A new oonopid genus endemic to Madagascar, Malagiella, is proposed and its 10 constituent species newly described and illustrated: M. ambalavo (♀), M. andringitra (♂♀), M. fisheri (♂♀), M. goodmani (♀), M. nikina (♀), M. ranavalona (♀), M. ranomafana (♂♀), M. toliara (♂♀), M. valterova (♂♀), and M. vohiparara (♂♀).
Malagiella is most similar to the Asian genus Camptoscaphiella in both somatic and genitalic features, but differs in some important characters. Unlike Camptoscaphiella, the Malagiella male has a palpal bulb completely fused with the tarsus and a sternum bearing stiff bristles; the female has a round copulatory opening and bifid 4th claws.
The species may be recognized by the genitalia. Male palpi are fairly uniform, but differ in segment proportion and details of the embolus complex, which consists of a broad dorsal embolus connected to a laminar ventral prong. Female genitalia are more variable, especially in the curvature of the receptaculum, which spans the range from nearly straight to widely sinuous and occurs in mirror-image versions having opposite coiling. These torsional variants, with females having either left- or right-handed receptacula, probably occur in all species, although they are not evident in species with straight receptacula and (obviously) unknown in species represented by singleton female specimens.
Malagiella species are very diverse somatically, ranging from dark, big, and large-eyed species to pale, small, and reduced-eyed ones. Our preliminary clustering uses mostly these somatic features, with some genitalic support, to identify three species groups: ranomafana, vohiparara, and toliara. Other genitalic characters that suggest different groupings are discussed.
INTRODUCTION
Oonopidae is a worldwide family that currently contains about 500 described species (Platnick, 2010), although the actual number is believed to be much greater. Current estimates, based on the survey of existing collections by the Goblin Spider Planetary Biodiversity Inventory (PBI) project ( http://research.amnh.org/oonopidae/index.php), suggest at least 2000 species. That oonopids have been inadequately sampled and studied is not surprising, as they are small, mostly tropical, and largely restricted to cryptozoic habitats, such as forest litter. As it turns out, they may be very abundant and diverse in favorable habitats.
A good example of the untapped diversity of goblin spiders is the fauna of Madagascar. Oonopids were completely unknown from that island until Millot (1948) first mentioned their presence, but that mention was only a brief account and did not record any species. As no subsequent studies followed, the Malagasy oonopids continue to be unknown (Griswold, 2003). However, recent expeditions to Madagascar reveal that this fauna is clearly not depauperate. A sampling of that island's arthropod fauna, through the numerous expeditions of Vincent and Barbara Roth, Mike Irwin, Rinha Harinhala and Evert Schlinger, Brian Fisher and Charles Griswold, and Hannah Wood, Fernando Álvarez Padilla, and Alma Saucedo (NSF grants DEB 9296271, DEB-0613775, DEB-0072713, and EAR-0228699), has turned up vast collections of over 10,000 oonopid specimens, representing roughly 100 species. In this paper, the first in a series of revisions of this fauna, we describe the new genus Malagiella and its 10 included species.
Generic Placement
Easily the most distinctive feature of Malagiella is the greatly enlarged palpal patella of the male (figs. 7, 481–486). Although similarly modified palpi are found in Opopaea Simon, the two genera are otherwise quite different. Unlike Opopaea, Malagiella has long and spiny legs (figs. 466–471), eyes contiguous and with convex lenses (figs. 13–18), abdominal scutes slightly (figs. 200–202) to strongly reduced (figs. 440–442), and fundamental differences in both male and female genitalia (see Platnick and Dupérré, 2009a, for details on Opopaea).
In all these characters, Malagiella most closely resembles Camptoscaphiella Caporiacco (Baehr and Ubick, 2010). In fact, their similarity in both somatic and genitalic features is so striking that it might be argued that only a single genus is here represented. A more detailed examination, however, reveals several differences. The most easily observed are those in the male genitalia and secondary sexual modifications, and the most unambiguous is the difference in the attachment of the palpal bulb to the tarsus. In Malagiella the bulb is completely fused to the tarsus (fig. 8), but in Camptoscaphiella it is strongly separated (fig. 2), even forming a narrowed “neck” (see also Baehr and Ubick, 2010: figs. 161–181). Interestingly, these differences represent the very extremes of this character transformation. Missing are the intermediate states of bulb free but more broadly attached (as in Heteroonops, Platnick and Dupérré, 2009b: fig. 385) and bulb fused but retaining full to partial seam (as in Stenoonops, Platnick and Dupérré, 2010: fig. 385). The degree of bulb fusion is extremely variable in Oonopidae, but seems to be fairly constant within a genus. The few genera, such as Oonops and Stenoonops, that presently include species with varying degrees of bulb fusion seem to be polyphyletic assemblages. For example, although the bulb and tarsus are strongly separated in Oonops tubulatus Dalmas (see fig. 3 in Machado, 1941) and completely fused in O. cubanus Dumitresco and Georgesco (see Dumitresco and Georgesco, 1983: pl. 11, fig. 3), no evidence has been presented that these species are actually congeneric. In fact, current ongoing revisions on Stenoonops indicate that it is a complex of several genera (Platnick and Dupérré, 2010), and that each is quite uniform in the degree of bulb fusion. Given this trend of intrageneric uniformity, the extreme differences of bulb fusion between species of Camptoscaphiella and Malagiella strongly argue, on the basis of that very character, that these are distinct genera. However, several other differences were found that support this interpretation to a varying degree.
The two genera also differ in male sternal modifications. The anterolateral margin has a pointed conical process in Malagiella (fig. 7), which is smaller and rounded in Camptoscaphiella (fig. 1). Also, the sternum in Malagiella (except for one species) has a patch of sharp, stiff bristles (fig. 7) that is absent in Camptoscaphiella (fig. 1). These bristles are also absent in M. fisheri (fig. 305), which is otherwise an unambiguous Malagiella, but it is not obvious whether the absence is a plesiomorphy or a derived loss.
