Zoosyst. Evol. 98 (2) 2022, 387-397 | DOI 10.3897/zse.98.90540

yee
BERLIN

Multigene phylogeny of the Indo—West Pacific genus Enosteoides
(Crustacea, Decapoda, Porcellanidae) with description of a new species
from Australia

Alexandra Hiller’, Bernd Werding*

1 Smithsonian Tropical Research Institute, Apartado 0843—03092, Panama, Panama
2 Institut fiir Tierokologie und Spezielle Zoologie der Justus—Liebig Universitat Giessen, Heinrich-Buff—Ring 29 (Tierhaus), 35392 Giessen, Germany

https://zoobank. org/DDDBC5 10-F D8 9-46BF-9107-4A3A 1B275B72

Corresponding author: Alexandra Hiller (hillera@si.edu)

Academic editor: Sammy De Grave @ Received 19 July 2022 # Accepted 13 September 2022 Published 4 October 2022

Abstract

The porcellanid genus Enosteoides Johnson, 1970, currently containing six species, was raised in the 1970s to contain aberrant Indo—
West Pacific forms of the diverse and cosmopolitan genus Porcellana Lamarck, 1801. Here, we describe the most aberrant form as
Enosteoides spinosus sp. nov., from the northeast and northwest coasts of Australia and present results on phylogenetic reconstruc-
tions of the genus, based on an 1,870 bp alignment of concatenated DNA sequences of three mitochondrial and one nuclear gene.
The new species is peculiarly spiny and has a higher morphological affinity to the type species of the genus, £. ornatus (Stimpson,
1858), than to the other congeneric species. Our molecular results indicate that Enosteoides is not monophyletic. The new species
and F. ornatus are encompassed in a clade, which does not share immediate common ancestry with the clade containing the other
species of Enosteoides. This clade is more closely related to species of Porcellana and Pisidia. Relatively large interspecific genetic
distances between and within the two clades, as compared to distances estimated in American pairs of species on each side of the
Panama Isthmus, suggest ancient divergence, probably followed by extinction events or low speciation rate. Relatively large intra-
specific distances between Australian populations of the new species of Enosteoides from geographically distant locations suggest
some level of phylogeographic structure.

Key Words

comparative morphology, marine biodiversity, mitochondrial and nuclear markers, molecular systematics, porcelain crabs,
systematics, taxonomy

Introduction and Werding 2019; Osawa and Sato 2022). While some

porcellanid genera are relatively diverse, with more than

Porcellanid crabs comprise a morphologically and
ecologically diverse family of decapod crustaceans
containing over 300 species in 29 genera with littoral
or sublittoral distributions in tropical and temperate
regions of all oceans (Haig 1960; Werding et al. 2003;
Osawa and Chan 2010; Osawa and McLaughlin 2010;
Hiller and Werding 2016; Hiller and Lessios 2017, 2019;
Werding and Hiller 2017; Osawa and Ng 2018; Hiller

100 species (e.g. the globally-distributed Petrolisthes
Stimpson, 1858), others contain few species (e.g. the
American Megalobrachium Stimpson, 1858) and some are
monospecific (e.g. the American Ulloaia Glassell, 1938).
The Indo—West Pacific (IWP) genus Enosteoides
Johnson, 1970 was first established by Johnson (1970) as
a subgenus of the cosmopolitan Porcellana de Lamarck,
1801 (currently with 15 species) to receive only one

Copyright Hiller, A. & Werding, B. 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.

388

species from Singapore, Porcellana corallicola (Haswell,
1882). The description by Haswell (1882), based on
material from Port Molle, Queensland, Australia, is
quite superficial, but allows unequivocal identification of
Enosteoides ornatus. Later, Miers (1884) synonymised
Haswell’s species with “Petrolisthes? corallicola?”, based
on a single female specimen from the same Australian
locality. His description also matches E. ornatus.

In her review of the genus Porcellana, Haig (1978,
p. 709) acknowledged Haswell’s Porcellana corallicola
as a junior synonym of Enosteoides ornatus, described
by Stimpson (1858) as Porcellana ornata from Hong
Kong. Haig elevated Johnson's subgenus to generic rank
to receive the “aberrant Porcellana forms”, including
two additional species from Palau, E. melissa (Miyake,
1942) and E. palauensis (Nakasone & Miyake, 1968).
Osawa (2009) described E. /obatus from Japan, stating
that the genus contained four IWP species. More
recently, two additional species were described from the
Philippines, FE. philippinensis Dolorosa & Werding, 2014
and FE. turkayi Osawa, 2016. Osawa (2009) stated that
E. lobatus is morphologically closer to EF. melissa and
E. palauensis than to E. ornatus, as this later species bears
distinctive spines on the margin of the carapace, on the
antennular peduncle and on the surface of the cheliped’s
palm. Osawa (2016) also emphasised the morphological
affinity amongst E. melissa, E. philippinensis and
E. turkayi, as they share a similar shape and structure
of rostrum and chelipeds and have slender walking legs.
However, E. turkayi is clearly distinguished by the bright
red colouration of the distal segments of all walking legs
and by the shape of the third thoracic sternite, which
resembles that of £. Jobatus (Osawa 2016). All species,
so far described, have a telson composed of seven plates.

