Two new species of the arachnid order Schizomida, Rowlandius ubajara sp.nov. and Rowlandius potiguar sp.nov., are described based on both male and female specimens collected in caves from northeastern Brazil. Rowlandius ubajara is known only from the Ubajara Cave, in the state of Ceará; R. potiguar is recorded from 20 caves of the Apodi Limestone Group, in the state of Rio Grande do Norte. A remarkable dimorphism in male pedipalp length is described and analyzed in R. potiguar. The distribution of male pedipalp length is clearly bimodal in the species, but the two male morphs (homeomorphic and heteromorphic) present some overlap in the sizes of this structure. Moreover, males show a steeper allometry in pedipalp length than females, indicating that this trait is under a different selective regime in males and in females.
Citation: Santos AJ, Ferreira RL, Buzatto BA (2013) Two New Cave-Dwelling Species of the Short-Tailed Whipscorpion Genus Rowlandius (Arachnida: Schizomida: Hubbardiidae) from Northeastern Brazil, with Comments on Male Dimorphism. PLoS ONE 8(5): e63616. https://doi.org/10.1371/journal.pone.0063616
Editor: Donald James Colgan, Australian Museum, Australia
Received: November 4, 2012; Accepted: April 3, 2013; Published: May 22, 2013
Copyright: © 2013 Santos et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: This study was financially supported by grants from Conselho Nacional de Desenvolvimento Cientifico e Tecnologico(CNPQ) (www.cnpq.br; Procs. 300498/2009–8), FAPEMIG (PPM-00553-11) and Instituto Nacional de Ciência e Tecnologia dos Hymenoptera Parasitóides da Região Sudeste Brasileira (http://www.hympar.ufscar.br) to AJS and CNPq (www.cnpq.br; procs. 477712/2006-1) to RLF. BAB was supported by the University of Western Australia through an International Postgraduate Research Scholarship (http://www.scholarships.uwa.edu.au/search?sc_view=1&id=454&page=1&q=IPRS&s=1&old_key=0). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
The arachnid order Schizomida, the short-tailed whipscorpions, is represented in South America mainly in northern forested areas. Besides its great diversity and broad distribution in Central America and the West Indies, in the continental South America it can be considered a poorly-known Amazonian group. Until very recently, the only species known from southern parts of the subcontinent was Stenochrus portoricensis Chamberlin, 1922 , , a widespread and synanthropic species. However, the scarcity of schizomid species outside the Amazonian forest can be attributed, at least in part, to collecting bias. This happens because schizomids occur mostly in poorly sampled habitats, like the soil leaf litter, termite and ant nests, and caves , . Subterranean habitats in particular can harbor large schizomid populations , and are a promising source of undescribed species.
Among South American countries, Brazil is known for its abundance of caves, which are scattered in several geological formations . Despite the richness of cave habitats, the Brazilian subterranean fauna is mostly unknown , though it is currently attracting the interest of many biologists.
The genus Rowlandius Reddell and Cokendolpher, 1995, the focus of this study, is a good example of how little is known about the schizomids and the cave fauna of Brazil. The majority of the 54 species of the genus , , , , ,  occur in Caribbean islands, mainly Cuba, Jamaica and Hispaniola (see for instance , , , , ). The genus is represented in continental South America by one species in Venezuela (R. arduus Armas, Villareal & Colmenares, 2009), one in the eastern Brazilian Amazonia (R. sul Cokendolpher & Reddell, 2000) and another, recently described species from the northeastern Brazilian Atlantic Forest (R. linsduarteae Santos, Dias, Brescovit & Santos, 2008) . In this study, two new species are described based on specimens collected in cave habitats in northeastern Brazil. Most caves from which specimens were retrieved are imbedded in the caatinga, a northeastern Brazilian, semi-arid biome , an unexpected habitat for a group mostly considered as a humid forest dweller.
Several species of Rowlandius and other genera of schizomids are known by the remarkable variation in the length of male pedipalp. Depending on the species, the length of the male pedipalp can vary from approximately the same size as those of the female to up to three times as long (e.g. , ). Authors describing species of these genera usually discriminate males in two categories, namely homeomorphic males and heteromorphic males, for specimens with short and long pedipalps, respectively . This classification is based on the assumption that two discrete male morphs can be recognized based on the pedipalp size, relative to total body size. Male dimorphism has been described for several groups of arthropods, like insects , crustaceans  and, among arachnids, spiders , mites , pseudoscorpions  and harvestmen , . This phenomenon has been attributed to intrasexual selection pressures favoring a conditional strategy with different tactics for small and large males . However, the detection of male dimorphism can be statistically challenging, especially when the differences between the morphs are subtle . For schizomids, no criteria have been proposed to discriminate between homeomorphic and heteromorphic males, and this distinction is generally based on small sample sizes, usually no more than five or six specimens. In this study, we take advantage of a large sample of specimens to evaluate whether or not it is possible to recognize discrete male morphs in one of the newly described species.