Females in the two genera also differ, although by less easily observed features; consequently, they have not been as thoroughly examined. A fundamental difference, although not recorded for many species, is the shape of the external opening (copulatory pore), which is round in Malagiella (fig. 11) but a longitudinal slit in Camptoscaphiella (fig. 5). Also, the anterior margin of the postepigastric scutum (PES) is unmodified in Malagiella (fig. 12, M. ranomafana and M. vohiparara examined) but bears a row of pores coplanar with the copulatory pore in Camptoscaphiella (fig. 6, only C. paquini examined). Another difference is the shape of the receptaculum, which is usually straight to slightly curved in most Camptoscaphiella but moderately to strongly so in most Malagiella. However, exceptions occur in both genera as the most sinuous receptaculum is found in C. paquini Ubick (Baehr and Ubick, 2010: figs. 323, 324) and the straightest in M. goodmani (figs. 423–429). Also, all female Malagiella have free sclerites laterad of the postepigastric scutum (fig. 213), but that are fused to the scutum in at least some Camptoscaphiella (as in C. paquini, Baehr and Ubick, 2010: fig. 321). Finally, female Malagiella have bifid 4th tarsal claw prongs (figs. 9, 10), which are simple in Camptoscaphiella (scanned only in C. paquini, figs. 3, 4).
Lastly, evidence for the generic distinctness of Malagiella and Camptoscaphiella comes from a recent, unpublished quantitative analysis of oonopid interrelationships. Utilizing a morphological data matrix extracted from the PBI descriptive database (Álvarez Padilla, Ubick, and Griswold, submitted), augmented by genitalic characters (coded by Alma Saucedo), Fernando Álvarez Padilla, Joel Ledford, and Saucedo performed a parsimony analysis using PAUP 4.0 that showed both Malagiella and Camptoscaphiella as distinct but related genera (Saucedo, Álvarez Padilla, and Ledford, personal commun.).
Higher Relationships
Males of the two genera share an additional character, the fusion of the dorsal and epigastric abdominal scuta. This fusion is complete (seamless) and is found in all Malagiella (figs. 31, 32, 142–146, 207, 243, 275, 308, 352, 437) and all but two species of Camptoscaphiella (Baehr and Ubick, 2010: figs. 17, 206, 241, 308). Interestingly, this scutal fusion is not restricted to these two genera, but is also found in males of somatically similar, large-eyed, spiny-legged species with reduced scutes. It is present in the widespread genus Ischnothyreus Simon. Although apparently overlooked in the many available descriptions, it has been clearly illustrated in some (e.g., Tong and Li, 2008: fig. 4B). Fused scuta have also been recorded from the Asian genus Aprusia Simon (Grismado et. al., 2011) and are also known from a few undescribed genera from East Asia and East Africa. Although these taxa are genitalically diverse, the shared secondary sexual character of scutal fusion adds to the value of their somatic similarity in suggesting relationship in an “Ischnothyreus complex.”
Unfortunately, homoplasy is rampant as male scutal fusion extends beyond the above genera. Some Neoxyphinus males have fused scuta (A. Bonaldo, personal commun.), although the fused region is not smooth but represented by a definite seam (see Abrahim et al., submitted: figs. 189, 235, 292, 293). Complete scutal fusion has been noted in some undescribed genera related to Gamasomorpha Karsch (R. Ott, personal commun.), an undescribed species of Zyngoonops Benoit (W. Fannes, in prep.), and a new genus from Asia (B. Eichenberger, in prep.). All these spiders, however, differ from Ischnothyreus in a number of characters (absence of leg spines, large abdominal scutes, and eye arrangements), suggesting that the scutal fusion in these cases is probably independently derived.
Females of at least some genera of this Ischnothyreus complex do seem to share another feature uncommon in oonopids: external copulatory openings that are separate from the uterus externus. This separation of openings for copulation and oviposition is the fundamental definition of entelegynae. The entelegyne condition is rare in haplogynes, but has been reported in several other oonopid genera, such as Antoonops Fannes and Jocqué (2008), Scaphiella Simon and Escaphiella Platnick and Dupérré (Platnick and Dupérré, 2009c), and Triaeris Simon (Burger, 2009).
In addition to their presence in Camptoscaphiella (figs. 5, 6) and Malagiella (figs. 11, 12), external epigynal openings were also reported for Ischnothyreus (Baehr and Ubick, 2010: fig. 326). Based on descriptions in the literature, Ischnothyreus peltifer Simon seems to have an external copulatory opening located within a posterior atrium (as shown in Dumitresco and Georgesco, 1983: pl. 18: fig. 4). However, a different interpretation was made by Berger who identifies, instead, a series of small openings (slits) located within an anterior atrium and that these slits connect to an internal sinuous gland, rather than to a receptaculum (Burger, in press: fig. 1D).
The male palpi of these genera are different in form and show no obvious similarity. The reduced and strongly sclerotized palp of Ischnothyreus (Saaristo, 2001: figs. 146, 147; Dumitresco and Georgesco, 1983: pl. 18) is quite different from the large palp with enlarged patella of Malagiella (figs. 85–88) and Camptoscaphiella (Baehr and Ubick, 2010: figs. 161–181) as these are from Aprusia and the undescribed genera. Despite the gross differences in palpal morphology, it is interesting that in both Ischnothyreus and Malagiella-Camptoscaphiella the palps require huge muscles to operate, although these are in different locations: in the carapace as opposed to the enlarged palpal patella.
Species Groups
The species of Malagiella present an interesting combination of characters, where fairly uniformly simple genitalia couple with considerable differences in somatic characters. This creates a problem in that the obvious characters for grouping species seem to be adaptive. Despite the pitfalls of recognizing grades rather than clades, these somatic differences suggest well-defined species groups and, pending a more thorough study of Malagiella genitalia (and especially of the unknown males), seem adequate for a preliminary hypothesis.
