#ZooKeys

ZooKeys 1233: 139-193 (2025)
DOI: 10.3897/zookeys.1233.128056

Research Article

Taxonomic revalidation of Selenobrachys Schmidt, 1999 and
Chilocosmia Schmidt & von Wirth, 1992 based on morphological
and molecular analyses (Araneae, Theraphosidae), with the
description of a new species from Romblon Island, Philippines

Darrell C. Acufia’?*©, Maria Mikaela U. Dumbrique™®, Maricel C. Ranido'’“®, Lorenz Rhuel P. Ragasa™,
Charles Nylxon C. Noriega’, Anna Beatriz R. Mayor®®, Gregorio Antonio Florendo Jr°,
Mary Jane A. Fadri®, Volker von Wirth®®, Myla R. Santiago-Bautista’?®, Leonardo A. Guevarra Jr'24©

an oOo FP WO NYP

Research Center for Natural and Applied Sciences, University of Santo Tomas, Sampaloc, Manila 1008, Philippines
Philippine Arachnological Society, Inc., Paco, Manila 1007, Philippines

Graduate School, Polytechnic University of the Philippines, Sta. Mesa, Manila 1016, Philippines

Department of Biochemistry, Faculty of Pharmacy, University of Santo Tomas, Sampaloc, Manila 1008, Philippines
Romblon State University, Odiongan, Romblon 5505, Philippines

Theraphosid Research Team, Hofmarksttr. 6, Eitting 85462, Germany

Corresponding author: Leonardo A. Guevarra Jr (laguevarra@ust.edu.ph)

OPEN Qaccess

Academic editor: Chris Hamilton
Received: 22 May 2024

Accepted: 7 October 2024
Published: 31 March 2025

ZooBank: https://zoobank.org/
E82A9CA6-EC67-4050-A3A9-
2A40AFBS28FE

Citation: Acufia DC, Dumbrique MMU,
Ranido MC, Ragasa LRP, Noriega CNC,
Mayor ABR, Florendo Jr GA, Fadri
MJA, von Wirth V, Santiago-Bautista
MR, Guevarra Jr LA (2025) Taxonomic
revalidation of Selenobrachys Schmidt,
1999 and Chilocosmia Schmidt & von
Wirth, 1992 based on morphological
and molecular analyses (Araneae,
Theraphosidae), with the description
of a new species from Romblon
Island, Philippines. ZooKeys 1233:
139-193. https://doi.org/10.3897/
zookeys.1233.128056

Copyright: © Darrell C. Acuna et al.

This is an open access article distributed under
terms of the Creative Commons Attribution
License (Attribution 4.0 International - CC BY 4.0).

Abstract

Selenobrachys Schmidt, 1999 and Chilocosmia Schmidt & von Wirth, 1992 were con-
sidered junior synonyms to Orphnaecus Simon, 1892 without further morphological in-
vestigation nor the use of molecular methods of analysis. Herein, the type specimens
are reexamined with newly collected samples of currently known Orphnaecus species,
including new specimens from Romblon Island, Philippines. Morphological and molecu-
lar analyses were performed, utilizing cytochrome oxidase | (COI) and ribosomal genes
(12S-tRNA-Val-16S). Synapomorphies in the structure of maxillary lyra, spermathecae,
and male palpal morphology were observed in O. philippinus and the Romblon specimen
which are distinct from other Orphnaecus species. In addition, lyrate morphology, setae
structure on the patella of palp dorsal, and the male palpal organ morphology of O. dichro-
matus differ from other Orphnaecus species. Cladistic separation observed in molecular
phylogenetic analyses supports morphological observations. Our findings suggest that
the genus Selenobrachys is distinct from Orphnaecus; hence, the genus Selenobrachys
Schmidt, 1999, stat. rev. and its type species Selenobrachys philippinus Schmidt, 1999,
comb. rest., are restored and the new species from Romblon Island, Selenobrachys us-
tromsupasius sp. nov., be identified as the second Selenobrachys species. Furthermore,
the genus Chilocosmia Schmidt & von Wirth, 1992, stat. rev. and the original combina-
tion of its type species, Chilocosmia dichromata Schmidt & von Wirth, 1992, comb. rest.
are restored. Male specimens of S. philippinus and C. dichromata were described for the
first time. Insights on the biogeography of Philippine tarantulas are discussed.

Key words: Asian tarantulas, biogeography, Orphnaecus, Philippine spiders, phylogeny,
Selenocosmiina

139

Darrell C. Acuna et al.: Taxonomic revalidation of Selenobrachys and Chilocosmia

Introduction

Tarantulas of the family Theraphosidae Thorell, 1869, are large-sized spiders
that currently comprise 168 genera and over 1000 species (World Spider Cata-
log 2024). These spiders currently have colonized every continent on Earth, ex-
cept Antarctica, and have a diverse array of terrestrial, burrowing, and arboreal
species that exhibit unique defense mechanisms, predatory behaviors, repro-
ductive strategies, and ecological adaptations (Pérez-Miles 2020; WSC 2024).

Orphnaecus Simon, 1892 is one of the 11 recognized tarantula genera of the
subfamily Selenocosmiinae Simon, 1899 found in Asia and Australia (following
the transfer of Poecilotheria Simon, 1885 from Selenocosmiinae to the revali-
dated subfamily Poecilotheriinae Simon, 1892 (Liiddecke et al. 2018; Foley et
al. 2019). This genus currently has five accepted species (WSC 2024), which
include O. adamsoni Salamanes et al., 2022, O. dichromatus, O. kwebaburdeos
(Barrion-Dupo et al., 2015), O. pellitus Simon, 1892, and O. philippinus (Schmidt,
1999). Aside from O. dichromatus, which was discovered in Western New Guin-
ea, Indonesia, the rest of the Orphnaecus species are endemic to the Philip-
pines (Schmidt and von Wirth 1992; Nunn et al. 2016).

Simon (1892) distinguished the genus Orphnaecus in having smaller and
more separated eyes. West et al. (2012) noted the unique structure of the max-
illary lyra of Orphnaecus by its patch of similar short bacilliform rods in reniform
shape and with rows of large clavate bacillae. Nunn et al. (2016) transferred
Phlogiellus kwebaburdeos to Orphnaecus by its lyrate morphology description
that obviously fits the genus. Recently, Salamanes et al. (2022) described a new
species, O. adamsoni, from the Dinagat Islands, Philippines.

Two species of Orphnaecus, namely O. philippinus and O. dichromatus, which
are currently known only from female specimens, became part of this genus after
Selenobrachys and Chilocosmia were synonymized with Orphnaecus (West et al.
2012). Selenobrachys philippinus was transferred to Orphnaecus despite its struc-
tural difference in lyrate morphology (West et al. 2012). This species has an oval
with a proximally truncate and distally tapering lyrate patch with rows of strong
paddles, which is atypical of the characteristic reniform shape with rows of clavate
bacillae generally found in Orphnaecus species (Schmidt 1999; West et al. 2012;
Nunn et al. 2016). This characteristic of O. philippinus was considered, particularly
the variation in lyrate morphology, as an autapomorphy, disregarding the recog-
nition of Selenobrachys as a separate genus (West et al. 2012). Chilocosmia di-
chromata was transferred to Selenocosmia Ausserer, 1871 after the synonymy of
Chilocosmia to Selenocosmia due to the lack of comparison which can adequately
support the recognition of the genus (Raven 2000). Later, Chilocosmia was syn-
onymized with Orphnaecus based on its lyrate morphology, median carapace line,
spermathecal shape, male embolus keel, and cheliceral striker morphology (West
et al. 2012). West et al. (2012) transferred only the type species, C. dichromata, to
Orphnaecus and the other species formerly placed in Chilocosmia were continued
to be treated as Selenocosmia (Se. arndsti, Se. barensteinerae, Se. peerboomi, and
Se. samarae) (WSC 2024). Schmidt (2015) disagreed with this and suggested that
genetic investigations be made to confirm the validity of the revision.

Molecular biology methods such as DNA barcoding and sequence anal-
ysis are techniques that have become useful in identifying organisms and

ZooKeys 1233: 139-193 (2025), DOI: 10.3897/zookeys.1233.128056 140

Darrell C. Acuna et al.: Taxonomic revalidation of Selenobrachys and Chilocosmia

resolving issues related to taxonomic identity (Hebert et al. 2003a, 2003b,
2004, 2016; Hebert and Gregory 2005; Antil et al. 2022). DNA barcoding has
been a complementary method that is used as a rapid method to identify
organisms and resolve taxonomic ambiguities (Tyagi et al. 2019). This tech-
nique allows rapid identification of organisms at the species level based on
the sequences of genes with a length of between 400 and 800 base pairs
(Kress and Erickson 2008). Typically, the mitochondrial markers cytochrome
oxidase | (COI) and 16S rRNA are the genes used in DNA barcoding for ani-
mals (Amer 2021). The ultimate objective of this technique is to produce and
report a DNA sequence that represents an organism in a global database and
use this as taxonomic information for comparison with unknown organisms
for identification (Hebert et al. 2003a, 2003b, 2004, 2016; Hebert and Gregory
2005; Wilson et al. 2018).

In this study, we restored two genera: Chilocosmia stat. rev. with type spe-
cies C. dichromata comb. rest. and Selenobrachys stat. rev. with type species
S. philippinus comb. rest. A new Selenobrachys species collected from Rom-
blon Island, Philippines is described. Males of C. dichromata comb. rest. and
S. philippinus comb. rest. are described for the first time. Also, we utilized the
concept of Pleistocene Aggregate Island Complexes (PAICs), which identify the
seven major biogeographical regions of the Philippines, to discuss our insights
on the biogeography of Philippine theraphosid fauna.

Materials and methods

Specimen collection

The newly collected specimens used in this study were collected through
opportunistic sampling, mostly after midday to night, from different site lo-
calities of tarantula spiders in the Philippines. Specimens of O. dichromatus
examined were from the Staatliches Museum fur Naturkunde Stuttgart collec-
tion in Germany. For field collection, permits and consent were acquired from
respective local government units and Protected Area Management Bureau
(PAMB). Gratuitous permit was secured from the Department of Environment
and Natural Resources- Biodiversity Management Bureau (DENR-BMB) prior to
sampling. Newly collected specimens were preserved in 80% ethanol.

Species concept

The unified species concept proposed by de Queiroz (2005, 2007) was followed,
which utilizes pluralistic evidence and a pragmatic approach. The best avail-
able evidence we have for species delimitation used in this study is morpho-
logical and genetic criteria. Species delimitation was conducted using morpho-
logical differences and then verified using genetic data based on the result of
phylogenetic analysis.

The undescribed putative species used in the phylogenetic analysis were
morphospecies initially identified based on their distribution and morphologi-
cal differences, such as in lyra, genitalia, legs, and setation. They are denoted by
their island locality and species number (e.g., “L1” = “Luzon Island species 1”).

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Darrell C. Acuna et al.: Taxonomic revalidation of Selenobrachys and Chilocosmia

Morphological analysis

The descriptive format generally follows West et al. (2012). Species and genera
described in this study are diagnosed and compared using type specimens and
newly collected samples. Observations and documentation were made using
an Olympus SZ61 stereomicroscope with a Touptek camera attachment or with
a 3.0 USB C-mount Touptek microscope camera adapted with a Nikon SMZ 18
stereo microscope. Illumination was a Starlight RL 5 ring light (daylight) and
a Starlight IL 11 incident light (pure white). Images were stacked with Helicon
Focus 8.2.0 and post-processed with Adobe Photoshop CS2 9.0. Micro mea-
surements were measured using ToupView software version X64, and macro
measurements were taken using digital calipers. All measurements are given in
millimeters to the nearest 0.01 mm. Measurement of total body length includes
chelicerae but does not include spinnerets. Carapace length is measured from
the anterior tip to the posterior longest point. Cephalic height is measured from
the base of the carapace to the highest point of the cephalic region laterally.
The cheliceral strikers are counted and categorized into three rows: the primary
rows are the strikers found at the lowest rows which are distinctly longer, sec-
ondary rows are in the middle rows which are often shorter than the primary
strikers, and the tertiary rows are above the secondary rows which are the very
tiny strikers. Pseudostrikers are rows of long and pallid setae found below the
cheliceral strikers. The length of leg segments was measured on the lateral as-
pect up to the longest point and did not include trochanter and coxa. Leg width
is measured through the widest point and includes both lateral and dorsal as-
pects. The length of the tarsus does not include claws and tufts. The width of
the tarsus and metatarsus does not include scopulae. The length and width of
the coxae and trochanter were measured ventrally. The leg formula is the order
of legs based on leg length given in descending order. The orientation of the
eye rows is described by connecting the center or midpoint of each eye. Eye
diameter is measured through the widest point or the major axis. The length
of curve structures (e.g., fangs, claws, etc.) is measured by their arc/curve
length. Fovea width and curve length were both measured. Palpal bulb struc-
ture followed Bertani (2000) based on the position of the keels. Measurements
of tegulum and embolus followed Bertani (2023). Spermathecae are cleaned
using lactic acid, and emboli are bleached using hydrogen peroxide (see von
Wirth and Hildebrandt 2022, 2023). Variation in measurements, if available,
is provided as ‘total sample size: minimum-—maximum’ (n: min-max). Indices
herein were created to ease comparative morphometrics between theraphosid
species for future referencing.

Indices used herein

Cl Carapace Index = Car. width/ Car. length x 100, the resulting value shows
the ratio of carapace width to length

CLI Cephalic Region Length Index = Cephalic region length/ Car. length x 100,
the resulting value shows the length ratio of the cephalic region within
the carapace

CHI Cephalic Region Height Index = Car. height/ Car. length x 100, the result-
ing value shows the ratio of the cephalic height to carapace length

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Darrell C. Acuna et al.: Taxonomic revalidation of Selenobrachys and Chilocosmia

EI Eye Index: El(AME) = AME diameter/Car. length x 100; EI(ALE) = ALE
diameter/Car. Length x 100; the resulting value shows the diameter ratio
of AME/ALE to carapace length

DLI Dorsal Leg Index = Leg dor. width/ Leg length x 100, the resulting value
shows the ratio of dorsal width to length of a leg

LLI Lateral Leg Index = Leg lat. width/ Leg length x 100, the resulting value
shows the ratio of lateral width to the length of a leg

RF~ Leg Relation Factor (von Wirth and Striffler 2005) = Leg | length/Leg IV
length x 100, the resulting value shows the length ratio of Leg | to Leg IV

MI Metatarsal Index = Met. length / Tib. length x 100, the resulting value
shows the length ratio of the metatarsus to the tibia of the same leg

Tl Tarsal Index = Tar. length/ Met. length x 100, the resulting value shows
the length ratio of tarsus to metatarsus of the same leg

EMI Embolic Index = Embolus length/ tegulum length x 100, the resulting
value shows the length ratio of the male embolus to its tegulum

POI Palpal Organ Index = (Embolus + tegulum length)/ Palp tib. length x 100,
the resulting value shows the length ratio of the male palpal organ to the
palpal tibia.

Setation followed Guadanucci et al. (2020) with additional terminologies.
Terminologies on setation used in this study herein are designated as:

TS __ Tactile setae: hard mechanosensory setae for touch perception, which
are the most common body sensilla of spiders (Guadanucci et al. 2020)
and are diverse in form

SC Cuticular scales: flattened lanceolate or acicular (some are wavy and
cotton-like) light-reflective covering setae or setal mat that have weak
pedicel, almost parallel to the cuticle (Townsend and Felgenhauer 1998;
Guadanucci et al. 2020)

ETB Epitrichobothria: tactile-like setae but very short, intermix with trichobo-
thria on clusters (Guadanucci et al. 2020)

TB __ Trichobothria: clavate or filiform, ground or air movement sensitive sen-
silla (Guadanucci et al. 2020)

CHS Chemosensory sensilla: tiny translucent erect sensilla tapering distally
(Guadanucci et al. 2020), usually found singly on the legs and abdomen

FS Femoral Setation: a field of modified tactile setae (TS) on the prolateral
surface of femora | which varies in form (e.g., sword-like, acicular, fili-
form, etc.), that can be diagnostic in identifying selenocosmiine genera

PB Palpal Brush (first mentioned in West et al. 2012): a layer of modified
elongated flat scales (SC) that is present on the male palpal patella
and tibia dorsally; long and dense in Orphnaecus. They are classified as
scales herein due to their weak pedicel and scale properties.

Abbreviations and acronyms

car. carapace; dor. dorsal; lat. lateral; fem. femur; met. metatarsus; OT ocular tu-
bercle; tib. tibia; troch. trochanter; PS prolateral superior keel; PI prolateral infe-
rior keel; A apical keel; BL basal lobe; Op embolic opening; StR subtegular ridge;
AME anterior median eye; ALE anterior lateral eye; PME posterior median eye;

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Darrell C. Acuna et al.: Taxonomic revalidation of Selenobrachys and Chilocosmia

PLE posterior lateral eye; PMS posterior median spinneret; PLS posterior lateral
spinneret; MNHN Muséum National d'Histoire Naturelle, Paris; PASI Philippine
Arachnological Society, Inc. Reference Collection, Manila; PNM Philippine Na-
tional Museum, Manila; SMF Senckenberg Museum, Frankfurt am Main; SMNS
Staatliches Museum fiir Naturkunde, Stuttgart; UPLB-MNH University of the
Philippines Los Bahos - Museum of Natural History, Laguna; UST-ARC Univer-
sity of Santo Tomas - Arachnid Reference Collection, Manila; ZMB Museum fir
Naturkunde, Berlin; PAIC Pleistocene Aggregated Island Complex.

