Zoosyst. Evol. 98 (2) 2022, 427-433 | DOI 10.3897/zse.98.93851

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BERLIN

A new cryptic species of land snail from the Northern Territory,
Australia (Stylommatophora, Camaenidae, Parglogenia)

Frank Kohler, Michael Shea!

1 Australian Museum, Sydney, Australia
https://zoobank. org/08CD0830-C65 7-4D7A-A8&C4-8049BBA3E7A5

Corresponding author: Frank Kohler (frank.koehler@austmus. gov.au)

Academic editor: Thomas von Rintelen # Received 23 August 2022 # Accepted 23 September 2022 Published 31 October 2022

Abstract

Parglogenia cobourgensis sp. nov., a new species of camaenid land snail is described from Cobourg Peninsula, Top End of the
Northern Territory in Australia. This new species has a shell that is identical to the type species of the genus, Parglogenia pelodes,
which also occurs in the Top End. However, both species clearly differ in their reproductive anatomy and are also well-differentiated
in terms of mitochondrial phylogenetics. A single specimen of a Parglogenia species from Croker Island, West Arnhem Land, is
hypothesized to represent a third species based on details of its reproductive anatomy. However, only a single historical specimen
was available for study. We therefore refrain from formally naming this species because of the incomplete information at hand. Helix
subgranosa Le Guillou, 1842, a nominal species previously placed in Parglogenia, is synonymized with Xanthomelon durvillii

(Hombron & Jacquinot, 1841).

Key Words

Eupulmonata, Helicoidea, land snail, Stylommatophora, taxonomy

Introduction

The camaenid Parglogenia Iredale, 1938 is a monotypic
genus endemic to the Top End of the Northern Territo-
ry in the Australian Monsoon Tropics. Its only known
member is Parglogenia pelodes (Pfeiffer, 1846), which
is known to occur in the western part of the Top End,
including the surroundings of Darwin, West Arnhem
Land, the Cobourg Peninsula, and the Tiwi Islands.
Another camaenid that exhibits a rather similar shell in
terms of overall size and shape is Arnemelassa creedi
(Cox, 1868). Arnemelassa creedi replaces Parglogenia
in the eastern part of the Top End and the species are not
known to occur in sympatry. Despite their conchological
similarity, both Parglogenia and Arnemelassa exhibit
vastly different reproductive anatomies indicating that
despite their similar shell these species are not closely
related (Kohler 2012).

Historically, the identity and delimitation of
Parglogenia pelodes has been somewhat controversial
mainly because of the imprecise type locality and the fact
that no type material was known to exist. To remove no-
menclatural uncertainty, Kohler (2012) designated a neo-
type using a specimen that was previously illustrated by
Solem (1979), notably including the taxonomically sig-
nificant reproductive anatomy. As a consequence of this
type designation, the type locality of Parglogenia pelodes
was restricted to Darwin, Dudley Point. Kohler (2012)
also figured the reproductive anatomy of another speci-
men of P. pelodes from Melville Island, which was found
to correspond closely with the anatomy of the neotype as
published by Solem (1979).

Subsequently, mitochondrial DNA sequences of
Parglogenia and Arnemelassa have been included in a
phylogenetic study of the Camaenidae from north-west-
ern Australia. This study confirmed that the taxa are

Copyright Kohler, F. & Shea, M. This is an open access article distributed under the terms of the Creative Commons Attribution License (CC BY 4.0), which permits unrestricted use,
distribution, and reproduction in any medium, provided the original author and source are credited.

428

indeed not immediately related although belonging to the
same principal clade (Kohler and Criscione 2015). The
sequences of Parglogenia pelodes used in this study were
from specimens collected on the Cobourg Peninsula,
about 200 km east of the type locality in Darwin. In the
present study, we sequenced additional specimens of P.
pelodes, including topotypic specimens from Darwin. In
addition, we have examined the reproductive anatomy of
museum specimens from Cobourg Peninsula and Croker
Island from the north-eastern part of the known range of
Parglogenia. These examinations have unearthed a pre-
viously unrecognised species, which is indistinguishable
from P. pelodes in terms of its shell morphology but ex-
hibits a sufficiently distinct reproductive anatomy to war-
rant its description as a new species.