Malagiella species are of basically two body types: larger, darker species with big eyes (fig. 201) and smaller, pale ones with smaller eyes (fig. 430). Closer inspection shows additional size-related differences, such as carapace reticulation, which ranges from strongly ridged and forming hexagonal cells (figs. 15, 16, 201, 211) to weak with elongate cells (figs. 117, 118, 121, 122, 346, 356) to an apparently complete absence (figs. 430, 441). Another is the size of the abdominal scutes, which may completely cover the abdomen (figs. 201, 211) or show moderate (figs. 346, 356) to very strong reduction (figs. 430, 441).
Size differences in Malagiella were explored a bit further in most of the available specimens (56) by measuring the carapace, which shows less intraspecific variation than the abdomen. The resulting plot of carapace width as a function of length is shown in figure 487 and separates the species fairly well. Of the obvious trends, females have both a longer and wider carapace than associated males and carapace length and width vary directly. However, the plot also produces a “hockey stick” graph, in that the smallest species (M. toliara) has a carapace longer than would be expected for its width. Differences in scute size are also apparent on the plot, as the female DS is largest in the three largest species (upper right on the plot), smallest in the three smallest species (lower left), and intermediate in the remaining. Eye sizes and body pigmentation similarly show a direct relationship to body size, but have not been quantified.
Figure 487 also shows our clustering of species into groups, which is supported by some additional characters. One is the junction of the fused dorsal scutes in males, which forms a sharp angle in the four largest species (fig. 207), but is rounded (fig. 352) to very obtuse (fig. 437) in the remaining two species represented by males. As the form of the scutal junction depends on scute size, this is also a size-dependent character. Two other characters are not obviously size dependent, although they also correlate with size: The male abdomen is round in cross section in the four largest species (fig. 207) and most strongly higher than wide in the smallest (fig. 437). Leg spine distributions show an even more unexpected pattern in that the smallest species have more spines than the largest. The hind legs of M. toliara, the smallest Malagiella, have both ventral and lateral spines (fig. 471). The largest species lack spines on the hind legs (fig. 467), whereas those of intermediate size have only ventroapical spines on the hind tibiae (fig. 469).
Using the above somatic differences, three species groups are recognized and compared in table 1. The ranomafana group includes large, dark species, with larger eyes, stronger carapace reticulation, largest abdominal scutes, and the absence of spines on the hind legs. The toliara group is represented by a single species, the smallest in the genus with the most diminutive structures, but with strongly spiny hind legs. The vohiparara group includes intermediate to small species, which have a few small spines on the hind legs.
TABLE 1
Comparison of the Malagiella species groups Abbreviations are defined in the Materials and Methods section. The character grouping “size” refers to differences that are apparently size related; “?” to those not obviously so; and “genitalic” to characters of the genitalia. Except for the few qualitative differences listed, the number of specimens examined is indicated by “N.”
The species are thus clearly placed in the groups, with some incongruity in the females of M. andringitra (figs. 278–280), which are somewhat paler and have a reduced dorsal scutum (DS), and so resemble members of the vohiparara group (figs. 355–357). However, the male of M. andringitra is readily included in the ranomafana group as it has a large DS with an acute scutal junction (figs. 275–277), and is unlike the reduced DS with a rounded scutal junction of male M. vohiparara (figs. 347, 352, 353). Despite this similarity, table 1 gives some genitalic characters that suggest a different species arrangement and are discussed below.
Genitalic Characters
Although these species groups are supported by mostly size-related adaptive characters, and run the risk of being merely grades, they also may have some genitalic support. Firstly, the size and position of the embolar opening is a possibility, although so far examined with SEM in only three species. In M. ranomafana the opening is large and centrally located (fig. 98), whereas in M. vohiparara (fig. 172) and M. toliara (fig. 193) it is smaller and in a more prolateral position. Secondly, the size of the sperm pore varies, being clearly larger in M. toliara (fig. 432) compared to the other species (figs. 203, 239, 271, 304, 348).
We were unable to find additional genitalic support for the species groups. The male palp differs only slightly among the species. The embolar region shows slight differences in shape and bulb ventral prong (BVP) length, and the palpal segments (primarily the patella and bulb) differ in size (figs. 481–486). But these differences do not suggest obvious groups. In fact, one character suggests an alternate grouping. A slight dorsal depression occurs on the bulb just distad of the tarsus boundary in M. toliara (fig. 486) and M. vohiparara (fig. 484). Although absent in most species of the ranomafana group (figs. 481, 483, 485), it also occurs in M. andringitra (fig. 482), suggesting either homoplasy or that the species is misplaced in that group.
The female genitalia are more variable and show differences in the degree of sclerotization, which are not easily quantified, and in the shape of the receptaculum, which varies from being relatively straight to broadly sinuous. The degree of sinuosity, here measured as the ratio of receptacular width to length (map 4), ups: (1) W/L = 0.2–0.4: M. andringitra, M. nikina, M. fisheri, M. goodmani; (2) W/L = 0.4–0.8: M. ranavalona, M. ranomafana, M. valterova; and (3) W/L = 0.9–1.2: M. vohiparara, M. ambalavo, M. toliara. This arrangement, summarized on map 4, is radically different from the one proposed above, since all three groups are now somatically heterogeneous by encompassing both larger and smaller species.
Intraspecific Variation
Although the male genitalia of Malagiella are fairly uniform in structure, there is considerable intraspecific variation in the female. This is most evident in M. ranomafana, not surprisingly the species represented by the largest series of specimens. Here the receptaculum varies in size and proportion, as well as degree of sinuosity (figs. 228–235). Although this degree of variation may suggest that multiple species are involved, the individuals are from a single region (two sites in Ranomafana National Park) where the variants occur sympatrically. And, as these individuals are otherwise similar in other characters, and no differences were observed in males, it seems that M. ranomafana as here defined represents a single species. Lesser differences in receptacular curvature also occur in M. nikina (figs. 405–408) and M. vohiparara (figs. 375–378).
