THE

NAUTILUS

A QUARTERLY JOURNAL

DEVOTED TO THE INTERESTS

OF CONCHOLOGISTS

VOL. 69
JULY, 1955 to APRIL, 1956

EDITORS AND PtJBUSHEBS

HENRY A. PILSBRY

Curator of the Department of Mollusks and Marine Invertebrates,

Academy of Natural Sciences

H. BURRINGTON BAKER

Professor of Zoology, University of Pennsylvania
Philadelphia, Pa.

lANCASTER PKESS, INC., LANCASTER, PA.

CONTENTS

Names of new genera and species in italics.

Achatina fulica 37, 142

Alderia modesta 22, 72

American Malacological Union 34, 71

Arctica islandica 53

Atlantic, western. .20, 26, 35, 47, 53, 73, 109, 115, 121, 139, 140

Arctic mollusks 139

Australia 6

Bland, Thomas 52

Bolivia 110

Bom's "Index'' and types 78

Bostryx (Platyhostryx) fisheri Pilsbry 92

California, inland 37, 100, 142

marine 22, 79

Cassididae predation 73

Cepaea nemoralis 104

Clam industry 53

Collecting data 88

Columbia 140

Conus andrangae Schwengel 14

Conus drangai Schwengel 13

Conus gradatus thaanumi Schengel 15

Conus macgintyi Pilsbry 47

Conus recurvus helenae Schwengel 15

Conus stinging 76

Crampton, Henry Edward 142

Crooke, John J 52

Cyclochittya schumoi Morrison, for Incerticyclus schermoi 72

Dates of The Nautilus 34

Davis, William T 52

Discus maeelintocki 34

Doryssa kappleri, anatomy 44

Family names in Pulmonata 128

Florida, marines 47, 73, 109, 121, 139

Geoduck, eastern 121

Georgia 69

Gonaxis 37, 142

Gracilinenia aequistriata Weyrauch 110

G. filicostulata 112

ill

iv THE NAUTILUS [Vol. 69 (4)

Gratacap, Louis P 50

Haplotrema kendeighi 126

Happia (Scolodens) 134

Hawaii and Helix aspersa 141

Hubbard, Eber W 51

Humholdtiana pergranulosa Solem 42

Hyridella australis 6

Illinois 28, 36

Iowa 34

Lottia gigantea, water circulation 79

Louisiana 124

Lysinoe sebastiana 43, 140

MegapalUfera Hubricbt, subg. of Pallif era 126

Mesodon normalis 140

Mexico 40, 93, 140

Minnesota 56

Missouri 36

Mucronalia nidorum Pilsbry 110

Nenia {Columhinia) zischkai Weyrauch 113

Neptunea decemcostata clenchi Clarke 116

N. d. turnerae 117

New York 48, 104

Nomenclature of families 128

North Carolina 126, 140

Ohio 35

Oklahoma 16

Ontario 18

Pacific, eastern 13, 22, 72, 79

western 1, 76

Pallif era fosteri 35

Pallifera, subg. MegapalUfera Hubricht 126

Panope bitruncata 121

Peru 92, 110

Polinices predation 20

Pollution of streams 96

Polygyra scintilla Pilsbry & Hubricht 94

Pomacea cumingi 140

Predatory snails 20, 37, 142

Prime, Temple 49

Pseudochama 1

Publications received 36, 107

Pulmonata, family names 128

Scolodens H. B. Baker, new name for Stenopus 134

Sea urchin spines, shells in 109

Smith, Sanderson 51

April, 1956] the nautilus v

Soil and land snails 62

Spirula spirula 35

St. Petersburg shell club 34

Stream pollution 96

Tennessee 123, 126, 128

Texas 93

Valentine collection 141

Venezuela 44

Ventridens intertextus eutropis 123

Virginia 62

Wheat, Silas C 49

INDEX TO AUTHORS

Abbott, Donald P 79

Abbott, R. Tucker 44, 141

Anonymous 88

Baker, H. Burrington 34, 128

Baily, Joshua L., Jr 100

Bureh, John B 62

Clarke, Arthur Haddleton, Jr 115

Dawley, Charlotte 56

Dexter, Ralph W 35, 141

Dundee, Dee Saunders 16

Hand, Cadet 72

Hand & Joan Steinberg 22

Hubricht, Leslie 34, 124, 126, 140

Hubricht (Pilsbry &) 93

Johnson, Malcolm C 121

Keen, A. Myra 139

Kline, George F 76

Kondo, Yoshio 141

Landman, M. Alan 104

McGinty, Thomas L 35

McMichael, Donald F 9

Mead, Albert R 37

Moore, Donald R 73

Morrison, J. P. E 72

Odhner, N. H 1

Parmalee, Paul W 28

Pemberton, C. E 142

Pilsbry, H. A 47, 92, 109, 140

Pilsbry & Leslie Hubricht 93

Russell, Henry D 53

Rutsch, R. F 78

Schwengel, Jeanne S 13

Solem, Alan 40

Steinberg, Joan (Hand &) 22

Swanker, Dr. & Mrs. W. A 18

Teskey, Margaret C 34, 69, 123

Turner, H. J., Jr 20

Weingartner, Mathilde P 48

Weyrauch, Wolfgang 110

Wurtz, Charles B 96

vi

THE NAUTILUS 69 (1)

PLATE 1

/./'//

'v ' . ^.

Odhner: On Pseuclochama.
(Exi)lanation on opposite page.)

The Nautilus

Vol. 69 JULY, 1955 No. 1

SOME NOTES ON PSEUDOCHAMA

By N. H. ODHNER

Stockholm

In 1919 I published an investigation on recent species and
genera of the Lamellibranchiate family Chamidae of which I
had in 1917 established the genus Pseudochama ^ for forms
fixed by means of the right valve in contrast to Chama, or those
fixed by their left valve. These two different genera proved to
be distinct also in their shell (as well as soft) morphology, inas-
much as the juvenile stage still persists with the different char-
acters preserved in the umbones of the adult shell. I held
in 1919 the genus Echinochama Fischer 1887 as well motived
on account of its characteristic sculpture ; else it shares the
principal features of Pseudochama, above all the umbonal
juvenile shell, which is quite different in Chama both in sculpture
and dentition in small free stages. It was stated, besides, that
a small recent form of Pseudochama, P. pusilla n.sp., offered
hinge characters primitive with regard to all other Pseudochama

1 Type by subsequent designation Chama crisiella Lamarck 1819 (cf.
Gardner 1926; Nicol 1952a,b).

Explanation of Figures, Plate I.

Fig. a-i, Pseudochama (Eopsemna) pusilla Odhner 1919
right valve of one specimen, exterior (a), interior (&), X 3.5
left valve of the same specimen, interior (c), exterior {d), X 3.5
a second specimen, left valve, interior (e), exterior (/), X 3.5
g hinge of left valve, X 7.5; /i, hinge of right valve, X 7.5; i
left valve with nepionic shell, X 20. From Odhner 1919. — j, k,
Pseudochama dra<^onis Dall 1903, hinge of left valve (i), hinge
of right valve (A:), X 6, D. Berg phot — 1, 2a, 2h etc. cardinal
teeth (Bernard's designations) ; LI, LII lateral teeth; M. mar-
ginal teeth.

2 THE NAUTILUS [Vol. 69 (1)

(incl. Echinochama), a fact which caused me to establish for
that new species a distinct subgenus Eopseuma.

Dr. D. Nicol of the U. S. National Museum has recently

(1952 and 1953) in some interesting and critical papers cor-
roborated my conclusions from 1919 and pointed out that the
genus Echinochama is to be derived from the earlier existing
P. draconis Dall 1903, a species that I had in 1919 already re-
ferred, from the original description by Dall, to Pseudochama.
Nicol now (1952) states, on material studied by him, that P.
draconis may be in reality the probable ancestor of the genus
Echinochama.

This statement induced me to a supposition that P. draconis
would perhaps also prove to belong in the subgenus Eopseuina
and to be closely related to the recent P. pusilla. My request
for material of P. draconis for examination was most kindly
answered by Dr. Nicol, who sent, together with his publications
on Chamidae, some valves of that species against other material
for exchange. Unfortunately, however, there is insufficient
material in the Swedish Riksmuseum for exchanging cotypes of
P. pusilla in return.

A comparison with the valves of the latter species in Riks-
museum (from Macassar Strait) and the received P. draconis
at once proved a close agreement in the hinge characteristics.
I give here two figures (j and k) showing the tooth elements of
P. draconis for comparison with those of P. pusilla reproduced
from my work of 1919 with a common designation of the par-
ticulars. A still persisting bipartition of the right cardinal
teeth (1 -f 3b) is clearly seen, and this character is stated by
me in 1919 (p. 75) as the chief significance of Eopseuma in con-
tradistinction to Echinochama and other Pseudochama species;
in Echinochama a separation of these teeth is scarcely \dsible
and, besides, the shell has become almost equivalve, which seems
to be a secondarily acquisition (Odhner 1919, p. 93; Nicol 1952c,
p. 804). In the second place the sculpture of the nepionic shell
should be decisive according to my table of classification (1919,
p. 75).

If now the dentition of P. (E.) pusilla is compared with that
of P. draconis, reproduced in figs. j. k., we find a great similarity
inasmuch as both parts of the right cardinal (1 + 3b) are still

July, 1955] THE NAUTILUS 3

distinct and well separated by a transverse deep furrow, and
also other elements of the hinge of P. pusilla can be recognized
(cf. figs, g, h). But they are more differentiated and altered
by additional details than in P. pusilla, thus already on the way
towards an Echinochama stage, where the original elements are
difficult to discern.

It is true, as mentioned, that some agreement of the dentition
exists between P. draconis and pusilla, but with regard to the
nepionic shell structure, a still stronger resemblance is extant
between P. draconis and Echinochama, as Nicol has already re-
marked. This similarity quite justifies Nicol's opinion that
P. draconis ''is the probable ancestor of Echinochama' ' (Nicol
1952c, p. 815). In P. draconis the nepionic shell is strikingly
larger than in P. pusilla and sharper marked off in its sculpture
from the remaining shell surface. It measures 1.5 mm in length
and resembles that of Echinochama arcinella figured by me
(1919, pi. 1, fig. 5), but the latter or properly nealogic one is
still larger (1. about 2.4 mm, Odhner, I.e., p. 75, 93) and fur-
nished with 6-7 concentric lamellae (Odhner, I.e., pi. 1, figs.
5, 6; p. 93), whereas in P. draconis there are only 5-6. This
difference implies a specific distinction which may certainly be
apt for separating other different species of Pseudochama too
(cf. figures in Odhner 1919, pi. 1 ; p. 93).

In P. pusilla, on the contrary (cf. fig. i — pi. 2, fig. 21 of
Odhner 1919), the nepionic shell is ''rounded square with a few
distant concentric threads and traces of some radiating posterior
riblets" (I.e., p. 24). The length of the nepionic shell proves to
be 1.2 mm, the number of concentric threads is 5-6 on half the
valve and as many on its posterior half, where the raised
lamellae (or threads) are broken into radiating rows of scales.
The latter feature is a peculiarity distinguishing P. pusilla
from both P. draconis and Echinochama. It also unequivocally
shows that P. pusilla is essentially distinct from P. draconis,
which, as mentioned, has only concentric sculpture and lacks
every trace of radial sculpture in its nepionic shell, which be-
sides, is more sharply limited off from the disk of the valve than
in P. pusilla.

These comparisons in sculpture and dentition give the im-
pression that there is less agreement in the former and more in

4 THE NAUTILUS [Vol. 69 (1)

the latter respect, and that the agreement in the dentition may
imply common stages of the development passed by both sections
(Pseudochama and Echinochama), whereas the shell sculpture
is a quality more independently acquired. The increasing size
and lamellae of the nepionic shell, if Eopseuma and Echino-
chama are compared, also give support to the supposition ex-
pressed by me in 1919 (p. 92) : ''This nepionic stage interjacent
between the prodissoconch and the permanent stage, is to be
considered as a juvenile specialization or a caenogenetical larval
stage, which has arisen through a development produced some-
what beyond the direct line of evolution."

When describing P. pusilla in 1919 from the Macassar Strait,
I supposed that a second find of this species had been made by
the Siboga Expedition and was represented in a small shell from
its St. 79^ and figured by Pelseneer (1911 on pi. XXI, fig. 7).
This specimen seems namely to have been fixed by its right valve
and to be as large as P. pusilla and sexually mature. In order
to subject this specimen to a direct examination, I asked to
borrow it from Holland, and Mrs. W. S. S. van der Feen most
obligingly sent it. The specimen has a complete left valve 7.5
mm in length, and a right one, defective but evidently the
moiety. Their colour is a vivid rose, deeper in the interior,
paler at the margins, and both colour and sculpture completely
agree with those of the typical specimens, just as do also the
teeth of the left valve. Without this direct comparison, the
identity could probably not have been ascertained,^ because
the Siboga specimen has its left valve umbo covered with a
colony of the rosy Polytrema miniaceum (Pallas), a Foraminifer,
which entirely hides the nepionic shell. In the right valve, the
upper portion with the hinge is broken off together with the
substratum of the mussel. Thus it has now been stated that this
species occurs also on the Siboga Station mentioned (the
Borneo Bank), not far from the type locality, or exactly 2°38'.5S,
117° 46' E, 54 m, coral-sand.

Pseudochama draconis has a peculiar shell sculpture consisting
of dense knots all over the valves but rising, towards the mar-
gins, to waved lamellae. Some variation seems to exist; the

2 Prashad (1932, p. 298) reported this specimen from St. 79a among
' * young shells apparently belonging to several species of the genus Chama. ' '

July, 1955] THE NAUTILUS 5

figure 3, pi. 119, in Nicol 1952c, shows a more separate arrange-
ment and pustulate shape of the knobs, whereas in fig. 5 in the
same plate they appear more in series and of a half open tubular
shape, similar to those of P. pusilla. It may be supposed that
this agreement implies a development from scales like those of
Eopseuma and that this mode of progression, thus, is also the
case with the sculpture of Echinochama.

In the genus Chama there are also differences in the sculpture
of the nepionic shell, but the latter is less distinctly marked off
from the valve than in Pseudochama; its sculpture passes, as in
Eopseuma, more continuously into that of the valve disc. This
difference is the more striking if we compare some of the fossil
forms, e.g. Chama lamellosa Lamarck or Ch. papyracea Deshayes,
both from the Eocene in France, with recent species (e.g. Ch.
gryphoides). In Ch. lamellosa the nepionic shell grows to
about 0.6 mm until it forms its first concentric lamella, and all
the sequent lamellae pass gradually into the spinose undulating
marginal ones. In recent species {Ch. gryphoides e.g.) the
nepionic shell of 0.4 mm 1. is microscopically striated radially
before the concentric and scaly sculpture of the adult shell be-
gins. It seems possible to base a classification also of the species
of the genus Chama on the different shape of the embryonic
shell stages, but presently this possibility can only be remarked
as a problem for future research.

References

Gardner, Julia, The Moll. Fauna of the Alum Bluff group of
Florida, II. U. S. Geol. Surv. Prof. Pap. 142 B, 1926.

Nicol, D., Nomenclatorial review of genera and subgenera of
Chamidae. Journ. Washington Acad, of Sci. 42: 5, May 15,
1952a.

, Designation of the type species of Pseudochama (addi-
tional note) . Journ. Washington Acad, of Sci. 42 : 8, Aug. 15,
1952b.

Revision of the Pelecypod Genus Echinochama. Journ. of

Paleontology 26: 5, Sept. 1952c.
Odhner, N. H., Results of Dr. E. Mjobergs Swed. Sci. Exp. to

Australia 1910-13. XVI Mollusca. K. Sv. Vet. Akad. Handl.

52: 16, 1917.
, Studies on the Morphology, Taxonomy and Relations of

Recent Chamidae. Ibid. 59 : 3, 1919.

6 THE NAUTILUS [Vol. 69 (1)

Pelseneer, p., Les Lamellibranches de 1 'expedition du Siboga.

Monogr. 53 a, 1911.
Prashad, B., The Lamellibranchia of the Siboga Expedition,

Syst. Part. II. Monogr. 53 c, 1932.

THE IDENTITY AND VALIDITY OF HYRIDELLA
AUSTRALIS (LAMARCK) 1819

By DONALD F. McMICHAEL

The Australian Museum, Sydney *

Lamarck (1819) described two species of freshwater mussels,
Unio australis and TJnio depressa, from Australia. The descrip-
tions were brief, without figures, and the only locality given was
New Holland. Unio depressa was figured by Delessert (1841)
and there is no doubt as to its identity, although the species was
known for many years as Unio paramattensis Lea (1862) which
is an absolute synonym of Unio depressa Lamarck. It is a
species widely distributed along the east coast of Australia, and
occurring in streams near Sydney, New South Wales, where
specimens could have been collected at the time Lamarck
described the species.

Unio australis was figured by Hanley (1843) but the figure
was very small and of little use in identification, and Lamarck's
description was repeated with it. Philippi (1847) also figured
and described this species, giving the dimensions of his specimen
and a full description. Possibly both these authors had studied
Lamarck's types, but despite Philippi 's account, its identity
remained uncertain. No further attempt has been made since
that time to determine this species exactly by examination of
Lamarck's types as far as I know.

The freshwater mussels of Australia were reviewed by Iredale
(1934; 1943) who divided them into four subfamilies, of which
two included most of the Australian species. These are the
subfamilies Velesunioninae and Propehyridellinae. The validity
and systematic position of these subfamilies need not be con-
sidered here, but the two groups serve to differentiate the

* By Permission of the Trustees.

July, 1955] THE NAUTILUS 7

Australian mussels on several characters. The Velesunioninae
all lack beak sculpture, and the subfamily includes the genus
Velesunio Iredale which possesses simple lamellar cardinal
teeth. The Propehyridellinae includes several genera in which
the beaks are sculptured with radial ridges, and the genus
Propehyridella Cotton and Gabriel possesses relatively complex,
grooved, erect cardinal teeth.

Simpson (1900) determined a species of Velesunio as Unio
australis Lamarck, and since that time the name has been ap-
plied more or less indiscriminately to species of this genus: see
Simpson (1914), Haas (1924), Cotton and Gabriel (1932), for
example. At no time after Simpson's account, till 1934, was
the name Unio australis associated with a member of the
Propehyridellinae .

Iredale (1934) noted the difficulties of accurately determining
this species, and logically assumed that it was likely to be a
species occurring near Sydney with Unio depressa Lamarck. A
species of Velesunio does occur there, but it is not found in
association with depressa. Two species of Propehyridellinae do
occur in association with depressa however, Propehyridella
nepeanensis (Conrad), a long-standing species, and another
species which had not previously been recognised as distinct
from nepeanensis and had not been described under any other
name. This species resembled Philippics figure, and Iredale
selected it as probably being australis. Iredale named several
subspecies of this form, including australis drapeta from North-
ern New South Wales and South Queensland. At first he
placed this species in a new genus Hyridunio, in the subfamily
Velesunioninae, but later (1943) transferred Hyridunio to the
Propehyridellinae, as specimens with uncorroded beaks showed
the characteristic beak sculpture.

During the course of research on the Australian freshwater
mussels it became necessary to determine this species definitely,
and M. Andre Franc, Curator of Mollusks, Museum National
d'Histoire Naturelle, Paris, kindly supplied photographs of
Lamarck's two specimens, with detailed descriptions. This in-
formation indicated that the types of Uriio australis were
identical with the species known for many years as Unio
nepeanensis Conrad (1850), the type species of Propehyridella,

8 THE NAUTILUS [Vol. 69 (1)

mentioned above as also occurring with TJnio depressa Lamarck.
M. Franc has compared two specimens of nepeanensis with
Lamarck's types and finds that they are the same species. He
wrote as follows: ''The two smaller valves are absolutely com-
parable to Lamarck's larger specimen. . . . But there are less
differences between your two smaller valves and Lamarck's
larger two, than between the two specimens of Lamarck. ... I
think that one could affirm the identity of the two forms ; it is in
any case, what I would do if I had to decide this question."
This difference in Lamarck's specimens might indicate that two
species are represented in the type lot, but the photographs
reveal only the normal differences between young and adult
specimens of nepeanensis. The only measurement given by
Lamarck was the length of the larger specimen, so that this
should be considered the lectotype and is here selected as such.
Thus TJnio nepeanensis Conrad 1850 must be placed in the
synonymy of Unio australis Lamarck 1819. The species selected
by Iredale must therefore take the next available name, and
becomes Hyridunio drapeta Iredale 1934.

The correct allocation of this specific name would be no great
problem in nomenclature if it were not for the fact that the
three specific names, australis Lamarck, nepeanensis Conrad,
and '^australis" drapeta Iredale, have all been designated as the
type species of different genera.

Swainson (1840) named Unio australis Lamarck as type
species of his genus Hyridella. For many years the name has
been listed as Hyridella australis (Lamarck). Cotton and
Gabriel (1932) still confusing australis with a species of
Yelesunio, named TJnio nepeanensis Conrad as type species of
their genus Propehyridella. Iredale (1934) pointed out that
Swainson 's description of the generic characters of Hyridella
based on his ^' TJnio australis Lamarck" could not apply to any
Australian species, and it seemed likely that Swainson had mis-
identified his type species. Iredale did not attempt to deter-
mine which species Swainson really had, but proceeded to reject
Hyridella for any Australian group. The validity of this
procedure will be discussed below. Meanwhile, for the species
he thought to be australis, Iredale gave the new generic name
Hyridunio, and in case he later proved to be mistaken in his

July, 1955] THE NAUTILUS 9

determination of australis, he designated the subspecies drapeta
Iredale as the type species of Hyridunio, in order that the latter
name would be associated with the species ** drapeta" and not
simply with the name australis.

Before discussing further the validity of the names involved
in this problem, some comments on the genera and species
themselves are necessary. There remain only two species in-
volved, Unio australis Lamarck (= Unio nepeanensis Conrad)
and Hyridunio drapeta Iredale, both valid specific names and
distinct species. Three generic names are involved, Propehy-
ridella and Hyridella, each with Unio australis Lamarck, or a
synonym as the designated type species, and Hyridunio with
drapeta Iredale as type species. I consider that there are no
valid grounds for maintaining the generic distinction between
these two species, so that Hyridunio Iredale must be considered
a synonym of one or both of the other names. The problem
which remains to be decided is, which of the available generic
names, Hyridella or Propehyridella, should be used for australis
Lamarck.

The genus Propehyridella presents no nomenclatural problem.
It was validly proposed, with a junior synonym of Unio
australis Lamarck as type species, and that species was cor-
rectly identified as Unio nepeanensis Conrad. It has been used
quite consistently since 1932 for the group which now proves
to include australis Lamarck, but has never been used for
''australis" of most authors, i.e. Velesunio sp. Two New
Zealand species at least belong in this genus, but Propehyridella
has never been used by New Zealand authors.

The genus Hyridella Swainson however, as Iredale (1934)
pointed out, was probably based on a misidentified species.
The generic characters given by Swainson were presumably
based on his ''Unio australis Lamarck" since the genus is
monotypic. These characters included, among others, "bosses
not sulcated; a posterior margin elevated and winged; one
cardinal and one lateral tooth in each valve" and Swainson
wrote that "the whole shell has very much the aspect of an
Anodon. " None of these characters describes Unio australis
Lamarck. Only one Australian species approaches this descrip-
tion, Unio wilsonii Lea 1859, from Central and north Western

10 THE NAUTILUS [Vol. 69 (1)

Australia, and Swainson may well have had that species be-
fore him. However, TJ. wilsonii Lea belongs with the Velesu-
nioninae, and in any case there is no way of proving just which
species Swainson had, since his material is presumably no
longer extant. As Iredale (1934) pointed out, quite possibly
Swainson did not have an Australian shell before him.

The correct procedure in handling cases of apparently mis-
identified type species of genera has been the subject of two
opinions of the International Commission on Zoological Nomen-
clature (Opinions 65 and 168) and was further deliberated upon
at the Paris meetings in 1948. The conclusions of the Inter-
national Commission are set out in the Bulletin of Zoological
Nomenclature, 4: 159. If there are grounds for believing that
the type species was misidentified, it is recommended that the
case be referred to the Commission, whereupon three possible
courses of action might be taken. If the species intended as
type species by the author can be identified, the Commission
could designate that species to be the type species. If the in-
tended species is doubtful, then a species could be designated as
type species in conformity with current usage. However, if
either of these actions would cause more confusion than uni-
formity, then the Commission could direct that the nominal
species cited by the author of the generic name be accepted as
type species.

In the present case, Swainson 's material is not available, so
that it is impossible to identify his intended type species. Even
if this were possible, action by the Commission designating the
intended species as type of the genus might not be advisable,
since the well known name Hyridella might be removed from
the Australian fauna, and might cause the displacement of some
other well established generic name elsewhere. None the less,
it is clearly laid down in principle by the discussion and con-
clusions of the Commission that credit should be given if pos-
sible to the author of a genus for the group which he intended
to recognise, and not to some other group simply because of an
error in identification.

The possibility of designating a type species in conformity
with current usage must be considered. Unfortunately this
cannot be done without confusion, since there is no agreement

July, 1955] THE NAUTILUS 11

on the usage of Hyridella. For example, current usage in
Australia places Hyridella with the Velesunioninae as a senior
synonym of Velesunio, since most Australian workers do not
follow Iredale, and still refer to Velesunio amhiguus (Philippi)
as Hyridella australis. To satisfy them, the Commission would
have to designate Vnio amhiguus Philippi as type species of
Hyridella. However, New Zealand workers, including the latest
reviewer, Dell (1953), refer their species to Hyridella, and
none of these belong to the Velesunioninae. To satisfy their
current usage, a Propehyridelline species, such as true Vnio
australis Lamarck would be the most acceptable type species.

It seems quite clear that the application of either of the first
two possible Commission rulings would lead to greater confusion
than uniformity. Hence the third possibility is the only logical
course of action, that is, to ignore Swainson's obvious error,
and to redefine the genus in terms of Vnio australis Lamarck as
here determined. This course is chosen for two principal rea-
sons ; first because Hyridella is associated throughout the world
with the Australian freshwater mussel fauna, and particularly
with the name australis Lamarck. Secondly, because this will
preserve the name Hyridella for the New Zealand species. It
is not proposed to take this problem to the International Com-
mission, since for the reasons outlined above, it is unlikely that
the Commission would follow any other course of action than
that adopted here.

The subfamily name will have to be changed to Hyridellinae
Iredale 1934, and the genus Propehyridella Cotton and Gabriel
1932 must be ranked as a junior synonym of Hyridella Swain-
son 1840. The generic characters of Hyridella will be those
listed by Cotton and Gabriel in their original definition of
Propehyridella, and not necessarily those of any previous
author, including Swainson. The generic characters of Hy-
ridella as given by Cotton and Gabriel (1932) must be dis-
carded, and the group known under this name by them will
take the name Velesunio Iredale 1934 with generic characters
as defined by Iredale (1934). The type species of Velesunio
Iredale is Vnio halonnensis Conrad 1850, which is a junior
synonym of V^iio amhiguus Philippi 1847. This systematic ar-
rangement is tabulated below:

12 THE NAUTILUS [Vol. 69 (1)

Subfamily Velesunioninae Iredale 1934

Genus Velesunio Iredale 1934 {— Hyridella of Cotton and
Gabriel 1932) non Hyridella Swainson 1840. Type species
= Unio ambignus Philippi 1847 (= TJ. Balonnensis Conrad
1850)

Subfamily Hyridellinae Iredale 1934

Genus Hyridella Swainson 1840 (emended) {= Propehyridella
Cotton and Gabriel 1932). Type species = Z7mo australis
Lamarck 1819 (= Unio nepeanensis Conrad 1850)

Species included in Hyridella: H. australis (Lamarck); H.
drapeta (Iredale) 1934; H. menziesi (Gray) 1843, and other
New Zealand species.

The main purpose of this paper has been to reveal the true
identity of Unio australis Lamarck 1819, and to bring to light
the facts concerning the genus Hyridella Swainson. It is hoped
that other workers will agree with the course of procedure sug-
gested here, and that the changes in collections made necessary
by the displacement of the name Hyridella from the usually
accepted group will be outweighed by the advantages of pre-
serving this name for the Australian and New Zealand faunas.

Acknowledgments: I wish to thank sincerely the following
persons for their help and cooperation in the completion of this
paper: M. A. Franc, Museum National d'Histoire Naturelle,
Paris, for photographs and descriptions of Lamarck's types;
Mr. T. Iredale for information concerning his previous research;
Drs. W. J. Clench and E. Mayr, of the Museum of Comparative
Zoology, Cambridge, Massachusetts for advice on the problem;
and Mr. E. K. Dell, Dominion Museum, Wellington, New
Zealand, for reading the original manuscript and for bringing
to my attention a number of important matters.

References

Conrad, T., 1850, Proc. Acad. Nat. Sci. Philadelphia 5 : 10.
Cotton, B. C, and C. J. Gabriel, 1932, Proc. Roy. Soc. Victoria

44: 155-160, pi. 16.
Delessert, B., 1841, Recueil Coquilles decrites par Lamarck,

pi. 12, fig. 5.

July, 1955] THE NAUTILUS ~ 13

Dell, R. K., 1953, Trans. Roy. Soc. New Zealand 81: 221-237,

pis. 17-19.
Gray, J. E., 1843 in Dieffenbach's *' Travels in New Zealand,"

vol. 2, p. 257.
Haas, F., 1924, Nova Guinea 15 : 65-76, pi. 2.
Hanley, S., 1843, Cat. Recent Bivalve Shells, p. 192, pi. 21, fig.

25.
International Commission on Zoological Nomenclature, 1914,

Opinions, No. 65, Smithsonian Institution Publ. No. 2256,

p. 152.
, 1945, Opinions and Declarations Rendered, No. 168,

London.
, 1950, Bull. Zooloor. Nomenclature 4 : 158-159.

Iredale, T., 1934, Australian Zoologist 8 : 57-78, pis. 3-6.

, 1943, Australian Naturalist 11 : 90.

Lamarck, J, B. P., 1819, Histoire Naturelle Animaux sans
Vertebres 6 : 80.

Lea, Isaac, 1859, Proc. Acad. Nat. Sci. Philadelphia 11 : 153.

, 1862, Proc. Acad. Nat. Sci. Philadelphia 14 : 176.

Philippi, R., 1847, Abbildung. Beschreib. neuer Conchylien,
vol. 3, Unio pi. 3, fig. 2, p. 7 (47).

, 1848, Ibid., Vol. 3, Unio pi. 5, fig. 5, p. 13 (81).

Simpson, C. T., 1900, Synopsis of the Naiades, Proc. U. S. Na-
tional Museum 22 : 501-1044.

, 1914, Descriptive Catalogue of the Naiades. Bryant

Walker, Detroit, Mich., 3: 1288-1308.

SwAiNSON, W., 1840, Treatise on Malacology, pp. 285, 360.

NEW CONUS FROM COSTA RICA

By JEANNE S. SCHWENGEL

CoNus DRANGAi n. sp. Plate 2, figs. 1, 2, 3, 4, 5, 6, 7.

Shell 32-35 mm. length, 16-20 mm. width; straight sided,
sloping to about 6 mm. width at base ; strong and solid, with a
heavy, dark brown periostracum which almost entirely obscures
the color pattern of the shell. Two to two and a half apical
whorls, glassy, buff colored ; followed by eight or nine revolving
body whorls. Color cinnamon to blackish brown, the tip
apricot-buff, this color spreading upward on the columnar
surface. A wide median band, occupying nearly a third of the
outer whorl, white and brown blotched, resembling somewhat

14 THE NAUTILUS [Vol. 69 (1)

a string of dancing paper dolls; four to six rows of revolving
brown dots, which show only on the white blotches; evenly
spaced, raised lineations on the body whorl, becoming gradually
stronger and closer as they near the base of shell. Lower
fifth or sixth of whorl very light buff, turning to apricot color
as it nears the inner lip ; aperture white.

The spire is thickly blotched with brown and white, giving a
somewhat checkered appearance. Definite sutures, whorls un-
evenly joined ; curved growth lines on spire which gives a raised,
laminate appearance to the peristracum. A faint suggestion of
raised, revolving lines on each whorl of the spire, sometimes
clearly defined and then almost disappearing, only to be re-
sumed farther on toward the last whorl. In appreciation of
assistance from Dr. Harald A. Rehder, the holotype and one
paratype is in the U.S.N.M. Other paratypes are in the col-
lections of Jeanne S. Schwengel and Ted T. Dranga, for whom
the shell is named. These shells were collected by Ted and
Anna Dranga in 1954 at Bahia Salinas, Costa Rica. Unfor-
tunately no live specimens were collected.

Conus drangai most nearly resembles Conus vittatus Bru-
guiere, though considerably smaller ; much darker brown ; not as
neatly and evenly patterned; with no spots on the encircling
raised lineations, except over the white areas. The bright
apricot tip is constant and very distinctive.

Conus andrangae n. sp. Plate 2, figs. 8, 9, 10, 11.

Shell 47 mm. length, 32 mm. width; heavy, straight sided,
low spire, each whorl coronated, body whorl having 15 stubby,
rounded, white-tipped nodes. Growth lines evident on spire
and body whorl. Ground color chestnut brown, splotched with
white near the periphery, with a median and basal white band.
Entire body whorl encircled with brown lineations which break
up into dots and dashes over the white areas, and become raised
and slightly nodulous on lower third of shell. Interior of
straight sided aperture white, slightly wider at base. Holotype
is in U.S.N.M. ; paratypes in collections of Jeanne S. Schwengel
and Ted T. Dranga. These shells were collected in 1953 at
Bahia El Coco, Costa Rica by Ted and Anna Dranga. This
species is named for Anna Dranga.

THE NAUTILUS 69 (1)

PLATE 2

%i^

Schweugel: Costa Eicaii Conus.

July, 1955] THE NAUTILUS 15

C. andrangae somewhat resembles C. hrunneus Wood, but
has no lineations on the spire, and the median and basal white
bands are constant ; the nodes on the spire are more conspicuous
and closer together, being placed more nearly as in C. diadema
Sowerby. The triangular shape is like C. hartschi Hanna and
Strong, though shorter and wider.

CoNUS GRADATUS THAANUMi n. subsp. Plate 2, figs. 12, 13.

Length 47 mm., width 21 mm. Specimens collected by Ted
and Anna Dranga are much more slender than C. regularis
Sowerby, a moderate spire, neither as high as Reeve's illustra-
tion of C. gradatus Gray nor as flat as C. regularis Sowerby.
They are marked with the spiral dotted lines, scarcely broken
below the center for one faint band, as in C. scalaris Valen-
ciennes and with the heavy longitudinal markings of chestnut
brown of C. gradatus Gray.

Having definite characteristics of so many different species,
it would seem to simplify the assorting of the several varieties
which are found in Lower California, if this shell were given
the sub-specific name above, to honor Mr. D. D. Thaanum, a
dear friend of Ted Dranga, and a great collector of conus.

These specimens were collected in 1954 at Bahia Salinas, Costa
Rica.

Conus recurvus helenae n. subsp. Plate 2, figs. 14, 15.

Length 44 mm., width 18 mm. This shell is quite slender, a
high spire, with slightly rounded shoulder, and no bands of
white, though nearer to C. recurvus Broderip than any other
named species. Beginning below center of body whorl are deep
spiral lineations, which do not seem to be mentioned in any of
the descriptions of C. recurvus Broderip in the various books.
Whether this should be a new species or only a sub-species is in
doubt, but we suggest a sub-specific name until numerous live
specimens may be obtained, at which time the study of this
shell should be pursued.

These specimens were collected in Curu, Gulf of Nicoya,
Costa Rica by Ted Dranga in 1952, and are named for his
mother.

16 THE NAUTILUS [Vol. 69 (1)

ADDITIONAL LOCALITIES FOR LAND MOLLUSCA
IN OKLAHOMA

By DEE SAUNDERS DUNDEE
University of Michigan

Land mollusks have now been reported from 65 of Oklahoma 's
77 counties. The total number of species (exclusive of their
subspecies, varieties and forms) reported so far is 81.

Oklahoma is an interesting state from an ecological stand-
point in that ten biotic districts (Blair and Hubbell, 1938)
exist within it. A deciduous forest element in the eastern part
of the state, a large area of grassland of the Great Plains ex-
tending from north to south through the central portion, and a
southern Rocky Mountain district in the extreme west are the
three principal subdivisions of the state. Elevations range from
350 feet in the Mississippi biotic district (a portion of the Gulf
Coastal Plain) to 4,500 feet in the Mesa de Maya district of
the west. The western portion of the state, largely open plains,
is drier and cooler than the rather heavily forested eastern part.
Annual precipitation ranges from 17 inches in the panhandle
to 50 inches in McCurtain County of the extreme southeast.

It is the purpose of this paper to make additions to the grow-
ing list of mollusks of Oklahoma so that the fauna will soon be
known. Only then can we correlate the distributions with data
such as those given above. Following the pattern set by Lutz
(1949), and adopted by Wallen (1951) and Wallen and Dunlap
(1954), only county names will be given here even though exact
locality data are available.

The specimens comprising this list have been collected over
the past three years by Harold Dundee and myself. Some of
these have been deposited in the U. S. National Museum and the
remainder will be placed in the collection of the Museum of
Zoology, University of Michigan.

Thanks are due Dr. J. P. E. Morrison of the U. S. National
Museum for checking identifications of many of the species and
to Dr. Henry van der Schalie of the Univ. of Michigan for read-
ing the manuscript.