Materials and Methods
Specimens and Laboratory Procedures
The specimens examined for this study were collected in several caves in two states in northeastern Brazil (Fig. 1) and were deposited in the arachnid collections of Coleção de Invertebrados Subterrâneos de Lavras, Universidade Federal de Lavras, Lavras (ISLA, curator R.L. Ferreira); Coleções Taxonômicas da UFMG, Belo Horizonte (UFMG, A.J. Santos); Departamento de Zoologia, Universidade de Brasília, Brasília (DZUB, P.C. Motta) and Instituto Butantan, São Paulo (IBSP, D.M. Barros-Battesti). Field collecting permits were issued to R.L. Ferreira by SISBIO/CECAV (license n. 14783-1). Cave geographic coordinates were obtained through CECAV’s database (available at http://www4.icmbio.gov.br/cecav/index.php?id_menu=228). Specimens were illustrated in a Leica MZ12.5 stereomicroscope with a camera lucida and measured in an Olympus SZ40. Female genitalia were excised, temporarily mounted in slides with clove oil and illustrated in a Zeiss Axioskop 20 binocular microscope with a camera lucida. Specimens for SEM were air-dried, mounted on stubs with double-faced tape and sputter-coated with 10 nm of gold. Stubs were examined and photographed under high vacuum in a Quanta 2000 Scanning Electron Microscope at the Centro de Microscopia da UFMG. Female genitalia was excised, immersed for two hours in a pancreatin solution (see ) to remove soft tissues, air-dried and mounted on the stub. Description format and abbreviations follow Santos et al.  and Santos & Pinto-da-Rocha . Morphological nomenclature follows  for chelicerae setation,  and  for flagellum setation and  for female internal genitalia. All measurements are in millimeters.
The black area represents the range of limestone outcrops from the Apodi Group in the state of Rio Grande do Norte.
Male Dimorphism Analysis
Male dimorphism was at first visually evaluated in scatterplots of prosoma length (as a proxy for general body size) and pedipalpal patella length (indicative of pedipalp size). To check whether a non-linear or discontinuous allometric pattern was apparent, natural values were used without logarithm transformation (caveats of such transformations explained in ), and the scatterplot axes were isometric (such that ΔX = ΔY; see  for why this is important). Both variables were checked for bimodality through adjustment of non-parametric kernel density estimates to frequency distributions. Pedipalp size distribution seemed strongly bimodal, and therefore was parameterized as a mixture of two ‘facing gamma distributions’ using finite mixture models, according to model <d> in . The ‘facing gamma distributions’ proposed by these authors accommodate skews in the distributions of the trait for each male morph, modeling a skew to the right (towards higher values) among homeomorphic males and a skew to the left (towards lower values) among heteromorphic males. This parameterization was performed in SAS version 9.2 (SAS Institute 2004) with code kindly provided by J.M. Rowland and C.R. Qualls. Finally, the likelihood of belonging to each male morph was computed from the mixture models for each male based on their pedipalp length.
Simple linear models were fitted to the allometric relationship between pedipalp length and prosoma length for females and for each male morph separately, through standard major axis regression using package ‘lmodel2’  in R version 2.14.2 . For this last step of the analysis, males were classified as homeomorphic or heteromorphic when their likelihood of belonging to one particular male morph (computed from the mixture models) was higher than 95%. Males with less than 95% chances of belonging to either male morph were left out when adjusting the allometric relationships between pedipalp length and prosoma length for homeomorphic and heteromorphic males.
The electronic edition of this article conforms to the requirements of the amended International Code of Zoological Nomenclature , and hence the new names contained herein are available under that Code from the electronic edition of this article. This published work and the nomenclatural acts it contains have been registered in ZooBank, the online registration system for the ICZN. The ZooBank LSIDs (Life Science Identifiers) can be resolved and the associated information viewed through any standard web browser by appending the LSID to the prefix "http://zoobank.org/". The LSID for this publication is: (urn:lsid:zoobank.org:pub:4882594A-5176-4668-A8B3-20DFFDD4DA73). The electronic edition of this work was published in a journal with an ISSN, and has been archived and is available from the following digital repositories: PubMed Central, LOCKSS.
Results and Discussion
Rowlandius ubajara sp.nov.
(A) Rowlandius ubajara sp.nov., female from Ubajara, Ceará, Brazil. (B, C) Rowlandius potiguar sp.nov., male from Felipe Guerra, Rio Grande do Norte, Brazil. Note the extremely elongated pedipalp (arrow). (D) R. potiguar, female from Felipe Guerra, Rio Grande do Norte, Brazil (arrow indicates the pedipalp).
(A) Male (holotype UFMG 3895), flagellum, dorsal view; (B) ventral, (C) lateral, (D) pedipalp, retrolateral view. (E) Female (paratype, IBSP 44), pedipalp, retrolateral view; (F) female internal genitalia, dorsal view (LL lateral lobes of the spermathecae, ML median lobes). Scale bars: 6–8 0.1 mm; 9–10 0.2 mm; 11 0.04 mm.
Holotype. Male from BRAZIL: Ceará: Ubajara (Parque Nacional de Ubajara, Gruta de Ubajara, 3o50′0′′S 40o54′1′′W), 30.XII.2006, R.L. Ferreira coll. (UFMG 3895). Paratypes. Female, same data as the holotype (UFMG 3896); male and female, same data (IBSP 44); female, same locality, 26.IV.2003, B.C. Cabral coll. (DZUB 2718).
Males of R. ubajara can be distinguished from the remaining species of the genus by the flagellum ovoid, wider at the basal third, with the anterior surface between setae dl3 wide and convex and with the dorsal projections wide, separated by a distance equivalent to their width and not touching or surpassing the lateral border of the flagellum (Fig. 3A, B). Females are recognized by the chitinized arch of the internal genitalia u-shaped, closed and pointed laterally, lateral lobes of the spermathecae with curved stalks and small bulbs and the median lobes cylindrical, wrinkled and with half the length of the lateral lobes (Fig. 3F).