One unusual variant is the presence of mirror-image differences in receptacular shape. This difference in curvature is not the result of rotation because the receptaculum is rigidly attached to the postepigastric scutum (figs. 182–184). Additionally, the receptaculum is also curved in more than one plane, three-dimensionally, to where a simple rotation would not account for the observed differences. Mirrored variants are shown here for M. ranomafana (figs. 230, 231), M. fisheri (figs. 327, 328), M. ranavalona (figs. 341, 342), M. vohiparara (figs. 375, 376), and M. nikina (figs. 405–408). Given this trend, it seems likely that this type of variation is common to the genus, and would be expected to occur in the remaining species currently represented mostly by singleton females. Of course, this variation is not apparent in M. goodmani, which has a straight receptaculum (figs. 423, 424). Of biological interest is whether these differences in receptacular handedness are reflected in the species' reproductive behavior; do the variants accommodate both right and left palpi equally?
Reproductive System
Male
The two prominent features of the male palp are the greatly enlarged patella and complete fusion of the bulb and cymbium (figs. 85–90, 93–97, 220–227). The embolus complex (E), positioned distally on the bulb, is compressed and retrolaterally concave. It consists of a ventral prong (BVP) and a dorsal embolus (E). The embolus has a retrolateral prong (ERP), which is in line with the BVP, and a prolateral prong (EPP), which along its anterior face has a groove (EG) extending from its tip to the orifice of the embolus (see figs. 93–99).
Female
The female reproductive system in Malagiella is externally fairly simple (figs. 100–107, 213, 228–235). The postepigastric scutum (PES) is narrow and reaches only slightly beyond the tracheae. The margins of the gonopore are swollen, glabrous, and smooth, in contrast to the adjacent cuticle. The posterior margin projects outward, forming a concavity that contains a round median orifice. Lateral of the median concavity are two patches of wrinkled cuticle, each bounded posteriorly by a slitlike orifice.
Internally (figs. 108–116, 179–184), the anterior edge of PES has a procurved carina with a deep groove along its posterior margin. Medially from this groove, a sclerotized tube originates and curves into the body cavity, bending posteriorly to about the level of PES. In most of our preparations, a membraneous sac, completely enclosing the tube and attaching to the edge of the carina, survived the digestion process (figs. 111–113). Additional digestion removed most of the sac, except for a distal remnant (figs. 182–184). On either side of the tube, level with the edges of the carina, originates a pair of stout apodemes, which also bend and extend posteriorly to the edge of PES. Given the relative placement of the external median orifice and internal tube, it is apparent that the former represents the copulatory opening and the latter, the receptaculum. The residual membrane must then represent the uterus wall. The paired, slitlike orifices clearly enter the base of the apodemes. A cross section further distad shows only a small, round opening, indicating that a broad slit must be restricted to the apodeme base.
Copulation
Images of the palpal tip and epigynum, in various views but at the same magnifications, were superimposed and examined in Photoshop. From these observations it is apparent that the copulatory opening (CO) is far too small to accommodate even the tip of the embolus. However, it is large enough to admit the tip of its prolateral prong. If this is the mode of insemination, then the embolar groove must function as an insemination tube, with the orifice of the embolus pressed against the adjacent cuticle to avoid losing sperm. The most likely place for this contact is in the median concavity, which in all species is glabrous and smooth. How this is achieved is uncertain, but it seems likely that some sort of stabilizing or anchoring mechanism would be needed. The immediate possibility is the male BVP and female apodeme orifices. Although the prongs (BVP) seem to be of the correct size to fit the orifices, this coupling would place the embolar opening (and the prolateral prong, EPP) far from the CO, unless the embolar complex can expand to accommodate the increased distance. However, the embolar region does not appear flexible and attempts to expand a palp in KOH did not change the relative positions of the embolar structures. A better possibility is that the ventral prong hooks into the gonopore (at the anterior lip of the PES), with the embolus tip resting on the side of the median concavity and the prolateral prong entering the CO. This genitalic orientation, with the male palp oriented 180° from that of the female, suggests a mating position with the male astride the female and the palp hooked over the female abdomen and into the epigynum. This possibility suggests a function to the male sternal bristles as gripping structures, and the palp, with its huge patellar musculature, as a clamping structure.
Sympatry
The species of Malagiella are largely allopatric, although this may be an artifact of inadequate collecting, as most of the species are known only from single localities and the range disjunctions suggest artificial gaps. The collections also suggest that the genus is rare, since the roughly 70 specimens sorted represent less than 1% of the total Malagasy oonopids available for study.
Presently, multiple species are known from only two regions, Ranomafana and Andringitra. Ranomafana is by far the most intensely sampled area of Madagascar, at least from the perspective of Malagiella, as the six collecting expeditions, totaling about five months of fieldwork, have produced 60% of all specimens. Of the two Malagiella species found here, the commonly collected M. ranomafana occurs in the Vatoharanana and Talatakely regions. The less common M. vohiparara is from a different region of the park, Vohiparara, but with a single collection at Talatakely where it is sympatric with M. ranomafana. Based on current collecting records, the two species are not broadly sympatric.
The second region, Andringitra, was much less intensely sampled, having been visited during a single expedition where Malagiella were collected on only three days. Despite this difference, three species were collected here, but all at different localities and elevations: M. andringitra at 1680 m, M. ambalavo at 1275 m, and M. nikina at 825 m. Despite their close distributions, these species are currently allopatric.
Biogeography
The species distributions are plotted on maps 1 to Map 2Map 34. Map 1 plots the species on the current vegetation map of Madagascar. Map 2 arranges the species into our tentative species groups based primarily on size differences. The ranomafana group (squares) occupies the easternmost part of the distribution and is parapatric with the vohiparara group (circles). The toliara group (triangles) is disjunct in the SW part of the island. Thus, the largest species are eastern and the smallest are western and southern.
Map 3 shows the palpi, depicted at the same scale, and arranged geographically. Here M. andringitra is grouped with M. vohiparara and M. toliara, on the basis of the dorsal depression of the palpal bulb. This group, in contrast to the arrangement based on somatic characters, includes a large, medium, and small species, and geographically spans the width of the island. The reduced ranomafana group shows a distinct cline of palp size, with the largest southernmost.