July, 1955] THE NAUTILUS 17

Polygyra leporina (Gould) 1848. Wagoner, Mayes, Bryan

Polygyra texasiana (Moricand) 1833. Rogers, Mayes, Hughes

Polygyra dorfeuilliana Lea 1838. Choctaw

Polygyra dorfeuilliana sampsoni Wetherby 1881. Adair, Chero-
kee, Sequoyah, Murray, Osage, Me Curtain, Bryan, Coal

Stenotrema labrosum (Bland) 1862. Adair, McCurtain

Stenotrema monodon aliciae (Pilsbry) 1893. Adair, Cherokee,
Rogers, Delaware, Coal, Hughes

Mesodon thyroidus (Say) 1816. Adair

Mesodon thyroidus hucculenta (Gould) 1848. Adair, Choctaw

Mesodon clausus (Bay) 1S21. Adair

Mesodon indianorum (Pilsbry) 1899. Latimer, Rogers

Mesodon hinneyanus (Pilsbry) 1899. McCurtain, Latimer

Mesodon kiowaensis (Simpson) 1888. Choctaw-McCurtain
County line

Mesodon inflectus (Say) 1821. Adair, Sequoyah, Mayes, Dela-
ware, Choctaw

Triodopsis cragini Call 1886. LeFlore, Mayes, Coal, Okmulgee,
Hughes, Latimer

Triodopsis alholahris alleni (Wetherby) 1883. Mayes, Dela-
ware, McCurtain

Triodopsis divesta (Gould) 1851. Adair, Latimer

Bulimulus dealhatus (Say) 1821. Cherokee, Sequoyah, Tulsa,
Mayes, Choctaw, Bryan

Retinella indentata paucilirata (Morelet) 1851. Murray, Cleve-
land, LeFlore, Mayes, Bryan, Coal Okmulgee, Latimer

Mesomphix friabilis (W. G. Binney) 1857. Adair, Sequoyah,
McCurtain

Mesomphix cupreus ozarkensis (Pilsbry and Ferriss) 1906.
Adair, LeFlore

Ventridens hrittsi (Pilsbry) 1892. Adair

Zonitoides arhoreus (Say) 1816. Adair, Coal, Okmulgee,
Hughes

Limax flavus Linnaeus 1758. McCurtain

Deroceras sp. Delaware

Hawaiia minuscula (Binney) 1840. Latimer

Anguispira alternata crassa Walker 1928. Sequoyah, Delaware,
McCurtain

18 THE NAUTILUS [Vol. 69 (1)

Philomycus caroUnianus (Bosc) 1802. Delaware, McCurtain,

McCurtain-Choctaw County line
Helicodiscus parallelus (Say) 1817. Okmulgee
Succinea grosvenori Lea 1864. Murray, Hughes
StroUlops texasiana (Pilsbry and Ferriss) 1906. Murray,

Tulsa, Bryan, Okmulgee, Hughes, Latimer
Gastrocopta armifera (Say) 1821. Sequoyah, Mayes, Bryan,

Latimer
Gastrocopta contracta (Say) 1822. Mayes, Bryan
Gastrocopta procera (Gould) 1840. Bryan
Pupoides albilahris (C. B. Adams) 1841. Mayes, Hughes,

Latimer
Oligyra orhiculata tropica Pfeiffer 1852. Sequoyah, Bryan

Literature Cited

Blair, W. F., and T. H. Hubbell, 1938, The biotic districts of
Oklahoma. Am. Mid. Nat. 20 (2) : 425-454.

LuTZ, Louis, 1949, A check list of the land snails of Oklahoma.
Proc. Okla. Acad. Sci. 30: 32-35.

Wallen, I. Eugene, 1951, Additions to ^'A check list of the land
snails of Oklahoma." Proc. Okla. Acad. Sci. 32: 27-30.

Wallen, I. Eugene, and Paul Dunlap, 1953, Further addi-
tions to the snail fauna of Oklahoma. Proc. Okla. Acad. Sci.
34 : 76-80.

SHELLS COLLECTED AT LOUGHBOROUGH LAKE,
ONTARIO, IN JULY

By Dr. and Mrs. W. A. SWANKER

Loughborough Lake is one of the numerous Rideau Lakes
Group which are to be found in Ontario, north of Kingston.
The southernmost of these lakes is Loughborough which extends
in northeasterly direction from a point a little west and some 20
miles north of Kingston. It is about 22 miles long and from
one-half to three-quarters of a mile wide. As it empties into
others of the Rideau Lake system, it is a part of the St. Lawrence
water shed.

July, 1955] THE NAUTILUS 19

The lake has numerous shallow mud-bottomed flats which have
a good growth of aquatic plants. It is here that shell collecting
is at its best. Most of the types listed below are seen in quan-
tity. The unios were the most widely recognized as they were
only partly buried in the mud among the sparcer areas of
vegetation. There were quantities of dead shells everywhere.
Among the dead shells, which seemed to be grouped as though
they had been swept together here and there, the first of the
Planorhis and Lymnaea were found. These dead shells stimu-
lated the search and soon several specimens of the living snails
were collected. Some were found on the bottom detritis while
many of the Planorhis were found feeding on the aquatic
vegetation.

Three stations were selected at or near the southern extremity
of the lake.

Station No. 1 : Nearest the tip, it had a shale shore which rose
from the water edge a few feet, extended back from the water
about 30 to 50 feet and then rose sharply to a high hill. The
bed of the lake at this station was covered with small stones,
decaying logs and aquatic vegetation out to 15-20 feet where
it gave way to a soft mucky ooze covered by a thick carpet of
vegetation. The water depth sloped slowly to 4 feet about 100
feet off shore. The species found there were:

Lymnaea stagnalis Linnaeus ; numerous dead and several

living shells.
Planorhis trivolvis Say; few dead and numerous living shells.
Elliptio complanatus Dillw^ii ; many valves and few pairs, no

living.
Anodonta marginata Say ; few valves, 1 pair, no living.

Station No. 2: Along the eastern shore of the lake about 2
miles from the first station, it had a gravelly shore line with a
low well wooded background. The bed of the lake here was a
more sandy type of mud, more sparsely covered with aquatic
vegetation in which there were areas of the bottom free of any
vegetation. The water depth was slight as this great sub-
merged flat extended out 300 feet with water reaching only
about 18" and then dropping off rapidly to a considerable depth.
The species found at this station were :

20 THE NAUTILUS [Vol. 69 (1)

Lymnaea stagnalis Limnaeus; numerous living and dead

shells.
Planorhis trivolvis Say; numerous living and dead shells.
Elliptio complanatus Dillwyn; numerous living and dead

shells.
Anodonta marginata Say ; many living, occasional valve.
Lampsilis luteolus Lamarck; occasional shells.
Lampsilis siliquoidea Barns ; 1 pair of valves.
Sphaerium sulcatum var. insigne; 1 pair and 2 valves.

Station No. 3 : Along the western shore about 2 miles from
the first station, there was a broad meadow that made a low
shoreline that was of a clayish gravelly nature. The slope of
the bed of the lake was much more acute, reaching a depth of
10 feet only about 25 feet from the shore. The aquatic vegeta-
tion was very sparse and consisted of small thin clumps here
and there. An occasional damaged old valve of a Unio was
found near the water's edge along with one or two old mud
filled Lymnaea shells. A few living Planorhis were found on
the vegetation. The absence of shell life was most striking when
one considers the abundance of mollusks across the lake only %
of a mile away (Station No, 2).

These specimens collected were housed in the shell collection
of the American Museum of Natural History in New York.

HOW CLAM DRILLS CAPTURE RAZOR CLAMS
By HARRY J. TURNER, JR. *

During the past few years, the author has observed a number
of instances of predation by the carnivorous marine snail,
Polinices duplicatus, on the razor clam, Ensis directus. In every
case, the snail and the razor clam were found on the surface of
the substratum with the clam enveloped in a coating of slime
and the snail attached along the mid-ventral region with its
proboscis inserted between the valves. No drilled razor clam
shells have ever been found.

* Contribution No. 777 from the Woods Hole Oeeanographic Institution.

July, 1955] THE NAUTILUS 21

It is difficult to imagine how P. duplicatus can capture a razor
clam and hold it long enough to render it inactive, because razor
clams normally retreat to considerable depths when disturbed.
Burrowing is accomplished by extending the foot downward,
expanding the distal portion as an anchor, and pulling the
body down by strong contractions of the proximal portion of the
foot. The process is then repeated so rapidly that a depth of
ten inches can be reached in a matter of seconds and the force
of the contractions is so great that the foot and part of the
viscera may be torn out if the shells of a burrowing razor clam
are held to prevent them from following the foot.

Recently, the author had the good fortune to make some ob-
servations on an attack by P. duplicatus on a razor clam which
gave some indications as to how the snail may immobilize its
prey. A 97 mm razor clam was found on the surface of the
sand with a 15 mm snail attached to the posterior end. The
clam was extending and retracting its foot in writhing motions
as if making an attempt to escape. The clam finally managed
to work its foot down into the sand, pull itself into an erect
position, and begin to burrow. As soon as the clam had erected
itself, the snail quickly crawled down the body and burrowed
into the sand along side of its prey. The razor clam continued
to dig in until % of its length was buried and then stopped.

After a two-minute period the razor clam suddenly forced its
way out of the sand with violent thrusts of its foot. The snail
was attached to the lower third of the body but the final thrust
detached it. The razor clam immediately extended its foot and
began to burrow, touching the snail as it did so. The snail
then dug in along side of the clam which again stopped as soon
as % of its length was buried. The clam made one or two
feeble attempts at digging in deeper. The posterior end was
just level with the surface when it suddenly forced its way out
again with the snail attached to the lower portion. The last
motions detached the snail and thrust it a few centimeters away
from the clam. The clam and the snail then dug in inde-
pendently although the activity of the clam was much slower
than during the early part of the encounter.

No further activity was observed for the next ten minutes.
The razor clam and the snail were then dug up and found to be

22 THE NAUTILUS [Vol. 69 (1)

separated from each other by five centimeters. The snail was
expanded with its head oriented away from the clam. When
placed on the sand, the clam showed no activity during the next
30 minutes after which observations were discontinued. All
but the lower (anterior) end of the body of the clam was
covered by an envelope of slime secreted by the foot of the snail.
It seems clear that P. duplicatus captures Ensis directus by
approaching it below the surface of the substratum and by ir-
ritating the lower portion so that it retreats upward. The snail
then coats the razor clam with an envelope of slime which ap-
pears to have anesthetic properties. Successful capture proba-
bly depends on the ability of the snail to maintain contact with
its prey until anesthesia takes place.

ON THE OCCURRENCE OF THE NUDIBRANCH

ALDERIA MODESTA (LOVEN, 1844) ON THE

CENTRAL CALIFORNIAN COAST

By CADET HAND and JOAN STEINBERG

Department of Zoology, University of California, Berkeley

Alderia modesta (Loven, 1844) has long been known from the
coasts of northern Europe. It has been recorded from as far
north as the Trondheim Fjord in Norway (Norman, 1893),
south to Skibbereen in Ireland (Allman, 1845) and on the
French coast (GoUien, 1929). Therefore, it has been of con-
siderable interest to us to find well-established populations of an
Alderia in two localities on the central Californian coast.
Through the kindness of Monsieur G. Van Put of the Royal
Institute of Natural Sciences of Belgium in Brussels and Dr.
Erik Rasmussen of the Royal Veterinary and Agricultural Col-
lege in Copenhagen, we have been able to compare specimens
of Alderia modesta from both Belgium and Denmark with
specimens collected by us from the California localities. The
results of these comparisons have shown the Alderia from
California to be identical with A. modesta.

July, 1955] THE NAUTILUS 23

Alderia Allman, 1845

Alderia Thompson, W. (nomen nudum), 1844, Rep. Brit. Assoc.

Adv. Sci. for 1843, p. 250.
Alderia Alder, J., and A. Hancock (nomen nudum), 1845, Rep.

Brit. Assoc. Adv. Sci. for 1844, p. 26.
Alderia Allman, G. J., 1845, Rep. Brit. Assoc. Adv. Sci. for

1844 ; Trans, of the Sections, p. 65.
Aldenu (error pro Alderia Allman, 1845) Paetel, 1875, Fam.

Gatt. Moll 6.

Type by subsequent designation: Stiliger modestus Loven,
1844.

Alderia modesta (Loven, 1844)

Stiliger modestus Loven, 1844, Of vers K. Vetensk.-Akad. For-

handl. Stockholm i (3), p. 49.
Alderia amphihia Thompson, W., 1844 nomen nudum, Rep. Brit.

Assoc. Adv. Sci. for 1843, p. 250 ; Alder, J., and A. Hancock,

1845, nomen nudum Rep. Brit. Assoc. Adv. Sci. for 1844, p. 26.
Alderia modesta Allman, 1846, Ann and Mag. Nat. Hist., ser.

1, 17, p. 5; Loven, 1846, Ofvers K. Vetensk.-Akad. Forhandl.

Stockholm, p. 8.
Alderia scaldiana Nyst, 1855, Bull, de I'Acad. de Belgique XXII,

no. 2, pp. 435-37, figs. 1, 2.

Diagnosis. — Alderia: Body elongate and elliptical. Head
without rhinophores but produced into rounded lobes on either
side of median line ; mouth a vertical slit ; eyes visible through
integument behind lobes. Foot nearly straight anteriorly,
bluntly tapered posteriorly; lateral margins wider than body.
Groove laterally between body and foot. Cerata cylindrical,
bluntly pointed apically; arranged longitudinally on either
side of posterior three-quarters of body and roughly divisible
into 3-5 rows set obliquely to longitudinal axis of body; number
of cerata variable, maximum 15-16 on a side, often fewer.
Anus on free tube located posteriorly in median line. Genital
pores situated below first cerata on right side. General ground
color translucent yellowish white ; dorsum and cerata speckled
with numerous black pigment spots ; cephalic lobes and anterior
dorsal region often heavily pigmented ; anterior edges of
cephalic lobes lacking pigment, unpigmented area sometimes
extending back to region of eyes as a colorless line ; cerata with
a few opaque white dots, especially apically. The animals
sometimes appear green because of the color of food present
in the highly ramified digestive diverticula.

Jaws absent. Radula uniserial with 11-14 spoon-shaped teeth
and sac containing discarded teeth at base ; a single tooth measur-

24

THE NAUTILUS

[Vol. 69 (1)
Penis bearing single

ing 120 fx. with a base of 40 fx (Fig. 1).
large spine 180 fx in length (Fig. 2).

The largest specimens collected measured 8 mm. in length.
One of average size measured 5.5 mm. in length, 1.2 mm. in
height and 2 mm. in breadth (Fig. 3).

Figure 1. Top and side views of a portion of the radula of Alderia
modesta. Figure 2. The penial spine of Alderia modesta. Figure 3.
Alderia modesta (Loven). Figure 4. Larval shell of Alderia modesta.

Occurrence: Type locality: Bohuslan, Sweden (Loven,
1844). Other localities: northern and central Europe. New
localities: (1) Bay Farm Island, Alameda Co., California, on
Vaucheria sp. in a Salicornia marsh bordering San Francisco
Bay in area wetted only by high tides, May, July, August, 1951
and March, 1954; with various ciliates, diatoms, nematodes, fly
larvae, mites, small oligochaetes, harpacticoid copepods, amphi-
pods. (2) Elkhorn Slough, Monterey Co., California, in Sali-
cornia marsh on Vaucheria sp., August, 1951 ; July, 1952 ; with
Cerithidea and Phytia.

July, 1955] THE NAUTILUS 25

Discussion : The eggs of Alderia modesta are laid in round to
elongate masses measuring about 5.5 mm. in length and 1.5 mm.
in diameter. These masses are anchored at one end to the
substrate and consist of an irregular coil of egg capsules em-
bedded in a soft gelatinous matrix. The coil is about 200 ^
wide. The capsules measure 150-180 fx, in diameter and each
contains a single egg measuring 70-80 fi in diameter. The
capsules may be so closely packed together in the coil that many
assume a polyhedral shape. The color of the eggs is yellowish
when laid but changes to white as development proceeds. The
veligers have been described by Rasmussen (1951), and ours
appear to be quite similar. The larval shell is bowl shaped
with only a suggestion of a whorl. A shell measured 124 fx in
length and 88/a in width (Fig. 4). There are no pigment spots
on the veligers.

Insemination has been observed several times and is accom-
plished by hypodermic injection. During copulation persistalic
waves move along the extended penis and a flow of seminal
material can be seen entering the recipient Alderia. Injection
can apparently occur at any point on the body, and after copula-
tion the body spaces, including those of the cerata, can be ob-
served to be full of sperm.

Copulation was not observed to be reciprocal nor was there
any indication of self-fertilization. Sperm were recovered from
a recipient Alderia after copulation and were found to be very
active. The sperm appear to have a spiral head (approx. 60 /x
long) and a tail piece (approx. 45 /x long), but no middle piece
could be distinguished.

On August 14, 1951 collections at Elkhorn Slough revealed
many egg masses as well as four juvenile specimens, each about
one millimeter long and having only a single pair of cerata with
the anus located between. Others, about % millimeter long,
were found without cerata and with the shell still present. At
this time an adult pair were observed copulating. One of the
individuals injected the sperm into the fourth ceras on the
right side of the other.

The animals, for the most part, are confined in their distribu-
tion to Vaucheria sp. which forms dark green mats on the mud.
Other mats of algae, lighter green in color, generally support no

26 THE NAUTILUS [Vol. 69 (1)

Alderia, These mats consist of a Cladophoracean (either
Rhizoclonium or ZJrospora), Oscillatorm and Enteromorpha.
The food of Alderia seems to consist entirely of Vaucheria on
which it actively grazes.

An interesting characteristic of Alderia is a peculiar sickly
sweet smell which is especially noticeable after a group of
animals have been confined to a jar for some time. Another
characteristic of the live animals is that the body surface, in-
cluding the cerata, possesses many scattered ciliated cells. These
cells appear to be effective in moving the film of water present
on the algal substrate over the body of the animal, thus keeping
the Alderia continuously wet in what approximates a terrestrial
habitat. Still another characteristic of Alderia is that the
cerata exhibit a rhythmic contraction which alternates from one
side to the other. There are no anterior-posterior differences in
the time of contraction.

Two other species ascribed to the genus Alderia have been
reported from the Pacific Basin. One, Alderia? alhopapillosa
Dall, 1872, has been shown by Bergh (1880) to belong to the
phanerobranchiate genus Adalaria Bergh. The other, Alderia
nigra Baba, 1937, possesses distinct rhinophores, a character
which excludes it from the genus Alderia. Alderia harvardien-
sis Gould and Binney, 1870, which was collected by A. Agassiz
(1851) in the Charles River and the creeks around Cambridge,
Massachusetts and by W. Stimpson (1853) in the region around
the mouth of the Bay of Fundy, New Brunswick, is distinguish-
able from A. modesta only in the form of the anterior margin
which appears in Agassiz 's drawing (in Gould and Binney,
1870) to be concave rather than bilobed and in the darker colora-
tion. There is, in the U. S. National Museum, a single specimen
of A. harvardiensis. Through the kindness of Dr. Rehder this
specimen has been examined by one of us (Steinberg), although
no decision as to its real identity could be made. The specimen
is in very poor condition and the anterior end has been damaged
and the radula removed. From the form of the body which is
still clear the specimen looked suspiciously like a small A.
modesta. This species has not been recorded since the last
century, but, if further material becomes available, it appears
quite possible that A. harvardiensis may actually be A. modesta.

July, 1955] THE NAUTILUS 27

Acknowledgments. — We gratefully acknowledge the kind
help of Dr. Isabella Abbott for the identifications of the several
genera of algae mentioned in the text, and Mrs. Lois Stone for
the preparation of the figures.

Literature Cited

Agassiz, a., 1851, A note in the Proc. Boston. Soc. Nat. Hist.

Ill, pg. 191.
Alder, J. and A. Hancock, 1845, Report on the British Nudi-

branehiate Mollusca. Rep't 14th Meeting Brit. Assoc. Adv.

Sci. for 1844, pg. 26.
Allman, G. J., 1845, On a new genus of Nudibranchiate Mol-
lusca. Rep't 14th Meeting Brit. Assoc. Adv. Sci. for 1844,

Trans, of Sections, pg. 65.
, 1846, Note on a new genus of Nudibranchiate Mollusca.

Ann. and Mag. Nat. Hist. XVII: 1-5.
Baba, K., 1937, A new noteworthy species of the Saccoglossan

genus Alderia from Amakusa, Japan. Dobutsvigaku zasshi

(English title: Zoological Magazine) Tokyo 49: 249-51, 3 figs.
Bergh, R., 1880, On the nudibranchiate gasteropod Mollusca of

the North Pacific Ocean, with special reference to those of

Alaska. Proc. Acad. Nat. Sci. Phila. for 1880, pg. 83.
Da Costa, A., 1867, Saggio sui Molluschi eolididei del golfo di

Napoli. Annuario del Mus. Zool. della R. Univ. di Napoli IV,

pg. 32, Tav. II, fig. 3.
Dall, W., 1872, Descriptions of sixty new forms of MoUusks

from the West Coast of North America and the North Pacific

Ocean. Amer. Journ. Conch., VII, pg. 137.
Eliot, Sir C, 1906, Notes on some British Nudibranches. J.

Mar. Biol. Assoc. 7(3) : 334-82.
Gallien, L., 1929, Etude de deux mollusques opisthobranches

d'eau saumatre. Bull. Soc. Linn. Normandie, Caen, Series 8,

1 : 162-89.
Gould, A. A., 1870, Invertebrata of Massachusetts, edited by W.

G. Binney, Boston.
Loven, S. L., 1844, Om nordiska Hafs-Mollusker. Ofvers. Kongl.

Vetensk.-Akad. Forh. Stockholm, 7, pg. 49.
, 1846, Index Molluscorum litora Scandinaviae occid. habi-

tantium. Ibid., Ill, pg. 8.
Norman, A., 1893, A month on the Trondheim Fjord. Ann. and

Mag. Nat. Hist., Series 6, XII, pg. 351.
Nyst, H., 1855, Description succincte d'un nouveau mollusque

marin des rives de I'Escaut. Bull, de I'Acad. Roy. des Sci.,

des Lettres et des beaux Arts de Belgique, Brussels XXII:

435-37, figs. 1-2.

28 THE NAUTILUS [Vol. 69 (1)

Paetel, T., 1875, Die bisher veroffentlichten Familien- und
Gattungsnamen der Mollusken, Berlin, 229 pp.

Stimpson, W., 1853, Synopsis of the Marine Invertebrata of
Grand Manan, pg. 25.

Thompson, W., 1844, Report of the fauna of Ireland: Div. In-
vertebrata. Rep't Brit. Assoc. Adv. Sei. for 1843, pg. 250.

SOME ECOLOGICAL ASPECTS OF THE NAIAD
FAUNA OF LAKE SPRINGFIELD, ILLINOIS

By PAUL W. PARMALEE

Lake Springfield, which is approximately 2 miles south and
east of Springfield, Sangamon County, underwent construction
in 1931 and was completed in May of 1935. The lake has a sur-
face area of 6.8 square miles; there is approximately 57 miles
of shoreline, 40 of which has been riprapped. By riprapping
(placing broken stone or rock along the lake edge) much of the
shoreline, silting resulting from eroded banks and bordering
fields has been reduced to a minimum. The lake was formed
by the damming of Sugar Creek, a small, relatively shallow,
muddy creek that presently has little or no effect in feeding
Lake Springfield with renewed water supplies. Lake Spring-
field is approximately 12 miles in length with a maximum
width of two miles. Maximum depth is about 40 feet; average
depth, 15 feet. Except for some emerging vegetation, there is
little or no submerged or floating aquatic vegetation in most
parts of the lake.

The year 1953 was one of below-average rainfall for Illinois
and there was 12-14 inches less precipitation than during normal
years. Because of this reduced precipitation and the continued
use of the lake as a source of water by the city of Springfield,
the water level dropped approximately seven feet during 1953.
The gradual receding of the water left most of the shallow bays
and inlets dry, and thereby exposing much of the mussel fauna
of these areas to desiccation.

During October, 1953, an attempt was made to determine the
species composition and relative abundance of the Lake Spring-

July, 1955] THE NAUTILUS 29

field mussels. This lake presented an interesting study since
(1) the effects on a mussel population by damming and thereby
changing the physiographic condition of a natural creek could
be observed; (2) it was possible to note the influence of bottom
types on distribution and abundance, and (3) the species
composition and relative abundance could be studied in this
somewhat limited area.

Twenty sites or stations (Fig. 1), including the various
bottom types, were sampled. At each site, all mussel shells were
removed within a space approximately 50 yards long and four
yards wide. The abundance of dead shells and partially or
almost wholly buried individuals at the water's edge would
tend to show their inability as a whole to retreat with the re-
ceding water. Although this distance varied slightly at some
sites, an effort was made to keep the area covered at all stations
equal in size. Numerous other localities were examined for
the purpose of locating species not found at the other sites, but
no additional species were discovered.

Unfortunately there are no early studies of the mussel fauna
of Sugar Creek and other neighboring streams and rivers, so
that comparisons of naiad populations in the lake with these
creeks and rivers must be based on current observations. In
addition, there have been numerous fish-stocking programs
since the completion of the lake in 1935, and these introduced
fish could carry glochidia and hence introduce and possibly
establish certain species.

The bottom types can arbitrarily be divided into either coarse
gravel and rock (riprap), a mixture of mud and sand, or mud,
the latter constituting a large percentage of the bottom surface
of the more sheltered bays and inlets. It is of interest to note
that portions of the lake bottom consisting of rock and gravel,
and sand in some cases, are often almost devoid of mussels.
For example, the shoreline in front of Spaulding Dam (Station
I) and the Dividing Dam (Station II), as well as Lake Park
(Station VI), is mostly rock fill and gravel, and the mussel
population in these areas is low in both abundance and number
of different species. Such areas of coarse gravel and rock
bottom are in themselves generally unsuitable for habitation by
the mussels, although these portions of the lake are more exposed

30 THE NAUTILUS [Vol. 69 (1)

to the prevailing winds and consequently a more severe wave
action results. A combination of less suitable bottom habitat
(conditioned in part by wave action) and frequently turbulent
waters would tend to inhibit the growth of naiad populations
in such situations. The mud-sand bottom, formerly covered
by water to a depth of two to four feet, appeared to have pro-
vided the most suitable habitat for these animals, and in such
areas the mussel fauna of Lake Springfield reached its greatest
abundance, both numerically and in numbers of species.

The majority of species now found in the lake were probably
present in Sugar Creek before it was dammed. These species
are also present in the Sangamon River and the South Fork
of the Sangamon. Other species such as Tritogonia verrucosa,
Quadrula pustulosa, Ohliquaria reftexa, Megalonaias gigantea,
Truncilla truncata, and Leptodea fragilis, common in the South
Fork of the Sangamon River (which flows at one point within
approximately half a mile of Lake Springfield), are absent from
the lake. If these, and possibly other stream or river species,
were ever present in Sugar Creek, they apparently were not
able to adjust to lake conditions after the creek was dammed.
Van der Schalie (1938) mentions the occurrence of T. iruncata
in Lake Erie and Brown, Clark and Gleissner (1938) refer to
Lake Erie specimens of Leptodea fragilis. However, the ability
of such river species to adjust to lake conditions in one instance
and not another may be the result of differences in size of the
body of water, the influence of current or the absence or abun-
dance of the regular host fish of the glochidia.

Normally M. gigantea, T. truncata and other species that are
adapted primarily to moving bodies of water would not be
expected in a lake environment. However, the common Maple-
leaf (Quadrula quadrula), a species also found typically in
larger rivers and streams, has become well adapted to a lake
habitat and constitutes over 45% of the total number of mussels
in Lake Springfield (Table 1). It is the most abundant species
and can be found in all parts of the lake. Amhlema costata,
primarily a species of medium-sized rivers, is also present in
the lake but in relatively small numbers. The predominating
mud bottom may limit the abundance of this species in the lake
since it appears to prefer a sand or gravel bottom, although it

July, 1955] THE NAUTILUS 31

was found to be most numerous in mud (Station XV) where
Lick Creek enters the lake.

In this connection it is of special interest to note the situation
encountered at Lake Decatur, a man-made lake lying immediately
southeast of the city of Decatur (approximately 45 miles east
of Springfield), Macon County, Illinois. This lake is somewhat
smaller and generally more narrow than Lake Springfield, and
it is fed directly by the Sangamon River. Much of the bottom
consists of a mixture of sand and mud, and at one point ap-
proximately % mile from the dam, large colonies of Truncilla
truncata, Quadrula quadrula, Q. pustulosa, Carunculina parva
and Fusconaia flava have become well established in three to
four feet of water. In comparison, Arcidens confragosus and
Amhlema costata are uncommon, but this particular situation
illustrates the adaptive ability of river forms to lake conditions.
Although F. flava has been recorded as part of the Lake Erie
fauna (Brown, Clark and Gleissner, 1938), it apparently be-
comes abundant only in rivers and in lakes (such as Lake
Decatur) that are influenced by river current. The occurrence
of river species such as F. flava, Quadrula quadrula, Q. pustulosa
and T. truncata would tend to verify the fact that Lake Decatur
is a river-lake, defined by Coker as **a body of relatively still
water as would ordinarily be called a lake, which is yet inti-
mately connected with a river, either as interpolated in the
course of the river, or as an arm of a river" (van der Schalie,
1938). Such river species would be expected in Lake Decatur
where river-lake conditions exist. It is reasonable to assume
that the almost complete lack of current influence in Lake
Springfield has inhibited the establishment of river mussel
populations, Quadrula quadrula being the one notable exception.

In Lake Springfield Anodonta grandis is widely distributed
but it is generally not common anywhere. It was found at a
variety of depths up to about six feet, in either a sand or mud
bottom or a combination of both, but preferably sand. Anodonta
imhecilis, although also distributed throughout the lake, is rela-
tively rare and is limited to those shallow bays and inlets with
a soft, black mud bottom.

Leptodea laevissima, the Fragile Heel-Splitter, is the second
most abundant species in the lake, constituting approximately

32

THE NAUTILUS

[Vol. 69 (1)

T«bl9 1, The Species Composition, Distribution, and R«l«tlT» AbundSDCo of th« nussla
of Lake Springfield, Illinois.

STATIOHS

I.

II

III

IV

V

VI

VII

VIII

IX

X

XI

XII

XIII

icrv

XV

;cvi

XVII

XVIII

XIX

XX

fotSTToT
of each

* Of Total,
f opulatloa

Qjiadrula Quadrula

r

2?

26

28

4

78

25

20

12

33

26

21

16

35

14

30

54

17

Species
472

47.81

Anodonta firandls

1

7

9

1

8

5

1

4

1

4

3

2

1

3

12

1

6S

6.38

2

1

1

1

1

1

7

.70

^"■°JS»"a coHElanata

11

g

S

3

10

3

16

5

3

12

8

9

3

13

4

111

11.24

3

IS

18

12

3

6

10

e

29

5

21

2

13

,

13

13

5

21

9

213

21.57

Llffiala subrostrata

2

25

17

6

9

1

2

4

5

6

5

3

4

10

1

5

105

10.63

Amblema eostata

1

1

2

2

6

8

14

^

1

.10

Pusccnala flava

1

1

.10

Totals

X

987

99.94

SUGAR CREEK

22% of the total population. This species is usually found in
large rivers on sand and mud bottom in good current (Baker,
1928) but, as in the case Q. quadrula, it can adapt itself to lake
conditions and has become quite numerous and widespread in
Lake Springfield. The adaptation of river species to a true lake
habitat is unusual although van der Schalie (1936) found such
a situation in the case of Lampsilis ventricosa and Strophitus
rugosus in a small lake in southern Michigan. The White Heel-
Splitter (Lasmigona complanata) , a species typical of the quiet

July, 1955] THE NAUTILUS 33

waters of rivers and creeks, is also quite common. In the lake,
both species of heel-splitters reach their greatest abundance in
the mud bottoms of shallow (one to three feet) bays and inlets.
Ligumia suhrostrata ranked fourth in abundance and, like
most species in the lake, becomes most numerous in the shallow,
mud bottom regions. It is often found in the quiet backwaters
and sloughs of rivers, so that the prevailing physiographic
conditions of Lake Springfield provide a comparable habitat.
Only one specimen (an adult) of Arcidens confragosus was
found and therefore it should be considered as accidental or
stray and not part of the permanent population. It is nor-
mally found in rivers and streams (occurring in the Sangamon
River) and does not ordinarily inhabit quiet waters. However
A. confragosus is never common when it is found in Illinois.
Representatives of the Sphaeriidae were found at only one
location in the lake (Station 3), a shallow, mud bottom inlet.
Apparently little is known concerning their means of distribu-
tion.

Summary

Lake Springfield is one of the largest man-made impound-
ments in Illinois; its surface area is almost seven square miles.
The lake has an average depth of 15 feet, and most of the bottom
is composed of a black, soft mud.

During 1953 the lake level dropped approximately seven
feet, exposing most of the shallow bays and inlets. In Oc-
tober, 1953, an attempt was made to determine the species com-
position and relative abundance of the mussels by collecting
them within a comparable measured area at 20 sites or stations
along the lake shore. Although only nine species of naiads
were encountered (excluding the Sphaeriidae), several, espe-
cially Quadrula quadrula and Leptodea laevissima, were ex-
ceedingly abundant. These two species are of particular in-
terest since in Illinois they are normally found in streams and
rivers, but in this instance they have very successfully adapted
themselves to a lake no longer influenced by current.

Protected bays and inlets (two to four feet in depth), having
a bottom surface composed of soft, black mud and/or sand,

34 THE NAUTILUS [Vol. 69 (1)

provided the most suitable habitat for the majority of species
and in such areas they reached their greatest abundance.

Literature Cited

Baker, Frank C, 1928, The fresh water Mollusca of Wisconsin.

Part II. Pelecypoda. Bull. 70 Univ. Wis., Gen. Series No.

301, 495 pp.
Brown, C. J. D., Clarence Clark and Bruce Gleissner, 1938,

The size of certain naiads from western Lake Erie in relation

to shoal exposure. Amer. Mid. Nat., Vol. 19, No. 3, pp. 682-

701.
Van der Schalie, Henry, 1936, An unusual naiad fauna of a

southern Michigan lake. Amer. Mid. Nat., Vol. 17, No. 3,

pp. 626-628.
, 1938, The naiad fauna of the Huron river, in southeastern

Michigan. Univ. Mich. Misc. Pub. No. 40, 83 pp.

NOTES AND NEWS

Dates of The Nautilus. — ^Vol. 68, no. 1, pp. 1-36, pi. 1, was
mailed July 24, 1954. No. 2, pp. 37-72, pi. 2, Nov. 15, 1954.
No. 3, pp. 73-108, pi. 3, Feb. 11, 1955. No. 4, pp. 108-144, i-v,
pi. 4, April 28, 1955.— H. B. B.

Discus macclintocki (F. C. Baker), I have finally found
living at Bixby State Park, Clayton Co., Iowa. In this park
is a cave from which a continuous blast of cold air (tempera-
ture about 50° F.) issues. The shells were found in pockets of
leaves and moss in crevices from which the cold air blows. —
Leslie Hubricht.

The St. Petersburg Shell Club held their annual Shell
Show in the Rod and Gun Clubhouse on March 5th to 9th. The
Smithsonian Institution award was given to James R. Kelley
and Mrs. J. F. Kelley.

The twenty-first annual meeting of the American Malaco-
logical Union will be held from July 26th to 29th at Wagner
College, Staten Island, New York. Details will be mailed
to members as soon as available. — Margaret C. Teskey, Secre-
tary.

July, 1955] THE NAUTILUS 35

Change of address: for American Malacological Union and
Margaret C. Teskey.

Old address: 144 Harlem Ave., Buffalo 24, N. Y. New ad-
dress: Buffalo Museum of Science, Humboldt Parkway, Buf-
falo 11, N. Y.

Spirula spirula Linne, a remarkable find. — ^While it is not
at all unusual to find these fragile coiled shells cast up upon
the beaches of Florida, little is known of the small squid-like
creature which forms the shell beyond the fact that it lives at
great depths and is world-wide in distribution. It is presumed
that the graceful white shell floats to the surface after the
squid's life is ended, then being extremely light with numerous
gas-filled chambers the dainty shell drifts with the sea-currents
until some of them are washed high and dry among the seaweed
on our beaches. Apparently most remain at the surface for a
considerable time for colonies of small goose barnacles are
oftener than not found attached to the shells. The late winter
of 1954 was a rather stormy one and it was in December that
Mrs. Elizabeth B. Phelps discovered one of these interesting
deep sea creatures which had just washed up on the shore at
Boynton Beach. The squid was in excellent condition, an adult
over 50 mm. in length, with the shell partly visible within the
animal. To my knowledge, this is the first record for this
squid-like creature having been found in Florida. This unique
specimen has been donated to the Academy of Natural Sciences
in Philadelphia. — Thomas L. McGinty.

Extension of known range of the slug Pallifera fosteri
F. C. Baker. — In my paper on the ''Distribution of the mollusks
in a basic bog lake and its margins" (Nautilus 64(1) : 19-26,
1950), I reported a specimen of Pallifera collected on the shore
of a glacial bog lake in Portage County of northeastern Ohio.
Since publication this specimen has been identified by Dr. C.
Bruce Lee, Materials Laboratory, Detroit Arsenal, as Pallifera
fosteri F. C. Baker 1939, confirming the belief of the writer
who did not want to put the name in print until checked by a
specialist on the group. The species was described by Baker
from specimens collected in Vermilion County, Illinois, and
additional specimens were collected from Monroe and Wayne
Counties (Fieldbook of Illinois Land Snails). H. A. Pilsbry's

36 THE NAUTILUS [Vol. 69 (1)

monograph of the "Land Mollusca of North America" (Vol. II,
part 2) also lists St. Louis Co., Missouri, attributed to Leslie
Hubricht. The known range is now extended from eastern Mis-
souri and central Illinois to northeastern Ohio. — Ralph W.
Dexter, Dept. of Biology, Kent State University, Kent, Ohio.

PUBLICATIONS RECEIVED

How TO COLLECT SHELLS. A symposium by members of the
American Malacological Union. 75 pp. A.M.U., Buffalo Mu-
seum of Science, Buffalo 11, N. Y. $1.00. 1955.— This hand-
some and inexpensive booklet contains a wealth of information
on how to collect, dredge, trap and clean marine, land and fresh-
water mollusks. There are two dozen chapters by well-known
American collectors, and both the novice and the experienced
will find this attractive manual extremely useful. Also in-
cluded are lists of useful books, shell clubs and outstanding
American mollusk collections. Mrs. Margaret C. Teskey, who
is largely responsible for assembling and editing the material,
is to be congratulated for what will doubtlessly be a very
popular publication — R. T. Abbott.