Here, we describe Enosteoides spinosus sp. nov. from
Australia, which, at first glance, looks quite different
from all known species of Enosteoides because of its
extremely spiny carapace and remarkably spiny and
sculptured chelipeds. Nevertheless, the new species
agrees with the diagnosis for Enosteoides by Haig
(1978), with one exception: the telson is composed of
five instead of seven plates. Through the reconstruction
of a molecular phylogeny, based on DNA sequences
of three mitochondrial and one nuclear gene, we tested
the monophyly of Enosteoides and explored intra— and
interspecific boundaries within the genus, as well as
evolutionary relationships with morphologically similar
genera, such as Porcellana and Pisidia Leach, 1820 and
with more distantly related genera, such as Petrolisthes
and Pachycheles Stimpson, 1858. For comparison
purposes, we refer to previously published dated molecular
divergence between geminates (sister lines on each side of
America) of Petrolisthes and Megalobrachium, assumed
to have diverged during the final stages of the rising of
the Isthmus of Panama (Hiller and Lessios 2017, 2019)
throughout the Pliocene, approximately 5 to 3 million
years ago (MYA).

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Hiller, A. & Werding, B.: Multigene phylogeny of Enosteo/des with description of a new species

Materials and methods

We collected or obtained specimens of Enosteoides and
other porcellanids from the following museums (see
Table 1 and Acknowledgements): Western Australian
Museum, Welshpool, Australia (WAM), Muséum
National d’Histoire Naturelle, Paris, France (MNHN),
Natural History Museum Los Angeles County (LACM),
Lee Kong Chian Natural History Museum, Singapore
(LIKCNHM, formerly known as the Raffles Museum of
Biodiversity Research—-ZRC) and the Western Philippines
University, Puerto Princesa (WPU). The type material
of the new species is listed below, under the Systematic
Account section. One WAM paratype was kindly donated
by A. Hosie (WAM) to be deposited in the crustacean
collections of the Naturmuseum Senckenberg, Frankfurt,
Germany (SMF). Carapace length and width (in mm) of
type specimens follow locality and collection information.

Molecular techniques

Specimens and GenBank sequences used in_ the
molecular analyses are listed in Table 1. In order to
test the monophyly of Enosteoides, we included in the
phylogenetic reconstruction specimens representing
four other genera of Porcellanidae Haworth, 1825: The
East Atlantic Porcellana platycheles (Pennant, 1777),
P. africana Chace, 1956 and Pisidia bluteli (Risso, 1816),
which are morphologically close to Enosteoides and the
more distantly related Petrolisthes armatus (Gibbes,
1850), Pachycheles monilifer (Dana, 1852) and P. pilosus
(Milne—Edwards, 1837). We used the galatheid Galathea
squamifera Leach, 1814 as an outgroup.

DNA was extracted from muscle tissue of chelipeds
or walking legs using the DNeasy Blood and Tissue Kit
(Qiagen) following the manufacturers protocol for animal
tissues. A 540 bp (base pair) fragment of the ribosomal
16S rDNA was amplified using primers 16Sar (5' CG-
CCTGTTTATCAAAAACAT) and 16Sbr (5' CCGGTCT-
GAACTCAGATCACGT) (Palumbi 1996) and trimmed
to 524 bp in the alignment. A 680 bp fragment of cyto-
chrome oxidase I (COT) was amplified using primers jgL-
CO1490 (5° TITCIACIAAYCAYAARGAYATTGG) and
jgHCO2198 (5° TAIACYTCIGGRTGICCRAARAAY-
CA) (Geller et al. 2013) and trimmed to 644 bp in the
alignment. A 450 bp of cytochrome b (Cytb) was ampli-
fied using primers UCYTBI51F (5' TGTGGRGCNA-
CYGTWATYACTAA) and UCYTB270R (5' AANAG-
GAARTAYCAYTCNGGYTG) (Merritt and Shi 1998)
and trimmed to 361 bp in the alignment. A 370 bp frag-
ment of Histone 3 (H3) was amplified using primers H3F
(5' ATGGCTCGTACCAAGCAGACVGC) and H3R
(5' ATATCCTTRGGCATRATRGTGAC) (Colgan et al.
1998) and trimmed to 338 bp in the alignment. Dou-
ble—-stranded amplifications were performed in 25 ul
reactions containing 5.0 ul of GoTaq—Flexi™ DNA Taq

Zoosyst. Evol. 98 (2) 2022, 387-397 389

Table 1. Species of porcellanids included in the molecular analyses, sampling localities and collection data. Taxa are listed in alpha-
betical order. Collection data are followed by DNA codes. GenBank (GB) sequences of each gene used in the molecular analyses are
shown with respective accession numbers. A species of galatheid squat lobster was used as outgroup (OG); See text for museum codes.