Our report of a new, morphologically cryptic species
in Parglogenia adds to earlier discoveries of cryptic
camaenid land snail species in the Northern Territory.
Notably, we showed earlier that the Top End harbours
three cryptic species of Xanthomelon that cannot be dis-
tinguished from each other by their shell (Kohler and
Burghardt 2016). The existence of such cryptic species
has been mainly attributed to conservativism in shell
shape in snails that are well adapted to living in a rel-
atively homogenous, yet harsh environment (Criscione
and Kohler 2013).

Material and methods

This study is based on analyses of ethanol preserved
specimens and dry shell material, including types, depos-
ited in the collections of the Australian Museum (AM)
and the Museum and Art Gallery of the Northern Territo-
ry (MAGNT).

Dimensions of fully mature shells (as recognised by
a finished apertural lip) were measured with callipers
precise to 0.1 mm: Height of shell (H), diameter of shell
(D). Whorls were counted as described by Kohler (2011).
Genital anatomy was studied using a binocular micro-
scope with drawing mirror.

Genomic DNA was extracted from small pieces of foot
muscle using a QIAGEN DNA extraction kit for animal
tissue following the standard procedure of the manual.
Fragments of two mitochondrial genes, 16S rRNA (16S)
and cytochrome c oxidase subunit 1 (COD), were ampli-
fied by PCR using the primer pairs 16Scs1 (5'-AAACAT-
ACCTTTTGCATAATGG-3') (Chiba 1999) and 16Sbd1
(5'-CTGAACTCAGATCATGTAGG-3') (Sutcharit et al.
2007) and L1490 (5'-GGTCAACAAATCATAAAGA-
TATTGG-3') and H2198 (5'-TAAACTTCAGGGTGAC-
CAAAAAATCA-3') (Folmer et al. 1994), respectively.
Reactions were performed with an annealing step of 60
s at 55 °C for 16S and at 50 °C for COI with elongation
times of 60-90 s, respectively. PCR fragments were pu-
rified with ExoSAP (Affymetrix) and both strands were
cycle sequenced by use of the PCR primers. Chromato-
grams were manually corrected for misreads, if necessary,

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Kohler, F. & Shea, M.: A new species of Parglogenia

and forward and reverse strands were merged into one se-
quence contig using CodonCode Aligner v. 3.6.1 (Codon-
Code Corporation). New sequences have been deposited
in GenBank under the accession numbers ON534065—
ONS534074 and ON532885—ON532893, respectively.
The 16S sequences were aligned using the online version
of MAFFT (version 7.4) (Katoh et al. 2002) available at
www. http://mafft.cbrc.jp/alignment/server/ by employ-
ing the iterative refinement method E-INS-i. We used the
online version of Gblocks (Castresana 2000) to identi-
fy and remove unreliable alignment regions in the 16S
alignment by employing options for a less stringent selec-
tion. The final sequence alignments of 16S and COI were
concatenated into one partitioned dataset. Four partitions
were designated: the entire 16S fragment plus each of the
three codon positions of the COI fragment. Phylogenetic
relationships were estimated by employing a maximum
likelihood-based method of tree reconstruction (ML) by
using IQ-TREE vs 1.6 (Nguyen et al. 2015). We used
ModelFinder (Kalyaanamoorthy et al. 2017) integrated
into IQ-Tree to identify the best-fit model of sequence
evolution for each sequence partition. We employed UI-
trafast Bootstrap Approximation (Minh et al. 2013) to es-
timate the statistical branch support of the best Maximum
Likelihood tree.

Molecular results

Our sequence data set contained concatenated sequences
of COI and 16S from 17 camaenids, of which nine se-
quences were of Parglogenia. The 16S alignment con-
sisted of 732 base pairs and the COI of 655 base pairs.
We selected several species that are more closely relat-
ed to Parglogenia as outgroup representatives based on
phylogenetic tree of north-western Australian Camaeni-
dae presented by Kohler and Criscione (2015). Sequenc-
es of eight camaenids were retrieved from GenBank
while sequences of nine samples have been produced
herein. These new sequences are of seven individuals of
Parglogenia, one individual of Arnemelassa, and one in-
dividual of Chloritis eustoma from the Solomon Islands
(Table 1).

The phylogenetic tree (Fig. 1) shows all Parglogenia
sequences to form a monophylum. The sequences of Par-
glogenia pelodes from Darwin (Buffalo Creek and East
Point Reserve) form the tight sister clade of Parglogenia
cobourgensis sp. nov. from the Cobourg Peninsula.