Marine Shells of the Western Coast of Florida. By
Louise M. Perry and Jeanne S. Schwengel. 198 pp., 55 pis.
Paleontological Research Institution, Ithaca, N. Y. $7.00.
1955. — Fifteen years ago. Dr. Louise M. Perry published her
''Marine Shells of the Southeast Coast of Florida" which soon
became the most popular of the several books written about
the marine mollusks of Florida. It has now been revised and
somewhat expanded by Dr. Jeanne S. Schwengel. The eleven
additional plates include drawings of the egg capsules and
veligers of 21 gastropods, a noteworthy addition to the knowl-
edge of the life histories of our AVestern Atlantic species. The
revisor, perhaps wisely, has avoided using the "common"
names of the Florida shells. The photographs are excellent,
and "shellers" along the west coast of Florida should find this
new edition very helpful. — R. Tucker Abbott.

The Nautilus

Vol. 69 OCTOBER, 1955 No. 2

THE PROPOSED INTRODUCTION OF PREDATORY
SNAILS INTO CALIFORNIA

By ALBERT R. MEAD

University of Arizona

Largely through the fact that there has been a great deal
of publicity on the subject, a surprising number of people know
that a small predatory snail from East Africa has been enlisted
in Man's fight against the giant African snail, Achatina fulica
Bowdich. This predatory snail, Gonaxis kihweziensis (E. A.
Smith), at present is scheduled to invade new areas at a rate
that may well outstrip the records set by its prey. One thing
is different. Man wants Gonaxis to spread. Or, more exactly,
those in charge of the proposed biological control program
want it to spread. Here is the story.

The small island of Agiguan, off the coast of Tinian in the
Marianas Islands, has for five years been the scene of an ex-
perimental battle between the giant snail and the predatory
snail. Even before the first phase of the battle was over,
Gonaxis was released in Oahu of the Hawaiian Islands, and
later in Guam and Maui in the hopes that it would help control
the giant snail. A seventh expedition to Agiguan in October
of 1955 has been planned to assist in spreading Gonaxis still
further. Reportedly, the mission is to collect as many live
Gonaxis as possible with the plan that one portion is to go to
Hawaii for further releases on Oahu and Maui ; a second portion
is to go to the Trust Territory of the Pacific Islands for release
on other infested islands, such as Saipan, Rota, and Truk; and
a third portion is to go to California under the tentative plan
to use it against the green snail (Helix aperta) in the San
Diego area, and against the brown snail (Helix aspersa) es-
pecially in the citrus groves of southern California.

37

38 THE NAUTILUS [Vol. 69 (2)

The announcement that it is to be introduced into California
will come as a surprise to many, especially in view of the
''anti-snail" legislation enacted by Congress only a relatively
few months ago. If the Secretary of Agriculture, who has
promulgated the required protective regulations, approves of
an introduction of this sort, there is the immediate implication
that he is acting on the advice of his consultants. With an
approval, the machinery for introduction is set in motion.
Without significant objection, at either the State or National
level, it is simply a matter of time, and short time at that, until
the introduction becomes a fait accompli.

For those who would take precious time in Man's battle
against pestiferous snails, the thoughts might occur, "Is an
introduction of this type really wise ? Is it scientifically sound ?
Is it actually justified? What if the experiment does not work
— then what? Are any dangers involved?" In an attempt to
find answers to these questions, there should be an examination
of the very small store of knowledge available on this subject.

First of all Gonaxis has not been scientifically proven to be
capable of controlling Achatina fulica or, for that matter, even
any snail in its own native heath. The observed buildup of
Gonaxis on Agiguan is not ipso facto evidence that there is
present an inherent capacity for controlling snails by predation.
A survey of the ecology of Agiguan was not made prior to the
release of Gonaxis and the observed results today therefore
cannot properly be evaluated. This is especially the case since
the bases of evaluation used in the several expeditions to
Agiguan are of different caliber and are therefore not resolvable
to comparison. Only a beginning has been made on a determi-
nation of the gustatory affinities and idiosyncrasies of Gonaxis;
but even with an exhaustive examination and testing in the
laboratory, there is no way of predicting for certainty what
will take place in the field at the population level. Nor can
one safely speculate transphyletically from the classical ex-
amples of biological control in the insect world.

As to the potential dangers, there are several. If the estab-
lishment of other foreign snails is any criterion, Gonaxis, once
established, will not be eradicated. Such is a road on which
there is no turning back. Furthermore, secondary foci will
unavoidably develop in spite of internal quarantines or other

Oct., 1955] THE NAUTILUS 39

measures to check their spread. What the snails will do in
Louisiana and Florida is anybody's guess. In the Pacific
Islands, the greatest potential danger is the irretrievable loss,
even before they can be studied, of the endemic snails, which
because of their secretive habits form precious ''keys" indeed
for unlocking the vast zoogeographic storehouse of the Pacific.
And now that snails are known to carry disease of their own,
still another item of precaution has made its appearance. It
may be apropos to recall at this point that Gonaxis was reported
last year to be dying off inexplicably in appreciable numbers
in the area of its first release on Agiguan.

In view of these fragmentary data, what sort of prognostica-
tion can be made at this early date ? Actually, until it is known,
among other things, just how much chilling Gonaxis can with-
stand, any prognostication can be hardly more than speculation.
In the warmer regions of this country, such as the areas where
H. aspersa is damaging citrus, Gonaxis probably will be able to
survive. In spite of the fact that Gonaxis has demonstrated its
ability to tolerate fairly long periods of drought in coastal East
Africa, there is less certainty about its ability to survive in the
open, grassy, usually very dry banks of the Tiajuana River
where H. aperta has become so thoroughly established in the
past few years. Gonaxis has the habit of burrowing three to
four inches below the surface of the ground during unfavorable
conditions; this may possibly permit it to escape the effects of
frost or near-frost temperatures. But it might not. Therefore
there is no way of predicting how far north in the United States
secondary infestations might become successfully established.
Snail-infested greenhouses quite probably will form the outposts
of penetration.

In areas where environmental conditions are suitable, Gonaxis
will build up in numbers, but subsequently it will go into a de-
cline. The resultant residual population will reflect the effects
of the selecting force of the environmental factors. Since the
complement of environmental factors will be different from that
of the autochthonous area, there might well be commensurate
differences in the populations — depending, of course, upon both
the genetic makeup of the introduced specimens and the relative
genetic stability of the species. But the introduced specimens
will have come from a population which has already suffered

40 THE NAUTILUS [Vol. 69 (2)

the modifying effects of a strange environment in Agiguan!
Whether any acceptable foreign environment or combination of
foreign environments can influence, through a number of gen-
erations, the formation of a population of individuals with strik-
ingly different feeding habits, is problematical, but certainly it
is not impossible. Nor would change of feeding habits consti-
tute a reversal of evolution, for herbivorousness and carnivorous-
ness are merely the extremes of a flexible scale of omnivorousness
on which there is every possible intergradation. It is the nature
and affinities of the individuals of the residual population which
will determine the relative success of the proposed experiment —
and no one can contemplate these.

Finally, there is a very great chance that if Gonaxis can be-
come established, it will eventually settle down in a semblance
of endemicity, doing little good or little harm save possibly the
extinction here and there of a localized endemic snail for which
it has developed an especial appetite. Conversely, there is a
slim chance that it will make considerable and permanent in-
roads in the populations of the introduced helicines; and it is
on this that the authorities concerned are pinning their hopes.
With the odds and penalties so great, it is questionable, in the
present seriously inadequate state of our knowledge that the de-
cision to introduce Gonaxis kibiveziensis into continental United
States and in the islands of the Pacific is a wise one at this time.
But in an adjudged emergency, with its unfortunate concomitant
''pressures," any measure that holds even the faintest promise
of success, irrespective of so-called "minor side effects," is con-
sidered by many to be worth trying. As one has said, ''When
crops are at stake, one cannot afford to be a conservationist."
But there is also an old adage, "The remedy is worse than the
disease. ' '

NEW AND LITTLE-KNOWN MEXICAN HELICIDAE
(MOLLUSCA, PULMONATA)

By ALAN SOLEM

Museum of Zoology, University of Michigan

During the author's tenure as Jessup Fellow at the Academy
of Natural Sciences of Philadelphia from June through August

Oct., 1955] THE NAUTILUS 41

1955, preliminary studies were raade towards a revision of the
Mexican Helicidae. Since completion of the study will be de-
layed, the figuring of two previously unfigured species, descrip-
tion of a new Humholdtiana and addition of several locality
records to the range of H. durangoensis Solem seem worthwhile.
I am indebted to Dr. Harald A. Rehder of the United States
National Museum (USNM) for the loan of type material, to
the Jessup Fund Committee of the Academy of Natural Sci-
ences (ANSP) for their financial support and to Dr. Henry A.
Pilsbry for his invaluable advice.

HUMBOLDTIANA QUERETAROANA Dall PL 3, figS. 4, 5, 6

(see Nautilus 11 (7) : 73)

The unique holotype (USNM 134691) from 8000-9500' at
Pinal de Amoles, Queretaro, Mexico, is a high-spired, bandless
shell of the same degree of granulosity as humholdtiana Pfeif-
fer, nuevoleonis Pilsbry, huffoniana Pfeiffer and taylori Drake
(see Pilsbry 1927: pi. 13, figs. 2-3). It differs from all of
these in its higher spire, lack of color bands and prominent
white axial streaks. The sculpture, umbilicus and apertural
callus are nearest to huffoniana Pfeiffer and further collecting
may show that queretaroana is only a high-spired, bandless
subspecies of huffoniana. The less depressed apex mentioned
by Dall may have been the result of an injury, since the shell
has a slight break just below the embryonic whorls. The high
spire is more characteristic of the durangoensis complex, but
the lack of color bands, much heavier sculpture, smaller nuclear
whorls and less deeply impressed sutures ally queretaroana to
the humholdtiana series.

HUMBOLDTIANA DURANGOENSIS Solcm

(see Nautilus 68 (1) : 4-6, pi. 1, fi^s. 2, 6)

Apparently H. durangoensis is the common species of the
Sierra Madre Occidental from the drainage basin of the Rio
Mezquital near Durango city, north to the Rio Mayo in SW. Chi-
huahua. Specimens from Tepehuanes (105° 42', 25° 22') (USNM
198517), El Bonete (105° 55', 24° 55') SW. of Santiago Papa-
squiaro at 8000' (ANSP 164047) and at 9000' on the trail from

42 THE NAUTILUS [Vol. 69 (2)

the town of Pueblo Nuevo (105° 24', 23° 24') to the Metates
lumber camp, Durango (ANSP 164053), give additional locality
records near the northern edge of the Rio Mezquital drainage.
The actual basin of the Rio Mezquital is inhabited by an un-
described Hum'boldtiana which probably extends into Zacatecas
and Aguacalientes (ANSP and USNM undescribed specimens).
Near Concepcion del Oro in eastern Zacatecas, another species,
H. chrysogona Pilsbry is found (ANSP 164055 and ANSP
164067). In SW Chihuahua, shells from Lareto (ANSP
188914) and the Sierra Saguaribo (ANSP 195108) on the Rio
Mayo are juvenile, but not conchologically separable from the
southern Durangan shells. Adult specimens from 65 mi. E. of
Batopilas (approx. 106° 40', 26° 35') near the Rio Verde
(USNM 251794) also seem to be durango ensis. The exact
boundary between durangoensis and the hogeana group remains
uncertain, but will probably be found in southern or central
Chihuahua.

The numerous fine granulations, dull color, large nuclear
whorls and many white color streaks easily separate durango-
ensis from the liumholdtiana series. The specimens from El
Bonete are quite large, the largest individual being 45.9 mm.
in diameter, 41.1 mm. high with 4% whorls.

HUMBOLDTIANA PERGRANULOSA, UCW SpCCicS PL 3, figS. 1, 2, 3

Diagnosis: A Humholdtiana the size, shape and coloration
of the humholdtiana Pfeiffer series, but allied to durangoensis
by its impressed sutures, large nuclear whorls and umbilicus.
It differs from both groups, and all other Humholdtiana, in the
very large granulations, hence the name pergranulosa.

Description: Shell large, solid, helicoid. Whorls 41/4, rap-
idly increasing in size with moderately impressed sutures. Nu-
clear whorls lyo, large, smooth, with a brown band below. Next
whorl worn, with only a few minute granulations. Penultimate
and body whorl with very large (0.05-0.75 mm.), numerous
white granulations. Ground color light chestnut, with three
reddish-brown spiral bands, the upper slightly wider than the
lower two. Aperture ovate, parietal callus almost absent. Lip
broken, but basal and columellar portions are slightly reflected.

THE NAUTILUS 69 (2)

PLxVTE 4

Boryssa hohenaclcrl form Vapplen.

THE NAUTILUS 69 (1

PLATE 3

1, 2, 3, Humholdtkiyia pergranulosa. 4, 5, 6, H. queretaroensis. 7,
Lysinoe sehastiana. 10, 11, Conns mcgintyi.

Oct., 1955] THE NAUTILUS 43

Diameter 42.5 mm., height 40.7 mm.

Type locality : San Jose Range Mts., Durango, Mexico.

HoLOTYPE : ANSP 194820, ex Brooklyn Museum.

Remarks: The size of the granules at once separates per-
granulosa from all the other Hunih oldtiana. The general ap-
pearance of pergranulosa is perhaps nearest to durangoensis,
but the tremendous difference in size of sculpture alone makes
separation advisable.

The exact location of the San Jose Mountains was not speci-
fied. There are nine towns named San Jose in Durango, but
the most probable location is in NE. Durango near the town of
Jaralito. The U. S. Army Mexican Air Navigation Map N-G
13-North shows a Cerro San Jose (104° 15', 26° 12') located
near a spur of the Mexican National Railways just north of
Jaralito. The isolated nature of the mountain and proximity
to the railroad make it rather probable that such a striking
endemic could have developed and yet been accessible to col-
lectors in 1903.

Lysinoe sebastiana Dall PI. 3, figs. 7, 8, 9

(see Nautilus 11: 74-75)

The unique holotype (USNM 251792) was collected by Nelson
in a canyon near Milpillas, about five miles from San Sebastian,
Jalisco, Mexico on March 16, 1897. The elevation was between
3850' and 6000'. A second specimen (UMMZ) was collected by
I. J. Cantrall at 6650' on the Sierra Autlan about 20 miles SSB
of Autlan, Jalisco. The Autlan shell is in much better condition
and has been figured for that reason. To Dall's description it
might be added that the last whorl descends sharply and the
lip is slightly reflected and thickened.

The Autlan shell is much smaller than the holotype and has
umbilical and a sub-peripheral color bands which the type
lacks. The comparative measurements of the two shells are:

Holotype: diameters 41.6 and 33.2 mm.; height 0.03 mm.; 4i/i

whorls.
UMMZ: diameters 32.1 and 28.1 mm.; height 24.1 mm.; 41/2

whorls.

44 THE NAUTILUS [Vol. 69 (2)

L. sehastiana is obviously related to L. eximia (Pfeiffer)
from Guatemala, but differs in having a keeled periphery, less
strongly reflected lip, darker color and finer sculpture. A
fully relaxed animal of sehastiana was obtained and a study on
the anatomy will be published later.

ANATOMY OF THE VENEZUELAN GASTROPOD,
DORYSSA KAPPLERI

By R. TUCKER ABBOTT

Pilsbry Chair of Malacology, Academy of Natural Sciences
of Philadelphia

This is a brief account of the gross anatomy of one of the
two fresh-water species of mollusks obtained on the Franco-
Venezuelan Expedition to the upper reaches of the Orinico
River in 1951-52. This was a government sponsored expedi-
tion led by Major Franz Risquez, F. A. V. Dr. Luis Carbonell
collected a total of 100 fresh-water specimens in four localities
along the river. Samples of the shells are in the Museo de
Ciencias Naturales in Caracas, the U. S. National Museum in
Washington, D. C, and the Museum of Comparative Zoology
at Harvard College, Massachusetts.

The accompanying anatomical drawings depict the gross
anatomy of Doryssa JiohenacJceri Philippi, form kappleri Vern-
hout 1913. The other species, which we did not dissect, is
Doryssa decollata Lamarck 1822. The latter differs from
hohenackeri in having very distinct decussate sculpturing which
may be seen in the illustration of Lamarck's type (Mermod, G.,
1952, p. 72, fig. 134-3). We do not think that Haltenorth and
Jaeckel (1940, p. 112) were justified in considering these species
as the same.

Doryssa hohenackeri, form kappleri Vernhout

D. kappleri was found in large numbers clinging to the rocks
in the rapids of the upper reaches of the Orinoco River. The
pH of the water was 5.7, a slightly acid condition likely re-

Oct., 1955] THE NAUTILUS 45

sponsible for the eroded spires of all specimens. An aquatic
plant (Podostemonaceae) was found associated with the snails.
Dr. Carbonell reports that these moUusks are eaten by the
"Waica (Oiaca, Uaica, Guaica, Uaika or Waika) Indians of
that area.

The collecting localities are all on small tributaries of the
Rio Orinoco in Territoria Amazonas: La Esmeralda (May 20,
1951) ; Randal Guaharibo (July 20) ; Ugueto; and Salto Boba-
dilla (Sept. 29).

Shell. — Turreted conic, with the early whorls eroded away;
length of adults varying from 25 to 40 mm., wddth 10 to 15 mm.
Early whorls with almost flat sides, becoming increasingly
rounded in the last three or four whorls. In young specimens,
periphery of whorl rather sharply angulate, but in adults the
last whorls are gently rounded. Aperture broadly oval and
almost as wide as high. In adults, the outer lip is usually
thickened on the outside, particularly at the shoulder. Colu-
mella very short, flattened laterally, and advanced at the base.
Shell smoothish, except for microscopic lines of growth. Spiral
sculpturing very weak, consisting of three to seven fine grooves
which are more prominent just below the suture. Lowest part
of the base of the shell with three to four w^eak, rounded spiral
threads. Suture smooth, finely indented, and with the upper
whorl slightly overhanging. Color of shell light-yellowish brown
to dark olive-yellow with numerous, irregularly-placed and —
shaped spots of dark chestnut-brown which in places coalesce
to form short, axial flammules.

Animal (PL 4, figs. a-j). — The animal is typical of that found
in the pleurocerid prosobranchs, having a broad, anteriorly bi-
furcate proboscis and relatively short tentacles with rather
swollen eye bases. The color of preserved animals is dark black-
ish gray to black. Operculum chitinous, transluscent-brown
and multispiral. The only unusual feature noted in the anatomy
are the numerous, blunt papillae that line the wall of the
esophagus and crop. Each of the papillae, which are possibly
secretory in function, is embedded with fine clumps of melanistic
granules. The two otocysts located at the base of the cerebral
ganglia are elongate in shape and each contains about 100

46 THE NAUTILUS [Vol. 69 (2)

variously-sized, oblong otolith crystals. The gills consist of about
200 low lamellae that are welded to the mantle. The inner
wall of the buccal opening is strongly plicate longitudinally.
Behind are two light-tan, translucent jaws. The radular ribbon
is long, consisting of about 105 transverse rows of teeth. The
first 20 rows are exposed and used for rasping.

DoRYSSA DECOLLATA Lamarck

Thirteen immature specimens, of which the largest is 20 mm. in
length, were collected at Ugueto, and seem referable to Lamarck's
species, D. decollata. They are characterized by a very distinct
microscopic sculpturing which is very evident in the rather thick
periostracum. The periostracum has strong spiral and axial
threads which cross at right angles to give a woven-cloth or
beaded appearance. The shells differ from kappleri in having
a flatter-sided spire of about 28° to 30°, while the former has
a spire angle of about 22° to 25°. The color markings are more
suffused and darker. The spiral threads at the base of the
shell are much stronger. The operculum is the same.

Literature Cited

Haltenorth, Th. and S. Jackel. 1940. Ueber einige am Rio
Jary im Nordwesten Brasiliens von der Schultz-Kampfhenckel-
Expedition 1935-37 gesammelte Mollusken. Archiv fiir Mol-
luskenkunde, vol. 72, no. 4, pp. 97-112.

Mermod, G. 1953. Les types de la Collection Lamarck au
Museum de Geneve. III. Revue Suisse de Zoologie, vol. 59,
no. 2, pp. 23-97 [72], figs. 94-153.

Vernhout, J. H. 1913, The Non-marine Molluscs of Surinam.
Notes from the Lyden Museum, vol. 36, pp. 1-46, 2 pis.

PI. 3, figs. a-j. Doryssa hohenacTceri, form Tcappleri. A, entire animal
with its shell removed; B. operculum; C. otocyst and its otoliths; D. view
of esophagus showing the papillae in cross-sections; E, jaws showing
detail of structure; F. entire radular ribbon; G, four views of the central
tooth; H. lateral tooth; I inner marginal; J. outer marginal. (cm =
columellar muscle ; cr = crop ; di = digestive gland ; ft = foot ; gi = gills ;
go z= gonads ; hy = hyaline sheath ; ms = muscle scar ; op = operculum ;
pr = proboscis ; ra = radula ; re = rectum ; st = stomach ; te = tentacle.)

Oct., 1955] THE NAUTILUS 47

ANOTHER FLORIDAN CONUS

By H. A. PILSBEY

CoNus MCGiNTYi new species Plate 3, figures 10, 11

Shell rarely reaching 2 inches in length, long, narrow, rather
thin, of about 12 whorls, including a glassy-smooth nucleus of
nearly 3 whorls. Spire extended, slightly concave, with the
carina (immediately above suture) prettily beaded on the early
whorls, the tubercles gradually becoming subobsolete on the
last whorl. There are 4 to 6 lightly wrinkled threads on the
sloping whorls of the spire. Body-whorl long, nearly flat-sided,
with spiral sculpture of flattened smooth cords separated by
slightly narrower grooves which are crossed by delicate axial
threads giving the surface a punctate appearance. Aperture
oblique, long and narrow. Color cream with dots or blotches
of light shades of brown, which are often arranged in spiral
rows, or streaked and diffused longitudinally. Periostracum
very thin^ straw colored. No operculum.

Holotype: Length 41.6 mm., greatest width 11.7 mm., length
aperture 30.5 mm., ANSP No. 193858, dredged 165° off Pensa-
cola, northwest Florida, by T. L. Moise, yacht ''Escape,"
July 12, 1954.

Figured paratype : Length 42.1 mm., greatest width 13.5 mm.,
in the McGinty collection, dredged living off Palm Beach,
Florida, in 70 fathoms, bottom mud and broken shell, "Triton"
Sta. 1256, August 24, 1953. Paratypes in the McGinty collec-
tion from off Palm Beach, Sombrero Key Light and Key West.
Paratypes in the collections of Dr. Jeanne S. Schwengel and
Mr. Arthur R. Thompson from the "Triton" dredgings. Depth
range known for live specimens in 70 to 120 fathoms.

This unusual cone has been figured in recent shell literature
as Conns mazei Deshayes. ("Johnsonia" No. 6 by William J.
Clench, Plate 9, figures 1 and 2; "American Seashells" by R.
Tucker Abbott, in color, Plate 14 K.) Mr. Axel A. Olsson when
abroad last summer examined the holotype of Deshayes in the
Paris Museum and he agreed with the conclusion I had formed
from a study of the description, that there are two distinct
species which in Florida have passed under the old name of
C. mazei. For the specimens which are uniformly sulcate all

48 THE NAUTILUS [Vol. 69 (2)

over the body whorl, the new name Conus mcgintyi is proposed.
The true C. mazei, from Martinique in 50 fathoms, is apparently-
known only from the unique type of Deshayes. It differs con-
spicuously from this new species by the smooth, shining sur-
face of the body-whorl and the regular brown spots arranged
as in Scaphella junonia.

There are several slender, strongly sculptured fossil cones, of
which C. gracilissimus Guppy from the Miocene of Jamaica
appears to be the nearest to mcgintyi.

The type of this cone was collected dead, but Mr. Thomas L.
McGinty has supplied the following details from living speci-
mens dredged by the "Triton." The animal is a dull yellow
with the sides of the foot and the area around the head peppered
with small black dots. A marginal tooth from the toxoglossate
radula is shown in figure 10. The tooth has two barbs on one
side and is very small, .19 mm. length. The camera lucida
drawing was made 310 X. While making a microscopic exami-
nation for an operculum, a pair of very minute mandibles was
found, probably, from a very small Cephalopod eaten by the
cone.

This striking new cone is named for Thomas L. McGinty.

SOME MALACOLOGISTS OF THE NEW YORK AREA

By MATHILDE P. WEINGARTNER
Staten Island Institute of Arts and Sciences

During the latter part of the 19th century and the early part
of the 20th there appear in the annals of malacological history
a few names of men who lived or worked in the New York area,
and who, not only because of the hobby they pursued, but
because of the people that this hobby brought together, led
very interesting lives.

These men may have had demanding jobs in the economic
struggles during their lifetime, but either as a diversion or as
a long delayed hobby in their older years, they took up natural
history. Most of them were well acquainted with each other
and spent a great deal of time in the field. They collected ex-

Oct., 1955] THE NAUTILUS 49

tensively, exchanged notes on their collections, and enriched
more than one museum with their finds. Here, after consider-
able research, are a few glimpses into their very interesting
lives.

Temple Prime was born at 1 Battery Place, N.Y.C. on
September 14th, 1832, the son of Rufus Prime. He was edu-
cated abroad, and upon his return took a course at Harvard
Law School. He was for some years connected with the United
States Legation at The Hague. When this service was over he
returned home and, as he had an ample fortune, he never en-
tered upon the practice of his chosen profession, but spent his
time managing his large estate at Huntington, Long Island. He
wrote a genealogy of the Temple family, which apparently
stemmed from English nobility.

In conjunction with Sanderson Smith he wrote A Report on the
Mollusca of Long Island published in theAnnals of the Lyceum
of Natural History, Vol. 9 (1870). He described the little
Gemma manhattensis, but his chief work was on the fresh water
fingernail or pea clams, publishing many papers on the Corbi-
culidae (+ Sphaeriidae) in the Proceedings of the Academy of
Natural Sciences of Philadelphia, the Annals of the Lyceum
N. H. of N. Y. and elsewhere. His magnum opus was the
^'Monograph of American Corbiculidae," in the Smithsonian
Miscellaneous Collections, no. 145 (1865). Though now long
past its useful times, this 90 year old monograph remains our
only American manual of this ubiquitous and very difficult
family. Prime's collection was left to the M. C. Z.

Silas Carmi Wheat was born in Franklin, N. Y. on De-
cember 11, 1852. He was graduated from the Delaware Li-
brary Institute in 1876. After many years of teaching he
received from New York University in 1898 the degree of
Master of Pedagogy. From 1894 until his death he was a
resident of Brooklyn, N. Y. In 1910 he became president of
the New York Men's Teachers Association. The impetus of
his strength is still felt in New York educational circles today.

But for his work as a scientist he will perhaps be most
widely recognized and longest remembered. He wrote many
articles on nature topics. He was long a member of the
Conchological Society of Great Britain and Ireland. For the
State Museum in Trenton he prepared a Report on the Mollusks

50 THE NAUTILUS [Vol. 69 (2)

of New Jersey and for the Brooklyn Institute of Arts and Sci-
ences he wrote a similar Report on the Mollusks of Long Island.
He contributed several papers to the Bulletin of the Brooklyn
Conchological Club (1907), of which he was President, one of
them a ''List of Long Island Shells." He also wrote a genea-
logy of the Wheat family. He was an honored member of the
Brooklyn Entomological Club as well as the Brooklyn Concho-
logical Club. He died suddenly on September 1st, 1922.

A contemporary of the previous two gentlemen was Louis
Pope Gratacap. He was born in Brooklyn on November 1st,
1851, the son of John and Lucinda Gratacap. He was gradu-
ated from the College of the City of New York in 1869, and
from the Columbia School of Mines in 1876. The family had
moved to Staten Island many years before, and it was from here
that young Louis attended college, a tedious journey in the days
of slow ferries and horse cars.

He was connected with the American Museum of Natural
History from 1876 on and became Curator of Mineralogy in
1881. With one assistant, Mr. Quinn, he not only kept the
great collection of this museum, both mineral and shells, in
excellent order, but he found time to give the displays artistic
settings. His writings were of a varied character. Among
them were: Vade Mecum Guide to Mineral Collections, Broad-
way Press, N. Y. (no date) ; three editions of the Geology of
The City of New York, Henry Holt & Co., and Brentano, N. Y.,
1901, 1904, and 1909. His principal conchological papers were
a catalogue of the Binney & Bland Collection in the American
Museum, and several articles published in Nautilus, 1906 to
1914. His non-scientific writings include: Substance of Litera-
ture, Frank Rogers, N. Y., 1913; Philosophy of Ritual, James
Pott & Co., N. Y., 1887 ; Analytics of a Belief in a Future Life,
James Pott & Co., N. Y., 1888; and novels like A Woman of
the Ice Age, Brentano, N. Y., 1906 ; Benjamine The Jew, Thomas
Benton, 1913 ; and The Evacuation of England, Brentano, 1908.

As a lecturer Mr. Gratacap had few equals. Not only did
he have original ideas, but these were expressed through the
medium of a remarkable vocabulary. He never cared to go
into public life but lived quietly with his brother. Pie had a
great many friends and was always helpful to them both with
kindly acts and financial aid.

I

Oct., 1955] THE NAUTILUS 51

In 1881 he became a member of the Natural Science Associa-
tion of Staten Island, and from 1887 to 1888 he was president
of this organization. From 1884 to 1901 he contributed twenty-
four papers to the Proceedings of this institution among them
a Memorandum on Lymnea palustris, Vol. 11, May 1891. In
this paper he described an experiment he carried on with these
snails, maintaining them in very cold water over winter. He
found that they survived, and he watched them breeding the
following spring. Other authors had believed that they wintered
in the form of eggs, a fact now disputed by Mr. Gratacap. His
busy life ended in December 1917, and he is buried in the
family vault in the churchyard at Trinity Church, Manhattan.

Another Staten Islander who gained fame in the malacological
world is Sanderson Smith. He was born in London, England,
in 1832 and died in Port Richmond, Staten Island, in 1915.
Little seems to be recorded about his early life and education,
but he was well known for the work he did for the United
States Fish Commission.

From 1881 to 1893 Mr. Smith was engaged by the American
Museum of Natural History to catalogue, label, and arrange
the shell collections, under Professor R. P. Whitfield.

He was elected first president of the Natural Science Associa-
tion of Staten Island in 1881 and made a number of contribu-
tions to the Proceedings of this organization. Among these
were: Notes on the Mollusca of Staten Island, Note on the
Distribution of Littorina Littorea, Note on Limax Maximus and
Notes on the Shells of the John J. Crooke Collection.

Of great interest to the local malacologists are: A Catalogue
of Mollusca of Staten Island, A Catalogue of Mollusca of Little
Gull Island, Suffolk County, N. Y., and his earliest paper, On
the Mollusca of Peconic and Gardiner Bays, Long Island which
was read before the New York Lyceum of Natural History on
December 5th, 1859, and printed in their Annals in 1862. The
other two papers were printed in the Annals of the Lyceum of
Natural History in 1867.

Mr. Eber Ward Hubbard, according to Leng and Davis'
Staten Island and its People, was born October 8th, 1797 in
Jefferson County, N. Y. He practiced medicine in La Grange
and Elmyra, Ohio, before he settled in Tottenville, Staten
Island. As an avocation he studied shells and, with Sanderson

52 THE NAUTILUS [Vol. 69 (2)

Smith, published that first Catalogue of Staten Island Mollusca
in 1865, which later appeared in the Annals of the Lyceum. In
this report his name is erroneously given as J. W. Hubbard.
He died May 7th 1872.

John J. Crooke, another of Staten Island's naturalists and
collectors was born in Columbia County, N. Y., in 1824. He
came to Staten Island and purchased a large tract of land on
the south shore of the island, where he built his house. This
point of land for many years bore his name, Crooke's Point,
until the New York City Department of Parks took over the
area and called it ''Great Kills Marine Park." Mr. Crooke
purchased and collected numerous natural history objects, in-
cluding herbarium specimens and shells. These later found
resting places in libraries and museums.

Sanderson Smith was given the job of going over the shell
collection which Mr. Crooke had accumulated, but he did not
find anything new to add to the list of local shells. Mr.
Crooke's collection consisted mainly of land shells, and, as
such, was a rather complete one. He not only had a great deal
of local material, but a large collection of shells from the West
Indies and South America assembled by Thomas Bland, and a
collection of land shells from the Pacific Islands by William
Harper Pease. Mr. Crooke does not seem to have interested
himself in marine shells, as his collection of such was a very
small one. Mr. Crooke's shells were presented to the American
Museum of Natural History.

Thomas Bland, 1809-1885, one of the great figures in
American land shell lore, was born in England, but he resided
for more than thirty years of his life in New York City. He
had lived for a time in Barbados, Jamaica and in Colombia,
and became deeply interested in West Indian land shell faunas.
Upon coming to New York he took up the study of United
States land shells, and collaborated with W. G. Binney in sev-
eral important publications. Bland was author of more than
70 papers, dealing with West Indian and North American land
shells, their distribution and relationships.

Perhaps Staten Island's foremost naturalist and collector was
William Thompson Davis. ''One Davis," as he liked to refer
to himself, was born in 1862 into an old Staten Island family,
the Thompsons, and an equally fine New England family, the

Oct., 1955] THE NAUTILUS 53

Davises, of Freetown, Massachusetts. He grew up with his
mother's people, and his only formal schooling came from two
Staten Island private schools. From early childhood he was
interested in flowers, plants, insects, mammals, and any other
natural phenomenon.

From 1883 to 1909 he worked faithfully at a book-keeping
job for the New York Produce Exchange. Being of a frugal
nature, he accumulated a small sum of money which, wisely
invested, brought back a comfortable living, so that he could
devote himself to his hobbies from 1909 on. His main interest
was entomology, but he by no means neglected other fields of
nature. Having always gone afield and collected natural ob-
jects, he did not neglect shells. Among other specimens, among
those carefully put away in shirt boxes, cigarette boxes, or
vials was a Mya arenaria, from whose grip he had released a
hapless sandpiper. All his specimens were carefully labeled, ex-
cept that the location given may be rather vague, such as ' ' South
Shore, S.I." This was due to the fact, perhaps, that Mr. Davis
was always conservation-minded and afraid that someone else
might go to the location and collect to excess. Mr. Davis carried
on a lively correspondence with many naturalists, and concho-
logists, such as Silas Wheat. In the Proceedings of the Staten
Island Institute of Arts and Sciences he also wrote about the
first occurrence of Littorina littorea, this being a milestone in
the migration of this mollusk along the Atlantic coast.

''Willie Davis" or ''Uncle Billie," as he was affectionally
called, will long be remembered by his friends, of whom he
made many in almost 80 years of nature rambling.

Many museums in the New York area can give thanks to the
diligent work that these men have contributed in the field of
malacology.

A NEW CLAM INDUSTRY IN NEW ENGLAND
By HENRY D. RUSSELL

A new deep ocean clam industry, dredging Arctica islandica
Linne, was incorporated in Massachusetts in February 1954.
This company. The Cape Cod Shellfish Corporation, was founded

54 THE NAUTILUS [Vol. 69 (2)

as a result of pioneering surveys carried forward by the Woods
Hole Oceanographic Institution during 1949. These surveys
indicated that there were beds of A. islandica in commercial
abundance south of Cape Cod and in Massachusetts Bay.

The purpose of this company was to dredge these clams,
eviscerate, chop, freeze them and attempt to meet the ever in-
creasing demand for frozen sea foods for the institutional and
restaurant trades. The use of polyethelene bags prevents
contamination and loss of flavor and insures a high degree of
sanitation for the chopped meats which are frozen in five pound
blocks, ten blocks to the case. A large plate-type freezer freezes
one and one-half tons in two and a half hours and the removed
frozen blocks are then ready for distribution or storage at —10°
F. at which temperature they keep for six months to one year
without deterioration.

The processing plant is located on the south bank of and at
the eastern end of the Cape Cod Canal. Here the vessels can
come alongside the dock and unload their deck cargos of culled
and washed clams directly into a conveyor leading to the
shucking room. Five minutes after the two-bushel, mud-free
boxes of clams are unloaded from the dredging vessel they are
on the tables in the shucking room and ready for removal of the
shells. An experienced shucker can shuck clams at a rate of one
every 3-5 seconds. A deft turn of the shucking knife sends
the shells into an empty 50 gallon drum and the meats into a
ten-quart stainless steel pail perforated with small holes.
Through these holes the clam juice drips into a second pail where
it is caught, later to be strained and frozen in one-gallon tins.
It is used chiefly for clam bouillon, adding flavor to clam
chowders and for clam juice cocktails.

As the stainless steel buckets are filled with clam meats, they
are passed through a window to the processing room. Here
the clams are eviscerated which removes the dark digestive
gland, gonads, stomach and intestine. The next step in the
process takes the eviscerated meats to the washer, a large
circular stainless steel tank three feet in diameter by two and
a half deep. Here they are stirred and agitated in water
through which air is forced under pressure, thus turning them
over and over and washing off any bits of broken shell or ad-
hering mud. Cleaned after five minutes, they are released from

Oct., 1955] THE NAUTILUS 55

the bottom of the tank and poured onto a drain board. Next
they are cut into approximately %-inch pieces and then weighed
out into five pound lots which are poured into polyethelene
bags. When a truck load of these five-pound bagged lots in
their respective waxed boxes has accumulated, it is sent to the
freezer a few miles away and the freezing and storage process
begins.

In addition to the shucking and processing rooms, there is a
second floor laboratory in the plant where the biology of A.
islandica is under investigation and where a dietician devises
new recipes and uses for clam products.