Species n Sampling localities

Enosteoides ornatus 2

Indian Ocean, Arabian Sea, India, Goa, Bogmolo Beach

Indian Ocean, Arabian Sea, India, Goa, Anjuna Beach

Collection Data and GB
Under rocks, 1.5 m (midtide), coll. S. Harkantra, A. Hiller, B. Werding,
Nov. 2006; DNA-W2A
Under rocks, 5 m (mid+tide), coll. S. Harkantra, A. Hiller, B. Werding,
Nov 2006; DNA-W3A

Enosteoides palauensis 2

West Pacific Ocean, Vanuatu, Espiritu Santo Island

Enosteoides 2
philippinensis

West Pacific Ocean, Philippines, Puerto Princesa Bay

West Pacific Ocean, Vanuatu, Espiritu Santo Island

West Pacific Ocean, Philippines, Puerto Princesa Bay

MNHN-IU200813587, Santo Marine Biodiversity Survey, 2006; Sta.
VMb53, coll. Tropical Deep Sea Benthos, 15 Sep 2006; DNA-POR46
MNHN-IU200813588, Santo Marine Biodiversity Survey, 2006; Sta.
FB61, coll. Tropical Deep Sea Benthos, 15 Sep 2006; DNA-POR91
WPU-O1; in mangrove forest with coral rubble, coll. R. Dolorosa,
14 Jun 2004; DNA-929A
WPU-O2; in mangrove forest with coral rubble, coll. R. Dolorosa,
14 Jun 2004; DNA-929B

Enosteoides spinosus 4

Indian Ocean, West Australia, Kimberley District, Beagle Reef

WAM C54779, 1M, 13 m, coll. A. M. Hosie, 20 Dec 2011; DNA-s46

Sp. nov. Indian Ocean, West Australia, Kimberley District, Patricia Island WAM C54781; 1M, 13 m, coll. A. M. Hosie, 22 Oct 2011; DNA-s47
West Pacific Ocean, East Australia, Queensland District, Heron LACM Acc. No. F.P.2.2003-43; mixed dead coral, 5 m, coll. R.
Island, NE side of Wistari Reef Wetzer, N.L. Bruce, N.D. Pentcheff, 13 Apr 2003; DNA-s24
West Pacific Ocean, East Australia, Queensland District, Heron LACM Acc. No. F.P.2.2003-43; rubble from edge of spur, 3.5 m,
Island, NE side of Wistari Reef coll. R. Wetzer, N.L. Bruce, N.D. Pentcheff, 13 Apr 2003; DNA-s25
Enosteoides turkayi 1 West Pacific Ocean, Philippines, Biking, Panglao Island LKCNHM (ex ZRC) 2RC2016.0063, paratype female, stn 129,
77-84 m, mud, coll. PANGLAO 2004 Marine Biodiversity Project,
1 Jul 2004; DNA-8280
Galathea squamifera 1 East Atlantic Ocean, France, Saint Malé Bay, Saint Mal6é Under rocks, intertidal, coll. A. Hiller, Sep. 2000; DNA-41
(OG)

Pachycheles biocellatus 1 East Pacific Ocean, Ecuador, Salinas
Pachycheles monilifer 1

Pachycheles pilosus 1

West Atlantic Ocean, Venezuela, Cubagua Island

West Atlantic Ocean, U.S.A., Florida, Key Biscayne

GB MN715753 (16S), MN711998 (Cytb), MN712184 (H3); DNA-
D29A
GB MN715754 (16S), MN711999, (Cytb), MN712185 (H3); DNA-
q9A
GB MN715755 (16S), MN712000 (Cytb), MN712186 (H3);
DNA-138B

Petrolisthes armatus 2 West Atlantic Ocean, U.S.A, Florida, Fort Pierce, intertidal
East Pacific Ocean, Colombia, Nuqui
Pisidia bluteli 2 East Atlantic Ocean, Balearic Sea, Spain, Catalonia, Costa Brava

East Atlantic Ocean, Adriatic Sea, Croatia, Rovinje
East Atlantic Ocean, Senegal, Ngor Island
East Atlantic Ocean, France, Saint Malé Bay, Saint Malo
East Atlantic Ocean, Strait of Gibraltar, Spain, Andalucia, Tarifa,

Porcellana africana 1
Porcellana platycheles 2

Torre de la Pena

buffer (5x), 3.4 ul of dNTP mix (8 mM), 1.2 ul of each
primer (10 uM), 2.4 ul of MgCl, (25 mM), 0.5 ul of Go-
Taq—Flexi DNA Taq Polymerase (Promega), 1.5 ul of
DNA template, 10.0 ul of ddH,0 and 1—-1.2 ul of DNA
(4-10 ng/ul). Thermal cycling for all amplifications, ex-
cept those performed for the COI fragment, consisted of
an initial denaturation step at 96 °C for 3 min, followed
by 30 cycles of 95 °C for 1 min, 50 °C for 1 min and
72 °C for 1 min. An extension step at 72 °C for 5 min fol-
lowed the last cycle. Amplifications of the COI fragment
followed Geller et al. (2013).

PCR product amplifications were cleaned using the
ExoSap-IT kit (USB Corporation). When more than one
PCR product were amplified, the one of proper size was
cut out of a 2% low—melt agarose gel after electrophore-
sis in 1x TAE buffer. Samples were incubated at 70 °C for
10 min and then, after adding 1.5 ul of GELase™ (Epi-
centre Biotechnologies), they were incubated at 45 °C for
5 hours. We used the BigDye™ Terminator version 3.1
Cycle Sequencing Kit to cycle-sequence clean PCR prod-