Among the included species, Parachloritis argilacea
from Timor-Leste is the sister taxon of Parglogenia. You-
wanjela wilsoni from the Kimberley and Chloritis eustoma
from Malaita, Solomon Islands are also more closely related.

Uncorrected genetic p-distances in COI were 0.14%-—
0.4% (on average 0.3%) among sequences of Pargloge-
nia cobourgensis (n= 3) and between 0 and 1.8% (on av-
erage 0.9%) among sequences of Parglogenia pelodes (n
= 6). Interspecific genetic distances between both species
ranged from 13.2% to 13.9% (on average 13.4%).

Zoosyst. Evol. 98 (2) 2022, 427-433

0.3

429

Parglogenia pelodes AM C478455a Buffalo Creek

Parglogenia pelodes AM C478455b Buffalo Creek

Parglogenia pelodes NTM P63374a Buffalo Creek

Parglogenia pelodes NTM P63374b Buffalo Creek

Parglogenia pelodes NIM P63373a East Point Reserve

Parglogenia pelodes NTM P63373b East Point Reserve

Parglogenia cobourgensis AM C460965 Cobourg Peninsula GenBank
Parglogenia cobourgensis AM C460961 Cobourg Peninsula
Parglogenia cobourgensis AM C594396 Cobourg Peninsula GenBank
Parachloritis argilacea Timor-Leste GenBank

Parachloritis argilacea Timor-Leste GenBank

Youwanjela wilsoni Kimberley GenBank

Chloritis eustoma Malaita AM C557142

Arnemelassa creedi East Arnhem Land GenBank

Arnemelassa creedi East Arnhem Land AM C459298

Torresitrachia bathurstensis Kimberley GenBank

Torresitrachia eclipsis Kimberley GenBank

Figure 1. Maximum Likelihood bootstrap consensus tree for a concatenated alignment of mitochondrial 16S and COI sequences
for selected Camaenidae from Northern Australia, Timor-Leste, and the Solomon Islands. Numbers next to branches indicate nodal
support by means of ultrafast bootstrapping. Scale bar: 30% modelled sequence divergence.

Table 1. Sequences used for phylogenetic reconstruction with GenBank and museum registration numbers.

Location
Australia, West Arnhem Land
Australia, West Arnhem Land

Solomon Islands, Malaita
Timor-Leste
Timor-Leste

Australia, Cobourg Peninsula
Australia, Cobourg Peninsula
Australia, Cobourg Peninsula

Species
Arnemelassa creedi
Arnemelassa creedi
Chloritis eustoma
Parachloritis argilacea
Parachloritis argilacea
Parglogenia cobourgensis
Parglogenia cobourgensis
Parglogenia cobourgensis
Parglogenia pelodes
Parglogenia pelodes
Parglogenia pelodes
Parglogenia pelodes
Parglogenia pelodes
Parglogenia pelodes
Torresitrachia bathurstensis
Torresitrachia eclipsis
Youwanjela wilsoni

Australia, Kimberley
Australia, Kimberley
Australia, Kimberley

Taxonomy

Parglogenia Iredale, 1938

Type species. Helix pelodes Pfeiffer, 1846, by original
designation.

Parglogenia pelodes (Pfeiffer, 1846)

Helix pelodes Pfeiffer, 1846: 126 (‘north coast of Australia’). Neotype
FMNH 182450, Darwin, Dudley Point (12°24'S, 130°49'E), desig-
nated by Kohler (2012).

Australia, Darwin, Buffalo Creek
Australia, Darwin, Buffalo Creek
Australia, Darwin, East Point Reserve
Australia, Darwin, East Point Reserve
Australia, Darwin, Buffalo Creek
Australia, Darwin, Buffalo Creek

Museum Voucher GenBank: 16S GenBank: COl
AM C462990 HQ245442 KP085373
AM C459298 ON532885 ON534065
AM C557142 ON532893 ON534074
AM C471161 HG515231 HG515082
AM C468971 HG515229 HG515084
AM C594396 KP085079 KP085395
AM C460965 HQ245508 ON534066
AM C460961 ON532886 ON534067
NTM P63374 ON532887 ON534068
NTM P63374 ON532888 ON534069
NTM P63373 ON532889 ON534070
NTM P63373 ON532890 ON534071
AM C478455 ON532891 ON534072
AM C478455 ON532892 ON534073
WAM S49549 KP085090 KP085409
WAM S49356 KP085093 KP085412
WAM S49583 HE588141 KP085427

Helix prunum — Pfeiffer 1851 [in 1849-1853]: 54, pl. 74, figs 11-13;
Reeve 1852 [in 1851-1854]: pl. 68, fig. 353; Cox 1868: 43, pl. 4, fig.
6 (not Helix prunum Feérussac, 1821).