Map 4 shows a representative epigynum of each species, also plotted geographically. Of interest is that the distribution, although different from that suggested by our preferred species groups, also has geographic integrity. The least sinuous receptacula occur in the SE corridor, the moderately sinuous to the north, and the most sinuous from eastern central to the southwest. Also interesting is that this latter range corresponds to the area suggested by the palpal bulb depression. The discovery and study of the unknown males of vohiparara group is critical for resolving the dilemma of which species grouping is to be preferred.
MATERIALS AND METHODS
Specimens were examined using a LEICA MZ 12.5, MZ16A and Nikon compound microscope. Automontaged images were made using the Leica LAS software. For scanning electron microscopy individuals were dehydrated in 100% ethanol, then critical point dried, sputter coated, and imaged with a LEO 1450 VP SEM or Hitachi S-520 SEM. Female genitalia were examined directly, using clove oil, lactic acid, and/or methyl salycilate, and with the soft tissues digested using pancreatin and lens-cleaning enzyme.
Descriptions were generated with the aid of the PBI descriptive goblin spider database and shortened where possible. Female descriptions include only differences from the male. For leg spination, the segment is divided into thirds and the number of included spines given basal to distal. Only spine-bearing surfaces are listed and are indentified by the abbreviations: p (prolateral), r (retrolateral), d (dorsal) or v (ventral). The localities were mapped using Google Earth and the plates prepared in Adobe Photoshop. The vegetation map of Madagascar is from Du Puy and Moat (2003) and was obtained online from the GIS Unit of the Royal Botanic Gardens, Kew, and used with permission. Measurements are in millimeters, unless indicated otherwise.
Coded numbering systems and databases featured in the paper include the Goblin Spider PBI specimen-level database and California Academy of Sciences Entomology specimen-level database. The former, e.g., PBI_OON plus the respective number, belongs to a database encompassing all specimen lots studied by the participants in the Goblin Spider PBI that represents more than 60,000 specimens from more than a score of institutions. The latter, e.g., CASENT plus the respective number, belongs to a specimen-level database at CAS with numbers assigned to lots for the more than 12,000 goblin spiders. Neither numbering system connotes specimen ownership: that information is contained within the databases. Other codes featured, e.g., BLF plus a number, represent collecting events. Full data are available from the authors upon request.
Abbreviations
abd abdomen
ALE anterior lateral eye(s)
ALS anterior lateral spinneret(s)
B bulb
BL book lung
BLC book lung cover
BVP bulb ventral prong
car carapace
CO copulatory orifice
DS dorsal scutum
E embolus
EG embolar groove
EPP embolar prolateral prong
ERP embolar retrolateral prong
ES epigastric scutum
F femur
G gonopore
H height
L length
P patella
PA posterior apodeme
PER posterior eye row
PES postepigastric scutum
PLE posterior lateral eye(s)
PLS posterior lateral spinneret(s)
PME posterior median eye(s)
PMS posterior median spinneret(s)
Ta tarsus
Ti tibia
TBL total body length
Tr trachea
VS ventral scutum (ES + PES)
W width
COLLECTIONS EXAMINED
AMNH American Museum of Natural History, New York
CAS California Academy of Sciences, San Francisco
FMNH Field Museum of Natural History, Chicago
MCZ Museum of Comparative Zoology, Harvard University
NHMB Natural History Museum, Bern
USNM National Museum of Natural History, Washington, D.C
SYSTEMATICS
Malagiella, new genus
Diagnosis
Malagiella differs from other oonopid genera, except Camptoscaphiella, by the combined presence of strong leg spines, reduced abdominal scutes, eyes contiguous, palpal patella greatly enlarged in male, and epigynum with single external copulatory opening. Males differ from Camptoscaphiella in having the palpal bulb fused to the cymbium (fig. 8) and the sternum with a median patch of stiff bristles (fig. 7, except in M. fisheri: figs. 305, 474) and its anterior margins forming pointed cones (figs. 7, 472–477). Females differ in having a round copulatory opening (fig. 11), which is slitlike in Camptoscaphiella (fig. 5), and bifid claws of leg 4 (figs. 9, 10), which are simple in Camptoscaphiella (figs. 3, 4).
Description: Male
Total length 1.0–1.7. Color uniform yellow orange (figs. 346, 430) to reddish brown (figs. 201, 269), with carapace and dorsal scute slightly darker than the legs and venter (figs. 270, 395); unsclerotized parts of abdomen pale to white (figs. 202, 347, 431); palpi usually darker than legs (figs. 474, 477). CEPHALOTHORAX: Carapace ovoid (figs. 15, 120, 201, 346) to elongate (fig. 430) in dorsal view, pars cephalica elevation slight (figs. 14, 202) to strong (figs. 117, 347), anteriorly narrowed from 0.53–0.64 times its maximum width (anterior width measured across eye area, as in fig. 15), with rounded posterolateral corners (figs. 201, 346, 430), posterolateral edge without pits, posterior margin not bulging below posterior rim, anterolateral corners without extension or projections, posterolateral surface without spikes; surface and sides of elevated portion of pars cephalica and thoracica with variable sculpturing, strong with reticulation of deep hexagonal cells (figs. 13–15) to weak with shallow and elongate cells (figs. 117–120) to smooth (fig. 430); thorax without depressions, fovea absent, without radiating rows of pits; lateral margin undulate strongly (fig. 202) to slightly (figs. 117, 347, 431), rebordered, without denticles; plumose setae near posterior margin of pars thoracica absent; nonmarginal pars cephalica setae needlelike; nonmarginal pars thoracica setae absent; marginal setae absent. Clypeus weakly rebordered, in front view slightly downcurved at sides (figs. 17, 119), sloping in lateral view; high, as long as eye area length (fig. 14) to twice eye area length (figs. 117, 119); setae present, light, needlelike; median projection absent. Chilum absent. Eyes six, large (fig. 13), medium sized (fig. 119), or small (fig. 430); ALE slightly larger than others, oval, PLE oval, PME squared; posterior eye row procurved in anterior and dorsal views; ALE touching, ALE-PLE touching, PLE-PME touching, PME touching for most of their length. Sternum longer than wide, not fused to carapace; with radial furrows between coxae