GB KY857020 (16S), KY857297 (COl), MN711994 (Cytb),
MN712180 (H3); DNA-135

GB KY857243 (16S), KY857520 (COl), MN711997 (Cytb),
MN712183 (H3); DNA-O11A

Under rocks, intertidal, coll. B. Werding, Sep 2001; DNA-51
Under rocks, intertidal, coll. J. Medenbach, Sep 2001; DNA-1119
Under rocks, 1 m, coll. P. Wirtz, Oct 2009; DNA-9165C
Under rocks, intertidal, coll. A. Hiller, Sep 2000; DNA-48
Under rocks, intertidal, coll. S. Sereda, Sep 2007; DNA-58

ucts in both directions and an Applied Biosystems3130
Genetic Analyzer to electrophorese resulting fragments.
The BIOEDIT Sequence Alignment Editor (Hall 1999)
was used to view sequences and chromatograms and to
trim primers. The programme CLUSTALW (Thompson
et al. 1994), implemented in BIOEDIT, was used to view
and align forward and reverse sequences and to aid in the
alignment of the protein—coding DNA regions (COI, Cytb
and H3). The ribosomal fragment (16S) was aligned with
MAFFT version 7 (Katoh and Standley 2013) using the
profile alignment method to align sequences according
to levels of divergence. Sequences of the four DNA re-
gions of each individual were concatenated, resulting ina
1,870 bp alignment. Redundant haplotypes were removed
from alignments of each gene and of the concatenated set
using TCS version 1.21 (Clement et al. 2000). For each
unique—haplotype gene set, the best model of evolution
was evaluated with the programme jModelTest2 (Darriba
et al. 2012), according to the Akaike Information Criteri-
on (AIC) (Akaike 1974). The concatenated data-set was

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390 Hiller, A. & Werding, B.: Multigene phylogeny of Enosteo/des with description of a new species

subjected to partitioned phylogenetic analyses applying
the appropriate model to each partition. Maximum Likeli-
hood (ML) reconstructions were generated with RAxML
(Stamatakis 2014) using the options for rapid bootstrap
and automatic halting. Support values of nodes were es-
timated from 200 bootstrap replicates. MrBayes version
3.2.7a (Ronquist et al. 2012) was used to conduct Bayes-
ian reconstructions, using as priors the models found by
jModelTest2, and run in four chains for 5 million steps,
needed for the average standard deviation of split fre-
quencies to fall below 0.01. Credibility values of nodes
were estimated by sampling every 500" tree after a burn-
in discard of 1,250 trees. Phylogenetic analyses were
conducted on the CIPRES Science Gateway (Miller et al.
2010). Intra— and interspecific percent two-parameter dis-
tances (K2P; Kimura 1980) were estimated using MEGA
version 7.0 (Kumar et al. 2016) for each gene separately
and for the concatenated alignment, within Enosteoides,
Pisidia and Porcellana and between Atlantic and Pacif-
ic individuals of Petrolisthes armatus (Gibbes). Gamma
corrections, estimated by j;ModelTest2, were implement-
ed in these calculations.

Distances between Atlantic and Pacific individuals of
Petrolisthes armatus have been reported as the smallest
between members of American geminate Porcellanidae
(Hiller et al. 2006; Hiller and Lessios 2017) and have
been assumed here as reference values of relatively re-
cently diverged lines, separated during the final stages of
the rising of the Central American Isthmus, approximate-
ly 3 MYA. Additionally, 16S and Cytb sequence diver-
gence, estimated and dated by Hiller and Lessios (2019)
between American geminate species of Megalobrachium,
was also used as reference of recent events of speciation
predating the complete emergence of the Isthmus.

Results

Systematic account
Family Porcellanidae Haworth, 1825.

Enosteoides spinosus sp. nov.
https://zoobank. org/24604764-3E13-43BD-ABS51-719E24927467
Figs 1, 2a-e, 3

Material examined. Holotype: WAM C54778, <6,
3.5 x 3.4mm. INDIAN OCEAN, WESTERN AUSTRA-
LIA, KIMBERLEY DISTRICT: Beagle Reef, 15°19.60'S,
123°32.15'E, Station 73/K11—T1, intertidal, 19 Oct 2011,
A.M. Hosie leg.

Paratypes: INDIAN OCEAN, WESTERN AUSTRA-
LIA, KIMBERLEY DISTRICT: White Island, 15°04.58'S,
124°20.40'E, Station 68/K11—T1, 14 m depth, 17 Oct 2011,
A.M. Hosie leg., WAM C54777, 13), 4.2 x 4.1 mm; White
Island, 15°04.58'S, 124°20.40'E, Station 68/K11-T1, 14 m
depth, 17 Oct 2011, A.M. Hosie leg., WAM C77600, 19, 3.3
x 3.4mm; Mavis Reef, 15°30.32'S, 123°36.50'E, Station 77/