Chloritis pseudoprunum Pilsbry, 1893: 271 (‘Port Darwin’; Holotype
ANSP 62411).

Parglogenia pelodes — Iredale 1938: 99; Solem 1979: 128-133, fig. 32,
pls 11a, b.

Taxonomic remarks. Since its original description, the
name Helix pelodes has been shrouded in uncertainty
until relatively recently. Pfeiffer (1851 [in 1849—1853]),
subsequently treated H. pelodes as a junior synonym
of Helix prunum Feérussac, 1821. Subsequently, Pilsbry

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430

Kohler, F. & Shea, M.: A new species of Parglogenia

Figure 2. Shells. A. Parglogenia cobourgensis holotype AM C.594396; B. Parglogenia sp. “Croker Island’ AM; C. 121141. Scale
bar: 10 mm.

(1890: 135) agreed with this synonymy, but accepted H.
prunum as an eastern Australian species with uncertain
systematic relationships. Based on this presumption, he
considered that all previous authors had misapplied the
name H. prunum for an unnamed species from Arnhem
Land, for which Pilsbry (1893) introduced the new name
Chloritis pseudoprunum. By contrast, Iredale (1938) and
Solem (1979) considered that the supposed synonymy of
H. pelodes with H. prunum was in error. While H. pru-
num continues to be a taxonomic enigma to this date
(Kohler 2012), Helix pelodes was removed from its syn-
onymy and treated as an accepted species, for which Ire-
dale (1938) described the genus Parglogenia. This treat-
ment rendered C. pseudoprunum a junior synonym of P.
pelodes. Iredale (1938) included a second species in this
genus, P. subgranosa (Le Guillou, 1842). Kohler (2012)
rejected this treatment, arguing that the type of Helix
subgranosa represented a juvenile shell of Xanthomelon
durvillii (Hombron & Jacquinot, 1841). However, Kohler
(2012) maintained H. suwbgranosa as a nomen inquiren-
dum. To remove the remaining ambiguity, Helix subgra-
nosa is herewith placed in the synonymy of X. durvillii.
Diagnosis. Shell relatively large (D = 14.3-31.5 mm,
H = 10.8—20.3 mm; n = 92), with strongly and almost
evenly elevated spire, comprising between 4.5 and 5.8
whorls. Apical sculpture of anastomosing ridges initial-
ly, becoming pustulated after first half whorl. Postapical
whorls with microsculpture of very small, rather widely
spaced setae and extremely fine ridgelets with weak ra-
dial ribs appearing on spire and body whorl. Umbilicus
very narrow, partly covered by reflected lip, internally
with crowded pustules. Body whorl globose, rounded,
only slightly descending behind strongly reflected, thin,
white lip. Shell light yellow brown, uniform. Vagina and

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penis very long, atrium short, bursa copulatrix very short,
without enlarged head. Free oviduct with glandular, con-
voluted walls. Vas deferens with bifurcated caecum on
ascending arm and entering the epiphallus near insertion
of penial retractor muscle without differentiation. A nar-
row, raised ridge separates the epiphallus from the penis;
inner penial walls with longitudinal corrugated ridges;
no penial sheath, verge, or epiphallic appendages present
(Solem 1979; Kohler 2012).

Comparative remarks. Solem (1979) provided a
detailed description of the shell and reproductive anat-
omy of this species based on examination of specimens
from near Darwin. He remarked that the periostracal se-
tae in P. pelodes were similar to those in Semotrachia,
Austrochloritis and “Chloritis argilacea” (presently Pa-
rachloritis argilacea;, see Kohler and Kessner 2014), but
that the genital anatomy of Parglogenia was highly dis-
tinctive. Kohler (2012) illustrated the reproductive anat-
omy of a specimen of P. pelodes from Melville Island,
which closely resembled that of specimens from Darwin.
Shells of P. pelodes, including the holotype of Chloritis
pseudoprunum, have been figured by Kohler (2012).