DNA Isolation, amplification, and analysis

DNA samples were isolated from tissue collected from the right leg III of the taran-
tulas. DNA extraction was performed using the QIAGEN DNeasy Blood and Tissue
Kit following the manufacturer's protocol. For amplification of the Cytochrome ox-
idase | (COI) gene, degenerate primer pairs LCO1490_PH (forward)-HCO2198_PH
(reverse) and C1-J- 2123-PH (forward)-C1-N-2776-PH (reverse) were used after
modifications from the reference primers (see Table 1). The PCR mix consisted
of a final concentration of 0.4uM each of forward and reverse primer, < 10 ng/uL
DNA, 12.5ul 2X GoTaq G2 Master Mix, and water for a final volume of 25 uL. PCR
conditions included an initial denaturation at 94 °C for 3 min, followed by five cycles
consisting of denaturation at 94 °C for 30 s, annealing at 45 °C for 30 s, extension at
72°C for 1 min, 35 cycles of denaturation at 94 °C for 30 s, annealing at 51 °C for 1
min, extension at 72 °C for 1 min, and a final extension at 72 °C for 10 min.

Amplification of the ribosomal genes, a continuous stretch of partial 12S,
complete tRNA- Val, and partial 16S (12S-tRNA-Val-16S), was performed using
our newly designed primer pair 12SUST-PHTarantula (forward)-16SUST-PHTa-
rantula (reverse) (Table 1). PCR mix content is the same as with the COI primers
above. PCR was performed with initial denaturation at 94 °C for 1 min, followed
by 25 cycles consisting of denaturation at 94 °C for 1 min, annealing at 68 °C
for 30 s, and extension at 72 °C for 1 min. This was followed by five cycles of
denaturation at 94 °C for 1 min, annealing at 55 °C for 30 s, and extension at 72
°C for 1 min. The final extension step was performed at 72 °C for 10 min.

After PCR amplification, the products were separated and visualized on a
1.2% agarose gel with a 1kb DNA ladder. The resulting amplicons were sent
for sequencing by Macrogen (Seoul, Republic of Korea). Sequence data was

Table 1. List of primers used to amplify and sequence the DNA barcoding regions COI and rRNA genes.

Primers Primer sequence Source
col
LCO1490_PH (forward) 5'-TTTCWACTAATCATARGGATATTGG-3’ modified from LCO1490aphonopelma (Hamilton et al. 2011)
HCO2198_PH (reverse) 5'-TAAACCTCCGGATGWCCAAAAAAYCA-3’ modified from dgHCO-2198 (Meyer 2003)
C1-J-2123_PH (forward) | 5’-GATCGAAATTTTAATACTTCKTTYTTTGA-3’ modified from C1-J-2123 (Vidergar et al. 2014)

C1-N-2776_PH (reverse) | 5-GGATAATCAGAATATCGTCGAGGTATTCCAT-3’ | modified from C1-N-2776 (Hedin and Maddison 2001)
12S-tRNA-Val-16S

12SUST_PHTarantula 5'-CGTCACCCTCGTCCAAAGAT-3’ this study
(forward)
16SUST_PHTarantula 5'-CGATAGGGTCTTGTCGTCCC-3’ this study
(reverse)

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Darrell C. Acufia et al.: Taxonomic revalidation of Selenobrachys and Chilocosmia

processed using PREGAP4 and GAP4 (Staden Package, http://staden.source-
forge.net/; Bonfield et al. 1995). Raw sequences were trimmed based on base
quality. Forward and reverse reads were aligned and manually checked for am-
biguous sites. A consensus sequence was then generated for each individual.
Sequences from all COI primer pairs were combined to generate the COI con-
sensus sequence for each individual for an extended length. Sequences were
aligned with Theraphosidae sequences from databases using the MUSCLE
algorithm. The hypervariable regions in rRNA gene alignment were removed
using GBLOCKS v. 0.91b online tool (Castresana 2000) under all of the less
stringent set of conditions. The rRNA genes were not separately analyzed due
to the short lengths of 12S and tRNA-Val genes after cleaning.

Maximum-likelihood trees with 10,000 bootstrap replicates were generated
in MEGA11 for both markers using the General Time Reversible model with
gamma-distributed rates among sites with invariant sites (GTR+G+l), chosen
in MEGA11 as best models for both markers based on the lowest Bayesian
Information Criterion (BIC) score (Tamura et al. 2021). All sequences were
used in generating the group (genus rank) mean and pairwise genetic distanc-
es using the Maximum Composite Likelihood model (Tamura et al. 2004) in
MEGA11. Percent similarity is computed by getting the difference of 100% and
the percent distance (similarity% = 100% - distance%). The two markers are not
concatenated due to the unsuccessful ribosomal gene sequencing for many
of the samples and many of the outgroups do not have corresponding COI or
ribosomal gene sequences, hence analyzed separately. DNA sequences of out-
groups were acquired from GenBank. The new sequences in this study are de-
posited to GenBank (Suppl. material 1).

Accession numbers of the sequences obtained from GenBank: COI—
«+ JNO18124 = Aphonopelma seemanni MNHN-JAC96 * JNO18125 = Chilo-
brachys huahini MNHN-JAC48 * JF884459 = Chilobrachys sp. 2GAB_PAK (iBOL)
* KJ744742 = Selenotholus sp. MYG381-T113579 * KT022078 = Grammostola
sp. JEA-2015 » KT995328 = Brachypelma verdezi IBUNAM:CNNA Ar003417
* MF804598 = Chilobrachys sp. USNM ENT 01117339 * MK234708 = Grammos-
tola rosea NCA 2017/394 ; 12S-tRNA-Val-16S— * MG273466 = Brachypelma
sp. ZSM-A 2017/0058 * MG273467 = Chilobrachys fimbriatus ZSM-A 2017/0059
* MG273468 = Cyriopagopus lividus ZSM-A 2017/0060 * MG273470 = Lam-
propelma nigerrimum ZSM-A 2017/0063 * MG273471 = Orphnaeus [Orphnae-
cus] sp. ZSM-A 2017/0064 * MG273476 = Lyrognathus giannisposatoi ZSM-A
2017/0070 * MG273477 = Phlogiellus sp. [?] ZSM-A 2017/0071 * MG273480
= Selenocosmia javanensis ZSM-A 2017/0074 * MG273484 = Poecilotheria for-
mosa PONAL1 * MG273485 = Grammostola pulchripes GRGOL1.

Materials of subject species described in this study are placed on their
respective taxonomic treatments (see Results).

Comparative materials examined
Type materials

* Orphnaecus adamsoni Salamanes et. al, 2022: PHILIPPINES: Dinagat Island—
Dinagat Islands Prov. * holotype 4, PNM 14889; Loreto, Mt. Mangkuno; Oct
2018, J Santos, GG Villancio leg., forest grounds « allotype 2, PNM 14888

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Darrell C. Acuna et al.: Taxonomic revalidation of Selenobrachys and Chilocosmia

[Ornithoctoninae sp.*]; Basilisa-Cagdianao, Mt. Arayat; Oct 2018, J Santos,

GG Villancio leg.; PNM

*Remarks: The allotype 2 (PNM 14888) described in Salamanes et al. (2022)
and herein examined was misidentified and misplaced in Orphnaecus. It be-
longs to Ornithoctoninae due to the presence of plumose setal field on ret-
rolateral chelicerae and has a stridulatory organ with rows of thorn setae on
the prolateral maxilla, which characteristics are absent in Selenocosmiinae but
synapomorphy to Ornithoctoninae. A taxon cannot be assigned for this speci-
men due to its poor condition.

* Orphnaecus kwebaburdeos (Barrion-Dupo et al., 2015): PHILIPPINES: Pollillo
Island—Quezon Prov. « paratypes, 3 34, BPB 2112012-4, BPB 2112012-12,
BPB 2112012-13 and 1 9, BPB 2112012-2; Burdeos, [Brgy. Aluyon], Puting
Bato Cave 3-4; 02 Nov 2012, J. Rasalan leg.; UPLB-MNH

* Orphnaecus pellitus Simon, 1892: PHILIPPINES: Luzon Island— Camarines
Sur Prov. * syntypes 3'2, AR4678; Libmanan, Calapnitan Caves [Culapnitan
Caves] (now Libmanan Caves National Park); MNHN

Other materials

* Orphnaecus kwebaburdeos (Barrion-Dupo et al., 2015): PHILIPPINES: Polillo Is-
land— Quezon Prov. « 4 33 and 14 29, 7 j, UST- ARC 0059-0083; Burdeos,
Brgy. Aluyon, inside Puting Bato Cave 2 and 3; 150 m horiz. depth, 13-14
May 2023, DC Acuna, JD Fornillos leg.; UST-ARC

* Orphnaecus pellitus Simon, 1892: PHILIPPINES: Luzon Island— Camarines Sur
Prov. * 2 34,3 29, 12 j, UST-ARC 0031-0047; Libmanan, Brgy. Sigamot, Lib-
manan Caves National Park (Culapnitan Caves), inside Kalangkawan Cave;
50-300 m horiz. depth, 20 Apr 2023, LA Guevarra, DC Acuna, CN Noriega,
JD Fornillos leg. * 4 j, UST-ARC 0048- 0051; [same general locality data as
above], inside Alinsanay Cave; 50 m horiz. depth, [same collection data as
above] +2 43,4 29, 1 j, UST-ARC 0052-0058; [same general locality data as
above], inside Laya Cave; 30-50 m horiz. depth, 20 Jul 2023, LA Guevarra, DC
Acuna, JD Fornillos leg.; UST-ARC

* Orphnaecus sp. ‘C1’: PHILIPPINES: Catanduanes Island— Catanduanes Prov.
°4°9,1j, PNM 18829-18833; Aug 1990, P Gonzales et al. leg.; PNM

* Orphnaecus sp. ‘L1’: PHILIPPINES: Luzon Island— Laguna-Quezon Prov. border
°14,7 99,1), USTARC 0105-0111; UP Sierra Madre Land Grant; 450 ma.s.l.,
burrows under rocks and logs, 19 Aug 2023, LA Guevarra, DC Acuna, CN Norie-
ga, JD Fornillos, EP Maglangit leg. — Laguna Prov. + 1 j, UST-ARC 0084; Siniloan,
Brgy. Magsaysay, Tulay na Bato Falls trail; 330 m a.s.I., burrows under logs, 04
Feb 2023, LA Guevarra, DC Acuna, CN Noriega, JD Fornillos leg.; UST-ARC

* Orphnaecus sp. ‘L2’: PHILIPPINES: Luzon Island— Laguna Prov. : 5 99, 9 j, UST-
ARC 0088-0101; Siniloan, Brgy. Halayhayin; 15-405 maz.s.l.,05 Feb 2023, LA
Guevarra, DC Acuna, CN Noriega, JD Fornillos leg. + 3 j, UST-ARC 0085-0087;
Brgy. Magsaysay-Galalan, Southern Sierra Madre; 470 m a.s.|., under logs, 04
Feb 2023, LA Guevarra, DC Acuna, CN Noriega, JD Fornillos leg. — Quezon
Prov. * 3 99, UST-ARC 0102-0104; Real, Brgy. Llavac; 300 m a.s.I., 14 May
2023; DC Acuna, CN Noriega, JD Fornillos leg.; UST-ARC

ZooKeys 1233: 139-193 (2025), DOI: 10.3897/zookeys.1233.128056 146

Darrell C. Acuna et al.: Taxonomic revalidation of Selenobrachys and Chilocosmia

* Orphnaecus sp. ‘L3’: PHILIPPINES: Luzon Island— Camarines Sur Prov. + 39
UST-ARC 0132-0133; Libmanan, Brgy. Sigamot, Libmanan Caves National
Park; burrows under and inside logs on forest slope near Kalangkawan Cave,
20 July 2023, LA Guevarra, DC Acufia, JD Fornillos leg. * ¢9 UST-ARC 0130-
0131; [same locality and natural history data as above]; 20 Apr 2023, LA Gue-
varra, DC Acuna, CN Noriega, JD Fornillos leg. * 9 UST-ARC 0134; Libmanan,
Brgy. Malinao; burrow under limestone rock, 20 Apr 2023, LA Guevarra, DC
Acuna, CN Noriega, JD Fornillos leg. * 3 4, 4 99, UST-ARC 0135-0139;
[same locality data as the latter]; 20 Jul 2023, burrows under piles of coconut
husks, LA Guevarra, DC Acuna, JD Fornillos leg.; UST-ARC

* Orphnaecus sp. ‘L4’: PHILIPPINES: Luzon Island— Camarines Sur Prov. * 4 °°,
UST-ARC 0141-0144; Libmanan, Brgy. Sigamot, Libmanan Caves National
Park; burrows under logs on forest slope near Laya Cave, 20 July 2023, LA
Guevarra, DC Acuna, JD Fornillos leg.; UST-ARC

* Orphnaecus sp. ‘L5’: PHILIPPINES: Luzon Island— Nueva Ecija Prov. > 9, UST-
ARC 0145; Bongabon; 2019, G Bathan leg. —Pangasinan Prov. « 3 34,3 29,
PASI ara0014-ara0019; Calasiao, Brgy. Nalsian, Sitio Centro; neglected res-
idential lot and mango orchard, burrows under leaf litter, 08 Nov 2022, DOR
Mapile leg.; UST-ARC/ PASI

* Orphnaecus sp. ‘L6’: PHILIPPINES: Luzon Island— Pangasinan Prov. * 2 PASI-
0020; Sison, Brgy. Poblacion Sur; residential lot, burrows under rock, 08 Apr
2023, DC Acuna leg.; PASI

* Orphnaecus sp. ‘M1’: PHILIPPINES: Mindanao Island— Agusan del Sur Prov.
- ©, UST-ARC 0146; Prosperidad, Brgy. Poblacion, Puting Buhangin Cave-
level 3; 2019, GD Petros leg.; UST-ARC

* Orphnaecus sp.: PHILIPPINES: Luzon Island—Metro Manila « 9°, ZMB 32341;
Manila; Scheteley leg.; ZMB

Results
DNA sequence and phylogenetic analysis

A total of 56 individuals were sampled which resulted in 45 new COI sequences
and 28 new 12S-tRNA-Val-16S sequences. Additional 8 COl sequences and
10 12S-tRNA-Val-16S sequences were obtained from GenBank (Liiddecke et
al. 2018). After alignment, a total of 53 sequences with 467 base pairs were
used for COI, and 38 sequences with 605 base pairs were used for 12S-tRNA-
Val-16S. The sequences under investigation include representatives from dif-
ferent genera, including Orphnaecus, Selenobrachys stat. rev., Chilocosmia stat.
rev., and outgroups (Suppl. material 1). The difference between Orphnaecus,
Selenobrachys stat. rev., and Chilocosmia stat. rev. is evident in genetic similari-
ty matrices as well as their distinct placements in the phylogenetic tree (Fig. 1).

Intergeneric genetic relationship

The phylogenetic tree topologies of both CO! and ribosomal genes (12S-tRNA-
Val-16S) depict the segregation of Orphnaecus, Selenobrachys, Chilocosmia
into different clades (Fig. 1A, C). In the rRNA phylogenetic tree, Orphnaecus,
Selenobrachys, Selenocosmiini genera (Lyrognathus and Selenocosmia), and

ZooKeys 1233: 139-193 (2025), DOI: 10.3897/zookeys.1233.128056 147

Darrell C. Acuna et al.: Taxonomic revalidation of Selenobrachys and Chilocosmia

A

COl

ML Tree 10,000 bootstraps/ 53 seq/ 467 bp

C

12S-tRNA-Val-16S

ML Tree 10,000 bootstraps/ 38 seq/ 605 bp

98 gp LS02-02
50 LSO3-01
QR1-01
og FP QR1-02 Orphnaecus sp. 'L2" hnaecus
aecus LS04-09
ae LS04-11
LS04-12
PSL01 | Orphnaecus sp. "L6' enobrachys CSL04-02
63
36 NEPT-003 Chilobrachys CSLO2-01
obrachys 42 Orphnaecus sp. ‘L5' ‘
‘Selen . 91 PC1-01 : 7 Phiogiellus [?] 100 ff Csto4-o3 | Orphnaecus sp. 'L3'
Selenotholus LS01-01 nocosmiini sane
{Chilocosmia Poecilotheriinae
cd UPLGO1-04 95 atone
rachys 3 hoctoni
1 a UPLG01-05 octoninae ot be
UPLG01-03 Orphnaecus sp. 'L1' 90
ae 99 QBI-03 Orphnaecus kwebaburdeos
aan UPLGO1-01 P
28 UPLG01-02 0.10 39 100 asi-10
CSLO6-02 | Orphnaecus sp. 'L4' MG273471 | Orphnaecus sp. 'N1'
23 s QB1-06 59 UPLGO1-01
Orphnaecus kwebaburdeos "wae
QB2-07 Getcotes Orphnaecus sp. 'L1
PBAT | Orphnaecus sp. "M1" 100
= eaREN PC1-01 | Orphnaecus sp. 'L5"
LS04-08
44 Cate a1 99 | Orphnaecus sp. 'L2"
55 CSL04-02 oe oa QRI-02
=] cst Orphnaecus sp. '"L3 51 CSLO1-01
CSL04-04 CSL01-02
CSLO4-05 CSLO1-08
CSLO05-05 i
86 100 Orphnaecus pellitus
CSL01-02
7 CSLO5-06

53

94

0.10

B

Orphnaecus

(32 seq./ 9 spp.)
Selenobrachys
stat. rev.(8 seq./ 2 spp.)
Chilocosmia
stat. rev.(5 seq./ 1 sp.)
‘Selenotholus'
(1 seq./ 1 sp.)

