation were approaching maturity, and a decided
improvement in the condition of the animals was noted in a very
short time: they gained rapidly in weight, the litters cast became
larger and sterility almost disappeared. At this stage of the
investigation it became possible to attempt to alter the sex
ratio by selection within the inbred strain. From the seventh
generation on, every female in the A series of inbreds that was
used for breeding was taken from a litter that contained an excess
of males; breeding females in the B series of inbreds were all
taken from litters containing an excess of females. The plan

EFFECTS OF INBREEDING ON THE SEX RATIO 5

of pairing a female twice with a litter brother and then twice
with an unrelated stock male was continued through the first
twenty-five generations of both inbred series.

In each series litters having the desired sex ratio were reared
as possible breeding stock only when the young were of large size
and lusty at birth; all other litters were discarded regardless of
their sex ratio. At the time that the animals became sexually
mature the largest and most vigorous pairs were the ones taken
to continue the strain. Selection of breeding stock, it will be
noted, was based primarily on the sex ratio in the litters, not on
the size or on the vigor of the young. This means that the
animals in one generation that became the. progenitors of the
succeeding generation were selected because of their parents,
tendency to produce young of a certain sex. A pair of rats that
produced two litters, each of which had the desired sex ratio,
was considered as having an unusually strong tendency to pro-
duce unisexual young; individuals from each of these litters were
used for breeding when possible. The basis of the selection,
therefore, was along the line in which Pearl (712, 12a, 717) has
obtained such marked success in increasing egg production in
poultry, i.e., according to the ability of the parents to transmit
to the offspring the quality desired.

In the early part of this investigation the number of breeding
females was, of necessity, small, but in the later generations about
twenty females in each series were used for breeding, so that at
least 1000 rats were obtained in each generation of the inbred
strain. Sex records for the first twenty-five generations are
given in the present paper; the data comprise 3408 litters con-
taining 25,452 individuals.

2. THE NORMAL SEX RATIO IN THE ALBINO RAT

The normal sex ratio in any species can properly be determined
only by obtaining the sex data for the total number of offspring
produced by many females during the entire period of their
reproductive activity. Unfortunately, no such series of data
for the albino rat have been recorded, and only two sets of ob-
servations regarding the normal sex ratio in this animal have,

———

6 HELEN DEAN KING

as yet, appeared. Cuénot (’99) examined thirty litters of albino
rats, containing 255 young, and found a sex ratio of 105.6:
100 ° ; data for 1089 litters of stock Albinos, collected by King and
Stotsenburg (’15), gave a sex ratio of 107.57:1009. Neither
of these determinations seemed to furnish a proper standard for
comparison with the sex ratios obtained in the inbred strain,
even though they differed by less than two points. The number
of individuals examined by Cuénot was too small to give results
of much statistical value. The sex ratio given by King and
Stotsenburg was based on the findings for a relatively large
number of animals, but the litters recorded were, for the most
part, cast by females that had not reached the height of their
reproductive activity. The sex ratio among the offspring of
young females could not justly be taken as a norm for the Albino
strain in general, since it has been shown that in the albino rat
the sex of the young seemingly depends, to a certain extent, on
the age of the mother (King, ’16 a).

In order to ascertain the normal proportion of the sexes in
the strain of Albinos from which the inbred animals were taken,
I obtained the complete breeding history of a considerable num-
ber of stock females during the past four years. As all of these
individuals were reared under the same environmental conditions
as the inbred rats, the sex ratio among their young would seem
to be a suitable standard by which to judge the sex ratios found
in various generations of the inbred animals. To make the ratios
more strictly comparable, the data for only the first four litters
of the stock series were used in computing the sex ratio which
was to serve as the norm. These data, arranged by litter groups,

are shown in table 1.
TABLE 1
Showing the sex ratios in the first four litters of a series of stock albino rats

LITTER SERIES |NUMBER a Reka MALES FEMALES ae 100 eae
1 116 717 385 332 115.9
>, 116 843 426 417 102.2
3 103 671 328 343 95.6
4 89 587 302 285 105.9
424 2818 1441 1377 104.6

EFFECTS OF INBREEDING ON THE SEX RATIO 7

Table 1 shows that there was a relatively large excess of males
in the first litters cast by this series of stock females (115.99:
100 2), and that in succeeding litters the sex ratio tended to fall
considerably. A similar change in the sex ratio of successive
litters of mice was noted by Copeman and Parsons (’04), and was
found also by King and Stotsenburg (’15; table 7) in a series of
stock albino rats. Large groups of statistics for human births,
as summarized by Ahlfeld (’76), by Diising (’83, ’84), by Punnet
(03), and by Newcomb (’04), all show that the sex ratio is very
high among the first children of young mothers and then tends to
fall with succeeding births until the mother is about thirty years
old. Whether a similar change in the sex ratio is characteristic
of other mammals has not been determined as yet.

Among the 2818 individuals comprised in this series of stock
litters there were 104.6 males to each 100 females. A sex ratio of
105: 100 2 was, therefore, taken as the norm by which to judge
the sex ratios obtained in the various groups of inbred rats. This
sex ratio, it will be noted, is very close to that given by Cuénot,
and is lower, by over two points, than the sex ratio found in the
large group of stock Albinos born in The Wistar Institute colony
during the years 1911-1914 (King and Stotsenburg, ’15).

3. THE SEX RATIO IN INBRED LITTERS OF ALBINO RATS

The A series of inbred rats may be designated as the ‘male
line,’ since after the sixth generation all of the breeding females
in this series were taken from litters that contained an excess of
males. Table 2 gives, by litter groups, the sex data for the 13,116
individuals obtained in the first twenty-five generations of this
series.

Table 2 is inserted chiefly for reference, and a detailed analysis
of the data, as given, will not be attempted. The summary of
the data for the various litter groups shows that the sex ratio for
the first litters produced was much higher than that for the
second, third, and fourth litters. A similar change in the sex
ratio was noted in the litter series of stock animals given in table 1.

The B series of inbreds is called the ‘female line,’ since, after
the sixth generation, all breeding females in this series came from

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EFFECTS OF INBREEDING ON THE SEX RATIO 9

litters containing an excess of females. Reference data showing
the proportion of males and females produced in the various
generations of this series are given, by litter groups, in table 3.
The data comprise a total of 1656 litters containing 12,336
individuals.

The summary for each of the four litter groups of the B series
(table 3) shows that the sex ratio was at its lowest point in the
first litter group, and then tended to rise in each of the subsequent
groups. This is a reversed relation of the sex ratios to that shown
in the litters of the stock controls (table 1) and in the litter groups
of the A series (table 2), and would seem to indicate that some
agency, other than environment or the age of the mother, had
influenced the relative proportion of the sexes in this series of
animals.

In order to compare the sex ratios in the litters sired by inbred
males with the sex ratios in the litters sired by stock males, the
sex records for the first and second litters produced in each
generation of the two series were combined, as were also the
records for the third and fourth litters. Table 4 shows the
combined data for the litter groups of the A series; table 5 shows
similar data for the litter groups of the B series.

Reference to the data given in table 4 and in table 5 will be
made later.

To facilitate an analysis of the results obtained in the A
series of inbreds, the data, as shown in table 4, were combined in
generation groups (table 6). This grouping of the data was
purely arbitrary. It seemed useless to compare such large series
of records generation by generation, or even to combine the records
for two succeeding generations. Since after the sixth generation
the selection of breeding animals was made according to a
definite plan, it would seem that, logically, the data for the first
seven generations should form one group. Such a group, how-
ever, was too large for the purpose of ascertaining whether
selection produced a varying effect in different generations. It
was finally decided to make a total of eight groups, each of which,
except the first, should contain the data for three generations.
Because of the small number of individuals, records for the first
four generations were combined in one group.

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EFFECTS OF INBREEDING ON THE SEX RATIO 1

TABLE 4

Showing the sex ratios in the inbred and in the half-inbred litters produced in each
of the first twenty-five generations of the A series of inbreds

INBRED HALF-INBRED
(FIRST AND SECOND LITTERS) | (THIRD AND FOURTH LITTERS) Soe t= 08 ALS Lite ns

males to 100

females
dividuals

dividuals

ters
males to 100

females
males to 100

Number of lit-

Number of in-
dividuals

Number of
females

Number of lit-

Number of in-

Number of

Number of lit-

Number of in-

Number of
ters

bo
_
ra
ND
(ee)
~I
or
=)
bo
_
ou
—
wo
bo
ior)
or
o
(=)
—
~~)
co
—
ve)
-—_
i=)
—
ve)
So
o

25); 88.0} 6) 33) 19) 14/ 135.0) 13) 80} 41] 39] 105.

oo
_
He
=
ee)
a
—
bo
ee)
—
He
Or
ies)
oo
ee)
bho
co
ive}
—
or
Or
5
ry
2 i=)
J _
DDare On De OC SO SO bw
es)
=}
lor)
_
oo
eo
He
—_
bo
~J
bo
—
bo
—

hee et ttt
So SS SES aS wo yoo. acre) ommmaarions
on
ns
ns
or
ns
bo
is
_—
bo
—
wo
—_
bak
wo
—_
we
60
0
©
ball
bo
=
=)
a
00
—
—_
—_
>
=)
=
=)
iS
or)
ass
on
ns
or
—
09
a)
nis
—
a
ty

iw)
o
Oo
rs
PS
=
~J
bo
(Se)
—_
jal
Go
ler)
ppm
bo
(Je)
_
r=
S
bo
~J
ie)
—
Ou
=]
_
bo
Le)
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oe)

5

46) 325) 186] 139} 133.8} 37} 290] 158) 132} 119.7] 83] 615] 344] 271] 126.
7
0

nb bo
Noe
or or
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Ce
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bo bo
H bo
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aS
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(=)

neg

103.1); 95] 768} 409} 359} 113.
122.8] 91] 672} 382} 290) 131
103.2} 93] 701) 369} 332) 111
25| 52] 376} 201) 175; 114.9) 38) 270] 154) 116} 132.8} 90] 646] 355) 291] 122.0

i)
w
or
So
w
for)
Ve)
bo
—
Or
_
Or
Ts
—
ow
Ve)
(or)
aS
—_
(oN)
i=]
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—
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(o’)
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for]
or
oo
w
for)
iw)
i)
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—
—
bo
~ = . bo . . . .
ePNTIOWOOOUN RF KF RPNTOTOWOR ODN OF

bo
rae
or
So
eo
Qo
rag
bo
co)
ioe)
—
~I
for)
—
=
oo
bo
a
oo
oe
_—
~J
—_
lor)
—_
_
or
ler)

968/7204/3948|3256| 121.3] 784|5912/3168/2744| 115.5)/1752|13116|7116|6000) 117.4

As the number of individuals in each of the first seven genera-
tions of the A series was comparatively small, it is not surprising
that the sex ratios in the inbred and in the half-bred groups of
litters should show a wide range of variation (table 4). When the
records for these generations wére combined, as shown in table
6, it was found that the 144 inbred litters hada sexratio of 110.407:

—

12 HELEN DEAN KING

TABLE 5

Showing the sexratios in the inbred and in the half-inbred litters produced in each of
the first twenty-five generations of the B series of inbred

(FIRST Keo he cone LITTERS) GEEORD AND THROES SUMMARY OF SS ELL ons
Hic ss |2 |A 3g jt |& 38
é|l3s |sa ig [68 |e oem eek oe
Bleg|ee| 2 aG&leeiee| 8 | 8 | GG) eel ge | 8 | € | Fas
Bis 8 [oss | cs & | s5ef|s8/se] a Elsee|/se/ ss] a & | 583
o |G a = & 14 Z Z = Fe WG qi Gi = & | A
1 1 Si lee coe GOR) 1 Sle Ii 8 "66a
2 41 31; 12} 19) 63.2 Bylo PAoH| P|! se Nh Setsy 7 7 ot] 624) 33) 7258
Sie Ii O2|, a4 28) ee. 2 5 4; 125.0} 14 AL ES39|h 32\| 129
4} 19} 135} 74) 61) 121.3) 10) 74} 36} 38} 94.7} 29] 209] 110] 99) 111.1
5| 40} 291) 148) 143] 103.5) 31) 245) 122) 123) 99.2) 71) 536] 270} 266} 101.5
6| 30} 224) 120) 104) 115.4) 22) 176) 92) 84) 109.5) 52} 400) 212) 188] 112.9
7} 30) 184) 96) 88] 109.1) 25) 182} 86} 96) 89.6} 55} 366] 182) 184) 98.9
8| 30} 237) 115) 122) 94.3) 16} 115} 58] 57) 101.8] 46) 352) 173) 179] 96.6
9} 40) 309} 152) 157; 96.8) 27; 176} 94! 82) 114.6} 67] 485] 246] 239) 102.9
10| 34) 249} 115) 134) 85.8) 30} 200) 100} 100) 100.0} 64) 449} 215) 234; 91.9
11} 38} 240] 115! 125; 92.0) 36) 287) 138] 149) 92.6) 74) 527] 253) 274) 92.3
12} 40} 314) 158) 156) 101.3) 31) 222) 100) 122) 82.0) 71} 536) 258) 278} 92.8
13} 42) 322) 127) 195} 65.1) 32) 254] 120) 134) 89.6) 74) 576) 247) 329) 75.1
14] 42) 277] 125} 152) 82.2) 38) 293) 142) 151) 94.0} 80} 570} 267) 303) 88.1
15} 40) 269] 119] 150} 79.3] 37} 313) 160} 153) 104.5] 77} 582) 279) 303) 92.1
16] 48] 342) 142) 200; 71.0} 41} 322) 148) 174} 85.1] 89} 664] 290} 374) 77.5
17| 44) 328) 142) 186} 76.3} 38) 286) 1385) 151) 89.4] 82) 614] 277) 337) 82.2
18} 46) 348] 159} 189} 84.1] 40) 320) 152) 168} 90.5) 86} 668] 311) 357} 87.1
19} 48) 407) 171] 236} 72.5) 35) 291) 127) 164) 77.4) 83! 698] 298} 400) 74.5
20| 52) 353) 159) 194) 82.0) 32) 245) 124) 121) 102.5} 84] 598) 283) 315) 89.8
21| 48} 365} 168) 197) 85.3) 34) 250) 114) 136] 83.8) 82) 615] 282) 333) 84.7
22| 52) 384) 178} 206} 86.4; 43) 350) 163) 187} 87.2) 95) 734] 341] 393) 86.8
23| 44) 376) 165) 211) 78.2) 45) 271] 116] 155} 74.8) 79) 647| 281) 366) . 76.8
24| 54! 396) 172) 224) 76.8) 43] 289) 148} 141) 105.0} 97} 685) 320) 365) 87.7
25| 52! 377) 169) 208) 81.3) 45} 315) 150) 165) 90.9] 97; 692) 319) 373] 85.5

930)/6825/3137/3688) 85.1) 726)5511/2642)2869} 92. 1)1656)12336|5779|6557| + 88.1

100 @, and that the 106 half-inbred litters had an even higher
proportion of males (114.07:100¢9). For the total of 250
litters the sex ratio was 113.207: 100°.

Until the seventh generation, as already stated, there was no
selection of breeding animals in’ either series. As the sex ratio
among the animals in the early generations of the A series was

EFFECTS OF INBREEDING ON THE SEX RATIO 13

TABLE 6

Showing, by generation groups, the sex ratios in the inbred and in the half-inbred
letters of the A series (male line)

INBRED HALF-INBRED } SHAY O s
2 (FIRST AND SECOND LITTERS) | (THIRD AND FOURTH LITTERS) ee OF ALL LPT EEs
Pp
5 1 1 “oS ' J “OS } 4 ' i
o |e | 4 oS j= | 8 | ae lie pose | oS
x |= = |
g. /e | oe pen fe | oa emo | ea mie

ab; 5 iE

& |e 55 a | om |5 55 2 | 20215 5 | ¢ | 224
e& Q KE = = qo 3 2 | 2-5 n “a a2Si/O2o|/ 25 |] = | e238
a /s2|82/ 2]| § See Be hig | Sea las! ge | 8.) 8 | Bas
Sisco ia joke (ooo a 1S PAS) aS so | | 8 | SRS
o |4 14 a |e |4 414 = Z Z Z =| 14

1-4 | 46) 257| 128) 129] 99.2) 32/ 194) 113) 81) 139.5) 78) 451) 241) 210) 114.8
5-7 | 98) 673) 360) 313) 115.0) ¢4) 488) 255) 233) 109.0) 172) 1161) 615) 546) 112.6

1-7 |144) 930) 488) 442) 110.4/106) 682) 368) 314) 114.0) 250) 1612) 856) 756) 113.2

8-10/108} 779} 412) 367) 112.5) 88) 651) 336) 315) 106.6) 196) 1430! 748) 682) 109.7
11-13}126| 953) 540) 413) 130.7|115) 904) 491) 413) 118.8) 241) 18571031) 826) 124.8
14-16)130} 999} 558) 441) 126.5)105) 810) 441) 369) 121.9) 235) 1809) 999) 810) 123.3
17—19/146)1144) 628) 516) 121.7|119) 955) 516) 439) 117.5) 265) 2099)1144) 955) 119.7
20—22)162)1270) 698} 572} 122.0)129 re 534! 486) 109.8} 291) 2290)1232/1058) 116.4
23-25}152/1129} 624] 505] 123.5)122) 890) 482) 408) 118.1) 274) 2019)1106) 913] 121.1

8-25/824| 6274) 3460) 2814) 122.3/678|5230)2800|2430) 115 .6)1502)11504/6260)/5244 119.3
+1.55 +1.47 +1.36

some eight points above the norm, it might appear that inbreed-
ing had tended to increase the relative number of males. Such
an interpretation of the results is not warranted, however, since
the sex ratio in the litters produced by the mating of unrelated
parents was higher than that in the litters obtained by the
mating of brother and sister, and since a similar increase in the
sex ratio was not found in corresponding litters of the B series
(table 7).

As the females of the seventh generations that were used for
breeding were all taken from litters that contained an excess of
‘males, it is among their offspring that we may look for a possible
alteration of the sex ratio as a result of selection. ‘The sex ratio
in the inbred litters of the eighth generation of the A series was
118.27:1009. This sex ratio is very much lower than that
found in the inbred litters of the seventh generation (150:
100 2), but it is still 13 points above the norm (1057: 100 @ ).
As examination of the records given in table 4 shows that in

14 HELEN DEAN KING

only one generation (the tenth) after the eighth did the sex ratio for
the inbred litters fall to norm, in all other generations it was con-
siderably above the norm, the highest ratio (145.3 o: 100 2) being
found in the litters of the eleventh generation.

While the sex ratios for the inbred litters of the eighth to the
twenty-fifth generations varied considerably, the variation was
much less after the twelfth generation than before (table 4). A
part of this variation was doubtless phenotypic, since seasonal
changes in temperature seem to alter the sex ratio in the rat
(King and Stotsenburg, °15), and probably also other agencies,
such as the age of the mother (King, *16 a), have a similar effect.
As all of the sex ratios were relatively high, however, the devia-
tions from the norm cannot be ascribed either to environment
or to chance, so they must have been due, in part at least, to the
manner in which the breeding animals were selected.

A most striking uniformity in the sex ratios of the inbred
litters belonging in the eighth to the twenty-fifth generations of
this series is shown by the grouping of the data as made in table 6.
The lowest sex ratio (112.57: 100 2) was found in the first group
(eighth to tenth generations) ; the highest sex ratio (130.7 @: 100 2 )
appeared in the second group (eleventh to thirteenth generations).
Between these extremes there was a difference of only 18 points,
while in the four following groups of litters the range of variation
in the sex ratios was less than 5 points. For the total of 824
inbred litters the sex ratio was 122.37:100¢2. This latter ratio
was not due to an abnormal preponderance of males in a few
sets of records, but was based on a series of data that in seventeen
out of eighteen cases showed an excess of males greater than that
considered as normal for the species. The results obtained,
therefore, seem to indicate that by selecting breeding animals
from litters that contain an excess of males, the sex ratio can be
swung in the direction of the selection, although the line is contin-
ually inbred, brother and sister. There was in this case, however,
no cumulative effect of the selection. The sex ratios were more
uniform in the later generations than in the earlier ones, but they
were no higher. It is rather an odd coincidence that the sex
ratios in the inbred litters of the eighth and of the twenty-fourth
generations were exactly the same (118.27: 100 9).

EFFECTS OF INBREEDING ON THE SEX RATIO 15

Data given in table 4 show that in the half-inbred litters pro-
duced in the eighth to the twenty-fifth generations of the A series
the range of variation in the sex ratios was from 99 to 140.8
males for each 100 females, six of these ratios being slightly below
the norm. When the data were combined in generation groups
(table 6), 7f was found that not a single group gave a sex ratio as
low as the norm. The sex ratios for the litters in the later genera-
tion groups were somewhat more uniform than those for the
litters in the earlier generation groups, but the uniformity was
not as striking as that in the corresponding groups of inbred
litters. For the total of 678 half-inbred litters the sex ratio was
115.6 #: 100 2. Thisratio was some 11 points above the norm
and less than 7 points lower than the sex ratio in the inbred litters
belonging to the same group of generations (122.30: 1009).
While the litters produced by the mating of inbred females with out-
bred stock males thus tended to havea lower sex ratio than did the
strictly inbred litters, they did not give the sex ratio that was to be
expected according to the current view that chance alone deter-
mines whether a male-producing or a female-producting spermato-
zoon shall fertilize the egg. Such an hypothesis requires that the
sexes shall appear in approximately equal numbers when large series
of sex/data are examined. In the present case the proportion of
the sexes among the 5230 individuals obtained was very far from
equal. In only one group (ninth generation) out of eighteen was
there a nearly equal proportion of the sexes, in all other groups
there was a pronounced excess of males.

The first twenty-five generations of the A series of inbreds com-
prised 1752 litters containing 13,116 individuals, 7116 males and
6000 females. The sex ratio for this series of animals was 117.4
3#:100 2°. This ratio was over 12 points above the norm, and
since it was based on data for such a large group of animals, it
would seem to indicate that in the rat the sex ratio can be altered
by selection within a closely inbred line. In this instance the
relative number of males was apparently increased by selecting
breeding females from litters that contained an excess of males.

The sex data for the inbred and for the half-inbred litters of the
B series, combined in generation groups, are shown in table 7.

16 HELEN DEAN KING

TABLE 7

Showing, by generation groups, the sex ratios in the inbred and in the half-inbred
litters of the B series (female line)

INBRED HALF-INBRED

(FIRST AND SECOND LITTERS) | (THIRD AND FOURTH LITTERS)| °0™MARY OF All LITTERS

Ee

=)

o

s

2 te. Pes |) Sl See romior Ses || os 68
Se a i: moe 2 Se 2 Se
+ (Sel SE) | 24 S3ede gee 8 | ea |Se| 35 & | 333
e jes|82| 2] & | $e8 (S2/88| =| & | S82 |8=| £8 | 2 | 8 | S88
Role ls belle Niels bal Ste Te he |) Boles
1-4 | 36} 233} 122) 111] 109.9) 15) 109} 53) 56) 94.6} 51] 342) 175) 167) 104.8
5-7 |100) 699) 364) 335) 108.7) 78) 603) 300 303 99.0) 178) 1302) 664) 638) 104.1
a8 ate eS eee bo aS |

8-10}104| 795] 382) 413) 92.5) 73) 491) 252/ 239) 105.4) 177| 1286) 634) 652) 97.2
11-13|120) 876) 400) 476) 84.0) 99) 763) 358) 405) 88.4) 219) 1639) 758) 881) 86.0
14-16/130) 888) 386) 502) 76.9/116) 928) 450) 478, 94.1) 246) 1816) 836) 980) 85.3
17-19]138}1083| 472) 611) 77.3)113) 897) 414) 483) 85.7) 251) 1980) 886)1094) 80.9
20-22|152)1102) 505) 597; 84.6)109) 845) 401) 444) 90.3) 261) 1947) 9061041; 87.0
23-25/150)1149) 506) 643) 78.7/123) 875) 414) 461) 89.8) 273) 2024) 920)1104) 83.3

1427|10692|4940|5752| 85.9

8-25|794|5893|2651/3242| 81.8]633/4799|2289/2510) 91.
|+1.56| £1.

“I
i
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pms
Cw
Ve}

In the B series, as in the A series, there was a wide range of
variation in the sex ratios of the litters produced in the first seven
generations (table 5). When the data were combined in genera-
tion groups (table 7), the sex ratio in the 136 inbred litters (109
o: 100 2) was found to be above the norm, while that in the
half-inbred litters (98.3 7: 100 2) was below the norm. ‘These-
two ratios so nearly balance each other that for the total of 229
litters the sex ratio was 104.2 #: 100 9°, or less than 1 point be-
low the norm: in the corresponding litters of the A series the sex
ratio was 8 points above the norm (113.2 @: 100 2). On com-
bining the records for the first seven generations of the two in-
bred series (A, B), it was found that the total of 479 litters gave a
sex ratio of 108.6 #: 100 2. While this ratio is over 3 points
above the norm, it is not sufficiently high to warrant the con-
clusion that the normal sex ratio was changed through inbreeding,
particularly as the ratio was due in great part to an unusual ex-
cess of males in the hal!-inbred litters of the A series (table 4).

EFFECTS OF INBREEDING ON THE SEX RATIO 17

As far as can be judged from the results of this part of the inves-
tigation, close inbreeding, even when the animals are poorly
nourished, does not increase the proportion of male offspring to
any extent.

The breeding females in the seventh generation of the B series
of inbred were all taken from litters that contained an excess of
females; among their offspring the sex ratio was 94.3 #: 100 @.
In not one of the subsequent generations was the sex ratio in the in-
bred litters as high as the norm, the nearest approach to the norm
was in the twelfth generation, where the sex ratio was 101.5 &:
100 2 (table 5). In these inbred litters, as in the corresponding
ones of the A series, the sex ratios were more uniform in the later
than in the earlier generations, but there was no cumulative
effect of selection in either case. In the Bseries, after the thir-
teenth generation, there was very little change in the relative
proportion of the sexes from one generation to the next, and some
of the variation found, as stated for the A series, can doubtless be
ascribed to environmental action.

When the data for the inbred litters of the eighth to the twenty-
fifth generations of the B series were combined in generation
groups (table 7), if was found that the sex ratios for the various
‘groups showed even greater deviations from the norm than did those
for corresponding litter groups in the A series, but that this deviation
was in the reverse direction, 7.e., the number of females born greatly
exceeded ithe number of males. The highest sex ratio for any
group in the B series was 92.5 #@ : 100 9: for the entire group of
794 litters the sex ratio was 81.8 #@ :100 9, or 23 points below the
norm. ‘Thislatter ratio is far too low to be considered as a chance
variation, and it certainly cannot be attributed to the action of
environment. For both series of inbreds were reared simul-
taneously under the same environmental conditions, and if one
ventured to suggest that environment swung the sex ratio in the
B series towards the female side it would be necessary to assume
that the same environment acted on the animals of the A series
in a reverse direction and so swung the sex ratio towards the
male side.

THE JOURNAL OF EXPERIMENTAL ZOOLOGY, VOL. 27, No. 1

18 HELEN DEAN KING

As the sex ratio for the inbred litters of the B series was 23
points below the norm, while that for corresponding litters of the
A series was 18 points above the norm, it would appear that the
sex ratio in the rat can be swung by selection farther towards
the female side than towards the male side. Moenkhaus (’11)
obtained a similar result in his inbreeding experiments with
Drosophila.

The half-inbred litters in the eighth generation of the B series
gave a sex ratio nearly 10 points higher than the norm, so here
selection was not effective at once in changing the sex ratio. In
none of the subsequent generations, however, was the sex ratio in these
litters above the norm, most of them were considerably below it (table
5). When the data were combined in generation groups (table 7),
it was found that the sex ratios for all groups except one (eighth
to tenth generations) were very low. For the total of 633 litters
the sex ratio was 91.1 # : 100 9°, thus being 14 points below the
norm and 9 points higher than the sex ratio for the inbred litters
of this series.

In each of the inbred series the sex ratiosin the half-inbred litters
belonging in the eighth to the twenty-fifth generations showed less
deviation from the norm than did the sex ratios in the corre-
sponding inbred litters, yet ineach case the difference between the
sex ratio for the inbred group of litters and that for the half-
inbred group was less than the difference between the sex ratio
for the half-inbred litters and the norm. The possible signifi-
cance of these results will be discussed later.

In order to obtain the sex ratios for the various generations of
the inbred strain as a whole, the data for the two series (A, B)
were combined as shown in table 8.

The range of variation in the sex ratios of the litters in the first
four generations of the inbred strain was greater than that among
all of the other generation groups (table 8). This result was to be
expected, considering the relatively small number of individuals in
these generations and the adverse conditions under which the
animals lived. When the data were combined, however, the sex
ratio obtained (110.3 ” : 100 2) was only 5 points above the

EFFECTS OF INBREEDING ON THE SEX RATIO 19

TABLE 8

Showing the sex data for each of the first twenty-five generations of the inbred strain
(series A, B), also the sex ratios when the data were combined in
generation groups

NUMBER OF
NUMBER OF | MALEs TO 100

GENERA- | NUMBER OF | NUMBER OF MALES FEMALES | MALES To 100 FEMALES

TIONS LITTERS INDIVIDUALS

FEMALES IN GENERATION
GROUPS
1 5 34 21 13 161.5
2 20 137 65 72 90.3
3 36 180 90 90 100.0
4 68 442 240 202 118.8 110.3
5 132 952 470 482 97.5
6 107 745 392 303 111.0
7 111 766 417 349 119.5 108.0
8 103 772 402 370 108.6
9 129 910 466 444 104.9
10 141 1034 514 520 98.8 103.6
11 154 1140 594 546 108.8
12 147 1127 586 541 108.3
13 159 1229 609 620 98.2 104.8
14 161 1215 619 596 1035.9
15 161 1255 649 606 107.1
16 159 1155 567 588 96.4 102.5
17 184 1459 728 731 99.6
18 166 1307 660 647 102.0
19 166 1313 642 671 95.7 99:1
20 178 1294 671 623 107.7
21 184 1441 717 724 99.0
22 190 1502 750 752 99°77 101.8
23 170 1319 663 656 101.1
24 190 1386 689 697 98.9
25 187 1338 674 664 101.5 100.4
3408 25452 12895 12557 102.7
+1.28

20 HELEN DEAN KING

norm. The sex ratios in the litters of the fifth to the twenty-
fifth generations varied from 95.7 to 119.5 males to each 100
females. Variation, it will be noted, was around the norm, eight
of the twenty-one ratios being at or above the norm, the rest
below it. When combined in generation groups the sex data gave
a very uniform series of ratios, as the last column of table 8 shows
—not one of these ratios varied more than 6 points from the norm.
A variation as great as this would doubtless be found in the sex
ratios of any other large series of albino rats, regardless of the
manner in which the animals were bred. For the 3256 individ-
uals comprised in the first seven generations of the inbred strain
the sex ratio was 108.6 # : 100 @. This ratio is sufficiently
close to the norm, I think, to indicate that, in the rat, inbreed-
ing per se does not produce a marked increase in the number of
male offspring. The sex ratio in the22,196 individuals in the re-
maining eighteen generations was 101 & :100 @ : for the entire
series of 25,452 animals in the inbred strain the sex ratio was
102.7 # :100 @. While these last two ratios are slightly below
the norm, it is evident that in the inbred strain as a whole the
sex ratio was not greatly influenced either by inbreeding or by
selection. The very different sex ratios obtained in the two series
of the inbred strain seem to show, however, that through selection
the one inbred strain was separated into two distinct lines, one
line (A) having a tendency to produce an excess of males, the
other line (B) tending to produce a preponderance of females.

Unfortunately, one cannot predict with certainty what the sex
ratio will be in the litters cast by any given inbred female, neither
does the sex ratio in the litters cast by one female give a clear
indication regarding the proportion of the sexes that will be
found among the offspring of asisterrat. Itis only by taking the
averages for a large number of litters in a given series that the
change in the sex ratio is made manifest. As an illustration of
the individual differences in females regarding their tendencies to
cast young of a certain sex, four sets of data for litters cast by
sister females areshown in table 9. In each case given, sister rats
were first paired with the same litter brother and later with the
same stock male.

EFFECTS OF INBREEDING ON THE SEX RATIO yA |

TABLE 9

Showing the difference between.inbred sisters regarding their tendency to produce
an excess of male or of female young when mated with the same male

NUMBER NUMBER
eek hee MALES FEMALES SIRE Pde BE hed MALES FEMALES SIRE
ft
Bra | Br
1 ul 3 ily dapee'l oa 10 Bilan lit taiBeg
2 iit 5 6 11B7s 2 11 8 3 11B 7s
3 10 2 8 Stock 3 11 7 4 Stock
4 9 5 4 Stock
32 10 22 | 41 26 16
2
7B | 17B;s
1 8 8 5 17Big 1 10 4 6 17Bi¢
2 9 4 5 17Big 2 10 3 7 17Bi¢
3 8 3 5 Stock 3 of 3 4 Stock
4 3 i 2, Stock 4 11 5 6 Stock
28 11 17 38 15 23
3
12Aj34 12Aj35
1 8 6 2 12Aise¢ 1 8 3° 5 12Ai3¢6
2 8 4 4 12Ai36 2 9 4 5 12Ai36
3 7 df Stock 3 5 4 1 Stock
4 9 3 6 Stock 4 9 5 4 Stock
32 13 19 31 16 15
4
13A 74, 13A%46
1 9 5 4 13A2, 1 7 5 Z 13A3,
Z 10 5 5 Aes 2 9 9 13AGs
3 10 5 5 Stock 3 12 a 5 Stock
4 10 5 ia), Stock 4 8 5 3 Stock

22 HELEN DEAN KING

The first set of records given in table 9 shows the very great
difference in the sex tendencies of two sister rats belonging in the
B series. Female 11B; had cast three litters when she de-
veloped pneumonia and had to be killed. Each of these litters
contained such a large excess of femalesthat among her thirty-two
offspring the sex ratio was only 45.4 # :100 9: Female 11Bys,
on the other hand, showed a very strong tendency to produce
male young, whether she was paired with a brother or with a
stock male; among her forty-one offspring the sex ratio was
162.5 7 :100 2. As yet no other sister rats have shown such
a pronounced difference in their sex tendencies.

A very great similarity in the sex tendencies of sister rats is
shown by the second set of records in table 9. Each litter cast by
17Byu and by 17B:s contained an excess of female young, whether
the sire of the litter was an inbred or a stock male. In each
group of litters the sex ratio was about 65 7 :100 °.

Female 12A;;s produced an excess of male young in each of the
two litters sired by her brother, but the two litters sired by a
stock male showed a very great excess of female young. Con-
versely, while female 12A;,; cast more female than male young
when paired with a brother, she showed a strong tendency to pro-
duce an excess of male young when mated with a stock male.

The last set of records in table 9 shows a case where the total
number of offspring produced by each of two sister rats contained
a nearly equal proportion of the sexes, but this proportion was
attained in very different ways. Female 13A¢ showed a most
pronounced tendency to produce an equal number of male and
female young in each of her four litters. In the litters of female
13A, the sexes were very unequally distributed; one litter of
nine young consisted entirely of females—a most unusual phe-
nomenon in a litter of such size.

Numerous other cases, similar to the ones given, could be fur-
nished from the records for these inbred rats. The cases cited
are sufficient, I think, to show the individual differences in the
females regarding their tendencies to cast male or female off-
spring. Incidentally, these records show, also, that the female
plays a more important réle in determining the sex ratio than is
generally believed.

EFFECTS OF INBREEDING ON THE SEX RATIO 23

An examination of the sex data for successive litters cast by
many hundreds of female rats does not indicate that there is “‘a
change of sex tendency from litter to litter’ in the female, as
Papanicolau (’15) states is the case in guinea-pigs. Such a
tendency is not shown in any of the cases given in table 8, and
while the sex-proportions in the litters do change inmany cases,
the change is not general or striking enough to warrant the con-
clusion that there is a definite sex-determining factor involved.

4. THE SEX RATIOS IN THE LITTERS OBTAINED BY THE MATING OF
STOCK FEMALES WITH INBRED MALES

As a check for the results obtained by the mating of inbred
females with stock males, series of stock females were bred to
males from various generations of the inbred strain. The num-
ber of such experiments was small, considering the scale on which
the main series of experiments was conducted, but the results
obtained were uniform enough to be significant.

The stock females used in these experiments werereared under
the same environmental conditions as the inbred rats. When
they were about three months old they were paired with males
from the A or from the B series that had sired inbred litters. In
order to make this series of records more strictly comparable to
that obtained in the inbred strain, only four litters from any
one female were recorded.

The data for the litters obtained by the mating of stock females
with inbred males are given in table 10.

Stock females paired with males from the fifth generation of the
inbred strain produced litters in which the sex ratio was below
the norm, whether the sire of the litter belonged to the A or to the
B series of inbreds. The litters sired by males from A series,
however, had a much higher sex ratio than did those sired
by males from the B series, although at the fifth generation
there was no selection of breeding animals in the inbred strain
according to a definite plan. The eighteen litters in this series
gave a sex ratio of 94.7 # :100 2, or 10 points below the norm.
This ratio might seem to indicate that inbred males tended to
produce an excess of female offspring, but the number of litters

24 HELEN DEAN KING

TABLE 10
Showing the sex ratios in litters produced by the mating of outbred stock females with
inbred males

INBRED GENERATION
SERIES TO TO WHICH | NUMBER OF | NUMBER OF wre asec NUMBER OF MALES
WHICH SIRES SIRES LITTERS INDIVIDUALS z ‘i To 100 FEMALES
BELONGED BELONGED

A 5) 10 59 30 29 103.5

B 5 8 52 24 28 85.7
18 111 54 57 94.7+4.30 .
A 9 7 51 28 23 121.7
A 12 12 60 30 30 100.0
A 13 5 33 20 13 153.9
A 15 19 177 79 98 80.6
A 16 ll 126 67 59 113.6
A 17 14 117 60 57 105.2
A 18 39 347 177 170 104.1
107 911 461 450 102.3+5.88
B 10 12 97 51 46 110.9
B 12 11 75 38 37 102.7
B 13 8 42 18 24 75.0
B 15 19 172 87 85 102.3
B 16 29 243 116 127 91.3
B 18 38 313 152 161 94.4
117 942 462 480 96.2+30.14
he 242 1964 977 987 99.1

examined was too small to warrant any general conclusion from
the results obtained.

The second section of table 10 shows the sex ratios in the vari-
ous groups of litters obtained from the matings of stock females
with males from the ninth to the eighteenth generations of the A
series of inbreds. There was considerable variation in these sex
ratios, as was to be expected considering the number of animals
involved. The total of 107 litters in this group gave a sex ratio
of 102.3 #7 :100 2. This ratio, it will be noted, was below the
norm, although the sires of the litters were males that, paired
with their sister, had fathered litters in which there was, as a rule,
a preponderance of male young.

EFFECTS OF INBREEDING ON THE SEX RATIO 25

The sex ratios in the various groups of litters obtained by the
mating of stock females with males from the tenth to the eigh-
teenth generations of the B series of inbreds showed a much nar-
rower range of variation than that found in the litters sired by
males of the A series of inbreds, although the number of litters
produced in the two series was about the same. The 117 litters
in this group gave a sex ratio of 96.2 ~ : 100 2, which was 9
points below the norm. Any significance that this ratio might
seem to have, when taken alone, is apparently annulled by the
fact that the sex ratios for the other litters groups were also below
the norm, whether the sires of the litters came from the A or from
the B series of inbreds. Moreover, the probable error of the mean,
calculated from the averages for the various sets of litters, was so
large in every case that the differences between the sex ratios of
the various groups were rendered valueless.

The 242 litters in this series gave a sex ratio of 99.1 @ : 100 @.
While this ratio was some 6 points below the norm, it differed by
only 4.4 points from the sex ratio found in the 1510 litters ob-
tained by the mating of inbred females with stock males (103.5 7
: 100 2). Theresults as a whole, therefore, do not indicate that
the sex ratio was influenced to any extent by the fact that the
sires of the litters were inbred rather than outbred males.

The final experiment to be made, the pairing of females from
the one inbred series with males from the other inbred series, was
not begun until the animals reached the twenty-sixth generation.
The number of litters as yet obtained is too small to afford a basis
for any general conclusion, but thus far females of the A series
(male line) when paired with males from the B series (female line)
have produced more male than female young, and, conversely,
females of the B series, when paired with males of the A series,
have shown a tendency to cast more female than male young.

The results of these various series of experiments are summar-
ized and discussed in the following section.

26 HELEN DEAN KING
5. DISCUSSION

As a basis for discussion the results obtained in this investi-
gation are briefly summarized as follows:

1. The inbreeding of litter brother and sister for six consecu-
tive generations, during which there was no selection of animals
for breeding, did not increase the number of male offspring to any
extent. The sex ratio in the 3256 young obtained was 108.6 @:
100 ¢, or less than 4 points above the sex ratio taken as the
norm (105 #7 : 100 @).

2. Beginning with the seventh generation all breeding females
in the A series were taken from litters that contained an excess
of males. After this time the females in this series tended to
produce an excess of male young, whether they were paired with a
litter brother or with an unrelated stock male (table 6). The
litters sired by inbred males gave a sex ratio of 122.3 7 :100 9,
or over 17 points above the norm; while the litters sired by stock
males showed a sex ratio of 115.6 # :100 9°, or nearly 11 points
above the norm.

3. From the time that the breeding females in the B series
were selected from litters containing an excess of females (seventh
generation), the litters produced showed a reverse proportion of
the sexes to that shown by corresponding litters in the A series
(table 7). Litters sired by inbred males had a very low sex ratio
(81.8 # :100 2); in the litters sired by stock males the sex ratio
was 9 points higher than that in the inbred litters (91.1 @ : 100
2), but it was still significantly lower than the norm.

4. On combining the data for the two inbred series it was found
that among the 25,452 individuals comprised in the inbred strain
the sex ratio was 102.7 # : 100 9°, or less than 3 points below the
norm (105.0 ~# :100 2). It thus appears that through selection
the inbred strain was separated into two distinct lines: one (A)
showing a high sex ratio, the other (B) a low sex ratio. Selection
had the greater influence on the female line, since the sex ratio
for the litters of the B series showed greater deviation from the
norm than did that for the litters of the A series.

5. Stock females mated with inbred males tended to produce
litters in which the sex ratio was below the norm, regardless of

EFFECTS OF INBREEDING ON THE SEX RATIO 27

_whether the male belonged to the A or to the B series of in-
breds. The litters sired by males from the A series showed a
higher sex ratio (102.3 # :100 2), however, than did the litters
sired by males from the B series (96.2 co :100 2), but these ratios
are not significant, since they differ from each other and from the
norm by less than three times the probable error (table 10).

Diising’s contention that close inbreeding increases the relative
number of male offspring was based mainly on statistics of human
births collected from several isolated communities in which there
were many consanguineous marriages, and on the supposedly great
preponderance of male births among the Jews, who are a clannish
race and intermarry more frequently than do other civilized
races. The latter evidence is undoubtedly invalid, as Pear! and
Salaman (713) have shown that the normal sex ratio among the
Jews is the same as that in other races of man (105 &@ : 100 °),
and that the anomalous sex ratio among them is due to faulty
registration, male births being recorded where those of females are
not. The high sex ratio in the other cases cited by Diising can
doubtless be attributed to a similar cause. The great excess of
males found in various strains of thoroughbred dogs Heape (’08)
ascribed in part to inbreeding, but in these cases also it is prob-
able that the statistics are not reliable, since female pups are
commonly discarded from large litters and males are registered
more often, as a rule, than females.

The inbreeding experiments of Huth (’87) on the rabbit, of
Schultze (03) and of Copeman and Parsons (’04) on mice were
made with relatively small numbers of animals, and the sex ratios
obtained showed no greater deviations from the norm than might
have been expected under the conditions of the experiments.
Shull (’13) found no change in the sex ratio of Hydatina senta as a
result of repeated inbreeding, the proportion of male-producers
and of female-producers remaining practically constant. In the
present series of inbreeding experiments with the albino rat, all of
the animals belonging to the earlier generations suffered severely
from malnutrition, which Diising (’84) considered as a very potent
factor in increasing the number of male offspring, yet among the
individuals in the first seven generations the sex ratio was only

28 HELEN DEAN KING

slightly higher than the norm. The results of these various series
of experiments would seem to indicate that inbreeding per se has
little, if any, effect on the sex ratio.

Moenkhaus’ (’11) extensive series of inbreeding experiments on
Drosophila so closely parallel my own experiments on the rat,
both in the manner in which the experiments were conducted and
in the results obtained, that a brief résumé of his work must be
given here.

In order to obtain the normal sex ratio in Drosophila, Moenk-
haus ascertained the sex of 26,933 imagos that developed from
eggs laid by wild flies, and found among them a sex ratio of 88.8
& :100 2. Inthis species, therefore, there is normally an excess
of females, as other investigators (Rawls, ’13; Hyde, ’14; Warren,
718) have noted. The experiments were conducted in the fol-
lowing way: ‘“‘Two pairs were selected from nature, the one
showing a high, the other a low female ratio. These were se-
lected as the parents of the two strains to be developed. From
among the offspring of each of these two pairs a number of single
matings were made. From among these the pair that showed the
most favorable ratio in the desired direction was selected to con-
tinue the strain. The same process was repeated as often as
desired.”’

In this way Moenkhaus developed two inbred strains in one of
which the individuals showed a high sex ratio, in the other a low
sexratio. The results of this part of the investigation showed that
‘Gt is possible to develop a strain with a high female ratio much
more easily and pronouncedly than a male strain.’”” Moenkhaus
then made reciprocal crosses between the two strains in order to
determine, ‘‘first, whether the maternal or the paternal elements
had an equal share in the control of this ratio, and second,
whether this ratio was determined in the process of fertilization.”
The experiments showed, in a most decided way, that ‘“‘the male
has little or no influence in determining the sex ratio in this species.
In most of the cases the ratio of the offspring falls pretty closely
around that of the strain from which the females were taken.

It is not certain, however, that the sex ratio is established
before fertilization, since the experiments do not with certainty

EFFECTS OF INBREEDING ON THE SEX RATIO 29
entirely exclude the male influence.”” In his summary Moenkhaus
states: ‘The sex ratio is one of the qualities that is, like color, an
inherent character of this creature, strongly transmissible and
amenable to the process of selection. . . . Sex is probably
very little, if at all, influenced at fertilization in this species, but
it is probably determined much earlier and by the female.’
Moenkhaus’ conclusions regarding the character of the sex
ratio and its amenability to selection are as applicable to the rat
as they are to Drosophila, judging from the results of my in-
breeding experiments on the former species. Neither of these
investigations, however, give any information regarding the
causes that condition sex, although each seems to indicate that
the female takes quite as important a part in this process as does
the male.

In the inbred strain, after the animals for breeding were selected
in each generation according to a definite plan, the two series
(A and B) became two separate lines as regards the sex-propor-
tions among the young. In the one line (A) the litters contained,
as a rule, an excess of males; in the other line (B) there was a cor-
responding excess of females. Between these two lines there was
no very marked difference as regards the size of the individuals
at a given age, their fertility or longevity, as the data given in
previous papers have shown (King, ’18, ’18 a). Generation after
generation, as far as the experiments have been carried, the sex
ratios in the inbred lines have remained distinct, and the varia-
tions from the norm have. been in the same direction in each
generation of each series. These results are definite enough, and
they are based on data from a sufficiently large number of animals.
I think, to warrant the conclusion that in the rat the sex ratio is
to a certain extent at least, a character that is amenable to
selection.

1 Warren (’18) has recently repeated Moenkhaus’ selection experiments on
Drosophila, and concludes that the sex ratio in this form is ‘‘not readily, if at all,
modifiable by selection.’’ Warren believes that the modified sex ratios found in
two of his three series of experiments were due to ‘chance variation,’ and he
attributes the anomalous sex ratios obtained by Moenkhaus to the action of a
sex-linked lethal factor—the explanation offered by Morgan (14 a) to account for
the unusually low sex ratios found in several strains of Drosophila.

30 HELEN DEAN KING

As the rats had been inbred brother and sister only, they were,
according to Fish’s (714) calculations, 79.687 per cent homozy-
gous at the time that the selection of breeding animals began
(seventh generation). Selection, if effective at all in changing
the sex ratio, should act in one or two generations, unless a con-
siderable number of factors were involved. In the latter case
selection might produce a gradual change in the sex ratio which
would reach its culmination only after a number of generations.
In each series, as table 4 and table 5 show, the sex ratio in the
inbred litters of the eighth generation was close to the sex ratio
that was the average for all of the litters produced in the eighth
to the twenty-fifth generations, and the sex ratios in the later
generations showed no greater deviation from the norm than did
those in the earlier generations, although they were somewhat
more uniform. Selection thus produced its maximum effect at
once, and could not shift the centre of gravity of the variation in
the direction of the selection, as it did in the experiments which
Castle and Phillips (14) made with piebald rats. It would
appear from these results that very few heritable factors concerned
in the production of the sex ratio, possibly not more than a single
pair, were acted upon by selection, and that, as Pearl (17) has
stated: ‘‘selection acts only as a mechanical sorter of existing
diversities in the germ plasm and not as a cause of alteration in
1

As sister rats show such marked individual difference regarding
their sex tendencies, and as both nutritive (Slonaker and Card,
18) and environmental conditions (King and Stotsenberg, ’15)
seem to influence the sex ratio in the rat, it would seem that the
sex ratio may be modified by so many agencies that it would be
useless to attempt to determine the number or the nature of the
particular factors that were acted upon by selection in the present
ease. The factors involved are evidently not of very great po-
tency, and their action is clearly shown only when a relatively
large number of animals are closely inbred under environmental
and nutritive conditions that are as uniform as it is possible to
make them. Whatever their nature, or in whatever manner they
may be inherited, I believe that these factors act on the metabo-

EFFECTS OF INBREEDING ON THE SEX RATIO ol

lism of the ova in such a way as to render the ova more easily fer-
tilized by one kind of spermatozoa than by the other. Inthe A
series of inbreds, under the conditions given, the ova tended to
attract spermatozoa that were ‘male-producing;’ in the B series,
the ova tended to attract spermatozoa that were ‘female-pro-
ducing.’

In advocating the possibility that fertilization may be selective
I am aware that I run counter to the general belief that any egg
is capable of fertilization by any spermatozoén that happens to
come in contact with it, and that those whose views have much
weight in molding biological opinion believe that this hypothesis
is ‘‘so improbable as almost to invalidate any interpretation
into which it enters’ (Wilson, °10). Just why this hypothesis
is considered so untenable is not clear. It is true that it has
not been definitely proved in any case, but neither has it been
disproved, nor has any convincing proof been offered, as yet,
for the very elaborate hypotheses that have been advanced to
account for heredity in general and in specific cases. The burden
of proof rests equally upon those who object to this hypothesis as
on those who maintain it.

We owe to McClung (’02) the suggestion that the accessory
chromosome may be a sex-determinant. In discussing the pos-
sible action of the accessory chromosome in determining sex,
McClung (’02 a) states: ‘even up to the time of fertilization the
female elements are so placed as to react readily to stimuli from
the mother. Here they are approached by the wandering male
elements from which they may choose—if we may use such a term
for what is probably chemical attraction—either the spermatozoa
containing the accessory chromosome or those from which it is
absent. In the female element, therefore, as in the female or-
ganism, resides the power to select that which is for the best
interest of the species.”’

In advocating selective fertilization as the probable cause of
anomalous sex ratios, Heape (’09) says: ‘‘it must be remembered
that there are an enormous number of spermatozoa available for
the fertilization of each ovum, and, moreover, it will be recol-
lected there are undoubtedly chemotactic properties associated

251 HELEN DEAN KING

with ova which insure that ova of different species floating in the
sea shall each be fertilized by spermatozoa of the same species, so
that to grant there is still more delicate chemotaxis at work is not
an illegitimate but is indeed a reasonable supposition.”’ Castle
(03) also postulated selective fertilization in the elaboration of
his Mendelian theory of sex-determination.

The one attempt that has been made to test the hypothesis of
selective fertilization (Morgan, Payne and Browne, ’10) seemed to
indicate that the egg is fertilized by the first spermatozo6n that
strikes it ‘head-on,’ but the conditions under which the obser-
vations were made were so abnormal that no definite conclusions
from them were possible, and even Morgan (’11) states that the
evidence is ‘admittedly insufficient.’

An earlier experiment that has a bearing in this connection seems
to have been overlooked and therefore needs to be noted here.
Marshall (’10) injected into the vagina of a pure-bred DandieDin-
mont bitch a mixture of seminal fluid taken from a pure-bred dog
of the same species and from a mongrel terrier of unknown an-
cestry. Fifty-nine days later the bitch littered, producing four
pups which were much alike. One of the pups died early, but
as the other three developed into mongrels which resembled the
terrier sire there was little doubt but that all four puppies were
mongrels. Marshall cites another case in which a Dandie Din-
mont bitch copulated with a dog of the same breed and two days
later with a Scotch terrier. The bitch littered three pups; one
was pure Dandie Dinmont, the other two half-bred Scotch terriers.
These cases, according to Marshall, were indicative of a ‘selec-
tive’ on the part of the ova of the pure-bred bitch to ‘“‘conjugate
with dissimilar rather than with related spermatozoa.”

I have recently been making a series of experiments somewhat
on the order of those cited by Marshall, and the results obtained
indicate a very strong tendency on the part of the ova of the al-
bino rat to conjugate with spermatozoa from the wild gray rat
rather than with the spermatozoa of the albino rat, although under
the conditions of the experiment, details of which will be pub-
lished later, the advantage in every case was with the spermato-"
zoa from the albino male. _ If fertilization can be selective in such

EFFECTS OF INBREEDING ON THE SEX RATIO 33

cases I can see no valid objection to the assumption that the
chemotactic reaction between ova and spermatozoa may be even
more delicate and thus, under given conditions, make possible
the fertilization of an egg by a spermatozo6n that has one sex
potency rather than the other.

There is another possible interpretation of the anomalous sex
ratios found in the inbred litters of the two series. .We might
assume that inbreeding had acted on the males in some way so as
to render one kind of spermatozo6n more potent than the other in
fertilizing the ova, and that this difference in potency came to
have an heritable basis in the germ plasm and so could be acted
upon by selection. In the A series of inbreds, according to this
assumption, the ‘male-producing’ spermatozoa became the more
potent; in the B series the ‘female-producing’ spermatozoa came
to have the greater potency. Were this assumption correct it
should receive confirmation both from the results of the experi-
ments in which inbred females were paired with stock males and
from the experiments in which stock females were paired with
males from different generations of the two inbred series. The
litters obtained in the former case should show a nearly equal
proportion of the sexes (provided it was merely a matter of chance
which kind of spermatozoa fertilized the ova), since the males
were outbred and therefore, theoretically, the two kinds of sper-
matozoa had equal power to fertilize the ova. In the latter case
the litters obtained should show a high sex ratio when the sire
eame from the A series of inbreds and a low sex ratio when the
sire belonged to the B series.

As shown in table 4 and in table 5, the half-inbred litters pro-
duced by the mating of inbred females with stock males gave sex
ratios that were very far from equality. In only one generation
of each series was there an approximately equal proportion of the
sexes, in all other cases the variation was in a definite direction:
in the A series there was an excess of males; in the B series the
females predominated. In both series, moreover, the sex ratios
in the half-inbred litters were much closer to those in the cor-
responding inbred litters than they were to the norm. ‘The uni-
formity in the various series of records and the small size of the

THE JOURNAL OF EXPERIMENTAL ZOOLOGY, VOL. 27, No. 1

34 HELEN DEAN KING

probable error of the mean exclude the possibility that the sex
ratios could have been produced by chance or by environmental
action. The results, therefore, do not support the contention
that the male is the chief factor in determining the sex ratio in
the rat.

The sex ratio in each of the three groups of litters obtained by
the mating of stock females with males from various generations
of the two inbred series was below the norm, whether the sire of
of the litters belonged in the A or the B series. The sex ratio
in the group of litters sired by males from the A series (102.3 @ :
100 ©) was only 6 points higher than that in the litters sired
by males from the B series (96.2 # :100 2). The results in this
case, therefore, do not indicate that inbreeding, with selection,
influenced the potency of the spermatozoa in any way; they seem
rather to signify that the particular stock females used for breed-
ing tended to attract spermatozoa that were ‘female-producing’
rather than those that were ‘male-producing.’

The results of the various experiments in which inbred and out-
bred animals were paired, taken in connection with those from
the experiments in which matings were made between litter
brother and sister, seem to show that in the rat, as in Drosophila
(Moenkhaus), the female has a greater influence than the male in
determining the sex ratio, and that chance alone cannot be the
factor that determines whether an egg shall be fertilized by a
‘male-producing’ or by a ‘female-producing’ spermatozoon.

The size of the probable error of the mean (tables 6 and 7) in-
dicates that in each series the difference between the sex ratio for
the group of inbred litters and that for the group of half-inbred
litters is a significant one. Apparently, therefore, the chemo-
tactic reaction between the ovum and the spermatozo6n is not
quite the same where these sexual elements come from unrelated
individuals as when they are produced by individuals that are
closely inbred. A somewhat analogous case is found in the her-
maphroditie ascidian, Ciona, where normally, as Castle (96) and
Morgan (’04, ’05) have shown, the eggs are not fertilized by sper-
matozoa from the same individual, although they are readily fer-
tilized by spermatozoa from any other individual, while the

EFFECTS OF INBREEDING ON THE SEX RATIO 30

spermatozoa from the first animal are functional when used with
ova of another animal. Morgan (’14) has suggested that the
infertility of the eggs of Ciona to spermatozoa from the same in-
dividual may be due to the similarity in the hereditary complex
of the germ cells which in some way decreases the chances of
their uniting. The selective fertilization experiments made by
Marshall (’10) with different varieties of dogs and also my own
experiments with different varieties of rats show that the ova of
these animals have a strong tendency to unite with spermatozoa
from individuals belonging to unrelated stock rather than with
spermatozoa from individuals of the same ‘blood.’ When my own
experiments are completed the results will show, I hope, whether
there is a still more delicate chematactic reaction between the
ova and the spermatozoa which will lead to the production of
more males than females among the hybrid offspring. The ano-
malous sex ratios that appear in F, hybrids almost invariably
show an excess of males. This suggests that the greater the dif-
ference between individuals as regards theis blood relationship the
stronger is the attraction between the ova and the ‘male-pro-
ducing spermatozoa. If this suggestion proves true, its converse
ought also be to true, and in a closely inbred line we would expect
that the chemotactic reaction between the ova and the sperma-
tozoa would be such that an excess of females would be produced.
Such a possibility is not incompatible with the results of the pres-
ent investigation, since in the inbred strain, as a whole, the sex
ratio was below the norm, while the sex ratios in the litters of the
female line (B) showed a greater deviation from the norm than
did the sex ratios in the litters of the male line (A).

The results of this series of experiments, as a whole, seem to
indicate that in the rat, as in the pigeon (Riddle, ’14, ’16, 717),
in Drosophila (Moenkhaus, ’11) and in the guinea-pig (Papani-
colau, 715), the female has more influence in determining the sex
ratio than hasthe male. Yet it is not in the differentiation of the
ova, nor in the development of the spermatozoa, that the key to
the riddle of sex-determination will be found. A knowledge of
the interaction of the germ cells, and of the conditions that in-
fluence it, must be gained before the final solution of this problem
can be attained.

AUTHOR'S ABSTRACT OF THIS PAPER ISSUED
BY THE BIBLIOGRAPHIC SERVICE, AUGUST 7

DEMONSTRATION OF EPITHELIAL MOVEMENT BY
THE USE OF VITAL STAINING, WITH OBSER-
VATIONS ON PHAGOCYTOSIS IN THE
CORNEAL EPITHELIUM

SHINICHI MATSUMOTO
Osborn Zoological Laboratory, Yale University

FOUR FIGURES

Though the cornea of the adult frog is thin and transparent
enough for the observance of epithelial movement, it is not an
easy matter to note in detail every part of the process. For
this reason certain vital stains were used in the present
experiments.

In the amphibians, vital staining ean be produced either by
introducing the dyes into water in which the animals swim, or
by injection, though the latter procedure is not practicable in
the case of corneal epithelium, owing to its lack of blood-vessels
The stained tissue may then be explanted. Another method is
to add the dyestuffs to the culture medium containing the un-
stained tissue. |

Several papers have appeared dealing with the different phases
of this subject (Lewis and Lewis, ’15; Russel, ’14).

For the purpose of the present work it is necessary that the
dyes should not have any deleterious effect upon the epithelial
cells in order that they may remain capable of maintaining their
normal activity. The staining must be produced easily and
last for a considerable time.

That the epithelium of amphibians (especially larvae) is
tingeable by various dyestuffs without affecting the organism or
tissue elements to any marked degree has been shown by various
observers (Fischel, ’01). Whether vital staining may be
employed in order to demonstrate moving epithelium in the cul-
ture is, however, another question.

37

38 SHINICHI MATSUMOTO

A. METHODS OF VITAL STAINING

1. Methods of staining by immersing the whole animal in water
containing dyes

a. Neutral red. Neutral red, which was first used by Ehrlich
for vital staining, was considered as probably being the most
suitable for the present purpose, and this proved to be the case.

In the majority of the experiments ‘‘neutral red for vital
staining (Ehrlich)? was used, and the frogs were subjected to
various concentrations of the dye for various lengths of time.

The experiments may be divided into two groups. In the
first the animals were subjected to a relatively concentrated
(1: 20,000) neutral red solution for a short time (one to five
hours), and in the second they were kept in a more dilute solu-
tion (1: 100,000 to 1,000,000) for a much longer period (one-half
to four days). The frog was then carefully washed in running
water, the tissue removed and prepared in a manner similar to
that used in previous experiments (Matsumoto, °18). Both
modes of staining are adapted to the study of the movement
of epithelium.

Though the frog could be stained an intense red without doing.
it any apparent harm, still the dye proved to be more or less
harmful to the cells. In fact, an earlier degeneration of the
explanted tissue due to the injury of cells in such preparations
was frequently seen. As it was desirable to stain the tissue in
such a manner that the granules would be just evident enough
for observation, weak solutions (such as 1: 100,000 to 1: 200,000;
ten to twenty-four hours) were preferable. The use of the more
rapid staining, at times, brought on the disadvantage of having
the granules appear unevenly distributed.

The arrangement of the neutral red granules shows a more or
less marked difference in the several cell layers of the corneal
epithelium. Observing from the upper (outer) surface of the
corneal tissue in the culture, we see the following:

1. The outermost layer (fig. 1, d) consists of flat polygonal
cells with large nucleus and unstained fine refractive granules in
the cytoplasm. These cells, which may be present all over the

VITAL STAINING OF CORNEAL EPITHELIUM 39

original epithelial surface or may be absent here and there, do not
usually exhibit neutral red granules and show no activity.

2. The next layer (fig. 1, ec), which is the uppermost layer in
some preparations, consists of cells which contain in the eyto-
plasm the most minute red granules, almost uniform in size.
These appear in abundance after prolonged intense staining.
The contour of the individual cells is hardly visible at first.
In some instances, especially when the rapid method of staining
was employed, larger granules appeared in the cells so abun-
dantly that they almost filled the cell body, leaving only a clear
round or oval space in the center, occupied by the nucleus.

3. The basal-cells (fig. 1, a), which are evidently smaller than
those of the upper layers, exhibit, as a rule, distinct and much
larger granules, not very uniform in size, and often more numer-
ous on one side of the nucleus than on the other.

4. Between the two latter layers frequently another layer of
cells (fig. 1, b) is visible. These are intermediate in size between
the cells of the basal layer and those of the layer above,andas
regards the arrangement of the colored granules show a resem-
blance to the cells of the second layer.

Furthermore, between the second and third layers there were
found a number of deeply red stained bodies, round or irregular
in shape, some of which showed a more deeply stained red spot
(one of these is shown in fig. 1, a, and another in fig. 2,a). The
origin of these bodies is unknown.

When the culture is observed several hours or more after the
preparation, the cells of the upper and basal layers are easily
distinguishable according to the distribution of granules in their
cytoplasm, and this becomes more marked as the tissue becomes
more translucent. The individual granules were sometimes
observed to coalesce gradually, changing in shape.

When the tissue is intensely stained, the cells of the connective
tissue and of the posterior endothelium also show distinct gran-
ules which are usually not so abundant and are more or less dis-
tinguishable from those of the epithelium. The nucleus re-
mains unstained throughout.

40 SHINICHI MATSUMOTO

Cultivated in vitro, the corneal epithelium, when stained with
neutral red, showed a condition entirely similar to that seen in
unstained preparations. The cells exhibited practically the same
degree of activity, though at times they degenerated a little
earlier than in the control preparation.

By this method, the cell movement along the tissue, which took
place, as a rule in the fluid or semifluid culture medium, could
be easily detected. That the spreading epithelium was, as a rule,
two and sometimes three layers thick, was clearly demonstrated
(fig. 2, a), while in an unstained preparation it was rather hard
to determine whether they were one or two cells in thickness.

As the epithelium spread out and the individual cells became
very flat and thin, a change in the arrangement of the granules
took place. Then the granules of the basal cells, which were
rather irregularly distributed at first, frequently assumed a cres-
cent-shaped arrangement (fig. 2, a). If the staining was light,
the tiniest red granules in the cells of the surface layer became
faint relatively earlier. As a rule, the hyalin processes of the
cells on the border did not exhibit any red granules. In general,
after all activity of cells ceased, the red granules faded out and
fatty granules increased, whereas the nucleus remained unstained.
The same was true of the isolated epithelial cell.

So far as our observations go, there was in general a direct
relation between the cell activity and presence of neutral red
granules, although of course the intensity or richness of the gran-
ules;was not alweys parallel with the cell activity.

b.& Some other dyes. In the corneal epithelium subjected to
‘Nile blue sulphate,’ the granules were beautifully stained. This
dye was found, however, to be injurious to the cells, and even
the solution 1: 200,000 in most instances caused more or less
injury to the epithelium, though not enough to interfere immedi-
ately with the cell activity, since in many cases the cells contin-
ued to move. Disintegration of cells took place earlier, and a
preparation which showed intense granulation never lived so long
as the control culture (unstained or stained with neutral red).
In addition to this, in the preparation subjected to the dye, fine
violet crystals appeared in the cells or in the medium. Nile blue,

VITAL STAINING OF CORNEAL EPITHELIUM 4]

therefore, does not seem to be a very favorable dye for the cor-
neal epithelium.

Neither is ‘methylene blue (rectif.)’ suitable for the purpose,
as it fades too easily.

So far as our observations go, ‘gentian violet’ did not give a
satisfactory result. Even the weakest solution, which stained
the cells, caused their death.

‘Brilliant cresyl blue 2 b’ and ‘methyl green’ did not stain the
granules clearly, nor did ‘indigo carmin,’ ‘toluidine blue,’ or
‘litmus’ give positive results.

2. Staining of the cornea by administration of dyes in the
conjunctival sac

Arnold (’00) demonstrated neutral red and methylene blue
granules in the frog cornea by conjunctival administration of the
dyes in the form of fine powder. In this way typical granules
appeared in the cells, often causing injury. No experiments of
this kind are recorded in the present paper.

3. Staining of excised cornea

In some experiments the cornea was first excised from the
animal and then stained. The tissue, after removal, was im-
mersed in physiological saline solution containing neutral red,
freshly prepared, so that the epithelium became intensely red,
and could later be cultivated after thorough washing. The tech-
nique is simple and is useful in some particular instances. Usu-
ally, however, crystals appeared in the culture, when this method
was employed.

4. Staining by addition of dyes to the culture medium

Both neutral red and Nile blue, freshly dissolved in salt solu-
tion, were experimented with. They are easily soluble in pure
water, but not so easily if the water contains any salt (NaCl).
The appearance of crystals and the uneveness of the staining
proved this method to be an unsatisfactory one. Staining of
nucleus and granules by the use of gentian violet failed. Methyl-
ene blue stained granules, but it could not be employed for the
purpose on hand.

4? SHINICHI MATSUMOTO

B. PHAGOCYTIC PHENOMENON OF THE CORNEAL EPITHELIUM

Though the experiments on this line have not yet been com-
pleted, some interesting phenomena will be described here.

It was noted in the course of this work, that not infrequently
in the preparations of cornea, where the pigment of the iris or
chorioidea was accidentally mixed with the epithelium, the cells
of the latter, originally not pigmented, took up the pigment, be-
coming gorged with it. This was easily demonstrable, but more

markedly when the pigment of the eye was finely teased and put.

into the culture medium with the corneal epithelium. The cells
of the moving border, especially, took up the dark pigment
abundantly.

That the melanin granules are really taken up in the cytoplasm
of cells, was clearly demonstrated in the preparations which were
first vitally stained with neutral red (fig. 3). That those pig-
mented cells were not the originally pigmented epithelium of eye,
accidentally mixed in the preparation, is beyond doubt. The
epithelial cells were able to take also melanin which was previ-
ously heated or boiled.

The arrangement of the pigment granules in the cytoplasm
was characteristic, resembling that of the neutral red granulations.
The cells of the basal layer were often abundantly packed with
the pigment, and those of upper layers were able to ingest it, too.

If in the epithelial cells which are originally not pigmented,
abundant melanin is taken up, it is extremely difficult to distin-
guish them from the original pigment cells.

The possibility of epithelial phagocytosis has been considered
by Riehl (’84) ; somewhat later, Rabl (’96) also took up the ques-
tion and found that the epithelium of adult salamanders (S.
maculosa) is able to take up carmin injected subcutaneously. In
cultures of carcinoma and sarcoma, Lambert and Hanes (11)
demonstrated that carmin granules are taken up by the cells.
Carrel and Burrows (’11) observed a similar phenomenon in cul-
tures of sarcoma.

The melanin problem represents one of the most interesting
questions in dermatohistology and experimental dermatology
and is a much discussed subject. I should not go, of course, so

en

VITAL STAINING OF CORNEAL EPITHELIUM 45

far as to say that the so-called ‘Einschleppungstheorie’ of melanin
is generally accepted, though the fact stated above shows the
possibility of its correctness.

Though the observations here recorded have been made only
upon cells in culture, still it may not be impossible that the same
occurrence takes place in vivo under certain conditions. At any
- rate, the phagocytic action toward melanin of epithelium of the
adult frog in culture is here definitely shown.

Therefore, it is not quite safe, in the culture of pigmented epi-
thelium, such as iris, to consider the pigment granules as the
peculiar possession of that epithelium, because the original non-
pigmented epithelium can ingest pigment granules. The study
of a complex and peculiar cell, such as the pigment cell, requires
great care in the methods used and in conclusions drawn.

Carmin, which was ground into fine powder, was also taken
up into the cell bodies, which then showed beautiful carmin
granulation. For this purpose the use of tissue, vitally stained
with Nile blue, offered great advantage.

The arrangement and distribution of the granules was entirely
similar to that of the melanin; the particles were arranged with
considerable uniformity around the periphery of the cytoplasm.

As figure 4 shows, corneal epithelium, cultivated in plasma (or
serum), containing both melanin and carmin, exhibits beautiful
melanin and carmin granulations which can be preserved safely.
Examination of such preparations in serial sections demon-
strated the intracellular and perinuclear position of the granules.
That they are in the cell bodies may be placed beyond doubt
even by the careful observance of fresh preparation. Further-
more, such preparations have the advantage of enabling the
observer to watch how cells with ingested granules may become
detached from the main mass and move off in the culture medium.

Fine granules of Chinese ink or minute foreign bodies acci-
dentally mixed in the culture were also taken up by the
epithelium.

In regard to this most interesting phenomenon of epithelial
phagocytosis, our present knowledge is very deficient. A strict
differentiation of the epithelial movement from that of leucocyte

44 SHINICHI MATSUMOTO

may not be possible in the case of the tissues of the frog living
in vitro. Not only in their movements, but also in the phago-
cytic phenomena (with respect to foreign bodies) do they show a
certain degree of resemblance.

The question of the said phenomena in the warm-blooded ani-
mals, as well as their bearing upon bacteriology and serology,
will be considered later.

I wish to thank Prof. R. G. Harrison for the direction and
support which he has given to this work.

C. SUMMARY

The epithelium of the cornea of the frog which was vitally
stained with neutral red and Nile blue exhibits characteristic
granules in the cytoplasm.

If properly stained, the granules exist through the entire
period of cell activity, without practically affecting the cells,
and facilitate the observance of cell movements.

Phagocytic phenomena of the corneal epithelium with refer-
ence to melanin, carmin, etec., are definitely demonstrated.

The distribution and arrangement of melanin and carmin gran-
ules, if finely powdered, show a certain degree of resemblance to
that of neutral red and Nile blue.

VITAL STAINING OF CORNEAL EPITHELIUM 45

LITERATURE CITED

ArNoLD 1900 Granulabilder an der lebenden Hornhaut und Nickhaut. Anat.
Anz., 18, 45.

CARREL AND Burrows: 1911 Cultivation in vitro of malignant tumors. Jour.
Exp. Med., 18, 571.

FiscHeL 1901 Untersuchung iiber vitale Fairbung. Anat. Hefte, 16, 417.

LAMBERT AND Hanes 1911 Characteristics of growth of sarcoma and carcinoma
cultivated in vitro. Jour. Exp. Med., 13, 495.

Lewis AnD Lewis 1915 Mitochondria and other cytoplasmic structures in tis-
sue cultures. Am. Jour. Anat., 17. 339.

Lores 1912 Growth of tissue in culture media and its significance for the analy-
sis of growth phenomena. Anat. Rec., 6, 109.

Matsumoto 1918 Contribution to the study of epithelial movement. The
corneal epithelium of the frog in tissue culture. Jour. Exp. Zodl.,
vol. 26.

OppreL 1912 Causalmorphologische Zellenstudien. V. Mitteilung. Arch.
Entw.-Mech., 35, 371.

Rast 1896 Untersuchungen iiber die menschliche Oberhaut und ihre Anhangs-
gebilde mit besonderer Riicksicht auf die Verhornung. Arch. Mikr.
Anat., 430.

Rrext 1884 Zur Kenntnis des Pigmentes im menschlichen Haar. Viertelj.
Derm. u. Syph.

Russet 1914 The effect of gentian violet on protozoa and on tissues growing
in vitro, with special reference to the nucleus. Jour. Exp. Med., 20,
545.

ZirLoNKo 1874 Uber die Entwicklung und Proliferation von Epithelien und
Endothelien. Arch. Mikr. Anat., 10, 351.

PLATE 1
EXPLANATION OF FIGURES

1 Experiment 202. C.11. Neutral red granules in different layers of the
corneal epithelium (adult frog) cultivated in plasma, 12 hours old. a, Granulesin
the basal cells; b, cells of a layer often recognizable between a and c; c, granules in
the cells of upper layer; d, cells of the uppermost layer, which show no activity.
x 450.

2 Experiment 206. A. 3, showing neutral red granules in the moving epithelium,
a, endothelium, b, and below, those of connective-tissue cells; c; 24 hours old.
Culture in plasma. Movement (from left to right) of the ameboid border of the
epithelium, a, on the endothelial surface b, is demonstrated. That the moving
epithelial membrane consists at least of two layers of cells is readily confirmed by
the types of granulation. Note the crescent-shaped arrangement of granules in
the basal cells. On the right, 6, those of the endothelium are represented; the
contours of the cells are not visible. Connective-tissue cells (c), the contours of
which are visible, show granules in their fine processes, too. As a rule, the
hyaline processes of the epithelium do not show any granules (see also figs. 3 and
4). The tissue was intensely stained (four days in the dye 1: 200,000). X 250.

3 Experiment 226. A. 2, showing phagocytic phenomenon of the corneal epi-
thelium, which are previously stained with neutral red; 24 hours old. Resemblance
of arrangement of melanin granules to that of neutral red isnoticeable. a, Drawn
from a part of epithelium, moving on the endothelial surface of cornea; 5, epithe-
lial cells of actively moving border. X 450.

4 Experiment 236.12. Phagocytosis of the epithelium to melanin and car-
min; 18 hours old. Culture in autoplasma, in which fine powdered carmin and
fresh melnin of iris were added. Drawn from a part of moving epithelial rim.
< 450.

+6

———————K<e— OO

VITAL STAINING OF CORNEAL EPITHELIUM PLATE 1
SHINICHI MATSUMOTO

47

AUTHOR’S ABSTRACT OF THIS PAPER ISSUED BY
THE BIBLIOGRAPHIC SERVICE, SEPTEMBER 16

OBSERVATIONS ON THE RELATION BETWEEN SUCK-
LING AND THE RATE OF EMBRYONIC
DEVELOPMENT IN MICE

WILLIAM B. KIRKHAM

Osborn Zoological Laboratory, Yale University
INTRODUCTION

The present paper embodies the results of two separate but
simultaneously conducted experiments, both designed to eluci-
date further the problems presented by the lengthened gesta-
tion period in mice which are pregnant and at the same time suck-
ling a previous litter. Daniel (’10), working with such animals,
obtained results which showed an almost constant relation of one
day added to the gestation period for each animal suckled; the
present writer (716), however, in a somewhat similar series of
experiments, obtained results which showed no correlation be-
tween the length of the gestation period and either the number
of young suckled or the number of embryos carried (cf. also table
3).. This work did, however, reveal the fact that when more
than two young are being suckled the implantation of embryos
instead of occurring on the fifth day after fertilization usually is
delayed until the fourteenth day, during which period the blas-
tulae lie free in the lumen of the uterus. The. cause of this de-
layed implantation was tentatively stated in that paper to be due
to an inhibition of some sort exerted by the fully activated mam-
mary glands upon the uterine mucosa. The testing out of this
hypothesis was the purpose of the following experiment.

INTERRUPTED SUCKLING AND THE RATE OF EMBRYONIC
DEVELOPMENT
The program for this experiment was to take healthy female
mice which had just given birth to litters, pair them for twenty-
four hours with healthy males, and then remove all but one of the

49

THE JOURNAL OF EXPERIMENTAL ZOOLOGY, VOL. 27, No. |

50 WILLIAM B. KIRKHAM

suckling young at intervals varying, with different females, from
one to thirteen days. One young animal was left in each case to
avoid too violent a reaction upon the lactating organs, and the
presence of a solitary suckling animal has been found to have no
influence upon the length of the gestation period. The females
were all killed on the thirteenth day after the birth of the suck-
ling young, and any embryos then present were sectioned and
their age determined by reference to a check series of known age
from non-suckling females (Kirkham, ’16). The results of this
experiment are set forth in table 1 and should be studied in two
groups. The first group, cases when the full litter was suckled
one to six days, embraces a period before the next set of embryos
were ready to implant, while the second group, the remainder of
the table, covers an interval when the blastulae were being in-

TABLE 1

Data of all mice used in an experiment to determine the effect on developing embryos
of removing all but one of the suckling young. Unless otherwise stated. the full
number of young born were suckled until removed for the purpose of the experiment.
Stage of development of embryos is in terms of actual age of similar embryos from
non-suckling females where thirteenth day post-partum equals twelfth day of
embryonic development. All the females were killed on the thirteenth day after the
birth of the suckled young

= STAGE
jormat, | mars. | weamemn on | sconoen or | ucmerone |! ama
days a
J 22 1 6 6 uf
J 21 2 7 6 11
J 26 3 6 1 12 1 young died
Ji2V 3 6 8 of
J 24 4 7 3 8
J: 20 4 6 6 10
J 18 5) 10 ii 11
JEL 6 i 11 8
J 28 6 5 5 10
J 29 6 + 6 10
J16 4 7 8 12 6 1 young died
J 42 8 12 10 i
Jess 9 5 6 6
J 10 10 7 9 6
Jeni i! 7 4+ a 1 horn uterus lost
T 14 13 5 9 4

SUCKLING—EMBRYONIC DEVELOPMENT IN MICE Dt

hibited from implanting. The importance of this grouping is
apparent when one considers that in the first group of cases in
every instance an interval of from a few hours to several days
intervened between the end of suckling by the full litter and any
readiness of the embryos to implant. Embryos in the second
group, on the contrary, were presumably all prepared, before the
removal of the suckling young, to implant themselves, and did
so as soon as the inhibition acting upon the uterine mucosa fell
below a certain minimum.

Analysis of the data, with these facts in mind, reveals the
interesting fact that while some sets of embryos (J 18, 21, and
26) are as fully developed as control series when no young were
being simultaneously suckled, others show a lag in development
of from one to four days. No such diversity of results has been
found by the writer in series of embryos from non-suckling fe-
males, and furthermore, it is evidently not directly correlated with
the number of young suckled (cf. J 26 and J 27), the number
of embryos (cf. J 21 and J 22), or with the combination of these
two numbers (cf. J 18 and J 27). There remains the explanation
that the irregularity is due to an individual variation either in the
strength of an inhibitory influence exerted by the mammary
glands upon the uterus or in the susceptibility of the uterus to
such influence. Evidently some individuals are so constituted
metabolically that the inhibition is rapidly and entirely neutral-
ized, so that if even a short interval elapses between cessation of
full mammary activity and the arrival of the eggs in the uterus,
implantation and further embryonic development proceed as
though no young had been suckled, while in other individuals an
even longer interval still leads to delay in embryonic growth.
The possible existence of such an inhibitory influence of the acti-
vated mammary glands upon the uterine mucosa has previously
been shown by the experiments of Adler (’12), who found that
repeated injection of extracts of mammary gland into pregnant
guinea-pigs and rabbits arrested the development of embryos and
often produced abortion.

Or
ho

WILLIAM B. KIRKHAM

CONSTANT NUMBER SUCKLING AND THE DEVELOPMENT OF
EMBRYOS

The second method of attacking the problem of prolonged
gestation in suckling female mice was to determine whether
or not, if the number of young suckled was constant, the stage of
embryonic development could at any given time after fertiliza-
tion be theoretically determined. Four was chosen as the con-
stant number, since it was neither the smallest size of litter known
to prolong gestation nor, on the other hand, was it such a large
number as to prevent the use of nearly all of the available material.

Females who had just given birth to litters of four or more
young had the male already present removed, together with any
excess number of young. ‘This was done the morning following the
birth of the litter, and at varying intervals thereafter the females
were killed, the eggs or embryos obtained from these females were
sectioned, and their stage of development determined, the as-
sembled data being shown in table 2.

The first notable feature in table 2 is the delay in implantation,
no implanted embryos being found before the twelfth day after
ovulation, a confirmation of work published by the writer in a
previous paper (716). After the twelfth day of gestation there
appears the same lack of correlation, as noted above in con-
nection with table 1, between their stage of development and
the time of ovulation, and since if degeneration is going to
occur it always takes place at the stage of four or five days’
development, this possible factor can be ruled out. In other
words, we have here proof of the fact that the irregularities in
the rate of development of embryos in females which are simul-
taneously pregnant and suckling is due, only in small measure,
if at all, to the number of young suckled, for if the number suckled
and the rate of embryonic development were correlated the
data in table 2 should indicate a regular correlation between
stage of development and age of embryos, and such is not the
case.

The explanation of this failure to correlate the ratio of embry-
onic development in suckling females with either the size of the

SUCKLING—-EMBRYONIC DEVELOPMENT IN MICE 53

TABLE 2

Data of all mice used in an experiment to determine the effect on developing embryos
of the suckling of a fixed number of young. In this experiment all litters within
twelve hours of their birth were reduced to four young. Stage of embryonic de-
velopment in terms of actual age of similar embryos from non-suckling females

SERIAL NUMBER SIZE OF LITTER AGE OF SUCKLED | STAGE EMBRYONIC

YOUNG DEVELOPMENT

days days days

T75 4 3 2 0
baht 4 4 3 0
T70 4 5 4 0
T 24 + 6 4 1
T63 8 9 4 4
T 67 8 10 4 5
T 43 + 11 4 6
T 42 4 12 7 aes fi
T 66 5 13 4 8
T 62 8 14 4 9
T15 4 15 10 4
T 54 5 16 7 8
5 ANS 6 17 9 7
T60 5 18 5 12
T 56 + 19 6 12
T68 8 20 14 5
Tid 4 21 18 2
T6l 5 22 9 12
57 6 23 13 8)
T59 8 24 11 12
be Al 7 26 17 8
tage, 9 26 19 6

litter or with any other factor is to be sought in the first part of
this paper, where the irregular influence of the termination of
suckling by a full litter is conclusively shown. Add to this the
fact that under normal circumstances the suckling young begin
to eat solid food at about the time implantation occurs in females
which are simultaneously pregnant, and the evidence here
presented all indicates that after full suckling ceases, whether by
removal of the litter or weaning matters not, the inhibition to
implantation is withdrawn or overcome at a widely different rate
in different females. Therefore, even when the number suckled
is the same, the sets of embryos show no constant rate of develop-

54 WILLIAM B. KIRKHAM

TABLE 3
Data regarding the length of the gestation period in mice simultaneously pregnant
and suckling young. The gestation period in non-suckling females averages
twenty days

NUMBER SUCKLED spencer DELAY REMARKS

days days
1 20 0 A male was present with
1 20 0 each female when the
2 19 0 young were born, and
2, 20 0 in each case the male
3 20 0 was removed 24 hours
3 29 9 later
3 30 10
4 31 11
4 30 10

ment, nor, as a consequence, is the period of gestation a matter
that can be figured out in advance, except with broad limitations
(table 3).

SUMMARY

1. In mice simultaneously suckling and pregnant the removal
of all but one of the suckling young at any time during the first
six days after the birth of the suckling litter leads in some in-
stances to implantation of the embryos as soon as they reach
the uterus; in other instances the implantation is more or less
delayed. These varying results can be correlated neither with
the time of removal nor with the number of young taken away.

2. In mice simultaneously suckling and pregnant the removal
of all but one of the suckling young at any time from seven to
fourteen days after the birth of the suckling litter regularly re-
sults in implantation being delayed, but the exact extent of this
delay can be correlated neither with the exact time of removal
nor with the number of young removed, although removal during
the earlier part of the period in question does hasten implanta-
tion as compared with the time required if the young had con-
tinued to suckle.

3. The facts in the above paragraphs justify the statement
that full activity of the mammary glands is the chief cause of

1

. SUCKLING—EMBRYONIC .DEVELOPMENT IN MICE 5
delayed implantation in the case of mice which are suckling young,
and also that this influence of the mammary glands is subject
to marked individual variation.

4. The suckling by pregnant female mice of the same number
(four in this experiment) of young will not necessarily lead to
either synchronous development of embryos or the same length
of gestation periods. ‘The only explanation that can be offered
at the present time for this lack of uniformity is the individual
variation, noted in the preceding paragraph, of the inhibition
from the mammary glands or in the strength of the counteracting
forees, probably due to metabolic idiosyncrasies.

LITERATURE CITED

Apter, L. 1912 Versuche mit ‘Mammimum Poehl’ betreffend die Function
der Brustdriise als innerlich sezernierende Organ. Miinchner Med.
Wochenschrift, 59.

DaniEL, J. F. 1910 Observations on the period of gestation in white mice.
Jour. Exp. Zool., vol. 9, no. 4.

Kirxuam, W. B. 1916 The prolonged gestation period in nursing mice. (Ab-
stract.) Anat. Rec., vol. 10, no. 3.

1916 The prolonged gestation period in suckling mice. Anat. Rec.,
vol. 11, no. 2.

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AUTHOR'S ABSTRACT OF THIS PAPER ISSUED
BY THE BIBLIOGRAPHIC SERVICE, OCTOBER 5

ANABIOSIS OF THE EARTHWORM

PETER SCHMIDT
Agricultural College in Petrograd

The remarkable biological phenomenon, now known under the
name of ‘anabiosis,’ given it by Preyer (’91), was already observed
in 1701 by the first Dutch microscopist, Anton Leeuwenhoek.
Studying microscopical animals, he found that some of them,
namely, the representatives of the present groups of Tardigrada
and Rotatoria, living in the moss of the roofs and in the sand of
the roof-gutters, can be completely dried up and retain for a
long time their vitality in such desiccated state. If after some
weeks or months of preservation one places in water the dried
bodies of these animals, they quickly become swollen and in a
_ short time the animals revive.

The same observation was made afterwards by Needham (1745)
and Baker (1764) on some Nematodes belonging to Anguillu-
lidae; Baker revived these microscopical worms after twenty-
seven years of preservation in the desiccated state.

The famous Italian biologist of the eighteenth century, Abbott
Spallanzani (1777), repeated all the experiments on the Tardi-
grada and Rotatoria of the previous authors; he came to the
same conclusions and cleared up many interesting details of the
phenomenon.

For a long time these experiments on resuscitation of micro-
scopic animals had interested the scientific world rather more as
a curiosity. But in the second half of the last century the at-
tention of the biologist was called to the fact of the resuscitation
in connection with the question of the origin of life and spon-
taneous generation.

The property of resuscitation of Rotatoria and Tardigrada
was once more carefully studied by Doyére (’42) and the resusci-
tation of Anguillulidae by Davaine (56). Afterwards this

57

58 PETER SCHMIDT

question was studied in a more detailed way by Gavarret (759).
In 1860 the ‘Société de Biologie’ in Paris was in such a degree
interested in clearing up this question that it elected a special
commission, with Broca as president and Balbiani, Brown-
Sequard, Darest, Guilliemint, and Robin as members, for con-
trolling the experiments on revivification of Rotatoria and
Tardigrada. This: commission (Broca, ’60) not only confirmed
the fact of the reviving of these microscopic animals, but also
stated their excessive endurance to high temperature. In the
dried state they endure a temperature of 100°C. and can remain
for very long time in a vacuum without loss of vitality.
However, this question has not been reviewed and reéxplored
in full measure by modern methods. Some zoologists who have
studied the resuscitation of one or another respresentative of
Rotatoria and Tardigrada for instance, Fromantel (’77), Plate
(86), Zacharias (’86) came to negative results, but the others,
such as Schulz (’15), have not only confirmed the results of
previous authors, but have also given new proofs of the re-
sistance of exsiccated animals to the absence of oxygen. Ac-
cording to experiments of Schulz, the Tardigrada, Rotatoria,
and Nematodes can remain exsiccated during one year in an
atmosphere of pure hydrogen and not lose their vitality.
Summarizing all that is known upon this subject, one may say
that most experimenters have succeeded in the revivification of
exsiccated Tardigrada, Rotatoria, and Nematodes, which, living
in moss and sand, are adapted to such loss of water.. The body
of these microscopic animals wrinkles up completely by the
exsiccation and loses its form, but if placed afterwards in water it
swells and regains its natural size and contour. It can be re-
garded as proved, also, that such exsiccated animalcules endure
easily and without injury high temperatures (100°C. and more;
in experiments of Doyére, 140°C.), as well as absence of oxygen.
But many points of this remarkable phenomenon remain
unelucidated and require further investigation. Firstly, it
would be necessary to ascertain how far the exsiccation can go
without loss of vitality. It is, a priori, improbable that the
animalcules can lose all the water contained in their living tissues,

ANABIOSIS OF THE EARTHWORM 59

and it may be that the uncertainty of the results stated by some
experimenters depends mostly upon the fact that not all animal-
cules lose the same quantity of water by the exsiccation. But
it is altogether impossible to determine the percentage of water
lost by the exsiccation of anabiotic Tardigrada, Rotatoria, and
~ Nematodes in consequence of the microscopic dimensions of the
creatures.

A casual observation has directed my attention to another
object more appropriate for experiments of this kind and show-
ing features completely analogous to the anabiotic Tardigrada,
Rotatoria, and Nematodes—that is the earthworm. The
Lumbricidae are animals also adapted by the nature of their
habitat to exsiccation; they live in the uppermost layers of the
soil, which are often more or less dry, and the worms must lose
water. Evidently they do not lose it in such degree as the moss
inhabitants, but, on the other hand, they have a higher organiza-
tion, and the loss of the same percentage of water must be for
them of more serious consequence. The comparatively large
size of earthworms permits a more detailed study of the process
of exsiceation and also the determination, with full precision, of
the degree of loss of water.

In the first study concerning the earthworms, made by me
in collaboration with my pupil, Miss T. V. Stechepkina (Schmidt
and Stchepkina, ’16), in the Zoological Laboratory of the Agri-
cultural College in Petrograd, we have tried to determine the
influence of lower temperatures on earthworms, and we have
shown by experiments that the loss of water has no influence on
the endurance of earthworms as to low temperature. The
normal worms, as well as the partly exsiccated ones, die between
—1.6° and —2°C. But in studying this question, we discovered
that the earthworms show a very great tolerance of loss of water
contained in their bodies.

I give here a table of results obtained in 1916 in these experi-
ments (table 1). :

60 ; PETER SCHMIDT

TABLE 1
ATHER ee THE ee eaaeat Loss TIME OF EXSICCATION
grams grams per cent
1 1.2720 0.2430 19.1 6 hours 45 minutes
x 0.8815 0.2995 33.4 6 hours 45 minutes
3 0.9055 0. 2670 28.3 6 hours 45 minutes
4 0.9255 0.2650 28.5 6 hours 45 minutes
5 1.1520 0.3255 28.1 6 hours 45 minutes
6 1.2589 0.2583 PAs all 6 hours 45 minutes

The exsiccated earthworms, having lost even 33.4 per cent of
the weight, are wrinkled and completely motionless, but placed
on moistened filter-paper they quickly revive and regain their
normal size. This observation excited my interest, but absence
of material in wintertime prevented the continuation of the
experiments.

In the summer of 1917 I spent one month in the Experimental
Agricultural Station Nikolaievskaya, belonging to the Petrograd
Agricultural College. The chemical laboratory of the station is
provided with all that was necessary for my study, and I profited
by this occasion to continue my experiments.

The question that I proposed to solve was to find out the most
convenient methods of exsiccation and of revivification of the
worms and to determine the percentage of the loss of water which
still leaves the possibility to revive.

The earthworms, belonging to the species Allolobophora
foetida, were dug out in the garden and then kept on moistened
filter-paper in a glass dish for two or three days, so that their
gut was cleaned from the earth it contained, which otherwise
would have disturbed the experiments. Before weighing, the
worm was always dried with the filter-paper and then placed in a
small glass dish, previously weighed on a chemical balance, and
tied up with a bit of muslin. After weighing, the glass dish with
the worm was placed in a desiccator with calcium chloride. Twice
or three*times a day all the glass dishes were weighed and the
percentage of loss calculated. The exsiccation was occasionally
delayed by the withdrawal of the glass dish from the desiccator.
If I considered the exsiceation to be sufficient, I took out the earth-

ANABIOSIS OF THE EARTHWORM 61

worm and placed it directly on moistened filter-paper for the
revivification or preserved it temporarily in a corked test-tube.

Before proceeding to the experiments on exsiccation I made a
series of weighings in order to determine the percentage of water
in the earthworms. The glass tubes with the worms were
weighed and placed in a steam-bath where they were dried at
100°C. until the weight became constant. Then the worms
were dried during a certain time in the desiccator over caleium
chloride and weighed once more.

The results of thirteen determinations is given in table 2.

TABLE 2
NUMBER © WEIGHT ee aes LIVING ie gp Nee a WATER
grams grams per cent
1 0.7122 0.1225 82.8
D, 0.8017 0.1340 83.6
3 0.9301 0.1434 84.5
4 0.8101 * 0.1500 81.5
5 0.8983 0.1379 84.6
6 0.5782 0.0845 85.3
7 0.5105 0.0901 82.3
8 0.6432 0.1395 78.3
9 0.657! 0.1115 83.0
10 0.5165 0.0647 87.4
11 0.5842 0.0739 87.3
12 0.5798 0.0669 88.4
13 0.7328 0.1099 85.0
Paeatine.. -eee Ae ee ew, 84.1

The results of these weighings are very near to those of similar
weighings undertaken by Miss Stchepkina and myself in 1916,
when we found the earthworms to contain on the average 82.7
per cent of water.

EXPERIMENTS, SERIES I

The first series of my experiments consisted in the exsiccation
of earthworms and their immediate revivification.
The results of the exsiccation are given in the following table 3.

62 PETER SCHMIDT

TABLE 3
WEIGHT OF J wmdur oF ||) =Oae
ee et emer weraaie | TEEVING | ”ercuva | uxsiocanron| THE EXSIC, | pun can OF
|
grams hours grams
1 | 25 VIL 17h! 1.0133 | 29 VII 20h 99 0.4081 47.5
2 | 25 VII 17h! 0.9194 | 27 VIL 11h 42 0.3114 66.8
3} ANA aye 0.8605 27 Villeisih 42 0.2134 15.2
4 | 25 VIL17h 1522225 | 27a eon 42 0.5304 56.2

1For brevity I use the astronomical mode of designation of time.

Earthworm no. 1 was exposed to a very gradual drying, it
being confined in a narrow glass cylinder. Towards the end of
the exsiccation (29 VII 20h) the worm had lost 47.5 per cent of
its weight, was strongly contracted, became dark brown, had
completely lost its mobility, but retained the elasticity of the
body. After drying it was kept for thirty-nine hours (until
31 VII 11h) in a small hermetically corked glass tube and then
placed on moistened filter-paper. It showed no signs of mobility,
but its body was elastic and not frangible. After one hour I
already observed some movements of the body. In the evening
31 VII it had completely revived. After reviving its weight was
0.9026 gram, i.e. 0.1117 gram lower than before the exsiccation.

Earthworms nos. 2 and 3 were dried more quickly and lost 66.8
and 75.2 per cent of the weight of the body. After exsiccation
they assumed a dark brown color and were covered with a dry,
crust-like skin. Four hours after the end of the exsiccation
(27 VII 14h 50’) they were placed on moistened filter-paper, but
did not revive and showed no signs of life.

Earthworm no. 4 lost 56.2 per cent of the weight of the body.
Its upper end was overdried and covered with crust-like skin.
Placed 27 VII 14h 50’ on moistened filter-paper, it showed at |
15h 50’ some weak contractions and movement on the caudal
end of the body, but the proximal end was much swollen. The
next day this individual died. .

This first series of experiments showed that the worms can
revive after the loss of nearly half the weight of their body; that 2s, a
loss of more than 50 per cent of the water contained in the body.

ANABIOSIS OF THE EARTHWORM 63

EXPERIMENTS, SERIES II

The second series was not so successful as the first, perhaps
because I used earthworms of a smaller size: they dried too
quickly and lost their elasticity. The conditions of these experi-
ments were the same as in the first series; the only difference was
that the worms were not exposed to exsiccation in flat glass dishes,
but in small cylindrical test-tubes. This seemed to be less
advantageous.

The results of the exsiccation were as follows (table 4):

TABLE 4
LOSS OF
WEIGHT OF WEIG y. c Dy
SUMBER | pore yaicaira | TEES | ee eevcanon| THE BXSIC~ | PER CENT OF
WORM
grams hours grams
il 29 VII 14h 0.3486 | 31 VII 20h 54 0.1113 69.1
2 29 VII 14h 0. 2806 31 VII 1th 45 0.1419 9.5
3 29 VII 14h 0. 2425 31 VII 11h 45 0.1074 55.8
4d 29 VII 14h 0.2216 31 VIL 11h 45 0.0983 56.6

Worm no. | was completely overdried, and when placed on
moistened filter-paper showed no signs of life. Worms nos. 2
and 3 also did not revive. Worm no. 4, placed on moistened
filter-paper 31 VII 11h, displayed after 1 hour some weak move-
ments in the caudal end of the body, but its proximal end was
dead. I tried to save the caudal end by cutting it off from the
proximal half of the body, but notwithstanding it died next day.

EXPERIMENTS, SERIES III

This series was undertaken with the purpose of finding out
whether it were possible to preserve the exsiccated worms and
how long at normal temperature. To this end I placed them,
after drying in sterilized test-tubes corked with cotton, with a
cork and covered with melted paraffin.

The results of the exsiccation are given below (table 5):

64 PETER SCHMIDT

TABLE 5
WEIGHT OF + WEIGHT OF LOSS OF
NUMBER | pron WEIGHING | Seng | gprs |= Ppa ot bak Ghwer oF
7: | WEIGHT
ees Fs) pa eee> 8 SS
grams hours grams
1 2 VIII 12h 1.2478 | 4 VIII 1th 47 0.6783 45.6
2 2 VIII 12h 1.0244 | 4 VIII 11h 47 0.5289 48.3
3 2 VIII 12h 0.8028 | 3 VIII 19h 31 0.3946 50.8
4 2 VIII 12h 0.9067 | 3 VIII 19h 31 0.5007 44.8
5 2 VIII 12h .| 0.6986 | 3 VIII 19h 31 0.3552 49.1
6 2 VIII 12h | 0.9241 | 4 VIII18h30’ 542 0.4946 46.4

After preservation in test-tubes for twenty-four hours, worms
nos. 1 and 3 were placed 5 VIII 11h on moistened filter-paper.
Both had died and did not revive. On the four other worms I
detected in the morning 6 VIII many white spots—colonies of
bacteria. The earthworms placed on filter-paper had all died
undoubtedly by infection with bacteria.

This series shows that it 7s impossible to preserve for a long time
the exsiccated earthworms at normal temperature, as it is certainly
impossible to sterilize them—their gut and body being full of
microorganisms.

EXPERIMENTS, SERIES IV

The purpose of the fourth series was to establish more precisely
the limit to which the earthworm can be exsiccated without loss
of vitality. The experiments were arranged in the same manner
asin series [and II. The worms were dried in glass dishes cov-
ered with muslin.

The results are given in table 6.

TABLE 6
WEIGHT OF LOSS OF
wownan| zurhonme,, EGNNGG| agora (tuum | "Hara, | ame,
5 WORM WEIGHT
grams hours grams by

1 7 VIII 13h 1.5272 | 9 VIII 19h 36’ 2 0.5775 61.6
2 7 VIII 13h 0.5798 | 8 VIII 13h 24 0.1539 73.4
3 7 VIII 13h 0.7328 | 8 VIII 16h 27 0. 2825 61.4
4 | 7 VIII 13h 0.5165 | 8 VIII 13h 24 0.1965 61.9
5 | 7 VIII 13h 0.5842 | 8 VIII 16h 27 0.1725 70.4
6 7 VIIT 13h 0.5782 | 8 VIII 13h 24 0.2334 59.6

ANABIOSIS OF THE EARTHWORM ee

After the exsiccation was finished the worms were placed at
once on moistened filter-paper. The revivification went on in
different ways.

Worm no. 1 was dried slowly and with an interruption (from
8 VIII 20h to 9 VIII 11h I kept it outside of the desiccator
placing the glass dish directly under a glass bell) ; it was complete-
ly motionless after the drying, but its body was smooth, elastic,
and without crust-like skin. Placed on moistened filter-paper
on 9 VIII 19h 40’, it had revived completely by the next morning,
had a normal appearance, and displayed very energetic move-
ments. Its weight was 1.3067 grams—nearly the same as before
the exsiccation. Placed on earth, it dug itself in at once. On
11 VIII 11h it was placed once more on filter-paper, and after
some hours I noticed that several of its posterior segments
(15 to 20) were twisting themselves away from the body and were
lost; certainly, they had suffered from the drying. Nevertheless,
the worm was alive, and 12 VIII I used it for the second time for
the experiments of exsiccation (cf. series VII).

Nos. 2 and 5 were overdried, and placed on moistened filter-
paper became only swollen. No. 5 showed some signs of life in
the caudal end of the body, but died also.

Worm no. 3 retained the cylindrical form of its body and was
smooth. Its body was elastic, dark brown, and covered with a
hard skin. Placed on moistened filter-paper 8 VIII 16h it became
after 40’ swollen, and exhibited slow contractions when touched
with the forceps. At 18h 30’ its body displayed spontaneous
contractions, but at 19h 305 I noticed that the middle part of the
body had become necrotic—the blood was flowing and staining
the filter-paper red. Next morning (9 VIII 11h) the upper
part of the body moved energetically, but the caudal end died
and showed blood effusion.

Worm no. 4 after drying was in its proximal part dark, and was
covered with a crust-like skin; its caudal end was not so dark and
more elastic. Placed on moistened filter-paper on 8 VIII 14h
it exhibited at 15h 30’ some slow contractions in the caudal end.
At 16h the contractions were noted also in the proximal end.
At 18h 30’ the caudal end contracted energetically, the proximal

THE JOURNAL OF EXPERIMENTAL ZOOLOGY, VOL. 27, No. |

66 PETER SCHMIDT

one slowly. Next morning (9 VIII 11h) the proximal end was
dead, the caudal end showed signs of life and contractions. At
13h the worm died completely. This case demonstrates very
clearly, that its death was caused by the overdrying of the proxi-
mal end of the body, which became necrotic and, infected by
microérganisms, infected also the revived caudal end.

Worm no. 6 had left the glass dish during the exsiccation and
was overdried in some parts of the body. Being revived it dis-
played some movements, but swellings had formed here and there
on its body. Its head revived and moved energetically, but in a
short time the worm had succumbed.

The experiments of this series have shown, that earthworms
can revive after the loss of even 61.6 per cent of the weight of the
body; 7.e. of 73 per cent of the full quantity of water in the organism!
But the revivification takes place only under favorable conditions
of exsiccation, probably when it proceeds equally and gradually.
When the exsiccation was too rapid, some parts of the body were
overdried and the skin became crust-like. In this case evidently
the blood-vessels of the skin burst during the swelling and the
blood flowed out. This blood effusion caused, as it seems, an
infection with microédrganisms and the overdried part of the body
perished, causing the death of the worm. This explains the
death of worms nos. 3 and 4, when some parts of the body were
revived and showed energetic movements.