I–II, II–III, III–IV (figs. 19, 125, 434), radial furrow opposite coxae III absent; cuticle smooth to finely wrinkled (figs. 19, 126), without pits, sickle-shaped structures absent, without posterior hump, posterior margin extending posteriorly beyond anterior edges of coxae IV as single extension; lateral margin with infracoxal grooves, grooves with openings at anterior and posterior ends (fig. 19) or only at posterior ends (fig. 125, of female in fig. 130), distance between coxae approximately equal, extensions of precoxal triangles present; anterior margin with continuous transverse groove, median longitudinal groove strong (fig. 20) or weakly represented (fig. 126); anterolateral margins with conical extensions (figs. 19, 126, 472–477); with two anteromedian patches of long stiff bristles (figs. 19, 125, 472, 473, 475–477) but absent in M. fisheri (fig. 474); lateral and posterior setae needlelike, originating from surface, without hair tufts. Chelicerae slightly divergent, anterior face unmodified; promargin with one tooth, retromargin without teeth (figs. 25, 136); fangs without toothlike projections, directed medially, shape normal, without prominent basal process, tip unmodified; setae light, needlelike, densest medially; paturon inner margin with scattered setae, distal region unmodified, posterior surface with three long setae (figs. 19, 135), promargin with row of flattened setae, inner margin with very long setae (figs. 24, 133), laminate groove absent. Labium triangular, anterior margin indented at middle; with six or more setae on anterior margin, subdistal portion with unmodified setae (figs. 26, 127); not fused to sternum, same as sternum in sclerotization. Endites distally excavated, serrula present in single row (figs. 27, 128); distomedian part with projection bearing dense scopula, distolateral part with swelling bearing serrula and three stout setae; posteromedian part unmodified (figs. 26, 27, 127, 128). ABDOMEN: Ovoid (figs. 201, 237, 269, 302) or cylindrical (figs. 346, 433), without long posterior extension, rounded posteriorly, interscutal membrane without rows of small sclerotized platelets. Book lung covers large, ovoid (figs. 207, 208, 352, 353, 438), without setae, anterolateral edge unmodified. Posterior spiracles not connected by groove (figs. 34, 147). Pedicel tube short (figs. 142, 353, 438) to medium length (figs. 31, 208, 309), scutum extending far dorsal of pedicel from about one (figs. 31, 208, 309) to almost two (figs. 142, 353, 438) pedicel diameters, scuto-pedicel region unmodified, plumose hairs absent, matted setae on anterior ventral abdomen in pedicel area absent, cuticular outgrowths near pedicel absent. Dorsal scutum without color pattern, covering abdomen completely (figs. 201, 202) or partially (figs. 346, 347, 430, 431); fused to epigastric scutum (figs. 31, 32, 142–146, 207, 208, 243, 275, 308, 352, 353, 437, 438), forming acute (fig. 207) or obtuse (figs. 352, 438) angle; anterior half without projecting denticles; middle surface smooth, sides smooth. Epigastric scutum strongly (figs. 207, 208) or weakly (figs. 437, 438) sclerotized, surrounding pedicel, not protruding, small lateral sclerites absent. Postepigastric scutum usually strongly sclerotized (fig. 208), rarely weakly (fig. 438); long, covering most of epigastric area (figs. 203, 348), or short (fig. 432); fusedto epigastric scutum, anterior margin unmodified, without posteriorly directed lateral apodemes. Abdominal setae uniform, light, needlelike; present on dorsal scutum, epigastric scutum, postepigastric scutum, and interscutal membrane; dense patch of setae anterior to spinnerets present, may be weak. Spinneret scutum present, incomplete ring with fringe of needlelike setae; supraanal scutum absent. Spinnerets (scanned in M. ranomafana, fig. 40, and M. vohiparara, fig. 149): ALS with three spigots (figs. 41, 150), PMS with two spigots (figs. 42, 151), PLS with four spigots in M. ranomafana (fig. 43) and three spigots in M. vohiparara (fig. 152). Colulus represented only by setae. LEGS: Without color pattern; femur IV not thickened, same size as femora I–III; patella plus tibia I longer than carapace, tibia I unmodified; tibia IV ventral scopula absent, specialized hairs on ventral apex absent; metatarsi I, II mesoapical comb absent, metatarsi III, IV weak ventral scopula absent. Leg spines present, longer than segment width, typical pattern: femur I p0-1-0; tibiae I, II v4-4-0; metatarsi I, II v2-2-0; additional spines in M. vohiparara and M. toliara: tibia IV v0-0-2 (apical spines); and in M. toliara: metatarsus III p0-1-0, r0-1-0, metatarsus IV, tibia IV p1-1-0, r1-1-0. Tarsi I–IV superior claws examined in detail (in M. ranomafana); tarsal proclaws and retroclaws with faces striate; tarsi I, II superior claws with three large teeth on lateral surfaces and three small teeth on median surfaces of both proclaw and retroclaw (figs. 74–76); tarsi III, IV superior claws with three teeth on lateral surfaces of proclaw and retroclaw, lacking teeth on median surfaces (figs. 77, 78); tarsal claws I–IV lacking inferior claw (figs. 74–78); tarsal claws III, IV each with three modified clawlike setae (figs. 77, 78). Trichobothria: tibia, each with three; metatarsus, each with one; trichobothrial base longitudinally narrowed, aperture internal texture not gratelike, hood covered by numerous low, closely spaced ridges (figs. 62–64), ridges usually transversely arranged, but radially in one of the two distalmost tibial trichobothria (fig. 63). Tarsal organ with 2 sensillae on palp and tarsi III, IV (figs. 57, 60, 61); 3 sensilla on tarsi I, II (figs. 58, 59). GENITALIA: Epigastric region with sperm pore large, oval, rebordered, situated between anterior and posterior spiracles (figs. 34–36, 148, 432); furrow without Ω-shaped insertions, without setae. Palp normal size, not strongly sclerotized (burnt); right and left palps symmetrical; embolus dark, prolateral excavation absent; trochanter normal size, unmodified; femur normal size, without posteriorly rounded lateral dilation, attaching to patella medially; patella greatly enlarged, three to five times femur length (figs. 481–486), without prolateral row of ridges, setae unmodified; tibia shorter than patella, tibia not enlarged, trichobothria not examined; cymbium ovoid in dorsal view, completely fused with bulb, no seam visible, not extending beyond distal tip of bulb, plumose setae absent, without stout setae, without distal patch of setae; bulb tapering apically.