This is but half the story, however, for it is the action on the
dredging vessels that is the stimulus for the events that take
place in the plant. Leaving the Cape Cod Canal early in the
morning to take advantage of calm weather conditions, the
dredging vessels arrive at the dredging grounds one to one and
one-half hours later. The two iron, 16-toothed, dredges with
their 7-foot iron ring bags are then lowered by a steel cable one
over each side. Feeling the vibration of the cable an experi-
enced fisherman can determine manually when the dredge is
on bottom, in general, what type of bottom, and whether the
dredge is fishing properly or not. After 20-30 minutes, the
dredge is brought to the surface, the draw strings of the iron
ring bag are pulled and the contents dumped on deck. The
catch is sprayed with salt water to wash off any mud and the
culling process begins. Broken shells and extraneous matter
are thrown over the side while whole clams and broken ones
are placed in separate 2-bushel wooden boxes and stacked on
deck. As the first catch is culled and stacked in boxes the
dredge is lowered over the side again and the second one starts
towards the surface where the process is repeated. This series
of events requires about twenty minutes so that it is about time
to haul the second dredge as the first one is lowered for the
second time. When a deck load has been gathered the vessel
returns to the plant where processing begins. Thus within
twenty-four hours of the time the clams leave their ocean bed
they are cleaned, frozen and ready for distribution. Their
distribution during the first year of operation has taken A.
islandica from Cape Cod south to Norfolk, Virginia, westward
to Oakland, California, into many hotels and restaurant chains

56 THE NAUTILUS [Vol. 69 (2)

in the northeastern and middle Atlantic states and into many
Massachusetts State Institutions.

After each day 's work both the shucking and processing rooms
and the apparatus in them are thoroughly washed with hot water,
soap or disinfectants, as a high standard of sanitation must be
maintained and the rooms are made ready for the next day.

The officers of the new company are Mr. William C. Waugh,
President, Mr. Charles T. Russell, Jr., Treasurer and the author
as Secretary.

MINNESOTA LAND SNAILS

By CHARLOTTE DAWLEY

The purpose of this paper is to summarize the present knowl-
edge of the land snails of Minnesota, exclusive of slugs. It
is based largely on the collections housed in the Zoology Depart-
ment of the University of Minnesota which were started in the
1880s by members of the Geological and Natural History Sur-
vey.

Minnesota is almost in the center of the northern tier of
states, directly south of Ontario and western Manitoba. Most
of the state is gently rolling or level, with an average elevation
of about 1200 feet above sea level. All except the extreme
southeastern tip has been glaciated at least once, and the effects
are still visible in the many lakes and swamps.

Vegetationally there are three regions — coniferous forest,
deciduous forest, and prairie. The northeastern third of the
state was originally coniferous forest, with white pine, red pine,
jack pine, white spruce, balsam fir and white birch in the well-
drained areas, and black spruce, tamarack, and white cedar in
the swamps. Much of this region is not a good habitat for
snails, the soil being poor and with very little lime, but many
of the smaller species are found in the wetter places and in the
islands of maple-basswood found here and there among the
predominating conifers.

Bordering the coniferous forest on the west and south was a
strip of deciduous forest, narrow in the northwest, broadest
in the central part of the state and narrow again along the

Oct., 1955] THE NAUTILUS 57

Mississippi River to the Iowa line. Oaks predominate in the
northern part. Sugar maple, basswood, elms, and red oak
formed an extensive climax forest in the rich calcareous soils
of the central part, now largely farms. Along the river bot-
toms the flood plain forests contain willow and cottonwood, with
white elm and soft maple on slightly higher ground.

The southwestern part of the state was mostly prairie, with
trees only along streams and around lakes. Very little col-
lecting of land snails has been done in this part of the state.

Land snails are reported from about thirty of the state's
eighty-seven counties. The most concentrated collecting has
been done in four different areas:

1) The southeastern corner of the state, chiefly in Houston
and Winona counties. Underlain by limestone and dissected
by many streams, the wooded hills along the Mississippi River
and its tributaries have yielded many species. Collecting be-
gan in the 1880s with J. W. Holzinger, a professor at the
Winona Normal School, and U. S. Grant of the Geological and
Natural History Survey and has continued to the present time.
North of this area some collecting has been done in AVabasha,
Goodhue, Rice, and Scott counties.

2) The central part of the state around St. Paul and Minne-
apolis, in Ramsey and Hennepin counties. The University of
Minnesota is found here and almost everybody who has been
interested in moUusks in the state has worked in this region.
It is an area of terminal moraines, cut through by the Min-
nesota and Mississippi Rivers. Pine, Chisago and Washington
counties are a few miles to the east along the St. Croix River,
and Anoka and Wright counties lie just north.

3) North central Minnesota. Collecting here has centered
around Itasca State Park in Clearwater County, famous for
containing the source of the Mississippi River. Since 1936
students of Dr. Samuel Eddy at the University of Minnesota
Biological Station have collected here each summer. The most
recent and most extensive collecting was done by Mrs. Marjorie
Harrison in 1949. She also collected farther north around Red
Lake in Beltrami County. L. E. Daniels collected in Marshall,
Pennington, Red Lake, and Becker counties in 1909.

4) Northeastern Minnesota. St. Louis, Lake, and Cook-

58 THE NAUTILUS [Vol. 69 (2)

ties form a triangle north and a little west of Lake Superior.
It is resort country, with many lakes and beautiful woods.
U. S. Grant collected around Tower on Lake Vermilion in St.
Louis County in the 1880s and F. C. Baker in the same region
in 1929 as well as in Itasca County a little farther west. Mrs.
Harrison in 1949 collected in Finland State Forest in Lake
County and on an Indian reservation in Cook County. I have
collected around Hibbing in St. Louis County.

Fifty-five species of land snails, not counting slugs, have been
reported in Minnesota.

Family Polygyridae

Stenotrema hirsutum (Say). Abundant in Winona County,
found also in Houston County. This is the smaller upland
form.

Stenotrema monodon (Eackett). Abundant at Hidden Falls,
a moist, shady glen on the banks of the Mississippi near St.
Paul. Also found in damp places in Winona, Hennepin, Scott,
and Wright counties.

Stenotrema fraternum (Say). Abundant in Nerstrand Woods
in Rice County and at Taylors Falls in Chisago County.
Widely distributed in central and southern Minnesota.

Mesodon thijroidus (Say). Found only in Winona County
where it is abundant in Whitewater State Park.

Mesodon clausus (Say). Several places in Houston County,
and once each in Winona and Ramsey counties.

Triodopsis albolahris alleni ('Wetherby' Sampson). Widely
distributed in southern and central Minnesota.

Triodopsis multilineata (Say). Southern and central Min-
nesota. They all seem to be the small form algonquinensis
Nason, which Pilsbry regards as an ecologic form inhabiting
woods rather than marshes.

Allogona profunda (Say). Southern and central Minnesota,
not found in large numbers anywhere.

Family Zonitidae

Euconulus fulviis (Mliller). Whole state except southeastern
part.

Oct., 1955] THE NAUTILUS 59

Euconulus chersmus polygyratus (Pilsbry). Whole state.
It is difficult to separate E. fulvus and E. cher sinus polygyratus
in our material because of the scarcity of mature forms, but
both species are present.

Retinella indent at a (Say). Houston, Winona, and Hennepin
counties, not abundant anywhere.

Retinella electrina (Gould). Whole state. Common.

Retinella hinneyana (Morse). Keported by F. C. Baker in
Itasca County and by Daniels from Becker and Red Lake
counties.

Hawaii minuscula (Binney). Whole state except north-
eastern part.

Zonitoides arhoreus (Say). Whole state. Very common.

Zonitoides nitidus (Miiller). Central and southern part of
state in wet places. Not common.

Striatura exigua (Stimpson). A northern species, found in
damp woods or bogs. Our largest collection is from a bog in
Itasca Park in Clearwater County, others from Finland State
Forest in Lake County, and the Indian reservation in Cook
County. A single specimen was found in Nerstrand Woods in
Rice County.

Striatura milium (Morse). Whole state, more common in
northern part.

Vitrina limpida (Gould). Rare; northern part of state.

Family Endodontidae

Anguispira alternata (Say). Whole state, more abundant
in the southern part.

Discus cronkhitei (Newcomb). Whole state. Abundant.

Helicodiscus parallelus (Say). Whole state. Common.

Punctum minutissimum (Lea). All parts of state except the
northeastern part.

Family Succineidae

Oxyloma retusa (Lea). Whole state.
Succinea ovalis Say. Whole state.
Succinea avara (Say). Whole state.

60 THE NAUTILUS [Vol. 69 (2)

Family Strobilopsidae

Strohilops labyrinthica (Say). Common in all parts of the
state. The colorless variety virgo is also found.

Strohilops affinis Pilsbry. Central and southern parts. Not
common.

Family Pupillidae

Gastrocopta armifera (Say). Central and southern parts of
state.

Gastrocopta contracta (Say). Whole state except north-
eastern part.

Gastrocopta holzingeri (Sterki). Abundant at Hidden Falls,
Eamsey County. Whole state except northeastern part.

Gastrocopta pentodon (Say). Whole state.

Gastrocopta tappaniana (C. B. Adams). Central and north-
ern parts.

Gastrocopta corticaria (Say). Found in small numbers in
central and northern parts.

Pupoides alhilahris {C.B. Adams). Rare. Houston, Winona
and Ramsey counties.

Vertigo milium (Gould). Ramsey, Hennepin and Pine coun-
ties.

Vertigo ovata (Say). Hennepin, Ramsey and Clearwater
counties, found especially on cattails or grasses on edge of lakes
or SAvamps.

Vertigo elatior Sterki. Hennepin and Clearwater counties.
Not common.

Vertigo ventricosa (Morse). Widely distributed through the
northern part of the state, south to Hennepin County.

Vertigo tridentata Wolf. Rare. Houston, Ramsey, Chisago
counties.

Vertigo nylanderi Sterki. Rare. Found by Mrs. Harrison in
1948 and 1949 at Bear Paw Point in Itasca Park, Clearwater
County.

Vertigo gouldi (Binney). Widely distributed through the
state. Large collections from Itasca Park, Clearwater County
and Tower, St. Louis County.

Columella edentula (Draparnaud). Abundant in Beaver

Oct., 1955] THE NAUTILUS 61

State Park, Houston County. Also found in Winona, Hennepin,
Pine, and Clearwater counties.

Family Vallonidae

Vallonia pulchella (Miiller). Abundant in leaf mold at Isaac
Walton Bass Ponds and Roberts Bird Sanctuary, Hennepin
County. Also collected from Winona, St. Louis and Big Stone
counties.

Vallonia costata (Miiller). Hennepin and Ramsey counties.

Vallonia parvula Sterki. Rare. River flats, Hennepin
County and Tower, St. Louis County.

Vallonia gracilocosta Reinhard. Whole state. Abundant in
Itasca Park, Clearwater County.

Vallonia perspectiva Sterki. Abundant at Hidden Falls.
Ramsey County. Also at other locations in central part of
state.

Planogyra astericus (Morse). Rare. F. C. Baker found
them in Itasca County and Mrs. Harrison in the Finland State
Forest in Lake County.

Zoogenetes harpa (Say.) Rare. Our only specimens were
collected in the 1880s by U. S. Grant from Tower, St. Louis
County.

Family CiONELLroAE

Cionella luhrica (Miiller). Whole state, more common in
north.

Family Carychiidae

Carychium exiguum (Say.) Found in small numbers in
several places in Clearwater and Hennepin counties.

Carychium exile canadense Clapp. Common in leaf sif tings
from all parts of the state.

Family Helicinidae

Hendersonia occulta (Say.) Found in several places on the
wooded hills and wet, rocky ravines along the Mississippi River
and its tributaries in Houston and Winona counties.

62 THE NAUTILUS [Vol. 69 (2)

Family Amnicolidae

Pomatiopsis lapidaria (Say.) Found in wet places in Hous-
ton, Winona, and Hennepin counties.

Literature Cited

Baker, F. C. 1929. Mollusca from Vermilion and Pelican

Lakes, Minn. Naut. 42 : 95-97 ; 131-136.
. 1935. Land and fresh-water Mollusca from North Star

Lake and vicinity, Itasca County, Minn. Amer. Mid. Nat. 16 :

257-274.
Daniels, L. E. 1909. Records of Minnesota Mollusks. Naut.

22 : 119-121.
Grant, U. S. 1885. Conchological notes. Ann. Kept. Geol.

and Nat. Hist. Surv. Minn. 14 : 114-124.
. 1887. Notes on the molluscan fauna of Minnesota.

Ibid. 16 : 481-484.
Holzinger, J. M. 1887. Notes on the Mollusca of Winona

County. Ann. Kept. Geol. and Nat. Hist. Surv. Minn. 16:

485-491.
PiLSBRY, H. A. 1939. Land Mollusca of North America.

Acad. Nat. Sci. Phila., monograph no. 3, v. 1, pt. 2.

SOME ECOLOGICAL FACTORS OF THE SOIL AF-
FECTING THE DISTRIBUTION AND ABUN-
DANCE OF LAND SNAILS IN
EASTERN VIRGINIA ^

By JOHN B. BUECH 2

University of Richmond

The purpose of this investigation was to study land snail ais-
tribution in relation to certain inorganic compounds, hydrogen-
ion concentration, and organic matter present in the soil.

Description of the area. — This study was made during 1952-
54 in Hanover, Henrico, and Chesterfield counties, an area of

1 From a M. S. thesis submitted to the Departm.ent of Biology, Univer-
sity of Richmond, June, 1954. This investigation was supported (in part)
by a research grant from the Virginia Academy of Science.

2 Present address : Museum of Zoology, University of Michigan.

Oct., 1955] THE NAUTILUS 63

1179 square miles in east-central Virginia. The area comprises
two physiographic regions, the Coastal Plain to the east and
the Piedmont Plateau to the west, which merge along a line that
crosses each county, dividing Hanover and Henrico counties
roughly into equal halves and Chesterfield County into an area
about four-fifths of which lies in the Piedmont Plateau. The
fall zone is several miles wide, with no definite boundaries.

The soils of the Piedmont province have been derived mainly
from granite and gneiss formations and comprise primarily the
Durham and Cecil series (Bloomer, 1938). The Cecil series is
the most widespread type of soil occurring over the Piedmont
region. It is a gray, red, or brown loam with a red clay sub-
soil. In its eastern part the Piedmont Plateau has an average
elevation of about two hundred feet above sea level, but it rises
gradually toward the west. What was formerly a plateau is
now so deeply eroded by drainageways that little of the plateau
surface remains.

The Coastal Plain is a region of sand, clay, and other soft
materials, which lie on an eastward-sloping floor of granite and
crystalline rock. The soils differ from those of the Piedmont
in their loose structure, lack of loaminess, the predominance of
sand, and the frequent occurrence of water worn gravel through-
out the soil profile. For the most part the Coastal Plain consists
of a wide plateau trenched by broad, terraced valleys of numer-
ous streams.

The major portion of the two regions is well drained by sev-
eral rivers and their tributaries. The most extensive drainage
system is the James Kiver which flows through the central part
of the area, marking the boundary between Henrico and Ches-
terfield counties. The Appomattox River is the largest tribu-
tary of the James in this area. The drainage system to the
north consists primarily of the North Anna, Little, New Found,
Pamunkey, Chickahominy, and South Anna Rivers.

Materials and methods. — Soil samples were taken at forty-one
stations, picked at random from the one hundred twenty-three
stations visited during a survey of the land Mollusca of this area.
This represented one-third of the total number of stations. At
each of these stations where soil analyses were made all the
snails found in an arbitrarily selected nine square feet of habitat

64

THE NAUTILUS

[Vol. 69 (2)

COLLECTING STATION
SOIL ANALYSIS

AShLAND 'HANOVER^ "^

0 # ,^

■^COUNTY

Fig. 1. Hanover, Henrico, and Chesterfield Counties, Virginia.

were recorded. A liter sample of soil and humus was taken and
analyzed for organic matter, calcium (CaO), magnesium (MgO),
potassium (KgO), and phosphorus (P2O5) by the Virginia Ag-
ricultural Experiment Station, Blacksburg, Virginia. The data
were recorded in terms of availability to plants, the amount
extracted by a weak acid. A flame photometer was used for the
determination of potassium and a photolometer for calcium,

Oct., 1955] THE NAUTILUS 65

magnesium, and phosphorus. The pH values were obtained by
a Hellige colorimeter as soon as the samx-)les were brought in
from the field.

Analysis of soil samples. — The correlation between lime sup-
ply and abundance of land snails is close enough that collectors
recognize the presence of limestone in the form of cliffs and out-
crops as particularly favorable collecting stations. It is to be
expected that snails would also be more abundant where cal-
cium is richest in an area devoid of limestone, such as the area
investigated in this study. The calcium obtained for growth
in these habitats must come directly from the soil, organic ma-
terials of the humus, or from shells of other snails. The number
of snails in this area was found to increase with the amount of
calcium present in the samples, the greatest number of both
species (Table I; Figure 2) and specimens (Table I; Figure 3)
occurring where the available calcium content was 0.075 per
cent or higher. No specimens were found in samples contain-
ing less than 0.019 per cent calcium.

Magnesium has been shown (Clarke and Wheeler, 1922) to
be an important constituent of marine mollusk shells. It might
also be expected essential for land snails. The correlation of
magnesium (MgO) with land snail distribution was somewhat
similar to that of calcium, the majority of the snails being
found where the concentration was 0.018 per cent or higher.
The number of snails also increased with an increase in the
concentration of potassium (KoC^) and reached a maximum at
a phosphorus (P2O5) concentration of 0.002-0.004 per cent, de-
clining for higher concentration. The effect of these two com-
pounds on snail distribution is probably indirect, being impor-
tant in plant metabolism.

The importance of organic matter or food as a limiting fac-
tor in snail distribution has received some attention and Boycott
(1929, 1936) and Oughton (1948) do not consider food, other
than calcium, restrictive. Shimek (1930) is of the opinion that
food is one of the prime factors in the distribution of land snails.
In this investigation a close correlation was found between the
amount of organic matter and presence of snails. Ninety-four
per cent of all snails collected were found where the organic
matter present in the samples was three per cent or greater, and

66

THE NAUTILUS

[Vol. 69 (2)

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very few where concentrations were less. Whether or not the
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food material per se may be questioned, but doubtless it gives
an indication of certain other environmental conditions.

Oct., 1955]

THE NAUTILUS

67

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68 THE NAUTILUS [Vol. 69 (2)

Studies on land snail distribution in relation to soil reaction
have produced varying results (Jacot, 1940; Oughton, 1948;
Atkins and Lebour, 1923 ; Okland, 1930 ; Archer, 1939 ; Stran-
dine, 1941; Lee, 1952; Burch, 1955). Land snails in this area
were found to occur at pH ranges of 4.8-7.7, and most fre-
quently at a pH range of 6.3-6.7. It is the opinion of this
investigator that pH is not a limiting factor in their distribu-
tion and probably has scarcely any influence. The occurrence
of snails within certain pH ranges can be related to numerous
conditions other than soil reaction, such as physical makeup of
the soil, content of available nutrients, and influences of climate
and vegetation.

Summary. — 1. Samples of soil and humus from forty-one
stations where land snails were collected were analyzed for
organic matter, certain inorganic compounds, and hydrogen-
ion concentration.

2. Snails were found to increase with increase in concen-
trations of calcium (CaO), magnesium (MgO), potassium
(K2O), and organic matter. They were found in greatest
abundance at a pH range of 6.3-6.7 and where the phosphorus
(P2O5) concentrations were between 0.002 and 0.004 per cent.

3. The primary conditions of the soil, other than moisture
and the provision of cover, which limit the distribution of land
snails in this area appear to be calcium, magnesium, and or-
ganic matter. Potassium, phosphorus, and hydrogen-ion con-
centration may have some indirect effect but are assumed not
to be limiting factors.

Acknowledgments

I wish to acknowledge the aid of Dr. N. E. Rice, University
of Richmond, for advice and criticism, and Dr. C. I. Rich and
Mr. W. W. Lewis, Virginia Agricultural Experiment Station,
for analysis of and information concerning soil samples.

Literature Cited

Archer, A. F. 1939. The ecology of the Mollusca of the
Edwin S. George Reserve, Livingston County, Michigan.
Occ. Papers Mus. Zool. U. Mich. 389: 1-24.

Atkins, W. R. G. and M. V. Lebour. 1923. The hydrogen-ion
concentration in the soil and natural waters in relation to

Oct., 1955] THE NAUTILUS 69

the distribution of snails. Proc. Koy. Dub. Soc. 17: 233-
240.

Bloomer, R. 0. 1938. The geology of the Piedmont in Chester-
field and Henrico counties, Virginia. M.S. Thesis. U. Va.
p. 8.

Boycott, A. E. 1929. The oecology of British land Mollusca,
with special reference to those of ill-defined habitat. Proc.
Malac. Soc. London. 18(5) : 213-224.

. 1936. The relation of slugs and snails to man in Britain.

Proc. Cotteswold Nat. Field Club. 26(1): 73-82.

BuRCH, J. B. 1955. The land snails of Hanover, Henrico,
and Chesterfield counties, Virginia. Va. Jour. Sci. (In
Press).

Clarke, F. W. and W. C. Wheeler. 1922. The inorganic con-
stituents of marine invertebrates. U.S.G.S. Prof. Papers
125: 1-62.

Jacot, a. p. 1940. The fauna of the soil. Quart. Rev. Biol.
15 : 28-58.

Lee, C. B. 1952. Ecological aspects of Stenotrema hirsutum
(Say) in the region of Ann Arbor, Michigan. Amer. Mid.
Nat. 47(1): 55-60.

Okland, p. 1930. Quantitative Untersuchungen der Land-
schenckenfauna Norwegens. I. Zeitschr., Wiss. Biol. Ab. t. A.
Zeitschr. Morphol. u. Okol. Tiere. 16: 748-804.

OuGHTON, J. 1948. A zoogeographical study of the land snails
of Ontario. Toronto Studies, Biol. Ser. 57: 1-126.

Shimek, B. 1930. Land snails as indicators of ecological con-
ditions. Ecol. 14(4) : 673-686.

Strandine, E. J. 1941. Quantitative study of a snail popula-
tion. Ecol. 22(1) : 86-91.

THE MOLLUSKS OF WARM SPRINGS, GEORGIA
By MAHGAEET C. TESKEY

"Warm Springs (Merriwether County), Georgia; popula-
tion 557, elevation 930 feet. Site of the Warm Springs Founda-
tion Hospital for Infantile Paralysis. Part-time home of Presi-
dent Franklin Delano Roosevelt which he loved and where
he died." So reads the guidebook. In the study of the late
president in the Little White House (now open to the public)
two shelves are crowded with books written on all phases of

70 THE NAUTILUS [Vol. 69 (2)

his life in this obscure village as well as in the world outside
it. Several describe the area in detail, yet it is safe to assume
that no one of them records the molluscan denizens of Warm
Springs.

An opportunity was afforded to collect there during the
final two days of June, 1955. The following stations were
investigated, all in the immediate vicinity of the village: (1)
grounds of the Foundation hospital, wooded and clogged with
undergrowth; (2) forest on slope at base of Pine Mountain
fire tower; (3) open field nearby, beneath pile of rotting plaster
sacks; (4) Dowdell's Knob, scenic lookout, outcropping of
granite boulders on mountain top, occasional rotting log; (5)
Cascade Falls, leaf mold on loose shale; (6) Parkman Pond,
detritus in crannies of stone walls and rotting timbers of old
mill; (7) state fish hatchery; (8) cattail swale at edge of man-
made pond.

Search in several brooks draining the so-called warm springs
was unrewarding. One faunistic detail might be mentioned:
at the first four stations, scorpions outnumbered the snails two
to one. This collector who works best in prone position learned
early in the day to first clear away elbow space.

I am indebted to Mr. Ralph W. Jackson who identified the
land material, to Dr. Henry A. Pilsbry who helped out on two
specimens which Mr. Jackson found puzzling, and to Dr. Wil-
liam J. Clench who identified the Physidae.

Following is a list of twenty-three species taken together
with the stations at which they occurred:

Stenotrema stenotrema Pfr. 2, 6

Stenotrema maxillatum Gould 5

Praticolella lawae Lewis 3

Mesodon thyroidus Say 6

Mesodon inflectus Say 2, 6

Mesodon perigraptus Pils. 6

Triodopsis albolahris major Binn. 2, 3

Triodopsis vannostrandi Bland 2, 3

Eucomilus chersinus Say 4, 5

Retinella indentata Say 5

Betinella indentata paucilirata Morel. 1, 2, 4, 5, 6

Mesomphix vulgatus H. B. Baker 1, 6

Oct., 1955] THE NAUTILUS 71

Mesomphix 2^^181) ryi Clapp 2, 4

Gastrodonta interna Say 2

Ventridens intertextus Binn. 2

Ventridens gidaris theloides Walker & Pils. 2, 4

Zonitoides arhoreus Say 6

Eelicodiscus parallelus Say 5

Succinea avara Say 5

Strohilops lahyrinthica Say 5, 6

Vertigo ovata Say 8

Vertigo rugosida oralis Sterki 6

Physa crocata Lea 7

AMERICAN MALACOLOGICAL UNION

Twenty-first Annual Meeting, July 26th-29th, 1955
By MAEGAEET C. TESKEY, Secretary

It was a combination of organizations and individuals work-
ing together which made the 1955 meeting an unqualified suc-
cess. Wagner College on Staten Island, New York, began by
providing a new dormitory, dining hall and meeting room,
even a spacious porch for lounging and quiet talk. And as
though such generosity was not enough, tendered a gracious
tea on the evening of opening day. The Staten Island Museum
opened its doors for an entire day, providing meeting facilities
for two sessions and a bountiful luncheon at noon. And finally,
the co-host New York Shell Club was represented by A.M.U.
President M. K. Jacobson and his right-hand team Mr. and Mrs.
Anthony D'Attilio who were everywhere at once, overseeing
the thousand-and-one details which entertainment on such scale
always brings forth.

About eighty members and their guests attended the meeting
representing eighteen states, the District of Columbia, Puerto
Rico and the Philippine Islands. It was hot in New York, but
hot too over the rest of the nation and Wagner's hilltop site
brought cooling breezes each evening. As the stars came out
so did the delegates, out upon the great stone porch to rest,

72 THE NAUTILUS [Vol. 69 (2)

to chat and watch the lighted ships as they passed up and down
the Narrows far below.

At the annual business meeting the following officers and
councillors were elected to serve for the next twelve months:
President, Allyn G. Smith; Vice-president, Ruth D. Turner;
2nd Vice-president, Edward P. Baker; Secretary-treasurer,
Margaret C. Teskey; Publications Editor, George M. Moore;
Councillors-at-Large, R. Tucker Abbott, Ralph W. Jackson,
Katherine Van Winkle Palmer, Juan J. Parodiz.

The scheduled program clicked off as the days passed: regis-
tration-reunion the morning of opening day; scientific sessions,
two each day; two field trips; the annual dinner followed by a
rib-tickling skit (one snail to another!) and movies by Dr.
William H. Loery, filmed on Guam with living mollusks in
leading roles.

Then it was over for another year. Who can say which
brings greater joy — remembering the past or planning for the
future? Future A.M.U. meetings, of course.

NOTES AND NEWS

Alderia modesta in Washington. — Since preparing the paper
on this nudibranch in July Nautilus I had an opportunity to
spend some time on San Juan Island, Washington. There I
discovered in a Salicornia marsh at Garrison Bay numerous
specimens of Alderia modesta. This then extents the distribu-
tion of this nudibranch on the American West Coast from
Central California to the Canadian border. — C. Hand.

Mr. John Q. Burch 1584 W. Vernon Ave., Los Angeles 62,
is now assembling names, addresses and interests for the 1956
Directory of Conchologists. Free listing.

A correction. — Dr. Pilsbry has kindly brought to my atten-
tion an error in the name of a Miocene fossil species of Cyclo-
phorid land snail from the Bowden Beds of Jamaica. The name
Cyclochittya schermoi Morrison (Journ. Wash. Acad. Sci. 45
(5) : 154, May 1955) should be corrected to C. schumoi. The
name of the collector was Silas L. Schumo. — J. P. E. Morrison.

The Nautilus

Vol. 69 JANUARY, 1956 No. 3

OBSERVATIONS OF PREDATION ON ECHINO-
DERMS BY THREE SPECIES OF CASSIDIDAE

By DONALD R. MOORE
Gulf Coast Research Laboratory, Ocean Springs, Mississippi

Recorded observations on living cassids are rare in the litera-
ture and the writer has found nothing in a search of the corn-
man works on the feeding habits or prey of these gastropods.
The following observations were made during the course of
several years diving in Florida waters.

In the spring of 1949, a collecting trip was made with Gilbert
Voss and Frank Lyman to the Florida Keys. On the morn-
ing of May 13th, just north of Conch Reef, a large colony of
Cassis madorgascariensis spinella Clench was sighted on clean
sand bottom in about twenty feet of water. This subspecies
seems to be limited to the Florida Keys (Clench, 1944, p. 16).

Some individuals were crawling on the bottom while others
were buried to a depth of six inches or more. Upon investiga-
tion it was found that they were feeding on heart urchins that
live buried in the sand. Mr. Voss later identified the urchin
as Plagiohrissus grandis (Gmelin). It is a large species at-
taining a length of more than 200 mm. This is one of the most
beautiful of the heart urchins and has been considered quite
rare by specialists on West Indian echinoderms. This apparent
rarity is probably due to its penchant for slightly deeper water
than other littoral echinoderms and to a very spotty distribution.
Where it is found, however, the colony may consist of many
individuals. Clark (1919, p. 62) states that it is common near
Nassau, Bahamas, but reliable records from elsewhere are rare.

The test of P. grandis is white, thin, flattened and very grace-
ful in outline. Clark (1917, p. 207) states, ''no ecinois so well
deserves the name grandis as does this magnificent spatangoid.
When in perfect condition with all its long, dorsal primary

73

74 THE NAUTILUS [Vol. 69 (3)

spines intact, it is certainly the handsomest and most remark-
able of shallow water spatangoids. "

Several Cassis were observed as they located a buried urchin.
They burrowed down at a rather steep angle and ploughed
through the sand to their prey. Several shells that were al-
most buried were removed with urchins clasped in the fore
part of the foot. One urchin that had escaped was seen
trundling along on its short secondary spines with a large Cassis
in hot pursuit. Evidently this was an exception, as no other
fugitives were seen. The result of the chase was not observed
but the heart urchin seemed to be making good his escape.

An examination of one of these urchins from which the
gastropod was removed showed that an area of approximately
25 mm. in diameter had been cleared of spines. In this area
there was a neatly drilled hole through the thin test. One
specimen, which was placed in The University of Miami Marine
Laboratory Museum (specimen No. 42: 33) has a hole 9 mm. in
diameter in the antero-lateral edge.

Most of the Cassis were large or very large and fully mature.
The largest specimen taken was nearly fourteen inches long
(approximately 350 mm.). A specimen collected a few miles
north of Conch Reef in 1952 measured 300 mm. long by 230
mm. wide by 185 mm. high. This is by no means a giant but
seems to be average size for the adults.

One hundred and fifty Cassis were counted and probably twice
as many more were seen. The author has found other Western
Atlantic species of this genus, but never in large colonies.

In June, 1950 the author, while following the edge of a reef,
observed another member of the genus in the act of feeding.
The empty tests of several sea urchins provided an easily fol-
lowed trail, at the end of which was a Cassis tuherosa (L.).
It was eating a large white sea urchin, Tripneustes esculentus
(Leske).

This handsome sea urchin is dark with white spines; the test
is circular in outline, but slightly depressed. Since it lives out
in the open, it has been taken much more frequently than has
Plagiohrissus grandis. It is fairly numerous in some localities,
but individuals are usually well scattered.

Cassis tuherosa appears to be a solitary species. This colorful
gastropod is usually found living on reefs where a supply of

Jan., 1956] the nautilus 75

sea urchins is always at hand. The author has never seen this
species except as single individuals.

In July, 1954, while examining the sea bottom about two
hundred yards off Pensacola Beach, Florida, the author found
a great concentration of the sand dollar, Mellita quinquies-
perforata (Leske). These echinoids are greatly flattened and
have secondarily acquired bilateral s^Tiimetry. Since they live
in a zone where large waves exert considerable force, they have
many partitions and columns which strengthen the test. Five
holes near the outer edge serve to strengthen the test also. They
were most numerous where the water was about twenty feet deep.
Here and there, they were so crowded that they overlapped,
with a density of more than ten per square foot.

At first, Mellita appeared to be not only the dominant organ-
ism, but the only one present. However, a search revealed the
presence of the sand dwelling gastropod, Oliva sayana Ravenel.
Three live PJialmm granulatum, the Scotch Bonnet, were also
found, each one perched on a Mellita. When these were re-
moved, a small hole was revealed near the center of the test of
each echinoderm. The holes were a little less than two mm. in
diameter, but since the test of the sand dollar has a rather
porous structure, the teeth of the radula did not leave any
distinctive marks.

Apparently, the sand dollar is a dominant organism in a
rather narrow zone just offshore along much of the Gulf coast.
Off the Texas coast, where the water is very turbid, this is the
most common animal to be found in fifteen to thirty foot depths.
In slightly deeper water, Mellita is replaced by another sand
dollar, Encope michelini (Agassiz). Whether or not this
species also serves as food for the Scotch Bonnet, remains to be
determined.

The members of the family Cassididae are carnivorous and
thus are normally solitary individuals. Although further ob-
servations are needed, it is perhaps significant that each of the
three species discussed in this paper was found feeding on three
different types of echinoids in slightly different habitats. The
zones of these echinoids apparently overlap little, if any.

Probably the concentration of Cassis madagascariensis spinella
off Conch Reef was due to its selective feeding habits. There
must have been a large colony of heart urchins at this locality,

76 THE NAUTILUS [Vol. 69 (3)

as shown by the number of empty tests lying around. This
local abundance of food was probably the cause of the ^ouping
of so many of these large predatory gastropods in such a small
area.

Although numerous at Pensacola Beach, the sand dollars
were actually part of a vast population extending for many miles
along the Gulf coast. Since there is no local concentration of
these animals it would be logical to find Phalium granulatum
well scattered. The author's observations indicate that this is
apparently the case.

Literature Cited

Clark, H. L. 1917. Mem. M. C. Z. 46, pt. 2.

. 1919. Carnegie Inst. Wash., Pub. 281.

Clench, W. J. 1944. Johnsonia 1, No. 16.

NOTES ON THE STINGING OPERATION OF CONUS

By GEOEGE F. KLINE i

While collecting on the ''Gloria Maris" expedition in the
Palau Islands, Western Caroline Group, during the summer
of 1955, we had several opportunities of observing specimens of
Conus stinging their victims. Much has been written regarding
the effects of the venom of Conus and the apparatus by means
of which it is injected, but to our knowledge no observations
have been recorded of the actual behavior at the moment of
attack.

Several species were used in our experiments, but only two
performed in captivity — Conus auratus Hwass and textile Linne.
One of the chief problems was to find some means to stimulate
the animal to attack. Most cones are quite retiring, and some
of the renowned venomous species, such as Conus marmoreus
Linne, striatus Linne, tulipa Linne, and geographus Linne, re-
fused to perform in our aquaria. In fact marmoreus would not
even emerge from its shell.

Conus auratus and textile seemed to be quite aggressive, and
would obligingly crawl about whenever placed in fresh sea

1 Eesearch supported by the Natural Science Foundation, Philadelphia,
Pa.

Jan., 1956] the nautilus 77

water. It was found that if the shell was held, aperture up,
and a few drops of fresh water or saliva allowed to drip on the
retracted animal, it would produce results rather quickly. If
the specimen was replaced in the sea water, its brilliant red
proboscis would immediately be thrust out in an exploratory
manner. At this stage, the proboscis is quite evenly tapered
from base to tip, and would be moved about in a deliberate,
sinuous manner. The proboscis can be extended to about three
quarters of the length of the shell — thus a two-inch specimen can
''reach out" to about a length of 1% inches.

If, while in this state of excitement, suitable prey was placed
nearby, the cone usually stung fairly promptly. The moving
proboscis would ''discover" the soft parts of, say, a Cypraea.
There seemed to be an immediate heightening of excitement
when the desirable location on the victim was found. The tip
of the proboscis was brought stationary at this point, and a
quick spasm of the whole proboscis immediately ensued, with
obvious thrusting pressure. It became momentarily rigid and
turgid, although usually in a curving rather than a straight line.
Simultaneously with the muscular spasm and thrust, a small
milky cloud appeared around the point of contact, and the
proboscis then was quickly withdrawn, still emitting a small
amount of the milky fluid. The cloud reached a diameter of
about one fourth to one half inch before it dissipated itself in
the water. Having executed its sting, the cone seemed to lose
interest in the prey. On several occasions the small, glass-like
barb was seen protruding from the victim following the striking
operation.

One of the most interesting occurrences was the lethal stinging
of Conus geographus by a C. textile about one-third its size.
Several textile, ranging from two to two and one-half inches in
length, were placed in a container of sea water with a four-
inch long geographus. Without any special stimulus one of the
smaller textile, which crawled close to the moving geographus,
instantly shot out its proboscis and stung the foot of the latter.
A few moments later a second textile made a similar strike and
within five minutes the geographus was limp and evidently dead.

Several species of "victims" were tried. The cones would not
sting Oliva or Nassarius, but readily responded when Cypraea
was offered. Small species of Cypraea were killed by one or two

78 THE NAUTILUS [Vol. 69 (3)

stings ; larger ones, such as Cypraea tigris Linne, seemed able to
absorb more of the venom and still live, although they obviously
became seriously affected.

REMARKS ON I. BORN'S INDEX RERUM NATURA-
LIUM MUSEI CAESAREI VINDOBONENSIS, 1778

By E. F. EUTSCH
University of Berne

Dodge in his valuable *' Historical Review of the Mollusks of
Linnaeus" (1952, 1953) refers to two publications of Ignatius
BoRN,^ the ''Index rerum naturalium Musei Caesarei Vindo-
bonensis" and the ''Testacea Musei Caesarei Vindobonensis "
and states (1952, p. 231; 1953, p. 125) :

"The 'Index' of Born, which bears the date 1778 on its title
page, was not published until 1780. His 'Testacea' bears the
date 1780 on its title page and was published in that year. The
latter is a folio volume and is not a second edition of the ' Index. '
It is limited to Mollusca. The two works were, however, pre-
pared simultaneously as they quote each other."