Male (holotype). Propeltidium pale brown, chelicerae and pedipalp reddish-brown. Metapeldium and legs pale-brown. Opisthosoma greenish-brown. Anterior process with one apical seta. Propeltidium with an anterior and a posterior pair of setae. Eyespot absent. Opisthosomal tergites I–IX each with a dorsal pair of setae, X–XI with a pair of lateral setae and a transversal row of five setae, XII with a dorsal and two lateral pairs and a ventral row of four setae. Segments XI–XII telescoped. Posterodorsal abdominal process wide, subrectangular (Fig. 3A). Fixed digit of chelicerae with four teeth, the ventral the longest. Chelicerae setation: 1: 3; 2: 5; 3: 3; 4: 2; 5: 6; 6: 1. Setae 1 with spicules, setae 3 pilose in the apex. Movable digit with serrula and a row of pilose bristles, guard tooth inconspicuous. Pedipalp with the trochanter slightly pointed anteriorly (Fig. 3D). Leg tarsal segments proportion 2:1:2. Femur IV robust, anterior margin produced dorsally, approximately two times longer than wide. Total length 2.72. Propeltidium 1.02 long, 0.56 wide. Prosoma 1.27 long, opisthosoma 1.7. Length of pedipalp segments: trochanter 0.2/femur 0.43/patella 0.48/tibia 0.43/tarsus 0.23/total 1.77. Length of leg segments: I trochanter 0.18/femur 1.12/patella 1.45/tibia 1.09/basitarsus 0.31/telotarsus 0.56/total 4.71. II 0.08/0.71/0.41/0.43/0.41/0.36/2.4. III 0.1/0,58/0.31/0.33/0.15/0.28/1.75. IV 0.13/1.03/1.12/0.64/0.18/0.23/3.33 Flagellum ovoid, with stalk short and wide (Fig. 3A–C). Setation of flagellum: dm1, dm4; dl1, dl3; vm1, vm2, vm4, vm5; vl1, vl2 (Fig. 3A–C); five lateral microsetae between dl1 and dl3.
Female (Paratype, UFMG 3896). As in male, except by the following. Prosoma, pedipalp and leg I reddish-brown (Fig. 2). Opisthosoma, chelicerae and legs II–IV greenish brown (Fig. 2). Anterior process with 1+1 setae. Flagellum with four segments, setation as in the male, except by three pairs of lateral microsetae: one pair in segment II (adjacent to dm1); one in III and one in IV (between dm4 and dl3). Fixed finger of chelicerae with five teeth, the ventral the longest and the dorsal rounded. Movable digit with conspicuous guard tooth. Total length 4.12. Propeltidium 1.23 long, 0.66 wide. Prosoma 1.7 long, opisthosoma 2.42. Length of pedipalp segments: trochanter 0.22/femur 0.58/patella 0.61/tibia 0.53/tarsus 0.28/total 2.22. Length of leg segments: I trochanter 0.18/femur 1.25/patella 1.55/tibia 1.14/basitarsus 0.34/telotarsus 0.53/total 4.99. II 0.08/0.86/0.48/0.53/0.46/0.36/2.77. III 0.13/0.74/0.31/0.41/0.51/0.41/2.51. IV 0.28/1.19/0.53/0.83/0.76/0.41/4.00. Spermathecae without gland duct openings (Fig. 3F).
Length of prosoma: male (N = 2) 1.27–1.37, female (N = 3) 1.26–1.73. Length of pedipalpal patella: male 0.48–0.6, female 0.53–0.66.
This species was recorded from a single limestone cave located in a small patch of Brazilian Atlantic forest in northeastern Brazil (in Ubajara National Park). Part of the cave is open for visitors and is illuminated by electric lamps. Specimens of R. ubajara were found in the inner part of the cave, which consists of a single passage through which a small stream flows. Potential food resources observed in the cave are mainly bat guano from insectivorous and hematophagous bats and potential prey for R. ubajara could be mainly springtails (Collembola) and booklice (Psocoptera: Psyllipsocidae). The population is apparently small, and only about 10 specimens were observed in the cave during the collection. The average temperature of the cave was 23.5°C and the humidity was 99% in the inner parts, where the species occurs. Although the population only occurs in the inner part of the cave and the species was observed in a single cave, the absence of eye spots is the only potentially troglomorphic trait exhibited by the species. This characteristic, as well as the absence of pigmentation and elongation of appendages, is frequently suggested as evidence of troglobiotism in schizomid species , . However, it is not uncommon to find schizomids with those traits associated with epigean habitats, as well as species without any apparent troglomorphism living in caves ( and references therein). It is reasonable to consider schizomids as pre-adapted for living in caves, mostly due to their low reliance on visual orientation. Except for four species with convex eye lenses , , the members of the order have either no eyes or only vestigial, pale eye spots . It is uncertain whether the eye spots, or even the well formed eyes, are truly functional, since no species have been evaluated through histological or behavioral methods. Thus, the presence or degree of development of the eyes does not seem to be a good indicator of adaptation to caves in this group. Since not all troglobiotic species necessarily possess troglomorphic traits , further studies should be conducted in the area (especially in the external environments) to actually confirm the degree of association of this species with hypogean habitats.
Known only from the type locality in the northeastern Brazilian state of Ceará (Fig. 1).
Rowlandius potiguar sp.nov.
(Figures 1, 2B–D, 4A–G, 5A–D, 6A–F, 7A–B).
(A) Male (holotype, UFMG 3897), flagellum, dorsal view; (B) ventral, (C) lateral, (D) pedipalp, retrolateral view. (E) Male (paratype UFMG 3899), pedipalp, retrolateral view. (F) Female (paratype, IBSP 45), pedipalp, retrolateral view; (G) female internal genitalia, dorsal view (G gonopod, LL lateral lobes of the spermathecae, ML median lobes). Scale bars: 12–14 0.1 mm; 15–17 0.2 mm; 18 0.04 mm.