If the loss is more than 70 per cent of the weight of the body—
i.e., more than 83 per cent of the whole quantity of water—the
worm does not revive, but sometimes, nevertheless, it showed
weak movements, as, for instance, no. 5. If the exsiccation
was not equal and uniform in the whole body, the death of the
worm was possible even at the loss of less than 60 per cent of the
weight of the body (for instance, no, 6).

EXPERIMENTS, SERIES V

The fifth series was a continuation of the third series. As the
worms kept in the test-tubes died evidently through infection
with microérganisms, I determined to try whether the dried
worms could not be preserved at a low temperature. To this

ANABIOSIS OF THE EARTHWORM 67

end the worms were placed after the exsiccation in test-tubes
upon the ice of an ice-house, where the temperature was about
+1°C.

The results of the drying are given in table 7.

TABLE 7
WEIGHT OF Fre papvclcere || MEPS CO) EE? leith
weno | ,2u0hargan [rmsume] ayagemees |S | Tatas, |. mara
grams hours grams

1 10 VIII 17h 0.5066 | 11 VIII 14h 21 0.1967 61.1
2 10 VIII 17h 0.7472 | 11 VIII 18h 30’ 254 0.3206 57.0
3 10 VIII 17h 0.5003 | 11 VIII 17h 24 0.1677 66.4
4 10 VIII 17h 0.5605 | 11 VIII 14h 21 0.2150 61.6
5 10 VIII 17h 0.5084 | 11 VIII 14h 21 0.2167 BY( RS;
6 10 VIII 17h 0.6656 | 12 VIII 20h 51 0.2527 62.0

Worms nos. 1, 4 and 5 were placed after drying in test-tubes
and carried to the ice-house. Worms nos. 3 and 6 were placed
immediately on moistened filter-paper. No. 2 was left in the
laboratory at the normal temperature of about 20°C. (in day-
time).

The worms placed upon the ice (nos. 1, 4, and 5) were kept there
for fifty-one hours (till 18 VIII 16h 20’) and seemed then to be
completely normal without signs of infection. Nevertheless, the
revivification was unsuccessful. Placed on moistened filter-paper
13 VIII 16h 30’ they displayed at 17h weak movements in the
proximal end and in the tail.

Worm no. | at 18h 45’ exhibited energetic contractions of the
proximal end, but its tail moved weakly and the middle part of
its body was motionless. Worm no. 4 was dead. No. 5 dis-
played energetic contractions in the tail and in the head, but the
middle part of the body with clitellum had died.

Next day (14 VIII 10h 30’) the proximal end of worm no. 1
and its tail contracted very energetically, but the middle part of
the body died. Clitellum showed blood effusion and the filter-
paper beneath was red. The proximal end and the middle part
of the body of worm no. 5 died, but its tail contracted. In the
evening 14 VIII both worms were definitely dead.

68 PETER SCHMIDT:

The ill success of these experiments was caused, I believe,
by the fact that I had occasionally used earthworms with clitel-
lums. The skin of the clitellum is very delicate and full of blood-
vessels, which suffer from the exsiccation and cause the blood
effusion and infection.

The revivification of the control worms nos. 2, 3, wad 6 also
yielded nearly negative results. Worm no. 2, preserved in a
test-tube at normal temperature during twenty-four hours, was
placed on 12 VIII 18h 50’ on moistened filter-paper. It seemed
to be in a good state of preservation and showed no signs of
infection. But as it was swollen, only some weak contractions
of the caudal end were seen, and at the proximal end white
swellings appeared, as a sign of infection. On the morning
13 VIII the worm was dead.

The worm no. 3 was exsicecated too quickly and overdried. It
showed no signs of life and at the proximal end a blood effusion
was observed.

Worm no. 6 proved to be overdried at the proximal end, evi-
dently also because there was a clitellum. The caudal two-
thirds of the body was revived and moved energetically, but the
proximal third perished. After twenty-four hours the whole
worm was dead.

This fifth series of experiments has nevertheless shown, that the
worms which have lost not more than 61 per cent of the weight of their
body, if preserved at low temperature, retain their vitality during
forty-eight hours. Their revivification was only partly obtained,
but this depended upon secondary causes, which could be
avoided. Unfortunately, lack of time prevented me from re-
peating this series of experiments with all necessary precautions,
needed after the foregoing ill success. Earthworms without cli-
tellum should be taken and exsiccated more slowly and gradually.

EXPERIMENTS, SERIES VI

The sixth series was undertaken with the view of studying the
influence of exsiccation effected at low temperature. The worms
were put into small glass-tubes and placed into a desiccator that
stood on the ice in the ice-house. The small size of the glass
tubes caused a very slow exsiccation of the worms.

ANABIOSIS OF THE EARTHWORM 69

The results of the exsiccation were as follows (table 8).

TABLE 8
‘ WEIGHT OF! Loss OF
‘ DATE OF THE ee a DATE OF FINAL BOUss oF THE EX- | WATER IN
NUMBER | -IRST WEIGHING pia WEIGHING eg | gee cic gree ——
grams hours | grams
1 13 VIII 13h 0.6351 | 16 VIII 15h 30’ 754 0.2965 53d
2 13 VIII 15h 0.4306 | 17 VIII 18h 99 0.1740 99.5
3 13 VIII 15h 0.4180 | 17 VIII 18h 99 Onigi7e 59-0
4 1S VEL Tsh 0.3294 | 14 VIII 19h 30 0.1196 63.6

Worm no. 1, placed 16 VIII 15h 30’ on moist filter-paper,
showed at 16h 40’ energetic contractions of the body, and in the
evening (19h) had completely revived.

Worms nos. 2 and 3 placed 17 VIII 18h 15’ on moist filter-
paper showed at 18h 35’ the first contractions of the proximal
part of the body. At 18 VIII 10h both worms were completely
revived and moved with great energy.

Worm no. 4 placed on moist filter-paper at 14 VIII 19h 30’
showed contractions at 22h, but died next morning (15 VIII
1th).

This sixth series shows, that the combination of exsiccation
and low temperature gives the most satisfactory results. Owing to
the slowness of the exsiccation and the retardation of the activity
of microorganisms the treatment affects the vitality of the worms
in a very small degree and the loss of water is easily endured.

Lack of time has not allowed me to repeat this series of experi-
ments and to try the preservation of earthworms exsiccated in
this manner at a low temperature. It is possible that the results
might be more successful than in the foregoing series.

EXPERIMENTS, SERIES VII

In this last series I intended to try the exsiccation of worms
that had already undergone this operation and had been revived.
But I could use for this purpose only worm no. 1 of series IV.

This earthworm was weighed on 12 VIII 19h and its weight
was 1.2610 gr.—the diminution of its weight as compared with

, lds

70 PETER SCHMIDT

its weight on 7 VIII 13h (cf. IV series) was caused by the loss of
its posterior segments after the first exsiccation (p. 10). Placed
in the desiccator on 12 VIII 19h, it was kept there until 14 VIII
19h (i.e., forty-eight hours) and its weight diminished on 0.4679
grams or 62.6 per cent of the weight of its body. At 19h 30’ it
was placed on moistened filter-paper and at 22h some contrac-
tions and movements of the proximal end and of the tail were
observed. But on the next morning (15 VIII 11h) it was found
dead. On the proximal end hemorrhage and swellings could be
seen. It is possible that the exsiccation had surpassed the limit
or had gone on too rapidly.

This experiment is of course not sufficient for denying the
possibility of repeated revivification of earthworms.

CONCLUSION

All the mentioned experiments, which for lack of time I had
no possibility of finishing, prove, as I believe, that the phenom-
ena manifested in the exsiccation of earthworms are completely
analogous to the results of exsiccation of Tardigrada, Rotatoria,
and Nematodes, and with full right may be called ‘anabiosis’
(‘over-life’).

Actually by the exsiccation the earthworms lose completely
their mobility, their size diminishes to one-half or one-third of
their length and volume and they show no manifestations of
life. In the dorsal vessel, sometimes well seen through the skin,
no contractions can be detected with a microscope. The seg-
ments of the body are also completely motionless. The exsic-
cated worm is dark brown, but must retain the elasticity of its
body and its skin must be soft if it is to revive. It has the ap-
pearance of a corpse ora mummy. In this state the worm can
retain the capacity for revivification for thirty-nine hours at
normal summer temperature (ef. worm no. 1 of the experiments
in series 1) and according to series V and VI, for 48 hours, and
perhaps more, at low temperature. It is possible, that at suit-
able low temperatures one can preserve the vitality of the exsic-
cated worms during a very long time. I shall undertake experi-
ments in this direction at the first opportunity.

4
ANABIOSIS OF THE EARTHWORM 71

Thus, only one difference can be stated in the earthworms as
compared with the other groups of anabiotic animals—it is that
they are not so amenable to continued preservation in the exsic-
cated state at normal temperature. This is evidently accounted
for by the more complicated organization of worms and the
presence of a more highly organized blood system, as well of a
large quantity of microorganisms in the gut. The exsiccation
of the skin carried on too far destroys its capillary vessels and
causes the blood effusion. The microorganisms of the gut and
of the surface of the body, multiplying under favorable con-
ditions, bring about the death of the worm.

While showing a full analogy to the anabiosis of Rotatoria,
Tardigrada, and Nematodes, the phenomenon of exsiccation of
the worms has the practical advantage of affording the possi-
bility of determining the amount of the loss of water contained
in the body of the worm. And in this direction I have discovered
a fact, which seems to be of great interest: a very large percentage
of water can be lost without the complete loss of vitality.

As my experiments (cf. series IV, worm no. 1) have evidenced,
earthworms can revive and regain the normal state of life after a
loss of 61.6 per cent of the weight of the body, or nearly 73 per cent
of the weight of the water contained in the body. -

If we take into consideration that the organization of the
earthworm is comparatively infinitely more complicated and
therefore more delicate than the organization of Rotatoria,
Tardigrada and Nematodes, we can readily admit, that these
microscopical animalcules may have the capacity to revive after
having lost 80 to 85 per cent of the amount of water in their
bodies, or perhaps even more.

This consideration throws some light on the seeming mysteri-
ousness of the phenomenon of anabiosis that was discovered
more than 200 years ago, but till now no known analogy in the
higher groups of the animal kingdom.

Petrograd, February 1. 1918.

72 PETER SCHMIDT

LITERATURE CITED

Baker 1764 Employments for the microscope.

Broca, P. 1860.a Etudes sur les animaux resuscitants. Presse Scientifique,
T. 1, pp- 211-222.
1860 b Rapport sur la question soumise 4 la Société de Biologie au
sujet de la reviviscence des animaux desséchés. Paris. Mémoires de
la Société de la Biologie, T. 2, pp. 1-140.

DavaINneE, C. 1856 Recherches expérimentales sur la vitalité des Anguillulides
du blé niéllé. Paris. Comp. Rend. Ac. Sce., 43, pp. 148-152; Ann.
Nat. Hist., 18, pp. 268-269.

Dormer 1842 Mémoire sur les Tardigrades. Annales des Sc. Naturelles, Paris,
II ser. T. 18 (Zool.), pp. 5-35.

FROMANTEL, E. DE 1877 Recherches sur le revivification des Rotiféres, des
Anguillulides et des Tardigrades. Associat. Frang. p. l’ avane. d.
sciences. C.R. dela VI sess. Le Havre, pp. 641-657.

GavaRReET, M. 1859 Quelques expériences sur les Rotiféres, les Tardigrades et
les Anguillulides des mousses des toits. Ann. d. Se. Natur. Paris,
IV ser. T 11 (Zool.), pp. 315-330.

LEEUWENHOEK, A. 1701 Epistolae ad Societatem Regiam Londinensem, vol. 2,
p. 381 ss. Lugd. Bat.

NEEDHAM 1745 New microscopical discoveries. London 8°.

Puate. L. 1885 Beitrige zur Naturgeschichte der Rotatorien. Jenaische Zeit.
f. Nat.,.Bd. 19,'p. 118.

Preyer 1891 Uber die Anabiose. Biolog. Centralbl., Bd. 11, no. 1, 2.

SPALLANZANI 1777 Opuscules. de Physique animale et végétale.. Trad. par
J. Sennebier, T. 2, p. 224 ss.

ScumiptT, P., pt SrcHePKINA, T. 1917 Sur l’anabiose des vers de terre. Comp.
Rend. Soc. Biol., Paris, 1917, pp. 366-368.

Scuuuz, E. 1915 On some investigations upon anabiosis (in russ.). Isvest.
Petrogr. Biol. Labor. (Bulletin du Laborat. Biologique de Petrograd),
vol. 15, pp. 81-86.

ZacHARIaAs, O. 1887 Kénnen die Rotatorien und Tardigraden nach vollstandi-
ger Austrocknung wieder aufleben oder nicht? Biolog. Centralbl.,
Bd. 6, pp. 230-235.

AUTHOR’S ABSTRACT OF THIS PAPER ISSUED
BY THE BIBLIOGRAPHIC SERVICE, SEPTEMBER 16

STUDIES OF NORMAL MOULT AND OF ARTIFICALLY
INDUCED REGENERATION OF PELAGE IN
PEROMYSCUS

H. H. COLLINS
Scripps Institution, La Jolla, California

FIFTEEN FIGURES

CONTENTS
DRIES ASV ERE oe PN 2 OE hs) RT SE PUR a 0 5 Baw: Ai avig horas MR ache ors 73
MEME In Vetere IHOUN na. atin ys Sete sae ee soe oe olnt en ae ee oe Se 76
AACE TAT Ul irene Ate a SO Ra AR eed ts Ae RAS to delacoaie tan, Late SRR A, 81
. Regeneration of pelage in juvenal mice................... 00. eee e cece eee 81
POP eHerAn MOE AGULin Delames: mies. o's ofocits ahs Ge ldun > = 6,¢ «5 away kGS ey ~ aie anes 86
— ie PE HIVSECOUIZ 9 assed Rance ERP Ss a a is 88
| SUMARIO A AS AI AY Le ee See en Ue ae 94

IO MOP wWhDe

1. INTRODUCTION

It is a matter of common knowledge among naturalists that
many birds and mammals undergo more or less marked changes
in appearance as the result of moult. These moults may mark
different stages in the life cycle of the individual or they may be
seasonal in character.

In general the greatest changes in appearance are incidental
to the transition from the juvenal to the adult. Especially
among birds, there are many species in which the differences are
quite striking.

To quote Allen (’94a) in regard to Passerine birds:

This ‘first’ or ‘nestling’ plumage can usually be recognized by its
loose, fluffy texture, as compared with that of adult birds of the same
species, even though the coloration may be similar; but generally it
differs notably also in color, and often in pattern of markings, from
that which immediately succeeds it, or from any plumage which may
be afterward acquired. Familiar illustrations are furnished by the
robin and the bluebird, where the first plumage is so strikingly unlike,
both in color and markings, that of the adult bird of either sex (p. 92).

73

74 H. H. COLLINS

In a later paragraph, he says, ‘“‘Although this first plumag is
particularly interesting and instructive, affording frequently
clues to ancestral relationships, it has not until recently attracted
the attention it deserves, even among ‘professional’ ornithologists.”’

Whitman (04) in his work with pigeons, appears to have re-
garded the comparative study of juvenal plumages as highly
important in tracing phylogenetic relationships. On the other
hand, it is said that closely allied subspecies sometimes differ
more at this early stage than at any later period. Apparently
there is still much to be learned concerning the real significance
of first plumages.

Though the general features of the change of pelage have been
described in many of the mammals, the ornithologists seem to
have proceeded somewhat farther in the study of the details of
the process. |

Dwight (00), in a study of the Passerine birds of New York,
writes as follows:

The plan on which a moult proceeds is a perfectly definite one, al-
though often much modified and obscured. Old feathers or rows
of feathers tend to remain until the newcomers adjacent have matured
sufficiently to assume their function, when the old fall out and their
places are taken by the new which develop from the same papillae.

The systematic replacement of areas of feathers shows most obviously
in the wings where not only do the remiges fall out one after another
in definite sequence and almost synchronously from each wing, but the
greater coverts are regularly replaced before the fall of the secondaries
beneath them, the lesser coverts before the median and even in the rows
of the lesser coverts alternation seems to be attempted. . . . On
the body the protective sequence is less obvious, but the moult regularly
begins at fairly definite points in the feather tracts radiating from them
in such manner that the outer rows of feathers where the tracts are
widest and the feathers of their extremities are normally the last to be
replaced (pp. 83, 84).

Furthermore, Dwight found a regular sequence in the de-
velopment of the various feather tracts, although in young birds
an outbreak of moult in any of the tracts earlier or later was
less unusual.

Although, as a rule, the moult proceeds so gradually and so
simultaneously on opposite sides of the body that the power of

MOULT AND REGENERATION OF PELAGE IN MICE 75

flight is not impaired, there are cases in which the process is not
so plainly adaptive.

The Duck family (Anatidae), among others, according to Coues,
drop their wing quills so nearly simultaneously as to be for some
time deprived of the power of flight.

The details of the process of moult are not so well known in
the case of mammals. However, it appears that in general the
process is more irregular than in birds. According to Allen (’94):
“As a rule, particularly among the Rodentia, the change be-
comes first apparent on the feet and about the nose extending
gradually up the limbs and over the head and from the base of
the tail anteriorly, and from the sides of the body toward the
median line.’”’” This appears to be the usual method especially
in the spring moult, but the process is said to be ‘‘subject to
much irregularity, even among individuals of the same species,
and it seems to vary Somewhat in different groups” (p. 107).

In describing the condition in rabbits Nelson (’09) says that
“the moults usually begin about the head and feet and proceed
more or less irregularly over the body, but there is no absolute
rule, and patches of new pelage may appear on any part of the
body, especially if the old coat has been thinned by abrasion or
‘other local cause” (p. 30). However, it appears that certain
other students of the genus do not find the process of moult as
irregular as described by Nelson.

According to Barrett-Hamilton (12), the order of change in
the European hares, though not invariable, generally follows a
fairly regular sequence. In the autumnal moult, the feet and
legs, the gray parts of the ears and parts of the head are first
to undergo the change. Then follows the rump, and the white
area of the ventral surface gradually creeps upward on the sides
until the brown of the summer coat is extinguished or remains
as a “‘small island or islands.’’ In the spring the sequence and
directions of growth are completely reversed, the new pelage
appearing first on the head and median dorsal region, growing
downwards. This same reversal is described by Allen in his
paper on the changes of pelage of the varying hare (Lepus ameri-
canus).

76 H. H. COLLINS

Passing to the Muridae, it may be said that although certain
species of this group have long been reared in captivity and used
extensively in experimental work, very little is known concerning
their changes of pelage. Probably the most complete account is
that of Osgood (’09) in his monograph of the genus Peromyscus.

As stated by Osgood, the mice of this genus pass through three
fairly distinct phases due to age—the juvenal (young in first
coat), the adolescent, and the adult. According to his descrip-
tion of the assumption of the postjuvenal or adolescent pelage,
“This li.e., Juvenal] stage is sueceeded by the adolescent pelage,
which first appears on the middle of the sides. Its growth pro-
ceeds rapidly upward on each side until union is effected in the
middle of the back, and then incloses the rest of the body, the
rump and nape, usually being the last parts to be covered”’ (p. 20).

With reference to seasonal changes, he says:

The new pelage may be acquired in regular and obvious manner
with the fresh coat well distinguished from the old worn one, the growth
proceeding from before backward and the middle of the rump being
the last part to be invested, or the change may be quite insidious and
apparent only upon careful examination. The regular method is fol-
lowed in the adults of most species, while the other is more often evident
in immature individuals (p. 19).

My own observations in this field have been, in the main, con-
fined to a few species of this same genus. During the past year
and a half I have devoted considerable attention to a study of
the seasonal and life-cycle changes in the pelage of several races
of California deer-mice, reared in the murarium of the Scripps
Institution. It is the purpose of the present paper to discuss,
somewhat in detail, the normal process of moult, especially with
reference to the assumption of the postjuvenal pelage, and,
furthermore, to describe certain modifications of this process
experimentally induced.

I take this occasion to express my sincere thanks to Dr. F. B.
Sumner for many valuable suggestions and criticisms.

2. THE POSTJUVENAL MOULT

The description of this moult is based upon an examination at
weekly intervals of a series of twenty specimens of the first cage-
born generation of Peromyscus maniculatus gambeli (Baird).

MOULT AND REGENERATION OF PELAGE IN MICE 77

Frequent examinations, somewhat more at random, were also
made upon the general stock, including the subspecies sonoriensis
(Le Conte) and rubidus Osgood, as well as a few specimens of
P. eremicus fraterculus (Miller) and P. ealifornicus insignis Rhoads.
By etherizing the animals and parting the fur, it was possible to
follow the moult from the time of the first appearance of the new
hairs through the skin.

At birth the body is devoid of hair and pigment except for the
vibrissae and supraorbital cilia. On the second day the upper
parts begin to assume a bluish-black color and the hair may be
seen coming through the skin of the pigmented area. A day or
two later, the ventral white hair may be observed.

At the age of four to five weeks, the young are, as a rule, in full
juvenal pelage. There are no further traces of pigment in the
skin, which is now flesh color. This pelage, like the later ones,
is made up of a fine soft underfur and a thinner coat of much
longer and coarser overhair. As is the case in the adult pelages
of many other rodents, the hairs of the underfur are banded or
ticked (agouti), being of a blackish plumbeous or slate color
basally, with a narrow subterminal zone of pallid mouse gray,
while the tips are black.1. The overhairs are not of the agouti
type, lacking the subterminal band. The general effect on the
dorsal surface may be described as between neutral and deep
neutral gray.

The juvenal pelage of the ventral surface, like that of the dor-
sum, is made up of underfur and overhairs. Basally, the color
is the same as in that of the dorsal surface, but the distal region
is white. The lateral line of demarcation between the dorsal
and ventral surfaces is very sharply defined (fig. 5).

The microscopic structure of the hairs in the juvenal pelage is
essentially the same as described by Sumner (18) for the adult.
There is, however, a very evident difference in the proportionate
number of the different kinds of hairs. The slender hairs with
but a single axial row of pigment bodies, alternating with the air
spaces, are much more numerous, while the yellow pigment is
much reduced in the subterminal bands. The overhairs are

1 Color descriptions are based on Ridgway’s key.

78 H. H. COLLINS

attenuated at the base, being no larger at this level than the hairs
of the underfur. Both kinds of hairs are very much flattened,
but the larger ones show no local attenuations such as are de-
seribed by Barrett-Hamilton (716) for Mus musculus, though
this appearance may be simulated by torsion.

In microscopic structure, the vibrissae are markedly different
from the hairs just mentioned. Though these are the largest
hairs on the body, there is but one axial row of lacunae containing
a relatively small amount of pigment. Most of the pigment
occurs in the cortex as small granules arranged in longitudinal
striae. This cortical pigment extends to the base, but gradually
disappears toward the tip. This is the reverse of the arrange-
ment in the body hairs, in which the greater part of the pigment
is found in the axial region arranged in from two to four rows of
lacunae in all except the smallest hairs. Furthermore, in the
body hairs, the cortical pigment, which is restricted mainly to the
superficial region of the cortex, is most dense in the terminal zone,
gradually disappearing toward the middle region. The lower
vibrissae are devoid of pigment almost or quite to the base, but
this terminal white region becomes much reduced dorsally. The
structure of the two supraorbital cilia and of the hairs of the tail
is similar to that of the vibrissae. In certain pelage removal
experiments to be described later, it will be noted that vibrissae
and body hairs are not regenerated in the same manner. This
fact suggests the possibility of some sort of correlation between
the morphological and physiological differences.

The transition from the juvenal to the postjuvenal pelage
usually begins at the age of six weeks and is completed about
eight weeks later. The new pelage first appears on the throat
near the angle of the jaw, or rarely on the anterior surface of the
forelimb along the lateral line.2 Growth proceeds toward the
median ventral line of the head and, at the same time, anteriorly
under the eye and ear and posteriorly over the forelimb and
shoulder. From these regions, it passes posteriorly above the
ventral white to the hind limbs, at the same time creeping up
toward the dorsal median line (figs. 1 to 3).

2 The line of demarcation between the white hair of the ventral surface and
the dark hair of the dorsum.

MOULT AND REGENERATION OF PELAGE IN MICE 79

Figs. 1 and 2 Diagrams of the dorsal and ventral surfaces, showing directions
of growth in the postjuvenal moult of P. maniculatus gambeli. The regions on
which moult proceeds more or less independently are shown by the dotted lines.
The longer arrows indicate more rapid growth. UL.l., lateral line; p., point of

origin.

Fig. 3 Diagram of lateral surface, showing directions of growth in the post-
juvenal moult of P. maniculatus gambeli. Symbols as in figures 1 and 2.

SO H. H. COLLINS

The moult may be well under way before there are any evi-
dences of it on the surface. The details of the process can be
learned only by parting the overlying juvenal pelage and obsery-
ing the new hair as it comes through the skin. The new post-
juvenal pelage is first seen on the surface, usually on the fore-
limbs, and somewhat later as triangular areas on the sides.
These lateral areas gradually become confluent, first, as a rule,
just posterior to the shoulders (figs. 5 and 6).

After this ‘saddle phase’ (fig. 6) has been reached, further
growth for days or weeks may be limited to the region posterior
to the saddle. The direction of growth is posterior and, at the
same time, upward on the hind limbs from the lateral line, the
region above the base of the tail being the last to undergo the
change (figs. 3, 7, 8).

On the ventral surface, the moult is regularly completed before
that of the dorsum. As shown in figure 2, growth proceeds from
the throat posteriorly. In many cases, there may be no super-
ficial indications of the change, though in some instances a de-
finite moult line? may be observed.

The moult is now completed over the whole body surface,
except the region extending on the dorsal surface from the tip
of the snout to the shoulders. The investment of this area may
occur soon after that of the rump, but usually only after an in-
active period which in extreme cases may be as long as two months.

In this region the postjuvenal pelage first appears, anteriorly,
on the tip of the snout, passing posteriorly to the eyes, thence as
two diverging strips to the anterior insertions of the ears, the
intervening space being filled in by lateral and posterior growth
(fig. 1). Posteriorly, the moult line moves from the shoulders
forward toward the ears, where the two areas coalesce. Growth
in the two directions may occur simultaneously or that of one
region may be slightly in advance of the other.

The postjuvenal pelage is somewhat longer and coarser, though
still shorter than that of the adult, which it closely resembles in
color and texture. The general color effect is quite different
from that of the juvenal. It may be described as varying from

’ The line separating the old and new pelages.

Ea

MOULT AND REGENERATION OF PELAGE IN MICE 81

Saecardo’s umber to sepia, with the dorsal median stripe more or
less strongly marked with black. This difference in the general
color of the two pelages appears to be due mainly to the increased
amount of yellow pigment in the subterminal bands of the post-
juvenal hairs.

The postjuvenal moult of two other races of California deer-
mice (P.m. sonorienses and rubidus) as well as in a ‘yellow’
mutant of gambeli, which appeared about two years ago in the
murarium stock is essentially the same as above described.

In two other species of Peromyscus (ecalifornicus insignis,
and eremicus fraterculus) which occur in the vicinity of La Jolla,
the process is quite similar, but upon a closer examination there
appear to be certain characteristic differences in the points of
origin and directions of growth.

3. LATER MOULTS

In general, in the assumption of the adult pelage and in the
seasonal moults, the process is the same as above described.
However, these later moults appear to be somewhat more irregu-
lar, and frequent partial moults further complicate the situation.
These moults will be treated more at length in a later paper.

4. REGENERATION OF PELAGE IN JUVENAL MICE

After having observed the rather marked regularity in points of
origin, sequence, and directions of growth, in the assumption of
the postjuvenal pelage, it seemed worth while to determine to
what extent, if at all, the process might be modified by the arti-
- ficial induction of regenerative processes.

In the series of experiments here described, a total of about
forty gambeli were used, varying in age from two and one-half to
seven weeks. The mice were etherized and the pelage was re-
moved by plucking out with the fingers. The hair is quite loose,
especially just previous to a moult, and may be very readily
removed in this manner without injury to the skin.

Except in those cases where the moult was too far advanced,
the following regions were operated on in every individual:

THE JOURNAL OF EXPERIMENTAL ZOOLOGY, VOL. 27, No. 1

82 H. H. COLLINS

1. The dorsal median region of the head from the tip of the
snout to the base of the skull.

2. The hips and thighs.

3. About 1 sq. em. between and anterior to the forelimbs.

4. About 1 sq. em. in the midventral region, just anterior to
the hind limbs.

Although individual differences were in some cases quite
noticeable, in general the mode of replacement on the depilated
areas was much the same.

The history of one brood (offspring of 2 106) may be regarded
as fairly typical. The three members of this brood were oper-
ated upon, as outlined above, at the age of eighteen days. At
that time they were in full juvenal pelage. Without exception,
the skin of the posterior half of the dorsum was still dark—an
indication that the growth of the juvenal hair was still in prog-
ress. The denuded areas on the head and ventral surface,
however, were devoid of pigment.

Two days later, the pigment in the skin of the dorsum had
almost entirely disappeared, except on the exposed area on the
hips. Here a rather striking effect was observed. The skin
was as dark as when the pelage was first removed, the line of
demarcation between the two areas being very clearly defined.

On the seventh day, the exposed skin on the head was begin-
ning to darken. That of the hips was somewhat lighter than when
last observed, though it was still much darker than the surround-
ing skin. On the ventral surface, there was a slight darkening of
the skin of the posterior area.

Ten days after the operation, the pigment in the skin of the
depilated region on the hips had not wholly disappeared. In the
meantime the exposed skin on the head had become much more
intensely pigmented. The throat patch remained flesh color,
while the posterior ventral area was slightly darkened.

When the brood was examined on the seventeenth day, some
rather marked individual differences were noted. In one case
the depilated area on the head was entirely covered with post-

4 Normally, the pigment disappears and the skin becomes flesh color after the
hair attains its full length.

MOULT AND REGENERATION OF PELAGE IN MICE 83

juvenal pelage, about half grown out, almost uniform in length,
though slightly longer posteriorly. Those of the ventral surface
were also wholly covered with pelage of about uniform length.
In the meantime the normal postjuvenal moult had appeared on
the throat near the point of the jaw, extending under the ear and
down on the anterior face of the forelimb entirely outside the
depilated region and in typical fashion. At the same time post-
juvenal pelage, barely through the skin, was found extending as
a narrow band on the lateral line from the base of the tail to the
forelimb on one side of the body, and from the hind limb to the
forelimb on the other. Both strips were continuous with the
new pelage coming in on the posterior ventral area. Never

having observed this condition in a normal moult, I am inclined

to regard the premature appearance of postjuvenal pelage in this
region as an abnormality resulting from the operation. At this
time the depilated area on the hips was still bare.

In the other two members of the litter the normal moult had
not appeared by the seventeenth day. The depilated regions
of the head were covered with a uniform growth of postjuvenal
pelage, but the hip regions showed no indications of regeneration.

Within a few days postjuvenal pelage appeared on the hips
where the juvenal pelage had been removed, and a month after
the operation the new pelage on all the depilated areas was fully
grown out. At this time both surviving members of the brood
were approaching the ‘saddle phase’ of the normal moult (fig. 12).

A comparison of the foregoing description with that of the
normal moult will show the marked extent to which the normal
process has been modified by artificially induced regeneration.

If replacement on the depilated areas were to follow the normal
sequence, the order would be as follows: 1) throat; 2) posterior
ventral area; 3) dorsal lumbar region; 4) dorsal head region.
Moreover, as already noted, the dorsal head region is normally
invested some weeks after the appearance of the new pelage on
the throat and forelimbs. .

It will be observed that growth on the depilated regions is
much more nearly simultaneous than is normally the case. Fur-
thermore, the sequence is not the same. Regeneration on the

84 H. H. COLLINS

head precedes replacement on the hips and hind limbs—an in-
version of the natural order. Growth is almost simultaneous on
the two denuded areas of the ventral surface, while the pelage
of the hips was last to be replaced.

It will be noted also that the mode of replacement on the head
was radically different from the normal process. Typically,
growth proceeds, a) dorsally, from the tip of the snout to the
anterior insertions of the ears, or, in some cases, posteriorly to a
point midway between the ears; b) from the shoulders, anteriorly
over the back of the neck to the ears. In contrast to this con-
dition, in regeneration the new hair appears almost simultane-
ously over the whole of the depilated area.

It is but natural to suppose that the normal process of growth ~
would be less profoundly modified were regeneration to occur
immediately before or during the normal moult. But this does
not seem to be the case. In mice operated upon at the age of
six weeks, with the normal moult well under way, regeneration
occurred in essentially the same manner, as regards sequences and
directions of growth. Even in an extreme case, in which the
entire body except the head and rump were covered with post-
juvenal pelage, replacement on the head was somewhat in
advance of that on the rump. Replacement on the head was
fairly uniform, though the snout below the eyes was last to be
invested—an inversion of the normal condition.

In exceptional cases the normal order is not so completely dis-
guised, as shown by the history of another brood (that of 2 105),
the four members of which were operated upon in the same
manner and at the same age as the former brood.

The first suggestion of the normal process, such as would
occur without operation, appeared on the depilated area of the
throat about a week after the hair was removed. Here there
was a perceptible darkening at the point of the jaw and along the -
anterior face of the forelimb, thus outlining the region where the
postjuvenal pelage normally first appears. At the same time the
rest of the exposed area showed no signs of pigment formation.
Within a few days incoming pelage appeared on this pigmented
area, the rest of the region being covered some days later. Typi-

MOULT AND REGENERATION OF PELAGE IN MICE 85

cally, as has been already indicated,® replacement after depilation
occurs simultaneously over the whole region.

A further reminder of the normal process was noted in the
mode of regeneration on the head. Instead of the fairly uniform
replacement usually observed after depilation, there were two
independent centers of growth. Pigment (followed in a few days
by the incoming hair) first appeared on the snout just below the
level of the eyes, spreading anteriorly to the tip and posteriorly
to a definite transverse line connecting the anterior insertions
of the ears, the skin posterior to the line remaining unpigmented
for several days. In another member of the brood pigment
developed at the same time on the snout and back of the ears,
leaving a small patch of pigmentless skin between them.

The incoming postjuvenal pelage does not ordinarily trans-
gress the limits of the depilated region and, as a rule, the mode
of change on the rest of the body surface remains unmodified.
Occasionally, however, there is apparently some ‘action at a
distance.’ One such case has already been cited. In another
instance, where the juvenal pelage had been removed from the
hips, the incoming postjuvenal, passing beyond the denuded
region, extended anteriorly to the middle of the dorsum, meeting
at this point the normal moult which was proceeding in the
opposite direction. In other words, the normal direction of
growth had been reversed on a part of the dorsum which had not
been operated upon.

In all cases where the juvenal pelage was removed it was
replaced by the postjuvenal. However, I have noted what at
first appeared to be an abortive attempt to regenerate juvenal
hairs.

During the week following the removal of the juvenal pelage
(in those cases only in which the skin was dark at the time)
a growth of fine short blackish hairs appeared on the denuded
areas. This was succeeded in a few days by the incoming post-
juvenal hair.

5 See page 83 above.
6 See page 83 above.

86 . Hi H. ‘COLLINS >

When subjected to microscopical examination, it was found
that these hairs represented the basal portions of juvenal hairs,
broken off in the skin at the time of the operation. In most
cases, the tips plainly show evidences of fracture. It is interesting
to note that in many of these hairs the localization of pigment
has been modified to a marked extent.

Evidences of the segmental arrangement may be partially or
wholly obliterated. The amount of pigment appears to be some-
what greater than in the normal hair at this level. This increase,
however, may be more apparent than real, as a result of the more
diffuse arrangement of the granules.

5. REGENERATION OF ADULT PELAGES

In addition to the foregoing studies of regeneration of hair
in juvenal mice, a number of rather incidental observations were
made on adults.

In order to facilitate the study of the details of normal moult,
the old pelage was removed by clipping close to the skin. In
all, seventeen adult gambeli were included in this series. Ten
of these mice were clipped over the whole body, including head
and limbs, while in the remaining cases the hair was removed
from one side only. The mode of replacement was so irregular
that the primary object of the experiment was not attained.
However, the results from the point of view of regeneration may
perhaps be of some interest.

Although obscured by various irregularities, there were some
vestiges of the normal process. The first evidence of growth
was seen, as a rule, on the throat and forelimbs. Replacement
on the ventral surface preceded that on the dorsum, while, in
general, the moult’? proceeded from before backward.

One of the most striking and characteristic departures from
the normal process was the appearance of more or less numerous
small isolated patches of hair over the posterior half or two-
thirds of the body. These ‘hair islands,’ which were usually

7 Since the process includes the shedding of the clipped hair, the term ‘moult’
may properly be used in this connection.

MOULT AND REGENERATION OF PELAGE IN MICE 87

more in evidence on the dorsal surface, appeared simultaneously
with the new pelage on the throat and forelimbs.

Following this partial restoration after the new hair had at-
tained its full length there were no further signs of regeneration
for a period varying in different individuals from one to four
months. Then new hair appeared at the same time on all the
bare spots between the ‘islands,’ except on the rump, where, in
most cases, replacement was still incomplete when the animals
were last examined, five months after the operation.

Although there appears to be no subsequent growth of the
body hairs, which were fully grown out at the time of the opera-
tion, it is worthy of note that the restoration of the vibrissae is
accomplished by the elongation of the identical hairs which
were cut. Although, as previously pointed out, there are cer-
tain structural differences between these two types of hairs, the
cause of the difference in the mode of regeneration is not at all
evident.

In those individuals in which the pelage was removed from
one side only, the mode of replacement was essentially the same.
Apparently, at least within these limits, there is no correlation
between the rate and mode of regeneration and the size of the
area operated upon.

While engaged in a study of seasonal changes in color due to
fading, abrasion, and other causes, it seemed highly desirable to
be able to compare old and new pelages on opposite sides of the
body of the same individual. With this object in view, a series
of twenty adult gambeli were trapped in worn and faded pelage,
a few weeks prior to the autumnal moultingseason. The animals
were etherized and the old hair was plucked out on one side only,
from the dorsal median line to the lateral line and from the tip
of the snout posteriorly to the base of the tail. Although this
series of experiments will be described more fully in a later paper
dealing with color variations, they may be briefly mentioned here
in connection with the topic of regeneration.

Replacement occurred much more rapidly than in the preceding
series. With but one exception, complete restoration was ac-
complished one month from the date of the operation (fig. 15).

88 H. H. COLLINS

Replacement occurred at about the same time over the whole
area, though that on the forelimbs and throat was slightly in
advance and the hip and hind limb were covered last. With
but few exceptions (probably not observed at the right time),
‘hair islands’ were seen particularly on the posterior part of the
dorsum, but they were obliterated within a few days by the
appearance of hair on the intervening patches.

The differences in the appearance of the two sides of the body
are slight and in no case comparable with the contrast in the
coloration of individuals representing buff and dark extremes
within the species.

6. DISCUSSION

A study of the details of moult in living juvenal Peromyscus
discloses a greater regularity in the process than appears to be
characteristic of adult mammals in general.

It is found that the change occurs more or less independently
on different parts of the body, suggesting tracts somewhat com-
parable to the pterylae in birds. This is most clearly seen in the
method of moult on the dorsal surface of the head where growth
proceeds from the neck anteriorly, and from the tip of the snout
posteriorly to the ears. Then again, moult appears independ-
ently, although synchronously on opposite sides of the body.

While the marked regularity of replacement of feathers on the
wings of birds may be regarded as an adaptation for the preserva-
tion of the power of flight, the sequence of moult on the various
pterylae, of the body proper, and the similar phenomenon in
mice as well could scarcely be interpreted in the same light. In
this connection, Dwight (’00) writes as follows:

The important part that the blood supply plays in this plan ap-
pears to have been quite overlooked nor have I had the opportunity
to fully investigate it. I may say, however, that the radiation of the
moult from given points corresponds very closely to the distribution
of the superficial arteries, beginning where the main trunks come to
the surface and ending with their ultimate ramifications (p. 84).

This same idea is suggested rather indirectly by Schultz (’16),
who regards the color markings of mammals as due to differen-

MOULT AND REGENERATION OF PELAGE IN MICE 89

tials in growth which are due, in turn, to inequalities in the pe-
ripheral blood supply. We shall consider this theory more at
length in the discussion of his studies of the regeneration of hair.

In the species of Peromyscus studied I find some deviations
from the process of moult as described by Osgood (’09) in his
monograph of the genus. With reference to the postjuvenal
moult he writes: ‘‘This [i.e., juvenal] stage is succeeded by the
adolescent pelage, which first appears on the middle of the sides”’
(p.20). I donot find this to be the case in any of the three species
examined. Another difference is in regard to the regions last
invested. Instead of the “rump and nape usually being the last
parts to be covered,” the juvenal pelage normally persists on the
head between and just anterior to the ears for days, often for
weeks after the complete investment of the rump region. In
these regards, the species in question do not appear to be typical
of the genus.

The precocious appearance of feathers or hair characteristic
of a later plumage or pelage has been mentioned by a number of
observers. With reference to the varying hares, Allen (’94b) says:

In the case of wounds from fighting or other cause, resulting in the
violent removal of large bunches of fur, it is interesting to note that in
the autumn the new hair comes out white, often weeks in advance of
the general change, and that in spring, under similar circumstances,
the hair comes out brown, like the summer coat, much in advance of
the general change from winter to summer pelage (p. 121).

A similar condition has been described by Schultz (’15) in the
Himalayan rabbit. In this animal, which is a pink-eyed albino
with black feet, muzzle, and ears, the black markings do not
appear in the juvenal pelage. By plucking out the hair on one
ear, Schultz obtained animals in which one ear was black while
the other remained unchanged until the next pelage was assumed.

In the domestic fowl the secondary sexual feathers which are
characteristic only of the adult plumage of the male may be
caused to appear prematurely by plucking out the undifferenti-
ated body feathers which precede them. According to Pearl
and Boring (’14), “If the juvenile feather is removed from the
follicle the next feather produced by that follicle will be the

90 H. H. COLLINS

secondary sexual feather, and not a feather of the juvenile type.
After that all further regenerations are of the sexually differen-
tiated feather” (p. 144).

I have occasionally noticed the premature appearance of post-
juvenal pelage without operation in young mice which had lost a
patch of hair before the time of the regular moult, or in places
where apparently the juvenal hair had failed to appear.

In the course of his rather extensive studies of the regeneration
of hair in rabbits, Schultz describes certain phenomena, similar
to those which I have found to oceur in mice.

For example, he found after shaving large patches on the dorsal
and ventral surfaces of an adult black and tan rabbit that
restoration was accomplished quickly on the ventral surface,
while the depilated region on the dorsum, with the exception of a
few ‘hair islands,’ remained bare for a year after the operation.
On the other hand, when the pelage was plucked out, restoration
was found to occur promptly at all seasons of the year and in
animals of different ages.

As already pointed out in my account of the regeneration of
adult pelages,’ the conditions are quite similar in the case of
Peromyscus. In both animals the activation of the hair follicles
is more readily accomplished when the mechanical stimulus is
added to the effects of temperature upon the exposed skin.

Schultz regards the appearance of ‘hair islands’ as due to
differences in the peripheral blood supply. Furthermore, he sees
in this phenomenon an evanescent manifestation of the mottled
color pattern, as seen, for example, in dappled gray horses.

Another of Schultz’ experiments may be briefly mentioned
because of its general bearing on his theory of animal coloration.
In the Himalayan rabbit, according to his account, when white
fur was plucked out it was replaced by black, although this
color is normally limited to the feet, ears, and muzzle. The
capacity for pigment formation seemed to be general and markings
could be produced at will on parts of the body where they never
occur in nature. In the course of his experiments, it became

8 See page 87 above.

MOULT AND REGENERATION OF PELAGE IN MICE 91

evident, so he believed, that light played an important role in the
production of pigment in the skin of the depilated surfaces. On
the margins of the depilated areas, shaded by the surrounding fur,
the regenerated hair was found to be white, while that in the
partially shaded region was less intensely pigmented than the
fully exposed central area. Furthermore, he describes having
obtained hairs of the banded or agouti type by exposing the
denuded skin to light at certain intervals only.

The experiments were repeated on a number of other rodents
with negative results. Nevertheless, Schultz suggests that the
differential coloration of the dorsal and ventral surfaces char-
acteristic of many mammals may be due largely to differences in
illumination.

While my own investigations have not as yet been carried far
enough to warrant the formulation of an alternative hypothesis,
it nevertheless appears obvious that the theories advanced by
Dwight and Schultz are inadequate to account for some of the
phenomena observed in the moults and color patterns of mammals.

Dwight’s theory of the correlation between the distribution of
peripheral blood-vessels, and the points of origin and the sequence
of moult on different parts of the body of birds does not appear to
be applicable in the case of mice. We should scarcely expect to
find differences in the arrangement of superficial blood-vessels
sufficient to account for the differences in points of origin of the
moult observed in species of the same genus. But, more than this,
the fact that, in regeneration following removal of pelage, the
normal sequence is so markedly modified speaks against this
hypothesis.

In no mammal are the differences in coloration of the dorsal
and ventral surfaces more marked, nor are the two regions more
sharply delimited than in some of the species of Peromyscus.
The sharpest contrast is seen on the tail.

Whatever the réle of light may have been in the evolution of
this color pattern, it appears to be a negligible factor in its
ontogenetic development. Since these animals are mainly
erepuscular or nocturnal in habit, the growth of the hair occurs
in diffuse light. Differences in illumination of the dorsal and

92 H. H. COLLINS

ventral surfaces are practically nil. Then, too, the dorsal surface
of the tail is rarely wholly covered by the median stripe. Here,
under identical conditions of illumination, heavily pigmented
and pigmentless hairs develop side by side.

Furthermore, I have observed no differences in the color of
hairs of the shaded margins and of the exposed central portions
of depilated areas. The capacity for the production of hairs of
the agouti type appears to be quite definitely confined to the
dorsum, the position of the lateral line apparently being unaffected
by the operation. Recognizing the fact that in a large number
of cases the markings of animals obviously cannot be attributed
to differences in intensity of illumination, Schultz has recourse to
a second theory, namely, that such color markings are due to the
inequalities in the peripheral blood supply. The black markings
of the Himalayan rabbit are found on the extremities where the
blood supply is somewhat reduced. The dorsal median stripe
found in many mammals, in Peromyscus for example (figs. 7, 9,
15), is said to be due to the pressure on the skin of the underlying
vertebrae, which impedes the circulation. The rings on a cat’s
tail overlie vertebral processes, and so on through the category.
It must be pointed out in this connection that Schultz appears
to be somewhat inconsistent in his application of this theory.
In one paragraph we read:

Meine Ergebnisse, dass wachsendes Haar besonders fiir Farbstoff-
bildung geeignet ist, und zwar um so mehr, je lebhafter die Wachstums-
vorginge, sind eine Art Nachahmung der von Darwin bemerkten Natur-
erscheinung, dass weisse Taubenrassen unbefiedert, dunkle befiedert
dem Ei entschliipfen. Die Kaninchenalbinos, die ich hielt, schienen
mir bei der Geburt auch so gut wie kahl, die farbig geborenen Rassen
aber starker behaart.

In vielen Naturmustern finden wir die staérksten Farbstoffanhaufun-
gen gerade an Stellen, die durch starkstes Haarwachstum gekennzeich-
net sind, und an solchen Vorspriingen und Ausbeutelungen der Haut,
die zeitweilig starker wachsen miissen als ihre Umgebung, z. B. Mahne,
Schweif und Beine der Grauschimmel (p. 1€1).

However, in regard to the black markings of the Himalayan
rabbit, he writes:

MOULT AND REGENERATION OF PELAGE IN MICE 93

Betrachtet man die Russenkaninchen als Ganzes, so erhalt'man den
Eindruck, dass an ihnen die mehr innen gelegenen Teile farblos bleiben,
daher nicht nur die andern inneren Gewebe, sondern sogar die roten
Augen, welche nach innen versenkt sind. Die dem Herzen ferneren,
den Schidigungen der Aussenwelt und der schlechteren Durchblutung
mehr ausgesetzten Teile, Nase, Schwanz, Ohren, Fiisse, sind der Farb-
bung verfallen, uberhaupt neigt daher insbesondere die Haut zur
Farbstoffbildung. Die inneren Organe scheinen gerade wegen ihrer
besseren Durchblutung, geringeren Schaddigung wegen Farblosigkeit
zu besitzen (pp. 551 and 552).

That is to say, pigment formation is most pronounced where
the processes of growth are most active, and at the same time,
in regions having a relatively poor blood supply. From which it
appears to follow that an adequate supply of blood tends to
inhibit growth.

It appears that, at best, Schultz’ theory of the relation of blood
supply to pigmentation is applicable only in a limited number of
cases. The list of exceptions is overwhelmingly large.

To cite a specific case, the hair on the feet of Peromyscus is
pigmentless. This is characteristic of the genus, whence the
name, ‘white-footed mice.’

Furthermore, in many species of small mammals, individuals
having white-tipped tails are of frequent occurrence. In the
ease of Zapus insignis, as cited by Miller (’93), this white-tipped
condition has become characteristic of the species. In certain
species of Peromyscus, Sumner (718) describes the occasional
appearance of the same character, and of pigmentless snouts as
well. In the alternative inheritance of many color patterns,
we are confronted by another category of facts which are not
readily interpreted in the light of Schultz’ hypothesis.

In conclusion, we may refer to the interesting and suggestive
researches of G. M. Allen. This investigator has found that in
general in mammals and birds, pigmentation centers in eleven
separate areas, five paired, and one unpaired. Pigmentless
markings are said to arise when contiguous areas fail to meet.
Each area may vary independently.

Further investigations along these lines may go far toward
clearing up some of the puzzling problems which one encounters
in a study of animal coloration.

94 H. H. COLLINS
7. SUMMARY

1. The process of normal moult has been followed in a large
series of living mice representing several species of Peromyscus.

2. In this study of the living material, the process of moult
is found to be, ina measure, comparable in regularity of sequence
and directions of growth with the moults of birds.

3. In the postjuvenal moult, growth occurs more or less in-
dependently on certain regions of the body, suggesting the mode
of moult in the pterylae of birds.

4. The moults of adults are generally of a more irregular
character.

5. In young mice the change of pelage is quite obvious, but
in adults it may be quite insidious and evident only upon close
examination.

6. In general, the process of moult is quite similar in different
species, but in some instances there appear to be certainminor
differences.

7. By plucking out juvenal hair, the precocious appearance
of the postjuvenal pelage may be induced.

8. Under certain conditions, the appearance of this postjuvenal
pelage, after artificial removal of the juvenal, is preceded by the
outgrowth of an aberrant type of hair which persists only for a
short time. Within these hairs the localization of pigment is
abnormal.

9. The normal sequence of the incoming hair is profoundly
modified by artificially induced regeneration.

10. Restoration of pelage in adults occurs irrespective of sea-
son, after the plucking out or clipping of the old hair.

11. This restoration is accomplished by the outgrowth of new
hairs, except in case of the vibrissae, which are replaced by the
elongation of the cut hairs.

12. Restoration is much more rapid when the hairs are plucked
out than when merely cut.

13. The differences in coloration of the old and the new pel-
ages as seen on opposite sides of the body of adult gambeli are

MOULT AND REGENERATION OF PELAGE IN MICE 95

slight, never approaching the differences between individuals
representing light and dark extremes within the species.

14. Light appears to be a negligible factor in the development
of the differential coloration of the dorsal and ventral surfaces.

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RipGway, Rosertr 1912 Color standards and nomenclature. Washington:
published by the author, 43 pp., 53 pls.

Scuuttz, WatrHerR 1915 Schwarzfiirbung weisser Haare durch Rasur und die
Entwicklungsmechanik der Farben von Haaren und Federn. I. Arch.
f. Entwm., vol. 41, p. 535-557.
1916a Schwarzfirbung weisser Haare durch Rasur und die Entwick-
lungsmechanik der Farben von Haaren und Federn. Ab. II. Arch.
f. Entwm., vol. 42, pp. 139-167.
1916b Schwarzfirbung weisser Haare durch Rasur und die Entwick-
lungsmechanik der Farben von Haaren und Federn. Ab. III. Arch.
f: Entwm., vol. 42, pp. 222-242.

Stumner, F. B. 1918 Continuous and discontinuous variations and their in-
heritance in Peromyscus. Am. Nat., vol. 52, no. 616, Apr., May,
pp. 177-208; nos. 618-619, June-July, pp. 290-301; nos. 620-621, Aug.—
Sept., pp. 439-455.

Wurman, C. O. 1904 The problem of the origin of species. Congress of Arts
and Science, Universal Exposition, St. Louis, vol. 5, pp. 1-18.

PLATE 1

EXPLANATION OF FIGURES

4 to 9 show various stages in the postjuvenal moult of P. maniculatus gambeli.

4 Young in full juvenal pelage.

5 Showing the growth of the postjuvenal pelage from the lateral line (L. 1.)
upward.

6 Early ‘saddle phase.’ The lateral areas, as seen in figure 5 have become
confluent on the dorsal median line.

7 Late ‘saddle phase,’ in which the juvenal pelage still persists on the head
and back of the neck, and on the rump. The dark strip extending from the
shoulders posteriorly to the rump is the dorsal median stripe of the postjuvenal
pelage. The difference between this stripe and the juvenal pelage on the rump
is not well shown in the figure, though the actual colors are quite unlike.

8 A later phase showing further decrease in size of the areas of juvenal pelage
on the head and rump.

9 Full postjuvenal pelage.

96

MOULT AND REGENERATION OF PELAGE IN MICE PLATE 1
H. H. COLLINS

THE JOURNAL OF EXPERIMENTAL ZOOLOGY VOL. 27, No. 1

PLATE 2

EXPLANATION OF FIGURES

10 to 14 show various abnormal phases and the precocious appearance of
postjuvenal pelage, as the result of depilation in P. maniculatus gambeli.

10 Showing postjuvenal pelage on the head, also on the rump extending barely
above the lateral line anteriorly to the forelimbs.

11 A phase similar to that shown in figure 10, but more nearly symmetrical
in pattern.

12 Showing the simultaneous occurrence of normal moult on the sides above
the lateral line and of induced regeneration on the rump.

13 An ‘island’ of juvenal pelage in the median dorsal region—an inversion
of the normal process. See pl. 1, fig. 6.

14 Juvenal pelage on the left side of the body, postjuvenal on the right.

15 Skin of an adult with new pelage on the left side of the body and the old
pelage on the right; one month after the operation.

MOULT AND REGENERATION OF PELAGE IN MICE PLATE 2

H. H. COLLINS

99

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AUTHORS’ ABSTRACT OF THIS PAPER ISSUED
BY THE BIBLIOGRAPHIC SERVICE, OCTOBER 8

THE REACTION OF SELACHIT TO INJECTIONS OF
VARIOUS NON-TOXIC SOLUTIONS AND
SUSPENSIONS (INCLUDING VITAL
DYES), AND TO EXCRETORY
TOXINS

E. R. HOSKINS AND M. M. HOSKINS
New York University and Bellevue Hospital Medical College

TWENTY-SEVEN FIGURES (sIx PLATES)

CONTENTS
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INTRODUCTION

The present study grew out of an attempt to determine the
function of the digitiform gland, the development of which has
recently been described (Hoskins, ’17). This gland is peculiar
to selachians, being found in no other group of animals, al-
though in Chimaera, there is present in the wall of the posterior
portion of the intestine a group of cells which may possibly
correspond to it (Disselhorst, ’04).

101

THE JOURNAL OF EXPERIMENTAL ZOOLOGY, VOL. 27, No. 2
NOVEMBER, 1918

102 E. R. HOSKINS AND M. M. HOSKINS

Nearly every reasonable function has been ascribed to the
digitiform gland, but usually from morphological or hypothetical
rather than physiological evidence (Hoskins, 717). The gland
is a compound tubular structure with a large central lumen or
duet which empties into the intestine about half way between
the spiral valve and the cloaca. It is suspended in the mesen-
tery above the intestine. Cytologically, the gland is not unlike
the kidney tubules, and this, together with the fact that its
secretion is discharged into the intestine posterior to the region
where digestion occurs, leads to the expectation that it has an
excretory function. The fact that the gland appears to be the
same in both sexes argues against the probability that it is
accessory to the sexual apparatus.

Another part of the work is a study of the function of the
kidney (mesonephros) compared with that of mammals (meta-
nephros). It is common knowledge that the former is a less
efficient excretory organ than the latter, but the subject has
never been completely studied experimentally. A study is
made also of the excretory function of the liver, which is of
considerable importance in selachians, on account of the ineffi-
ciency of the kidney. In selachians the liver undergoes fatty
metamorphosis to such extent that nearly every cell appears
filled with fat, yet the organ is able to excrete solutions and
particles freely and in large amounts.

Denis (13) has shown that dogfish are able to withstand large
doses of excretory toxins, but this author did not study the
problem histologically. The question of vital staining is con-
sidered here only incidentally and no attempt is made to deseribe
completely the reaction of the dogfish to vital stains. These
substances were used primarily as an aid to the study of the
excretory function.

Most of the experiments were performed at the Marine Bio-
logical Laboratory at Woods’ Hole, Massachusetts, in quarters
provided us through the kindness of the Department of Zoology
of Yale University and of Dr. Frank Lillie. The accompanying
photomicrographs were made at the Osborn Zoological Labora-
tory of Yale University. Two experiments were done at the

REACTION OF SELACHII TO INJECTIONS 103

Aquarium in New York. We desire here to express our thanks
to the Zoology Department of Yale University, to Dr. Lillie,
and to Dr. C. H. Townsend, of the Aquarium.

MATERIAL AND METHODS

The animal used in most of the experiments is the dogfish
Mustelus canis, which is fairly abundant at Wood’s Hole. In
the two experiments performed at the New York Aquarium we
used Acanthias. In all about seventy-five animals were made
use of. These were of both sexes and of various sizes, but most
of them were adult males.

The study was divided into three phases; a) the reaction to
non-toxic solutions; 6) the reaction to suspended particles, and,
c) the reaction to excretory toxins. The solutions used are
indigo-carmine, potassium iodide, dextrose, sucrose, pheno-
sulphonepthalein, and Weed’s potassium ferrocyanide-iron am-
monium citrate solution. The supensions are carmine, Congo
red, neutral red, and trypan blue. The toxins are potassium
chromate, tartaric acid, and uranium nitrate. All were pre-
pared with sea-water, which is isotonic with the blood of dogfish.
In preparing Weed’s solution, sea-water, diluted one-third, was
used.

Injections were made either into the muscles of the tail and
back or intravascularly. In the latter method the large vessels
of the pectoral fins were used. A small wooden peg may be
used for a hemostat and is very convenient as it can be easily
removed for repeated injections. Intravascular injections may
be made, also, directly into the sinuses of the head.

A simple device for holding the animals during the experi-
ment may be made from a board 4 inches wide and 2 feet long.
A long hole is made near one end for the dorsal fins and a row
of nails driven partly in along each side of the board. The ani-
mal will be securely held on this if a cord is laced from the nails
back and forth across its body. A tube of running water in-
serted into the animal’s mouth will provide for respiration dur-
ing an operation. The entire apparatus with the fish in normal
position may be immersed in the aquarium if it is necessary that

104 E. R. HOSKINS AND M. M. HOSKINS

the animal be kept immobilized. In collecting urine from an
immersed animal the receptacle can be sealed tight and weighted
to keep it under the water. A long glass tube leading into it
will permit the air to excape as the urine accumulates. If a long
rubber tube is used to connect the cannula with the collecting
bottle the animal can even be permitted to swim about in the
aquarium while the urine is being collected. Denis (’12) also
describes a good method for collecting urine.

The duct of the digitiform gland enters the intestine at a
peculiar angle, being completely bent on itself. In order to
insert a cannula into the duct it is best to reach into the intes-
tine with a pair of blunt forceps and turn the gut inside out
through the cloaca. This straightens the duct and a cannula
can then be introduced directly into it. No anaesthetic is
required in operations as the animal will lie quietly in the ap-
paratus described above and seems insensible to pain. Anti-
septics were also found to be unnecessary in operations.

EXPERIMENTS
1. Solutions

A. Indigo-carmine. 1. An adult male dogfish was injected
intramuscularly with 5 ec. of 0.5 per cent indigo-carmine. This
appeared in the urine in fifteen minutes. It did not appear in
the stomach, spiral-valve or digitiform gland contents, at least
in detectable quantities. The bile was bluer than normal.

2. The experiment was repeated with a female, and similar
results obtained.

3. Two animals, a male and a female, each received 5 ce. of
the above solution intravenously. It was recovered from the
urine of each after eight minutes.

4. A female was injected as in ‘3’ and permitted to live five
hours, at which time the urine was still dark blue in color.

All five of the above-mentioned animals were autopsied at
various times after injections, varying from a half-hour to five
hours. All secretions examined gave the same reactions as in

REACTION OF SELACHII TO INJECTIONS 105

‘1.’ Also in every case the anterior portion of the kidney and
liver was of a light blue color. The posterior portion of the kid-
ney was dark blue and a dissection of the liver showed the bile
ducts to be colored blue rather than the usual green. The
other organs of the body cavity were not distinctly blue in color.

Glands were fixed in absolute alcohol, but the dye soon dis-
appeared either by fading or going into solution. Sections were
made and examined microscopically, but no blue granules were
seen even though the gross specimens were blue. The dye was
probably impure and hence dissolved out in the alcohol, as was
found to be true in some eases by Heidenhain (’83) working with
other animals.

B. Potassium iodide. An adult male fish received 10 ec. of
a 3 per cent solution of potassium iodide intravenously. After
three and a half hours tests were made with nitric acid and
starch (Hawk, 716), and the iodide was found to be present in
the urine in the gastric and intestinal fluids, the bile, and the
secretion of the digitiform gland.

C. Dextrose. An adult female fish received intravenously
15 ec. of 25 per cent dextrose solution. At the end of one hour
the urine was negative to Benedict’s sugar test (Hawk,’16),
but was positive after four hours and negative again after nine
hours. At the latter time the bile gave a positive reaction, but
the secretion of the digitiform gland reacted negatively.

D. Sucrose. The animal received intravenously 15 ec. of
30 per cent sucrose, and after six and one-half hours was autop-
sied. The reaction to Benedict’s test was positive in the case
of the urine, bile, and blood serum, but negative with the gastric
and spiral-valve contents. The digitiform gland secretion was
not tested.

E. Phenosulphonepthalein (Rowntree and Geraghty, ’12).
1. One and two-tenths ce. of this pthalein was injected intra-
muscularly. It appeared in the urine in fourteen minutes. At
autopsy it was not present in detectable amounts in the stom-
ach, intestines, or digitiform gland.

2. An animal received intravenously 1 cc. of pthalein. Au-
topsy was performed after one hour. At this time the pthalein

106 E. R. HOSKINS AND M. M. HOSKINS

was present in the urine, bile, and in the stomach and spiral-
valve contents. The secretion of the digitiform gland and an
extract of the spleen were negative.

3. An adult fish received 1.4 ec. of pthalein. The urine was
collected for five and a half hours and the bile in the gall-bladder
was removed at the end of that time. The urine, bile, and
1.4 ec. of pthalein in graduated cylinders were each diluted with
water, acidified and all compared (Rowntree and Geraghty, 712).
By this comparison it was shown that approximately one-half
of the injected pthalein had been recovered, and of this, about
one-fourth was in the urine and three-fourths in the bile. The
bile pigments interfere slightly with the test. A trace of ptha-
lein was found in the serum, digitiform gland secretion, and in
the stomach and spiral-valve contents. That in the latter two
may have come from excreted bile.

4. An adult received 1 ec. of pthalein. A cannula was in-
serted to collect the urine and the animal was then permitted
to swim about in the aquarium for four and a half hours in
order that the excretion might not in any way be interfered with
by the unnatural position of the animal in the holding apparatus
that was used in the first three experiments. In this specimen
as in the others more pthalein was recovered in the bile than in
the urine. Pthalein was also found in the spiral valve, but not
in the stomach.

F. Weed’s solution (potassium ferrocyanide and iron ammo-
nium citrate, Weed, 712). 1. A young male (0.8 kg.) received
intra muscularly 7.5 ec. of Weed’s solution and was autopsied
after four hours. The urine and bile gave the Prussian-blue
reaction with acid. The serum and the stomach and spiral-
valve contents were negative to the test.

2. A young animal (0.5 kg.) received intramuscularly 9 ce.
of Weed’s solution, followed after five hours by 9 cc., and after
twenty-two hours by 8 ee. Twenty-five hours after the first
injection the Prussian-blue reaction was obtained with the
urine, bile, and serum. The liver turned blue on standing.

3. A young female (0.5 kg.) received, as above, 10 ec. of the
solution, followed by 5 ce. after four hours, and 5 ec. after seven

REACTION OF SELACHII TO INJECTIONS 107

hours. Autopsy was performed eight hours after the first injec-
tion. The Prussian-blue reaction was obtained from the serum
and urine, but not from the bile, or stomach and spiral-valve
contents. Pieces of organs were fixed in 20 per cent formal-
dehyde acidified to 1 per cent with hydrochloric acid.

4, An adult (Acanthias) received four hourly injections of 6
ec. each of Weed’s solution, and was autopsied four and a half
hours after the first dose. Organs were fixed in absolute alcohol
acidified as above.

5. An adult (Acanthias) received three injections of 9 ce.
each of Weed’s solution at hour intervals and was autopsied
forty-five minutes after the last injection. Forty per cent for-
maldehyde acidified to 1 per cent was used as a fixative. Mi-
croscopic examinations were made of various organs from the
animals, ‘3,’ ‘4,’ and ‘5’ with the following results:

a. Digitiform gland. In all the specimens examined there is a
central, distinctly blue zone, the width of about one-half the
radius of the gland as seen in transverse sections. Microscopi-
eally, the blue granules are seen almost entirely within the
blood-vessels, although a very few are found in the cells of the
tubules, but none in the lumen. The granules are present in the
capillaries and central venous sinuses in greater concentration
than in the vessels of any other organ.

b. Kidney. The gross specimens are dark blue in color.
Sections show many Prussian-blue granules in the blood-vessels
and tubules. A very few only are present in the glomerular
cavities. They are found in the cytoplasm of both the secretory
and excretory tubules. Blue granules are found also in the con-
nective tissue of the kidney.

c. Liver. The gross specimens are all light blue in color. In
a few hepatic cells blue granules are seen and they are present
in greater number in the ducts. This indicates either that the
solution passed directly into the ducts, as was thought to be the
case of trypan blue in bony fishes (Wislocki, ’17), or else that the
solution passed through the epithelium quickly and out of the
ducts more slowly, thus becoming concentrated in the ducts.
In the liver of animal ‘3’ the endothelium and the leucocytes of

108 E. R. HOSKINS AND M. M. HOSKINS

the hepatic sinuses have a deposit of blue granules on or in them.
This condition is not seen in other organs of the same animal
nor in the liver of other animals.

d. Spleen. Blue granules are scattered throughout the spleen
among, but not within the cells.

e. Spiral-valve, stomach, gills, and muscle. All these have
blue granules in the blood-vessels and scattered through the
connective tissue, but none within any cells. In gross free-
hand sections the epithelium of the stomach and spiral-valve
appears white, in striking contrast with the dark blue connec-
tive-tissue.

2. Suspensions

A. Carmine. Powdered carmine was used for coarse granules,
although some of it seems to go into solution in sea-water. It
will not all settle out on standing, cannot be separated out with
ordinary filter-paper, and will even pass through a celloidin
membrane. After passing through celloidin no granules can be
seen with the ordinary microscope. This may not be in true
solution, but if not it is practically so.

1. Filtered carmine after settling for several days was inj jected
intravenously into an adult male dogfish. The animal received
four daily doses of 12 ec. each and was autopsied eight hours
after the last injection. Microscopic examination of the various
organs failed to show the presence of any carmine granules,
although the spleen appeared distinctly red after fixation. The
granules were either too small and too much scattered to be
seen or else the carmine was in solution and washed out in pre-
paring the sections. The urine was not collected.

2. Ten adult animals were injected intravenously each with
10 ec. of a heavy suspension of powdered carmine in sea-water
and autopsied after various periods as follows: 14, 63, 21, 24,
50, and 96 hours. This carmine was not filtered. Pieces of the
various organs and tissues were fixed in formalin, sectioned in
paraffin, and stained with haematoxylin, or examined unstained.

Urine was collected from several of the animals, but in only
ohe specimen of it was any carmine found, and in that but one

REACTION OF SELACHII TO INJECTIONS 109

granule. This sample of urine also contained a few blood cor-
puscles and hence the carmine probably entered with the blood.

Microscopical examination. a. Digitiform gland. Carmine
is present in the endothelium and leucocytes of the blood-vessels
in this gland in all stages, but very little in the first (14 hours),
and less in all the sections than in the endothelium of the kid-
ney, liver, spleen, and gills. In the 21-, 24-, and 50-hour speci-
mens there is an occasional carmine granule seen in the cyto-
plasm of the tubules. These few granules may possibly have
been dragged into the cells in the cutting of the sections and in
any case are too few in number to be of any importance. None
was seen in the lumen of the tubules.

b. Kidney. In the first two stages there is considerable
amount of free carmine in the capillaries, much of it in large
clumps filling the entire vessel, and a few leucocytes and endo-
thelial cells contain carmine granules.

In later stages (21 to 96 hours) there is a gradual decrease in
the amount of free carmine in the capillaries and there are no
large masses of it present. There is a decreasing amount seen
in the leucocytes and endothelium. A few sections have ear-
mine granules in the connective-tissue cells. In only three
tubules of the hundreds of sections examined are carmine gran-
ules to be seen in the cytoplasm. These few granules may have
been carried in, in the preparation, and as in the digitiform gland
are considered to be of no practical significance. Each of two
tubules of one section contained a granule in the lumen, but
one also finds blood corpuscles occasionally in the tubules and
these carmine granules may have entered accidentally.

c. Liver. Carmine granules are seen in all stages after the
first, in the leucocytes and endothelial cells of the sinusoids, in
the hepatic cells, and in the normal pigment accumulations,
which are very abundant in the liver of the dogfish.

Carmine was found in the bile in all stages after the first, as
free granules, in cells resembling leucocytes and mixed with
the normal pigment.

d. Spleen. Carmine is present in all the sections of spleen
examined and in decreasing amounts in later stages (fig. 1).

110 E. R. HOSKINS AND M. M. HOSKINS

In all stages carmine may be seen as granules free in the sinuses,
and ingested by the endothelium of the sinuses and by splenic
cells. The insert in figure 1 shows an endothelial cell that has
extended a pseudopodial process and engulfed a very large
granule. The figure also shows an endothelial cell filled with
carmine and apparently about to be liberated as a free phago-
cyte (macrophage?). In many places the ingested carmine
seems to be enclosed in vacuoles.

There is a decided increase in the number of mitotic figures
seen in the spleen beginning with the 21-hour stage, indicating a
leucocytosis.

e. Spiral-valve and stomach. In these organs there is an
occasional phagocyte in the capillaries that contains carmine.
There is no carmine outside the vessels.

f. Gills. The large sinuses which are interposed between the
branchial arterial arches and the capillaries in the filaments are
lined with an endothelium which is very phagocytic. This will
be described in detail under ‘Trypan blue.’ In the earlier stages
the gills were not examined, but sections of later stages (50 and
96 hours) show the endothelial cells of the sinuses to be en-
gorged with carmine granules. Many of these cells have also
been ‘budded off’ and lie in the channel as free phagocytes.
This endothelium is doubtless one of the sources of circulating
phagocytes in the dogsfish.

Even the arterial arches are lined with phagocytic endothelium
especially along the side next to the sinuses.

g. Heart. The 13-hour stage shows a few cells of the endo-
cardium that are phagocytic to carmine. The heart in other
stages was not examined.

h. Blood. In all stages the blood contains free carmine and
granules ingested by phagocytes. The number of free granules
decreases in the later stages.

B. Neutral red. Two series of experiments were conducted
with neutral red and to some extent with different results. In
1916 the sample of neutral red used seemed to form a true suspen-
sion, as it could all be separated from the water with ordinary
filter-paper.

REACTION OF SELACHII TO INJECTIONS 111

1. An adult received intravenously 10 ec. of suspension of
neutral red and was permitted to swim about in the aquarium.
At that time the animal was immobilized, received an addi-
tional 18 ce. of the suspension, and .its urine was collected for
five hours without any of the neutral red appearing in it. Au-
topsy showed the bile to be reddish brown. This turned orange
with alkali and dark lilac with acid. Serum gave a similar
reaction, but the gastric fluid was negative. The suspension
was prepared by stirring neutral red in sea-water and allowing
the mixture to settle.

2. An adult was injected intravenously with 15 ee. of satu-
rated neutral red suspension. The urine was collected for six
hours and was at all times free of the dye. Autopsy showed
neutral red in the bile in a considerable amount.

3. A female received intravenously, 10 ce. of the neutral red
suspension and the urine was collected for eight and a half
hours without any of the dye appearing in it. As above, it was
present in the bile.

The two following experiments were carried out a year later
- than the former, with a different sample of neutral red. This
could not all be removed by filtering and part of it even passed
through a celloidin sac, so that it probably was partly in
solution.

4. Ten ec. of filtered neutral red in sea-water was injected
intravenously into an adult fish. Four hours later, examination
showed the dye to be in both the bile and urine, but not in the
stomach or spiral-valve contents.

5. Eight ec. of the dye in the above form was injected intra-
venously into an adult dogfish. There was 24 ee. of bright red
urine collected in twenty-four hours, and at autopsy 2.5 ec of
reddish-brown bile was removed from the gall-bladder. The
24 ce. of urine was diluted to 100 ec. with water and the 2.5 ce.
of bile to 200 ce. Maximum redness was produced by neutral-
izing, and the color of the two were then of about the same
intensity. Thus the total excretion of the dye by the liver was
more than eighty times as much as that excreted by the kidney.
The total amount of dye removed by the liver was not collected

hi? E. R. HOSKINS AND M. M. HOSKINS

because some escaped with bile into the intestine. The neutral
red in the urine appeared to be in solution when examined under
the microscope, whereas some, at least, of that im the bile was in
granular form. Before the filtered neutral red was injected it
appeared to have only very minute granules, smaller than those
in the bile, so that in passing through the liver, granules must
have collected together. Denis (’12) found the urine acid to
litmus, but neutral red excreted in it retained its red color. ©

C. Congo red. The Congo red used could easily be removed
by filtration or settling and would not pass through a celloidin
membrane.

1. Two adult dogfish received intravenously each 5 cc. of a
heavy suspension of Congo red in sea-water. After twelve
hours the urine was still free from the dye, as was the stomach
and spiral-valve contents. A considerable amount was present
in the bile.

2. A young fish (0.25 kg.) received doses of Congo red of 12
ee. and 18 ec., respectively, on two successive days and was
autopsied forty-eight hours after the first injection. The liver
and spleen were stained deeply with the dye, but the other
organs of the body cavity appeared practically normal in color.
The gills were not examined. A large amount of the dye was
present in the bile, a small amount in the spiral valve, and a
trace in the stomach. The dye in the spiral valve entered with
the bile probably entirely and that in the stomach probably was
regurgitated from the spiral-valve.

D. Trypan blue. Trypan blue was used primarily in studying
the excretory function. Its action as a vital stain, although
not exhaustively studied, will be considered also from the data
we have, because the reaction in selachians seems to be in some
ways different from that in teleosts as described recently by
Wislocki (17). A brief review of our results with this dye has
been published (Hoskins and Hoskins, 718).

1. An adult male was injected intravenously with 9 ce. of a
2 per cent suspension of filtered trypan blue in sea-water. Four
hours later the animal received 6 cc. more. Fifteen hours later
another injection of 6 ec. was made. Autopsy was performed

REACTION OF SELACHII TO INJECTIONS 113

thirty hours after the first injection. The urine was examined
several times and was free of dye until nearly the time of au-
topsy, when a trace of the red portion (Wislocki, ’17) was pres-
ent. The bile contained a considerable amount of the whole
dye. It was also recovered from the serum, but not from the
stomach or spiral-valve contents. The liver and spleen were of
a slightly darker blue color than the other organs, but all of the
organs as well as the skin and peritoneum appeared slightly
colored by the dye.

Microscopical examinations were made of the digitiform
gland, kidney, liver, spleen, spiral valve, stomach, skin, and mus-
culature. All of these retained their blue color after fixation as
seen in gross specimens, but blue granules are found under the
microscope, definitely, in only the endothelium of the liver and
spleen. The stain in the other organs and tissues is either too
diffuse to be seen microscopically or else was all free in the blood-
vessels, and hence washed out in preparing the sections.

2. A young fish (0.25 kg.) was given four daily intravenous
injections of 3 cc. each of the above-mentioned trypan blue,
and was autopsied five days after the first injection. The dye
was found in considerable amount in the bile and serum and
was also present in the spiral-valve, but not in the stomach
contents. The liver and spleen were very dark blue in color as
were the gills at the base of the filaments. The skin was dark
blue before fixation, but light blue afterwards. The digitiform
gland, spiral valve, post valvular intestine, peritoneum, and
fascia of the muscles were light blue in color, the stomach was
still lighter, and the kidney, except the peritoneal covering and
connective tissue, was practically normal in color.

All these organs except the first three were of a lighter shade
after fixation than before, owing doubtless to loss of blood which
contained trypan blue.

Microscopical examination. a. Digitiform gland. Most of
the dye is too diffuse to be located microscopically. A few
leucocytes and endothelial cells of the capillaries of the paren-
chyma and serosa contain blue granules and one cell of a tubule
contains eight such granules in a vacuole, but the amount of

114 E. R. HOSKINS AND M. M. HOSKINS

the dye detectable in this organ is too small to be of practical
importance.

b. Kidney. Microscopically, the dye can be seen in only a
few leucocytes and endothelial cells of the capillaries.

c. Liver. The liver contains most of the fixed trypan blue in
the entire body. This organ is relatively large and in almost
every cell in a large number of sections examined there are from
five to twenty blue granules of different sizes (fig. 2). In places
the granules appear to be in vacuoles. A rather large number of
endothelial cells of the sinusoids likewise are seen to contain the
dye. In figure 2 one such is seen nearly separated from the wall
of the vessel and so full of stain that the nucleus is barely visible.
In the liver of the dogfish there is a relatively large amount of
normal pigment both in the sinusoids and in the parenchyma,
collected into large masses. These black granules are often
found in phagocytes. The large mass shown in a sinusoid in
figure 2 is made up both of this black pigment and trypan blue
granules. These black pigment masses may be found in the
bile normally, and in the present experiment both black masses
and masses of both blue and black granules were seen. There
were found also in the bile many blue granules free and in es-
. caped cells which are present also in normal bile. All the
granules shown in figure 2 in the hepatic and endothelial cells
and in the leucocyte are trypan blue. The mass at x is mostly
normal black pigment.

d. Spleen. <A free-hand section of the spleen showed the dye
to be scattered uniformly through the tissue. The specimen
was not examined microscopically, but nearly every cell must
have ingested the dye.

e. The spiral valve, stomach, postvalvular portion of the
intestine, muscles, and skin were still light blue in color after
being embedded in paraffin, but under the microscope definite
blue granules can be seen in only a few free phagocytes in the
blood-vessels. A free-hand tangential section of the tegument
was cleared in oil, but the dye present was too diffuse to be made
out after clearing. The pigment in the melanophores was all
black and the subcutaneous vessels were colorless.

3

REACTION OF SELACHII TO INJECTIONS 115

f. Gills. The sinuses which intervene between the arterial
arches and the capillaries in the filaments, as described in the
experiments with carmine, are lined with endothelium very
phagocytic to trypan blue. The dye is in greater concentration
in these cells than in any others examined. In some sinuses
(figs. 3 and 4) every cell is engorged with the dye. Even in the
large artery (fig. 3) a few of the endothelial cells contain blue
granules. In figure 4 the cells and nuclei have rounded. Many
are nearly detached or are lying free in the sinus ready to move
with the blood stream as circulating phagocytes. Some of the
granules in the cells seem to be contained in vacuoles, although
the fact is not shown in the drawing. Most of the granules
shown are trypan blue, but two cells marked ‘2’ contain also
some normal black pigment. In some cells the dye completely
hides the nucleus. Practically all the sinuses examined are
completely lined with eells filled with trypan blue, but a few
sinuses are unstained.

A few cells in the capillaries contain blue granules. The
epithelium covering the filaments does not contain trypan blue,
although some investigators have suggested that the gills may
excrete other substances besides gas.

‘ 3. Excretory toxins

A. Potassium chromate. 1. An adult dogfish received intra-
muscularly 150 mg. per kg. body weight of potassium chromate
in a 1 per cent solution. Autopsy was performed after thirty
hours and when the animal was moribund.

The kidneys and spiral valve were greatly congested, the
latter containing a bloody fluid. Other organs appeared to be
normal at autopsy.

2. An adult received intramuscularly 75 mg. per kg. body
weight of potassium chromate in 1 per cent solution. Autopsy
was performed after twenty-four hours while the animal was
still active. The amount of toxin injected was less than that
which Denis (714) found to be necessary to kill a dogfish. In
this specimen all the organs appeared normal except the spiral
valve and kidney, which were slightly congested.

116 E. R. HOSKINS AND M. M. HOSKINS

3. Four adults were injected intravenously with 100 mg.
per kg. body weight of potassium chromate in dilute solution,
to study the effect of sudden intoxication. Every one of the
four died in a short time, varying from a few minutes to three
hours, although they received much less toxin than is necessary to
kill them if it were injected intramuscularly and slowly absorbed.
In each of them at autopsy the blood was brown and ‘granular’
in appearance, showing that the erythrocytes had been destroyed
and the haemoglobin oxidized by the chromate, which is a com-
monly used oxidizing reagent.

Microscopical examination. a. Digitiform gland. This or-
gan in animal ‘1’ is severely congested (fig. 10), but there is
no great increase in the relative number of leucocytes. The
central venous sinuses are greatly distended with blood. At
the periphery most of the tubules have undergone vacuolar
(hydropic) degeneration (figs. 11, 12, 13), which in some places
is complete. Here the epithelial cells are cytolysed and the
nuclei shrunken and darkly stained and in some cases are
pyknotic. A few nuclei, on the other hand, are swollen and
hypochromatic.

The area of extreme degeneration is about one-twelfth as wide
as the radius of the gland. In a narrow strip, internal to this
area, there is a gradual transition to normal condition, the cells
exhibiting varying degrees of cytolysis and pyknosis or karyol-
ysis. Scattered through the remainder of the gland are indi-
vidual tubules showing mild cellular degeneration. It should
be noted that in normal animals a few cells occasionally are
degenerate, probably from cell inanition, (a term applied by
Jackson (’16) in a study of the thyroid).

Cellular debris containing degenerated nuclei may be seen in
some tubules and in the central lumen of the gland.

The erythrocytes in the digitiform artery appear normal, but
in the central sinuses all appear granular and some are com-
pletely broken down.

2. The digitiform gland in the second animal was not injured
by the potassium chromate.

REACTION OF SELACHII TO INJECTIONS 117

b. Kidney. 1. The kidney in the first two animals is severely
congested. Capillaries are dilated in the glomeruli and among
the tubules. Erythrocytes show signs of degeneration. The
glomeruli are not destroyed, but are probably somewhat injured.
Many of their nuclei (fig. 6) are either hypochromatic or hyper-
chromatic and an oceasional vacuole is seen in the capsule.

Two distinct types of degeneration are seen in the tubules of
this specimen and a third type in the second animal. These two
types we may call granular and hydropic (vacuolar), and of
these, the former greatly predominates.

The granular degenerative process occurs as follows: Tirst the
cytoplasm loses its network appearance (fig. 7) in which the
granules are very small and brightly stained with eosin. The
granules become dull and adjacent cell walls disappear and
finally the cytoplasm breaks through into the lumen. At the
same time the entire tubule may shrink in places and pull away
from its connective-tissue capsule. The degenerated mass of
cytoplasm may spread and lose all shape (fig. 9). While these
processes are occurring the nuclei are degenerating in the follow-
ing manner. Most of them shrink, becoming hyperchromatic,
and stain poorly. The chromatin may become merely a dull
mass (fig. 8). The nuclei may shrink to nearly invisible size.
In some tubules the nuclei degenerate differently. These grad-
ually swell, becoming hypochromatic, and then undergo com-
plete karyolysis. Both kinds may be seen in the same tubule.

The hydropic type of cellular degeneration is that in which
vacuoles appear in the cells which gradually undergo cytolysis.
The cytoplasm at first undergoes slight granular degeneration.
In these cells the nuclei may undergo either hyperchromatosis
or karyolysis. There is relatively little hydropic degeneration
present in the chromate nephritis and it will be described later.

Destruction of epithelium is largely confined to the thick-
walled secretory tubules of the posterior region of the kidney,
where nearly every such tubule shows signs of degeneration.

There is an increase in the number of leucocytes present
in the degenerated areas.

THE JOURNAL OF EXPERIMENTAL ZOOOLGY, VOL. 27, NO. 2

118 E. R. HOSKINS AND M. M. HOSKINS

2. The kidney of the second animal was much less severely
injured than in the first, as was to be expected since it received a
smaller dose and was autopsied sooner

The glomeruli are seen to be very slightly injured, as is evi-
denced by their hyperchromatie and hypochromatic nuclei. A
considerable number of secretory tubules show the beginning of
either granular or hydropie degeneration. Animal ‘2’ shows in
20 per cent of the tubules in the posterior part of the kidney a
third type of nephritis that may be called hyaline. It is not
seen in the kidney of the first animal. In this type there is a
gradual accumulation in the cells of droplets of abright homo-
geneous substance which stains readily with eosin. In extreme
cases the tubule is completely changed into a mere mass of these
droplets. The nuclei may appear normal or hyperchromatic.
The hyaline degeneration will be described later.

e. Liver. There is no serious degeneration in the first animal
and almost none at all in the second. In the former a number
of nuclei are hyperchromatic and in places the cytoplasm stains
poorly. There is a slight congestion in both specimens. The
ducts and gall-bladder are uninjured.

d. Spleen. The spleen was examined microscopically in the
first animal only. It is congested, the capillaries and sinuses
being somewhat dilated. They contain erythrocytes which
appear to be degenerated. In these the nuclei are darkly stained
and the haemoglobin appears granular. Some erythrocytes are
entirely broken down and are shown only as nuclei surrounded
by a few granules. The splenic cells proper and endothelium
are intact but some stain poorly.

e. Spiral valve (figs. 14 and 15). The spiral valve shows sim-
ilar changes in both animals, but the injury in the second is
less severe than in the other.

Both are greatly congested and oedematous. The surface
epithelium has completely desquamated in large patches, espe-
cially where it is most exposed, on the folds of the mucosa (fig.
15). The surface epithelium remaining stains poorly, appearnig
dull, and the nuclei are either hypochromatic or hyperchromatie.
A few cells are cytolysed. The epithelium in the bottom of the

REACTION OF SELACHII TO INJECTIONS 119

erypts is nearly normal in appearance. The erythrocytes in the
spiral valve of the first animal show considerable injury, but
those in the second do not.

f. Stomach. The stomach is not seriously injured in the first
specimen and not at all in the second. In the former there is
slight congestion, the surface epithelium contains a few hyper-
chromatic and a few hypochromatic nuclei and the deepest
glands show slight cytolysis in a few cells.

g. Blood. As indicated above, severe injury to erythrocytes
is done with potassium chromate. In some of the vessels of
every organ examined there are degenerated red _ blood-cells,
although in other vessels the cells are normal in appearance.
The injury is greatest in congested areas where the flow of blood
was interfered with. Intravenous injections of potassium chro-
mate lakes the blood rather quickly.

B. Tartaric acid. An adult male received intramuscularly
100 mg. per kg. body weight of tartaric acid and was autopsied
after thirty hours when it was moribund. All of the organs
appeared normal except the spleen, which was pale.

Microscopical examination. a. Digitiform gland. This or-
gan is severely congested, but except for a very slight cytolysis
and hypochromatosis near the periphery there is evidently no
injury to the tubules.

b. Kidney. Nephritis in all regions of the kidney is very
severe. Congestion is marked. The glomeruli are not particu-
larly affected, but have hyperchromatic nuclei. In some trans-
verse sections of the posterior part of the kidney fully 90 per cent
of the secretory tubules and many of the excretory tubules show
signs of degeneration, ranging from mild changes to complete
destruction (fig. 17).

All three types of nephritis are present, but the granular
variety (fig. 19) predominates. Granular nephritis is much the
same as that described in chromate nephritis (see figs. 8, 9, 18,
19, and 20). The destruction in the case of the tartaric acid
nephritis is more complete (fig. 20), and in addition there is
present in the surrounding tissue a very considerable number of
cells with large eosinophilic granules and nuclei of different

120 E. R. HOSKINS AND M. M. HOSKINS

sizes. These granules stain more readily than the tubules.
Some of these cells might possibly be degenerated erythrocytes,
but most of them have nuclei resembling leucocytes and endo-
thelial phagocytes. These cells were found only in this experi-
ment. In places even the connective tissue and blood-vessels
are injured.

Hydropic degeneration is confined largely to the thinner-
walled (collecting) tubules, as may be seen from a careful study
of figure 17. In some of these tubules the cell outline is fairly
distinct and the nucleus nearly normal in appearance, but every
bit of cytoplasm has dissolved out. In other tubules the nuclei
are shrunken and darkly stained and the cell’s walls are indis-
tinguishable. Only a few of the secretory tubules contain
vacuoles.

Hyaline degeneration is confined entirely to the secretory
tubules. In this type the hyaline substance first appears im
very small droplets near the nucleus. The small black dots in
the cytoplasm in figure 17 are of this hyaline substance. The
hyaline droplets gradually increase in size and number (fig. 21).
They finally break through into the lumen of the tubule. Dur-
ing the process the nuclei may shrink and become hyperchro-
matic or swell and become hypochromatic, but they are not so
severely injured as in granular degeneration.

c. Liver. The liver is not greatly congested. The tubules
contain more debris than usual and both hypochromatic and
hyperchromatic nuclei are rather numerous. In the sinuses are
many cells with eosinophilic granules like those seen in the kid-
ney, but in smaller number.

d. Spleen. The spleen itself is uninjured, but contains many
of the eosinophilic cells noted above and also a considerable
number of degenerate erythrocytes and free nuclei. There are
also a few peculiarly shaped nuclei which will be described
below.

e. Spiral valve. The injury done to the spiral valve by the
tartaric acid is about as extensive as in the case of potassium
chromate. Both karyorrhexis and pyknosis are shown in the
epithelium. In the lamina propria of the mucosa there are

REACTION OF SELACHII TO INJECTIONS 121

numerous eosinophilic leucocytes. In sections of the spiral
valve stained together with sections of a normal spiral valve the
chromatin in the epithelial cells of the former which appear
otherwise normal in structure stains much less darkly with
haematoxylin than does that of the normal tissue.

_g. Stomach. The stomach is in about the same condition as
in the ‘chromate’ specimen. There are present in the blood-
vessels and lamina propria numerous eosinophilic leucocytes.

C. Uranium nitrate. 1. An adult received intramuscularly
90 mg. per kg. body weight of uranium nitrate in 1 per cent solu-
tion. It lived forty-four hours and was then autopsied at once.
The spiral valve was greatly congested, but the other organs
appeared normal.

2. A male of 1 kg. received 100 mg. of uranium nitrate as
above. Respiration ceased after two hours, but was restored by
an hour of artificial respiration produced by inserting a tube of
running water into the animal’s mouth. The fish died after
twenty-eight and a half hours and was immediately autopsied.
The spiral valve contained bloody fluid and its mucosa was con-
gested. A few small hemorrhages appeared in the kidney.
No other abnormalities were noted.

3. An adult of 1 kg. received intramuscularly 100 mg. of
uranium nitrate. A cannula was inserted into the bile duct to
prevent any toxin that might be in the bile from reaching the
spiral valve. After five hours the urine was tested and found to
contain uranium nitrate. The next morning the animal received
an additional 90 mg. of the toxin. At 8 P.M. it was still active,
but died in the early morning, about forty hours after the first
injection. The body was not yet rigid at 8 A.M., so tissues
were fixed for microscopical examination, as few postmortem
changes had had time to occur. This was confirmed by the
microscopical examination. The kidneys were congested, but
other organs appeared normal.

4, Hight dogfish of various sizes were injected with 100 mg. to
200 mg. per kg. body weight, of uranium nitrate. A cannula
was inserted into the bile duct to protect the spiral valve from
toxin in the bile. The urine was collected. Uranium nitrate

122 E. R. HOSKINS AND M. M. HOSKINS

was found in the urine, but the color of the bile made it uncer-
tain whether or not the toxin was present there. One animal
receiving 200 mg. of the toxin in two equal daily doses survived
for eighty hours, the others dying in shorter time. Two animals
while still living were noticed to have a bloody discharge from
the cloaca. Autopsy showed that in all the animals the spiral
valve was greatly congested and its mucosa was injured. The
stomach and the postvalvular portion of the intestine appeared
to be uninjured.

Microscopical examination. Sections of the various organs
of the first three animals described above, were examined
microscopically.

a. Digitiform gland. In all specimens there is considerable
congestion and slight cytolysis at the periphery and scattered
through the gland, caused either directly by the toxin or by its
interference with the blood supply, or from both causes. The
injury was not very severe in any case.

b. Kidney. The kidney in every ease is greatly congested,
especially in the posterior region. The glomeruli are not very
seriously injured in these specimens, but in most of them the
capillaries are dilated and the nuclei of the capsule are hyper-
chromatic and shrunken.

Injury to the tubules is confined largely to the secretory
tubules of the posterior portion of the gland (figs. 22, 23, 24, 25).
In the third animal the changes are most severe, due either to
the fact that it received more toxin than the first two animals, or
else to postmortem changes, or to both reasons. In the third
animal nearly every tubule in the posterior region is degenerated
and some have completely disappeared. All three types of
degeneration are seen, but the granular type predominates.
Both hyperchromatization and hypochromatization of the
nuclei are evident. In the former the nucleus gradually shrinks
until it finally disappears (fig. 23). In the latter the nucleus
absorbs water and swells often to two or three times the original
diameter, the chromatin gradually disappearing until the nucleus
looks like a ring. In the third specimen almost every nucleus
has changed from the normal oval to the spherical shape, and

REACTION OF SELACHII TO INJECTIONS 123

most of them have suffered chromatin changes. The blood-
vessels in the kidney of this animal contain a large amount of
debris.

In the first animal there are present in the blood-vessels of
the degenerated region of the kidney many nuclei of a very
peculiar shape (fig. 26). This may indicate an attempt at
amitosis by phagocytes, probably in the spleen and gills. One
cannot make out any cytoplasm, so that if a cell wall is present
it is tightly adherent to the nucleus. On the whole, the kidney
is less seriously injured in the uranium series than in the chro-
mate or tartaric. However, the size of the dose of the toxin
and the time element are probably the most important factors
in the amount of injury produced.

In the anterior region the tubules show no signs of degenera-
tion in some sections, and very few in any. The congestion is
mild as compared with that in the posterior region. A few
tubules stain poorly and their cytoplasm is quite granular.

e. Liver. The liver and gall-bladder are practically uninjured
even in the third animal. In all sections.a few nuclei of the
hepatic cells and ducts are hyperchromatie and shrunken, but
not in more than 12 per cent at most. In the third animal
(which received a large dose and which died before autopsy)
the ducts contain considerable debris, and a few of their cells
are very slightly cytolysed.

d. Spleen. The spleen is congested in every specimen. The
sinuses are dilated and contain granular debris, which probably
has come in from the kidney. The endothelial cells of the
sinuses contain these granules and their nuclei are often swollen
and hypochromatic. In the first animal (fig. 27) there are many
peculiar-shaped nuclei which resemble those seen in the kidney
and gills. Some of these at least are endothelial in origin, as
they can be seen in the cells lining the sinuses. They may
represent abnormal amitosis. Many mitotic figures can be seen
in the spleen of this animal, although they are fewer than when
carmine was injected. The splenic cells proper are not par-
ticularly abnormal in appearance, although a few have hypo-
chromatic nuclei.

i
Se

124 E. R. HOSKINS AND M. M. HOSKINS

e. Spiral-valve. In the first two animals in which the bile
(presumably containing the toxin) was allowed to enter the gut,
the spiral valve showed approximately the same amount of
injury as in the chromate and tartaric experiments. In the
third animal in which the bile was kept out of the intestine the
injury is less extensive than in the others, although there is
some congestion of the mucosa and desquamation of its surface
epithelium. This was true also of other animals which were not
examined microscopically, as stated above (4).

f. Stomach. The stomach in the first two animals resembles
that in the chromate experiments. In the third, the stomach is
practically normal, and the very few alterations observed might
be postmortem in origin, or the result of vascular injury which
causes cell inanition.

g. Postvalvular intestine. That portion of the intestine
posterior to the spiral valve was examined microscopically in the
second animal, and is entirely normal in appearance, although
the spiral valve which empties into it is seriously injured. Its
epithelium is stratified while that of the spiral valve is simple
columnar.

h. Gills. The gills of the first animal were examined and
show some signs of injury. In the sinuses at the base of the
filaments the endothelial cells have rounded as they do when
granules are injected. Here are seen many peculiar nuclei
(fig. 27) such as were seen in the spleen and kidney, some of
which may be found protruding from the endothelium. The
endothelial cells in places are full of dull granules which have
come originally from the blood, or else are formed in the cells by
degeneration. Many free cells are to be found in the sinuses,
indicating a proliferation of the endothelium.

DISCUSSION
1. Digitiform gland

The digitiform gland reacted somewhat as an excretory organ,
but it is not very efficient as such. In this it resembles the
kidney. Its normal secretion collected from three adult dogfish

REACTION OF SELACHII TO INJECTIONS $25

averaged only 0.25 ce. in six hours, or at the rate of 1 cc. a day.
The excretion is alkaline to litmus. It is clear, but contains
bits of mucus. The amount of this excretion is not copious, but
the entire amount produced by both kidneys is only a little over
20 cc. in twenty-four hours. Since the size of the digitiform
gland is much less than one-twentieth of that of the kidneys, its
excretion is relatively greater than the amount of urine given off.
Crawford (’99) obtained urea from the digitiform gland and sug-
gested the possibility of excretory function for this organ.
Hyrtl (58) regarded it as an accessory sex gland, and Blanchard
(82) stated that it is potentially able to aid digestion because an
extract of it splits starch and emulsifies fat. An extract is, how-
ever, not the same thing as a secretion and hence Blanchard’s
conclusion may not be correct. It should be borne in mind that
the product from the gland is discharged into the intestine just
above the cloaca at a place where digestion has doubtless ceased.
Morgera (’16) thought that the digitiform gland has an internal
secretion which causes the intestines to contract, thus aiding in
the passage of substances through the gut, because he found
that passage of food through the intestine was checked by extir-
pation of the gland and restored by the injection of an extract of
it. One must consider that the interference with the passage of
food in these experiments may have been but a temporary dis-
turbance from the operation, that would have disappeared later.
Also, as stated above a glandular extract is not the same thing
as a normal secretion of the gland.

Cushny (’17) believes that urine is excreted by glomeruli
and not by the renal tubules. If the secretion of the digiti-
form gland is a true excretion, then the renal tubules may also
be able to exerete, in which case, Cushny’s theory is incorrect.

We were able to recover in the excretion from the digitiform
gland after injection into the animal two solutions, namely,
potassium iodide and pthalein, but not any of the others used.
The other solutions if present were too dilute to be demon-
strated.. Weed’s solution passed into the cells of the tubules,
as shown microscopically, only in small amounts, although it
was present in the blood-vessels in relatively concentrated form.

126 E. R. HOSKINS AND M. M. HOSKINS

Particulate matter is not taken into the tubules of the digiti-
form gland, except for an occasional granule, even though the
particles are very small. In this the gland resembles the kid-
ney, so the failure to take in granules does not argue against
possible excretory function.

Exeretory toxins caused congestion in all cases, but in only
one animal receiving potassium chromate was the injury to the
tubules very severe. Morgera (’16) obtained cytolysis of the
tubules by cutting off the blood supply, and the congestion noted
in our animals. may account in this way for some of the degen-
eration noticed. One finds occasional cytolysed cells in the
digitiform gland of normal animals. The question of cellular
inanition must be considered in all experimental degeneration
of tissues produced by administered toxins. The toxins we used
certainly were injurious to erythrocytes, and this together with
interference with blood supply in congested organs must deprive
the cells of needed substances.. However, we believe that a
part of the injury seen was caused by the toxins which the
gland was trying to excrete.

2. Kidney

The kidney (mesonephros) of the dogfish is of far less impor-
tance to the animal than the kidney (metanephros) of mammals,
as has been noted previously. Denis (12) found that adults
produce an average of only 21.7 ec. of urine a ‘day, and in our
experiments the greatest amount of urine obtained was 24 ee.
in twenty four hours, from an animal weighing more than 1.5
kg. The urea in the urine amounts to 0.6 to 1.4 per cent, or
less than half the concentration of that in the blood (Baglioni,
706) and less than half that in mammalian urine. This differ-
ence is made up partly at least by a considerable amount of urea
excreted in the bile. The great concentration of urea in the
blood seems to be necessary to preserve life, for Baglioni (’05)
found that isotonic (3.5 per cent) salt solution without urea was
unsatisfactory for perfusion experiments. This requirement
does not account for the small amount of urea excreted, as has

REACTION OF SELACHII TO INJECTIONS 127

been argued, because, an equilibrium having been established, all
urea formed would need to be eliminated. Hence if there is
little urea excreted it is because relatively little is formed. The
limited excretion of urea in the urine.is dependent upon the
metabolism, which must proceed at a slow rate in these forms,
and also upon the amount of urea excreted in the bile.

MacCallum, in the 1917 Herter Lectures in New York, stated
that the selachians entered the sea when its salt concentration
was less than it now is and that as the sea became concentrated
the selachians retained more and more urea in the blood to
keep it isotonic with the sea-water.

We found that the dogfish kidney is able to excrete injected
solutions quite as rapidly as the mammalian kidney and hence
the inefficiency of the former is not one of rate of excretion, but
of amount and of inability to eliminate certain kinds of sub-
stance. Non-toxic solutions of all kinds when injected into the
muscles of the body wall appeared in the urine in fourteen or
fifteen minutes, and when injected intravenously appeared in
the urine in about eight minutes. In this rate the dogfish com-
pares favorably with mammals. (Rowntree and Geraghty, ’12).
The dogfish kidney would probably eliminate all of an injected
solution in time, if it were not for the fact that the liver quickly
eliminates the larger part of it. The liver is many times larger
than the kidneys and has taken over much of the excretory
function. As noted above, when pheno-sulphonepthalein was
injected, the liver excreted in a given time more than twice as
much of it as did the kidneys, and in concentration many times
greater. However, the difference in amount excreted by the
two organs was less than the relative difference in size by which
the liver surpasses the kidney.

Colored solutions stained the posterior part of the kidney
more intensely than the anterior end, thus demonstrating the
fact that in the former the excretory function is better developed
than in the anterior or sexual (Felix, ’12) end. The anterior
region is able to excrete some part of solutions injected, so it is
not entirely devoid of excretory function, as some investigators
have believed. This point should be studied further. The

128 E. R. HOSKINS AND M. M. HOSKINS

ability of the urine to reduce copper sulphate after sucrose had
been injected demonstrates that the selachians can invert this
sugar as mammals do (Kuryama, 716).

The dogfish kidney was not stained vitally by injected sus-
pensions of various dyes, since they were not removed from the
blood by the kidney, at least up to five days’ time, even when
administered in very considerable amounts. There was no
difference in this respect between the reaction to very minute
particles (trypan blue) or coarse granules (powdered carmine).
One sample of neutral red passed through the kidney and one
did not do so. The first probably formed a true solution. At-
tention of investigators should be called to the fact that some
differences they obtain in the use of vital dyes in experiments
may well be due to differences in the manufacture of these
substances. Colloidal dyes, if impure, may be soluble.

The inability of the kidney of dogfish to remove particulate
matter from the blood is another difference between this organ
and the kidney of higher animals, as shown in the very numer-
ous experiments of Chrzonszezewski (’64), Siebel (’86), Schmidt
(91), Museatello (95), Buxton and Torrey (’06), Suzuki (12),
Héber (714), Kiyono (714), Evans-Schuleman (’14), Downey
(17), and many others.

In higher animals the renal epithelium and sometimes the
cavity of the glomerulus may be seen to contain particles that
have been injected, but in the dogfish, if such matter is present
in the kidney parenchyma or glomeruli, it is much too diffuse
to be detected in our preparations. The only dye which really
stained the kidneys in our animals was indigo-carmine, and
this appeared to be in solution. Fresh kidney tissue was not
examined microscopically in the trypan blue experiments, but
it probably contained the pink substance that Wislocki noted
in teleosts, as the urine was pink.