Parglogenia cobourgensis sp. nov.
https://zoobank.org/16BEC236-647A-49DF-954F-D346F576411C

Holotype. AUSTRALIA - 1| preserved specimen; Northern
Territory, Cobourg Peninsula, 3.4 km NE of Black Point
Ranger Station; 11°08'27.6"S, 132°10'12.0"E; vine thicket;
leg. Vince Kessner, 4 Feb 2007; AM C.594396 (Fig. 2A).
Paratypes. AUSTRALIA - 1 preserved specimen;
same data as holotype; AM C460965. 2 preserved spec-
imens; Northern Territory, Cobourg Peninsula, Black

Zoosyst. Evol. 98 (2) 2022, 427-433

Point nr barge landing; 11°9'18"S, 132°8'44"E; leg. Vince
Kessner, 2 Feb 2007; AM C.460961.

Type locality. Australia, Northern Territory, Cobourg
Peninsula, 3.4 km NE of Black Point Ranger Station
(1.1°08'27°6" S132" 1012-0" EF).

Etymology. For Cobourg Peninsula, where this spe-
cles Occurs.

Additional, non-type material. AUSTRALIA - 1
dry shell; Northern Territory, Port Essington; 11°16'S,
132°9'E; leg. 1900; AM C.64926.

Description. Shell (Fig. 2A). Moderately large (D =
24.4—29.9 mm, H= 19.2—23.1 mm; n=7), globose-conical
with low domed spire, comprising 5 to 5.5 rounded whorls,
moderately to rapidly increasing in diameter, separated by
moderately to strongly incised suture. Teleoconch with
microsculpture of widely to moderately spaced rounded
pustules, in juveniles with short periostracal setae that are
only retained along suture lines in adult specimens. Proto-
conch with microsculpture of elongate pustules arranged
in oblique spirals. Umbilicus narrowly open. Outer lip
moderately developed, outwardly reflected, without sul-
cus behind outer lip. Shell colour light brown, outer lip
pale pinkish to white (Fig. 2A; based on 2 specimens).

Reproductive anatomy (Fig. 3C—F). Bursa copulatrix
about a quarter to half of length of oviduct, with slightly
enlarged to broad head, base broad above uterus junction
becoming inflated and then narrowing before spermathecal
head. Epiphallus broad and bulb-like or narrowing at apex,
length equivalent to about one fifth to one tenth of length
of penis; retractor muscle attached to apex of epiphallus;
vas deferens attached at apex of epiphallus, next to penial
retractor; with small bi-lobed caecum at about one quarter
of its length. Penis straight to slightly kinked to bent above
terminal end, cylindrical, about as long to twice as long as
vagina. Penial walls very thick and muscular. Inner penial
wall sculpture comprising lattice work of filaments below
epiphallus, giving rise to longitudinal rows of intercon-
nected thread-like filaments to corrugated pilasters toward
genital pore; with one or two narrow, wrinkled longitudi-
nal pilasters forming at around mid penis. Penial sheath
absent (Fig. 3C—F; based on 2 specimens).

Head wart oval to trunk-shaped, about 2x3 to 3x5 mm
in size (Fig. 3B); mantle roof typically camaenid (Fig. 3A).

Comparative remarks. Shell effectively indistin-
guishable from Parglogenia pelodes. Fewer shells of
P. cobourgensis were available for examination. These
completely overlapped in size range with P. pelodes oc-
cupying a smaller size range overall. This species differs
from P. pelodes most conspicuously in having a com-
pletely different penial wall sculpture (P. pelodes has lon-
gitudinal corrugated ridges) and by having much shorter
penis, epiphallus, vagina, and bursa copulatrix.

Distribution. The distribution of Parglogenia cobour-
gensis is difficult to delineate due to the paucity of suit-
able material. Here, the known distribution of P. cobour-
gensis is restricted to the Cobourg Peninsula and coastal
parts of west Arnhem Land excluding Croker Island (see
below). Denser sampling is required to delimitate the

431

distributions of P. pelodes and P. cobourgensis more ac-
curately and to clarify the taxonomic status of the Croker
Island population.