(A) Male (UFMG 3901), flagellum and posterior tip of opisthosoma, posterior-dorsal view, (B) apex of male flagellum, lateral view (arrows indicate uropygid pores), (C) male pedipalp, trochanter, prolateral view (arrow indicates prolateral spur), (D) male pedipalp, tarsus, prolateral view (arrows indicate tarsal spurs).
(A) Male (UFMG 3901), pedipalp, tarsus, prolateral view (arrows indicate uropygid pores), (B) chelicerae, apex, prolateral view (S serrula; numbers indicate setae types, according to ). (C) Female (UFMG 3902), flagellum and posterior tip of abdomen, dorsal view; (D) internal genitalia, dorsal view (arrows indicate chitinized arch); (E) lateral lobe of spermathecae, bulb; (F) gonopod (arrow), dorsal view.
(A) Histogram of male pedipalpal patella length overlaid by the two ‘facing gamma distributions’ (θ = 0.163, λ = 1.91, lower bound = 0.48 mm for homeomorphic males; θ = 0.201, λ = 2.88, upper bound = 2.25 mm for heteromorphic males) estimated by a finite mixture model (as proposed by Rowland & Qualls ). The bars represent the frequency (scale on the left) of males in each pedipalpal patella length bin, and the curves represent the distributions of predicted probabilities (scale on the right, in %) of each pedipalpal patella length for both male morphs, as estimated by the model. (B) The relationship between the length of pedipalpal patella and the length of prosoma. Filled black dots and black line indicate males with a probability of being heteromorphic higher than 95%, empty dots and dashed line indicate males with a probability of being homeomorphic higher than 95%, filled gray dots indicate males with probabilities lower than 95% of being either morph, and crosses and dotted line indicate females. Axes are isometric to show male morphs in the most objective fashion.
Holotype. Male from BRAZIL: Rio Grande do Norte: Felipe Guerra (Gruta da Carrapateira, 5°33′38′′S 37°39′50′′W), 28.VII.2009, M.P.A. Oliveira coll. (UFMG 3897). Paratypes. Female from BRAZIL: Rio Grande do Norte: Felipe Guerra (Gruta do Geílson, 5°35′53′′S 37°41′18′′W), 16.VI.2008, M.P.A. Oliveira coll. (UFMG 3898); male and female, same data as the holotype (UFMG 3899); male and female, ditto (IBSP 45); male and female from BRAZIL: Rio Grande do Norte: Baraúna (Gruta dos Cipós, 5°2′40′′ 37°34′35′′W); D.M. Bento coll. (ISLA 1837).
Additional Material Examined
BRAZIL: Rio Grande do Norte: Baraúna (Gruta do Britador, 5°1′26′′S 37°29′50′′W); 11/VI/2010; D.M. Bento coll.; 2 males 2 females 2 juv (ISLA 1843); (Gruta do Pinga, 5°3′8′′ 37°32′23′′W); 28/I/2010; D.M. Bento coll.; 1 male 1 female 1 juv. (ISLA 1835); (Gruta dos Cipós, 5°2′40′′ 37°34′35′′W); D.M. Bento coll. 1 male 1 female 2 juv. (ISLA 1850); (Gruta Furna Feia; 5°2′12′′S 37°33′37′′W); 29/I/2010; D.M. Bento coll.; 2 males 2 females 1 juv. (ISLA 1834); (Gruta do Lago; 5°2′11′′ 37°34′15′′W; 26/I/2010; D.M. Bento coll.; 1 male 5 juv. (ISLA 1846); ditto; 30/VII/2010; D.M. Bento coll.; 1 male 1 female 2 juv. (ISLA 1840); (Gruta Esquecida, 5°2′20′′S 37°33′41′′W); D.M. Bento coll.; 1 male 2 females 1 juv. (ISLA 1826); same details, 12/VI/2010; D.M. Bento coll.; 1 male 1 female 3 juv. (ISLA 1838); Felipe Guerra (Gruta da Carrapateira, 5°33′38′′S 37°39′50′′W), 28.VII.2009, 4 males 2 females (UFMG 3900); (Gruta do Arapuá, 5°31′48′′S 37°36′58′′W); 3/VIII/2010; D.M. Bento coll.; 1 female (ISLA 1828); ditto, 7/I/2010; D.M. Bento coll.; 3 males 4 females (ISLA 1831); (Gruta Beira Rio, 5°33′7′′ 37°37′43′′W); D.M. Bento coll.; 2 males 2 females 2 juv. (ISLA 1822); (Gruta do Crotes, 5°33′39′′S 37°39′32′′W); 19/I/2010; D.M. Bento coll.; 3 males 3 females 1 juv. (ISLA 1827); ditto; 4/VI/2010; 1 female 2 juv. (ISLA 1832); ditto; no date, 1 female (ISLA 1847); (Gruta do Geílson, 5°35’53”S 37°41’18”W), 16.VI.2008, R.L. Ferreira coll., 6 males 2 females 7juv. (UFMG 3901); (Gruta do Buraco Redondo, 5°34′43′′S 37°39′5′′W); D.M. Bento coll.; 1 male (ISLA 1825); (Gruta Lapa 1, 5°33′42′′S 37°41′42′′W); D.M. Bento coll.; 1 male (ISLA 1821); (Gruta da Rumana; 5°33′54′′S 37°39′7′′W); 10/I/2010; D.M. Bento coll.; 2 males 1 female (ISLA 1842); Governador Dix-sept Rosado (Gruta da Boniteza, 5°30′51′′S 37°33′22′′W); 2/II/2009; D.M. Bento coll.; 1 male 2 juv. (ISLA 1829); (Gruta Capoeira do João Carlos, 5°30′57′′S 37°31′42′′W); D.M. Bento coll.; 1 male 4 females (ISLA 1823); ditto; 3/6/2010; 2 females 4 juv. (ISLA 1845); (Gruta do Lajedo Grande, 5°27′42′′S 37°33′14′′W); D.M. Bento coll.; 1 females (ISLA 1820); (Gruta do Marimbondo Caboclo, 5°29′44′′S 37°32′42′′W); D.M. Bento coll.; 4 males 5 females 1 juv. (ISLA 1824); ditto; 20/VII/2010; D.M. Bento coll.; 3 males 2 females 4 juv. (ISLA 1844); Martins (Gruta Casa de Pedra, 6°4′17′′S 37°52′59′′W), VI.2008, R.L. Ferreira coll., 4 males 6 females 1juv. (UFMG 3902); Mossoró (Gruta do Trinta, 5°12′44′′S 37°15′51′′W); 10/VI/2010; D.M. Bento coll.; 1 female (ISLA 1830).