The endothelium of the renal capillaries in the dogfish is but
poorly able to ingest particulate matter from the blood as com-
pared with that of the renal portal vessels of teleosts, as described
by Wislocki (17). Wislocki found that this endothelium becomes
blue from ingested dye after injections of trypan blue, while in our

REACTION OF SELACHII TO INJECTIONS 129

animals up to five days only an occasional one of these cells
was able to take in visible amounts of carmine or trypan blue.
It is possib’e that after a greater length of time this endothelium
in dogfish would react as does that of teleosts toward trypan
blue. Wislocki also found a small amount of dye in the epithe-
lium of the kidney in teleosts. This he believed might have
been resorbed from the urine. Previous investigators have
agreed with him (Cushny, ’17). He also implies that the
endothelium of the vessels in the kidney developed from the
aorta is not able to take in and store trypan blue, but it is
difficult in microscopical sections to distinguish the efferent
glomerular vessels from renal-portal vessels.

Wislocki suggests three possible functions of the renal-portal
endothelium in the kidney which he calls a mechanism. The
first function is to prevent loss of colloidal metabolites, thus
accounting for the relatively low output of nitrogen in fish
urine, but the real reason for this is probably in the slow rate of
metabolism in fish and a large output of nitrogen in the bile.
The second function Wislocki attributes to the renal-portal
endothelium is to protect the animal from toxic substances, but
in an animal not being experimented on, any toxic substances
present would more likely be in solution than in suspension, and
solutions pass freely through the kidney. The third function.
referred to is a resorption of substances from the urine, but the
reaction to trypan blue does not prove any such function, as it
has not been shown that in these experiments the endothelium
in question absorbed dye in this way. The possibility of such
resorption of dyes has been considered previously, as noted
above. All that Wislocki’s experiments actually prove is that
the endothelium of the renal vessels is phagocytic, but not very
permeable, if permeable at all, to particulate matter.

The liver excretes particles freely, but whether such function
failed to develop in the kidney because of this fact or whether
the inability of the kidney to excrete particulate matter forced
the liver to develop the function cannot be determined. Nor-
mally, particles in the circulation which are to be eliminated are
mostly bile pigments which of course need not go into the urine.

130 .E. R. HOSKINS AND M. M. HOSKINS

The effects of excretory toxins on the kidney in dogfish are
somewhat the same as in mammals, as described by Ophuls
(08, ’11), Schlayer-Takayasu (’09), Suzuki (12), Pohl (12),
Dickson (712), Christian-O’Hare (713), Underhill-Blatherwick
(14), Potter-Bell (715), Tribe-Hopkins-Barcroft (16), and
various others who administered potassium chromate, tartaric
acid, and uranium nitrate. Denis (’13) noted that dogfish can
withstand many times as much potassium chromate and ura-
nium nitrate as will kill a mammal, and we can add tartaric
acid to the list. One of our fish which received 200 mg. per kg.
body weight of uranium nitrate lived for eighty hours. In
extreme cases the dogfish kidney shows nearly complete destruc-
tion of the tubules by these poisons. The blood-vessels usually
are not noticeably injured, but severe congestion occurs. The
glomeruli, as in mammals, are injured only slightly when at all.
Three distinct types of degenerative processes in the tubules are
produced by all three of the toxins used. The deposit of hyaline
substance in renal tubules in mammals after injection of tartaric
acid was noted by Underhill-Blatherwick, and Christian-O’ Hare
found it in blood-vessels after uranium poisoning. Granular
degeneration is probably a constant type in all such experi-
ments, and hydropic degeneration usually but not always occurs
with it. In our specimens there is some vacuolization in the
cells showing the former type of degeneration, but some cells
undergo cytolysis without first passing through granular change.
The reason for these three different kinds of degeneration is not
apparent. All three types were present in the same animal in
some of the experiments and often two could be seen in a single
tubule. They are not simply different steps in one and the same
process as a study of the accompanying figures easily shows.
In the hyaline type a definite new substance is formed. There
are two distinct types of nuclear degeneration m our experi-
ments with nephritis and they are exactly opposite in nature.
In one type the nucleus absorbs water, swells to two or three
times its normal size, and the nuclear substances gradually go
into solution, while in the other type the nucleus becomes opaque
and shrinks until it completely disappears. This shrinkage is

REACTION OF SELACHII TO INJECTIONS 131
gradual at times and the nucleus retains a regular outline, but
in other cases the loss of karyoplasm is sudden and the nuclear
membrane collapses and is then irregular. Both types of nu-
clear degeneration are found in all the specimens examined and
both may occur in the same tubule.

The cellular changes which one observes in nephritis are
doubtless due to cellular inanition as well as to poisoning of the
cells. Jackson (’16) has described some of these changes in the
thyroid of starved rats. Congestion of the organs and injury
or destruction of erythrocytes interferes with the general metab-
olism of the cells, thus bringing about inanition changes.

Differences in the process of degeneration in different cells
and nuclei in nephritic kidneys may be influenced by their
sudden or their slow death.

3. Liver

The liver of selachians and probably of other fish is a very
important excretory organ, although Pillet (90) stated that its
biliary function is not well developed. Denis (’13) stated that
the liver of dogfish apparently has an excretory function, but
did not give any reasons for the belief. The liver, like the other
organs of selachii contains a large amount of urea (Staedler-
Frerichs, *58). v. Schroeder (’90) stated that this amounts to
1.36 per cent of the entire liver substance. Heidenhain (’83)
found urea in the bile of selachians, Hammersten (’97) stated
that it occurs there in large amounts, and Van Slyke-White
(11) determined the concentration of urea in the bile to be 1.7
per cent. This is greater than that in the urine (Baglioni, ’06),
and more than half as great as that in the blood (2.6 per cent,
v. Schroeder, 90).

All the non-toxic solutions we injected were recovered in the
bile. A quantitative determination of the relative amount of an
injected solution (pthalein) excreted by the liver showed that
there was present in the gall-bladder five and a half hours after
injection three times as much pthalein as had been excreted in
the urine. Some pthalein had escaped with bile into the intes-
tine and some was still present in the bile ducts. In mammals

132, E. R. HOSKINS AND M. M. HOSKINS

the kidneys normally excrete nearly all of such injected pthalein
in four hours and very little appears in the bile at all (Rown-
tree and Geraghty, 712). In mammals with tartrate nephritis,
or with their renal veins ligated, injected pthalein is excreted by
the liver (Underhill-Blatherwiek, ’14).

All of the injected granular dyes appeared in the bile in con-
siderable concentration, and were not excreted by any organ
other than the liver, so far as determined. Siebel (’86) believed
that frogs and dogs receiving injections of carmine excreted
such particles through the liver, lungs, and tonsils, and Kiyono
(14) and numerous other investigators have found that mam-
mals excrete lithiuin carmine through the kidney.

In our experiments one sample of neutral red appeared after
injection in both the urine and bile, but its concentration in the
latter was more than eighty times as great as in the former. It
is believed that some of this neutral red was in solution and that
it was this part which passed through the kidney. The liver was
able to excrete the dye both in the dissolved and in the granular
form. Another sample of neutral red was excreted only in the
bile.

Trypan blue after injection into dogfish collects in the hepatic
parenchyma and the cells lining the sinusoids. Wislocki (717)
noted this also. It is exereted freely into the bile. In bony
fishes Wislocki found that trypan blue entered the bile, but
was not stored in the liver cells. He thought that it diffused
directly into the bile ducts from the blood-vessels but more
probably it passed through the liver cells too diffusely to be
seen under the microscope.

In the dogfish there is present normally in the liver and bile
a very large amount of bile pigment (Pillet, 90) and after injec-
tion of trypan blue some of the masses of pigment seen in sec-
tions of the liver contain both trypan blue granules and normal
pigment mixed together. ‘These masses of mixed pigment may
be seen in the bile also, thus showing that the excretion of par-
ticulate matter by the liver is a normal function and is not due
merely to experimental conditions. Experimenters are often
inclined to overlook the fact that results they obtain do not

REACTION OF SELACHII TO INJECTIONS 133

necessarily portray normal functions, because their experiments
place their animals under abnormal conditions.

Excretory toxins usually caused congestion of the liver, but
not serious injury to the parenchyma. We did not prove abso-
lutely that the toxins passed through the liver into the bile, but
we believe that they did so because all the other solutions and
suspensions were recovered in the bile, and because the liver
itself was injured by the toxins. Tests were made for uranium
nitrate, but the green color of the bile prevented our determining
Whether the injected toxin was present or not. Injury to the
liver was indicated by relatively few hyperchromatic shrunken
nuclei and an increased amount of granular débris in the bile
ducts. In none of the sections examined did more than 12 per
cent of the nuclei appear injured. If the liver is able to elirai-
nate excretory toxins, as it probably does, and without serious
injury to itself, we must agree with Denis (’13) that this helps
explain why dogfish are able to withstand large doses of such
poisons.

4. Spleen

The spleen in the experiments with Weed’s solution was seen
to be impregnated with Prussian blue granules. This indicates
that the vessels open directly into the pulp or else that the endo-
thelium is very permeable to solutions because relatively more
Prussian blue was found in this organ than in other non-excre-
tory organs. The spleen of the dogfish seems to be very well
adapted for phagocytic activity, although Wislocki (’17) believes
that such is not the case in bony fishes.

Injected granules of dyes are taken up very quickly by the
spleen which thus becomes deeply stained. In this respect it is
equaled only by the liver. Injection of particulate matter was
followed by a leucocytosis, and the number of mitotic figures
seen in such cases is greatly increased.

Toxins caused congestion in the spleen in most specimens.
In one uranium nitrate experiment there were present in the
spleen a very large number of peculiar-shaped nuclei. These
are found only occasionally in the other specimens. They

THE JOURNAL OF BXPERIMENTAL ZOOOLGY, VOL. 27, No. 2

134 E. R. HOSKINS AND M. M. HOSKINS

probably indicate an abnormal attempt at leucocytosis by
amitotie division.

Other masses of lymphoid tissue were not examined, but they
probably are phagocytic to dye granules.

5. Spiral valve and postvalvular intestine

Denis (’13) mentions the possibility of an excretory function
possessed by the intestine of dogfish. Several of the solutions
and dyes which we injected were found later in the spiral valve.
However, these entered the intestine partly if not entirely in
the bile. With Weed’s solution Prussian blue was not deposited
in the epithelium nor were any granules of injected dye found in
it. Potassium iodide was obtained in the spiral valve after ni-
jection, but this will go through almost any gland and is not a
specific test. Indigo-carmine did not stain the epithelium, nor
could it be detected in the contents of the spiral valve. Experi-
ments in which solutions of various kinds, including dyes, are
injected, should be performed with dogfish in which bile is pre-
vented from entering the intestine. We hope to do this at a
later date. The toxins injected caused severe injury to the
spiral valve whether the bile was permitted to enter the intes-
tine or not. In every case there was severe congestion and
destruction of a considerable amount of the epithelium. The
capillaries in the mucosa ruptured producing hemorrhage into
the intestine. These vessels were injured probably more that
those in any other organ, although there was some vascular
injury in the kidney. The spiral-valve contents were tested for
the toxins that had been injected, but even with small amounts
of blood and bile present the tests were not sufficient to deter-
mine the presence of the toxins. Probably more delicate tests
would be successful. Our not finding some of the injected solu-
tions in the spiral-valve contents also was due possibly to tests
not sufficiently delicate. While the injury of the spiral valve by
excretory toxins does not absolutely prove that this organ has
normally an excretory function, it tends to support the theory.
The fact that intestine posterior to the spiral valve was not
injured at all by the injected poisons adds evidence in favor of
this theory.

REACTION OF SELACHII TO INJECTIONS 135

6. Stomach

A few solutions and one granular dye were recovered in the
stomach, but the possibility of regurgitated bile was not elimi-
nated as should have been done. Weed’s Prussian blue was
not deposited in the epithelium of the stomach nor were any of
the injected dyes. The excretory toxins caused slight conges-
tion of the stomach in some cases and in a few specimens the
surface epithelium stained poorly. A small amount of cytolysis
was present in some cases, but the slight damage noted in the
stomach might have been done by toxin regurgitated from the
intestine or by cell’ inanition resulting from vascular injury.
Regurgitation is often observed.

Cecil-Weil (’17) found that after injection of Congo-red into
patients with gastric ulcers it could be recovered in the stomach
contents, but they admitted the fact that it is excreted in the
bile and they did not eliminate the possibility of regurgitation
of bile into the stomach. The stomach in selachians appar-
ently is able to excrete only a few injected solutions, and is
probably not normally an excretory organ of any importance,
if it has this function at all.

7. Gills

In the experiments with non-toxic solutions the gills were
examined in only those animals receiving Weed’s solution. In
these specimens Prussian blue was found in the blood-vessels
of course, but there was none in the epithelium covering the
gills nor in the connective tissue. This argues against the
theory that the gills can excrete solutions. Since the gills are
bathed by the isotonic sea-water, it would seem natural that
solutions might diffuse into it from the branchial vessels, but we
have no evidence that this occurs.

Granular dyes are ingested freely by the endothelium which
lines the sinuses that are interposed between the arterial arches
and the capillaries in the gill filaments. It is also ingested by
the endothelium of the branchial arteries. In fact, in these
cells of the gill sinuses the phagocytic function seems to be

136 E. R. HOSKINS AND M. M. HOSKINS

more highly developed than in any other cells in the entire
body. They are described in a previous section (see ‘Experi-
ments’). These cells lining the sinuses are one of the sources
of free phagocytes which circulate through the body. Wislocki
(17) does not mention these cells in his discussion of endo-
thelial phagocytes in fishes. He states that in no endothelium
in fishes has trypan blue been seen except in the lymphaties,
renal- and hepatic-portal vessels, and splenic sinuses. He appar-
ently would use trypan blue to distinguish between blood-vas-
cular endothelium (other than ‘specialized’ endothelium of the
kidney, spleen, and liver) and lymphatic endothelium. He also
would use trypan blue to solve the problem of the origin of
lymphatics in fishes. We do not believe that trypan blue or
other particulate substances can be used in this way. It is
highly probable that more extensive research would disclose the
fact that the endothelium in various blood-vessels, both arterial
and venous, in different parts of the fish’s body, is able to ingest
trypan blue. The rate at which the dye moves through the
vessels is probably one of the most important factors in this, as is
believed by Downey (17). This could be tested by decreasing
the rate of blood flow in different vessels with ligatures or other
means. Downey ('17) stopped the blood flow completely and
found that the leucocytes could then ingest dye granules.* In an
attempt to distinguish between lymphatic and blood-vascular
endothelium from the ingestion of trypan blue, one should not
set aside all blood-vascular endothelium that is phagocytic to
the dye as ‘specialized endothelium.’

Cells in general react toward trypan blue as they do toward
other small particles in the circulation and it is not to be used
as a specific cure-all for our angiological troubles. Arey (17)
and Downey (717) have pointed out several ways in which the
use of trypan blue has been overdone.

In our experiments the sinuses in the gills were affected by
toxins in somewhat the same way as those in the spleen. There
was a proliferation of the endothelium to produce free phago-
cytes. Some of these cells stain poorly and in some the cyto-
plasm is coarsely granular. There are present in one specimen

REACTION OF SELACHII TO INJECTIONS iBys

poisoned with uranium nitrate, peculiarly shaped nuclei like
those found in the spleen which probably indicate an abnormal
amitosis.

8. Body wall (muscles, skin, and peritoneum)

In these tissues dyes were recovered only in the blood-vessels
and connective tissue where an occasional phagocyte is seen.
These tissues were not injured by the toxins so far as could be
determined.

9. Vascular system

This system has already been discussed in part. Leucocytes
and fixed phagocytes of endothelial and tissue origin were seen
to contain trypan blue and carmine granules. Carmine was
found ingested by endothelial cells lining the heart. Fixed
phagocytes in the spleen, kidney, and gills apparently are injured
by circulating toxins. Phagocytes containing carmine were found
in the circulating blood within two hours after injection of the dye.

The blood-vessels of all the organs examined were congested
by the excretory toxins injected, the most severe congestion
occurring in the digitiform gland, kidney, and spiral valve.
All three toxins—potassium chromate, tartaric acid, and uranium
nitrate—caused injury to the erythrocytes, and when potassium
chromate was injected directly into the blood-vessels these cells
were destroyed, sometimes in a few minutes. Ophuls (711)
stated, in his paper on potassium chromate nephritis in mam-
mals, that the cause of death in such experiments is not due to
the injury to the kidney. It is probable that death is due to
injury to the blood corpuscles, especially the erythrocytes. In
all our sections of tissues, from animals that had received injec-
tions of excretory toxins, degenerated erythrocytes can be seen.
When we injected potassium chromate intravascularly, the blood
was laked and the hemoglobin oxidized, as shown by the ‘gran-
ular’ appearance and brown color of the blood at autopsy.
Lymphatics were not stained by trypan blue or carmine to any
noticeable extent up to the end of five days’ time, although
they might take up these dyes if more time were allowed.

138 E. R. HOSKINS AND M. M. HOSKINS

SUMMARY AND CONCLUSIONS
1. Digitiform gland

The digitiform gland of Mustelus excretes about 1 ec. a day
of clear alkaline fluid containing urea. Certain injected solu-
tions, but no suspensions, were recovered in this excretion.
Injections of excretory toxins injure this gland.

2. Kidney (mesonephros)

The selachian kidney is a less efficient excretory organ than
the mammalian kidney (metanephros). The daily urine out-
put amounts to about 18 cc. per kg. body weight, with a urea
content of about 1 per cent (Baglioni, ’06). The dogfish kidney
excretes injected solutions as rapidly as the mammalian kidney,
but only in small amounts, the solutions appearing in the urine
in eight minutes after intravenous injection and in fourteen
minutes after intramuscular injection. The dogfish kidney
does not excrete injected particulate matter and the tubules
are not noticeably stained by insoluble vital dyes, at least in
five days. Large amounts of renal toxins (potassium chromate,
tartaric acid, and uranium nitrate) are withstood by the dogfish
for long periods. These toxins produce nephritis in which three
different types of degeneration occur. These are hyaline, gran-
ular, and hydropic degeneration of the cytoplasm, especially of
the excretory tubules. The nuclei are destroyed after either
hyperchromatosis or hypochromatosis. Some of these cellular
changes are due to inanition. The blood-vessels in the glomeruli
and among the tubules are not seriously affected except after
severe necrosis. The capsules of the glomeruli are only slightly
injured.

3. Liver

The liver in dogfish is relatively a very efficient excretory
organ. The bile contains 1.7 per cent of urea (Van Slyke-
White, ’11). The liver eliminates injected solutions and sus-
pensions readily and in great concentration. In a given time
the liver excretes injected solutions in several times the amount
excreted by the kidney. The liver is the only organ in the

REACTION OF SELACHII TO INJECTIONS 139

body definitely proven in our experiments as able to excrete
particulate matter. It is stained deeply by such substances.
The liver contains a great deal of normal pigment which is
excreted in the bile in the same way that injected pigments are
excreted, thus demonstrating that the latter act is a normal
process.

Excretory toxins are probably excreted by the liver and they
cause very little injury to this organ. When the kidneys were
almost entirely destroyed, the liver showed slight injury to
about 12 per cent of the nuclei, which were hyperchromatic
and slightly shrunken, and in the bile ducts there was more
than the usual amount of granular substance, probably degen-
erated cytoplasm. ‘The vessels of the liver are discussed below.

4. Spleen

The spleen is very well adapted for phagocytic activity, and is
stained deeply by injected insoluble dyes. Injected particles
produce leucocytosis. Toxins cause congestion in the spleen,
the endothelium appears to be injured, very peculiarly shaped nu-
clei may be produced, and many nuclei become hypochromatie.

5. Spiral valve

The spiral valve has previously been considered to possess
excretory function and may have such function for certain
dissolved substances, but not all solutions we injected could be
recovered in the intestine and none of the dyes were taken up by
the epithelium. Excretory toxins pass through this epithelium
and destroy it, although they do not injure the intestine imme-
diately anterior or posterior to the spiral valve. We believe with
Denis (’13) that the spiral valve has some excretory function.

6. Stomach

A few injected solutions were recovered from the stomach,
but we do not believe that this organ has an excretory function.
Excretory toxins do not injure it directly and vital dyes do not
stain its epithelium.

140 E. R. HOSKINS AND M. M. HOSKINS

7. Gills

The endothelium lining the arterial arches and especially the
large sinuses in the gills is very phagocytic to injected trypan
blue and coarsely powdered carmine. It stores such substances
in concentration greater than that in any other cells examined,
and at the same time it proliferates and produces free phago-
cytes which circulate through the body. Such proliferation and
an abnormal amitosis occur after injection of excretory toxins,
which also seem to produce degeneration of these cells. There
is no indication that the gills are able to excrete solutions or
particulate matter into the water surrounding them. ‘They are
probably a normal source of phagocytes for the circulation.~

8. Body wall

The muscles, skin, and peritoneum had in general a negative
reaction to non-toxic solutions, vital dyes, and toxins.

9. Vascular system

The blood-vascular system reacted negatively to non-toxic
solutions so far as determined, except that sucrose in the blood
was inverted. Trypan blue and carmine were found in occa- ~
sional leucocytes and endothelial cells in the blood-vessels of the
‘kidney, digitiform gland, spiral valve, stomach, and body wall.
Endothelium lining the branchial and splenic sinuses and hepatic
sinusoids is very phagocytic toward trypan blue and carmine.
The arterial arches of the gills are lined with endothelium phago-
eytic to trypan blue.

The lymphatics were not noticeably stained with vital dyes
up to five days, but the subject needs further study.

Excretory toxins cause slight injury to the fixed endothelial
phagocytes, especially in the spleen and gills. They cause con-
gestion in all the organs especially in the kidney, digitiform
gland, and spiral valve. If injected intramuscularly they cause
slow degeneration of the erythrocytes, and if injected intra-
venously, sudden destruction of these cells. This destruction is
probably the cause of death in some cases of experimental
nephritis studied by other investigators.

REACTION OF SELACHII TO INJECTIONS 141

LITERATURE CITED

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1906 Einige Daten zur Kenntnis der quantitativen Zusammenset-
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BLANCHARD, R. 1882 Sur les functions de la glande digitiforme ou superanale
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CurisTIAN, H. A., anp O’Hare, J. P., 1913 Glomerular lesions in acute exper-
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Cusuny, A. R. 1917 The secretion of urine. Longmans Green & Co., New
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Denis, W. 1912 Metabolism studies on cold-blooded animals. I. The urine
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1913 Note on the tolerance shown by elasmobranch fish toward
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Dickson, E. C. 1912 A further report on the production of experimental
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DissevHorRsT, R. 1904 Ausfiihrapparat und Anhangsdriisen der minnlichen
Geschlechtsorgane. Oppel’s Lehrbuch der vergleichenden mikro-
scopischen Anatomie. Teil, IV. G. Fischer, Jena.

Downey, H. 1917 Reactions of blood and tissue cells to acid colloidal dyes
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Evans, H. M., anp ScouLeMANN, W. 1914 The action of vital stains belong-
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142 E. R. HOSKINS AND M. M. HOSKINS

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Wistock1, G.B. 1917 The action of vital dyes on teleosts. Anat. Rec., vol. 12.

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PLATE I

EXPLANATION OF FIGURES
VITAL DYES

1 Spleen four days after injection of coarse carmine granules. The black
bodies are carmine. Insert shows an endothelial cell with a pseudopodial proec-
ess full of carmine.

2. Liver five days after injection of trypan blue. Black bodies are trypan
blue except in the cell at x which contains both trypan blue and normal black
pigment.

3 to5 Gill five days after injection of trypan blue. Figure 3 shows arterial
arch and sinuses at the base of the filaments lined with endothelium which has
ingested trypan blue, and containing free phagocytes filled with the dye; figure 4
shows normal endothelium from a sinus, and figure 5 shows two sinuses from
figure 3, showing the reaction to the injected dye. The phagocyte at x contains
both blue and black granules.

144

REACTION OF SELACHIL TO INJECTIONS PLATE 1
E. R. HOSKINS AND M. M. HOSKINS

145

THE JOURNAL OF EXPERIMENTAL ZOQGLOGY, VOL. 27, NO. 2

PLATE 2

EXPLANATION OF FIGURES
KIDNEY. POTASSIUM CHROMATE

6 Normal excretory tubule.

7 Glomerulus and collecting tubule after poisoning. Note the shrunken
nuclei and vacuoles. :

8 Excretory tubule. Note the granular degeneration and shrunken nuclei.

9 Extreme case of granular degeneration. The supporting connective tissue
has broken and allowed the débris to spread. Desquamated cells become ron
Hyaline and hydropic degeneration not shown.

146 twa

PLATE, 2

_

REACTION OF SELACHITI TO INJECTIONS

FE. R. HOSKINS AND M. M. HOSKINS

147

PLATE 3

EXPLANATION OF FIGURES
_ DIGITIFORM GLAND. POTASSIUM CHROMATE — a

10 Shows congestion at the center and cytolysis at the periphery.
11 Shows a normal tubule.
12 and 13. Show different degrees of cytolysis with shrunken, opaque nuclei.

148

REACTION OF SELACHII TO INJECTIONS PLATE 3
E. R. HOSKINS AND M. M. HOSKINS

149

oa

isa? PLATE, 4
EXPLANATION OF ¥IGURES © =

SPIRAL VALVE. POTASSIUM CHROMATE ~~

~-

14. Normal pal valve. .

15 Effect on spiral valve of potassium chromate poisoning. Note fre loss
of innermost epithelium. Severe congestion. The entire section is — poorly
stained, although it was prepared similarly and stained simultaneously with the
section oe in figure 14.

150

4

PLATE

CTIONS

4

F SELACHI TO INJE

SACTION O

RE

HOSKINS

M.

HOSKINS AND M.

R.

>)

1

5)

PLATE 5

EXPLANATION OF FIGURES

; KIDNEY. TARTARIC ACID
16 Normal kidney. :

17 Kidney poisoned with tartaric acid. Note the shrunken nuclei, broken
tubules, and débris. The very small black bodies in the cells of the excretory —
tubules are of eosinophilic hyaline substance.

18 Normal exeretory tubule.

2 EFFECT OF TARTARIC ACID

19 Small excretory tubule showing granular degeneration with shrunken
opaque nuclei. ey

20 Extreme stage of granular degeneration. The tubule is represented by a
mere mass of débris. Note the surrounding cells with large eosinophilic granules.

21 Hyaline degeneration, showing hyaline droplets and shrunken nuclei. —

PLATE 5

REACTION OF SELACHIL TO INJECTIONS

E. R. HOSKINS AND M M. HOSKINS

~~

Ven)

PLATE 6

EXPLANATION OF FIGURES
KIDNEY, SPLEEN, AND GILL. URANIUM NITRATE
(See figure 18 for normal kidney)

22 Mild granular degeneration.

23 Late granular degeneration.

24 Granular and hydropic degeneration, but not typical of the latter type.

25 Beginning of hyaline degeneration. Late stage not shown.

26 Nuclei found in the blood-vessels and connective tissue of kidney, coming
probably from endothelium of spleen and gills.

27 Nuclei from the endothelium of the spleen and gill sinuses and probably
representing abnormal amitosis in production of phagocytes. The cell ‘x’ repre-
sents a mitotic figure seen in the spleen.

REACTION OF SELACHII TO INJECTIONS

E. R. HOSKINS AND M, M. HOSKINS

PLATE 6

AUTHOR’S ABSTRACT OF THIS PAPER ISSUED
BY THE BIBLIOGRAPHIC SERVICE OCTOBER 8

FLUCTUATIONS IN A RECESSIVE MENDELIAN
CHARACTER AND SELECTION!

ELMER ROBERTS

University of Illinois, Urbana, Illinois

TWO PLATES AND THREE TEXT-FIGURES

CONTENTS
Ney FISCLUIG GOL ET es te ene ee ae Se IE Shs eG re as Peek oe 157
spirit iN GC NEt NOUS 0. ore sees so rotates 4b hoes, age. 6 a8 158
leg SOULCES Of Errors... 2.5 FEN NRO SNA, ESE RRA oe Sa 160
Lie LEED EU S57 i a hl a as Ry Nh i AE Ac er 161
fee Selectea Series VAG: See hited eee dea eee eee ME. kde 161
Gtiite eto selecuiOne se ss-he nee oe Air ae Oa ae ae ee ons 5 be 161
Bete ONGTOMAETICS PEEL 5 eh A eee ene Se iad Sepa s idles ac ene 163
Pee EC Ol DeHIDCERGUTE cer cay) Ss 2 oo x, mide aE a Pen «eee 163
2.) ‘ Crossed—-m-and-seleeted” series ©... 0050... 2. ee 164
Bee Ch GiRselGCulon sss eee Lees oc: Pater ti eel ote vane 164
Doe Hi eCit Olu CEOSSIM GING: Stecre nes py See y ako io ate en Tye a = 166
PLC CIO’ TCMIPCLAGUEC: cs a ko ele sie ira ere haere (a ene ct 168
Benet Ghowiti One e225) 2504520 AO. SEE A 169
NN IIALEFI NTR ALO REHM 58 6 ot5 sons 2 fie Ss Mal ts ond 8 Ap ee Pee eee oes 170
MN OTIS T Pe A ar oh hone a bts tte cip Seu ee EE a cae Lee 171
1. Effect of selection.......... ae, tea Re pe Se ss eat 171
nee ir CTONSINGESIN «os. ao cats a tes gD hoe heme eee ae 172
OPN EOE SAEC CITC a) ties = 6S ok ldo nas Lak 03 tee ee BO eee 176
RUE Cah FP ee on. Spe Racks hale HaGPaee s sa Sara deeds ee ee 178
Ie wa aadpeeaeagn Sid g bork sine cid ee ere ee 182

I. INTRODUCTION

During the past few years there has been much discussion
concerning the purity of the germ-plasm and the constancy of
Mendelian characters. Johannsen, De Vries, and others have

1 Paper No. 7 from the Laboratory of Genetics, Department of Animal Hus-
bandry, University of Illinois. The writer wishes to acknowledge his indebted-
ness to Dr. J. A. Detlefsen, under whose direction the work was carried on, for
- many valuable suggestions and criticisms.

157

THE JOURNAL OF EXPERIMENTAL ZOOLOGY, VOL, 27, No. 2

158 ELMER ROBERTS

maintained that in asexually reproduced organisms and in indi-
viduals arising by self-fertilization selection is futile except for
the purpose of isolating pure lines. The original interpretation
of a pure line was that it consisted of the offspring of a self-fer-
tilized individual. Later, the term, pure line, was extended to
homozygous characters in individuals reproduced dioeciously or
biparentally. It has been the belief of the majority of workers
in genetics that selection only separates pure lines and is ineffec-
tive when applied to a unit character. Such an hypothesis must
also assume a gametic or factorial purity which is unchanging
except through mutation.

The questions with which the present investigation deals are:

1. Does long-continued selection have an effect upon a Men-
delian character?

2. Can there be a gametic or factorial contamination of a char-
eter, and, if so, is selection then efficacious?

Il. MATERIAL AND METHODS

In Drosophila ampelophila, the fruit fly, there is a wingless
or vestigial winged variety, the origin of which was described by
Morgan and Lynch (712). This vestigial wing behaves as a re-
cessive character when crossed to individuals with normal long
wings. The offspring in the first generation have long wings
while in the second generation both long-winged and vestigial-
winged are produced. However, the ratio of long-winged to
vestigial-winged is not 3:1. In this experiment, 9248 F, indi-
viduals were produced, 7381 of which were long-winged and 1867
vestigial, or a ratio 3.95:1. With this number of individuals
such a departure from a 3: 1 ratio cannot be attributed to chance.
Morgan explains the departure from the theoretical ratio as
being due to the low viability of the vestigial-winged variety.
A vestigial and a normal wing are shown in plate 1, figures 1
and 14. This character, vestigial wing, is well adapted to such
an investigation as outlined, because it is a well-defined Mende-
lian character and shows some variability in size and venation.
The stock was originally obtained through the courtesy of Prof.
T. H. Morgan, of Columbia University.

A RECESSIVE CHARACTER AND SELECTION 159

One male and one female were taken at random as the begin-
ning of all the series. From the offspring of these two individuals,
the male and female with the longest vestigial wings were used to
begin selected series A. The brothers and sisters of these bred
inter se started control series-B to be used as a check. The
third series, which will be referred to as ‘crossed-in-and-selected’
series C, had its origin as follows: ten selected males from the six-
teenth generation of selected series A were crossed to long-
winged females of wild Drosophila obtained from bananas in a
local grocery. The first generation was long-winged, while in the
second, long-winged and vestigial-winged appeared. Selection
was begun among the vestigial-winged segregates of the second
generation, those individuals with the longest vestigial wings
being used as parents of the next generation, and so on. Some
of the vestigial-winged males of the second generation of the
cross were mated again to long-winged females. This process of
‘crossing-in’ was repeated eight times in some of the series, but
in this paper a series which was crossed-in only once is reported
for the reason that it consists of a larger number of generations
than any of the others. Duplicate series were also run, formed
by crossing vestigial-winged females to long-winged males, the
reciprocal of the above cross. ‘

The length of the vestigial wing is the measurement used to
determine the effect of selection and of ‘crossing-in.’ The ideal
method would have been to measure the surface of the wing and
note the venation, but this was prohibitive on account of the labor
involved. However, the length is a good character to use as an
indication of any changes in size. It is better than width, for
in large thin vestigial wings, curling sometimes renders the
measurement of the width impossible or extremely difficult. The
generations were preserved in 75 per cent alcohol and measure-
ments made later.

In all cases selections were made by simple inspection with a
hand lens, the effectiveness of which can be seen from tables 1,
3, 5, 6, 7 and 9.

Measurements were made by the use of a camera lucida,
tracing the length of the wing and measuring the line thus pro-

160 ELMER ROBERTS

duced. The most convenient method of placing the flies under
the microscope was by means of a grooved microscopic slide,
using glycerin to support them in a horizontal position. The
magnification is 29 expressed in millimeters. This magnification
is used in the text and tables without reduction to actual sizes.
In generations containing several hundred individuals, one hun-
dred of each sex, taken at random, were measured.

In selecting the parents,: the length of the vestigial wing was
not the only factor taken into consideration. The goal in view
was a perfect wing, hence the breadth and the position of the
wing relative to the body of the fly were also considered. The
usual method of feeding fermented banana, as described by
Morgan, Sturtevant, Muller and Bridges (’15), was used.

1. Sources of error

As a possible source of error, it may be mentioned that the
wings were broken off in some cases, rendering the inclusion of
such individuals in the tabulations impossible. This was more
common among the parents than among the others of the genera-
tion, since the parents were kept much longer before preservation
than were the others. Some of the parents died in the breeding
bottles and occasionally the wings became mutilated to such an
extent that measurement was impossible. Also there was a slight
tendency to curling and shrinking among the larger wings, this
type being more common among parents selected for wing length.

For the most part, mass selection was practiced because of the
danger of losing the series if only two individuals were used.
Consequently, those selected for parents differed in size of ves-
tigial wing. Therefore, one cannot be sure which of those se-
lected were the actual parents of the next generation in case all
did not mate or if mating was indiscriminate. Since the average
of the parents was always larger than the average of the genera-
tion from which they were selected, except in cases where all
the offspring were used as parents, this is not a very serious
objection.

A RECESSIVE CHARACTER AND SELECTION 161

The object of the experiment was to select toward the normal
long wing. In some instances individuals with shorter wings
were given preference in selection, for the reason that they ap-
proached more nearly the long-wing type in form and venation.

It is assumed that the expression of this somatic character,
vestigial wing, is an index of the germinal constitution. In any
selection experiment, without the progeny test, selection is
effective only when the somatic character is an index of the
germinal constitution to some degree at least. However, en-
vironmental factors may affect the somatic expression and thus
render selection less effective.

Ill. EXPERIMENTAL DATA
1. Selected series A

This series began, as described in section II, with a mating of
a vestigial-winged male and female taken at random, and was
continued for thirty-four generations. Table 1 gives the means,
standard deviations, and coefficients of variability of males and
females in each generation. The males and females are treated
separately in order to show any sex differences.

a. Effect of selection. In table 5 are found the weighted aver-
age wing lengths of parents and offspring for each generation in
selected series A. By an inspection of text figure 1, which is
constructed from table 5, it is at once seen that no increase in
size of wing was made during the process of selection. This is
further borne out by the correlation between the average wing
length of the parents and that of the offspring which is

r = + 0.329 + 0.103.

This correlation is not significant when judged by the probable
error. To be sure, a marked correlation is not necessarily a
measure of the amount of progress made by selection, for en-
vironment may produce a significant correlation, but it is ob-
vious that if there is no significant correlation between the size
of the parents and the size of the offspring selection is of no
avail.

ELMER ROBERTS

162

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SHLD.

A RECESSIVE CHARACTER AND SELECTION 163

From table 1, it is to be noted that some generations are much
more variable than others when judged by the standard devia-
tions which range from 2.11 + 0.010 to 11.50 + 0.60 in the
males and 1.69 + 0.17 to 7.68 + 0.49 in the females. The
coefficients of variability are 10.85 + 1.58 to 42.50 + 2.61 for
the males and 8.86 + 0.89 to 31.66 + 2.19 for the females.
The means of the wing lengths of the different generations vary
from 16.23 to 26.88.

b. Control series B. Control series B had its origin in the
random mating of the brothers and sisters of the two individuals
used for selected series A, and was carried for sixteen genera-
tions. Table 2 gives the means, standard deviations, and co-
efficients of variability of the males and females separately, while
in table 4 are found the averages of the wing lengths of males
and females in the different generations.

This series shows in general the same things as selected series
A. It is to be noted from text figure 1, which is constructed
from the means of the generations given in table 4, that the
wing length in the control series is smaller in every generation,
except the Fy,, than in the selected series. It is thought that this
difference is due to the method of handling rather than to any
inherent difference. In the selected series only a few parents
were in the breeding bottle and the offspring were removed every
eighteen hours or more often, while in the control series, the flies
were not removed so frequently and a large number of parents
was used. The food conditions and space in the breeding bottles
were not so favorable in the control as in the selected series. In
working with the flies, one received the impression that those of
the control series were smaller than those of the selected series.
Measurements of the body lengths of males in the sixth generation
of each series were made, giving 62.9 for the selected and 60.4 for
the control. Males were measured in preference to the females
in this comparison because the body size in the males is more
constant than in females due to the presence or absence of eggs
in the latter.

c. Effect of temperature. The high means in the Fy» generation
of control series B and in the Fio, Fis, and F2» generations of se-

164 ELMER ROBERTS

lected series A occurred during the summer of 1914 and 1915
when there was extremely warm weather. The connection be-
tween high temperature and size of wing was unknown at first
and consequently no temperature records were kept during the
first part of the experiment. Thereafter records were kept and
a series of flies was subjected to high temperature in an incubator,
the outcome of which is discussed later in this paper. It is
significant to note that during the production of the F2, genera-
tion in selected series A, higher temperature occurred than in
either the F.s or Fs) generation. The males are more affected
than the females, as can be seen from the means, standard devia-
tions, and coefficients of variability in the generations noted
above (tables 1 and 2).

¢ . .
2. ‘Crossed-in-and-selected’ series C

This series was obtained as described in section II, by the
crossing of ten vestigial-winged males from the Fis generation
of selected series A with long-winged females. Selection was
started among the vestigial-winged segregates appearing in the
second subsequent generation. Table 3 exhibits the means,
standard deviations, and coefficients of variability of males and
females separately. The means of the males and females com-
bined are given in table 6.

a. Effect of selection. Text figure 2 is constructed from the
means of the generations given in table 6. By an inspection of
this graph, one cannot say that selection has been effective. If
the experiment had been brought to an end in the twenty-first
generation, probably one would have concluded that selection
had been effective, but such fluctuations as are found in the Fe.
and F.5 generations prevent such a conclusion. However, it
may have been that the somatic appearance was not always an
index of the germinal constitution, in which case there is a pos-
sibility that selection may have been effective, but that environ-
mental factors suppressed the full expression of the germinal
potency or constitution. Under the conditions of this experi-
ment, selection had no visible effect upon the expression of the
character in question.

165

A RECESSIVE CHARACTER AND SELECTION

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166 ELMER ROBERTS

b. Effect of ‘crossing-in.’ If selection had no effect in either
of the two series, then the differences existing must have some
other explanation. It will be of value to compare the generations
in the two series, which were produced during the same period of
time. Generations Fs. to F3s of selected series A and F; to Fi,
of “crossed-in-and-selected’ series C were produced at the same
time and were subject to the same conditions, except that the
latter series had been crossed to long-winged stock a few gen-
erations back in its history.

Text figure 3 shows the curves of the means for the contempo-
rary generations of these series noted above. In only one ease,
the twelfth generation, does the ‘crossed-in-and-selected’ series
fall as low as the simple selected series. By taking the average
of the means of the males and females in each of these series, we
have 19.07 + 0.069 for selected series A (Fx. to F3,) and 25.62 +
0.12 for ‘crossed-in-and-selected’ series C (F; to Fi9). This is a
significant difference. As the average of all the generations in
each series, we have 19.27 + 0.043 for selected series A and
25.68 + 0.073 for ‘crossed-in-and-selected’ series C. This is
also a significant difference when judged by their probable
errors.”

The males were more affected by ‘crossing-in’ than were the
females. The average of the males for generations noted above
in the ‘crossed-in-and-selected’ series is 27.99 + 0.19 and of the
females 23.40 + 0.14. That this difference is due to having been
crossed with the long wing is proved by the fact that in the
generations of selected series A produced at the same time (Fe:
to F;,) the average of the males is 19.43 + 0.11, and of the females
18.69 + 0.078. For all the generations in ‘crossed-in-and-
selected’ series C, the males average 27.70 + 0.12 and the fe-
males 23.73 + 0.090, while selected series A gives 19.40 + 0.068

2'The probable error of an average of averages was calculated from the
formula:

il
B= N Vn? e;? + no? e2" = eae Hes Dm? em?

in which 7 is the number of individuals in the generation, e the probable error,
and WN the total number of individuals.

167

A RECESSIVE CHARACTER AND SELECTION

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SHIONGT 40 GOVUGAYy

168 ELMER ROBERTS

for the males and 19.13 + 0.052 for the females. There can be
no doubt, then, that ‘crossing-in’ has modified the character.

c. Effect of temperature. In this series, as in the other, high
temperature increased the size of the wing, and the increase was
greater among the males than among the females. To determine
more exactly the effect of temperature, the following experiment
was performed. After the parents were selected for the Feo
generation of ‘“crossed-in-and-selected’ series C, they were
allowed to deposit eggs in four bottles, two of which were put
into an incubator set to run from 27°C. to 28°C. The tem-
perature, however, ranged from 26.7°C. to 35.7°C. This high
temperature was caused by the extremely warm weather in the
summer of 1916. The other two bottles were kept at the lab-
oratory temperature, which ranged from 18°C. to 35.1°C., but
for the most part arcund 22°C. to 24°C. Readings were made
twice daily, morning and evening. The average temperature in
the incubator during the experiment was 28.4°C. and in the lab-
oratory 25.9°C. Table 7 gives the means, standard deviations,
and coefficients of variability of males and females separately.
Table 9 gives the means of the generations by combining the
males and females.

From text figure 2 a comparison can be made between the
generations produced in the incubator and those kept in the
laboratory. The difference is very marked even though the
temperature in the laboratory approached that in the incubator,
due to the hot summer weather. The average of the means of
the males and females in the laboratory is 24.49 + 0.14 and of
those in the incubator 42.79 + 0.25. These averages are for
F., to F;; generations in both the laboratory and incubator series,
It must be clear, then, that temperature has a marked effect
upon the somatic expression of vestigial wings.

It is to be noted that in the incubator series the Fs. generation
has a much lower mean than any of the other generations. The
two bottles were not placed in the incubator until after all the
eggs had been deposited and many pupae formed. This seems to
indicate that the effect of high temperature took place between
the fertilization of the egg and the pupal stage.

A RECESSIVE CHARACTER AND SELECTION 169

From tables 3 and 7 it is to be seen that the coefficients of
variability have decreased in the generations produced under high
temperature, but that the standard deviations are about the same.
This does not necessarily mean that the range of variation has
decreased. Since the coefficient of variability is obtained by

: o
dividing the standard deviation by the mean, C = ive it is quite

obvious that as M increases, C’ decreases if ¢ remains constant.
When dealing with biological materials of the same kind, stand-
ard deviation is sometimes a much safer criterion of variability
than the coefficient of variability.

Another fact brought out by an inspection of table 7 is that
there is little difference between the males and females with
regard to length of wing. The average for the males is 45.90 +
0.26 and for the females 42.50 + 0.35 (Fe. to F3;). By leaving
out of the calculations the Fs, generation which underwent some
of its development outside of the incubator, the averages become
49.25 + 0.23 for the males and 48.35 + 0.27 for the females.
This shows a much smaller difference than above, and is not
significant when judged by their probable errors. Judging from
the very large differences existing between the males and females
in the series outside the incubator, it seems that the males are
more easily affected by high temperature than are the females,
but that under constantly high temperature both males and
females were equally affected.

3. Form of wings

Some of the types of wings found in these series are shown in
plate 1. There is great variability in the size, shape, and vena-
tion. A very good graded series could have been obtained from
the normal vestigial type (1) to the normal long wing (14). Figure
13 shows a common type of wing produced in the high-tem-
perature series and less frequently in the other series. It is in
size and venation like a normal long wing. Other types similar
to ‘strap,’ truncate, and beaded as described by Morgan (’16)
appeared.

170 ELMER ROBERTS

In none of the series did the individuals breed true for the
type of wing possessed. Under high temperature the size,
judged by length of wing, was constantly much larger than the
normal vestigial wing, but the form was variable, though more
wings were produced like the normal long wing than under any
other conditions. It is interesting to compare the length of
wings in wild Drosophila with the length of vestigial wings
found in this experiment. For twenty-four wild males the
average length is 57.7 and for twenty-six females 68. Some of the
vestigial wings were as long as the long wings of the wild stock.
The position of the wing in relation to the body was also vari-
able. In the normal vestigial-winged fly, the wing seems to be
stationary and projects from the side of the body at an angle of
about 60°. In many of the flies with large vestigial wings pro-
duced in these series, the wings were in the position of the nor-
mal wing and some functioned as normal wings. In fact, a few
individuals escaped by flying away. These wings were thinner
than those of the wild Drosophila.

In vestigial-winged Drosophila the balancers are much reduced
in size. Normal balancers from long-winged flies are shown in
plate 2, figures 21 and 22, while figures 15 and 16 show the bal-
ancers from normal vestigial-winged flies. In those flies with
large vestigial wings, balancers of the normal type were present
(figs. 17 to 20).

Unfortunately, the experiment was brought to a close by the hot
weather and further work on fixing these types was brought to
an end.

The other series, previously noted, obtained by crossing ves-
tigial-winged individuals two, four, and eight successive times to
long-winged, gave in general the same results as the series reported
at length in this paper.

IV. SUMMARY OF RESULTS

1. Selection failed to modify the size of vestigial wing in
Drosophila (tables 5 and 6, and text figs. 1 and 2).

2. The size and form of the vestigial wing were affected by
crossing to long-winged flies (tables 1 and 3, and text fig. 3).

A RECESSIVE CHARACTER AND SELECTION 171

3. The males showed greater effects from ’crossing-in’ than
did the females (table 3).

4. The size and form of the vestigial wing were affected by
high temperature (tables 1, 2 and 3, and text figs. 1 and 2).

5. The males were more easily affected by high temperature
than were the females (tables 1 and 2).

V. DISCUSSION
1. Effect of selection

It is possible to assume that selection had no effect upon the
size of vestigial wing in this experiment, because of the gametic
- purity of this character. Upon this assumption the variability
was due to environmental factors alone and under such conditions
one would not expect selection to be effective. Such an hypothe-
sis 1s supported by evidence from. the work of Johannsen (’03,
09) with beans, Jennings (’09) with the protozoan Paramecium,
Tower (06) with the potato-beetle, Leptinotarsa decemlineata,
Ewing (14a, 714b, ’16) with Aphis, and Lashley (’15, 716)
with Hydra.

However, there is also evidence that in some cases unit-char-
acters do change under the process of selection. Castle and
Phillips (14) found that the amount of pigment in the hooded
rat could be increased or decreased at will by selection. Cuénot
(04) noted the same results in working with spotted mice. The
work of Jennings (’16) on Difflugia corona, the reproduction of
which is uniparental, showed that selection was effective in
changing the number and length of spines and size of body.
Similar results were obtained by Middleton (’15) with Stylonychia
and Stocking (’15) with Paramecium. All of these results may
be explained by assuming that the factors themselves are vari-
able. Castle held this view concerning the hooded character in
rats. The pure-linist attempts to explain Castle’s results upon
the assumption that modifiers are present and that selection
separates diverse types. Concerning the work of Jennings on
Difflugia, Morgan (’16) says: “If through sexual union (a proc-
ess that occurs in Difflugia) the germ plasm (chromatin) of these

172 ELMER ROBERTS

wild types has in times past been recombined, then selection
would be expected to separate certain types again, if, at divi-
sion, irregular sampling of the germ plasm takes place.”

In this case Morgan desires proof that the characters were not
in a heterozygous condition. On the other hand, the question
might be asked if there is any proof of the occurrence of irregular
sampling of the germ plasm in Difflugia.

Since an environmental factor, temperature, affects the ves-
tigial wing to a marked degree, a consistent germinal selection
may not have been in operation in these experiments. In gen-
erations occurring at a time favorable to the production of large
vestigial wings, selection was easily possible, but in generations
when the vestigial wing was inhibited by a low temperature,
selection of individuals potent for larger wings could not be
made except as they were included by chance.

2. Effect of ‘crossing-in’

The data establish beyond question that crossing the vestigial-
winged flies to normal long-winged had a very marked influence
on increasing the size of vestigial wings in the ‘crossed-in’ series.
Castle (15) reported on some unpublished work of Dr. D. H.
Wenrich that the extracted vestigials from a vestigial, long-
wing cross showed greater variability in length of wing than did
the uncrossed. To what this increase is due is not known, but
there are two possible explanations:

1. The increased size and variability may have been due to the
introduction of modifying factors from the wild stock, these
factors acting more effectively when the temperature was higher
than the normal; or

2. A gametic contamination may have occurred when the ves-
tigial wing factor came into association with its allelomorph,
long wing (or the association of the developer for wings with the
absence of this developer).

There is some evidence in favor of the first explanation gained
from the following experiment performed to test this view. A
large vestigial-winged male from F3. generation produced in the

A RECESSIVE CHARACTER AND SELECTION 7

incubator, having a wing of the general form shown in plate 1,
figure 13, was mated to small vestigial-winged females from the
original stock. This cross was carried through the second gen-
eration and was kept from the beginning in the incubator.
Table 8 summarizes the means, standard deviations, and co-
efficients of variability of the males and females separately. It
is to be noted that the variability in the second generation, when
judged by the standard deviation, is greater than in the first—
a condition to be expected if differential factors were involved.
The difference between the males in the first and second genera-
tions is not highly significant when judged by the probable errors,
but that between the females is. However, the variability of the
males is greater in the second generation than in the first. The
average variability of the males and females combined in the F;
generation is 5.81 + 0.48 and in the F, 9.93 + 0.76. That the
males are more affected than the females is again brought out
in this cross. .

The correlation between the averages of wing lengths in the
parents and in the offpring for the “crossed-in’ series is expressed
by

r = 0.528 + 0.086

This probably indicates that both parents and offspring were
produced at a time favorable to the development of large vestigial
wings.

If the increased size and variable form of wing are due to
factors, the original stock must have contained at least some of
these factors since, under high temperature, the size and form of
wing were much affected in the simple selected series (table 1).
Morgan (’16) writes concerning the vestigial wing character:
“This condition arose at a single step and breeds true, although
it appears to be influenced to some extent by temperature, also
by modifiers that sometimes appear in the stock.”

Morgan and Lynch (’12) state that the vestigial wing was
crossed to the long wing and segregated again in order to in-
crease viability. Hence, factors may have been introduced and
carried in the stock from that time, and were effective only
when temperature was favorable.

THE JOURNAL OF EXPERIMENTAL ZOOLOGY, VOL. 27, No, 2

174 ELMER ROBERTS

There are other cases in Drosophila of factors which find ex-
pression only under certain environmental conditions. Miss
Hoge (’15) found that in a certain stock of Drosophila super-
nunierary legs were produced in a Mendelian ratio at about 10°C.,
but at normal temperature this character was very rare. Mor-
gan (’15) described the case of abnormal abdomen in which the
black bands, normally present, are broken and irregular or en-
tirely absent. This abnormal condition is induced by the pres-
ence of moist food, but when the food becomes more dry, the
individuals that emerge are entirely normal in appearance.
Dexter (’14) also found that more beaded wings were produced
in a wet culture than in a dry, and more in alkaline than in acid
cultures. Extra number of bristles in Drosophila was decreased
by a scanty food supply (MacDowell, 715). :

Further investigation under a constant environment will be
necessary before one can come to a conclusion concerning the
efficacy of selection on the size of vestigial wing. On the basis
of this explanation, selection failed because the somatic expres-
sion of this character was not indicative of the full germinal
potency.

The second plausible explanation of the increased size and
variability of the vestigial wing in the ‘crossed-in’ series is fac-
torial contamination. Castle, particularly, held that such a con-
tamination might occur—that gametes are subject to change and
inconstant. Castle and Forbes (06) concluded that there was
contamination of the germ-cells produced by the cross-breds of
long- and short-haired guinea pigs, due to the association of the
factors for long and short hair. Likewise, MacCurdy and
Castle (07) were of the opinion that the gametes of cross-breds
from a cross of hooded and Irish rats had changed because the
extracted patterns were somewhat changed. Contamination of
the gametes would mean variation of the unit-character in ques-
tion. It was the variability in this hooded pattern of rats which
furnishéd the foundation for the extensive selection experiment
by Castle and Phillips (14). The results of their experiment
showed that the amount of pigment could be diminished or in-
creased at will by selection. They adopted the hypothesis that

A RECESSIVE CHARACTER AND SELECTION 175

some of the variability was due to modifying factors, but later
Castle (16) claimed to have disproved that modifying factors
were concerned because there was no decrease in the rapidity of
change after seventeen successive selections. For this and other
reasons Castle (Castle and Wright, ’16; Castle, ’17) rejects the
hypothesis of modifying factors.

On the other hand, Marshall and Muller (’17) found that the
factor for balloon wing which is variable showed no evidence of
contamination after having been in association with its allelo-
morph for more than fifty generations. Morgan (’15) concluded
from the evidence furnished by the character, abnormal abdo-
men, that no contamination of genes or gametes occurred. The
expression of this character is dependent upon the environment,
rendering it possible for the individual to be normal in appear-
ance when the character is either heterozygous or homozygous
for abnormal. If the environment is favorable, a heterozygous
individual will be abnormal. In none of his work did Morgan
find any evidence to support the theory of gametic contamination.

Either gametic contamination or modifying factors would cause
characters to vary, and in both cases progress by selection would
be possible. Zeleny and Mattoon (’15) found that the number
of facets in ‘bar eye’ Drosophila could be increased or decreased
by selection. They are inclined to the belief that the variabily
in the number of facets is due to ‘differences in factorial com-
position.” MacDowell (15) showed that selection was effective
in increasing the number of extra bristles in Drosophila. He
says: “The hypothesis of accessory factors will explain all the
facts, and that of modification of a Mendelian factor may be
employed to interpret most of them.’’

Morgan (’16) reports that in his laboratory Muller selected for
shorter wings in the truncate stock of Drosophila and obtained
individuals at the end of the experiment with much shorter wings
than those with which he started. He showed by means of link-
age experiments “that at least three factors were present that
modified the wings.” Dexter (’14) found that the variability
of beaded wing was affected by a modifying factor in the second
chromosome, which could be eliminated or preserved, thus making

176 ELMER ROBERTS

selection effective. Lutz (’11) decreased the length of veins in
the wings of Drosophila. Whether modifying factors were in-
volved in this case is not known. All must agree that unit
characters vary, but there is some difference of opinion as to
whether the germinal cause of variability is modifiers or gametic
contamination.

It might be thought that selection was effective, since the
flies placed in the incubator at high temperature showed con-
stantly large wings. This, however, may have been due to
crossing the vestigial-winged ‘to long-winged flies, introducing
factors from the long-winged stock which would have increased
the wing size among the vestigial winged segregates in the second
generation, if the environment had been favorable. It is also
conceivable that there was a factorial contamination which
would show fully only under high temperature.

Why the’males were affected more easily by temperature than
the females is not known. Investigation is now in progress with
some hope of finding evidence on this point.

VI. LITERATURE CITED

CasTtLeE, W. E. 1915 Mr. Muller on the constancy of Mendelian factors. Am.
Nat., vol. 49, pp. 37-42.
1916 Genetics and eugenics. Harvard Univ. Press. Cambridge.
1917 Piebald rats and multiple factors... Am. Nat., vol. 51, pp.
102-114.

CasTLE, W. E., AND ALEXANDER ForsBes 1906 Heredity of hair-length in
guinea-pigs and its bearing on the theory of pure gametes. Carnegie
Instit. Wash., Publ. No. 49.

CastLE, W. E., anp Joun C. Putturps 1914 Piebald rats and selection. Car-
negie Instit. Wash., Publ. No. 195.

CastLe, W. E., AND SEWALL WricHT 1916 Studies of inheritance in guinea-
pigs and rats. Carnegie Instit. Wash., Publ. No. 241.

Cutnot, L. 1904 L’hérédité de la pigmentation chez les souris. (3me note.)
Arch. de Zool. expér. et gén. (Sér. 4), T. 2, notes et Revue, pp. 45-46. .

DextTeER, JouN B. 1914 The analysis of a case of continuous variation in Droso-
phila by a study of its linkage relations. Am. Nat., vol. 48, pp.
712-758.

Ewine, H. E. 1914a Pure line inheritance and parthenogenesis. Biol. Bull.,
vol. 26, pp. 25-35. i
1914b Notes on regression in a pure line of plant lice. Biol. Bull.,
vol. 27, pp. 164-168.

A RECESSIVE CHARACTER AND SELECTION 177

Ewinec, H. E. 1916 Eighty-seven generations in a parthenogenetic pure line of
Aphis avenae Fab. Biol. Bull., vol. 31, pp. 53-112.

Hoce, Miuprep A. 1915 The influence of temperature on the development of
a Mendelian character. Jour. Exp. Zodél., vol. 18, pp. 241-297.

JenninGs, H. 8. 1909 Heredity and variations in the simplest organisms.
Am. Nat., vol. 43, pp. 321-337.
1916 Heredity, variation and the results of selection in the uni-
parental reproduction of Difflugia corona. Genetics, vol. 1, pp.
407-534.

JoHANNSEN, W. 1903 Uber Erblichkeit in Populationen und in reinen Linien.
Jena. ;
1909 Elemente der exakten Erblichkeitslehre. Jena.

Lasuutry, K. 8. 1915 Inheritance in the asexual reproduction of Hydra.
Jour. Exp. Zoél., vol. 19, pp. 157-210.
1916 Results of continued selection in Hydra. Jour. Exp. Zodl., vol.
20, pp. 19-26.

Lutz, Frank E. 1911 Experiments with Drosophila ampelophila concerning
evolution. Carnegie Instit. Wash., Publ. No. 143.

MacCurpy, Hansrorp, anp W. E. Castite 1907 Selection and cross-breeding
in relation to the inheritance of coat-pigments and coat-patterns in
rats and guinea-pigs. Carnegie Instit. Wash., Publ. No. 70.

MacDowe tt, E. C. 1915 Bristle inheritance in Drosophila. Jour. Exp. Zodl.,
vol. 19, pp. 61-98.

MarsHALL, WALTER W., AND HERMANN J. MULLER 1917 The effect of long-con-
tinued heterozygosis on a variable character in Drosophila. Jour.
Exp. Zoél., vol. 22, pp. 457-470.

Mippieton, A. R. 1915 Heritable variations and the results of selection in the
fission rate of Stylonychia pustulata. Jour. Exp. Zoél., vol. 19, pp.
451-503.

Morean, T. H. 1915 The réle of the environment in the realization of a sex-
linked Mendelian character in Drosophila. Am. Nat., vol. 49, pp.
385-429.
1916 A critique of the theory of evolution. Princeton University
Press, Princeton.

Morean, T. H., AnD Ciuara J. LyncH 1912 The linkage of two factors in Droso-
phila that are not sex-linked. Biol. Bull., vol. 25, pp. 174-182.

Morean, T. H., A. H. Srurtevant, H. J. Muuer, anp C. B. Bripces 1915
The mechanism of Mendelian heredity. New York, Henry Holt
& Co.

Srockxine, Ruts J. 1915 Variations and inheritance in abnormalities occur-
ring after conjugation in Parameciuum cadatum. Jour. Exp. Zéol.,
vol. 19. no. 4, pp. 387-449.

Tower, W. L. 1906 An investigation of evolution in Chrysomelid beetles of
the genus Leptinotarsa. Carnegie Instit. Wash., Publ. No. 48.

ZELENY, CHARLES, AND E. W. Martroon 1915 The effect of selection upon the
‘bar eye’ mutant of Drosophila. Jour. Exp. Zodl., vol. 19, pp.
515-529.

PLATE 1
EXPLANATION OF FIGURES

Photographs of camera-lucida drawings. X 38.

1 Short vestigial wing.

2, 3, 5, 6, 8,9 From selected series A.

4,7, 10,12 From ‘crossed-in-and-selected’ series C.

13 From the ‘crossed-in-and-selected’ series subjected to high temperature.
14 Normal long wings.

178

' A RECESSIVE

CHARACTER AND SELECTION
ELMER ROBERTS

179

PLATE 1

PLATE 2
EXPLANATION OF FIGURES

Photographs of camera-lucida drawings of balancers. X 5°. _
15, 16 From short vestigial winged flies.

17, 18, 19, 20 From vestigial-winged flies with large wings.
21, 22 From normal long-winged.

A RECESSIVE CHARACTER AND SELECTION PLATE 2
ELMER ROBERTS

vd ‘on

ae

182 ELMER ROBERTS

TABLE 1

Means, standard deviations, and coefficients of variability of length of vestigial wings
in selected series A

PARENTS OFFSPRING
Standard Coefiici

Means peaaeerind i
16.22 +0.92] 4.08 +0.65 | 25.15 + 4.24
16.244 0.41 | 2.79: 0.29 | 17.1824 84
16.69 + 0.24] 2.57 +0.17| 15.40 + 1.02
16.04 +0.33| 3.25 + 0.23 | 20.26 + 1.50
19.41 +0.67| 4.74+0.47 | 24.42 + 2.57
19.09 + 0.24] 1.69+0.17| 8.86+0.89
18.19 420.20 | 2273:3-'0,14 | 11-72 ee
18.81 4. 0.31 | 2°804-.0,22 | 14.8926
17.35 +0:27| 2.50+0.19] 14.4141.11
19.45 +0.31] 3.19 + 0.22] 16.40 +1.17
17.97 + 0.22] 3.01 40.15 | 16.75 + 0.87
17.92 +0.22| 2.61+0.16] 14.56 + 0.89
18.97 + 0.23] 2.85 +0.16]| 15.02 + 0.86
18.75 +0.25| 2.99 +0.18| 15.95 + 0.97
18.65 +0.25| 3.24+0.18| 17.387 40.97
18.75 40.21] 2.91 +0.15 | 15.52 + 0.82
17-08 + 0.20) 3.00 +0.14| 17.56 + 0.86
18.06 + 0.22} 3.31 +0.16| 18.33 + 0.90
26.59 + 0.84 | 11.30 + 0.60 | 42.50 + 2.61
24.26 + 0.69| 7.68 +0.49 | 31.66 + 2.19
21.48 +0.28| 4.204 0.20] 19.55 + 0.97
20.76 +0.23| 3.34+0.16]| 16.09 + 0.79
28.50 + 1.41 | 7.82 +1.00 | 27.44 + 3.75
25.00 + 0.77| 3.98 £0.55 | 15.92 4+ 2.25
19.00 + 0.28} 2.40 + 0.20] 12.63 + 1.05
18.68 + 0.27] 2.97 +0.19] 15.90 + 1.04
20.06 + 0.33 | 4.89 + 0.23 | 24.38 + 1.23
18.75 3: 0.22) 3.31 4-016) 17,464 Oe

A RECESSIVE CHARACTER AND SELECTION

TABLE 1—Continued

183

OFFSPRING

mowna Nr] ace | Seat | pti

26.75) 43118.99+0.44) 4.32 +0.31 | 22.75 + 1.74
19.40) 44] 19.324+0.34] 3.37 +0.24| 17.444 1.29
22.20} 78 | 18.88 +0.30| 3.99 + 0.22 | 21.13 +.1.19
22.70} 69 | 20.12+0.35) 4.35 + 0.25 | 21.62 + 1.30
24.63) 28 | 21.43+0.54| 4.26 + 0.38 | 19.88 + 1.86
26.29) 39 | 22.01 +0.35| 3.26 +0.25 | 14.81 + 1.16
24°89; 100 | 18.07 +0.19| 2.75 + 0.13} 15.22 + 0.74
23.73} 100 | 19.18 +0.19| 2.88+0.14]| 15.02 + 0.73
20.87; 80 | 19.70+0.22| 2.96 + 0.16} 15.03 + 0.82
20.67; 68 | 20.7440.33| 4.07 + 0.24) 19.62 + 1.18
22.20) 51 | 17.98 +0.27| 2.87 + 0.19 | 15.96 + 1.09
25.57; 30 | 20.4840.56| 4.52 + 0.39 | 22.12 + 2.02
20.60} 44 | 18°32 + 0.33 |_ 3.23 + 0.23 | 17.63 + 1.31
23.20) 50 | 19.50 + 0.32] 3.35 + 0.23 | 17.184 1.19
20.50} 111 | 16.744+0.14| 2.11 +0.10 | 12.60 + 0.58
20.63} 109 | 17.66+0.16| 2.46 + 0.11 | 13.93 + 0.65
18.25, 50/19.2040.27| 2.884 0.19 | 15.00 + 1.03
21.00) 37} 19.03 +0.36] 3.21 + 0.25 | 16.87 + 1.36
22.50) 83] 19.10 +0.35] 4.77 + 0.25 | 24.97 + 1.39
23.29) 100 | 17.42+0.17} 2.55+0.12| 14.644 0.71
26.57} 100 | 17.09 = 0.15] 2.26240.11 | 13.22 + 0.64
20.00} 99 |17.8840.17| 2.45 +9.12 | 14.10 + 0.69
21.50} 39] 18.33 40.26| 2.45 +0.19 | 13.37 + 1.04
21.00} 25 /19.52+0.30} 2.234 0.21] 11.42+1.10
20.60} 47 | 18.89 +0.38| 3.87 + 0.27 | 20.49 + 1.48
20.67} 38)19.2140.41| 3.74+0.29 |} 19.47 + 1.56
24.67} 28/18.7140.31|] 2.438 + 0.22 | 12.994 1.19
23.71] 26 | 20.1540.47| 3.52 + 0.33 | 17.47 + 1.68

184

ELMER ROBERTS

TABLE 1—Concluded

TION

PARENTS

114
104

11
14

OFFSPRING

24.77 + 0.56
22.41 + 0.40

20.00 + 0.34
19.19 + 0.48
16.26 + 0.18

17.86 + 0.25
17.32 + 0.16

22.43 + 0.45
20.38 + 0.26

20.55 + 0.45

]
16.52 + 0.20
23.07 + 0. “dt| fie alegcee| saesalesnie

Standard
deviation

8.95 + 0.39
6.02 = 0.29

2.50 + 0.24
3.28 + 0.34

2.28 + 0.14
2.52 + 0.13

3.75 +0. ;
2.36 + 0.11

7.19 + 0.32
3.89 + 0.18

2.23 + 0.32
3.39 + 0.43

Coefficient of
variability

36.13 + 1.79

26.86 + 1.36

12.50 + 1.21
17.09 + 1.83

13.80 + 0.86
15.50 + 0.82

21.00 + 1.04
13.63 + 0.66

32.06 + 1.57
19.09 + 0.92

10.85 + 1.58
14.69 + 1.91

A RECESSIVE CHARACTER AND SELECTION

TABLE 2
Means, standard deviations, and coefficients of variability of length of vestigial

wings in control series B

185

| eee ee

F,

F,

F;

Fe

GENERATION

SEX

40 Qy 40 Qy 40 Qy 40 Qy 40 Qy 40 Qy 40 Q, 40 Qy 40 Qy 40 Qy 40 Q 40 Qy 40 Q,

10%

NUM-
BER

1
1

MEAN

18.00
22.00

16.22 + 0.
16.24 + 0.

16.32 + 0.
16.24 + 0.

16.36 + 0.
£7.66 2-0.

17-89 = 0:
16.67 + 0.

17.53 + 0.
16.10 + 0.

17.08 + 0.
15.95 + 0.

17.76 +0.
16.73 + 0.

16.30 + 0.

16.19 + 0.2

1b516 = ©.
15.42 + 0.

26. fia Oe
23.57 + 0.

19.02 + 0.
18.01 + 0.

18.42 + 0.
18.05 + 0.

16.63 + 0.
17.21 + 0.

92
Al

41
40

25
18 |

STANDARD
DEVIATION

COEFFICIENT

OF

VARIABILITY

25.15 + 4.
17 he Sa

1G tS == £:
Ld AS ee a

22.86 + 1.
15.40 + 0.

20.29 + 3.
13.92 + 1.

20.37 + 1.
21.18 =e:

if.33 =
14.86 + 1.

16.72 ===
16.38 + 1.

14.66 + 0.
16292 2,1.

15e7e == 9.
15.24 + 0.

41.65 + 2.
BP aie a

34.07 + 2.
2b 27 = I.

at 34 4-1.
16.90 + 0.

15.94 + 0.
16.15 + 0.

00
82

20
11

10
94

90
97

186

of ff O_O | _______________|

GENERATION SEX ee
Fy oer { a ee
Hpee st eee. { e =
Tbe # dake { 2 3

TABLE 2—Coneluded

MEAN

21.43 + 0.50
18.64 + 0.33

16.42 + 0.30
16.92 + 0.17

16.92 + 0.20
16.53 + 0.18

ELMER ROBERTS

STANDARD
DEVIATION

5.42 + 0.35
4.39 + 0.238

2.16 + 0.21
1.51 + 0.12

2.63 + 0.14
2.48 + 0.13

COEFFICIENT OF
VARIABILITY

25.29 + 1.74
23.55 + 1.32

13.15 + 1.30
8.92 + 0.70

15.54 + 0.85
15.00 + 0.80

GENERA-

TION

A RECESSIVE CHARACTER AND SELECTION

eI
4

PARENTS

TABLE 3

Means, standard deviations, and coefficients of variability in ‘crossed-in-and-
selected’ series C

OFFSPRING

Standard
deviation

a ee

E

10
Q | 12
si
2
o 78
9] 8
sig) Sead
Q 2
og aes)
OF vets
eels: Al
oe eG
eo |. 6
os pone
ois
hal ded
ty
Ss
‘sige
Q | 18
omy eer
g r¢
| 4
e156
Oh. 4
9 | 8

20.50
Long winged

Long winged
Long winged

36.60
23.62

22.67
25.00

30.20
23.71

28.25
21.50

25.00
22.29

34.00
21.86

30.40
24.00

39.42
28.83

32.00
29.14

22.50
21.67

28.75
20.87

Long winged
Long winged

19.74 + 0.40
18.06 + 0.21

17.81 + 0.21
17.49 + 0.17

24.58 + 1.33
23.71 + 0.75

19.50 + 0.67
18.39 + 0.29

19.27 + 0.34
19.51 + 0.29

21.36 + 0.42
19.04 + 0.14

23.01 + 0.43
20.29 + 0.20

30.50 + 0.66
22.81 + 0.47

21.71 + 0.53
21.61 + 0.33

19.30 + 0.76
19.18 + 0.64

19.20 + 0.84
18.89 + 0.47

21.53 + 0.55
18.57 + 0.24

5.96 + 0.28
3.02 + 0.15

3.08 + 0.15
2.52 + 0.12

6.82 + 0.94
2.96 + 0.53

4.90 + 0.48
2.49 + 0.21

3.68 + 0.24
2.86 + 0.20

5.33 + 0.30
2.27 + 0.10

5.32 + 0.30
2.90 + 0.14

7.83 + 0.47
5.48 + 0.33

5.97 + 0.37
3.86 + 0.23

3.58 + 0.54
3.16 + 0.45

5.56 + 0.59
2.94 + 0.33

6.26 + 0.39
2.51 + 0.17

187

Coefficient of
variability

30.19 + 1.55
16.72 + 0.88

17.29 + 0.84
14.41 + 0.70

27.75 + 4.10
12.48 + 2.28

25.13 + 2.60
13.54 + 1.14

19.10 + 1.30
14.66 + 1.06

24.95 + 1.49
11.92 + 0.54

23.12 + 1.39
14.29 + 0.72

25.67 + 1.63
24.02 + 1.55

27.50 + 1.85
1%. 86 + 1.12

18.55 + 2.89
16.48 + 2.43

28.96 + 3.34
15.56 + 1.79

29.08 + 1.94
13.52 + 0.94

188

GENERA-

TION

PARENTS

ELMER ROBERTS

TABLE 3—Continued

OFFSPRING

Standard
deviation

10

40 9

33.97 + 0.91
31.47 + 1.33

28.53 + 1.39
23.79 + 0.52

19.74 + 0.46
17.46 + 0.35

30.31 + 0.77
23.82 + 0.58

39.15 + 0.64
35.04 + 0.67

35.71 + 0.64
26.27 + 0.51

40.60 + 0.46
34.94 + 0.64

39.23 + 0.67
37.43 + 0.83

24.74 + 0.92
24.17 + 0.59

27.32 + 0.87
24.89 + 0.57

36.05 + 0.88
29.70 + 0.91

31.57 + 0.90
25.40 + 0.76

33.54 + 1.22
26.54 + 1.05

27.52 + 0.65
22.10 + 0.44

10°78 =: 0:
tea 4 Se (0).

8.99 = 0:
3.37 + 0.

3.99 = 0.
2.78 + 0.

133 (=e 0%
6.75 + 0.

io ---0e
8.49 + 0.

Sor =p:
10% 2:0

(/ ULE 0)
9.41 = 0.

8.48 + 0.
10.14+0.

7.36 + 0.
aoe ee

9.12 +0.
6.63 + 0.

8.29 + 0.
10.05 + 0.

Je i eal
8.00 + 0.

11.55 + 0.
8.26 + 0.

9.06 + 0.
Ge Aen al

31

Coefficient of
variability

31.73 + 2.07

36.61 + 3.37

31.51 + 3.77
14.17 + 1.58

20.21 + 1.72
15.92 + 1.47

25.97 + 1.92
28.34 + 1.85

18.72 = 119
24.23 + 1.42

26.63 + 1.34
28.70 + 1.47

17.27 + 0.82
26.93 + 1.40

21.49 + 1.27
27.09 + 1.68

29.75 + 2.86
17.25 + 1.77

33.38 + 2.49
26.64 + 1.72

23.00 + 1.82
33.84 + 2.39

29.74 + 2.20
31.50 + 2.33

34.44 + 2.85
31.12 + 3.06

32.92 + 1.84
23.39 + 1.48

ar eel

A RECESSIVE CHARACTER AND SELECTION 189

TABLE 3—Concluded

PARENTS OFFSPRING
ase. SEX| 1: P
uw ue ffi 7 f
BB) Means | 33) Means Fanaeoe™ |’ panentey
r a | 9 32.78 70| 23.41 +0.45| 5.55 + 0.32] 23.71 + 1.48
poet \l io 4) 5 31.00 72| 20.60 + 0.29} 3.60 + 0.20] 17.48 + 1.01
F Nee? 28.57 Al| 18.32 + 0.42] 3.97 + 0.30] 21.67 + 1.69
eh baae 22.43 34] 18.53 + 0.29] 2.53 + 0.21/13.65 + 1.14
P { gi 3 22.00 71! 21.87 + 0.48 | 5.98 + 0.34] 27.34 + 1.66
oe? Must y 20.83 107| 19.16 +0.18| 2.69 + 0.12] 14.04 + 0.66
Fr ants 24.00 91] 23.66 + 0.58 | 8.21 + 0.41] 34.70 + 1.93
‘wl ash 6 24.00 105) 18.83 + 0.21 | 3.18 + 0.15] 16.89 + 0.81
F ao | 4 40.50 47| 28.11 +0.91| 9.20 + 0.64| 32.73 + 2.51
foe yl 9 Wg 27.20 65| 21.388 +0.35| 4.21 + 0.25] 19.69 + 1.21
F a | 3 38.00 59| 43.23 + 0.40 | 4.56 + 0.28] 10.55 + 0.66
al 0 a 27.86 55| 39.15 + 0.66 | 7.39 + 0.47| 18.62 + 1.24
K & | 15 40.73 2) 49.50
a yh ey | 12 44.33 6| 40.33 + 1.82] 6.60 + 1.29] 16.36 + 3.27
TABLE 4

Average of length of vestigial wings of males and females in control series B

AVERAGE ; AVERAGE
GENERATION NUMBER OF GENERATION NUMBER OF
OFFSPRING OFFSPRING
[Piet ot ie eo eee 2 20.00 gris Sak < oie eee 184 15.59
Pe AA witha s/o... 30 16.23 Big Siege rege vee 2 re tare coseeel ae o 25.32
ee 36 16.28 lee ae eee wer 158 18.44
Is Se 206 17.03 ae eee oe 171 18.25
1 ete ca Gr CoC 21 17.19 Bis aprtan 0 «see 142 16.90
Eg. RE at, Son 148 16.75 Lyre, S SA RR cs 2 135 19.76
ee eo cee ae 32 16.41 Eiiecmen vaca < « < otetnciee 62 16.73
Ee: «eb es Se oes 115 17.26 ieee deers... ote 162 16.72
aerator aber 119 16.25

THE JOURNAL OF EXPERIMENTAL ZOOLOGY, VOL. 27, No. 2

190 ELMER ROBERTS

TABLE 5
Average of length of vestigial wings of males and females in selected series A
AVERAGE AVERAGE AVERAGE AVERAGE
GENERATION OF OF GENERATION OF OF
PARENTS OFFSPRING PARENTS | OFFSPRING
Beyonce pee 20.00 16.23 Fis. 24.22 18.62
Bigs S42 Fo soe sh ee ie 19.50 16.39 ee eo Sac 20.76 20.18
int ee ee ee 18.00 19.25 ghey: se:-- 2A 24.17 18.89
gore ee oe: ee 24.25 18.45 | OS Ae iia ere ene ae 21.90 18.95
Fh ge oS - Ee 19.71 UM Meetbs. . Ses): oe Ss Ske oe 20.57 17.20
be eee ee, ae ey ee 22.11 17.95 Fy3. 20.00 19.13
1 a Se sah eeden See 21.83 18.87 Fog. 22.93 18.18
he Sd. Bat re fh 21.27 18.70 Fo5. 22.42 17.23
Ty da Sk Melek ae 22.17 17.57 Fog. 21.17 18.79
igre. ae. hak. ths Soe 20.21 25.63 Foz. 20.64 19.03
ee eee eee 40.46 21.12 Fog. 24.15 19.40
Fy. 26.58 26.88 Fog. 23.00 23.68
Fi; 30.69 18.80 (a et: Bae eee 34.87 19.63
yas st iat Ax. Sat et 21.09 19.40 Bar? Sos cia a FAD = ike Se 20.87 16.37
Bye: S226 On Hea 23.92 19.16 | ne oo oe 18.07 17.59
eg. paste eee 22.45 19.46 Poe cb ae iaik ae 22.93 21.45
Wag: cd AX Hos 45 eee 21.77 , ee ee 33.00 21.96
TABLE 6
Average of length of vestigial wings of males and females in ‘crossed-in-and-selected’
series C
GENERA- AVERAGE OF AVERAGE OF GENERA- AVERAGE OF AVERAGE OF
TION PARENTS OFFSPRING TION PARENTS OFFSPRING
Hitt ae 20.50 andlong-| Long-winged || Fis...... 35.24 36.88
winged Wygse seat 42.77 31.01
openness Long-winged * 18.92 io ee 37.20 37.90
ghia et' 28.62 17.65 Beysties 44.05 38.35
_ gaa 23.60 24.26 1 ee 45.50 24.49
Biche ee 26.41 18.86 Mass och 29.08 25.97
A eae 24.20 19.38 Wace 2 se 34.60 32.35
ated eae 23.54 19.95 ee. 39.93 28.45
| ae sae 26.92 21.45 | Dae 37.19 30.70
Bate. ce « 26.46 26.75 Way. .e5.- 40.08 25.27
Lt Reeaaae S307) 21.66 (Hee... ee 32.14 21.99
ae... 30.00 19.24 pr eae: 25.50 18.42
Rigas os. : 22.00 19.05 Bisg-2 5 oe 21.22 20.24
Bee se. 23.50 20.20 1 ae pe 24.00 21.07
eee Ss. 24.67 33.10 doe Re 33.11 24.20
Ce 45.80 26.16 Byes 2 30.90 41.26
Neg 31.40 18.71 Rage te: ee ea 42.62
ee 21.85 26.52

ee

A RECESSIVE CHARACTER AND SELECTION 191

TABLE 7

Means, standard deviations, and coefficients of variability in ‘crossed-in-and-

selected’ series C subjected to high temperature

PARENTS A OFFSPRING
GENERATION | SEX Sta. Aard Co. ficient of
- - ni
Bee Means bar’ Means deviation variability
~ {le 7 | 28.57; 88 | 39.73+0.60| 8.18+0.43 | 20.46+1.12
et fe) 7 | 22.43) 95 | 33.77+0.66! 9.48+0.46 | 28.07+1.48
e ee 1 | 53.00] 37 | 48.64+40.61] 5.53+40.43 | 11.37-+0.90
are oy Q 3 | 42.67, 39 | 45.4640.83| 7.65+0.58 | 16.83 41.32
F a 1 | 55.00] 11 | 53.64+0.99| 4.8540.70| 9.04+41.31
as elle 2 | 50.50| 7 | 42.8641.40| 5.51+0.99 | 12.86 + 2.36
e
F o | 11 | 53.64] 44 | 47.9340.39| 3.88+0.28| 8.10-+0.59
oer Q 7 | 42.86) 40 | 48.35+0.69| 6.45+0.49 | 13.34+1.02
r ea 8 | 49.871 15 | 49.7340.43| 2.46+0.30| 4.95+0.51
ded “\! 9 | 12 | 52.75] 16 | 50.06+1.05| 6.25-+0.75 | 12.49 +1.51
Fr a dos 49:73) 1d | 50.09-0°77-|. 3.78 +-0.54. |. 7.40. 107
of “\} 9 | 16 | 50.06] 16 | 52.1941.10| 6.54+0.78 | 12.53 +1.52
F a | dk | 509] 35- 1-49.37 £0.48 |. 3.80 4-0°31 | 7. 70-0562
7 ane 9] 16 | 52.19] 24 | 50.96+0.67 | 4.84+0.47|] 9.50+0.93

TABLE 8

Means, standard deviations, and coefficients of variability in a cross of a long
vestigial-winged male and short vestigial-winged females, under high temperature

GENERATION ad |e MEAN eee eres
Pp {|e 1 | With almost perfect wings—length about 50
ld e\6\ee «4 0 0) ce Q 3 16 : 33

F a 70 | 32.13 + 0.62 7.7140.44 | 24.00 +1.44
eae ee Ss 9 89 | 22.63 + 0.28 3.92 +0.20 | 17.32 +0.90

of 56 | 40.14+ 0.90 10.04 + 0.64 25.01 + 1.69
; | 132 | 31.64 + 0.58 9.83 + 0.41 31.07 + 1.41

SE hy’) a ae ne

192 ELMER ROBERTS

TABLE 9

Average of length of vestigial wings of males and females in ‘crossed-in-and-sele lec
series C subjected to high temperature

ayers) | _ | AVERAG
OF OF ss *4

GENERATION © OF GENERA- GENERATION

a |
Slereiatavala eee = © esl sie if “dt ater ff) SECT IRRER OT) Bk BS oo 0 os se) ofp aus em © (ete

ayes) tare ielicelehahe cate ec olf) Gre IGP 'F SEM ey eR FN) SEO 4-3) 0). ates «ie fist a alate 4) = tH

lofe, vowue iets! ees \e 6 ha

AUTHOR’S ABSTRACT OF THIS PAPER ISSUED
BY THE BIBLIOGRAPHIC SERVICE, OCTOBER 8

REACTIONS OF LAND ISOPODS TO LIGHT

CHARLES HARLAN ABBOTT

Biological Laboratory, Brown University

CONTENTS

EDA TIMCLMUEACSE Oo d eet Ck Se Ste tN FG a oa aha a od a al 194
SE RAR VE TEEN pe ert ttt, he Sena hateye «oslo, <olcle tinin, he 40's diame, os cisamiatia/ a agile s 195
EER, Ate es ere SEN OSA ER ces pace cis Rees eee ese 196
Cun Geied ls DENTINE Lt Petite acai <2 kick tts filet us Sahota chee SER We ES 197
Pape ER EPEC OTA GLONIGEHIY -gsick siege nisin oe “eisiods Abd <)= p\ny chighe ohare mista ara ne oo 197
JPM Eley) Sn ETT et ee OR ee ne RS ee a 2 Pie 197
PETES GINGA. cra get ae PMS GIRS SN ctchn enlaces colds cparcyalas sw, eae 197
PAVIISLONIOR SA Meith cette Tole cine SirAeeeeeta ts Ake oer 198
Be Belahion Of. comtach And: VISION. ac.%:. <a. ss.» 34s «epee Pe aneies Soar 198
Me Hxpemments with directive. light. .o72 26.2 sete ok «oe cine ssiele den oh ve oes 199
PACE ANSEAT VOUS cree) <istarceePateset on ve rata erm creel trorNe slehns ccs amtscciaenN Mere <, opel ead of 199
ESR INOTIGAN ORE LIOUS: 5. Sh tieitais coat ee eee tek Seta se Pde toe eA Eh ORR 205
1. Positive and negative responseS...................0-+002- 206
Pe OMEN ADION, 625 1e Se aka Shaye dae FOE © ste inlets slate tae 208
oO: Angle’ OF NEPAtIVENESS: .c. 751-5 was eee Sete of da ea 2 Oa oe 211
LON COCTEPY E017 pe a A La oA OR Ko: Beret eee eM che SL 214
C. Modifiability of the light reactions.................... Eye AE te 215
i Reaction to. difierent: intensities... 02. <3 = 252. Scryers aoe) ee 216
2. iieet ol repeated stimulation: «0s, 52.42. «+2 seas ses Sees. 220

3. Comparison of reactions following exposure to light and to
Geile de kd. gate ake ID. SUAS oo Sadie 7 ee 223

4. Comparison of reactions of individuals from dry and moist
LOTS as Se AP MEME Si lS oes 225
Pema O LEH MINIT SL OD: «oi told a5) </4;</5lxi gaat oie rthales natame anne = aarti 226
6. Comparison of phototaxis in Oniscus and Porcellio......... 228
PP IMPCUMENADA. 545/08 Fiat'st lads le sak sere E a arts oR ee eS 230
Op UR ITS De) EE a ee Be ee TPES 5) | oe os ae 231
a REM RECTUC OES 0 a Soho ic acl sib.» « o/n int nicotine oop Og apes ga meets 231
ily, ABFA OT FE Tian Ae sale oe hs Ban Cece aI RIENCE oc TOR I SPR Re Peters Sta Ae 232
2. Structural and physiological adaptations.................. 232
GOB INERTIOU cele so. i cd piek oo wate okie TSE ON Mette Site dp Sache 232
MNES, uterine so)... so's:s PER wi ah IMR vine dR BS a coh Ay 233
Se EUS COVENT «yc, 0in's sin binie a centeein Pate wane aise Gare oe 233
GEES OIA VLOY ty) sae PAE os hinc.s Dade an s Salo ee Oak wh RIES 233

193

194 CHARLES HARLAN ABBOTT

SaResgchionsiot and lsOpodsasameriee ser eee eee 234

a. Reactions to humidity and evaporation............... 234

b. Reactions to contact. .20..6 6:5. occ e eee eee 235

co Reactions, tolightys... atc | eee ee eee 235

B. The problem ‘of orientation... . 2.0...) .4.2a..42 0) eee 238

1. Direct orientation versus method of trial.................. 239

2. Constant intensity versus change of intensity.............. 239

3 e@onclusiOns:: . 2. acces okie vets oo ee eee ee 243

Vile Summary. 2 OCC BRE 2. 2a. URGE no ae 243
VAITES Bibliography ....c. 5... 5 4s gsmeye despre ee oo cas ei ein See eae er 245

I. INTRODUCTION

Land isopods, commonly called sowbugs, have always been of
interest as the only Crustacea which are truly terrestrial. How-
ever, most previous studies of the adaptation of this group of
animals to a land environment have been devoted only to the
structure and function of the respiratory organs. The behavior
has been almost entirely neglected. Behavior studies, always of
interest to comparative psychologists, have been made increas-
ingly important by the récent development of animal ecology
into an experimental science, in which behavior is used as a test
of the influence of environment. ‘This use of behavior investi-
gations is emphasized in the general ecological works of Adams
(13) and Shelford (’13), and has been applied by Banta (’10)
and Allee (712, ’14) to the study of fresh-water isopods.

The present study of land isopods has therefore been under-
taken in order to learn if their behavior is of ecological im-
portance. The plan has been, 1) to study the reactions to in-
dividual factors of the environment, and 2) to find out if these
reactions assist in fitting the animals in question to occupy their
present habitat.

This paper reports a study of the behavior of land isopods
with respect to one of the most important environmental factors,
namely, light. Although the results are considered also from the
standpoint of the problems which particularly interest all stu-
dents of animal behavior, the ecological viewpoint has been the
guiding principle throughout.

The experiments were carried on at the Biological Laboratory,
Brown University. I wish to thank the authorities of the uni-

REACTIONS OF LAND ISOPODS TO LIGHT 195

versity and of the laboratory for the opportunities and facilities
for research which were furnished me. My greatest debt is to
Prof. H. E. Walter, under whose supervision the work was done,
for stimulating my first interest in behavior studies, and for helpful
suggestions and criticisms at every stage of the investigation.

II. HISTORICAL

While naturalists have commonly concluded thag land isopods
are negatively phototactic, very little experimental work has
been done on their reactions. The papers of Cole (’07) and
Torrey and Hays (’14) appear to form the entire literature on
the subject. ;

Cole ('07, pp. 371 to 375) in “‘an experimental study of the
image-forming powers of various types of eyes’? found Oniscus
asellus negative to light, but not so uniformly as some other
animals, for example the mealworm (larva of Tenebrio molitor
Linn.). ‘‘Only 45 per cent to 51 per cent of the reactions were
away from the light, in excess of those toward the light.” Cole
exposed Oniscus to illumination from the side, and recorded the
place where the animal crossed the circumference of a circle
which had a radius of 10 cm. The intensity of the light used
varied from 1.5 to 5 candle meters. Cole further found that
Oniscus shows a slight discrimination between two sources of
light of different diameters which deliver the same intensity on
the animal.

Torrey and Hays (’14), working on the orientation of Por-
cellio secaber, recorded that the animal has a negative response
to light, and may be oriented very accurately, 1) by a constant
light from behind, 2) by a sudden exposure to lateral light, or
3) by a ‘‘sudden exposure to light from the front at angles be-
tween 90° and 15°.” ‘‘When exposed suddenly to light coming
from the front at angles less than 15°, Porcellio moved with less
consistency away from the light, but the reactions were, on the
whole, markedly negative.” These authors concluded that the
orientation of this species is direct, and is not brought about by
selection of random movements.

196 CHARLES HARLAN ABBOTT

In the experiments of Torrey and Hays the source of illumi-
nation was a Mazda bulb held near the animal. No attempt was
made to measure the intensity, but apparently all the work was
done with rather high intensities.

Many of the questions which arise with regard to the light
reactions of land isopods are not answered by either of the
papers just referred to. The present study is an attempt to
gain a more thorough understanding of the reaction of land
isopods to lift, in order to interpret the ecological significance
of the behavior.

III. MATERIAL

The common species of land isopods belong to the superfamily
Oniscoidea and to the family Oniscidae. They are favorable for
experimental work because they are abundant, are generalized
in their mode of life, and are suited to life in a laboratory. The
species Oniscus asellus Linn. was used chiefly for the study, but
for comparative purposes two other common species, Porcellio
rathkei Brandt and Porcellio scaber Latreille, were also tested
in many of the experiments. Complete descriptions of these
species are found in Richardson’s Monograph (Richardson, ’05),
and it is not necessary to repeat them here. Various points in
the description important from an environmental standpoint,
particularly differences between the genera, are given in suc-
ceeding pages.

As sowbugs live normally under almost any object that fur-
nishes concealment together with a certain degree of moisture,
and as they frequently invade houses, it is not difficult to du-
plicate their natural surroundings in the laboratory. They were
kept in round glass dishes, containing earth, dry leaves, and
bark, and covered to prevent evaporation. To allow for pos-
sible results of differences in temperature, some were placed in
ordinary heated rooms, while others were left out of doors in
wooden boxes. Attempts to keep them alive outside the building
during the winter months were, however, unsuccessful. Other-
wise many of them lived an apparently normal life for several
months in the various habitats, and some which were kept in a
warm room produced broods of young in December.

REACTIONS OF LAND ISOPODS TO LIGHT 197

IV. NORMAL BEHAVIOR
A. REACTIONS TO LIGHT

Animals respond to photic stimuli by three methods:

1. Increased or decreased activity, without orientation.
(Photokinesis. )

2. Definite orientation with respect to the source of light,
usually accompanied by locomotion toward or away from the
light. (Phototaxis.)

3. In animals with image-forming eyes, response to some sort
of image made upon the photoreceptive cells. (Vision.)

Inasmuch as sowbugs live in concealed places, the part which
light normally plays in their activity is not easily observed. It
is, however, clear that they can become accustomed to living
in the ordinary daily rhythm of light and dark, because they
lived a normal life for weeks in the laboratory under these
conditions.

1. Photokinesis

Sowbugs appear to respond to sudden increases in intensity
of light, both when they are exposed by the overturning of a
log under which they are concealed. and, in the laboratory,
when a near-by artificial light is turned on. Two types of re-
sponse follow under either of the described conditions:

1. Increased activity.

2. Complete cessation of activity.

If the response is one of increased activity, the animals usu-
ally keep moving until they reach concealment or, at least, par-
tial concealment in a crevice. The individuals which are inac-
tive at first later become active and seek a more protected situa-
tion. No sowbugs are left in sight a short time after a log which
has concealed them is overturned.

2. Phototaxis

Under the conditions just described, the light is too diffuse to
bring about any definite orientation of the isopods. When,

198 CHARLES HARLAN ABBOTT

however, they accidentally start to.wander out from dark cavi-
ties, a definite phototactic reaction probably turns them back
into the dark again. This behavior is difficult to observe in the
field, and analysis is, moreover, complicated by reaction to
contact.

Simple experiments show that land isopods have a phototactic
response to light, even when the light is somewkat diffuse. For
example, at 4 P.M. on January 19th, when the light entering the
room through a north window was becoming rather dim, indi-
viduals of Oniscus, placed on a table several feet from the win-
dow, definitely and consistently turned away from the light
and traveled in the opposite direction. Such experiments show
that these animals have a definite negative phototaxis in ordinary
daylight.

The experiments in the following sections are devoted to
analysis of this reaction.

3. Vision

Land isopods have rather primitive compound eyes, and are
to be classed among the animals which have the beginning of
vision. As they live constantly in the dark, it does not seem
probable that vision plays any appreciable part in their normal
life. Observation of the use of the antennae in ordinary iso-
pod activity indicates that vision is of much less importance
than reaction to contact in the ordinary life of these animals.

B. RELATION OF CONTACT AND VISION

The antennae, the most important contact organs of the
isopod, are in constant use during ordinary locomotion. They
are extended in front of the head and the tips are repeatedly
touched to the substratum. The animal often pauses and waves
its antennae about in the air or rubs them over any object which
chances to be in its path. The antennae are used to test the
nature of the environment in a way similar to that in which a
blind person, by passing the finger-tips over objects and by the
use of a cane when walking, uses the sense of contact as a sub-
stitute for the sense of sight.

REACTIONS OF LAND ISOPODS TO LIGHT 199

When the isopod is at rest, the antennae are often spread on the
substratum before it. They are frequently moved independently
of the rest of the body either just before locomotion begins or,
sometimes, at the moment when the animal pauses before chang-
ing the direction of its course. When the animal is stimulated
by directive light, similar movements of the antennae usually
occur before locomotion is started. They are described by
Torrey and Hays (14) as analogous to the so-called ‘random
movements’ of the earthworm or blowfly larva.

Another common movement of sowbugs, both during ordinary
activity and when stimulated, is that of ‘wiping’ or ‘cleaning’
the antennae. This ‘cleaning,’ which occurs in other higher
Crustacea as well, consists in passing the first walking leg over
the antenna as if cleaning it.

The importance of the antennae is shown further by observa-
tion of the locomotion after the antennae are removed. Without
antennae, obstructions in the path are not usually avoided until
the head or the anterior walking legs come in contact with them.
On the other hand, according to Torrey and Hays (14), “‘totally
blind individuals avoid obstacles with the ease of normal indi-
viduals.”” These results following blinding and removal of
antennae indicate that the eyes are not normally used for vision.

V. EXPERIMENTS WITH DIRECTIVE LIGHT
A. APPARATUS

The experiments were performed in an experimental dark-
room in the basement of the Arnold Biological Laboratory,
Brown University. A description will be given of the apparatus
which was employed after applying the ‘trial and error method’
to the devising of apparatus. A table, 122x 75 cm., painted
dead black, was placed in the center of the room, under a con-
venient overhead light. This table, with space for the ob-
server, was surrounded by a black curtain which cut off both the
dim light from the ventilator of the room and reflections from all
other objects which were not painted black.

200 CHARLES HARLAN ABBOTT

At one end of the table was placed a wooden box, black both
inside and outside, containing the source of light—a 60-watt,
250-volt Mazda lamp. To insure symmetrical illumination of
both sides of the field, the lamp was placed in a vertical position
in the box. The light passed out through a horizontal slit,
41x23 mm., in a diaphragm. The lower edge of this slit was 5
mm. above the table top, insuring the illumination of the surface
of the table and at the same time allowing the light to strike
the eyes of the isopod from a horizontal direction. _ The slit was
covered with thin paraffined paper in order to make a source of
even illumination. The relation between the table top and the
source of light is shown in figures 1 and 2.

Fig. 1 Vertical diagram of apparatus: mn, table top; D, diaphragm; s, slit
in diaphragm through which light passes; L, light; W, rectangular jar of distilled
water to cut out heat; p, position where animals were placed; mp, path of light
to point p.

A horizontal field, 60 x 40 em.. divided into squares 10 em. on
a side, was marked out or i... part of the table next to the
light (fig. 2). This gave an area with the intensity gradually
diminishing both from the source of light to the opposite end
of the field and from the center to the sides. As the slit in the
diaphragm through which the light passed was only 41 mm. in
length, dark corners (fig. 2, ¢ and c’), were left at the sides and
not included in the experimental field. Black strips of wood
were placed along the lines ef and 7 & to shut off possible side
reflections. The diaphragm was 5 mm. from the edge of the
field. .

In most of the experiments the animals were exposed to the
light after they had been placed in the center of the field, i.e.,

REACTIONS OF LAND ISOPODS TO LIGHT 201

30.5 em. from the diaphragm and 20 em. from the sides of the
field. A circle with a radius of 10 em. was drawn about this
point as a center, and was divided into sixteen sectors, which
were numbered 1 to 8 on each side of the central axis mn
(fig. 2).

The intensity of the light was measured by means of a Mac-
beth illuminometer, which was kindly loaned by Prof. W. E.
Kenerson, of the Engineering Department. Intensities in candle
meters (C.M.) of the principal points of the field, determined

Fig. 2 Horizontal diagram of apparatus: efghjk, experimental field, divided
into squares 10 cm. on a side, with a circle of 10 em. radius at the center; mn,
central axis of field, receiving the most intense light; c and c’, dark corners; B,
box containing light; L, light; D, diaphragm; s, slit in diaphragm; W, rectangu-
lar jar of distilled water to cut out heat.

early in the experiments, are indicated in figure 3. The inten-
sities at three points along the axis m n, i.e., at 20.5, 30.5, and
40.5 cm. from the diaphragm, were determined with considerable
accuracy. The intensities of the other points indicated were less
easily determined, due to the angles at which it was necessary
to make the readings and to the rapidly decreasing light on the
sides of the field. This difficulty will account for the differences
in the readings from the two sides. The constancy of illumina-
tion throughout the experiments is indicated by a reading of

202 CHARLES HARLAN ABBOTT

12.79 C.M. for the central point, made six weeks after the read-
ing of 12.955 C.M. recorded in figure 3.

It can be seen from figure 3 that an animal starting from the
central point will go into a region of diminished intensity unless
it travels into the quadrant of the circle toward the source of

i Diirecition of

Fig. 3 Diagram of experimental field, showing intensities of light in C.M.
at principal points of the field, measured with Macbeth illuminometer. Heavy
black line shows the division of the circle into two parts, negative and positive.

light. This fact makes possible a division of the circle into the
two parts shown in figure 3. If the animal leaves the circle in
the quadrant nearest the light, it goes into a region of increased
illumination, and hence shows a positive response. If it goes in
any other direction, the response is negative.

REACTIONS OF LAND ISOPODS TO LIGHT 203

For convenience in manipulating the animals, small cardboard
boxes were used, a little longer than the animal and just wide
enough to enclose it without allowing it to turn around (fig. 4).
When the sowbug had been shoved to the desired position, the
box was removed, and the course taken by the animal was
observed and recorded.

In the experiments the isopod was tested successively in four
different positions, namely, facing the light (A), facing away
from the light (B), with the right side illuminated (C), and with
the left side illuminated (D). This was to eliminate errors due
to a possible tendency of the isopod to travel in the direction
in which it was already headed.

WA

| \

he

Fig. 4 Diagram of frame with which animals were manipulated on the
table top.

The reactions were recorded on printed sheets of paper like
that shown in figure 5. It contains four diagrams of the experi-
mental field, the squares corresponding to the 10-cm. squares on
the table. With the aid of the squares it was possible for the
observer to duplicate the course of the animal with considerable
accuracy. The four diagrams were used for the four: positions
A, B, C, D just referred to. Each record consisted of twenty
trials, five each in the four positions. These were made in the
order A, B, C, D, A, B, ete., to avoid effects of immediate repe-
tition of the same stimulus. The responses were numbered in
the order in which they occurred in the series. Figure 5 is a
typical record of the reactions of a normally negative Oniscus.

ABBOTT

CHARLES HARLAN

s

204

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REACTIONS OF LAND ISOPODS TO LIGHT 205

B. NORMAL REACTIONS

The actual record of the single set of responses shown in figure
5 gives an idea of the usual behavior of Oniscus. That this in-
dividual was unquestionably negative to light is shown by a
comparison of the reactions in the four positions. The only in-
stance in which the animal continued in the direction in which
it was headed occurred when it was illuminated from behind
and movement straight ahead carried it away from the light.
In all other cases it turned very decidedly away from the source
of illumination.

Three different conditions may be noted in the activity of the
animal when the box was removed, exposing it to the light: 1)
the animal had not come to rest, and merely continued in locomo-
tion; 2) the animal had come to rest, but started locomotion at
once when exposed to the light; 3) the animal had come to rest,
and did not start locomotion at once when exposed to the light.
On account of this variation in the initial conditions, these ex-
periments with directive light do not show whether locomotion
was an effect of stimulation by light. The matter is further
complicated by the fact that handling the animals may have had
an activating effect, an inhibitory effect, or, as is most prob-
able, sometimes one and sometimes the other. However, as these
experiments were a test only of the directive influence of light
when the animal was already in locomotion, the question whether
more than one of these factors entered into the cause of the loco-
motion need not be considered. For this reason no record was
made of the interval before response in most cases. When there
was a delay before response, the antennae were often kept
moving, particularly just before locomotion was started, al-
though few if any of these movements could properly be called
‘trial movements.’

Much individual variation was observed. While the direc-
tion of locomotion was usually determined by the light, there
were many turns and circles, the causes of which were not so
easily analyzed. An example is shown in figure 5, D, response
no. 8.

THE JOURNAL OF EXPERIMENTAL ZOOLOGY, VOL. 27, No. 2

206 CHARLES HARLAN ABBOTT

An examination of a large number of records showed that
Oniscus is decidedly negative to light. This conclusion is shown
best, however, by applying to the records more than one method
of analysis, in order to give a clearer idea of what is involved in
the negative reaction. Three methods will be described on the
basis of results obtained while studying the individual behavior
of these isopods on successive days. The three animals which
will be particularly considered are designated as A 10, A 11,
and A 12. They were placed in all cases in the center of the
field, as in the typical method described, and exposed to an
average intensity of 12.955 candle meters.