This is certainly incorrect. The Library of the University of
Berne has a copy of the "Index" with the handwritten comment
of J. S. Wyttenbach (one of the founders of the Swiss Society
of Natural History), that he received this copy in 1779. More-
over Brauer (1878) in his publication on Ignatius Born cites
1778 as the date of publication of the ' ' Index. ' ' We have there-
fore no reason to doubt that Born's "Index" was really pub-
lished in 1778.

Several living East American species such as Phalium granu-
latum (Born), Ostraea cristata (Born), Dosinia concentrica
(Born), Tivela mactroides (Born), etc. date from 1778 and not
from 1780 as often stated in American conchological literature
(e.g. Johnson 1934, Clench 1944, etc.).

I wish also to draw the attention of American conchologists
to the fact that according to Brauer (1878) many of Born's
types are still preserved in the Zoological Museum at Vienna.

1 Ignatius Born (1742-1791) was curator of the ' ' Kaiserliches Natural-
ienkabinet" of Vienna from 1776 on.

Jan., 1956] the nautilus 79

Literature

Born, J. (1778) : Index Rerum Naturalium Musei Caesarei

Vindobonensis. Pars I : Testacea. Verzeichnis der natlir-

lichen Seltenheiten des k. k. Natnralien Cabinets zu Wien.

Brster Theil: Schalthiere. Vindobonae (ex. officina Kransi-

ana) 1778.
Born, J. (1780) : Testacea Musei Caesarei Vindobonensis.

Vindobonae, 1780.
Brauer, Fr. (1878) : Bemerkmigen iiber die ini kaiserlieh zoo-

logischen Museum aufgefundenen Original-Exemplare zu Ign.

V. Born's Testaceis Musei Caesarei Vindobonensis. Sitzber.

Kais. Akad. Wiss. (Wien) Math. Natw. CI. 77, Abt. 1, No. 2,

p. 117-192.
Clench, W. J. (1944) : The Genera Casmaria, Galeodea,

PJialium and Cassifi in the Western Atlantic. Johnsonia 1,

No. 16, pp. 1-16.
Dodge, H. (1952) : A historical review of the Mollusks of

Linnaeus. Part 1. The Class Loricata and Pelecypoda.

Bull. Am. Mus. Nat. Hist. 100, Article 1, pp. 1-263.
Dodge, H. (1953) : A historical review of the Mollusks of

Linnaeus. Part 2. The Class Cephalopoda and the Genera

Conns and Cypraea of the Class Gastropoda. Bull. Am. Mus.

Nat. Hist. 103, Article 1, pp. 1-34.
Johnson, Ch. W. (1934) : List of marine mollusca of the At-
lantic Coast from Labrador to Texas. Proceed. Boston Soc.

Nat. Hist. 40, No. 1, p. 1-203.

WATER CIRCULATION IN THE MANTLE CAVITY

OF THE OWL LIMPET LOTTIA

GIGANTEA GRAY

By DONALD P. ABBOTT
Hopkins Marine Station, Pacific Grove, California.

On the Californian coast the owl limpet, Lottia gigantea Gray,
occurs on intertidal rocks in and above the mussel beds in areas
where wave action is often severe. The anatomy of this form is
well known through the work of Fisher (1904). As in other
members of the Patellacea, the mantle cavity includes not only
the nuchal cavity lying back of the head, but also the pallial
groove surrounding the body. In Lottia the pallial groove
bears a cordon of secondary gills consisting of lappet-like out-
growths of the mantle (Figs. A, C). This ring of gills is in-

80 THE NAUTILUS [Vol. 69 (3)

complete anteriorly, and is poorly developed or absent in indi-
viduals less than about 20 mm. in length (Fisher, 1904). The
nuchal cavity bears the single left ctenidium; this is oriented
such that the efferent ("ventral") vessel lies toward the left side,
and the afferent ("dorsal") vessel is directed toward the right
(Figs. A, B). Afferent and efferent suspensory membranes are
virtually absent.

The pallial water currents produced by Lottia have never been
reported, though Yonge (1947) has predicted the probable
circulation of water in this genus from a study of living repre-
sentatives of the related limpets Helcion {Patina), Patella, and
Acmaea (Patelloida) . He notes that "... the presence of the
ctenidium indicates ... an inhalant current on the left of the
head. The pallial gills presumably produce diffuse inhalant
streams into the pallial grooves, while conditions in Patina indi-
cate the probability of a sediment-laden exhalant current on the
right of the head" (Yonge, 1947, p. 472, and Fig. 23 B). These
predictions have proved substantially correct.

In the present studj^ ciliary currents in Lottia were observed
in living intact individuals immersed in seawater containing a
small quantity of suspended carmine. Some individuals were
attached to upright or inverted glass plates ; other animals were
inverted unattached. Additional observations were made on
living animals in which the anterior portion of the shell was re-
moved and the nuchal cavity laid open.

The ctenidium resembles that of Theodoxus as described and
figured by Yonge (1947, p. 476 and Fig. 18 B) ; it differs in ap-
pearing somewhat more regularly elliptical in cross-section, and
in having very active lateral cilia distributed all over the flat
surfaces of the filaments instead of being confined to definite
bands. Circulation in the nuchal cavity results largely from the
beating of these lateral cilia on the filaments. Water enters the
nuchal cavity on the left side, passes between adjacent filaments
above and below the ctenidial axis, and exits on the right side
accompanied by waste materials from the anus and renal aper-
tures (Fig. B). In addition, there are powerful ciliary currents
on the posterior head and neck which sweep from left to right.
The roof of the nuchal cavity shows very little ciliary activity.

In contrast to the water currents of the nuchal cavity, those
of the pallial groove are rather weak. The mantle margin in the

Jan., 1956 J the nautilus 81

region of the sensory tentacles shows little or no ciliary activity.
The remainder of the flat mantle surface and the basal portions
of each pallial gill possess incnrrent ciliary tracts. The erect
surfaces of the pallial gills bear ciliated areas that carry ma-
terials toward the free margin of the gill (Fig. C) . The sides of
the foot and body which form the inner wall of the pallial
groove show almost no ciliary activity. Sediments entering
with the inhalant current tend to accumulate along the mantle
margin and along the side of the foot, trapped in a layer of
mucus. In a moving animal this material is left behind with the
mucous trail; in stationary individuals it is expelled not by
ciliary action but by irregular muscular movements of the ani-
mal. Proper determination of the ciliary currents of the pallial
groove is rendered more difficult in bigger individuals by the
presence of large numbers of both attached and free-moving
ciliated protozoans on the mantle and gill surfaces.

The functional significance of the ciliary currents is not en-
tirely clear from laboratory studies of owl limpets attached to
glass plates. For one thing, the anterior margin of the shell in
Lottia is usually curved downward, making it impossible for
the animal to seal itself tightly to a smooth flat surface. On
such a surface the lateral margins of the shell remain slightly
elevated, and even when the animal is firmly clamped down,
the shell may be rocked slightly from side to side. This shell
condition is rather consistent regardless of the substrate form,
though the nature of the modification is somewhat similar to that
noted by Comfort (1946) in Patella growing on mussels or um-
bonate rocks. On a flat rock this shell-form would insure an
opening through which water could always be drawn into the
pallial and nuchal cavities at high tide. However, the presence
of such a groove is not in consonance wdth the commonly held
picture of a limpet clamped to a perfectly-fitting home scar at
low tide to prevent water loss from the pallial complex. Numer-
ous questions arise : Is the pallial groove open to the outside or
sealed off at low tide? At low water is the pallial groove filled
with air or water? How does wave action affect water move-
ment in the mantle cavity? Field observations of Lottia have
been made at various phases of the tidal cycle. These have pro-
vided some interesting and somewhat unexpected answers to the
above and related questions.

82 THE NAUTILUS fVol. 69 (3)

At Mussel Point, Pacific Grove, California, Lottia occurs on
surf-beaten rocks in the intertidal zone from the 0.0 datum line
to about 4.0 ft., the great majority of the individuals being found
within the range of 0.5 to 3.4 ft. (Hewatt, 1937, PI. 1). Oc-
casional individuals occur higher in crevices or in areas where
wave splash is great. In southern California, Lottia is said to
occur a bit higher in the intertidal (Rasmussen, 1935; Ricketts
and Calvin, 1952). The upper limit of Lottia coincides remark-
ably well with the 3.4 ft. height reached by the very lowest of
the lower high waters in this region (Ricketts and Calvin, 1952,
Figs. 1, 132). Animals below this level are never exposed for
periods longer than about 10 hours, and are always covered by
the tides twice each day. Above this level, the forms present
may be covered by the sea only once in 24 hours during equa-
torial tides, and the maximum period of continuous exposure
extends abruptly to about 18 hours.

During periods of low water Lottia is generally inactive.
Some individuals are found occupjang distinct ''home scars"
which fit the shell margin very well. Frequently, however, there
is no clear scar below or near the animal, and the shell margin
does not conform very well with local small irregiilarities of the
granite. Where scars are present, these are usually nearly as
well covered by an algal film as the adjoining rock surface, sug-
gesting that individuals of Lottia are often away from home.
Probably, as in Patella, the homing habit is not so well de-
veloped in individuals living on a relatively even substrate,
and the animals may not remain in the same place for long
periods (Orton, 1929; Jones, 1948).

Many Lottia have been examined closely at low tide. With
few exceptions these show the following features. First, the
shell, while it rests lightly against the substrate, is seldom
clamped firmlj^ down. Especially along the lateral margins
there usually remain slight gaps between shell and rock. The
mantle often protrudes slightly in these areas, and here and
there are places where a narrow open communication exists be-
tween the pallial groove and the outside. With the shell muscle
slightly relaxed, an air space is present in the pallial groove, and
the ciliary currents described earlier are probably effective in
circulating the surface film of moisture over the mantle and
pallial gills. When disturbed the animal clamps firmly down;

Jan., 1956] the nautilus 83

this reduces the volume of the nuchal cavity and compresses the
pallial groove to a mere slit, eliminating the air space and often
squeezing a bit of water out at the shell edges as well. Subse-
quent relaxation again opens the pallial groove and draws air in
under the shell. It appears, then, that at low water the pallial
groove contains a sizeable air space, that under these conditions
the pallial gills and relatively vascular mantle are wet but ex-
posed to air, and that these ciliated structures probably play a
primary role in aerial respiration. Openings to the outside are
so small that desiccation is probably no problem, for exposures to
air never exceed 10 hours and are usually of a shorter duration.
The pallial groove and nuchal cavity contain considerable
residual water, and any surfaces tending to dry out could be
wetted by an occasional slight contraction of the shell muscle.
Such movements might also help ventilate the pallial cavity,
though this would not appear to be necessary.

Observations of limpet behavior when the tide is in are by no
means so easy. However, with the aid of binoculars, good ob-
servation>s were obtained on a total of 18 Lottia which were being
regularly pounded and exposed again by the waves at inter-
mediate water levels. Six animals were watched during tidal
ebb, and twelve during tidal flow. The findings were somewhat
surprising to one accustomed to thinking of limpets as tightly
drawn to the rocks in pounding seas. With only two exceptions,
all of these individuals had their shell margins elevated an esti-
mated distance of two to six mm. above the rock surface, leaving
the pallial groove broadly open to the surging waters all around.
Thus with every wave the pallial cavities and grooves were
flushed with a torrent of water, and even in the full force of the
waves the shell was not clamped to the rock surface, though the
animals were stationary. It seems clear that at this phase of the
tide, the real work of circulating water through the pallial com-
plex is accomplished not so much by ciliary activity as by the
action of the sea itself. No observations have been carried out
during the highest waters, for the animals are then fully and
continuously submerged and the rocks scarcely approachable.
Under conditions of full submersion it would seem that the
respiratory effectiveness of the ctenidium would reach its peak;
in contrast, the pallial gills would appear to be able to operate
effectivelv regardless of the height of the water. This is of

84 THE NAUTILUS [Vol. 69 (3)

interest in view of the series one finds in the Patellacea : Acmaea
with ctenidium only, Lottia with ctenidium and pallial gills, and
the Patellidae with pallial gills only.

The vast majority of Lottia are found clinging to steeply
sloping or vertical surfaces of rock in central California. Dur-
ing the tidal periods when they are being wetted by the sea, they
are subjected to moving water coming from various directions.
The most persistent water flow, however, is from above, consist-
ing of waters draining down the surface of the rock. It is ap-
parent that the current of water down the face of the rocks and
around animals whose shells are slightly raised, might serve
either to reenforce or to counteract the action of the ciliary
currents, particularly those of the nuchal cavity, depending on
the orientation of the individual animal on the rock. If the
anterior end of the animal, as viewed from the dorsal surface,
is directed to the right or downward (from about 2 to 5 or 6
o'clock), the water runoff would tend to supplement and reen-
force the ciliary currents of the nuchal cavity and flush wastes
away from the ctenidium. For animals with the head pointed
upward or inclined toward the left, the reverse would be true,
and these individuals would appear to be at some disadvantage.

Orientation of the body on the rock surface was plotted for
175 animals. Of this number, 9 were on approximately hori-
zontal surfaces, the remaining 166 on rather steeply sloping or
vertical rock faces. Distribution of the 166 individuals into 8
classes on the basis of body orientation is shown in Fig. D.
Very clearly there is a tendency for the animals to orient with
their heads more or less do^\^iward, and a Chi-square test indi-
cates the odds are less than one in 10,000 that such a distribution
of orientations is due to chance alone.

If we omit, for the moment, animals with heads pointing either
up or down (octants IV and VIII, Fig. D) and consider the re-
mainder, the tendency for the animals to orient with the head
to the right rather than to the left is by no means so clear.
While a total of 58 individuals were assigned to the right-facing
group (presumably advantageous octants I-III), and only 40 to
the left-facing group (presumably disadvantageous octants V-
VII), the difference here proves only of borderline or dubious
statistical significance (5% level). Such a difference is sug-
gestive but scarcely conclusive.

Jan., 1956] the nautilus 85

The real and significant tendency seems to be to keep the
head down. This finding agrees in general with that of Wells
(1917), who found positive reactions to gravity and ''the cur-
rent made by the waves" in five species of limpets including L.
gigantea. Over one-third of the present animals have the head
pointed almost straight downward, while fully two-thirds fall
into octants III-V. In these animals, the ciliary currents of the
nuchal cavity would be slightly helped, slightly hindered, or
relatively unaffected. The possible advantages of the head-
downward position would appear, on speculation, to be at least
two-fold. First, this position affords the best drainage from the
nuchal cavity of contaminating renal and fecal wastes. Point-
ing the head toward the right would be better than to the left,
but head downward would be best under conditions of exposure
at low water. With any significant downflow of water on the
rock the sanitary problem would be negligible. Second, with
the head down, water trapped in the mantle cavity at ebb tide
would tend to drain toward the anterior end, where a deep
recess underlies the beak of the shell. Thus under any condi-
tions where desiccation might become a problem, the head and
nuchal cavity bearing sense organs and ctenidium would be the
last structures to suffer from drying. It seems doubtful that
orientation would make much difference as far as deflecting the
force of oncoming waves is concerned. The shell is low, offering
little resistance to water coming from any direction, and, to an
animal which can cling firmly in pounding seas with its shell
raised almost like an umbrella above the body, this should be a
negligible factor.

Summary: Ciliary currents in the nuchal cavity and pallial
groove of Lottia gigantea are described and figured ; these eon-
firm earlier predictions of Yonge and add details. Studies of
Lottia in the field indicate that the pallial gills serve as organs
of aerial respiration at low tide, that wave action is the primary
moving agent in water circulation at intermediate water levels,
and that Lottia tends to orient on sloping rock surfaces with the
head downward.

86

THE NAUTILUS

[Vol. 69 (3)

Explanation

Fig. a. Dorsal view of Lottia gigantea Gray Avitli the shell removed
and the mantle cut away anteriorly to show the head and structures in the
nuchal cavity. The horseshoe-shaped shell muscle is heavily stippled.
Lateral to this the positions of the pallial gills below the mantle are
indicated by short black lines.

Jan., 1956] the nautilus 87

Literature Cited

Comfort, A, 1946. Patella vulgata L. : Relation of habit to
form. Jour. Conchol. 22(9) : 216-217.

Fisher, W. K. 1904. The anatomy of Lottia gigantea Gray.
Zool. Jahrb. Anat. 20(1) : 1-66.

Hewatt, W. G. 1937. Ecological studies on selected marine
intertidal communities of Monterey Bay, California. Amer.
Mid. Nat. 18(2): 161-206.

Jones, N. S. 1948. Observations and experiments on the
biology of Patella vulgata at Port St. Mary, Isle of Man.
Trans. Liverpool Biol. Soc. 56: 60-77.

Orton, J. H. 1929. Observations on Patella vulgata. Part
III. Habitat and habits. Jour. Mar. Biol. Assn. U.K. 16(1) :
277-288.

Rasmussen, D. I. 1935. Southern California Balanus-Lit-
torina communities. Effects of wave action and friable ma-
terial. In: Shelf ord et al. Some marine biotic communities
of the Pacific coast of North America. Part I. General sur-
vey of the communities. Ecol. Monogr. 5 : 249-354.

Ricketts, E. F. and J. Calvin. 1952. Between Pacific Tides,
3rd ed., revised by J. Hedgpeth. Stanford University Press.
1-502.

Wells, M. M. 1917. The behavior of limpets with particular
reference to the homing instinct. Jour. Animal Behavior
7(6): 387-395.

Yonge, C. M. 1947. The pallial organs in the aspidobranch
Gastropoda and their evolution throughout the Mollusca.
Phil. Trans. Roy. Soc. Lond., Ser. B, 232(591) : 443-518.

Fig. B. Dorsal view of the head and nuchal cavity with the mantle
removed. Solid arrows indicate the main flow of water through the cavity.
Dotted-line arrows show ciliary currents on the head, neck, and ctenidium.

Fig. C. Cross-section through the shell, mantle, pallial groove, and
adjacent body and foot in the mid-body region. Arrows indicate ciliary
currents on the flat mantle surface and pallial gills.

Fig. D. Graph showing orientation of individuals of Lottia gigantea
on steeply sloping or vertical granite surfaces at Pacific Grove, California.
Arrows indicate direction of the anterior end. Arabic numerals and black
bars show the number of individuals observed whose orientations were as-
signed to each octant.

88 THE NAUTILUS [Vol. 69 (3)

TWO ANONYMOUS LETTERS

Dear Dr. Curator :

With the current interest in all phases of natural sciences,
with more and more people travelling each year, with increasing
knowledge of the sea and its abundant life, the ranks of shell
collectors are growing by leaps and bounds. Perhaps one should
say by ''stoops" and ''dunks" as generally the novice starts by
beachcombing.

From here the next phase can be illustrated by watching a
hypothetical Mr. X who in all innocence has gathered a few
shells on his vacation. He pockets a dozen or so and they find
their way into his homeward bound luggage. The next step is
a critical one for him. If he ceases to be interested in his bag
or box of shells when his vacation has passed, all well and good,
but if he so much as questions the name of one small mollusk
he is in danger of starting on a hobby that can become in-
triguing, rewarding and time-taking.

As the years slip by Mr. and Mrs. X realize that their hobby
has brought them much more than a collection of sea shells.
They have covered a considerable area in pursuit of moUusks,
bounded only by economic considerations. Their horizon has
broadened as their travels have introduced them to people and
customs they might never have encountered had they not become
members of the shell collecting group. Interest in one aspect
of natural science has brought with it an awakening to other
forms of nature ; with each new awareness they have gained im-
measurably as human beings. They have learned that any
pleasure is deepened with a fuller understanding of the subject.
Our couple has become sincerely interested in conchology. They
have purchased serious volumes on shells, have visited museums,
and have met others who share their interest. No longer do
beach specimens have the power to charm them — shells from the
living animals are now their aim. Gradually the X's realize
that their shelling trips might in some w^ay be helpful to the
scientists in the museums. Is there any way they can contribute
to this great renaissance ?

At this point our imaginary couple becomes real and joins
the group of collectors who exist in substantial numbers. Man}^
of us are in that odd position of an amateur status but advanced

Jan., 1956] the nautilus 89

enough that the language of the scientist no longer seems strange.
We can understand reasonably well a lecture or an article on
mollusks. We have a sincere wish to contribute something and
we think we can. How and what and where, are the big ques-
tions. Through education and more aggressive public relations
work on the part of museums the public is more and more aware
that with intelligent cooperation our great institutions can be-
come even greater. Statistics prove that globe trotting is wide-
spread and growing and there seems to be ample proof that
many of the * trotters" are collectors. There must be some way
for the museums to capitalize on this state of affairs. It is at
this point that the non-professional is apt to flounder. The in-
telligent collector knows that he can help. The question is how?
We all know that the scientist has said in as many ways as
there are scientists '* Shells with proper data are welcome ad-
ditions to any scientific collection." Right here Dr. Curator,
is where we need your help. Just what do you mean by proper
data? You tell us to keep good and accurate field notes. Speci-
fically^ what, in your opinion, IS a good set of field notes? We
ask you what kind of shells you would be particularly interested
in having from Idyllic Reef and you say "Bring any you can".
Seriously, do you mean you really want a basket full of, say,
Neritas, or should we try to bring a representative group of
shells from a particular locality? Another question, learned
Dr. — Do you want shells with opercula or not ? If the answer is
* ' yes, ' ' do you mean that you want each shell with its individual
operculum, or do you mean for instance, fifty Neritas from one
station with a bag of their fifty opercula collectively? And
still another question — Are you interested in pictures or descrip-
tions of the living mollusks ? Does a description of any interest-
ing characteristic behavior mean anything? For example —
would you like to know that on several occasions it was observed
that a particular species cut off part of its body when disturbed?
Does it interest you to learn that some species described as
"rare" in certain recognized publications proved quite common
once the idea of "fanning" (stirring with the hand or a swim
fin to sweep the sand away) for them was tried? Would you
want any record of population in certain species? Would it be
of any significance to record that particular varieties are con-
sidered a gastronomical delicac}' on a certain island?

90 THE NAUTILUS [Vol. 69 (3)

The questions could go on and on, but these few will illustrate
our quandary. You see, Dr. Curator, we are serious in a desire
to help you, we earnestly want to do a good job. We 're in the
hemi-, demi-, semi-, state of being a bit above the amateur in the
strictest sense of the word and are conscious that we have a long
way to go to rank with the professional, but. Dr. Curator, we're
a mighty big group and you have created us — the next move is
up to you.

How 'bout straightening us out?

(signed) A Collector

Dear Mr. and Mrs. Collector:

Your quandary is not limited to the legions of serious amateurs
who wish to add to the knowledge of mollusks, but is a dilemma
which faces any scientific observer, professional or otherwise,
who goes into the field to pry into nature 's secrets. The amount
and types of data to be made are in direct proportion to the
observer's training, interests and experience, but practical mat-
ters, such as time, money, equipment and physical endurance,
will, in the end, dictate the nature and limits of the studies. It
is the sum of these factors that helps the expedition-bound
Curator to answer your same questions for himself.

Let's take this matter of a good set of field notes. I know
a competent Curator and field observer who has made five or
six summer trips to the West Indies in search of mollusks. His
field notes consist, for example, merely of ''One mile south of
Pirate's Town, Grand Cay. August 1, 1935. Xancus and Oliva
abundant. " Profound notes? No, but he was not making a life
history study of Xancus, nor an ecologic investigation of Grand
Cay. He was sampling the marine fauna at 500 stations in the
Bahamas. This was later to serve as an important basis for the
study of speciation and zoogeography of the Western Atlantic
marine mollusks. I also know of a curator who spent three
years in the Andaman Islands, Indian Ocean, making observa-
tions and experiments on one species of marine gastropod. The
result was a splendid and worthwhile report on the biology of
Trochus, but we know practically nothing about the other
marine mollusks of the Andamans to this day. These are two
extreme examples of how much information can go into field
notes.

Jan., 1956] the nautilus 91

Your notes should be geared to fit your circumstances. If
you are making short, annual trips to far-off places, make your
notes on marine species brief and accurate, and, as time affords,
include the following in descending importance ; geographical
location to within a half-mile ; date ; general ecological habitat
(sandflats, rocks, beach, dredged in 10 feet, etc.) ; special water
conditions (heavy surf, quiet bay, cold or warm water, etc.) ;
relative abundance or scarcity of mollusks, other animals or
plants; outstanding habits noticed about certain species (feed-
ing, reproduction, locomotion, etc.) ; colored paintings of or
color notes on certain species; ethnological observations (native
uses, methods of collecting, legends). If you are a born col-
lector and hope a Conus gloria-maris will turn up at the next
reef, you'll be lucky if you have time to write down the first two
observations.

On the other hand, if you live a coconut's throw from that
Elysian Reef, your notes can follow the above outline, but think
of the possibilities! Not just one date, but a year round
chronicle of the changing tides, moving sand bars, the seasonal
disappearance and reappearance of different species, the breed-
ing and egg-laying periods, the months of increasing size of
individuals, the days when predators or storms produce their
havoc. And with the help of an aquarium, think how many
pages you could write on the color phases, feeding and egg-laying
habits and locomotion of your local mollusks! Any curator
would be glad to show you a dozen good publications which re-
sulted from such simple observations.

As for some of your specific questions, Mr. Collector, I be-
lieve you will find many answers in the booklet entitled "How to
Collect Shells" issued by the American Malacological Union in
1955 or in some larger popular books on seashells (modesty pre-
vents me from mentioning one in particular). You should also
read an excellent article by Dr. David Nicol, ' ' The Scientific Role
of the Amateur Malaeologist, " which appeared in the October
1953 issue of the Nautilus (vol. 67, no. 2, pp. 41-44). And as
for how many specimens to bring back for the museum. Sir or
Madam, you underestimate the greed of a Curator ! Seriously,
though, most curators would prefer to select out a representa-
tive set for their research collections, and return the surplus to
you or use them for exchange. Some departments of mollusks

92 THE NAUTILUS [Vol. 69 (3)

are over-crowded, others specialize only in certain groups, al-
though, a few are singularly in position to absorb, exchange or
even sell surplus material (modesty again prevents me from
mentioning a certain Pennsylvanian institution).

And before I climb the stairs to my ivory tower to continue
identifying dusty shells, let me remind you, Mr. and Mrs.
Collector, that an amateur is not ''just an amateur" or novice,
but one who loves his work or hobby, whether he be a so-called
professional or not, and I would add that it was the widespread
interest among many people who created the Curator, and not
we few professionals who made your mighty big group.

(signed) A Curator

A NEW BOSTRYX FROM PERU

By H. a. PILSBEY

Some years ago a paper on the carinate Bulimulidae of Peru
was brought out by A. A. Olsson and the writer. In the ex-
amination of Peruvian collections made by the geologist Mr.
A. G. Fisher an addition to this peculiar series of land shells
came to light. Four specimens of this species were found, all
dead and more or less broken, but so distinct from known
species that it should be described.

BosTRYX (Platybostryx) fisheri, new species. PI. 5, figs. 4, 5.

The shell is somewhat wider than high, openly umbilicate, the
periphery carinate. The first 1% whorls are smooth, strongly
convex, forming a short, obtuse apical nipple. The following
whorl is less convex, and the third whorl becomes flattened and
carinate, the keel projecting above the suture. The last
whorl has a flat, horizontal upper surface and strongly ex-
pressed peripheral keel; the somewhat convex lateral outline
slopes inward anteriorly, and the base is strongly angular
around the ample, funnel-shaped umbilicus. The aperture is
sub triangular ; peristome simple.

Height 5.6 mm. ; diameter 6 mm. ; 4% whorls.

Peru: below Tarma on the Tarma-Chanchamayo road. Col-
lected by Mr. A. G. Fisher. Type and three paratypes are
196550 ANSP.

THE NAUTILUS 69 (3)

PLATE 5

1, la, Poliigiira Uimanlipasensis Lea, type. 2, 2a, Polygyra polita P. &
H., type. 3, 3a, Polygyra scintilla P. .S: H., type. 4, 5, Bostryx fisheri

Pils., type and immature paratype.

All

larged.

Jan., 1956] the nautilus 93

This species appears to be related to B. erymothauma of north-
ern Chile, but that is a much larger shell, 12 to 15 mm. in
diameter with about the same number of whorls. The spire of
B. fisheri is much higher than that of the Chilian species and
the umbilicus is not so wide. Some specimens show very weak
traces of axial wrinkles.

This addition to the small group of carinate Bostryx is named
in honor of its discoverer.

With these shells there is a fragmentary spire of some other
species having a thin keel projecting above the suture, the
generic relation unknown.

BEACH DRIFT POLYGYRIDAE FROM
SOUTHERN TEXAS

By HENRY A. PILSBEY AND LESLIE HUBEICHT

At the bases of the dunes, near the beaches along the Gulf
of Mexico in southern Texas, are to be found incredible num-
bers of land shells which have been washed in from the sea.
Most of these shells are of species which are found living in
Texas, but many of them are of Mexican species. The Texas
shells appear to be derived from the drainages of the Rio
Grande, Brazos, and Colorado Rivers. Not many shells char-
acteristic of the Mexican side of the Rio Grande drainage were
found. The El Azucar dam on the lower Rio San Juan and the
Don Martin dam on the Rio Salado have apparently prevented
many shells from reaching the sea. Most of the Mexican shells
appear to be from farther south, from the Rio Panuco drainage
southward.

Shells were collected at the following three places. The ab-
breviations BC, Pla, and PIb are used, followed by the number
of specimens found.

BC. Near the mouth of the Rio Grande, 1 mile south of
Boca Chica, Cameron Co., Texas. At this locality, shells were
found literally by the millions. Most of the shells were Polygyra
texasiana. Sorting through the piles of this species became
so tedious that not as many foreign shells were found here as
at the other localities where P. texasiana was not so abundant.

94 THE NAUTILUS [Vol. 69 (3)

Pla. Padre Island, 2.5 miles north of the Port Isabel Cause-
way Road, Cameron Co. T. texasiana was not as abundant here,
numbermg in the thousands, but was still numerous enough to
hamper collecting of the foreign shells.

PIb. Padre Island, 30 miles north of the Port Isabel Cause-
way Road, in Willacy Co., Texas. Here the percentage of
Mexican shells Avas higher than at the other localities.

Polygyra cereolus (Miihlfeld), PIb-1.

Polygyra cereolus fehigeri (Bland), PIa-3.

Folygyra auriformis (Bland), BC-2, PIa-61, PIb-101.

Polygyra oppUata (Morelet), BC-27, PIa-270, PIb-139.

Polygyra oppilata (Morelet) var. ?, BC-1, PIa-7, PIb-1.

These shells differ from typical P. oppilata in having a narrow
channel separating the parietal tooth from the end of the upper
lip. It may prove to be a distinct species.

Polygyra implicata (Martens), BC-23, PIa-145, PIb-217.
This species has been considered a subspecies of P. oppilata,
but there was no intergradation in the beach drift shells. The
two species sorted without difficulty.

Polygyra leporina (Gould), BC-1, PIa-12, PIb-39.

Polygyra rhoadsi Pilsbry, BC-2.

Polygyra ariadnae (Pfr.), BC-1.

Polygyra texasiana (Moricand). The material found on the
beaches shows all the variation in size and sculpture found in
the species. In sculpture the shells vary from smooth to rib-
striate above and below. Smooth shells are found living along
the western edge of the range of the species, being found from
the Pecos River eastward to Roma, Starr Co., Texas, and Oglesby,
Coryell County. In Mexico it is found at Cerralvo, Nuevo
Leon. Shells with basal rib-striae are found only within a few
miles of the coast, in Cameron, Willacy, Calhoun, and Harris
Counties, Texas.

Three sinistral specimens were found at Boca Chica.

Polygyra texasensis Pilsbry, BC-10, PIa-33, PIb-2.

Polygyra scintilla, new species, pi. 5, figs. 3, 3a. BC-15, Pla-
38, PIb-4.

The shell is strongly depressed, with rounded periphery, the
spire very low or nearly flat. The surface is almost smooth,
being finely striate above and below, with a few rib-striae behind

Jan., 1956] the nautilus 95

the lip. Color pale brown, usually with a narrow reddish-brown
band above the periphery. The umbilicus has an externally
small axial hole, expanding in the last half whorl to about one-
seventh of the diameter of the shell. The last quarter whorl is
strongly expanded, giving the shell an oval outline. The last
whorl descends abruptly in front, and is deeply contracted be-
hind the lip. The lip is reflected, forming about three-fourths
of a circle, rather heavily callused within, strongly dished, with
two rather slender teeth, set close together, one basal, the other
on the outer margin. Parietal tooth v-shaped, lower branch
straight or nearly so, upper branch with a slight curve. There
is no internal tubercle on the columellar wall.

Height 3.6 mm. Diameter 7.5 mm. 4.3 whorls. Paratype.
Height 4.8 mm. Diameter 10.0 mm. 5.0 whorls. Paratype.
Height 4.2 mm. Diameter 9.1 mm. 4.7 whorls. Holotype.

Texas : Willacy Co. : along the railroad, 1.5 miles north of
Raymondville. Holotype 196560 and Paratypes 196559 ANSP
Paratypes 14407, collection of L. Hubricht. Mexico: Nuevo
Leon: drift, Rio Sabinas, Sabinas Hidalgo. Tamaulipas: loess,
1.4 miles southeast of Cuidad Mier; drift, Rio San Fernando,
San Fernando ; roadside, 9 miles southwest of Santa Teresa.

This species differs from Polygyra texasiana (Moricand) by
its more depressed, more oval shell, and the smaller central hole
of the umbilicus. The lip is more dished, the ends of the lip
come closer together, and the teeth are more slender. The lower
branch of the parietal tooth is straighter. The umbilical region
resembles that of P. jacksoni (Bland).

For comparison we figure (pi. 5, figs. 2, 2a) Polygyra polita
Pilsbry and Hinckley, 1907, described from Tampico, in river
debris (Nautilus 21: 38, pi. 5, f. 11). This has a wider axial
hole of the umbilicus than P. scintilla and the peristome is more
"dished."

Polygyra texasiana tamauUpasensis Lea (pi. 5, figs. 1, la) as
another related species, of which we figure the holotype, 117885
USNM., by courtes}^ of Dr. Rehder. It has a nearly flat spire
of 4% whorls, with a diameter of 9.6 mm. The surface is
nearly smooth except behind the upper and outer lip where
there are five or six riblets. The umbilicus is contained about
4.8 times in the diameter. Its axial hole is larger than in P.
polita, therefore much wider than in P. scintilla; and it differs
from both in having the tooth of the outer lip on the same level

96 THE NAUTILUS [Vol. 69 (3)

as the basal tooth. In poUta and scintilla the outer tooth is
more deeply placed, only partly visible in a direct basal view.

P. t. tamaulipasensis seems to be completely identical with the
form described as P. t. hyperoUa Pilsbrj^ & Ferriss (Proc.
A.N.S. Phila. 1906, p. 128, pi. 5, figs. 13-15) from the high mesa
west of Devils River, Val Verde Co., Texas. Lea's type looks
like a river drift specimen, having their characteristic polish.

Polygyra mooreana (W. G. Binney), PIa-83, PIb-192.

Polygyra tholus (W. G. Binney), BC-2, PIa-69, PIb-217. The
shells of this species sorted from those of P. mooreana without
difficulty.

Polygyra clorf enilliana Lea, PIa-45, PIb-96.

Polygyra clorf euilliana sampsoni Wetherby, PIa-1. For this
specimen to have come from the known range of sampsoni in
northwestern Arkansas or northeastern Oklahoma it would
have had to drift down some Arkansas river into the Mississippi,
thence into and across the Gulf of Mexico, which seems an im-
possible journey. It is more probable that it is an aberrant shell
from somewhere in Texas.

Stenotrema leai aliciae (Pilsbry), BC-15, PIa-147, PIb-359.
PraUcolella griseola (Pfr.), BC-2, PIa-2.
Praticolella herlandieriana (Moricand), BC-9, PIa-1.
PraUcolella pachyloma ('Menke' Pfr.), PIa-1.

FRESH-WATER MOLLUSKS AND STREAM
POLLUTION

By CHARLES B. WURTZ
Consulting Biologists, Philadelphia 2, Pa.

The intense interest throughout the nation today on pollu-
tion, clean-stream programs and conservation, has led to an
intensification of study into the biological effects of pollution.

Pollution is commonly divided into three basic types. These
are physical, such as siltation or high temperatures; chemical,
such as acidity or toxic wastes ; and biological or organic. The
latter consists of ororanic waste material that is not in itself

Jan., 1956] the nautilus 97

toxic, but which may, by its decomposition in nature, exert an
oxygen demand in excess of that found in natural waters. Both
sewage and many industrial wastes contribute to this type of
pollution. Since the effect of both physical and chemical pollu-
tion upon the fauna of a body of water is usually direct, and
usually absolute, these types of pollution are not further con-
sidered here.

Organic pollution passes through various degrees of intensity.
When an organic pollutant first enters a body of water it may
have no immediate effect upon the water. As time passes this
material is broken down by bacterial action. The bacteria
concerned demand oxygen for their life processes, although some
phases of decomposition may be effected by anaerobic bacteria.
If the volume of organic material is slight in comparison to the
volume of water in the receiving body, the pollutant may, in
effect, be nothing but an enrichment of the water. Actually,
this is fertilization of the water. Because of this, a slight or-
ganic pollution may be a desirable feature in a stream or lake.
However, when the volume of organic waste flowing into a body
of water is so large that the bacteria that contribute to the de-
composition of the material exhaust the available oxygen in
the water, septic conditions occur. This is putrefaction and is
gross pollution. All intermediate conditions occur.

In flowing water, which is the usual depository for effluents
disposing of waste materials, a septic condition usually does not
occur until the material has passed some distance downstream.
The actual distance is quite variable and depends on tempera-
ture, rate of flow, volume of organic matter in relation to water
volume, and many other factors.