Chilobrachys

(3 seq./ 3 spp.)

COI Group Mean Percent Similarity Heatmap
O.

Orphnaecus pellitus 100 CSL05-01

CSLO5-07

81 5 NOM1A-04
100

NOM1A-01
60
NOM1A-07
99 » R02-02
8 RO2-16
92 0
400 RO1-02
ce RO1-01 7
MG273467 Chilobrachys fimbriatus
MG273477, ss Phiogiellus sp.[?]
KJ744742 ‘Selenotholus’ sp. MG273476 Lyrognathus giannisposatoi
49
OTU11 1 FS 052014 is MG273480 Selenocosmia javanensis
OTU7 2 FS 052014 Chil ia dich Q MG273484 Poecilotheria f
oTut01JR 012002) Sf ‘ bags jichromata oecilot ae: ‘ormosa
OTUS 2. JR 012002 * MG273468 Cyriopagopus lividus
MG273470 ==Lampropeima nigerrimum
74 # OTUS 4 JR 012002 MG273470 ee :
MF804598 Chilobrachys sp. MG273485 Grammostola pulchripes
JF884459 =Chilobrachys sp. Ast Aphonopelma seemanni
: Poet 89
JNO18125 Chilobrachys huahini E MG273466 = Brachypelma sp.
JNO18124 Aphonopelma seemanni
KT995328 Brachypelma verdezi
KT022078 Grammostola sp. 0.10
99 MK234708 Grammostola rosea

D 12S-tRNA-Val-—16S Group Mean Percent Similarity Heatmap

Ss. C. Sel. Ch. O. S. P. Ch. L. Se.

Orphnaecus

(21 seq./ 7 spp.)
Selenobrachys
stat. rev.(7 seq./ 2 spp.)
Phlogiellus [?]
(1 seq./ 1 sp.)
Chilobrachys

(1 seq./ 1 sp.)
Lyrognathus

(1 seq./ 1 sp.)

Selenocosmia
(1 seq./ 1 sp.)

Figure 1. Maximum-Likelihood phylogenetic tree of A COI gene C rRNA genes (12S-tRNA-Val-16S). Group mean percent

similarity heatmap of B COI

gene D rRNA genes (12S-tRNA-Val-16S), using the Maximum Composite Likelihood model.

Abbreviations: O. = Orphnaecus, S. = Selenobrachys, C. = Chilocosmia, Ch. = Chilobrachys, P. = Phlogiellus, Se. = Selenocos-
mia, Sel. = Selenotholus. Note: dashes (-) in B and D denote values that are not computed because they only contain one

gene sequence.

ZooKeys 1233: 139-193 (2025), DOI: 10.3897/zookeys.1233.128056

Ornithoctoninae are among the clades that have moderate to good support,
with bs = 76-99 (Fig. 1C). However, it is noticeable that all clade separations in
the COI phylogenetic tree (Fig. 1A) have very low support (except Theraphos-
inae outgroups) despite having a good alignment during the analysis. This gene

148

Darrell C. Acufia et al.: Taxonomic revalidation of Selenobrachys and Chilocosmia

probably cannot resolve cladistic distinctions for these taxa or might need more
gene samples to have better support to clades. The separation of Orphnaecus
and Selenobrachys in the rRNA phylogenetic tree has moderate support with bs
= 76. On the other hand, this separation is well supported by the genetic simi-
larity matrices, indicating substantial genetic divergence between Orphnaecus
and Selenobrachys clades, with an average of 88% similarity in COI and an av-
erage of 85% similarity in rRNA genes (Fig. 1B, D). The percent similarity of the
two genera using both markers shows their close affinity suggesting that they
have common ancestry and that Selenobrachys might have recently diverged
into a distinct clade. Percent pairwise distance among individual samples
between Orphnaecus and Selenobrachys ranges from 10.20%-15.50% in COl
and from 12.05%-18.33% in rRNA genes (Suppl. material 2). Chilocosmia is
more distant at a lower average similarity value of 86% to both Orphnaecus and
Selenobrachys, as well as to Selenotholus, using the COI marker (rRNA gene
sequences for Chilocosmia are not available) (Fig. 1B, D). Pairwise percent dis-
tances among individual samples of Chilocosmia from Orphnaecus individuals
using the COI gene range from 10.59%-16.76%, and from Selenobrachys sam-
ples range from 11.81%-18.11% (Suppl. material 2).

Interspecific genetic relationship

The percent similarity values between putative 9 species (only 7 putative
species were successfully sequenced for rRNA genes) within Orphnaecus
range from 89.14%—-95.10% (at 4.9%-10.86% distance) in COI sequences and
86.46%-95.02% (at 4.98%-13.54% distance) in 12S-tRNA-Val-16S sequenc-
es using Maximum Composite Likelihood model (Tamura et al. 2004) (Sup-
pl. material 2). Some species within Orphnaecus have relatively high pairwise
distance values for COI. For instance, between O. pellitus (the type species)
and the clade of the putative species Orphnaecus spp. ‘L1’, ‘L2’, ‘L5’, and ‘L6’
have 9.63%-10.86% pairwise distance (Suppl. material 2). Some species of
this group have a closer genetic distance from other Orphnaecus species which
does not support separation from Orphnaecus (Suppl. material 2). On the other
hand, O. kwebaburdeos and Orphnaecus sp. ‘L3’ recorded the closest genet-
ic affinity having a 4.90%-5.09% distance in COI, but heterospecificity is well
supported by their distinct genital structures. In the rRNA genes, the furthest
distance recorded with 12.03%-13.54% distance is between O. pellitus and Or-
phnaecus spp. ‘L2’, and ‘L3’ (‘L6’ has no successful sequence), except for Or-
phnaecus sp. ‘L1’ which has 8.47%-9.46% distance to O. pellitus. The closest
distance is also between O. kwebaburdeos and Orphnaecus sp. ‘L3’ with 4.98%
distance in all rRNA gene sequences.

The close relationship between the two Selenobrachys species, S. philippi-
nus comb. rest. and S. ustromsupasius sp. nov., is evident in both the COI and
rRNA genes (12S-tRNA- Val-16S) genetic matrices (Suppl. material 2). In the
phylogenetic tree, their relationship has enough support in COI (bs = 95) and
rRNA genes (bs = 93) (Fig. 1A, C). In the COI matrix, these two species exhib-
it percent similarity values of 90.57%—-91.74% (8.43%-9.26% distance), while
in the rRNA genes matrix, they show values of 90.18%-90.84% (9.16%-9.82%
distance) (Suppl. material 2). These higher similarity values compared to oth-
er sequences suggest a relatively reduced genetic divergence between them.

ZooKeys 1233: 139-193 (2025), DOI: 10.3897/zookeys.1233.128056 149

Darrell C. Acuna et al.: Taxonomic revalidation of Selenobrachys and Chilocosmia

The phylogenetic tree placement further corroborates this observation. The COI
sequences of S. philippinus comb. rest. and S. ustromsupasius sp. nov. cluster
together within a distinct clade, suggesting a shared evolutionary history.

Taxonomy

Family Theraphosidae Thorell, 1869
Subfamily Selenocosmiinae Simon, 1889

Tribe Selenocosmiini Simon 1889
Phlogiini Simon, 1892 (synonymized by Simon 1903).

Included genera. Chilocosmia Schmidt & von Wirth, 1992 stat. rev. (provision-
ally placed), Coremiocnemis Simon, 1892, Lyrognathus Pocock, 1895, Psednoc-
nemis West, Nunn & Hogg, 2012, Selenocosmia Ausserer, 1871.

Remarks. The genus Chilocosmia does not fit to any of the three currently
recognized selenocosmiine tribes (Chilobrachini, Selenocosmiini, and Yamii-
ni) and probably belongs to a tribe currently in synonymy with Selenocosmii-
ni (probably Phlogiini Simon, 1892); hence, we provisionally placed it in Sele-
nocosmiini until further investigation is conducted on the proper systematic
placement of most of Papuan and Australian taxa.

Genus Chilocosmia Schmidt & von Wirth, 1992, stat. rev.

Type and included species. C. dichromata Schmidt & von Wirth, 1992, comb.
rest., by original designation and monotypy.

Diagnosis. Chilocosmia stat. rev. differs from all known selenocosmiine gen-
era (i) in having a palpal organ with twisted tegulum (Figs 4A-C, 5A-D) and (ii)
in having a stridulatory organ on the prolateral maxilla with short bacilliform
rods that form an arcuate strip of a lyrate patch and with club-shaped bacillae
at lowest row (Fig. 3D, E). The lyra of Chilocosmia stat. rev. (Fig. 3D, E) quite
resembles the lyra of Orphnaecus (Fig. 20G) but differs in the shape of the larg-
est stridulating setae which lacks a pointed apex (Fig. 20C, F). It further differs
from Orphnaecus in the male palpal organ morphology in having a twisted tegu-
lum and a thicker embolus with shorter PS and lacking a basal lobe (Fig. 5A-—E),
and in lacking palpal brush on dorsal palp in males (Fig. 4D).

Distribution. Indonesia: West New Guinea.

Etymology. A combination of two Greek words chilos (cheilos; yeidoc),
which means lip, and kosmein (Koousiv), which means arrange or keep in order
(Schmidt and von Wirth 1992). Gender is feminine.

Chilocosmia dichromata Schmidt & von Wirth, 1992, comb. rest.
Figs: 2-6, 20, F.211,.J

Type material examined. INDONESIA— West New Guinea * holotype °, SMF
37099-84; Sorong; SMF.

ZooKeys 1233: 139-193 (2025), DOI: 10.3897/zookeys.1233.128056 150

Darrell C. Acufia et al.: Taxonomic revalidation of Selenobrachys and Chilocosmia

Other material examined. INDONESIA— West New Guinea « 2 ¢' SMNS Aran-
004182 and Aran-004183, 5 99, SMNS Aran-004184, Aran-004185 and Aran-
004162-004164, 3 j, SMNS Aran-004186; Sorong; 00°47'36.4"S, 131°26'32.8'E,
F. Schneider leg., 2014; SMNS.

Diagnosis. See genus diagnosis.

Description. Male (SMNS Aran-004182). Body length 38.50 (n = 238.50-38.62).

Carapace (Fig. 2B). 17.2 long, 14.9 wide, anterior width 8,95, cephalic height
4.9, cephalic region 11.3 long, thoracic region 4.79 long. Cl 86.62, CLI 65.69,
CHI 28.48. Fovea width 1.85, curve length 2.11, procurved (Fig. 2E). Carapace
has four pairs of furrows, mainly covered with yellowish brown setae directed
towards fovea, lateral profile low and flat, and integument dark brown. Setation:
TS(a), rows of very short pale yellowish brown setae covering entire carapace,
directed towards fovea and OT anteriorly. Posterior surface of OT with few long
pale brown TS. TS(b), long pale yellowish brown setae at carapace margin, an-
terior margin pale brown. SC(a), brown flat scales sparsely covering OT. SC(b),
sparse, pale yellowish brown, acicular scales covering carapace, anteriorly.

Eyes (Fig. 2D). Ocular Tubercle 3.12 long, 2.28 wide, OT integument entirely
dark. AME round, rest of the eyes ovoid. Anterior row of eyes slightly procurved,
posterior row of eyes recurved. Eyes: AME 0.69, ALE 0.79, PME 0.46, PLE 0.61.
Interocular distances: AME-AME 0.38, ALE-ALE 1.94, PME-PME 1.48, PLE-PLE
2.21, AME-ALE 0.13, AME-PME 0.22, AME-PLE 0.56, ALE-PLE 0.23, ALE-PME
0.47, PME-PLE 0.14. El (AME) 4.01, El (ALE) 4.59.

Chelicerae (Fig. 3A—C). length 9.72, dorsal width 3.27, lateral width 5.99, fang
curve length 7.29. Teeth 12, mesoventral denticles sparse 45. Setation: TS, long
pale brown setae on dorsal and upper 1/2 retrolateral surface, longer anteriorly.
Lower 1/2 of retrolateral surface posteriorly with rows of pallid filiform setae
and anteriorly with patch of pallid needleform setae. Mesoretrolateral surface
with rows of very sparse setae basally spiniform and anteriorly needleform.
Mesoprolateral surface with intercheliceral setae, arcuate strip of rows of pallid
needleform setae originating basally. Lower 1/2 prolaterally sparsely covered
with setae, brown needleform at lower rows, and pale brown filiform at upper
rows. SC, flat, translucent, pale brown scales, covering dorsal and upper ret-
rolateral surface. Integument mostly dark brown. Cheliceral strikers (Fig. 3C):
111, 0.20-1.03, dark, long spiniform with filiform ends.

Maxillae (Fig. 3D, F). Prolateral maxilla 6.33 long, 4.02 wide laterally, 3.58
wide ventrally. Maxilla prolaterally planoconvex, anterior lobe well pronounced,
integument orangey brown, dark dorsally, basoventral cuspules 212. Lyra (Fig.
3D): lyrate patch, 2.24 long, 1.38 high, total rods 190, 10 or 11 rows, surrounded
by very fine setae, denser above and distally. Short rods form an arcuate strip
of patch. Longest club-shaped rods in lowest row 13, 0.27-0.78. Setation: TS,
pale brown setae, longer ventrally, stronger at distodorsal margin. Lyrate patch
surrounded by fine setae. Above maxillary suture, rows of ~ 13 stiff dark TS. SC,
brownish white flat scales covering dorsally. Retrolateral surface smooth, with
rows of short semi-transparent bristles at the lower margin.

Labium and sternum (Fig. 2C, F). Labium: 2.30 long, 3.12 wide. Integument
orangey brown, dark at posterior margin, anterior 1/3 with cuspules 371. Seta-
tion: TS(a), long, pale brown with pale filiform ends, covering labium anterior-
ly and laterally except on cuspule cluster, longer and greater at anterior edge,
all pointing anteriorly. TS(b), brown, short needleform below cuspule cluster.

ZooKeys 1233: 139-193 (2025), DOI: 10.3897/zookeys.1233.128056 151

Darrell C. Acuna et al.: Taxonomic revalidation of Selenobrachys and Chilocosmia

Bre

s
. »

Wr
——
ze 2
d d y ke

or

wha
ed

-

&

= 7

Z;

FT,

eo . ‘ 4 y

q = %s Sine f " At : ;
. f ; : j 55 a : A VN

ee RT Ae LL WGP A XY

LOS MIE Wt

4 YOSSs = Nf EAS 4 eR

; pM EGE Be d
% vy oa Sys N

I

AS

&
tS
aaa

Sea A 92 ff. Ex NAY
SS =e en pl Zi A i i ty Be yaa: i ; iS
Figure 2. Chilocosmia dichromata comb. rest. 4, SMNS Aran-004182 A habitus, in situ B prosoma, dorsal view C ventral
view D ocular tubercle, dorsal view E fovea, dorsal view F labium, ventral view. Photo credit: Frank Schneider (Fig. 2A).

Sternum: 8.2 long, 6.93 wide integument yellowish brown. Posterior sternal
corner acuminate, lateral corners weakly acuminate. Setation: TS(a), long pale
brown spiniform setae, pale apically, on entire sternum, but very sparse. TS(b),
short pale brown setae covering sternum entirely. TS (c) fine, pallid, and short
spiniform, at sternal margin. SC, brownish white flat scale mat densely cover-
ing entire sternum. Labiosternal sigilla 1.07 long, 0.34 wide, 0.83 apart. Sternal
sigilla 2 pairs, median sigilla 0.69 long, 0.35 wide, 3.91 apart and 0.58 away
from sternal margin adjacent to coxa II, posterior sigilla 1.08 long, 0.42 wide,
1.59 apart and 1.77 away from sternal margin adjacent to coxa Ill (Fig. 2C).

ZooKeys 1233: 139-193 (2025), DOI: 10.3897/zookeys.1233.128056 159

Darrell C. Acuna et al.: Taxonomic revalidation of Selenobrachys and Chilocosmia

ZZ

ff
A

Mh

| Ayaan i
mn Li.

Figure 3. Chilocosmia dichromata comb. rest. 4, SMNS Aran-004182 A left chelicera, retrolateral view B prolateral view
C cheliceral strikers, retrolateral view D maxillary lyra on left prolateral maxilla E left maxilla, prolateral view.

1mm

Abdomen and spinnerets. Abdomen: 17.56 long, 10.09 wide. ovular elongat-
ed, integument pale brown. Setation: TS(a), long, pale brown with darker bases,
needleform, on entire abdomen, shorter ventrally, pallid on book lungs. TS(b),
pallid short paddle-like, on book lungs and sparse on epigynal plate. SC, over-
lapping pale brown translucent scales covering entire abdomen. Spinnerets:
PMS 2.39 long, 0.84 wide, PLS, anterior 2.30 long, 0.71 wide, median 1.82 long,

ZooKeys 1233: 139-193 (2025), DOI: 10.3897/zookeys.1233.128056 153

Darrell C. Acuna et al.: Taxonomic revalidation of Selenobrachys and Chilocosmia

Figure 4. Chilocosmia dichromata comb. rest. 4, SMNS Aran-004182 A left pedipalp, prolateral view B ventral view
C retrolateral view D left palpal patella and tibia, prolateral view.