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K11-T1, 12 m depth, 20 Oct 2011, A.M. Hosie leg., WAM
C48628, 13’, 3.2 x 3.0 mm; Jamieson Reef, 14°10.32'S,
125°32.95'E, Station 111/K12—T2, 4 m depth, 20 Oct 2011,
A.M. Hosie leg., WAM C54780,19, 2.2 x 2.2 mm; Patri-
cia Island, 14°17.98'S, 125°22.43'E, Station 114/K12-T2,
13 m depth, 22 Oct 2011, A.M. Hosie leg., WAM C54781,
14, 3.0 x 2.6 mm; Beagle Reef, 15°21.13'S, 123°32.20'E,
75/K11—-T1, 13 m depth, 20 Oct 2011, A.M. Hosie leg.,
WAM C54779, 14, 2.3 x 2.3 mm; Long Reef, 13°53.37'S,
125°44.56'E, Station 44/K10-T1, 12 m depth, 20 Oct 2010,
A.M. Hosie leg., WAM C45725, 19, 4.6 x 4.8 mm; Bea-
gle Reef, 15°19.60'S, 123°32.15'E, Station 73/K11-T1,
Intertidal, 19 Oct 2011, A.M. Hosie leg., SMF58470 (ex-
WAM C54778b), 1Q(ov), 3.6 x 3.7 mm; WEST PACIFIC
OCEAN, AUSTRALIA: Queensland, Heron Island, NE
side of Wistari Reef, 23°26.93'S, 151°53.41'E, rubble from
edge of spur, 3.5 m depth, 11 Apr 2003, R. Wetzer, N.L.
Bruce, N.D. Pentcheff leg., LACM CR-21354 (RW03.121),
12, 4,0 x 3.9 mm, 1 Q(ov), 3.9 x 4.2 mm.

Diagnosis. Carapace hexagonal, broadest at meso-
branchial level; dorsal surface strongly areolate, with
spines on hepatic and epibranchial regions; acute spines
on orbital, epibranchial and mesobranchial borders; front
prominent, trilobed in frontal view, median lobe pro-
nounced, lateral lobes each with a sharp terminal spine.
Cheliped carpus about three times as long as wide, dorsal
surface heavily eroded, with two broad longitudinal ridg-
es, anterior margin straight with a row of three or more
slender spines, posterior margin with five or six strong
teeth; manus broad, depressed dorsoventrally, dorsal sur-
face with irregular granules and a prominent crest on mid-
line, inner border with strong, upright tooth; outer border
concave, with row of sparse strong spines, dactylus with
rounded median crest on dorsal surface and strong spines
on inner border. Telson broad, composed of five plates.

Description. Carapace about as long as wide, broadest
at mesobranchial level; dorsal surface strongly areolate,
regions distinct and separated by deep grooves; proto-
gastric crest blunt, but steep, with scattered, stiff setae.
Front prominent, truncate in dorsal view, trilobed in fron-
tal view, lateral lobes subparallel, each with a sharp, for-
wardly directed spine terminally, followed inwards by a
smaller, rounded tooth; median lobe pronounced exceed-
ing lateral lobes, outer borders with a row of small, acute
spines, decreasing in size posteriorly; frontal margin with
long, stiff setae.

Orbits relatively shallow, each with one prominent su-
praorbital spine and a smaller spine at outer orbital angle.
Hepatic region with a strong, forwardly directed spine
above elevation of median part; hepatic margin with a
prominent spine. Epibranchial region with small spines
on elevation. Mesobranchial border with three spines, an-
terior two spines strong, third spine smallest, located near
metabranchial region.

Sidewalls broad, surface granulated and eroded, with
transverse ridge, partly covered with long, feathered se-
tae; anterior margin ventrally with a row of forwardly di-
rected blunt spines.

Zoosyst. Evol. 98 (2) 2022, 387-397

391

Figure 1. Enosteoides spinosus sp. nov., female paratype WAM C45725, Indian Ocean, West Australia, Kimberly District. Left
cheliped absent, symmetrically complemented in the figure. Scale bar: 2 mm.

Anterior margin of third thoracic sternite slightly
convex, lateral lobes prominent, resembling forwardly
directed horns. Anterior margin of fourth thoracic ster-
nite concave.

Eyes moderately large, ocular peduncles largely visi-
ble from dorsal side, distally with a distal, forwardly di-
rected stiff seta, dorsal extension into cornea rounded.

Basal segment of antennular peduncle elongate, inner
and outer lobes of anterior margin each with a terminal
strong spine, inner lobe with a row of smaller spines on
inner border. First segment of antennal peduncle strong-
ly produced forwardly, broadly in contact with orbital
margin, anterior margin bent upwards with a bifurcat-
ed, upwardly directed lobe; second to fourth segments
movable, second segment short, with small spine at pos-
terior distal end; third segment elongated with strong
anterodistal spine; fourth segment rounded with small
anterodistal spine. Antennal flagellum about 2.5 times as
long as carapace, articulations thickened distally, bearing
some stiff setae.

Ischium of third maxilliped broad, rounded distally;
merus triangular, slightly concave distally; inner margin
with some small spinules on distal edge; carpus with a tri-
angular, spine—tipped projection on inner margin; propo-

dus broad at proximal end, narrower distally; dactylus
elongate, rounded on distal margin.

Chelipeds subequal, slender, dorsal surface heavi-
ly eroded. Merus granulated with scattered, irregular,
scale—like and acute protuberances on dorsal surface,
anterodistal margin produced into a broad, rounded
lobe with irregular protuberances and squarrose out-
er border. Carpus about three times as long as wide;
dorsal surface with two broad longitudinal ridges, one
running along mid-line, ending distally in a serrated
lobe; another ridge along anterior border, separated
from median ridge by a deep, steep grove; anterior
margin straight, with row of three or more slender, dis-
tally somewhat curved spines of different size; poste-
rior margin slightly convex, separated from dorsome-
dian ridge by a steep slope, bordered with five or six
massive, distally curved teeth. Manus broad, depressed
dorsoventrally, outer border concave; surface of propo-
dus with large, irregular granules and a prominent,
granulated longitudinal crest; outer border concave on
median part, with a row of sparse, massive spines bear-
ing long, simple setae. Dactylus with rounded median
crest on dorsal surface and a row of massive spines on
outer border.

