AMERICAN MUSEUM NOVITATES

Number 3930, 24 pp.

June 26, 2019

Myrmecicultoridae, a New Family of Myrmecophilic
Spiders from the Chihuahuan Desert
(Araneae: Entelegynae)

MARTIN J. RAMIREZ, 1 CRISTIAN J. GRISMADO, 1 DARRELL UBICK, 2 VLADIMIR
OVTSHARENKO, 3 PAULA E. CUSHING, 4 NORMAN I. PLATNICK, 5 WARD C. WHEELER, 5
LORENZO PRENDINI, 5 LOUISE M. CROWLEY, 5 AND NORMAN V. HORNER 6

ABSTRACT

The new genus and species Myrmecicultor chihuahuensis Ramirez, Grismado, and Ubick is
described and proposed as the type of the new family, Myrmecicultoridae Ramirez, Grismado, and
Ubick. The species is ecribellate, with entelegyne genitalia, two tarsal claws, without claw tufts, and
the males have a retrolateral palpal tibial apophysis. Some morphological characters suggest a pos¬
sible relationship with Zodariidae or Prodidomidae, but the phylogenetic analysis of six markers
from the mitochondrial (12S rDNA, 16S rDNA, cytochrome oxidase subunit I) and nuclear (histone
H3, 18S rDNA, 28S rDNA) genomes indicate that M. chihuahuensis is a separate lineage emerging
near the base of the Dionycha and the Oval Calamistrum clade. The same result is obtained when
the molecular data are combined with a dataset of morphological characters. Specimens of M. chi¬
huahuensis were found associated with three species of harvester ants, Pogonomyrmex rugosus,
Novomessor albisetosis, and Novomessor cockerelli, and were collected in pitfall traps when the ants
are most active. The known distribution spans the Big Bend region of Texas (Presidio, Brewster, and
Hudspeth counties), to Coahuila (Cuatro Cienegas) and Aguascalientes (Tepezala), Mexico.

1 Museo Argentino de Ciencias Naturales “Bernardino Rivadavia” - CONICET, Buenos Aires.

2 California Academy of Sciences, San Francisco.

3 Hostos Community College, City University of New York.

4 Denver Museum of Nature & Science.

5 American Museum of Natural History, New York.

6 Midwestern State University, Wichita Falls, Texas.

Copyright © American Museum of Natural History 2019

ISSN 0003-0082

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INTRODUCTION

Many arthropods live as symbionts or commensals in ant nests, which constitute close,
protected habitats with a stable provision of resources (Cushing, 1997, 2012). The colonization
of subterranean ant nests is frequently associated with evolutionary changes due to reduced
selection pressure on visual cues and senses, and increased pressure on chemical and tactile
interactions with the ants (e.g., Dettner and Liepert, 1994; Elgar and Allan, 2004; Witte et al.,
2008). One example of marked morphological transformation is the corinnid genus, Attacobius
Mello-Leitao, associated with leaf-cutter ants (Roewer, 1935; Platnick and Baptista, 1995; Erthal
and Tonhasca, 2001). With their pale brown uniform coloration and reduced eyes, they are so
unlike regular corinnids that they have been placed in five families (Clubionidae, Liocranidae,
Gnaphosidae, Prodidomidae, and Corinnidae). Arachnologists were so confused by Attacobius
that not only was its family placement uncertain, but, as remarked by Bonaldo and Brescovit
(2005), a handful of specimens produced no fewer than five generic names.

We describe here Myrmecicultor chihuahuensis Ramirez, Grismado, and Ubick, a new spe¬
cies and genus of a mysterious myrmecophilic spider collected from the Big Bend Region
(Presidio, Brewster, and Hudspeth counties) of Texas, and near Cuatro Cienegas in Coahuila,
Mexico. This taxon puzzled nine spider taxonomists for over 15 years. The specimens were first
discovered in pitfall traps in 1999 by Greg Broussard, a biology Masters student, while conduct¬
ing a spider survey of the Dalquest Desert Research Station (DDRS). Broussards major advisor,
N.V.H., was unable to identify these specimens and suspected they represented a new species.
The station is situated on the northeast corner of the Big Bend Ranch State Park and bisected
by the Presidio/Brewster county line (Broussard and Horner, 2006; map 1). In 2008, David
Lightfoot from the Museum of Southwestern Biology, University of New Mexico, observed
several spiders on the surface of a nest of the harvester ant Pogonomyrmex rugosus Emery, near
Cuatro Cienegas, 335 km south of the DDRS site, with a similar Chihuahuan Desert habitat
(fig. 11E, F). Lightfoot took several photographs, collected a small series, and showed them to
Sandra Brantley, also at the Museum of Southwestern Biology. Brantley suggested they send
them to N.I.P. at the American Museum of Natural History for identification, who recognized
the specimens as the same spider species from the DDRS previously sent by N.V.H. Once the
association with harvester ants was revealed, the annual collection of spiders at the DDRS more
than doubled after setting pitfall traps a meter from the entrance of the ant nests.

Myrmecicultor chihuahuensis specimens have entelegyne female genitalia, a retrolateral
tibial apophysis on the male palp, and the bases of the trichobothrial shafts bear an expansion
covered by small bumps, all indicating they belong in the RTA clade (Griswold et al., 2005,
Ramirez, 2014). Only two tarsal claws are present, and the tapeta of the posterior median eyes
is characteristically oriented at 90°, a disposition considered typical of gnaphosids and related
families by Homann (1952, 1971). This peculiar morphology is known to function as a sky
compass in a gnaphosid species (Dacke et al., 1999), and may have the same function in a large
clade of dionychan spiders (the “OMT clade”; see Ramirez, 2014). The species was included (as
cf. Gnaphosoidea TEX) in a phylogenetic analysis of dionychan spiders using morphological
data, but its relationships remained unresolved, with low support in the OMT clade, and its

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relationships and taxonomic associations changed with every subtle modification of the dataset
(Ramirez, 2014: 331). With the addition of DNA sequence data, it became clear that the sig¬
nificance of the OMT character should be reevaluated. Wheeler et al. (2017) presented a phy-
logeny of spiders wherein most of the OMT clade appeared as monophyletic (labeled as
Dionycha part A; see fig. 1), except for the Prodidomidae, which grouped as sister to the rest
of Dionycha. Because prodidomids have typical gnaphosidlike tapeta in their posterior median
eyes, this opened the possibility that the oblique tapeta represents a synapomorphy of all the
Dionycha, later lost in the Dionycha part B.