In making each record, the sex of the animal was recorded.
However, no differences were found between the reactions of the
two sexes, so that the results of both were used indiscriminately
in compiling tables and angles.

1. Positive and negative response—first method of analysis

This method of tabulating results is shown in table 1, which
summarizes the results from Oniscus A 10, extending over
seventeen days.

Responses are classified as positive or negative according to
the grouping explained in figure 3. When the animal crossed
the circle within the positive quadrant, the response was recorded
as positive; otherwise, it was considered negative, because the
animal went into a region of diminished intensity. The letters
A, B, C, D refer to the four positions in which the animal was
placed with reference to the light.

The results are given in percentages of each kind of response.
The positive responses number 5.9 per cent, and the negative
responses, 94.1 per cent. The variation in the four columns
A, B, C, and D is slight, showing that the direction in which the
isopod was headed made little difference in the nature of the
response. This Oniscus was thoroughly negative to light,
although in a few isolated instances it went toward the light.
If the positive response were 25 per cent of the total, it might be
concluded that the animal was indifferent to light, as the posi-

REACTIONS OF LAND ISOPODS TO LIGHT 207

TABLE 1

Reaction of Oniscus A 10 to directive light of 12.955 C.M., showing results of daily
- tests for 17 days. Tests were made with the animal facing the light (A), facing
away from the light (B), and illuminated on the right (C) and left (D) sides

POSITIVE REACTIONS NEGATIVE REACTIONS

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1 When less than 20 responses are recorded, the animal failed to respond in
the other instances.

tive section of the field is only 25 per cent of the whole. How-
ever, the 5.9 per cent calculated shows that the animal was
unquestionably negative. The occasion when it would naturally
have gone toward the light if it were indifferent, was when it was
facing the light at the start, but even under that condition it
turned away in 91.7 per cent of the trials.

A similar tabulation of percentages is shown in table 2 for
Oniscus A 11, tested for fifteen days.

A higher record of positiveness was made by Oniscus A 12,
which received fifteen daily tests. Most of the positive responses
came in the first four days, the animal being 45 per cent positive
on the first day. After the fourth day, the reaction was as

208 CHARLES HARLAN ABBOTT

TABLE 2

Summary of reaction of Oniscus A 11, to directive light of 12.955 C.M., showing
results of daily tests for 15 days. Tests were made with the animal facing the
light (A), facing away from the light (B), and illuminated on the right (C) and
left (D) sides

POSITIVE REACTIONS NEGATIVE RBACTIONS
Sip A B Cc D Total | A B Cc D | Total
ROUGUS Bo. oe gent + Ree 3 5 Se 59 61 | 61 | 57 | 238
Percentages........ 6.3 0.0/4.7] 8.1 48 “93.71 100 | 95.3] 91.9| 95.2

typically negative as that of either of the other individuals just
described. . Table 3 shows how this isopod gradually changed
from indifferent or positive to negative.

As an indifferent animal would be about 25 per cent positive,
the 45 per cent recorded on the first day shows a considerable
degree of positiveness on that day.

This method of classification shows that these isopods, when
stimulated by directive light, usually avoid the light by locomo-
tion to regions of lower intensity. As the light stimulus is re-
ceived through the eyes, it is further important to know the result
of unequal stimulation of the two eyes. This is shown by a
study of the angle of the course taken by the animal after it
has been exposed to the light.

2. Orientation—-second method

As was shown in figure 2, the circle on the light field was
divided into sixteen sectors, numbered 1 to 8 on each side of
the central axis mn. If the homologous classes on the right and
left sides are grouped together, the responses of any individual
isopod can be divided into eight degrees of negativeness, accord-
ing to the sector of the circle which the animal crossed after
exposure to the light.

The same records which were summarized in tables 1 and 3 are
shown graphically in figures 6 and 7, after tabulation according
to this second method. Figure 6 shows the degree of negative-
ness of Oniscus A 10, the numerals on the abscissae corresponding

REACTIONS OF LAND ISOPODS TO LIGHT 209

TABLE 3

Reaction of Oniscus A 12 to directive light of 12.955 C.M., showing results of daily
tests for 15 days. Tests were made with the animal facing the light (A), facing
away from the light (B), and illuminated on the right (C) and left (D) sides

POSITIVE REACTION NEGATIVE REACTIONS
DAY
D | Total| A | B | C_| D | Total
1 2 9 2 4 2 3 11
2 z 5 3 5 5 Zi 15
3 4 3 5 3 5 16
4 4 2 4 3 4 13
5 iI 1 2 4 2 3 11
6 0 3 4 4 3 14
7 0 3 4 5 Z 14
8 2 3 5 5 5 18
9 1 1 5 & 5 5 20
10 0 4 5 4 5 18
11 1 1 5 5 5 4 19
11 0 2 2 4 Z 10
12 0 5 5 5 5 20
13 1 1 4 4 2 11
14 1 3 4 5 4 16
15 1 1 Awad 3 11
PROUAISE So ee Pade 3 8 30 AG GO G4 Page R237
Percentages 12.3] 11.2 | 77.0] 98.6] 90.1] 87.7] 88.8

1 A second set of responses was recorded on the eleventh day.

to the eight degrees of negativeness just referred to and the nu-
merals on the ordinates being the number of responses which
fall into each of these eight classes. The lines A, B, C, D repre-
sent the four positions with respect to the light in which the
animal was placed, while the dotted line is the average of the four
positions.

As would be expected, the greatest degree of negativeness is
when the animal is headed away from the light, and the lowest,
when facing the light. As only data in classes 1 and 2 on the
abscissa indicate a positive response, all of the curves show that
this isopod was thoroughly negative. There is a close corre-
spondence between the nearly identical reactions in positions C
and D and the average for all positions. This indicates that the

CHARLES HARLAN ABBOTT

210

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REACTIONS OF LAND ISOPODS TO LIGHT 211

reaction when the animal is illuminated on the side shows the
true degree of negative reaction, and, moreover, that the re-
sults in positions A and B balance each other, so that the aver-
age in all four positions is a suitable control for the correctness
of the results from stimulation on the side.

The reaction of Oniscus A 12 is given in figure 7. These
curves show more positive responses than occurred in A 10, due
to the many instances in which this isopod went toward the
light during the first four days. From the average for the
entire pericd of the experiment, it appears that A 12 became
the more negative of the two animals, because, in spite of the
degree of positiveness at first, the average in figure 7 shows the
greatest number of responses in classes 7 and 8 on the abscissa,
while in figure 6 classes 5 and 6 are the largest. In figure 7 the
correspondence between the average reaction and the reaction in
positions C and D is not quite so close as in figure 6, but the
average is much nearer to these than to the reactions in posi-
tions A and B.

The graphical method shows more definitely what is involved
in the negative reaction than was shown by a simple enumera-
tion of positive and negative responses. The animals regularly
turned away from the light in whatever position they were
originally placed, except that when they were already headed
away from the light they nearly always traveled in the direction
in which they were headed. From this method of analysis it
may be concluded that Oniscus is definitely oriented by the
light and that the response involves something more than
moving at random into a lower intensity.

5. Angle of negativeness—third method

This method was devised to express the degree of negativeness
of any one individual isopod or group of isopods by a single
figure, which might be used for comparison with the results ob-
tained in succeeding experiments. For this purpose the angle
of negativeness was chosen. This term will be applied to the
average angle of the course taken by the animal with respect to
the position of the source of light.

CHARLES HARLAN ABBOTT

212

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REACTIONS OF LAND ISOPODS TO LIGHT 2S

The method of calculation is as follows: Each response is
given the number of the sector in which it falls as in the second
method (fig. 2). For example, in the records of class A in figure
4, four of the responses fall into sector 5 and one into sector 6.
The average of the five responses is thus 5.2. The middle points
of the eight sectors, expressed in terms of angular deviation
from the central axis mn are: 1. 11.25°; 2. 33.75°; 3. 56.25°;
esi et 257; 0; IAS 75) 5+ fA 25-83 16845) «| The
difference between each of these figures and the succeeding one
is 22.50°, or one-sixteenth of 360°. The figure 5.2 expressed in
angles is equivalent to the angle just given for 5, 101.25°, plus
two-tenths of 22.50°, making 105.75°, the angle of negativeness
for the responses recorded in figure 4, A, when the animal was
facing the light.

As an application of this method, table 4 expresses the angle
of negativeness for the reactions which were shown graphically
in figures 6 and 7.

The table shows that both of these animals were negative, be-
cause they turned, on the average, at least 90° away from the
light when they were facing the light, and, respectively, 14°
and 32° away when they were already at right angles to the
light.

The fact that Oniscus A 12 was positive or indifferent on the
first day and gradually became negative is shown by the angles,
when the animal was stimulated on the side, for the first seven
days of the experiment: Ist day, 78.75°; 2nd, 96.75°; 3rd,
103.50°; 4th, 85.50°; 5th, 108.00°; 6th, 1389.50°; 7th, 139.50°.

TABLE 4
Angle of negativeness for Oniscus A 10 (tested for 17 days) and A 12 (tested for 16
days). Intensity of light 12.955 C.M. Tests were made with the animals facing
the light (A), facing away from the light (B), and illuminated on the right (C) and
left (D) sides

ANIMAL A B c D cones TOTAL C, D
’

A, B, C, D
10 96.75° 135.00° 105.75° 101. 25° 108 .00° 104.625°

12 90 .00° 155. 25° 148. 50° 119.25° 130. 50° 122.40

214 CHARLES HARLAN ABBOTT

. As an angle of negativeness of 90° represents the average course
of an animal placed at right angles to the light, if it is indifferent
to light, the angle for the first day shows that this individual
was somewhat positive on that day, because it turned on the
average 11.25° toward the light. This accords with the 45 per
cent positive response calculated according to the first method.

The responses in any record fall into three classes with respect
to the angle of negativeness:

1. When the animal is facing the light (position A), it is pos-
sible to measure only the angle of turning away from the light.

2. When the animal is facing away from the light (position
B), it is possible to measure only the angle of turning toward the
light.

3. When the light strikes the animal on the side (positions C
and D) either the angle of turning away from the light or the
angle of turning toward the light can be measured.

This difference raised the question whether the angle of
negativeness should be measured only from the results in positions
C and D or from those of the four positions combined. A test
series showed that the results are approximately the same,
whichever method is used. Of course the smallest angle is ob-
tained when the animal is facing the light and the largest when
facing away from the light, but these two extremes balance each’
other. The series which shows this is given in the section on
the comparison of Oniscus and Porcellio (table 10, page 228).
Compare also the last two columns in table 4. In the follow-
ing pages, wherever the angle is given without further expla-
nation, the angle calculated from the positions C and D is
given.

4. Conclusions

a. The individual isopods which have been considered in the
preceding pages were, except in the instance of one individual on
a single day, definitely negative to light. This is shown by the
calculation of a high percentage of negative responses and by
the measurement of the average angles through which these
animals turned in their movements away from the light.

REACTIONS OF LAND ISOPODS TO LIGHT 215

b. The results which have been analyzed are typical for the
species Oniscus asellus. The reaction of nearly all individuals is
negative, with only occasional reversals to. positiveness. The
constancy of these results will be shown in the experiments to
be described later in this paper.

c. Nothing has been said as yet about the reactions of Por-
cellio. The two species of Porcellio are also negative to light,
but the reaction is less consistent than that of Oniscus. The
difference between the two genera will be shown repeatedly in
the following pages, and, finally, will be summarized in the sec-
tion on the comparison of Oniscus and Porcellio.

C. MODIFIABILITY OF THE LIGHT REACTIONS |

A consideration of the ecological importance of isopod be-
havior involves the question whether the behavior is constant or
is easily modified by environmental changes. Shelford has
pointed out the fallacy of the assumption that the behavior of a
given species is a constant characteristic, whatever the environ-
mental conditions. In recent studies of fresh-water animals
(Shelford, 14) and.marine forms (Shelford, 716), he has shown
that behavior characters belong to a community even more than
to a species, and that behavior differences between individuals
of a single species from different habitats may be greater than
those between widely diverse species which occupy the same
habitat.

As an illustration of this principle, Allee (’12) has shown dif-
ferences in the rheotaxis of the fresh-water isopod Asellus com-
munis Say, according as the individuals tested came from ponds
or from streams.

Modification of behavior, however caused, is shown in many
ways, of which the three following are important: 1) by a par-
tial or entire failure to respond to the stimulus; 2) by an inten-
sification of response; 3) by a reversal of response. Allee (12,
14) obtained the first two of these modifications by subjecting
Asellus to various experimental conditions which changed the
metabolism of the animal. He found that conditions similar to

216 CHARLES HARLAN ABBOTT

those of stream life induced a definite positive rheotaxis in pond
isopods, while conditions similar to those of pond life decreased
the rheotaxis of stream isopods. That these -differences are
adaptive is shown by the fact that reaction to current is important
in the normal life of stream forms, but of less significance for
animals that live in quiet water.

The third result, a reversal of response, has been observed in
various animals, due to many different causes. The work on
this subject is well summarized by Holmes (16) ina chapter
entitled ‘‘The Reversal of Tropisms.”’

The following problems were undertaken, in order to learn
whether the behavior of land isopods is constant or is easily
changed by external conditions:

1. Reaction to various intensities of light.

2. Effect on reaction of repeated stimulation by the same
light intensity.

3. Comparison of reactions following exposure to light and
to dark.

4. Comparison of reactions of individuals from dry and moist
habitats.

5. Reaction in water.

1. Reaction to different intensities

a. Average intensities. Studies of the effect of different in-
tensities were easily accomplished by placing the isopods at
various distances from the source of light. The intensities at the
points chosen furnished a range from 3 to 100 C.M. The actual
intensities, as determined by the illuminometer, are given
below.

POSITION DISTANCE FROM DIAPHRAGM (CM.) INTENSITY

cm, CM.

1 10.5 97.28

2 20.5 25.52

3 30.5 12.955

4 40.5 7.665

5 50.5 4.205

6 60.5 2.93

REACTIONS OF LAND ISOPODS TO LIGHT 217

The test was made by three methods: 1) testing individual ani-
mals for a series of days, each day at a different intensity; 2)
testing several animals from the same habitat on the same day,
each animal at a different intensity, and 3) trying the different
intensities in turn on each animal.

The experiments showed that the response is in general the
same to all intensities which were tried. If an individual isopod
is negative it is negative to all intensities, while if it is indif-
ferent, it is alike indifferent to all intensities. This result was
obtained by all three of the methods described, so that the
different methods furnish a check on each other.

Grades of

Negativeness

Negative 8

+
6
—— —-26
2 25
4
3 © 24
im
Positive 4 5 Centimeters
10.5 20.5 30.5 40.5 50.5 60. sas

Fig. 8 Reactions to light of different intensities. Two individuals of Oniscus
(23 and 25) and two of Porcellio rathkei (24 and 26). Numbers on abscissa indi-
cate distances in centimeters from slit in diaphragm through which light passes.
Intensities at each of these points are given in the table on page 216. Numbers
on ordinate indicate the eight degrees of negativeness shown in figure 2. Shows
no consistent variation corresponding to the intensity.

The third method is perhaps the most satisfactory, because
it eliminates errors due to differences between individuals and
to variations in ‘physiological state’ on successive days. It has
the disadvantage that the result is based on four responses only
(one in each position) at each intensity, rather than on twenty
responses.

The reactions of four isopods, classified according to this
method, are shown graphically in figure 8. The numbers on the
abscissae indicate the distances from the light, which correspond

218 CHARLES HARLAN ABBOTT

to the intensities given in the above table, while the numbers
on the ordinates refer to the eight degrees of negativeness, ac-
cording to the classification of figure 2.

In the diagram the reactions of the two individuals of Oniscus
(A 23 and A 25) are represented by nearly straight lines, show-
ing approximately the same negative response to all intensities
used in the experiment. Porcellio rathkei (A 24 and A 26)
has the usual variations for the species, but these bear no rela-
tion to the intensity. The figure merely illustrates graphically
the conclusions given above.

When tested by the first method described above, Porcellio
seaber gave its normal reaction also at a point 5.5 cm. from the
diaphragm, where the intensity was approximately 400 C.M.

b. Low intensities. Some species of animals which are nor-
mally negative to light are indifferent to low intensities, while a
few are positive under the same conditions. For this reason, a
series of tests with low intensities was arranged. These intensi-
ties were obtained by using Mazda and carbon lights of lower
power and by increasing the distance between the isopod and the
source of light.

After finding Oniscus negative to intensities of 0.859 C.M.
and 0.648 C.M., a final series was tried with intensities which
were too low to be measured directly by the illuminometer, but
which could be calculated from illuminometer readings at other
points, according to the law of inverse squares. The results in
this series, given in table 5, represent the reaction of ten individ-
uals each of Oniscus and Porcellio seaber at each intensity, the
figures referring to the average reaction for each individual,
rather than to the individual responses.

As the animals were tested when facing the light only, those
which went toward the light were perhaps indifferent instead of
positive.

Table 5 shows that Oniscus was negative, even at these low
intensities. This was shown so strikingly by the test at the
lowest intensity recorded (0.0119 C.M.) that a further de-
seription will be given of this particular experiment. The
illumination of the table was so slight that the sowbugs were

REACTIONS OF LAND ISOPODS TO LIGHT 219

TABLE 5

Reactions to low intensities of light. Numbers refer to the average reactions of
individual isopods

REACTION

ISOPODS INTENSITY
Negative Positive Indifferent No response
Com.
0.169 10
Oni 0.0749 7 1 2
MNIscus....... 0 t 0255 10
0.0119 9 1
0.169 6 3 1
; 0.0749 a 7 1
Percellio..... 0.0255 3 9 9 3
0.0119 7 1 rm

almost invisible, although scarcely 30 cm. from the eye of the
observer. A faint reflection on the chitin covering made it
possible, but not easy, to determine the position of the animal,
particularly during locomotion. Of course the actual hori-
zontal illumination which reached the eyes of the animal was
considerably greater than was reflected to the observer above.
In spite of the fact that the light was so dim, Oniscus turned
away from it as definitely as from the stronger intensities be-
tween 1 and 100 C.M. Nearly all of the individual animals, on
starting locomotion, turned directly away, without describing as
large an are as is common when higher intensities are used.

As a control for this experiment, ten individuals of Oniscus
were tested immediately afterwards in total darkness. The
result showed no orientation to any external stimulus, and in
most instances locomotion was in the direction in which the
animals were already headed. The actual course taken was
determined by means of a flashlight after the isopod had been
in the dark long enough to start in a definite direction. As all
conditions except exposure to light were the same in the control
as in the experiment, the results with low intensities must have
been due solely to the light.

According to Patten (17, p. 260), ‘“‘It is the abruptness with
which orientation is attained, rather than the final accuracy of

220 CHARLES HARLAN ABBOTT

orientation, which shows the results of slight differences in
effectiveness of the receptive mechanism.” If that be so, the
abrupt and definite orientation of Oniscus to low intensities
indicates that Oniscus is extremely sensitive to light and is
definitely oriented by light.

The reactions of Porcellio to low intensities show as usual
more variation than those of Oniscus, but they are in the main
negative, and essentially the same as the reactions to higher in-
tensities. They show that Porcellio, as well as Oniscus, is re-
sponsive to extremely low intensities of light.

These results are particularly interesting, because Banta (’10)
found Asellus communis unresponsive to light of an intensity of
1 C.M. or less. As will be considered later, Oniscus and Por-
cellio appear to be more sensitive to light than is Asellus, the
common fresh-water isopod.

The conclusion to be derived from these experiments is that
land isopods are sensitive to a wide range of light intensity and
their reaction to all intensities is essentially the same.

2. Effect of repeated stimulation

A second condition which might change or reverse the reac-
tion is repeated stimulation. For these experiments, Oniscus,
since it is definitely negative, was chosen, in order to watch for a
possible reversal from negative to positive phototaxis. The
animals were placed facing the light, so that every negative re-
sponse would necessarily mean a definite turning away from the
source of the stimulus. Records were made in each instance
of the course taken and of the interval before response. When-
ever no response occurred during sixty seconds, the result was
recorded as “‘no response, sixty seconds.”

Sixteen individuals were used in these experiments and were
given a varying number of successive stimuli: one animal re-
ceived 100 successive stimuli, three received 60, one received 40,
five received 30, and six received 20. The longest time used in
testing any one animal was one hour. ‘The first individual men-
tioned, which gave 100 responses in one hour, was unusually
active.

REACTIONS OF LAND ISOPODS TO LIGHT 221

TABLE 6

Results of experiments testing the influence of repeated stimulation on Oniscus.
The animals were facing the light in all instances. Intensity 12.955 C.M.

RESPONSES Iya ae oe get yaynea ee enone.
1-10 16 81.00° 9.25
11-20 16 78.75° 21.01
21-30 10 87.75° 25.60
31-40 5 90 .00° 15.56
41-50 4 91.125° 16.875
51-60 4 81.00° 25.625

1 The numbers in this column diminish, because the tests of only four indi-
viduals were continued through 60 stimuli, others extending only to 40, 30, and 20.

The results were compiled by dividing the responses into
groups of ten successive responses and measuring the average
angle of negativeness.

Table 6, which summarizes the reactions of these sixteen ani-
mals, shows no influence of repetition upon the character of the
response.

The average turning from the light was as definite after sixty
successive stimuli as at first.

Whatever effect was caused by the delay is shown by a lessen-
ing of activity as is indicated by the interval before response,
shown in the last column of table 6. The figures are only ap-
proximate, as all delays over 60 seconds were counted as 60
seconds in making the averages. The essential conclusion is
that after the first few trials there is usually a slight decrease
in responsiveness, but from that time on there is little change.
The delay is probably due chiefly to the effects of handling, as a
similar delay occurs just as readily when the animals are moved
about on the table by the same method of manipulation, but not
exposed to light at all.

Furthermore, while there were changes in individual behavior
which are not shown in the above table, there was no consistent
change in phototaxis which could be traced to the effects of repe-
tition. In some individuals the angle of negativeness decreased
with continued stimulation, in others it increased, while in still
others it passed through both of these variations successively.

THE JOURNAL OF EXPERIMENTAL ZOGLOGY, VOL. 27, NO. 2

shed CHARLES HARLAN ABBOTT

TABLE 7

Analysis of the reaction of Oniscus F 2, exposed to light of 12.955 C.M. for 100
successive stimuli. Duration of experiment one hour

INTERVAL IN SECONDS BEFORE

RESPONSES ANGLE OF NEGATIVENESS RESPONSE

1-10 49. 5Q° 5.5
11-20 90 .00° 7.0
21-30 96.75° 7.0
31-40 74.75° 3.0
41-50 81.00° 8.0
51-60 94.50° 15.0
61-70 40. 50° 12.5
71-80 54.00° 7.0
81-90 HL e765: 9.0
91-100 42.75° 0.0

Some individuals appeared to ‘tire out,’ others continued active
as long as they were tested, but no correlation was observed
between delayed reaction and definiteness of turning from the
light.

As an example of individual rather than of species behavior, a
summary is given in table 7, of the reaction of Oniscus F 2 which
responded to 100 successive stimuli.

The characteristics of this animal were that it was very ac-
tive without any diminution of activity at the end of 100 stimuli
and that it was not as negative to light as are most individuals of
this species. In the first ten responses it was indifferent or posi-
tive, then it became much more negative for fifty successive re-
sponses, after which it became once more somewhat indifferent.
These changes are shown in the table by the column for the
angles of negativeness. As the animal was not negative at the
beginning, this table does not illustrate the usual behavior for
the species.

From this series of experiments on repeated stimulation it
may be concluded that the phototaxis of Oniscus is not changed
or reversed by a long series of successive responses. Even when
the animals become gradually less active, they continue to turn
away from the light by as definite an angle as when they were
first exposed to it.

REACTIONS OF LAND ISOPODS TO LIGHT 223

3. Comparison of reactions following exposure to light and to dark

Most of the isopods used in the preceding experiments had
been living in the dark, but some had been exposed to the daily
changes of an ordinary room. No relation was observed be-
tween the degree of negative phototaxis and this difference of
exposure.

The effect of continued illumination by strong artificial light
was tested in a few individuals of both Oniscus and Porcellio.
They were placed in a dark room and exposed for a few hours,
and in some instances for a longer period, to an electric light,
with a rectangular glass jar’of water to absorb the heat, be-
tween the light and the terrarium. While most of the experi-
ments already described furnish a suitable control on these
results, additional tests were made, using animals which had
been placed in a dark corner of the room during the time that
the other individuals were exposed to light. In a few instances,
the same animals were placed alternately in the two habitats.

A comparison of the reactions of isopods from these two
sources is shown by the diagrams in figures 9 and 10, and by the
angles of negativeness in table 8.

TABLE 8

Comparison of the angles of negativeness, following exposure to artificial light and
to darkness. Oniscus and Porcellio rathket

ONISCUS PORCELLIO
Riera TAG he As SSE ek! Pte, che 117.00° 67.50°

PEG TAM GL SATE hy oy = cA es nates api cach ann ec 122402 103.50°

The results after exposure to light are compiled from five indi-
viduals each of Oniscus and Porcellio rathkei. The control for
Porcellio is compiled from records for ten individuals. That
for Oniscus is a summary of the daily reaction for fifteen days
of Oniscus A 12 (tables 3 and 4, fig. 7), which was a member of
this control series. In the charts, the eight degrees of negative
reaction are represented by the abscissae, while the ordinates
indicate the proportional number of responses, all the curves
being drawn to the same scale.

224 CHARLES HARLAN ABBOTT

A generic difference appears in the results. Oniscus was nega-
tive, regardless of previous exposure, with the reaction appar-
ently uninfluenced by strong light. On the other hand, Porcellio
showed a high degree of positiveness after exposure to light. A
probable explanation for the two modes in the curve for Por-
cellio (after exposure to light) is that three out of five indi-

Number of
Responses

16

42 Oniscus

1 Z 3 4 5 6 iT & Grades of
Rsiti ve g Negative Neqetnere r

Number of
Responses

20

Porcellio a 14

Grades of

sh Nedgativen
Pesitive 10 Negative ega yenes
Figs. 9 and 10 Comparison of reactions after exposure to strong artificial
light and to dark. Fig. 9, Oniscus; Fig. 10, Porcellio rathkei. Numbers on
abscissae indicate grades of negativeness shown in figure 2. Numbers on ordi-
nates indicate number of responses in each of the eight classes. Fig. 9 shows
little difference between the responses of Oniscus under the two conditions.

Fig. 10 shows that Porcellio was somewhat positive after exposure to strong
light.

REACTIONS OF LAND ISOPODS TO LIGHT 225

viduals tested were decidedly positive, while the other two were
negative. The positive animals were in fact so decidedly posi-
tive that two of the three gave positive responses even when
they were headed away from the light. The difference is shown
in table 9, which summarizes the individual reactions of the
five animals after exposure to light, together with a second
series of reactions after exposure to dark, made two days later
by approximately the same individuals.

In table 9 the numbers are arranged in order of magnitude,
but most of the individuals appear in both columns.

TABLE 9

Individual behavior in the species Porcellio rathkei after exposure to light and to
dark. Intensity 12.955 C.M.

FROM LIGHT (NOVEMBER 20) FROM DARK (NOVEMBER 22)
Identification number Angle ies gative- Identification number Angle phe ah
VERS eae oe Rk eee 6 ee Siero 4 Gust’, 8) RRA 76.50°
ete cheats. Force. Bebe ClDeertss batds: wee 78.752
pee Se ce es ag 42.75° (Gil (ae eae SEES et 108.00°
Br tetera aga ar a ik eee ale 99.00° , C1 ed eradicate. Um 126.00°
Bie ss oe see 130.50° CORAL A Sat eee 8 139.50°
PGCPALC coo. ficl 4.6 + 9: 67.50° | AVOPSEC. oped oc cna 103.50°

These experiments on the influence of preceding illumination,
while they were not carried far, indicate the possibility that nega-
tive phototaxis in land isopods may be diminished or reversed
by exposure to strong light. This appears from the experiments
to have been true for some individuals of Porcellio, but the fact
that a like result was not obtained from Oniscus makes it less
conclusive.

4. Comparison of reactions of individuals from dry and moist
habitats

The moisture conditions of a habitat are not easily measured,
but it is possible to place sowbugs in what must be close to the
extremes in which they ean live, so far as moisture is concerned.
For a minimum of moisture, they can be kept in an environment

226 CHARLES HARLAN ABBOTT

so dry that few individuals of Oniscus survive, Oniscus requir-
ing more moisture in its surroundings than does Poreellio. For
a maximum, the substratum can easily be kept saturated with
water.

A comparison of the reactions, after keeping the isopods for
over a month in these two extreme habitats, is shown in figures
11 and 12.

According to figure 11, Oniscus gave essentially the same
negative reaction regardless of preceding moisture conditions.
Both curves are typically negative and resemble each other
closely.

On the other hand, Porcellio seaber (fig. 12) from the dry
habitat was somewhat less negative than the same species from
moist surroundings, but both curves for Porcellio show a con-
siderable degree of indifference to the stimulus.

There is, therefore, little evidence that the reaction varies
greatly according to the amount of moisture in an isopod’s en-
vironment. The chief observable difference in the effect of the
two habitats is an increase of activity under dry conditions,
which has no apparent relation to the character of the photo-
taxis. It is interesting that, although, of the two genera, Por-
cellio is the more adapted to survive atmospheric dryness, lack
of moisture should apparently affect its behavior more than that
of Oniscus.

5. Reaction in water

In studying the amphipod, Orchestia agilis, which spends
most of its life out of water, Holmes found (’16, p. 105) that,
when thrown into water, these normally positive Crustaceans
became at once strongly negative. As sowbugs, when placed in
water, will remain active for some time before showing ill effects,
it was possible to try a similar test with them. Five individuals
each of Oniscus and Porcellio rathkei were placed in a rectangular
jar of water and exposed to horizontal light of an intensity close
to that used in most of the experiments previously described.
The isopods moved about to a considerable extent, but there
was no orientation with respect to the position of the light.

REACTIONS OF LAND ISOPODS TO LIGHT 227

Apparently the unnatural condition of being submerged in water
made them indifferent to light.

This change from a negative reaction to indifference corre-
sponds to the changes found by Holmes, in that normal photo-

Number of
Responses
20 > ‘6
slag
wats
4, Oniscus : 0

12

Grades of
; 2 3 4 5 6 t 8 Negativeness
Positive Negative

Number of
Responses

1 3 4 5 6 q 8 Grades of
Positive Negative Negativeness

12

Figs. 11 and 12 Comparison of reactions after exposure to a minimum and
maximum of environmental moisture. Fig. 11, Oniscus; Fig. 12, Porcellio scaber.
Numbers on abscissae indicate grades of negativeness shown in figure 2. Num-
bers on ordinates indicate number of responses in each class. Fig. 11 shows
practically no difference between the responses of Oniscus under the two con-
ditions. Fig. 12 shows a slight difference in Porcellio under the two ees
the animals being less negative after living in a dry habitat.

228 CHARLES HARLAN ABBOTT

taxis is altered by throwing the animals into water. The effect
is due, according to Holmes’ explanation, to unusual contact
stimuli.

6. Comparison of phototaxis in Oniscus and Porcellio

In the foregoing discussion many references have been made
to differences between Oniscus and Porcellio. Any conclusions
which may be drawn from these experiments in modifiability of
behavior will be more clear after consideration of this generic
difference.

A comparative study of the phototaxis of Oniscus and of
Porcellio is given in table 10, which records the angles of nega-
tiveness in six series of experiments, most of them already
reported in the preceding pages.

TABLE 10
Comparison of angles of negativeness of Oniscus and Porcellio in various photo-
taxis experiments. A, animal facing light; B, animal facing away from light;
C, right side illuminated; D, left side illuminated

ONISCUS PORCELLIO
MATERIAL S Ss S SPECIES
Spes| Sep Sees eye

Newly collecteds.... 3 o255.- «a. 139.50°| 135.00°| 110.25°| 105.75° Pasealig
From maximum of moisture.....| 123.75°} 126.00°| 117.00°| 119.25° Sop :
From minimum of moisture..... 121.50°| 123.75°| 92.25°| 87.75°|| 2Cave
Prom-dark. 2... =? lee 130.50°| 122.40°| 101.25°| 103.50°) Porcellio
From strong light.............. 114.75°| 117.00°| 72.00° wed waite
At different intensities.......... 128. 25°} 126.00° 72.00°| 61.87° ,;

As the parallel columns show little differences in the two
methods of compiling results, the angles from positions C and D
will be referred to, whenever, in the discussion, quotations are
made from the table.

1. The phototactic response of Oniscus was negative, with
little variation in the degree of negativeness under the different
conditions. The averages, from the lowest (117°) to the highest
(135°), show a range of only 18°, which is less than the difference

—— ed

REACTIONS OF LAND ISOPODS TO LIGHT 229

(22.5°) between any two adjoining classes of the eight grades of
negativeness (fig. 2). The smallness of this range is shown dia-
grammatically in figure 13.

2. Porcellio showed a much wider variation, the differences
between the lowest (61.87°) and the highest (119.25°) aver-
ages recorded being 57.38°. This also is shown in figure 13,

Direction of light

GlByau.
Porcellio Oniscus
119 25° OT
135°

Fig. 13 Diagrammatic representation of the comparison of the reactions of
Oniscus and Porcellio given in table 10. The shaded areas show the range of
the average angles of negativeness under the six conditions, when the animals
were illuminated on the side (positions C and D). Porcellio has a wider range
than Oniscus, part of the averages showing a slight turn toward the light.

which shows a considerable degree of variability. In what were
probably the more normal of the conditions (i.e., when newly
collected, from a dark normal habitat, and from a maximum of
moisture), the reaction of Porcellio was negative, but, after con-
tinued exposure to strong light and when exposed successively
to light of different intensities, the reaction tended to be positive.

230 CHARLES HARLAN ABBOTT

The reactions of the two species of Porcellio appeared in various
experiments to be essentially alike, but no comparative tests
were made. The present paper deals only with generic
differences.

3. Oniscus was more negative than Porcellio under all condi-
tions! in which comparative experiments were made, and, as is
shown in figure 13, the range of reaction in Porcellio was much
greater. Furthermore, a decided reversal of reaction from
negative to positive was observed more frequently in Porcellio
than in Oniscus. While in most instances the cause of this re-
versal was not determined, one apparent cause in the case of
Porcellio was continued exposure to strong artificial light (fig.
10, table 9).

4. To summarize the preceding statements, Oniscus and
Porcellio are both negative to directive light, but Porcellio is the
less negative. The reaction of Porcellio appears to be modified
more readily by changes in both internal and external condi-
tions. The possible ecological significance of this difference
between the genera will be considered in a later section.

7. Conclusions

The reaction of Oniscus is negative under nearly all of the con-
ditions tried and is not easily modified. At times in the course
of the experiments, individuals of this species have shown a high
degree of positiveness, but the cause for this occasional be-
havior has not as yet been found in any of the modifying condi-
tions tried. The normal negative phototaxis was lost under the
unnatural conditions of an aquatic environment.

1 In the one instance where there is apparently little difference between the
two genera, when the animals were taken from a maximum of moisture, the real
contrast is shown by a comparison of figures 9 and 10. The arithmetical mean
(A.M.), from which the figures for the angle of negativeness were derived, was
similar in the two instances, but the true distinction is shown by the average
deviation (A.D.), and by calculating the coefficient of variability (C.V.) by the

formula C.V. = oo The results are shown in a table.
MESETUIS MOA es F< choy erick at oat ee he A.M. A.D. Cie
CTS Err A ae Se PS ed 6.1 0.741 0.121

IDC ELL UE. A er ene Sees 5.8 Gs 0.268

REACTIONS OF LAND ISOPODS TO LIGHT 231

According to the experiments, the behavior of Porcellio ap-
pears to be somewhat modified by external conditions. These
animals were less negative after living in a dry atmosphere,
after exposure to strong light, and when exposed successively to
different intensities. The most striking result was a reversal
to positiveness which occurred in certain individuals after ex-
posure to strong light (fig. 10, table 9).

As was shown in the preceding section, the normal phototaxis
of Porcellio shows a great amount of variation, and hence it is
difficult to say to what extent these modifications are actually
due to the external conditions of the experiments.

VI. DISCUSSION
A. ECOLOGICAL ANALYSIS

Ecology is the study of the relation between organisms and
their environment. Ecological studies deal both with the dis-
tribution of animals and plants and with adaptation, which
may be defined as the sum of the structural and functional
methods by which the organism is fitted to its environment.
The word adaptation is used without implying any theory as
to the cause of adaptation. Inasmuch as the present emphasis
of studies in animal and plant ecology is particularly on adapta-
tions of a physiological nature, the study of animal behavior
has become of increasing ecological importance.

One of the essential distinctions between structure and be-
havior is that structure, in the main, is dependent on genetic
relationships, while behavior is closely related to the nature of
the environment. Without attempting to settle the problem
whether environment is the cause of behavior, the facts remain
that animals of various structures tend to have the same behavior,
if they occupy the same environment (Shelford, 714, ’16) and
that individuals of a single species from different environments
often have a difference in behavior corresponding to the environ-
ment (Allee, 712, 714; Adams, 715). <A particular plan of struc-
ture may be suited to a wide variation in environment, pro-
vided that the behavior of the animal varies according to the

Poe CHARLES HARLAN ABBOTT

environment. Because of this fact, such diverse animals as
annelid worms, gasteropods, and crustaceans, which are all found
in a wide variety of habitats, frequently occur together in the
same ecological association.

The environmental importance of behavior characters is shown
further in a discussion by Vestal (’14), in which he compares in
detail five sets of characters—structural, physiological, psycho-
logical, biographical, and numerical. Vestal concludes that, at
least so far as competition with other animals is concerned,
‘psychological’ or, as he preferably calls them in another con-
nection, behavior characters, are actually the most important
of all.

In order to discuss intelligently the significance of the photo-
taxis of land isopods, a partial ecological analysis of these ani-
mals will be given.

1. Habitat

A habitat analysis may be made on the basis of a table by
Adams (’15, p. 95), which summarzizes for comparative purposes
the habitats of prairie and forest invertebrates. The ground
stratum of the forest, which land isopods typically occupy, is a
region where they are exposed, comparatively speaking, to a
large amount of humidity, a small amount of evaporation, and
a fairly constant temperature. For animals only slightly
adapted to land life, these appear to be the optimum conditions,

2. Structural and physiological adaptations

A brief discussion will be given of a few of the characteristics
of land isopods which make possible their living in a habitat
furnishing the conditions just mentioned.

a. Respiration. Land isopods have a somewhat generalized
crustacean structure, with a hard outer covering of chitin, which
prevents evaporation of water from the body. The organs of
respiration, as in the aquatic isopods, are modified abdominal
appendages (pleopods). The nature of the mechanism of res-
piration is still somewhat in doubt, although the subject has

REACTIONS OF LAND ISOPODS TO LIGHT 233

always been the center of interest in these animals, and recent
studies have been made by Stoller (’99), Bepler (09), Bernecker
(09), Unwin (’09), Miller (10), and Herold (13). The fol-
lowing statements represent perhaps the most widely accepted
opinion among these investigators.

1. In most and probably all genera the thin-walled inner
branches (endopodites) of the pleopods are used for respiration.
They are covered and thus protected by the outer branches
(exopodites) and are kept moist by glandular secretions.

2. The outer branches in most forms, besides serving as a pro-
tection for the inner branches, have trachea-like modifications
for breathing atmospheric air. Of-the two genera used in the
experiments reported in the present paper, Porcellio has these
structures better developed than Oniscus. Correlated with this
fact is the ability of Porcellio to live in drier situations than
~Oniscus. Of the species of Porcellio, P. rathkei is somewhat
better adapted to air-breathing than P. scaber.

3. The character of the endopodites resembles closely that of
the same structures in Asellus communis, the fresh-water isopod
previously referred to. The most primitive land isopods, the
family Ligydidae, have ‘gills’ closely resembling those of Asellus.
This seems to indicate that isopods as a group were particularly
suited to a change from water to land, since only slight modi-
fications in the respiratory mechanism proved necessary.

b. Food. The food and feeding habits of land isopods and of
Asellus have been investigated, respectively, by Murlin (’02) and
Banta (710, p. 477). Both kinds of animals exercise little selec-
tion in their choice of food and take a large percentage of inor-
ganic matter into the digestive tract with the food.

c. Care of young. The developing young of isopods remain
in a brood-pouch on the ventral surface of the female until they
have developed into the adult structure. In this way the young
are protected during their early existence and no special device
during the early stages is necessary to adapt them to land life.

d. Behavior. So far as respiration, feeding habits, and pro-
tection of developing young are concerned, land isopods are
little different from their aquatic relatives. The isopod plan of

234 CHARLES HARLAN ABBOTT

structure seems to be suited to terrestrial as well as aquatic life.
However, land isopods are confined to a limited, protected en-
vironment, and are not suited, like insects, to become domi-
nant land animals. The fact that they remain in the environ-
ment in which they are fitted to survive is probably due chiefly
to another set of characters, those which make up the behavior.
These characters will now be considered.

3. Reactions of land isopods

Although the entire behavior complex is involved in adapta-
tion, it is possible to make a partial analysis into reactions to
various classes of stimuli. Among the most important factors
of the environment of land animals are humidity, evaporation,
contact, and light.

a. Reactions to humidity and evaporation. So far as observa-
tion shows, the effect on land isopods of exposure to a dry at-
mosphere, including the first effect in desiccation experiments,
is an increase of activity. This is a useful adaptation, provided
the activity carries them to other regions where moisture condi-
tions approach more nearly the optimum.

The problem whether these animals have a definite reaction
to differences in humidity and evaporation has not been inves-
tigated. The most satisfactory method yet devised for making
such tests is doubtless that of Shelford for testing reactions to
the evaporating power of air. Among the species of animals in
which he has found such a response (Shelford, 713 a) are several
commonly associated with sowbugs, including ground beetles,
salamanders, snails, and the yellow-margined millipede (Fon-
taria corrugate Wood). No similar experiments have thus far
been recorded for land isopods, but it is quite possible that
they, too, give a negative reaction to increased evaporating
power of air, and as a result remain in places where evaporation
is at a minimum. The somewhat unusual occasions when they
visit exposed places may possibly be only at times when there
is a large amount of atmospheric humidity.

REACTIONS OF LAND ISOPODS TO LIGHT 235

b. Reactions to contact. Isopods as a group have the general
plan of structure common to contact animals, as is seen best of
all in the oval bodies, with flattened ventral surfaces, which
characterize the Oniscoidea. Positive thigmotaxis is doubtless
an important factor in keeping them in a suitable habitat. The
use of the sense of contact as a substitute for the sense of sight
has already been referred to (page 198).

c. Reactions to light. With the recognition that land isopods
are contact animals and that further studies will probably show
reactions to other classes of stimuli, the part in their normal life
played by the reaction to light remains to be considered. Since
studies of the reaction, both to artificial light and to daylight,
have shown that sowbugs are decidedly negative, even to low in-
tensities and since the reaction is constant under most condi-
tions, it seems reasonable to conclude that negative phototaxis
is a character to be considered in an ecological interpretation
of these animals.

Inasmuch as sowbugs usually live in the dark, it seems prob-
able that during the greater part of the time light is not an influ-
ential factor in their lives. When, however, they accidentally
wander from their places of concealment, their reaction to light
may be expected to turn them back again into the dark. Their
actual behavior out of doors when exposed to light can be ob-
served when a log or other object concealing them is overturned.
Under these conditions, some of the sowbugs become active at
once, soon disappearing in crevices or under the log, while others
crouch down motionless. In the latter case, when thigmotaxis
apparently overcomes phototaxis, the result is only temporary,
for in a short time no sowbugs are in sight. Although the light
is so diffuse that it cannot direct their course as unmistakably
as under experimental conditions, yet its influence seems sufh-
cient to carry them to dark places and to keep them there. From
this fact it may be concluded that light serves as a stimulus to
turn them back whenever they wander into it in the course of
their ordinary activities. The same is probably true in the
early morning, whenever they leave their places of concealment
at night.

236 CHARLES HARLAN ABBOTT

The fact that the reaction of Porcellio appeared from the ex-
periments to be less negative than that of Oniscus is correlated
with other generic differences. Porcellio, because of the structure
of its respiratory appendages, is better provided for living in dry
situations than is Oniscus, and hence has perhaps less need of
a definite negative reaction to keep it in its proper environment.

Furthermore, the phototaxis of Poreellio seems to be reversed
from negative to indifferent or positive more easily than that of
Oniscus. This has been observed under natural as well as
experimental conditions. A good example was noted at Cold
Spring Harbor, Long Island, in July, 1916, when Porcellio was
found commonly for three or four days on green plants at a
height of four or five feet from the ground. Among the possible
causes for this unusual behavior was a partial or complete flood-
ing of the ground habitat, but, whatever the cause, it was appar-
ently accompanied by a reversal from the usual negative photo-
taxis, with perhaps also a reversal of geotaxis.

Table 10 also suggests, although in this case it does not offer
a suitable basis for comparison, that possibly Porcellio rathkei is
less negative than P. scaber. If so, this furnishes a further cor-
relation, since, as has been mentioned, the breathing appendages
of P. rathkei are, of the two species, the better adapted to air
respiration, and its habitat is probably slightly less restricted.

Whether or not it is possible to find any evolutionary signifi-
cance in this behavior, it is, at any rate, worth while to com-
pare the phototaxis of land and of water isopods. The most
complete study of the light reactions of any aquatic isopods
which has yet been made is that by Banta (10). Table 11 com-
pares the results for Oniscus, recorded in the present paper,
with Banta’s summary (10, p. 268) of the reactions of Asellus
communis.

This comparison indicates that, of the two genera, Oniscus is
the more definitely negative. The negative reaction helps to
prevent Oniscus from leaving its habitat in the daytime, while
Asellus, with no such restricted habitat, is at definite times
positive to light.

REACTIONS OF LAND ISOPODS TO LIGHT 231

TABLE 11
Comparison of phototazis of Oniscus asellus (this paper) and of Asellus communis
(Banta 710, p. 268)

ONISCUS ASELLUS

Reacts to intensities as low as 0.0119 | Does not react to intensities of 1 C.M.
C.M. or less

Negative to light, regardless of pre- | Negative after exposure to diffuse day-
vious exposure light
Positive for a few hours after exposure
to darkness

When Porcellio is compared with Asellus, the contrast is not
so striking, because Porcellio is somewhat like Asellus in not
being always negative. However, the fact that Porcellio, like
Oniscus, responds to intensities as low as 0.0119 C.M. suggests
that it, too, is more discriminating in its reaction to light than
Asellus. Whether or not negative phototaxis was intensified as
an adjustment to land life, it at least appears to be a more im-
portant factor in the activities of land isopods than of aquatic
isopods.

In this connection a few observations will be given concern-
ing one of the most primitive of land isopods, so regarded because
its structure is less specialized for life on land. The large active
isopod, known as the sea slater (genus Ligyda), lives in crevices
of rocky shores just above the high-tide line among the San
Juan Islands of the northern part of Puget Sound. At low tide
these isopods emerge from their hiding-places and migrate down
the rocks nearly to the low-tide line. During this period they
ean often be seen moving about with apparent disregard of the
bright sunlight. At other times, however, they are found in
crevices, and in the laboratory they give a negative reaction to
sunlight. In their case the reversal of reaction keeps them in
the damp region close to the water’s edge, so perhaps it is advan-
tageous for them not to have so consistent a negative reaction
to light as that of Oniscus.

From this ecological study of the phototaxis of land isopods
it may be concluded that the usual negative phototaxis is advan-

THE JOURNAL OF EXPERIMENTAL ZOOLOGY. VOL. 27, No. 2

238 CHARLES HARLAN ABBOTT

tageous to this group of animals, because it keeps them in a suit-
able habitat. Such reversals of reaction as occur are probably
adaptive also. Unless other reactions are so important as to
overcome the influence of the phototaxis in ways not yet deter-
mined, observations and experiments indicate that this reaction is
an important ecological character, and, further, that it may have
been one of the factors which made possible the migration of the
ancestors of the present land isopods from water to land.

B. THE PROBLEM OF ORIENTATION

In addition to the ecological analysis, a few observations can
be related to the problem of orientation, which has a large place
in behavior studies. The subject of orientation has been so thor-
oughly discussed, particularly in such general works as those of
Jennings (’06), Mast (11), Loeb (716), and Holmes (’16), that
no extended introduction is necessary. A distinction which Dar-
win (’80) made, according to Mast, is, however of importance.
To quote from Mast (’11, p. 47): ‘To explain orientation, Darwin
said, we do not need to account for movement; it is only neces-
sary to account for changes in the direction of movement.”

The problem is well formulated by Bancroft (713) in two ques-
tions which he applies to Euglena, but which could be asked
equally well with regard to any other organism:

1. Does Euglena become oriented to light as directly as its method
of orientation admits, or does it orient indirectly by the method of trial
and error? In either case the reaction will be heliotropic, but the
method of orientation will be different.

2. Is heliotropism in Euglena brought about by response to tem-
poral changes in light intensity, or is it caused by the continuous action
of the light independent. of changes in intensity?

This division of the subject by Bancroft into two distinct
problems avoids a source of confusion which has occurred in
most discussions of the question.

REACTIONS OF LAND ISOPODS TO LIGHT 239

1. Direct orientation versus method of trial

The study of Torrey and Hays (714) on the orientation of
Poreellio to light resulted in the conclusion that orientation is
direct and that the many preliminary movements of the antennae
before locomotion, which appear to correspond to the ‘random
movements’ in the forms studied by Holmes (’05), have no rela-
tion to orientation. These authors concluded that: ‘‘The con-
sistency with which many individuals turned away from the
light, whether the latter was on one side or the other, left no
room for doubt that the reaction was forced in a definite direction.”’

Although the present investigation was not made specifically
to determine the mechanics of response, observations in the or-
dinary experiments indicated that there is a definite orientation,
which is little obscured by random movements. In the usual
negative responses there is a time difference which makes pos-
sible a division into three classes of responses: 1) those in which
- orientation occurs without locomotion; 2) those in which orien-
tation occurs abruptly at the beginning of locomotion; 3) those
in which orientation occurs gradually during locomotion. Of
these, the first is not frequent, although a characteristic response,
while the second and third are both common. The third method,
where orientation is secured by a gradually curved course, is in
reality just as direct as the other two. If necessary allowance
is made for individual peculiarities in the response, due prob-
ably to internal causes, the response seems to involve a direct
orientation by the light, in which trial movements do not play
any essential part.

2. Constant intensity versus change of intensity

The basis of most present discussions of orientation is, how-
ever, the second of those quoted from Bancroft, the question
whether the response is due to continuous stimulation from light
acting at a constant intensity or to the shock resulting from
changes of intensity. A possible contribution to the solution of
this problem may be found in an analysis of the frequent delays
before response. Even when an isopod responds vigorously at

240 CHARLES HARLAN ABBOTT

first, the delay sets in on the average after ten responses, so
that in nearly every ordinary series of twenty trials some re-
sponses occur only after an interval.

When an animal does not respond to the initial light stimulus,
there are three possible explanations why it responds later.
These are: 1) a delayed response to the initial stimulus; 2) a
response to the continuous stimulus, and 3) a response due to
causes wholly other than light stimuli. Whichever of these is
true, the difference between immediate and delayed response is
a difference in photokinesis rather than in phototaxis, because
orientation is quite as definite when the response is delayed as
when it is immediate.

The opportunity for observing the influence of continuous
stimulation after delayed reaction is found in those instances
when orientation occurs before locomotion, whether or not it is
accompanied by locomotion. Under these circumstances, the
first locomotor movement of the animal after a delay is a turn-
ing movement, and the cause of the turning cannot be found in ~
any change of intensity which has occurred since the initial
stimulus on the eyes of the animal. That is, the reaction under
these conditions must be due either to the continuous constant
stimulus or to an after-effect of the shock produced by the
initial stimulus. ;

This raises the further question: Would an isopod give an
orienting response after a delay if the stimulus were not con-
tinued? Mast (’12) tested fireflies from this point of view, and
in his summary says:

The males do not orient when exposed to continuous illumination.
They respond only to flashes of light and the reaction does not begin
until after the light has disappeared. Removal of the female imme-
diately after she glows has no effect on the reaction. Thus orientation
may take place in total darkness, and it is surprising how accurately
these animals turn through the proper angle in the total absence of the
stimulating agent. Here we have a case in which it is clearly demon-
strated that light does not act continuously in the process of orientation
as demanded by Loeb’s theories, a case in which it is also clearly dem-
onstrated that the continuous action of the stimulating agent is not
necessary to keep the organism oriented.

REACTIONS OF LAND ISOPODS TO LIGHT 241

This statement is not at all surprising, because sudden flashes
of light are a part of the natural environment of the firefly, and
the firefly is adapted to them in a unique way. On the other
hand, since most animals are exposed to constant illumination
and to gradual changes rather than to sudden changes, the
firefly is hardly a typical animal in which to test out this point.

For this reason an experiment was devised to determine
whether Oniscus can be oriented after a delay, in the absence
of the original stimulus. Twelve individuals of Oniscus were
tested in the position facing the light, according to the usual
method. Record was made only when there was a delay in
response lasting more than five seconds. In approximately half
of these instances of delayed response in each animal, the light
was turned off after five seconds; in the other half the animals
were exposed to the light until they responded. (If no response
occurred during 60 seconds, it was recorded as ‘no response.’)
The course taken by the animal and the interval before response
were both recorded in each instance. The individual animals
were given repeated stimuli until several delayed responses had
been recorded under each of the two conditions.

In order to observe the animal after the light was turned off,
the influence of overhead lights was tested until one was found so
dim as not to affect the accuracy of orientation and yet strong
enough to make it possible to watch the movements of the ani-
mals. In a preliminary test series with the light finally chosen,
five individuals of Oniscus showed an average angle of negative-
ness of 126°, which is thoroughly normal, and shows that the
overhead light did not disturb the normal reaction to horizontal
illumination. This light was, therefore, used during the entire
experiment.

The result is shown in figure 14 and table 12. According to
figure 14, the greatest number of responses when the light had
been turned off fell into class 1 on the abscissa, with a gradually
decreasing number of responses in the other classes. This shows
that the animals moved in general in the direction in which they
were headed, with no apparent response to the initial light stimu-
lus. On the other hand, the curve of the responses when the

242 CHARLES HARLAN ABBOTT

TABLE 12

Comparison of reactions of Oniscus after delay when light is continuous and when
light is extinguished after 5 seconds. Intensity, 12.79 C.M.

| WITH CONTINUOUS |WITHOUT CONTINUOUS

LIGHT LIGHTj «ind!
Whole number of delays in response con-
SUT ETRE T Moats 5) i gel eg SO eS MIE Se sie 84 80
Responses after delay......................-.|58 (69 per cent)|50 (62.5 per cent)
Failures to respond after delay............... 26 30
Average interval before delayed response..... 31.7 seconds (34.6 seconds
Average angle of negativeness in delayed
WeEPOHSE. =. 2 eet ace os Poe eas nee oe oe 76.50° 49 .50°
Number of
Responses
ion 15

Grades of
i . 5 3 $ 6 t 8 Negativeness
Positive Nedative

Fig. 14 Comparison of responses of Oniscus in instances of delayed response,
when the light is turned off after five seconds (solid line) and when the light is
continued (broken line). Numbers on abscissa indicate grades of negativeness
in figure 2. Numbers on ordinate indicate number of each type of response.
Shows practically no response after delay unless the light is continued.

light was continuous is nearly typical for the ordinary negative
reaction of an animal facing the light. (Compare with A in
figs. 6 and 7.) This set of responses after delay has a larger
proportion of positive responses than was shown in figures 6
and 7, but it forms essentially the same type of curve and is quite
different from the results when the light was turned off. The
same difference is shown, though less noticeably, in table 12,
where the angles of negativeness differ by 27°.

REACTIONS OF LAND ISOPODS TO LIGHT 243

According to table 12, the length of the intervals before re-
sponse and the percentage of response after delay are essentially
the same under the two conditions of the experiment. This is,
however, probably a matter of photokinesis rather than of
phototaxis.

From this experiment it may be concluded that orientation in
land isopods occurs after delayed response only when the stimu-
lus is continuous. In other words, if the initial stimulus is not
sufficient to bring about immediate response, the stimulus must
be continued in order for orientation to occur. Since, then, the
response to a continuous constant intensity can occur in cases
of delayed response, there appears to be no reason why the same
type of stimulus cannot be a cause of the reaction when the
response is not delayed.

3. Conclusions

From the preceding experiments and discussion the following
conclusions may be drawn:

a. Orientation of land isopods appears to be direct, and not
the result of a selection of random movements.

b. Orientation is at times due to the continuous action of
light acting at constant intensity, even though it may also be
due to the shock produced by changes of intensity.

VII. SUMMARY

A study of the reactions to light of three species of land iso-
pods, Oniscus asellus, Porcellio rathkei, and Porcellio seaber,
resulted in the following conclusions:

1. Land isopods respond to light stimuli in three ways: by
photokinesis, by phototaxis, and by vision. Vision is, however,
only slightly developed. The experiments were confined to
phototaxis.

2. Oniscus is negative to diffuse daylight and to controlled
horizontal illumination by artificial light. The latter was shown
in detail by a study of the percentage of negative responses,
by a graphical representation of the degree of turning away

244 CHARLES HARLAN ABBOTT

from the light, and by calculation of the average ‘angle of
negativeness.’

3. Porcellio is in general negative to the same stimuli as
Oniscus, but is, of the two genera, the less consistently negative.

4. Oniscus and Porcellio were found to respond to a range of
intensities from 100 C.M. to 0.01 C.M. The response is the
same to all intensities. On account of the extreme sensitive-
ness to low intensities, the threshold of stimulation was not
determined.

5. No consistent cities in the phototaxis of Oniscus was
caused by repetition of stimuli. Under these conditions, the
animal usually became less active, but accuracy of orientation
was not interfered with.

6. The reaction of Oniscus was essentially the same BiG...
previously exposed to strong light or to dark and whether kept
in a2 maximum or minimum of moisture. Porcellio was some-
what less negative after living in a dry habitat, and some indi-
viduals of this genus were found to be Pee after exposure to
strong light.

7. When the isopods were immersed in water, they did not
respond to light.

8. Land isopods are not greatly different structurally from
their aquatic relatives. They are confined to a limited habitat
on the land, where humidity is comparatively high and the
evaporating power of the air is relatively low.

9. Negative phototaxis appears to be a factor in keeping these
animals in a suitable habitat, and is thus important in fitting
them for life on land.

10. Oniseus, with a more restricted habitat than Porcellio,
has a more consistent negative reaction to light. ‘

11. Land isopods are more definitely negative to light than
the fresh-water isopod, Asellus communis. Negative photo-
taxis appears to be a more important ecological factor for land
isopods than for aquatic isopods.

12. Oniscus appears to be oriented directly by light, and to
respond, at least under some circumstances, to a continuous
light stimulus acting at a constant intensity.

~.

rm)

REACTIONS OF LAND ISOPODS TO LIGHT 245

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246 CHARLES HARLAN ABBOTT

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vol. 48, pp. 413-445.

AUTHOR’S ABSTRACT OF THIS PAPER ISSUED
BY THE BIBLIOGRAPHIC SERVICE, OCTOBER 8

VEL.

ASSORTIVE MATING IN A NUDIBRANCH,
CHROMODORIS ZEBRA HEILPRIN!

W. J. CROZIER

Bermuda Biological Station for Research
TWENTY-THREE FIGURES AND CHARTS

CONTENTS

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1. Homogamy in Paramecium and in man.......................

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i, ‘INTRODUCTORY

288

AZo

Observation of copulating pairs of the large nudibranch Chro-
modoris zebra Heilprin under natural conditions in the field sug-
gested that the component members of a pair tend to be of

nearly the same size.

Sexually mature individuals of this species

which engage in mating at the same time and within a restricted
area are found to range in total length from 4 to 18 ems.
ference in the size of two closely approximated specimens is

A dif-

1 Contributions from the Bermuda Biological Station for Research No. 98.

247

248 W. J. CROZIER

usually quite evident to the eye when the pair is viewed through
a water glass. Two animals were considered to constitute a
mating pair when they were found together in the proper rela-
tive attitudes and were seen to be stationary in these attitudes
for some minutes. Copulating individuals remain in close con-
tact for a relatively long time, in some cases several hours.

It is true that when collecting in a fathom or more of water
from a boat, mistakes may be made in judging mating couples,
although I believe that this error has not been great. Because
of this possibility, however, and a desire to observe more closely
the details of behavior in copulation, with reference to the pos-
sible mechanism of assortive mating (should this condition be
found to exist), experiments were performed under laboratory
conditions with a large number of individuals.

The pairs collected in the field, and those obtained in laboratory
matings were measured in the living condition. Analysis of the
dimensions of the individuals found spontaneously copulating
amply confirms the impression derived from the inspection of
mating couples under natural conditions. A moderately high
degree of correlation between the sizes of the two individuals
forming a mating pair is evident in the measurements obtained.
This can only be understood in terms of the conclusion,—which
is substantiated by the study of individual behavior in conju-
gation,—that assortive mating with respect to size (? age) is
practiced by Chromodoris zebra.

The magnitude of the correlation index for the ‘total length’
measurements is somewhat greater than the average known for
cultures of Paramecium containing a mixture of races. The
principal significance of assortive mating in Chromodoris is,
however, probably different from that assigned to homogamy in
Paramecium (Jennings). It seems that in C. zebra the imme-
diate result of assortive mating is to increase the number of
larvae beyond that which could be established by random
pairing.

From the standpoint of species survival and dispersal, granted
the condition that animals of very different sizes are sexually
mature, this effect of homogamy is distinctly purposeful. It is

ASSORTIVE MATING IN CHROMODORIS ZEBRA 249

desirable to emphasize the probably mechanical nature of the
origin and maintenance of this ‘adaptive’ condition, which can
be shown to depend upon the way in which the body of Chromo-
doris is constructed.

II MATING PAIRS UNDER NATURAL CONDITIONS

The copulating couples used in this study were gathered dur-
ing the month April 5 to May 5, 1917. All the specimens were
taken in Fairyland Creek, a_ broad, shallow, tidal stream bor-
dered by mangroves, near the laboratory of the Bermuda Bio-
logical Station. Collecting was purposely restricted to this one
locality. .The nudibranchs are very plentiful there, at certain
times. Chromodoris copulates at all hours of the day, but it
seems that a somewhat larger number of pairs are obtained here
during the three or four hours after sunrise, and again in the
late afternoon, than during the middle of the day. The state
of the tide has, in some places, a secondary influence upon the
occurrence of mating, the creek being so shallow that in certain
spots the bottom is exposed to the air at low water; the free
movement of the nudibranchs is thus restricted, and they are
forced to lie hidden under the thick masses of Zostera, Halimeda,
Laurentia, and associated plants which cover the greater portion
of the muddy bed of the creek. When they are free to move
about, their positive phototropism? assists in causing them to
appear freely upon brightly illuminated areas, where their con-
spicuous coloration renders them easily visible.

As each pair was secured it was deposited in a separate aqua-
rium jar, the different pairs being carefully kept distinct until the
dimensions of the animals had been ascertained, after the return
to the laboratory. Non-mating animals, found creeping alone
over the bottom, were frequently collected at the same time;
these individuals furnished a basis upon which to compare the
size of conjugants with that of non-conjugants, and also sup-

* The phototropism of C. zebra is not in any sense a ‘“‘laboratory product,”’
but on the contrary a very real element in its behavior under conditions of free-
dom in nature. Some account of the natural movements and behavior of C. zebra
will be given in another place.

250 W. J. CROZIER

plied a part of the material for mating experiments. Each
time that a collection was made it was attempted to secure all
the mating pairs present within the area considered, no selection
being exercised other than that involved in deciding whether or
not a given couple was actually engaged in copulation; as a rule
no difficulty was experienced upon this point. The correlation
tables (vide infra) include data on all the pairs found during the
interval April 5—May 5, with the exception of three pairs neces-
sarily rejected because one or both members were, owing to in-
jury (as subsequently explained), unfit for measurement.

The animals were measured on the same day as that on which
they were collected, and usually within a few hours after their
removal from the sea. This was thought necessary since certain
dimensions might have been altered if the nudibranchs had
been allowed time in which to deposit their large egg masses.
When, in the process of collection, a copulating couple is dis-
turbed, one or both of the individuals, without subsequent con-
jugation, may within the next twenty-four hours deposit a large
or a small (abnormal) egg mass.

III MEASUREMENTS

The body of a Chromodoris zebra is soft, contractile, within
certain limits easily changed in shape, and without any hard
supporting skeleton. The accurate estimation of its dimensions
therefore preserts a certain amount of difficulty. It was not
practicable to get consistent results by the measurement of
length while the animal was creeping freely over a smooth hori-
zontal surface. By removing the specimen from the water, how-
ever, and placing it, dorsal surface downward, upon a _ hori-
zontal plate of smooth glass freshly wetted with seawater,’ it
was possible to get length measurements which could be dupli-
cated in successive trials to within 0.3 em. Since the mean

3QOn a dry surface, or upon a glass plate wetted with seawater which has
been allowed to evaporate somewhat, the nudibranchs were stimulated to restless
contortions. When treated in the manner above outlined they become extended

to their maximal length and remain so, quietly, for several minutes, during
which the length of the body can be measured with fair precision.

ASSORTIVE MATING IN CHROMODORIS ZEBRA 25h

length of the nudibranchs was 11-12 ems., with a range of 4-18
ems., these measurements were of sufficient refinement for sta-
tistical purposes. The measurements were always made in
duplicate.

Fig. 1 Chromodoris zebra, seen from the right side and above, showing
dimensions measured. A~-B, total length; C-B, mantle length; D—E, distance of
genital papilla from the mouth. The animal is shown as it appears when creep-
ing upon a horizontal surface.

Fig. 2 Chromodoris zebra. The animal is shown as it appears when placed
dorsal surface downward upon a glass plate which is moistened with seawater.
The characteristic reaction in which the lateral margins of the foot are closely
approximated when the organ is not applied to a flat surface should be noted.
Lettering asin Fig. 1. (See text.)

The dimensions considered will be understood by reference to
figures 1 and 2. They include:

1) the total length, from the anterior edge of the buccal veil
to the posterior termination of the foot;

2) the mantle length, from the anterior margin of the buccal
veil to the posterior edge of the caudal veil;

252 W. J. CROZIER

3) the distance between the genital papilla and the mouth,
measured from the external orifice of the genital atrium (center
of the papilla) to the center of the mouth, along a horizontal line
parallel to the median plane of the body;

4) the distance of the genital aperture above the surface of the
foot.

Some of these dimensions were studied in independent series of
individuals, not included in the series of mating couples, and
for other series of individuals, included among the pairs of copu-
lating nudibranchs, the weight and the volume were ascertained
for each individual. The weights were obtained with a platform
belance accurate to 0.1 gm., the nudibranchs being dried and
deprived of superficial slime by rolling them gently in a towel
before weighing. Volumes were ascertained by the displacement
of sea water in a narrow graduated cylinder, the animals being
given a preliminary drying as in finding the weight; successive
determinations of the volume of the same anunaal agreed to
within 1-2 ec.

It was not possible to carry out all of these measurements
upon each individual, owing to lack of time. My first object
being merely to ascertain whether or not assortive mating occurs
in Chromodoris, and if so, to measure its intensity, it was con-
sidered that the measurements made were sufficient for this
purpose.

A word of explanation is required concerning the choice of -
points between which measurements were made, particularly
with reference to the estimation of total length (A-—B, fig. 2),
upon which the chief reliance is placed. Under ideal conditions
it would probably be preferable to employ the mantle length
as defined above. The projecting ‘tail’ of the foot is contractile,
and its length when at rest may vary in a way not closely cor-
related with the length of the individual. But with a number
of specimens it was not permissible to employ the mantle length,
because the animals nae suffered a very curious type of natural
injury.

In a preliminary paper concerned with the question of ‘‘ warn-
ing” coloration in C. zebra (Crozier, ’16b), I stated that the

ASSORTIVE MATING IN CHROMODORIS ZEBRA 253

only type of structural injury shown by specimens of this species
as obtained in the field amounted to a slight, and relatively in-
frequent, damage to the projecting margin of the mantle. This
statement was correct so far as concerns the several thousand
‘specimens which had passed through my hands in the preceding
two years. In 1917, however, collecting over the same territory
as in previous years and particularly in Fairyland Creek, a con-
siderable number of individuals were obtained in which a piece,
of varying size, had obviously been bitten from the middle of the
dorsal surface. As many as 20-50 per cent of the specimens col-
lected at one time would be found so injured. Animals thus
afflicted were seen to engage in normal copulation (with unin-
jured or with damaged partners, in equal frequency), and in the

————
~~ ee

Cts 5

— SS

Fig. 3 Showing the type of injury found inflicted upon C. zebra in nature,
and its effect in producing puckering and a shortening of the ‘‘mantle length;”’
a somewhat extreme case, dorsal view. The corresponding outline of an un-
damaged specimen is indicated approximately by dashes.

great majority of instances they already showed signs of regen-
erative activity appropriate to the ultimate repair of the injury.
They were found to deposit good egg-masses. ‘In all these cases
there was present a greater or less degree of puckering on the
dorsal surface (fig. 3), which caused the actual ‘‘mantle length”
(B-C, figs. 1, 2) to be shorter than that of uninjured specimens of
about the same general size. This was especially true when the
wounded dorsal parts were stimulated by contact with the glass
plate during measurement. The amount of tissue lost as the re-
sult of injury was rarely considerable, and the fotal length (A—5,
figs. 1, 2) of the damaged nudibranchs seemed not to be seriously
influenced. Since it was desirable to include all the mating

4 The nature, distribution, frequency, and significance of these injuries will
be discussed in another place.

THE JOURNAL OF EXPERIMENTAL ZOOLOGY. VOL. 27, NO. 2

254 W. J. CROZIER

couples obtained, the ‘total length’ measurement was mainly
used.

The length of a Chromodoris as measured in the way described
is somewhat greater than that obtained from the quietly creeping
specimen. The body is of but little greater density than sea
water (1.062-1.072 gms./cem., as compared with 1.0265), but
is so soft that when adjusted upon the measuring plate its weight
is sufficient to noticeably flatten the animal. The distortion in-
duced in this way is probably greater, proportionally, in the case
of large individuals, weighing up to 75 gms., than in the smaller
specimens, which weighed 10-15 gms. The flattening of the
body through the pressure of its own mass, under the conditions
imposed during the measurement, helps to obscure the smooth-
ness of the expected theoretical relation between length and
volume (fig. 4). It should also be remarked that the nudi-
branchs may tend to elongate somewhat, by muscular contrac-
tions, as a preliminary to righting movements. The volume and
weight of a Chromodoris may also vary independently of the
length, owing to the influence of such factors as: 1) the number
of egg masses which have been deposited, and 2) the amount of
water contained in the intramuscular spaces of the foot and
body-wall. Nevertheless, the qualitative agreement between
the indices of correlation in mating calculated from the several
kinds of measurements taken shows that the estimations of
‘total length’ as here carried out are adequate for the determina-
tion of assortive mating with respect to size. The charac-
teristic reaction of the foot when removed from contact with a
flat substratum, namely the rolling up into close approximation
of its lateral borders in the median plane (fig. 2), helped to
insure a uniform attitude among the various individuals during
measurement.

IV ASSORTIVE MATING IN NATURE

1. Total length. No significant difference was observed be-
tween the size of the nudibranchs obtained as members of con-
jugating couples and those taken singly, either in the collections
of any one day (illustrated by the data in figures 5 and 6), or

ASSORTIVE MATING IN CHROMODORIS ZEBRA 255

in the total population examined. Laboratory observation
proved that specimens of any length between 4 and 18 ems.
would copulate successfully with appropriate mates, and de-
posit eggs; hence it is probable that all the animals seen in the

CC.
'sI@)

(O
60
50
40
5O

20

eee To OT Tee ME 1S 16 ty er ig Cis.

Fig. 4 Showing the irregular distribution of the volumes of 95 specimens of
Chromodoris zebra in relation to the “‘total length.’’ Animals measured imme-
diately after being taken from the sea.

field were (or had recently been) physiologically primed for con-
jugation, and that chance, in combination with the normal ra-
pidity of repeated pairing for animals of different sizes, as
related to the size-frequency distribution, determined the num-
ber and kind of pairs obtained in the various collections. It

256 W. J. CROZIER

should be noted, further, that there is no detectable tendency
for individuals of any given size to copulate at a different time
of day, or season, from those of any other size.

One hundred and forty-eight pairs gathered in Fairyland
Creek were composed of individuals giving the length-frequency
distribution exhibited in figure 7. The relation between the

wb A HO ©

8 9 0 il 28 4 5 16 cms

6 9 Wl l2is 4 15 16 CMs.

Figs. 5 and 6 The frequency distribution of sizes (total lengths) for mating
and non-mating individuals in two random collections (Apr. 24th and Apr. 30th,
respectively); the continuous line denotes mating individuals, the dotted line
non-mating individuals. Showing that there was no significant difference be-
tween the sizes of mating and of non-mating specimens.

lengths of the two individuals constituting a pair is set forth in
table 1. This is a single-entry correlation table, constructed and
used in accord with the manner suggested by Jennings (’11 a,
"11 b) for cases of this kind. The coefficient of correlation is
found to be

r = 0.608 + 0.024,

ASSORTIVE MATING IN CHROMODORIS ZEBRA 257

Ao

26h 69-213 JA (AG 16 cing:

Fig. 7 The lighter line shows the frequency distribution of total-lengths for
the constituents of pairs of Chromodoris zebra obtained in the field (148 pairs,
296 individuals); the heavier line shows the same for pairs formed in laboratory
experiments (119 pairs, 238 individuals).

TABLE 1

Correlation table for the lengths of 148 pairs of Chromodoris zebra found under nat-
ural conditions. The larger member of a pair is entered in the vertical columns,
the smaller in the horizontal rows. The unit of measurement is 1 cm. The in-
dex of correlation is r = 0.608 + 0.024,.

7 2 1 3
8 2 3 1 1 1 8
9 2 2 t 4 3 2 17
10 6 6 4 6 1 2 25
11 Uf 9 a 2 i 1 22
12 10 9} 10 4 3 36
13 As eo dh dt 1 1 1 22
14 3 4 2 9
15 2 3 5
16 1 1

258 W. J. CROZIER

The degree of correlation between the sizes of individuals
mating together is further shown graphically in a regression
plot (fig. 8). The two components of a copulating pair are usu-
ally not of identical size. The value of the index of correlation
signifies, however, that as a rule large individuals mate with

IG 16 15-14 BPN 0 Sa

Fig. 8 Showing the relation between the length of specimens of C. zebra
(abscissas) and the average lengths of their mates (ordinates), for 148 pairs.
If there were no correlation between the lengths of components of mating pairs
the observed points, [2], would fall upon the line mm’ (= the general mean);
if assortive mating were perfect, the line [2] would coincide with [1]. The
smoothed line of regression is shown by the dot-and-dash line; in this and suc-
ceeding plots it is assumed that the regression is linear throughout. This is
possibly not quite correct, but does not affect the special conclusion drawn from
these data, namely that large individuals mate together. The class unit is 1
em. The index of correlation is r = 0.608.

large, small individuals with small. For each 1.0 cm. difference
in the total lengths of two specimens of C. zebra there will, on
the average, be found a difference, corresponding in sign, of
about 0.6 em. between the lengths of the partners during their
conjugation under natural circumstances.

ASSORTIVE MATING IN CHROMODORIS ZEBRA 259

TABLE 2

Correlation table for the mantle-length of 89 pairs of C. zebra. The larger member
of a pair ts entered in the vertical columns, the smaller in the horizontal rows.
The class unit is 1 cm. The index of correlation is r = 0.518 + 0.0527.

10 11 12 13 14 15 16

ae ore
CO OO WwW Or
—"
Own wore
Dw ow
bo
for)

16 24 25 13 2 0 1 89

2. Other measurements. The degree of homogamy shown by
the measurements of other characters may be briefly considered.

A. A series of mating pairs, comprising 89 normal uninjured
couples obtained successively in the field, whereof the mantle-
length was determined for each specimen, gave data summarized
in table 2. A small, homogeneous series was used, consisting
of a set of animals collected at one time and measured with par-
ticular reference to the mantle-length, rather than a larger
series selected from among the general field collections. Such a
selection would otherwise have been necessary, owing to the
relatively frequent occurrence, at this time, of injuries upon the
dorsal surface of Chromodoris. As previously stated, these in-
juries, in addition to making the nudibranchs difficult to meas-
ure, resulted in the distortion of the ‘‘mantle length” through
puckering about the wound.

The coefficient of correlation calculated from table 2 is

r = 0.518 + 0.052;

The result is in sufficiently good agreement with that obtained
from the measurements of ‘total length’ (r = 0.608). The cor-
responding regression plot is given in figure 9. The number of
pairs (89) involved in the tabulation of mantle lengths is smaller

260 W. J. CROZIER

than that measured for the total length (148). For the same
group the correlation based upon total length estimations is
r = 0.492 (table 3). This agreement (fig. 10) is sufficient to
show that the method of measuring ‘total length,’ as previously
described, is free from serious objection so far as the variable
length of the ‘tail’ of the foot is concerned. Even with small

16

StS 4 IS tee do 3S) BY PG

Fig. 9 Showing the relation between the “mantle-length”’ of specimens of
C. zebra (abscissas) and the average length of their mates (ordinates), for 89
pairs; (1) is the line upon which the observed points, (2), would fall if no cor-
relation were involved; m—m’ is the mean for all. The smoothed regression line
is shown thus -—-—-—. The class unit is 1 em.; r = 0.518.

numbers of this sort the correlation is entirely too high to be
explained as the result of assortive mating.

B. In one small series of 66 pairs the volume of the animals
was measured. The frequency distribution of volumes is shown
in figure 12. The correlation index for these pairs, on a volume
basis, is low (r = 0.1353), as shown in table 4, and the distri-
bution of the measurements is very irregular (fig. 13). This
series is not extensive, yet the result of its examination has
some value. The volume of a Chromodoris may in part de-

ASSORTIVE MATING IN CHROMODORIS ZEBRA 261

TABLE 3

Correlation table for the ‘‘total lengths’’ of the 89 pairs of C. zebra whose ‘‘mantle-
length’’ correlation is given tn table 2 (see fig. 10), r = 0.492.

8 9 10 Pt es ela) Pee ab 27) 16) | a2) |. 18
8 2 2
9 1 2 2 4 3 1 13
10 5 4 1 2 1 2 15
i 3 6 2 1 1 13
12 5 4 4 73) 16
13 } 6 9 3} 1 1 20
14 4 2} A "i
15 US ae 2
16 1 1
2 1 7 9 165) Ch 20-1), S 1 89

TABLE 4

10 15 20 25 30 35 40 45 50 55
10 a ee | 5
15 2G. eS 1 13
20 Ge Wate eA. eer, 2 21
25 ae ea ie a ale ae ie) a6
30 | bBo | 8
35 BS es 3
40 1 1

pend upon the condition of the gonad and associated reproductive
glands; perhaps in some additional manner the volume of an
individual may be a function of the number of egg masses which
the nudibranch has recently deposited. If this interpretation be
correct, it follows that length (and correlated external dimen-
sions), rather than reproductive condition (provided the animals
in question be still capable of being stimulated to copulate), is
the basis of selection in pairing. This would explain the low cor-
relation for homogamy in the volume series of measurements (al-
though the small number of cases may be responsible), and would
be intelligible in view of the irregular relation between volume

262 W. J. CROZIER

10

1 6 AS 14 TS! Te 0 2

13

50 = 40 30 20 Te)

Fig. 10 Regression plot for data in Table III; r’ = regression line as calcu-
lated from ‘‘mantle-length;’’ r, same as calculated from “‘total-length’’ meas-
urements for the same 89 pairs. (See text.)

Fig. 13 Regression plot for correlation in volume between members of 66
mating pairs (see Table IV). The regression is probably not strictly linear (cf.
Fig. 8). The unit of classification is 5 ccm.

ASSORTIVE MATING IN CHROMODORIS ZEBRA 263

CMS

1G If).

}

Mantle len
Co

8 hO Ver les ora 116 Pie nS:
lolal lengih |

lO 15 2025 30 35 40 45 5055 CCM.

Fig. 11 Showing the relation between ‘‘total length’’ and ‘‘mantle length”
in 103 uninjured specimens of C. zebra (cf. Fig. 2). The relation is almost, if not
quite exactly, linear.

Fig. 12 Frequency distribution of the volumes of specimens of C. zebra.
The class unit is 5 ccm.

264 W. J. CROZIER

and length (fig. 4), and between weight and length (fig. 14).
This point of view is supported by the results of mating experi-
ments with starved animals, tests which are discussed in a
subsequent section.

C. The distance of the genital papilla from the anterior end
of the animal (mouth), and its height above the ventral surface
of the foot, were also measured in a number of specimens. These

3 10 12 }4 i6 cms

Leng?

Fig. 14 Showing the irregular relation between length and weightjin freshly
collected individuals, which cannot be due to irregularities in the weight of the
stomach contents.

figures are neither numerous enough nor sufficiently homo-
geneous to enable cross-correlation indices to be calculated;
moreover, such calculations would be unnecessary for present
purposes. The data obtained in this connection are detailed
on a subsequent page; they are intended to give an idea of
the topographical position of the genital papilla in nudibranchs of
different sizes. The important point is that the genital papilla

ASSORTIVE MATING IN CHROMODORIS ZEBRA 265

is situated in almost precisely the same relative position in in-
dividuals of all sizes, its distance from the mouth and from the
surface of the foot being each proportional to the length of the
animal.

V MATINGS IN MASS EXPERIMENTS

1. Method and findings. Approximately four hundred speci-
mens, freshly collected, were allowed to mate together in lab-
oratory aquaria. The experiments were made during the time
covered by the collection ‘of the field data. About half of the
animals involved had originally been ‘obtained as members of
copulating pairs, the other half being collected as single, non-
mating individuals. Forty to fifty animals, taken at random
but including in every instance a fair representation of the differ-
ent sizes of specimens, were put into each of a number of nine-
gallon aquaria. The ‘crowding together’ brought about in this
way was intentional. The nudibranchs mate with sufficient fre-
quency, at this time of year (April), so that the pairs observed
under these conditions did not involve merely the originally
non-mating individuals.

The aquaria were supplied with running seawater, as the
nudibranchs will neither copulate nor deposit eggs in still water.
The water of the laboratory supply-system was less alkaline than
the ‘‘outside” sea water, but the chromodorids lived in it for many
months. The water inlet was so arranged as to be in about
the center of the aquarium, and midway from top to bottom.
This precaution was important, as when the incoming water was
allowed to form a current starting at the wall of the aquarium a
’ considerable number of the individuals became massed about
the inlet. Copulating pairs would under these conditions have
been difficult to distinguish with certainty; with the arrange-
ment here specified, localized crowding was largely avoided, and
it was easy to be sure that a given pair was actually engaged in
conjugation.

There is a very pronounced tendéney toward the occurrence’
of epidemics of pairing. Many conjugating couples occur at
about the same time in any one aquarium. This is advan-

266 W. J. CROZIER

tageous, as a large number of couples were in this way obtain-
able at the same time. It is also important as pointing to the
possible existence of specific secretions which may induce pairing.

Twenty-four to forty-eight hours after the nudibranchs had
been put into an aquarium, the mating-pairs noted were re-
moved, placed separately in small dishes, and as soon as pos-
sible submitted to measurement. In this way data were secured

6 15 44 0512 N19 SB eG
Fig. 15 Regression plot (r, r) for data in Table V; 7’, r’, regression line ob-
tained from pairs collected in nature (Fig. 8).

regarding the lengths of the constituents of 119 pairs (ef. fig. 7).
These figures are arranged in table 5, and in a regression plot
(fig. 15). The index of correlation for the total lengths of the
components of mating couples is here r = 0.721 + 0.023.

2. Comparison with normal conditions. The degree of homo-
gamy exhibited in this series of laboratory matings is appreciably
higher than that found for the pairs collected in the field (fig.
15). This may be the outcome of chance variation incident to

ASSORTIVE MATING IN CHROMODORIS ZEBRA 267

TABLE 5

Correlation table for total lengths of 119 pairs of C. zebra obtained in laboratory
matings (mass experiments); r = 0.721 + 0.023 (cf. Fig. 15)

6 UT 8 9 10 11 12 13 14 15 16

4 1 1
5 1 1
6 1 i 1 3
x 1 1 2
8 1 2 2 1 6
9 2 2 4 1 2 11
10 5 6 3 3 2 1 20
11 5 | 12 2 3 1 23
12 5 5) 7 Ged 24
13 7 4 yin as | 17
14 2 5} 2 9
15 1 1
16 1 1
1 3 2 5 9 Te Peo | 18" | aaa MG 119

the restricted number of matings available for study. Several
other influences may also be concerned. In the aquaria the
nudibranchs creep over a smooth substratum, and there is less
opportunity than in nature for discrepancy in the sizes of two
specimens to be discounted by the unevenness of the bottom
upon which they might be resting. From this point of view the
irregular substratum presented by masses of algae, rocks, and
sand would be regarded as favoring the apposition of the genital
papillae in the case of two animals differing somewhat as to
size. The efficiency of this influence cannot be very great,
however; its exact value I am unable to estimate. It is, in addi-
tion, entirely possible that some ‘pairs’ collected in the field
were in reality misjudged, in which event the index of regression
obtained from the mass experiments would perhaps more nearly
represent the true state of affairs.

The significant point, however, lies in the fact that the lab-
oratory matings confirm the qualitative correctness of the con-
clusion that there is practiced by Chromodoris zebra a rather
intensive degree of homogamy with respect to size (Crozier,

268 W. J. CROZIER

17.c). Given the conditions imposed upon the nudibranchs in
the experiments just described, it is legitimate to conceive that
here, if ever, the animals would have conjugated according to
the chance dictates of random contact. The magnitude of the
correlation index makes untenable the idea of random pairing;
moreover, close study of the behavior of C. zebra in copulation
fully substantiates the proposition that true selective conjuga-
tion does indeed occur.

VI THE BASIS OF HOMOGAMY

1. Homogamy in Paramecium and in man. In human mar-
riages there occurs, according to Pearson (Pearson and Lee, ’03)
and others, an appreciable degree of positive correlation between
the two members of a mating pair as regards their stature and
certain other characters. The evidence available with refer-
ence to this matter has been reviewed in an interesting essay by
Harris (12a). The cause of assortive mating in man is in
most cases far from obvious; its significance, its consequences,
cannot be followed in detail. ,

For Paramecium the case is clearer. It was proved by Pearl
(07) that in Paramecium there exists a rather high degree of
correlation between the lengths of the components of conjugat-
ing pairs. Pearl held this correlation to be the result of assortive
mating, and he was inclined to accept as its explanation a rela-
tively simple mechanical condition concerned with the manner
in which two conjugants become adjusted to each other in a
successful mating. According to Pearl, if two individuals, in
the proper physiological condition for conjugation, are by a
chance mutual approach induced to draw together, ‘‘their oral
surfaces adhere in whole or in part. The extreme anterior ends
of the oral grooves firmly adhere to one another first. If the two
individuals are so nearly the same size that the mouths ap-
proximately coincide when the anterior ends are together, firm
union occurs at the mouth regions and definite conjugation fol-
lows” (Pearl, ’07, p. 267). If the two individuals do not ‘fit,’
they separate, or die. ‘‘The homogamic correlations arise, then,
as a result of the necessity for the mouths of the two individuals

ASSORTIVE’ MATING IN CHROMODORIS ZEBRA 269

to come together (or ‘fit’) when the extreme anterior ends are
united.’ This explanation was not based upon personal ob-
servation, and later work has shown it to be somewhat too
schematic, although entirely correct in principle.

Jennings (’11b) substantiated Pearl’s discovery of assortive
mating in Paramecium, and was able to make certain the con-
clusion that the observed correlation between the lengths of
conjugating individuals is indeed largely due to true homogamy,
rather than to any process of mutual equalization of sizes during
the progress of conjugation. Jennings is also in essential agree-
ment with Pearl regarding the mechanical cause of assortive
mating. On the basis of direct observation of the mating proc-
ess, Jennings showed that in a general way the explanation
offered by Pearl, as previously quoted, is quite sound. However,
in many cases conjugants of unequal length are able to pair
successfully through a series of bending movements and con-
tractions which cause their lengths to become more or less equal-
ized. This influence is, nevertheless, found inadequate to ac-
eount for more than a small part of the correlation. It remains
true that two individuals conjugate most readily when they are
of nearly the same size. This is the automatic outcome of the
manner in which the conjugation-postures of Paramecium are
brought about, and of the fact that the total length of Para-
mecium (and any other dimension which may be used as an index
of size) is rather closely correlated with the distance from the
anterior end to the mouth. Upon the equality of the latter
character in two individuals the possibility of their successful
conjugation is in large measure mechanically dependent.

It does not appear that the pairing of animals, other than Para-
mecium, several other infusorians (Jennings, ’11b, p. 85-88),
and man, has ever been examined with reference to the possible
occurrence of assortive mating. Yet it is generally recognized
that this matter of homogamy is one of great importance. In
addition to its implications for other phases of evolutionary
speculation, assortive mating (where it can be shown to occur)
may provide in particular an interesting example of a mechani-
cally determined result having the superficial characteristics of a

270 W. J. CROZIER

‘purposeful adaptation.’ This phase of the matter does not
seem to have received sufficient emphasis, although the scanty
observations available with reference to selective pairing contain
little evidence that such a process might be directly ‘‘beneficial’’
to a species. The case of Chromodoris zebra affords an instance
among metazoans which is exceptionally favorable for study. It
becomes, then, of special interest to discover, if possible, the
basis, or method, of the assortive mating practiced by this
nudibranch.

2. Mating behavior of nudibranchs. Assortive mating with re-
gard to size would be expected to occur only where there is avail-
able some physical basis for the process of mutual selection
(‘fitting’) which is necessarily involved. According to Orton
(1914 a), the sea urchin Echinus miliaris, in its breeding season,
‘‘has the habit of associating together in pairs;’”’ the association
is often close, and in many instances the pairs found together
contain one individual of either sex. I have noticed instances
of this sort in Lytechinus variegatus, and several good examples
of the same nature have been observed by me with Tripneustes
esculentus. These cases have not yet been examined for the
occurrence of assortive pairing. In passing, it may be remarked
that if this type of ‘‘conjugation”’ is indeed at all general among
echinoids, it is apparently not sufficiently specific altogether to
prevent hybridization in nature (Shearer, de Morgan, and Fuchs,
14). A possible basis might readily be conceived upon which
might be founded a correlation between the sizes of individuals
‘pairing’ in this way. Nevertheless it seems probable that in-
vertebrates which reproduce by external fertilization will not,
in general, yield evidence of assortive mating with respect to
size. Among nudibranchs, however, where a true copulation is
a prerequisite for the internal fertilization of the eggs,—as may
be demonstrated experimentally, and by the existence in some
forms, e.g., Doto, of recognizable anatomical arrangements mak-
ing for the prevention of self fertilization (Dreyer, ’12, p. 342),—
there is a possibility that the mechanical conditions controlling
copulation may determine real homogamy as to size. This is
more especially true since, image-forming eyes being absent,

ASSORTIVE MATING IN CHROMODORIS ZEBRA 271

tactile and chemical senses seem the main, if not the only,
channels through which the manouvers of conjugation may be
controlled and directed.

The mating behavior of certain nudibranchs other than Chro-
modoris throws an interesting light upon this question, although
the material available for comparison is very limited. In the
littoral nudibranch Cenia, as described by Pelseneer (’99, p.
518, footnote 2), the three widely separated external genital
openings of one member of a mating couple are simultaneously
brought into close relation with the appropriate openings of the
other individual, the posterior female orifice of each receiving
the ‘opposite’ penis. If it be true that this type of conjugation
is necessary in Cenia (further observations on the point would
be valuable), and if mutual equalization of the sizes of conju-
gants be inadequate to overcome natural variation in the sizes
of reproducing individuals, then in this species there is an ob-
vious mechanical basis upon which assortive mating might be
required to operate. There is the difficulty, in the case of Cenia,
and of other ‘‘ Elysiens’’ which I have been able to study, that the
conjugating population is of very nearly uniform size, which is
decidedly not the case with Chromodoris. The important fact,
however, which indeed forms the basis of selection in pairing, is
the necessity for the reproductive openings to be brought into
close contact. In at least one nudibranch (Cumanotus) there
are present. somewhat unusual ‘clasping organs,’ which help to
insure the close approximation of the respective male and fe-
male apertures (Crawshay, quoted by Eliot, 08). This is neces-
sary both in cases where the male and female openings.are dis-
tinctly separated, and in species where they are concentrated

upon a relatively small papilla (Montagua, Smallwood, ’03;
- Chromodoris), and is of course the condition obtaining in some
other gastropods (cf. Meisenheimer, ’07). C. zebra conjugates
after the fashion employed by other members of its family.
Two individuals come together with their right sides in con-
tact, and when the central aperture of the genital papilla of one
specimen is closely applied to that of its mate, the short conical
penis of one is inserted into the aperture of the other and insemi-
nation then proceeds.

De W. J. CROZIER

There is evidently some influence other than chance contact
which is at work to bring mating individuals together. Shore-
ward movements out of deep water at certain periods (Crozier,
17 b), which nevertheless do not appear to be carried out ‘‘for’’
purposes of reproduction, play a part in this process. So do the
reactions leading to the concentration of individuals in the man-
grove creeks and upon open sandy bottoms. In one particular
place it has been clear that water currents have been important
in bringing a number of individuals to come near to one another.
This spot is along one border of a shallow strip across which there
is a water connection between two arms of Fairyland Creek.
A row of flat stones is situated along the north edge of this
strip, and with the change in the tide a strong current flows over
the narrow neck. A number of chromodorids were usually
found in pockets hollowed out by the current underneath the
stones referred to. This is probably the result of their being
“entrapped” there at periods when the current is not strong;
they move into the “pockets,” or are forcibly carried there, in a
somewhat passive fashion, as the animals are not rheotropic.
This is the only place where I have found C. zebra under stones;
it paired in this situation, and deposited eggs. Unlike some
other species of this genus, C. zebra moves toward the light.
This positive phototropism is in itself a factor tending to bring
into company a large number of individuals.

It is a noteworthy fact that these nudibranchs are very sel-
dom found to occur singly. If only a very few specimens are dis-
covered in the course of a day’s collecting, it is nevertheless usu-
ally found that the animals tend to occur in groups, the indi-
viduals being relatively near together. When the nudibranchs
are actively engaged in breeding, groups of specimens, such as
are illustrated in the following records, are not infrequent :—

May 2nd 1917. Groups of C. zebra observed in Fairyland Creek.
All the individuals in each group were closely packed together, each
group being well separated from all the others. The individuals mat-
ing together in each group (when copulating couples could be distin-
guished with certainty) are bracketed together. The measurements
are those of ‘total length,’ in cms.

ASSORTIVE MATING IN CHROMODORIS ZEBRA 2S

Group Group Group

| ies 33 4, 14.4) So. 13:5
10.8 12.5 10.7
9.3 13.9 9.3

bo
Ree
aaonww
1 |
—
iat
ws

ore wb
bho
a ee Sy
=
nore
C oOo oO
ee SS Se,
“I
—
Or
nS I

eR Re
ee
SI bt) bo
ee
H= Od
or do
—-

To what extent ‘attractive’ secretions may be involved in
producing these groupings, I am as yet unable to state. The
matter will be studied further, as it is of interest, among other
things, to determine why the several species of Chromodoris
cannot be made to conjugate with one another. C. zebra does
possess a characteristic and very penetrating odor.

The details of copulations were examined in the laboratory.
When two individuals come near together it is frequently to be
observed that one of them is stationary, the other moving toward
it. This occurs in still (non-circulating) water. When they have
come within about 10 ems. of each other, if not before, the
genital papillae are frequently protruded. In many instances the
protrusion is evidenced by one of the animals earlier, or more
strikingly, than by the other; in a number of cases it was noted
that the former individual was relatively stationary, the latter
moving toward it. Often the animals come together either with
their left sides in apposition, or ‘head on;’ in either event they
slowly move about until finally, headed in opposite directions,
the surfaces of the right sides are in contact. This operation
may require as much as an hour, or longer. The genital papillae
become gradually more prominent, and exhibit movements of
extension and partial retraction which are more or less rhythmic.
Not uncommonly the protrusible pharynx is everted, and the
lips are passed over the surface of the other animal. This be-
havior has also been observed in the field.

When the two individuals are of nearly the same size, they be-
come fitted to one another after the manner sketched in figure 16.

THE JOURNAL OF EXPERIMENTAL ZOOLOGY, VOL. 27, NO. 2

274. . W. J. CROZIER

Sometimes conjugation is effected with less trouble, or more
speedily, because the specimens are of nearly identical size and
are from the first so situated that their right sides are in con-
tact (figs. 17, 18); in other cases difficulty is experienced in
bringing the reproductive openings together. Two nudibranchs
differing greatly in size are, under ordinary conditions, unable
to accomplish this (fig. 19), and, following futile attempts at
copulation, will (usually after a short time) wander apart.

The whole character of the animal’s behavior in these experi-
ments supports the contention that the nudibranchs are ‘at-
tracted’ to one another as a result of reactions to specific secre-
tions; the ‘epidemics’ of conjugation in aquaria, referred to in a
previous section, may also be cited in this connection. The con-
summation of pairing depends upon these specific reactions (in-
cluding those of the terminal papilla of the genital ducts), and
upon the mechanical condition that the papillae may be brought
together.

A certain amount of equalization of ‘size’ does occur, but it
is not efficient in promoting copulation between individuals dif-
fering several centimeters in length. The openings of the repro-
ductive ducts are situated in the same relative position in speci-
mens of all sizes, the distance from the mouth and height above
the surface of the foot (when the animal is quietly creeping)
being each directly proportional to the total length of the ani-
mal (fig. 20). Contractions of the general body musculature,
and movements of the protruded genital papilla, are both in-
volved in the efforts to overcome differences in the sizes of indi-
viduals endeavoring to mate; the latter movements are the less
important. These nudibranchs can contract to such an extent
that the length ‘over all’ is about 80-85 per cent of its normal
extent when not specially contracted; the distance between
mouth and genital atrium can be similarly shortened. In the
copulation of two specimens of equal size the animals are some-
times contracted to a certain extent, but the usual condition in
such a case does not involve noticeable shortening. The prin-
cipal effect of the shortening is to bring about an elevation of
the genital orifice. It may in this way be employed by a smaller

18

19
\7

Fig. 16 Illustrating the attempted conjugation of two specimens of some-
what different size. Outline sketch, dorsal view (gills omitted). X %. At the
side, sketch showing manner in which the genital papilla is protruded. X 1.

Fig. 17 Illustrating the copulation of two individuals of equal size; seen from
the ventral surface, through glass wall of aquarium; as contrasted with the pair
shown in Fig. 16. The animals here are somewhat contracted. X 3.

Fig. 18 A case similar to that in Fig. 17. The anterior end of individual
to the left is extended, the lips being passed over the surface of its partner.
~ 4.

Fig. 19 Unsuccessful attempt of two individuals of different sizes to engage
in conjugation. Relative positions of reproductive appertures indicated by
dotted circles (2, that of individual to the left; 1, of that to the right; 2 was
about 1 cm. higher than 1). X 3.

275

276 W. J. CROZIER

animal endeavoring to mate with a large one, but such attempts
are not as a rule successful. In special situations this process of
‘equalization’ of sizes may be effective, but it is not of primary
importance.

Nor, as a rule, are the movements of the elevated genital pa-
pilla effective in ‘equalizing’ the size of two nudibranchs. Dur-
ing the close approach of two specimens which are attempting
to copulate their papillae are considerably protruded. In the
center of each papilla is the opening which communicates with

6%. BA oI Fa. DS A Rel) ho ee
Tota/ /erg7%.

Fig. 20 Showing the relation (A) between total length and distance of genital
papilla from mouth; and (B) between total length and height of the papilla
above ventral surface of the foot, in creeping.

the sperm-receptacle and seminal duct. The surface of the
papilla apparently corresponds to the inner surface of the ‘genital
atrium’ of Smallwood and Clark (’12), who give a diagrammatic
figure of the reproductive apparatus in this species. As the
two papillae are brought nearer and nearer together, they be-
come still further enlarged, and when their tips come into con-
tact the movements of the animals as a whole cease. A slow
pulsatile motion of extension and retraction is now evidenced
by each papilla, the movements being reciprocal and the two
papillae remaining closely pressed together. If two individuals
in this condition are separated by a slight displacement of one of
them with a glass rod, the genital papillae become widely pro-
truded, and are usually quickly successful in returning to their

ASSORTIVE MATING IN CHROMODORIS ZEBRA ATE

former position when the rod is withdrawn. If one individual of
a pair be slowly moved away from its mate, the papilla of the
untouched nudibranch endeavors to follow its partner in its en-
forced retreat. The termination of the preparatory manoeuvers
comes when the penis of one Chromodoris is inserted into the
central opening of the papilla of its mate. The reproductive

apertures are in this case pressed together by muscular contrac-
tions, and not held in place, as in some other nudibranchs,
either by copulatory clasping organs (Cumanotus; Eliot, ’08),
or by a thickened mucous secretion (Montagua; Smallwood, ’03).
The penis is unarmed.

I have made attempts, but without success as yet, to deter-
mine whether or not that individual of a pair which has been
most active in conjugation (the moving member of the typical
pair previously described) is in every case, or in most cases, the
first to engage in insemination. If the pair be undisturbed,
mutual insemination frequently occurs, and I believe it to be
usually the case here, as in other large nudibranchs.

Finally, some examples may be cited which serve to illustrate
the efficiency of the process of mutual selection with respect to
size. Where the difference in the length of two specimens
amounted to 5 or 6 ems., the ‘trial and rejection’ (to use a con-
venient but misleading phrase) occupied but a few minutes.
The observations here given are typical of many others which
were collected.

Expt. 10.42. April 18, 1917. Chromodorids maintained in the
laboratory three and one-half months, without food. Their sizes had
decreased to such an extent that most of the specimens were one-half
to two-thirds their original length. The following pairs were ob-
served to be in copulation at one time, there being in all 13 specimens of
different sizes in the one aquarium.

PAIR LENGTH

cms. cms.

oP WO Ne
NO O & CoO
—
ooo om
S2enmat or

278 W. J. CROZIER

Expt. 10.57. April 24. In an aquarium containing 18 freshly col-
lected chromodorids, a specimen 13.5 ems. long was seen to be unsuc-
cessful in attempting to copulate with another 8.7 cms. in length;
15 min. later it ‘refused’ a second one, 9.5 ems. long. After 30 min.
it mated successfully with an individual which measured 12.2 ems.

Expts. 10.61-10.64. In each of the following cases the animals
whose lengths are tabulated together were placed in a single aquarium.
The individuals which conjugated are enclosed in brackets.

EXPERIMENT
a | b c d e
cms cms. cms cms. cms
15.0 17.0 11.4 13.9 14.0
feopins.-!.. eee oe 12.0 9.5) 13.8 13.0
12.5 11.0 9.3f | 12.6 12.5
12.6)
10.3/

Expt. 10.93.1. May 18. Five C. zebra were placed in a 9-gallon
aquarium supplied with running water. Their lengths were respec-
tively

ANIMAL
a b c d e
cms. cms. ems cms cms,
5.8 7.0 13c5 15.0 16.1

These individuals were all collected on May 18, but in different
places, (a) and (c) being obtained in Millbrook Creek, the rest in
Fairyland Creek. They were ‘ear-marked,’ so as to be separately
recognizable, by having a small piece clipped from different parts of
the mantle; this injury caused the nudibranchs no inconvenience.

After two hours, @ was observed unsuccessfully attempting to copu-
late with e, and b ‘with c. On May 19, there were found pairing to-
gether a with b and c with d. The animals were isolated, and b and d
subsequently laid egg masses.

VII ON THE CONSEQUENCE OF HOMOGAMY

This paper is concerned primarily with the demonstration of
the fact of assortive-mating in Chromodoris. It may never-
theless be well to consider some of the possible results of homog-
amy in this nudibranch, although several of the matters con-

ASSORTIVE MATING IN CHROMODORIS ZEBRA 279

cerned in this discussion are in need of more complete treat-
ment; the evidence required for such treatment I hope to obtain
in the near future. On some points the evidence already se-
cured is, I believe, sufficiently clear.

When two specimens of C. zebra have successfully copulated
they after a time wander apart and usually proceed each to de-
posit an egg mass. This does not invariably occur, since some-
times only one member of a couple will lay eggs, but it is by
far the more usual condition. There is here no evidence of
functional protandric hermaphroditism, as claimed by Orton
(14 b, p. 324) for some small nudibranchs (Galvina); indeed, it
would seem improbable that protandry could coexist with assort-
ive mating, whatever be the relative rates at which the eggs and
sperm are originally matured. Active sperm was found in the
vas deferens of animals which contained well developed eggs,
as well as in some which had just deposited egg masses after con-
jugation, including certain small specimens (5 ems. long), as
well as some of average length, and some very large ones (18
ems. long).