The specific epithet is an adjective used in Brazil to designate the natives from the state of Rio Grande do Norte.
Males of Rowlandius potiguar resemble those of R. linsduarteae Santos et al., 2008 in the subquadrate flagellum, but differ in its rounded sides, dorsal projections narrower in dorsal view and the setae dm4 closer to the posterior border (Fig. 4A–C, 5A). The flagellum of this species is also similar to that of R. monticola Armas, 2002 in general shape (fig. 3b in ), but differs in the wider stalk and the dorsal projections closer to each other. Females are similar to those of R. sul Cokendolpher & Reddell, 2000 and R. linsduarteae in the conical shape of the median lobes of the spermathecae (fig. 6 in ) and specifically to R. linsduarteae in the lateral lobes of the spermathecae with curved stalks and large bulbs (figure 6 in ). These species can be distinguished by the lateral lobes with thinner stalks and larger bulbs and by the presence of a gonopod in R. potiguar (Figs. 4G, 6D–F). As in several other species of Rowlandius, male pedipalp are variably longer than in the female (Figs. 2B, C; 4D, E; 7A, B – see discussion below). However, unlike some species, such as R. gladiger (Dumitresco, 1977), R. biconourus (Rowland & Reddell, 1979) R. longipalpus (Rowland & Reddell, 1979) and R. falcifemur Teruel, 2003 (figs. 51, 55, 57 in , fig. 7 in ), neither the trochanter nor the femur has anterior projections (Fig. 4D, E).
Male (holotype). Prosoma, pedipalp and leg I reddish-brown. Opisthosoma, chelicerae and legs II–IV greenish brown (Fig. 2B, C). Anterior process with 1+1 setae. Propeltidium with an anterior and a posterior pair of setae. Eyespot inconspicuous, almost circular. Opisthosomal tergites I–IX each with a dorsal pair of setae, X–XI with a pair of lateral setae and a transversal row of five setae, XII with a dorsal and two lateral pairs of setae and a ventral row of four. Segments XI–XII telescoped. Posterodorsal abdominal process short, subtriangular (Fig. 4A). Fixed digit of chelicerae with seven teeth, the ventral the longest. Chelicerae setation: 1: 3; 2: 5; 3: 3; 4: 2; 5: 7; 6: 1. Setae 1 with spicules, setae 3 pilose in the apex. Movable digit with serrula and a row of pilose bristles, guard tooth conspicuous. Chelicerae with five apical teeth, the ventral one the longest (Fig. 6B). Prolateral spur of pedipalp conical, attenuated apically (Fig. 5C). Tarsal spurs of pedipalp as long as half the length of tarsal claw (Fig. 5D). Dorsal and lateral setae of pedipalp tarsus smooth, ventral setae pilose (Fig. 5D). Uropygid pores present in tarsus of leg I and tarsus of pedipalp (Fig. 6A) and in the flagellum (Fig. 5B). Leg tarsal segments proportion 2:1:2. Femur IV robust, anterior margin produced dorsally, approximately two times longer than wide. Total length 3.58. Propeltidium 1.09 long, 0.64 wide. Prosoma 1.55 long, opisthosoma 2.03. Length of pepipalpus segments: trochanter 0.53/femur 1.23/patella 1.17/tibia 0.66/tarsus 0.41/total 4.00. Length of leg segments: I trochanter 0.23/femur 1.07/patella 1.37/tibia 1.02/basitarsus 0.31/telotarsus 0.48/total 4.48. II 0.11/0.74/0.43/0.43/0.43/0.34/2.48. III 0.13/0.69/0.33/0.23/0.41/0.33/2.12. IV 0.15/1.07/0.43/0.69/0.64/0.38/3.36. Setation of flagellum: dm1, dm4; dl1, dl3; vm1, vm2, vm4, vm5; vl1, vl2 (Fig. 4A–C). One pair of dorso-lateral microsetae adjacent to dl1, six lateral microsetae between dl1 and dl3 (Fig. 5A, B, only five visible in the figure). Setae with spicules, microsetae smooth (Fig. 5B).