Other than the eyes, the morphology of these spiders offers few clues as to their relation¬
ships. The long cheliceral fangs, the apical dorsal patch of chemosensory setae on the palpal
tarsus and some details of the tarsus-metatarsus joint suggest a relationship with the subfamily
Prodidominae, but their spinnerets, especially the anterior laterals, lack the specialization of
those spiders, such as the elongated piriform-gland spigot bases flanked by long setae. On the
other hand, the short posterior spinnerets of M. chihuahuensis, the strongly procurved anterior
eye row, and the leg setae are similar to those of Zodariidae, a family frequently associated with
ants (Jocque, 1991; Pekar et al., 2011). However, M. chihuahuensis differs from zodariids in sev¬
eral characters: the major ampullate spigots of the anterior lateral spinnerets are situated laterally
rather than centrally; the serrula on the endite is normally developed; and the legs lack a tibial
process that fits on a metatarsal pouch (Ramirez et al., 2014; Jocque and Henrard, 2015). In the
present contribution, we analyze DNA sequences and morphological data to help determine the
phylogenetic position of M. chihuahuensis. Although we did not arrive at a precise placement of
this mysterious spider, we consider it time to make this remarkable species widely known.

MATERIAL AND METHODS

The format of description follows that of Ubick and Vetter (2005), except for macrosetae,
as in Ramirez (2003). Morphological terms follow Ramirez (2014). Specimens are deposited in
the collections of the American Museum of Natural History, New York (AMNH), the Califor¬
nia Academy of Sciences Entomology, San Francisco (CAS), the Denver Museum of Nature
and Science, Colorado (DMNS), the Museo Argentino de Ciencias Naturales “Bernardino
Rivadavia,” Buenos Aires (MACN-Ar), the Museum of Southwestern Biology, University of
New Mexico, Albuquerque (MSBA), and Midwestern State University, Wichita Falls, Texas
(MSU).

Samples were critical point dried and coated with gold-palladium for scanning electron
microscopy (SEM) with a FEI-XL30 or Hitachi S-520 standard SEM, or a Hitachi-S4700 field
emission SEM, all under high vacuum.

Morphological characters and outgroup were taken from Ramirez (2014), adding scorings
for Penestomus (Penestomidae) and Zodariidae following Miller et al. (2010) and Ramirez et
al. (2014); the morphology and combined data matrix are deposited in Zenodo (doi: 10.5281/
zenodo.2648632). DNA sequences of six markers from the mitochondrial genome, 12S rDNA
(12S), 16S rDNA (16S), cytochrome oxidase subunit I (COI) and the nuclear genome, histone

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H3 (H3), 18S rDNA (18S), 28S rDNA (28S) were generated at the AMNH, using the primers
and protocols provided in Wheeler et al. (2017). The new sequences are deposited in GenBank
with accession numbers MK775712-MK775717. The taxon sampling was chosen to represent
the major groups of the RTA clade, with a denser sampling of two groups sharing potential
synapomorphies with M. chihuahuensis (zodarioids and prodidomids; see Introduction).

Sequences were aligned with MAFFT (Katoh and Standley, 2013) using the online platform
at the European Bioinformatics Institute (http://www.ebi.ac.uk/Tools/msa/mafif/) with default
parameters. Models for the six markers were selected using jModeltest (Darriba et al., 2012).
The molecular data partition was then analyzed with MrBayes (Ronquist et al., 2012) using the
CIPRES portal (Miller et al., 2010) for 20 million generations. The morphological data partition
was analyzed under implied weights parsimony using TNT, with a concavity constant k = 12;
k values between 3 and 30 were examined as well. The combined data partitions were analyzed
with MrBayes, using the standard Mk model for the morphological partition, plus the sequence
data partition as above.

The pitfall traps used for collecting consisted of two 18 oz. durable plastic cups, one inside
the other. Using a gardening hand trowel, holes were dug to a depth that allowed the stacked
cups to be inserted into the ground so that the rim of the upper cup was at ground level. Holes
were backfilled, and soil packed around the cups. This design allowed removal of the upper cup
while the lower cup remained in the ground to preserve the integrity of the hole. Approximately
300 ml of Sierra Antifreeze® (propylene glycol) was poured into the upper cup. The propylene
glycol served as both a killing and preserving fluid, which allowed the traps to be collected
approximately every 30 days. The traps were covered with flat stones rested on smaller stones to
give 1 cm clearance, allowing insects and spiders free access to the trap. On collection dates, the
upper cup was removed, and its contents strained through a fine mesh tea strainer. Specimens
were stored in 95% ethanol and transported to the laboratory for separation and identification.
The samples were sorted and stored in 70%, 95%, or 100% ETOH, the last group targeted for
DNA analysis. A total of 140 traps were used in the collecting period from 1999 to 2016: 20 total
traps were set in 1999 and 2000; from 2006-2016, 10 traps were set each year. In 2008, the
association of the spiders with the ants was established and from 2009 to 2016, the traps were
set approximately 1 m from ant-nest entrances, yielding larger numbers of spiders in the traps
than previously caught when the traps were set randomly in the habitat. A total of 147 specimens
were collected from these pitfalls, including 64 males, 37 females, and 46 immatures. The months
of December to April were not sampled on a regular basis because the specimens were not found
in the cooler months of the year, seemingly related to the inactivity of the ants.