During the copulation of Chromodoris the exchange of sperm
is not simultaneous, but one individual first acts as a male,
then the other; so that if two conjugating specimens be arti-
ficially separated after they have been united for a short time,
it is frequently to be observed that sperm is flowing from the
short penis of one nudibranch, which had been inserted into the
vaginal orifice of the other. When conjugating specimens are
segregated in separate aquaria, it is found that in many in-
stances one nudibranch will deposit eggs, the other not; while -
in still other cases both animals will deposit egg ribbons, al-
though one of these may be very imperfect and contain but a
few fertilized eggs. From such observations I draw the con-
clusion, that as a rule mutual fertilization takes place during
the conjugation of Chromodoris. This conclusion rests further
upon the continued observation of animals which had conju-
gated. in aquaria and had subsequently wandered apart without
being in any way disturbed; in most instances two egg masses
were the result of such matings.

280 W. J. CROZIER

It is true, however, that a number of instances have been
watched in detail where the animals after conjugation separated
in the absence of outside intervention, yet only one of them de-
posited eggs. In these instances the same two nudibranchs,
when placed together in a separate aquarium, were found to pair
together again within the next day or two, the result being that
the other specimen deposited an egg ribbon.

These observations receive additional support from the field
collections. It is not uncommon to find two Chromodoris and
two nearby egg masses in the contents of a single dredge haul.
Moreover, in the one situation (described on a previous page)
where C. zebra has been found in ‘pockets’ under the cover of
stones, I-was able to convince myself at different times that the
number of freshly attached egg ribbons noted in these places
corresponded to the number of animals present.

Hence it is, I believe, safe to employ the idea that, broadly
speaking, reciprocal fertilization occurs in these nudibranchs; if
this is not true at each particular act of conjugation, at least
it can be held that animals of nearly the same size fertilize each
other, and that each animal deposits eggs.

1. Number of larvae produced. The size of the egg mass de-
posited by C. zebra is a function of the size of theanimal. This
concerns the length of the egg ribbon as well as its breadth, the
latter probably depending upon the diameter of the oviduct.
The number of eggs contained in each mass also depends upon
the size of the individual. The length of an egg ribbon and the
number of its contained eggs may, of course, be determined by
other, additional, influences—such, for example, as the number
of eggs already laid during the season. The reception of some
sperm is apparently sufficient to induce the beginning of egg lay-
ing, and there is a certain amount of evidence going to show that
once started the process of deposition continues automatically,
whether the ribbon of jelly contains fertilized eggs or not. Thus,
if an individual be separated from its mate before insemination
has been carried to completion, it will in many eases lay a ribbon
of jelly which is of normal size, but in which only the part first
deposited contains fertilized eggs, these being sometimes fol-

ASSORTIVE MATING IN CHROMODORIS ZEBRA 281

lowed by an unorganized mass of unfertilized ones. Also, if the
nudibranch be disturbed during the act of egg laying, the egg
string is usually broken off and another (disorganized) one
formed subsequently. Very few irregular egg masses are ever
found in nature, however, and it is unlikely that the animals are
disturbed to any extent while engaged in egg-laying. The num-
ber of eggs lost through this agency cannot, consequently, be
very great. On the other hand, the abnormal egg masses, in-
cluding many unfertilized eggs, which are laid by Chromodoris
as the result of insufficient insemination, have an important bear-
ing upon the possible significance of assortive conjugation.

It is well known that most nudibranchs deposit large quanti-
ties of eggs (ef. Eliot, 10). For Chromodoris zebra, Smallwood
(10, p. 140) calculated that 8,000—10,000 eggs were contained in
each spiral. It is said that in Doris tuberculata 50,000 eggs
may be laid in a single mass, and correspondingly large numbers
have been observed for some other genera. I made estimations
of the number of eggs in the ribbons deposited by C. zebra,
and found this number to vary from 2,380 to about 20,000.
The eggs when laid are imbedded in a flat, fairly regular, closely
coiled spiral ribbon of jelly. The estimates were made by care-
fully counting the number of eggs in each of three or five turns
at different positions in the spiral, and then multiplying the
averages of these counts by the number of turns in the whole
ribbon. The data are plotted in figure 21. The egg-masses
involved in this tabulation were laid by freshly collected nudi-
branchs, segregated in the laboratory, so that the origin of the
eggs was definitely known. Egg masses obviously abnormal were
excluded from the counts.

Egg masses collected in natural surroundings were also exam-
ined, and found in some instances to contain a little larger
number of eggs than the largest one incorporated in figure 21.
The range of sizes, and of numbers of eggs, was not, however,
significantly different from that for the egg ribbons laid in the
aquaria. It is therefore legitimate to conclude that the larger
nudibranchs normally deposit many more eggs at a single laying
than do the small ones.

282 W. J. CROZIER

It was to be expected that the number of eggs laid by Chromo-
doris would increase with the size of the animal. This has been
shown to be the case with other molluses,—in Crepidula, for

Sy 10 iS cms.

Fig. 21 Showing the relation between length of individual and number of
eggs deposited in one egg ribbon.

example (Conklin, 12). By analogy with other processes, such
as rhythmic movements (Crozier, ’16 a, p. 311) and the produc-
tion of water currents (e.g., in Ascidia; Hecht, ’16), we should

ASSORTIVE MATING IN CHROMODORIS ZEBRA 283

expect manifestations of energy transformation per unit weight
of individual (within a given species) to decrease with increasing
size of the animal. In Chromodoris the number of eggs depos-
ited at one time is almost directly proportional to the length of
the animal (fig. 21), the slope of the curve even increasing some-
what with the larger lengths. Figure 22 makes it appear that
the production of eggs at one time per unit weight of animal,
as in the other instances of energy transformation cited, falls off
somewhat with increasing weight.

Jo.
gqgs
laid.

12,000

8,000

A000

ie) 20 40 40 5O gms.

Fig. 22 Curve indicating, on the basis of Figs. 14 and 21, the general relation
between weight of animal and number of eggs deposited at one time.

It is possible that the larger animals mate oftener, and lay a
greater number of egg masses, than do the small ones; if this is
indeed the case, their relative importance in propagation is to
that degree enhanced.

From the foregoing discussion it will appear that in any at-
tempt to appraise the significance of assortive conjugation in
Chromodoris the following items must be considered :—

1) Effective mutual fertilization is involved.

2) As the result of insemination, a single egg mass is deposited.

3) If the sperm received be insufficient in amount, a disor-
ganized mass of unfertilized eggs is frequently deposited.

284 W. J. CROZIER

4) The number of eggs contained in a single normal egg
ribbon is proportional to the size of the animal.

These facts lead to the view that assortive mating is distinctly
advantageous to C. zebra. It results in the conservation of eggs
(presumably of sperm also), and, through the coupling of large
individuals, insures that the number of fertilized eggs actually
set free shall be greater than that which would follow from
random pairing. Both of these effects may be regarded as
making more certain the establishment of the greatest possible
number of larvae. |

The adult C. zebra, as I have elsewhere described (Crozier,
16 b; ’17 a), is well provided with the means for securing im-
munity from destructive attack. This opinion is not vitiated,
but is on the contrary emphatically substantiated, by the oc-
currence of injured specimens, as previously noted in this paper.
This nudibranch is in fact one of the most plentiful animals in
Bermuda waters. That the pelagic veliger is equally immune,
seems highly improbable. For the continuance and increase of
the species the larvae must be as numerous as possible, and
toward this end many features in the ecology of Chromodoris
codperate. From April to June the eggs require 15 to 20 days
(in the field) before they escape from the ribbon of jelly and
lead for a time a free swimming existence; this is about the
period recorded by other observers for the development to hatch-
ing in various Doris eggs (Pelseneer, 99, p. 515, where the hatch-
ing time of Eolis eggs is given as 9-17 days; and Eliot, 710).
During this early developmental period, the eggs are pro-
tected by a repugnant jelly. I have never found an egg mass in
nature which had been damaged, and no animals will partake of
them, although they are commonly deposited in exposed situa-
tions, and are of a bright red color (becoming pale orange as
development proceeds). Among the notable features of this
case the following may be mentioned: 1) reproduction through-
out the year; 2) the shoreward migrations of many individuals
at certain periods, and the responses which at such times result
in the concentration of the nudibranchs within the boundaries
of creeks and bays, so that large numbers (sometimes hundreds)

ASSORTIVE MATING IN CHROMODORIS ZEBRA 285

of the animals in proper physiological condition for reproduction
are simultaneously brought near together; 3) the immunity of
the adults, and of their egg ribbons; and 4) the practice of
assortive mating with respect to size.

‘Concerning the last of these points, it has been shown that
assortive coupling probably operates by conserving the genital
products and by insuring that as the result of any particular
copulation the number of eggs fertilized and liberated is, on the
average, greater than that which would be the outcome of ran-
dom pairing. On these grounds I believe it not entirely correct
to say, as Pearl does (07, p. 274), that assortive mating in
somas is probably vastly less important than it would be if it
occurred in the fusion of gametes. It is well known that some
littoral molluses which pass through a pelagic stage (e.g., Ischno-
chiton; Heath, 1899) lay vast numbers of eggs, very few of which
are able to attain the adult state. For the continuance of the
race—and for the multiplication of its members, thus possibly
affording greater opportunities for its evolution—any influence
tending to further the production of numerous young is clearly
of the utmost consequence.

From the standpoint of the theory of adaptation it is, I take
it, highly significant that this ‘adaptive’ result may be under-
stood to follow mechanically from the circumstance that Chromo-
doris of different sizes are sexually mature. This is not exactly a
case which can be grouped with the striking instances of adapta-
tion to which EKigenmann, Cuénot, Loeb (’16, p. 343), and others
have applied the term (or idea) of ‘preadaptation.’ It is rather
one of those eminently ‘purposeful’ practices—yielding no spe-
cific ulterior advantage to the individual, yet probably signifi-
cant in the history of the race—which nevertheless depend auto-
matically upon the structure of the organism (Parker, ’13),* in
itself determined by quite independent and unrelated causes.

* In this connection it may be noted that in the interesting case of some vivip-
arous teleosts there is exhibited a condition which might at first be taken to
favor assortive mating, in the sense that homogamy of a certain type might
thereby be rendered ‘‘valuable to the species.’’ There is, however, no evidence

of assortive pairing, and indeed, with respect to the character in question, it
could not occur. According to Eigenmann (1894, p. 417), in Cymatogaster the

286 W. J. CROZIER

2. Size. It is said that many nudibranchs die soon after de-
positing eggs (Ehot, ’10, p. 18). These animals are often sup-
posed to live for but one year, passing through a single breeding
season. The life history of Aplysia is said also to be of this sort
(Storrow, 715). Available knowledge of the life histories of
marine animals is far too fragmentary to allow of much generali-
zation, but as a rule this particular kind of life cycle seems
typical of species exhibiting a restricted period of breeding in-
itiated by some special kind of behavior (e.g., the case of the
medusa Linerges; Conklin, ’08); in many of these instances the
mature animals are all of about the same size.

With Chromodoris zebra I find it difficult to believe either that
the individuals live but one year, or that they breed but once.
The size frequency distribution is practically identical through-
out the year. It is true that, after depositing eggs, some indi-
viduals quickly succumb when confined in aquaria; it is also
true, however, that specimens of lengths ranging from 4 to 17
ems. will, even in the absence of food, live in the laboratory for
several months after they have first deposited eggs, during which
period they usually lay several additional egg ribbons. The
several moribund specimens which I have been able to discover
in the field were each 14-16 cms. long. Provided the idea were
correct that C. zebra is an annual, and that the size variation
could not wholly be accounted for on the basis of the amounts of
food assimilated in different cases, then it might be necessary to
fall back upon the conception of ‘‘pure lines” possessing differ-
ential genetic factors for size, asin Paramecium. In this event,—
which is, however, highly problematical,—assortive pairing would
have the effect ascribed to it in Paramecium (Jennings, ’11b),
namely that the boundaries of the several ‘pure lines’ would
through this influence tend to be perpetuated and maintained as
number of eggs or embryos contained in a single female increases with the size
of the animal; the larger females are said to mature earlier than the smaller ones.
But conjugation with males (which are smaller than the female) occurs in June
or early July, whereas the eggs are not fertilized, at the earliest, until the ensu-
ing December. This may, I believe, be regarded as one of those instances in

which part at least of the apparatus essential for highly ‘‘purposeful’’ behavior
seems to be available, yet remains unused.

ASSORTIVE MATING IN CHROMODORIS ZEBRA 287

the result of biparental inheritance. Beyond commenting on
the possibility of such an effect, there is no good reason to
speculate upon the matter. |

The coloration of C. zebra is rather variable. Certain fairly
distinct types of coloration may be distinguished. There is no
correlation between color variation and size, and there is no de-
tectable tendency for specimens of the same color type to pair
together.

3. Species crossing. One other species of Chromodoris, C.
roseapicta Verrill, is also found at Bermuda. It is commonly
of about the same size as C. zebra, but it is much less numerous
and its habits are quite different. The two species have never
been found in association. So far as size merely is concerned,
there seems no a priori reason why members of these two species
should not pair. In nature it is probable that they meet rarely
if at all. Even when they are confined in small dishes I have
never succeeded in inducing C. zebra to mate with roseapicta.
The mutual attraction of members of each species probably de-
pends upon reactions to specific substances which the ripe indi-
viduals secrete. Assortive mating can play no part in the pre-
vention of interspecific crossing.

VIII SUMMARY

1. Conjugating pairs of the nudibranch Chromodoris zebra
mating under natural conditions were secured to the number of
148. Copulating individuals ranged from about 4 to 18 ems. in
total length.

There is found a rather high degree of correlation between
total length (and other dimensions) of the two components of a
pair. For the total length, r = 0.608.

2. Mass experiments under laboratory conditions substantiate
this finding. The index of correlation for total length, in 119
pairs, was r = 0.721.

3. Direct observation of mating behavior shows how this cor-
relation is the result of assortive mating. In most cases large in-
dividuals mate successfully with large, small individuals with
small. The homogamic correlations for different dimensions of

288 W. J. CROZIER

pairs in nature also suggest that size as such, and not (?) position
in the reproductive cycle, is the basis of selection.

4. C. zebra is functionally hermaphroditic, and effective re-
ciprocal insemination is practiced.

5. The number of eggs deposited in a single mass varies from
2,000 to 20,000, and is almost. directly proportional to the
length of the animal. The larger animals possibly lay several
more egg masses in a given time than do the small ones.

6. It is consequently of advantage to the species that large
individuals should mate together. In this way the numbers of
eggs fertilized, and presumably of larvae set free, as the result
of any one mating, is on the average greater than that which
would be produced if randon pairing were the rule. Moreover, by
means of assortive conjugation eggs (and sperm?) are conserved.

7. Selective pairing has in this case a result which is there-
fore of a distinctly advantageous or ‘‘ purposeful” character, since
it makes for the multiplication of the species. . This ““adaptive’’
behavior is nevertheless clearly an automatic consequence 1) of
the fact that the eggs are fertilized internally, necessitating the
copulation of adults; and 2), more immediately, of the very
condition that the size of the body is not identical in all sexually
mature individuals.

IX POSTSCRIPT

The preceding account is based on observations made in late
spring (April 5-May 5, 1917). It was thought to be of sufficient
importance, as part of a further study of this matter, to see to
what extent similar findings would result at another season of
the year. Early in December, 1917, at the beginning of a
period of shoreward flocking (Crozier, ’17 ¢), naturally occurring
pairs were very infrequent in Fairyland Creek, the area dealt
with in the collections of the previous spring; not enough ma-
terial of a homogeneous order could be secured for the purpose
in view before the work had to be interrupted, although in the
isolated pairs secured it was evident that assortive conjugation
was the rule. Recourse was therefore had to a mating experi-
ment, carried out with animals secured at this time.

ASSORTIVE MATING IN CHROMODORIS ZEBRA 289

Between fcrty and fifty random individuals of various sizes
were placed in a large jar of running sea water. Two days later
nineteen mating pairs were simultaneously secured in this popu-
lation, and measured. The method of measurement was as
given in the early part of this paper. The accompanying table
(table 6) and figure (fig. 23) present a summary of the evidence
thus obtained. The number of pairs (19) is small, yet affords
adequate ground for the contention that at this season (De-
cember) the intensity of homogamy with respect to size is as
great as that found in April.

It seemed that toward the end of the first week in June, 1917,
the abundance of Chromodoris in shallow situations began no-
tably to decrease; this was not due to my “‘overfishing”’ in the
area most intensively studied, since it was equally true in other,
unmolested, areas normally frequented by this nudibranch. In
December they began again to increase in number in shallow
regions near the shore. If it were to be held that these months
mark approximately the termination of one ‘breeding season’
and the initiation of the next succeeding ‘reproductive period,’
we should be faced by the difficulty that individuals of such
diverse sizes are about equally engaged in propagation at the
beginning and at the conclusion of a ‘reproductive season.’
This condition is, however, consistent with, and adds something
to, a conclusion elsewhere (Crozier, ’17b, p. 381) favored, namely
that the more or less periodic shoreward flocking of C. zebra
does not signify the incidence of a special propagative period.

In December, under laboratory conditions, two individuals of
average size (10 ems.) will conjugate, or attempt to, at intervals
of four or five days. One pair laid four egg masses (two each)
in twelve days, and other couples deposited eggs in six-day to
seven-day periods; however, after the third egg laying, which com-
prised a relatively small number of eggs, no further masses were
obtained.’ Egg laying, at this season, occurs two and a half to
three days after conjugation; in June, within one to two days.
The number of eggs contained in a single mass is, for animals of

6 In most cases after a variable number of weeks, even without food, eggs
are again deposited.

290 W. J. CROZIER

Suit Gh ey tO A fe NS

Fig. 23 Showing the relation between the length of C. zebra and the average
size of its mates in conjugation, for 19 pairs obtained in an experiment under
laboratory conditions. The class unit is 1 em., the measurements being of
total length. Length classes, abscissae; average length of mates, ordinates.

TABLE 6

Single-entry correlation table (Jennings), showing the size relations in 19 pairs of
C. zebra obtained in one mating experiment (see text)
Nore: The unusually high correlation observed in this table is an accidental
result of the small number of pairs (19) concerned.

3 4 | 5 | 6 7 8 9 10 11 | 12 13 |
3 1 | a 2
4 1 1
5 Mh 3
6 eal els 8
7
8 2 2
9 2 2
10
ul
12 1 1
1 1 | 3 | re 2| 2 1 38

about the same size, somewhat less in December than in May-
June; thus, in May, with a sea temperature of 26°, 11 animals
between 9 and 12 ems. length laid on the average 7,870 eggs in a

ASSORTIVE MATING IN CHROMODORIS ZEBRA 291

single mass, while in December, with a sea temperature of 18°,
9 masses laid by individuals 9 to 12 ems. long contained on the
average 5,290 eggs (indicating a “temperature coefficient (?)”’
of about 1.6). The time required for the deposition of a mass
containing 4,000-6,000 eggs varies from 3 to 5} hours.”

IX LITERATURE CITED’

Conxutn, E.G. 1908 The habits and early development of Linerges mercurius.
Carnegie Instn. Wash., Publn. 103, p. 153-170.
1912 Cell size and body size. Jour. Morph., vol. 23, p. 159-188.

Crozier, W. J. 1916a The rhythmic pulsation of the cloaca of holothurians.
Jour. Exp. Zodl., vol. 20, p. 297-356.
1916 b On the immunity coloration of some nudibranchs. Proc. Nat.
Acad. Sci., vol. 2, p. 672-675.
1917 a The nature of the conical bodies on the mantle of certain nudi-
branchs. Nautilus, vol. 30, p. 103-106.
1917 b On the shoreward migrations of tropical nudibranchs. Amer.
Nat., vol. 51, p. 377-382. (The two figures illustrating this article
have by some means undergone an interchange of legends.)
1917 c Evidence of assortive mating in a nudibranch. Proc. Nat.
Acad. Sci., vol. 3, p. 519-522.

Dreyer, T. F. 1912 A contribution to our knowledge of the reproductive or-
gans of the nudibranchiata. Rept. 9th Ann. Meet. South African
Assn. Adv. Sci. (1911), p. 340-348.

EIGENMANN, C. H. 1894 On the viviparous fishes of the Pacific coast of North
America. Bull. U.S. Fish Comm., vol. 12 (1892), p. 381-478.

Exiot,C. 1908 On the genus Cumanotus. Jour. Mar. Biol. Assn. (Plymouth),
vol. 8, p. 313-314.
1910 The British nudibranchiate mollusca, Part VIII (Supplemen-
tary). Ray Soc., 1917 pp., 8 pls.

Harris, J.A. 1912a Assortivematinginman. Pop. Sci. Mo., May, p. 476-492.
1912 b Pearl and Jennings on assortive conjugation in the Protozoa.
[Review.] Science, N. S., vol. 35, p. 740, 741.

Heatu, H. 1899 The development of Ischnochiton. Zool. Jahrb., Abt. Ontog.,
vol. 12, p. 1-90.

Hecut, S. 1916 The water current produced by Ascidia atra Lesueur. Jour.
Exp. Zodl., vol. 20, p. 429434.

Jennines, H. S. 19114 Computing correlation in cases where symmetrical
tables are commonly used. Amer. Nat., vol. 45, p. 123-128.
1911 b Assortive mating, variability and inheritance of size, in the
conjugation of Paramecium. Jour. Exp. Zoél., vol. 11, p. 1-134.

’ Proof of this paper has been read by Dr. E. L. Mark. It has not been possi-
ble to submit it to the author for his revision.—Eprror.

*I am indebted to Prof. E. L. Mark for the use of separates of a number of
the articles consulted, and to Prof. H. S. Jennings for a copy of his paper, 1911 a.

292 W. J. CROZIER

Jennincs, H. §., anp Lasutey, K. 8. 1913 a Biparental inheritance and the
question of sexuality in Paramecium. ibid., vol. 14, p. 393-466.

1913 b Biparental inheritance of size in Paramecium. ibid., vol. 15,
p. 193-199.

Logs, J. 1916 The organism as a whole. New York, X + 379 pp.

MBEISENHEIMER, J. 1907 Biologie, Morphologie und Physiologie des Begat-
tungsvorgangs und der Eiablage von Helix pomatia. Zool. Jahrb.,
Abt. Biol., Bd. 25, p. 461-502, 3 Taf.

Orton, J. H. 1914a On the breeding habits of Echinus miliaris, with a note
on the feeding habits of Patella vulgata. Jour. Mar. Biol. Assn.
(Plymouth), vol. 10, p. 254-257.
1914b Preliminary account of a contribution to an evaluation of the
sea. ibid., p. 312-326.

Parker, G. H. 1913 Adaptation in animal reactions. Amer. Nat., vol. 47,
p. 83-89.

Peart, R. 1907 A biometrical study of conjugation in Paramecium. Bio-
metrika, vol. 5, p. 213-297.

Pearson, K., anp Ler, Atice 1903 On the laws of inheritance in man. I,
Inheritance of physical characters. ibid., vol. 2, p. 372-377.
PELSENEER, P. 1894 Hermaphroditism in mullusea. Quart. Jour. Micr. Sci.,

vol. 37, p. 19-46.
1899 La condensation embryogénique chez un nudibranche. Trav.
Stat. Zool. Wimereux, Tom. 7 (Miscel. biol. dediées au Prof. A. Giard),
p. 513-520, 1 pl.

SHEARER, C., DE Morcan, W., AND Fucus, H. M. 1914 On the experimental
hybridization of echinoids. Phil. Trans. Roy. Soc., B, vol. 204, p. 255-
363.

SmaLLwoop, W. M. 1903 Notes on the natural history of some of the nudi-
branchs. Bull. Syracuse Univ., Ser. 4, No. 1, p. 14-17.

1910 Notes on the hydroids and nudibranchs of Bermuda. Proc.
Zool. Soe. Lond., 1910 (1), p. 187-145.

SmaALLwoop, W. M., anp Ciark, ExizaBpeta G. 1912 Chromodoris zebra Heil-
prin: a distinct species. Jour. Morph., vol. 238, p. 625-636.

Storrow, B. 1915 Faunistic Notes. Rept. Dove Mar. Lab., p. 59.

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Resumido por el autor, Gary N. Calkins.

Uroleptus mobilis Engelm.
I. Historia de los nucleos durante la divisién y conjugacién.

Uroleptus mobilis, un ciliado hipétrico muy raro, se divide y
conjuga facilmente cuando se cultiva en una infusién de heno y
harina. El macrontcleo esta formado por ocho ntcleos separados
que se fusionan en uno solo antes de la divisién; este ultimo se di-
vide tres veces sin mitosis antes que la célula se divida, y una vez
después de la division de esta. El nimero de micronticleos es
variable (cuatro a seis). Con excepcién de dos de ellos todos los
demas son absorbidos antes de la divisi6n celular; los dos que per-
sisten se dividen por mitosis dos o tres veces y un numero varia-
ble de los asi producidos desaparece por absorcién. Durante la
conjugacion los macrontcleos no se fusionan pero sufren una de-
generacion granular y finalmente son absorbidos por el citoplasma.
Los micronucleos experimentan dos divisiones madurativas,
caracterizada la primera de ellas por una profase en forma de
paracaidas, de la cual se derivan un huso tipico y ocho cromoso-
mas. En la segunda divisién madurativa el numero de cromoso-
mas se reduce a cuatro. Los prontcleos funcionales se forman por
una tercera division de uno de los nticleos producidos en la segunda
division madurativa, si bien pueden produeirse hasta ocho pro-
nticleos de los cuales seis son absorbidos. El] pronticleo emigrante
se caracteriza por la presencia de una esfera atractiva. La fusién
de los pronticleos produce un anfinticleo con ocho cromosomas,
que se divide inmediatamente en dos grandes micronticleos, uno
de los cuales se divide de nuevo para formar un gran nticleo vesi-
cular destinado a desarrollarse en los ocho nuevos macronucleos
y un producto mas pequefio, homogéneo, que degenera y desapa-
rece. El otro gran micronticleo se divide para formar los dos
micronticleos funcionales del nuevo organismo. La reorganizacién
de la célula, después de tener lugar la conjugacién, requiere un
periodo de cinco dias.

Translation by Dr. José F. Nonidez,
Columbia University.

AUTHOR’S ABSTRACT OF THIS PAPER ISSUED
BY THE BIBLIOGRAPHIC SERVICE, OCTOBER 28

UROLEPTUS MOBILIS, ENGELM.

I. HISTORY OF THE NUCLEI DURING DIVISION AND CONJUGATION

GARY N. CALKINS
Columbia University, New York City

NINETY-FIVE TEXT FIGURES

Uroleptus mobilis is a rare hypotrichous ciliate first described
by-Engelmann (’62) and apparently not recognized since then,
for I find no further description of it in any of the more important
contributions to taxonomy of the Infusoria.

In October, 1917, the organism appeared in considerable num-
bers in an old hay infusion that had been standing for several
months in the zoological laboratory of Columbia University.
It was successfully cultivated, and abundant material for study
of all the important phases of the life history was secured.

Engelmann’s description of Uroleptus mobilis is as follows:

Body form constant; plastic; circular in section; about 12 times longer
than broad; tapering gradually to a broadly pointed posterior end.
Lateral cilia equally long throughout. With six elongate nuclei. This
species, which came from the Boticzbach near Prag, is distinguished
from the other species of Uroleptus recently described by Stein, by the
constant presence of six nuclei arranged one behind the other. It
stands close to Stein’s Uroleptus rattulus but, unlike this species, it
possesses no sharply pointed posterior end, and the lateral cilia are
equally long on the tail and body. The adoral row of cilia (adoral zone)
occupies about one-ninth of the total body length, with an undulating
membrane fastened on its inner side; a peristome field appears to be
entirely absent, or at least extremely narrow. Whether, as in other
Uroleptus species, two longitudinal rows of fine ventral cilia are present,
I could not make out since the animal is very lively and inclined to
creep about, snake-like, between plant remains. Our species, more-
over, which appeared in great numbers, measured on the average, 0.30
mm. Al] specimens were about of the same size. Division was not
observed. (Loe. cit., p. 386.)

The essential characteristics here are the elongate cylindrical
body with circular section, the frontal cirri, the equally long
293

OP
\»

294 GARY N. CALKINS

lateral cilia, the multiple macronuclei, and the tapering posterior
end with a broad point. Less important characteristics are the
size, the exact number of macronuclei, and the position of the
contractile vacuole. (Engelmann does not mention the econ-
tractile vacuole in his description, but in the two figures which he
gives it is represented as a simple spherical vessel lying in the
posterior part of the anterior third of the body.)

The New York variety differs in respect to these minor char-
acteristics as indicated in the following description:

New York variety of Uroleptus mobilis. Body form constant,
plastic, circular in section (figs. 1, 3); about 10.5 times longer
than broad (based on averages of measurements of length and
of breadth at center of body), and tapering gradually to a broadly
pointed posterior end. The posterior end is permanently curved
towards the ventral side. (Engelmann does not mention this
curvature, but represents it in his figure.) The lateral cilia are
long and distinct and sparsely distributed along straight rows
running from end to end and around the posterior end of the
body. Owing to density of the protoplasm, the ventral cilia
cannot be made out on the living organism, but in cross-sections
it is evident that three rows of ventral cilia are present, and
that they are finer and shorter than the lateral cilia (fig. 3).
The frontal cirri, three in number, are placed in an oblique row
at the extreme anterior end of the ventral surface. The termi-
nal cilia of the ventral rows are conspicuous at the anterior end
and give the impression of five or six frontal cirri.

The peristome occupies about one-sixth of the entire length
of the body and this region is slightly flattened. The peristome
is very narrow with an obliquely curved row of powerful pyra-
midal membranelles on the left side, but almost filling the peri-
stomial area. The right margin is sharply cut with a narrow un-
dulating membrane inserted between it and the adoral zone
(fig, 2).

The macronuclei are eight in number, and, in the vegetative
stages, each possesses a typical nuclear cleft. The micronuclei
are variable in number from two to six. They are minute and
homogeneous.

THE NUCLEI OF UROLEPTUS MOBILIS 295

Fig. 1 Uroleptus mobilis Engelmann. Normal vegetative individual with
characteristic curvature of posteror end; eight macronuclei each with a nuclear
cleft; four micronuclei and central contractile vacuole. > 800.

Fig. 2 Peristomial details. Adoral zone, undulating membrane and three
frontal cirri. 1500.

Fig. 3 Cross-section through anterior region near the mouth of a conjugating
individual. Two lateral and three ventral cilia are shown in characteristic posi-
tion, indicating the five lines of cilia. The asymmetical peristome is indicated
by the single membranelle. The section also shows the anterior macronucleus
and one of the maturation micronuclei. > 1500.

296 ; GARY N. CALKINS

The contractile vacuole is single, spherical, and lies in the
center of the body near the dorsal surface. .

The protoplasm is dense and alveolar with few granules in the
endoplasm, but with many refringent granules forming a heavy
granular coating in the cortex. These granules may possibly
be mitochondria, although the mitochondria methods have not
been used to determine this point. They are spherical in the
ordinary vegetative stages, but are drawn out into rods which
divide transversely during division stages.

The length of vegetative forms varies from 140 to 165 uw, and
the diameter at the center of the body, from 11 to 17 u.

The cysts are spherical and the cyst wall smooth with an
average diameter of 32.7 u.

While Engelmann’s species averages 300 u in length, the present
form averages only 158 » in the normal vegetative condition.
The dividing and conjugating stages are much shorter, but
have a larger diameter. These measurements are shown in the
accor panying table:

| |
| AVERAGE AVERAGE
LENGTH DIAMETER | SASS
> . es s
Wecetative stares... 5. cer tae eee ae 158.6 u 15 yu 146 u=168 pw
WiviSiOn*StAagess.cah stoke oes See 99.0 u 30 pu 93 u-115 w
Conjugation stavess..60 g- oe ee | 105.2% 15 p 85 »-120 p

A second variation from Engelmann’s species is the number of
macronuclei. While in the earlier description six macronuclei is
given as the invariable number, in the New York variety the
number is eight, six being found in only one individual out of
many hundreds examined; nine, ten, eleven, and even twelve
macronuclei are found more frequently than six.

__A third variation is the position of the contractile vacuole
which lies in the center of the body and not in the anterior third.

These variations are not important enough to warrant a new
species of Uroleptus; they are consistent and permanent, how-
ever, and justify the belief that the present organism is a new
and a well-marked variety of Uroleptus mobilis. -

THE NUCLEI OF UROLEPTUS MOBILIS 297

I. TECHNIQUE

A. Culture methods

The first attempts to cultivate Uroleptus on hay infusion
failed. The organisms were gradually accustomed to the stand-
ard hay infusion diet by placing individuals on successive days
in the medium in which they were found, diluted each day with
increasing proportions of fresh standard infusion. In all of these
attempts, after the organisms were finally accustomed to fresh
twenty-four-hour hay infusion, their vitality was soon lost and
death resulted. Fresh hay infusion was then discarded, and
boiled flour water, twenty-four hours old, was substituted. To
make this, 150 mg. of white flour is boiled for ten minutes in 100
ec. of spring water and allowed to stand exposed to the air for
twenty-four hours.

With this medium it was found that the organisms would live
and would divide about once in three days. Later, a more sat-
isfactory medium was obtained by mixing two parts of this
flour water, two parts of spring water, and one part of old hay
infusion. This improved medium was used for nearly three
months, the individuals dividing approximately once a day.
Finally, a still better medium was obtained by boiling 100 mg.
of chopped hay with 130 mg. of flour in 100 ec. of spring water
for ten minutes, and diluting this, when twenty-four hours old,
with an equal part of fresh spring water. With this medium
made fresh every day, the organisms divide from one to three
times per day, giving abundant material for the study of various
vital activities.

As in previous culture work, a single individual is transferred
to about 200 mg. of the culture medium contained in a flat, 40-
mm. square, ground glass, hollowed dish, 8 mm. in thickness.
On the following day the number of individuals is counted and
a record is made of the number of divisions that have taken place.
A single individual from these is then isolated and transferred to
fresh culture medium made the day before. This procedure is
followed daily, the records furnishing data for comparison of the
states of vitality of the race that is not allowed to conjugate.

298 GARY N. CALKINS

After an individual is transferred to fresh medium, the re-
maining individuals are placed in a Syracuse dish containing
about 10 ec. of the fresh culture medium: Here they multiply
in large numbers, constituting the ‘stock’ material, the source
of dividing and conjugating forms.

B. Total preparations

In handling the material for fixing and staining, the following
methods have been used. <A dividing individual, or a conju-
gating pair, is drawn up in a capillary pipette and deposited on
a clean slide with a minimum of water. The object is then coy-
ered with a couple of drops of killing fluid. After three to five
minutes, the object is drawn into a second capillary pipette
(used only for the killing agent) and transferred to a watch-glass
containing 95 per cent alcohol. A clean, thin cover-glass is then
prepared by smearing one surface with egg albumen. The
specimen is then drawn up in a third capillary pipette from the
alcohol and spurted on the smeared side of the cover-glass. The
accompanying alcohol coagulates the albumen which holds the
object during subsequent treatment. Care must be taken to
prevent drying of the specimen when the alcohol evaporates;
this is accomplished by flooding the smeared surface with the
stain to be used, and setting the cover-glass in a moist chamber.
To dehydrate, after staining, the cover-glass is placed, with for-
ceps, into salt cellars or Syracuse dishes containing successive
grades of alcohol. It is well to use at least two dishes of abso-
lute aleohol to prepare the object for xylol. After clearmg in
xylol the unsmeared surface of the cover-glass is carefully wiped
with a dry cloth, and the object is finally mounted in balsam.

For study of the nuclear structures, I have found that, for
killing, a saturated aqueous solution of bichloride of mercury,
with a trace of acetic acid, gives excellent results when followed
by the iron-haematoxylin stain, and this method was mainly
used in the present investigation. All stages were confirmed
on material fixed in Flemming’s fluid, Bouin’s fluid, and Schau-
dinn’s fluid.

THE NUCLEI OF UROLEPTUS MOBILIS 299

C. Sections

The only sure method of getting good sections of conjugating
or dividing forms is to embed and section each individual, or
pair, separately, after staining with eosin in absolute alcohol.
This, however, is a laborious method, and for purposes of con-
firming or supplementing the observations on total preparations,
fixing and embedding en masse is adequate. For this purpose I
use the following method. Only rich cultures of conjugating or
dividing forms should be used. These should be collected in a
pipette with as little water as possible and spurted into a test-
tube filled with the killing agent. At the same time a quantity
of thick zoogloea from an old hay infusion is fixed with the organ-
isms to be sectioned.

The test-tube is thoroughly shaken in order to entangle the
organisms in the zoogloea. After these have settled, the fluid is
decanted and the process repeated with the different fluids needed
for washing and dehydrating. The material is stained with
eosin in absolute alcohol, and the zoogloea, now a compact,
rounded mass, is finally embedded and sectioned. This method
has been employed for many kinds of minute organisms.

II. THE NUCLEI IN DIVISION

In the living material early stages of division are easily recog-
nized by the reduced length and the increased diameter of ‘the
body. If a good culture, which has not been recently fed, is
transferred to fresh culture medium, a rich harvest of dividing
forms may be obtained in a few hours, and all stages of division
will be found amongst them.

A. The macronucler

The eight resting macronuclei of Uroleptus mobilis, all have
the same structure (fig. 1). They are densely granular, with a
delicate membrane about them, and with the nuclear cleft (Kern-
spalt) characteristic of the hypotrichous ciliates. As to the sig-
nificance of this nuclear cleft, I shall have something to say in a

300 GARY N. CALKINS :
subsequent paper. It is not present in young cells after divi-
sion, nor during conjugation, and disappears at an early stage
of the division activities.

The two portions of each macronucleus, separated by the
nuclear cleft, are. apparently different in chromatin make-up,

Fig. 4 Early stage of division. The macronuclei have lost, or are losing, the
nuclear cleft and the distal chromatin; the five micronuclei are in mitosis; the
new adoral zone forms anteriorly to the center of the body. X 800.

Fig. 5 Division stage with fragmented macronucleus preparatory to fusion.
x 800.

Fig. 6 Fusion of the macronuclei. Four micronuclei in mitosis. > 800.

one portion being less dense than the other. At an early stage
in division the chromatin granules of the less dense portion, con-
centrate into a single granule in each nucleus (fig. 4). Later,
these granules are cast off, and are absorbed in the cytoplasm
(fig. 5). This differentiation may be accompanied by further

THE NUCLEI OF UROLEPTUS MOBILIS 301

fragmentation of the remaining nuclear parts, resulting in from
twelve to fourteen smaller masses (fig. 5). In all cases, however,
after elimination of the chromatin granules, the nuclear fragments
fuse to form a single elongate and irregularly wound nuclear mass
(figs. 6 to 9). The granular contents condense, with shortening

Figs. 7,8,and9 Stages in concentration of the macronucleus. Threeandtwo
mitotic nuclei. _ 800.

and loss of the irregularities, until a single, densely granular and
massive, nucleus results (fig. 10). It is now ready to divide; it
assumes an ellipsoidal form; its chromatin granules become
arranged in lines running from end to end (figs. 11 and 12),
and it constricts in the center, forming a typical dumb-bell
figure before there is any external sign of cytoplasmic division
(figs. 18 and 14).

GARY N. CALKINS

302
The daughter nuclei next divide to form four nuclei, and these
in turn form eight, four of which belong to the anterior half,
four to the posterior. The lines of densely staining chromatin
granules are retained throughout all of these division stages, a
characteristic dumb-bell nucleus being formed at each stage
(figs. 15 to 18). During the division from four into eight the
cell constriction deepens in the division zone, and the cell divides,
the two daughter cells having four nuclei each (figs. 18 and 19).

_
_

“NLL L i '"

yea

Figs. 10, 11 and 12 In figure 10 the nuclei are fully prepared for division;
figures 11 and 12 show elongation of the macronucleus and increase of micronuclei
to four and six, one degenerating micronucleus in figure 12. X 800.
The four nuclei finally divide once again, after division of the
cell and after separation, and the eight nuclei, characteristic of

the normal vegetative phase, are formed (figs. 20 and 21). At
each nuclear division the connecting strands are severed so that
the daughter nuclei are not connected by any linin or chromatin

material.
The formation and significance of the nuclear cleft after divi-
sion is a complicated problem in itself which will be discussed in

THE NUCLEI OF UROLEPTUS MOBILIS 303

a subsequent publication in connection with its appearance after
encystment, after conjugation, and during regeneration.

In connection with the history of the macronucleus as given
above, I find it difficult to interpret Engelmann’s statement that
the number of these nuclei, in his species, is constantly six.
Such a condition might arise if two of the nuclei produced by the
second division, should divide again; or it might arise if two of

Figs. 13, 14, and 15 Division of the macronucleus and beginning cell division.
x 800.

the eight nuclei formed by the third division should degenerate.
A third possibility seems more probable, viz., that Engelmann
was mistaken.

B. The micronuclei

The history of the micronuclei during cell division is much
less clear than that of the macronuclei. This is due mainly to
the fact that the number is not constant; some cells have six,

304 GARY N. CALKINS

some five, some four, others three, and still others only two.
The minimum number, apparently, is two; this is the number
present during reconstruction of the nuclear apparatus after
conjugation and the number that undergo the second matura-
tion division. That some micronuclei disappear by absorption

16, yr
~
y

SS

—-

=

UWL

Figs. 16, 17 and 18 Second division of macronuclei, eight and twelve micro-
nuclei. > 800.

during vegetative stages is evident from the not infrequent pres-
ence of faintly staining ghosts of micronuclei. That some divide
and others fail to divide is evident in some cases. That reduc-
tion in number is due to fusion or coalescence is not supported by
evidence of any kind. I should interpret the variation in num-
ber, therefore, as due to absorption and irregular division, but

not to fusion.

THE NUCLEI OF UROLEPTUS MOBILIS 305

In the vegetative stages the micronuclei are very minute
(1.6 u in diameter) and homogeneous in structure. They are
variously distributed in the cell, a typical distribution being
shown in figure 1. They lie, as a rule, close to the macronuclei,
but are never embedded in the latter. They undergo mitosis

Figs. 19, 20, and 21. Cell division completed; four macronuclei present (fig.
19) which divide to form eight after daughter cells separate. The six micronu-
clei are reduced to four. 800.

which must be a slow process, for mitotic figures persist from
the beginning of segregation of the macronuclei until the ellip-
soidal nucleus is formed and ready to divide. Actual division
of all such mitotic nuclei does not occur, for there is no increase
in number at this period.

On the contrary, the number actually decreases until, when
the macronucleus is ready to divide, there are only two micro-
nuclei, and these are in mitosis (figs. 4 to 10). This decrease is

306 GARY N. CALKINS

due, probably, to absorption, for pale micronuclei are frequently
found in addition to the densely staining mitotic nuclei. At any
rate, when the macronucleus is ready for division, as in the later
coalescence phases, there are only two micronuclei. Their divi-
sion is completed prior to division of the macronucleus, the four
daughter nuclei always forming a characteristic linear group on the
side of the macronucleus (fig. 11). These daughter nuclei pass
directly from the telophase of the first division to the metaphase
of the second, as indicated by the absence of resting nuclei dur-
ing these stages. - The second division may result in eight nuclei
(figs. 14 and 15), or one of the four may disappear while the
remaining three divide, thus giving rise to six micronuclei (fig.
12). If eight are formed, two of them disappear and six are
left; finally these six divide for the third time, forming twelve
micronuclei, and the cell, now ready for division, contains two
sets of six, one set passing to each daughter individual (figs.
16 to 18). In some young daughter cells there are only four
micronuclei (figs. 17, 19, and 21); in others there are six (figs.
16 and 18), and in others there are only five. These variations
are probably due to the earlier or later disappearance of the mi-
eronuclei. The normal number would be eight had none dis-
appeared, this number agreeing with the number of macronuclei.
In the majority of hypotrichous ciliates the typical arrangement
is one micronucleus for each macronucleus, but here the charac-
teristic pairing is lost. The disappearance may be due to ab-
sorption of the nuclei in the cytoplasm, abundant evidence for
which is given by the frequent presence of faintly staining nuclei.
While the number is thus variable, the great majority of the
individuals studied have only four micronuclei (figs. 1 and 21).
The formation of the mitotic spindles is the same throughout.
The nucleus first swells in size, losing its characteristic homoge-
neous structure, and becomes vesicular. The chromatin is, at
first, in the form of eight (?) granular masses which may become
four double smooth, and homogeneous rods stretching from pole
to pole, or combinations of double and single rods may occur
Whether these rods are divided transversely or longitudinally
cannot be determined owing to their minute size and densely

THE NUCLEI OF UROLEPTUS MOBILIS 307

packed condition. Whichever method occurs, they are con-
tinued as rods in the daughter nuclei where they undergo sub-
sequent divisions until the definite nuclei are formed (figs. 10
to 17). The fully formed spindle measures 3 u in length (figs.

22 and 23).

Fig. 22 Micronucleus in metaphase of vegetative mitosis. Seven chromo-
somes could be counted, probably eight are present. 3200.

Fig. 23 Telophase of vegetative mitosis. X 3200.

Figs. 24, 25 and 26 Conjugating specimens with parachute stage of first
maturation nuclei. One to three degenerating micronuclei. Macronuclei finely
granular. > 800.

THE JOURNAL OF EXPERIMENTAL ZOOLOGY, VOL. 27, No. 3

308 GARY N. CALKINS

IJ. THE NUCLEI IN CONJUGATION

Conjugation between closely related individuals of Uroleptus
mobilis is a periodic phenomenon occurring at certain stages in
the life eyele. Up to the present it has never taken place in the
isolation culture dishes, but in the ‘stock’ dishes epidemics at
certain periods are inevitable. The conditions under which such
epidemics occur will be considered in a subsequent paper on the
life history of the organism.

_ Epidemics of conjugation are invariably preceded by a char-
acteristic massing or agglomeration of individuals. These
masses vary in size from one-eighth to one-quarter of an inch in
diameter and include thousands of individuals so closely packed
together that is it impossible to see through the mass. It is a
favorable opportunity for securing material for fixation in bulk
of the preconjugation and early conjugation stages.

If such a mass of agglomerated individuals is transferred to
another Syracuse dish containing fresh medium, an epidemic of
conjugation will invariably follow, and material in different
stages may be obtained during the following three days, as the
time of conjugation varies from twenty-eight to thirty-six hours.

The organisms unite and fuse at the anterior ends. The ex-
treme tips of the peristomes are the first to unite, and fantastic
shapes of the pair, due to independent movements of the two indi-
viduals, are characteristic of this early stage. Later, the organ-
isms settle into place and fusion of the peristomial grooves fol-
lows, until from two-thirds to three-quarters of the peristomial
areas are securely united. The mouth regions are never fused.
With this union the possibility of independent movements is
limited and a characteristic V-form of the pair results. This
and its variations are shown in figures 24 to 26. The various
stages of maturation and interchange of nuclei are synchronous
in the individuals of a pair.

A. The macronuclei during conjugation

The eight macronuclei retain their individuality throughout
the entire process of conjugation and finally disappear on the
fourth or fifth day after separation. While eight is the typical

THE NUCLEI OF UROLEPTUS MOBILIS - 309

number, a considerable percentage of individuals have from ten
to twelve or even fourteen macronuclei during the early stages.
I have not seen one with less than eight.

The first change undergone by these nuclei, as in preparation —
for division, is the loss of the nuclear cleft, and it is in this phase
that the increase in number occurs, if at all. The finer structure
at this time is finely granular and homogeneous (figs. 24 to 27).

As conjugation progresses a few scattered, larger granules
appear in each nucleus. These increase in number and in size
until, at the period of nuclear interchange, the granules are from
1 uw to 2 w in diameter (figs. 68 and 69). The membranes are
apparently lost, and what were homogeneous finely granular nu-
clei are now mere masses of large irregular chromatin bodies.
The fixing fluids evidently have something to do with the ap-
parent disappearance of the membranes, for they are apparent
in all stages of conjugants fixed with Flemming, while the gran-
ules are always smaller than in material fixed with sublimate
acetic. The nuclei are in this condition of granular disintegra-
tion at the time of separation of the conjugating individuals, and
remain so for an hour or more after separation (figs. 76 and 80).
This stage, however, is soon replaced by a highly characteristic
phase. The masses of large granules again fuse, forming eight
homogeneous, non-granular, and smooth spherical nuclei with an
intense staining capacity. These slowly fade away in the cyto-
plasm, first one, then another disappearing, so that ex-conjugants
with 8, 7, 6, 5, 4, 3, 2, and 1 degenerating macronuclei are found
(figs. 86 to 90). Occasionally a mass of fine granules marks the
spot where a nucleus has disappeared, but usually it vanishes
without leaving a trace. The first evidence of degeneration is
loss of staining capacity; six or seven of the nuclei may stain in-
tensely while the others appear pale and ghost-like. Or four or
five will stain deeply and there will be no trace of the others.
Finally, at 96 hours after separation the old macronuclei are
entirely absorbed in the cytoplasm and the new macronucleus
begins to divide and to form the eight characteristic nuclei of
the vegetative phases.

310 GARY N. CALKINS

The new macronucleus is formed as a product of the second
division of one nucleus resulting from the first division of the
fertilization nucleus. This always occurs prior to separation of
the two conjugants. The division starts in an equipolar mitotie
nucleus, but in the telophase there is a marked difference in the
two poles (figs. 88 to 85). One nucleus, which is ultimately
absorbed, becomes a small, dense, homogeneous body of the typical -
micronucleus form 2 u in diameter; the other nucleus, 5 uw in diam-
eter, becomes vesicular with chromatin granules distributed about
the periphery and with a linin network filling the interior (fig. 85).
Granules of chromatin appear on the reticulum at a later state
and the peripheral granules disappear. These internal granules
have only a weak staining capacity, so that the young macro-
nucleus at this period appears as a pale spherical body in striking
contrast to the intensely stained chromatin of the old macro-
nuclei and the new micronucleus. This is the condition of the
new macronucleus at the period of separation of the conjugants,
and its further history will be followed in connection with the
changes which the ex-conjugants undergo (section IV).

B. History of the micronucler

The variations in the number of micronuclei in vegetative
stages make it difficult to determine the normal number that
are active during conjugation. Careful study of more than 500
pairs convinces me that the number is inconstant, even during
the important maturation stages. In order to determine if there
is a constant difference in nuclei in the two individuals of a pair
and in the early stages of conjugation, I made a careful count

Fig. 27 Conjugating specimens each with two-parachute nuclei and three
degenerating micronuclei. X 800.

Figs. 28to44 Stages in the transformation of the parachute nucleus and for-
mation of the first maturation spindle. X 3200. Figures 28to34show the centro-
somes and connecting fibers, the homogeneous nucleus and its metamorphosis
into, first, a chromatin network, and second, free granules of chromatin. Figures
35 to 39 represent the first type of maturation spindle with 24+ chromosomes;
Figures 38 to 39 telophase of same. Figure 40, second type of first maturation
spindle with eight chromosomes; Figures 41 and 42, 43 and 44, anaphase and
telophase of same.

311

NUCLEI OF UROLEPTUS MOBILIS

THE

St GARY N. CALKINS

of the micronuclei in thirty-one pairs. This comparison was
suggested by the possibility of sexual differences in the two indi-
viduals forming a pair. The results are tabulated in the accom-
panying table:

| !
INDIVIDUALS INDIVIDUALS INDIVIDUALS

PeATRS © yee ee eee SPATS a | Ee eee PAS ————
A B A B A B
1 6 4 11 5 4 21 5 4 16 pairs, 5 and 4
2 4 4 12 4 4 22 6 5 7 pairs, 4 and 4
3 4 4 1S 3a ee) 4 23 6 5 3 pairs, 6 and 5
4 5 4 14 5 4 24 5 4 2 pairs, 5 and 5
5 5 a 15 5 4 25 5 5 2 pairs, 6 and 4
6|6]| 5 1D (fie. en Re a Boa ee: ap ae 1 pair, 4 and 3
a 5 4. 17 5 4 27 5 5
8 5 + 18 + 4 28 5 4
9 5 + 19 + 4 29 6 4
10 4 4 20 5 4 30 5 a
3l 5 4

It is evident that no constant relation exists between the con-
jugating individuals and the number of micronuclei present at
the beginning of conjugation. The predominating number is
four and the predominating combination is five and four. In
all cases one or more is degenerating. In later stages the differ-
ences are greater owing to the numbers of degenerating micro-
nuclei resulting from the maturation mitoses.

Not all of the nuclei present at the beginning of conjugation
take part in the maturation divisions. The largest number of
first maturation spindles seen in any individual is four (fig. 47).
and in this case all of the micronuclei participated; but in its
mate, only three of five nuclei formed spindles. The fate of
these unused nuclei is only conjectural, but they probably de-
g-nerate. Nor is there any morphological peculiarity to distin-
guish those nuclei which will form spindles from those which will
not. It appears to be a matter of position, for the spindles are
usually found in the anterior and central parts of the organism
while the inactive nuclei are usually in the posterior ends.

The maturation divisions follow the usual sequence in ciliates,
viz., first maturation, second maturation, and third, or pronuclei

THE NUCLEI OF UROLEPTUS MOBILIS 313

forming, division. Three to four micronuclei take part in the
first; two (very rarely three) nuclei take part in the second; and
three or four take part in the third division. Thus of the eight
possible products of the first division five or six degenerate. Of
the four to six products of the second, two to five degenerate;
and of the six or eight possible products of the third division, all
but one pair degenerate, and this pair forms the wandering and
the stationary pronuclei.

a. The first maturation mitosis. The formation of the first
maturation spindle starts with the swelling of the homogeneous
nucleus and the projection of one pole of the nuclear membrane.
This projection contains one or more granules of intensely stain-
ing material which apparently corresponds with the intranuclear
division center of a typical flagellate nucleus of the centronucleus
type. As in the latter, a deeply staining fiber connects the pro-
jected granule with the nuclear mass (figs. 28 to 34). The pro-
jection forms a large vesicular region at one pole of the nucleus
and is traversed by fibers running from the pole to the chromatin
mass and surrounded by the nuclear membrane. At the outset
of nuclear change the micronucleus is ellipsoidal and measures
from 23 u to 34 u in its longest diameter. The projection forms
on the side, not at the end, and when fully developed the nuclei
measure from 5 uw to 7 uw (figs. 28 to 34). The granular mass in
the projection forms one pole of the mitotic figure, while the fibers
traversing the projection form the spindle fibers. One entire
half of the mitotic figure is thus formed before there is any trace
of the chromosomes or of the other pole of the spindle.

The ‘chromosomes’ are formed from the disintegrated chroma-
tin mass of the micronucleus. At first a thick net-work of chroma-
tin surrounds the denser chromatin mass (fig. 28). Later, dis-
tinct granules of chromatin appear at nodes on the net-work.
Both network and granules are formed at the expense of the
chromatin mass, which during this metamorphosis continually
grows smaller (figs. 29 to 31). The entire micronuclear complex
at this stage has a characteristic and striking appearance which
suggests a parachute when examined with relatively low magni-
fication (figs. 24, 25, and 26), and I shall refer to this phase here-

314 GARY N. CALKINS

after as the parachute nucleus. It is analogous in its period of
formation, and in its subsequent stages, to the crescent nucleus
of Paramecium (caudatum, aurelia, and bursaria).

The ‘chromosomes’ are the chromatin granules formed by seg-
regation of chromatin of the denser net-work derived from the
mass of the micronucleus. A small granule, alone, remains as a
reminiscence of the original dense micronucleus, and this gran-
ule forms thé second pole of the mitotic figure (fig. 34).

The second pole of the mitotic spindle ultimately formed starts
as a projection, again, from the, now granular, chromatin ag-
gregate. A second vesicular region, traversed by fibers and sur-
rounded by the nuclear membrane, is thus formed. The two
poles of the spindle, therefore, are not developed simultaneously,
although formed in the same way by migration of a granular
constituent of the original chromatin mass. In the center, mid-
way between the granule-holding poles, lies the group of chro-
matin granules which, by further segregation of the chromatin
substance from the net-work, now lie as independent ‘chromo-
somes’ in and among the spindle fibers (figs. 35 and 36). The
finished spindles measure from 8 u to 10 uw in length and from 23
to 4 » in diameter at the widest part.

The granules of chromatin forming the nuclear oli of the
metaphase stage undoubtedly correspond to the chromosomes
of metazoon nuclei. But, of these there are two distinct types
in these first maturation spindles (figs. 47 and 48). In one type,
owing to their very minute size and to their usually crowded ar-
rangement, it is impossible to count them with any degree of
accuracy. <A few favorable specimens (figs. 35, 36, and 37) show
conclusively, however, that they are more numerous than twenty,
and my best counts average twenty-four. In this type of mitosis
the granules apparently pass undivided to the daughter nuclei
(figs. 38 and 39).

In the second type of the first maturation spindle the chromo-
somes are larger, more compact, and form a definite nuclear plate
(fig. 40 to 44). Here they are distinctly eight in number and
eight daughter chromosomes pass to each pole of the spindle.
An early anaphase stage is shown in figure 40, from which it might

THE NUCLEI OF UROLEPTUS MOBILIS ah

be inferred that division of the chromosomes is transverse. The
evidence for this, however, is by no means convincing and the
~ plane of chromosome division, for the present at least, must remain
an open question.

In later anaphase stages, these daughter chromosomes become
drawn out into loose and irregular lines of chromatin granules
(figs. 41 and 42) and in the telophase stage a definite chromatin
reticulum is present (figs. 43 and 44). After division, this chro-
matin reticulum resolves itself into homogeneous granules of the
vesicular nucleus characteristic of the prophase of the second
maturation division.

The absence of uniformity in these first maturation spindles
is peculiar and difficult to interpret. If both types were found
in the same individual we might conclude that the first and more
indefinite type is characteristic of nuclei destined to take no
further part in the maturation processes. Unfortunately, each
conjugant contains only one type and, since almost all ex-con-
jugants continue to live after conjugation (of sixty isolated ex-con-
jugants all but seven continued to live and to divide), one type
appears to be as potent as the other.

Not only is there a difference in the first maturation spindles,
but there is also a difference in the prophases or parachute stages.
I have been unable, however, to correlate these different and rela-
tively rare types of prophase with either of the two types of
maturation spindles. In the second type of prophase, the gran-
ule forming the first pole of the spindle is accompanied by ap-
proximately one-half of the total chromatin content of the mi-
cronucleus (figs. 49 to 53). I have not found spindles that can
be interpreted as arising from these aberrant parachutes, and,
from the number of micronuclei in individuals containing them,
I regard them as nuclei undergoing degeneration.

b. The second maturation division and reduction of chromosomes.
There are from four to eight products of the first maturation
division, most of which undergo granular disintegration and dis-
appear. ‘Two or sometimes three of them take part in the second
maturation division, but I have not seen any individual with
more than three, while the great majority of pairs in this stage

316 GARY N. CALKINS

of maturation have only two nuclei which complete the division
process in each individual.

After the telophase of the first maturation division, the nuclei
do not reform the dense homogeneous nuclei characteristic of
the early stages of conjugation. They become more compact, but
remain vesicular with a strong staining capacity. The chroma-

Figs. 45 and 46 Two pairs with different types of first maturation nuclei.
xX 800.

tin at first is in a rather dense reticulum (figs. 54, a). It then
collects into eight chromatin aggregates with irregular shapes,
distributed throughout the nucleus. These aggregates are trans-
formed into elongate rods or chromosomes (figs. 54, b, ¢, d).

The full history of this second maturation spindle is extremely
difficult to work out. During its division, the number of chrom-
osomes is reduced from eight to four, as proved by the four

wii

THE NUCLEI OF UROLEPTUS MOBILIS Sy.

chromosomes which appear in the ensuing third division, but,
notwithstanding an abundance of material obtained in this stage
of conjugation, I am unable to decide how the chromosomes actu-
ally divide. The minute size of the spindles and the close
packing of the chromosomes are conditions which render direct
observation uncertain and encourage any tendency which the

Fig. 47 First maturation spindles, first type, four in one individual, three in
the other. 800.

observer may have to infer an interpretation along the lines of
preconceived ideas of what the process should be. I will try
to avoid the latter pitfall by describing some actual spindles as
they appear under the highest lens system at my command.
The most conspicuous and the most frequent stage is illustrated
in figure 55, a. In this stage the chromosomes are densely
stained and appear as rods occupying the two central quarters

318 GARY N. CALKINS

of the spindle. The number of rods is four but each rod is
double. How these double chromosomes are formed from the
eight single ones I am unable to decide. Another, and a less fre-
quent stage, is illustrated in figure 55, c. Here there are eight

Fig. 48 First maturation spindles, second type, with definite nuclear plates.

x 800.

Fig. 49 Pair in prophase stage of first maturation division, with degenerating
parachute nuclei. X 800.

Figs. 50 to 53. Division of granular mass of chromatin in degeneration of first
maturation nuclei into two parts, and vesicular swelling of the nuclear membrane.
x 3200.

distinct chromosomes arranged in groups of four. If the former
stage is a metaphase, is the latter an anaphase or a prophase
stage subsequent to that shown in figure 54, d? In no case found
do the chromosomes lie with their long axes at right angles to the

THE NUCLEI OF UROLEPTUS MOBILIS 319

long axis of the spindle, and in no case is there any evidence of
V’s or Y’s. In some eases the rods appear to run unbroken
from pole to pole of the spindle (figs. 55, 6). In other cases there
may be more than four distinct chromosomes, sometimes five or
six or seven, in the nuclear plate. In still other cases there are
four definite chromosomes at the poles of the anaphase stage
(fig. 55, d).

Until I can be convinced of the exact method of chromosome
division by further study of this phase, I will not offer an inter-
pretation of this puzzling problem. Let it suffice here to state

Figs. 54 and 55 Prophase, metaphase, anaphase, and telophase stages of
second maturation mitosis where four double chromosomes are reduced to four
single ones. Bouin fixation, iron-haematoxylin stain. X .38200.

that the number of chromosomes is reduced from eight to four
by this second division. The four chromosomes of the anaphase
stage (fig. 55, d) lose their identity in the chromatin mass of the
late telophase (fig. 55, e). The final division of the nuclei is
rather abrupt, and there is no evidence of long connecting’strands
between the daughter products.

c. The third division. The products of the second division are
small granular micronuclei, usually four in number, which are
ready for the third division with no extensive intervening resting
stage. In some individuals all four of them undergo this third
division (fig. 57, left); in some only three, while in others only

320 GARY N. CALKINS

two divide (figs. 56 and 60). In all individuals the functional
pronuclei are only two in number and both come from the same
one of the four original nuclei. The others disappear by ab-
sorption, although they may persist until some time after the
union of pronuclei.

A a

= at RE

/ > 59 \ }I

56 ‘pt: “> x 4Ny

®

\
\
\

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a\
3

Fig. 56 Pair, each with two nuclei in the third maturation division. > 800.

Fig. 57 Telophase of third division; four pairs of nuclei in one, three pairs in
the other individual. Macronuclei fragmented. X 800.

Figs. 58 and 59 Nuclei in metaphase and anaphase of third maturation divi-
sion. XX 3200.

The early spindles of the third division are smaller (2 u wide
and 6 u long), but are similar in type to those of the second mat-
uration division (figs. 58 and 59). There are, again, four bars
of chromatin, or four chromosomes, and four are present in the
daughter nuclei after division (fig. 59), which is apparently
transverse.

THE NUCLEI OF UROLEPTUS MOBILIS 321

The third division figures are easily distinguished from those
of the first and second divisions by the greatly elongated con-
necting body between the daughter nuclei. In some cases these
connecting fibers attain a length of 30 u, and different stages of
division are frequently found in the same individual or in the
pair. The- nuclear membrane plays the chief réle in this con-

Fig. 60 Late telophase of third division and formation of pronuclei (on right).
* 800.

Fig. 61 Unusual phase in which eight daughter nuclei of the third division and
two undivided nuclei are present without pronuclei formation. X 800.

necting fiber, the chromatin apparently forming no part of it
(figs. 62 and 63). As the nuclei separate the walls come together
until they appear like a single connecting line (fig. 60). The
chromatin now separates into granules which become distributed
throughout the nuclear vesicle; the membrane closes and the
pronucleus is formed.

322 GARY N. CALKINS

This history is not followed by the nuclei which degenerate.
With them no vesicle is formed, but the daughter nuclei, if they
do not degenerate first, form homogeneous massive nuclei which
gradually lose their staining capacity and ultimately disappear
by absorption.

Figs. 62 and 63° Intermediate telophase stages of the third division. > 3200.

Fig. 64 Stage of interchange. The two migrating pronuclei with their attrac-
tion spheres,’ are passing one another in the anterior fused region. One undi-
vided third division nucleus is present in each cell. X 800.

d. The pronucleit and the interchange. 'There is no difference
in type, although there may be a slight difference in size without
significance, perceptible in the two pronuclei formed by this
third division. The stationary pronucleus is nearly always in

the central region of the cell where it is left after the third divi-
sion. The migrating pronucleus, formed at the other pole of the
dividing nucleus, is left some 30 u nearer the anterior end. While

THE NUCLEI OF UROLEPTUS MOBILIS 323

there is no internal structural characteristic to distinguish it from
the stationary pronucleus, a peculiar external or cytoplasmic
structure now appears which is decidedly characteristic and
which is absent from the stationary nucleus. This structure
consists of a clearly defined homogeneous mass of very fine

Ss
Poca
ur

y

Ne
"4

ak
ay

Ye &

‘
*

/
4

Figs. 65, 66,and67 Three pairs with migrating pronuclei in different positions.
The attraction sphere precedes the pronucleus. 800.

granules which replace the ordinary alveolar make-up of the
cytoplasm. It resembles an attraction sphere and behaves as
such in the later history (figs. 64 to 66 and 71 to 75).

The wandering pronucleus in each cell, preceded by this homo-
geneous granular mass, moves towards the anterior end where cell
fusion has taken place (figs. 64, 65, 66, 71 to 75). The two pass

THE JOURNAL OF EXPERIMENTAL Z°2OLOGY, VOL. 27, NO. 3

324. GARY N. CALKINS

one another in the posterior part of the connecting bridge of pro-
toplasm (fig. 64) and then each continues its migration in the
foreign cytoplasm (fig. 66) down to the stationary micronucleus

Figs. 68 and 69 Two pairs with pronuclei close together. The ‘attraction
spheres’ have disappeared. 800.

Fig. 70 Two pronuclei about to fuse. The difference in size is without sig-
nificance. XX 3200.

(figs. 68 and 69). Here the cytoplasmic guide can no longer
be made out. The two spherical pronuclei lie close to one an-
other, then elongate to form two ellipsoidal nuclei (figs. 70, 76,
77 and 78), and finally fuse.

THE NUCLEI OF UROLEPTUS MOBILIS 325

e. The amphinucleus. The two pronuclei unite in a region of
the body slightly anterior to the geometrical center. There is

Figs. 71 and 72 Enlargements of the wandering pronuclei and ‘attraction
spheres.’ > 1500.

some evidence that the stationary nucleus advances to meet the
migrating nucleus, since the former is formed either in the center,
or posterior to the center, of the cell (figs. 64, 68, 69 and 76).

326 GARY N. CALKINS

Each is spherical and vesicular (figs. 70 and 77) at first, but both
elongate and become spindle-formed before fusion occurs. This
double spindle becomes the first cleavage spindle in which eight
large, homogeneous chromosomes are present. In figure 81 the
chromosomes of one side have divided before those of the other
side. Its division results in two nuclei of similar size and char-
acter; one becomes the first micronucleus, the other (after a

\

Fig. 73 Relative positions of wandering and stationary pronuclei and of ‘at-
traction spheres’ about to pass one another. X 1500.

later division), the first macronucleus of the ex-conjugant (figs.
82 to 85). They are both small, and their chromatin is condensed
into the homogeneous massive type of micronuclei. One is an-
terior, the other central in position. The former divides to form
two micronuclei which condense to form the vegetative micro-
nuclei, the other forms a spindle (fig. 82), which gives rise to
two products of dissimilar fate, one becomes swollen and vesicular

THE NUCLEI OF UROLEPTUS MOBILIS S21

with its chromatin collected in granules arranged about the
periphery (figs. 83 to 85), the other degenerates. The vesicular
phase of the former is preliminary to the formation of large,

Figs. 74 and 75 Wandering pronuclei passing and after passing one another.
x 1500.

poorly staining granules which fill the vesicular nucleus (figs.
86 and 87). As these granules are formed, the peripheral chro-

matin bodies disappear, their material evidently changing into

328 GARY N. CALKINS

the larger, pale granules. With this new nuclear complex, viz.,
one ghost-like new macronucleus (‘placenta’), one degenerating
micronucleus, and two functional micronuclei, the conjugating
individuals separate (figs. 79, 80, and 86).

Fig. 76 Pair with pronuclei in each individual about to fuse. 800.
Fig. 77 Initial stage of fusion of the pronuclei. > 1500.
Fig. 7

8 Elongation to spindle form of the fusing pronuclei. 1500.

IV.. THE EX-CONJUGANT

Separation of the conjugating individuals begins at the pos-
terior part of the fused regions, progress in separation being
marked by the increasing length of the free peristomes (figs. 79
and 80). Finally, a connection remains only at the frontal mar-
gins, and the two cells pull apart. For a few seconds, only, they
remain quiet, but within a few minutes their activities are fully
restored.

THE NUCLEI OF UROLEPTUS MOBILIS 329

Unlike most of the hypotrichous ciliates in culture, the great
majority of Uroleptus individuals continue to live after conjuga-
tion. Of thirty pairs isolated, no less than fifty-three ex-conju-
gants continued to live and to divide. When we consider Bait-

Figs. 79 and 80 Early stages in the development of the new macronuclei.

sell’s (12) experience with Stylonychia and my own experience
with the heterotrich Blepharisma, in which 100 per cent of the
ex-conjugants died, this result is remarkable. Even Paramecium
has a much larger post-conjugation mortality. There is no a
priori reason why mortality in one genus should be higher than

330 GARY N. CALKINS

Fig. 81 First division metaphase of the amphinucleus; the chromosomes on
one side are partly divided. X 3200.

Fig. 82 Anaphase of the second division after fertilization with two sets of
eight chromosomes, and resting nucleus, the other product of the first division.
x 3200.

Figs. 83, 84, and 85 Late telophage stages and final separation of the macro-
nucleus-forming second division after fertilization. > 3200.

Figs. 86 to 90 Stages in the development of the new macronucleus, concen-
tration of the fragments of the old macronuclei and their ultimate disappearance,
and stages in the concentration of the two new micronuclei. Figure 86 one hour
old, the others from 48 hours to 96 hours old. X 800.

THE NUCLEI OF UROLEPTUS MOBILIS 331

that in another, and certainly no theoretical interpretation of
the purpose of conjugation, admits a mortality of 100 per cent.
The explanation of such mortality must be sought in the environ-
mental conditions, and particularly in the culture medium used.
The continued life of Uroleptus ex-conjugants indicates a normal
condition of environment and a culture medium that satisfies all
conditions of vitality.

The living ex-conjugants can be distinguished at a glance from
individuals in any other phase of vitality. They are shorterthan
ordinary vegetative forms and larger in diameter. From dividing
forms, or individuals immediately after division, they are distin-
guished by the clear, non-refractile, vesicular macronucleus
which appears, vacuole-like, for two or three days after
conjugation.

The young ex-conjugant contains, in addition to the new mac-
ronucleus and two new micronuclei, the granular remains of the
eight original macronuclei (fig. 86, one hour old). In some in-
dividuals, the typical linear arrangement of the original macro-
nuclei is retained (fig. 86). In others there is some confusion in
arrangement with a tendency to mass near the center (fig. 87).
In all cases such massing eventually occurs preliminary to final
absorption and always in the posterior half of the cell. During
the first forty-eight hours after separation, each of the eight
macronuclei which had developed increasingly large granules
during the conjugation stages again forms a compact, spherical,
homogeneous mass of chromatin which takes an intense nuclear
stain (fig. 87). These slowly disappear by absorption in the
protoplasm. First one, then another, loses its staining capacity
and fades away leaving no trace. In some cases, however, they
again undergo granular fragmentation before being absorbed in
the cytoplasm (figs. 88 and 89). Ultimately, four to five days
after separation, not a trace remains of the old macronuclei.

In the meantime a new macronucleus is developing. The pale
ghost-like character of this cell organ is retained for at least
three days, but it becomes much larger and ellipsoidal in form
during this period (figs. 89 to 91). The granules within, and
solidly filling it, now assume a definite spherical form and begin

332 GARY N. CALKINS

to stain more intensely. Each elongates to form a chromatin rod,
and these arrange themselves in lines running from end to end of
the nucleus. This ultimately divides by simple constriction with
dumb-bell formation; the two daughter nuclei divide again, and
these once again, until eight new macronuclei replace those that.
were absorbed (figs. 91 to 95).

Figs. 91to095 Stages in the division of macronuclei and micronuclei leading to
the formation of the typical nuclear complex of the vegetative forms, 96 to 120
hours after separation of the conjugants. X S800.

The micronuclei also divide during this period until from six
to eight are formed. Some of these degenerate, leaving the
typical number four to six, in the young individual (figs. 93 to
95). :
The formation of the nuclear clefts in the macronuclei of the
young individuals involves some processes which strongly sug-
gest the entrance of supernumerary micronuclei. This will be
left for further investigation, however, and will be dealt with in a
separate paper on the formation and significance of the nuclear
cleft.

THE NUCLEI OF UROLEPTUS MOBILIS jo

V. COMPARISONS
A. Multiple nuclei in ciliates

In many ciliates a multiple number of nuclei, both macro-
nuclei and micronuclei, is the rule. Balbiani (’60, ’61), in his
earlier work at least, held that the number of micronuclei is always
the same as the number of macronuclei, or in beaded forms, as
many as there are segments of the macronucleus. Maupas
(83), Gruber (’87), Biitschli (88), and many later observers,
disproved this view and demonstrated that, in some cases, the
_numbers are the same (as in the majority of Oxytrichidae): in
other cases, e.g., Trachelius ovum, Condylostoma patens, Stentor,
ete., the micronuclei outnumber the macronuclei; and in still
other cases the macronuclei outnumber the micronuclei (e.g.,
Uronychia transfuga, Gonostomum pediculiforme, Holosticha
lacazei, Loxophyllum meleagris, Spirostomum ambiguum, etc.).
The relative numbers of the two types of nuclei, furthermore,
may differ in different individuals of the same species. This is
the case in Uroleptus mobilis, where also the number of micro-
nuclei is inferior to.the number of macronuclei.

a. Fusion of macronuclei during division. It is quite probable
that the multinucleate condition of macronuclei is only an ad-
vanced stage in physiological adaptation to the needs of the cell.
At one extreme, the more generalized condition, we find the
typical uninucleate cells of the majority of the infusoria. At the
other extreme are forms like Dileptus gigas, in which the endo-
plasm is filled with minute chromatin bodies each of which be-
haves like a granular nucleus. Between these two extremes lie
the ciliates with band-form, branched, beaded, or multiple
macronuclei. The single nucleus of Spathidium spathula is
drawn out as a rod; in Euplotes, Aspidisca, Didinium, Vorticella,
ete., the rod becomes horseshoe shape; in many species of Suc-
toria it becomes much branched; in Stentor, Spirostomum ambi-
guum, Bursaria, and others the rod becomes more or less con-
stricted at intervals to form the characteristic beaded nuclei. All
of these conditions are modifications of the uninucleate type.

334 GARY N. CALKINS

The transition to the multinucleate type is by no means abrupt.
In the genus Stentor, for example, Johnson (’93) shows that in
S. polymorpha the connecting strands (commissures) are relatively
thick and conspicuous, while in 8. pyriformis and in 8. igneus
no trace of such commissures could befound. Inthese two species,
therefore, the multinucleate condition results from a fragmen-
tation of the beaded rod form. A similar fragmentation of a
homogeneous rod results in the formation of ten to fourteen
nuclei of Uronychia transfuga, but in this case a very delicate
connecting membrane can be made out. An extreme case,
again, is the multiple fragmentation observed by Lebedew (’08)
in Trachelocerca.

Balbiani, Biitschli (88), Maupas (’83), and others have main-
tained that, with few exceptions, in all multinucleate forms, the
separate nuclei, or fragments, are held together by similar com-
missures and are in effect, therefore, single nuclei. This conclu-
sion was based in part upon the obvious connecting strands in
many forms and in part upon the fusion, prior to division, of all
the parts, or fragments, to form a single homogeneous dividing
nucleus. The fact of fusion was regarded as proof of the fact of
invisible commissures.

Against this view, which is unquestionably too general, are
the facts associated with those forms in which the multinucleate
condition is a result, not of fragmentation, but of consecutive
nuclear division. In most of the binucleate Oxytrichidae the two
nuclei arise by equal division, the division taking place just prior
to cell division. Here there is, indeed, no fusion, and the effect is
that of a single nucleus which has divided precociously for the
following cell division.

Gruber (’87) showed that a similar fusion of entirely discon-
nected small nuclei of Holosticha scutellum occurs during prep-
aration for division, and that these nuclei arise from the repeated
independent divisions of a single nucleus during and immediately
subsequent to cell division. Exactly the same phenomenon oc-
curs in Uroleptus mobilis; the disconnected nuclei, both after
division and after conjugation, arise by repeated consecutive
divisions of a single nucleus.

THE NUCLEI OF UROLEPTUS MOBILIS 335

It is obvious, in these cases, that the multinucleate phase is
an adaptation from the uninucleate condition, and the conclu-
sion may be drawn that the independent nuclei, by fusion, return
to a more primitive and more generalized uninucleate condition
prior to division.

In some forms, finally, the independent nuclei do not fuse
again prior to division and each divides independently, the prog-
eny passing to the daughter cell in which they happen to be
(Trachelocerea, Dileptus gigas, Ichthyophthirius, Opalina).

b. Absence of fusion of micronucler during division. The num-
ber of micronuclei in Uroleptus mobilis varies between two and
six. At no time during vegetative life, division, or conjugation is
the number reduced to one, except for the very brief period during
conjugation, when the functional pronuclei fuse, and before the
first division of the synkaryon. Even at this time, however,
there are still from three to five degenerating pronuclei in the
cytoplasm of each individual. During the five days required
for reorganization of the cell after conjugation, there are two
micronuclei, and they begin to divide in the same period as the
new macronucleus. As a result of their division, the fully reor-
ganized cell has six to seven micronuclei. During the early
phases of division, viz., during the fusion of the macronuclei,
these micronuclei are found in full mitosis (figs. 4 to 14). I have
never seen aS Many As Six in mitosis at one time, but have fre-
quently found individuals with five and four at this period of
macronuclear concentration. When the macronucleus is ready
to divide I have found individuals with two and with four micro-
nuclei in mitosis (figs. 10 and 11), but never with more. If two
is the initial number as indicated by ex-conjugants, then it is
reasonable to infer that the number becomes reduced to two
before division of the macronucleus. If this is the case, how
has the reduction taken place? On this point I have no certain
evidence. :

Balbiani (’60, 61) at first believed that multiple micronuclei
are bound together in a common pouch with fine connectives like
those between multiple macronuclei. No later observer has
confirmed the hypothesis, and Balbiani himself retracted this

336 GARY N. CALKINS

view in 1881. Gruber (’87) observed a single micronucleus in the
dividing stage of Stichotricha scutellum and followed it through
two or three divisions, after which he was unable to detect any
trace Of micronuclei. He inferred that they become progres-
sively reduced in size until they could not be identified among
the many macronuclei. He also inferred that the conspicuous
micronucleus at the time of division is a product of the fusion of
all the minute nuclei distributed throughout the cell, just as the
single macronucleus is the fusion product of all the macronuclei.
At best this was only an hypothesis. Other cases of fusion have
been suspected either during so-called autogamous fertilization
(Ichthyophthirius, Neresheimer, 08; Buschkiel, ’11) or during
encystment (Stylonychia, Fermor, ’12). In no ease, except at
fertilization, has the fusion of micronuclei been. established.

Nor in Uroleptus mobilis have I any evidence that the reduc-
tion of micronuclei at division is due to fusion. The two micro-
nuclei at this period are no larger than the five nuclei at an
earlier stage (figs. 10 and 11). All that I can say is that some
micronuclei, after attaining a condition of full mitosis, simply
disappear.

B. Conjugation

There are approximately 1800 species of ciliated protozoa
known to science. In 98 per cent of these the conjugation proe-
esses are entirely unknown, while the facts regarding conjuga-
tion in the remainder are in many cases only fragmentary and
the full history is largely conjectural. In a few instances the
story is fairly complete and, verified by different observers, has
come to be regarded as the characteristic history of conjugation
in all ciliates. How far this is true can only be determined by
independent study of conjugation in different species and a study
uninfluenced by preconceived notions of what the process should
be. The widely diverging accounts of the details in forms like
Paramecium (Hertwig, Maupas, Hamburger, Calkins and Cull),
Anoplophrya (Collin), Trachelocerea (Lebedew), Ichthyophthirius
(Nerescheimer, Buschkiel) show that no uniformity characterizes
the phenomena and that, until many more data are obtained,
generalizations have little value.

THE NUCLEI OF UROLEPTUS MOBILIS Bo7

Very few complete studies have been made of conjugation in
hypotrichs. Apart from, and since, the classical, epoch-making
work of Maupas, who included the full history of conjugation in
the hypotrich Onychodromus grandis and a somewhat less com-
plete history of Stylonychia pustulata, of Euplotes patella, and
E. charon, there has been only one work on hypotrichs, that of
Prowazek on Stylonychia pustulata in 1899.

As is well known, Maupas (’88) described eight (A to H) phases
common to all types in the process of conjugation. Phase A, the
initial phase, is characterized by the growth and early changes
of the micronucleus; the second phase, B, by the first divis on
of the micronucleus. In modern terms this phase is called the
first maturation division or first meiotic division. The third
phase, C, is the period of the second division, now called the
second maturation or second meiotic division. The fourth phase,
D, is the period of the third division resulting in the formation
of the pronuclei. The fifth phase, E, is the period of interchange
and fusion of the pronuclei; the sixth, F, and seventh, G, are
the stages of the first and second divisions, respectively, of the
fertilization nucleus or amphinucleus. The last phase, H, finally
is the period between the second division of the amphinucleus
and the first fission of the cell after conjugation. The keen
powers of observation and generalization which Maupas pos-
sessed are well shown by this recognition of the successive stages
in conjugation, particularly in connection with the distinction
between the first and second divisions of the micronucleus, and
at a time when the significance of these divisions in maturation
phenomena was quite unknown. Subsequent investigations have
shown that, with minor variations, these successive phases hold
good for the great majority of cases.

a. The preparatory stage (phase A) of Uroleptus mobilis. The
difficulties in working out the initial stages of conjugation in
Uroleptus are increased because of the multinucleate condition
of the conjugating organisms. The number of micronuclei in
vegetative stages varies from four to six and the same variable
numbers appear in the conjugating individuals. Analogous con-
ditions are found in Paramecium aurelia (Hertwig, Maupas),

338 ' GARY N. CALKINS

Onychodromus grandis (Maupas), Stylonychia pustulata (Mau-
pas, Prowazek, ’99), each having two micronuclei; in Didinium
nasutum, with two or three (Prandtl, ’06), in Blepharisma undu-
lans, with from four to five micronuclei (Calkins, 712) and in
Bursaria truncatella with from sixteen to eighteen micronuclei
(Prowazek, ’99).

Maupas (’88) described an anomalous, additional, or prelim-
inary division in the case of Euplotes patella and in E. charon,
where it is found in both conjugants. In other cases where such
a division occurs (in the peritrichida) it is limited to the mi-
crogamete (Vorticella monilata, V. nebulifera (Maupas, ’88),
Carchesium polypinum (Maupas, ’88; Popoff, ’08), Ophrydium
versatile (Kaltenbach, °15), and Opercularia coarctata (En-
riques, ’07).

The prophases of the first maturation spindle in ciliates are fre-
quently highly characteristic. In Loxophyllum meleagris (Mau-
pas, ’88), Spirostomum teres (Maupas, ’88), Euplotes patella
(Maupas, ’88), Colpidium colpoda (Hoyer, 799), and in Ble-
pharisma undulans (Calkins, 712) however, there appears to be
no typical prophase stages beyond the swelling of the nucleus,
fragmentation of the homogeneous chromatin of the micronu-
cleus and formation of the chromosomes. Hoyer (’99) describes
a typical spireme in the case of Colpidium colpoda, but this is
very exceptional in ciliates and needs confirmation.

In Paramecium (aurelia, bursaria, and caudatum) a very typi-
cal prophase stage occurs in the form of a crescent, derived from
the homogeneous micronucleus which first draws out in the form
of a long cylinder which later forms the characteristic crescent.
A modification of the crescent occurs in Chilodon uncinatus
(Maupas, ’88; Enriques, ’08), where the chromatin is drawn out
in the form of an elongate comma-shaped band. This is still
further modified in Cryptochilum-nigricans (Maupas, ’88), Vorti-
cella monilata and V. nebulifera (Maupas, ’88), and in Oper-
cularia coarctata (Enriques, ’07), where a long chromatin rod
extends, in some cases, the entire length of the cell.

Still another type of prophase, and a type to which Uroleptus
belongs, is found in Onychodromus grandis (Maupas, ’88), Bur-
saria truncatella (Prowazek, 99), Didinium nasutum (Prandtl,

THE NUCLEI OF UROLEPTUS MOBILIS 339

06), and Anoplophrya branchiarum (Collin, ’09). Here the nu-
clear membrane first swells up to form a nucleus two or three
times the diameter of the original micronucleus, while the com-
pact mass of chromatin, placed either centrally or peripherally,
fragments into numerous chromatin granules. In Uroleptus mo-
bilis there is an intranuclear centrosome which divides, one-half
passing to the periphery of the nucleus at the pole opposite the
chromatin mass, while the other half remains in this mass. The
two halves remain connected by a deeply staining strand (prim-
ary centrodesmus) throughout the prophase period, but none
of these structures can be demonstrated in the fully formed
spindle (figs. 28 to 34). The distal centrosome is the focal point
of spindle fibers which spread out from it to the fragmenting
chromatin mass and forms one pole of the mitotic figure. It was
a similar stage in Anoplophrya that suggested the term ‘cande-
labra’ to Collin. I have called it the parachute nucleus.

So far as I am aware, this is the first demonstration of the
centronucleus type of nucleus in ciliates.

The majority of investigators show signs of embarrassment
when it comes to the description of the formation of the second
pole, or the full spindle, of the first maturation nucleus. In the
transformation of the crescent type, Maupas, Hertwig, and Ham-
burger all agree that the spindle is formed by the shortening of
the long axis of the crescent and that the tips of the crescent
form the poles of the spindle. Calkins and Cull, however, find
that the division center or kinoplasmic mass which forms the
poles of the spindle, migrates from its terminal position in the
crescent to the center of the convex side. This new position
becomes the first pole of the spindle.

In the candelabra or parachute type, the second pole is formed
by the outgrowth from the chromatin mass, of a second pole
similar to the first, the chromatin granules thus being left in the
nuclear plate position or center of the spindle figure. In Uroleptus
mobilis this second pole is formed by the migration of the proxi-
mal centrosome from the chromatin mass while the connecting
strand between the two centrosomes becomes thinner and im-
possible to distinguish, in the later stages, from the spindle fibers.

THE JOURNAL OF EXPERIMENTAL ZOOLOGY, VOL. 27, No. 3

340 GARY N. CALKINS

b. First maturation spindle and the chromosome problem. In
the conjugation of ciliates with multiple micronuclei the usual
result of the prophase activities is the formation of one first
maturation spindle for each of the micronuclei present. In
Onychodromus grandis each of the two micronuclei forms a
spindle (Maupas,’88). The same is true of Stylonychia pustulata
(Maupas, ’88; Prowazek, ’99), and Paramecium aurelia (Hert-
wig, ’89). In Didinium nasutum (Prandtl, ’06), and in Blephar-
isma. undulans (Calkins, 12), if more than two micronuclei are
present, only two of them form spindles; in Bursaria truncatella, —
on the other hand, all of the sixteen to eighteen micronuclei are
active at this stage (Prowazek, ’99). In Uroleptus mobilis
there may be two, three, or four of these primary spindles (figs.
45 to 47).

The chief interest of these first maturation nuclei lies in the
so-called chromosomes, especially in the methods of their for-
mation and division. Unfortunately, we have but little exact
knowledge on these points owing to the frequent large numbers
and small size of the chromatin elements.

Maupas (’88) made no attempt to enumerate the chromosomes;
nor did he describe their formation beyond the brief account of
the fragmentation of the homogeneous chromatin masses of the
micronuclei. Hertwig (’89) believed that there were eight or
nine chromosomes in Paramecium aurelia, basing his view not on
the chromosomes, but on the number of fibers which he could
distinguish in the connecting strand between the two daughter
nuclei. Later observers find that the number, in all species of
Paramecium, is very much greater than this (more than 100
(Hamburger, Calkins, and Cull) ).

In some more favorable types than Paramecium the number
of chromosomes has been made out with some degree of accuracy.
Prandtl (’06) finds sixteen in Didinium nasutum, a number which
I have been able to confirm (unpublished). Prowazek (’99) was
a little in doubt whether there were twelve or thirteen in the nu-
clei of Bursaria truncatella, but describes six chromosomes in
Stylonychia pustulata. Stevens (710) describes four chromosomes
in Boveria subcylindrica, var. concharum, but gives no details as to

THE NUCLEI OF UROLEPTUS MOBILIS 341

their formation or reduction; Enriques (’08) finds the same num-
ber in Chilodon uncinatus. Popoff (08) enumerates sixteen
chromosomes in Carchesium polypinum in the first maturation
spindle, and Enriques (’07) finds the same number in Opercularia
coarctata, while Kaltenbach (’15), somewhat doubtfully, attrib-
utes twenty chromosomes to Ophrydium versatile. Collin
(09), finally describes six chromosomal elements in the first
spindle of Anoplophrya branchiarum.

Hamburger (’04) is a bit hazy in her description of the origin
of the chromosomes in Paramecium bursaria. The late stage of
the crescent is regarded as a spireme from which the chromosomes
are formed as short, curved, or V-shaped rods. Calkins and
Cull derive the chromosomes of Paramecium caudatum from a
synezesis stage which precedes the crescent, and from which the
chromosomes emerge as double rods which are fully divided by
the time the first spindle is completed. According to this ac-
count, the metaphase stage occurs during the metamorphosis of
the crescent into the spindle, so that the latter when formed is
always in the early anaphase stage.

The process of chromosome formation in Paramecium caudatum
may be regarded as a linear fragmentation of the dense chromatin
of the micronucleus. In the other forms in which the chromatin
history has been followed, the process may be interpreted as a
granular fragmentation, and the problem is to construct the
chromosomes from these granules. The parachute nucleus,
which is characteristic of most of the ciliates with a small number
of chromosomes, may be compared with the Paramecium nucleus
at the time when the division center has migrated from the apex
of the crescent to the middle of the convex side. The chromatin
content of such parachute nuclei consists of separated granules
of chromatin, of which the number is difficult to count. In
Uroleptus mobilis when diffusion of the granules has apparently
reached its limit, I find from twenty-four to twenty-eight such
granules (figs. 35 to 37). Prandtl’s figures show that there are
approximately thirty-two in Didinium nasutum. Enriques (’08)
and Collin (’09) describe a similar fragmentation of the comma-
form chomatin rod of Chilodon uncinatus and of the homogeneous

et A Ok

342 GARY N. CALKINS

‘chromatin mass of Anoplophrya branchiarum, the granules of

chromatin collecting in the center of the first maturation spindle.
In Didinium, Chilodon and Anoplophrya, these granules fuse
until a definite number of chromosomes result, sixteen in Didin-
tum, four in Chilodon and six in Anoplophrya. In Uroleptus
there may be such a fusion of granules to form eight chromosomes,
(fig. 40), or the nucleus may divide without such fusion, the
granules being distributed in two equal groups in the daughter
nuclei (figs. 38 and 39). It is tempting to assume that the former
mode is typical and that eight chromosomes represent the normal
condition of the first maturation spindle. This assumption
would bring Uroleptus in line with the maturation phenomena
of higher animals. But the fact of the matter is that I find just
as many spindles of one type as of the other, and both types
are, apparently, equally potent.

In no ciliate, in which the number of chromosomes can be
counted, does this first division result in a reduction to one-half.
Furthermore, there is much uncertainty as to whether the divi-
sion of the chromosomes is longitudinal or transverse. Prandtl
(06) could not determine which it is in Didinium nasutum;
Collin (09) was equally uncertain; indeed, he seems to have had
some doubts as to whether these granular elements on the first
maturation spindle were even to be regarded as chromosomes.
Enriques (’08), while admitting the difficulties of interpretation,
is convinced that the chromosomes of Chilodon uncinatus are
transversely divided. Popoff (08) did not observe the fact, but
assumes, apparently from analogy with conditions in many meta-
zoa, that this first division in Carchesium polypinum is equational.

In Paramecium the chromosomes are not granules, but rods
which are too numerous to count. With this form it should not
be difficult to determine whether the division of each rod is trans-
verse or longitudinal. Owing to the early views in regard to the
origin of the first spindle from the crescent, it was generally
assumed that division was transverse. Calkins and Cull (’07),
however, found that the rods are double when formed and that
the pairs are each separated in this first maturation division.
Such a longitudinal division would correspond, therefore, with a

THE NUCLEI OF UROLEPTUS MOBILIS 343

reducing division if the conditions in protozoa are the same as in
metazoa. This, however, cannot be granted offhand for the
second division is also longitudinal, and it was impossible to tell
whether the double chromosomes‘ were likewise longitudinally
divided.

Waldeyer (’88) defines chromosomes as ‘‘the deeply staining
bodies into which the chromatic nuclear net-work resolves itself
during mitotic cell-division” (quoted from Wilson, 799). Apart
from the chromatic nuclear net-work from which they originate,
this definition would include the chromosomes of the ciliate
micronucleus. But it would also include the granules of chro-
matin which elongate and divide in the typical macronucleus
during division. The number of chromosomes, furthermore, is
regarded as fixed for the same species, but the number of dividing
chromatin granules in the macronucleus is immeasurably greater
than the number of chromosomes of the micronucleus. It follows
that either these dividing granules of chromatin are not all chro-
mosomes or that the number of chromosomes is not fixed for the
same species in all cases. It is obvious that, according to the
definition, all chromatin bodies which arise from the chromatin
of the resting nucleus are not chromosomes. The difficulty in
most cases might be avoided by a strict interpretation of the
definition which involves ‘mitotic’ cell division, although in some
cases, e.g., Spirochona gemmipara (Hertwig, ’77), the macro-
nucleus divides by mitosis. The suggestion made by Rabl that
the chromosomes retam their individuality throughout life of the
organism has grown to a strong conviction in later years, es-
pecially through the work of Conklin, Morgan and recently
Richards. I doubt very much, however, if anyone can be found
hardy enough to apply this conception to the chromosomes of
protozoa. Nevertheless, I believe that we are justified in re-
garding chromosomes in ciliates as equivalent structures to
chromosomes of the metazoa. In the prophases of the first
maturation spindle in ciliates we find parallel stages with those
of the first maturation division in higher animals. The synezesis
stage is represented by the chromatic net-work which arises from
the homogeneous chromatin in the parachute type of nucleus

344 GARY N. CALKINS

(figs. 28 and 29) and the fusion of granules to form the chromo-
somes parallels their origin in higher forms.

c. The second maturation division. In all ciliates in which the
number of chromosomes has been accurately counted, the reduc-
tion in number occurs during the second maturation division.
This was first made out in the case of Didinium nasutum by
Prandtl (’06), who found that the sixteen chromosomes resulting
from the first maturation division, were separated into two
groups of eight each in the second division. This method of
reduction appears to be characteristic for ciliates and agrees with
what Goldschmidt (’05) designates the ‘first type of reduction’
exemplified among metazoa by Zoogonus mirus.

Prior to Prandtl’s work there were no conclusive observations
on reduction in ciliates. Maupas (’88) and Hertwig (’89) made
no attempt to follow the chromosome history. Prowazek (99),
while mentioning twelve to thirteen chromosomes in the first
maturation division of Bursaria truncatella and six in Stylony-
chia pustulata, does not give their fate in the second division.
Subsequent to Prandtl’s work, we find a number of well-defined
eases of chromosome reduction. In Opercularia coarctata En-
riques (’07) finds a reduction from sixteen chromosomes to
eight, the process agreeing with that in Didinium. In Chilodon
uncinatus (Enriques, ’08) the same observer describes the four
chomosomes resulting from the first maturation division as fusing
to form two pairs in the telophase stage. In the second divi-
sion each pair divides, the daughter nuclei receiving two chro-
mosomes each. A similar fusion of two pairs of chromosomes in
vegetative mitosis was observed by Stevens (710) in Boveria
subcylindrica, but she was unable to trace the history of the
four chromosomes in the maturation processes. In Carchesitum
polypinum, Popoff (’08) there are, again, sixteen chromosomes
in the products of the first maturation division, which are sep-
arated into two groups of eight each by the second division.
In Anoplophrya branchiarum, Collin (’09) describes six chromo-
somes in the first maturation spindle, each of which is equally
divided. The second maturation spindles were not identified,
but this excellent and equally candid observer finds only three

THE NUCLEI OF UROLEPTUS MOBILIS 345

chromosomes in the nuclei undergoing the third division, and
concludes that the reduction must have taken place during the
second maturation division. In Uroleptus mobilis, finally, we
find a process of reduction conforming to these processes in the
other ciliates described. The eight chromosomes of the first
maturation mitosis (or the many granules of chromatin in aber-
rant types, fig. 40}, fuse, after division, to form eight chromosomes
of the metaphase of the second maturation division (figs. 54
and 55). But these eight chromosomes become partially fused
to form four pairs. This phenomenon is similar to that de-
scribed by Enriques (’08) as occurring in Chilodon uncinatus;
but in Uroleptus the fusion is not complete, the two distinct
chromosomes of each pair simply lie in close contact (fig. 55, a).
The early anaphase stages of this second division furnish some
evidence indicating that the two members of each pair possibly
slide apart in opposite directions, so that four single chromosomes
finally collect at each pole (fig. 55).

The observations on chromosomes and reduction in ciliates may
be summarized in tabular form as follows:

gas |286
ree |mEe
Od < Oad
q : : Baby| Sab

GENUS, SPECIES, AND ORDER OBSERVER 2 S & Sle = g z

ROA S|ROzG

ZORPIEOOS

> aR = zNA
Anoplophrya branchiarum (Holotrich)......... Collins, ’09 6 3
Boveria subcylindrica (Holotrich)..............] Stevens, ’10 4 ?
Bursaria truncatella (Heterotrich)..............] Prowazek, ’99 12-13 ?
Carchesium polypinum (Peritrich)............. Popoff, ’08 16 8
Chilodon uncinatus (Holotrich)................ Enriques, ’08 16 8
Didinium nasutum (Holotrich).................| Prandtl, ’06 16 8
Opercularia coarctata (Peritrich).............. Enriques, ’07 16 8
Ophrydium versatile (Peritrich)................| Kaltenbach, 715 | 20+ te
Stylonychia pustulata (Hypotrich).............] Prowazek, ’98 6 ?
Uroleptus mobilis (Hypotrich).................| Calkins, ’19 8 4

As to the number of nuclei participating in the second matura-
tion or reducing division, we find many variations. In ciliates
having but one micronucleus in the vegetative stages the numer-

346 GARY N. CALKINS

ical relations are fairly uniform, two spindles in the second
maturation division being the rule. There are, however, some
exceptions. Thus in Paramecium bursaria, according to Ham-
burger (’04), one of the nuclei formed by the first maturation divi-
sion degenerates without forming a spindle, so that only one
nucleus undergoes the second maturation division. A second
exception is found in Euplotes patella and in all vorticellidae
examined up to the present time. Here the micronucleus under-
goes one preliminary mitosis prior to the first maturation divi-
sion (p. 338). The resulting two nuclei then undergo the first
maturation division and the four resulting nuclei form eight by
the second maturation division. In vorticellidae this unusual
division occurs only in the microgamete. The micronucleus of
the macrogametes, on the other hand, does not undergo a pre-
liminary division and the usual history of uninucleate forms is
followed.

In ciliates with two micronuclei, both undergo the first matu-
ration division. According to Prowazek (’99), the four resulting
nuclei in Stylonychia pustulata divide again, thus forming eight
products of the second division. According to Maupas (’88),
however, two of these first four nuclei of Stylonychia pustulata,
and of Onychodromus grandis as well, degenerate so that only
two nuclei divide in the second maturation division.

In ciliates with many micronuclei in the vegetative stage there
seems to be no general rule as to the number which undergo the
second maturation division, unless, indeed, it be variability.
Prandtl (06) found a variable number in Didinium nasutum;
Prowazek, (’99) a large number in Bursaria truncatella, and I find
a variable number in Uroleptus mobilis. The usual number of
spindles in the second maturation division here is two, although
three are frequently found, while individuals with one or with four
have not been seen.

d. The third division. The third, or pronuclei-forming divi-
‘ sion, is a peculiarity apparently almost universal in the Infusoria.
The spindles are frequently heteropolar (Didinium, Paramecium),
and the telophase stage is often characterized by long connecting
strands of nuclear substances (Paramecium Blepharisma, Uro-

THE NUCLEI OF UROLEPTUS MOBILIS 347

leptis, etc.). There is no uniformity in regard to the number of
nuclei to undergo this third division, although only one of the
dividing nuclei provides the functional pronuclei. In Anoplo-
phrya, Paramecium, Chilodon, Colpidium, Leucophrys, Glau-
coma, Loxophyllum, Spirostomum, Bursaria, Blepharisma, Bo-
veria, Lionotus, and in the vorticellidae only one spindle is
formed for this third division. In Onychodromus, Stylonychia,
and Euplotes, according to Maupas (’88), two spindles are pres-
ent and four pronuclei are formed, two of which degenerate and
disappear (in Stylonychia, according to Prowazek (’99), only one
third division spindle is present). Uroleptus mobilis differs from
the majority of other ciliates in having from two to four nuclei
undergoing this third division at the same time, and as many as
eight products of this division may be present in the cell before
any two are metamorphosed into pronuclei (fig. 61).

e. The pronuclet. Prandtl ((06) was the first to note a differ-
‘ence in size between the wandering and the stationary pronuclei
of Didinium nasutum. Calkins and Cull (’07) noted a similar
difference in pronuclei of Paramecium caudatum, and were able
to trace this difference back to a heteropolar third-division spin-
dle. Other observers have failed to find any constant differ-
ences, and this is the case in Uroleptus mobilis, where the size
relations of the fully formed pronuclei, as carefully measured in
ten individuals, are as follows:

PAIR INDIVIDUAL WANDERING PRONUCLEUS ' STATIONARY
1 A 24 x 3u a3 yl
B 3.x 3u 24x 2h un
2, A 21x 25m Sexi
B Bh oe 8h jn 2ix3u
3 A Bes ay ]0 Dao
B yD 2+ x 2ty
4 A 24 x 2h uw 24 x3 u
B Sh) Neat fh 2ix3u
5} A 33 X 34 uw 3) Sho
B Seon 4x 43u

' Pairs 1 to 4 were fixed in Bouin’s fluid; pair 5 in sublimate acetic.

348 GARY N. CALKINS

These differences are too uncertain to permit any conclusion
as to the size relations between wandering and stationary pro-
nuclei. In some cases the wandering pronucleus is smaller, in
other cases larger than the stationary pronucleus.

Apart from size differences, we occasionally find structural
differences between the wandering and the stationary pronuclei.
Maupas (’88) was the first to note the presence of a dense aggre-
gate of cytoplasmic granules at the forward end of the advancing
pronucleus of Euplotes patella, while no such aggregate was seen
in connection with the stationary pronucleus. Hoyer (’99) ob-
served ‘astral rays’ about each of the pronuclei of Colpidium
colpoda, but without distinctive differences; similar radiations,
more pronounced about the wandering pronucleus, were de-
scribed by Prandtl for Didintum nasutum. In Uroleptus mobilis
there are no radiations such as occur in Didinium, but the granu-
lar aggregate at the forward end of the wandering pronucleus is
highly characteristic and its presence confirmed in material fixed
in sublimate acetic, in Flemming’s fluid, in Bouin’s fluid and in
Schaudinn’s fluid. It appears to be a directive center, possibly
analogous to the centrosphere of Noctiluca: It cannot be inter-
preted as a collection of granules due to pressure of an advancing
solid for the advanced end of the mass curves around the anterior
end in a definite way (figs. 71 to 75). With the approach and
union of the pronuclei this mass disappears.

f. Fusion of the pronuclet. The outcome of the interchange of
pronuclei is the fusion of migrating and stationary pronuclei.
In all ciliates which have been carefully examined, with the ex-
ception of the vorticellidae, this interchange and fusion is mutual.
Hoyer (99), however, holds a different view. He, like Maupas
before him, failed to find evidence of the union of pronuclei in
Colpidium colpoda, and concluded that no fusion occurs, the
foreign pronucleus in each individual forming the functional
micronucleus. In the face of the overwhelming evidence in other,
and probably more favorable ciliates, this peculiar view cannot
be*admitted. In the vorticellidae the microgamete fuses with
the macrogamete and loses its identity in the protoplasm of the
larger conjugant. Here one of the two pronuclei formed by

THE NUCLEI OF UROLEPTUS MOBILIS 349

each conjugant degenerates, and only a single fertilization nu-
cleus is formed.