0.99 wide, posterior 3.65 long, 1.39 wide. Setation: TS(a), long, pale brown
with darker bases, needleform, on dorsal PMS and PLS. TS(b), dark and short,
pale brown paddle-like, intermixed with spigots, on PMS and PLS ventrally. SC,
brownish white flat scales covering PLS dorsally.

Genitalia (Figs 4A—-C, 5A-E). Palpal Organ: almost 3/4 of palp tibia length
(POI 73.70). Tegulum 2.67 long, 2.14 wide, twisted, widest medially, subtegu-
lar projection very weakly pronounced (Fig. 5A—D). Embolus length 3.30, width
0.54 basally, tip 0.10 wide (EMI 123.56), base robust, tapering distally, curved
retrolaterally and ending to a weakly tip. There is a prolateral inferior keel (Pl)

ZooKeys 1233: 139-193 (2025), DOI: 10.3897/zookeys.1233.128056 154

Darrell C. Acuna et al.: Taxonomic revalidation of Selenobrachys and Chilocosmia

Figure 5. Chilocosmia dichromata comb. rest. 3’, SMNS Aran-004182 A left palpal organ, prolateral view B retrolateral
view C ventral view D apical view E tip of embolus, prolateral view F, G claws on left tarsus IV of two 3'¢ of C. dichromata
F SMNS Aran-004182 G SMNS Aran-004183, retrolateral view. Abbreviations: PS- prolateral superior keel, PI- prolateral
inferior keel, A- apical keel, Op- embolic opening.

and prolateral superior keel (PS) in the apical third of the embolus (Fig. 5E). The
apical keel (A) is located at the tip of the embolus and is semicircular in shape
(Fig. 5E). Embolic opening (Op) located between PS and PI near the tip. Basal
lobe is not present.

Legs. Leg formula: IV, I, Il, Ill. RF ~ 91.77, LLI (I) 26.54, LLI (IV) 21.15, DLI (1)
23.18, DLI (IV) 18.49, MI (I) 76.25, MI (IV) 132, TI (I) 69.67, TI (IV) 45.45. Leg
lengths (fem, pat, tib, met, tar/cym): Palp 26 (10, 4.2, 8.1, -, 3.7) Leg 1 61.3 (16.5,
8.1, 16, 12.2, 8.5) Leg Il 55.6 (15, 7.1, 13, 12.5, 8) Leg III 49.5 (13, 6, 9, 14.5, 7)
Leg IV 66.8 (17, 6, 15, 19.8, 9). Leg lateral width (fem, pat, tib, met, tar/cym):
Palp (3.24, 2.92, 3.21, -, 2.46) Leg | (4.15, 3.51, 3.62, 2.82, 2.17) Leg Il (4.33,

ZooKeys 1233: 139-193 (2025), DOI: 10.3897/zookeys.1233.128056 155

Darrell C. Acuna et al.: Taxonomic revalidation of Selenobrachys and Chilocosmia

3.36, 3.16, 2.37, 1.94) Leg Ill (4.88, 3.45, 3.04, 2.45, 1.91) Leg IV (3.99, 3.47, 3,
1.96, 1.71) Leg dorsal width (fem, pat, tib, met, tar/cym): Palp (3.19, 2.93, 3.21,
-, 2.88) Leg | (3.38, 3.30, 2.84, 2.18, 2.51) Leg II (3.40, 3.13, 2.59, 2.05, 2.07) Leg
Ill (4.22, 3.17, 2.42, 1.90, 2.13) Leg IV (3,40, 3,06, 2.54, 1.89, 1.46). Cymbium
bipartite. Tarsi lV transversely cracked apically.

Leg setation and spines. Setation (femur to tarsus): TS on all legs pale brown
and short, longer on all metatarsi dorsally, femur of rear legs ventrally and on all
tibia ventrally, dense on tibiae | and Il, ventrally. There are only pale brown TS.
PB is also not present on the palps. There are only pale brown TS. SC, brown-
ish. Other sensory setae: ETB, pair of thin inverted L-shaped cluster of short
dark brown setae, basoretrolateral on Met. | and II, single cluster on Met III.
Cymbium with single cluster dorsally that broadens basally. TB(a), long and
short filiform TB intermix with ETB in two rows, longest dorsally. TB(b), rows
of unordered clavate TB, varying in size, present in all tarsi, and intermix with
tarsal ETB. CHS, tiny, pale brown translucent erect sensilla tapering apically,
present on the palpal and all leg femora to tarsi and intermixes with tarsal and
metatarsal scopulae. Spines (dorsal-dorsoprolateral-dorsoretrolateral-ventral):
Met II (0-0-0-2). Met III (0-1-1-2). Met IV (0-0-1-4).

Coxae and trochantera. Coxae: Length (coxa |, Il, Ill, IV), 8.68, 6.05, 6.76, 6.83.
Width (coxa I, Il, Ill, IV), 4.46, 3.68, 4.17, 4.59. Setation: TS, long brown setae,
dorsally and ventrally; strong and short spiniform setae, prolaterally and ret-
rolaterally on all coxae. Trochantera: Length (troch. palp |, Il, Ill, IV), 3.20, 3.21,
2.92, 3.38, 4.03. Width (troch. Palp |, Ill, Ill, IV), 2.77, 4.15, 3.88, 3.55, 3.72.

Scopulae and claws. Scopulae: cymbium scopulated ventrally. Tar. |, entire,
with very few longer setae. Tar. Il, entire, with very few longer setae. Tar. Ill, en-
tire, with very few longer setae. Tar. IV, in the basal 1/4 divided by three or four
long setae. The tarsus is cracked in the apical 1/4. Met. | covered almost all
ventral surfaces, entire, but with a few very sparse long setae. Met. Il, almost all
ventral surface covered, entire, but with a few very sparse long setae. Met. Ill,
almost all ventral surface covered, entire, but with a few very sparse long setae.
Met. IV, covering 90% of ventral surface, divided by two or three rows of strong
long setae. Claws: longest tarsal IV claw 1.70, no inferior third claw (Fig. 5G)
(but present on some specimens; Fig. 5F), but there are a few large teeth on the
claws whose number can vary from one claw to another.

Color in life. The opisthosoma and legs, except for the coxa and trochanter,
are black in color (Fig. 2A). Coxa and trochanter as well as the carapace and
the chelicerae basal segment are bronze-colored (Fig. 2A, C). The underside of
the cephalothorax is also black. The area around the eye tubercle, as well as
two diverging hairless stripes on the carapace, which frame the head, are dark
brown in color. On each chelicerae basal segment there is also an elongated
dark brown stripe in the middle of the bronze coloration.

Variation. The third inferior claw is present or almost absent on some spec-
imens and varies in length if present, which is also observed in other species
in this study.

Etymology. Greek dyo chrdmata (6Vo ypwyata) means two colors, which
refers to the bicolored orange and black coloration of this species (Schmidt
and von Wirth 1992).

Natural history and distribution. The spiders live in tubes in the primary for-
est whose entrances are well camouflaged and difficult to find (Fig. 6B). In the

ZooKeys 1233: 139-193 (2025), DOI: 10.3897/zookeys.1233.128056 156

Darrell C. Acuna et al.: Taxonomic revalidation of Selenobrachys and Chilocosmia

Ae el bey ae 6 |
. WN ae y
< ANY Vas 2, fs
“a ts 7
>. Ve ig

" ih ry A “aE ee RET
AN ray ee *

Pe « X “a '

aN OIG Yt

! q

J
.
-

<
an

mh
tae: Don

Figure 6. Chilocosmia dichromata comb. rest. natural habitat A C. dichromata comb. rest., female, in situ B burrow en-
trance camouflaged with leaf litter C, D primary forest habitat in Sorong, West New Guinea, Indonesia. Photo credits:
Frank Schneider.

habitat of C. dichromata comb. rest., there is apparently only this species of
tarantula (Fig. 6). All tubes were filled with water to a depth of ~ 10 cm. The
temperature in the tubes was 24-26 °C. The water in the tubes was ~ 2 °C cool-
er. Probably the spiders flee into the water when disturbed. Known only from
Sorong, West New Guinea (now Southwest Papua Province), Indonesia.

Tribe Yamiini Kishida, 1920
Phlogiellini West et al., 2012 (synonymised by Nunn et al. 2016).

Included genera. Orphnaecus Simon, 1892, Phlogiellus Pocock, 1897, Seleno-
brachys Schmidt, 1999, stat. rev.

Genus Orphnaecus Simon, 1892

Type species. Orphnaecus pellitus Simon, 1892, by monotypy.

Included species. O. adamsoni Salamanes et al., 2022, O. kwebaburdeos
(Barrion-Dupo et al., 2015), O. pellitus Simon, 1892.

Diagnosis. Orphnaecus differs from all selenocosmiine genera (including
Chilocosmia stat. rev.), except Phlogiellus and Selenobrachys stat. rev., by

ZooKeys 1233: 139-193 (2025), DOI: 10.3897/zookeys.1233.128056 157

Darrell C. Acuna et al.: Taxonomic revalidation of Selenobrachys and Chilocosmia

having a long prolateral superior keel (PS) (= retrolateral keel (R) in West et
al. 2012) from tip to base with pronounced basal lobe (BL) on the embolus of
males. Orphnaecus differs from Phlogiellus and Selenobrachys stat. rev., (i) in
having a reniform patch, proximally broader, of short bacilliform rods, whereby
the bacillae in the lowest row are larger, club-shaped, and rounded at the tip,
prolaterally (Fig. 20A, D, G). It can also be distinguished from Selenobrachys
stat. rev. in having long and dense dorsal palpal brush of setae on patella in
males (Fig. 15A), in having a palpal tibia in males proximally swollen and distal-
ly tapering (Fig. 15A), and in having long acicular femoral setation on prolateral
femur | (Fig. 21A-D).

Remarks. Raven (1985) and Sivayyapram et al. (2020) distinguished Or-
phnaecus from other selenocosmiine genera in lacking an unpaired third claw
at least on leg IV. However, the absence of a third claw cannot stand alone
as the only diagnostic and defining characteristic of Orphnaecus against its
known species that possess a third claw, while their genital and lyrate mor-
phology is the same. In the Orphnaecus specimens (including syntypes of O.
pellitus) mentioned and examined herein, we were able to find adult specimens
within one species and one locality with a developed third claw, as well as those
with a very reduced 3" claw, and even a few specimens that did not have a third
claw at all (Fig. 5G). Raven (1985) may have examined a type specimen from
the same type series of O. pellitus with no third claw. Most of the syntypes and
newly collected specimens of O. pellitus possess an unpaired third claw on leg
IV (Fig. 15E). Congeners, herein directly examined (types and non-types), also
possess a third claw on leg IV. Simon (1892) distinguished Orphnaecus in hav-
ing tiny and more separated eyes caused by troglomorphic adaptation. Howev-
er, this is only phenotypic plasticity and cannot serve as a defining characteris-
tic of the genus, as it arises solely from prolonged habitation in completely dark
cave environments.

Distribution. Philippine endemic: Luzon Is. (Simon 1892), Polillo Is. (Barrion-Du-
po et al. 2015), Catanduanes Is., Masbate Is. (West et al. 2012), Negros Is. (Liid-
decke et al. 2018), Dinagat Is. (Salamanes et al. 2022), and Mindanao Is. (Fig. 22).
Probably widespread from Luzon PAIC, West Visayas PAIC, to Mindanao PAIC.

Etymology. Orphnaeus, one of the four horses that drew the golden chariot
of Hades, the king of the underworld in Greek mythology, attached with the
suffix -cus (probably to avoid homonymy with a centipede genus, Orphnaeus
Meinert, 1870). The type species O. pellitus is possibly a troglobitic species,
exhibiting troglomorphism and spending its whole life inside the cave (Simon
1892). Gender is masculine.

Genus Selenobrachys Schmidt, 1999, stat. rev.

Type species. Selenobrachys philippinus Schmidt, 1999, comb. rest., by original
designation and monotypy.

Included species. (2 species) S. philippinus Schmidt, 1999, comb. rest.,
S. ustromsupasius sp. nov.

Diagnosis. Selenobrachys stat. rev. differs from all other selenocosmiine
genera (including Chilocosmia stat. rev.), except sister genera Orphnaecus and
Phlogiellus, in having a long prolateral superior keel (PS) (= retrolateral keel

ZooKeys 1233: 139-193 (2025), DOI: 10.3897/zookeys.1233.128056 158

Darrell C. Acuna et al.: Taxonomic revalidation of Selenobrachys and Chilocosmia

in West et al. 2012) from base to tip with a pronounced basal lobe (BL) on
the embolus of males (Figs 10A-F, 14A-E). Selenobrachys stat. rev. differs
from Orphnaecus, and Phlogiellus (i) in having an ovoid proximally truncated
and distally mildly tapering lyrate patch on the prolateral maxilla, with rows of
strong paddle-shaped bacillae possessing thick and strong shafts (Figs 7F, G,
1E, F, 17E, F, 20E) (reniform lyrate morphology for Orphnaecus; see above and
Fig. 20G; rudimentary patch of needleform rods, if present, for Phlogiellus; see
Nunn et al. 2016) and where the largest ones in the lowest row have a more
pointed tip in prolateral view (Fig. 20E); (ii) in having greater number of chelicer-
al strikers (< 150; excluding tertiary rows) (Figs 8C, 13C, D, 17C, D); (iii) in having
a long and cylindrical palpal tibia in males (Figs 9A—D, 15B, C) (proximally swol-
len and distally tapering in Phlogiellus and Orphnaecus; see Fig. 15A and Nunn
et al. 2016); and (iv) in having a broad and short, not reduced ends, almost
symmetrical, tombstone-shaped spermathecal lobe in females (Fig. 18A, B). It
further differs from Orphnaecus in lacking long and dense dorsal scopulate pal-
pal brush in adult males (Figs 9D, 15B, C) and in having short sword-like femoral
setation on prolateral femur | (Fig. 21E-H). It also differs from Phlogiellus in
having a greater number of labial cuspules (~ 331-760) and a wider fovea than
the ocular tubercle (Nunn et al. 2016; Sivayyapram et al. 2020).

Distribution. Philippine endemic: Negros Is. (Schmidt 1999; West et al. 2012)
and Romblon Is. (this study; Fig. 22). Probably restricted to West Visayas PAIC
and Romblon PAIC.

Etymology. A combination of two generic names, Selenocosmia and Chilo-
brachys (Seleno- + -brachys) (Schmidt 1999). Gender is masculine.

Selenobrachys philippinus Schmidt, 1999, comb. rest.
Figs 7-10, 18B, 20B, E, 21G, H

Type material examined. PHILIPPINES: Negros Island— Negros Occidental Prov.
* holotype 2, SMF 39202-84; Mambucal (now Mambucal Resort and Wildlife
Sanctuary); SMF.

Other material examined. PHILIPPINES: Negros Island— Negros Occidental
Prov.* 4, PASI ara0006, 9 29, 8 j, UST-ARC 0112-UST-ARC 0127 (field#NO-
M1A-01-NOM1A-16); Mambucal Resort and Wildlife Sanctuary; 365 m a.s.l.,
26 Jun 2023, burrows under metamorphic rock boulders and crevices, LA Gue-
varra, DC Acuna, CN Noriega, R Enguito, LUS Villaflor leg.; PASI/ UST- ARC = 9,
SMNS Aran-004192, 5 33, SMNS Aran-004187-—Aran-004191; Mount Canlaon;
2010, JM Verdez leg.; SMNS.

Diagnosis. Selenobrachys philippinus comb. rest. can be distinguished from
its congener, S. ustromsupasius sp. nov., (i) in having longer leg IV than leg |
(RF~ 89-98): (ii) in having broader posterior sigilla on the sternum (Fig. 7E); (iii)
in having a palpal organ in males with lower palpal organ index (POI < 42), with
embolus with narrower basal lobe (BL) (Fig. 10B), with thinner prolateral supe-
rior keel (PS) (Fig. 10A, B) but broader at the tip (Fig. 10E, F), and with less pro-
nounced subtegular ridge (StR) (Fig. 10A, B); and (iv) in having lesser number
of maxillary (< 305) and labial (< 471) cuspules. It also differs in color, having
an orange to orangey brown general body coloration (Fig. 7A; Schmidt 1999).

Description. Male (PASI ara0006). Body length 42.07 (n = 6: 41.43-43.98).

ZooKeys 1233: 139-193 (2025), DOI: 10.3897/zookeys.1233.128056 159

Darrell C. Acuna et al.: Taxonomic revalidation of Selenobrachys and Chilocosmia

: 1 bh % " XS 4 eed ee?
= ’ =,” . 7 eh - x ey We, Af Z
' ee peo ee a as en
ie * e
z , ty iu
, ¥ 4
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OS. | Ee
t SS SAS

1mm
LEE

Figure 7. Selenobrachys philippinus comb. rest. 3’, PASI ara0006 A dorsal habitus B prosoma dorsal view C ventral view
D ocular tubercle, dorsal view E posterior sternal sigilla F left maxilla, prolateral view G lyra on left prolateral maxilla.