Female
Total length 1.3–1.9. Color as in male, but abdomen paler because of more exposed membrane (figs. 212, 357, 440–442) and palpi no darker than legs (figs. 478–480). CEPHALOTHORAX: Carapace as in male, but pars cephalica less strongly elevated (figs. 18, 212, 121, 357, 442) and narrower, anteriorly narrowed from 0.49–0.41 times its maximum width. Clypeus lower than in male (figs. 18, 121). Sternum as in male but anterior margin without transverse groove (figs. 21, 129), surface smoother and lacking median longitudinal groove; anterolateral margin unmodified, lacking conical extensions; anteromedian patch of strong bristles absent; setae unmodified, evenly scattered (figs. 21, 130). Chelicerae (figs. 28, 29) as in male. Labium (figs. 29, 132) as in male. Endites distally not excavated, without median or lateral modifications, three setae near serrula slender, not stout (figs. 29, 30, 132). Female palp lacking claw or spines; tarsus unmodified; tibia with three trichobothria; patella without prolateral row of ridges (figs. 48–50, 463–465). ABDOMEN: Ovoid (figs. 211, 356) or cylindrical (fig. 441). Book lung covers (figs. 217, 218, 386, 447) as in male. Pedicel tube, as in male, either short (figs. 337, 363, 448) or of medium length (figs. 218, 319); scutum dorsal extension shorter than in male, from 0.2 to 0.6 pedicel diameters (figs. 116, 336, 362, 386, 400, 447) to about one diameter (figs. 217, 253, 318). Dorsal scutum size variable, may cover abdomen almost completely (figs. 247, 248), partially (figs. 279, 356), or minimally (figs. 330, 441); not fused to epigastric scutum (figs. 37, 38, 217, 336, 362). Epigastric scutum strongly (figs. 217, 218) or weakly (figs. 336, 337) sclerotized, without lateral joints. Postepigastric scutum broadly hexagonal; sclerotized strongly (fig. 228), or weakly (figs. 375, 459); not fused to epigastric scutum, with posteriorly directed lateral apodemes, with small lateral sclerites (figs. 213, 342, 382). Dense patch of setae anterior to spinnerets present (figs. 218, 219), but may be weak (figs. 364, 448). Spinnerets (scanned in M. ranomafana, fig. 44, and M. vohiparara, fig. 153): ALS with three spigots (figs. 45, 154), PMS with three spigots (figs. 46, 155), PLS with six spigots in M. ranomafana (fig. 47) and five spigots in M. vohiparara (fig. 156). LEGS: Leg spination (figs. 466–471) as in male. Tarsi I–III superior claws (figs. 79–82) as in male, tarus IV superior claws with three teeth on lateral surfaces and one large apical tooth on median surfaces of both proclaw and retroclaw (figs. 83, 84). Trichobothria (figs. 70–73) as in male. Tarsal organ (figs. 65–69) as in male.
Natural History
Little can be said of the natural history of Malagiella. All species for which there is information occur in forests; most are from eastern evergreen humid forests, M. toliara and M. goodmani are from southern deciduous dry forests. Based on collection data, 38 specimens were collected from sifted leaf litter and 18 from pitfall traps. Females represent most of the sifted specimens (25) and males most of the pitfall specimens (12), in both cases by a factor of 2. This suggests that females are more stationary in favorable litter habitats and that males are more mobile, as would be expected.
Species Included
Malagiella ambalavo, M. andringitra, M. fisheri, M. goodmani, M. nikina, M. ranavalona, M. ranomafana, M. toliara, M. valterova, and M. vohiparara.
Distribution
Known only from Madagascar.
Key to the Species of Malagiella
1 Males (not known for M. ambalavo, M. goodmani, M. nikina, and M. ranavalona)2
– Females7
2 Size large, TBL > 1.5; eyes large, PER W = 0.5 cephalon W (fig. 205); color reddish brown; carapace strongly reticulated, forming rounded cells (fig. 15); abdomen with dorsal and ventral scutes broad, contact zone a sharp, acute indentation (figs. 31, 32, 207, 243, 275, 308); legs III and IV lacking spines(ranomafana group) 3
– Size smaller, TBL < 1.4; eyes smaller, PER W < 0.4 cephalon W (figs. 350, 435); color orange to yellowish brown; carapace weakly reticulated, forming elongate cells (figs. 117, 118), or smooth (figs. 430, 431); abdomen with dorsal and ventral scutes narrower, contact zone a rounded, broader indentation (figs. 142–146, 352, 353, 437, 438); at least tibia IV with ventroapical spines6
3 Sternum lacking long stiff bristles (figs. 323, 474); palpal patella-tibia L > cephalothorax H (figs. 303, 306)M. fisheri
– Sternum with long stiff bristles (figs. 7, 204); palpal patella-tibia L < cephalothorax H (figs. 202, 238, 270)4
4 Cymbium-bulb larger; about 0.6 patella-tibia L (fig. 482); bulb with dorsal depression at tarsal junction (figs. 288, 289, 294, 295); eyes slightly smaller (fig. 270)M. andringitra
– Cymbium-bulb smaller; about 0.5 patella-tibia L (figs. 481, 483); bulb lacking dorsal depression (figs. 481, 483); eyes slightly larger (figs. 202, 238)5
5 Palpal patella relatively shorter (fig. 481), abdomen with ventral scute slightly shorter (figs. 203, 208, 209)M. ranomafana