At the time of fusion the pronuclei may be either in the form of
spherical and vesicular nuclei or drawn out into more or less
pointed spindle form. We find the former type in Anoplophrya
branchiarum, Didinium nasutum, Spirostomum teres, Blepharisma
undulans, and Opercularia coarctata, while union of pronuclei in
the spindle form is reported in all species of Paramecium, Chilodon
uncinatus, Leucophrys patula, Onychodromus grandis, Stylony-
chia pustulata, Vorticella nebulifera, Ophrydium versatile and
Lionotus fasciola. In some cases it seems to be immaterial
whether the pronuclei are vesicular or spindle form at the time
of fusion (Loxophyllum meleagris, Carchesium polypinum).
Uroleptus mobilis appears to be an intermediate type, for here
the pronuclei approach and meet while in the spherical and
vesicular form, but before the fusion membrane dissolves both
pronuclei elongate and assume the spindle shape (figs. 77 and
78). The chromatin, however, is not aggregated into chromo-
somes at this period, but lies in diffuse granular form exactly as
in Paramecium caudatum. While the general form is that of a
nucleus in division, these fusing pronuclei can no more be re-
garded as mitotic spindles than can the fusing spherical nuclei;
in both types we have merely the antecedent phases of mitosis.

g. Reconstruction of the vegetative nuclei. The first division of
the fertilization nucleus occurs very quickly after fusion and is
not often seen. In Uroleptus I have found only one spindle
that can be identified as the first division spindle (fig. 81). In
this spindle the two sides are not symmetrical, indicating the di-
vision of chromosomes from one pronucleus earlier than in the
other. The further history of the first two nuclei after conjuga-
tion differs in different cases, and for some species the accounts
by different observers do not agree. According to Enriques (’08),
in Chilodon uncinatus one of these first two forms the new macro-
nucleus and the other the new micronucleus. This, perhaps, is
the simplest case on record. In all of the other cases described
by different observers the macronucleus is not differentiated
from the micronucleus until at least four nuclei have been formed

350 GARY N. CALKINS

by a second division of the first two. One or two of these four
may degenerate; one or two may form macronuclei. Or the four
may divide again, forming eight nuclei before differentiation be-
gins. In Anoplophrya branchiarum and in Euplotes patella two
of the four nuclei degenerate, the other two form one macronu-
cleus and one micronucleus. In Colpidium colpoda (Hoyer,
99), Stylonychia pustulata (Maupas, ’88) and in Lionotus fas-
ciola (Prowazek, ’09), only one of the four degenerates, two be-
come functional micronuclei, and one becomes the macronucleus.
In Dadinium nasutum (Prandtl, ’06), Paramecium bursaria
(Hamburger, ’04), Glaucoma scintillans (Maupas, ’88), Leuco-
phrys patula (Maupas), Spirostomum teres (Maupas), and in
Stylonychia pustulata (Maupas), two of the four nuclei become
macronuclei and two become micronuclei, none of the nuelei
degenerating. In Blepharisma undulans (Calkins, *12) all four
of this stage become macronuclei enclosing the micronuclei.

In another group the first four nuclei divide once again before
the nuclei are differentiated. Here we find Paramecium cauda-
tum, Paramecium putrinum, Cryptochilum nigricans, Carchesium
polypinum, Vorticella nebulifera, and Ophrydium versatile. In
the last three mentioned, seven of the eight nuclei form macro-
nuclei. These fuse to form one in Cryptochilum (Maupas), but
in the other three forms they remain separated and are distrib-
uted to the daughter cells by unequal division until each cell
has one (Maupas, Kaltenbach, Popoff). In Paramecium cauda-
tum and in P. putrinum, four of the eight nuclei form macronuclei,
while the fate of the other four is differently interpreted. Mau-
pas (88) and Doflein (11) hold that three of these degenerate,
leaving one functional micronucleus. Calkins and Cull (07)
find that all four are functional.

An exceptional history is shown in the reorganization of Bur-
saria truncatella. Here no differentiation occurs until sixteen
nuclei are formed (Prowazek, 99). Two to five of them form
macronuclei, three or more form micronuclei, and the remainder
degenerate.

In Uroleptus mobilis differentiation of the nuclei occurs with the
second division of the fertilization nucleus. One of the two nuclei
formed by the first division divides unequally into a large vesicu-

THE NUCLEI OF UROLEPTUS MOBILIS 351

lar nucleus, the beginning of the macronuclei, and a small nucleus
which degenerates. The chromosomes are eight in number in
the first two divisions of the fertilization nucleus where they can
be counted without much difficulty. After the differentiating
second division there is a long pause, during which the young’
macronucleus undergoes its metamorphosis. During this period,
which lasts for approximately 72 hours, the two functional mi-
cronuclei become more compact and smaller, and when they
finally divide, the spindles are so minute that no sure observation
can be made as to the number of chromosomes contained. In
mitoses from ordinary vegetative divisions, however, the number
is eight, the chromosomes frequently lying in four pairs similar
to the condition in the second maturation division but occa-
sionally one or more pairs are not united so that five, six, or
seven may be counted.

h. Fate of the old macronucleus. All observers, with the ex-
ception of Prowazek (’99, ’09), are agreed as to the fate of the
old macronucleus. Prowazek, among the recent workers at
least, appears to be alone in concluding that the old macronucleus
is cast out of the cell as waste material. His conclusion is drawn
from the premise that nucleins cannot be digested and must
therefore be eliminated. . As Collin (’09) points out, Prowazek
describes the loss of staining power of the old macronucleus frag-
ments, and to this extent at least admits that the nuclei are di-
gested. As he offers no evidence of such elimination from direct
observation of the reorganization processes of Bursaria, Stylon-
ychia pustulata, and Lionotus fasciola, his conclusion may be
dismissed as highly improbable.

The majority of observers have traced the gradual reduction in
size of the old macronucleus or its fragments until nothing re-
mains. This certainly is its history in Uroleptus mobilis, where
the eight old macronuclei become greatly reduced in size and then
fade away, one by one, until all are absorbed in the cytoplasm.

The following table is a summary of the points made by dif-
ferent observers on different species of ciliates and is useful for
purposes of comparison. In most cases where two or more ob-
servers have worked on the same species only the most important
papers are cited.

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353

354 GARY N. CALKINS

SUMMARY OF OBSERVATIONS

1. Subject Uroleptus mobilis, Engelmann, a ciliate belonging
to the family Oxytrichidae, order Hypotrichida of the Infusoria.

2. Treatment. Description of species, pp. 293 to 296; tech-
nical methods, pp. 297 to 299; history of the nuclei during divi-
sion, pp. 299 to 307; during conjugation, pp. 308 to 332; com-,
parisons with other ciliates, pp. 333 to 353.

3. Macronuclei 8 in number. In preparation for cell division
these fuse to form one (pp. 299 to 301). Prior to division of the
cell this macronucleus divides twice; after division of the cell
these four divide once again to form 8 (pp. 301 to 303). Divisions
are amitotiec.

4. Micronuclei variable in number from 2 to 6. They do not
fuse in preparation for cell division but the number is reduced to
2, probably by absorption (pp. 303 to 305). With cell division
the 2 nuclei divide. One of the 4 may degenerate or all may
divide. In latter case 2 degenerate while 6 divide to form 12,
6 for each daughter cell. Of these 6, one or two may degenerate
(pp- 306 to 307). Divisions are always mitotic with 8 single
or partially fused chromosomes. Whether chromosome division
is transverse or longitudinal could not be determined.

5. Paedogamous conjugation lasts from 28 to 36 hours. The
macronuclei are retained throughout the process, but undergo
progressive granular disintegration (pp. 308 to 309). They are
finally absorbed in the protoplasm and have disappeared on the
fourth or fifth day after conjugation (pp. 309 to 310).

6. Four micronuclei is the usual number in conjugants. All,
or a part of them only, form first maturation spindles. The pro-
phase stage for these is a characteristic nucleus termed the para-
chute nucleus, with an intranuclear division center (p. 313). The
massed chromatin disperses first as a dense reticulum; chromatin
collects at the nodes of this reticulum to form granules 24+ in
number. Eight definite chromosomes may be formed by further
fusion (type 2) or the nuclei may divide without such fusion
(type 1), 12= granules going to each daughter nucleus (p. 314).
Whether division is transverse or longitudinal could not be deter-
mined (p. 315). .

THE NUCLEI OF UROLEPTUS MOBILIS 355

7. The second maturation spindles are usually 2 in number.
Each contains 8 chromosomes arranged in 4 pairs. Division
separates the members of each pair, resulting in reduction in
chromosomes from 8 to 4 (p. 316).

8. All four products of the second division may undergo the
third division; or one, or two, may degenerate. The functional
pronuclei are always derived from the division of one of these 4,
the remainder degenerate (p. 319). The spindles are character-
ized by 4 chromosomes in the metaphase and anaphase stages,
and by long connecting strands in telophase stages (p. 321).
The pronuclei are not differentiated in size or shape; the wander-
ing pronucleus is accompanied by a granular ‘attraction sphere’
of cytoplasmic origin (p. 323).

9. Fusion of pronuclei begins while in the vesicular state; be-
fore fusion is complete the pronuclei assume a spindle form which
becomes the first division spindle with 8 chromosomes (p. 326).

10. The first two nuclei divide again; one gives rise to the
functional micronuclei, the other to one micronucleus which de-
generates and to one which enlarges to form the new macronu-
cleus (p. 326). The conjugants separate at this stage.

11. The new nuclear apparatus is formed by 3 divisions of the
new macronucleus and two of the micronuclei during the first 6
days subsequent to conjugation and the first division of the ex-
conjugant occurs on or about the sixth day.

Columbia University
May, 1918

THE JOURNAL OF EXPERIMENTAL ZOOLOGY, VOL. 27, NO. 3

356 GARY N. CALKINS

LITERATURE CITED

BaitsELt, G. A. 1912 Experiments on the reproduction of the hypotrichous
Infusoria. 1. Conjugation between closely related individuals of
Stylonychia pustulata. Jour. Exp. Zool., vol. 13, no. 1. —

Barpiani, G. 1860 Observat. et expér. sur les phénom. de la reprod. fissipare
chez les Infusoires ciliées. C. R. Ac. Se. Paris, T. 50, p. 1191.

1861 Recherches sur les phénom. sexuelles des Infusoires. Jour. de
la Physiol., T. 4.
1881 Les Protozoaires. Jour. de Micrograph., T. 5.

BuscuxiEL, A. L. 1911 Ichthyophthirius multifiliis. Arch. Protist., vol. 21.

Burtscaui, O. 1888 Protozoa. Bronn’s Thierreich. 1, part 3.

Cauxins,G.N. 1912 The Paedogamous Conjugation of Blepharisma undulans.
Jour. Morph., vol. 23.

Cauxins, G. N., AnD Cutt, 8. W. 1907 The conjugation of Paramecium aurelia
(caudatum). Arch. Protist., vol. 10.

Couuin, B. 1909 La conjugaison d’Anoplophrya branchiarum St. Arch. d.
Zool. Exp. et Gén., 5th Series, T. 1.

Dor.eEIn, F. 1911 Lehrb. d. Protozoenkunde. 3rd edition, p. 188 (Param. pu-
trinum).

ENGELMANN, W. 1862 Zur Naturgesch. d. Infusionsthiere. Zeit. wiss. Zool.,
Bd. 11.

Enriques, P. 1907 La coniugatione e il differenziamto sessuale negli Infusori.
Arch. Protist., vol. 9, p. 195.

1908 Die Conjugation und sexuelle Differenzierung der Infusorien.
Arch. Protist., vol. 12, S. 213.

Fermor, X. 1913 Die Bedeutung der Encystierung bei Stylonychia pustulata
Ehr. Zool. Anz., Bd. 42, p. 380.

Gotpscumipt, R. 1905 Eireifung, Befruchtung und Embryonalentwick. des
Zoogonus mirus Lss. Zool. Jahrb. (Anat.), Bd. 21

GruBer, A. 1887 Weitere Beobachtungen an vielkernigen Infusorien. Ber. d.
Naturf. Ges. z. Freiburg, Bd. 3, S. 57.

Hampurcer, C. 1904 Die Konjugation von Paramecium bursaria Foche.

: Arch. Protist., vol. 4, p. 199.

Hertwic, R. 1877 Uber den Bau u. die Entwickl. v. Spirochona gemmipara.
Jen. Zeit. f. Naturges., Bd. 11, 8. 149.

1889 Uber die Konjugation der Infusorien. Abh. d. kgl. Bayr. Akad.
d. Wiss, 2K) Baz:

Hoyer, H. 1899 Uber das Verhalten der Kerne bei der Konjugation des In-
fusors Colpidium colpoda St. Arch. mik. Anat., Bd. 54, 8. 95.

Jonnson, H. P. 1893 <A contribution to the Toranoloey and biology of the
Stentors. Jour. Morph., vol. 8, no. 3, p. 467.

Kaurenpacn, R. 1915 Die Conjugation von Ophrydium versatile. Arch.
Protist., vol. 36, p. 67.

Lesepew, W. 1908 Uber Trachelocerca phoenicopterus, ein marines Infusor.
Arch. Protist., vol. 13, p. 70.

THE NUCLEI OF UROLEPTUS MOBILIS 315%

Mauvpas, E. 1883 Contrib. a l’étude morpholog. et anatomiq. des Infusoires
ciliées. Arch. d. Zool. Exp. et Gén., 2nd Ser., T. 1.
1888 Le rajeunissement karyogamique chez les ciliés. Arch. d. Zool.
Exp. et Gén., 2nd. Ser., T. 7, p. 149.

NERESCHEIMER, E. 1908 Fortpflanz. eines parasitischen Infusors (Ichthyoph-
thirius). Sitz. Ber. Ges. Morph. Physiol. in Miinchen, Bd. 23.

Poporr, M. 1908 Die Gametenbildung u. d. Conjugation von Carchesium poly-

- pinum. Zeit. w. Zool., Bd. 89,8. 478.

PranptL, H. 1906 Die Konjugation von Didinium nasutum O. F. M. Arch.
Protist., vol. 7, p. 229.

ProwazeEk, 8. 1899 Protozoenstudien. (Bursaria truncatella and Stylonychia
pustulata). Arb. a. d. Zool. Inst. Univers. Wien., Bd. 2, 8. 195.
1909 Conjugation von Lionotus. Zool. Anz., Bd. 34, S. 626.

Stevens, N. M. 1910 The chromosomes and conjugation in Boveria subcylin-
drica var. concharum. Arch. Protist., vol. 20, p. 126.

Waxpeyer, W. 1888 Uber Karyokinese u. ihre Beziehungen z. d. Befruchtungs-
vorgingen. Arch. Mik. Anat., Bd. 32.

Witson, E. B. 1899 The cell in development and inheritance. New York, 1899.

Resumido por el autor, W. J. Crozier.

Sobre el uso del pié en algunos moluscos.

El presente trabajo ahade un nuevo tipo de locomocién (el
‘‘salto’”? de Xenophora) a los conocidos entre los gasterépodos;
susministra un segundo buen ejemplo de progresién pedia arit-
mica (Conus) y agrega tres especies de Chiton (Ischnochiton,
Acanthochites, Tonica) a la lista de los moluscos conocidos que
se mueven por medio de ondas pedias retrégradas. Ischnochiton
se mueve hacia atrds, conservando el caracter retrogrado de sus
ondas pedias, con considerable libertad y por distancias aprecia-
bles. Ischnochiton también presenta un ‘‘galope’’ como el de
Helix, el cual es independiente de las ondas pedias.

Translation by Dr. José F. Nonidez,
Columbia University.

AUTHOR’S ABSTRACT OF THIS PAPER IS-
SUED BY THE BIBLIOGRAPHIC SERVICE

ON THE USE OF THE FOOT IN SOME MOLLUSKS!

W. J. CROZIER

Bermuda Biological Station

ONE FIGURE

From time to time I have had the opportunity of observing
the method of locomotion in some mollusks which appear not to
have been studied previously from this standpoint; since these
observations add somewhat to our knowledge of the distribu-
tion and variety of pedal movements in chitons and in gastro-
pods, they may be briefly recorded.

Ischnochiton purpurascens Ad., Acanthochites spiculosus
Reeve,’ and an undetermined species of Tonicia were found to
agree with the two chitons whose locomotion has hitherto been
observed, namely, Acanthochites fascicularis (by Vlés, ’07) and
Chiton tuberculatus (by Parker, ’11), since they all progress an-
teriorly by means of monotaxic retrograde pedal waves. They
add, therefore, to the conclusion (Parker, ’11) that a certain
mode of pedal activity may be of general occurence throughout
single morphologic groups of creeping mollusks. Similarly, a
small species of Onchidiella I find to move by means of direct
monotaxic waves, like Onchidium (Vlés, ’07; Parker, ’11); in
this Onchidiella the foot is quite small, 1.2 mm. x 3 mm., and
usually one, but sometimes two, waves are present on the foot
at one time. Three species of Crepidula which I have observed

1 Contributions from the Bermuda Biological Station for Research, No. 100.

* This species or one of its so-called ‘varieties.’ Some of the ‘varieties’ re-
corded in the taxonomic literature of the chitons are nothing more than ‘color
varieties’ induced by the conditions of food supply, as I know from studies of Chiton
tuberculatus. The Acanthochites, now for the first time recorded from the Ber-
muda area, had brownish spinules, not greenish, as is recorded for some varieties
of A. spiculosus.

309

360 W. J. CROZIER

move, as Parker (’11) has described for C. fornicata, by means of
direct waves. In one of these crepidulas the use of the whole
foot as a sucker was very clear, and in fact sometimes during
creeping the circumference only of the foot was in contact with
the substratum (of smooth glass).

TIschnochiton was of particular interest, as it moved in a pos-
terior direction with great freedom. The animal is long and
narrow (15 mm. x 5 mm.), the foot being about 2 mm. broad.
When disturbed it presses the girdle firmly to the substratum and
elevates the midregion of the body, in this way exerting suction
and thereby adhering tightly to the rock or other surface. The
girdle is in fact the prime ‘holdfast’ organ in all the chitons, and
not the foot. During the process of exerting suction the foot of
Ischnochiton may be more or less clearly removed, in its mid
portion, from all contact with the supporting surface, and it ex-
hibits also a type of reaction which is not without special inter-
est: the foot shows a decided tendency to fold together longitud-
inally, a deep depression appearing along its middle, giving it a
‘ditaxic’ appearance. Usually, in creeping, one retrograde pedal
wave is present on the foot. Ischnochiton does not carry out
pivoting movements so readily as do some other chitons, but
in contrast with them does move posteriorly in a ‘spontaneous’
way for considerable distances, although it does subsequently
pivot or turn in a circular path if forced to move by continuous
directive stimulating agencies.2 During posterior locomotion the
retrograde character of the pedal wave is retained, as Olmsted
(17) found to be true in Chiton tuberculatus. Olmsted forced
C. tuberculatus to creep posteriorly by attaching the posterior
end of the foot to a glass plate. Ischnochiton, however, moves

3 This type of behavior is of special interest for the analysis of the phototro-
pism of Ischnochiton. It might be remarked that in the present species without
careful inspection there is some difficulty in distinguishing in dorsal view anterior
and posterior ends, owing to the indistinct sutures between the valves. Hence
it would appear that the lack of pronounced external signs of polarity is cor-
related with ready locomotion in either anterior or posterior direction. However,
there is not the slightest reason to suspect that any ethological significant is
involved in this correlation.

USE OF THE FOOT IN SOME MOLLUSKS 361

posteriorly, in a straight line, away from a source of light, and
its backward creeping may therefore be studied with ease.

When Ischnochiton is creeping ventral side uppermost on a
slip of glass, it sometimes (and almost always if stimulated by
strong light) releases the anterior part of the foot, until finally
it remains attached only by means of about 2 sq. mm. of foot
surface. Hence it would appear that here, as in Chiton (Parker,
14), the foot sucks locally.

In moving anteriorly away from a strong light, the anterior
part of the body is sometimes completely freed from the sub-
stratum, then brought back to it, and then attached at the an-
terior end of the foot, initiating in this way a ‘giant wave,’
‘which, traveling the length of the foot, gives the appearance of a
‘gallop,’ probably analogous to that of Helix dupetithoutarsi and
of Aplysia (Parker, ’11,’17), since it is retrograde, ‘monotaxic,’ and
involves the body musculature generally, not merely the foot.
Five or six waves of this character, one at a time, but sometimes
not quite coincident with the normal pedal wave (which may
therefore be seen independently), may be carried out in
succession. .

In these chitons the essential mechanism of progression is un-
doubtedly that outlined by Parker (711) and illustrated on a gross
scale by the movements of Aplysia californica (Parker, ’17). I
have been able to verify this idea for a ditaxie foot, that of
Turbo. This mollusk also has a retrograde pedal wave which,
like that of Tectarius, is alternate ditaxic, anteriorly, but may
become opposite ditaxic after the first third of the foot has been
passed over. The foot is divided in the midline by a distinct
groove. When creeping on a vertical surface in air, it can be
clearly seen that the anterior region of one side of the foot is
first lifted 3 or 4 mm. from the surface, extended, and attached
at the anterior end; then the anterior portion of the opposite
side is moved similarly. This snail is an active creeper. The
foot measures 17 mm. x 25 mm., and the movements on its sur-
face can easily be followed. In creeping under water the pedal
waves are minute and frequently opposite ditaxic over the whole

362 W. J. CROZIER

length of the foot. In air, however, they are clearly alternate
ditaxic at the anterior end, corresponding to Parker’s (’11)
analogy with the movements of a ‘person in a sack walk.’ In
Trochus, where the pedal waves are ditaxic but direct, Gosse (65,
p. 8) long ago gave a somewhat accurate statement of this matter
and employed the same comparison: “If your own two feet
were enclosed in one elastic stocking, your own progress would
appear very much like that of the Trochus,”’ showing that he
had correctly appreciated the essential mechanical features of
this mode of progression.

The foot of Conus agassizii is relatively large and bulky. In
full extension it measures 2 cm. x 4.5 em., tapering somewhat
posteriorly, but abruptly truncate at the anterior end. About 1
em. from the anterior margin of the foot, in the midline, is lo-

Fig. 1. Diagrammatic cross-section of the foot of Conus, showing the way in
which the foot is embedded in the mud. X 3.

cated the opening of the pedal gland. The ventral pedal sur-
face can be pressed out completely in contact with a smooth
surface, but usually this is not done. As collected, the shell is
commonly found in a horizontal position partially imbedded in
the mud, and it seems that the very distinct epipodial ridge has a
special functional significance for locomotion when the animal
is thus partly buried, although, as just stated, the distinction
between epipodium and foot proper can be obliterated. The con-
trol of the foot is in some respects distinctly bilateral. If one
side of the foot be touched lightly, that side as a whole is con-
tracted toward the shell aperture. This mode of response (seen
also in the fact that, if the shell be lightly pressed upon from
above, a distinct depression appears along the midline of the
foot, even though it may not be retracted) is undoubtedly con-
nected with the fact that the shell aperture is long and narrow,

USE OF THE FOOT IN SOME MOLLUSKS 363

so that the foot must be folded together longitudinally before
it may be withdrawn into the shell. When disturbed sufficiently
to induce retraction of the foot, the right half of this organ is
retracted first.

Withdrawal of the foot is very readily induced by even mod-
erate stimulation; this is correlated with the condition that the
foot is never very firmly attached to a substratum. Only with
difficulty can a Conus attach the foot to a glass surface firmly
enough to right itself when the shell aperture has been placed
dorsally. Nor can the animal usually creep up a smooth surface
inclined at an angle of more than 60°. The foot is conspicuously
a burrowing organ, and is in this respect very efficient. At
extremely low tides, Conus may be found on sandy beaches bur-
rowing vertically into the sand, the spire being uppermost.
This is accomplished by means of a clockwise rotation of the whole
animal, the foot doing the work of excavation.

In spite of the fact that the foot of Conus is large enough to
make observation an easy matter,* and of the further fact that
the positive phototropism of the animal may be used to induce
it to creep with some rapidity (1.3 em. per minute at 19°), neither
when the animal is creeping in air nor when submerged in sea-
water have I been able to distinguish wave motions upon the
pedal surface. In view of the powerful musculature of the foot
and of its bilateral control in retraction, such movements might
have been expected. Locomotion is, however, accomplished by
a smooth gliding movement. No cilia can be demonstrated upon
the foot, although there is abundant mucus, through which ad-
hesion is mainly effected. Distinct variations in the rate of
movement on the foot can, however, be detected along the an-
terior edge and at the sides. The foot is marked by longitudi-
nally disposed pigment flecks, which would make the detection of
rhythmic waves relatively easy. There seems no doubt, then,
that Conus affords a second instance of that type of pedal loeomo-
tion which Parker (’11, p. 158) characterized as arythmic, with

* It was necessary, of course, to study the locomotion by means of observations
from beneath, the animals being in a broad glass dish.

364 W. J. CROZIER

Alectrion (Ilyanassa) as example. Alectrion inhabits bottoms
of soft mud, very much like those frequented by Conus so far
as the physical consistency of the substratum is concerned; but
on the other hand, Conus and Turbo (vide ante) are taken in
company on the same bottom, yet have quite different methods
of progression; hence little significance can perhaps be attached to
this correlation; Turbo however, does not burrow as Conus does.
The genus Xenophora comprises snails which exhibit the inter-
esting habit of reinforcing their shell with the dead shells and
skeletons of other organisms. To the rough surface thus pro-
duced, various living mollusks, corals, ascidians, worms, algae,
and so forth become attached, resulting in a shell mass which
weighs in different cases from 150 to nearly 300 grams. The
foot itself is relatively small, measuring, when spread out for
attachment, about 2 em. x2 em., whereas the circumference of the
depressed conical shell-mass may be as much as 12 to 15 em.
There is correlated with this disparity between the size of foot
and the size and weight of the shell a type of locomotion which is
somewhat remarkable and finds no place in the present classifica-
tion (ef. Olmsted, 717) of pedal operations among gastropods.
Xenophoras of apparently two species were obtained upon
muddy bottoms in 5 to 8 fathoms. The method of locomotion
must be observed from below, as the animal cannot creep up an
inclined surface (nor can it right itself after being turned over).
The foot is, when unattached, of a roughly dumb-bell outline, and
in life is covered with a thin layer of mud held by a slime secre-
tion. At its posterior end it carries the horny operculum. The
anterior part of the foot is compact and tough, with a firm an-
terior margin. When the animal begins to creep, this anterior
part is the first to be applied to the substratum. Before the
foot is so applied, however, the anterior part of the animal’s
body is thrust forward or to one side as far as possible. The
foot is then attached, beginning at its anterior margin and con-
tinuing with a smoothly ‘flowing’ motion until the whole foot
is in contact, but there are no perceptible pedal waves. The
central portion of the foot is then pulled sharply away from the
substratum, forming a very efficient sucker, since the anterior

USE OF THE FOOT IN SOME MOLLUSKS 365

and posterior ends and the lateral margins remain firmly attached.
The body musculature then contracts, pulling the whole shell
forward into such a position that the aperture is immediately
over the foot. <A ‘step’ of 3 cm. can thus be taken in about one
minute. Usually, when a freshly collected specimen is used, five
or six steps in a more or less continuous series occur in succes-
sion. The direction of progression isreadily altered by the body’s
being extended at an angle, previous to the attachment of the
foot. I did not obtain any evidence of backward steps. The ac-
tion of the foot as a sucker is clearly seen when the animal is at
rest, in which case the foot is not attached to the substratum at
all, but its middle third is distinctly arched, as it is in preserved
specimens.

This type of locomotion is not exactly comparable with that
of a measuring worm, although in a sense these movements are
not dissimilar. The creeping of Xenophora under normal con-
ditions is probably rhythmic, but involves the body musculature _
generally, and is in that sense non-pedal, although the suction of
the foot is essential to progression. Perhaps this type of loco-
motion is for the present better classed with the ‘gallop’ of Helix
(Carlson) and of Ischnochiton, although here again there are
distinctive features.

SUMMARY

This paper adds a further type of locomotion to those known
among gastropods (the ‘looping’ of Xenophora), provides a second
good example of arythmic pedal progression (Conus), and adds
three species of chitons (Ischnochiton, Acanthochites, Tonicia), to
the list of those known to move by means of retrograde pedal
waves. Ischnochiton moves posteriorly, preserving the retrograde
characacter of its pedal waves, with considerable freedom and for
appreciable distances. Ischnochiton also exhibits a ‘gallop,’ like
that of Helix (Carlson), which is independent of the pedal waves.

Dyer Island, Bermuda
May 15, 1918

366

W. J. CROZIER

LITERATURE CITED

Goss, P. H. 1865 A yearat the shore. London, xii + 330 p., 36 pl.

OLMSTED,

J. M. D. 1917 Notes on the locomotion Of certain. Bermudian mol-
lusks. Jour. Exp. Zoél., vol. 24, p. 223-236.

Parker, G. H. 1911 The mechanism of locomotion in gastropods. Jour.

Vuirs, F.

Morph., vol, 22, p. 155-170.
1914 The locomotion of Chiton. Contrib. Bermuda Biol. Sta. vol. 2,
no. 31, 2 pp.
1917 The pedal locomotion of the sea-hare Aplysia californica. Jour.
Exp. Zodl., vol. 24, p. 139-145.

1907 Sur les ondes pédieuses des Mollusques reptateurs. Compt.
rend. Acad. Sci., Paris, T. 145, p. 276-278

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366
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Resumido por el autor, S. O. Mast.

Reversién en la orientacién hacia la luz en las formas coloniales
Volvox globator y Pandorina morum.

1. Volvox y Pandorina son generalmente positivos en la luz
débil y negativos en la luz intensa, si estan adaptados a la oscuri-
dad; pero si estén adaptados a la luz, lo contrario sucede a veces.
2. Silas colonias adaptadas a la oscuridad se exponen a una ilumi-
nacién constante, al principio se comportan como neutrales, de-
spués se transforman en positivas, mas tarde en negativas y final-
mente en positivas otra vez. Cudnto mas intensa es la ilumina-
cién mds corto es el tiempo necesario para pasar por todos estos
estados, pero en tales intensidades es necesaria mucha mas energia
para producir los cambios en la orientacién que en una ilumina-
cion menos intensa. 3. La reversién depende en cierto grado de
la cantidad de energia recibida, pero bajo ciertas condiciones pa-
rece depender principalmente de la duraci6én del cambio de ilumi-
nacion. 4. La reversién no esta regida por la fotosintesis. La
luz roja y la amarilla, en las cuales la fotosintesis se verifica con
relativa intensidad, producen pocos efectos sobre la reversi6n,
mientras que en la luz verde y en la azul, en las cuales la fotosin-
tesis es relativamente débil, son casi tan efectivas como la luz
blanea. 5. Los rayos que poseen la mayor eficiencia estimulante
(azul y verde) son los mas potentes en la produccién de la rever-
sidn. 6. El sentido de la orientacién depende del estado fisio-
légico de las colonias, asi como de la constitucién del medio de
cultivo. Depende también de la edad de las colonias. Las
colonias j6venes son mas aptas para ser negativas que las de mas
edad. 7. La reversién esta probablemente asociada con cam-
bios en la permeabilidad.

Translation by Dr. José F. Nonidez,
Columbia University.

AUTHOR’S ABSTRACT OF THIS PAPER ISSUED
BY THE BIBLIOGRAPHIC SERVICE, DECEMBER 9

REVERSION IN THE SENSE OF ORIENTATION TO
LIGHT IN THE COLONIAL FORMS, VOLVOX
GLOBATOR AND PANDORINA MORUM
52.0: MAST

Marine Biological Laboratory, Woods Hole, and the Zoological Laboratory of the
Johns Hopkins University

TWO FIGURES

CONTENTS
Tired ipa Riverinornges co chad ORI Os Os RONEN 6 0 ORES CO AE onerD Oe OeIROEE fc 0. SaMNeRres 367
idle esrenlle: priv PITTA GIS: Geese ee a. - Rn ce er es 2 ee 368
Relation between illumination and reversion in orientation........:....... 369

Relation between reversion in orientation and the quantity of light energy 375
Relation between reversion in orientation and the time rate of change in

TH Naw ean ehiOy als 3 aaetesc Ato CR ae a Cnt Ne One LOPE IRAs ai | Semenenimtaee 377
Effect of the age of the colonies on reversion..................-.eeceeeeeees 378
Mitect On phoLosyaHesIs OM TEVEISION: -.. <2 cc si. 24's ode el dae dae ee Wael oe 379
Ere ciqOLeMpPeratire*OMETEVeLSIOM: se c.ayoysa--erdeie age ova Seen os ws lene 382
EEC MOINC HEM CalSsONUTEVETSIONS secs 6% «a polassiais, ots atta ev as ctetls, oem Rese aos «asks 383
IDPS SVOT Se Se SR ae See tie BROS ELT 3 OEE IRE ee ERIN Ac Rae Rl RN ak 385
SHIMADA Tem Bee oor eenerte hoe Renee ee ee a OE, a San RED bens aR i, i 3 388
IL TiiSTED LATS WONG ese Bacco alee ha OSs Bia Meee een Meo DORR G od corn od oe coe 390

INTRODUCTION

The literature on reversion in the sense of orientation was
briefly reviewed in a preceding paper which dealt primarily with
the effect of chemicals on the sense of orientation to light in
Spondylomorum (Mast, ’18). The results presented in that
paper indicate that reduction in alkalinity, increase in some anes-
thetics, increase in temperature and decrease in illumination all
have the same effect on the sense of orientation, causing photo-
negative specimens to become photopositive. They also indi-
cate that the same change in the sense of orientation may occur
without any appreciable change in the environment. On the
basis of these results it was concluded that reversion in the sense

367

368 S. O. MAST

of orientation is probably due to some specific change or state in
the physiological processes of the organisms which can be induced
by any one of the factors mentioned, i.e., alkalis, anesthetics,
temperature, or light.

In this paper we shall deal primarily with the effect of mie
nation on the sense of orientation, but we shall also briefly con-
sider some other factors.

MATERIALS AND METHODS

The specimens used in this investigation were all collected at.
Woods Hole in a fresh-water pond. Volvox appeared early in
July and continued for nearly a month. It was found only at
the edge of the pond in a few small puddles, but in these it was.
very abundant most of the time. Pandocrina appeared early in.
August, shortly after Volvox had disappeared, and it continued
nearly to the end of the month. It was not found in all parts:
of the pond, but was much more widely distributed than Volvox
and equally abundant.

Pandorina thrived much better in the laboratory than Volvox,
but neither lived more than a week or two. Most of the obser-
vations were consequently made on specimens within a few days:
after they had been collected.

The observations were all made in a large basement dark-room
in which there was remarkably little variation in temperature
throughout the season and practically none during the time occu-
pied by any given experiment. The dark-room was so fitted up
that either natural or artificial light could be used. Aside from
ordinary electric lamps, there were two gas-filled stereopticon
lamps, one 250 and the other 1,000 watt. These two lamps were
mounted in an adjoining room from which light was admitted
to the dark-room through a hole in the wall, which could be
varied in size (fig. 1). Thus a horizontal beam of light of the
desired size was produced. This extended through the dark-room
parallel with the surface of a series of black tables 7 m. long
The two lamps could readily be interchanged in position. By
this means and by varying the distance between the organisms

REVERSION IN ORIENTATION TO LIGHT 369

and the lamps it was possible to obtain quickly a wide range in
illuminations. The beam of light, before it entered the dark-
room; passed through a heat-screen consisting of a Pfeifer warm-
ing-stage containing distilled water. This screen was so ar-
ranged that a stream of water continuously flowed through it so
as to prevent excessive heating. The observations were prac-
tically all made in six rectangular glass aquaria which were des-
ignated observation aquaria. These aquaria were 2.7 cm. wide,
2.7 em. long and about 1 cm. deep. They were constructed from
pieces of the best-quality microscope slides and Khotinsky
sealing-wax.

a a a oh
a ' .

LLL
o : g

LZ LLL

t s 5

\\

Fig. 1 Diagram representing arrangement of apparatus. a, rectangular ob-
servation aquaria; l, gas-filled stériopticon lamp; 6, beam of light; w, wall be-
tween dark-room and room containing lamp; h, heat-screen containing running
distilled water or saturated solution of chlorophy] in 96 per cent alcohol; t, dead
black table, 7 m. long; s, light-screens.

RELATION BETWEEN ILLUMINATION AND ‘REVERSION IN
ORIENTATION

Both Volvox and Pandorina are very sensitive to light and they
orient fairly precisely. Like a considerable number of other
similar org’anisms, they have ordinarily been found to be posi-
tive in weak and negative in strong light. This has often been
observed in previous work (Mast, ’07, ’11, 718) and it was re-
peatedly observed in the experiments performed in connection
with this work. The following detailed description of a typical
series of observations clearly illustrates the relation between this
change in the sense of orientation and the intensity of illumination.

On August 8, 4.40 p.m., colonies of Pandorina which had been
in darkness for nearly four days were exposed in strong direct
sunlight. At first they were very inactive and there was no indi-

THE JOURNAL OF EXPERIMENTAL ZOOLOGY, VOL. 27, NO. 3

370 Ss. O. MAST

cation whatever of orientation. But after approximately one
minute it could be seen clearly that they were swimming slowly
from the light. Gradually they became more and more active,
and as they became more active they became more strongly
negative, until at 4.50 p.m. they were swimming rapidly and
fairly directly from the source of light. At 4.55 p.M., they were
moved 4 m. from the window and placed in diffuse light. Here
they promptly became strongly positive. They were then re-
turned to direct sunlight near the window, when they again
promptly became strongly negative. These changes in illumi-
nation were repeated several times and the same results were
obtained each time.

It is thus evident that strong illumination tends to make these
organisms negative and that weak illumination tends to make
them positive. Under certain conditions, however, just the
opposite holds. In previous work this was observed only once
(Mast, ’07, p. 165). In the observations now under considera-
tion it was, however, repeatedly observed both in Volvox and
in Pandorina, and the conditions under which it occurs have
been discovered. This is demonstrated by the results obtained
in the observations described below:

On July 18, Volvox colonies were collected at 7.30 a.M., in a
pool fully exposed to direct sunlight. They were taken to the
laboratory, and put into two finger-bowls. One bowl was put
into total darkness, the other was exposed in strong diffuse day-
light. Thus one group of colonies remained light-adapted,
while the other group became dark-adapted. At 3 p.m., light-
adapted colonies and dark-adapted colonies were put, respectively,
into each of six rectangular observation aquaria. These were
then exposed in the dark-room in light from the 250-watt lamp,
one aquarium containing dark- and one containing light-adapted
colonies side by side in each of the following illuminations, 62.5
m.c., 250 m.c., and 4,000 m.e. (fig. 1). The dark-adapted colonies
were strongly positive in all the illuminations and the light-
adapted were negative in all, but they were clearly more strongly
negative in the lowest intensity than they were in the highest.
In 4,000 m.c. they were only slightly negative; in 250 m.c.

REVERSION IN ORIENTATION TO LIGHT By!

they were clearly more strongly negative. One of the aquaria
was then moved nearer to the lamp into an illumination of 16,000
m.c. The colonies immediately became positive, although not
strongly. The dark-adapted colonies were not tested in this
intensity, but judging from results obtained in numerous other
experiments, one of which is described in detail in the preceding
pages, they probably would have been negative.

These results seem to indicate that long exposure in strong
light produces changes in Volvox which make it negative in
weak and positive in strong light. The following results ob-
tained in observations on Pandorina support this conclusion.

August 4 was a bright clear day. At 11.30 a.m., Pandorina
was taken in abundance from a small puddle at the edge of the
collecting pond. This puddle had been fully exposed to direct
sunlight all forenoon. The specimens collected were taken to the
laboratory and some of them were immediately exposed to direct
sunlight in an observation aquarium, surrounded by water which
was changed from time to time so as to prevent excessive rise
in temperature. They were strongly positive and remained so.
At 3 p.m. the aquarium was placed on the stage of a microscope
in direct sunlight, and a beam of direct sunlight, concentrated
by means of the concave mirror, was thrown up through the
aquarium. The colonies promptly aggregated in this extremely
intense illumination forming a dense mass. At 5 p.m. many colo-
nies were lying on the bottom inactive, but all the rest were
still fairly strongly positive. These results indicate clearly that
under certain conditions Pandorina cannot be made negative
by exposure to intense light. The specimens used in this experi-
ment were unfortunately not tested in weaker light, but judging
from the results of other observations they probably would have
been negative. For example, at 3 p.m., August 11, colonies
-adapted to strong diffuse light were exposed in an illumination
of 16,000 m.c. They were inactive for a few moments and
then became definitely positive. The illumination was then
considerably reduced. The colonies continued to proceed toward
the light, but only for a few moments, when practically all of
them turned through 180 degrees and proceeded from the light.

372 S. O. MAST

This was repeated many times and the same results were per-
sistently obtained. Thus itisclear that, under certain conditions,
Pandorina is definitely positive in strong and definitely negative
in weak light. What are the conditions under which this occurs?

It was repeatedly observed that colonies exposed in strong
diffuse light, in which they were strongly positive, usually become
negative in the evening at the approach of twilight. This sug-
gests that the phenomena may be associated with the night and
day variations in illumination and that it may be analogous to
the so-called sleep movements in higher plants. The fact, how-
ever, that it does not occur in dark-adapted colonies and in colo-
nies which have been exposed to relatively weak light does not
support this contention.

The physiological condition in which the colonies are positive
in strong and negative in weak light is, in all probability, de-
pendent upon the amount of light energy received in the immedi-
ate past as the following results indicate.

At 8 a.m., August 23, dark-adapted specimens in observation
aquaria were exposed in illuminations of 16,000 m.c., of 4,000
m.c. and in lower intensities. Twenty minutes later, 8.20 A.M.,
a few of the small colonies in 16,000 m.c. were negative, the
rest were all strongly positive. The aquarium was left in this
illumination in the dark-room and observations were made every
hour. The temperature remained practically constant through-
out the day. At 9 and 10 a.m., the reactions were practically
the same as they had been at 8.20 a.m. At 11 a.m. practically
all of the small colonies and a few of the large ones were negative.
More and more continued to become negative, until at 3 P.M.,
practically all were negative. At 4 p.m. a few of the colonies
were scattered, all the rest were negative. From this time on
gradually more and more became scattered. At 7 P.M. many of
the colonies were scattered, some were negative and some were
distinctly positive. At 8 p.m. there were more positive colonies,
and at 9 p.m., when the experiment was closed, there was a
large positive collection.

In the aquarium in 4,000 m.c. the colonies were at first all
positive. An hour later, 9 a.m., a few were negative. From

REVERSION IN ORIENTATION TO LIGHT ave

this time on gradually more became negative, until at 6 P.M.
nearly all were negative. At 9 p.M., when the experiment-.was
closed, more of the colonies were scattered than earlier, but
there were no positive colonies. In 62.5 and 250 m.c. many of
the colonies became negative, but some of them remained positive
throughout the experiment. In all intensities lower than 62.5
m.c., none of the colonies became negative at all.

This experiment demonstrates that a certain intensity of
light is necessary to induce reversion in the sense of orientation
from positive to negative, that the time required depends upon
the intensity, and that in strong illumination the colonies, after
having become negative, become positive again if they are ex-
posed long enough. Whether or not they continue positive in-
definitely after the last reversion was not ascertained, nor was
it ascertained in this experiment whether or not they would have
been negative in low illumination after they had become positive
in high. But in all probability these colonies would have re-
mained positive in strong and would have been negative in weak
illumination indefinitely, for negative orientation in weak light
was never observed in dark-adapted colonies; it was observed
only after long exposure to intense light, and continued exposure
to such light failed to make the colonies negative after they had
once become positive in this light.

The changes that occur in the reactions of Pandorina as indi-
cated by the results described above may be visualized by means
of a graph presented in figure 2. This graph indicates that
dark-adapted colonies of Pandorina when first exposed to light
are neutral for a short time, i.e., they do not orient (fig. 2, a—b),
that they then become positive, increasing rapidly to a maximum
(b-c) then decreasing slowly to a minimum (c-d), after which
they become negative, passing through a maximum at e, and that
they finally become positive again (f-g). It is probably during
this last period that the colonies are positive in strong and nega-
tive in weak light. ©

As previously stated, this reaction is found only. in light-
adapted colonies, never in dark-adapted ones. What, now, is
the difference in different illuminations in the reaction of colonies
in these two states?

374 Ss. O. MAST

Numerous observations were made to ascertain this. In all
of these observations dark-adapted colonies were put into one
rectangular aquarium and light-adapted ones into another.
These two aquaria were then placed side by side at the desired
distance from the source of light and the reactions of the colo-
nies compared. Frequently three sets of such aquaria were
exposed in different illuminations at the same time.

The results obtained appear to be. extremely contradictory.
Usually the light-adapted colonies were found to be more strongly

. 3.00 8.00
8 20 8.40 p.m

Fig. 2 Graph representing changes in the sense of orientation in dark-adapted
Pandorina exposed to constant illumination of high intensity. The horizontal
axis represents time, the vertical axis degree of orientation, above the base line
positive, below the base line negative. The graph indicates that,Pandorina was
first neutral (a—b) then became positive, increasing to a maximum (b-c) then de-
creasing to a minimum (c—d), after which it became negative, increasing to a maxi-
mum (d-e), then decreasing to a minimum (e-f), after which it again became
positive (f-g). After the colonies reach the last stage they are probably in a
state such that they are positive in strong and negative in weak illumination.

positive in strong and less strongly positive in weak light than
the dark-adapted ones, but in many instances precisely the oppo-
site was found to be true and in some there was no appreciable
difference in the reaction. Moreover, in a given intensity, e.g.,
4,000 m.c., the light-adapted were in some instances more strongly
positive and in others less strongly positive than the dark-
adapted colonies. How can these puzzling results be explained?

Dark-adapted specimens, as we have seen, are frequently neu-
tral when first exposed to light, then they become strongly posi-
tive and later negative. If they are in the strongly positive
stage when their reactions are compared with those of light-

REVERSION IN ORIENTATION TO LIGHT 315

adapted specimens, they are likely to be more strongly positive
than the light-adapted specimens; whereas if they are in the
negative stage they will be found to be less strongly positive.
Other contradictory features in these results can be similarly
explained.

The cause of the passage through the various stages mentioned
above, especially the return to positive orientation after having
been negative, is not known. It may be associated with what
is ordinarily called acclimatization or adjustment or with some
sort of a periodicity. However this may be, reversion is un-
doubtedly associated with physiological processes or states and
these processes are dependent both upon time and intensity
of illumination. This the evidence presented clearly indicates.
How are these processes related to the amount of light energy
received?

RELATION BETWEEN REVERSION IN ORIENTATION AND THE
QUANTITY OF LIGHT ENERGY

The relation between reversion and the amount of light energy
received was ascertained as follows: Colonies of Pandorina
adapted to darkness or to weak light were put into each of
seven observation aquaria. These were then exposed in various
intensities of light from the 1,000-watt lamp as indicated in
table 1. Observations were then made, first at intervals of
thirty minutes and later at intervals of one hour. After each
observation the position of the colonies in each aquarium was
recorded. From these records the approximate time at which
reversion occurred in each intensity was ascertained. The re-
sults thus obtained appear in table 1.

When first exposed the colonies in all of the aquaria were
neutral and relatively inactive. Gradually they became more
and more active, and as they became more active they began to
swim toward the side of the aquarium nearest the source of light,
where in the course of several minutes practically all had col-
lected in a dense mass. This occurred first in the aquarium in
the highest and last in that in the lowest illumination. Later

376 S. O. MAST

the colonies began to scatter, evidently becoming neutral again.
Thus they remained for some time, then they became negative,
and finally collected along the side of the aquarium farthest
from the source of light as definitely as they had formerly col-
lected on the opposite side. This again occurred first in the
highest and last in the lowest illumination.

In all of the aquaria the smaller colonies invariably became
negative before the larger ones. Thus there was often found in

TABLE 1

Relation between time of exposure, intensity of illumination and reversion in
orientation

ENERGY IN

e TIME IN HOURS |METER-CANDLES

“ient in | anyesaon | ==0ersep 70! | Gone
METER-CANDLES OCCURRED REVERSION INDUCE

REVERSION

August 22. Specimens 16,000 .0 3.45 P.M. 5 80 000
which had been in weak 4,000.0 4_45 6 24,000
light several days 1,000.0 5.45 a 7,000
250.0 6.45 8 2,000
111.0 6.45 8 888
Dia 6.45 8 444

20.4 (?) ? 160(?)
August 23 Same speci- 16,000 .0 3 7 112,000
mens after having been 4,000 .0 4 8 32,000
in darkness overnight 1,000 .0 7 10 10,000
250.0 8 11 2,750

111.0 9(?) 13(?) 1,443(?)

Oe 9 No reversion
20.0 9 No reversion
|

aquaria a very definite positive collection and at the same time
an equally definite negative collection. Later, however, prac-
tically all of the colonies became negative, and the record in the
table indicates the time when this occurred in each aquarium.
The table mentioned contains the results obtained in two ex-
periments made on two successive days with the same organisms.
By referring to this table it will be seen at once that reversion
from positive to negative orientation depends upon the intensity
of illumination and upon the time of exposure, but that the energy

REVERSION IN ORIENTATION TO LIGHT Tes

required to induce reversion varies with the intensity of the
illumination and with the condition of the colonies. In one
experiment it required in all intensities much more energy than
it did in the same intensities in the other and in both experiments
it required much more energy in the higher than in the lower
intensities. In one experiment no reversion was observed in illu-
minations below 250 m.ec., and longer exposure probably would
not have induced it, for at the close of the experiment, 9 P.M.,
the colonies were inactive. In the other experiment reversion
was observed, to some extent, in the lowest illumination tested,
20.4 m.e. The question as to whether or not it occurs in all
intensities that induce positive orientation is consequently not
definitely settled.

Why it requires more energy to induce reversion from positive
to negative orientation in strong than it does in weak light is
not clear. Itis, however, well known that in Euglena and Volvox
heat and light energy have opposite effects on reversion (Mast,
"11, p. 300). The same is true for Pandorina as we shall dem-
onstrate later. Now, a certain amount of light which is absorbed
is doubtless transformed into heat. This probably occurs in all
illuminations in the same proportion, but in the lower illumina-
tions it occurs so slowly that radiation may have relatively a
much greater effect than in the higher. Consequently, the heat
produced would be more effective in the higher illuminations than
in the lower, and since heat tends to make the colonies positive,
it would require more light energy to overcome its effect in the
higher than in the lower illuminations. The value of this sug-
gestion could doubtless be ascertained by studying the effect of
different regions in the spectrum on reversion.

RELATION BETWEEN REVERSION IN ORIENTATION AND THE TIME
RATE OF CHANGE IN ILLUMINATION

In the experiments just discussed, it required to induce rever-
sion, sufficient time to indicate that it is dependent upon the
quantity of energy received. Under certain circumstances, re-
version is, however, of such a nature that it appears to be asso-

378 Ss. O. MAST

ciated with the time-rate of change in illumination rather than
with the quantity of light. For example, on August 8 colonies
of Pandorina which had been in darkness four days were exposed
to direct sunlight at 4.40 p.m. They were inactive for about
one minute, then they began to swim, slowly at first and gradu-
ally more and more actively, and in practically every case from
the light. They were definitely negative. The observation aqua-
rium was now moved 4 m. from the window. Here the colo-
nies were strongly positive. This change in illumination was
repeated several times with the same results. The aquarium
was then exposed in direct sunlight near the window a few centi-
meters from the diffuse light. The colonies soon began to swim
rapidly from the light. The microscope was then carefully
moved into the diffuse light without changing the distance from
the window. ‘The colonies immediately became strongly positive,
but after they had proceeded toward the window about 1.5
e.m., they became neutral, and approximately one minute later
they were strongly negative again. The aquarium was now re-
turned to direct sunlight. The colonies remained negative.
They were then again moved into diffuse light where they im-
mediately again became strongly positive, than neutral and later
negative. This change in illumination was repeated many times
and the same results were always obtained.

Now, the reversion from negative to positive orientation ob-
served in this experiment, after sudden reduction of intensity,
was in all probability dependent upon the time-rate of change in
illumination, for without any further change the colonies, in the
course of about one minute, again became negative. This
seems clearly to indicate that if the reduction had consumed
sufficient time there would have been no reversion.

EFFECT OF THE AGE OF THE COLONIES ON REVERSION

In the preceding section it was pointed out that in the experi-
ments on the relation between the intensity of the illumination
the smaller colonies of Pandorina invariably became negative
before the larger ones did. No observations in reference to this

REVERSION IN ORIENTATION TO LIGHT 379

were made on Volvox, but it was repeatedly observed in various
cultures of Pandorina, especial'y in those left uncovered for
some days, permitting evaporation. |

Whether or not the younger colonies in dark-adapted cultures
exposed to light became active and positive before the older ones
was not ascertained.

EFFECT OF PHOTOSYNTHESIS ON REVERSION IN THE SENSE OF
ORIENTATION

It is well known that acids added to the culture solution tend
to make Volvox and similar organisms positive in their reactions
to light and that under certain conditions low illuminations also
tend to make them positive, while high il'uminations tend to make
them negative. In low illuminations there is, owing to limited
photosynthesis and continued respiration, a tendency toward an
accumulation of carbon dioxid, result ng in an increase in acidity,
while ‘n high illumination there is, owing to rapid photosynthesis,
a tendency toward a reduction in carbon dioxid. This seems to
ndicate that the tendency toward positive orientation n low and
negative orientation in high illumination may be dependent upon
photosynthesis. If this is true, then red and yellow light in
which photosynthesis is relatively strong should be more effective
in producing reversion in the sense of orientation than blue and
green in which photosynthesis is relatively weak. Numerous
observations on both Volvox and Pandorina adapted to the colors
mentioned were made as follows:

Some of the colonies to be tested were put into jars in each
of four black light-tight boxes containing a large window made
of blue, green, yellow, and red glass, respectively. Others were
put into jars in absolute darkness and still others into jars in
strong diffuse sunlight. After having been in these conditions
eight hours or longer specimens were taken from each jar and
put respectively into six observation aquaria. These aquaria
were then placed side by side in the same illumination in the
dark-room, others similarly treated were placed in other illumina-
tions. In this way the reactions in different illuminations of the

380 Ss. O. MAST

colonies adapted to the various colors could readily and accu-
rately be compared with each other and with those of the colonies
adapted to darkness or to strong diffuse light.

Without going into details regarding the results obtained, it
may be said that in practically every test the red- or yellow-
adapted colonies responded essentially like dark-adapted colonies
and the blue- or green-adapted ones responded essentially like
light-adapted colonies. The red- and yellow-adapted colonies
were usually negative in strong and positive in weak illumination,
never the reverse; while the green- or blue-adapted colonies, like
light-adapted ones, were frequently positive in strong and
negative in weak illuminations.

The colors to which these colonies were adapted were not
spectroscopically tested and the illumination was not measured.
The question, consequently, arises as to whether or not, under
the conditions of the experiments, photosynthesis in the red and
the yellow was actually greater than in the blue and the green.
This question was answered as follows:

A given amount of pond-water taken from a vessel containing
colonies equally distributed was put into each of six 100-ce. wide-
mouthed bottles. One of these bottles was now placed in each
of the four boxes mentioned above, i.e., in the red, the yellow,
the green, and the blue light used in the preceding experiments;
one was put into darkness and the remaining one into strong
diffuse light. After having been in these illuminations one or
more days a given amount of solution was removed from each
bottle and put into a test-tube. A drop of neutral red was now
added to the solution in each tube. This solution was found to
be distinctly akaline in every case. Hydrochloric acid was then
added to each tube until all were practically neutral and the
same in color. The solution in the tube which required the
greatest amount of hydrochloric acid was, of course, the most
strongly alkaline, and in this solution photosynthesis had been
most rapid, for carbon dioxid is consumed in the process of pho-
tosynthesis and the alkalinity is dependent upon the amount of
carbon dioxid present.

REVERSION IN ORIENTATION TO LIGHT 381

There was considerable difference in the results obtained in
the different tests, but taken as a whole they show conclusively
that photosynthesis was most rapid in the diffuse white light and
less rapid in the other illuminations in the following order:
yellow, red, blue, green, darkness.

These results, consequently, demonstrate that photosynthesis
was more rapid in the red and the yellow light used in these
experiments than in the blue and the green. And since the blue
and the green were more effective in producing reversion in the
sense of orientation than the red and the yellow, it is evident
that the effect of light on reversion is not determined by photo-
synthesis unless the photosynthesis which occurred during the
exposure to white light in making the tests in the dark-room is
involved. This, however, does not seem probable since all of
the aquaria were exposed to the same illuminations. Moreover,
essentially the same results were obtained in observations in
which the aquaria were exposed to green light produced by means
of passing the beam of light in the dark-room through a satu-
rated solution of chlorophyl in 95 per cent alcohol. Now, since
photosynthesis is reduced to a minimum in green light produced
in this way and since the reactions of the colonies in the different
aquaria were essentially the same as in white light, it is evident
that photosynthesis during exposure in the dark-room is of no
practical consequence. The conclusions, therefore, that rever-
sion in the sense of orientation is not determined by photosynthe-
sis appears to be valid.

The region in the spectrum of maximum stimulating efficiency
lies in the green near wave-length 524 uu for Pandorina (Mast, ’17,
p. 509) and in the blue-green near wave-length 494 uy for Volvox
(Laurens, ’18). The results of the experiments described above
indicate that the regions of maximum efficiency in producing re-
version in the sense of orientation in Pandorina and Volvox prob-
ably have the same location as the regions of maximum stimu-
lating efficiency. If this is true, it is probable, although by no
means certain, that the processes involved in stimulation are
also involved in reversion.

382 Ss. O. MAST

EFFECT OF TEMPERATURE ON REVERSION

In nearly all of the organisms that have been tested increase
in temperature tends to induce positive and decrease in tempera-
ture negative orientation to light There are only a few forms
in which changes in temperature appear to have the opposite
effect, but there are a considerable number in which changes in
temperature have no effect on the sense of orientation (Mast,
"11, pp. 272-279).

The sense of orientation is probably not specifically related
to the temperature in any of the forms studied. For example, the
results obtained in observations on Euglena (Mast, ’11, pp. 274—
277) indicate that this form may be, under certain conditions,
negative or positive in practically all temperatures in which it
orients at all. .

The effect of changes in temperature on the sense of orienta-
tion in Volvox and Pandorina was ascertained as follows: The
colonies were mounted on a Pfeifer warming-stage under a bin-
ocular. This stage was so arranged that hot or cold water could
be passed through it at any rate desired. The whole apparatus
was then exposed to constant illumination of the desired intensity.

The results obtained are in harmony with those obtained in the
study of Euglena. The reactions of Volvox were, however, only
superficially studied. Without going into details, it may be said
that the results clearly show that arise in temperature tends to
produce positive, and a fall in temperature negative photic ori-
entations, and that the sense of orientation is not directly de-
pendent upon the temperature. For example, in one experiment
it was found that Pandorina continuously exposed in a given
illumination was, at 10.43 a.M., negative in 16 degrees, neutral in
17 degrees, and positive in 18 degrees; at 11.19 a.m., the same
colonies were negative in 13.5 degrees, neutral in 14 degrees, and
positive in higher temperature, and at 11.28 a.m. they were
positive in 14 degrees. Thus the point at which they became
positive changed from 18 degrees at 10.43 a.m. to 14 degrees
at 11.28 a.m.

REVERSION IN ORIENTATION TO LIGHT 383

EFFECT OF CHEMICALS ON REVERSION

It is well known that acids and some narcotics tend to make
many organisms that orient to light, photopositive. Salts and
alkalis, on the other hand, rarely have any effect on the sense of
orientation. In a recent paper on Spondylomorum (’18) it was
fairly clearly demonstrated that the effect of the addition of
acids is due to the reduction in the alkalinity of the culture
medium and not to the acids as such. The results obtained in
experiments on Volvox and Pandorina support this contention
and they show that the response of the organism is not specifically
dependent upon the chemical constitution of the surrounding
medium.

The effect of acid on the sense of orientation in Volvox and
Pandorina is in all essentials precisely the same as it is in Spon-
dylomorum (Mast, ’18). If a trace of acid is added to a solution
containing negative colonies they become strongly positive, re-
main so a few moments and then become negative again. If
‘more acid is now added they again become positive and later
negative, just as they did after the first addition of acid. Thus
they continue to become positive and negative after each addition
of acid until the solution becomes fatal.

The water in the pond in which the Volvox and the Pandorina
used in these experiments appeared gave, in every instance, a
very definite alkaline reaction with neutral red, and when acid
was added the sense of orientation was reversed long before the
alkalinity was neutralized. In fact, sufficient acid to give even
the slightest acid reaction invariably proved. fatal. This seems
to indicate that reversion in these forms, just as in spondylo-
morum, is due to a reduction in alkalinity, and not to the effect
of acid as such. It also indicates that the sense of orientation
is not directly related with the concentration of the alkalis.

The amount of reduction in alkalinity required to produce
reversion varies with the concentration of the solution and the
physiological state of the organisms. It is usually very small.
For example, in one experiment titration against HCl showed
that the water in which the colonies (Pandorina) lived was 0.0019

384 ; Ss. O. MAST

N alkaline. In this solution, under the conditions of the experi-
ment, the colonies were strongly negative. After the addition of
sufficient acid to make the colonies positive, the solution was
0.0015 N alkaline, and in a few other tests the reduction necessary
was even less. In some it was, however, considerably more.
This shows that the condition of the organism is involved inthe
process.

In Spondylomorum it was found that reduction in alkalinity
produced by the addition of distilled water had little, if any, effect
on the sense of orientation (Mast, ’18, p. 512). Similar results
were obtained in Volvox and Pandorina. Both of these forms
live for several days in chemically pure water and respond nor-
mally, but only in relatively few tests was there any indication
whatever of reversion due to the dilution of pond water with
pure water, and in these tests the effect of the dilution was very
slight. But that there was actually an effect was shown by the
fact that in diluted pond water it required considerably less acid
to induce positive reactions than it did in normal pond water.
For example, in a given test in a solution consisting of one part
of pond water and nine parts of pure water, it required only one-
third as much acid to induce reversion as it did in the pond water.
The dilution consequently seems to tend to make the colonies
positive, but not in proportion to the degree of dilution.

If a reduction in alkalinity produces reversion from negative
to positive orientation, it seems reasonable to expect the reverse
if the alkalinity is increased by means of adding alkalis. This,
however, does not appear to occur. I repeatedly added sodium
hydrate to solutions containing positive colonies of Volvox or

Pandorina, but never obtained any indication of reversion except
in case the alkali was added immediately after the colonies had
been made positive by the addition of acids, and in such cases
there was always some question as to the actual effect of the
alkali. However, an increase in the concentration of the solu-
tion due to slow evaporation clearly tends to make the colonies
negative. These results are in full harmony with those obtained
on Spondylomorum (Mast, ’18, p. 512).

REVERSION IN ORIENTATION TO LIGHT 385

Chloroform has the same effect on reversion that acids have,
but ether and alcohol have very little, if any effect. With
ether, no clear case of reversion was obtained at all, and with
aleohol reversion occurred only in colonies that were almost
neutral. The concentration of alcohol necessary to kill these
colonies, especially Volvox, is very surprising. In equal parts
of pond water and 96 per cent alcohol they live for several hours.

The cause of the effect of anesthetics on reversion is not known,
but it is certainly not dependent upon reduction in alkalinity,
for the chloroform used was clearly slightly alkaline. This
- question will be discussed in the following section.

The evidence presented thus far indicates that the sense of
orientation is dependent upon the constitution of the culture
medium. This contention is further supported by the fact
that ordinarily if colonies are negative in one jar and positive
in another in the same illumination, as often happens, the solu-
tion in the former is more strongly alkaline than that in the
latter. This is, however, by no means always true, and in some
instances in which it was found to be true it was also found that
the colonies retained their sense of orientation after they were
interchanged. That is, the colonies which had been positive in
the weaker solution were now positive in the stronger, and those
which had been negative in the stronger were now negative in
the. weaker solution. This demonstrates conclusively that the
state of the colonies may determine the sense of orientation.

DISCUSSION

It has been demonstrated in the preceding pages that decrease
in illumination, decrease in alkalinity, increase in temperature,
increase in anesthetics, and increase in the age of the colonies
all tend to make them positive. It has also been demonstrated
that light-adapted colonies are, under certain conditions, positive
in strong and negative in weak light, and that reversion at times
depends upon the time-rate of change in illumination. It has,
moreover, been demonstrated that the region in the spectrum
of maximum efficiency in producing reversion probably coin-
cides with that for maximum stimulating efficiency. Reversion

THE JOURNAL OF EXPERIMENTAL ZOOLOGY, VOL. 27, No. 3

386 Ss. O. MAST

in the sense of orientation, consequently, can be induced by a —
number of different factors, and this seems to indicate, as con-
cluded in the preceding paper in this series (’18, p. 518) that it
is due to some specific physiological change which can be pro-
duced by any one of the factors referred to.

The fact that the region of maximum efficiency for reversion
probably coincides with that for stimulation indicates that the
physiological phenomena associated with these two processes
may be the same. Stimulation, however, is usually if not al-
ways accompanied with an increase in permeability and a de-
crease in electrical potential. Reversion, then, if our contention
is correct, should also be accompanied with changes in permea-
bility and all of the factors which produce positive orientation
should induce changes in one direction while all those which
produce negative orientation should induce changes in the oppo-
site direction. As previously stated, decrease in illumination,
decrease in alkalinity, increase in anesthetics, increase in tem-
perature, and increase in age all tend to produce positive orienta-
tion. What effect have these factors on permeability?

Krabbe (’96) found in stems of Helianthus annuus that a rise
in temperature greatly increases permeability, and Rysselberghe
found the same -in experiments on Tradescantia and Spirogyra
(Tréndle, ’10, p. 173). He maintains that the permeability for
water, potassium nitrate, glycerine and urea increases slowly from
0 to 6 degrees, more rapidly from 6 to 20 degrees, and again more
slowly from 20 to 30 degrees, and that it is eight times as rapid
at 30 degrees as it is at zero. This shows clearly that increase
in temperature produces increase in permeability. We have
demonstrated, as stated above, that increase in temperature
causes positive photic orientation. Therefore, if reversion is due
to change in permeability, positive orientation must be associated
with increase in permeability, and if this is true then all of the
factors which produce positive orientation should cause increase
in permeability.

The work of Lillie (09, p. 248) indicates that this is true for
decrease in alkalinity; Tréndle maintains that moderate illumi-
nation, such as favors positive orientation, causes increase in

REVERSION IN ORIENTATION TO LIGHT 387

permeability, and that strong illumination, in which negative ori-
entation is usually found, causes decrease in permeability; and
according to McClendon (17, p. 141), a considerable number of
investigators hold that anesthetics in low concentration stimu-
late. The concentrations of anesthetics that produce reversion,
therefore, probably cause increase in permeability, although Os-
terhout (713) in his ingenious experiments did not discover any
such effect. We thus have considerable evidence in favor of the
idea that positive orientation is dependent upon increase in per-
meability. However, if this is true, then permeability ought,
under certain conditions, depend upon the time-rate of change
in illumination; it ought to be greater in old than in young colo-
nies and it ought, under certain conditions, be greater in intense
than in moderate illumination. Moreover, all conditions which
cause increase in permeability, e.g., NaCl, ought to produce posi-
tive orientation, while all those which cause decrease in permea-
bility ought to produce negative orientation. With these ques-
tions, concerning which there is at present no trustworthy
evidence, I hope to deal in the following paper in this series.

Some investigators maintain that in many of the unicellular and
colonial forms orientation is due to a series of shock-reactions;
others maintain that there is no definite relation between shock-
reactions and orientation. However this may be, it is certain
that Euglena and'Gonium and probably all other similar organ-
isms usually, if not always, respond with the shock-reaction to a
sudden increase in illumination if they are negative and to a
sudden decrease if they are positive. That is, the same reaction
may be induced either by a sudden increase or by a sudden de-
crease in illumination, depending upon whether the organisms
are negative or positive.

If shock-reactions are due to increase in permeability then
increase in permeability must be due, in negative specimens, to
increase and, in positive specimens, to decrease in illumination.
And if orientation is due to shock-reactions, then reversion in
orientation must be due to the phenomena which produce this
change in the cause of increase in permeability. In relatively
high temperature or moderate illumination and in solutions rela-

388 Ss. O. MAST

tively weak in alkalinity or relatively strong in narcotics, in all
of which orientation is positive and permeability relatively high,
a sudden decrease in illumination must produce an increase in
permeability, and in relatively low temperature or intense light
and in solutions strong in alkalinity or anesthetics, all of which
tend to produce negative orientation and low permeability, a
sudden increase in illumination must produce increase in permea-
bility.

There is at present no evidence which bears on these problems.
I have stated them in order to emphasize the fact, that whether
orientation depends upon shock-reactions or not, any theory
that accounts for reversion in orientation should account for the
changes in the cause of the shock-reactions which accompany it.

SUMMARY

1. The reactions to light in Volvox and Pandorina are prac-
tically the same. Both forms orient fairly precisely and both
may be either negative or positive.

2. Dark-adapted colonies are usually positive in weak and
negative in strong illumination, never the opposite. Light-
adapted colonies are sometimes positive in strong and negative
in weak illumination.

3. If dark-adapted colonies are exposed to continuous illumi-
nation they are neutral for a short time, then they become posi-
tive, passing through a maximum, after which they become
neutral again, then they become negative, passing through a maxi-
mum, after which they again become neutral and finally positive
again. After they have reached this final state they remain posi-
tive no matter how intense the light may be, and they probably
are negative in weak light.

4. The time required to pass through these various stages de-
pends upon the intensity of the light. The higher the illumina-
tion, the shorter the time. Reversion is, therefore, dependent
upon the time of exposure’ as well as upon the intensity of the
illumination. But it requires much more energy to induce re-
version in high that it does in low illumination.

REVERSION IN ORIENTATION TO LIGHT 389

5. Under certain conditions, sudden decrease in illumination
makes negative colonies momentarily positive. This change in
the sense of orientation is dependent upon the time-rate of change
in the intensity of the illumination.

6. Reversion is not primarily dependent upon photosynthesis.
Red and yellow light in which photosynthesis is relatively strong
have little effect on reversion, while green and blue, in which
photosynthesis is relatively weak, are nearly as effective as white
light.

7. The rays of light which have the greatest stimulating
efficiency (green and blue) are the most potent in producing
reversion in the sense of orientation.

8. Increase in temperature causes negative specimens to be-
come positive and decrease causes the opposite, but neither the
degree nor the extent of change in the temperature is specific in
its effect. Under certain conditions, the colonies may be nega-
tive or positive in practically all temperatures in which they
orient at all.

9. Alkalis have little, if any effect on reversion. Acids and
some anesthetics, especially chloroform, cause negative colonies
to become strongly positive, but reversion is not specifically de-
pendent upon the concentration of the chemicals. Colonies
which are positive in a solution having a given chemical concen-
tration may be negative in the same solution or even in a weaker
solution. The effect of acids is probably due to the accompany-
ing reduction in the alkalinity of the cultural solution.

10. The sense of orientation is dependent upon the physio-
logical state of the colonies as well as upon the constitution of
the culture medium.

11. The sense of orientation is dependent upon the age of the
colonies. Young colonies are more likely to be negative than
old ones. In a given solution the young specimens frequently
collect at the side of the dish farthest from the light while the
old ones collect at the opposite side.

12. Reversion in orientation is probably associated with
changes in permeability, positive orientation being associated
with an increase and negative orientation with a decrease in
permeability. |

390 S. O. MAST

LITERATURE CITED

KrasseE, G. 1896 Uber den Einfluss der Temparatur auf die osmotischen Pro-
zesse lebender Zellen. Jahrb. f. wiss. Bot., Bd. 29, S. 441-498.

Laurens, H, anp Hooxer, H. D. 1918 The relative sensitivity of Volvox to
spectral lights of equal radiant energy content. Anat. Rec., vol. 14,
pp. 97-98.

Linuiz, R.S. 1909 On the connection between stimulation and changes in the
permeabilty of the plasma membranes of the irritable elements. Sci.,
vol. 30, pp. 245-249.

Mast, 8S. O. 1907 Light reactions in lower organisms. IJ. Volvox. Jour.
Comp. Neur. and Psy., vol. 17, pp. 99-180.
1911 Light and the behavior of organisms. New York, 386 pp.
1917 The relation between spectral color and stimulation in the lower
organisms. Jour. Exp. Zo6l., vol. 22, pp. 471-528.
1918 Effect of chemicals on reversion in orientation to light in the
colonial form, Spondylomorum quarternarium. Jour. Exp. Zodl., vol.
26, pp. 503-520.

McCienpon, J. F. 1917 Physical chemistry of vital phenomena. Princeton,
240 pp.

OstERHOUT, W. J. V. 1913 The effect of anesthetics upon permeability. Sei.,
vol. 37, pp. 111-112.

RYSSELBERGHE, Fr. vAN 1902 Influence de la température sur la perméabilité
du protoplasme vivant pour l’eau et les substances dissoutes. Rec. de
l’Inst. bot., Univ. de Brux., T. 5, p. 207.

TrRONDLE, A. 1910 Der Hinfluss des Lichtes auf die Permeabilitat der Plasma-
haut. Jahrb. f. wiss. Bot., Bd. 48, S. 170-282.

Numerous other references on this subject may be foundin Washburn, Animal
Mind, 917, pp. 200-214; Holmes, Studies in Animal Behavior, 1916, pp. 116-119,
and Mast, Light and the behavior of organisms, 1911, pp 264-287.

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Los efectos de la adrenina sobre la emigracién del pigmento en
los melandéforos de la piel y en las células pigmentarias
de la retina de la rana.

El presente estudio se ha efectuado sobre Rana pipiens, com-
parando los resultados obtenidos con los producidos en otras
especies. El autor ha comprobado los efectos de la luz y la oseuri-
dad sobre la rana normal. Los efectos de la adrenina sobre el
pigmento de las células de la retina fueron estudiados en ranas
sometidas a la accion de la luz y en otras colocadas en la oscuridad
durante varias horas. En las ranas sometidas a la accién de la
luz, el pigmento aparece difundido, como sucede normalmente en
estas condiciones, pero en las ranas que han permanecido algun
tiempo en la oscuridad también aparecia difundido, demostrando
esto que la adrenina produce la difusién de dicha substancia.
Puesto que los efectos de la adrenina y la luz son los mismos no
pueden ser estudiados en las ranas colocadas a la luz, pero en las
que han permanecido cierto tiempo en la oscuridad, que normal-
mente produce la contraccién del pigmento, la influencia de la
adrenina se hace notar; 4leanza el mdximum de intensidad a los
siete minutos y sus efectos no cesan hasta pasadas unas cinco
horas. Después de comprobar los puntos mencionados, el autor
empleé diversas concentraciones y ha encontrado que con solu-
ciones tan diluidas como la de 1: 5,000,000, la influencia de la
adrenina sobre el pigmento puede comprobarse. El pigmento de
los melan6foros de la piel fué examinado bajo las mismas condi-
ciones que el de la retina y se pudo comprobar que la adrenina
produce su contraccién a la luz, en vez de provocar su difusi6n.

Translation by Dr. José F. Nonidez,
Columbia University.

AUTHOR’S ABSTRACT OF THIS PAPER ISSUED
BY THE BIBLIOGRAPHIC SERVICE, DECEMBER 9

THE. EFFECT OF ADRENIN ON THE PIGMENT
MIGRATION IN THE MELANOPHORES OF
THE SKIN AND IN THE PIGMENT
CELLS OF THE RETINA OF
THE FROG!

ANDREW JOHNSON BIGNEY

The purpose of this paper is to discuss the influence of adrenin
on the pigment migration in the dermal melanophores and the
retinal pigment cells of the frog. It seems to be fairly well es-
tablished by the work of a number of investigators that adrenin
does induce a migration of the pigment granules from the cell
processes into the body of the cell of the dermal melanophores of
fishes, amphibians and reptiles. This has been proved in the
frog by Corona e Moroni (’98) and by Lieben (’06). According
to Klett (08), the retinal pigment of the frog also migrates into
the body of the cell under the influence of adrenin, but Fujita
(11) states that this drug produces just the opposite effect on
this pigment. In order to clear up this uncertainty and to de-
termine the relation of the retinal migration to that of the skin,
the present investigation was undertaken. The work was sug-
gested by that of Redfield (17) and was done under the direction
of Prof. G. H. Parker, to whom I make due acknowledgment for
his many valuable suggestions.

The frogs used in these experiments were almost entirely Rana
pipiens Schreber, though a few of Rana clamitans Latreille were
used, but there was no difference seen in the migration of the
pigment in either the skin or the retina of these two species.
The adrenin employed was that prepared by Parke, Davis &
Co. and sold under the name of “Adrenalin Chloride in strength
1 to 1000.”

1 Contributions from the Zoélogical Laboratory of the Museum of Compara-
tive Zoélogy at Harvard College. No. 314.

391

392 ANDREW JOHNSON BIGNEY =

In testing the effects of this drug on the melanophores of the
skin, preliminary experiments were made on the effect of light
and darkness on these cells. This was merely to confirm the
work of previous investigators that in the light the pigment
expands and in the dark it contracts. This action takes place
in an hour or so; but to be sure that there was a complete migra-
tion, the frogs were kept either in the light or in the dark for
six hours.

To determine the influence of adrenin on this pigment, two
frogs were placed in strong, diffused daylight for six hours,
after which 0.06 cc. of a solution of adrenin one part in a thousand
was injected into the dorsal lymph spaces of each animal. The
frogs were then kept a quarter of an hour in the light and killed
and a small portion of the skin from the hip was removed and
prepared for microscopic examination by fixing it in Perenyi’s
fluid and mounting it, unstained, by the usual method. In both
instances the melanophores were found to be strongly retracted,
which was opposite to the state induced by light.

Two more frogs were next treated in the same manner, but
they were kept in the dark, and upon examining their skin the
melanophores were found retracted, thus showing that the adre-
nin produces no other effect in the dark, These results harmo-
nize with the investigations of previous workers.

To determine the strength of the adrenin necessary to produce
these reactions, a number of frogs were kept in the light the
usual time, then injected with the adrenin in concentrations,
one part in ten thousand, one in fifty thousand, and one in five
hundred thousand. The frogs were killed at the end of an
hour. Those with one part in ten thousand had the pigment al-
most completely retracted, while those with one in fifty thousand
had slght retraction, and those with one in five hundred
thousand showed no effect.

The same concentrations were used on frogs kept in the dark
and in all instances the melanophores remained retracted, as
was to have been expected.

To determine how long the influence of the adrenin lasted, the
usual amount, 0.06 cc. of a solution one in a thousand was in-

EFFECT OF ADRENIN ON PIGMENT IN FROG 393

jected into the lymph spaces of a number of frogs kept in the
light and they were killed at varying intervals from seven min-
utes to five hours. Complete retraction was found to last for
about two hours; at three hours, moderate contraction was noted,
while in four to five hours retraction was replaced by full expan-
sion, thus showing that the influence of the adrenin had com-
pletely passed off.

The migration of the retinal pigment under the influence of
light and darkness is well known to be outward from the cell in
light and into the cell in the dark. To test the influence of adre-
nin on these pigment cells, eight frogs that had been kept in the
light for five hours were injected each with 0.06 cc. of adrenin
solution one in a thousand and were killed in pairs, the first pair
after fifteen minutes’ exposure to the drug, the second after
thirty minutes, the third after forty-five minutes, and the fourth
at the end of an hour. The eyes after removal were fixed in
Perenyi’s fluid, cut into sections, and mounted unstained. In
all instances the retinal pigment was found to be fully expanded.

The experiment was then reversed, the frogs being kept in the
dark five hours and subjected to the adrenin while still in the
dark. They were also killed in pairs at quarter-hour intervals.
To my surprise, the retinal pigment in every case was fully
expanded. To avoid possible error, I repeated the experiment,
with exactly the same results. Control frogs injected with phys-
iological salt solution, instead of adrenin, were made to accom-
pany the others. The retinal pigment in all of these remained
retracted as in the regular dark condition. It is therefore cer-
tain that the adrenin acts upon the retinal pigment in the same
way as light, as maintained by Fujita (11). It thus appears
that the action of adrenin on the retinal pigment cells is the op-
posite of what it is on the melanophores of the skin. My results,
therefore, are opposed to those of Klett (’08), who maintained
that adrenin caused a retraction of the retinal pigment. His re-
sults were obtained by an intra-ocular application and not by
injecting it into the blood stream. He could get no results by
the latter method. In all his experiments the frogs were in
direct, strong light or in diffused light, but never in the dark,

394 ANDREW JOHNSON BIGNEY

and the concentration of adrenin was strong enough to be poison-
ous to the animals. ‘It is, therefore, not surprising that he failed
to observe the real action of the drug. Furthermore, since the
adrenin and light act in the same way, the real action of the drug
could not be noticed in the light condition. Had Klett carried
on his tests with frogs kept in the dark instead of the light, I
am convinced that his results would have agreed with Fujita’s
and mine.

To determine the concentration necessary to produce the mi-
gration of the retinal pigment, frogs that had been kept in the
dark were injected with adrenin in strengths varying from one
part in a thousand to one in one hundred million. The frogs
were subjected to the influence of the drug for one hour and then
killed. At concentration one to one thousand there was com-
plete expansion of the pigment, at one to ten thousand almost
complete, at one to fifty thousand there was less expansion and
less regularity in the condition of the preparation, and at one to
one million or one to five million the results were not very uni-
form. While the influence of the adrenin could still be detected
at these dilutions, there was an irregularity which recalled the
variation often noticed in normal frogs. The action of the
drug on the retinal pigment is possible in even greater dilutions.
This sensitiveness of the retina is in marked contrast with that
of the skin, which is not nearly so responsive. There seems to
be no sharp ending in its influence either on the skin or the re-
tina, but a gradual diminution.

To determine how long the influence of the adrenin on the
retinal pigment lasted, a number of frogs kept in the dark were
injected with a solution of adrenin one in one thousand and the
eyes were prepared at hour intervals from one to six. After
an hour the pigment showed complete expansion; after two hours
somewhat reduced expansion; in three to four hours still further
reduction, and in five to six hours the retraction was complete,
thus showing that the influence passes off in about four hours.

It is clear from these experiments that adrenin causes a con-
traction of the pigment in the dermal melanophores and an ex-
pansion of that in the retinal cells—processes precisely the oppo-
site of each other.

i

EFFECT OF ADRENIN ON PIGMENT IN FROG 395

Another interesting question presents itself. How does this
drug act in causing the above results? Is it through the nerves
or directly upon the cells by being carried in the blood? To
answer these questions, frogs in which the optic nerve of one
eye had been cut very close to the brain, the other optic nerve
not having been disturbed, were injected with adrenin under the
usual conditions. In this experiment the retinal pigment was
found to be expanded in both eyes, thus showing that the optic
nerve is not concerned in this action, but that it is very probably
due to the drug carried in the blood.

Another experiment was performed in which the eyes of several
frogs were removed and treated directly by injecting the adrenin
into the eyeball of one side and physiological salt solution into
the eyeball of the other side in each frog. Irregular results were
obtained, the pigment sometimes being retracted, but most gen-
erally expanded in all the eyes. These irregularities were evi-
dent in the control frogs as in the experimental set. This led to
the suspicion that the condition of the frogs was notsatisfactory
owing to the season of the year. The earlier part of this work
was performed in the autumn and winter and the results were
strikingly uniform and consistent, but the later part of it was
done in the spring. It was, therefore, suspected that the advent
of the breeding season had something to do with the results. It
is not improbable that this irregular condition is dependent, as
Fuchs (’06) has suggested, on an especially excited state of the
animals whereby adrenin is secreted naturally and in considerable
quantities by the frog itself. This suggestion, which seems
plausible, is nevertheless purely hypothetical. It is intended to
continue this part of the work with the view of a final determina-
tion as to the real cause of this irregularity.

396 ANDREW JOHNSON BIGNEY

BIBLIOGRAPHY

Corona, A., E Moroni, A. 1898 Contributo allo studio dell’ estratto di cap-
suli surrenali. La Riforma Medica, anno 14. (Cited from van Ryn-
berk, 1906.)

Fucus, R. F. 1906 Zur Physiologie der Pigmentzellen. Biol. Centralbl., Bd.
26, S. 863-879, 888-910.

Fusira, H. 1911 Pigmentbewegung und Zapfenkontraktion im Dunkelauge des
Frosches bei Einwirkung verschiedener Reize. Arch vergl. Ophthalm.,
Jahrg. 2, S. 164-179,

Kuetrr 1908 Zur Beeinflussung der phototropen -Epithelreaktion in der
Froschretina durch Adrenalin. Arch. Anat. Physiol., Jahrg., 1908,
Physiol. Abt., Suppl. Bd., S. 213-218.

Lizsen, S. 1906 Uber die Wirkung von Extrakten chromaffinen Gewebes
(Adrenalin) auf die Pigmentzellen. Zentralbl. Physiol., Bd. 20, S.
108-117.

RepFietp, A. C. 1917 The codrdination of the melanophore reactions of the
horned toad. Proceed. Nat. Acad. Sci., vol. 3, pp. 204-205.

vaAN Rynsperx, G. 1906 Uber den durch Chromatophoren bedingten Farben-
wechsel der Tiere. Ergeb. Physiol., Jahrg. 5, S. 347-571.

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Resumido por el autor, W. W. Swingle.

Estudios sobre la relacién del iodo con la tiroides.

I. Los efectos de la alimentaci6én iodada sobre los renacuajos
normales y tiroidectomizados.

El presente estudio trata del problema entre la relacién del iodo
y sus compuestos con la actividad y funci6én de la tiroides, deter-
minada por los efectos que siguen a la ingestién de estas substan-
cias por las larvas de rana, normales y desprovistas de tiroides.
Cuando se alimentan renacuajos normales con cristales de iodo,
los cambios propios de la metamorfosis aparecen pocos dias
después y dicho proceso se lleva a cabo en corto tiempo si se

alimentan con algun cuidado. La ingestién del iodoformo pro-.

duce resultados semejantes pero sus efectos no son tan rdpidos;
con el ioduro potdsico se obtienen los mismos resultados. El
iodato potdsico no parece producir efecto alguno sobre la meta-
morfosis. En animales privados de las glandulas tiroides cuando
median 4 mm, de longitud, alimentados después con iodo, la
metamorfosis se llevé a cabo rapidamente, a pesar de que en las

larvas desprovistas de tiroides y alimentadas con los alimentos.

adecuados nunca aparecen cambios metamOrficos, sino que, por
el contrario, crecen hasta convertirse en renacuajos gigantes. El
examen microseépico de estas larvas no pudo revelar indicacién

alguna de tejido tiroideo. La comparaci6n entre la rapidez de

la metamorfosis en las larvas alimentadas con iodo y las alimen-
tadas con extracto de la tiroides o con tejido tiroideo demuestra

que el iodo es mas potente en la produccién de los cambios meta-.
morficos. El autor consigna experimentos describiendo el efecto:

del iodo sobre el canal alimenticio y otros érganos y hace notar
que el iodo actta dentro de los tejidos como un verdadero hor-

mon, sin intermedio de la glindula tiroides, que funciona princi-

palmente como un reservorio del iodo.

Translation by Dr. José F. Nonidez,
Columbia University.

AUTHOR’S ABSTRACT OF THIS PAPER ISSUED
BY THE BIBLIOGRAPHIC SERVICE, DECEMBER 23

STUDIES ON THE RELATION OF IODIN TO THE
THYROID!

I. THE EFFECTS OF FEEDING IODIN TO NORMAL AND
THYROIDEGTOMIZED TADPOLES
~W. W. SWINGLE

Fellow in Biology, Princeton University

CONTENTS

CIPHER yg Be oa ed oes Oe One DEB OO 6 UIE SiS o SORE CESSES Sara net Ss? 397
“LCPDPTYREERE. 5 o Ba 2 = SRE ONG Shc co CRSIRRO cae R ENCE Te SNR ener = 398
‘signal, ord Linea nays ke 2 ee. See GODS Se En Or, © Senne ee 400
Observations (Feeding of iodin compounds to normal larvae).............. 401
OUTRO Sse vr ote CAA 6 So O20 Se ee ny eA, ee oS 401
SNAIERRINEPUNGLS po. See eros, North a Scan cs aces Sao ES +e sale cen 405

8 STG Th AE ep te a | Os eee ge 409
Feeding iodin to thyroidectomized larvae .....................22 eee eees 411
a RSPEI RISES OYE 9 Pn es 5 cores OE. wich eh Row Waid. bie ateiieis 2G Sapa t'e wn Lie reels 414

INTRODUCTION

Early in the spring, while carrying on a series of feeding ex-
periments with tadpoles, the writer suggested to Mr. A. C.
Eitzen, a student in the Medical School of the University of
Kansas, that he undertake the problem of feeding inorganic
lodin, and various organic compounds of this substance to frog
larvae. The object was to note the macroscopic effect upon
growth and metamorphosis and the histological effects on the
thyroid and germ glands.

Most of the investigators who have dealt wth the problem
of the relation of iodin and its compounds to the activity of the
thyroid have used mammals as experimental material, forms
which, in the author’s opinion, offer no such sure and certain

1 The experimental work for this paper was done while the writer was in-

structor in zoology at the University of Kansas. Acknowledgment is made to
this laboratory.

397

THE JOURNAL OF EXPERIMENTAL ZOOLOGY, VOL. 27, No. 3

398 W. W. SWINGLE

eriteria for judging the effect of iodin administration and
thyroid activity upon the organism as do frog larvae. The
original work of Gudernatsch (since followed by that of Morse,
Lenhart, and Swingle) showed that any increased stimulation of
thyroid activity, as for instance by feeding thyroid extract, was
at once indicated by metamorphic changes in the tadpoles. The
present problem was to utilize these somatic changes as a cri-
terion of hyperthyroid function and to gauge the effects of iodin
upon the gland by feeding it to immature larvae.

Mr. Eitzen followed the suggestion, and, in conjunction with
the writer, started the work, but owing to induction into military
service shortly afterward gave up the problem. Consequently
if fell to the writer to work out his own suggestion. The results
obtained contribute some additional information regarding the
relation of iodin to the physiological activity of the thyroid, to
the probable réle of this gland in the economy of the organism,
and to the more general problem of amphibian metamorphosis.

LITERATURE

The active principle of the thyroid gland is at present un-
known, or at any rate much in dispute. The relation of iodin
to this gland has been for many years a matter of great interest
to clinicians and investigators, and it has long been recognized
that iodin holds an important place among the constituents of
the thyroid. Since 1820 iodin has been’ used more or less in the
treatment of thyroid diseases, but it was not until 1895 that it
became known that the glands usually contain iodin. Baumann
(95) contributed this important information to our knowledge
of the gland.

This investigator isolated a specific iodin compound from the
gland which he named iodothyrin. It apparently has many of
the specific properties of the gland tissue itself.

Oswald (’02) succeeded in isolating the protein with which the
iodin in the gland is combined. He called this protein thyro-
globulin; it was found to constitute one-third to one-half of the
weight of the dry gland. The iodin content varied from zero to
0.86 per cent or more. Baumann’s iodothyrin could be obtained
from it by hydrolysis.

RELATION OF IODIN TO THYROID 399

Kendall (’14) has reported’ the separation of the physiologi-
cally important thyroid constituents into two fractions: an A or
alpha fraction, containing ten times the percentage of iodin of
the original thyroid. This alpha fraction is toxic and its ad-
ministration produces typical symptoms of excess thyroid
feeding. The B fraction contains less iodin and is non-toxic.

The relation of iodin to the physiological activity of the
thyroid is very close; in fact, the activity of the gland appears
to depend upon its iodin content.

One investigator, Roos (99), working with dogs, found that
more nitrogen was excreted after the administration of thyroid
rich in iodin than after that of thyroid containing little iodin.

Marine and Williams (’08) observed that thyroid containing a
larger percentage of iodin caused a greater loss of weight in dogs
than did a preparation containing a smaller percentage.

Hunt and Hunt and Seidell (07 and ’08), in an extended
series of experiments in which the effects of thyroid upon the
resistance of animals to certain poisons was determined, found
that the physiological activity of the thyroid depended upon
its iodin content.

Morse (14) fed the larvae of Rana pipiens on various iodin
compounds, but obtained negative results with all inorganic
iodin. He was able to accelerate metamorphosis in these
animals by feeding iodized amino-acids (3-5-di-iodo-thyrosin,
C, H;OHI.CH2.CH,.CHNH;COOH). This amino-acid was de-
rived from the thyroid tissue by acid hydrolysis.

Lenhart (15) fed thyroid tissue to tadpoles and observed that
the higher the iodin content of the gland fed, the more rapid the
body metabolism.

This review is by no means exhaustive. Besides the investi-
gators quoted, there are equally as many, if not more, who claim
that iodin has no relation to thyroid activity and that it does
not function within the organism.

400 W. W. SWINGLE
MATERIAL AND METHODS

Late in March (1918) several bunches of Rana pipiens eggs in
late segmentation stages were collected and brought to the lab-
oratory to develop. All of the animals used in a single experi-
ment were taken from cultures, the larvae of which came orig-
inally from the same bunch of eggs, hence were of the same
age. The animals were separated into lots of fifty each when
the free feeding stage was reached and kept in large glass con-
tainers under identical environmental conditions. Several groups
of fifty tadpoles each were fed inorganic iodin crystals finely
ground, mixed with wheat flour in the proportions of 1 to 100,
using the same procedure described by the writer in a previous
paper (’18) for administration of thyroid extract. Another lot
of larvae was fed iodoform mixed with flour as described. Two
other cultures were fed potassium iodide, also in flour, using the
same proportions as before. Solutions of potassium iodide sere
prepared and an attempt made to rear the tadpoles in them,
but the method proved unsatisfactory and so was abandoned.

The larvae were fed each day, care being taken not to overfeed ;
the water was changed daily, and with the advent of warm
weather twice daily. Very early in the work it was observed
that unless the iodin was mixed with food in some way, the
larvae refused to eat it. This was especially true of the iodin
crystals. Great mortality results if the crystals are merely
thrown into the containers among the tadpoles. The quickest
and most effective way of rendering the iodin palatable was to
mix finely ground crystals with wheat flour (1 to 100) stir until
the flour was a delicate brownish hue and then feed the dry
mixture. Small bits of algae were fed the animals along with
the iodin. 7

The various mixtures of iodin and flour prepared by the
method described by the writer in a previous paper (718) for
thyroid administration keep well, with the exception of the iodin
crystals and flour. The mixture appears to lose strength after
about two weeks. Regarding the chemical nature of the sub-
stances formed by the mixture of iodin and its compounds with

RELATION OF IODIN TO THYROID 401

flour, no mention will be made here. This phase of the work
together with certain histological data gathered by examination of
normal and thyroidectomized iodine-fed larvae, will be the
subject-matter of part II of this paper. -The results obtained
with feeding normal larvae potassium iodine will be discussed
first.

QBSERVATIONS

I. Experiments with feeding potassium vodide to normal tadpoles

The tadpoles were first fed potassium iodide and flour when
they averaged 10 mm. in length; none of the animals showed
indications of limb buds. April 11th, eight days after the
first administation of potassium iodide, the animals were
measured and examined with a microscope for limb buds. At
this time some of the larvae appeared somewhat emaciated and
about one-fourth of the animals had hind limb buds, though the
buds were small. The controls were somewhat larger than the
experimental larvae, but no limb buds were found. Table 1
gives the total length of twenty of the larvae from each culture,
in millimeters and indicates those animals with limb buds.

April 18th. When examined on this date the potassium-
iodide-fed animals were lighter in color than their controls but
‘of about the same size. All of the experimental animals had
hind limb buds whereas none of the controls had developed
them (table 2). The emaciated appearance of the larvae,
noted at the previous examination, had disappeared.

April 26th. The potassium-iodide-fed larvae had by this time
outgrown their controls and were considerably lighter in color.
All of the experimental animals had well-developed hind limbs
showing differentiation into the two primary divisions with toe
points. Only three of the controls had limb buds, none showed
any differentiation of parts. The difference between the two
cultures of larvae in regard to limb development was striking
(table 3).

May 6th. The animals fed on the iodine compound were now
distinctly larger than the algae-fed larvae. The light color of
these animals was marked. Their limbs were well developed—

402 W. W. SWINGLE

TABLE 1
April 11
KIL-FED LARVAE | CONTROLS FOR KI-FED LARVAE _
Length | Limb buds Length Limb buds
mm. mm.
16.0 => 15.0 _
15.5 == 1Ges -
13-5 =e sat =
14.5 = 17.0 —
15.0 == 18.5 _—
14.0 == 17.0 _
16.0 _ 16.5 —
14.0 =e 15.0 -
13.5 =e 19.5 —
14.0 = 18.5 —
17.5 =. 20.0 ES
14.0 = 19.0 oo
13.0 = 18.5 -
1) = 16.0 ~
16.0 = 20.0 =
14.5 — 18.5 _
14.0 + ies —
1525 = 17.0 =
13.0 = 19.5 _-
14.5 =m 15.5 =
Average 17.5

length. .14.5

much in advance of the controls (table 4). No mortality had
occurred in the cultures of either group.

May 18th. The experimental animals were much larger than
the controls, more sluggish, lighter in color, limbs much more
highly developed and much larger. No other differences were
noted (table 5).

The animals of this culture were not measured again, owing
to the pressure of other work at this time. They were fed and
tended as usual, however. It was observed sometime later
that the potassium-iodide-fed animals appeared to be slowly
falling behind in growth rate. They remained much lighter in
color and had limbs much longer than the controls. The cul-
tures were kept until the Ist of June. When it became impos-

RELATION OF IODIN TO THYROID 403

TABLE 2
April 18
KI-reD LARVAE _ CONTROLS FOR KI-FED LARVAE
Length Limbs Length Limbs
mm. mm.
21.0 a5 23 .0 --
18.5 SP 18.5 _
17.0 == 22.0 ~-
20.0 sf 21.5 =
21.5 =F 20.0 _
19.5 + 22.0 _
18.0 =F 19.0 —
21.0 ae 20.5 —
22.0 =r 22).5 _
19.5 + 18.5 —
20.0 == 19.0 =
23 .0 =F 21.0 =
2135 == 19.5 _
175 + 23.0 --
22.0 == 18.0 —
20.5 + 24.0 a
19.0 == 20.5 =
23.5 == 22.0 —
22.0 == 23.5 —
20.5 + 23.0 i
20 .37 21.07

sible to prolong the experiment, the animals were killed and
preserved for microscopic examination.

Discussion of potassium vodide feeding experiment. The results
of this experiment, while not so interesting perhaps as those
obtained by administration of iodin crystals, seemed worth
recording in detail. The table of measurements shows that the
growth capacities of the larvae receiving potassium iodide were
much increased. It is interesting to note in this connection that
Adler (13), in a brief paper dealing with the effects of iodin
upon the germ glands of amphibians and mammals, observed
that iodin compounds appeared to stimulate the growth rate of
the amphibian larvae with which he worked. He records no
measurements, however, and made no observations regarding
metamorphic changes.

404 W. W. SWINGLE

TABLE 3
April 26
KI-FED LARVAE CONTROLS FoR KI-FED LARVAE

Length ? Limbs Length I Limbs
mm. mm.
28.5 + 26.5 +
27.0 + 28 .0 +
Piee + 26.0 —
30.0 — 27.5 _
29.5 + PANES =
28 .9 == 30.0 -
oto + 27.5 +
29.5 + 26.0 =e
32.0 + 23.0 _
O20 + 26.5 =
33.0 + 29 .0 +
30.0 + 21.5 a
33.0 + 24.5 +
3220 + 26.0 _
29.5 + 27.5 =
31.0 + 31.0 =
29.0 + 25.0 _—
33.5 + 25.0 =
30.5 + 27.0 _
32.0 + 28.5 _
30.5 27.05

Potassium iodide in flour clearly stimulates the growth and
differentiation of limbs. Morse (’14) was unable to produce
metamorphic change by administration of iodin compounds to
tadpoles, with the exception of iodized blood albumin. In the
light of the results obtained by the writer with iodin crystals,
it is difficult to understand why this investigator failed to get
positive results. His method of feeding the iodin probably
accounts for the discrepancy in our results. Why feeding
potassium iodide stimulated the growth of tadpoles is not clear.
Feeding other iodin compounds gives just the reverse results,
i.e., growth ceases.

RELATION OF IODIN TO THYROID 405

TABLE 4
May 6 .
KI-FED LARVAE CONTROLS FOR KI-FED LARVAE

Length Limbs Length . Limbs
an Ce mm

34.0 5 28.5 air
35.5 ap ° 26.0 _
30.0 =F 29.5 +
29.5 + 25.5 =
32.5 AE 27 .0 aa
36.0 + 30.0 + P
39.0 + 27.5 -
32.0 a5 29.0 —;
34.0 aS 31.5 >
33.5 =a 28 .0 ar
41.0 + 28.5 ate
38.0 + 30.0 +
36.5 =F 29.0 ar
44.0 ae 31.5 Si
40.0 =F 27.5 =
33.5 + 30.0 a
36.0 == 26.5 —
39.0 + 30.0 =
41.5 + 31.0 ate
38 .0 a 28.5
36.2 28.7

2. Experiments with feeding iodin crystals to normal larvae

This experiment was conducted in the same manner as de-
scribed for the potassium iodide experiment. The larvae
averaged 10.5 mm. in length when the iodin was first fed, April
4th. None of the animals of either control or experimental
cultures showed any indications of limb development. Seven
days after the first feeding, the animals fed on the iodin had limb
buds and showed other bodily changes not found in the controls
{table 6). The larvae appeared emaciated; head much elongated
(this change is only apparent and has been shown by the writer
to be due to atrophy of the coiled gut); body thin; eyes bulging;
pigmentation light. One or two of the animals showed signs of
tail involution. All of the larvae were extremely sluggish and

406 WwW. W. SWINGLE

TABLE 5
May 18
KI-FED LARVAE CONTROL OF KI-rED LARVAE

Length . Limbs Length Limbs
mm. mm.

44.0 Large 32.5 Very small
46.0 Large Sil 0) Very small
45.5 Large 34.0 Very small
44.0 Large 31.0 Very small
39.5 Large 34.0 Very small

$ 46.0 Large 33.5 Very small

46.5 Large 29.5 Very small
44.0 Large 35.0 Very small
47.0 Large , 30.5 Very small
38.5 Large 30.0 Very small
45.0 Large 33.5 Very small
42.5 Large 31.0 Very small
40.0 Large 34.0 Very small
43.5 Large 33.5 Very small
39.0 Large 30.0 Very small
41.5 Large 33.0 Very small
42.0 Large 30.5 Very small
38 .0 Large 29.5 Very small
40.5 Large 34.0 Very small
44.0 Large SURFS Very small
42.3 32.05

remained near the surface of the containers. The hind limbs
were small, and as yet they had not differentiated into their two
primary divisions with toe points.

These animals revealed clearly all of the symptoms:of hyper-
thyroidism, the “reaction to which is characteristic in this
species. Examination of the controls showed none of these
changes. None of the animals had limb buds.

April 17. On this date the differences between iodin-fed and
control larvae were marked. All of the body changes noted on
April 11th were now much more obvious. ‘The tails of the iodin-
fed animals were undergoing atrophy; the hind limbs were plainly
visible and had differentiated toes. The total length of the ani-
mals had decreased owing to tail resorption (table 7). There was
great mortality among the larvae of the iodin culture. Out of

RELATION OF IODIN TO THYROID 407

TABLE 6
valjoypoll. atl
IODIN-FED LARVAE » CONTROL FOR IODIN-FED
A Length Limbs Length ° Limbs

mm. mm.
11.0 aq 15.0 —
12.0 =F 16.5 —
1b 63) ar 15.0 —
10.5 ae 18.5 —
12.0 =F UG os —
To) ae 16.0 -
125 a 20.0 _
13.0 =e 18.0 —
11.0 Se 15-5 -
15 ar 19.5 a
13.5 =e 17.0 -
10.0 35 iio —
12.0 a 20.0 —
10.5 + 19.0 _
11.0 ar 15.0 —
12.5 == 1725 =
10.0 = 17.0 —
13.5 ata 19.0 —
11.0 a 21.0 —
12.0 se 18.5 _
11.6 = 17 6 —

several cultures containing fifty larvae each, only thirty animals
remained alive on this date. The controls had increased in size
during this interval, but none showed signs of limb development.