Carapace (Fig. 7B). 17.51 long, 14.94 wide, anterior width 10.24, cephalic
height 3.8, cephalic region 11.6 long, thoracic region 5.91 long. Cl 85.32, CLI
66.25, CHI 21.70. Fovea width 2.27, curve length 2.43, procurved. Carapace has
four pairs of weak furrows, lateral profile low and flat, and integument orang-
ey brown, darker anteriorly. Setation: TS(a), rows of very short pale yellowish
brown setae covering entire carapace, directed towards fovea and anteriorly to
OT. Posterior surface of OT with pale brown short TS(a). TS(b), long pale yel-
lowish brown setae at carapace margin, anterior margin light brown. SC(a), very
short light brown flat scales sparsely covering OT. SC(b), pale yellowish brown
acicular scales covering carapace, dense anteriorly, very sparse medially.

ZooKeys 1233: 139-193 (2025), DOI: 10.3897/zookeys.1233.128056 160

Darrell C. Acuna et al.: Taxonomic revalidation of Selenobrachys and Chilocosmia

Figure 8. Selenobrachys philippinus comb. rest. 3, PASI ara0006 A left chelicera, retrolateral view B prolateral view
C cheliceral strikers, retrolateral view.

Eyes (Fig. 7D). Ocular tubercle 2.09 long, 2.73 wide, integument dark, paler
anteriorly. AME round, rest of the eyes ovoid. Anterior row of eyes slightly pro-
curved, posterior row of eyes recurved. Eyes: AME 0.61, ALE 0.76, PME 0.51,
PLE 0.51. Interocular distances: AME- AME 0.26, ALE-ALE 1.55, PME-PME 1.25,
PLE-PLE 1.98, AME-ALE 0.18, AME-PME 0.13, AME-PLE 0.64, ALE-PLE 0.31,
ALE-PME 0.35, PME-PLE 0.14. El (AME) 3.48, El (ALE) 4.34.

Chelicerae (Fig. 8A—C). length 8.92, dorsal width 3.68, lateral width 6.28,
fang curve length 7.48. Teeth 11, mesoventral denticles sparse ~ 35. Seta-
tion: TS, long pale brown setae on dorsal and upper 1/2 retrolateral surface,
longer anteriorly. Lower 1/2 of retrolateral surface posteriorly with a patch of
pallid filiform setae, anteriorly needleform. Mesoretrolateral surface with rows
of very sparse setae basally spiniform, anteriorly needleform. Mesoprolateral
surface with intercheliceral setae in arcuate strip of rows of pallid needleform
setae originating basally. Lower 1/2, prolaterally, sparsely covered with brown
needleform setae, filiform above. SC, flat, translucent, brownish white scales,

ZooKeys 1233: 139-193 (2025), DOI: 10.3897/zookeys.1233.128056 161

Darrell C. Acuna et al.: Taxonomic revalidation of Selenobrachys and Chilocosmia

Va
aw
7 ia
i
é AL
F

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4

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a4
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=

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+ i
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ea
oy 4

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7
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—
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ade

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Z ZG Z

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o
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Figure 9. Selenobrachys philippinus comb. rest. 4 PASI ara0006, left pedipalp A tibia, cymbium, and palpal organ, prolat-
eral view B ventral view C retrolateral view D left patella to tibia, retrolateral view.

covering dorsal and upper retrolateral surface. Cheliceral strikers (Fig. 8C): Pri-
mary rows, ~ 16, 0.65-0.91 dark, long spiniform with filiform ends. Secondary
rows, ~ 136, 0.21-0.55, dark long and short spiniform. Tertiary rows, ~ 114,

0.16-0.23, pallid very short needleform setae. Pseudostrikers long and pallid,
and present ventrally.

ZooKeys 1233: 139-193 (2025), DOI: 10.3897/zookeys.1233.128056 162

Darrell C. Acuna et al.: Taxonomic revalidation of Selenobrachys and Chilocosmia

Maxillae (Fig. 7F, G). Prolateral maxilla 7.47 long, 4.53 wide laterally, 3.75
wide ventrally. Maxilla prolaterally planoconvex, anterior lobe well pronounced,
integument orangey brown, darker dorsally, basoventral cuspules ~ 305. Max-
illary lyra (Fig. 7G): lyrate patch dense, in ovoid shape, truncated proximally,
mildly tapering distally, 3.90 long, 2.10 high, total rods ~ 539, on 10-11 rows,
surrounded by very fine setae, denser above and distally. Short bacilliform rods
~ 496, 0.24-0.39, needleform. Longer rods ~ 43, 0.49-0.85, paddle-shaped
with pointed ends, which ~ 12 have well-defined paddle blades, and thick
strong shafts slightly curved outward, located at the lowest rows. Setation: TS,
pale brown spiniform setae, longer ventrally, stronger at distodorsal margin.
Lyrate patch surrounded by fine setae. Above maxillary suture, two rows of ~
15 stiff dark spiniform TS. Retrolateral surface is smooth, with rows of short
semi-transparent bristles at lower margin. SC, flat whitish yellow-brown scales
covering dorsal surface.

Labium and sternum (Fig. 7C, E). Labium: 2.32 long, 3.15 wide. Integument
orangey brown, darker posteriorly, anterior 1/3 with cuspules ~ 471. Setation:
TS(a), long, pale brown with pale filiform ends, covering labium anteriorly and
laterally except on cuspule cluster, longer and greater at anterior edge, all point-
ing anteriorly. TS(b), dark, short needleform below cuspule cluster. Sternum:
8.20 long, 6.93 wide, integument yellowish brown. Posterior sternal corner
acuminate and lateral corners weakly acuminate. Setation: TS(a), long pale
brown spiniform setae, pale apically, on entire sternum but sparse medially.
TS(b), fine, pallid, and short spiniform, at sternal margin. SC, white flat scale
mat covering entire sternum. Labiosternal sigilla 1.49 long, 0.38 wide, 0.75
apart. Sternal sigilla 3 pairs, anterior sigilla 0.34 long, 0.22 wide, 4.53 apart,
and 0.26 away from sternal margin adjacent to coxa |, median sigilla 0.81 long,
0. 34 wide, 3.93 apart, and 0.50 away from sternal margin adjacent to coxa Il,
posterior sigilla broad (Fig. 7E), 1.40 long, 0.58 wide, 1.60 apart, and 1.17 away
from sternal margin adjacent to coxa Ill.

Abdomen and spinnerets. Abdomen: 18.69 long, 7.65 wide. ovular elongated,
integument pale citron brown. Setation: TS(a), long, citron brown with darker
bases, needleform, on entire abdomen, shorter ventrally, and pallid on book
lungs. TS(b), rows of pallid and short paddle-like on book lungs and sparse
on epigynal plate. SC, dense, overlapping flat, translucent, pale brown scales
lightened by pale citron integument producing an orangey brown mat covering
entire abdomen. Spinnerets: PMS 2.24 long, 0.74 wide, PLS, anterior 2.56 long,
1.52 wide, median 2.84 long, 1.12 wide, posterior 3.76 long, 1.00 wide. Setation:
TS (a), long, citron brown with darker bases, needle form, on dorsal PMS and
PLS. TS(b), dark and short, pale brown paddle-like TS, intermixed with spigots,
on PMS and PLS ventrally. SC, flat brownish white scales covering PLS dorsally.

Genitalia (Figs 9A-C, 10A-E). Palpal Organ: approximately 2/5 of palp tib-
ia length (POI 41.45). Tegulum 1.92 long, 1.81 wide, globular, widest medially,
subtegular ridge (StR) weakly pronounced (Fig. 10A, B). Embolus length 2.42,
width 1.20 basally and 0.37 medially, tip 0.16 wide, Embolus length 1.26 times
longer than tegulum length (EMI 126.04), base robust, tapering distally, curved
retrolaterally and ending to a broad tip. Embolus has a long and stout prolateral
superior keel (PS) (Fig. 10A, B) but broad at tip (Fig. 10E, F); has prolateral in-
ferior keel (PI) short, emerged from the tip to rear at apical 1/5, below PS and

ZooKeys 1233: 139-193 (2025), DOI: 10.3897/zookeys.1233.128056 163

Darrell C. Acuna et al.: Taxonomic revalidation of Selenobrachys and Chilocosmia

embolic opening (Op) (Fig. 10E, F); apical keel (A) very short, emerged almost at
the tip; embolic opening (Op) located between PS and PI near the tip (Fig. 10E,
F). Basal lobe pronounced but not broad, projected proximally (Fig. 10A, B).

Legs. Leg formula: IV, |, Il, Ill. RF~ 91.94, LLI (I) 20.93, LLI (IV) 16.39, DLI (1)
19.97, DLI (IV) 16.23, MI (I) 80.99, MI (IV) 124.10, TI (I) 59.78, TI (IV) 44.41. Leg
lengths (fem, pat, tib, met, tar/cym): Palp 31.96 (11.08, 6.46, 10.47, -, 3.95) Leg
| 66.41(18.11, 9.92, 16.73, 13.55, 8. 1) Leg Il 58.56 (15.7, 8.16, 14.59, 12.86,
7.25) Leg Ill 51.81(13.04, 6.59, 11.54, 13.63, 7.01) Leg IV 72.23 (17.64, 7.68,
16.8, 20.85, 9.26). Leg lateral width (fem, pat, tib, met, tar/cym): Palp (2.64,
2.34, 2.56, -, 2.35) Leg | (4.05, 3.61, 3.06, 1.9, 1.28) Leg II (3.49, 3.35, 2.58, 1.45,
1.37) Leg Ill (3.61, 2.8, 2.39, 1.75, 1.2) Leg IV (3.77, 3.08, 2.34, 1.55, 1.1) Leg
dorsal width (fem, pat, tib, met, tar/cym): Palp (2.63, 2.27, 2-,, 2.38) Leg | (3.75,
3.08, 2.96, 1.84, 1.63) Leg II (3.31, 2.69, 2.54, 1.65, 1.35) Leg Il (3.43, 2.61, 2.44,
1.72, 1.31) Leg IV (3.25, 2.76, 2.48, 1.96, 1.27). Cymbium bipartite. Tarsi I-IV
transversely cracked, shows transverse weakening or pallid region, tar. | and
tar. II more anteriorly, tar. III and tar. IV medially.

Leg setation and spines. Setation (femur to tarsus): TS(a), brown spiniform
setae on all legs, longer TS pale brown, longer on all femora, ventrally and on
palp patella and tibia, thicker on leg Ill and IV, dense citron brown on tibiae
| and Il, ventrally. TS(b), short and pallid paddle-like setae, dense on ventral
femur I, sparse on ventral palpal femur, ventral patella |, and ventral femur II.
FS, prolateral femur | with dense field (less dense than females) of elongated
sword-like TS. PB, thin layer of short, flat, pale brown, scales, present on dorsal
palpal patella and dorsal palpal tibia but very sparse (Fig. 9D). SC, flat whitish
scales, darkened by reddish brown integument, covering all legs. Other sensory
setae: ETB, pair of thin inverted L-shaped clusters of short pale brown setae,
starting from basolateral to dorsal Met. | and Il, single cluster on Met III and IV.
Cymbium with a single cluster dorsally that broadens basally. TB(a), long and
short filiform TB intermix with ETB in two rows, longest dorsally. TB(b), rows
of unordered clavate TB, varying in size, present in all tarsi, and intermix with
tarsal ETB. CHS, tiny, pale brown translucent erect sensilla tapering apically,
present on the palpal and all leg femora to tarsi and intermixes with tarsal and
metatarsal scopulae. Spines (dorsal-dorsoprolateral-dorsoretrolateral-ventral):
Met | (0-0-0-1), Met II (0-0-0-3). Met III (0-1-1-4). Met IV (0-1-1-3).

Coxae and trochantera. Coxae: Length (coxa |, Il, Ill, IV), 8.16, 7.88, 6.78, 7.31.
Width (coxa |, Il, Ill, IV), 4.49, 3.97, 4.27, 4.21. Setation: TS(a), long pale brown
setae, covering dorsal and ventral surfaces; TS(b), strong and short spiniform
setae, prolaterally on all coxae; TS(c), patches of fine setal fringe present laterally
on coxae, intermixed with TS; TS(d), Coxae I-IV have rows of short semi-trans-
lucent bristles, prolaterally, denser on coxae | and Il. SC(a), flat, grayish brown
scales, covering the ventral to retrolateral 1/2; SC(b), white, cottony, and acicular,
covering the dorsal of all coxae. Trochantera: Length (troch. palp |, Il, Ill, IV), 2.78,
3.95, 3.02, 1.84, 2.77. Width (troch. palp |, Il, Ill, IV), 2.59, 3.99, 3.52, 3.44, 3.62.

Scopulae and claws. Scopulae: cymbium scopulated ventrally. Tar. |, entire,
but intermixed with one or two longitudinal rows of very sparse short spini-
form setae. Tar. Il, entire, but intermixed with one or two longitudinal rows of
very sparse short spiniform setae. Tar. Ill, entire, but intermixed with two or
three longitudinal rows of short spiniform setae. Tar. IV, divided by four rows

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1mm

D PS

Figure 10. Selenobrachys philippinus comb. rest. @, PASI ara0006, left palpal organ A prolateral view B retrolateral view
C ventral view D apical view E tip of embolus, dorsal view F prolateral view. Abbreviations: PS- prolateral superior keel,
PI- prolateral inferior keel, A- apical keel, BL- basal lobe, Op- embolic opening, StR- subtegular ridge.

of strong and long spiniform setae. Met. | ventral surface almost completely
scopulated, entire, but with one or two longitudinal rows of very sparse long
setae. Met. Il, almost all ventral surface covered, entire, but intermixed with one
or two longitudinal rows of very sparse long setae. Met. Ill, covering 4/5 distal-
ly, entire, but intermixed with one or two longitudinal rows of very sparse long
setae. Met. IV, covering 3/4 distally, divided by two or three rows of strong long
setae. Claws: pair of claws present on all leg tarsi, with one to three teeth on
each claw. Tarsal IV claw, 2.27, with unpaired inferior third claw. 0.20.

Color in life. Monochromatic. The reddish brown integument is lightened
by whitish scales creating a uniform orange to orangey brown body coloration
(Fig. 7A).

Variation. The third inferior claw is absent or almost absent on some spec-
imens and varies in length if present, which is also observed in other species
in this study.

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Natural history and distribution. Spiders are found roaming outside near
their burrows at night. Burrows, not self-dug, are found near streams under
metamorphic rock boulders and crevices on mountain slopes. Known only
from Mambucal Resort and Wildlife Sanctuary (at the foot of Mt. Canlaon) and
Sipalay City (West et al. 2012) in Negros Occidental, Negros Island, Philippines.
Reports from the internet in the islands of Panay, Guimaras, and Cebu are unver-
ified and may represent a separate island endemic species of Selenobrachys.

Etymology. The specific epithet is a masculine adjective derived from the
country locality, the Philippines (Schmidt 1999).

Selenobrachys ustromsupasius sp. nov.
https://zoobank.org/96F1B924-D25E-48A5-AEB9-4548078E2E15
Figs 11-14, 15B-D, 16, 17, 18A, 21E, F

Type material examined. PHILIPPINES: Romblon Island— Romblon Prov. «
holotype 3, UST-ARC 0002 (field#R01-02), paratypes 4 3.4, 8 29,1 j, USTARC
0001, 0003-0014 (field#RO1-01, RO1-03—R01-14); Municipality of Romblon,
Brgy. Tambac; 12°32.0106'N, 122°17.6595'E, 200 m a.s.I., Sep 2022, AB Mayor,
L De Capiz, RM De Capiz leg. * paratypes 2 3, 4 29, 10 j, UST-ARC 0015-
0030 (field#RO2-01—R02-16); Municipality of Romblon, Brgy. Guimpingan;
12°35.2478'N, 122°17.2416'E, 80 maz.s.l., 24 Feb 2023, DC Acuna, LA Guevarra
Jr., CN Noriega, MJ Fadri, GA Florendo Jr., CJ Cabisuelas leg.; UST-ARC.

Diagnosis. Selenobrachys ustromsupasius sp. nov. can be distinguished
from its congener, S. philippinus comb. rest, (i) in having longer leg | than leg
IV, with RF ~ 104-111; (ii) in having narrower posterior sigilla (Figs 12B, 16C);
(iii) in having a palpal organ in males with greater palpal organ index (POI > 48),
with embolus with broader basal lobe (Fig. 14B), with thicker prolateral superior
keel (PS) (Fig. 14A, B) but stouter at tip (Fig. 14E), and with less pronounced
subtegular ridge (StR) (Fig. 14A, B); and (iv) in having greater number of maxil-
lary (> 365) and labial (> 608) cuspules. It also differs in color, having a brown
to dark brown general body coloration (Figs 11A, B, 19G, H).

Description. Holotype <, UST-ARC 0002 (field#RO1-02). Body length 43.18.
(n = 7: 43.00-45.19) Figs 11A, 12-14, 15B-D.

Carapace (Fig. 12A). Length, 17.41, median width 15.34, Cl 88.11, CLI 65.88,
CHI 22.75. Integument dark reddish brown. Caput profile low and flat, cephalic
region slightly higher. Fovea procurved (Fig. 12D), width 1.72, curve length 1.89.
Distance of fovea to posterior carapace margin 4.55; distance to OT 9.68. Seta-
tion: TS(a) long, thin, pale brown setae at carapace margin, pointing anteriorly.
TS(b) long, strong, dark brown setae, pale brown apically, intermixed with TS(a)
and SC, at clypeus, and few at the top of OT between AMEs. TS(c) rows of short
pale or dark brown setae, pale brown apically, that run along radial grooves
pointing to fovea. SC(a), very short, thick, flat, pale brown scales covering ante-
rior 1/2 surface of OT. SC(b), mat of long, dense, whitish acicular scales, cover-
ing lateral sides and front of OT, pointing towards OT and carapace, sparse to
none on middle surface, denser on coastal surface, mostly pointing anteriorly.