From 9-12 June 2015, RE.C., N.V.H., and two students excavated two Novomessor albisetosis
(Mayr) nests near Alamo Spring (N 29.555", W 103.785°, elevation 1137 m). The nest sites were
in the South Fork of the Alamo de Cesario Creek, which normally is a dry creek bed, but may
contain a large amount of water with rains of an inch or more. These nests of N. albisetosis were
unlike those of Pogonomyrmex, which occur in more stable soils, in that the nest chambers did
not branch off a single centralized underground runway, as is characteristic of the nests of many
seed harvesting ant species. Rather, in N. albisetosis habitat, underground rocks ranging in size

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5

from 10 kg down to pea size forced the ants to spread the nest chambers out from a generally
central area in a more horizontal fashion. Visual observations were made in the ant chambers
using a flashlight, the loose contents taken from the nest were screened through a 6.25 mm wire
mesh screen onto a white cloth, and organisms picked from the cloth with a camel hair brush.

SYSTEMATICS

The analysis of the sequence data partition (fig. 1) recovered the main clades of entelegyne
spiders as in the comprehensive analyses of target sequence data by Wheeler et al. (2017). This
is expected, as the analysis is based on the same data with the addition of sequences of M.
chihuahuensis. The main clades are also compatible with the new analysis of transcriptomic
data by Fernandez et al. (2018). According to this analysis, M. chihuahuensis belongs to the
RTA clade, sister to the Oval Calamistrum clade plus Dionycha.

The analysis of the morphological partition (fig. 2A) did not recover many of the higher
groups, accentuating the problems found in the morphological analysis of Ramirez (2014),
probably due to the shallow taxon sampling. In particular, the Oval Calamistrum clade and the
sparassids all fall within dionychans, and Penestomus is far from zodarioids. The morphological
data place M. chihuahuensis close to zodarioids, but with low support. As expected by the
disorienting morphology of M. chihuahuensis, no clear family assignation arises from this data
partition. The analysis of the combined data partitions (fig. 2B) basically reproduced the larger
sequence data partition.

Given that the independently obtained transcriptomic data (Garrison et al., 2016; Fernan¬
dez et al., 2018) largely agrees with our target sequence analysis, the molecular data partition
appears to be a more reliable indicator of relationships in this dataset, compared to the mor¬
phology partition. Our phylogenetic analysis indicates that M. chihuahuensis is a member of
the RTA clade, but it is not nested in any of its main groups, namely the dionychans, the Oval
Calamistrum clade, or the zodarioids. For this reason, we create a new family.

The four putative morphological synapomorphies grouping M. chihuahuensis with
Dionycha + the Oval Calamistrum clade are rather unconvincing: patellar indentation I—II
width: narrow; apical ventral tarsal cuticle sclerotization: entire sclerotized; inferior tarsal claw
I: absent; cymbium dorsal chemosensory patch: present (chars. 108, 131, 134, and 324 of
Ramirez, 2014). All present several reversals and convergences in other taxa (consistency indi¬
ces of 0.20, 0.09, 0.17, and 0.10, respectively). In particular, the absence of the inferior claw in
M. chihuahuensis is probably an independent loss, because several members of the Oval
Calamistrum clade possess three claws.

Myrmecicultoridae Ramirez, Grismado, and Ubick, new family
Type Genus. Myrmecicultor, new genus.

Diagnosis. Ecribellate entelegyne with two tarsal claws, without claw tufts, males with
retrolateral palpal tibial apophysis, six spinnerets in a group, and female palpal claw well devel-

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oped. It resembles zodariids in the procurved eye rows and the short posterior lateral spinner¬
ets, but can be distinguished by having a serrula on the endites and the major ampullate gland
spigots situated laterally rather than centrally It resembles prodidomines in the procurved pos¬
terior eye row and the obliquely oriented tapetum on the posterior median eyes, but can be
distinguished from those by having unmodified piriform gland spigots without flanking setae.

Myrmecicultor Ramirez, Grismado, and Ubick, new genus
Type Species. Myrmecicultor chihuahuensis, new species.

Etymology. The generic name is a combination of myrmex (ancient Greek for “ant”) and
cultor (Latin for worshiper, follower), and refers to the association between these spiders and
their host ants. Gender masculine.

Diagnosis. By the characters of the family.

Description. See under the species description.

Myrmecicultor chihuahuensis Ramirez, Grismado, and Ubick, new species

Figures 1-12, map 1

Cf. Gnaphosoidea TEX, Ramirez, 2014 (provisional name in phylogenetic analysis).

Types. Male holotype (CAS 9067289; temporary preparations CJG-1504, 1508), from the
United States: Texas, Brewster Co., Dalquest Desert Research Station (DDRS), Big Sandy #4, N
29°33'05.7", W 103°47'38.3", 1232 m, Oct. 16-Nov. 1, 2014, N.V. Horner, propylene glycol
pitfall traps, in 100% ETOH. Male and female paratypes (CAS 9067288), DDRS, Big Sandy #3,
N 29°33'04.2", W 103°47'38.3", elev. 1232 m, Sept. 24-Oct. 15, 2014, N.V. Horner, in 100%
ETOH. Female paratype (CAS 9067293; temporary preparation CJG-1505), DDRS, below
Alamo #4, N 29°33'20.00", W 103°47'04.7", 1143 m, Oct. 16-Nov. 1, 2014, N.V. Horner, pro¬
pylene glycol pitfall traps, in 100% ETOH. Female paratype (AMNH [ARANP19], temporary
preparations CJG-620, 632, MJR-1382-1383), DDRS, Sandy Canyon Sept. 22-Oct. 4, 2005,

N. V. Horner and G.H. Broussard, pitfall covered, in propylene glycol.

Etymology. The specific epithet is an adjective referring to the Chihuahuan Desert, where
most specimens were collected.

Diagnosis. By the characters of the family.