When large volumes of organic waste are dumped into a
stream, the stream first enters a zone of degradation. As the
pollutant proceeds downstream, and the bacterial content in-
creases, a septic zone develops where there is no oxygen. Be-
low the septic zone, and associated with the completed decom-
position of the organic waste, a recovery zone is found. Below
the recovery zone the stream returns to a clean-stream condition.
If the pollution load is not too great there may not be a septic
zone; the zone of degradation gives way to the recovery zone.
In most streams in the highly industrialized east one waste

98 THE NAUTILUS [Vol. 69 (3)

effluent succeeds another in the course of the stream from its
headwaters to its mouth. As a result, the stream may not have
a clean-water zone anywhere throughout its whole course, al-
though septic pollution may not be present.

In the study of stream biology in relation to pollution, it was
early recognized that some species of organisms could with-
stand pollution in varying degrees of intensity, while others
were eliminated from the fauna if only a small amount of pollu-
tion was present. As these latter species disappeared, reducing
the number of species in any particular habitat, the more toler-
ant species increased in number to take advantage of the avail-
able food or fill the available space. If predator species are
eliminated by pollution (and many are) there is no way to hold
the more tolerant species in check, and large populations of these
species occur. A typical example of this is the very tolerant
worms of the family Tubificidae. Some species of this family
are so tolerant that they develop vast populations below sewage
outlets where other animals cannot live. This phenomenon has
resulted in their common name, '* sewage worms."

During the course of my own work in this field, I have culled
the literature on the subject, and gathered together all the avail-
able information on the response of North American fresh-water
mollusks to pollution. This includes only those mollusks identi-
fied to the species level. General statements concerning families
or genera are not helpful when interpreting stream conditions
based on specimens actually collected at a given spot. Some ob-
servations are based on my own field work, while others were
originally made known by other workers.

In presenting the following list of species known to be tolerant
it must be borne in mind that we are woefully lacking in knowl-
edge on this subject. We do not yet know the exact tolerance
limits of any of these species, although, so far as I have been able
to ascertain, no mollusks are able to withstand protracted gross
pollution. We can anticipate that many species will be added
to the list as further work continues. The species listed below
can survive, at least to some degree, in the zones of degradation
and recovery.

Jan., 1956]

THE NAUTILUS

99

Mytilopsis leucophaeatus

(Conr.)
Bangia cuneata Gray
Sphaerium rhomhoideiim

(Say)
Sphaerium corneum (L.) ^
Sphaerium striatinum

(Lam.) 2
Sphaerium sulcatum (Lam.)
Sphaerium (Musculium)

securis Prime

Pelecypoda

Sphaerium (Musculium)

transversum (Say)
Pisidium amnicum (Miill.) ^
Pisidium casertanum (Poll)
Pisidium compressum Prime
^ Pisidium fallax Sterki

Pisidium henslowanum

(Sheppard)
Pisidium suhtruncatum Malm.

Gastropoda
Campeloma integrum (Say) Helisoma anceps (Menke)

Campeloma riifum (Hald.)
Bulimus tentaculatus (L.) ^
Lymnaea caperata Say
Lymnaea humilis Say
Lymnaea ohrussa Saj^
Lymnaea palustris (Miill.)
Lymnaea stagnalis (L.)
Lymnaea auricularia (L.) •''
Pseudosuccinea columella

Helisoma trivolvis (Say)
Gyraulus arcticus (Miill.)
Menetus dilatatus (Gould)
Aplexa hypnorum (L.)
Physa gyrina Say
Physa heterostropha (Say)
Physa integra Hald.
Ferrissia fusca (C. B. Adams)
Ferrissia tarda (Say)

(Say)

Physa heterostropha is the most tolerant species that has been
found. As it is common and widespread it would be expected
to occur repeatedly in collections. It is tolerant to the extent
that some workers have considered it as an ''indicator species"
for pollution. Members of this genus have been known to clog
trickling filters in waste disposal systems, but to date I have
had no opportunity to examine any material of this type so can-
not venture an opinion on the species concerned.

No Unionidae have been found to be tolerant to polluted con-
ditions. We can conclude that this family is more sensitive to

1 Found throughout the Great Lakes region and may represent a European
introduction.

2 This has been recorded from a pollution zone as S. notatum Sterki.

3 Recently introduced into the Great Lakes region.

4 Introduced into the Great Lakes region where it is now very common.

100 THE NAUTILUS [Vol. 69 (3)

pollution than the Sphaeriidae. Unionidae are found in the
Pennypaek Creek in Philadelphia, and this stream was just
this year (1955) closed to public bathing: because of ''pollution."
However, this closure was based on public health standards and
is contingent on the coliform bacteria count. It does not imply
a heavy pollutional load, but, rather, reflects water quality.
The coliform bacteria are an indication of pollution from sewage,
and a very little of this goes a long way when it comes to recrea-
tional waters.

OBSERVATIONS ON THE RECENTLY EXTINCT
MOLLUSK FAUNA OF PANAMINT LAKE

By JOSHUA L. BAILY, JE.

The opportunity to examine an interesting collection of semi-
fossil shells from the dry bed of Panamint Lake in Inj^o County,
California, has recently been given this writer b}^ Dr. Carl L.
Hubbs of the Scripps Institution of Oceanography at La Jolla,
California. This opportunity was especially welcome because
it makes possible the comparison of the mollusk fauna of this
area with that of the pleistocene Lakes Lahontan and Bonneville,
upon which the present writer has recentl}^ reported (Nautilus,
vol. 63, pp. 73 et seq.).

The physiography of the Panamint area is now the object of
Dr. Hubbs' researches, and he is now preparing a report upon
it. The mollusks taken by Dr. Hubbs are as follows :

Valvata humeralis CALIFORNIA Pilsbry

The type locality of this species is in Mexico, but the variety
is found as far north as Puget Sound. It has a less elevated
spire than the typical form. Specimens from Panamint Lake
are intermediate between the type and the varietj^, just as has
already been found to be the case in Utah Lake and Bear Lake.

Amnicola longinqua Gould

The Amnicola from Panamint Lake is certainly not Amnicola
Integra Say, the species characteristic of Lake Lahontan, nor is
it Amnicola limosa Say, which characterizes Lake Bonneville.

Jan., 1956] the nautilus 101

It seems more prudent at present to identify it with Amnicola
longinqua Gould, a well-known species from Lake LeConte in the
Colorado Desert, which has also been reported from Utah. It
resembles Amnicola pilshryana Baily (loc. cit., p. 50, pi. 4, f. 3,
as A. Pilshryi, preoc.) but is about twice the linear dimensions
of that species. Further, the latter is known only from Bear
Lake in Utah and Idaho, and this writer naturally hesitates to
identify as conspecific two populations from two localities so
remote from each other, when no similar form is found in the
intervening territory.

Lymnaea kingii utahensis Call

This form was originally described as a distinct species (Bull.
U.S. Geol. Surv. no. 11, p. 47, 1884) but some modern authorities
believe it to be indistinguishable from the Pliocene Lymnaea
kingii Meek (U. S. Geol. Surv. Terr., vol. IX, p. 532, 1876) of
which it is undoubtedly a lineal descendant. F. C. Baker (The
Lymnaeidae of North and Middle America, pi. XVII, f . 1, 2, and
pi. XXIV, f. 22-7, 1945) has illustrated both nominal species.
The columella, which in L. kingii is plaited and oblique, and in
L. k. utahensis simple and vertical, seems to afford a basis for
its recognition as a subspecies, for which reason Call's name is
retained here with that rank. Baker's statement (loc. cit., p.
103) that Call's figures are not good and do not correctly
represent the species is not borne out by his reproduction of
them (loc. cit., pi. XXII, f. 9-11) ; actually they are very good
representations of an extreme form sometimes assumed by this
very variable subspecies.

Parapholyx effusa costata Hemphill.

Baker (The Molluscan Family Planorbidae, p. 164, 1945)
recognized as valid five species of the genus Parapholyx together
with four varieties which he considers entitled to the rank of sub-
species. While it is quite possible that several different species
may be involved, variation in this genus is so great that examina-
tion of a large series of individuals seems to eradicate many of
the supposed differences, just as the present vrriter had already
found the situation in the case of this genus from Pyramid and
Humboldt Lakes (loc. cit., p. 86).

102 THE NAUTILUS [Vol. 69 (3)

On the Panamint Lake material the predominating form seems
to be characterized by two sets of costae intersecting each
other at right angles, either one of which may be absent, for
which reason this writer is inclined to identify this material as
P. e. costata Hemphill, but it must be borne in mind that speci-
mens entirely devoid of costae occur in this population, and these
are connected with the costate forms by intergrades, so that
their separation is not practical. In fact, Baker (loc. cit., pi.
116, f. 12-4) figures completely smooth examples under this
name.

Haldane (Science Advances, pp. 85-95; 213-4; 227-32, 1948)
has expressed the belief that a race must not be conceived of as a
separate variant but as a mixed population of several variants
distinguished by the proportions in the population constituted
by each variant. If this definition of race be accepted then it
becomes clear that the Panamint population is not a subspecies
though it may be a race. On the whole, the shell of the Panamint
race tends to be heavier and more costate than that of the
Lahontan race, although it would be easy to select individuals
of any pattern from the two populations that would be quite
indistinguishable from each other.

Carinifex newberryi Lea

Baker (loc. cit., p. 158) lists four species and three additional
subspecies of this genus. Although the Panamint material is
highly variable no one need hesitate to assign all of it to this
species.

In addition to the five species mentioned above there is one
species each of Physa, Anodonta, and Pisidium. Any guess as
to the specific identity of these is hardly justified by the present
state of our knowledge.

The Anodonta is represented by a single fragmentary cast,
the Pisidia are all single valves and too young, and the nomen-
clatorially chaotic state of the genus Physa is such as to make
it extremely hazardous for any one to ' ' stick out his neck " in an
effort to append a name to these specimens that will not meet
with disapproval from some quarter.

There are two peculiar features of the Panamint Lake fauna.
First is the complete absence of the genera Gyraulus and

Jan., 1956] the nautilus 103

Helisoma. These are represented practically everywhere in
North America. Both contain widespread species and species
of limited distribution, sometimes several species of each are
found together in the same body of water, and in number of
individuals they usually surpass those of other species living
with them.

Second is the occurrence so far south of the genera Carinifex
and Parapholyx and the subspecies Lymnaea kingii utahensis.
The first of these has two species of highly localized distribution,
one in Klamath Lake, Oregon, and the other in Jackson's Hole,
Wyoming. These are readily recognizable. The third species,
Carinifex newherryi, is very variable and its habitat extends
from Clear Lake in California to Bear Lake in Utah and Idaho.
The present writer cannot recognize more than one species of
Parapholyx, whose distribution is almost as wdde as that of
Carinifex. Baker (The Ljinnaidae of North and Middle Amer-
ica, p. 460) restricts the habitat of Lymnaea kingii utahensis
to Utah. Panamint Lake is so far outside the limits of the re-
corded ranges of these three species as to be quite a surprise.

Baker (The Molluscan Family Planorbidae, p. 164) lists
Parapholyx leana H. and A. Adams from West Columbia, which
locality he identifies as British Columbia, and doubts that this
practically unknown species could have been taken north of the
United States. The present writer would suggest that West
Columbia in the original description may be a typographical
error for West Colombia, a name formerly applied to what is
now called Ecuador. This country is far outside the range of
Parapholyx, but the next nation to the south, Peru, is the home
of the genus Taphius, which while not closely related anatomi-
cally to Parapholyx bears a striking conchological resemblance
to it. Since the older of the two Adams brothers worked ex-
tensively with South American land snails, it seems reasonable
to suppose that ^'Pompholyx^' leana may have been a Taphius
from Ecuador.

In conclusion the writer wishes to thank Dr. Hubbs for the
privilege of examining this collection.

104 THE NAUTILUS [Vol. 69 (3)

STATISTICS ON A COLONY OF

CEPAEA NEMORALIS

By M. ALAN LANDMAN

In his paper, ''The Variation of Banding in Cepaea," Dr.
F. A. Schilder of the University of Halle, Germany, wrote in
the Nautilus (62: 4) : ''. . . statistical studies need further re-
search ; it could be supported by American malacologists publish-
ing similar exact data on the Cepaea observed in restricted lo-
calities. ..." Recently I compiled some data concerning a
colony of Cepaea nemoralis which I hope will further these
studies.

On Thursday, September 23, 1955, I discovered the colony
on a section of a city block in Springfield Gardens, Queens,
New York City. The block is about 145 meters by 60 meters in
area and is bounded by Merrick Blvd., Sunbury Rd., Irwin
Place and Ursina Rd. in Springfield Gardens. About one-
quarter of the block at Irwin PI. and Ursina Rd. has dwellings,
but the lot area takes up about 6300 square meters. At least
four-fifths of the specimens collected were taken in the quadrant
at Irwin PL and Sunbury Rd. and, in fact, very little else on
the block was explored. Thus, I would estimate that the colony
consists of about 5000 individuals on that block.

The surface of the lot has many depressions and much debris
is scattered about, providing good cover for snails. The debris
consists of corrugated board boxes and wooden boards and slats,
with a couple of rejected seat cushions also yielding a good
quantity of snails. The lot is overgrown with the usual com-
mon weeds, such as crabgrass {Digit aria sp.), dandelion (Tarax-
acum officinale) and dock (Riimex). The trees include oak,
maple and wild cherry. Ragweed (Ambrosia), milkweed (As-
clepias) and poison ivy (Toxicodendron) also have a foothold.
Numerous Diptera were present, there being some garbage ma-
terial on Irwin PL One Limax maximus was found and sev-
eral dozen Blattidae were seen scurrying around and under
some of the cardboard pieces lying around. Two DeKay snakes
were also seen under wooden slats.

In four trips to the colony I collected 1297 individuals and
indexed them according to bands. A majority of the snails have

Jan., 1956

THE NAUTILUS

105

a yellow ground color (variety lihelulla), but a few red snails
(var. rubella) were also present. The variations are as fol-
lows :

yellow

ground color

669

00000

3

(12)0(45)

12340

333

12345

3

10345

10000

43

00300

2

(12)045

(12) (34)5

44

123(45)

2

(123)45

023(45)

28

12045

2

1(23)45

00340

12

(12)3(45)

2

12305

10045

6

02345

2

(12345)

red g)

^ound color

6

(123) (45)

1

120(45)

104

00000

5

(12)345

1

12(34)5

4

12345

5

(23) (45)

1

(12) (345)

13

00300

In practically all specimens the shells were in prime condition,
only a few showing signs of erosion of the nuclear whorls. It
was noticed, though, that the best preserved shells were taken
from the ragweed on Irwin Place and from the clumps of iris
lining the side of the dwellings, the rest of the lot ground being
comparatively open.

While I was collecting, I talked to a number of people nearby.
One man said that he had noticed the snails for more than forty
years. This seems to agree with the large number of specimens
found and seen in such a relatively small area. To a degree
it also coincides chronologically with reports of a Flushing
colony in 1906. The present colony is located not far from
Flushing, and its origin may well be in specimens from the latter
area.

Along with the main colony at Merrick Blvd. and Sunbury
Rd. in which I spent four hours, I also explored some secondary
lots and discovered more nemoralis. About two blocks from
the main lot is a smaller one at the corner of Sunbury Rd. and
120 St. This block, incidentally, is in St. Albans. I spent
two hours there and indexed 92 snails. The totals :

yellow

red

50 00000

2

(12)3(45)

6

00000

25 12345

1

10345

7 00300

1

12045

106 THE NAUTILUS [Vol. 69 (3)

The results seem to show this group as some sort of offshoot of
the large lot. Among the plants seen were bouncing-bet {Sapo-
naria officinalis), Japanese honey-suckle {Lonicera japonica),
Ambrosia, Quercus, Acer, Primus, Aster, snapdragon {Antir-
rhinum), golden rod {Solidago sp.), milkweed {Asclepias sp.)
and sassafras {Sassafras variifolium) . Limax maximus were
present and I also took a specimen of the beautiful Coptocycla
(or Metriona) hicolor.

On Sunday, September 26 I collected again. It was right
after a rain and the ground was in good snailing condition.
Five blocks down Merrick Blvd, from Sunbury Road past the St.
Albans Naval Hospital is a park at the northwest corner of
Linden and Merrick Blvds. At its outskirts, behind large bill-
boards, is a very nice lot section. Browsing through it, I
turned up five interesting specimens. There were single speci-
mens of (all yellow): 00300; 123(45); (12)3(45); (123)(45)
and 00345. This seems unusual, since the other lots were com-
pletely dominated by 00000 and 12345. There are many spec-
ulations possible with regard to this but only five individuals
were found and there doesn't seem much basis for a definite
statement.

Finally, across the street at Sunbury Rd. on the same side
of Merrick Blvd. is another lot. It is also bounded by Baisley
Blvd. A quick look through it brought out eight snails which
followed the common percentages well. Included were:

Yellow

red

3 00000

1 00000

2 12345

1 123(45)

1 (12)3(45)

I have a number of plans concerning the snails reported on
here and intend to use them for a breeding project. I hope
in a later issue of the Nautilus to report on my experiment and
observations.

I wish to acknowledge the kind advice and assistance of Dr.
William J. Clench of the Museum of Comparative Zoology, Dr.
R. Tucker Abbott of the Pilsbry Chair of Malacology at The
Academy of Natural Sciences of Philadelphia, and Mr. Morris
K. Jacobson.

Jan., 1956] the nautilus 107

PUBLICATIONS RECEIVED

BiVALViA. By F. Haas. Bronns Klassen und Ordnungen des
Tierreichs, "Band" 3, class 3, part (real vol.) 2, no. 4, pp. 679-
909, i-xii, 2 textfigs. 1955. — After a necessary wait of 14 years,
this issue, to be followed by bibliographic supplement, concludes
the text of the two volumes on pelecypods. In completion of
the general subject of ecology, it discusses environmental rela-
tions (mainly in no. 3), the American oyster, the edible mussel,
and gill function, nourishment, excretion, chemical make-up,
blood, growth and age, reactions, intelligence and diseases of
the class. It also includes references to the autecologic (and
physiologic) authors, supplementary lists for vols. 1 and 2, and
a fine index for vol. 2. Title pages, preface and table of con-
tents are appended. The text is semantically clear and pleasant
to read, since it does not hesitate to use relatively terse (and
international) terms. Dr. Haas must be indeed proud of these
indispensable reference books, which bring up to date the
accumulated knowledge about bivalves, and point the way for
future studies.

One apologizes for any criticism of so much masterly achieve-
ment. The great ability of most mollusks, in the reversible
transfer of Ca-salts between body fluids and shell, is discussed
(pp. 743-5 and 810-2) but the treatment of its ecologic sig-
nificance seems inadequate. For example, is not the solution
from the shell of CaCOg, since it buffers the tendency towards
pH reduction (increase of CO2) in the blood during aestiva-
tion (when shells are closed or sealed), fundamentally im-
portant in the animals' resistance to dryness (pp. 698-701)?
— H. B. B.

Ulpia, nuevo genero de Gastropoda terrestre. Par M. I.
Hylton Scott (Neotropica 1, No. 5, pp. 65-68, figs. 1^). The
genus Ulpia is proposed for a minute, conical, openly umbilicate
land shell having apertural teeth similar to Gastrocopta, as the
author remarks. It was found by Dr. Max Biraben at Lum-
brera, province of Salta, Argentina. It is placed provisionally
in the Odontostominae, but we think that it belongs to the
Pupillidae, subfamily Gastrocoptinae, near the little-known
Gibhulina infundihuliformis (Orbigny) ; but it differs from that
species by the more lateral aperture and the presence of five
teeth. — PiLSBRY.

108 THE NAUTILUS [Vol. 69 (3)

American Seashells, third printing. — In the third printing
of American Seashells (D. Van Nostrand Co., N. Y., May 1955),
approximately 200 text changes were made, most of which were
typographical adjustments, although some names were changed,
ranges corrected, and additional bibliographic references added.
The author wishes to thank the many people who kindly pointed
out needed improvements. Some corrections were not included
by the publisher: p. 119, Tegula hotessierana Orbigny should
be considered a young and threaded form of Tegula fasciata
Born; p. 123 (and pi. 3k, m) for Astraea longispina Lamarck,
read A. phoehia Roding; p. 198, Bursa granulans Roding, upon
examination of the radula and anatomy, proves to be a distinct
Indo-Pacific species, so that we must return to the name cuhani-
ana Orbigny for our West Indian species (see also pi. 25-0) ; p.
363, Pecten tereinus Dall is evidently a sjnionym of chazaliei
Dautzenberg (see G. Grau, Nautilus, vol. 68, p. 113). — R. Tucker
Abbott.

Critical review^ of biology and control of oyster drills,
Urosalpinx and Eupleura. By M. R. Carriker. Special Sci-
entific Report, Fisheries no. 148, U. S. Fish and Wildlife Service.
150 pp., 15 tables. 1955. — This is a very careful, complete and
much-needed review of the great amount of research that has
been done on the biology and control of U. cinerea Say and E.
caudata of our Atlantic coast. Many interesting summaries are
given concerning the geographical distribution, morphology, life
history, relation to environmental factors, and control of these
two species. The bibliography contains 177 useful references,
most of which deal directly with these oyster drills. — R. T. A.

Nev^ marine mollusks from Florida. By Thomas L. Mc-
Ginty. Proc. Acad. Nat. Sci. Phila., vol. 107, pp. 75-85, 2 pis.
Nov. 1955. — Twelve new species of deep-water marine mollusks
are described in this article. Included is a remarkable new
genus and species {Aclistothyra atlantica) of a Galeommid bi-
valve resembling the Ephippodonta of the Indo-Pacific. A new
Fasciolariid genus, Fusilatirus, is erected for pauli, new species
and type, and cayohuesonicus Sowerby, on the basis of the very
unusual lateral radular teeth. The shells, however, are ex-
tremely close to those in the genus Dolicholatirus Bellardi 1884,
and the recent species of the latter could bear investigation. —
R. T. A.

THE XAUTILT^S 69 (4)

PLATE 6

1, Gracilincnia filicosfulata Lubomirski. 2, G. aequistriafa Weyrauch,
type. 3, Nenia (Colum'binia) ziscMcai Weyraucli, type. 4, 5, 6, Mucro-
nalia nidorum Pilsbry, shells. 7, 8, nests in sea urchin spines. 9, oper-
culum.

The Nautilus

Vol. 69 APRIL, 1956 No. 4

A GASTROPOD DOMICILIARY IN SEA URCHIN

SPINES

By HENEY A. PILSBRY

Some years ago, in the *' Triton" dredgings off Palm Beach,
Florida, Thomas and Paul McGinty found that the sea urchin
Eucidaris tribuloides (Lamarck) was occasionally found to have
a very short and swollen spine or two among those of the normal
cylindric shape. On examination, these were seen to be spines
modified to form cup-like ''nests" of small white gastropods.
One of these "nests" is drawn in Plate 6, figs. 7 and 8.

One of the sea urchins was kept alive for several days. The
modified spines could be moved about slowly, like the others.
The enlargement forming the nest begins above the smooth dark
red band around the spine next to the joint, and is oval in shape,
as in the drawings. It is often concealed by the body scales of
the urchin. It is nearly rigid, though not quite as hard as the
normal spines, and of about the same dull red color. The nest
drawn is about 5.5 mm. long, 4.5 mm. in diameter. It had one
large and three smaller inmates. Some other nests contained
single snails.

The snails were retracted and quiet by day, but evidently
active at night. Several were seen abroad early in the morning,
one on a spine more than an inch from the nest, to which it
returned later. However, I never saw one in motion, though
I spent a good deal of time watching them.

The earliest reference I have found to a similar use of sea
urchin spines is as far back as 1860: Hupe, in Magazin de
Zoologie (2 ser.) 12: 118-125. He described a Stylifer orhig-
nyanus from "Nouvelle HoUande." This Australian species
has a very short spire and large last whorl and seems properly
referred to Stylifer, but it apparently lives in much the same
way as our Ploridan species.

109

110 THE NAUTILUS [Vol. 69 (4)

So far as I know, this interesting snail has not been noticed
before. A description of the shell follows. The generic ref-
ference is not certain.

MucRONALiA NiDORUM, ncw spccics. Plate 6, figs. 4, 5, 6.

The rather thin white shell is imperforate, lanceolate, smooth
and glossy. The upper part (about a fourth of the length) is
somewhat attenuate and slightly curved. The minute apex is
erect with rounded tip. Several following whorls are only
weakly convex, with superficial suture. The aperture is con-
tained about 2% times in the length; the peristome with regu-
larly semicircular outer and basal margin; the inner margin
concave. Columella thickened.

The operculum is very thin, long ovate, showing some faint
lines indicating former stages of growth; the nucleus is appar-
ently near the base on the columellar margin, but not distinctly
indicated (PI. 6, fig. 9).

No radula could be found.

Length 3.7 mm., diameter 1.7 mm. ; 9% whorls.

The type and figured paratypes are no. 196745 ANSP., from
''Triton" (A. R. Thompson's yacht) station 821, off Palm
Beach, Florida, in 25 fms. Other paratypes in McGinty col-
lection.

The amount of curvature of the upper part of spire apparent
depends of course upon the position of the shell, but there seems
to be a little individual variation in this feature, curvature
being scarcely noticeable in some examples, more distinct in
others.

The author is deeply indebted to the McGinty brothers for
opportunity to examine this interesting mollusk, and to Axel A.
Olsson for excellent photographs (Figs. 4-6) of difficult sub-
jects. Thanks are also offered to Miss Elizabeth Deichmann of
the M. C. Z. for identification of the sea urchin.

TWO NEW SPECIES OF CLAUSILIIDAE FROM
PERU AND BOLIVIA

By Dr. WOLFGANG WEYRAUCH
Professor of Zoology, University of San Marcos, Lima, Peru.

Gracilinenia aequistriata, new species. Plate 6, fig. 2.

Diagnosis: A species of the genus Gracilinenia, characterized
by its considerable length, equally spaced striation and flattened
whorls.

April, 1956] the nautilus 111

Description of type: The shell is entire, very thin, extremely
slenderly fusiform-turrited. Color uniform light, somewhat
reddish brown, whitish frosted by the sculpture of the surface.
The apex globular. Second embryonic whorl decidedly convex,
wider than the first and 3d whorl. Third to seventh whorls
slowly diminishing in convexity; later whorls very slightly con-
vex, nearly flat. From the 3d to the largest, third from last
whorl steadily and slowly increasing in width. The last whorl
with straight lateral outlines, flattened on the upper half of the
back, strongly descending and widely built forward to the aper-
ture. The surface matt, with sculpture of thin lamella-like
raised riblets, mostly whitish, in places light brown, slightly
oblique, continuous and very shortly curved to the right at the
upper end, where they are falling into the furrow of the deeply
impressed suture. The riblets are regularly spaced, on the face
of the last and penult whorl 8 in 1 mm., on the earlier whorls
slightly more spaced, on the face of the seventh whorl 5 to 6 in
1 mm. The aperture is funnel-shaped, slightly longer than wide,
evenly rounded, except for the left side, which is somewhat
straightened. The peristome is broadly expanded, slightly
thickened. The upper margin of the peristome is white, like
the adjacent part of the aperture ; its outer and basal margins
are yellowish brown, like the adjacent interior of the aperture.
The superior lamella is white, high, emerging to the lip edge,
not surpassing the plane of aperture, rather thick, slightly
oblique towards the concave left side; it slowly diminishes
within and is continuous with the spiral lamella. The inferior
lamella is white, very low, but shortly visible in front view of
the aperture; its lower end rapidly converging towards the
superior lamella; its upper half parallel and very close to the
spiral lamella. The subcolumellar lamella is largely visible in
oblique view in the aperture and is widely separated from the
lower end of the lunella. The principal plica is low, white on
the upper rim, light brown on the sides, parallel to the suture,
half a whorl long and surpassing slightly the upper end of the
lunella. The lunella is developed merely as a very low, whitish,
callous ridge, short, slightly and evenly curved. The clausilium
occupies the whole space between lunella and subcolumellaris,
is wide at the middle of the spatula, and its end pointed.

Notes on paratypes: 24 specimens with the same data as the
type. All characters rather constant, except the following: 13
specimens decollate and 11 entire. Color varying from light
reddish to yellowish brown. In the latter specimens the in-
terior of the aperture is very light brown and the peristome
entirely white. The lunella is shortly or widely separated from
the subcolumellaris or continuous with that. Accordingly the

112 THE NAUTILUS [Vol. 69 (4)

end of the clausilium is more or less pointed or more or less
broadly rounded. The following measurements are in mm.

Alt.

Lat.

Alt.

Diam.

apert.

apert.

Whorls

30,4

3,5

3,8

3,6

18 entire, Type

30,5

3,5

3,9

3,8

163/^ entire

29,7

4,0

3,7

3,5

17M entire

29,6

3,8

3,6

3,4

173^ entire

26,8

3,8

4,3

3,6

n}4 decollate

24,2

3,6

4,0

3,7

113/^ decollate

22,3

3,2

3,8

3,2

9}4 decollate

21,7

3,5

3,6

3,5

9}/2 decollate

Type locality: Peru: Valle de Chanchamayo, on the highway
from Hacienda Naranjal near the village San Ramon to the
mine ''Pichita-Caluga"; elevation not measured, but probably
at about 1300 m. Collected by the author.

Material: Type WW 1531 and 11 paratypes in the author's
collection; 2 paratypes in the Senckenberg Museum, Frankfurt
a.M. ; 2 paratypes in the Academy of Natural Sciences of Phila-
delphia; 2 paratypes in the Museum of Comparative Zoology,
Cambridge, Mass. ; 2 paratypes in the Chicago Natural History
Museum; 3 paratypes in the collection of Dr. F. E. Loosjes,
Wageningen, Netherlands ; 2 paratypes in the collection of Prof.
Dr. W. Blume, Gottingen.

Comparisons : Closely related to Gracilinenia filicostitlata Lu-
bomirski, which is figured for comparison (Plate 6, fig. 1), but
mainly different by equal spaced striation and strikingly flat-
tened whorls. Secondary differences: shell higher, somewhat
wider, several whorls more, color darker, more solid, either de-
collate or entire in completely adult specimens, whereas fili-
costulata is always decollate in adult state.

Ecology : The 25 specimens were collected in 5 minutes on the
bare face of an isolated limestone block, about 2 m. high and 3
m. wide, in a clearing of the tumid and high arboreal vegetation
of the subtropical rainforest. The block was protected against
direct sunlight by some high brushes and young large-leaved trees
of 0 chroma spec. Strewn around the big block were smaller lime-
stones of varying sizes, on which no specimen could be detected.
The black animals were met on a cloudy, though not rainy day,
at 3 p.m. crawling upward on the vertical planes of the rock,
which were covered with a sheet of green, unicellular Chlorella-
like algae. The shells were partly covered with the same algae.
The excrements, deposited by the animals, were of uniform light

April, 1956] the nautilus 113

green color in all specimens. A microscopical study revealed
merely the destroyed remains of algae and no trace of fibers of
higher plants. 16 specimens of Peruinia peruana slosarskii
(Lubomirski) were found crawling around on the same lime-
stone block, not only on its vertical surfaces, but also on top of
the rock, covered with a thick layer of rotting leaves.

Nenia (columbinia) zischkai, new species. Plate 6, figures
3, 3a.

Diagnosis: A species of the subgenus ColuniMnia, character-
ized by its considerable size, almost cylindric shape and sculp-
ture of strong, evenly spaced and strongly slanting riblets.

Description of type : The shell is entire, sinistral, rather solid,
elongate cylindric-fusiform, widest at the two penult whorls.
The color is uniform cinnamon-brown, except for a very thin,
whitish band below the suture. Apparently collected shortly
after death, and therefore with a thin layer of a brownish white,
calcareous overwash, filling partly the interspaces of the rib-
lets and the interior of aperture. The apex obtuse and very
large. First three postembryonal whorls very weakly convex;
later whorls nearly flat; the last whorl much elongated, be-
coming free and produced to the aperture. Suture moderately
impressed, very regularly obtusely denticulate by the riblets,
which are somewhat thickened and projecting at the upper end.
Surface matt, and after 2 embryonic whorls, whose sculpture is
corroded by weathering; it has a rough sculpture of strong,
low, rounded riblets, continuous between the suture, somewhat
narrower than their intervals, strongly oblique, more so on the
last three whorls, where they form an angle of 45 degrees with
the suture. There are 3 riblets in 1 mm. on the two penult
whorls and 42 riblets crossing the periphery of the penult
whorl. On the last whorl, the riblets become lower, more
crowded; behind the peristome they are still narrower, more
wavy and frequently interrupted. The principal plica and
lunella are marked in their whole course on the outside of the
last whorl by a deep and very thin incision, just as though cut
with the point of a sharp knife and interrupting the riblets.
Aperture completely free, evenly rounded, broadly ovate, some-
what pear-shaped. Plane of aperture somewhat oblique, convex
in profile and evenly concave in the direction of the shell axis.
Interior of aperture light rose-brown, fading to a dirty ivory-
white on the upper and right side of the peristome, whose left
and inferior half is colored like the interior of the aperture.
Peristome thickened, strongly expanded throughout and well
reflected. Superior lamella not protruding above the peristome,
thick, highly raised, emerging to the lip edge, earlike, very

114 THE NAUTILUS [Vol. 69 (4)

deeply concave on the left side, continuous with the lower spiral
lamella, forming with this a slightly S-shaped curve. The in-
ferior lamella is of light rose-brown color, low, but shortly vis-
ible in front view, not reaching the edge of the peristome, con-
siderably thickened on the upper rim, channel-like arching
over to the junction of superior lamella and the spiralis. Sub-
columellar lamella short, deeply immersed, but shortly visible in
very oblique view in the aperture, terminating widely separated
from the lower end of the lunella. Principal plica white, high,
thin, dorso-lateral, half a whorl long, slightly surpassing the
upper end of lunella and shortly separated from that. The
lunella is dorso-lateral, well developed as a low and wide ridge,
weakly and evenly arched, brownish-rose colored and darker
than the surrounding inside of the shell. The clausilium is
strongly curved lengthwise and transversely, evenly rounded at
the end, close to the subcolumellar lamella, but slightly sepa-
rated from the lunella.

Notes on paratype: One specimen, same locality as the type,
partly bleached, somewhat damaged, has the earlier whorls more
slowly tapering and the whitish band below the suture a little
broader. In all other features, this paratype corresponds per-
fectly with the type.

Measurements are in mm. :

Alt. Lat.

Alt. Diam. apert. apert. Whorls

34,8 6,2 6,9 5,8 SH Type

32,0 5,8 6,6 5,4 SH

Type locality: Eastern Bolivia: Yungas de Palmar, 700 m.,
tropical rain forest. Collected by Mr. Rudolf Zischka, after
whom this new species is named.

Material: Type WW 1368 in the author's collection; 1 para-
type in the Academy of Natural Sciences of Philadelphia.

Comparisons : C. zischkai can only be compared with the group
of C. hartletti Adams {= ohesa Haas), comprising reyrei Jous-
seaume, huancahamhensis Rolle, juninensis M. Smith and hinkiae
Pilsbry, all described from the subtropical and tropical forest
of Ecuador and eastern Peru, and all at hand except reyrei.
Our novelty is nearest to hinkiae from south eastern Peru, which
has (1) the same evenly spaced, strong, low and rounded rib-
lets, (2) the same regularly and obtusely denticulate suture,
and (3) the same very obtuse apex. But zischkai is twice as
high as hinkiae^ is decidingly less fusiform, has the riblets more
oblique on the last three whorls and its inferior lamella is

April, 1956] the nautilus 115

channel-like arched towards the superior lamella and spiralis,
not plain as in hinkiae. For its height, zischkai is nearest to
juninensis of 30 mm. length, but this is (1) attenuate above,
(2) has the suture irregularly crenulate and (3) its riblets are
finer, more crowded, often interrupted, often changing the
direction and less slanting. Only hartletti (= ohesa) has a
slightly arched inferior lamella; but zischkai differs from that
by greater length, straightened outlines, and the sculpture of
surface, which is in ohesa intermediate between hinkiae and
juninensis.

I consider the above mentioned species of the group of C.
hartletti only subspecifically distinct, in the sense of geographi-
cal races. But I regard zischkai specifically different for the
following characters: (1) shell less ventricose; (2) height of
last whorl in front view, including expansion of peristome, con-
tained 2y2 times in altitude of shell, whereas in hartletti and its
races this proportion is 1:2.

TWO NEW SUBSPECIES OF NEPTUNEA
DECEMCOSTATA

By ARTHUR HADDLETON CLARKE, JR. *

In 1953, an extensive collection of deep water marine mol-
lusks was presented to the Department of Mollusks of the Mu-
seum of Comparative Zoology by Mr. W. C. Schroeder, Associate
Curator of Fishes at that institution. The specimens had been
obtained during a faunal survey of the continental slope area of
northeastern North America conducted by the Woods Hole
Oceanographic Institution in 1952 and 1953. Operations were
under the direction of Mr. Schroeder, and the trawler Cap'n
Bill II had been used for the survey. A report on these mol-
lusks has been published (Clarke, 1954).

From the material collected, apparently considerable varia-
tion in shell form existed between lots of Neptunea decemcostata
Say. All the western Atlantic specimens of Neptunea in the
Museum of Comparative Zoology and the United States National
Museum were examined and measured, and many Eastern At-
lantic specimens were studied also. The existence of two mor-

* Curator of Mollusks, Department of Geology, Cornell University.

116 THE NAUTILUS [Vol. 69 (4)

phometrically divergent allopatric populations geographically
removed from the main population of decemcostata became ap-
parent. These newly defined assemblages are here described as
subspecies of decemcostata.

Such a treatment is admittedly conservative, and further re-
searches may show that one of these (clenchi) is a distinct
species standing between N. despecta Linne (sensu latu) and N.
decemcostata. The world-wide problem will be studied further.

Neptunea decemcostata clenchi, new subspecies. Plate 7,
fig. 1.