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392 Hiller, A. & Werding, B.: Multigene phylogeny of Enosteo/des with description of a new species

Figure 2. Enosteoides spinosus sp. nov., female paratype WAM C45725, Indian Ocean, West Australia, Kimberly District. a. Left
lateral view; b. Front, anterior dorsal view; ¢. Third and fourth thoracic sternites, ventral view; d. Telson, ventral view; e. Basal
segment of left antennular peduncle, ventral view; f. Third maxilliped, ventral view. Scale bar: 1.0 mm.

Merus of walking legs smooth with scattered, simple
and feathered setae; upper border with an acute spine near
distal end, additional spines sometimes present. Carpus
with longitudinal depression and some stiff setae on up-
per side, with a strong spine; additional spines sometimes
present on median part. Propodus slender, dorsal margin
with one to three spines on different positions. Dactylus
with four movable spines ventrally.

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Telson broad, composed of five plates.

Etymology. The specific name spinosus refers to the
extremely spiny appearance of the new species.

Distribution. Enosteoides spinosus sp. nov. has been
so far reported from the Australian coasts of the Kimber-
ley and Queensland Districts.

Ecology. The species was found in the intertidal region
to a depth of 14 m, in patchy reef structures with inver-

Zoosyst. Evol. 98 (2) 2022, 387-397

393

Figure 3. Enosteoides spinosus sp. nov., female paratype LACM CR-21354, habitus, Pacific Ocean, East Australia, Queensland,
Heron Island. a. Dorsal view; b. Ventral view. Scale bar: 4.0 mm.

tebrates such as sponges, hydroids, hard and soft corals
and in areas with coral rubble, coarse sediment and a fine
dusting of silt.

Colouration. The specimens from Kimberly had been
recently preserved at the time of examination and co-
louration was greyish-brown.

Remarks. The new species gives a first impression of
being morphologically distant from the other species of
Enosteoides as currently defined, mainly due to the excess
of sharp spines ornamenting the carapace and chelipeds.
The new species is morphologically closer to E. ornatus
than to any other species in the genus. Common charac-
ters to the two species are the spiny basal article of the
antennular peduncle, the distinct spines on supra-orbital,
hepatic and branchial regions and the spiny or tubercu-
late surface of the outer half of the palm of the chelipeds.
The two main diagnostic characters of the new species 1s
the telson, which 1s composed of five plates, instead of
seven, a condition present in all other congeneric species
and the proximal margin of the carpus, which bears sharp
teeth in the new species, while it bears small denticules
in E. ornatus.

Molecular phylogeny and genetic distances

The topologies of the phylogenetic trees of Enosteoides
and other porcellanid taxa produced by Maximum
Likelihood (ML) and Bayesian Inference (BI), based
on concatenated sequences of three mitochondrial and
one nuclear gene, were congruent. The consensus tree
(Fig. 4) shows nodes supported by values larger than 80%
bootstrap iterations (ML) and posterior probabilities (BI).
Nodes with lower support values were collapsed. The
phylogeny shows three main clades: clade A containing
American species of Petrolisthes and Pachycheles, clade
B encompassing Enosteoides ornatus and E. spinosus
sp. nov. and clade C gathering Enosteoides palauensis,
E. turkayi, E. philippinensis and the species of Porcellana
and Pisidia included in these analyses. The inclusion
of Pisidia bluteli and of Porcellana platycheles and

P. africana in clade C (subclades C2 and C3, respectively)
and the molecular divergence between this clade and clade
B confirm that Enosteoides is not monophyletic. Since the
type species of the genus, FE. ornatus, is included in clade
B together with E. spinosus sp. nov., all other species of
Enosteoides, included in subclade C1, warrant their own
generic status.

Table 2 lists mean percent two-parameter distances
(K2P) estimated between and within species of
Enosteoides, Pisidia and Porcellana and between
Atlantic and Pacific individuals of Petrolisthes armatus,
for each mitochondrial gene fragment (16S, COI and
Cytb) and for the concatenated set (Conc). Distances
between American geminate species of Megalobrachium,
published by Hiller and Lessios (2019), are also listed in
Table 2 and were also used as reference of molecular lines
recently diverging in allopatry as the barrier comprised
by the Central American Isthmus gradually finished
emerging. Given that Hiller and Lessios (2019) published
COI distances, based on a different fragment of this gene,
we refer to 16S and Cytb comparisons only.

The smallest concatenated distances between Atlantic
and Pacific individuals of Petrolisthes armatus are close
to 3% and those based on 16S and Cytb sequences are
around 2% and 5%, respectively. Interspecific concate-
nated distances within Enostoides are remarkably large,
with the smallest values (around 10—13%) corresponding
to comparisons between EF. palauensis, E. philippinensis
and E. turkayi (Clade C1). Distances between these spe-
cies, based on the 16S and Cytb fragments are, respec-
tively, almost three and two times larger than those esti-
mated between American geminates of Megalobrachium.