Male (holotype): Total length 2.89. Carapace length 1.47, width 1.20. Clypeus 0.26 (at AME),

O. 19 (at ALE). Eye sizes and interdistances: AME 0.13, ALE 0.10, PME 0.13, PLE 0.09, AME-AME
0.06, AME-PME 0.08, AME-ALE 0.02, PME-PME 0.03, PME-PLE 0.07, ALE-PLE 0.02, AER
0.39, PLE-PLE 0.03, PER 0.43. Leg lengths: Leg I: total 4.70 (femur 1.55, patella 0.56, tibia 1.32,
metatarsus 1.27, tarsus broken); Leg II: 4.98 (1.32 0.56 1.10 1.18 0.78); Leg III: 4.43 (1.19 0.49 0.97
1.13 0.65); Leg IV: 5.70 (1.47 0.56 1.29 1.55 0.83). Leg formula 4123. Color in alcohol: Carapace
whitish, black in eye region; sternum whitish. Abdomen uniformly whitish both dorsally and
ventrally. Legs also whitish, but distal podomeres slightly darker. Live specimens darker, with pale

Segestriidae: Ariadna boesenbergi
Hypochilidae: Hypochilus pococki
— Filistatidae: Filistata insidiatrix

2019

RAMIREZ ET AL.: NEW FAMILY OF MYRMECOPHILIC SPIDERS

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0

o

.<2 -3

K

<UCD r?

CDCD'->
TJr
= 0
50
2d.

Q)

T3

csi

o

FIG. 1. Phylogenetic tree obtained from the Bayesian analysis of sequence data from six markers in the mitochondrial (12S rDNA, 16S rDNA,
cytochrome oxidase subunit I) and nuclear (histone H3, 18S rDNA, 28S rDNA) genomes. Circles on nodes indicate support values.

AMERICAN MUSEUM NOVITATES

NO. 3930

Hypochilidae: Hypochilus pococki

Filistatidae: Filistata insidiatrix
Huttoniidae: Huttonia sp. CGI66
Segestriidae: Ariadna boesenbergi
Eresidae: Eresus walckenaeri
— Oecobiidae: Oecobius cellariorum

Araneidae: Araneus diadematus
Mimetidae : Mimetus banksi

Megadictynidae: Megadictyna thilenii

Austrochilidae: Thaida peculiaris
Uloboridae: Uloborus glomosus

Penestomidae: Penestomus egazini
Titanoecidae: Titanoeca sp. CG64
Amaurobiidae: Pimus ivei
Stiphidiidae: Stiphidion facetum

Desidae: Badumna longinqua

jackknifing
• 0.75-1
O 0.60-0.74

Desidae: Metaltella sp. CG23

Myrmecicultoridae: Myrmecicultor chihuahuensis

Homalonychidae: Homalonychus theologus
Zodariidae: Cybaeodamus ornatus
Zodariidae: Cyrioctea spinifera
Corinnidae: Falconina gracilis
Viridasiidae: Vulsor sp. CG29

Miturgidae: Miturga lineata

Psechridae: Psechrus sp. CG75

Zoropsidae: Zoropsis spinimana
Sparassidae: Polybetes pythagoricus
Thomisidae: Stephanopis ditissima
Ctenidae: Ctenus crulsi

Cycloctenidae: Cycloctenus sp. CG98
Pisauridae: Dolomedes tenebrosus
Oxyopidae: Oxyopes salticus
Senoculidae: Senoculus cfiricolor
Eutichuridae: Cheiracanthium sp. MR366
Anyphaenidae: Anyphaena accentuata
— Philodromidae: Philodromus aureoius
Salticidae: Plexippus paykulli

Phrurolithidae: Otacilia sp. MR81
Trachelidae: Meriola barrosi
Gnaphosidae: Gnaphosa lucifuga
Prodidomidae: cf. Tricongius sp. ARG NP18M-R16
Prodidomidae: Molycria broadwater
Prodidomidae: Myandra bicincta
Prodidomidae: Eleleis sp. MR738

Prodidomidae: Neozimiris pubescens
Prodidomidae: Prodidomus rufus

FIG. 2. A. Phylogenetic tree obtained from the parsimony analysis of morphological data under implied
weights; the tree shown under concavity constant k = 12 is also the majority-rule consensus of trees obtained
with values of k between 3 and 30. B. Phylogenetic tree obtained from the Bayesian analysis of sequences and
morphological data. Circles on nodes indicate support values.

brown coloration (fig. 1 IF). Vestiture: Carapace almost glabrous, chelicerae with few needlelike
setae at promargin. Sternum with marginal setae, some setae on posterior extension. Abdomen
dorsum with two types of setae, mostly needlelike, with some thickened setae scattered irregu¬
larly; appendages densely clothed with thick setae, but with few spines (see below); metatarsi III

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B

-Hypochilidae: Hypochilus pococki
— Filistatidae: Filistata insidiatrix

•Austrochilidae: Thaida peculiaris

L- C

• Huttoniidae: Huttonia sp. CGI66

Oecobiidae: Oecobius cellariorum

Titanoecidae: Titanoeca sp. CG64

• Megadictynidae: Megadictyna thilenii
Araneidae: Araneus diadematus

Mimetidae: Mimetus banksi

- Eresidae: Eresus walckenaeri

Uloboridae: Uloborus glomosus
Homalonychidae: Homalonychus theologus
Penestomidae: Penestomus egazini
Zodariidae: Cybaeodamus ornatus
Zodariidae: Cyrioctea spinifera
Amaurobiidae: Pimus ivei

Cycloctenidae: Cycloctenus sp. CG98
Stiphidiidae: Stiphidion facetum
Desidae: Badumna longinqua
Desidae: Metaltella sp. CG23

Myrmecicultoridae: Myrmecicultor chihuahuensis
Zoropsidae: Zoropsis spinimana
Ctenidae: Ctenus crulsi

Psechridae: Psechrus sp. CG75
Thomisidae: Stephanopis ditissima
Pisauridae: Dolomedes tenebrosus
Oxyopidae: Oxyopes salticus
Senoculidae: Senoculus cfiricolor
Sparassidae: Polybetes pythagoricus

Prodidomidae: cf. Tricongius sp. ARG NP18M-R16
Prodidomidae: Chilongius palmas frayjorge
Prodidomidae: Neozimiris pubescens
Prodidomidae: Eleleis sp. MR738
Prodidomidae: Prodidomus flavipes
Prodidomidae: Prodidomus rufus
Corinnidae: Falconina gracilis
Miturgidae: Miturga lineata
Viridasiidae: Vulsorsp. CG29

Eutichuridae: Cheiracanthium sp. MR366
Philodromidae: Philodromus aureolus
Salticidae: Plexippus paykulli
Anyphaenidae: Anyphaena accentuata
Trachelidae: Meriola barrosi