Adult shell about 80 to 128 mm. in length, sturdy, spire
greatly extended, imperforate and possessing numerous reddish-
brown, revolving ribs; ground color brownish-white; whorls
eight to nine and convex, and spire produced at an angle of
about 48° to 58°. Aperture sub-ovate with the siphonal canal
somewhat extended and rather broad; outer lip sharp and
crenated at the upper margin; umbilical and parietal areas
covered by a rather narrow callus; columella produced as a
shallow sigmoid curve; and suture slightly impressed. The
sculpture consists of numerous reddish-brown spiral chords
which are usually somewhat darker than the ground color;
major chords approximately equidistant and varying from 12
to 14 on the body whorl with about 4 showing on the earlier
whorls; peripheral chord largest and defining a wide convex
shoulder with one minor chord between it and the suture;
sutural chord faint or absent; other chords decreasing in thick-
ness and becoming extinct near the base of the siphonal canal.
A series of minor chords between the major ones may also be
present. The lower whorls are also sculptured with fine, re-
volving threads which are restricted to the area between the
chords. Axial lines of growth are numerous, prominent, and
coarse. The operculum is mahogany brown, corneous and un-
guiculate with an apical nucleus and coarse concentric growth
lines ; inner side of operculum with a thickened marginal callus
and concentric ridges in the scar area.

Remarks. The outstanding characteristic of the benthic Nep-
tunea decemcostata clenchi is its long, slender form. This will
immediately distinguish it from the normally sub-littoral N.
decemcostata Say. In addition, clenchi exhibits eight to nine
whorls and twelve to fourteen major spiral chords on the body
whorl, while decemcostata has six to eight whorls and nine to
eleven major spiral chords. Also, the chords on clenchi are only
slightly raised and of moderate prominence, but decemcostata

April, 1956] the nautilus 117

has strongly elevated and very prominent chords. See further
remarks under discussion.

Types. The holotype is number 202152 in the Museum of
Comparative Zoology. It was taken from a depth of 340 to 350
fathoms at 42° 46' N. latitude and 63° 22' W. longitude (ap-
proximately 100 miles E.S.E. of Cape Sable, Nova Scotia, Cap^n
Bill II station 88) by members of the staff of the Woods Hole
Oeeanographic Institution during a faunal survey of a portion
of the continental slope. Two paratypes were taken at the same
station (M.C.Z. no. 202153).

Length (L)

Width (W)

W/L

Holotype

110 mm.

48 mm.

0.44

Paratype

84

40

0.48

Paratype

127

59

0.46

Specimens examined were from: Station 86, 42° 23' N. Lat.,
64° 58' W. Long, in 230-245 f ms. ; Station 88 (type locality)
42° 46' N. Lat., 63° 22' W. Long, in 340-350 fms.; Station 95,
42° 45' N. Lat., 63° 47' W. Long, in 330-340 fms.; Station 104,
42° 40' N. Lat., 64° 08' W. Long, in 350-380 fms.; Station 165,
42° 42' N. Lat., 63° 47' W. Long, in 360-370 fms.; Station 173,
42° 40' N. Lat., 64° 10' W. Long, in 240-270 fms.; Station 182,
42° 28' N. Lat., 64° 31' W. Long, in 280-305 fms. ; Station 184,
42° 23' N. Lat., 64° 52' W. Long, in 265-295 fms.

These stations are all on the continental slope and are ap-
proximately 80 miles southeast of Cape Sable, Nova Scotia. All
specimens were obtained by the Cap^n Bill II survey, to which
the station numbers refer.

I take pleasure in naming this subspecies in honor of Dr.
William J. Clench, whose helpful guidance and sound judgment
have been a valuable aid on many occasions, and under whose
watchful eye the basic work on this paper was done while the
author was a graduate student at Harvard University.

Neptunea decemcostata turnerae, new subspecies. Plate 7,
%. 2.

Adult shell about 60 to 85 mm. in length, sturdy, spire slightly
extended, sub-imperforate and possessing numerous strong, red-
dish-brown, revolving ribs ; ground color brownish-white ; whorls
six to seven and convex, and spire produced at an angle of about

118 THE NAUTILUS [Vol. 69 (4)

68° to 75°. Aperture sub-ovate with the siphonal canal short
and broad ; outer lip sharp and crenated at the margin ; parietal
callus thin and sometimes partially lacking; umbilicus shallow
or lacking and usually covered by the callus ; columella produced
as a shallow sigmoid curve ; and suture well marked. The sculp-
ture consists of numerous heavy, raised spiral chords which may
be the same or somewhat darker than the ground color; chords
approximately equidistant and varying from 9 to 10 on the body
whorl with 2 to 3 showing on the earlier whorls; peripheral
chord largest, set at some distance from the suture and forming
the edge of a wide, excavated shoulder; other chords decrease
in thickness anteriorly and become extinct at the base of the
siphonal canal; and chords barely visible within the aperture
as shallow grooves. The lower whorls are also sculptured with
numerous fine, revolving threads which occur both between and
on the spiral chords. Axial lines of growth are numerous,
prominent, and coarse. The operculum is mahogany brown,
corneous and unguiculate with an apical nucleus and coarse con-
centric growth lines; inner side of operculum with a thickened
marginal callus and concentric ridges in the scar area.

Remarks. The short, obese form and abbreviated spire of the
localized Neptunea decemcostata turnerae are the most obvious
and reliable differential characteristics between it and the widely
distributed N. decemcostata decemcostata Say. In addition,
turnerae has six to seven whorls and nine to ten major spiral
chords on the body whorl, whereas decemcostata has six to eight
whorls and nine to eleven major spiral chords. Also, the chords
of turnerae are usually somewhat more prominent than those of
decemcostata. See discussion for additional comments.

Types. The holotype is number 202151 in the Museum of
Comparative Zoology and was taken by A. E. Verrill at Grand
Manan Island, New Brunswick, Canada. Fourteen paratypes
from the same station are in the M.C.Z. collection (No. 72584).

Length (L)

Width (W)

W/L

Holotype

62 mm.

43 mm.

0.69

Paratype

68

48

0.71

Paratype

61

40

0.66

Specimens examined were from. New Brunswick: Grand
Manan Island (type locality) (Museum of Comparative Zoology,
United States National Museum). Maine: Lubec, Washington
Co.; Trenton Point, Hancock Co. (both Museum of Comparative
Zoology).

April, 1956] the nautilus 119

I take pleasure in naming this subspecies in honor of Dr. Ruth
D. Turner, who has cheerfully given many hours of valuable
help in connection with this paper and other related problems
and who is doing a great deal to advance the science of
malacology.

Discussion

Neptunea decemcostata occurs from the Grand Banks and the
Gulf of St. Lawrence southwestward to the latitude of North
Carolina. North of Cape Cod, specimens may be found at sta-
tions ranging from just below low tide line to beyond the outer
edge of the continental shelf, but south of New England the
species is known only from the upper continental slope. As far
as is now known, individual shell form does not vary to any
significant degree throughout this range except in the two small
areas populated by clenchi and turnerae. The type locality of
Fusus 10-costata given by Say: 'Hhe coast near Boston," is
near the center of the range of typical decemcostata, and his
measurements (3.3 inches long and 1.9 inches wide) give a width
to length ratio of 0.576, and show that he had the common form.
His description is also of a typical specimen.

The elongate subspecies N. d. clenchi has been found only
over a small area of the continental slope about 80 miles south-
east of Cape Sable, Nova Scotia, in depths ranging from about
245 to 360 fathoms. Specimens from similar depths taken at
points further southwest are typical decemcostata. No collec-
tions have been made at these depths from points immediately
northeast of the known range of clenchi, or in deeper water near
the area worked. Further investigations may therefore extend
the known geographic and bathymetric range of this subspecies.

The short-spired subspecies N. d. turnerae is known only from
the area between Grand Manan Island, New Brunswick, and
Trenton Point, Maine (near Mount Desert Island). How far
eastward the subspecies occurs is unknown because of lack of
records, but specimens from Digby and from Halifax, Nova
Scotia, are typical decemcostata. A large number of lots from
stations southwest and south of Trenton Point have been ex-
amined, and they are all normal decemcostata. Specimens from
Eastport, Maine seem to be a mixture of decemcostata and tur-
nerae however, and this is the only area known to the author
where a heterogeneous population occurs. As is well known,

120 THE NAUTILUS [Vol. 69 (4)

such mixtures are to be expected at zones of contact between
subspecies.

Application of the 75% rule adds strength to the hypothesis
that clenchi and turnerae are subspecifically distinct from de-
cemcostata. Utilizing the largest lots of specimens available,
and applying the statistical principles for subspecific discrimi-
nation suggested by Mayr (Mayr et al., 1953) the following data
were computed (N = number of specimens; W/L = ratio of
maximum width to length, or index of obesity ; and S.D. =
standard deviation from the mean). Localities of shells tabu-
lated are as follows: N. d. clenchi, all available specimens from
type area. Typical subspecies, population A, from off Flemish
Cap, Grand Banks, 200-250 fms. ; B, from off Cape Ann, Mass.,
25-60 fms. N. d. turnerae, 2 lots from Grand Manan Island.

Width

-7- length

Subspecies

No.

Max.

Min.

Mean

S.D.

clenchi

16

.54

.44

.491

.026

decemcostata

16

.61

.53

.580

.021

(population A)

decemcostata

23

.62

.54

.583

.029

(population B)

turnerae

24

.71

.61

.662

.025

From the above data, the CD. (Coefficient of Difference) was
calculated for the populations to be compared. A CD. of 1.28
indicates that 75% of the individuals of population I are dif-
ferent from 97% of the individuals of population II, or that
90% of population I is different from 90% of population II
(90% non-overlap). This is the conventional level of subspecific
difference, and higher CD. or non-overlap (N.O.) values are
progressively more significant.

The CD. and non-overlap values derived from the above data
are as follows: clenchi-decemcostata (A), 1.89 CD., 97% N.O. ;
clenchi-decemcostata (B), 1.67 CD., 95% N.O. ; turnerae-decem-
costata (A), 1.78 CD., 96% N.O. ; turnerae-decemcostata (B),
1.46 CD., 94% N.O.

From these figures it may be seen that the degree of difference
in index of obesity between clenchi and decemcostata and be-
tween turnerae and decemcostata is well above the conventional
level necessary for subspecific discrimination. Similar calcula-
tions using other shell characteristics would have given com-

THE NAUTILUS 69 (4)

PLATE 7

1, Neptunea decemcostata clenchi Clarke, type. 2, .Y. d. tunierae Clarke,
type. S, X. d. decemcostata (Saj). All figs, x 1.2.

THE NAUTILUS 69 (4)

PLATE 8

«liiaiiiiili»li»

Panope 'bitruncata

April, 1956] the nautilus 121

parable results. These facts, when considered together with the
allopatric distribution patterns involved, qualify these popula-
tions as distinct subspecies.

Acknowledgments

In addition to Drs. W. J. Clench and R. D. Turner, who have
been cited, I wish to thank Dr. Harald Rehder for his generous
cooperation in loaning for study the entire United States Na-
tional Museum collection of Western Atlantic specimens of the
genus Neptunea.

Bibliography

Clarke, Jr., A. H. 1954. Some Mollusks from the Continental
Slope of Northeastern North America. Breviora, v. 40, pp.
1-10 + map.

Gould, A. A. 1870. Report on the Invertebrata of Massachu-
setts. Edited by W. G. Binney. Boston. Pp. i-v + 1-524,
12 pis.

Mayr, E., E. G. Linsley, and R. L. Usinger. 1953. Methods
and Principles of Systematic Zoology. McGraw-Hill Book
Co., Inc. Pp. i-x + 1-328.

Say, Thomas. 1827. Descriptions of Marine Shells recently
discovered on the Coast of the United States. Journal of the
Academy of Natural Sciences of Philadelphia, v. 5, pp.
207-221.

A LIVING SPECIMEN OF THE EAST COAST
GEODUCK FROM ST. AUGUSTINE, FLORIDA

By MALCOLM C. JOHNSON

Marineland Research Laboratory, Marineland, Florida

On August 14, 1954 an unusual clam was taken from a mud-
bank in the iMatanzas River, St. Augustine, Florida, by Mr.
Verle A. Pope of that city (Pope, 1954).^ The clam was ten-
tatively identified by me as being Panope hitruncata Conrad.
Mr. Percy Morris of the Peabody Museum at Yale, later con-
firmed this identification from a photograph.

The robust shell was evenly rounded anteriorly and trun-

1 A captioned photograph of Pope and his specimen appeared in the
December, 1954 edition of the Quarterly Journal of the Florida Academy
of Sciences.

122 THE NAUTILUS [Vol. 69 (4)

cated behind; it was offwhite in color with prominent concen-
tric growth rings. The shell was 5.75 inches in length, 4.25
inches in depth and had a thickness of 3.0 inches. The anterior
gape measured %-inch at the widest point and extended from
the forward edge of the hinge to the mid-ventral margin. The
valves of the shell met for a distance of one inch in this area;
the posterior gape then extended to the ligament and measured
two inches at the widest point.

The heavy *'neck" could not be completely withdrawn into
the shell. It was not measured when extended while the animal
was fresh. However, it was 7.50 inches long after the clam had
been preserved in sea-water formalin for several weeks.

Mr. Pope remembers seeing such a clam as a boy. He re-
marked on this in my presence several years ago shortly after
he had noticed what he described as its characteristic '' squirt."
While boating August 14, 1954 his curiosity was further aroused
when he found a shell of Panope on a mudbank. He secured a
shovel, returned and succeeded in uncovering the one specimen
described here. The substrate from which it was taken is al-
luvial mud typical of the salt marshes of the Southeastern Coast.
However, the bank which is alternately inundated and exposed
by the tides is overlain with sand deposited by the fast flowing
waters of the main river channel and will support a man with-
out miring. Pope estimated the body of the clam was four feet
below the surface. To date no others have been found.

The rarity of this clam is attested by the fact that in an area
where a good segment of the population traditionally takes its
living from the sea or its margins, only one or two persons have
claimed any knowledge of its presence in spite of much local
publicity. Their statemenst were typically prefaced thusly:
''Many years ago . "

Smith (1937) reported that individuals living in easily mov-
able material such as sand or fine mud are thinner, longer and
less distorted than those associated with gravel. This could
imply that he had seen living specimens. However, this is
doubtful since he had improperly oriented the shell and de-
scribed it as "obliquely cut off at the anterior end." Morris
(1947) described the shell of P. hitruncata as being quite
smooth; the pronounced sculpturing of the living specimen
would indicate that the ones he had in hand were quite old and

April, 1956] the nautilus 123

eroded. Abbott (1954) stated that he had never seen a living
specimen and that it was probably extinct.

The clam is presently in the collection of the Marineland Re-
search Laboratory.

Literature Cited

Abbott, R. Tucker. 1954. American Seashells. D. van Nos-
trand Company, Inc., New York, 454.

Morris, Percy A. 1947. A Field Guide to the Shells of Our
Atlantic Coast. Houghton Mifflin Company, Boston, 67.

Pope, Verle A. 1954. The Geoduck Clam in Florida. Quart.
J. FaL Acad. Sci., v. 17 (4) : 252.

Smith, Maxwell. 1937. East. Coast Marine Shells. Ed-
wards Brothers, Inc., Ann Arbor, Mich.

VENTRIDENS INTERTEXTUS EUTROPIS
LIVES HERE

By MARGARET C. TESKEY

In 1935 Dr. Henry A. Pilsbry and Mr. Cyril Harvey collected
in Central Tennessee a single specimen of an acutely carinate
*'dead" shell, subsequently described as Ventridens intertextus
eutropis Pilsbry, a new subspecies. Since then the type locality
has been searched by other collectors without yielding another
specimen of this unique moUusk.

In July, 1955 the writer made a chance stop and hurried
search of a small wooded area some sixty miles northwest of the
type locality and collected two living specimens of Ventridens
intertextus eutropis Pilsbry which unfortunately were cleaned
before they were recognized. These specimens, one adult, one
immature, have been deposited in the collection of the U. S.
National Museum.

In September Mr. Leslie Hubricht visited the site and col-
lected seven specimens, three living but immature, four adult
but dead. And on December 17th and 23rd, the writer was
again in the area, devoting a half hour to collecting on each
occasion, and each time was rewarded with two specimens, dead
to be sure but adult and a prize considering that the logs be-
neath which they were found were covered by crusted snow.

Because this site has yielded thirteen specimens of a hereto-

124 THE NAUTILUS [Vol. 69 (4)

fore rare subspecies, directions are presented for reaching it, as
a guide to other collectors.

At the extreme northeastern edge of Cheatham County, Ten-
nessee, it is about halfway between Nashville and Clarksville,
on the east side of U. S. highway 41A, exactly 1.7 miles south
of the intersection of Tennessee highway 49 which appears on
some maps as the village of Pleasant View. The heavily wooded
area of perhaps fifty acres covers both slopes of a shallow ravine ;
the predominant growth is oak and hickory and there is little
underbrush save for a bramble which takes a toll of all but the
most rugged of collecting garb.

This woodlot is bordered on the north by a gravel road which
affords a turnout and parking space, necessary since the main
highway is narrow at this point and heavily traveled. Because
of this important fact, collectors should visit the spot as soon as
possible. For U. S. 41 together with its alternates is the most
direct route between Chicago and the gulf coast cities of North-
western Florida. Much of it is already a divided highway,
other portions are undergoing a widening process; hence the
future will certainly see at least part of an especially reward-
ing collecting area disappear beneath a ribbon of asphalt.

Reference

PiLSBRY, Henry A. 1946. Land Mollusca of North America,
Vol. 2, Pt. 1, p. 470.

LAND SNAILS FROM LOUISIANA

By LESLIE HUBRICHT

During July, 1955 the author spent two days in Louisiana
collecting land snails. Although only fifty-two lots, belonging
to 17 species were collected, they are from a region in which
the land snail fauna is poorly understood. For this reason it
seems advisable to publish the records.

Polygyra leporina (Gould). Grant Parish: 1.8 miles south of
Bentley.

Polygyra dorfeuilliana Lea. Claiborne Parish: 11 miles south-
west of Homer.

April, 1956] the nautilus 125

Stenotrema leai aliciae (Pilsbry). Calcasieu Parish: 2.5 miles
west of Sulphur. Evangeline Parish : Beaver. Allen Parish :
3.3 miles northwest of Oakdale. Vernon Parish: 1.5 miles
west of Simpson. Eapides Parish : 2.5 miles east of flatwoods.
Grant Parish: 1.8 miles south of Bentley; just west of Pol-
lock; 5 miles northeast of Pollock.

Mesodon thyroidus (Say). Calcasieu Parish: 2.5 miles west of
Sulphur. Grant Parish : just west of Pollock ; 5 miles north-
east of Pollock. Ouachita Parish : 6 miles southwest of West
Monroe.

Mesodon inflectus (Say). Calcasieu Parish: 2.5 miles west of
Sulphur. Evangeline Parish: Beaver. Vernon Parish: 1.5
miles west of Simpson. Grant Parish: 1.8 miles south of
Bentley; just west of Pollock; 5 miles northeast of Pollock.
LaSalle Parish: 7 miles southwest of Trout.

Triodopsis cragini (Call). Grant Parish: just west of Pollock.
Claiborne Parish : 11 miles southwest of Homer ; 3 miles south-
west of Summerfield.

Triodopsis albolahris (Say). Ouachita Parish: 6 miles south-
west of West Monroe.

Haplotrema concaviim (Say). LaSalle Parish: 7 miles south-
west of Trout.

Retinella indentata (Say). LaSalle Parish: 7 miles southwest
of Trout.

Retinella indentata paucilirata (Morelet). Claiborne Parish:
11 miles southwest of Homer.

Mesomphix vulgatus H. B. Baker. Vernon Parish: 1.5 miles
west of Simpson. LaSalle Parish : 7 miles southwest of Trout.

Ventridens demissus (Binney). Vernon Parish: 1.5 miles west
of Simpson. Grant Parish: just west of Pollock; 5 miles
northeast of Pollock. LaSalle Parish: 7 miles southwest of
Trout.

Ventridens intertextus (Binney). Calcasieu Parish: 2.5 miles
west of Sulphur. Evangeline Parish: Beaver. LaSalle Par-
ish: 7 miles southwest of Trout. Claiborne Parish: 11 miles
southwest of Homer.

Anguispira crassa Walker. Calcasieu Parish: 2.5 miles west of
Sulphur. Evangeline Parish: Beaver. Vernon Parish: 1.5
miles west of Simpson. Grant Parish: 1.8 miles south of
Bentley. Ouachita Parish: 6 miles southwest of West Mon-
roe. Claiborne Parish : 11 miles southwest of Homer.

Fliilomyciis carolinianus (Bosc). Calcasieu Parish: 2.5 miles
west of Sulphur. Evangeline Parish : Beaver. Richland Par-
ish: 8.5 miles west-northwest of Alto. Ouachita Parish: 6
miles southwest of West Monroe.

Pallifera marmorea Pilsbry. Vernon Parish: 1.5 miles west of
Simpson. Grant Parish: just west of Pollock. These speci-
mens are paler than those from Missouri and Arkansas and
do not have the reddish margin to the foot.

126 THE NAUTILUS [Vol. 69 (4)

Megapallifera, new subgenus

Animal large, sometimes reaching 100 mm. in length when
extended in crawling. The margin of the foot is never reddish,
being either grayish or white. The jaw with from 10 to 16 ribs.
There is a pilaster extending from the lower vagina into the
upper atrium.

Type species: Pallifera mutabilis Hubricht. 1951, Naut.
65:57.

This subgenus contains three known species: P. mutahilis
Hubricht, P. ragsdalei (Webb), and P. weatherhyi W. G. Bin-
ney. Because of their large size, these species have been con-
fused with species of Philomycus. Most of the records for
Philomycus flexuolaris Rafinesque from west of the Appalachian
Mountains are based on P. mutaMlis.

Pallifera mutaMlis Hubricht. Grant Parish : 12 miles south of

Colfax.
Helicina orhiculata (Say). Evangeline Parish: Beaver.

HAPLOTREMA KENDEIGHI WEBB

By LESLIE HUBRICHT

A new subspecies of Haplotrema concavum (Say) was de-
scribed by Glenn R. Webb in 1951 (Trans. Kans. Acad. Sci. 54:
78-82) from the Great Smoky Mountains National Park and
named H. c. kendeighi. The subspecies was distinguished by
the following shell differences: ^^ Haplotrema concavum ken-
deighi is particularly characterized by the pronounced inflation
of the lower part of the aperture — causing the lower peristome
to join the base at about a 90 degree angle and helping give the
shell a quadroid aperture. The new subspecies differs from
typical H. c. concavum in : ( 1 ) having a markedly asymmetrical
aperture; (2) in lacking sigmoid curvature of the dorsal peri-
stome; (3) in the thinner, more polished, more translucent,
greener-colored shell; (4) in the wider spacing of the growth-
zones; and (5) in the absence or sparsity of revolving striae."

A study of a large series of shells of Haplotrema concavum
collected over most of its range shows that none of the above
characters, either singly or in combination, can be used to divide

April, 1956] the nautilus 127

Eaplotrema of the eastern United States. There is complete
intergradation in all shell characters.

In the vicinity of Blowing Spring, Cliff Ridge, Nantahala
Gorge, Swain Co., North Carolina, there are two distinct sizes
of Eaplotrema occuring together. Measurements of some speci-
mens of the two sizes are as follows:

Diam.

Ht.

Umb. D.

Wis.

H/D

D/U

22.4

9.5

7.4 mm.

5.5

.42

3.0

21.4

9.3

6.7 mm.

5.3

.44

3.2

21.2

10.6

6.5 mm.

5.4

.50

3.3

19.5

9.6

5.4 mm.

5.4

.49

3.6

Diam.

Ht.

Umb. D.

Wis.

H/D

D/U

16.4

7.2

5.0 mm.

5.3

.45

3.3

16.4

7.1

4.9 mm.

5.3

.43

3.4

15.9

7.4

4.5 mm.

5.2

.47

3.3

15.4

6.8

4.6 mm.

5.0

.44

3.3

The above measurements show that there is no difference in
proportions between the two forms. There is no difference in
the development of the spiral sculpture, it being very weak.
There is apparently a difference in breeding season. On June
6, 1953, mature specimens of the large form were common, but
specimens of the small form were all immature. On August 31,
1952, mature specimens of the small form were found, but ma-
ture specimens of the large form were rare.

When they were being collected, one conspicuous difference
was noted in the color of the foot. The foot of the large form
was a dull yellowish-gray, while the foot of the small form was
bright blue. On dissection, the small form was found to have
a cloaca at least twice the size of that of the large form. Eaplo-
trema c. kendeighi from the type locality and from Clingmans
Dome was found to have a blue foot and a large cloaca. The
large form is E. concaviim and the small form E. c. kendeighi,
and, in view of the anatomical difference and since the two occur
together without intergradation, the latter, despite the absence
of shell differences, is undoubtedly a distinct species.

Although the shells of Eaplotrema kendeighi cannot be dis-
tinguished from shells of E. concavum from northern Iowa or
southern Michigan, they can be readily separated from those
found within its range in western North Carolina and eastern
Tennessee where E. concavum reaches its maximum size.

128 THE NAUTILUS [Vol. 69 (4)

Eaplotrema kendeighi is known from the following localities:
Tennessee : Sevier Co. : slopes of the Chimneys above the camp
area on the west prong of Little Pigeon River near Tenn.-71, in
mixed-hardwoods deciduous forest (Type Locality) ; 6600 ft.,
Clingmans Dome; Mt. LeConte (Clench & Archer). North
Carolina : Swain Co. : near Blowing Spring, Cliff Ridge, Nanta-
hala Gorge.

FAMILY NAMES IN PULMONATA
By H. BUERINGTON BAKER

The original international code for zoological nomenclature
was established (1905) in the hope that uniformity might be
attained. Some such artificial rules were thought necessary
for the names of genera down to subspecies because of their
great numbers. Names above the genera, since they were less
numerous, wisely were left to scientific judgment.

Although, as everyone knows, more useless name-changes have
taken place since 1905 than in any other half century of taxo-
nomic history, the new articles 4 and 5 (Follett, 1955, ''Not
published") apparently intend to extend the priority rule to
groups (taxons) up towards orders. In addition, so far as its
dating is concerned, each ''family-group name" would be re-
garded as equal, regardless of its termination, and independent
of the synonymy or even the homonymy of its 'Hype genus."
After 50 years, this would reverse the old article 5 completely.

The most disturbing feature of the new article 5 is its 3rd
paragraph, which not only predates names but actually deter-
mines a "type species" for each family or subfamily which
contains a prior synonym based on a preoccupied (homonymous)
generic or subgeneric name. For some of the worst changes in-
volved, see Achatinidae (Cecilioides), Brachypodella, Bulimus,
Euconulinae, Psiloicus, Pupillidae (Gastrocoptinae), Scolodens,
Streptaxidae (Zophos), Vitrinidae (Vitreinae & Zonitinae) and
Xestidae.

An alphabetic list of the families of Pulmonata follows, with
included subfamilies arranged chronologically under each. It

April, 1956] the nautilus 129

is presented simply as an argument against these proposed
amendments; none of the changes is accepted. To illustrate
how and what names are employed at present, references cite
Pilsbry's ''Land Mollusca of North America" (OINA-.l means
volume 1, page 1; LMNA2 is vol. 2) and to Thiele's ''Handbuch
der systematischen Weichtierkunde, " part 2 (HSW:461 means
page 461). Names which are, or would become synonyms are
in parentheses.

Of course, no hope is offered that these hasty arrangements
would be final. Probably all the changes involved would not
be discovered before the end of the century, and by that time a
new set of rules will start the cycle all over again.

Acav-inae Pilsbry, 1895; -idae P., 1900, HSW:647. SubF:
Clavatorinae (-idae Th. in K., 1926, HSW:648). Caryodinae
(-idae T. in K., 1926, HSW:649; Hedleyelloidea & Pedino-
gyroidea I., 1942). F. of Helicoidea?

Achatin-ae Swainson, 1840 (SubF); -inae Adams, 1855; -idae
Tryon, 1867, LMNA2:169, HSW:558. SubF: C-inae, Cecili-
oides Fer., 1814 (Caeciliae ^ Morch, 1864, F. ; Caecilianellinae ^
Crosse & Fischer, 1877; -idae Bgt., 1887; Ferussacidae Bgt.,
1883; -iidae HSW:546; -iinae HBB., 1945, LMNA2:184;
Opeatinae^ HSW:552, genus LMNA2:181). Stenogyrinae *
Wenz, 1923 (-idae C. & F., 1877; Subulininae C. & F., 1877,
LMNA2 :170-180 ; -idae Thle., 1926, HSW:549; Obeliscinae &
Rumininae (-idae Wenz, 1923) HSW:554; Cryptelasminae
Jaume & Fuentes, 1943). Coeliaxinae Pilsbry, 1907, HSW:
556 (-idae Wenz, 1923). F. of Achatinoidea.

Achatinellidae : Man. Conch. 21-22, HSW :498 ; see Helicteridae.

Acrore-idae (Acroriidae ^ Wenz, 1923). F. of Limnophila?

Ailly-idae HBB., 1930, genus HSW:666. F. of Heterurethra.

Amastr-inae Pilsbry, 1911; -idae P., 1914, HSW:500. SubF:
Leptachatininae P. & Cooke, 1914, HSW:500 (-ini Ckll., 1913).
F. of Cionelloidea.

Amphibol-idae Gray, 1840, HSW:470 (Ampullaceridae ^ Tro-
schel, 1845). F. of Thalassophila.

Ancyl-idia Raf., 1815 (SubF) ; -idae Dall, 1870, HSW:482 (Ac-
roloxinae HSW :484) . SubF : Neoplanorbinae Hannibal, 1912.
Laevapicinae H., 1912 (-idae 1914; Ferrissiinae * B. Walker,
1917). Rhodacminae W., 1917. Pseudancylinae & Ancy-
lastrinae W., 1923. F. of Ancyloidea.
1 <'Type genus" a clear homonym; i.e., preoccupied.
2 ''Type genus" an objective synonym; i.e., with same type species.

3 ' ' Type genus ' ' a misusage ; i.e., with wrong type species.

4 < < Type genus ' ' a subjective synonym ; i.e., with different type species.

130 THE NAUTILUS [Vol. 69 (4)

Aper-idae^ MUdff., 1902, HSW:726 (Chlamydeplioridae CkU.,

1935). F. of SuperF. Rhytididae.
Arion-idae Gray in Turton, 1840, LMNA2:660, HSW:600.

SubF: Binneyinae Ckll., 1891, LMNA2:732, HSW:601.

Oopeltinae Ckll., 1891, HSW:604. Ariolimacinae Pils. &

Van., 1898, LMNA2:706, HSW:601. Anadeninae Pils., 1948,

LMNA2 :676. F. of Arionoidea.
Ariophantidae : HSW:611; see Xestidae.
Atlioracophor-idae Fischer, 1883, HSW:495 ( Janellidae ^ Gray,

1853). SubF: Aneiteinae (-adae Gray, I860; Aneitinae Gr.

& Hffm., 1924). F. of Heterurethra or Tracheopulmonata.
Aurieul-ae Ferussac, 1821 ; -adae Gray, 1824 ; -idae Risso, 1826

(EUobiidae^ Adams, 1855, HSW:463). SubF: C-inae (Co-

novulidae^ Clarke, 1850; Melampidae Stimpson, 1851; -inae

Adams, 1855; -odinae C. & F., 1880). Searabinae ^ (Pytbi-

inae Odhner, 1925) & Pedipedinae (HSW:463) C. & F., 1880.

Cassidulinae ^ 0., 1925. F. of Aetophila.
Brachypodella Beck, 1837: -idae ( Cylindrellidae ^ Tryon, 1868;

Urocoptidae Pils. & Van., 1898, LMNA2:103, HSW:668).

SubF: Berendtinae Cr. & Fiseh., 1872 (Euealodinae C. & F.,

1873; -iinae HSW:668; -iidae Str. & Pfeffer, 1879). Micro-

ceraminae Pils., 1904, LMNA2:107, HSW:671. Holospirinae

Pils., 1946, LMNA2:111. F. of SuperF. Orthalicidae.
Bradybaenidae : LMNA:15; see Eulotidae.
Bulimin-ida* Clessin, 1879; -idae Kobelt, 1880 (Enidae Pils. &

Cooke, 1914, HSW:517; Chondrinidae ^ Steenberg, 1925).

SubF: Cerastinae Wenz, 1923 {Cerastua,^ 1928; Pacbnodinae

& -idae S., 1925; Napaeinae Wagn., 1927, HSW:523). Chon-

drulinae * Wenz, 1923 (-idae Wagner, 1927; Jaminiinae

HSW:517). F. of Pupilloidea.
Bulimulidae: Man. Conch. 11-14, LMNA2:1, HSW:651; see

Orthalicidae.
Bulimus^ Scopoli, 1786, Brug., 1789, not Scopoli, 1777: type

Helix oUonga Miiller : -idae Guilding, 1828 ; -ida Beck, 1837 ;

-inae Adams, 1855, etc., for almost a century. See Psiloicus

and Strophocheilidae.
Camaenidae : Man. Conch. 9, LMNA :410 ; see Lucerna.
Carychi-adae Jeffreys, 1829; -inae C. & F., 1880, HSW:464;

-idae Wenz, 1923, LMNA2 :1051. F. of Aetophila.
Caryodidae: HSW:649; see Acavidae.
Cepolidae: see Xanthonycidae.
Cerion-idae= Pilsbry, 1901, LMNA2:158, HSW:667 (Pup-adae^

Fleming or Guilding, 1828; -inae Adams, 1855; -idae Gill,

1871. On Pupa Lamarck, 1801, or Draparnaud, 1801?). F.

of Cerionoidea.
Chilin-idae Adams, 1855, HSW:472. F. of Limnophila.

5 < ' Type genus ' ' now on official list.

April, 1956] the nautilus 131

Cionell-ida Clessin, 1879; -idae Kobelt, 1880, L]MNA2:1045
(Cochlicopidae ^ Pilsbry, 1900, HSW:502; Spelaeoconcliinae
Wagn., 1927). F. of Cionelloidea.

Clausili-eae ^ Morch, 1864(F) ; -idae Stoliczka, 1871; HSW:526
(Baleinae Wagner, 1922; Laminiferinae Wenz, 1923; Mentis-
soideinae & Fusulinae Lindholm, 1924). SubF : Alopiinae
Wagner, 1921 (Garnieriinae Hffm., 1928). Phaedusinae
Wagner, 1922, HSW:527. Neniinae Wenz, 1923, HSW:533
(Neniastrinae - HBB., 1930). Marpessinae Wenz, 1923 (Co-
ehlodininae^ Hffm., 1928, HSW:540). Triptyehiinae & Fil-
holiidae Wenz, 1923. F. of SuperF. Orthalicidae ?

Clavatoridae : HSW:648; see Acavidae.

Cochlicopidae : ^ HSW:502; see Cionellidae & Oleaeinidae.

Corillidae: HSW:585; see Plectopylididae.

Dorcasi-idae Thle., 1926, HSW:646. F. of Cerionoidea.

Ellobiidae:^ HSW:463; see Anriculidae.

Enidae: HSW:517; see Buliminidae.

Endodontidae : Man. Conch. 9, L]\INA2:565, HSW:566; see
Punctidae.

Euconul-inae HBB., 1928, L]\INA2:233; HSW:613, genus
(Conulinae^ Strebel & Pfeffer, 1879; Durgellinidae * &
Hedleyoconchidae * I., 1941). SubF. or Tribe: Microcys-
tinae Thiele, 1931, HSW:618 (-idae I., 1937; Trocbo-
naninidae ^ Germain, 1921; -inae HSW:616; Liardetiae &
Philonesiae HBB., 1938; Fanulidae * & Advenidae* I., 1945).
F. or primary SubF. (which see) : Xestinae (-idae, 1941),
Helicarioninae Godwin-Austen, 1888 (-idae, 1909), and Uro-
cyclidae Simroth, 1889. Incertae sedis: Cystopeltinae CklL,
1891, HSW:625. Sophininae Blanford & G.-A., 1908, HSW:
637. Chroninae HSW:626. F. of Limacoidea.

Eulot-idae^ Wenz, 1923; -inae Ihering, 1929 (Fruticicolidae *
Lindholm, 1927, HSW:688; Buliminopsinae Hffm., 1928;
Bradybaenidae Pils., 1939, LMNA:15; Aegistinae Habe, 1955).
SubF: Helicostylinae Hffm., 1928, HSW:688 (Cochlostyl-
inae* Ihering, 1929). F. of Helicoidea or SubF. of Xan-
thonycidae.

Ferussacidae : Man. Conch. 19, HSW:546; see Achatinidae
(Cecilioides).

Fruticicolidae : * HSW:688; see Eulotidae & Hygromiidae.

Gadini-adae^ Gray, 1840; -idae Ball, 1870, HSW:470. F. of
Limnophila !

Haplotremat-idae HBB., 1925, LMNA2:201, HSW:723, in part
(Circinariidae^ Pilsbry, 1898, in part). F. of SuperF.
Khytididae.

Helicarion-inae Godwin- Austen, 1888, HSW:637; -idae Kobelt,
1909 (Pseudotrochatellinae Wagner, 1905, genus HSW:82;
Ereptinae HSW:614). SubF. or Tribe: Sesarinae Thiele,

132 THE NAUTILUS [Vol. 69 (4)

1931, HSW:620 (Kaliellinae HSW:612, type genus; Geo-
trochidae I., 1941; Nitoridae * I., 1944, section HSW:617).
SubF. of F. Euconulinae, or F. of Limacoidea.

Helicellinae ^ Wenz, 1923, HSW:702; -idae LMNA:14; see Hy-
gromiidae. Not Helicellinae ^ Adams, 1855 ; -idae Tryon,
1866; see Vitrinidae (Vitreinae & Zonitinae) and Helicidae.