Eyes (Fig. 12C). OT length 1.94, width 2.86. Clypeus 0.5, integument dark.
Eyes anterior row slightly procurved, posterior row recurved. Eyes: AME 0.61
(round), ALE 0.78 (ovoid), PME 0.44 (ovoid), PLE 0.47 (ovoid). Interocular

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15mm

Figure 11. Selenobrachys ustromsupasius sp. nov. dorsal habitus A holotype <4’, UST-ARC 0002 B paratype 2, UST-ARC 0005.

distances: AME-AME 0.31, PLE-PLE 1.97, ALE-ALE 1.59, PME-PME 1.24, ALE-
PLE 0.21, AME-ALE 0.20, AME-PME 0.12, ALE-PME 0.32, PME-PLE 0.09, AME-
PLE 0.55. EI(AME)3.50, EI(ALE) 4.48.

Chelicerae (Fig. 13A—D). Dorsal length 8.51, dorsal width 3.79, lateral width
6.49. Fang curve length 6.68. Prolateral surface: more than upper 1/2 integu-
ment dark, lower surface reddish brown, with long brown fine setae, lowest por-
tion above teeth darker and longer. Intercheliceral pegs absent but with rows
of stiff setae. Retrolateral surface: integument upper 2/3 dark, lower surface
reddish brown to amber, flat whitish scales (SCa), fine, white, cottony acicular
scales (SCb), and long strong setae (TS) covering dorsal and upper retrolateral
surfaces, greater anteriorly, patch of fine and long, mostly slightly curved se-
tae at posterior area of lower retrolateral surface, patch of very fine setae with
curved ends at anterior area of retrolateral surface, proximomedial setae nee-
dleform, very sparse. Long, pale reddish brown brush of setae ventrally. Teeth
11, mesoventral denticles sparse, ~ 41, on three or four rows. Lyrate region (Fig.
13C, D): 237-248 total strikers on six to seven horizontal rows, unordered, the
strongest and longest strikers on lower rows. Primary rows ~ 11 (0.80-0.83
long) long dark brown with long curved filiform ends pointing distally. Second-
ary rows ~ 142 (0.17—-0.66), dark spiniform with short curved filiform ends
pointing inward. Tertiary rows ~ 90 (0.09-0.18), short, pallid, and needleform,
located above secondary rows. Long, pallid pseudostrikers present ventrally.

Maxillae (Fig. 13E, F). Prolaterally planoconvex, anterior lobe well pronounced,
cuspules on inner basoventral surface ~ 365. Stridulatory organ (Fig. 13F): ~
465 total bacilliform rods, in nine or ten rows, form long and dense ovoid patch,
proximally truncated and distally mildly tapering (3.31 long, 1.70 high). Short
bacilliform rods ~ 424, 0.22-0.53, needleform. Longer rods ~ 41, 0.55-0.77,

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a
ue
ota gy" G

Figure 12. Selenobrachys ustromsupasius sp. nov., holotype <, UST-ARC 0002 A prosoma, dorsal view B ventral view
C ocular tubercle, dorsal view D fovea, dorsal view E labium, ventral view F spinnerets, ventral view.

paddle-shaped with thick and strong shafts and pointed ends, ~ 10 of which
have well-defined paddle blades, located at lowest rows. Paddles flattened per-
pendicularly to maxillary surface. Setation: TS, brown setae, with upper part
paler, present dorsally and ventrally, longest ventrally. Proximodorsal with erect

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Figure 13. Selenobrachys ustromsupasius sp. nov., holotype <, UST-ARC 0002, left chelicera and maxilla A left chelicera
retrolateral view B prolateral view C cheliceral strikers retrolateral view D ventrolateral view E left maxilla, prolateral view
F maxillary lyra on left prolateral maxilla.

fine pallid setae. Lyrate patch surrounded by fine setae. Above maxillary suture,
two rows of ~ 20 stiff dark TS. SC, flat whitish scales covering dorsal surface.
Retrolateral surface smooth, with rows of short semi-transparent bristles at
lower margin.

Labium and sternum (Fig. 12B, E). Labium (Fig. 12E): length 2.30, width 3.30,
integument reddish brown, paler anteriorly. Labial cuspules ~ 608, dark, at api-
cal 1/3. Setation: TS(a), long brown with filiform ends, covering labium anteri-
orly and laterally except on cuspule cluster, longer and denser at anterior edge,
all pointing anteriorly. TS(b), dark, spiniform, on posterior surface. Sternum
(Fig. 12B): sternum length 7.68, width 6.80, integument reddish brown, slightly

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darker at margin. Posterior sternal corner acuminate, lateral corners weakly
acuminate. Labiosternal sigilla ovoid, 1.12 long and 0.40 wide, 0.72 apart. Ster-
nal sigilla 3 pairs, ovoid. Anterior pair 0.28 long, 0.16 wide, 4.72 apart, and 0.16
away from the sternal margin adjacent to coxa |. Median pair 0.88 long, 0.24
wide, 3.88 apart, and 0.20 away from the sternal margin adjacent to coxa Il.
Posterior pair 1.44 long, 0.44 wide, 1.48 apart, and 1.16 away from the sternal
margin adjacent to coxa Ill. Setation: TS(a), long and short dark spiniform setae
on entire sternum, sparse on middle surface. TS(b), dark and pallid, short spin-
iform with filiform ends, at sternal margin. SC, flat grayish brown scales mat
covering entire sternum.

Abdomen and spinnerets. Abdomen 14.70 long, 8.25 wide, ovular elongated,
integument pale brown. Pedicel 1.8, pale brown, dorsally striated. Setation: TS,
long brown setae, paler apically, covering entire abdomen, except book lungs
and epigynal plate, denser laterally. Book lungs covered with short, pale brown
spiniform setae. PTS, dark and short, covering book lungs and epigynal plate,
intermixed with semi-transparent thin and short sensilla. SC, grayish brown,
covering entire, sparse on book lungs and epigynal plate. All setae pointing
distad. Spinnerets (Fig. 12F): PMS 2.02 long, 0.60 wide. PLS 9.52 long (ant.
3.12, mid. 2.84, pos. 3.56), and 2.88 wide (ant. 1.32, med. 0.92, post. 0.64). Se-
tation: TS, long brown setae, paler apically, covering dorsally and laterally. PTS,
dark and short, covering ventrally, intermixed with spigots. SC, grayish brown,
sparse, present dorsally.

Genitalia. Palpal organ (Fig. 14A-E): almost 1/2 of palp tibia length (POI
48.35). Tegulum length 1.91, width 1.78. Embolus length 2.79, basal width 1.11,
middle length 0.33, tip 0.21 wide. Tegulum globular, widest medially, subtegular
ridge (StR) pronounced (Fig. 14A, B). Embolus 146 times longer than tegulum
(EMI 146.07), robust at the base (Fig. 14A, B), tapering distally, Embolus has long
and thick prolateral superior keel (PS) from base to tip (Fig. 14A, B) but stout at
the tip (Fig. 14E); prolateral inferior keel (Pl) short, emerged from the tip to rear
at apical 1/5, located below PS and embolic opening (Op) (Fig. 14E); apical keel
(A) very short, emerged almost at the tip (Fig. 14E); embolic opening (Op) locat-
ed between PS and PI near the tip (Fig. 14E). Basal lobe pronounced and broad,
projected proximally (Fig. 14B). Palpal tibia long and cylindrical (Fig. 15B, C).

Legs. Leg formula: |, lV, Il, Ill. RF ~ 110.99, LLI (I) 20.90, LLI (IV) 18.83, DLI
(1) 20.85, DLI (IV) 18.67, TI(IV) 44.03, MI(IV) 108.80. Leg lengths total (fem.,
pat., tib., met., tar. /cym.): Palp 31.51 (11.24, 6.82, 9.72, n/a, 3.73), Leg | 64.31
(17.72, 9.63, 16.01, 13.19, 7.76), Leg Il 53.39 (14.59, 7.88, 12.36, 11.65, 6.91),
Leg Ill 45.83 (12.24, 6.31, 9.63, 11.51, 6.14), Leg IV 57.94 (15.47, 6.89, 13.86,
15.08, 6.64). Leg lateral widths (fem., pat., tib., met., tar. /cym.): Palp (2.53, 2.38,
2.24, n/a, 2.61), Leg | (4.23, 3.21, 2.85, 1.76, 1.39), Leg II (3.85, 3.16, 2.40, 1.58,
1.32), Leg Ill (4.19, 2.94, 2.47, 1.56, 1.25), Leg IV (3.52, 2.89, 2.17, 1.43, 0.91).
Leg dorsal widths (fem., pat., tib., met., tar. /cym.): Palp (2.74, 2.50, 2.07, n/a,
2.50), Leg | (3.56, 3.36, 2.99, 1.93, 1.57), Leg Il (3.38, 3.04, 2.45, 1.78, 1.40), Leg
Ill (3.66, 2.75, 2.54, 1.73, 1.29), Leg IV (3.20, 2.52, 2.33, 1.65, 1.12). Cymbium
bipartite. Tarsi I-IV transversely cracked, shows transverse weakening or mild
pallid region, tar. | and tar. Il more anteriorly, tar. Ill and tar. IV medially.

Leg setation (femora to tarsi) and spines. Setation: TS, long, dark brown se-
tae with contrasting pale brown filiform ends, present on palp and to all legs,
but sparse to all tarsi, prolateral femora | and Il, and retrolateral femur IV, all

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1mm

“s

Figure 14. Selenobrachys ustromsupasius sp. nov., holotype <4, UST-ARC 0002, left palpal organ A prolateral view B ret-
rolateral view C apical view D tip of embolus, retrolateral E prolateral view. Abbreviations: PS- prolateral superior keel,
PI- prolateral inferior keel, A- apical keel, BL- basal lobe, Op- embolic opening, StR- subtegular ridge.

pointing distad, with some erect rows on leg1 dorsally. PTS, short and pallid,
dense on ventral femur |, sparse on ventral palpal femur, prolateral to ventral
patella |, and ventral femur II. FS, prolateral femur | with dense field (less dense
than females) of elongated sword-like setae. SC, reflective grayish brown, cov-
ering all legs, longer and fine on all femora, pale brown on all patellae. PB, gray-
ish, present on dorsal palpal patella but not long and dense, also present on
dorsal palpal tibia but very sparse (Fig. 15B, C). ETB, short brown setae in pair
of thin inverted L-shaped clusters, starting from basolateral to dorsal Met | to Il,
single cluster on Met III to IV. Cymbium with single cluster dorsally that broad-
ens basally. TB, long and short filiform intermix with ETB in two rows, longest
dorsally. Rows of clavate TB, unordered, varying in size, present in all tarsi and

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cymbium, and intermix with tarsal ETB. CHS tiny, pale brown translucent erect
sensilla tapering apically, present on the palpal and all leg femora to tarsi and
intermix with tarsal and metatarsal scopulae. Spines: (dorsal-dorsoprolater-
al-dorsoretrolateral-ventral): Met | (0-0-0-1), Met II (0-0-0-3). Met III (0-1-1-3).
Met IV (0-1-1-5).

Coxae and trochantera. Coxae: Palp coxa (see Maxillae). Lengths (coxa |, Il,
Il, IV) 7.52, 5.80, 5.20, and 5.60. Widths (coxa |, Il, III, IV) 4.00, 3.48, 3.44, 3.88.
Setation: TS, long brown setae, dorsally and ventrally; strong and short spini-
form setae, prolaterally on all coxae. SC(a), flat scales covering the ventral to
retrolateral 1/2. SC(b), white, cottony, acicular scales covering the dorsal of
all coxae. Patches of fine setal fringe present laterally on coxae, intermixed
with short spiniform setae. Coxae I-IV have rows of short semi-translucent
bristles, prolaterally, denser on coxae | and II. Trochantera: Lengths (troch.
palp, I, Il, Ill, IV) 2.12, 3.52, 3.32, 3.08, 2.72. Widths (coxa palp, I, Il, Ill, IV) 2.48,
3:40) :2:96,-3:02;.3:28.

Scopulae and claws. Scopulae: cymbium scopulated ventrally. Tar. |, entire,
but intermixed with longitudinal one or two rows of very sparse short spiniform
setae. Tar. Il, entire, but intermixed with longitudinal one or two rows of very
sparse short spiniform setae. Tar. Ill, entire, but intermixed with longitudinal
two or three rows of strong, long setae. Tar. IV, divided by four rows of strong,
long setae. All tarsi with a bald spot ventrobasally. Met. |, almost all ventral
surface covered, entire, but intermixed with longitudinal one or two rows of very
sparse long setae. Met. Il, most ventral surface covered, entire, but intermixed
with longitudinal one or two rows of very sparse long setae. Met. Ill, covering
4/5 distally, entire, but intermixed with longitudinal one or two rows of very
sparse long setae. Met. IV, covering 3/4 distally, divided by two or three rows
of strong long setae. Claws: pair of claws present on all leg tarsi with one to
three teeth on each claw. Unpaired inferior third claw 0.13, very short, present
on tarsus IV (Fig. 15D).

Color in life. Slightly dichromatic, dark on carapace and all femora, and cov-
ered with pale brown setae on leg patellae, tibiae, metatarsi, and tarsi, including
trochantera, sternum, abdomen, and spinnerets (Fig. 11A). Almost uniformly
dark brown with a mild purplish blue sheen reflected by scales just after ecdy-
sis, which fades in a few days.

Paratype 2, UST-ARC 0005 (field#RO1-05). Body length 53.85 (n = 12: 42.56-
55.13) Figs 11B, 16, 17, 18A, 21E, F

Carapace (Fig. 16A). Length 18.82, median width 15.61, anterior width 9.47,
Cl 82.94, LI 66.84, CHI 27.42. Integument reddish brown. Caput profile low
and flat, and cephalic region slightly higher. Fovea procurved (Fig. 16E), width
2.13, with curve length 2.22. Distance of fovea to posterior carapace margin
4.74, distance to ocular tubercle 10.67. Setation: TS(a), long, thin, pale brown
setae at the margin of carapace, directed anteriorly; TS(b), long, strong, dark
brown setae and pale brown apically, intermixed with TS(a) and SC(b), at cly-
peus, and one or two at top of OT between AMEs; TS(c), rows of short pale
brown or dark brown setae, pale brown apically, that runs to radial grooves
pointing to fovea; SC(a), short, flat, pale brown scales covering anterior 1/2
surface of OT; SC(b), mat of satiny white acicular scales covering carapace
but sparse to absent medially and greater on margin, most directed anteriorly
(denser and longer on male).

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1mm

Figure 15. B—D Selenobrachys ustromsupasius sp. nov., holotype <, UST-ARC 0002, pedipalp and tarsus B Left palpal
patella and tibia, prolateral view C dorsal view D claws on left tarsus IV, retrolateral view A, E Orphnaecus pellitus, syntype
3, MNHN AR4678 A left pedipalp, prolateral view E claws on left tarsus IV, retrolateral view.

Eyes (Fig. 16A, B). Ocular tubercle (OT) length 2.16, width 2.99. Clypeus 1.2.
Eyes anterior row slightly procurved, posterior row recurved. Eyes: AME 0.68
(round), ALE 0.85 (ovoid), PME 0.54 (ovoid), PLE 0.52 (ovoid). Interocular dis-
tances: AME-AME 0.34, PLE- PLE 2.16, ALE-ALE 1.69, PME-PME 1.34, ALE-PLE
0.20, AME-ALE 0.19, AME-PME 0.06, ALE-PME 0.27, PME-PLE 0.20, AME-PLE
0.57. EI(AME)3.61, EI(ALE) 4.52.

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Figure 16. Selenobrachys ustromsupasius sp. nov., paratype 2, UST-ARC 0005 A, B ocular tubercle, dorsal view C proso-
ma, ventral view D labium, ventral view E fovea, dorsal view.

Chelicerae (Fig. 17A—D). Dorsal length 11.48, dorsal width 4.79, lateral width
67.46. Fang curve length 8.86. Prolateral surface (Fig. 17B): reddish brown,
darker distally and paler proximally, long brown fine setae at lower surface,
darker and longer at lowest portion above teeth. Intercheliceral pegs are ab-
sent but with rows of stiff setae. Retrolateral surface (Fig. 17A): integument,
upper 2/3 dark brown, lower surface reddish brown to amber, flat whitish scales
(SCa), fine, white, cottony acicular (SCb), and long, strong tactile setae (TS)
covering dorsal and upper retrolateral surface, greater anteriorly, patch of fine
and long, mostly slightly curved setae at posterior area of lower retrolateral
surface, patch of very fine straight setae at anterior area of retrolateral surface,
proximomedial setae needle form, very sparse. Long pale reddish brown brush
of setae, ventrally. Teeth 16 (including 4 uprooted and 5 smaller teeth) (0.13-
0.51), mesoventral denticles dense, ~ 77, on three or four rows. Lyrate region

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4. 4j
Ve

Figure 17. Selenobrachys ustromsupasius sp. nov., paratype 2, UST-ARC 0005, left chelicera and maxilla A left chelicera,
retrolateral view B prolateral view C cheliceral strikers, retrolateral view D ventrolateral view E left maxilla, prolateral view
F maxillary lyra on left maxilla.