Parglogenia sp. nov. ‘Croker Island’

Material examined. AUSTRALIA - 1 preserved spec-
imen, 4 dried shells; Northern Territory, Croker Island,
near airstrip; 11°10'0"S, 132°29'6"E; leg. 28 Mar 1980;
AM C.121141 (Fig. 2B). 1 dried shell; Croker Island;
11°7'S, 132°33'E; leg. 28 Mar 1980; AM C.582514.

Description. Shell (Fig. 2B). Moderately large (D =
27.6-34.2 mm, H = 21.5—24.8 mm; n = 5), globose-con-
ical with low domed spire, comprising 5 to 5.5 round-
ed whorls, moderately to rapidly increasing in diameter,
separated by moderately to strongly incised suture. Te-
leoconch with microsculpture of widely to moderately
spaced rounded pustules, in juveniles with short periostr-
acal setae that are only retained along suture lines in adult
specimens. Protoconch with microsculpture of elongate
pustules arranged in oblique spirals. Umbilicus narrow-
ly open. Outer lip moderately developed, outwardly re-
flected, without sulcus behind outer lip. Shell colour light
brown, out lip pale pinkish to white (Fig. 2B).

Reproductive anatomy (Fig. 3G, H). Bursa copulatrix
about a quarter to half of length of oviduct, with broad
head, base broad above uterus junction, narrowing before
spermathecal head. Epiphallus broad, narrowing at apex,
length equivalent to about one fifth to one tenth of length of
penis; retractor muscle attached to apex of epiphallus; vas
deferens attached at apex of epiphallus, next to penial re-
tractor; with small bi-lobed caecum at about one quarter of
its length. Penis slightly kinked to bent above terminal end,
cylindrical, about as long to twice as long as vagina. Penial
walls very thick and muscular. Inner penial wall sculpture
comprising lattice work of filaments below epiphallus, giv-
ing rise to longitudinal rows of interconnected thread-like
filaments to corrugated pilasters toward genital pore; with
one or two narrow, wrinkled longitudinal pilasters forming
at around mid penis. Penial sheath absent (Fig. 3G, H).

Comparative remarks. Shell effectively indistin-
guishable from P. pelodes and P. cobourgensis. The few
available specimens are at the larger end of the size distri-
bution in this genus, but this might be a sampling artifact.
Differs from P. pelodes most conspicuously in having a
completely different penial wall sculpture that resembles
P. cobourgensis. From P. cobourgensis, the Croker Island
specimen differs in having a shorter bursa copulatrix, a
broad spermathecal head, and a slightly longer epiphal-
lus (one fifth of penis vs. one sixth to one tenth of penis
length), inner penial wall has several longitudinal pilas-
ters instead of only two.

Just a single historical specimen was available for
dissection and not suitable for DNA extraction. For the
paucity of suitable material, we refrain from a formal de-
scription of the Croker Island species.

Distribution. Presumably endemic to Croker Island.

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432 Kohler, F. & Shea, M.: A new species of Parglogenia

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Figure 3. Anatomy of Parglogenia species. A—D. Parglogenia cobourgensis holotype AM C.594396; A. Mantle roof; B. Head wart;
C. Reproductive anatomy; D. Penial anatomy; E, F. Parglogenia cobourgensis paratype AM C.460961; E. Reproductive anatomy;
F. Penial anatomy; G, H. Parglogenia sp. ‘Croker Island’ AM C. 121141; G. Reproductive anatomy; H. Penial anatomy. Abbrevia-
tions: ag, albumen gland; at, atrium; bc, bursa copulatrix; ca, caecum; ep, epiphallus; epv, efferent pulmonary vessel; hd, hermaph-
roditic duct; ipw, inner penial wall; me, mantle edge; mr, mantle roof; ne, nephridium; p, penis; re, rectum; so, spermoviduct; ue,
ureter; va, vagina; vd, vas deferens; vt, ventricle. Scale bars: 10 mm (A, D, F, G); 2 mm (B).

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Zoosyst. Evol. 98 (2) 2022, 427-433

Acknowledgements

Thanks are due to Vince Kessner for collecting much of
the material used in the present study. We thank Isabel
Hyman and Junn Foon for carefully reviewing an earlier
version of this manuscript. Their comments have helped
to improve the quality of this work.

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