Helic-inia^ Raf., 1815 (F) ; -idae Gray, 1824, LMNA:1 (Heli-
cellinae ^ Adams, 1855 ; Xerophil-ae ^ Morch, 1864 ; -inae Wag-
ner, 1927 ; Theb-ea ^ Wenz, 1923, -inae Germ., 1929 ; Eupary-
phinae^ Perrot, 1939. Murellinae Hesse, 1920). SubF: A-
inae ( Ariantidae * Morch, 1864 ; Campylaeinae Bttg. & Wenz,
1921 ; Helicigoninae ^ HSW :713 ) . Helicodontinae Hesse,
1918, HSW:711. Leptaxinae Wenz, 1923, HSW:715. See
also Hygromiidae (SubF. of Helicidae, HSW:702) & Xan-
thonycidae. F. of Helicoidea.

Helicter-inae * Pease, 1869 ; -idae Fischer, 1883 (Achatinellinae
Gulick, 1873; -idae Kobelt, 1880, HSW:498). SubF: Tor-
natellinidae (which see) & Auriculellinae ? F. of Pupilloidea.

Helminthoglyptidae : LMNA:24, see Xanthonycidae.

Hygromi-inae Tryon, 1866, LMNA:16, HSW:707; -idae Mlldff.,
1890 (Trochulinae 2 Lindholm, 1927; Fruticicolidae ^ Hffm.,
1928). SubF: L-inae (Xerophilae^ Morch, 1864; Leucochro-
idae^'^ Westerlund, 1886; Helicellinae ^ Wenz, 1923, HSW:
702, not Adams, 1855; -idae LMN'A:14; Geomitrinae Wenz,
1923; Jacostidae Pilsbry, 1948, LMNA2:1091). F. of Helico-
idea.

Jacostidae : LMNA2 :1091 ; see preceding.

Lanc-inae Hannibal, 1914, HSW:477; -idae Pilsbry, 1925. F.
of Ljonnoidea.

Lati-inae Hannibal, 1912; -idae Thle., 1926, HSW:473. F. of
Limnophila.

Limaxia (F) and Limac-idia^ (SubF) Raf., 1815; -idae Gray,
1821, Turton, 1831, LMNA2:521, HSW:605 (Agriolimacinae *
Wagner, 1935). SubF: Parmacellinae HSW:605 (-idae &
Cryptellidae Gray, 1860) . Milacinae CklL, 1935, LMNA2 :563
(-idae Ellis, 1926). F. of Limacoidea.

Lucerna * * ' Humphreys ' ' Swainson, 1840, type L. acutissima =
Helix lucerna acuta Lam., 1816; not preoccupied by ''Lu-
cerna" Willughby, 1686 (Pisces), or ''Humphreys" 1797 (see
opinion 51) or "Fer." (citation of preceding in synonymy) :
L-idae; Lucerninae * Swainson, 1840 (Camaeninae Pilsbry,
1895 ; -idae Mlldff., 1898, LININA :410 ; Amphidrominae Kobelt,
1902; Pleurodontidae Ihering, 1912, HSW:676; Chloritidae,
Hadridae,* Papuinidae, Planispiridae, Rhagadidae * & Xan-
thomelonidae I., 1937-8). SubF: Megomphicinae (see Thy-
sanophoridae) ? Oreohelicinae Pilsbry, 1939, LMNA:412.
F. of Helicoidea.

April, 1956] the nautilus 133

Lymnaea (Lymnoeaf) : Lymn-idia Raf., 1815 (SubF) ; Limn-
acea Blainville, 1824 ; -aeadae Risso, 1826 ; -adae Turton, 1831 ;
-aeoidea Fitz., 1833; Lymneidae Orbigny, 1837; -aeidae,
HSW:475 (Amphipeplidae 2 & Limnophysidae * Dybowski,
1903 ; Acellinae * Hamiibal, 1912) . F. of Lymnoidea.

Macrocycl-idae Thle., 1926, HSW:651. F. of SuperF. Rhy-
tididae ?

Megaspir-idae Pilsbry, 1904, HSW:557. F. of Achatinoidea.

Mesodont-inae Tryon, 1866 (Polygyrinae Pilsbry, 1895; -idae
Ihering, 1912, LMNA: 575, HSW:579 in part). SubF: Tri-
odopsinae Pils., 1940, LMNA:789. F. of SuperF. Meso-
dontinae.

Oleacin-inae,^ -idae Adams, 1855, Gray, 1860, LMNA2:188, in
part, HSW:562, in part (Glandinidae - Strebel, 1878; Co-
chlicopidae ^ Pils., 1900 ; Varicellarum HBB., 1941, genus
LMNA2:200). See also Spiraxidae. F. of Oleacinoidea.

Onchid-ia Raf., 1815 (SubF) ; -iadae Gray, 1824; -iidae Adams,
1855; Oncidiidae HSW:486 (Oncidiellidae,^ Peroniidae ^ &
Scaphidae * Labbe, 1934). F. of Gymnophila.

Orthalic-ea Albers-Martens, 1860; -idae Tryon, 1866, & -inae,
1867, LMNA2:29, HSW:663. SubF: Bulimulinae Tryon,
1867, L]VINA2:3, HSW:651 (-idae C. & F., 1873, LMNA2:1,
HSW:651). Amphibuliminae Crosse & Fischer, 1873, HSW:
665. Odontostominae Pils. & Van., 1898, HSW:660 (-idae
Wenz, 1923; Grangerellidae Russell, 1931). F. of SuperF.
Orthalicidae.

Otin-inae Adams, 1855; -idae Chenu, 1859, HSW:468. F. of
Actophila.

Partul-idae Pilsbry, 1900, genus HSW:658. F. of Cerionoidea
or near Pupilloidea?

Paryphantidae : HSW:724; see Rhytididae.

Philomyc-ina Gray, 1847; -idae Keferstein, 1866, LMNA2:748,
HSW:604 (Tebennophorinae^ Morse, 1864; -idae C. & F.,
1872). F. of Arionoidea.

Phys-oidea^ Fitzins^er, 1833; -ina Gray in Turton, 1840; -idae
Ball, 1870, HSW:474. F. of Ancyloidea.

Planorb-ia Raf., 1815 (SubF) ; -ina Gray in Turton, 1840; -inae
Adams, 1855; -idae Dybowski, 1903, HSW:478. SubF: B-
inae (Bullinea^ Oken, 1815; Camptoceratinae Dall, 1870;
Bulininae Cr. & Fisch., 1880 ; -idae Germain, 1931 ; Isidorinae *
Wenz, 1923 ; Protancylinae B. Walker, 1923) . C-inae (Coretini
Gray, 1847; Pompholicinae^ Dall, 1866, 1870, -idae Hender-
son, 1924 ; Pompholycodeinae ^ Lind., 1927 ; Helisomatinae F.
C. Baker, 1928). Choanomphalinae C. & F., 1880. Planor-
bulinae Pilsbry, 1934. Segmentininae F. C. Baker, 1945.
Biomphalariinae Watson, 1954. F. of Ancyloidea.

Plectopylid-idae Mlldff., 1900 (Corillinae P., 1905; -idae T. in
K., 1926, HSW:585). F. of Cerionoidea.

134 THE NAUTILUS [Vol. 69 (4)

Pleurodisc-idae Wenz, 1923, LMNA2:1019, HSW:517, in part.
SubF: Pyramidulinae Wenz, 1923 (-eae HSW:503). F. of
Pupilloidea.

Pleurodontidae : HSW:676; see Lucernu.

Polygyridae: Man. Conch. 9, LMNA:575, HSW:579; see Meso-
dontinae.

Psiloicus'' Morretes, 1952, or Corns ^ ''Jouss., 1877" Strand,
1928,^ type Helix ohlonga Miiller ; see Bulimus and Stropho-
eheilidae.

Punct-inae Morse, 1864, LMNA2 :640 ; -idae ''Gill" Pilsbry, 1895
(Laominae Suter, 1913, HSW:567; -idae Iredale, 1937; Patu-
lastridae * Steenberg, 1925, see HSW:517; Paralaomidae * I.,
1941). SubF: Patulinae ^ Tryon, 1866, section LMNA2:616;
-idae Mlldff., 1890 (Charopidae Button, 1884; Endodontidae
Pils., 1895, LMNA2:565, HSW:566; Thysanotinae G.-A., 1907;
Goniodiscinae ^ Wagn., 1927; Discinae HSW:578). Ph-inae
(Phenacohelicidae * Suter, 1892 = section, HSW:577; Oto-
conchinae Ckll., 1893; -idae HBB., 1938; Amphidoxinae
HSW:575; Flammulinidae I., 1937; Gudeconchidae * & Pseu-
docharopidae ^ I., 1944). Helicodiscinae ''Pilsbry" HBB.,
1927, L]\INA2:622, HSW:568. Eotadiscinae HBB., 1927,
HSW:567. Stenopylinae HSW:569? F. of Arionoidea.

Pupill-adae Turton, 1831; -idae Pilsbry, 1905, LMNA2:868;
-inae Pils., 1918, L]\INA2:920, HSW:507 (Lauriinae Steen-
berg, 1925; -eae HSW:509). SubF: Vertigininae P., 1918,
LMNA2:943 (-oidea Fitz., 1833; -idae Stimpson, 1851,
HSW:503; Truncatellininae Steenberg, 1925; -eae HSW:503).
Orculinae P., 1918, HSW:510 (-idae S., 1925). Gastrocop-
tinae P., 1918, LMNA2:871 (Includes Ahida = Pupa^ Drap.,
1801; see Cerion; Chondrinidae ^ S., 1925; -inae HSW:511).
Pagodulininae P., 1924 (genus HSW:510; Pagodininae ^ P.,
1918). Nesopupinae S., 1925, LMNA2:1006 (-eae HSW:505).
F. of Pupilloidea.

Kathouis-idae Sarasin, 1899; iidae Mlldff., 1902, HSW:489. F.
of Gymmophila.

Rhytid-idae Pilsbry, Feb. 2, 1895 ( Paryphantinae G.-A., 1895;
-idae HSW:724). F. of SuperF. Rhytididae.

Sagd-inae Pilsbry, 1895; -idae Wenz, 1923, LMNA :978-983,
HSW:581, in part. SubF: Aquebaninae & Platysuccineinae
HBB., 1940. F. of Oleacinoidea.

Scolodens, new name for Stenopus ^ Guilding, 1828, Zoo. J.
3 :527, type ;S^. cruentatus Guilding : -idae (Stenopidae ^ Adams,
1855, Chenu, 1859; Scolodontidae HBB., 1925; Systrophiidae
Thiele, 1926, HSW:596). F. of Limacoidea?

Scolodontidae: see preceding.

Siphonari-adae Gray, 1840; -idae Adams, 1855, Dall, 1870,
HSW:471. F. of Thalassophila.

April, 1956] the nautilus 135

Spirax-inae HBB., 1939 (genus HSW:562): -idae HBB., 1955.
SubF: -inae Streptostylarum (genus HSW:564) & Euglan-
dinarum (genus LMNA2:188, HSW:565) HBB., 1941. See
also Oleacinidae. F. of Achatinoidea.

Stenacm-idae Pilsbry, 1945. F. of Thalassophila.

Streptax-idae Gray, 1860, HSW:727. SubF: Z-inae; Zophos^
Gude, 1911 ( Selenitidae ^ Fischer, 1883; Austroselenitinae
HBB., 1941)? Enneinae* Mlldff., 1903 (subgenus HSW:
734 ; -idae auct. ; Ptychotrematinae Pilsbry, 1919, genus HSW :
733). F. of Achatinoidea.

Strobilops-inae Pils., 1918; -idae Hanna, 1922, LMNA2:848
(Strobilidae^ Joos, 1911). See also Vallonidae. F. of Pu-
pilloidea.

Strophocheil-idae Thle. 1926 (-chilinae Pils., 1902; -idae HSW:
650). See also Bulimus. F. of Cerionoidea.

Subulinidae: HSW:549; see Achatinidae (Stenogyrinae).

Succin-ida^ Beck, 1837; -inae Adams, 1855; -idae Gill, 1871
(-eae Morch, 1864; -eidae Tryon, 1866, LMNA2:771, HSW:
493; Catinellinae Odhner. 1950). SubF. Hyalimacinae
G.-A., 1882. F. of Succinoidea (Heterurethra).

Systrophiidae : HSW :596 ; see Scolodens.

Testacell-ina Gray in Turton, 1840 ; -idae Adams, 1855, LMNA2 :
230, HSW:565. F. of Testacelloidea, near Limacoidea.

Thyrophorell-idae T. in K., 1926, HSW:586. F. (?) of Lima-
coidea.

Thysanophor-inae Pilsbry, 1926, LMNA:984-994, HSW:582, in
part. SubF: Megomphicinae * HBB., Jan., 1930, LMNA2:
506, HSW:578 (Ammonitellinae* Pils., Dec, 1930, LMNA:
554, HSW:579, genus p. 698; Polygyrellinae HBB., 1955)?
F. of Arionoidea or SuperF. Mesodontinae ?

Tornatellin-idae ^ Pilsbry, 1910, HSW:496 (Pacificellidae Steen.,
1925; Elasmatinidae ^ I., 1944). SubF: Auriculellinae Pils.
& Cooke, 1914, HSW:496 (-idae Odhner, 1922). Helicteridae
or F. of Pupilloidea?

Trigonochlamyd-ina Hesse, 1882 ; -inae Ckll., 1891 ; -idae Mlldff.,
1902, HSW:610. SubF: Parmacellillinae Hesse, 1926, HSW:
610. F. of Limacoidea.

Urocoptidae: Man. Conch. 15-16, LMNA2:103, HSW:668. See
Brachypodella.

Urocycl-idae Simroth, 1889; -inae HSW:643. SubF. or Tribe:
Trochonanininae Connolly, 1912 (-idae Germain, 1921; Tro-
chozonitinae I., 1914, genus HSW:621; Ledoulxiinae * Pils.,
1919). Peltatinae* G.-A., 1912 (Sheldoniinae Connolly,
1925). SubF. of F. Euconulinae or F. of Limacoidea.

Vaginulidae: HSW:489; see Veronicellidae.

Vallon-inae Morse, 1864; -iidae Pilsbry, 1900, LMNA2:1018,
HSW:514; -iinae Watson, 1920 (Circinariidae ^ Pilsbry, 1898;

136 THE NAUTILUS [Vol. 69 (4)

Aeanthinulidae Steenb., 1917; -inae Pilsbry, 1918; Spelaeo-
diseiiiae & Aspasitinae "* S., 1925). See also Strobilopsidae.
F. of Pupilloidea.

Veronieell-idae Gray, 1840, 1842, L]\INA2:1062 (Vaginiilidae
Gill, 1871, HSW:489; -inae, Sarasiniilinae,"* Semperulinae * &
Meisenheimeriiuae - Hffm., 1925). SubP: Imeriniinae &
Pseiidoverouicellinae Hffm., 1928. F. of Gymnophila.

Vertigiiiidae : HSW:503; see Pupillidae.

Vitrin-oidea ^ Fitzinger, 1833; -ida Beck, 1837; -inae Adams,
1855, LMNA2 :499 ; -idae Gill, 1871, HSW :598. SubF : Vitre-
inae HBB., 1930, HSW:587, first 2 and last 2 genera
(L]\INA2:39-J^24; Helicellinae ^ Adams, 1855; -idae Tryon,
1866 ) . Zonitinae, L]\INA2 :246-393, HSW :590 ( Helicellinae ^
in part; Zonitidae Morch, 1864, LMNA2:233, HSW:587; Hya-
liniinae- S. & P., 1879; Godwiniinae^ Cooke, 1921, HSW:
595). Gastrodontinae Tryon, 1866, L]\INA:425, HSW:594
(Janiilinae Wenz, 1923, genns HSW: 573; Poeeilozonitinae
Pils., 1924). Trochomorphinae HSW:622, in part (-idae
MUdff., 1890). Plutoniinae CklL, 1893, HSW:600 (-idae
Mlldff., 1902; Yitrip.- Collinge, 1893; Vitrinop.- Thle., 1926).
Daudebardiinae Pilsbry, 1908, HSW:596 (-idae Kobelt,
1906). F. of Limaeoidea.

Xanthonyc-idae Strebel & Pfeffer, 1879 (Lysinoinae Hffm.,
1928). SubF: Cepolinae Hffm., 1928 (-idae Pils., 1934;
-iinae P., 1939, L]\INA:26). Epiphragmophorinae Hffm.,
1928, HSW:697, tjipe subgenus. HelmintlioghT)tinae Pils.,
1939, L]\1NA:31 (-idae, p. 24). Sonorellinae P., 1939,
L]\INA:267. Humboldtianinae P., 1939, L:MNA:395. In-
cludes Eulotidae? F. of Helicoidea.

Xest-inae Gude & Woodward, 1921, HSW:632, type genus only;
-idae I., 1941 (Naninidae ^ ^'Pfeffer" Martens, 1880; -inae
Pfeffer, 1882; Ariophantinae G.-A., 1888, HSW:629; -idae
Germain, 1921, HSW:611; Hemiplectinae G. & W., 1921).
SubF. or Tribe: Macrochlamydinae - G.-A., 1888, HSW:626
(-idae Wenz, 1923; Tanyehlamydinae HBB., 1928). Durgel-
linae G.-A., 1888, HSW:634 (-idae I., 1937; Sitalinae Sykes,
1900; -idae Germain, 1921; Ostracolethidae * Simr., 1901;
Myotestidae Coll., 1902). Parmarioninae Blanf. & G.-A.,
1908, HSW:642. Dvakinae G. & W.. 1921 (-iinae Laidlaw,
1931; Staffordiinae HSW:632; Pseudoplectinae Thiele, 1934).
Girasiinae HSW:640. SubF. of F. Euconulinae or F. of
Limaeoidea.

Zonitidae: Li\INA2 :233, HSW:587; see Yitrinidae.

From the preceding, Aneylidae, Helieidae,^ Limacidae,^ L^th-

nidae (or L\Tnnoeidae?), Onchididae and Planorbidae appar-

6 At least a distinct tribe, including L5^rN'A2: 253-393 and (?) Betinella

April, 1956] the nautilus 137

ently would date from that indefatigable proposer of unidenti-
fiable names, Rafinesque, 1815. Since, according to tbeir nu-
merous emenders, neither Lymnoea nor Onchidium were words
of ''Greek or Latin origin" (new article 4), should these form
Lymnidae (cf. Blainville & Turton) and Onchididae, which ad-
mittedly would be improvements on their modern spellings ? In
the same year, would Bullinea Oken protect Bulininae, 1880,
against Camptoceratinae, 1870?

Auriculidae, regardless of Roding, would date from 1821 or
1824. (Anyway, since 2 or 3 copies of a sales catalog, privately
distributed, do not constitute publication, opinion 96 is invalid.)

Cerionidae, if dated from 1828, would include a special prob-
lem. Most authors cited Pupa"" Drap., 1801 (-idae, 1828?),
which is a synonym of Ahida in Gastrocoptinae, 1918 ; although
Cerion uva, the only species in Pupa Lamarck, 1801, was kept
in the genus until near the end of the century. May Drapar-
naud's homonym be considered a usage of that of Lamarck?
Similarly, if dated from Bulimidae,^ 1828, Strophocheilidae,
1902, would be called by a family name based on Psiloicus, 1952,
or Corns, 1928. Like Pupa Drap., and despite internal evidence,
may the Bulimus of a century of authors be considered a mis-
usage of Scopoli, 1777 ?

Carychiidae would start in 1829, Pupillidae in 1831, and
Physidae,^ Vertigininae and Vitrinidae ^ in 1833. Succinidae ^
(not -eidae) would go back to Beck, 1837.

Achatinidae would come along in 1840, despite Swainson^s
habitually eccentric spelling. But a family based on his Lu-
cerninae * would replace Camaenidae or Pleurodontidae. Gray
would initiate Amphibolidae, Arionidae, Gadiniidae, Siphonari-
idae, Testacellidae and Veronicellidae in the same year; Philo-
mycidae in 1847; and Athoracophoridae ( Janellidae ^) in 1853.
Coretini, 1847, or a name (1866) based on Parapliolyx, 1922,
would be prior to Helisomatinae, 1928.

H. and A. Adams, 1855, would add Chilinidae, Oleacinidae ^
and Otinidae. On the other hand, their Stenopidae ^ apparently
would make Happia {Scolodens *) type of a family name prior
to Scolodontidae, 1925, or Systrophiidae, 1927. But this change,
like that of Zophos * (Streptaxidae) would fix the family-group
names on ''genera" which have been studied more than either
Scolodonta or Austroselenites.

138 THE NAUTILUS [Vol. 69 (4)

With Hyalinia {= Oxychilus) and Vitrea in sjmonymy, Heli-
cella^ ''Lam." Adams, 1855, Gen. Moll. 2:118 C'Lam., 1812"
Chenu), type now selected Vitrea diaphana Fitzinger, 1833,
Beitr. Land. Oest. 3 :99, has no provable connection with Heli-
cella Fer., 1821, although both were adoptions of Lamarck's
(1812) empty vernacular helicelle. Helicellinae/ 1855, is also
prior to Zonitidae, 1864. But if the Commission, which is study-
ing the case, would validate Lamarck, 1812, with the first (Herr-
mannsen) type species. Helix ericetorum, Helicellidae, 1855,
would include Hygromiinae, 1866. It is also listed, as a con-
futed misusage,^ under Helix, where Helicella temporarily, let
us hope, has become the name of Euparypha-Xerophila-Theha.
(All roads lead to Pisa?)

In 1860, Gray would add Streptaxidae ; and Alb ers-Mar tens
would initiate Orthalicidae, under which Tryon, 1867, also
subordinated Bulimulinae (-idae, 1873).

Morse's (1864) Punctinae would be the earliest of 4 names
prior to Endodontidae, 1895, but his Valloninae (-iidae, 1900)
would be prior to Circinariidae,^ 1898. In the same year, Morch
would start Clausiliidae and Zonitidae, but his Ariantidae *
might replace modern names. Apparently, his Caeciliae ^ would
initiate a subfamily name based on Cecilioides; either it or
Caecilianellinae ^ C. & F., 1877, would replace Ferussacidae,
1883.

Tryon 's (1866) Mesodontinae would be prior to Polygyrinae,
1895, and his Patulinae- to either Endodontinae or Discinae.
Equally bad, a family name based on Brachypodella (same type
as Cylindrella^) and Pease's forgotten Helicterinae,* 1869, mis-
begotten on helicteres, would replace the well known Urocopti-
dae, 1898, and Achatinellidae, 1873, respectively.

Buliminidae,* 1879, although used in the Conch. Cab., would
be longer and more confusing than Enidae, 1914 ; it is another
of the wide-flung spawn of old bulinus Adanson. Clessin would
also initiate Cionellidae. Stenogyridae,* 1877, would include
Subulininae (-idae, 1928) and replace Obeliscinae, 1931.

Xanthonycidae, 1879, is prior to Cepolinae, 1928, or Euloti-
dae,2 1923. Euconulinae apparently would acquire the same
date, 1879, which would make it prior to Godwin- Austen 's
(1888) Helicarioninae (-idae, 1908), Ariophantinae (-idae,
1921), Durgellinae (-idae, 1937) and Macrochlamydinae ^ (-idae,

April, 1956] the nautilus 139

1923), or Simroth's (1889) Urocyclidae. Similarly, Naninidae ^
Martens, 1880, based on Pfeffer's (1878) vernacular Naniniden,
would make Xestinae prior to Ariophantinae. Sower by 's Nan-
inm, 1842, is obviously an erroneous subsequent spelling, al-
though accepted by me, 1936.

The cited superfamilies would be dated: Helicoidea,^ Lima-
coidea,^ Lymnoidea and Ancyloidea, 1815. Cerionoidea,^ 1828?
Pupilloidea, 1831. Succinoidea,^ 1837. Achatinoidea, Ario-
noidea and Testacelloidea, 1840. Oleacinoidea,^ 1855. Ortha-
licidae, 1860. Mesodontinae, 1866. Cionelloidea, 1879. Rhy-
tididae, 1895.

Thus, as in genera, the rule of priority, if applied also to
families, would favor the careless splitter, and establish names
impetuously applied to aberrant and isolated forms. And why
should homonyms, which are almost inseparable from misusages,
deserve any special consideration?

The original code, although artificial, at least was planned by
systematists for the good of all naturalists. The new rules seem
to have been written by orismologists for the sole benefit of
museums.

NOTES AND NEWS

Comment on a paper by David Nicol. — As the paper by David
Nicol, ''An analysis of the Arctic marine pelecypod fauna,"
Nautilus, vol. 68, no. 4, pp. 115-122, July 1955, has attracted
some comment, it seems that certain points should be clarified.
The Arctic collection on which the paper was in large part based
had been made by Prof. G. E. MacGinitie, from dredgings in one
small area near Point Barrow, Alaska. It had been left at the
U. S. National Museum by Mrs. MacGinitie pending her analysis
and publication of results. It was not (as Nicol himself ad-
mitted) a complete sample. I saw additional material that Mrs.
MacGinitie brought to Stanford for study and know that at least
three families, representing six or more genera, were not in-
cluded. These added lots might well make a significant change
in Nicol's comparisons — if we were to grant that he is justified
in comparing an Arctic suite dredged offshore in one small area
with a catalogue list of Floridan material from an area of indefi-
nite size and undefined ecologic boundaries (L, M. Perry,

140 THE NAUTILUS [Vol. 69 (4)

** Marine shells of the southwest coast of Florida," Bulls. Amer.
Paleont, no. 95, 260 pp., 39 pis., 1950; revised by J. S.
Schwengel, 1955). Hence, I feel constrained to point out that
the conclusions Nicol reached may be vitiated by inadequate
control of basic data. — A. Myra Keen, Stanford University,
California.

Mesodon normalis (Pils.) — The land snail usually known as
Mesodon andrewsae normalis (Pils.) generally has been con-
sidered to be a low elevation form of the mountain top M.
andrewsae (W. G. Binney) because it differs only in being larger
and in having a heavier shell. However, the two forms have
been found together at three localities without any intergrada-
tion, which would indicate that they are distinct species. These
localities are: below the Blue Ridge Parkway, near milepost
354, near the Pinnacle of the Blue Ridge, Yancey Co., North
Carolina ; Newfound Gap, Great Smoky Mtns. Nat. Park, Swain
Co., N. C. ; and Beach Gap, south of Sunburst, in Transylvania
Co., N. C. — Leslie Hubricht.

Southern record for Pomacea cumingi (King). — Speci-
mens of this species heretofore known only from Panama have
been received from a lumber camp called La Nueva on the Rio
Truando, dept. Choco, in northwestern Colombia (no. 195769
ANSP., from Mr. F. J. Barcroft of the U. S. Embassy, Bogota).
The Truando is a tributary of the Rio Atrato. The specimens
may eventually be thought subspecifically separable, as they dif-
fer from the Panamic forms by having the suture less impressed
and the interior of the aperture very dark, almost black in some
examples. The largest one measures, height 48 mm., diameter
50 mm., spire eroded. — H. A. P.

Lysinoe sebastiana Dall, a correction. — By typographical
error in the fourth line from the bottom of p. 43 of the October
number, the height given as 0.03 mm. should be 30.3 mm.

Additional marine mollusks at Cape Ann, Massachusetts.
— Recent records of marine mollusks collected as the result of
intensive surveys at Cape Ann, Massachusetts, have been pub-
lished by Dexter (Nautilus 56: 57-61; 57: 67-68; 58: 18-24;
71: 135-142; 59: 69-70. 1942-45) and Clarke (Nautilus 67: 112-
120. 1954). Two species have come to hand which are not re-
ported in the above references. On September 12, 1952, a
single specimen of the chiton, Lepidochiton ruber, was collected

April, 1956] the nautilus 141

by the writer among sea-weeds washed ashore at Good Harbor
Beach.

In the summer of 1947, Mr. Harold Geary brought to the
writer six specimens of an octopus taken in otter trawls made in
Ipswich Bay by the dragger lAicretia under command of Capt.
Sam Nicastro. On August 26, the writer accompanied the crew
on a trawling trip in Ipswich Bay to collect bottom organisms
and to look especially for additional specimens of the octopus.
While 105 specimens of squid were collected, no octopus was
found that day. The six specimens of Octopoda captured earlier
were identified by Dr. Grace E. Pickford of the Bingham
Oceanographic Laboratory, Yale University, as Bathypolypus
arcticus (Prosch). Four specimens were males and two were
females. One of the females had a spermatophore attached to
the first right arm. The specimens have been given to Dr.
Pickford for further study.

Doubtless, the specimens of Xylophaga sp. reported from the
Annisquam River (tidal inlet) at Cape Ann by Dexter (Nautilus
56: 61. 1942) should be referred to X. atlantica Richards 1942
(see Johnsonia 3(34): 152-154. 1955).— Ralph W. Dexter,
Kent State University, Kent, Ohio.

The Kimball Valentine Collection. — The Academy of
Natural Sciences of Philadelphia has recently received as a gift
the extensive marine collection of Beatrice and Kimball Valen-
tine of Washington, D. C. The approximately 2000 lots are
mainly dredged shells from Florida and consist of many un-
usually perfect and rare collectors' items which were assembled
over a period of ten years. — R. T. A.

First Helix aspersa in Hawaii. — On February 7, 1952, Q. C.
Chock of the Territory of Hawaii Board of Agriculture and
Forestry received from Masao Miyamoto, photographer for the
University of Hawaii, a mature, live specimen of Helix aspersa
Muller which the latter had found in his own yard in Kaimuki,
Honolulu. The snail was released in my care and kept in
quarantine in the insectary of the Hawaiian Sugar Planters
Association Experiment station until its death about October 2,
1952. There was no reproduction.

This is the first record of the European brown snail in the
Hawaiian Islands. Its mode of importation to the islands from
its source is unknown. Two speculative methods of introduction

142 THE NAUTILUS [Vol. 69 (4)

may be mentioned. (1) Hawaii imports great quantities of
vegetables and fruits from California where the European
brown snail is a common pest. An occasional juvenile specimen
of the species could easily arrive here, undetected and alive,
hidden among the leaves of vegetables. (2) Immigrant wives of
Hawaiian servicemen returning from Europe could bring speci-
mens back for food. The snail is reported to be easily raised
and propagated at home. — Yoshio Kondo.

Henry Edward Crampton, 1875-1956. — Dr. Crampton died
in the Presbyterian Hospital, New York City, February 26th.
Among malacologists, he was known especially for his very
thorough studies on the distribution and speciation of Partuli-
dae, from islands of the Pacific, to which he made several ex-
peditions. He will be missed by all who knew him. — H. B. B.

Defense of a predator. — In your issue of the Nautilus, Vol.
69, No. 2, October, 1955, pages 37^0, appears an article by
Albert R. Mead entitled ''The Proposed Introduction of Preda-
tory Snails into California." This article was brought to the
attention of the Invertebrate Consultants Committee for the
Pacific, Pacific Science Board, at their annual meeting held in
Honolulu on February 8, 1956. The Committee took strong ex-
ception to some of the statements and inferences appearing in
the paper and have directed the undersigned, as Chairman of
the Committee, to express to you their conclusions with respect
to this article.

The tone of the paper suggests an effort on the part of the
author to discredit one of the most important projects under-
taken by the Committee; a project of great potential economic
significance to the peoples of the Pacific where the African snail
Achatina fulica is a serious threat to food crops essential to
their general welfare. This project has been underway for
nine years, has been heavily financed by the Department of the
Navy through the Ofiice of Naval Research, supported in every
possible manner by the Trust Territory of the Pacific Islands
and carefully planned and directed by highly competent and
mature scientists thoroughly trained and experienced in the
subject of biological control. In fact, some of the members of
the Committee have gained both national and international
prominence because of many achievements of importance in this
general field of science. All are broadly versed in animal ecol-
ogy, evolution and biology. In view of their long and success-

April, 1956] the nautilus 143

ful participation in biological control work, they would not be
prone to encourage or engage in hastily planned or ill advised
projects. Some of Dr. Mead's statements to which we take
issue follow.

Dr. Mead begins his paper with reference to our distribution
of the predatory snail Gonaxis kihweziensis as an invasion rather
than a planned distribution. The very use of the word "in-
vade" suggests the spread of something undesirable, such as a
recognized pest. This Gonaxis has been known a long time, is
not a pest and has never even been considered one. It has been
carefully studied and is known to be carnivorous on other snails,
which habit it has undoubtedly adhered to for countless gen-
erations.

Dr. Mead directly states that the only persons who want to
spread Gonaxis are those in charge of this project. This is, of
course, absurd. As soon as it became known to various insti-
tutions and a great many people in the Pacific, and elsewhere,
that Gonaxis was at least one natural enemy of Achatina fulica,
our Committee has been besieged from many sources requesting
colonies of Gonaxis.

With reference to our introduction of Gonaxis into the Pacific,
Dr. Mead asks ''Is it actually justified." In consideration of
the serious development of Achatina in the Pacific and our proof
that Gonaxis feeds heavily upon the young Achatina, and that
Gonaxis is not otherwise harmful, excepting for its attack on
other non-arboreal snails, we are confident that this introduction
is amply justified. With the march of civilization and com-
merce and the expansion of human populations within the Pa-
cific, we consider the welfare of the human populations more
important than that of the harmless native snails, which will
inevitably suffer with the changes in vegetation coincident with
the advance of man over the areas they now occupy. It is not
unreasonable to assume that masses of uncontrolled Achatina,
may of themselves supplant or suppress certain native snails,
through sheer numbers, and do so as effectively as the Gonaxis.
We consider even a moderate control of Achatina by Gonaxis
justified. Recent investigations on the island of Agiguan still
further strengthen our feeling that Gonaxis is an important
enemy of the African snail. Heavy predation was noted wher-
ever Achatina egg-clusters occurred, with a coincident scarcity
of young snails in such areas.

144 THE NAUTILUS [Vol. 69 (4)

In opposition to our project Dr. Mead states that '^Gonaxis
has not been scientifically proven to be capable of controlling
Achatina fulica." If carefully studied by competent workers
and then considered safe for introduction to new areas, how can
proof of any degree of control be established without liberation?
In the extensive introductions of beneficial parasitic and preda-
tory organisms from one country to another during the past fifty
years or more, if proof of results would be required prior to in-
troduction, there would be no introductions, since proof would
be impossible to determine in advance. This is a philosophy of
defeatism. Had such a philosophy prevailed over modern man,
we could not point with pride to the vast benefits that have ac-
crued through the intelligent biological control work on intro-
duced pests. As examples, this would have precluded the de-
velopment of the present thriving citrus and sugar industries
in California and Hawaii respectively.

Dr. Mead refers to the possible danger of Gonaxis assuming
** strikingly different feeding habits" after passing through a
number of generations in the ''strange environment of Agig-
uan." With his probable training in animal behavior, animal
ecology and evolution as a professor of zoology, it is impossible
to understand how he could believe that such could be possible.
If there is any change in the feeding habits of Gonaxis, after a
few years residence on the island of Agiguan, only one is so far
suggested. There seems to be evidence that Gonaxis is feeding
and developing on Achatina more voraciously on this island than
in its original habitat in Africa.

Though the title of the article relates only to the proposed
introduction of Gonaxis into California, the body of his text
covers our problem in the Pacific as well and in his last para-
graph he refers directly to what he calls the ' ' questionable wis-
dom" of introducing the snail into the Pacific. Finally, his
remark or quotation from an old saying that ''The remedy is
worse than the disease" injects an inference that the whole
project is dangerous and should not have been carried out. We
cannot endorse such an inference since there is no evidence in
this case that the remedy is worse than the disease. In fact, all
evidence indicates the reverse. — C. E. Pemberton, Chairman,
Invertebrate Consultants Committee for the Pacific, Pacific Sci-
ence Board.

Vol.69 JULY, 1955 No. 1 ^

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New Conns from Costa Rica. By Jeanne 8. Schwengel . . 13

Additional localities for land Mollusca in Oklahoma. Bj^

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Shells collected at Loughborough Lake, Ontario. By Dr.

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How clam drills capture razor clams. By H. J. Turner,

Jr 20

On the Nudibranch Alderia modest a (Loven) on the central
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Ecological aspects of the Naiad fauna of Lake Springfield,

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The Pyramidellid Mollusks of the Pliocene Deposits of
North St. Petersburg, Florida. By Paul Bartsch. Smith-
sonian Miscellaneous Collections, vol. 125, no. 2, 102 pp., 18 pis.
1955. — This is the Pyramidellid supplement to the ''Pliocene
Mollusca of Southern Florida with Special Reference to those
from North Saint Petersburg, ' ' by Olsson, Harbison, Fargo and
Pilsbry. The taxonomic treatment of the Pyramidellids by
Dr. Bartsch is quite unlike that of the main report. Of the 113
species of Pyramidellids found at North St. Petersburg, all but
one are described as new, and in most cases are based upon one
or two specimens. While Olsson et al. report that about 32
per cent of the Pliocene species are represented in the Recent
fauna. Dr. Bartsch has made no attempt to compare his many
new species with those of other strata. No degree of morpho-
logical variation is accorded most of the species, and while most
students would be inclined to recognize one or two species in the
St. Petersburg Chrysallida, Bartsch creates 21 new species.
However, he does recognize considerable variation in one species,
having given careful study and innumerable illustrations of
Striopyrgus hyhridus, a species which is as variable as some
Chrysallida or Pyrgiscus. Of the latter, Dall and Bartsch
once stated (1909), "to describe these [varieties] would not aid
science or the collector. ..." It appears that the author be-
lieves the great variation in hyhridus is due to hybridization,
not just between two species, but of two genera, Striotur'bonilla
and Pyrgiscus. He, therefore, erects what he calls the "pseudo-
genus" Striopyrgus. It is interesting that no Strioturhonilla
species have been found in this particular fauna, and it is likely
that the strong, incised spiral grooves of S. hyhridus have arisen
independently as chance mutations without the influence of
generic hybridization. In any event, Striopyrgus is nomen-
clatorially a new genus and not a so-called " pseudogenus " or
' ' form genus ' ' of botanists and horticulturalists. As the author
states, a card catalog of names is helpful when working in so
confused a group, and we draw to his attention two of his
primary homonyms: Odostomia cooperi Bartsch 1955, non Dall
and Bartsch 1907, and 0. stearnsi Bartsch 1955, non Dall and
Bartsch 1903. — R. Tucker Abbott.

iv THE NAUTILUS

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