(Fig. 17C, D): 234-245 strikers on six or seven horizontal rows, unordered.
Strongest and longest strikers on lower rows. Primary rows ~ 11 (0.86-0.95)
long and dark brown, with long, curved filiform ends pointed distally. Secondary
rows ~ 140 (0.19-0.67) dark and lanceolate with short curved filiform ends
pointed downward. Tertiary rows ~ 89 (0.12—0.15) short, pallid, and needle-
form. Long, pallid pseudostrikers present ventrally.

Maxillae (Fig. 17E, F). Prolaterally planoconvex, anterior lobe well pro-
nounced, cuspules on inner basoventral surface ~ 365. Stridulatory organ
(Fig. 17F): ~ 370 bacilliform rods, in nine or ten rows, form a long and dense
ovoid patch, proximally truncated, distally mildly pointed (3.47 long, 1.71 high).

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Short bacilliform rods 0.21-0.51, with pointed ends. Longer rods 0.49-0.84,
paddle-shaped, with paddle blades 0.23-0.36 long and pointed ends, with
thick, strong shafts slightly curved outward located at lowest rows. Paddles
are flattened perpendicularly to maxillary surface. Total number of rods with
paddle blades ~ 40, ~ 10 of them have well-defined paddle blades. Setation:
TS, brown setae, with upper part paler, present dorsally and ventrally, longest
ventrally. Proximodorsal surface with erect pallid fine setae. Lyrate patch sur-
rounded by fine setae. Above maxilla suture with two rows of ~ 24 stiff dark TS.
SC, flat whitish scales covering dorsal surface.

Labium and sternum. Labium (Fig. 16D) length 2.76, width 3.45, integument
reddish brown, paler anteriorly. Labial cuspules ~ 759 (0.05-0.08), dark, at api-
cal 1/3. Setation: TS(a), long, brown with filiform ends, covering labium anteri-
orly and laterally except on cuspule cluster, longer and greater at anterior edge,
all pointing anteriorly. TS(b), dark, spiniform, on posterior surface. Sternum (Fig.
16C) length 8.04, width 7.88, integument pale brown, slightly darker at margin.
Posterior sternal corner acuminate, lateral corners weakly acuminate. Labioster-
nal sigilla ovoid, 1.36 long and 0.49 wide, 1.15 apart. Sternal sigilla three pairs,
ovoid. Anterior pair 0.48 long, 0.30 wide, 4.60 apart, and 0.67 away from sternal
margin adjacent to coxa |. Median pair 0.48 long, 0.30 wide, 4.92 apart, and 0.52
away from sternal margin adjacent to coxa II. Posterior pair 1.64 long, 0.55 wide,
1.90 apart, and 1.38 away from sternal margin adjacent to coxa Ill. Setation:
TS(a), long and short dark spiniform setae on entire sternum, less concentrated
on middle surface. TS(b), dark and pallid, short spiniform with filiform ends, at
sternal margin. SC, grayish brown flat scale mat covering entire sternum.

Abdomen and spinnerets. Abdomen 23.55 long, 16.33 wide, ovular elongated,
integument pale brown. Pedicel 1.87, brown, dorsally striated. Setation: TS(a),
long brown setae, paler apically, covering entire abdomen except book lungs
and epigynal plate, shorter ventrally. Book lungs covered with short brown spin-
iform setae. TS(b), dark short paddle-like, covering entire epigynal plate dense-
ly, intermixed with semi-transparent thin and short sensilla, and long spiniform
setae anteriorly. SC, flat grayish brown scales, covering entire area, darker on
epigynal plate. All setae pointing distad. Spinnerets: PMS 2.40 long, 0.84 wide.
PLS 10.76 long (ant. 3.72, mid. 3.08, pos. 3.96), 4.08 wide (ant. 1.68, mid. 1.32,
pos. 1.08). Setation: TS(a), long brown setae, paler apically, covering dorsally
and laterally. TS(b), dark short paddle-like, covering ventrally. Spigots present on
all segments ventrally. SC, flat grayish brown scales, sparse, present dorsally.

Genitalia. Spermathecae unilobed, not fused. Lobe length 1.25, width 0.93,
basal width 1.10, very broad and short tombstone-shaped spermathecal lobe
with rounded ends and almost parallel lateral margins (Fig. 18A). Entirely scle-
rotized, greater apically and weaker basally. Lobes close to each other, separat-
ed by 0.07. Epigastric fold 3.96 long.

Legs. Leg formula: I, IV, Il, II. RF~ 104.28., LLI (1) 24.43, LLI (IV) 21.84, DLI (I)
23.37, DLI (IV) 20.48, (MI (IV) 126.80, TI (IV) 50.92. Leg lengths total (fem., pat.,
tib., met., tar./cym.): Palp 32.07 (10.72, 6.28, 7.92, n/a, 7.15), Leg | 61.35 (16.42,
10.08, 14.29, 11.65, 8.91) Leg Il 48.54 (13.13, 8.06, 10.90, 10.10, 6.35), Leg III
42.60 (11.33, 6.30, 8.48, 10.35, 6.14), Leg IV 58.83 (15.07, 7.66, 12.39, 15.71,
8.00). Leg lateral widths (fem., pat., tib., met., tar./cym.): Palp (3.95, 2.50, 2.68,
n/a, 0.93), Leg | (4.31, 3.50, 3.02, 2.49, 1.67), Leg II (4.13, 3.28, 2.54, 1.78, 1.41),
Leg Ill (3.69, 3.05, 2.66, 1.74, 1.33), Leg IV (4.06, 3.11, 2.86, 1.61, 1.21). Leg

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Figure 18. Spermathecae, dorsal view A Selenobrachys ustromsupasius sp. nov., paratype 2, UST-ARC 0005 B Seleno-
brachys philippinus comb. rest., 29, UST-ARC 0117 C Orphnaecus kwebaburdeos, 2, UST- ARC 0060 D Orphnaecus pellitus,

9, UST-ARC 0031.

dorsal widths (fem., pat., tib., met., tar./cym.): Palp (2.67, 2.42, 2.46, n/a, 1.70),
Leg | (3.42, 3.66, 3.04, 2.31, 1.91), Leg II (3.20, 2.94, 2.51, 2.04, 1.73), Leg III
(3.54, 2.60, 2.45, 1.89, 1.64), Leg IV (3.34, 2.79, 2.62, 1.75, 1.55). Tarsus I-V with
transverse weakening, tar. | and tar. II more anteriorly, tar. Ill and tar. |V medially.

Leg setation (femora to tarsi) and spines. Setation: TS(a), long and short
brown spiniform setae, paler on upper part, covering all over palp and legs ex-
cept to median to lower prolateral palpal femur surface and leg | and II prolat-
eral femora, longest on palpal tibia and ventral palpal femur, and all leg femora,
tibiae, metatarsi, and tarsi. Leg retrolateral femur IV with stout setae. All point-
ing distad but erect on all ventral femora. TS(b), dark paddle-like setae, pres-
ent on palp (prolateral to ventral distal femur, patella, and proximal tibia), leg |
(dorsolateral and ventral femur, ventral to prolateral patella, and proximal tibia),
leg II (prolateral and ventral femur, patella, and proximal tibia), and leg III and IV
(ventral femora). Very dense on ventral femora | and II and prolateral tibia | and
femora Il. FS, prolateral femur | with a dense field of short sword-like TS (Fig.
21F), similar to TS(b) but shorter and with pointed ends. SC, reflective, flat, gray-
ish brown scales, pale brown on all dorsal patellae, covering all legs and palp
except prolateral palpal femur proximally, which leaves an ovoid smooth sur-
face. Other sensory setae: ETB, short brown setae in two thin inverted L-shaped
clusters, starting from basolateral to dorsal Met | to Il, and a single cluster on
Met III to IV. TB(a), long and short filiform TB intermix with ETB in two rows,

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Darrell C. Acuna et al.: Taxonomic revalidation of Selenobrachys and Chilocosmia

longest dorsally. TB(b) rows of unordered clavate TB, varying in size, present
to all tarsi, and intermix with tarsal ETB. CHS, tiny pale brown translucent erect
sensilla tapering apically, present on palpal and all leg femora to tarsi, and also
intermixes with tarsal and metatarsal scopulae. Spines: (dorsal-dorsoprolater-
al-dorsoretrolateral-ventral): Met | (0-0-0-1), Met II (0-0-0-3). Met III (O-1-1-3).
Met IV (0-1-1-3).

Coxae and trochantera. Coxae: Palp coxa (see Maxillae). Lengths (coxa |, Il,
Il, IV) 8.42, 7.28, 5.72, 6.12. Widths (coxa I, Il, Ill, IV) 4.40, 4.04, 3.88, 4.28. Se-
tation: TS, long brown setae dorsally and ventrally, strong and short spiniform
setae prolaterally on all coxae. SC(a), flat scales covering ventral to retrolateral
1/2. SC(b), white cottony acicular covering dorsal of all coxae. Patches of fine
setal fringe present laterally on coxae, intermixed with short spiniform setae.
Coxae I-IV have rows of short semi-translucent bristles, prolaterally, denser
on Coxae | and II. Trochantera: Lengths (troch. palp, |, Il, Ill, IV) 2.84, 4.32, 3.88,
3.12, 3.64. Widths (coxa palp, I, Il, Ill, IV) 2.92, 3.76, 3.20, 3.04, 3.52.

Scopulae and claws. Scopulae (left): Palp tarsus undivided but parted. Tar-
sus |, entire, but intermixed with longitudinal one or two rows of very sparse
short spiniform setae. Tarsus II, entire, but intermixed with very sparse longitu-
dinal one or two rows of short spiniform setae. Tarsus III, entire, but intermixed
with longitudinal two or three rows of strong long setae. Tarsus IV, entire, divid-
ed by four rows of strong long setae. All tarsi with a bald spot ventrobasally.
Met. | covered almost all ventral surfaces, entire, but with longitudinal one or
two rows of very sparse long setae. Met. Il, covered almost all ventral surface,
entire, but with longitudinal one or two rows of very sparse long setae. Met. Ill,
covered 4/5 distally, entire, but with longitudinal one or two rows of very sparse
long setae. Met. IV, covered 3/4 distally, divided by two or three rows of strong
long setae. Claws: pair of claws present on all leg tarsi with one to three teeth
on each claw. Tarsus IV with a short unpaired third inferior claw.

Color in life. Females are mildly dichromatic (Fig. 11B), with dark brown on
carapace, abdomen, palp, and all legs, contrasted by dark femora on all legs
and palp. Dark brown legs (except femora) are topped with pale brown setae,
sparsely hirsute. Legs and abdomen reflect (by scales) a deep, mild purplish
blue sheen. Generally, uniformly dark with a mild bluish sheen after ecdysis,
which fades in a few days. Coloration changes, becoming pale brown, as the
exoskeleton ages before ecdysis.

Natural history and distribution. Mature males were collected in September,
and females with egg sacs (Fig. 19E) were found in February. Burrows, not self-
dug, were found under piles of coconut husks (Fig. 19B, G) piles and crevices
of metamorphosed limestones (marble) at the roadside embankments (Fig.
19C-—F). They are also found in the beach forest of Bon Bon Beach in the north-
western coast of Romblon Island. The spiders were found on the burrow en-
trance at night, waiting for prey to ambush. This species is known only to occur
in Romblon Island, Philippines (Fig. 22).

Etymology. The specific epithet is a masculine adjective derived from the
combined names of the collaborating academic institutions and an organiza-
tion of the project in which this study is involved, namely, the University of Santo
Tomas (UST), Romblon State University (RSU), Mindanao State University-lligan
State University (MSU-IIT), University of the Philippines-Diliman (UPD), and the
Philippine Arachnological Society, Inc. (PASI), attached with the Latin suffix -us.

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piles and crevices and piles of coconut husks E female with egg sac E-H paratype females, in situ.

Discussion

Morphology and gene sequences are the two most important data that can
be used in taxonomy and systematics. Taxonomic information acquired from
the morphological analysis is, in many cases, being questioned and subjected
to debate among taxonomists due to their differences in interpretations and
opinions (Sites and Marshall 2004; Wiens 2004; Will and Rubinoff 2004; Dayrat
2005; Vences et al. 2013). The gene sequencing method appears to be ideal as
it is very specific, but this method still needs to be supported with a physically
observable characteristic to affirm its validity. The review of the taxa in this
study is based on the combined information of morphology and DNA sequenc-
es with insights into their biogeography.

Morphological basis on the validity of Selenobrachys stat. rev. and
Chilocosmia. stat. rev.

Selenobrachys and Chilocosmia were considered junior synonyms of Orphnae-
cus by Westet al. (2012) based on the characters used in their cladistic analysis.
They considered the oval proximally truncated lyrate patch of Selenobrachys an

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Darrell C. Acuna et al.: Taxonomic revalidation of Selenobrachys and Chilocosmia

autapomorphy in the Orphnaecus clade, but we consider this synapomorphy
within Selenobrachys with the discovery of additional Selenobrachys species
(S. ustromsupasius sp. nov.) and five other potential undescribed species from
other islands of Romblon PAIC and West Visayas PAIC known to the authors,
which share the same lyrate morphology and spermathecal morphology. Addi-
tionally, the maxillary lyra of Selenobrachys is differentiated from Orphnaecus
by its short bacilliform rods forming a dense ovoid patch that is truncated prox-
imally and mildly tapering distally, and the rows of paddle-shaped lyrate bacil-
lae at the lowest rows have distinctly thicker shafts prolaterally whereas the
largest ones in the lowest row have a more pointed tip in prolateral view (Figs
7G, 13F, 17F, 20B, E). The short bacilliform rods on the lyra of Orphnaecus form
a reniform patch (West et al. 2012), less dense, with rows of clavate bacillae
that have elongated paddles and longer and stouter shafts and the largest have
a rounded tip (Fig. 20A, D).

The secondary rows of cheliceral strikers of Selenobrachys philippinus
comb. rest. were scored similarly (lanceolate in shape) with Orphnaecus spec-
imens in the same cladistic study (West et al. 2012). However, our analysis
shows that all Selenobrachys materials we examined have secondary rows
of cheliceral strikers that are shorter, slightly curved, and spiniform in shape
(Figs 8C, 13C, D, 17C, D), while Orphnaecus has straighter and longer lanceo-
late secondary strikers (West et al. 2012). West et al. (2012) also noted < 50
strikers in Orphnaecus and Phlogiellus, as one of the synapomorphies of the
tribe Yamiini Kishida, 1920, but we recorded > 150 strikers (excluding tertiary
strikers) on our Selenobrachys specimens. We also noticed that the very short
needle-form tertiary rows of cheliceral strikers in Selenobrachys are greater in
number (100-200) (Figs 8C, 13C, D, 17C, D) which corresponds with the very
dense lyrate patch of the genus.

West et al. (2012) mentioned the similarity in spermathecal morphology
(tombstone-shaped) of S. philippinus comb. rest. to their Orphnaecus specimens
(QM S83782, S83783) from Masbate Island. With the absence of an illustration
of the spermathecae of their Orphnaecus species, we can assume that it is just
a resemblance, considering that the spermathecal morphology of O. kwebabur-
deos (Fig. 18C) is almost in a tombstone-shape but still fits our description of
Orphnaecus, in having longer spermathecal lobes with more concave prolateral
margins which slightly pointing inward apically, creating asymmetry to the lobe
(Fig. 18C, D). All Selenobrachys specimens we examined have broad and short
spermathecal lobes, in a tombstone shape, almost symmetrical, with lateral
margins almost parallel and very mildly or not concave prolaterally, not con-
verging distally, and the apically rounded ends not pointing inward (Fig. 18A, B).

The male of S. philippinus comb. rest. has been unknown since the original
description of the species. Fortunately, we were able to collect new specimens
from the type locality in Mambucal, Negros Island, which included a single adult
male. Additional S. philippinus male specimens were examined from SMNS.
The palpal tibiae of male Selenobrachys are distinctly longer and cylindrical
(Figs 9A-D, 15A, B), while in the sister genera, the palpal tibiae of males are
proximally incrassate and tapering distally. Additionally, Orphnaecus males have
a distinct, very dense, very long dorsal brush on the palpal patellae (Fig. 154A;
West et al. 2012) which are also present on the palpal tibiae in some species.

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Darrell C. Acuna et al.: Taxonomic revalidation of Selenobrachys and Chilocosmia

0.1 mm

Figure 20. Largest stridulating setae on maxillary lyra A-C dorsal view D-F prolateral view A, D Orphnaecus sp.
B, E Selenobrachys philippinus comb. rest C, F Chilocosmia dichromata comb. rest G Orphnaecus pellitus, syntype 9, lyra
on prolateral maxillary surface.

West et al. (2012) mentioned the synapomorphy of Yamiini of having a single
retrolateral keel on the embolus of males. Based on our analyses of the palpal
organ morphology of male Orphnaecus and Selenobrachys specimens, the ret-
rolateral keel is actually an extremely long prolateral superior keel, following the

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Darrell C. Acuna et al.: Taxonomic revalidation of Selenobrachys and Chilocosmia

work of Bertani (2000), for which we adopted the structures on the embolus of
males based on the position of the keels. The retrolateral keel emerges retrolat-
erally from the apex of the embolus to the rear (Bertani 2000), which is not the
case in Orphnaecus and Selenobrachys. However, further studies on homolo-
gizing the structures of male palpal organs of Selenocosmiinae are necessary.