Phrurolithidae: Otacilia sp. MR81
Gnaphosidae: Gnaphosa lucifuga
Prodidomidae: Myandra bicincta
Prodidomidae: Molycria broadwater
Prodidomidae: Molycria sp. MR670

post. prob.
0.95-1
0.90-0.94

0.2

and IV with distal preening brush of plumose setae. Carapace broadly oval in dorsal view, highest
in front of fovea; thoracic fovea narrow, dark longitudinal line. Eyes mostly surrounded by black
pigment, contrasting sharply with pale carapace (fig. 4D); AME largest, most convex, lateral eyes
subequal, partly surrounded by black pigment, PME nearly rectangular, with oblique tapeta at
90° angle. AER procurved in dorsal view, PER strongly procurved in dorsal view; both eye rows
procurved in anterior view. Clypeus high, about twice ALE diameter (fig. 4C). Chelicerae as in
female. Sternum heart shaped, anteriorly truncate, with posterior pointed extension between

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coxae IV, with marginal setae. Precoxal triangles absent. Labium trapezoidal, wider than long;
endites quadrate, with serrula on anterior margin. Abdomen lacking dorsal scute. Epiandrum
with two spigots (observed in KOH-digested specimen). Respiratory system consisting of two
book lungs and wide tracheal spiracle slightly separated from spinnerets, giving origin to four
simple, unbranched tracheae, all limited to abdomen, gradually attenuated. Spinnerets superfi¬
cially as in female, but not examined with SEM; PMS apparently lacking spigots (as observed with
stereomicroscope). Leg spines: I: femur dl-1-0, pl-0-0, metatarsus v2ap; II: femur 1-1-0, pi (very
small)-0-0, metatarsus v2ap; III: femur dl-1-0, tibia v2ap, metatarsus v2ap (below preening
brush); IV: femur dl-1-0, tibia v2ap, metatarsus v2ap (below preening brush). Palp: femur with
1-1 dorsal macrosetae, lacking ventral process; tibia cup shaped, with RTA forming procurved
concavity with retrolateral dorsal small, pointed protrusion; cymbium with dorsoapical patch of
chemosensory setae (fig. 9G) situated in a cavity, dorsal surface with widened bipectinate setae
(probably scales) (fig. 9F), and seven trichobothria in two longitudinal rows. Copulatory bulb:
subtegulum simple, visible from retrolateral side; tegulum simple bearing spermophore without
loops; median apophysis articulated, small hook in retrobasal position; two conductors (Cl and
C2; figs. 9D, 10D), latter larger than former, more sclerotized, coiled, anteriorly directed. Embolus
articulated, bent at right angle to retrolateral side; tip widened.

Female (paratype CAS 9067293): Total length 2.73. Carapace length 1.26, width 1.09. Clyp-
eus 0.13 (at AME), 0.07 (at ALE). Eye sizes and interdistances: AME 0.14, ALE 0.09, PME 0.12,
PLE 0.09, AME-AME 0.05, AME-ALE almost touching, AME-PME 0.06, PME-PME 0.02, PME-
PLE 0.06, ALE-PLE 0.03, AER 0.37, PER 0.41. Palpus and leg lengths: Palpus: 1.35 (0.39 0.21 0.29
0.46); Leg I: 4.86 (1.33 0.51 1.14 1.09 0.79); Leg II: 4.27 (1.12 0.45 0.97 1.02 0.71); Leg III: 3.91
(1.03 0.40 0.84 1.03 0.61); Leg IV: 5.04 (1.28 0.49 1.16 1.35 0.75). Leg formula 4123. Leg spines:
Palp: tarsus dl-1; I: femur dl-1-0, pi (very small)-0-0; metatarsus vlap; II: femur 1-1-0; meta¬
tarsus vlap; III: femur dl-1-0, metatarsus vlap (below preening brush); IV: femur dl-1-0, tibia
vlap, metatarsus vlap (below preening brush, fig. 6B). Tarsal organ (observed on leg II) as simple
pit, not domed (fig. 7C). Patellar indentation narrow, leading to retrolateral lyriform organs (fig.
7A). Tarsal step opposing metatarsal sensory organ with irregular, mainly longitudinal ridges (fig.
6G). Two tarsal claws, pectinate, without claw tuft or any other adhesive setae (fig. 6E, F); only
two large setae with many barbs oriented distally, but without expanded tips. Trichobothrial shaft
with expanded base covered by bumps, hood with several proximal transverse ridges (fig. 7B),
on single row on leg tarsi. Palpal claw well developed, with teeth, tarsus apically with dorsal cavity
containing a patch of chemosensory setae (fig. 5F, G). Color and general morphology (fig. 3) as
in male. Vestiture as in male, widened bipectinate setae as that of male cymbium present on
prolateral sides of palpal tibia and tarsus. Chelicerae slightly expanded anteriorly, anterior surface
(fig. 5B, D) with row of rake setae and row of whisker setae parallel to fang, one promarginal
whisker seta large (the promarginal escort seta), weak promarginal mound in front of fang base,
promargin with one very small tooth (seen in male digested with KOH), retromargin without
teeth, retromarginal escort seta present (socket observed, fig. 5E). Cheliceral fang very long, fal¬
cate, flat, with shaft serrula, venom duct opening present (fig. 5B-E). Genitalia: epigynum as
single sclerotized plate with unpaired, shallow median concavity (fig. 3E). Posterior margin sinu-

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ous, with two rounded cavities (fig. 10F). Copulatory openings not visible, probably near central
depression. Copulatory ducts fused anteriorly, with tortuous lumen, leading to simple sperma-
thecae, copulatory duct and spermatheca together in uniformly sclerotized, solid piece (fig. 10F).
Spinnerets small, clustered together, arising from slightly projecting base (fig. 8). ALS with basal
articles conical, adjacent to each other, distal articles crescent-shaped, sclerotized, ectal area with
setae (fig. 8C); seven piriform gland spigots tightly grouped, with shafts well defined from base,
two major ampullate gland spigots with shafts larger than those of piriforms; no setae associated
with piriform bases. PMS, PLS much shorter than ALS. PMS conical, with single spigot with thick
shaft, probably cylindrical gland spigot. PLS with basal spigot with thick shaft, probably cylindri¬
cal gland spigot, and four smaller ones, probably aciniform gland spigots.