Female (paratype, UFMG 3898). As in male (Fig. 2D), except by the following. Flagellum with four segments, setation as in male except by three pairs of lateral microsetae: one pair in segment II (adjacent to dm1); one in III and one in IV (between dm4 and dl3) (Fig. 6C). Setae with spicules, microsetae smooth. Total length 4.17. Propeltidium 1.14 long, 0.64 wide. Prosoma 1.7 long, opisthosoma 2.47. Length of pedipalp segments: trochanter 0.2/femur 0.5/patella 0.58/tibia 0.48/tarsus 0.25/total 2.01. Length of leg segments: I trochanter 0.2/femur 0.97/patella 1.25/tibia 0.94/basitarsus 0.28/telotarsus 0.46/total 4.1. II 0.09/0.76/0.41/0.41/0.36/0.25/2.28. III 0.13/0.61/0.33/0.33/0.38/0.28/2.06. IV 0.15/1.04/0.46/0.71/0.53/0.33/3.22. Chitinized arch of internal genitalia closed and v-shaped (Fig. 6D), lateral lobes of spermathecae globular (Fig. 6E), gonopod membranous, with a pair of basal pores (Fig. 6F). Spermathecae without gland duct openings (Fig. 4G).
A peculiar lobed aperture was described from the appendages of Schizomida and Thelyphonida by Santos & Pinto-da-Rocha  and was proposed as a potential synapomorphy of Uropygi. This peculiar aperture has been reported from the tarsus of leg I and the flagellum, in both males and females of three schizomid and two thelyphonid genera. In the current study, we also report this structure in the male pedipalp of R. potiguar (Fig. 6A). Although Santos & Pinto-da-Rocha  suggest this aperture could be a glandular opening, its function remains unclear. Thus, we here propose to refer to this structure simply as the uropygid pore.
Length of prosoma: male (N = 45) 1.25–1.73, female (N = 17) 1.27–1.83. Length of pedipalpal patella: male 0.53–2.2 (see Fig. 7), female 0.52–0.6.
This species is distributed in 20 caves along the Apodi limestone group, in the western part of the state of Rio Grande do Norte. The area is located in the caatinga, a seasonally-dry forest formation . This limestone group is composed of huge outcrops, located in various municipalities, including Jandaíra, Felipe Guerra, Apodi, Martins and Baraúnas. Populations of R. potiguar were found in many caves (Fig. 1), although the population sizes were variable, possibly due to different conditions in each cave. The species is apparently associated with moist caves, since no specimens have been observed in completely dry caves. In the dry Casa de Pedra cave, the southernmost record of the species, the single specimen observed was in the only wet area of the cave, in sediments humidified by dripping water. Field observations suggest that this species occurs in large populations, with hundreds of individuals, particularly close to bat guano or seed deposits transported by bats. These organic piles harbor several scavenger invertebrates, like springtails (Collembola), small flies (Diptera) and booklice (Psocoptera); which could serve as prey for schizomids.
Known from 20 caves in the northeastern Brazilian state of Rio Grande do Norte (Fig. 1).
Pedipalp length in R. potiguar males is remarkably variable, presenting 20.11 times more variance than prosoma length (variances standardized by the means of the traits), and its distribution is clearly bimodal (Figure 7A). Meanwhile, the same trait in conspecific females presents a unimodal distribution, with only 0.50 of the variance presented by prosoma length (variances standardized by the means of the traits). Moreover, a mixture of two ‘facing gamma distributions’ (θ = 0.163, λ = 1.91, lower bound = 0.48 mm for homeomorphic males; θ = 0.201, λ = 2.88, upper bound = 2.25 mm for heteromorphic males; Figure 7A) fits the distribution of male pedipalp length very well. This model estimates that at least 95% of males with pedipalpal patella shorter than 1.02 mm represent the homeomorphic morph (empty circles, Figure 7B) and at least 95% of the males with pedipalpal patella longer than 1.23 mm represent the heteromorphic morph (full black circles, Figure 7B).
The only known cases of elongated male-dimorphic traits in arachnids were described for the order Opiliones , , where the elongation of the second or fourth pair of legs is bimodal and extremely variable among males. In these cases, the male dimorphic traits are sexually selected weapons used in male-male fights. As far as we know, there is no evidence of male-male fights in Schizomida, and the only studies that describe the courtship and copulation in the order ,  do not indicate any participation of the male pedipalp in mating. However, there is evidence that males of the schizomid Hubbardia pentapeltis use their pedipalps during courtship. In this species, the male stretches out his pedipalps, picks up small twigs, and manipulates them in various ways while the female seemingly examines the male’s behavior, repeatedly touching his anterior body parts with her first legs (JM Rowland, personal communication). In conclusion, it is also possible that the elongation of pedipalps in R. potiguar evolved in the context of courtship.
The fact that the static allometry of pedipalps is significantly steeper in males than in females (Figure 7, Table 1) cannot be readily taken as evidence that such pedipalps are under sexual selection , as it has been interpreted in the past for other taxa . However, it does indicate that pedipalp length is under a different selective regime in males than in females. We urge for studies on the sexual behavior of R. potiguar and other schizomids, which would be promising approaches to shedding light on the evolutionary causes of pedipalp elongation and male dimorphism in the group.
In conclusion, an objective and robust discrimination of male morphs might be crucial for in depth behavioral and ecological studies of particular male dimorphic species, but it does not seem to be so important for taxonomic descriptions. Nevertheless, it is still essential that taxonomists realize the existence of male dimorphism, and hence avoid describing male morphs as different species. This does not seem to be a problem in schizomid systematics, since species distinction is based mainly on male flagellum. Yet, it is relevant to report variation in male pedipalp length within species and, whenever a reasonably big sample is available, discriminate morphs properly. The detection of male dimorphism by taxonomists can in itself stimulate behavioral ecology studies on these animals, which could elucidate their mating systems and unveil the alternative mating tactics of males that are potentially behind the evolution of male dimorphism in Schizomida.