Selenobrachys species have relatively stouter legs dorsally (except for
O. pellitus which also has stout legs caused by troglomorphism). We also
explored the setation field on the prolateral surface of femur |, which we
herein call femoral setation (FS): we found that Selenobrachys species have
a field of short sword-shaped setae with a narrow base (Fig. 21E-H), while
Orphnaecus have longer needle-form setae (Fig. 21A—D). However, it is sug-
gested to further study the ultramorphology of the femoral setation under a
scanning electron microscope.

Chilocosmia stat. rev. was synonymized based on the synapomorphic char-
acters of Orphnaecus (West et al. 2012). Schmidt and von Wirth (1992) de-
scribed the lyra of this genus as an arcuate strip of short rods consisting of
an arcuate row of clavate bacillae. The largest bacillae are stronger (Fig. 21C,
F) and the short rods are less dense (< 200) than in Orphnaecus and Seleno-
brachys stat rev. (> 300; if not absent or not rudimentary which are consequenc-
es of phenotypic plasticity). In addition, the morphology of the embolus with its
strongly twisted tegulum and its missing BL and the missing long PS keel of
the male of C. dichromata comb. rest. are not found in any described species
of Orphnaecus and Selenobrachys stat. rev. (Fig. 5A-E). The dense long palpal
brush on the dorsal male palpal patellae is also missing in C. dichromata comb.
rest. (Fig. 5D). The female spermathecae of C. dichromata comb. rest. have
reduced ends or are distally converging as in Orphnaecus, but not concave pro-
laterally and not pointing inwards (Schmidt and von Wirth 1992). The median
carapace line in Orphnaecus is not unique to the genus but is also present in
other Yamiini genera.

Genetic data sequencing and phylogenetic investigation

Most barcoding studies in animals utilize the cytochrome c oxidase subunit
| (COI) gene due to its key characteristics such as universality and rapid sub-
stitution at the third codon position; the expansion of genetic databases has
established a firm basis for utilizing this gene in the identification of speci-
mens. However, the assessment of COI and 16S for DNA barcoding of farm-
land spiders from previous studies showed the potential efficiency of rRNA
genes in identifying genetic species boundaries (Hamilton et al. 2011, 2016;
Turner et al. 2018; Briggs et al. 2023) and their capability in identification during
high-throughput experiments using various metabarcoding protocols (Wang et
al. 2017; Vences et al. 2005). In this study, COl and rRNA genes have provided
a preliminary understanding of the relationships between known Philippine ta-
rantula species. Although the COI phylogenetic tree received very low bootstrap
support, the assessment of genetic distances and support from morphology
collectively contribute to a more robust depiction of the distinction between
Orphnaecus, Selenobrachys stat. rev., and Chilocosmia stat. rev. This first mo-
lecular analysis for Philippine tarantula spiders is an important initiative for
more molecular studies on these taxa.

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Darrell C. Acuna et al.: Taxonomic revalidation of Selenobrachys and Chilocosmia

Figure 21. Femoral Setation (FS) on left prolateral femur |
C, D Orphnaecus sp.’ L3’, 9, UST-ARC 0134 E, F Selenobrachys ustromsupasius sp. nov., paratype 2, UST-ARC 0005
G, H Selenobrachys philippinus comb. rest., 2, UST-ARC 0112 I, J Chilocosmia dichromata comb. rest., 4, SMNS Aran-
004182 B, D, F, H, J magnified view of the left femur | median prolateral surface.

Significantly, the arrangement of species within clades on the phylogenet-
ic trees (Fig. 1A, C) supports the morphological synapomorphies, particular-
ly evident in instances like S. philippinus comb. rest. and the newly described
species S. ustromsupasius sp. nov., across phylogenetic trees of both genes.

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Darrell C. Acuna et al.: Taxonomic revalidation of Selenobrachys and Chilocosmia

The analysis of genetic distances offers quantitative insights into the extent
of genetic similarity or divergence among different species that were initial-
ly delimited with morphological differences (Suppl. material 2). The observed
pairwise distance values for both genes provide additional evidence of the re-
lationships between genus and species. Earlier studies showed the differenc-
es in percentage values of intraspecific distance that was much lower than
interspecific genetic distance (Powell and Caccone 1989; Cadiz et al. 2018;
Ma et al. 2019, 2022). This supports the results of this study that the lower
percentage differences between intraspecies and the higher percentage dif-
ferences among the interspecies in the genetic distances of tarantula spiders
indicate greater genetic similarity and divergence, respectively. The compar-
ison of these values across species aligns well with both the morphological
synapomorphies and the phylogenetic tree topology.

The Pleistocene Aggregate Island Complexes (PAICs) paradigm

Unlike most of the islands in Southeast Asia and Oceania, the Philippine Arc
did not evolve from the Sahulian biogeographic realm nor the Eurasian plate
(Queafo et al. 2020). The present islands of the Philippines, except Palawan,
originated from the Philippine Islands arc system, which evolved as a result of
subduction of the ocean floor along the trenches surrounding the Philippines
during the Cretaceous period (Yumul et al. 2008; Aurelio et al. 2013). This pa-
leogeographic history of the Philippines explains the existence of numerous
flora and fauna unique to this country (Jones and Kennedy 2008).

Islands in the Philippine archipelago have been grouped and interconnected
in the past due to Pleistocene sea level drops during the glacial periods (Heaney
1991; Heaney et al. 1998). These major island groups are known as Pleisto-
cene Aggregate Island Complexes (PAICs) (Esselstyn and Brown 2009) and are
based on the present 120 m isobath (Fig. 22). This formation has created the
seven major biogeographical regions—namely, the Luzon PAIC (Greater Luzon),
Mindanao PAIC (Greater Mindanao), West Visayan PAIC, Palawan PAIC, Sulu
PAIC, Mindoro PAIC, and Romblon PAIC (Romblon Island Group; RIG) (Fig. 22).
This concept may have facilitated the colonization and diversification of Filipi-
no tarantulas. Tarantula spiders, like most mygalomorphs, have a limited mode
of dispersion that is limited only to ground movement, making them less mo-
bile than the araneomorph spiders. The archipelagic setting of the Philippines
could have promoted rich diversification and unique evolutionary radiation for
tarantula spiders, which is evident in the rich terrestrial fauna of the country
(Heaney et al. 2016; Oaks et al. 2019; Pitchay and Torrentira 2022).

The results of our morphological and molecular analyses support the resur-
rection of the genus Se/enobrachys, but we recognize its close relationship to
Orphnaecus as a sister genus. Biogeographically, Selenobrachys might be limit-
ed to the Romblon Island Group + West Visayan PAIC. Citizen science sightings
known by the first author provide the presence of the genus in other West Visay-
an + Romblon PAIC islands (except Masbate Island) which could still have five
or more island-endemic new undescribed Selenobrachys species. Given its cur-
rent distance from the rest of West Visayan PAIC islands, Masbate could have
fragmented earlier from the rest of West Visayan PAIC islands before the diver-
sification of the genus, hence explaining their potential absence on the island.

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Darrell C. Acuna et al.: Taxonomic revalidation of Selenobrachys and Chilocosmia

Contour

Nd ,
eS a
2. ——250 ¥ <9 Banton
— 1000 .
. Maestro de Si
Elevation (masl) : Iimara
Ocampo
| <= 500
(} 500 - 1000
MH) 1000 - 1500
MB 1500 - 2000
MM 2000 - 2500
_2 MM > 2500
2
ap
»* Mindoro
: ROMBLON ISLAND GROUP
= *Palawan
=O
2
=@ ta Tl ASelenobrachys spp. @ Orphnaecus spp.
Ls
0 100 200 300 km» & *Sulu #4 Selenobrachys ustromsupasius sp. nov. type localities
i —|
116.0°E 120.0°E 124.0°E 128.0°E
i i I I

Figure 22. The seven major Philippine biogeographic regions based on the PAIC (Pleistocene Aggregate Island Complex)
paradigm and the distribution map of valid species and published records of Orphnaecus (blue circles) and Seleno-
brachys (orange triangle). Inset: type localities of Selenobrachys ustromsupasius sp. nov.

We presume that the genus evolved from Orphnaecus-Selenobrachys ancestor
from Luzon when West Visayan PAIC was still connected to Greater Luzon and
became isolated upon its fragmentation. Molecular dating is needed to test
this hypothesis. Orphnaecus is one of the most widespread theraphosid taxa in
the Philippines, but they might not be able to colonize Mindoro, Romblon Island
Group, Sulu Island Group, and the Palawan realm, owing to their different land
mass origins. Proto-Orphnaecus may have ridden the proto-Luzon mass while
rafting northward to its present position through the Philippine Arc System. The
presence of Orphnaecus in West Visayan PAIC may be the result of recoloniza-
tion after the first colonization and isolation of Selenobrachys when the islands
reconnected through the oscillating water level during the Late Pleistocene, but
during that time Romblon PAIC may not be reconnected to Panay thus explains
the absence of Orphnaecus in the said island group, and Panay became their
terminal expansion westward.

The placement of the Papuan species, C. dichromata comb. rest., in Orphnae-
cus is biogeographically suspicious. Morphologically, this species is distinct
from the Philippine Orphnaecus species for having an arcuate strip of short rods
in lyra (Schmidt and von Wirth 1992), with slight differences in the structure
of the spermathecae and a vastly different genital morphology of the males.

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The Philippine Arc System and Papuan geographical disjunct is dramatic,
although, the most recent possible land connection may have happened during
the Late Oligocene to Late Miocene (~ 25-10 mya) when the Philippine Arc
and Halmahera Arc may have aligned together creating a path for dispersal
(Kalkman et al. 2018; Bocek and Bocak 2019). Genetic investigation by Autelin
et al. (2021) on the freshwater gastropod subfamily, Miratestinae, reveals mi-
gration from Sahul to the Indo-Australian Archipelago, the Philippines, and the
West Pacific Islands in the Early Miocene. It is interesting to test the same with
Selenocosmiinae if they have utilized the same routes, which can only be done
with the availability of more genetic data from the Sahulian and Sundaic taxa.

Conclusions

Evidence from morphological and molecular analyses as well as biogeograph-
ical insights revealed that the taxonomic status of the genus Selenobrachys
is indeed valid. We therefore remove Selenobrachys Schmidt, 1999 from the
synonymy of Orphnaecus Simon, 1892, and we restore the genus to its valid
genus status, with its type species, Orphnaecus philippinus, original combina-
tion restored becoming Selenobrachys philippinus comb. rest., and we describe
a second species for the genus, Selenobrachys ustromsupasius sp. nov., from
Romblon Island. Furthermore, we recognize the close relationship of Seleno-
brachys and Orphnaecus based on the synapomorphic characters within the
tribe Yamiini, thus placing Selenobrachys in this clade. As discussed above, we
also restore the genus Chilocosmia Schmidt & von Wirth, 1992 stat. rev. and its
type species Chilocosmia dichromata Schmidt & von Wirth, 1992, comb. rest.
based on morphological, molecular, and biogeographic points. The number of
genera within the subfamily Selenocosmiinae has now increased to 13, and
the theraphosid fauna of the Philippines is now five genera and 14 species.
Studying the biogeography of animals in the Philippines that are mostly limited
to ground dispersal, like most mygalomorph spiders, may help us better under-
stand the biogeographic history of the Philippines. Molecular analysis should
always be supported by morphology (and vice versa) and other available evi-
dence because delimitation based only on genetic divergence is subjective and
has no universal standards and the variations in morphology do not always
warrant species boundaries.

Acknowledgments

The authors would like to express their gratitude to the Philippines’ Depart-
ment of Science and Technology (DOST) and the National Research Council
of the Philippines (NRCP) for the funding support provided to the GAGAMBA
Research Program; to the Department of Environment and Natural Resourc-
es-Biodiversity Management Bureau (DENR-BMB) for granting our request for
a gratuitous permit to collect samples and conduct research; to DENR- Region
IV-B (MIMAROPA), Provincial Environment Natural Resources Office-Romblon
(PENRO-Romblon), and Barangays Tambac and Guimpingan for providing the
permits and clearances which allowed us to collect samples and conduct
our research in Romblon Island; to the Community Environment and Natural
Resources Office-Sipocot (CENRO-Sipocot), Protected Area Management

ZooKeys 1233: 139-193 (2025), DOI: 10.3897/zookeys.1233.128056 186

Darrell C. Acuna et al.: Taxonomic revalidation of Selenobrachys and Chilocosmia

Bureau-Libmanan Caves National Park (PAMB-LCNP), PENRO-Camarines Sur
for their hospitality and for allowing us to collect samples from LCNP; to the
Provincial Government of Negros Occidental and the Northern Negros Natural
Park-Protected Area Management Bureau (NNNP-PAMB) for generous assis-
tance extended to us during collection and sampling in Negros Occidental; to
CENRO-Real, Municipality of Real, and Barangay Aluyon, Burdeos for providing
clearances during the sampling in Polillo Island and Real, Quezon Province; to
the Municipality of Siniloan, Laguna and UP- Land Grant Management Office for
providing clearances and assistance during the sampling in Siniloan and UPLG;
to Dr. Henrik Krehenwinkel of Trier University (Germany) for conducting the COI
sequencing of C. dichromata used in this study; to Dr. Christine Rolland (MHNP)
and Boris Striffler for the opportunity to examine the syntypes of O. pellitus; to
Dr. Peter Jaeger (SMF) for the opportunity to examine the holotype of S. philip-
pinus and C. dichromata; to Dr. Joachim Holstein and Ingo Wendt (SMNS) for
the opportunity to examine the specimens of C. dichromata and S. philippinus
deposited in SMNS; to the University of Los Banos Museum of Natural History
(UPLB-MNH) for the opportunity to examine the type specimens of O. kweba-
burdeos; to Mr. Perry Buenavente of the Philippine National Museum (PNM) for
the opportunity to examine the types of O. adamsoni and other spider speci-
mens; to Mr. Frank Schneider for the natural history data and corresponding
images of C. dichromata stat.rev.; to Mr. Erl Pfian Maglangit (MSU-IIT) for as-
sisting in editing the images; to John Denver Fornillos of Laguna Polytechnic
State University (Sta. Cruz), Lucky Jay Villaflor (Zambales), and Romel Enguito
(Negros Occidental) for assistance in field sampling; and to the anonymous
reviewers for their very detailed comments which greatly improved this paper.

Additional information

Conflict of interest

The authors have declared that no competing interests exist.

Ethical statement

No ethical statement was reported.

Funding

This work was supported by Department of Science and Technology - Philippines.

Author contributions

DCA is involved in the field sampling, conducted morphological and molecular phyloge-
netic analyses, examination of type specimens in the Philippines, and is the main per-
son involved in writing the morphological and molecular analysis part of the manuscript;
VVW examined the type specimens and other Selenocosmiinae specimens deposited
in European collections and natural history museums and is also involved in writing the
morphological analysis part of the manuscript. MKUD, MCR, and LPR performed DNA ex-
traction and amplification, and were involved in writing the molecular analysis part; CNCN
and ABRM participated in field sampling and preparation of the manuscript; GAF and
MJAF assisted in sampling and preliminary morphological analysis; MRSB and LAG are
involved in the conceptualization of the research, proposal writing and grants acquisition,
preparation of the manuscript, and review, revision, and finalization of the manuscript.

ZooKeys 1233: 139-193 (2025), DOI: 10.3897/zookeys.1233.128056 187

Darrell C. Acuna et al.: Taxonomic revalidation of Selenobrachys and Chilocosmia

Author ORCIDs

Darrell C. Acufia © https://orcid.org/0000-0002-2958-8763

Maria Mikaela U. Dumbrique © https://orcid.org/0000-0003-3592-2585
Maricel C. Ranido © https://orcid.org/0000-0002-4083-5489

Lorenz Rhuel P. Ragasa © https://orcid.org/0000-0001-8581-9872
Anna Beatriz R. Mayor ® https://orcid.org/0000-0002-2256-1357

Mary Jane A. Fadri © https://orcid.org/0000-0001-6906-0157

Volker von Wirth © https://orcid.org/0000-0003-2868-0768

Myla R. Santiago-Bautista © https://orcid.org/0000-0001-91 73-7320
Leonardo A. Guevarra Jr © https://orcid.org/0000-0002-2031-0300

Data availability

All of the data that support the findings of this study are available in the main text or
Supplementary Information.

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Supplementary material 1
List of all new genetic sequences deposited in GenBank

Authors: Darrell C. Acuna, Myla R. Santiago-Bautista, Leonardo A. Guevarra Jr

Data type: pdf

Copyright notice: This dataset is made available under the Open Database License
(http://opendatacommons.org/licenses/odbl/1.0/). The Open Database License
(ODbL) is a license agreement intended to allow users to freely share, modify, and
use this Dataset while maintaining this same freedom for others, provided that the
original source and author(s) are credited.

Link: https://doi.org/10.3897/zookeys.1233.128056.suppl1

Supplementary material 2

Percent pairwise distances of all sequences of CO1 and 12S-tRNA-Val-16S

Authors: Darrell C. Acuna, Myla R. Santiago-Bautista, Leonardo A. Guevarra Jr

Data type: pdf

Copyright notice: This dataset is made available under the Open Database License
(http://opendatacommons.org/licenses/odbl/1.0/). The Open Database License
(ODbL) is a license agreement intended to allow users to freely share, modify, and
use this Dataset while maintaining this same freedom for others, provided that the
original source and author(s) are credited.

Link: https://doi.org/10.3897/zookeys.1233.128056.suppl2

ZooKeys 1233: 139-193 (2025), DOI: 10.3897/zookeys.1233.128056 193