Additional Material Examined. MEXICO: Coahuila: Municipio de Cuatrocienegas de Car¬
ranza: Cuatrocienegas Protected Area, ca. 9.7 km S Cuatrocienegas, N 26°54'31.896", W
102°07'6.718", Sep. 23, 2011, D.C. Lightfoot, 3d (MSBA 51822). Aguascalientes: Municipio de
Tepazald: 12 km (7.5 mi) N Tepezala, Aug. 30,1965, W. Gertsch, R. Hastings, 3d (AMNH; discov¬
ered by N.I.P. in May of 2019 while sorting unidentified specimens). U.S.A.: Texas: Hudspeth Co.:
Indio Mountains Research Station (UTEP), N 30°46'34.7", W 105°01'09.3", Jul. 28-Aug. 30, 2017,
N.V. Horner, 3d, 1 juv. (CAS 9063001). Presidio Co.: Big Bend Ranch State Park: Ojito Adentro, N
29°29.5', W 104°03.7', Oct. 14, 2000, under rock, P.W. Hyder, 3 9 (AMNH 1256). DDRS Camp, N
29°33'25.91", W 103°47'37.95", 1266 m (4154 ft), propylene glycol pitfall trap [PGPT], G.H. Brous¬
sard: Sep. 5,1999,1 d (AMNH); Sep. 15,2000,19 (AMNH). White Canyon Rd. #6, N 29°33'46.9",
W 103°48'03.2", 1273 m (4177 ft), PGPT, N.V. Horner: Aug. 15-Sep. 9,2015,1 d (MSU); Oct. 4-20,
2015, 19 (MSU). Brewster Co.: Below Alamo Springs, N 29°33'15.6", W 103°47'08.4" to N
29°33'17.8", W 103°47'11" to N 29°33'20", W 103°47'04.7", 1121-1158 m (3742-3798 ft), PGPT,
N.V. Horner: May. 30-Jun. 30,2014, 8 juv. (MSU), 7 juv. (CAS 9067292); Jul. 18-Aug. 17, 2012,4d
(CAS 9076507); Jul. 4-Aug. 12, 2013, 3 juv. (CAS 9067290, 9067291); Jul, 30-Sep. 2, 2014, 7d
(MSU); Aug. 15-Sep. 9, 2015, 3d (MSU); Aug. 24-Oct. 1, 2016, 3d, 19 (MACN-Ar 38650), Id
(MACN-Ar 38649); Sep. 2-27, 2007, 1 d (AMNH); Sep. 21-Oct 6, 2007, 19 (CAS 9076536); Sep.
14-Oct. 9, 2010, 19 (CAS 9076511); Sep. 10-Oct. 3, 2015, 8d, 3 9 (MSU); Oct. 7-Nov. 5, 2012,
Id, 19 (CAS 9076528); 19 (CAS 9076530); Oct. 16-Nov. 1, 2014, 19(CAS 9067293); Oct. 21-
Nov. 21, 2015, 2 9 (MACN-Ar 38651, 38663); Main Canyon, N 29.55512°, W 103.78561°, 1137 m,
inside ant nest, P.E. Cushing, N.V. Horner, K. Sanko, C. Dowling, 10-11 Jun 2015, Id (DMNS
ZA.40328), 11 Jun 2015, 1 juvenile (DMNS ZA.40329); same, N 29.55506°, W 103.78536°, 12 Jun
2015 (DMNS ZA.40330). Brewster and Presidio Counties: Sandy Canyon, [N 29°33'07", W
103°47'36", 1215 m (3988 ft)], PGPT, G.H. Broussard: Oct. 7, 1999, 2d (AMNH); Sep. 15, 2000,
2d, 19 (CAS 9076539, d used for SEM); Big Sandy Canyon, N 29°33'07.38", W 103°47'37.51" to
N 29°33'01.2", W 103°47'38.1", 1207-1260m (3960-4133 ft), PGPT, N.V. Horner: May. 23-Jun. 16,
2010, 1 juv. (CAS 9076513, Id used for SEM); May. 30-Jun. 30, 2014, Id, 19,4 juv. (MSU); Jun.
27-Jul. 13, 2009, 1 juv. (AMNH); Jun. 17-Jul. 22, 2010, 1 juv. (CAS 9076510); Jun. 14-Jul. 9, 2011,
1 juv. (CAS 9076519); Jun. 21-Jul. 17, 2012, 6 juv. (CAS 9076522, 9076526); Jun. 25-Jul. 24, 2016,
4 juv. (MSU); Jul. 14-Aug. 22, 2009,4d (AMNH); Jul. 23-Aug. 10,2010,2 juv. (CAS 9076512); Jul.
10-Aug. 12,2011,1 juvenile (CAS 9076532); Jul. 18-Aug. 17,2012,3d (CAS 9076516), Id, 19,3

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FIG. 3. Myrmecicultor chihuahuensis, new species, female structures. A. Habitus, dorsal view. B. Same, ventral
view. C. Prosoma, ventral view. D. Same, anterior view. E. Epigyne, ventral view. (A-D, paratype CAS 9067293;
E, AMNH [ARANP19]).

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FIG. 4. Myrmecicultor chihuahuensis, new species, male structures. A. Habitus, dorsal view. B. Prosoma, dorsal
view. C. Same, anterior view. D. Eyes, dorsal view. E. Right palp, mirrored image, prolateral view. F. Same,
ventral view. G. Same, retrolateral view. (A-D, holotype; E-G, CAS 9076539).

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FIG. 5. Myrmecicultor chihuahuensis, new species, female structures. A. Eyes, dorsal view. B. Left chelicera,
anterior view. C. Same, posterior view. D. Same, detail of promarginal setae and fang, anterior view. E. Fang
and retromargin, posterior view, arrow to socket of retromarginal escort seta. F. Palpal tarsus tip, dorsal apical
view, arrow to patch of chemosensory setae. G. Same, detail of claw and chemosensory setae. Abbreviations:
Ch = chemosensory seta; FgS = fang shaft serrula; PEs = promarginal escort seta; Rk = promarginal rake seta;
Wh = cheliceral whisker seta.