We are grateful to Marconi Souza Silva, Xavier Prous, CECAV-RN team (especially Jocy B. Cruz, Diego M. Bento, Uilson P. Campos and José Yatagan M. Freitas) and Geilson Goes Fernandes for help in field work; to Alessando P.L. Giupponi for sending us the DZUB specimen, and to Antonio D. Brescovit for the use of microscopes for specimen illustration. The SEM images were produced in the Centro de Microscopia da UFMG with the help of Breno B. Moreira, and Kin Master Produtos Químicos kindly provided a free sample of pancreatin to AJS. We are also in debt to Adriano B. Kury for German translation and Glauco Machado for stimulating discussions on male dimorphism. We would also like to thank Joe Tomkins for statistical advice and J. Mark Rowland and Clifford R. Qualls for invaluable discussions about the methods available to discriminate male morphs and for the SAS code used to analyze male dimorphism. JM Rowland was also kind enough to provide unpublished observations on schizomid courtship behavior. The earlier versions of the manuscript were significantly improved by comments from G. Machado, Jairo A. Moreno-González, J.M. Rowland and the Plos One Academic Editor Don Colgan. Any omission or inaccuracy remaining in the text are the authors’ responsibility.
Conceived and designed the experiments: AJS RLF BAB. Performed the experiments: AJS RLF BAB. Analyzed the data: AJS BAB. Contributed reagents/materials/analysis tools: AJS. Wrote the paper: AJS RLF BAB.
- 1. Tourinho ALM, Kury AB (1999) The Southernmost record of Schizomida in South America, first record of Schizomida for Rio de Janeiro and of Stenochrus Chamberlin, 1922 for Brazil (Arachnida, Schizomida, Hubbardiidae). Boletim do Museu Nacional, Zoologia 405: 1–6.
- 2. Santos AJ, Dias SC, Brescovit AD, Santos PP (2008) The arachnid order Schizomida in the Brazilian Atlantic Forest: a new species of Rowlandius and new records of Stenochrus portoricensis (Schizomida: Hubbardiidae). Zootaxa 1850: 53–60.
- 3. Reddell JR, Cokendolpher JC (1995) Catalogue, bibliography and generic revision of the order Schizomida (Arachnida). Texas Memorial Museum, Speleological Monographs 4: 1–170.
Auler A, Rubbioli E, Brandi R (2001) As grandes cavernas do Brasil. Belo Horizonte: Grupo Bambuí de Pesquisas Espeleológicas. 228 p.
Ferreira RL, Souza-Silva M, Oliveira-Bernardi LF (2009) Contexto bioespeleológico. In: Drummond GM, Martins CS, Greco MB, Vieira F, editors. Biota Minas: diagnóstico do conhecimento sobre a biodiversidade no estado de Minas Gerais – subsídio para o programa Biota Minas. Belo Horizonte: Fundação Biodiversitas. 160–175.
- 6. Armas LF (2009) Dos nuevas especies de Hansenochrus y Rowlandius (Schizomida: Hubbardiidae) de Costa Rica. Bol SEA 45: 253–257.
- 7. Armas LF (2010a) Nuevos arácnidos de Puerto Rico (Arachnida: Amblypygi, Araneae, Opiliones, Parasitiformes, Schizomida, Scorpiones). Bol SEA 47: 55–64.
- 8. Armas LF (2010b) Schizomida de Sudamérica (Chelicerata: Arachnida). Bol SEA 46: 203–234.
- 9. Armas LF, Villarreal Manzanilla O, Colmenares-García PA (2009) Nuevo Rowlandius Reddell & Cokendolpher, 1995 (Schizomida: Hubbardiidae) de la Sierra San Luis, Venezuela noroccidental. Pap Avulsos Zool 49: 361–368.
Harvey MS (2007) Smaller Arachnid Orders Catalogue (SAOCat), database (version Oct. 2007). Integrated Taxonomic Information System on-line database. Available: http://www.itis.gov. Accessed 2011 November.
- 11. Armas LF (1989) Adiciones al orden Schizomida (Arachnida) en Cuba. Poeyana 387: 1–45.
- 12. Armas LF (2004) Arácnidos de República Dominicana. Palpigradi, Schizomida, Solifugae y Thelyphonida (Chelicerata: Arachnida). Revista Ibérica de Aracnología, Volumen Especial Monográfico 2: 3–63.
Harvey MS (2003) Catalogue of the smaller arachnid orders of the world: Amblypygi, Uropygi, Schizomida, Palpigradi, Ricinulei and Solifugae. Melbourne: CSIRO Publishing. 385 p.
- 14. Rowland JM, Reddell JR (1979) The order Schizomida (Arachnida) in the New World. I. Protoschizomidae and dumitrescoae group (Schizomidae, Schizomus). J Arachnol 6: 161–196.
- 15. Teruel R (2003) Adiciones a la fauna cubana de esquizómidos, con la descripción de un nuevo género y nueve especies nuevas de Hubbardiidae (Arachnida: Schizomida). Revista Ibérica de Aracnología 7: 39–69.
Mittermeier RA, Mittermeier CG, Robles Gil P, Pilgrim J (2003) Wilderness: Earth’s Last Wild Places. Washington: Conservation International. 576 p.
Brockmann HJ (2008) Alternative reproductive tactics in insects. In: Oliveira RF, Taborsky M, Brockmann HJ, editors. Alternative reproductive tactics: an integrative approach. Cambridge: Cambridge University Press. 177–223.