A new series of cultures of iodin-fed animals was started. The
animals averaged 13 mm. in length when first fed iodin. Eight
days later the first indications of body change appeared, and ten
days from the date of first feeding the limb buds of the experi-
mental larvae averaged 0.8 mm. in length. The controls showed
no signs of limb development. At this time the animals were
taken off the iodin diet and fed alge in order to prolong the ex-
periment, as the mortality rate was abnormally high. The con-
trol animals at this time averaged 19 mm. in length; the iodin-fed
larvae, 14.5 mm. For several days both sets of tadpoles were
fed only algae and then measured at the end of the period. The

408 W. W. SWINGLE

TABLE 7
April 17
IODIN-FED LARVAE CONTROL OF IODIN-FED

Length : Limbs Length Limbs

mm, mm. mm d
12.0 1G: 20.5 None
10.0 1.0 24.0 None
9.0 1.4 21.0 None
9.5 0.5 73) 05) None
9.0 1.0 22.0 None
10.5 ia) 24.5 None
10.0 1.0 20.0 None
15 2.0 19.0 None
13.0 iL 21.0 None
10.5 0.5 DS} ai) None
9.0 0.5 20.0 None
9.5 iL 20.5 None
10.0 1.0 21.0 None
PIORS Hee 24.5 None
9.0 1.0 22.0 None
TL 5% 2.0 20.0 None
12.0 iL ‘19.5 None
2) 1.0 21.0 None
9.0 OFS 23 .0 None
9.0 1.0 20.5 None

10.4 tel DABS

controls averaged 23.5 mm.; the iodin fed, 16.5 mm. The latter
had well-developed hind limbs. Jodin was again administered
for eight days and the animals measured. Table 8 indicates
the differences between the two sets of larvae.

The fore limbs of the iodin-fed larvae appeared shortly after-
wards. Six of these animals were reared to metamorphosis
before death occurred. One of the lot was the smallest frog the
writer has ever seen. The controls for this lot developed nor-
mally, but have not at the present writing undergone metamor-
phosis. The fore limbs have not yet appeared.

In a previous paper the writer had found that when thyroid
extract is adminstered to frog larvae, the alimentary tract under-
goes a remarkable shortening process in a brief space of time.

RELATION OF IODIN TO THYROID 409

TABLE 8
IODIN-FED LARVAE 7 CONTROL OF IODIN-FED

Length Limbs Length Limbs
mm, mm. mm. mm.
17.5 6.0 27.0 0.3
16.0 4.5 28.5 0.5
15.5 5.0 30.0 0.5
15.0 6.5 25.5 0.6
16.5 6.0 23.0 0.4
16.5 4.0 29.5 0.2
14.5 5.5 32.0 0.3
18.0 7.0 26.5 0.6
17.0 6.0 28.0 0.4
16.5 3.5 98.5 0.3
15.0 4.0 31.0 0.5
16.5 5.5 29.5 0.6
' 15.0 5.0 26.0 0.2
14.5 4.5 28.0 0.3
14.0 7.0 30.0 0.5
- 18.5 5.0 33.0 0.6
Pe 170 4.0 27.5 0.4
17.5 8.0 29.0 0.2
14.0 7.0 30.5 0.3
16.0 4.0 26.5 0.4

15.0 5.4 28.6 0.405

An attempt was made to see if feeding iodin had the same effect
upon the gut. A series of larvae appropriately controlled was
started upon the iodin diet to test this matter. The animals
were fed iodin for twenty days. Table 9 shows the effect upon
the gut at the end of this interval.

3. Experiments with feeding iodoform to normal larvae

An experiment similar in all respects to the potassium iodide
and iodin feeding was carried out in which iodoform and flour
was used as food. The proportions of flour and iodoform used
was the same as described for the other experiments. JIodoform
appears to have a marked effect in accelerating metamorphic
changes in frog larvae, although the reaction is not so rapid as
when iodin crystals are used. The iodoform is toxic for the

410 W. W. SWINGLE
TABLE 9
IODIN-FED LARVAE CONTROL FOR IODIN-FED LARVAE
Body length Length of gut Body length Length of gut

mm. mm. mm. mm.
20.5 33.0 25.0 107.0
20.0 39.0 23 .0 102.0
19.5 32.0 P28) 5f9) 121.0
21.0 36.0 26.0 117.0
19.5 38 .0 AD) 15) 111.0
20.0 32.0 DEAD 119.0
20.0 31.0 Zico 97 .0
16.5 36.0 24.5 123.0
2225 24.0 30.0 99 .0
19.0 28 .0 27.0 116.0
20.0 31.0 PANY) 102.0
NBS 35.0 28.5 97 .0
20.0 34.0 26.0 114.0
18.0 29.0 23.5 118.0
Zio 24.0 28 .0 99.0
18.5 PA AD) 22.0 105.0
20.0 30.0 24.5 122.0
18.5 25.0 29.0 96.0
19.0 28 .0 ZORS 98 .0
ie 30.0 26.0 110.0
19.45 30.9 25.85 108 -6

animals and the mortality rate is very high when this compound
is fed for any length of time. Several cultures were kept long
enough to show the accelerating effect of this substance upon
metamorphosis. One culture, the animals of which averaged
12.5 mm. when first fed the iodoform, was kept for ten days.
During this interval the animals ceased to grow and showed the
reaction characteristic of iodin or thyroid feeding. Limb buds
were found on all of the experimental animals, but none on
the controls. This phase of the work was not carried out in
detail because of the toxicity of the iodoform mixture.
Discussion of the experiments with feeding todin to normal
larvae. The results obtained by feeding iodin crystals and
iodoform are identical with those obtained when extract of the
thyroid gland is used as food. The changes typical of hyper-

RELATION OF IODIN TO THYROID 411

thyroidism appear a few days after administration of the sub-
stance. Overfeeding with iodin has the same result as over-
feeding with thyroid extract—death of the organisms from a too
rapid rate of metabolism. lIodin, if carefully administered, will
stimulate metamorphosis in a shorter time than the fresh gland
tissue. Two years ago the writer fed fresh thyroid gland to
frog larvae and kept a record of the rate of body change and
the time required for such changes to occur when the larvae were
fed fresh tissue and the powdered extract. A comparison of
these time intervals with those of the iodin-fed animals of the
present experiment show clearly that the fresh gland tissue is
not so effective in inducing metamorphic change as the inorganic
iodin. The animals used in both cases were of the same species.

EXPERIMENTS WITH FEEDING THYROIDECTOMIZED LARVAE
IODIN

Since normal larvae were found to react to iodin feeding by
marked metamorphic changes, it was considered worth while to
carry out the same experiment upon animals whose thyroids had
been removed during early embryonic life. The work of Allen
(18) has shown that thyroidectomized larvae fail to undergo
metamorphosis, but instead permanently retain their larval
characters. If such thyroidless animals could be induced to
metamorphose under the stimulus of iodin feeding, new light
would be shed upon the iodin-thyroid problem and upon the
causes of amphibian metamorphosis.

Kighty very young toad tadpoles, the thyroid glands of which
had been removed at the 4-mm. stage by Prof. B. M. Allen, of
the University of Kansas, were obtained through the generosity
of this investigator when the larvae averaged 6.5 mm. in length.
The animals were fed agae until they were 10 mm. long and then
fed iodin crystals and flour. This series was controlled by both
normal and other thyroidectomized larvae of the same age. The
iodin mixture was first administered the 27th of May. Ten
days later, examination of the culture revealed well-developed
limbs on all of the thyroidless larvae. The limbs were visible
without the aid of a lens and had differentiated toe points. The

412 W. W. SWINGLE

animals appeared emaciated and showed other symptoms charac-
teristic of hyperthyroidism. ‘The controls had increased in size
somewhat, and microscopic examination showed tiny limb buds.
The iodin feeding was continued until the time of metamor-
phosis, which took place in a normal manner and was success-
fully completed by all with the exception of nine larvae which died
during early metamorphic change. The thyroidless animals
under the stimulus of the iodin completed metamorphosis in a
much shorter time than the normal control animals with thyroid
glands intact. The thyroidectomized animals used as controls
for the series are at the present writing very large and show no
signs of limb buds.

About this time twenty extremely large thyroidless toad
larvae were obtained from Miss Mary Larson, of the University
of Kansas. The glands of these animals had been removed
several weeks before; they were much larger than normal toad
tadpoles at metamorphosis; they were, in fact, typical giant
thyroidectomized larvae like those described by Allen. These
animals showed no indications of limb buds when started on the
iodin diet, but are at the present writing (June 12th) undergoing
metamorphosis. The fore and hind legs of the animals are well
developed; mouth is changing from larval to adult form; tails
almost completely resorbed.

Four of these giant thyroidless larvae used as controls for the
iodin-fed culture are larger than at the beginning of the experi-
ment, but show no signs of limb development.

A number of both large and small thyroidectomized tadpoles
were killed at different stages of the experiment and preserved
for microscopic examination. Careful search made for vestiges
of the thyroid gland have yielded only negative results. No
indications of accessory thyroid glands have been found in any
of the thyroidectomized animals examined by me in connection
with this work.

An experiment to test the ability of thyroidectomized larvae
to withstand the deleterious effects of iodin in different con-
centrations was attempted. lIodin is only very slightly soluble
in water, but if the crystals are finely ground, a certain pro-

RELATION OF IODIN TO THYROID 413

portion is dissolved. It was soon found that both normal and
thyroidless animals are quickly killed by very weak dilutions.
Two ce. of such a solution of iodin in 500 cc. of water suffices to
kill both kinds of animals in a few hours. No conclusions could
be drawn from the results, save, perhaps, that flour when mixed
with iodin must in some way protect the tissues of the larvae
from the latter.

Discussion of effects of feeding iodin to thyroidectomized larvae.
The results of iodin feeding just recorded should in some measure
serve to clarify the conflicting views regarding the relation of
iodin to the physiological activity of the thyroid and inciden-
tally throw some light upon the causes underlying amphibian
metamorphosis. .

The various views regarding the relation of iodin to the thyroid
held by investigators to-day may be briefly summarized under
three heads: 1. Some are of the opinion that the activity of the
thyroid depends upon its iodin content and that thyroid free of
iodin has no physiological activity. 2. Another group of
writers take the view that there is no relation whatever between
the physiological activity of the thyroid and its iodin content;
i.e., that the iodin usually present has no importance in the
economy of the organism. 3. Still other investigators admit the
parallelism between physiological activity and iodin content, but
deny that iodin is the causal agent, believing rather it is simply
associated accidentally with the active principle of the gland.

The effects of iodin feeding to normal tadpoles give additional
confirmation to the first of these views. But especially interesting
in this connection are the results with feeding iodin to thyroid-
less larvae. If animals without the vestige of a thyroid gland
are stimulated to complete metamorphosis in an abnormally
short time by iodin, it would appear that iodin functions within
the organism as a hormone itself and that the gland functions
chiefly for storage purposes. The evidence from the thyroidec-
tomized larvae indicates that the animal body is capable of
utilizing iodin directly without the intermediation of the gland.

The fact that the thyroid gland of man and animals does not
invariably contain iodin (shown by. Miwa and Stoeltzner, Roos

THE JOURNAL OF EXPERIMENTAL ZOOLOGY, VOL. 27, No.3

414 WwW. W. SWINGLE

‘Toépfer and Jolin) and yet such individuals remain healthy may
be explained by assuming that the tissues of such animals assimi-
late directly the iodin taken into the body, leaving no surplus to
be collected by the thyroid. Since the tissues of thyroidec-
tomized tadpoles can take up iodin in large quantities and use
it, there seems nothing inherently improbable in the suggestion.

According to Voegtlin and Strouse, iodized amino-acid when
fed to tadpoles accelerates the metamorphosis of the animals,
but fails to replace the function of the thyroid in pathological
cases where there is a deficiency of thyroid function.

The work of these authors, in so’far as the acceleration of
metamorphosis is concerned, agrees with the results obtained in
the present experiments. The function of the thyroid in patho-
logical cases, however, may be an entirely different question.

SUMMARY AND CONCLUSION

1. Iodin and its compounds when fed to the larvae of Rana
pipiens and Bufo lentiginosus stimulate metamorphosis in these
animals very rapidly.

2. Inorganic iodin when fed to thyroidless larvae of Bufo
lentiginosus brings about metamorphosis in an abnormally short
time.

3. Iodin appears to function within the organism as a hormone
itself without the intermediation of the gland.

4. The suggestion is made that the extraction of iodin from
the blood and its storage is the chief function of the thyroid gland.

RELATION OF IODIN TO THYROID 415

LITERATURE CITED

ALLEN, B. M. 1918 Jour. Exp. Zodél., vol. 24, no. 3.
BasInceR 1916 Arch. Int. Med., vol. 17, p. 260.
Baumann, E. 1895 Zeits. f. physiol. Chem., Bd. 21, p. 319.
Brevi, ArrHuR 1913 The internal secretory organs.
Hunt, R. 1907 J. Am. Med. Assn., vol. 49: p. 1325.
Hunt, R., AND SerpEtL, A. 1908 Bull. No. 47. Hyg. Lab , U.S. Pub. Health
and Mar. Hosp. Serv., Wash., D. C.
Hurcutnson, R. 1896 Jour. Physiol. 20. 8S. 494.
1898 Jour. Physiol., vol. 23, p. 181.
Joutn, 8S. 1896 Festschrift, O. Hammarsten, Upsala.
Kenpatu, E. C. 1914 Jour. of Biol. Chem., vol. 20, p. 501.
1917 Jour. Amer. Med. Assn., vol. 66, p. 811.
Lennart, C.H. 1915 Jour. Exp. Med., vol. 22, p. 739.
Menpe., L. B. 1900 Am. J. Physiol., vol. 3, p. 290.
Maring,'D., anp Wituiams, W. W., 1908, Arch. Int. Med., vol. 1, p. 378
Miwa, 8S., AND STOELTZNER, W. 1897 Jahrb. f. Kinderh, Bd. 45, S. 83.
Morse, M. W. 1914 Jour. Biol. Chem., vol. 19, no. 3, p. 421.
1918 Biol. Bull., vol. 34, no. 3.
Oswatp, A. 1902 Arch. f. Path. Anat., Bd. 169, S. 461.
1902 Beitr. z. Chem. Physiol. u. Path., Bd. 2, 8. 555.
SwinecLe, W.W. 1918 Jour. Exp. Zoél., vol. 24, no. 3, p. 521.
1918 Jour. Exp. Zoél., vol. 24, no. 3, p. 545.
1917 Biol. Bull., vol. 33, no. 2, p. 116.
Toprer 1896, Wien, klin. Wehnschr., Bd. 9, 8S. 141 (quoted by Hunt and Seidell).

Resumido por el autor, W. W. Swingle.

Estudios sobre la relacién del iodo con la tiroides.

II. Comparaci6n entre la tiroides de las larvas normales de rana
y la de las larvas alimentadas con iodo.

En este trabajo el autor demuestra que la ingestién del iodo y
sus compuestos, iodoformo y ioduro potdsico, por las larvas de
rana, produce rapidamente la metamorfosis, estimulando de este
modo la aeccién del tejido o del extracto tiroideos. El examen
microseépico de la tiroides de larvas alimentadas con iodo y el
de la misma glandula de larvas normales de la misma edad, man-
tenidas con el mismo tamafio que los animales sujetos al experi-
mento por medio de una nutricién deficiente, demuestra: que las
glindulas de aquellas son mayores que las de las larvas normales
y contienen mas substancia iodada. La comparacién entre la
tiroides de larvas de una longitud media de 10.5 mm., alimenta-
das con iodo, y la de larvas normales de la misma edad pero de
una longitud media de 21.5 mm., producida por una alimentacion
abundante, demuestra que las glindulas de ambos grupos de
animales son aparentemente del mismo tamano. El autor de-
scribe experimentos en los que se ha comparado la rapidez de
accion de varios compuestos iodados sobre la iniciacién de la
metamorfosis. El iodo inorgdnico result6 ser el mas eficiente y
en segundo y tercer lugar el iodoformo y ioduro potasico, respec-
tivamente. Los experimentos llevados a cabo para determinar
la solubilidad del iodo en el suero sanguineo normal demuestran
que el del conejo a 37°C. acttia como disolvente de los cristales de
iodo en una proporcion de .00075 gramos de esta substancia por
centimetro ctibico. El poder disolvente del suero de la rana es
algo menor que el del conejo, pero considerablemente mayor que
el del agua. El autor incluye en el trabajo una discusién sobre
la relacién del iodo con la metamorfosis de los anfibios y la funcién
tiroidea.

Translation by Dr. José F. Nonidez,
Columbia University.

,

AUTHOR’S ABSTRACT OF THIS PAPER ISSUED
BY THE BIBLIOGRAPHIC SERVICE, DECEMBER 23

STUDIES ON THE RELATION OF IODIN TO THE
THYROID!

II. COMPARISON OF THE THYROID GLANDS OF IODIN-FED
AND NORMAL FROG LARVAE

W. W. SWINGLE
Fellow in Biology, Princeton University

INTRODUCTION

In the foregoing paper (part I of these studies) the writer
described the effects of feeding iodin and various of its com-
pounds to normal and thyroidless frog larvae. It was found
that the administration of iodin, iodoform, and potassium iodide
greatly accelerated metamorphosis in these animals, despite the
fact that normally thyroidless tadpoles never assume the adult
characters.

The results obtained with feeding iodin to thyroidectomized
larvae had led the writer to advance the view. that iodin functions
within the organism as a hormone itself, without the inter-
mediation of the gland. Furthermore, it was suggested that the
chief function of the thyroid appears to be that of iodin storage,
and not, as the current view would have us believe, the elabora-’
tion of internal secretion. The present paper is a presentation
of the results of a comparative study of the thyroid glands of
iodin-fed and normal animals of the same age together with
some additional data gathered since the publication of part I of
this series on iodin feeding and amphibian metamorphosis.

MATERIAL AND METHODS

Some of the material used in the present work was obtained
from the iodin-fed and control cultures described in part I. The
1 The experimental work for this paper was done while the writer was
instructor in zoology at the University of Kansas.
417

418 WwW. W. SWINGLE

material taken from these earlier cultures consisted entirely of
Rana pipiens larvae. The remainder of the material was taken
from cultures of iodin-fed Bufo larvae. All animals used were
appropriately controlled with animals of the same age and
reared under the same environmental conditions. The iodin-fed
larvae were killed and preserved for microscopic examination
when they showed marked indications of hyperthyroidism. The
fixing fluid used was potassium-bichromate-acetic (Tellye-
snicky’s). Only the lower jaw and heart region were preserved.
After washing thoroughly, the tissue was placed in toto in alum-
cochineal for thirty hours; washed in distilled water and run
up through the alcohols to absolute. The tissue was cleared
and kept in oil of wintergreen until ready for use. All measure-
ments recorded for the glands were made with an eye-piece
micrometer, Bausch & Lomb microscope, 16-mm. objective,
ocular 1. The greatest length and width of the gland only were
measured. i

CULTURE I. IODIN-FED AND CONTROL LARVAE

The animals of this culture averaged 10.5 mm. in length when
first started on the iodin diet; none of the animals revealed any
indications of limb buds. Thirteen days from the date of first
iodin administration all of the experimental animals showed
marked symptoms of hyperthyroidism, the indications of which
are characteristic in this species (Rana pipiens). All growth of
the larvae had ceased with the first iodin feeding, and from then
on had in many of the animals actually decreased, owing to tail
resorbtion; the larvae were emaciated; tail atrophy was apparent;
movement sluggish; all iodin-fed animals had _ well-developed
hind limbs. The controls for this culture showed none of the
changes enumerated, but had increased considerably in size.
None of the controls had limb buds.

Table 1 gives the length of the animals of both experimental
and control groups and indicates the condition of the lmbs
thirteen days from the beginning of the experiment. ‘Two sets
of controls were used for each iodin-fed culture, one set was
fed. beef and large quantities of algae each day, the other set

RELATION OF IODIN TO THYROID 419

was fed very little in order to hold the growth of the animals
in check so as to keep them approximately of the same body
length as the animals of the iodin-fed culture. The length of
the well-fed group of controls only is indicated in the table; the
animals of the underfed culture measured 10.5 mm.

TABLE 1
10DIN-FED LARVAE ‘CONTROLS FOR IODIN-FED LARVAE
Total length Limbs Total length Limbs
mm. mm.
12.9 + : 20.5 —
10.0 + 24.0 —
9.0 + 21.0 | _
9.5 + 205 —
9.0 + 22.0 —
10.5 + 24.5 —
12.5 ++ 20.0 —
10.0 + 19.0 —
13.0 + 21.0 —
10.5 af 23.5 =
9.0 =F 20.0 -
9.5 + 20.5 a
10.0 =F PAL AY =
10.5 = 24.5 =
9.0 + 22.0
Tike) + 20.0 ~
1220 + 19.5 _
12.5 + 21.0 --
9.0 + 23.0 —
9.0 =F 2025 —
10.36 PAN SYS)

Microscopic examination of the thyroid glands of this series
of tadpoles revealed a rather interesting condition; the glands of
the iodin-fed larvae were approximately of equal size with those
of the controls. This, despite the fact that in regard to body
size, the iodin-fed animals were only half the size of the controls
as a glance at table 1 shows. When the glands of the iodin-fed
animals were compared with those of normal animals of the same
age held at 10.5 mm. by underfeeding, it was found that the
iodin-fed larvae had considerably larger glands. The average

420 W. W. SWINGLE

length and width of twenty thyroid glands of these underfed
animals compared with those of iodin-fed and overfed animals
is shown in table 2. The measurements given are of the right
glands: the left glands were also measured, but as they showed
nothing unusual the measurement for them are not recorded in
the table.

TABLE 2
Measurements of the thyroid

IODIN-FED LARVAE CONTROL (UNDERFED) CONTROL (WELL-FED)
Length Width Length Width Length Width
mm. mm. “mm. mm. mm. mm.
0.2727 0.0909 0.1818 0.0545 0.3636 0.1270
0.3090 0.1090 0.1727 0.0545 0.3181 0.1181
0.2363 0.0818 0.1727 0.0636 0.2363 0.0909
0.3726 0.1636 0.1545 0.0545 0.2999 0.1090
0.3181 0.1270 0.1818 0.0818 0.2727 0.0999
0.2908 0.1090 0.1636 0.0727 0.2636 0.0999
0.2727 0.0999 0.1818 0.0727 0.3272 0.1270
0.2817 0.1181 Oobi27 0.0636 0.2636 0.0909 »
0.2727 0.1090 0.1454 0.0818 0.2727 0.1090
(0.2908 0.0909 0.1636 0.0454 0.3090 0.1181
0.2545 0.0909 0.1363 0.0545 0. 2545 0.0909
0.2727 0.0818 0.1818 0.0727 0.2999 0.1270
0. 2636 0.1181 0.1636 0.0727 0. 2545 0.0999
‘0.2999 0.0999 0.1727 0.0545 0.2272 0.0818
(0.2817 0.0999 0.1454 0.0454 0.2999 0.1090
0. 2454 0.0909 0.1545 0.0818 0. 2454 0.1090
0. 2636 0.0818 0.1636 0.0636 0. 2636 0.1181
0.2727 0.0818 0.1908 0.0909 0.3181 0.1270
0. 2545 0.1090 0.1454 0.0545 0.2908 0.1181
0.2999 0.1090 0.1818 0.0818 0.2363 0.0818
OE 2912 0.1031 0.1663 0.0658 0.2808 0.1076

It is obvious from these figures that the thyroid glands of
iodin-fed larvae are larger than those of normal larvae of the
same age and body size (held at 10.5 mm. length by under-
feeding), though they are not larger than the glands of normal
animals of the same age presenting marked size differences due
to overfeeding. As is well known, the thyroids of frog larvae
increase in size with the growth of the organism as a whole. When
the fact is taken into consideration that the iodin-fed tadpoles

RELATION OF IODIN TO THYROID 421

are just half the size of the animals of the well-fed culture of
controls, it is clear the iodin-fed animals have relatively
much the larger glands. Microscopic examination of the colloid
content of the glands of the experimental and the two control
cultures of larvae, shows a marked difference in the amount of
colloid visible in the follicles. The glands of the iodin-fed
animals were packed with this substance, whereas the glands of
the controls showed a rather scanty amount.

Since the completion of part I of these studies, the writer has
carried out several more iodin-feeding experiments in order to
test various points left untouched in the earlier work. One of
these points barely touched upon was the comparative rapidity of
action of the various iodin compounds in accelerating meta-
morphosis in normal and thyroidless tadpoles. A detailed ac-
count of the experiment will not be given here, as it was for the
most part a repetition of the experiments described in the earlier
paper. Suffice to state here that iodin crystals when fed to frog
or toad larvae with and without thyroid glands bring about
metamorphic changes in the larvae much more rapidly than any
of the compounds used; iodoform is somewhat slower in its
action, but is much more rapid than potassium iodide. Three
feeding experiments were carried out in which potassium iodate
was used as food, but as only negative results were obtained the
conclusion is justified that this compound has no accelerating
effect upon metamorphosis. The larvae eat the substance, but
apparently are unable to break it down sufficiently to release
free iodin.

While engaged in the experimental work which formed the
subject-matter of the previous paper, the writer was under the
impression that perhaps the resultS obtained from feeding iodin
to tadpoles were due to the mixture of flour, iodin, and water
used, and not entirely to the iodin itself. This erroneous idea
was due to the fact that in several earlier experiments made
to test this point it was observed that frog larvae die very quickly
if placed in containers with inorganic iodin crystals or in weak
solutions of this substance. However, further work along this

422 WwW. W. SWINGLE

line has shown that both normal or thyroidless frog or toad
larvae will undergo metamorphosis very quickly if placed in
extremely weak solutions of iodin. The defect in the earlier
work was that the solutions were too strong. Just a trace of
iodin in the water is sufficient to produce results if the solution
is kept fresh. Cultures of tadpoles fed on wheat-flower paste
showed no changes whatever when compared with beef-fed or
algae-fed controls. This experiment shows clearly that iodin is
the active principle of the mixture of flour, iodin, and water, fed
in the previous work, and that the flour has nothing to do with
the results obtained.

The fact that thyroidless tadpoles readily undergo meta-
morphosis when fed iodin led the writer to suggest that the
function of this gland is chiefly that of iodin storage, rather than
the elaboration of a specific hormone, and, moreover, that the
tissues of animals are capable of utilizing iodin directly without
the intermediation of the gland. In this connection the results
of tests made to determine the solubility of iodin in normal
blood serum may be of interest. The serum of amphibians and
mammals was used; the amphibian serum was obtained from
adult Rana pipiens, the mammal serum from rabbits. The
serum of the latter at 37°C. acts as a solvent for finely ground
iodin crystals to the extent of 0.00075 gram per cubic centi-
meter when stirred vigorously. The solvent powder of Rana
pipiens serum is somewhat less than that of rabbits, though
considerably more than that of water. |

DISCUSSION

The iodin-feeding experiments described in this and the pre-
ceding paper should prove of-interest to students of amphibian
metamorphosis, as they give a clue as to the nature of one of
the underlying causes of this phenomenon. It has been assumed,
and probably correctly so, that one of the prime requisites of
the change from the larval to adult condition in Anurans is a
heightened metabolism. The work of Gudernatsch with feeding
thyroid to tadpoles showed that this substance accelerated meta-
morphosis, and it is generally agreed that the effect of thyroid

RELATION OF IODIN TO THYROID 423

extract on tadpoles is accomplished chiefly by greatly accelerating
catabolic activities. The writer in 1915-1916 (results published
in 1918) in an experiment to test the effects of inanition upon
the development of the germ cells and germ glands of frog
larvae, found that starvation totally*inhibits all body growth
and differentiation, the animals consequently never assuming
the adult condition. Such prolonged starvation undoubtedly
acts as a depressor of metabolism. Later Allen observed that
thyroidless tadpoles do not undergo metamorphosis, but instead
grow abnormally large. In this case the absence of the thyroid
function had led to a prolonging of the anabolic phase of the
metabolic activities. In part I of this series of iodin studies it
was shown that iodin accelerates metamorphosis in both normal
and thyroidless tadpoles. The iodin effect like that of the
thyroid tissue or extract (and indeed iodin seems to be the
active principle of the thyroid) is in heightening catabolism.

In these four experiments there is fairly good evidence for the
view that amphibian metamorphosis was due, in part at least, to
heightened metabolism of the catabolic type. In a state of
nature the metamorphosis of frog larvae, is under normal con-
ditions, effected by none of the experimental agencies mentioned,
except iodin. This substance is found in many plants (though
perhaps accidentally present, as sorne authors believe); it is
present in the soil in combination with other substances and
present in the thyroids of most animals. [odin in some form or
other may be said to constitute a normal environmental factor
of amphibians, a factor which, when considered in connection
with the hereditary factors governing growth processes in larval
amphibians, gives a rationale of the factors involved in the
metamorphosis of these animals.

As pointed out by Morse (718), it is impossible to bring about
complete metamorphosis in extremely young larvae, when an
attempt to do so is made by feeding large quantities of thyroid
or iodin, the animals die. Marked metamorphic changes appear,
but death usually supervenes before complete transformation
takes place. A certain cycle of events must take place before
metamorphosis, and this normal cycle is in all probability de-

424 W. W. SWINGLE

termined by the hereditary constitution of the organism. Bufo
metamorphoses after a few weeks, Rana pipiens requires at
least two months; Rana catesbiana is said to require two, three,
and sometimes four seasons for complete metamorphosis. The
difference in the time required by these amphibians to meta-
morphose is very great, and yet at certain stages in their life
history they may all be found living together in the same pool.
It is obvious that the hereditary factors controlling the growth
processes play a very great réle in determining the time of
metamorphosis, and that iodin is simply an initiator of the
process.

SUMMARY AND CONCLUSION

1. The thyroid glands of iodin-fed frog larvae are larger than
the glands of control animals held at the same body length as
the animals of the iodin-fed culture by underfeeding.

2. The follicles of the glands of such iodin-fed larvae contain
much greater colloid mass than the follicles of the controls.

3. Solutions of iodin will bring about metamorphosis in both
normal and thyroidless tadpoles in a short time.

4. Iodin is much more active in accelerating metamorphosis
than any of its compounds. Next in order of activity are iodo-
form, potassium iodide. Potassium iodate appears to have
no effect.

5. The suggestion is made that amphibian metamorphosis is
a result of the interaction of environmental agencies, such as
iodin and its compounds, with the hereditary factors controlling
the growth processes.

RELATION OF IODIN TO THYROID 425

LITERATURE CITED

Auten, B. M. 1918 The results of thyroid removal in the larvae of Rana
pipiens. Jour. Exp. Zodl., vol. 24, no. 3.

GuUDERNATSCH, J. F. 1914 Feeding experiments with tadpoles; a further con-
tribution to the knowledge of organs with internal secretions. Am.
Jour. Anat., vol. 15.
1916 Studies on internal secretions. IV. Treatment of tadpoles
with thyroid and thymus extracts. Reported at the thirty-third
session of the Am. Asso. of Anatomists.

Morse, M. 1914 The effective principle in thyroid accelerating involution in
frog larvae. Jour. Biol. Chem., vol. 19, p. 421.
1918 Factors involved in the atrophy of the organs of the larval
frog. Biol. Bull., vol. 34, no. 3.

Swinete, W. W. 1918 The acceleration of stctaianahents in frog larvae by
thyroid feeding and the effects upon the alimentary tract and sex
glands. Jour. Exp. Zo6l., vol. 24, no. 3.
1918 The effect of inanition upon the development of the germ cells
and germ glands of frog larvae. Jour. Exp. Zo6l., vol. 24, no. 3.

Resumido por el autor, Merkel Henry Jacobs.

La aclimatacién como factor capaz de afectar el punto en que
acaece la muerte de los organismos sometidos a
temperaturas elevadas

Si se conoce el tiempo necesario para producir la muerte de
las larvas de estrella de mar sometidas a una cierta temperatura
elevada, el tiempo necesario para producir el mismo efecto a cual-
quier otra temperatura puede determinarse con un grado muy
aproximado de exactitud. En general, el coeficiente de tempera-
tura es proximamente 2 para cada elevacion térmica de 1°C. Elco-
eficiente de temperatura de Paramoecium bajo condiciones seme-
jantes estdé mucho mas sujeto a variacién, pudiendo ser 3 0 mas
algunas veces, en otras ocasiones menos de 2. Durante la ele-
vacion gradual de la temperatura en las larvas de estrella de mar,
se suman los efectos nocivos de todas las temperaturas por las
cuales han pasado durante dicha elevacién y mueren casi en el
mismo momento en que se alcanza el punto en que deben morir
tedricamente como resultado de la suma de todos los efectos noci-
vos. El punto en que tiene lugar la muerte del animal es tanto
mas bajo cuanto mas lenta es la elevacién de la temperatura. En
Paramecium, por el contrario, el punto en que el animal muere
es tanto mds alto cuanto mds lenta es la elevacién de la tempera-
tura. En esta especie la aclimatacién modifica las relaciones tan
simples que se presentan en la larva de la estrella de mar. El
grado de aclimatacién en una forma determinada puede estimarse
cuantitativamente determinando el ‘‘exceso de resistencia” (sur-
plus resistance) mediante el método que el autor describe en el
trabajo. Medido en términos de cantidad de efectos nocivos
necesarios para producir un resultado fatal, este ‘‘exceso de resis-
tencia’”’ es proximo a cero en las'larvas de estrella de mar, mien-
tras que en Paramecium llega a ser 45. Estas cifras dan una
medida aproximada de la capacidad de adaptacién a tempera-
turas mds y mds elevadas en las dos especies mencionadas.

Translation by Dr. José F. Nonidez,
Columbia University.

‘AUTHOR'S ABSTRACT OF THIS PAPER ISSUED
BY THE BIBLIOGRAPHIC SERVICE, DECEMBER 9

ACCLIMATIZATION AS A FACTOR AFFECTING THE
UPPER THERMAL DEATH POINTS OF
ORGANISMS

M. H. JACOBS

_ University of Pennsylvania
1. INTRODUCTION

The question of the effects produced on organisms by high
temperatures is one which has received the attention of biologists
formany years. The olderworkers were interested chiefly in the
determination of the so-called ‘upper thermal death points.’
A résumé of their observations is given by Davenport (’97). In
more recent times, the importance of the time factor, overlooked
in this earlier work, has been recognized, and modern investi-
gators have been more concerned with ‘temperature coefficients’
(Piitter, ’14; Kanitz, 715) and with the possible causes of injury
at the elevated temperatures. In most of the recent, and in
practically all of the older work, however, a factor not sufficiently

taken into account is the method by which the temperatures used
in the experiments have been attained.

There are, in general, three chief ways of bringing an organism
to a given high temperature. 1) The change may be practically
instantaneous, as, for example, if a minute animal in a small
quantity of water is suddenly expelled from a pipette into a
large volume of water at the required temperature. 2) The
change may be gradual, but uniform, as, for example, if the
animal is placed in a vessel of water at room temperature,
and heat applied in such a way that the rise per minute remains
constant until the desired point is reached. 3) The change may
be gradual, but at a constantly decreasing rate, as, for example,
if the animal is placed in a test-tube containing water at room
temperature, aud the test-tube is then plunged into a large

427

ge > anagem me oi

~

428 M. H. JACOBS

vessel of water which is kept at the final temperature. In this
case, the rise is at first rapid, becoming progressively slower and
slower—being represented, in fact, by the logarithmic curve of
Newton’s well-known ‘law of cooling bodies,’ except that the
temperature in this case is increasing instead of decreasing.

Of the three methods mentioned, the third is generally unde-
sirable, partly because of the greater difficulty of making allow-
ance for a constantly changing rate of temperature increase,
partly on account of the difficulty of determining the exact time
when the desired temperature has been reached, and chiefly
because of the great length of exposure (due to the slow rate of
change as the end point is approached) to temperatures whose
effects are almost as great as those of the one finally attained.
Method 1, in exact work, is applicable only to very small organ-
isms, since any attempt to apply it to large ones results in secur-
ing essentially the effects of method 3, with the additional disad-
vantage that on account of the slow conduction of heat, different
parts of the body reach the final temperature at different times.
Method 2, therefore, which involves raising the temperature at
a known rate until the desired point has been reached, is the most
suitable one for all except very small organisms and has been most
frequently employed. But in the past very little effort has been
made to take into account the influence on the final result of the
rate at which the temperature is raised. That this factor is
probably of importance is obvious, but to predict in advance in
what direction and to what extent it will operate is not ee
an easy matter.

Suppose, for example, that in a certain experiment. a io of
organisms are brought in the course of ten minutes from room
temperature to 40°C. and kept at the latter point until death
occurs. Would the time required to cause death at 40° be
greater, or less, if in another similar experiment the preliminary
rise were allowed to occupy thirty minutes instead of ten? It
might be argued, on the one hand, that the slower rate would
be less favorable to the organisms than the rapid one because of
the greater length of exposure to temperatures below 40°, but
still sufficiently high to produce in the aggregate considerable

UPPER THERMAL DEATH POINTS 429

injury before the final temperature had been attained. The
possibility exists, however, on the other hand, that the slower
rate would be more favorable than the rapid one in giving greater
opportunity for adjustment or acclimatization to occur. Which
of these two alternatives is the correct one for a given form can,
as a matter of fact, be decided only by experiment.
In the present paper a method is suggested for determining
this point and for dealing quantitatively with certain other
- aspects of the general problem of acclimatization. The writer
wishes to express his indebtedness to Prof. F. R. Lillie for kindly
placing at his disposal on several occasions the facilities of the
Marine Biological Laboratory at Woods Hole and to Mr. Francis
H. Adler for assistance in making certain of the observations on
which the paper is based.

2. MATERIAL AND APPARATUS

In the experiments to be described, the use of both methods 1
and 2 was necessary for the quantitative estimation of the extent
to which acclimatization occurs. For this reason, only small
organisms were employed, starfish larvae eighteen to forty-eight
hours old and Paramecium caudatum being the ones chosen.
The medium in which they were heated was for the starfish
larvae fresh sea-water and for Paramecium, in most cases, the
natural culture fluid filtered to remove all animals. It was
recognized that the complex nature of the culture fluid might
introduce undesirable complicating factors, but preliminary
experiments showed that, as a matter of fact, distilled water,
which would naturally have been preferred on account of its
uniform composition and in which the animals lived normally
at room temperature for days, was quite unsuitable for sudden
exposures to high temperatures, the animals dying far more quickly
in it than in their own culture medium, and the results obtained
being markedly irregular. That at least part of the effect of the
distilled water was of an osmotic nature was shown by the fact
that the addition to the same water of slight amounts of neutral
salts or even of cane sugar made it considerably lessinjurious. It

THE JOURNAL OF EXPERIMENTAL ZCOLOGY, VOL. 27, NO.3 ~

SS Gey =| a ep lat tao Vio: [oe rn ir mn ae eee ce aeronea

430 M. H. JACOBS

is perhaps possible also that the absence of appreciable amounts
of ‘buffer substances’ may have been another of the factors con-
cerned, since there is some evidence of the production of abnornial
amounts of acids at elevated temperatures. At any rate, it was
found that apparently the most reliable results could be ob-
tained when normal culture fluid was used, although very similar
results were also secured in some cases with pond-water when
the animals had been kept in it for at least twelve hours previous
to the experiments.

The apparatus employed was of a sin.ple nature. It consisted
of a 2-liter beaker, used as a water-bath, supported on a stand
and heated from below by an alcohol lamp whose position could
be altered to furnish much or little heat as desired. In the
beaker were placed a number of test-tubes containing enough
water or culture fluid to make them float upright. The trans-
parency of the whole apparatus was found to be of advantage,
not-only in favoring such manipulations of the material as were
necessary, but in making it possible to observe the visible effects
_ of the high temperature on, for example, the movements of the
animals.

When a sudden exposure was desired, the water in the water-
bath and in the test-tubes was first allowed to assume the proper
temperature, and then a considerable number of the organisms
were taken in the smallest possible quantity of water in a capillary
pipette (this being very easy in the case of both of the animals
used on account of their habit of collecting in a dense ring around

_ the edges of the culture jar) and suddenly forced into one of the

test-tubes in such a way as to insure thorough mixing. The
quantity of water used was so small as practically not to affect
the temperature of the water in the test-tube, calculation showing
that the momentary lowering of its temperature, which was not
even indicated on an ordinary mercurial thermometer, could not
have been, as a rule, more than 0.1°C. After this sudden intro-
duction to the temperature of the experiment the organisms were
either ail allowed to remain in the test-tube for the required
length of time and then suddenly poured into sufficient cool
water to bring them back immediately to within their normal

UPPER THERMAL DEATH POINTS 431

range of temperature, or they were removed, a few at a time, at
the proper intervals with a capillary pipette.

Where a gradual rate of temperature increase was desired, the
same general methods were employed except that the animals,
instead of being introduced suddenly into the test-tubes, were
placed in them at room temperature and the whole apparatus
was heated at the desired rate, samples of the animals being
removed, usually at half-degree intervals. The animals, whether
suddenly or gradually exposed, were kept under observation
after removal in Syracuse watch-glasses until they had either
died or recovered, which in some cases required as much as
twenty-four hours, although as a rule their behavior when first
examined left little doubt as to the ultimate outcome of the
experiment.

3. METHOD OF ESTIMATING ACCLIMATIZATION

The extent to which acclimatization occurs during a slow rise
of temperature may theoretically be estimated by first finding
by method 1 (where there is no opportunity for preliminary
acclimatization to occur) the amount of injury inflicted in unit
time at the various temperatures passed through during the
rise, and in them adding together these separate injuries, be-
ginning with the lowest temperature, and taking into account
the duration of each, until a total just sufficient theoretically to
cause death is arrived at. The point at which this total is
reached is compared with the observed death point in the case
of the gradual rise. If the two points practically coincide, it
may be said that there is no evidence of acclimatization.- If, on
the other hand, the observed death point is higher than the
calculated one, the presumption is that acclimatization has
occurred and the amount of the latter can be estimated, roughly
at least, in quantitative form. It must be remembered, of
course, that the calculated death point cannot be determined by
merely adding the theoretical amounts of injury at, for example,
34°, 35°, 36°, ete., since the rise does not proceed by a series of
sudden jumps, but continuously. Since, however, the relation of

432 M. H. JACOBS

the amount of injury inflicted in unit time at any one tempera-
ture to that inflicted in the same time at any other temperature
is, for a certain range, in the forms studied, governed by a simple
mathematical law, it is possible by making observations at a
few selected temperatures, and thus determining the necessary
constants, to calculate the theoretical effect of a continuous
change of temperature at any desired rate. The details of the
method will be made clearer in the following sections where the
actual experiments are discussed.

4, EXPERIMENTS ON STARFISH LARVAE

Since the results obtained with starfish larvae are simpler than
those with Paramecium, they may be considered first. In
table 1 are given the lengths of exposure found to cause death
when the animals were suddenly subjected by method 1 to the
temperatures in question. The fatal exposure in each case is

TABLE 1

Times required to kill approximately one-half of the individuals of starfish larvae
when suddenly subjected to various temperatures :

E june 16, 18 HOURS OLD. JUNE 21, 48 HOURS OLD | JUNE 22, 24 HOURS OLD PF eba 8t.
| | |
a Fatal exposure | Qu Fatal exposure Q1 Fatal exposure | Qi Fatal exposure
deg.C
40 8 seconds 10 seconds
1.9 1.8
39 | 15 seconds 18 seconds
i} 7
38 | 23 seconds 30 seconds
Pe heel
37 | 50 seconds 50 seconds 45 seconds 35 seconds
1s 1.9 2.0
36 | 1.25 minutes 95 seconds 1.5 minutes
Pe PY Be 25
35 | 2.75 minutes 3.5 minutes _ 4 minutes 2.5 minutes
2.5 2.3 2.0
34 7 minutes 8 minutes 8 minutes
PAL ; 2.5
33 | 15 minutes é 20 minutes 13 minutes

ayy 45 minutes 30 minutes

—————$—— eee OO”]

)

taken somewhat arbitrarily, as the time required to produce
injuries from which approximately half of the individuals failed
to recover. The actual death of the animals, according to the
temperatures employed, may occur in from a few minutes to
twenty-four hours or more after restoration to normal conditions.
Undoubtedly such differences are in certain respects significant,
but for purposes of immediate comparison they may be disre-
garded and the degree of injury which is just sufficient ultimately
to lead to death, regardless of the time required, may be accepted
as the most satisfactory available criterion. Itmay be mentioned
that the starfish gastrulae obtained from a single lot of eggs
show little individual variation; the fatal exposure is very nearly
the same for all. In this respect they differ from Paramecium
in which the individual differences are large.

It will be noticed in table 1 that the time required to produce
fatal injury at any temperature bears a fairly definite relation
to the time required at other temperatures. Thus, at 34°, for
example, about twice as long a time is required as at 35° and
about one-half as long a time as at 33°. Expressed in mathe-
matical symbols,

UPPER THERMAL DEATH POINTS 433

Ly
Lg+1

=Q:=2

where L denotes the length of life, @ the temperature, and Q,
the temperature coefficient for a change of one degree. Values
of Q, are given in alternate columns of table 1. The general
average of all of the values of Q, is 2.1. This value agrees closely
with that found, for example, by Loeb (’08) for the eggs of
Strongylocentrotus and Moore (’10) for Tubularia crocea.

These results may also be stated in another form (table 2).
The amount of injury (Is) inflicted at, the temperature @ by an
exposure of unit time (one minute) can be expressed in quanti-
tative form by taking as unity the amount of injury just
sufficient to produce death. Thus at 38°, in the series selected
for table 2, where an exposure of twenty-three seconds is necessary
to cause death, Isg>-=2.6; in the same way I3;-=0.14; and the
other values are given in column 2 of table 2. The mathematical

434 M. H. JACOBS

TABLE 2

- Theoretical amounts of injury inflicted on starfish larvae at various temperatures.
The fatal exposures are taken from column 1 of table 1

TEMPERATURE TOTAL EXPOSURE INJURY IN UNIT TIME
deg. C. seconds
40 8 7.5
39 15 “ 4.0
38 23 2.6
37 50 ’ i2
36 75 ea 0.8
35 165 > 0.36
34 420 y 0.14
33 900 3. 0.07

relation that exists between the amounts of injury inflicted in
unit time at different temperatures is

iE =a I,Q?

where I, is the amount of injury inflicted at the temperature
chosen as the standard for comparison, and I, the amount
inflicted at any other temperature separated from the first one
by p degrees. If the second temperature is lower than the
first, p, of course, has a negative sign. Of the two constants in
the above expression, Q, may in general be taken for starfish
larvae-with sufficient accuracy as equal approximately to 2,
and I, may be determined experimentally for a given lot of
organisms for any convenient temperature, preferably a rather
low one, as the percentage of error is then less. Having these
two constants, it is possible to calculate not only the amount of
injury that would be inflicted by an exposure of any length to
any temperature to which the above equation applies, but like-
wise the amount of injury that ought theoretically to be in-
flicted during a gradual rise from room temperature to any
desired temperature. In the latter case, the amount of injury
would be represented graphically by the area of the curve: “/

y =aQr

UPPER THERMAL DEATH POINTS 435

between the limits x = — b (room temperature) and x = p (the
highest temperature attained) ; b and p, of course, being measured
from the temperature selected as the point of comparison. The
constant a is the amount of injury, lo, inflicted in unit time at
this temperature. The area of the curve, A, which represents
the total ey I, therefore is:

A=I= a Qi dx -9°( 25-25)

Since b (the aearen of degrees the room temperature lies below
the temperature chosen for comparison) is relatively large, the
second half of tne expression within the parentheses becomes
negligibly small and may be disregarded. This is equivalent to
calculating the injury that would be inflicted in a rise from an
infinitely low temperature instead of from room temperature,
but this amounts to practically the same thing, since even
considerably above room temperature the injury inflicted in
env ordine~y time has ceased to be appreciable.

If instead of Taisit,;; “ho temperature at the rate of one degree
per minute as implied in the Gienianion just given, the rate had
been slower, say one degree in t minutes, the right-hand side of
the equation would have to b} multiplied by t. The general
expression therefore for the are, A, which represents the total
injury, I, inflicted up to the Ghmaperature p- when the rate of
rise is one degree in t minutes becomes (when a is replaced by
its equivalent I,):

Dp
_ Ey r Qi
: - log, Q:

In the case of starfish larvae where Q, is equal to approximately
2.0 and log. Q, therefore to approximately 0.7 we have finally:

9p .
E=ti, 3
pc O.8
In case it is desired to know how high the temperature would
have to be raised to inflict just fatal injury, it is only necessary

436 M. H. JACOBS

to substitute for I the numerical vale 1.0 and solve the equation.
for p. In such cases (taking log fio 2 = 0.3)

0.7
loew( tr)
O10 tl, v4

Peis 10S ‘

The results of applying this method to a gradual and regular

rate of temperature increase in the case of starfish larvae are

shown in table 3. In the first column is given the rate at which
the temperature was raised, in the second the observed death

point, and in the third the point at which death ought theo- -

retically to have occurred (i.e., the point at which the area
enclosed by the curve becomes unity) when the value of the
constant, Q,, was taken as equal to 2 (this value holding approxi-
mately for all of the starfish larvae studied). The value of Ip,
which varies somewhat for different lots of larvae according to
age, etc., was determined especially for the animals used in these

experiments, and was found to be 0.05 at ae temperature.

(83°C.) chosen for comparison. r

It must be recognized, of course, that for the portion of the
curve between room temperature and 32°, no exact observations
are available, and it is uncertain to what extent the above equation
applies to it. But the area of this portion of the curve is in any
case so small as compared with that above 32° that the final
result would be little affeeted even if a different relation were

TABLE 3

Temperatures at which death of starfish larvae occurred afte~ varying rates of tem-
perature increase from a starting point of approximately 20°C.

THEORETI- THEORETI-~
CAL DEATH CAL DEATH

RATE OF TEMPERATURE TEMPERA-~ TEMPERA-
INCREASE IN OBSERVED DEATH TEMPERATURE TURE TURE
DEGREES PER MINUTE CALCULATED | CALCUI-ATED
FROM FROM

Qi = 2.0 Qi = 2.2

1°C. in 1.8 minutes | About one-third dead at 36.0° 36.0° 30280

1°C. in 4 minutes 35.0° Sul ih 34.8°
1°C. in 5 minutes 34. 5e 3b a 34.5°

1°C. in 8 minutes All living at 33.5°, all One. at 34.0°] 33.8° 33.9°

UPPER THERMAL DEATH POINTS 437

shown to hold in this region. It may also be noticed that for the
region from 32° to the point of death in these particular experi-
ments the value of Q; is in general higher than 2.0, the approx-
imate average value for the whole range of temperature studied.
In the last column of table 3, the theoretical death temperature
is therefore calculated for comparison from the value, Q, =2.2.
It will be noticed that in either case the calculated death tem-
perature lies within a few tenths of a degree of that actually
observed, and the amount of acclimatization that bas occurred,
if any, is consequently extremely small. In similar experiments
on Paramecium, immediately to be described, the difference may
amount to several degrees.

5. EXPERIMENTS ON PARAMECIUM CAUDATUM .

: Tn the case of Paramecium, the results are more complicated.
In the first place, there is considerably more cultural and racial
variation in the length of life at any given temperature (de-

termined by method 1) than in the case of starfish larvae where
the results, on the whole, seem to be remarkably uniform. This
is shown in table 4 where some of the results obtained with this
form are summarized.

The figures in columns 6 and 7 and probably in column 1 are
for the three-vacuoled race described by Hance (715, 717), which

TABLE 4

Times required to kill approximately one-half of the individuals of Paramecium
caudatum of different races at different temperatures

|
RACE 1 (?) RACE 2 | RACE 3 RACE 4 RACE 5 RACE 6 RACE 6§

TEMPERA~

TURE

deg.C :
43 30.0 sec. : 15 sec. | 30 sec.
42 1.5 min.| 15.0 sec. | 20 0 sec. | 20.0 sec. | 20 sec.; 1 min.| 2 min.
41 4.5 min. | 45.0 see. 45 sec. | 1.0 min.|} 1 min.!| 8min.| 4 min.
40 13.0 min.} 2.5 min.}] 2.5 min.| 2.5 min.| 5min.}| 20min.| 7 min.
39 18.0 min.} 3.0 min.| 3.0 min.| 4.0 min.| 9min. 18 min.
38 3.5 min. | 7.0 min.
37 4.0 min.
36 | 6.0 min.

438 M. H. JACOBS

in these, as well as in other experiments, has shown itself to be
remarkably resistant to high temperatures as compared with the
ordinary races. In the second place, the temperature coeffi-
cient, Q:, in a given set of experiments is subject to far more
variation than in the case of starfish larvae, being as a rule much
higher (usually approximately 3) in the region above 40° than in
that below this temperature, and being subject at all times to
considerable and sometimes inexplicable fluctuations. For this
reason, calculations made by the method described are not so
exact as in the case of the starfish larvae, but fortunately this is
not necessary since Paramecium shows such a high degree of
acclimatization that the error due to the simplifying assumption
that the value, Q:=3, applies to ail temperatures is not able to
disguise this fact. In other words, the error that arises from
taking this value of Q, for the entire range, while, as a matter
of fact, it is considerably less at lower temperatures, is of such
a nature as simply to make the difference between the calculated
and observed death points less striking than it would otherwise
have been. If acclimatization is shown when such a simplifying
assumption is made, it would a fortiori. be indicated if more
exact calculations had been made.

This point will be made clearer by an actual example. It was
found in one set of experiments that for the three-vacuoled race,
Q, between 40° and 43° was equal to almost exactly 3.0. The
length of life after a sudden exposure to 41° was found to be 4.5
minutes, i.e., I, (taking this temperature as the standard of
comparison) was equal to 0.22. It was also found that when
the animals were heated gradually, at the rate of 1° in eight
minutes, the observed death point was very close to 44°. The
calculated death point, on the assumption that Q; is equal to 3.0
for all temperatures is approximately 40.6°, a difference of 3.4°,
indicating a very considerable amount of acclimatization. If
instead of assuming that below 40° the injury at any temperature
in unit time is only one-third as great as that at the temperature
one degree higher (as implied by the value, Q: =3), we had taken
into account the lower values of the temperature coefficient
which usually apply to this region. it is clear that the amount of

UPPER’ THERMAL DEATH POINTS 439

injury inflicted at the temperatures below 40° would not drop
off so rapidly, or, in other words, that the animals would be
more injured during their gradual rise by the time they had
reached 40°, and that consequently the calculated death tem-
perature would be even lower than before. But this would only
make stronger the evidence of acclimatization already obtained
by the rough calculation.

It is of some interest not merely to show that acclimatization
occurs, but to attempt to express its extent in quantitative form.
This can be done in an approximate fashion by calculating the
area enclosed by the given curve up to = 44° and comparing
this area with that which represents unit injury, i.e., death.
Such results, of course, are only rough approximations, but have
nevertheless a considerable interest. Using the formula already
given: :

Q?
=tI,-
: . log. Qu

the area in the case Just mentioned proves to be 44 units of
injury. In other words, before death occurred, during the
gradual rise, the animals had withstood about forty-four times
the usual fatal injury. It is suggested that in this and in similar
cases the excess in area enclosed by the curve of injury, up to
the point of death, over the area (taken as unity) which repre-
sents an amount of injury just fatal when the change is sudden,
may be called the surplus resistance, and be used as a rough
quantitative measure of the extent of acclimatization. In this
case the surplus resistance is equal to 43. The animals have, in
other words, added to their normal lives, so to speak, forty-
three additional lives by their ability to adjust themselves to
the changing environment. °

The favorable effect of a slow as compared with a rapid rise
of temperature on Paramecium is shown by another experiment
in which method 3 was combined with method 2. In this case,
a tube of very small caliber (3 mm.) with extremely thin walls
was prepared by drawing out the lower portion of a thin-walled
test-tube in a flame to a considerable length and sealing the small

Ss ee

440 M. H. JACOBS ge

end. Drops of water containing Paramecium could be placed in
it and removed with a capillary pipette. It was found by the
insertion of a thermocouple in such a drop of water and another
in a vessel of water at 41°C. into which the tube was plunged,
that the water in the tube reached approximately the tempera-
ture of that in the surrounding vessel in about twenty seconds.
This fact being known, a number of animals were placed in it
and plunged into water at 41° for two minutes and twenty
seconds (giving therefore an exposure of two minutes at 41°).
On removal, it was found that all were fatally injured. Another
lot were placed in the same tube, but they were brought at a
uniform rate from room temperature to 41° in two minutes and
then kept at exactly 41° for two minutes longer. In this case
about one-quarter of the individuals recovered. A third lot
were treated in the same way except that in this case the rise ©
to 41° occupied twelve minutes. About one-half of these animals
recovered. Doubtless a slower increase of temperature would
have given even a higher percentage of recoveries. With starfish
larvae, it may be mentioned, that experiments made in the
same manner showed in every case exactly the reverse effect,
i.e., the slower the rate of temperature increase, the higher
the mortality.

A considerable number of other experiments were tried with
Paramecium with the same general results as those mentioned.
The degree to which a slow change increased the final resistance
varied considerably with different races and under different ex-
perimental conditions, but in all cases it was very appreciable.
It is apparent, therefore, that in the case of this organism, at
least, the upper thermal death points that will be obtained in
different experiments by the methods usually employed may be
expected to be subject to considerable variations, which in many
cases will be difficult to predict. To what extent the same prin-
ciple will be found to apply in the case of other organisms can be
determined only by further observations. In any event, however,
the author believes that to be of value, data on the upper thermal
death points of organisms must include not only the length of

UPPER THERMAL DEATH POINTS © 441

exposure to the particular fatal temperature under considera-
tion, but in addition, an exact statement of the manner in which
this temperature was reached.

SUMMARY

1. The length of life of starfish larvae eighteen to forty-eight
hours old at temperatures between 32° and 40°C. is governed
with a very fair degree of accuracy by the relation:

—? _ = Q, = approximately 2

For Paramecium, the value of Q; is subject to considerably more
variation; above 40°C. it is Preduently in the vicinity of 3;
below 40° often less than 2.

2. Knowing the above relation and the length of life after a
sudden exposure to one or more selected temperatures, it is
possible to calculate by the method given in the body of the
paper the point at which death ought theoretically to occur
when the temperature is raised uniformly at any given rate. By
comparing this point with the observed death point under the
same conditions, it can usually be determined whether or not
acclimatization has occurred.

3. With the different rates of temperature increase employed
in these experiments the observed death points of starfish larvae
agree very closely with the calculated ones, indicating prac-
tically no acclimatization. With Paramecium caudatum the
observed death point may be much higher than the calculated
one, indicating that acclimatization occurs even in experiments
of short duration.

4. If desired, the ‘surplus resistance’ in a given experiment
may be obtained in quantitative form by determining the excess
in area enclosed by the curve of injury up to the point of death,
over the area (taken as unity) which represents an amount of
injury just fatal when the temperature is changed suddenly.

5. As determined in this way, the ‘surplus resistance’ for star-
fish larvae for a number of different rates of increase of tempera-

449 M. H. JACOBS

ture was found to be in the vicinity of zero., For Paramecium

caudatum, on the other hand, a ‘surplus resistance’ as high as
43 has been found.

6. In general, the slower rates of temperature increase are
more favorable for Paramecium and more unfavorable for
starfish larvae than the more rapid ones.

7. It is suggested that future data on upper thermal death
points, ete., shall include not only the times of exposure to the
temperatures In question, but exact statements as to the methods
by which these temperatures have been reached.

LITERATURE CITED

Davenport, C. B. 1897 Experimental Morphology. New York. Vol. 1.

Hance, R. T. 1915 The inheritance.of extra contractile vacuoles in an unusual
race of Paramecium caudatum. Science, N.S., 42.
1917 Studies on a race of Paramectum caudatum possessing extra
contractile vacuoles. Jour Exp. Zodl., vol. 23.

Kanitz, A. 1915 Temperatur und Lebensvorgange. Berlin.

Loes, J. 1908 Uber den Temperaturkoeffizienten fiir die Lebensdauer kalt-
bliitiger Tiere und iiber die Ursache des natiirlichen Todes. Pfliiger’s
Archiv, 124.

Moors, A. R. 1910 The temperature coefficient of the duration of life in
Tubularia crocea. Arch. Entwick., Bd. 29. 4

TH™ JOURNAL OF EXPERIMENTAL ZOOLOGY, VOL. 27, No. 4
FEBRUARY, 1919

a fs

Resumido por el autor, G. M. White.

La asociacién y distincién de los colores por los peces Umbra
limi y Eucalia inconstans.

Los peces de agua dulce Umbra limi y Eucalia inconstans
fueron ensefiados a asociar los alimentos con un cierto color y
al mismo tiempo a asociar substancias insipidas, tales como el
papel, con otro color. Los individuos de Umbra distinguian
entre si las siguientes luces monocromdticas: roja y verde, roja
y azul, amarilla y verde. La variacién de intensidad de las
luces roja y verde desde 1.4 em. hasta 4.9 cm. no impide la
distincién del color por parte de los peces, indicando esto que
su reaccién en tales circunstancias se debe mas bien al color de
la luz que a su intensidad. Mientras que los individuos de
Eucalia distinguian entre las luces roja y verde, asocidndolas
con el alimento y el papel, nunca pudieron aprender a diferen-
ciar el azul del amarillo. Ambas clases de peces fueron también
sometidos a la accién de la luz transmitida a través de placas —
fotogrificas veladas con diferentes tonos de gris, para probar si
podian asociar con ellas los alimentos y substancias insipidas,
conforme habian hecho con las luces de otros colores. Tal
asociacién no se llevé a cabo, lo cual prueba atin mejor que la
distincién de los colores por parte de estos animales se debe
mas bien a sus longitudes de onda que a su intensidad. Los ex-
perimentos efectuados con ambos peces para comprobar si
pueden percibir diversos dibujos dieron tan solo resultados
negativos, indicando esto que su distincién asi como la de las
diferencias en los fondos no son de gran importancia en la busca
del alimento. La percepcién del color y la del movimiento
parecen ser de la mayor importancia para este fin.

Translation by Dr. José F. Nonidez
Columbia University

AUTHOR’S ABSTRACT OF THIS PAPER ISSUED
BY THE BIBLIOGRAPHIC SERVICE, FEBRUARY 3

ASSOCIATION AND COLOR DISCRIMINATION IN
MUDMINNOWS AND STICKLEBACKS

GERTRUDE MAREAN WHITE ;
Department of Zoology, University of Wisconsin
TEN FIGURES
CONTENTS

LEST NO OS SA ee ee ee nS ee... Oop 444
ieview of literature on the behavior of fishes. ..:......0.092....... 72s: 444
General review of literature on color vision in fishes................... 446
Wandsitons,omexperimentation = ccjc. it...so 1 es « a Sees... eae. 452
MRGivieniveuMOVEMECMES. cus. thoes. Shscieoc 5 oarn eS - . - eR 453
Periodic activities and daily rhythm of the mudminnow.................... 453
Senperareany used in seeking TOOd:. .. 5. ...). 22. = gas eee ee tO 455
Cia LG ie CONS (Crastaeh cP Coy 0 ae ae rr ree ac =e 456
Experiments performed upon the mudminnow.......................... 458
(Crovloneyo yoy: WoC eee eee eo) eee ee MEE. cose ae 458
menochromatic: light filters... 2.2. . ./>c.ccaceptentletaeneere enna 462
Constant and varied intensity of illuminmation...................... 466
Monochromatic green and yellow filters........................008- 469
shorzedvepnotorraphic) plates’... +./..-aaeeeeet eee = «neat 474
Summary of experiments in regard to color vision of mudminnows..... 475
Experiments performed upon the stickleback.......................... 475
Monochromatic blue and yellow filters.......................0..... 481
Monochromatic redtand ereen filters.<....... .:.1<.0 gees eee. 481

PN Re httie OMAR TICKLE WACKS 28. o.cts ood. < ~ i. 2. | EE ee: wes 483

Hor redumphovoonaphicnplatesic: +. .d..... +... =. deat Seeeeeeteon 485
Summary of results in regard to color vision in fishes.................. 485
Experiments on the discrimination of patterns.......................0.000s 488
PESO UG EOMIE GCOMERIE TH NO VMN INCRE so 808 66 f0o.-va.zcnnore's. ce olen: +. =a) 5) RIG OE a tales ov 489
VPESHOlL ASSO CLARION SNE eM rt eis... eS A ors be Sao «1a apo A aco seo 489
Slica CymmmeasOeMttlOUS eats ho eco. ss. cok oe MR Sou ae oe 491
Complexity ai AssOebiongmeiee!, 4 24s..5 8%... sys s+ ale CE gc cote * 491
(eeSioamtchelayevelen (als GY tcrer hey n\s | A 2 et i ee ere. Sl ae eee 492
Modification of associations................... Ry 3 05s OR Ree 492
Generar disetseronrane COUCIIBIONS, sete. cc... . ... soe Dee we ve see ee 493
S[OMNaN OVS Ee Oe As A bo clonic we ableton ae. eae 6 oo clo.o Uae 2 494

444 GERTRUDE MAREAN WHITE

The behavior of fishes has been a subject of special interest to
a large number of scientific investigators. While observations
have been made upon a number of species, insufficient evidence
has thus far been brought together to furnish a basis for the
comparison of various aspects of the psychology of fishes with
those of other vertebrates. In connection with this general
problem, a series of experiments on the behavior of the mud-
minnow, Umbra limi (Kirtland), and the stickleback, Eucalia
inconstans (Kirtland), were undertaken to determine their
ability to form associations and to discriminate colors and pat-
terns. These experiments were performed in the Zoological
Laboratories of the University of Wisconsin. The problem was
suggested by Prof. A. S. Pearse, from whom valuable criticism
and assistance were received. |

REVIEW OF THE LITERATURE ON THE BEHAVIOR OF FISHES

The gustatory and olfactory senses of fishes have been studied
by Parker, Copeland, and Herrick. Herrick (’03) concludes
that the bullhead, the shiner, and the spotted sucker perceive
their food through gustatory sense organs. They detect food
from a distance and exhibit a ‘seeking reaction.’ The gadoid fishes
(pollock, hake, tomeod) are stimulated to take food by the gus-
tatory sense, which is located on the fins as well as about the
mouth. The tactile sense is also used in finding food, combined
with the gustatory sense in these gadoid fishes. Parker (’10, 711,
712, 713) shows that a true sense of smell, distinct from,taste,
exists in the bullhead, the dogfish, and the killifish. He defines
smell in water as the perception of very dilute substances ema-
nating from a distance; taste as the perception of substances
near at hand and present in comparatively large amount. Cope-
land (12) shows that the puffer possesses a sense of smell by
which it is able to discover hidden food.

That fishes are able to hear is a tradition universally accepted
by fishermen. Yet Bdteson (’89’—90) asserts that fishes are not
desturbed by sounds made in the air, and that on the whole shocks
‘and concussions do not play much part in the activities of fishes.

ASSOCIATION AND COLOR DISCRIMINATION 445

Parker (’03, ’08, 710, ’11) believes that certain sounds of low
vibration, like the discharge of a gun, are heard and that the
sacculus is the chief organ of hearing.

According to Parker (’04), the lateral line organs are geneti-
cally related to the ear, and are not stimulated by light, heat,
salinity of the surrounding water, food, carbon dioxide, oxygen,
foulness of the water, currents, or sound, but by vibrations of
_ low frequency—about six per second. Since these organs appear

to be affected by such stimuli as disturbances caused by winds
and by bodies falling into the water, they may be of significance
in orientation, but take no more part in equilibration than the
skin, and are less important in this connection than the eye and
ear.

The sense of touch is well developed in fishes. Bateson (’89-
90) states that the sole appears to use this sense in discovering
its food. Herrick (’03) finds that the gadoid fishes which he
observed detect their food by means of the tactile sense com-
bined with gustatory.

Shelford and Allee (18, *14) made elaborate experiments
showing that fishes may react in various ways to gradients of
dissolved gases, but no study was made of the sense organs con-
cerned. The resistance of fishes to different concentrations of
oxygen and carbon dioxide is discussed by Wells (’15).

In a delicate and ingenious series of experiments, Lyon (’04)
proved that the reaction to current in the killifish, the secup, the
stickleback, and the butterfish is an optical reflex—as the fish is
carried down stream by current, the bottom of the stream ap
pears to move in the opposite direction; the fish has a tendency
to follow its passing field of vision, and consequently swims
against the current.

Experiments to show that goldfish and Fundulus ean find
their way through mazes are reported by Churchhill (’16) and
Thorndike (711), respectively.

Eigenmann (’00) shows that the integumentary nerves of the
blind fishes, Chologaster and Amblyopis, are sensitive to light.
According to Parker (’05, ’09), the same is true of ammocoetes;
but no salt-water fishes which he observed possessed such photo-

446 GERTRUDE MAREAN WHITE

receptors on the skin. Tschermak (15) gives a good survey o!
vision in fishes, in which he discusses conditions of vision in
water, the absorption of light by water, the formation of an im-
age in the fish eye, accommodation, and bifocal vision.

ns LITERATURE ON COLOR VISION IN FISHES

The question of color perception in fishes has been a matter

of considerable dispute and evidence concerning it has been
accumulated from various sources.

Adaptation to background by the pigment cells of the skin. The
expansion and contraction of pigment cells in such a way as to
conform the color and pattern of the skin to the background
against which the animal rests have been observed in many
fishes. If such changes in the pigment cells are brought about
by stimulation received through the eyes and central nervous
system, they may serve as evidence of color vision. Lowe (17)
states that the cells of the brook-trout begin to react to back-
ground after the yolk-sac is absorbed. When the trout are
placed in a dark dish, the pigment cells expand, making the fishes
appear dark; but when the fishes are in a light dish, the cells are
contracted, giving the skin a pale appearance.

Frisch (12, ’14) finds that Crenilabrus roissali changes in
color when subjected to red, green, and blue light. Adaptation
to green and blue light is by means of the contraction of the
pigment cells and also by an increase of the blue-green coloring
matter. He argues that the adaptation is to color rather than
to luminosity, for if the colors used are arranged as they would
appear according to their intensity to a color-blind person—
yellow, green, blue, red—the fish is reacting to the brightest by con-
traction and “to the darkest by expansion. This is contrary to
all other experiments on the reaction of pigment cells. Frisch
also finds that Phoxinus laevis adapts itself to green, blue, and
violet by the contraction of its pigment cells which produces a
lighter color, and to red and yellow by expansion of the red and
yellow pigment cells; the color patterns remaining unchanged
for months under constant stimulation. The color markings

ASSOCIATION AND COLOR DISCRIMINATION 447

of the skin conform to the general background rather than to
some particular part. In males the reactions are more pro-
nounced than in females. Frisch concludes that the stimulus
is received through the eye, since blinded fishes show no adap-
tive changes.

Sumner (11) states that the skin of the flatfishes, Rhom-
boidichthys podas, Phombas laevis, and Lophopsetta maculata,
shows adaptation in pattern, shade, and color. They react toa
black, brown, and gray, but not to red and yellow. Such
changes take place irrespective of the intensity of illumination.

Mast (14) finds that the flounders, Paralichthys and Ancylop-
setta, simulate their background in shade, color, and pattern,
exhibiting a remarkable ability to mimic blue, green, yellow,
orange, pink, and brown backgrounds. Production of color
changes is regulated by stimulation through the eye and de-
pends upon the length of the light waves. That this indicates
color vision is supported by the fact that flounders adapted to
blue and green, when allowed a choice of backgrounds of different
colors, prefer the background with which they harmonize in
shade and color.

In his observations on coral-reef fishes, Longley (714, ’15, ’17)
finds that color changes in the pigmentation of the skin are com-
mon among even the most brightly tinted fishes, and that the
colors have a tendency to resemble those of the surroundings.

In general, these observations seem to indicate that fishes of
various genera exhibit adaptive reactions in their pigment cells
to backgrounds of various colors, that the stimulus is received
by the eye and transmitted through the central nervous system.

Mating colors. Bright colors, particularly reds and yellows,
appear on the ventral side of the males of many species at the
time of spawning. The amount of light at the place of spawning
must be sufficient for the female to perceive the colors if they
have any recognition value. Frisch (’12) cites examples of
fishes possessing such colors and spawning in shallow water by
day light and also of fishes spawning in deep water or at night
which do not exhibit decorative coloration.

-448 GERTRUDE MAREAN WHITE

Warning coloration. There seems to be no valid case of warn-
ing coloration in any animal fed upon by fishes. Reighard
(08) tried to discover whether the conspicuousness of coral-reef
fishes might not have this significance. He found that the gray
snapper could be taught to avoid snapping at red fishes when
they were treated so as to be unpalatable, but that when none
were artificially treated the gray snapper devoured all species
‘of coral-reef fishes with the same avidity. Longly (17) rejects
the hypothesis of warning coloration as accounting for the bright
colors of coral-reef fishes. |

Choice of colored lights and backgrounds. The method has
been tried of illuminating different parts of an aquarium con-
taining fishes with lights of different colors, or of placing va-
riously colored papers or glasses under or around the aquarium.
The fishes are allowed to choose the part of the tank they prefer.
The chief difficulty with this type of experiment is that unless
spectral light is used the colors are not pure, and it is extremely
difficult to obtain lights of various wave-lengths which have the
same luminosity. Pigmented papers have not been made
which will reflect light of a single color.

The first experiments relating to color discrimination were
performed by Graber (’84), who used glass slides of different
colors. Such screens were not ‘pure,’ but allowed light of va-
rious wave-lengths to pass through. Although the fishes Cob-
itus barbatula and Alburnus spec. showed decided preferences
for red, there is little to indicate that the choice was necessarily
due to the length of the light waves.

Bauer (710) reports a difference between light and dark
adapted fishes. Light adapted Charax puntazzo and Atherma
hepsetus avoided a light shining through a red filter 680 to 710u,
but when ‘dark adapted’ these fishes prefered red to blue, which
Bauer considered to be of the same intensity. These observa-
tions were interpreted to mean that fishes are able to recognize
colors, but that when they are ‘dark adapted’ color perception
of the red end of the spectrum ceases much sooner than for nor-
mal human eyes.

ASSOCIATION AND COLOR DISCRIMINATION 449

Goldsmith (712) arranged aquaria with colored bottoms.
Young plaice preferred red to any othér color and came to rest
there, while gobies avoided red, refusing to go through a red
passageway until it had been sanded. Red, yellow, green, and
blue were chosen in order by Gasterosteus. This author thinks
that her results show a color sense, but the possibility that the
fishes were reacting to brightness does not seem to be eliminated.

Feeding experiments. In such experiments a motive is intro-
duced. Discrimination on the part of the fish is indicated by
an attempt to take food.

Zolotnitzky (’01) placed pieces of wool of different colors
having the shape and:size of chironomid larvae on the wall of
an aquarium containing Macropodes. The fish snapped often
at the red wool, less frequently at the yellow, and left the other
colors untouched.

Frisch (’14) placed bits of food on colored paper of various
shades. Fishes that had been accustomed to eat yellow food
snapped at it in preference to other colors and red food was
taken by fishes trained to eat red. Red food was taken on a
black background, but black food was not taken from a black
surface nor gray from a gray background. Red and yellow
were often confused with each other and with purplish red, but
not with gray, green, or blue.

Minkiewicz (’12) taught a Julis vulgaris to seek food dropped
into the tank through a blue tube and at the same time to dis-
regard a piece of thread dropped in through a yellow tube.

- Goldsmith (’12) reports that plaice and gobies learned to take
food from colored forceps thrust into the water, and later chose
the color which had been associated with food even when the
relative position of the forceps was changed. The fishes per-
sisted in examining the same forceps after an interval of four
days even when no food was present.

Washburn and Bently (’06) were able to establish an associ-
ation involving ‘color’ discrimination in the creek club. This
fish was fed from forceps to which red sticks were attached.
When a similar pair of forceps attached to green sticks was offered
simultaneously, the fish preferred the red forceps, even when

450 GERTRUDE MAREAN WHITE

neither fork contained food. The probability that the dis-
crimination was based upon luminosity was said to be lessened
by using a much lighter red in some of the tests. Blue forceps
were distinguished from red in the same way. Food was later
placed in the green forceps, and the fish learned to go to the
ereon frst.“

According to Reighard (’08), the gray snapper can distinguish
colors. White Athermas were taken in preference to those
that had been stained blue. Though blue, light green, and dark
green Atherinas were taken indiscriminately, red Atherinas
were snapped at least often. Red Atherinas with the tentacles
of the medusa, Cassiopea xamachana, sewed into their mouths,
were refused, and very soon all red Atherinas were refused
whether tentacled or not. This association of unpalatability
with red lasted without any further practice from July 19 to
August 8.

The feeding experiments taken as a whole offer strong evi-
dence of a color sense in the fishes observed. The same criticism
may be made of all of them, however; pure colors were not
used, and the possibility exists that the fishes were reacting to
brightness.

Hess (09, 712, 713) is the chief opponent of color vision in
fishes, maintaining that fishes see colors only as shades of gray—
as a totally color-blind person perceives them. He offers the
following reasons for this view:

In spectral light young Atherina hepsetus and young Squalus
cephalus congregated in the yellow-green and green, i.e., in the
brightest part of the spectrum of the dark adapted totally color-
blind human eye. Some were found in the green-blue, very few
in the red. By moving a black card along the spectrum and
intercepting certain rays, the fishes could be driven inte the
-_blue or even into the violet, though they always returned when
the card was removed.. The longer light waves in the red pro-
duced no more effect upon the fishes than complete darkness.
The luminosity values of different parts of the spectrum were
worked out. This was done by lighting one-half of the tank
with monochromatic light and the other with equivalent mixed

ASSOCIATION AND COLOR DISCRIMINATION 451

light which could be varied in intensity. When the fishes were
arranged evenly in both parts of the tank, Hess considered that
the two lights were equally bright. By measuring the intensity
of white lights which had the same effect on the fishes as various
colored lights, he obtained a luminosity curve which agreed very
well with that of the totally color-blind human eye.

Hess offered the fishes imitation baits of various colors on
different backgrounds. If the brightness of the bait corre-
sponded with that of the background, it was not taken.

Contrary to the observations of Frisch, Hess found no adap-
tation to brightness in the pigment cells of the epithelium of
Crenilabrus.

For fishes living any distance below the surface, Hess insists
that a color sense would be useless because of the increasing
absorption of light by the water as greater depth is reached,
particularly the longer waves. Hence mating colors are value-
less. Hess admits the possibility, however, that fishes living
in shallow water may possess the ability to discriminate colors.

Hess also attempts to account for the reactions of Daphnia
and some other animals by assuming that they react to the lumi-
nosity of the spectrum as it appears to the color-blind human
eye. Loeb and Wasteneys (’15) criticise this assumption on the
ground that there is no proof that the heliotropic effects of
light in lower animals are accompanied or determined by sen-
sations of brightness, and, furthermore, that color-blind human
beings do not show any positive heliotropism. Hess’ further
contention that animals and plants are sensitive to different
parts of the spectrum—all animals to the yellowish-green, and
all plants to the blue—is shown to be incorrect.

From the sources discussed considerable evidence has been
accumulated to show that fishes perceive colors. Adaptive
changes in the pigment cells of the skin of various species in re-
lation to backgrounds of different colors have been observed,
and when allowed a choice, fishes show preferences for back-
grounds of particular colors. Mating colors may furnish further
evidence of color discrimination. Thus far there seems to be
no valid case of warning coloration in animals serving as food

452 GERTRUDE MAREAN WHITE

for fishes. The results of feeding experiments are strongly in-
dicative of a color sense. On the other hand, Hess contends
that fishes see colors as shades of gray, as a totally color-blind
uuman being perceives them.

CONDITIONS OF EXPERIMENTATION

The mudminnows and sticklebacks used in the experiments

to be described in this paper were obtained from Lake Wingra —

and Lake Mendota, near Madison, Wisconsin. They were not
kept in running water, since it was found that they thrived
_ equally well without it, provided the water was changed from
one to three times a week. City water was used because ‘t is
drawn from an artesian well and contains few organisms inju-
rions to fishes. Individuals were kept in separate jars and care-
fully observed, as many experiments as possible being per-
formed upon each fish. One mudminnow which is still alive has
been under observation over three years.

When first introduced into aquaria the fishes were left undis-
turbed for something like a week, except for changing the water.
They commonly refused to eat during this period of adjustment;
usually some died at first, but thereafter few were lost. By the
end of a week the survivors were likely to be hungry and suffi-
ciently accustomed to the presence of persons in the room to eat
bits of food dropped into the water. Shortly after this they
could generally be induced to take food at the surface, and after
several days to jump out of the water for food. It was neces-
sary to estimate carefully the amount of food to be given, as the
fishes have a tendency to consume large quantities at one time
and then fast for several days. In most cases feeding was car-
ried on in the laboratory from one to three months before ex-
periments were begun, or until the fishes had formed the habit
of taking food daily.

Although the following observations were made especially
on the mudminnow, they apparently apply to the stickleback
as well. In making selection for training experiments, marked
differences in the adaptability of fishes of different ages were
found. Whereas mature mudminnows spend most of the time

ASSOCIATION AND COLOR DISCRIMINATION 453

lying quietly in the bottom of the aquarium and are wary about
coming to the surface for food, the younger fishes swim about
actively, are less easily disturbed by jars and movements, and
take food more eagerly. But fry under one and a half inches
in length are undesirable for such work, as their movements are
irregular and unsteady.

INSTINCTIVE MOVEMENTS

Instinctive movements may be defined as locomotor responses
exhibited by an animal without previous training. Taken as
a whole, these responses make up what Jennings has defined as
the ‘action’ system, and they nearly always determine how any
animal is going to react under a given set of conditions. The
mudminnow and the stickleback have the same types of in-
stinctive movements, namely, swimming, leaping out of water,
and flopping about on land. The mudminnow swims rather
deliberately with a smooth motion. When accustomed to lab-
oratory conditions, it sometimes springs up and seizes objects
outside of the water. Before doing so, it usually hesitates a
short distance from the surface, switching its tail in an agitated
manner. If the tank containing the mudminnows is left un-
covered, the fishes are liable to leap entirely out of the recepta-
cle.1| Mudminnows bury themselves in the mud to tide over
dry seasons.

The stickleback swims in a jerky, nervous manner, never going
far in one direction, but darting hither and thither. It leaps
out of water, but usually not so far as the mudminnow; generally
it comes to the surface and bobs up and down, thrusting out
only its nose. It is less timid, though always wary.

PERIODIC ACTIVITIES AND DAILY RHYTHM OF THE MUDMINNOW

Seasonal variations in the activities of fishes are not readily
subject to laboratory observation. In almost all cases, however,
the best results in the training experiments to be described were

1 Tt is reported by Mast (715) that Fundulus leaps from tide pools and succeeds

in transporting itself by flopping along on land across a barrier of dry ground
more than 3 m. wide and 10 em. high.

454 GERTRUDE MAREAN WHITE

obtained in July, August, January, February, March, and April,
since during the summer and winter months the fishes were less
restless and came for food more readily. That better results
were not always recorded for experiments during the fall might
be due to the fact that fishes were usually obtained in Sep-
tember and early October and were not yet adjusted to labora-
tory conditions.

In the middle of April, May, and early June a marked rest-
lessness was noticed—often the fishes ate erratically and were
unfit for experimental work. It hardly seems probable that this
was due to a rise in temperature, as the fishes had been kept in
a room at ordinary temperature during the winter, and a series
of experiments had been carried on successfully during the hot-
test weeks of the summer. It was probably due to breeding
activities. The breeding season of the mudminnow comes dur-
ing the spring after the ice leaves the creeks and ponds where
they live. The fishes which have been confined in the laboratory
during the winter rarely, if ever, mature eggs, but there is prob-
ably a change in the gonads at this season. Two fishes which
had been accustomed to eat daily from forceps during the winter
months became restless in the spring, eating very irregularly,
but in July and August were again available for experiment.

The mudminnow was the subject of a series of observations
on daily rhythm of activity. Across one corner of a room was
hung a large opaque window shade. In this a hole was cut three
inches square and about three feet from the floor. A table
was placed in front of the curtain in such a position that vessels
containing fishes could be seen by the observer who was seated
behind the curtain. The space behind the curtain was dark-
ened, and the observer kept as quiet as possible so that her
movements might not disturb the fishes. The vessels con-
taining the fishes were always allowed to remain on the table
several hours before observations were made, During the hours
of the day and night, the movements of individual fishes within
the tanks were carefully mapped out on paper with as much
minuteness as possible, and the amount of time spent in each
position recorded with a stop-watch.

ASSOCIATION AND COLOR DISCRIMINATION 455

Twenty fishes (all young fry—1li to 1? inches—except one)
were observed during an entire night in November from 10:30
P.M. until 7:30 a.m. The vessels containing them were placed
on tables where there was only enough illumination to faintly
discern the outlines of the fishes. The position of each fish
was noted every half hour, also whether it was active or at rest.
Of 201 observations made, the fishes were in 124 instances near
the surface, and in 77 instances the fishes rested on or near the
bottom. At daybreak nearly all the fishes were moving about
actively. Likewise, nineteen fishes were observed at half-hour
intervals during one afternoon and evening. From all these
observations it was concluded that mudminnows, while only
slightly less active at night than during the day, exhibit some-
what greater activity at daybreak. Although very young in-
dividuals came to rest anywhere in the dish, they spent rela-
tively more time at the surface than on the bottom, whereas
older individuals evinced a preference for the botton. Protec-
tive adaptation would seem to cause the young fry to stay at the
surface, since the large fishes which are their natural enemies
are usually found near the bottom.

SENSE ORGANS USED IN SEEKING FOOD

_ In these fishes the senses of sight and smell are most used in
seeking food. The stickleback displays more alertness in using
both senses and much higher degree of acuteness of the olfactory
sense. The method used by Parker (’11) in testing the olfactory
sense of fishes was tried with both mudminnows and stickle-
backs. Cloth packets, one of which contained meat and the
other cotton, were suspended at opposite ends of the aquarium.
The mudminnows did not show that they perceived either
packet though they swam in close proximity to both.

The sticklebacks behaved differently. The appearance of the
packets attracted them at once. Those fishes which went to-
wards the packet containing meat darted furiously upon it and
pulled at it with great excitement, but those which swam in the
direction of the packet of cotton in most cases stopped about
4 cm. away and turned off sharply in another direction. Only

456 GERTRUDE MAREAN WHITE

once or twice did they actually snap at the cotton packet. Then
perceiving the struggles of the rest of the fishes with the other
packet, they swam over and joined them. Repetition of this
experiment gave similar results. At Woods Hole, Massachu-
setts, the same test was performed upon Fundulus heteroclitus
for comparison, since this species had been found by Parker to
discriminate between the packets. The sticklebacks reacted
fully as well to the stimulus of concealed food as did Fundulus.

In the use of the sense of sight the mudminnow compares
more favorably with the stickleback, though the latter reacts
more quickly. Both species pursue moving objects without
cedor, such as bits of paper, or objects above the surface of the
water; both exhibit skioptic reactions, and are stimulated by
an increase in the amount of illumination.

COLOR DISCRIMINATION

Notwithstanding numerous investigations, the question as
to whether fishes possess color vision is still somewhat unsettled.
Fishes live in a medium where, except at the surface, the light
is rather dim. The permeability of water to light depends
largely upon its depth and clearness. There is an unequal ab-
sorption of different parts of the spectrum as rays of light pene-
trate; the red end is absorbed more rapidly than the blue, so
that at a depth of several meters in clear water fishes see as if
through a blue-green glass. This fact might lead one to the
view that for fishes living at any great depth, the ability to dis-
ceriminate colors would be valueless. There is the possibility,
however, that the eye of such fishes is better adapted to perceive
minute differences in shade and color of objects in a dim lght
than is our own—a consideration which should not be rejected
because fishes are rather unspecialized in structure compared
with other vertebrates. Even though fishes, which live at a
depth where red, orange, and yellow rays of light do not penetrate,
may have no use for a color sense, this cannot be true of fishes
living and feeding at the surface, where rays of light are only
slightly refracted and absorbed by the water.

In dealing with this problem there are certain questions to
be considered:

ASSOCIATION AND COLOR DISCRIMINATION 457

1. Do the fishes studied discriminate colors?

2. If so, is the discrimination due to wave-length or to in-
tensity? In other words, do fishes see colors as such, or as
shades of gray?

3. If the eyes of fishes are affected by differences in wave-
length, is their color vision like that of a normal human being?

4, Can fishes form associations with colors?

5. Would such associations be of value to them in their struggle
for existence?

6. How do the results agree with present theories of color
vision?

The following series of experiments were aimed to answer
these questions and to supplement the evidence furnished by
other workers. They were planned with a view to training
fishes to secure food in particular ways, and extended through
three years.

The general problem presented to the fishes was that of learning
to associate food with a certain color and at the same time asso-
ciate unpalatable substances such as paper with another color.
The mudminnow and the stickleback are both shallow-water
fishes which discover their food largely by sense of sight. Va-
rious methods of presenting food were tried. Considerable
time was consumed at the beginning by using colored electrodes.
These were thrust into the water at the sides of the dish and
food was offered on forceps in the water. The fishes were given
a mild electric shock when they snapped at bait on the wrong
color. This method had to be abandoned because one shock
often caused a fish to refuse food for several days.

Instead of this, the fishes were fed on only one color, while
on the color with which unpalatability was to be associated,
they were offered balls of paper closely matching the food in
appearance and color. In order that there might be no chance
to smell the’ food, the bait was not dropped into the water, but
the fishes were taught to leap out of water regularly and take
it from forceps. Minced snail meat was the most attractive
bait in the long run, although this was varied at times with
chopped earthworms, slugs, and liver. Repeated trials deter-

THE JOURNAL OF EXPERIMENTAL ZOOLOGY, VOL. 27, No. 4

458 GERTRUDE MAREAN WHITE

mined that the fishes were not able to distinguish between the
imitation baits and the food when both were offered out of water
under the same conditions. The use of this method usually
caused some delay on account of the necessary training of a week
or two at the beginning of a set of experiments. The proportion
of mudminnows successfully trained was only about two out of
every five, but nearly all the sticklebacks could be taught to
take food as desired.

EXPERIMENTS WITH MUDMINNOWS
Experiments with colored papers

The first set of experiments with mudminnows was carried
on during the winter of 1914 to 1915. Five were placed in sep-
arate bowls to be trained, but only two of these could be induced
to eat with regularity. The experiments were performed by
day before a large window. Discs of colored? papers were cut
7.3 cm. in diameter and stiffened with cardboard. An aperture
was made in the center of each large enough to allow the dises
to be slipped down over the ends of the forceps from which the
fishes were fed. The fishes were at first somewhat disturbed by
the paper dises and required a little time to become accustomed
to them. In a week this timidity vanished; the appearance of
a colored dise became a signal for the fishes to dart to the surface
and spring out of the water after food. When this association
with one color seemed to be thoroughly established, a dise of
another color was substituted with paper closely resembling the
food in color and appearance in the forceps. The same pair of
forceps was never used for both food and paper so that there
should be no possibility that the taste of food might be trans-
ferred to the paper. The colored dises slipped down over the
forceps were offered alternately. This furnished a severer test
of the power of association than did the experiments of Wash-
burn and Bently (’06) in which the forceps of two different
eolors with only one holding food were thrust into the water
simultaneously.

’ 2 The colors correspond with the following numbers in Klingsiek and Valette’s
Code de Coleur: red: rouge no. 2, blue: blue no. 431, violet: blue-violet, no. 481.

459

ASSOCIATION AND COLOR DISCRIMINATION

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The first test was successfully accomplished by only one fish,
no. 27. The colored dises offered were blue as a signal that the
forceps held food and red to represent paper. The forceps with
the colored discs attached were presented singly. The duration
of the experiment was seventeen days (Feburary 11 to February
27). The results are shown in figure 1, B. On the first day
three errors were made, i.e., the fish snapped at the paper under
the red disc three times. On the second and third days the fish
refused to eat on red, but took food on the appearance of the
blue dise. Two mistakes were made on the fourth day, after
which the fish no longer attempted to obtain food on red. In
two instances a day intervened when the fish was not fed, in
one instance two consecutive days, after which intervals the fish
made a perfect record.

The curves for all the experiments to be described are plotted
in the same way. The days of the experiments are shown in
the abscissa and the number of errors recorded each day on the
ordinate. When no mistakes were made the curve is at 0, but
the number of correct tests is not designated in the curves. The
results of all the experiments with the mudminnows and stick-
lebacks are summarized in tables 1 and 3, respectively, showing
the duration of each experiment, the total number of trials,
the number of errors and of correct records, and the percentage
of errors and of successes in each case.

After mudminnow no. 27 had learned to distinguish between
the red and the blue discs, violet was substituted for the blue
disc. (Fig. 1, D, and table 1.) The entire experiment con-

TABLE 1

Results of experiments in which mudminnows were taught to take food offered with
certain colored papers or with light passed through monochromatic gelatin filters,
and to refuse paper resembling food in appearance when offered with certain other
colored papers or other monochromatic lights. ‘Lights from flashlight’ means that
the source of illumination was a hand electric flashlight and that the light passed
through a monochromatic gelatin filter before reaching the fish; ‘lights dim’ means
that the dry cell in the flashlight ran down so that the light had a low intensity.
‘Lights’ means that an incandescent electric lamp was used and that the light was
passed through monochromatic gelatin filters. ‘Intensity varied’ means that differ-

ent known intensities of light were passed through the monochromatic gelatin
filters. ‘Colors reversed’ means that the color which in the first part of an experi-
ment had indicated the presence of food was changed to mean paper, and that food
was now given on the color with which paper had formerly been associated. The
letiers indicate the colors; blue is represented by B, green by G, red by R, violet by
Vand yellow by Y. ‘Gray plates’ means that ‘fogged’ photographic plates were used
and that the source of the light shining through them was an incandescent lamp.
“Square and dots’ means that, instead of monochromatic gelatin filters, glass plates
with these designs on them were used with the light from an incandescent lamp

passed through them. The appearance of the square was accompanied by food and
the dots by paper.

ae p Se 2
aCe eer hae ite. Vo
FISH TYPE OF EXPERIMENT g z a 4 See z a ee a 3
| a8 | $2 |28e| 22 |,28| ee
FT| ee gel ae |ce ie | eam
s SS BranciG papers: 1330. sae ss 79 | 108 | 94 12 | 88.89) 11.11
R and G lights from flash-
No. 25 Whee ones ees t2 |) 33 (cot -| 12" |-eraleaars
LUTE UNS OCG Vita i ell eal aes, aa 10 | 27 14 ile 51.06} 48.14
Batteries renewed ............ 14:0) 15 14) 6 > L? (93k 34 Pe Gs66
185 FomaKe (od By of) OVS een Boos ee 1 st -20 | Ge | 00) SHOU
NW Graaye! 4BN joys y overs Oe aes Alain Gor {45 ft -59 | 15% | eAoepiez0e28
B and R lights from flash- | |
fetuses at to eek ste tos! 14 43 20 23 | 46.51] 53.49
No. 27 Piteerns penttna eres 5. aha 8 10 44 18 26 | 41.36] 58.64
Batteries renewed............ 10. > 10v [10 0 {100.00} 0.00
Ryan wens. 28 nS 48 | 69 | 45 24 | 65.22) 34.78
Imtensity; varied’.:...:..:.... 22>) 48 | 41 7 | 85.42) 14.58
: oquare’ and dots’.......0 224.2: 38 52, "| Srp ad. 9.8 | 90.2
G and R lights from flash- |
| [i ions ie AE ce 1D) |) (24>) SiO SeirSiearmto. 5D
: Welightadimists secre. Jax: + 10 | 37 | 22 | 15 | 40.54) 59.46
| 5) 40 Batteries renewed............ 10 | 14 | 14 | 0 {100.00} 0.00
SA eee f| 10 31 15 | 16 | 48.38) 51.62
tie Meme ieee FSS. if, 21s M12 12 | O {100.00} 0.00
(jock elo 33 50 32 18 | 64.00} 36.00
Intensity varied -............ 22; 47 39 8 | 82.98] 17.02
, | |
f jee mda Tight oe tates. 24 | 24 | 20 | 4 ‘| 88.34] 16.66
Intensity varied. . She, oR Bed ee 22 | 22 | 0 {100.00} 0.00
No. 55 Guangiie ligite ee. ek. 33 31 27 4 7.10} 12
Intensity varied ............. 36 27 24 3 | 88.89 1
Gray plates .......... Saeed. 30 | 28 5 | 23 | 17.85] 82.15
No. 60 {| Gand Ylights........: ae 41 | 39 | 30 9 | 76.93] 23.07
) Gerayaplatce. re tee 9 Th Br. |’ “38 12 eae. | 629631 '93.37

461

462 GERTRUDE MAREAN WHITE

tinued seventy-five days (March 3 to May 17). During the
last thirty-five days (April 18 to May 17) not a single mistake
occurred. This period included thirteen consecutive days when
the fish would not eat, but the associational impression was re-
tained during the interval. The blue-violet combination seemed
a more difficult one for the fish to master than the red-blue,
since the time required for enough consecutive perfect records
to be made to show that the association was established was
much longer than in the previous experiment. The previously
formed association did not seem to be of any assistance as a
preparation for learning the new combination.

Mudminnow no. 25 was also tested with the red and the blue
dises presented alternately under the same conditions used with
mudminnow no. 27, but no color association was formed. The
dises were then offered simultaneously to discover whether the
failure was due to the complexity of the test or to lack of color
vision. When the two discs appeared at the same time, the
fish learned to seek the blue first. This showed that while
the fish was able to discriminate between the red and the blue
papers, it did not inhibit the impulse to take food when one disc
was shown separately. The duration of the test was seventy-
nine days (March 3 to May 22.) (Fig. 1, A, and table 1.)

These experiments are subject to the criticisn made upon the
work of other investigators, as the colors are not spectrally pure.
In any case, however, they clearly demonstrate that fishes are
capable of forming associations and receiving suggestions from —
the conditions connected with obtaining their food, and that
these associations may persist for a considerable time.

Experiments with monochromatic light filters attached to the end of
a flashlight

In order to test accurately what wave-lengths of light could
be discriminated by the fishes, monochromatic filters were used
instead of the colored papers. A set of Wratten monochromatic
gelatin filters was obtained from Eastman Kodak Company.
The set consists of seven filters, mounted between glass slides,
which allow light of the following waves-lengths to pass through:

ASSOCIATION AND COLOR DISCRIMINATION 463

Red no. 70: 640u to 730u
Red no. 71: 600u to 730u
Orange no. 72: 580u to 630un 660u to 710.
Yellow no. 73: 550u to 680u 570u to 720u
Green no. 74: 510 to 570u
Green no. 75: 460u to 540u
Blue no. 76: 420u to 480u
A flashlight was fitted out with a tin hood like the accom-
panying diagram (fig. 2). The hood, H, was slipped over the

Fig. 2 Flashlight with hood, H, attached at the end to hold the gelatin filters,
F. The light shines through the filters at the opening, OQ. .

end of the flashlight and the monochromatic gelatin filter inserted
in a groove in the end of the hood where it could be locked in
position, /. The light was directed from above on the vessel
containing the fishes and food offered from forceps held beneath
the light. The experiments were performed at twilight during
the summer months. Of six mudminnows which were fed at
the beginning, only three ate regularly enough to give results
of value. As before, the fishes were made to spring out of the
water after their food, and paper which matched the food was
offered on the color which was to be refused.

464 GERTRUDE MAREAN WHITE

Mudminnow no. 27, with which the two previous sets of ex-
periments with the colored dises had been successfully com-
pleted, learned to discriminate between red and blue lights
shining through monochromatic filters (red, no. 71; blue, no.
76) when they were presented alternately; blue representing the
food stimulus and red, paper. The duration of the experiment
was thirty-four days (July 9 to August 11). No errors were
made during the last ten days. Red no. 70 was substituted for
red no. 71 without affecting the outcome (fig. 1, C).

Fish no. 25 (which during the winter had not given successful
results when the red and blue discs were presented alternately,
but had later learned to discriminate between them when they ap-
peared simultaneously) made a perfect record for ten days with
the lights red no. 71 and green no. 74 in a series of tests which
lasted thirty-six days (July 11 to‘August 15). The lights were
flashed upon the vessels alternately, red representing food and
green, paper. During this experiment red no. 70 and green no.
75 were several times substituted for the filters habitually used,
and the fish reacted in the same manner as it was accustomed
to react to red no. 71 and green no. 74. (Fig. 3, A, and table 1.)

In both of these experiments with the gelatin filters a rather
interesting occurrence took place. The flashlight batteries be-
gan to grow dim about the thirteenth day and were not renewed
until the twenty-third day. During the period when the lights
were dim, there was a great increase in the number of errors,
which ceased as soon as the batteries were renewed. <A sudden
rise in curve CG, figure 1 (a—a), and curve A, figure 3 (a—a) during
the time when the lights were dim may be noted.

The greatest aptitude displayed by any fish was that of mud-
minnow no. 40, a female ready to spawn. The colored lights
used were green no. 74 for food and red no. 71 to be rejected.
On the first day when both colors were offered, the fish made
three failures, attempting three times to take food in red light.
For the eleven daysfollowing this she made correct discriminations.
Her behavior at the appearance of the two lights was different.
To green she responded by rising immediately to the surface;
when red was flashed upon her, she swam about rather excitedly,

465

ASSOCIATION AND COLOR DISCRIMINATION

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466 GERTRUDE MAREAN WHITE

but seldom came to the top. She also was confused by the
dimming down of the lights, as is shown by the sudden rise in
curve B, figure 3 (a—a), but with the renewing of the batteries
the errors ceased. The experiment was continued until ten
consecutive errorless days were recorded.

Using the same mudminnow, the colors were then reversed.
(Fig. 3, B,c.) Although the forceps under the green light now
contained paper, the mudminnow persisted in leaping out at
them, but refused to do so when red light with food was sub-
stituted. For five days this fish could not be induced to take
food in red light, so that it was necessary to drop bits of food
into the water without colored illumination in order to keep her
in proper condition for experiment. On the sixth day she ate
once in red light after snapping at paper in green light, but
would not take food again in light of either color. On the
seventh and eighth days she would not eat except when food
was dropped into the water without colored lights. She sprang:
out after food in light of either color on the ninth day. Then
followed eleven cays of perfect record when she consistently
took food under red light, but refused to do so under green
light, (Fig. 3, B, and table 1.)

Experiments with constant and varied intensity of illumination

Since a flashlight does not yield a uniform illumination for
any considerable length of time, an apparatus was contrived in
which an electric lamp could be used for passing light through
the gelatin filters (Fig. 4). An oblong tin box was constructed,
6em.x6em.x12.5em. The electric light bulb was fitted into
one end of the box. At the other was an opening 4 cm. in
diameter before which was a groove to hold the gelatin filters in
position. Two plates of glass (P, P’,) were inserted between the
light and the gelatin plates to prevent the plates being over-
heated. A sliding cover was fitted tightly over the top of
the box.

The electric lamp was connected with a rheostat (fig. 5, R)
by which the intensity of the light could be regulated and varied.

ASSOCIATION AND COLOR DISCRIMINATION 467

Thus, although no method was at hand for determining the
intensity of a colored light, lights of varying intensity could be
passed through the monochromatic filters and the effect noted.
The following intensities of light were used: 4.9 candlemeters,
2.5 candlemeters, 1.4 candlemeters, 0.68 candlemeters. These
values were obtained by measuring the light when it was in the
box shining through the two glass plates inserted to protect the
gelatin filters. When the color filters were in position, the in-

' [fe

P
] |
| i
| |

Fig. 4 Tin box in which light from an electric lamp, L, was passed through the
gelatin filters, F. P, P! are glass plates inserted to prevent overheating the gela-
tin filters, F. During the experiments the box was covered with a tight lid
which is not shown in the diagram.

tensity was greatly decreased. During these experiments the
translucent window shades were tightly drawn to increase the
effect of the colored lights, and the fish tanks were surrounded
by a black opaque screen (S) so that the fishes might not be in-
fluenced by the movements of the investigator.

Experiments were first carried on with mudminnow no. 27 and
mudminnow no. 40. The light was first used full strength (4.9
c.m.) with red no. 71 for paper and green no. 74 for food. When
these fishes has shown by a perfect record that they had formed

468 GERTRUDE MAREAN WHITE

the association, the intensity of the light was varied, but no in-
crease was noted in the number of mistakes, nor did the dis-
crepancies seem to be correlated with the relative intensities of
the light (fig. 3, C, and table 1).

Mudminnow no. 55 was tested in two sets of experiments.
The first set was carried on in the fall of 1916 between October

'
‘
'
,
'
'
'
'
:
'
'
N
,

Fig. 5 Representing the conditions of experiments with gelatin filters il-
luminated by an electric lamp. The electric lamp in box, B, was connected
with the rheostat, R, by which the intensity of the light could be varied. During
the experiments the jar containing the fish was surrounded by an opaque screen,
S, and the colored light was flashed upon the fish at the same time that food
was offered from forceps.