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FIG. 6. Myrmecicultor chihuahuensis, new species, female structures. A. Left tarsus II, dorsal view, white
arrows point to trichobothrial sockets, black arrow to tarsal organ. B. Same, retrolateral view. C. Metatarsus
II, dorsal view, white arrows point to trichobothrial sockets. D. Tip of metatarsus III showing preening brush.
E. Left claws II, apical view. F. Same, retrolateral apical view, inset to barbs of setae, showing unexpanded tips.
G. Metatarsus-tarsus II articulation, arrow to irregular longitudinal ridges on tarsal step. H. Tibia-metatarsus
II articulation.

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FIG. 7. Myrmecicultor chihuahuensis, new species, female structures of left leg II. A. Patella, retrolateral view.
B. Trichobothrium on metatarsus. C. Tarsal organ and slit sensilla. D. Chemosensory seta on metatarsus.
Abbreviations: Pin = patellar indentation; Ly = lyriform organ; TO = tarsal organ; SS = slit sensillum.

juv. (CAS 9076518); Jul. 30-Sep. 3, 2014, 2 juv. (MSU); Aug. 15-Sep. 3, 2006, 1$ (MSU); Aug.
29-Sep. 19, 2008, 1? (CAS 9076523); Aug. 10-28, 2010, 3 c? (MSU); Aug. 29-Sep. 13, 2010, 1$
(MSU); Aug. 13-Sep, 14, 2011, 2c?, 19 (CAS 9076533, 9076540, 9076537); Aug. 24-Oct. 1, 2016,
1c? (MSU), 1 $ (MACN-Ar 38636); Sep. 22-Oct. 4,2005,1 $ (AMNH); Sep. 26-Oct 10,2006,19
(MSU); Sep. 28-Oct. 9, 2008, 1? (CAS 9076535); Sep. 19-27, 2008, 28 (CAS 9076538); Sep. 14-
Oct. 9, 2010, 28, 2 9 (CAS 9076509, 9076514, 9076517); Sep. 15-Oct. 19, 2011, 18, 2 9 (CAS
9076520, 9076525, 9076527); 24 Sep-15 Oct 2014, 48, 1 juv. (MSU), 18, 19 (CAS 9067288); 9
Oct-2 Nov 2008, 1 8, 2 9 (AMNH); 4-14 Oct 2009, 19 (AMNH); 6 Oct-5 Nov 2012, 4 9 (CAS
9076521, 9076529,9076534); 16 Oct-1 Nov 2014,1 8 ,19 (DMNS ZA.40327), 1 8 (CAS 9067289).

Distribution. Known only from the Big Bend region (Presidio, Brewster and Hudspeth
counties) of Texas, and in Mexico from Cuatro Cienegas, Coahuila, and Tepezala, Aguascali-
entes (map 1).

NATURAL HISTORY

Specimens of M. chihuahuensis were associated with three species of harvester ants, Pogono-
myrmex rugosus, Novomessor albisetosis, and Novomessor cockerelli (Andre). In DDRS, the most
abundant host species was N. albisetosis, which to date is the only species of harvester ant found
in the dry creek bed of the South Fork of the Alamo de Cesario Creek. Pogonomyrmex rugosus

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FIG. 8. Myrmecicultor chihuahuensis , new species, female spinnerets. A. Spinnerets, ventral-posterior view.
B. Right ALS. C. Left ALS, arrows to sclerotized ectal area of distal article, bearing setae. D. Left PMS. E.
Right PMS. F. Right PLS. G. Left PLS. Abbreviations: Ac = aciniform gland spigot; ALS = anterior lateral
spinneret; Cy = cylindrical gland spigot; MaAm = major ampullate gland spigot; Pi = piriform gland spigot;
PLS = posterior lateral spinneret; PMS = posterior median spinneret.

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FIG. 9. Myrmecicultor chihuahuensis, new species, male left palp (CAS 9076539). A. Prolateral view. B. Same,
retrolateral-ventral view. C. Same, ventral view. D. Same, detail of copulatory bulb, retrolateral-ventral view.
E. Same, dorsal view. F. Same, detail of setae (probably scales). G. Tip of cymbium, detail of apical patch of
chemosensory setae. H. Tibia and RTA, dorsal view. Abbreviations: Cl, C2 = conductors; E = embolus; MA
= median apophysis; T = tegulum.

and N. cockerelli were the hosts at higher elevations, where there was less moisture and a coarser
soil type. The specimens collected in Hudspeth County were collected from the Indio Mountain
Research Station operated by the University of Texas at El Paso. The host ant at this site was N.
cockerelli. The specimens collected in Cuatrocienegas were on the surface of a P. rugosus nest. Two
M. chihuahuensis were collected from one nest excavation pit and one from the other excavation
pit. Because of the uncommon underground structure of these nests, it was not possible to deter¬
mine whether the spiders were living inside nest chambers, although it is likely that they were.

DDRS Ant Habitats

The site known as White Canyon Road leads to the edge of the canyon, N 29°33'47.6" W
103°48'09.8", at an elevation of 1272 m where the ant N. cockerelli was found and only two
spiders were collected. Dominant vegetation at this site included creosote bush (. Larrea triden-
tata), cat claw ( Acacia neovernicosa), and lechuguilla ( Agave lechuguilla ). The soil was poor,
mostly desert pavement.

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FIG. 10. Myrmecicultor chihuahuensis, new species, genitalia. A. Left male palp, prolateral view. B. Same,
ventral view. C. Same, retrolateral view. D. Same, detail of copulatory bulb, cleared. E. Female genitalia, ventral
view, cleared. F. Same, dorsal view. (A-E, CAS 9067289; E-F, AMNH [ARANP19]). Abbreviations: Cl, C2 =
conductors. CD = copulatory duct; E = embolus; FD = fertilization duct; MA = median apophysis; RTA =
retrolateral tibial apophysis; S = spermatheca; St = subtegulum; T = tegulum.