Concatenated distances between E. spinosus sp. nov.
and E. ornatus show divergence close to 18% and those
estimated between these two species and the rest of Enos-
teoides range between 23% and 26%. Such large distanc-
es, along with the topology of the phylogeny depicting
independent clades, one conformed by the new species
and EF. ornatus (Clade B) and the other by the other spe-
cies of Ensoteoides (Clade C1), confirm that the genus is
not monophyletic.

zse.pensoft.net

394

Table 2. Mean percent Kimura two-parameter distances with-
in Enosteoides and between sister taxa of other porcellanid
genera. Distances were estimated for each mitochondrial gene
fragment (16S, COI and Cytb) and for the concatenated set
(Conc) of mitochondrial and nuclear genes (H3) and are listed
in ascending order of divergence. EM = East Mediterranean;
EP = East Pacific; G = Gibraltar; WInd = West India; K = Kim-
berley District, Australia; NF = Northern France; Phil = Philip-
pines; Q = Queensland District, Australia, S = Senegal; Vanu
= Vanuatu; WA = West Atlantic; WM = West Mediterranean;
NA = non-applicable because no COI sequences of the fragment
used in the present analyses are available (see text).

Species 16S COl Cytb Conc
Between species
ene platycheles (NF+G)-P. africana 1.32 6.20 3.31 2.21
Enosteoides palauensis-E. philippinensis 8.77 12.44 21.06 10.37
Enosteoides turkayi-E. philippinensis 8.90 12.24 28.45 11.51
Enosteoides palauensis-E. turkayi 11.34: 16.58 27:66 13.51
Enosteoides ornatus-E. spinosus sp.nov. 17.15 23.37 30.65 18.44
Enosteoides philippinensis—E. spinosus 24.78 24.57 36.05 23.50

sp. nov.

Enosteoides philippinensis—E. ornatus 26.86 24.26 37.84 23.98

Enosteoides turkayi-E. ornatus 21 -53::25-51,, 35/91 —25;07
Enosteoides turkayi-E. spinosus sp.nov. 28.95 26.37 39.80 25.67
Enosteoides palauensis-E. ornatus 31.67 26.54 38116925375

Enosteoides palauensis-E. spinosus sp. nov. 32.22 26.00 40.08 26.14
Between geminate species

Petrolisthes armatus (WA)4EP) 1.74 5.29 4.41 3.21
ee poeyi (WA)-M. pacificum 3.41 NA 13.65 NA

Megalobrachium mortenseni 4.21 NA 13.71 NA

(WA}-M. lemaitrei (EP)

Megalobrachium roseum (WA)-M. festai (EP) 5.27. NA 15.58 NA

Within species

Porcellana platycheles (NF]HG) 0.20 0.64 0.34 0.34
Enosteoides ornatus (Wind) 0.40 0.79 1.41 0.66
Enosteoides philippinensis (Phil) 0.00 0.67 2.88 0.78
Enosteoides palauensis (Vanu) 0.60 1.15 1.99 0.95
Enosteoides spinosus sp. nov. (KH{Q) 0.00. 2.93 2:45. 1,31
Pisidia bluteli (WM)-(EM) 0.21 3.24 6.49 2.29

Although few specimens of the East Atlantic species
of Porcellana and Pisidia were included in our analyses,
comparisons of their concatenated distances serve as
reference of relatively recent speciation events. Individuals
of Porcellana platycheles from the North and the
Mediterranean Seas differ from P. africana from Senegal
by distances close to 2%, which are smaller than those
found between the Western Atlantic and Eastern Pacific
populations of Petrolisthes armatus. The concatenated
distance estimated between the two Australian populations
of Enosteoides spinosus sp. nov. from distant localities on
the northeast and northwest coasts of Australia averaged at
around 1.3%. This value is smaller than the transisthmian
distance of P. armatus and the distance estimated between
individuals of Pisidia bluteli from opposite coasts of
the Mediterranean (approximately 2.3%). However, the
distance within Enosteoides spinosus sp. nov. is larger
than that found within E. palauensis (approximately 1%)
and E. philippinensis (approximately 0.8%), suggesting
some level of restriction of gene flow between the
Kimberley and Queensland regions.

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Hiller, A. & Werding, B.: Multigene phylogeny of Enosteo/des with description of a new species

Discussion

Our phylogenetic reconstructions of Enosteoides, based
on three mitochondrial and one nuclear gene, depict two
distantly-related lines independently leading to similar
diagnostic morphologies: one line (clade B in Fig. 4),
containing the type species E. ornatus and E. spinosus
sp. nov. and another line (clade Cl) encompassing the
rest of species of Enosteoides. Although we could not
include E. Jobatus and E. melissa in this study, we expect
these species to join the morphologically homogeneous
group comprised by EF. palauensis, E. turkayi and
E. philippinensis (as defined by Osawa 2009, 2016). Our
results justify retention of EF. ornatus and E. spinosus sp.
nov. in Enosteoides and a future designation of a new
genus to contain all other species.

Our results rely on few samples of each species and,
therefore, our phylogeographic deductions should be tak-
en with caution and be confirmed or rejected in a future
study including larger samples from different populations.
The large interspecific genetic distances within each of
the independent clades of Enosteoides suggest either an-
cient speciation events probably followed by high rates of
extinction or a low rate of speciation within these evolu-
tionary lines. Our reference to small interspecific genetic
distances and to relatively-recent dates of divergence in
other genera relies on values estimated between the ex-
tant American transisthmian Petrolisthes armatus and the
geminate pairs of Megalobrachium. The lowest diver-
gence values between geminates of Megalobrachium date
from the late Miocene (approximately 8.9 million years
ago-M YA) to the late Pliocene (circa 3 MYA), when the
Isthmus of Panama was completed (Hiller and Lessios
2019 and references herein). Due to a limited sample size
of Enosteoides, we have not placed dates of divergence in
our phylogeny. Distances estimated between Enosteoides
ornatus and E. spinosus sp. nov. suggest an older specia-
tion event, as early as the mid—Miocene, over 12 MYA.