25 and November 29 (thirty-six days), with green light indicating
the presence of food and red indicating paper. No errors were
recorded after November 1, the eighth day of the experiment, as
the fish consistently refrained from snapping at paper in red
light, but took food in green light. Beginning with November
15th, the lights were varied in intensity. The results of this ex-

ASSOCIATION AND COLOR DISCRIMINATION 469

periment and the one following are tabulated so as to show ex-
actly what occurred at each feeding and with each intensity of
light (fig. 3, D, and tables 1 and 2).

Beginning with January 12th, this experiment was repeated
with the same mudminnow and continued for sixty-nine days.
An especially interesting fact in connection with this experiment
was that no failures were noted during the first three days,
although the time which had elapsed since the completion of the
first experiment was forty-two days (table 2). This occurrence
may have been an accident, but if so, it was the only time a fish
made no failures at the beginning of an experiment. It seems
more logical to suppose that the fish had preserved the acquired
association of green light with food and red with paper through-
out this interval. The experiment seems to show a clear case of
color discrimination. The number of errors was in all only
seven. Three of these occurred during the time when the lights
were being varied, but as with fish no. 27 and fish no. 40, there
seemed to be no correlation between the errors and the relative ~
intensities of the lights. On one occasion the fish snapped at
the bait in the red light when the light which shone through the
red filter was 1.4 candlemeters without the color screen and that
which shone through the green filter 4.9 candlemeters (February
25). At another time, the fish was confused when the light
passing through the red filter was 4.9 candlemeters and that
illuminating the green 2.5 candlemeters (March 4). On an-
other day the red was 2.5 candlemeters and the green 4.9 candle-
“meters (March 8). On two occasions when errors were made,
the light passing through the green filter was the more intense,
but in the other instance, the red was stronger. (Fig. 3, E, and
tables 1 and 2.)

Experiments with green and yellow filters

Mudminnow no. 60 was given the problem of distinguishing
green no. 74 from yellow no. 73. The yellow, which, it may be
noted, had two absorption bands, appeared to the human eye
considerably brighter than the green. On this account a weaker

470 GERTRUDE MAREAN WHITE

TABLE 2

Detailed results of two experiments with mudminnow No. 55 described on p. 468-9.
The table shows the number of times food was taken or refused with each intensity
of light passed through a green monochromatic gelatin filter on each day of the ex-
periment; also the number of times paper was taken or refused with each intensity
of light passed through a red monochromatic gelatin filter on each day of the ex-
periment. All light intensities are given in candle meters as measured with the
monochromatic gelatin filters removed.

GREEN RED
DATE : Number of : Number of
cotieht | times food | yueensity | times Paper
cm. cm.
Welober 20a se ee eee 4.9 3 4.9 1
0
October:26: -ece hon eee 4.9 2 4.9 0
October 2724-0 ee 4.9 2 4.9 1
October 28-..4-5- 55545 - = ae 4.9 2 4.9 0
October.29: 2.20. eee 4.9 3 4.9 1
0
October 30) :4.c7.6 hee 4.9 2 4.9 0
October/3l- pas eee ae 4.9 2 4.9 0
INovember “10h. Ave se eee 4.9 2 4.9 il
0 0
INO Vem Der s2s4: senosct eke ase 4.9 2 4.9 0
0
Wovember-2o¢ 20 802. oe eee 4.9 2 4.9 0
November s4 42 tae 4.9 2 4.9 0
Novem ber 5 cgi se-2 bea 4.9 2 4.9 0
November s653.25554.0- sees 4.9 2, 4.9 0
INOVeMmber Mitac ashe sec tee 4.9 2 4.9 0
November 925../22- eS 4.9 0 4.9 0
Navemben10; ees: Piers: 4.9 1 4.9 0
November 44... .n cece s oars 4.9 , 4.9 0
November 123.2) 52ec soa ee 4.9 0 4.9 0
Ninvember 1a... s.. oer 4.9 0 4.9 0
Nowember 14" 5... oc neer ee 4.9 0 4.9 0
November th... : osc. see 4.9 1 4.9 0
November iG............ see 4.9 2 4.9 0
November 17... <2... .. 2.6 4.9 2 4.9 0
Nevemberds. 22:2... 2-2 4.9 3 4.9 0
2.5 0
Nevember 19...-.... 2.05.2 { oe : aM :
f 4.9 1 4.9 0
November 20.............. 4 25 1 1.4 0
{ 0.68 1

ASSOCIATION AND COLOR DISCRIMINATION 471

TABLE 2—Continued

| GREEN RED

DATE ears | Number of : Number of
intensity | fmeefood | intensity | mes nape
cm. cm.
4.9 1 4.9 0
INovemben 2 jesse cence 229) 1 1.4 0
0.68 1
( 4.9 1 4.9 0
November ()22).c2s0.8 5. -<<: an ; as o
| 2.5 1
( 4.9 1 2.5 0
INOVEMDER 23... .sss5s..s 5s 0.68 1 1.4 0
| 1.4 1
November 24.---. aces 4- { ce ; oe :
INOW] OS ey AA ec nee 4.9 0 4.9 0
ING VeMberH2O.,.s seater So <0 - 4.9 0 4.9 0
[ 4.9 1 4.9 0
INOWEINDeTZ’ | treks users <e- poe ; ae .
2.5 1
( 4.9 1 4.9 0
INovember 284. 3. Made .0554- 0.68 1 1.4 0
2.9 il
2.9 1 4.9 0
4.9 1 1.4 0
November: 29:22... 66.6.0: 0.68 i 225 0
4.9 1
20 1
November 30-January 11....| Experiment|s discontinujed
JG M2 Saeed ape Sir 4.9 Pe 4.9 0
TDiITeii? IIB, Boke 6 eee ee 4.9 3 4.9 0
PROUAIY 1464. ohhh... 3. 4.9 2 4.9 0
Vrain clisiae sani HS anion Elem 4.9 2 4.9 2
0
0
J ANUATY LOSE n Emi </ erae 4.9 2 4.9 0
JEAN a gel Shh oe, cee Bie 4.9 2 4.9 1
0 0
arary: 1S. Bae |e: 4.9 2 4.9 0
TESTOR ag URE ne a oe 4.9 2 4.9 0
TRMUATY OO: f.caehtenter. ekidae cs « +4.9 2 4.9 0
ATU AE ee Leen). Sastsias 4.9 2 4.9 0
JAMMU AE eee enon cet sis ch dans 4.9 0 4.9 0

472 GERTRUDE MAREAN WHITE

TABLE 2—Continued

GREEN RED
DATE Light Number of icht Number of
intensity | times food ister beet
4 cm. cm.
JONUATY, 255-5 eee 4.9 2 4.9 0
January 2 leeks ee eee 4.9 2 4.9 0
JaAnuanyacn ses. eee eee 4.9 2 4.9 0
Hanudanyi2G! as. ose ety 4.9 2 4.9 0
JANUALY. 0 cee sy 4.9 1 4.9 0
0
January 28........ Soci GSE 4.9 2 4.9 0
January 29-3. .5-5: 2 se 4.9 2 4.9 0
Janvany oO: cere ce ee 4.9 0 4.9 0
January 31....... miu Ee 4.9 2 4.9 0
Hebrasicy 12 7 ee oo ee 4.9 2 4.9 0
Pebruary 22... sh5.. --2=- 4.9 1 4.9 0
0
Repraary. S244 eee bch 4.9 | 2 4.9 0
Hebranry © 4.25.2 2 ens: bee 4.9 2 4.9 0
Hebruary 05..2.. tec: 4.9 0 4.9 0
Hebraary G2 25.9 ose ree 4.9 1 4.9 0
0
Hepryary 3735... seo ee 4.9 0 4.9 0
Benny Slo eee eee 4.9 2 4.9 1
Hebronry ‘O80 oF ok. fen 4.9 2 4.9 0
4.9 1 4.9 0
Rebruary 10.¢.3.2<7..; - Sek 2.9 1
[ 1.4 1
Webriary 1 oo. ole 2ceetes 4.9 a 4.9 0
1
Meprusny 122).'..5. 2: save Fish was frjozen into icje and thawejd out
Hebruanysts! ec ee oe bee 4.9 0 4.9 0
ebrusarg 145 02M hos ce 4.9 2 225 0
LOE A a oe 4.9 0 4.9 0
peteuraary. 162.2. 2 2... 2524722: 4.9 0 4.9 0
i if 4.9 1 2.5 0
DE Ca re iY so \ ae 1
f 25 1 4.9 0
Dh ihe \ 14 l
f 1.4 1 4.9 0
MertarytO). 222... 2.5 .ce \ 25 1
Peters ess... ok 2. 4.9 0 4.9 0
4.9 el 4.9 0
‘ f
JETS Le \ 25 1 on 0

ASSOCIATION AND COLOR DISCRIMINATION 473:

TABLE 2—Continued

GREEN RED
DATE c Number of . Number of
Ligh é Ligh ,
intensity | timesfoodwas| intensity | times paper
cm. cm.
: 1 ;

nepruary 22.3 in Hie id. { § : 1 28 0
BebrudEy, 2.0) ee essere: 4.9 0 4.9 0
Rebruany 24. yea es s.ck 4.9 0 4.9 0
4.9 1 1.4 1

Hebnuanyacose. syeseeees os { ee 1
4.9 1 4.9 0

HebruanvacOsmereet...ce'5 > c-"- { aye 1
4.9 1 7435, 0

BIG DT AGVE 2 0... croiere cons 26 + { lee 1
4.9 1 QE 0

Meuruary 28.0. ......2- 06s» { 1.4 1
EDC) Cont i ee arate, Rape manera 1.4 1 4.9 0
Wiarcive-2 ese ie wt Pi Ne FUSS, als 1 4.9 0:
Nianchwasass) see goo f 7 . os 4.5 0 4.9 0
IMIS HOA 2 Se ee A ee ee Dy) 3 4.9 il
4.9 0
4.9 1 4.9 0

ome tue Disc, 8 oe Rc. oes oho { 25 1
IMinitoloe ace Lae Be ete ere Pet) 2; 4.9 0
lWleaielin 7A SSeS Sener 4.9 0 4.9 0
ieanClME SE ert. ae er cae ce ve 4.9 2 2.5 1
Vier O SS eter. ote oe Sera tease 4.9 2 D5) 0
WiarchelO ste 25%. is4 satesear 4.9 2 4.9 0
: 0

Wiercheiiltes ran, SMI Me, 2): { ; i ; fa

i 4.9 1 4.9 0

Ieee a) 1 ee Sere as \ 25 1
Wianchelstiy mera te ack At. 4.9 1 4.9 0
4.9 1 Deb 0

Micimralay TAtei Peto eye. { en 1
285 1 4.9 0

March: Lorfe. : Serouy.. terse 4.9 1

1.4 1
25 1 4.9 0

Miare ht 16 6 tay ee ey, 4 yen { 14 1
ING Helot Yee re Se ie ee 2.5 1 4.9 0
IVs chit 2 | £ ee te ey 4.9 0 4.9 0
WWiemCie Oe st 2 ates «eine 4.9 0 4.9 0
War chin 20 e024) sae Bato. owen 4.9 2 2a 0
Mirch Ota ore eee Were est, 4.9 2 QS 0

THE JOURNAL OF EXPERIMENTAL ZOOLOGY, VOL. 27, No. 4

474 GERTRUDE MAREAN WHITE

light (2.5 c.m.) was frequently used with the yellow filter (4.9
c.m. being used for the green). The experiment lasted forty-
one days (February 25 to April 6). On each of nine days one
mistake was made, but errors were never recorded on two con-
secutive days. The fish never made a perfect record for solong
a period as did the fishes in the experiments previously described,
but in two instances a perfect record was shown for five succes-
sive days, and in two instances for four successive days. It
seems safe to conclude that mudminnows are able to distinguish
green from yellow, but that these colors are not so readily dis-
criminated as are green and red, and blue and red (fig. 1, E).

Experiments with gray filters

In order to check up Hess’ theory that fishes perceive colors
as shades of gray, as a totally color-blind human being perceives
them, further experiments were performed. Two photographic
plates were exposed to the light one second and four seconds,
respectively, producing on one a light and on the other a dark
gray surface. These plates were cut to the size of the gelatin
filters and the gelatin surface protected by glass so that they
could be inserted without scratching in the box shown in figures
4 and 5, and the experiment performed under the same condi-
tions as the color tests. If the fishes were reacting to shades of
gray, they ought to be able to distinguish between the two pho-
tographic plates just as they had done with the colored filters.
Mudminnow no. 60, which had distinguished green and yellow,
did not show the slightest sign that it could perceive any differ-
ence between the two photographic plates during fifty-one dasy
(April 21 to June 10). It took food a little irregularly, as some-
times happens in the spring, but the results were consistent
throughout, since the fish attempted in the same manner to take
whatever was offered with both plates (fig. 6, B, and table 1).

Mudminnow no. 55, which had learned the red-green combi-
nation, was also used with the two grays. The fish also gave no
evidence of a perception of difference between the light and dark
plates (fig. 6, A, and table 1).

ASSOCIATION AND COLOR DISCRIMINATION A475

Summary of experiments in regard to color vision of mudminnows

1. Mudminnows are able to distinguish between the following
wave lengths of light: red, 600u to 730u and green 510u to 570u;
red 600u to 730u and blue 420u to 480u; yellow 580u to 630u,
660 to 710u, and green 510u to 570u, as is shown by the forma-
tion of associations of paper and food with these colored lights.

2. Red and blue, and red and violet papers are distinguished
in the same way.

3. Varying the relative intensities of the colored lights from
1.4 c.m. to 4.9 c.m. does not affect the result, which indicates
that the reaction is to color rather than to intensity.

4. This conclusion is further supported by the fact that fishes
(no. 55 and no. 60) which had previously shown that they per-
ceived the difference between monochromatic gelatin filters
(mudminnow no. 55 has shown a nearly perfect record with red
and green, fig. 3, D) could not distinguish between photographic
plates which had been ‘fogged’ to different shades of gray.

EXPERIMENTS WITH STICKLEBACKS

The tests applied to the sticklebacks were similar to those
made upon the mudminnow. Experiments were performed using
the electrical apparatus attached to the rheostat previously de-
scribed (fig. 5). Two sets of monochromatic filters were pre-
sented to the fishes; these were yellow no. 73 with blue no. 76,
and red no. 71 with green no. 74. After repeated tests with the
red and green filters, the light intensity was varied, as had been
done with the mudminnows. Observations were also made to
test the discrimination of shades of gray.

EXPLANATION OF FIGURES ON FOLDER

Fig. 6 Curves representing the results of experiments on the discrimina-
tion of light shining through photographic plates ‘fogged’ to different shades
of gray. Construction of curves same as in figure 1.

A. Mudminnow no. 55. Dark gray plate indicating presence of food and
lighter gray plate indicating presence of paper. Duration of the experiment,
30 days, May 12 to June 10.

B. Mudminnow no. 60. Dark gray plate indicated presence of food and
light gray plate indicated presence of paper. Duration of the experiment, 51
days, April 21 to June 10. There was no day without one or more errors.

476 GERTRUDE MAREAN WHITE

Fig. 7 Curves representing the results of experiments on the discrimination
of colors and light intensities by sticklebacks. Construction of curves same as
in preceding figures.

A. Stickleback no. 65. Blue and yellow lights, blue indicated presence of
food and yellow indicated paper. Duration of experiment, 18 days, April 28 to
May 15.

B. Stickleback no. 66. Blue and yellow lights, blue indicated presence of
food and yellow indicated paper. Duration of the experiment, 16 days, April
26 to May 13.

GC. Stickleback no. 65. Green and red lights; green indicated presence of
food and red indicated paper. Duration of the experiment, 21 days, May 16
to June 5.

D. Stickleback no. 66. Green and red lights, green indicated presence of
food and red indicated paper. Duration of the experiment, 17 days, May 16 to ~
June 1.

E. Stickleback no. 65. Light shining through photographic plates ‘fogged’
different shades of gray, the darker plate (exposed to light 4 seconds) indicated
presence of food and the lighter plate (exposed to light 1 second) indicated paper.
Duration of the experiment, 32 days, March 27 to April 27.

F. Stickleback no. 66. Light shining through photographic plates ‘fogged’
different shades of gray, the darker plate (exposed to light 4 seconds) indicated
presence of food and the lighter plate (exposed to light 1 second) indicated paper.
Duration of the experiment, 32 days, March 27 to April 27.

Fig. 8 Curves representing the results of experiments on the discrimination
of colored lights by sti¢éklebacks. Construction of curves and lettering same as
in figure 1.

A. Stickleback no. 46. Green and red lights. During the first 34 days (b-c)
green indicated presence of food and red indicated paper; during the remaining
56 days, red indicated presence of food and green indicated paper. The duration
of the entire experiment was 90 days, December 5 to April 3.

B. Stickleback no. 50. Green and red lights. During the first 32 days (b-c)
green indicated presence of food and red indicated paper; during the remaining
92 days (c-d) red indicated food and green indicated paper. During the last
20 days the lights were varied in intensity (v-v). Duration of the entire ex-
periment, 124 days, January 6 to May 8.

Fig. 9 Curve representing the results of experiment on the discrimination
of patterns by mudminnow no. 27. Construction of curves same as in preceding
figures. A square of black paper 2.7 cm. indicated presence of food and four
black dots 1 em. in diameter indicated paper. Duration of the experiment, 38
days, February 27 to April 5.

Fig. 10 Curves representing the results of experiments on the discrimina-
tion of calves’ liver and gray paper offered alternately to stickleback no. 57.
As in figure 1, only the errors of each day’s record are shown in the curves.

A. Duration of the experiment, 35 days, October 24 to November 28.

B. Repetition of experiment represented by curve A. This was begun 44
days after the first experiment had been discontinued. Duration of the experi-
ment, 30 days, January 12 to February 10.

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ASSOCIATION AND COLOR DISCRIMINATION 481

Experiments with monochromatic blue and yellow filters

Tests with blue and yellow filters were applied to two stickle-
backs, no. 65 and no. 66. The lights were flashed alternately
upon the fishes, the blue being associated with food and the
yellow with paper. The yellow light seemed to the human eye
considerably brighter than the blue, and the blue plate was much
more opaque than the green plate which was used in combination
with the yellow in the test made upon mudminnow no. 60. If
intensity of light was the determining factor in these discrimi-
nations by the fishes, the yellow-blue combination offered the
greatest contrast of any experiment tried and might have been
expected to secure the most positive results. But, strange to
say, the records of this experiment fail to show any clear evi-
dence of discrimination. Only 22.22 per cent of the total number
of trials proved to be correct for stickleback no. 65, and 16.12
per cent in the case of stickleback no. 66. It was demonstrated
in a later experiment that the failure was not due to the complex-
ity of the test since these fishes learned to discriminate red and
green lights (fig. 7, A, B; table 3).

Experiments with monochromatic red and green filters

Red and green lights were presented alternately to four
sticklebacks including the two which had given negative results
in the experiment with blue and yellow lights just described.

The experiments on no. 65 and no. 66 were among the last
tests made, but an account will be given of them here so that
these results may be compared with the yellow-blue experiment.
The fishes very soon demonstrated that they detected qualitative
differences in the green (no. 74) and red (no. 71) lights which
were flashed upon them, reacting differently to each light.
After several trials the fishes exhibited hesitation in approach- ~
ing the forceps in red light or refused to do so altogether, while
in every ‘case they snapped at the forceps in green illumination.
The test lasted only seventeen days for stickleback no. 66 and
twenty days with stickleback no. 65, since it was the purpose
of this experiment to observe whether they could discriminate

482 GERTRUDE MAREAN WHITE

TABLE 3

Results of experiments in which sticklebacks were taught to take food offered with
light passed through monochromatic gelatin filters, and to refuse paper resembling
food in appearance, when offered with other monochromatic lights. ‘Lights,’
‘colors reversed,’ ‘intensity varied,’ ‘gray plates,’ have the same meaning as in
table 1 and the colors are as before represented by B for blue, G for green, R for
red, and Y for yellow. ‘Food and paper’ means that calves’ liver and gray paper
quite different in appearance were offered alternately without colored illumination

Wee 4 NUM- PER
PION oF NUM- |BER OF] NUM- |CENT OF| PER

FISH TYPE OF EXPERIMENT | EXPER- BER OF| TIMES |BER OF} TIMES |CENT OF
| IMENT | TRIALS COR- |ERRORS| COR- |ERRORS

| RECT RECT

days | -

(1 Gram Nehits. geen eed 34 66 54 81.82} 18.18
No. 46 {| Colors reversed.............. | 28 | 108 8 8.00) 92.00
| 28 34 24 70.59} 29.41
( Guape RR ehtep. +A, 2 SEE | 32 58 45 77.59| 22.41
| (| 20 83 15 18.07) 81.938
No. 50 {| Colors reversed............ 1} 90 | 50 34 68.00) 32.00
| | 20 9) 52, 41 78.85) 21.15
|| Intensity varied.............. has 91 84 92.32) 7.68
[| Guavanlatess sey 8 5 tee cae 32 | 39 1 2.56] 97.44
Now65 4 | Biand*¥ fights... -sheee 18 27 6 22).22\) C0 208
|| emdGriehits..8) ).5. 220" opr | SaaS Eee 77 28) 2a
( | Guang leche: ok 5 sent Sete .-| 32 34 00 00.00)100.00
No. 66.4) Brand Yolighiss ss) case) | 16 31 5 16.12) 83.18
Lf Apesbuee Gry A gs einai gee ee | ily 11 64.72] 35.28
No. 57 {| Pood*and paper: .2.:..24 .. uaa 39 33 84.62) 15.38
“ld Boddvand paper: 2 fee ee 30 | 41 34 82.93] 17.07

between the colored lights, rather than whether a permanent
association could be formed (fig. 7, C, D; table 3).
Experiments of longer duration were performed on stickle-
back no. 46 and stickleback no. 50. No. 46 was first trained to
come for food in green light, and to inhibit the impulse when
paper closely resembling the food in color was offered in red
light. This test continued thirty-four days, January 5 to Febru-
ary 7. On only seven days do the records show errors, and dur-
ing sixteen successive days a perfect record was maintained. On
the thirty-fifth day the colors were reversed. The permanency

ASSOCIATION AND COLOR DISCRIMINATION 483

of the acquired association was demonstrated by the fact that
during the twenty days following the fish persisted in attempting
to take the paper under the green light which had previously
shone upon its food. The reversal of the colors seemed to con-
fuse the fish, and an errorless record with the new conditions
was never shown as in the previous test. It required a much
longer period to form the habit of taking food in red light and
refusing paper in green light than to form the first association.
The entire experiment lasted ninety days, January 5 to April 3
(fig. 8, A; table 3). .

Stickleback no. 50 learned to react negatively to paper offered
in red light and positively to food in green light in a series of
tests continuing thirty-two days, at the end of which there was
a perfect record of fifteen days. Stickleback no. 50 reacted in
the same manner to the reversal of colors as had stickleback
no. 46. The association of food with green light was overcome
with great difficulty, but after seventy-one days of experiment
had elapsed, the fish was tested on ten successive days without
errors being made. Although the light intensity was varied for
the last twenty-three days of the experiment, the oscillations of
successes and failures which took place seemed not to be corre-
lated with the relative intensities of the lights, and it may be
noted in the tabulated results (table 2) that the highest percent-
age of successes for the whole experiment was recorded during
this period (fig. 8, B).

Like the mudminnows, the sticklebacks tested showed that
they were able to distinguish between red (600u to 730u) and
green (510u to 570x), but the experiments indicated that with
blue (420u to 480.) and yellow (580, to 630, 660 to 7101) there
was no such discrimination.

Experiment with an aquarium of sticklebacks

An interesting piece of evidence was obtained from an aqua-
rium containing fourteen sticklebacks. These fishes were kept
under observation for several months, during which they were
regularly fed and became very tame. Calves’ liver was given to

484 GERTRUDE MAREAN WHITE

them nearly every day from forceps. It was very amusing to see
all fourteen of them dart to the top at a slight movement of anyone
near them and begin sticking their noses out of the water in
anticipation of food. When food was held a slight distance out
of water, they would with one accord leap out after it, and at
times hang on so tightly that they could be lifted several inches
out of the water before letting go their hold.

On one occasion, after the sticklebacks had been given a
small piece of calves’ liver, the forceps were held out to them
empty. None of the sticklebacks approached the forceps, but
the merest bit of dark red liver was sufficient to attract them,

A bit of rather bright red paper rolled into a ball and substi-
tuted for the food was at once attacked. Tan-yellow presented in
the same way ellcited no positive response. Lavender which had
a pinkish tinge was snapped at twice, while dark blue, gray,
yellow, and green failed to attract. When dark red paper.
which most closely resembled the color of the liver, appeared the
fishes darted towards it from all directions seizing it voraciously.
Reddish purple was snapped at several times. These papers
were compared with Klingsiek and Valette’s Code de Coleur
and were found to resemble most closely the following numbers:

Dark red—rouge no. 3
Red—rouge no. 6
Tan-yellow—orange no. 146
Yellow—orange-jaune no. 166
Green—vert no. 301
Blue—bleu violet no. 452
Gray—bleu violet no. 460
Lavender—violet no. 528B
Purple—violet rouge no. 571

This experiment indicates that the color of the food which
sticklebacks take habitually makes an impression difficult to
eradicate. Red no. 6 seemed to the eye to be very bright; red
no. 3 was quite as dark as blue no. 452, and not so dark as gray
no. 460 which was rejected.

ASSOCIATION AND COLOR DISCRIMINATION 485

Experiments with gray filters

Gray filters were presented alternately to the two sticklebacks
no. 65 and no. 66 exactly as they had been offered to mudmin-
nows no. 55 and no. 60. It may be noted that these were the
same sticklebacks which had been subjected to the experiment
with vellow and blue lights and to the experiment with red
and green; both had manifested the power to discriminate
between red and green. In contrast the experiment with
the gray filters was very striking, for on no occasion does the
record show a day without error for either fish. Neither of the
curves touches the point at O at any time during the experiments
(fig. 7, E, F; table 3).

Summary of results in regard to color vision of sticklebacks

1. Sticklebacks were not able to distinguish between blue and
yellow lights of the following wave-lengths: 420u to 480u and 580y
to 630u and 660u to 710u.

2. Red 600u to 730u and green 510 to 570u were distinguished
even when the relative intensities of these lights are varied from
Pt em. to 4:9°¢.m.

3. Photographic plates ‘fogged’ to a light and a dark gray
were not distinguished.

4. Sticklebacks form decided associations respecting the color
of the food which they habitually eat.

GENERAL CONCLUSIONS ON COLOR VISION IN FISHES

The experiments described in this paper and the work of other
investigators furnish evidence that some species of fishes perceive
differences in colors, and that this discrimination is based upon
the wave-length of the light, not on intensity. It seems rather
unlikely that the color vision of fishes approximates in character
that of human beings. It would be of interest to know what
range of colors fishes react to. The stickleback, at least, seems
unable to discriminate between blue (420u to 480u) and yellow
(580u to 630u, 660u to 710u). Whether these colors are con-
fused by mudminnows also has not been tested.

486 GERTRUDE MAREAN WHITE

Color perception seems to be of some importance in the lives
of fishes, since color associations are formed and persist for a
considerable time. Such associations may be formed even
when the colors are not present simultaneously. The value of
such associations to fishes which seek their food in shallow water
would be obvious. Food of a particular color once found to be
desirable may be singled out and pursued and undesirable sub-
stances more easily avoided. |

It is somewhat premature to discuss at length the theory of
color vision which the results of these experiments would seem
to support. The duplicity theory of von Kries assumes that
achromatic scotopic (dark-adapted) human vision is carried out
through the mediation of the rods alone, the cones being the
organ of photopic (light-adapted) vision. This conclusion is
derived from the fact that the fovea of the eye consists entirely
of cones, while the extreme periphery contains only rods; the
remainder of the retina had both rods and cones. The visual >
purple is located in the rods. For the light-adapted eye, the
fovea is the point of keenest vision, and the brightest part of
the spectrum is in the yellow. When the eye is dark-adapted,
on the other hand, the fovea is no longer the seat of keenest vis-
ion, but instead objects are seen more clearly when focused at
points away from the center of the eye. Green appears to the
dark-adapted eye as the brightest area of the spectrum and it
is in green light that visual purple is most strongly bleached.
The theory accounts very well for cases of total color-blindness
where the fovea of the eye is affected and the eye is unable to
focus strongly on any object. In such instances bright light
hinders vision. Night blindness might be explained on the
basis of a defect in the rods’ interfering with vision in low illu-
mination, but leaving vision in light of higher intensity unim-
paired. The researches of Hess on the comparative physiology
of vision in the lower animals, however, give little support to the
duplicity theory, since the eyes of all classes of vertebrates show
adaptation to light and darkness, even including tortoises which
have neither rods nor visual purple. The results of the experi-
ments with the sticklebacks described in this paper seem to have
little or no bearing upon this theory.

ASSOCIATION AND COLOR DISCRIMINATION 487

Hering bases his theory of opponent colors on the sensations
of complementary colors. When certain wave-lengths of red
and green are presented to the human eye simultaneously, the
result is a colorless sensation. The simultaneous perception of
yellow and blue of certain wave-lengths produces the same effect.
These four color sensations, red, green, blue, and yellow, are
regarded by Hering as the primary ones from mixtures or
dilutions of which all other color sensations are derived.
To these are added the primary sensations, black and white,
which on mixture result in sensations of gray. This theory
maintains that there exists in the eye three distinct visual sub-
stances affected by pairs of antagonistic physiological processes
in such a way as to produce the six primary sensations, white-
black, red-green, and yellow-blue.. In favor of this theory is
claimed for consideration the color sensitivity of the part of the
normal human retina lying outside of the fovea. The extreme
periphery of the retina is color-blind. Within this totally color-
blind zone lies an area which is red-green blind, but is sensitive
to blue and yellow stimuli, while the center of the retina is sen-
sitive to all colors. The most common form of color-blindness
is that in which red and green are not discriminated, and cases
are known in which yellow and blue are confused. Either type
of color-blindness might be explained by the absence of one of
the physiological substances. The same explanation might be
applied to account for the failure of the sticklebacks in the ex-
periments described to discriminate between yellow and blue.

The observation that on mixture red, green, and blue produce
white is the basis for the Young-Helmholtz theory, according to
which there are three primary colors instead of four from which
all other colors are derived. The wave-lengths of the red and the
blue are closely identical with the fundamental colors chosen by
the upholders of the four-color theory, while the green lies on
the yellow side of the green of Hering’s theory. This theory
explains very well certain cases of partial color-blindness by as-
suming the absence or diminution of one of the three theoret-
ical components. If this theory accounts for the inability of
sticklebacks in these experiments to discriminate between blue

488 GERTRUDE MAREAN WHITE

and yellow, the blue component must be assumed to be lacking.
These results seem to be explained equally well according to the
four-color theory of Hering and the three-color theory of Young-
Helmholtz.

EXPERIMENTS IN THE DISCRIMINATION OF PATTERNS

Mast (714) and Sumner (’11) have shown that certain flat fishes
adapt the color markings of their skin to the background against
which they rest. Such an adaptation would be frequently of
protective value. According to Mast, such stimulation is re-
ceived through the eye. One naturally inquires whether rec-
ognition of differences in the configuration of their environment
is of use to fishes in seeking their food. Experiments with a view
to ascertaining whether this is the case were carried out on the
stickleback and the mudminnow.

Mudminnows no. 27 and no. 40 which had given positive re-
sults in the color experiments were tested in several ways to
discover whether they could, form associations of food and paper
with various patterns. On the center of a round piece of card-
board 7 cm. in diameter was pasted a five-pointed star of black
paper. A ring of black paper 5.3 em. in diameter and 1 cm. wide
was pasted to a similar white card. When the star was held
above the tank containing the fish, forceps containing food were
presented, while the circle signified gray paper which matched
the food. As in the color tests, the fishes were made to leap out
of water to obtain the bait. Mudminnow no. 40 when sub-
jected to this test exhibited during twelve days no signs of form-
ing an association with the patterns.

Dots and stripes were the test next applied. Black stripes
1 em. wide were pasted on white cardboard 1 em. apart. On
another white cardboard were pasted black dots 1.8 cm. in di-
ameter and the same distance apart. Except for the designs
on the cards the test was in all respects similar to the previous
one, and the results were similar, for mudminnows no. 27 and
no. 40 to which it was applied attempted to take food in the
same manner when either card was held above them.

ASSOCIATION AND COLOR DISCRIMINATION 489

A circle of black paper 4.5 em. in diameter pasted on a white
ecard was not distinguished from a black square 4 cm. across,
- when they were presented under the same conditions as those
used in the tests described above, by mudminnow no. 39 during
thirty-seven days.

In order as nearly as possible to duplicate the conditions of
the experiments with colored lights, two pieces of glass were cut
the size of the gelatin filters. Upon the center of one was placed
a square of black paper 2.7 cm. across and upon the other four
black circles 1 cm. in diameter. These plates of glass were in-
serted in the tin box and the light flashed through them upon
the fishes. The appearence of the square was accompanied by
food and the black dots were to suggest paper. At the end of
thirty-eight days (February 27 to April 5). mudminnow no. 27
showed no signs of discrimination (fig. 9).

Two sticklebacks, no. 63 and no. 64, were subjected ti the
following experiment. Glass plates fitting into the tin box were
used. On one was a square 2 cm. in size and on the other a
black circle 2.5 em. in diameter. Neither fish showed that it
perceived the difference between them, though the experiment
continued sixty days.

While these experiments do not absolutely prove that differ-
ences in pattern are not perceived by mudminnows and stickle-
backs, they suggest that the discrimination of patterns and
differences in backgrounds does not have a very important
function in their search for food. No associations appeared to
be formed with the patterns used. These results are in sharp
contrast with those of the tests with colors.

ASSOCIATIONS FORMED IN FISHES
Types of associations

The analysis of the psychology of a fish, like that of any other
animal, can only be made by interpreting its immediate reactions
to stimuli of various sorts. The nature of the sense organs and
the reacting organism must determine the types of associations
formed, whether they are merely associations of particular

490 GERTRUDE MAREAN WHITE

muscular reactions with special stimuli without apparent con-
sciousness of their purpose on the part of the animal, or psy-
chological associations of a higher type.

The formation of associations with color stimuli has already
been shown to exist, but under similar conditions associations
with patterns were not formed in the tests made.

Associations with objects were found to occur. A large live
dobson-larva was dropped into a tank containing a mudminnow.
At first the larva was repeatedly attacked, but when, after a
dozen or more trials, the fish was unable to devour it, the larva
was completely ignored, although living Crustacea, worms, and
other baits were taken. At other times forceps containing no
food attracted mudminnows.

Moving objects and shadows nearly always induced reaction.
Sudden .movements caused the fishes to swim about rapidly as
if frightened and in search of cover. After the fishes had become
accustomed to being fed at the top of the water, the approach
of anyone caused the fishes to swim to the surface. Short, jerky.
wriggling motions as those of a worm attracted and agitated
them.

Jarring the tank produced the same result, probably owing to
the fact that it was customary to lift the vessel containing a fish
about to be tested and set it on the front of the table. While
moving a receptacle, it was necessary to keep it covered because
the fishes were likely to leap out of the water, sometimes land-
ing outside of the vessel. Fishes freshly brought into the lab-
oratory or those which had not been experimented upon could
be carried about in small vessels without showing any inclination
to jump out. A very definite moter association seemed to exist
in all the fishes with which tests were made, for shadows, move-
ments of the investigator, jarring the aquaria, all excited the
fishes to leap out of water, even when no food was in sight.

There is some evidence that the fishes associated a certain time
of day with their feeding. It was generally the custom to perform
the experiments at about the same hour each day; usually in the
afternoon. Changing the water in the tanks was found to be a
more difficult proceeding if it was done at the usual feeding

ASSOCIATION AND COLOR DISCRIMINATION 491

hour, even if the fishes had been fed, for they were more likely
to become excited. Goldsmith (’12) reports place association
in gobies and plaice. This has not been confirmed by tests on
the mudminnow and the stickleback in any respect other than
their swimming to the surface for food. An effort was made to
induce them to seek habitually a certain end of the tank where
food was dropped in through a tube, but there was no indication
that such a habit had been formed.

Delicacy of associations

It was presumed that associations formed in the nervous or-
ganism of fishes would not be such as to admit of fine discrimi-
nations; this was borne out by the experiments. Filters of
different shades of red and green could be interchanged without
affecting the reactions. The pattern experiments brought no
positive results.

A stickleback, no. 57, was offered minced liver and gray paper
alternately thirty-nine times in thirty-five days. The fish
learned very quickly to refuse the paper and to leap out after the
liver, but small pieces of angleworm could be substituted for the
liver without the fish obviously perceiving the difference. The
successes were 84.62 per cent and the errors 15.38 per cent;
during the last ten days of the experiment not a single error
was recorded. A similar record was shown when the experiment
was repeated with the same stickleback, when in thirty days the
successes were 83.03 per cent and the mistakes were 17.07 per
cent; all the reactions during the last nine days were perfect
(fig. 10; table 3).

Complexity of associations.

Fishes are evidently capable of forming only very simple as-
sociations directly related to their struggle for existence. This
is to be expected, since, so far as is indicated, they possess only
the kind of attention which leads directly to activity. Thorn-
dike (11) reports being able to induce Fundulus to seek exit from

492 GERTRUDE MAREAN WHITE

a box into the sun through an opening. According to Churchill
(16), goldfish are able to ‘learn a maze’ consisting of two par-
titions placed at intervals across a vessel a short distance from
each other. The fishes were placed in a compartment at one
end and were obliged to pass through holes in the two partitions
in order to reach the opposite end of the aquarium where food
was located. The habit proved to be fairly well established,
for, after thirteen days’ lapse, the fishes were able to follow the
route correctly.

In the present experiments sticklebacks showed no disposition
to lessen the time of passing through a triangular opening at the
bottom of a glass partition when food was dropped on the other
side, but simply darted against the glass until they chanced to
hit the opening and swim through. The experiment continued
thirty-four days, two fishes being used. _ The trials were carefully
timed with a stop-watch, and no improvement or lessening of the
time was noted.

Permanence of associations

The results of the experiments described have some bearing
on the permanence of associations. Mudminnow no. 55 showed
the influence of previous training by red and green filters forty-
two days after the first series of experiments had ceased. Dur-
ing the color tests perfect records of ten or more consecutive days
were frequently shown, while in one instance a fish made no
mistakes during fifteen days and in another instance during
sixteen days. Discontinuing an experiment for a day or two
after an association was fairly well established never seemed to
dull the impression received. When trained to spring out of
water after food, the fishes repeated the action indefinitely as
long as food could be procured in that manner and almost com-
pletely, ignored bits of food dropped into the water.

Modification of associations

Associations once established persisted in a rather stereotyped
fashion. After being accustomed to take food in light of a certain

ASSOCIATION AND COLOR DISCRIMINATION 493

color, mudminnows, and even more especially the sticklebacks
were confused by the reversal of the food and paper in relation
to the colors. The reversed combination seemed to be more
difficult to master than the original one.

GENERAL CONCLUSIONS FROM THE EXPERIMENTS DESCRIBED

Compared with land vertebrates, fishes live in a constant
medium where little premium is put upon sensory specialization.
None of the sense organs have a marked degree of perfection.
The behavior of fishes is stereotyped. Their associations are
simple, few in number, and are not readily modified, though
they are often fairly permanent when once formed. ‘ Learning’
seems to consist for the most part in the gradual elimination of
useless movements and the establishing of useful ones.

There is little evidence of the formation of new types of move-
ments. A considerable period of training in concentrating the
attention upon the object in view seems to be necessary before
associations can be formed.

That instincts may be inhibited is demonstrated in the color
experiments where the fishes gradually overcame the impulse
to Jeap out after paper which resembles their food in light of
a certain color when they had thus been several times unsuc-
cessful in obtaining food. Stickleback no. 57, after being re-
peatedly offered gray paper alternately with pieces of liver,
refused to spring out after the paper.

Fishes do not seem to be capable of anything which might
properly be called a concept, nor to exhibit memory in the sense
of having ideas about absent objects. They do react more
readily to present objects with which they have had experience
in the past, particularly if this experience has been several times
repeated. There is nothing to indicate that they are able to
recall an image of their past experience. After some repetition
- of a reaction they form associations and habits.

Imitation in fishes is well described by Hobhouse’s definition
of sensory-motor imitation: ‘‘the perception of what is done
discharges a motor impulse to do the same thing quite apart
from any purpose to be served by doing it.”’ Sticklebacks which

THE JOURNAL OF EXPERIMENTAL ZOOLOGY, VOL. 27, No. 4

494 GERTRUDE MAREAN WHITE

swim in schools show no evidence of an intelligent purpose in
swimming in any particular direction other than that one indi-
vidual, not always the same one, happens to make a sudden dart.
The movement is perceived by the rest and immediately followed.
If one of the fishes chances to obtain a bit of food, the others
attracted by the motion, are as likely to pounce upon the fortu-
nate one as they are to attack the food lying close at hand. They
strike their rival quite as often on the tail or fins as on the mouth.
If the aggregation of fishes into schools represents the beginning
of social consciousness it must be very dim and obscure. It is
quite possible that fishes of the same school are attracted to
each other by characteristic odors and the movements peculiar
to the species. There seems to be no clear proof of the subor-
dination of the welfare of the individual to the general good of
its kind, nor any decided development of a social or gregarious
instinct.

GENERAL SUMMARY

1. Mudminnows were able to discriminate between the fol-
lowing wave-lengths of light: red 6004 to 730u and green 510y
to 570u, red 600u to 730u, and blue 420u to 480u, yellow 580u
to 630u, 6604 to 710, and green 510u to 570, as is shown by
associations of paper and food with these colored lights (pp.
462-474).

2. Varying the intensity of the red and green lights and the
yellow and green lights from 1.4 ¢.m. to 4.9 e.m. did not affect
such discrimination, indicating that the reactions were to color
rather than to intensity. This conclusion is further supported
by the fact that fishes which had previously shown that they
perceived differences between monochromatic gelatin filters were
not able to distinguish between photographic plates which had
been ‘fogged’ to different shades of gray (pp. 466-474).

3. Sticklebacks were not able to discriminate between the
following wave-lengths of light: blue 420u to 480u and yellow
580u to 630u, 660u to 710u, but were able to discriminate be-
tween red 600n to 730 and green 510 to 570u, forming asso-
ciations of food and paper with them. These associations per-

ASSOCIATION AND COLOR DISCRIMINATION 495

sisted unchanged even when the relative intensities of these
lights were varied from 1.4 c.m. to 4.9 ¢.m. Differences in the
intensity of light passing through photographic plates ‘fogged’
to a light and dark gray were not distinguished (pp. 475-483,
485).

4. That sticklebacks form decided associations respecting the
color of the food which they habitually eat was further shown by
the experiment in which fourteen sticklebacks in an aquarium
were offered food and paper of various colors (pp. 483-484).

5. Although the experiments summarized above show that
the discrimination of differences in colors by mudminnows and
sticklebacks is based upon wave-length rather than intensity,
it seems unlikely that the color vision of: fishes is as highly de-
veloped as that of man, for sticklebacks, at least, seem unable
to distinguish between blue 4204 to 480u and yellow 580u to 630,
660 to 710n.

6. The results of the experiments with sticklebacks give little
support to the duplicity theory of v. Kries, but might be ex-
plained upon the basis of Hering’s theory of opponent colors if
it is assumed that the yellow-blue substance is lacking. The
conclusions seem to accord with the Young-Helmholtz theory if
it is supposed that the eye of sticklebacks has none of the blue
component.

7. The negative results in the experiments with patterns
strongly suggest that the discrimination of patterns and differ-
ences in backgrounds by mudminnows and sticklebacks does
not have a very important function in their search for food.
The perception of color and movement seem to be of the most
importance. In sticklebacks the sense of smell is also used to
a ‘considerable extent.

8. The behavior of fishes is stereotyped. The associations
formed are simple, few in number, and not open to ready modifi-
cation, though they may be fairly permanent, and may involve
considerable acuity in sensory discrimination. ‘Learning’ seems
to consist for the most part in the gradual elimination of useless
movements and the establishing of those which are useful:

496 GERTRUDE MAREAN WHITE

BIBLIOGRAPHY

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1, pp. 225-256.
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1912 Sind die Fische farbenblind? Ibid., Bd. 33, S. 107-126.
1912 Uber die Farbenanpassung des Crenilabrus. Ibid., Bd. 33, S.
151-164.
1914 Weitere Untersuchungen iiber den Farbensinn der Fische.
Ibid., Bd. 34, S. 43-68.
GoxpsmitH, M. 1912 Contribution a l’étude de la mémoire chez les poissons.
Bull. Inst. Gén. Psych., T. 12, pp. 161-176.
GraBer, V. 1884 Grundlinien zur Erforschung des Helligskeits- und Far-
bensinnes der Tiere. Prag und Leipsig, S. 126-132.
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Hess, C. 1909 Untersuchungen iiber den Lichtsinn bei Fischen. Arch. Augen-
heilkde., Ergiinzungsheft, Bd. 64, S. 1-38.
1912 Untersuchungen zur Frage noch dem Vorkommen von Farben-
sinn bei Fischen. Zool. Jahrb., Allge. Zool., Bd. 31, S. 629-646.
1913 Neue Untersuchungen zur vergleichenden Physiologie des Ge-
sichtsinnes. Ibid., Bd. 33, 8. 387-440.
Logs, J., AND WasteNnEys, H. 1915 The identity of heliotropism in animals
“and plants. Science, N.S., vol. 41, pp. 328-330.
Lonatey, W. H. 1914 Report upon the color of fishes of the Torgugas Reefs.
Year Book of the Carnegie Inst. of Wash., no. 13, pp. 207-208. ~
1915 Coloration of tropical reef fishes. Ibid., no. 14, pp. 208-209.
1917 Studies upon the biological significance of animal coloration.
I. Colors and color changes of coral-reef fishes. Jour. Exper. Zodl.,
vol. 23, pp. 533-599.
Lyon, E. P. 1904 On rheotropism. I. Rheotropism in fishes. Amer. Jour.
Physiol., vol. 12, pp. 149-161.
Mast, 8S. O. 1914 Changes in shade, color, and pattern in fishes, and their
bearing. on the problem of adaptation and behavior, with special

|

ASSOCIATION AND COLOR DISCRIMINATION 497

reference to the flounders Paralichthys and Ancylopsetta. Bull. U.
S. Bur. Fish., vol. 34, pp. 173-238.

1915 The behaviour of Fundulus with especial reference to overland
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MinkrEwicz, R. 1912 Recherches sur la formation des habitudes, le sens des
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graphique (Monaco), T. 5, Fasc. IV, pp. 1-53.

Parker, G. H. 1903 Hearing and allied senses in fishes. Bull. U. S. Bur.
Fish., vol. 22, pp. 45-64.

1905 The function of the lateral line organ in fishes. Ibid., vol. 24,
pp. 183-207.

1909 ‘The integumentary nerves of fishes as photoreceptors and their
significance for the origin of the vertebrate eye. Am. Jour. Physiol.,
vol. 25, pp. 77-80.

1910 Structure and functions of the ear of the Squeteague. Bull.
U.S. Bur. Fish., vol. 28, pp. 1211-1224.

1910 Influence of the eyes, ears, and other allied sense organs on the
movements of the dogfish, Mustelus canis (Mitchell). Ibid., vol. 29,
pp. 43-55.

1910 Olfactory reactions of fishes. Jour. Exper. Zodl., vol. 8, pp.
535-542.

1911 The olfactory reactions of the common killifish, Fundulus
heteroclitus (Linn.). Jour. Exper. Zoél., vol. 10, pp. 1-5.

1911 Effects of explosive sounds such as those produced by motor
boats and guns upon fishes. U.S. Bur. Fish., Doc., no. 752, pp. 3-9.
1912 Sound as a directing influence in the movements of fishes. Bull.
U.S. Bur. Fish., vol. 30, pp. 97-104.

1913 The directive influence of the sense of smell in the dogfish.
Ibid., vol. 33, pp. 61-68.

Parker, G. H., AnD SHELDON, R. L. 1912 The sense of smell in fishes. Bull.
U. S. Bur. Fish., vol. 32, pp. 35-46. .

Parsons, J. H. 1915 An introduction to the study of color vision. Cam-
bridge: at the University Press, New York: G. P. Putnam’s Sons.

REIGHARD, J. 1908 An experimental field-study of warning coloration in coral-
reef fishes. Papers from the Tortugas Lab., Carnegie Inst. Wash.,
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SHELFORD, V. E., anp ALLEE, W. C. 1913 The reactions of fishes to gradients
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207-266.

1914 Rapid modification of the behavior of fishes by contact with
modified water. Jour. An. Beh., vol. 4, pp. 1-30.

Sumner, F. B. 1911 The adjustment of flatfishes to various backgrounds:
a study of adaptive color change. Jour. Exper. Zodl., vol. 10, pp.
409-505.

THORNDIKE, HE. L. 1911 Animal intelligence. Macmillan Co., New York. pp.
169-171.

498 GERTRUDE MAREAN WHITE

TscuerRMAK, V. A. 1915 Das Sehen der Fische. Die Naturwissenschaften,
vol. 3, S. 177-181.

Wasusurn, M. F. 1913 The animal mind. Macmillan Co., New York, pp.
214, 221, 248, 251.

WasuBurn, M. F., anp Bentiey, 1. M. 1906 The establishment of an associa-
tion involving color discrimination in the creek chub, Semotilus
atromaculatus. Jour. Comp. Neur. and Psych., vol. 16, pp. 113-125.

Wetis, M.H. 1915 Reactions and resistance of fishes in their natural environ-
ment to acidity, alkalinity, and neutrality. Biol. Bull., vol. 29, pp.
221-257.

ZototTnitzky, N. 1901 Les poissons distinguent ills les couleurs? Arch. de
Zool. Expér. et Gén. 3° Série, T. 9, no. 1, pp. I-V (Notes et Revue).

“I<. BOM OMS RES
Oo) eT Ona
e230! ) ip sess
at sHithericy ide
Tit ERS vapeardd nite

i PS cee ier frat
aol A ae je eeleeet
AS |e TS

Resumido por el autor, George Howard Parker.

La organizacion de Renilla.

La rapidez de transmisi6n en la red nerviosa del borde del pié
en la columna de la anémone de mar Metridium fué medida por
el autor sirviéndose del método empleado comunmente para
determinar la velocidad de transmisién en las fibras nerviosas.
A la temperatura de 21°C., la velocidad de transmisi6én en dicha
red nerviosa es de 121 a 146 mm. por segundo.

Translation by Dr. José F. Nonidez
Columbia University

AUTHOR’S ABSTRACT OF THIS PAPER ISSUED
BY THE BIBLIOGRAPHIC SERVICE, FEBRUARY 3

THE ORGANIZATION OF RENILLA!
G. H. PARKER

ONE FIGURE

The curious sea-pen Renilla is a most favorable form in which
to study colonial organization, for the relatively large size of its
autozodids and its complete and natural freedom from attach-
ment make it an unusually satisfactory organism for experi-
mental study. The species upon which the work recorded in
this paper was. done was Renilla amethystina Verrill:from the
coast of Southern California, and I am under obligations to the
staff of the Scripps Institution for Biological Research at La
Jolla for many courtesies while I was carrying on this work.

Renilla is unlike other pennatulids in that its rachis, instead
of being elongate, is expanded into a’ broad heart-shaped or kid-
ney-shaped disc, only one surface of which carries zodids. The
peduncle is a ileshy tail-like extension and is peculiar in that it
is without an axial skeleton. In Renilla amethystina the ex-
panded rachis may measure as much as 6 or 7 em. in breadth and
may carry several hundred autozoéids and many more siphono-
zoodids. The peduncle, when distended, may reach the length
of 5 to 6em. Some confusion exists as to the terminology used
for the surfaces of Renilla. In the conventional system employed
for pennatulids the face corresponding to that on which the
zooids are borne in Renilla is known as the ventral face and the
opposite as the dorsal one. As Renilla rests on the sand in
natural position the upper face is what according to this system
would be called ventral, hence this condition has led to some
confusion in terminology, for not a few authors have naturally

‘ Contributions from the Zoédlogical Laboratory of the Museum of Compara-
tive Zodlogy at Harvard College, No. 316.

499

500 G. H. PARKER

called the upper face dorsal. I shall, therefore, not use the terms
dorsal and ventral for the parts in Renilla, but shall employ
superior and inferior as indicated by the natural position of the
animal. The face of the rachis that is upper when the animal
is normally at rest and that carries the zodids is superior, the
opposite face inferior.

If an expanded Renilla is watched in sea-water its autozodids,
generally distended, will be seen to exhibit from time to time
spontaneous withdrawals and expansions. When one of these
withdraws, its eight tentacles are first folded together, after
which the whole zoéid bends sharply to one side so as to appear
to be lying almost flat on the surface of the colony while it slowly
slips backward into the cavity occupied by it in the colony as a
whole. The complete withdrawal is accomplished in a few sec-
onds. In spontaneous expansion the eight tentacles first open
at the aperture in the colonial flesh into which the autozoéid has
withdrawn and its body next slowly elongates and rises out of
this aperture till it becomes fully extended. The process of
expansion requires also only a few seconds, but is usually some-
what slower than that of withdrawal.

In spontaneous withdrawal and expansion the various auto-
zooids seem to act with complete independence, for no unanimity
or sequence of response was observable among them. ‘The in-
dividual autozodids are extremely inert to mechanical stimula-
tion. It is scarcely possible to induce them to respond even to
vigorous prodding. They are, however, very responsive to a
faradic current, withdrawing at once when this stimulus is ap-
plied to them. In this instance, as in spontaneous withdrawal,
they act with complete independence and repeated attempts to
influence adjacent autozodids by stimulating a given one always
resulted negatively. Only under particular conditions did many
of them respond together. When the flesh of the colony as a -
whole contracted and the contained fluids were thus put under
unusual pressure, many autozodids—withdrawn but apparently
relaxed—expanded in unison. Muscular action also appeared at
times to increase the volume of the colony as a whole and, under
these conditions, many autozodids simultaneously withdrew.

ORGANIZATION OF RENILLA 501

Both these states, however, were quite obviously dependent upon
internal pressure relations and yielded no evidence in favor of
the view that one autozoéid has effective nervous connections
with another, and thus acts in unison with its neighbor. In
fact, the evidence seemed conclusive that so far as nervous or-
ganization is concerned the autozodids are strikingly independ-
ent of one another and resemble in this independence the separate
fingers of such a sponge as Stylotella.

The control of the pressure relations within the body of Renilla
is accomplished by a mechanism that has been more or less
worked out by previous investigators. If a freshly collected
Renilla is placed in a basin of sea-water, its volume will be found
to be much reduced and its autozodids mostly contracted.
Gradually it will be observed to become more and more inflated
and its autozodids will slowly expand, as already described by
Miller (64, p. 354). During the time the Renilla is filling it-
self with water, for such the operation is, the peduncle exhibits
rhythmic contractions that have a striking resemblance to in-
testinal peristalsis. At each onset of activity a wave of con-
traction can be seen to start in the region where the peduncle is
attached to the rachis and proceed thence to the distal end of
the peduncle. Waves of this kind run over the peduncle with
considerable regularity and occur ordinarily every thirty-five to
forty-five seconds. The regular association of this movement of
the peduncle with the distention of the body of Renilla suggests
that the activity of the peduncle is the chief means of accom-
plishing the distention of the colony as a whole and the canal
system within the colony supports this idea.

If a Renilla is anesthetized with magnesium sulphate and the
peduncle is cut transversely, this body can be seen to consist of a
stiff-walled tube containing, as has long been known (Miiller,
64; Verrill, 66-69; Kolliker, ’72; Eisen, ’76), two canals, one
(the inferior) about twice the cross-section of the other. These
canals are separated by a thin firm membrane, the transverse
septum. If the larger cavity is injected with sea-water contain-
ing some indifferent coloring matter in solution, such as methy-
lene blue, the colored fluid passes freely into the cavities of the

502 G. H. PARKER

rachis and flows out with equal freedom from the mouths of the
autozodids over the whole superior surface. If a similar injec-
tion is made into the smaller cavity, the colored fluid flows out of
only one orifice. This is near the middle of the superior face of
the rachis, and at the end of an axial band of somewhat smooth
tissue that leads from near the root of the peduncle over the
rachis to the region of its center. This orifice was first identi-
fied by Miiller (’64, p. 354), who described it as the general inlet
for the whole canal system of Renilla. Kolliker (72) suspected
it to be the mouth of the axial zodid, but Wilson’s studies (’84)
on the embryology of Renilla showed it to be a much enlarged

Fig. 1 Diagram of a median section of the rachis (R) and the peduncle (P)
of Renilla, showing the orifice (O) into the superior canal (S), which, near the
distal end of the peduncle, connects through the transverse septum with the
inferior canal (J). This in turn communicates with the bases of the zodids (Z),
whose mouths are open to the exterior.

siphonozodid. It was believed by Wilson (’84, p. 725) to be an
exhalent orifice, the other siphonozodids serving as means of
entrance for the water. If the connection of this orifice with the
smaller cavity in the peduncle is dissected out, it is found to be
a well-defined tube, extending from the external opening over
the superior face of the rachis, where its course is marked by the
band of smooth tissue already referred to, to the peduncle,
down whose whole length it can be followed as the superior canal
of that structure. The inferior canal in Renilla can also be shown
_to extend from the end of the peduncle through the length of that
structure and into the inferior portion of the rachis, where it

ORGANIZATION OF RENILLA 503

breaks up into small cavernous spaces that pass over ultimately
into the central cavities of the autozodids and thus communicate
through the mouths of these individuals with the exterior.

In the rachis and the proximal part of the peduncle the two
systems of canals, the superior and the inferior, are completely
distinct and fluids injected’ into one system never find their way
naturally into the other. This is not true of the distal part of
the peduncle. Here an injection driven distally into one canal
flows out freely from the other, showing that the two canals have
ready means of communication. The passage from one canal to
the other seems to be dependent upon one or more pores in the
transverse septum. I found no evidence of a terminal pore con-
necting the interior of the peduncle of Renilla with the outer
sea-water as described originally by Miller (64, p. 354) and
more recently for other pennatulids by Musgrave (’09).

From this description of the anatomical relations of the canals
and other cavities in the body of Renilla and from the observed
activities of this pennatulid, it is clear that the peduncle is a
highly differentiated structure connected with the inflation of
the colony. In Renilla the peduncle is not used so generally for
burrowing as in many other pennatulids, nor is there reason to
suppose that it is especially concerned with locomotion. The
fact that a specialized orifice (fig. 1, O) on the superior surface of
the rachis (2) in Renilla leads directly into the superior canal
(S), which near the distal end of the peduncle (P) communicates
with the inferior canal (J) and this in turn opens out through
the mouths of the autozodids (Z), is sufficient when taken in
connection with the peristalsis of the peduncle to suggest that
this is the system primarily concerned with the inflation of the
colony and consequently with its internal currents. In what
direction these currents set through the system, however, has .
never been accurately determined. Agassiz (50, p. 209) be-
lieved that the water entered and left Renilla through the mouths
of its autozodids. Miiller (’64, p. 354) stated that the water en-
tered through the large central siphonozodid first identified by
him. Wilson (’84, p. 725) regarded this opening as the outlet
for the system, the water entering through the other siphono-

504 G. H. PARKER

zooids; thus a direction the reverse of that implied by Miiller
was suggested. Possibly the current may take either direction,
depending upon circumstances. These are questions, however,
that must be tested out-on living material. The point to be
emphasized here is that, though the autozodids are extremely
independent in their individual activities, they may be unified
in a measure in their actions by the single organ for inflation,
the rhythmically contracting peduncle, which thus serves tke
colony as a whole.

Although the autozodéids of Renilla exhibit great independence
in activity and give evidence of only a slight unifying principle
that is almost purely mechanical, there is another feature in the
activities of this pennatulid that exhibits for the colony a much
more fundamental form of unity. This is its phosphorescence.
This peculiarity of Renilla was long ago observed by Agassiz
(50, p. 209), and in consequence of the brightness of the light
produced by this form it has commonly been listed among the
highly phosphorescent animals (Mangold, ’10-14, p. 250).
Its phosphorescence is characteristic of the night. If a living
specimen during the day is carried into a dark room and stim-
wlated, it will show no phosphorescence. If it is stimulated at
night by being prodded with a blunt implement or by the ap-
plication of a faradic current, waves of light will be seen to run
over the superior surface of its rachis. That the phosphorescence
is developed in the dark can be seen by keeping Renilla away
from the light during daytime. Such an animal, after having
been put in the dark, will show no trace of phosphorescence for
some time. After an hour or two, depending upon the inde-
vidual, a few phosphorescent points will appear on stimulation,
and in from two to three hours waves of phosphorescence will
course over the whole colony at each stimulus much as they do
at night. This condition may be maintained so long as the an-
imal is kept in the dark. It is lost in a quarter to half an hour
after the animal is returned to the light. In this respect Re-
nilla is like the ctenophore Mnemiopsis, whose phosphorescence,
as shown by Peters (’05), develops in the dark, but is inhibited
in the light.

TT

—. ©

ORGANIZATION OF RENILLA 505

The phosphorescence of Renilla is limited to the superior sur-
face of the rachis, and when this surface is scrutinized closely
under a hand lens, it is found that the phosphorescence is not
a property of the whole surface, but appears only in certain al-
most microscopic white granulations. These occur around the
openings in the common flesh through which the autozodids
emerge and particularly on the siphonozodids. When these
small white granules are touched with a fine needle-point, they
can be seen to shine for a considerable time with a bright blue-
green light. This individual activity is easily excited, but it
is not the characteristic form of luminous response. If an area
on the superior surface of the rachis is vigorously stimulated
mechanically or by a faradic current, waves of phosphorescence
sweep from this area as a center over.the whole of the superior
face of the rachis. These waves succeed one another at such a
rapid rate that the whole superior surface seems to be covered
with a rippling glow emanating from the region of stimulation.
After the application of the stimulus the luminous response
quickly subsides.

The general luminosity just described may be excited from
any point on the superior surface of the rachis. When the edge
of the rachis is stimulated, waves semicircular in form emanate
in rapid succession from the stimulated spot. When a central
position is chosen for stimulation, the waves pass out as ever
enlarging circles concentric about the point stimulated. <A close
scrutiny of each wave shows that it is not due to a general phos-
phorescence of the whole surface, but is the result of successive
glowings of the white granulations already mentioned. It is
difficult to understand how these successive activities are induced
unless it is assumed that the luminous points are all controlled
by a nerve-net whose form of transmission is reflected in the
outward moving circles of light. Since individual granules may
be made to glow brightly and persistently, it is plain that the
light of one granule does not automatically excite the next and
so on thus resulting in a wave of luminosity. The whole phe-
nomenon presents much more the appearance of a field of minute
luminous organs innervated by a nerve-net of an unpolarized

506 G. H. PARKER

type and, therefere, capable of transmitting in its own plane
from any point as a center radially in all directions. But, how-
ever transmission may be explained, the luminous response of
Renilla belongs to that category of reactions that involves the
organization of Renilla as a whole and, though the transmission
is obviously of a diffuse character, the luminous response is much
more indicative of colonial unity than, for instance, the action
of the autozodids is.

The relations pointed out in this paper are not without a cer-
tain morphological interest. The unit of structure of such a
colony as that of Renilla is quite obviously the zoéid. Each
zooid is made up of cells combined into tissue and these into
organs. Thus each zodid exhibits a series of graded relations
that are also characteristic of any metazoan individual. It has
long been recognized that most protozoans are unicellular and
hence cannot be said in any proper sense to have tissues or or-
gans, for these are always formed by combinations of cells. It
is obvious, however, that the single protozoan cell often has
special parts that perform particular functions in precisely the
same way that the organs of metazoans do. As these parts can-
not be properly designated as organs, they have been termed
by some organellae. If it is inappropriate to speak of organs
in protozoans because this term should be restricted to the mul-
ticellular parts of the metazoan individual, it is also inappro-
priate to use it in reference to a structure in a metazoan colony,
even though it may there perform a special function. Thus
while it is quite appropriate to designate the tentacle of a zodid
in Renilla as an organ, for it is a multicellular functional unit
in a single individual, it is not appropriate to speak of the pe-
duncle of Renilla as an organ, for this is a structure that serves
the whole colony of individuals. Such structures stand above
ordinary organs as organs stand above organellae. They might,
therefore, be called superorgans. In Renilla they are repre-
sented not only by the peduncle as a structure concerned with
the inflation of the colony as a whole, but by the nerve-net that
controls colonial luminosity. Superorgans give a unity to a
colony that is often unexpressed in the individuals of which it
is composed.

_

,

)

ORGANIZATION OF RENILLA 50

“I

BIBLIOGRAPHY

Aeassiz, L. 1850 On the structure of the Halcyonoid Polypi. Proceed. Amer.
Assoc. Adv. Sci., vol. 3, pp. 207-213.

Ersen, G. 1876. Beidrag till Kinnedomen om Pennatulidsligtet Renilla Lamk.
Kongl. Svenska Vet.-Akad. Handlingar, ny féljd, bd. 30, pp. 1-15,
taf. 1-3.

K6OLLIKER, A. 1872 Anatomisch-systematische Beschreibung der Alcyonarien.
Abhandl. Senckenberg. naturf. Gesell., Bd. 8, S. 85-275, Taf. 18—24

Mancotp, E. 1910-1914 Die Produktion von Licht. Winterstein, Handb.
vergl. Physiol., Bd. 3, Halfte 2, S. 225-392.

Méuter, F. 1864 Ein Wort iiber die Gattung Herklotsia J. E. Gray. Arch.
Naturgesch., Jahrg. 30, Bd. 1, S. 352-358.

Méserave, E. M. 1909 Experimental observations on the organs of circula-
tion and the powers of locomotion in pennatulids. Quart. Jour.
Micr. Sci., new ser., vol. 54, pp. 443-481, pls. 26-27.

Peters, A. W. 1905 Phosphorescence in ctenophores. Jour. Exp. Zoél., vol.
2, pp. 103-116.

VERRILL, A. E. 1866-1869 Revision of the Polypi of the eastern coast of the
United States. Mem. Boston Soe. Nat. Hist., vol. 1, pp. 1-45, pl. 1.

Witson, E. B. 1884 The development of Renilla. Philos. Trans. Roy. Soc.
London, vol. 174, pp. 723-815, pls. 52-67.

THE JOURNAL OF EXPERIMENTAL ZOOLOGY, VOL. 27, No. 4

Resumido por la autora, Mary B. Stark.

Un tumor hereditario.

El presente trabajo es un estudio de un tumor ligado con el
sexo, el cual aparece tan solo en la mitad de las larvas que han
de producir machos, en la mosca de los frutos, Drosophila, cau-
sando la muerte de dichos machos. Se ocupa de esta materia
bajo los siguientes epigrafe : 1). Desarrollo del tumor a ex-
pensas de una suspensién de sus células. Estas suspensiones se _
inyectaron en moscas adultas y en gusanos de la harina (Tene-
brio), en ambos de los cuales tuvieron lugar crecimientos anor-
males que eventualmente causaron la muerte de las mosca o
del gusano. Los tumores se mantuvieron vivos en una gota
pendiente de la solucién de Locke y presentaron desarrollo
ulterior. 2). El tumor no se debe a un microorganismo. Todos
los medios de cultivo de uso corriente en los laboratorios fueron
inoculados con suspensi6n de células del tumor e incubados bajo
condiciones aerobias y anaerobias sin que se produjese creci-
miento aleuno. Las moscas fueron criadas en medios estériles,
bajo condiciones de absoluta esterilidad, pero los tumores con-
tinuaron desarrollindose lo mismo que antes. 3.) Desarrollo
del tumor. El tumor se desarrolla en elementos embrionarios
destinados a producir los 6rganos del adulto durante el estado
de ninfa. Su desarrollo se inicia con una excesiva produccidn de
melanina la cual, a su vez, aumenta la proliferacién celular. La
melanina existe normalmente en las células ganglionares y estas
células estdin en relacién con algunos de los rudimentos em-
brionarios por medio de fibras ganglionadas. 4.) Presencia de
metastasas. Las metastasas se presentan normalmente en las
larvas con tumores. El trabajo esta ilustrado con doce figuras
en ldminas, que representan diversos estados de desarrollo del
tumor en los diversos rudimentos embrionarios.

Translation by Dr. José F. Nonidez
Columbia University

|
|

AUTHOR’S ABSTRACT OF THIS PAPER ISSUED
BY THE BIBLIOGRAPHIC SERVICE, FEBRUARY 3

AN HEREDITARY TUMOR

MARY B. STARK
From The New York Medical College and Hospital for Women

TWELVE FIGURES (THREE PLATES)

A report has already been made of the injection of tumor-cell
suspension of Drosophila into normal larvae (Jour. of Cane.
Res., July, 1918). Although nearly one-half of these larvae sur-
vived the operation and were active for at least twelve hours,
they eventually died without completing metamorphosis. Death
may have been due to the toxic effects of the cell suspension or
may have been due to infection. The larvae from which tumors
were removed and the larvae into which the cell suspension was
injected had been washed repeatedly in sterile water. This
would not, however, be sufficient to rid the larvae of all bacteria,
and some may have entered the body cavity with the pipette,
in which case infection could easily result.

An attempt has been made to transplant the tumor into the
adult fly. Sixty flies have been injected with a sterile tumor-
cell suspension. A large percentage of these flies survived the
operation and lived from twenty-four to thirty-six hours. Only
10 per cent, however, continued to live. The great mortality
is again probably due to infection, brought on by contamina-
tion. It is almost impossible to produce a clean surface on the
fly for inoculation as the least moisture on the body of the fly
will entangle the wings and legs and cause the fly to become
stuck to the side of the container or to the food. I tried cutting
off the wings to prevent this, but these flies did not survive any
better than the others. Two of the six flies that continued to
live developed a dark spot within the place of inoculation.
These flies were fixed, sectioned, and stained. On microscopic
examination, the spot in each fly was found to be an abnormal
growth. In one fly the growth was found near the surface just

509

510 MARY B. STARK

below the place of inoculation and in the other fly it was deep
in the thorax, between the muscles, and spreading into one of
the muscles. Both growths were deeply pigmented and looked
very much like old tumors of the larvae, where the cells have
become so crowded with pigment that the cell outlines are en-
tirely lost. Figure 1 shows a section through the center of the
tumor. Near the periphery of the growth may be noticed cells
that are not so densely pigmented. These cells resemble those
of the tumor originally injected and evidently must have de-
veloped from the injected tumor cells. That the tumors could
be kept alive and could even increase in size in a medium outside
the body of the fly larva was ascertained in the spring of 1916,
when very young tumors were removed from larvae and placed
in a hanging drop of sterile Locke’s solution, sealing the cover-
slip with vaselin. In this condition the tumors were kept alive
for several days, during which time a perceptible increase in
size was noticed, also a change from a light tumor to a dark
mature tumor by the increase in the amount of pigment. If
only a portion of the tumor was placed in the hanging drop
there was an irregular spreading of the cells as growth continued.

The mortality due to the operation was considerably decreased
by repeating the last experiment under absolutely aseptic con-
ditions. The tumors of larvae bred on sterile media in Erlen-
meyer flasks, and the flies operated upon were also reared on
sterile media. Table 1 gives the results of this experiment.

One hundred and eighty-two flies were operated upon. Of
these, seventy-three died from the effect of the ether. The
forty flies that died within twenty-four hours were never very
active and probably died from the effects of the operation.
The remaining sixty-nine flies recovered from the operation and
were very active and normal in their behavior until just before
death, when they became sluggish and inactive. Of these,
twenty-nine died within forty-eight hours, thirteen within three
days, six within four days, and twenty after one week. Of the
flies that recovered from the effects of the ether, 36.69 per cent
died from the operation and 63.30 per cent died from the effects
of the tumor suspension.

————

AN HEREDITARY TUMOR 5 ID |

One fly developed a tumor visible to the naked eye. Several
of the flies that died were fixed and prepared for microscopic
examination. In two of these were found abnormal tissues.

As a control, sterile Locke’s solution was injected into one
hundred flies free from bacteria. Of these, thirty died from the

TABLE 1
2 dene ea alate ja jag| @ fa
3 A 3 a 2 z 4 Z By 3 5
: E lhos lee ae heel 2a ces be
a |eelee|se| a] 8) e4las|28) 2 1s
s /EESE/ 83/2 | 2/26/28] 35] & | ee
pb |pF 16°) 54) 5 5 | 5 5o)as & ae
A |Z Z Z Z Be q < Onl ei
WMecember 12, 1Ol7 ......'... HOM ES es ea 4 1} Yes} 1
amiramy Oe OUST. pevks. se = LOD rou Aa a 4] 1
January LOIS. v.23... HOS eSole eons 4 3 | 4
Hebruary i, 1918.2)... 0.5: 10 0 4 2 4 4 6
February 15, 1918 . 2.2... «. 10) 45 | AN 2 4) 2
MirchucoralOuss oon 2. we 516s. 10 Da rE 3 1 A | 4
SAU og I) kaa in LOS ce le A ad 2. As) aa) Mes
My 16 1919, 15 | 14 1 1 | Yes
Mi 176 1918. | 2 bec. a! 81 5 3 3
lave ali CH pea aoe er 4 3 1 1
IES ISD Se ee er DV A 6 1 7
wd (athe sO: Se ib, lp oH 3 9
i ive U8 2 [a ol 2y 2 2 2 | Yes
Rise TOUS, 22).90. ie...» 10 6 | 1 Sie! ano eer
MU ON a Ec: 13 5 6 2 8
MeyesIegts 2)... 10) | -4 |, 4 1 1] 4] 2
ay SPONe te . Jt 2, Ls 11 2 1 4 4 1 8 | Yes
Mav e25 I OISi sa cae dea 13 5 5) 2 1 5 3
182 | 73 | 40 | 29/13] 6 | 20 | 40 | 68 1

effects of the ether, twenty-eight from the operation, while
forty-two recovered and continued to live.

Since the injected tumor cells developed in the adult fly and
since tumors could be kept alive in Locke’s solution and show
growth in the same, there is evidence that the tumor cells when
placed in suitable media will grow outside the body of the larva.

aI MARY B. STARK

It is possible that the death of all the larvae into which the sus-
pension was injected may be partly due to the toxic effects of
the tumor cells injected and partly due to the effects of tumors
developed from the suspension. The larvae did not live suffi-
ciently long to allow the growth of tumors large enough to be
seen with the naked eye, but some development must have taken
place. The adult tissues of the fly are more resistant than those
of the larvae and are not so much affected by the toxic products
of the tumor-cell suspension. The flies continue to live suffi-
ciently long to allow the development of a tumor from the in-
jected tumor cells. Death occurred sooner or later, however,
and it is evidently due to the development of a tumor from the
injected cell suspension.

MEAL-WORM INOCULATION

Hoping to increase the percentage of tumors developed from
tumor-cell suspension, it occurred to me to inject the suspension
into larger insects. The meal worm was tried, since it is easily
obtained and lives as a larva two years, a period more than
long enough for the development of a tumor.

The tumor-cell suspension was prepared as before. The meal
worms were washed in alcohol and kept in sterile Petri dishes
until the wounds healed. The inoculation was normally made
between the seventh and eighth pleurites. Two sets of controls
were used: one Locke’s solution and the other normal-cell sus-
pension in Locke’s solution. Two weeks after the inoculation, I
noticed in many of the worms that had received the tumor-cell
suspension the appearance of small black spots. These spots
were often near the place of inoculation, but were also found in
other regions of the body. Some of these worms were killed and
the regions with spots were fixed, sectioned, and stained. Mji-
eroscopic examination revealed the fact that they were abnormal
growths. A section through the growth, as in figure 2, shows the
center to be made up of a necrotic area surrounded by a new
growth of the connective-tissue cells of the meal worm. All
the growths examined were similar in structure. It looks as

AN HEREDITARY TUMOR 513

if there had been an abnormal growth, stimulated probably by
the injected substance, in which degeneration has occurred,
brought on by the new growth of the meal worm.

At first I did not notice any spots in the controls, but later
they appeared in as great numbers in the worms that had re-
ceived the normal-cell suspension as in those receiving the tumor-
cell suspension.

Table 2 gives the number of meal worms injected with tumor-
cell suspension, normal-cell suspension, and Locke’s solution
respectively, and the number of new growths developed. Since
these abnormal growths occurred in the controls as well as in the
worms receiving the tumor-cell suspension, it is evident that they
are not all due to the injected tumor cells, but rather to an
infection. The growths resemble very much the tubercles de-
scribed by Adami. I tested the suspension for sterility after this
and isolated many of the ordinary bacteria. Of these I injected
fifteen-hour broth cultures of Staphylococcus and also B. subtilis
into meal worms. The worms receiving the Staphylococci died
within twenty-four hours. Those receiving B. subtilis contin-
ued to live and eventually developed growths like those already
described. Since this inoculation was done under absolutely
aseptic conditions—the broth having been sterile to all organisms
excepting B. subtilis, the pipette sterile, and the place of inocula-
tion on the worm kept moist with 85 per cent alcohol for ten
minutes—it is evident that the growth is due to an infection
brought on by B. subtilis.

I have repeated the experiment of injecting tumor-cell sus-
pension into meal worms under absolutely aseptic conditions,
that is, sterilizing the fly larvae in 85 per cent alcohol, leaving
them in ten minutes, washing the meal worms more carefully,
and sterilizing the Locke’s solution after each time used. The
suspension was tested each time for sterility, and if found not
sterile, the worms having received the injection were discarded.
Results are shown in table 3. No tumors developed in the meal
worms receiving the Locke’s solution and normal-cell suspen-
sion. Of those that received the tumor-cell suspension, two
developed tumors and died. Seven other worms that died

MARY B. STARK
TABLE 2

514

SuOWAL
woud aVad WoL WON

NOIWVuUado
WOU dvaid WHHNON

IVWUON YWHAW ON

\ avid
§8L0d8 HLIM UMANWON

8L0Od8 HALIM UWANON

SIGIM fF
NIWGIM GVO WoHWON

sAva J
NIWLIM AVG UAW ON

SUMO QF
NIHGIM GVH UGAWON

SUnO
~Z NIHJIM Aviad

dauLvTOOONT uagawon

a. Locke’s solution

-

os |

13

>|

14

15.53

22.22
18.16

PERCENTAGE DEAD FROM TUMORS

34.48

OPERATION
19.22

c. Tumor-cell suspension
PERCENTAGE DEAD FROM

b. Normal cell suspension

(a0) Se
(ce) .

515

AN HEREDITARY TUMOR

TABLE 3

SuOWOL
WOUdT Gvaad WaHWON

NOW vuaddo
Wout avid UAHWoON

IVAUON UMAWON

avaa
S8LOdS HLIM UAHNON

§LOds HLIM HAHWON

SUGAM F
NIHGIM AVEC UACWON

Siva )
NIHGIM Ava Wad WON

SUNOH oF
NIHLIM GVAa wAAWON

SUN0H FZ
NIHGIM AVEC WHEW ON

aaLVIOOONI UaaWoNn

a. Locke’s solution

1D I~ wk

Normal-cell solution

b.

NOON OD oO
ri

me N oD Ne}
coee|s
i> E

NN oD wo
OD CY) sH co No)
re

c. Tumor-cell solution

N

9

6

ms NAN

PERCENTAGE DEAD FROM

PERCENTAGE DEAD FROM OPER-

TUMORS

ATION

(2) OS Pleas a ha a ee

(C) oe eae

516 MARY B. STARK

nearly four weeks after the operation must have died from the
effects of the tumor-cell suspension. The tumors, if any had
developed, were too small to be seen through the thick exo-
skeleton of the meal worm. All these worms had been dead
too long for microscopical examination, and it cannot be said
definitely that tumors had developed in the last sevenworms
mentioned. The meal worms seem more resistant to the mocu-
lation of the tumor-cell suspension, since 57.5 per cent of the
worms inoculated remained normal. It is to be expected that
the tumor cells cannot be transplanted successfully into all
insects. Erwin F. Smith has had the same experience with his
crown galls. Some plants, he found, are too resistant for the
development of the gall when cells of the same are transplanted
into them. (Johns Hopkins Hospital Bull., Vol. 28, 1917.)

THE TUMOR NOT DUE TO AN INFECTION

Since the tumor of Drosophila is hereditary—occurring ex-
actly in one-half of the males in every generation—it does not
seem probable that it is due to an infection. However, sus-
ceptibility to an infection may be hereditary. In that case the
infection is possible only in the presence of the microorganism to
which susceptibility is hereditary and the tumor could develop
only in the presence of the specific microorganism. To deter-
mine whether the tumor is due to an infection or not, I made an
attempt to isolate a specific organism. I sterilized larvae with
tumors, removed the tumors, exercising all aseptic precautions,
and ground them into pieces in some Locke’s solution. All the
ordinary laboratory media were inoculated with this cell sus-
pension and incubated under both aerobic and anaerobic con-
ditions. Twice I got a growth of B. subtilis, otherwise no growth
whatever. B. subtilis is a saprophyte commonly found in tu-
mors and is probably not the cause of this tumor. Before pre-
paring special media for the specific organisms that might be
the cause of the tumor, it occurred to me to cultivate the flies in
which the tumor occurs under aseptic conditions. Eggs were
picked and sterilized in 85 per cent alcohol for ten minutes.
They were then transferred to sterile media in Erlenmeyer

AN HEREDITARY TUMOR 517

flasks. The culture media which proved most satisfactory was
the banana—yeast-agar method, based on the work of several
investigators. The formula used was that recommended by
Baumberger (Science, 17). The media consisted of one cake of
yeast dissolved in 50 cc. of water added to one-half dozen mashed
bananas, mixing thoroughly and allowing it to ferment for
twenty-four hours. This was pressed through a cloth and the
resulting liquid heated with 1.5 grams agar-agar per 100 ec. and
poured into Erlenmeyer flasks, plugged and sterilized in an
Arnold sterilizer three successive days. ‘Thirty sterile eggs were
placed in each of four flasks. Larvae with tumors appeared in
all the flasks. Larvae from each flask were removed with a
sterile platinum loop and placed in plain broth—sugar broth—
and allowed to crawl over slant agar. On two of the slant agar
and in one dextrose broth I got a pure culture of yeast, but sterile
otherwise as regards bacteria. The yeast is necessarily present,
since it is the chief food of the larvae. At regular intervals
the medium in the Erlenmeyer flasks was tested for its sterility
and was in every case found free from bacteria. When the flies
emerged from their pupa cases they were passed into other
flasks with fresh, sterile media. Some were passed into slant
agar tubes and allowed to walk over the agar. These tubes
were incubated, but no growth occurred except a pure culture
of yeast on one agar slant. From the eggs laid by the sterile
flies larvae hatched which. developed tumors. These larvae
were tested for.sterility as before and were found free from bac-
teria. Since the tumor is developed in larvae bred in absolutely
sterile conditions, it is quite evident that it is not due to an
infection, taking for granted that an absolutely sterile condition
means a condition not only free from the ordinary bacteria of
contamination, but also ultramicroscopic organisms.

It is known that in certain diseases the infection is due to the
presence of microorganisms within the eggs, the eggs becoming
contaminated from the mother before enclosed in the outer shell.
To determine whether the egg is the source of infection in the
case of this hereditary tumor, hundreds of eggs laid upon sterile
media by flies free from bacteria were picked and ground up in

518 MARY B. STARK

sterile Locke’s solution. All the ordinary laboratory media were
inoculated by this suspension and incubated under both aerobic
and anaerobic conditions. No growth appeared. The sterile
egg suspension was also mixed with the sterile media upon
which stocks of flies without tumors were reared. The larvae
that fed upon this food contaminated with the egg suspension
developed normally.

The suspension was also injected into adult flies. The flies
that survived the operation continued to live and to produce
normally. The egg is evidently not the source of infection.

DEVELOPMENT OF THE TUMOR

Tumors have been found to occur in various regions of the
body of the larva. Whether it occurs more often in any par-
ticular region has not yet been definitely determined. Sections
of larvae show, however, that the tumor occurs in embryonic
tissues destined to build up the adult organs during the pupa
stage. These tissues are spoken of as imaginal disks and imagi-
nal rudiments.

In the dorsal region of the thoracic segments of the larva there
are six groups of embryonic cells or imaginal rudiments in which
the tumor may take its origin. Figure 3 shows a tumor de-
veloping in the two anterior rudiments. Figure 4 shows the
tumor developing in the posterior rudiment. In the early
stages of the development of the tumor the cells of the imaginal
rudiment begin to deposit pigment. As development goes on,
there is a tendency for the pigment cells to be pushed toward
the periphery by the rapidly proliferating cells of the rudiment
and there become deposited in laminated layers, as shown in
figure 3. Figure 4 shows the entire rudiment encapsulated by
the pigmented, flattened, peripheral cells and entirely separated
from the other rudiments. The laminated layers of flattened
cells may again be surrounded by proliferating cells, as shown
in figure 4.

The tumor may also develop in the ganglion of the proventric-
ulus. This ganglion consists of a number of large cells very

AN HEREDITARY TUMOR 519

loosely connected with one another. Granules of brown pig-
ment are normally present in these cells. The ganglion forms a
crutch over the anterior portion of the proventriculus, giving off
ganglionated nerves to it and the chyle stomach, also on each
side to the salivary glands, terminating in ganglionated plexuses
in the wall of the gland. A dorsoventral section of the ganglion,
(fig. 5), shows an early stage in the development of the tumor.
There is an increased number of cells as compared with the num-
ber of cells present in the ganglion of normal larvae. There is
also an increase in the amount of pigment. Figure 9 shows a
later stage in development, where the cells have become compact
with pigment.

Very often, when the proventriculus ganglion becomes affected,
the cells of the salivary glands become loaded with pigment, as
shown in figure 7. Sometimes only one gland becomes affected
(as shown in fig. 5, Jour. Canc. Res.), where the left gland is en-
tirely permeated by pigment and the entire gland seems hard
and, in places, very much shriveled. In the Jour. Canc. Res.,
July, 1918, figure 2 shows the ends of the two glands affected.

In the anterior end of the salivary glands are the imaginal
cells of the adult salivary glands. These cells have also been
found affected as have the imaginal cells of the proventriculus
and also those of the chyle stomach. The oesophageal ganglion
has in two cases been found increased in size and abnormally
loaded with pigment, and in these cases the infection has spread
to the imaginal cells of the oesophagus.

The tumor found so often in the posterior end of the Jarva
takes its origin in a group of embryonic cells closely associated
with the nerve cells of the pericardial plexus, found on the
margin of the pericardial septum. The nerve cells are large,
bipolar cells with large vesicular nuclei and distinct nuclei.
They are loaded with brown granular pigment in the normal
larvae. Figure 8 shows the initial stage in the production of
pigment in a group of cells underneath the pericardial septum.
Figure 6 shows a great increase in the number of cells and a
tendency to push the pigment cells toward the periphery. Fig-
ure 1 from the report in the Jour. Canc. Res., July, 1918, is a
section of a matured tumor developed in this region.

520 MARY B. STARK

In the spring of 1916 an interesting mutation arose in the
form of a pigmented bar on the ventral surface of the last ab-
dominal segment of some of the larvae with tumors, as shown in
figure 10. Microscopic examination of a cross-section through
the bar revealed the fact that the ,Pigment was deposited in the
large hypodermal cells of this segment, as shown in figure 11.
The bar was always perfectly shaped, as shown in figure 10, and
appeared only in larvae with tumors (fig. 12). An attempt
has been made to separate this mutation from the stock, but
this attempt has as yet not been successful.

The tumor wherever developed is characterized by the pres-
ence of pigment, which increases excessively in amount with the
proliferation of the tumor cells. Pigment is normally present in
ganglion cells of the fly larva and, since the tumor usually de-
velops in cells closely associated with pigmented ganglion cells,
it may be possible that the pigment is derived from the ganglion
cells. The excessive production of pigment is probably due to
imperfect metabolism. Adami says: “It may well be that the
extraordinary deposit of melanin in melanotic tumors, far from
being a progressive acquirement, indicates a deficiency in the
disintegrative mechanism of the cell, whereby the normal, final
stage of colorless chromogen formation or of protein disintegra-
tion is not reached.’”’ May not the imperfect metabolism which
is the cause of the excessive production of pigment also be the
chemical stimulant productive of abnormal cell proliferation?

METASTASES

Mention has already been made of the presence of more than
one tumor in a larva. As many as fifteen have been observed in
‘some larvae. Most of these tumors were very small, however.
The smallest tumors are often found lodged within the dorsal
aorta. It may be that cells from the primary tumor have been
carried by the blood into the dorsal aorta where they develop
into secondary tumors or metastases. In a number of larvae,
tumors have been observed in all the regions described above
at the same time. In other larvae, the large primary tumor may

AN HEREDITARY TUMOR 521

be one of these regions and the smaller tumors are merely sec-
ondary tumors developed from cells derived from the primary
tumor and carried by the blood to another region of the body.

The so-called secondary tumors are made up of cells similar
in character to thore of the primary tumor. When the primary
tumor is large and irregular in shape, portions of it can easily be
broken off by pressing and manipulating the tumor in the body
cavity and can be pushed through the body cavity, away from
the large tumor. Metastases, thus artificially produced, have,
after an interval of a day or two, shown increase in size. It is
not improbable that the metastases are normally formed by
pressure against the tumor as the larva bores through the food
and thus breaks away small portions of the tumor which are
carried by the blood to other regions of the body for lodgment
and further development.

Irregularities in the mitotic figures of rapidly growing tumors
have been noted. Investigation of these is being continued
and a report on them will be reserved for another paper.

SUMMARY

1. Cell suspension from an hereditary tumor in the fly Dro-
sophila was injected into adult flies. Abnormal growths oc-
curred in some of the flies and caused their death.

2. Tumors were kept alive and showed further development in
hanging drops of Locke’s solution.

3. Tumor-cell suspension was injected into meal worms, but
the resistance of some of them was too great to allow the de-
velopment of many tumors. Only a small percentage died and
only two of these had tumors visible to the naked eye.

4. All ordinary laboratory media were inoculated with tumor-
cell suspension and incubated under aerobic and anaerobic con-
ditions. No growths occurred.

5. The flies were bred on sterile media under absolutely
sterile conditions, but the tumor continued to develop as before
and is evidently not due to a microorganism.

6. The tumor develéps in embryonic rudiments, destined to
develop the adult organs during the pupa stage.

=~

522 F MARY B. STARK

7. Development of tumor is initiated by excessive production
of melanin.

8. Melanin occurs normally in ganglion cells, and these cells
are related to some of the embryonic rudiments by ganglionated
fibres.

9. Metastases occur normally in many of the larvae with
tumors. .

10. A mutation occurred in certain flies of such a kind that
pigment appeared in the hypodermal cells of the ventral surface
of the last segment forming a pigmented bar. It occurred only
in larvae that had tumors. So far the character has not been
separated from,the stock with hereditary tumor.

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PLATES

523

THE JOURNAL OF EXPERIMENTAL ZOOLOGY; VOL. 27 »NO. 4

ee) | oe

PLATE 1
EXPLANATION OF FIGURES

All figures were drawn with the aid of a camera lucida, using a 4 mm. objective
and ocular no. 4 with tube length of 165 mm. except figure 9 for which ocular
no. 6 was used.

1 A section through the center of a tumor developed in a fly after inoculation
with tumor-cell suspension.

2 A section through the center of a tumor developed in a meal worm after
inoculation with tumor-cell suspension.

3 A section through the dorsal imaginal rudiments showing tumor develop-
ing in the two anterior rudiments.

4 Same, with the tumor fully developed in posterior rudiment.

—_— =.

1

PLATE

TUMOR
K

AN HEREDITARY

TAR

Ss

MARY B.

25

3

PLATE 2
EXPLANATION OF FIGURES

5 Anearly stage in the development of a tumor in the proventriculus ganglion
located between the brain and the proventriculus.

6 An early stage in the development of the abdominal tumor showing
increase in the number of cells and a tendency to push the pigment cells toward
the periphery.

7 Cells of the salivary glands loaded with pigment.

8 Initial stage in the production of pigment in a group of cells underneath
the pericardial septum.

526

PLATE 2

MOR

AN HEREDITARY TU

STARK

MARY B.

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PLATE 3 — to
EXPLANATION OF FIGURES re ee

9 A natural tumor in proventriculus ganglion.
10 Pigmented bar on the ventral surface of the last abdominal see
larva with a tumor.
11 Section through same, showing pigment in hypodermal cells.
12 Same, showing relation to the other tissues and the tumor.

os

‘528

HEREDITARY TUMOR
MARY B. STARK

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PLATE 3

INDEX

BBOTT, Cuartes Hartan. Reactions

of land isopods to light.......----.----- 1
Acclimatization as a factor affecting the upper
thermal death points of organisms......- 42

Adrenin on the pigment migration in the
melanophores of the skin and in the pig-
ment cells of the retina of the frog. The

GATOR OL ae ee se ete oe sen or asetalare eheregetetratatot 391
Anabiosis of the earthworm....-- Sbbeeeacssse 57
Association and color discrimination in mud-

minnows and sticklebacks.....-...----+-+- 443

Assortive mating in a nudibranch Chromo-
doris zebra Heilprin.........--+-++-+++++: 24

IGNEY, Anprew Jonnson. The effect of

B adrenin on the pigment migration in the

melanophores of the skin and in the pig-
ment cells of the retina of the frog.....-.-- 391

ALKINS, Gary N. Uroleptus mobilis,
Engelm. I. History of the nuclei dur-

ing division and conjugation.........-. 293
Cells of the retina of the frog. The effect of
adrenin on the pigment migration in the
melanophores of the skin and in the pig-

i GID, Son BES Boo ge eee eamoponone eouE 391
Character and selection. Fluctuations in a

recessive Mendelian......:...------++++--- 57
Chromodoris zebra Heilprin. Assortive mat-

ing in a nudibranch...........----------- 247

Cottrxs, H. H. Studies of normal moult
and of artificially induced regeneration of

pelage in Peromyscus........- Rocheoo70ASE 73
Color discrimination in mudminnows and
sticklebacks. Association and............ 443

Comparison of the thyroid glands of iodin-fed
and normal frog larvee. Studies on the
relation of iodin to the thyroid. II...... 417

Conjugation. Uroleptus mobilis, Engelm.

I. History of the nuclei during division
ERT eee, oe ales ae choteia piers einrate nctnyatess 293

Corneal epithelium. Demonstration of epi-
thelial movement by the use of vital
staining, with observations on phagocy-

TOsis dab ener eee eet Seagcorucbone sen OM
Crozier, W. J. Assortive matinginanudi- _
braneh Chromodoris zebra Heilprin..... 247

——. On the use of the foot in some mollusks 359

EATH points of organisms. Acclimati-
Dp zation as a factor affecting the upper
HELIN Alpes ate rere cick eis ace eacetwiars Heleiesels 427
Development in mice. Observations on the
relation between suckling and the rate of

_ embryonic..........-. Cun ne pe pode Gennes 49
Discrimination in mudminnows and stickle-
backs. Association and color............. 443

Division and conjugation. Uroleptus mo-
bilis, Engelm. I. History of the nuclei
aiid ta nen SUES BE OrnaR ba HCA OD SURE 293

Dyes), and to excretory toxins. The reac-
tion of Selachii to injections of various
non-toxic solutions and suspensions (in-
CGlatcaxipremitial te tacte ts seta acitesesten ttc seistegs 101

I
a

1 ee aoe Anabiosis of the.........

Embryonic development in mice. Obser-
vations on the relation between suckling
ANG CHEALO ORNs cloaca chen ciate ielnlstelaietsia 49

Engelm. I. History of the nuclei during
division and conjugation. Uroleptus
TAINS eee ee aon 0 cas HEAT SUS alaceva noel y 293

Epithelial movement by the use of vital
staining, with observations on phagocyto-
sis in the corneal epithelium. Demon-
SULAMIOUOsneaa ede creme ats hle simmers aie’ ® syotele 37

Excretory toxins. The reaction of Selachii to
injections to various non-toxic solutions
and suspensions (including vital dyes),

Fir G GU eee BBO AR Oe Uno ne abou ras 101
LUCTUATIONS in a recessive Mende-

lian character and selection............- 157

Foot in some mollusks. On the use of the... 359

Frog larve. Studies on the relation of iodin
to the thyroid. II. Comparison of the
thyroid glands of iodin-fed and normal.. 417
——. The effect of adrenin on the pigment
migration in the melanophores of the
skin and in the pigment cells of the
MELA Ol UnGs- ec cee sce se cleo sta ote 391

LANDS of iodin-fed and normal frog
larvae. Studies on the relation of iodin
to the thyroid. II. Comparison of the
{HOR ANOG bone nctip sooAseogdodo odie. SU BDUCOARMBE 417

| oes igre, eNeacoaoatooneoe 507

Hoskins, E. R., anp Hoskins, M. M. The
reaction of Selachii to injections of vari-
ous non-toxic solutions and suspensions
(including vital dyes), and to excretory
TOKAI hire eee ie cei iay see ee tenets 101

——, M. M., Hosxins, E. R., anp. The re-
action of Selachii to injections of various
non-toxic solutions and suspensions (in-
eluding vital dyes), and to excretory
BORATIS 5 ein Wa cites ae eioeue tat tara petite 101

| ieee nes Ill. The effects of in-
breeding, with selection, on the sex ratio o
the albinorat. Studies on.............! 1
Injections of various non-toxie solutions and
suspensions (including vital dyes), and to
excretory toxins. The reaction of Selachii

to
Iodin-fed and normal frog larvae. Studies
on the relation of iodin to the thyroid.
Il. Comparison of the thyroid glands of. 417
—tothe thyroid. I. The effects of feeding
iodin to normal and thyroidectomized
tadpoles. Studies on the relation of..... 397
—— to the thyroid. II. Comparison of the
thyroid glands of iodin-fed and normal
frog larvae. Studies on the relation of.. 417
Isopods to light. Reactions of land......... 193

ACOBS, M. H. Acclimatization as a fac-
tor affecting the upper thermal death
points Of OLZANISMS:.:-... 2. ss -8---=-- 427

Ke Heten Dean. Studies on in-
breeding. III. The effects of inbreed-
ing, with selection, on the sex ratio of

theral Pino rates tates toe eieleiess s,sh ore 1
KirkKHam, Witti1AM B. Observations on the

relation between suckling and the rate of

embryonic development in mice......... 49

ARVAE. Studies on the relation of iodin
to the thyroid. II. Comparison of the
thyroid glands of iodin-fed and normal
FOG L. scale tinetee eee gare alate erelelofe a a. atmo 417
Light in the colonial forms, Volvox glabator
and Pandorina morum. Reversion in the
sense of orientation to..............-++--- 367
——. Reactions of land isopods to.......... 193

AST, S. O. Reversion in the sense of
orientation to light in the colonial
forms, Volvox globator and Pandorina

morum....... ns fase aril ne enees Pisin ssi 367
Mating in a nudibranch Chromodoris zebra
Heilprin. Assortive...........-.+++ss++-- 247

ne

532

Martscemoro, SuHinicur. Demonstration of
epithelial movement by the use of vital
staining, with observations on phagocyto-
sis in the corneal epithelium..............

Melanophores of the skin and in the pigment
cells of the retina of the frog. The effect
pe adrenin on the pigment migration in
UO 295 sa teje satay tera oeic alguns ats isla sie ae eleiste cies f

Mendelian character and selection. Fluctua-
tionsjN' a MECESSIVEW .e yee seu ek cae aoe as

Mice. Observations on the relation between
suckling and the rate of embryonic devel-

GPMEM Trane tees a iaes oe Pree teatcceentin celeto 49
Migration in the melanophores of the skin and
in the pigment cells of the retina of the
frog. The effect of adrenin on the pig-
HAVA ML eae Someta aey Oe hs Dee eee ise 391
Mobilis, Engelm. I. History of the nuclei
during division and conjugation. Uro-
WOW GUS screertcra tices: Merete ete ciaee aera etter 293
Mollusks. On the use of the foot insome.... 359
Moult and of artificially induced regenera-
tion of pelage in Peromyscus. Studies of
MOTI Hotes Plan kee ti che ek a ape Oe 73
Mudminnows and sticklebacks. Association
and color discrimination in............... 443
UCLEI during division and conjugation.
Uroleptus mobilis, Engelm. I. History
Ofsthes acest ce seers nee Re aan 293
Nudibranch Chromodoris zebra Heilprin.
Assortiveimating ina... 2 2ge.ct «de ehes eae 247
RGANISMS. Acclimatization as a factor
affecting the upper thermal death
DOMUS TOM eenc herp eae ee eee se ee 427
Organization of Renilla. The.........:...... 499

Orientation to light in the colonial forms.
Volvox globator and Pandorina morum.
Reversion in the sense of................ 3

ANDORINA morum. Reversion in the
sense of orientation to light in the
colonial forms, Volvox globator and.... 367

Parker, G. H. The organization of Renilla. 499
Pelage in Peromyscus. Studies of normal
moult and of artificially induced regen-
erahionuOls.ey-tiecs ache a ea ee ee
Peromyscus. Studies of normal moult and
of artificially induced regeneration of
Delage Ms ase os eee eee
Phagocytosis in the corneal epithelium.

Demonstration of epithelial movement by

the use of vital staining, with observa-

TLONIS(OW yet Acc erie omic REL eee

Pigment migration in the melanophores of the
skin and in the pigment cells of the retina
of the frog. The effect of adrenin on the.

AT. Studies on inbreeding. III. The
effects of inbreeding, with selection, on _

73

non-toxic solutions and suspensions (in-
cluding vital dyes), and to exeretory tox-
ins. The

Relation of iodin to the thyroid. I. The ef-
fects of feeding iodin to normal and thy-
roidectomized tadpoles. Studies on the.

II. Comparison of the thyroid glands
of iodin-fed and normal frog larvae.

RMGUIES ODS NEN reas cee «cose Settee 4

Renilla. The organization of.................

Retina of the frog. The effect of adrenin
on the pigment migration in the melano-
phores of the skin and in the pigment
Ul OSs, Gan sae ROS ae aoe nee eee ae

Reversion in the sense of orientation to light
in the colonial forms, Volvox globator and
HAMNGOUINEG IOOLUM 6c .scsedeccecckewhaees 367

391

INDEX

/

Roserts, Ermer. Fluctuations in a reces-

sive Mendelian character and selection...
CHMIDT, Peter. Anabiosis of the earth-
WOT). . isan seioca: One oe Ee eee

Selachii to injections of various non-toxic
solutions and suspensions (including vital
dyes), and to excretory toxins. The re-
action :Of sc5 ste. detec ooo ae

Selection. Fluctuations in a recessive Men-
delian ‘character)and) 5... bene neers

—, on the sex ratio of the albino rat.
Studies on inbreeding. III. The effects
Of inbreeding. within. eee eee

Sex ratio of the albino rat. Studies on in-
breeding. III. The effects of inbreeding,
with selection, onsther: +... - eae eee

Skin and in the pigment cells of the retina of
the frog. The effect of adrenin on the
pigment migration in the melanophores

Staining, with observations on phagocytosis
in the corneal’ epithelium. Demonstra-
tion of epithelial movement by the use of
ALIEN Eales OcheMa AR one Smee Eee Ooms o

Stark, Mary B. An hereditary tumor.....

Sticklebacks. Association and color dis-
crimination in mudminnows and

Suckling and the rate of embryonic develop-
ment in mice. Observations on the rela-
tionkbetiween!: 15-2353 es oe eee

Swinete, W. W. Studies on the relation of
iodin to the thyroid. I. The effects of
feeding iodin to normal and thyroidecto-

mized tadpoles: 535-6 cece sicher 3

Studies on the relation of iodin to the
thyroid. II. Comparison of the thyroid
glands of iodin-fed and normal frog
VaR VAs traci daisies Ho ke eaOkn Oe eee

i heen empress Studies on the relation of
iodin to the thyroid. I. The effects of
feeding iodin to normal and thyroidec-
tomized
Thyroid. I. The effects of feeding iodin to
normal and thyroidectomized tadpoles.
Studies on the relation of iodin to the....
II. Comparison of the thyroid glands
of iodin-fed and normal frog larvae.
Studies on the relation of iodin to the....
Thyroidectomized tadpoles. Studies on the
relation of iodin to the thyroid. I. The
effects of feeding iodin to normal and... .
Toxins. The reaction of Selachii to injec-
tions of various non-toxic solutions and
suspensions (including vital dyes), and to
(S(O 0) APSA DA OAOACEOR CIOL c oH iticie coe
Tumor: on hereditarye. scsi ete ae

ROLEPTUS mobilis, Engelm. I. His-
tory of the nuclei during division and
CONJULAtION A: Katee see eee Oe eee

ITAL dyes), and to excretory toxins.
The reaction of Selachii to injections of
various non-toxic solutions and sus-

pensions (neludiney.-es-]: ese esse eee
staining, with observations on phagocy-

tosis in the corneal epithelium. Demon-
stration of epithelial movement by the

HITE, Gerrrupe Marean. Associa-
tion and color discrimination in mud-
minnows and sticklebacks......... F

EBRA Heilprin. Assortive mating in a
nudibranch Chromodoris.............--

157

397

397

417

397

101

293

101

37

367

. 443

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