An area known as the Camp Site was next to the canyon edge, N 29°33'25.2" W 103°47'33.5",
at an elevation of 1276 m. This was the primary site for the ant P. rugosus. Few spiders were
collected from this site. The dominant vegetation was creosote bush (Larrea tridentate), tarbush
(Vachellia vernicosa), and lechuguilla ( Agave lechuguilla). Some soil was present with mixed
desert pavement.

The creek bed in the canyon, N 29°33'18.8" W 103°47'08.4", at an elevation of 1118.6 m,
was the primary site for the ant N. albisetosis. The vast majority of the spiders were collected
near nests of this species. This site was characterized by mixed vegetation dominated by

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FIG. 11. Nests and habitats of harvester ants and Myrmecicultor chihuahuensis, new species A. South Fork of
Alamo De Cesario Creek. B. Dry creek (1118 m), habitat of Novomessor albisetosis which requires adequate
moisture and soil depth. C. Habitat of Novomessor cockerelli (1272 m), which requires sparse vegetation and
less moisture. D. Mound nest of Pogonomyrmex rugosus (1276 m), soil mixed with desert pavement (small
stones) and limited moisture. E. Nest of P. rugosus with 10 specimens of M. chihuahuensis (arrows). F. Same
nest, spiders beside a host worker of P. rugosus; inset to a female. G. Excavation of N. albisetosis nest. (E-F,
photos by D. Lightfoot, University of New Mexico).

desert willow ( Chilopsis linearis ), desert walnut ( Juglans major), false willow or Roosevelt
weed ( Baccharis salicina), and scattered oak (Quercus sp.) The soil was composed of loose
sand dropped by running water in the creek bed, mixed with small to large stones.

The symbiotic relationship between the spider and the three species of harvester ants
is not known at present. Observation proves that the spider is not a mimic of the ant, and
the ant appears to tolerate the spider. Based on size difference, it appears the spiders do
not feed on the adult ants. Larval myrmecophagy is a possibility, but doubtful. The biology
of this myrmecophilic spider may be similar to that of the linyphiid Masoncus pogonophi-
lus Cushing that inhabits the nest chambers of the harvester ant, Pogonomyrmex badius

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FIG. 12. Phenology of Myrmecicultor chihuahuensis, new species, including all collection records. All but 12
(labelled “o”) of the 159 specimens collected are from the Dalquest Desert Research Station (DDRS) and,
except for those excavated from an ant nest (“x”), were collected in pitfall traps. Juvenile specimens (i) are
indicated in orange, males (m) in blue, and females (f) in red. Intermonth records are from trap runs that
spanned two months, where each month contained at least 20% of the trap days. For example, results of a trap
from 14 September to 9 October are recorded as intermonth, whereas one from 7 October to 5 November is
recorded as October.

(Latreille), where it feeds on other small nest symbionts such as Collembola (Cushing,
1995, 1998).

The DDRS collection data suggest that the spiders come to the surface after a rain.
Since precipitation records began in 2007, 131 spiders were collected shortly after rain. In
contrast, only two juvenile spiders were collected—one in July of 2009 and one in June of
2011—without a close rain event being recorded. We suspect the spiders come to the sur¬
face synchronously with alate reproductive ants, which also are common on the surface
after rain. Do the spiders come to the surface on their own, or do the worker ants bring
them to the surface? The answer is unknown.

Phenology

As this spider is associated with the harvester ants, P. rugosus, N. albisetosis, and N. cockerelli,
it was collected when the ants were most active (fig. 12), i.e., May to November. Of the 159 spiders
collected, 48 were juveniles, 71 males, and 40 females. The immatures first appeared, followed by
males, then females. May was the earliest record of a single juvenile, and one late season immature
was collected in September. 91% of juveniles were collected in June and July. The majority, 99%,

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MAP 1. Known localities of Myrmecicultor chihuahuensis, new species, plotted on a political map of North
America (A) and three topographic maps (B-D) at increasing magnifications, as indicated by the rectangular
boxes, with D showing the most densely sampled sites at the DDRS. The vertical line in C and D is the Pre¬
sidio/Brewster County border.

of the males appeared between mid-July and October, with one male appearing in June. Of the
females, 85% were collected during September and October, with the earliest in June and two in
November. These data are based on trap samples that could be sorted. Some trap samples were
lost due to heavy rainfall, which diluted the propylene glycol and washed sediment into the traps.
Males mature about a month before the females (fig. 12). Certainly, overlap occurs, but immatures
appear first, then males, followed by the females. Based on this information, the males and
females do not overwinter. The juveniles probably overwinter and start their development before
the ants become active in the spring. If so, they are feeding on something in the ant nest.

ACKNOWLEDGMENTS

We thank Greg Broussard (New Mexico Community College) for initially finding the new
spider. Sandra Brantley and David Lightfoot (University of New Mexico), for making the asso¬
ciation with harvester ants, Jerry Johnson (University of Texas El Paso) for granting permission
to collect on Indio Mountain Research Station, Dave Richman and Paul Hyder (New Mexico
State University) for finding specimens in Big Bend Ranch State Park, James Cokendolpher
(Texas Tech University) and Allen Dean (Texas A & M University) for help searching for the
spider. David Lightfoot provided photographs of living specimens. William Cook of Midwest¬
ern State University identified plants. Christin Smith and Katie Sanko helped P.E.C. with exca-

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vation of ant nests (funding for this fieldwork from the DMNS Teen Science Scholars fund).
Guilherme Azevedo (MACN) assisted with the phylogenetic analysis. Thanks also go to Robert
Johnson (Arizona State University) for identifying the ants and to Brian Fischer (California
Academy of Sciences) for providing the contact. Robert Raven and Alexandre Bonaldo pro¬
vided useful comments to improve the manuscript. West Texas fieldwork in search of these
spiders in 2005 was funded by the Peter J. Solomon Family Research Fund (AMNH). This study
was funded by grants FONCyT PICT 2015-0283 to M.J.R. and NSF EAR-0228699 to W.C.W.

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