Relatively-large intraspecific genetic distances between
E. spinosus sp. nov. from the northeast and northwest coast
of Australia provide a first glance into a possible phylo-
geographic break along the coastline separating the Kim-
berley and Queensland regions, a geographic distance of
over 5,000 km. Convoluted patterns of water circulation
between the Indian and Pacific Oceans (Gordon 2005) may
constitute a contemporary barrier restricting larval disper-
sal in the Indo—Australian Archipelago (Barber et al. 2006).

Despite low sample size, comparisons within the East
Atlantic species of Porcellana and Pisidia included in this
study, allow predictions of recent speciation events and
phylogeographic breaks. The highly similar Porce/lana
platycheles and P. africana were first designated by Chace
(1956) as two subspecies, P. platycheles platycheles from
the European Atlantic coast and the Mediterranean Sea,
with an extra-limital distribution in the Canary Islands and
P. platycheles africana, restricted to the East African coast,
from Western Sahara to Senegal. Our results confirm those
published by Griffiths et al. (2018), who based on morpho-
logical and molecular data, validated the African variant

Zoosyst. Evol. 98 (2) 2022, 387-397

C1

C3

395
Enosteoides palauensis Vanuatu (POR46)
Enosteoides palauensis Vanuatu (PORQ91)
Enosteoides turkayi Philippines (8280)
Enosteoides philippinensis Philippines (929A)
Enosteoides philippinensis Philippines (929B)
C2 Pisidia bluteli Catalonia (51)
Pisidia bluteli Croatia (1119)
Porcellana platycheles Brittany (48)
Porcellana platycheles Gibraltar (58)
Porcellana africana Senegal (9165C)
Enosteoides spinosus n.sp. Queensland (s24)
Enosteoides spinosus n.sp. Queensland (s25)
Enosteoides spinosus n.sp. Kimberley District (S47)

Enosteoides spinosus n.sp. Kimberley District (S46)

>

Enosteoides ornatus Goa (W2A)
Enosteoides ornatus Goa (W3A)
Petrolisthes armatus Florida (135)
Petrolisthes armatus Colombian Pacific (011A)
Pachycheles biocellatus Ecuador (D29A)
Pachycheles monilifer Venezuela (q9A)

Pachycheles pilosus Florida (138B)

ooo Haein telat ier Sen SP eee Galathea squamifera Brittany (41)

Figure 4. Phylogeny of concatenated mitochondrial (16S, COI and Cytb) and nuclear (H3) haplotypes of Enosteoides illustrating the con-
sensus tree inferred by Maximum Likelihood (ML) and Bayesian (BA) analyses. Clades with < 80% bootstrap support (ML reconstruc-
tion) or posterior probability (BA reconstruction) were collapsed. Tip labels show names of species, sampling locality and DNA code.

as a Separate species, Porcellana africana. Concatenated
distances between these two species are smaller than those
found between the American Petrolisthes armatus, sug-
gesting a Late Pliocene (<< 2.5 MYA) disruption of gene
flow between the North Atlantic and Mediterranean popu-
lations and those on the southward African coast.

Relatively high intraspecific divergence within Pisidia
bluteli from opposite coasts of the Mediterranean 1s in-
dicative of either isolation by distance or the presence of
a species complex.

Data availability statement

DNA sequences are available in GenBank with
accession numbers ON521708—ON521724 (for 16S
rDNA), ON521170-—ON521189 (for COI), ON548209—
ON548225 (for Cytb) and ON548226—ON548242 (for
H3). Input files used in analyses: Dryad https://doi.
org/10.5061/dryad.ksn02v77q.

Acknowledgements

We thank A.M. Hosie (WAM), L. Corvari and R. Cleva
(MNHN), J. C. E. Mendoza (LKCNHM), R.G. Dolorosa
(WPU), R. Wetzer (LACM), S. Harkantra (National In-
stitute of Oceanography), P. Wirtz (Madeira, Portugal), S.
Sereda (Justus—Liebig University Giessen, Germany) and J.
Medenbach (Regensburg University, Germany) for collect-
ing or providing access to specimens. We thank O.I. Sanjur
(STRI) for sponsoring A.H., and H. Lessios (STRI) and S.
Samadi (MNHN) for hosting A.H. Thanks to S. Sereda for
inking the drawings of the new species. Specimens from the
WAM were collected during the Woodside Collection Proj-
ect (Kimberley), funded by Woodside Energy Ltd. H. Les-
sios commented on a first draft of this manuscript. We thank
T. Komai and an anonymous reviewer for comments that
helped improve this manuscript. This study was supported
by a Smithsonian postdoctoral fellowship (A.H.) and the
European Commision SyntheSys Programme (A.H. and
B.W.). The authors have no competing interests to declare.

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396 Hiller, A. & Werding, B.: Multigene phylogeny of Enosteo/des with description of a new species

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