Shuster SM (2008) The expression of crustacean mating strategies., In: Oliveira RF, Taborsky M., Brockmann HJ, editors. Alternative reproductive tactics: an integrative approach. Cambridge: Cambridge University Press. 224–250.
- 19. Vanacker D, Maes L, Pardo S, Hendrickx F, Maelfait JP (2003) Is the hairy groove in the gibbosus male morph of Oedothorax gibbosus (Blackwall 1841) a nuptial feeding device? J Arachnol 31: 309–315.
- 20. Radwan J, Bogacz I (2000) Comparison of life-history traits of the two male morphs of the bulb mite, Rhizoglyphus robini. Exp Appl Acarol 24: 115–121.
- 21. Zeh JA, Zeh DW (2013) On the threshold of dispersal: hitchhiking on a giant ﬂy favours exaggerated male traits in a male-dimorphic pseudoscorpion. Biol J Linn Soc Lond 108: 509–520.
- 22. Buzatto BA, Requena GS, Lourenço RS, Munguía-Steyer R, Machado G (2011) Conditional male dimorphism and alternative reproductive tactics in a Neotropical arachnid (Opiliones). Evolutionary Ecology 25: 331–349.
- 23. Zatz C, Werneck RM, Macias-Ordonez R, Machado G (2011) Alternative mating tactics in dimorphic males of the harvestman Longiperna concolor (Arachnida: Opiliones). Behav Ecol Sociobiol 65: 995–1005.
- 24. Gross MR (1996) Alternative reproductive strategies and tactics: diversity within sexes. Trends Ecol Evol 11: 92–98.
- 25. Knell RJ (2009) On the analysis of non-linear allometries. Ecol Entomol 34: 1–11.
- 26. Alvarez-Padilla F, Hormiga G (2008) A protocol for digesting internal soft tissues and mounting spiders for scanning electron microscopy. J Arachnol 35: 538–542.
- 27. Santos AJ, Pinto-da-Rocha R (2009) A new micro-whip scorpion species from Brazilian Amazonia (Arachnida: Schizomida: Hubbardiidae), with the description of a new synapomorphy for Uropygi. J Arachnol 37: 39–44.
- 28. Lawrence RF (1969) The trichoid structures on the chelicarae of the short-tailed whip-scorpions (Schizomida; Arachnida). Transactions of the Royal Society of South Africa 38: 123–132.
- 29. Cokendolpher JC, Reddell JR (1992) Revision of Protoschizomidae (Arachnida: Schizomidae) with notes on the phylogeny of the order. Texas Memorial Museum Speleological Monographs 3: 31–74.
- 30. Harvey MS (1992) The Schizomida (Chelicerata) of Australia. Invertebrate Taxonomy 6: 77–129.
- 31. Packard GC (2012) Is non-loglinear allometry a statistical artifact? Biol J Linn Soc Lond 107: 764–773.
- 32. Tomkins JL, Moczek AP (2009) Patterns of threshold evolution in polyphenic insects under different developmental models. Evolution 63: 459–468.
- 33. Rowland JM, Qualls CR (2005) Likelihood models for discriminating alternative phenotypes in morphologically dimorphic species. Evol Ecol Res 7: 421–434.
Legendre P (2011) lmodel2: Model II Regression. R package version 1.7–0. http://CRAN.R-project.org/package=lmodel2.
R Development Core Team (2012) R: a language and environment for statistical computing. R Foundation for Statistical Computing, Vienna, Austria. ISBN 3–900051–07–0. Avalilable: http://www.R-project.org. Accessed March 2012.
- 36. ICZN (2012) Amendment of Articles 8, 9, 10, 21 and 78 of the International Code of Zoological Nomenclature to expand and refine methods of publication. Zootaxa 3450: 1–7.
- 37. Teruel R (2007) Esquizómidos troglomorfos de Cuba, con las descripciones de dos géneros y una especie nuevos (Schizomida: Hubbardiidae: Hubbardiinae). Bol. SEA 40: 39–53.
- 38. Sissom WD (1980) the eyed schizomids, with a description of a new species from Sumatra (Schizomida: Schizomidae). J Arachnol 8: 187–192.
- 39. Cokendolpher JC, Sites RW (1988) A new species of eyed Schizomus (Schizomida: Schizomidae) from Java. Acta Arachnologica 36: 79–85.
- 40. Sket B (2008) Can we agree on an ecological classification of subterranean animals? J Nat Hist 42: 1549–1563.
- 41. Armas LF (2002) Nuevas especies de Rowlandius Reddell & Cokendolpher, 1995 (Schizomida: Hubbardiidae) de Cuba. Revista Ibérica de Aracnología 6: 149–167.
- 42. Cokendolpher JC, Reddell JR (2000) New and rare Schizomida (Arachnida: Hubbardiidae) from South America. Amazoniana 16: 187–212.
- 43. Sturm H (1958) Indirekte spermatophorenübertragung bei dem Geisselskorpion Trithyreus sturmi Kraus (Schizomidae, Pedipalpi). Naturwissenschaften 45: 142–143.
- 44. Sturm H (1973) Zur Ethologie von Trithyreus sturmi Kraus (Arachnida, Pedipalpi, Schizopeltidia). Z Tierpsychol 33: 113–140.
- 45. Bonduriansky R (2007) Sexual selection and allometry: a critical reappraisal of the evidence and ideas. Evolution 61: 838–849.
- 46. Kodric-Brown A, Sibly RM, Brown JH (2006) The allometry of ornaments and weapons. Proc. Natl. Acad. Sci. U.S.A. 103: 8733–8738.