– Palpal patella relatively longer (fig. 483), abdomen with ventral scute slightly longer (figs. 238, 244, 245)M. valterova
6 Size smaller (TBL < 1.2); DS narrow, about as wide as DS-VS contact zone (figs. 432, 433, 437); VS short, distance from sperm pore to posterior edge shorter than to anterior edge (fig. 432); palpal patella short, patella-tibia L/cymbium-bulb L = 1.3 (fig. 486); tibia III and IV with lateral spines(toliara group) M. toliara
– Size larger (TBL 1.2–1.4); DS wider, much wider than DS-VS contact zone (fig. 352); VS long, distance from sperm pore to posterior edge longer than to anterior edge (fig. 358); palpal patella longer, patella-tibia L/cymbium-bulb L = 1.9 (fig. 484); tibia III and IV lacking lateral spines(vohiparara group) M. vohiparara
7 Size small, TBL ca 1.3; color yellowish orange; legs III and IV with distinct lateral spines (fig. 471)(toliara group) M. toliara
– Size larger, TBL ≥ 1.4; color orange to dark brown; legs III and IV lacking lateral spines (figs. 467, 469)8
8 Tibia IV lacking ventroapical spines (fig. 467); larger darker species with larger eyes, eye area at least 0.5 cephalon width (fig. 283), usually wider (figs. 16, 215, 251, 316), eye area longer than clypeus (figs. 14, 212, 248, 280, 313)(ranomafana group) 9
– Tibia IV with a pair of small ventroapical spines (fig. 469); smaller paler species with smaller eyes, eye area less than 0.5 cephalon width (figs. 123, 334), eye area as long as clypeus (fig. 121); eyes somewhat larger in M. nikina, which has an eye row approaching 0.5 cephalon width (fig. 394)(vohiparara group) 12
9 DS small, L < 0.7 abdomen L, W < 0.6 abdomen W (figs. 279, 280); receptaculum relatively straight in ventral view (figs. 296–298)M. andringitra
– DS large, L > 0.8 abdomen L, W > 0.7 abdomen W (figs. 211, 247, 312); receptaculum curvature variable (figs. 228–235, 264–267, 327, 328)10
10 Receptaculum nearly straight in ventral view, W/L < 0.3 (map 4); posterior margin of PES procurved (figs. 328, 329)M. fisheri
– Receptaculum more strongly sinuous, W/L > 0.3 (map 4); posterior margin of PES straight (figs. 228–235, 264–267)11
11 Receptaculum more sinuous, W/L = 0.7 (figs. 264–267); DS with anterior margin broad (fig. 253)M. valterova
– Receptaculum less sinuous, W/L = 0.3–0.5 (figs. 228–235); DS with anterior margin pointed (fig. 217)M. ranomafana
12 Receptaculum relatively straight, W/L < 0.4 (map 4)13
– Receptaculum sinuous, W/L > 0.7 (map 4)14
13 Receptaculum slender and somewhat sinuous (figs. 403–410); larger size, TBL = 1.48–1.64; larger eyes, eye area about 0.5 cephalon width (fig. 394)M. nikina
– Recepataculum stout and very straight (figs. 421–428); smaller size, TBL = 1.40–1.48; smaller eyes, eye area clearly less that 0.5 cephalon width (figs. 412, 416)M. goodmani
14 DS small, about 0.3 abdomen width, 0.5 abdomen length (fig. 330); receptaculum moderately sinuous, W/L = 0.76 (figs. 339–344)M. ranavalona
– DS larger, about 0.5 abdomen width, 0.7 abdomen length (figs. 356, 380); receptaculum strongly sinuous, W/L = 0.9–1.2 (figs. 373–378, 389–392)15
15 Receptaculum more sinuous, W/L = 1.0–1.2 (figs. 373–378)M. vohiparara
– Receptaculum less sinuous, W/L = 0.9 (figs. 389–392)M. ambalavo
Malagiella ranomafana species group
Diagnosis
Members of this group are large reddish brown species with prominent carapace reticulation (figs. 13–18) and an absence of spines on the hind legs (fig. 467). Eyes are large, with PER width about 0.5 cephalon width (figs. 15, 16) and eye area length subequal to clypeus in males (fig. 14) or greater than clypeus length in females (fig. 18). Male abdomen with dorsal and ventral scutes broad (fig. 201), with contact zone acutely indented (figs. 207, 208).
Species Included
Malagiella andringitra, M. fisheri, M. ranomafana, and M. valterova.
Malagiella ranomafana, new species
Figures 7–Figs. 13–18Figs. 19–23Figs. 24–30Figs. 31–39Figs. 40–47Figs. 48–56Figs. 57–73Figs. 74–84Figs. 85–92Figs. 93–99Figs. 100–107116, 200–Figs. 210–219Figs. 220–227235, 463, 466, 467, 475, 478, 481, 487; maps 1–Map 2Map 34; table 1
Type
Male holotype, female allotype, and female paratype from Talatakely, P.N. Ranomafana, 21°15′S, 47°25′E, 900 m, Fianarantsoa Province, Madagascar (5–7 Dec 1993, N. Scharff, S. Larcher, C. Griswold, R. Andriamasimanana), deposited in CAS (CASENT 9029645, PBI_OON 03225).
Diagnosis
The male may be distinguished from other species in the group by the combination of sternum strongly bristly, bulb-cymbium small (about 0.5 patella-tibia length), and a palpal patella of moderate size (fig. 481). The female differs by the combination of large dorsal scutum, PES with straight posterior margin, and receptaculum moderately sinuous (W/L = 0.3–0.5) (figs. 228–235).
Male (PBI_OON 03225)
Total length 1.70 (1.56–1.70), carapace length 0.80 (0.78–0.80), width 0.64 (0.62–0.66), N = 12. CEPHALOTHORAX: Carapace ovoid in dorsal view, pars cephalica slightly elevated in lateral view, anteriorly narrowed to about 0.55 times its maximum width; lateral margin strongly undulate (fig. 14). Eye area width 0.5 carapace width, length 1.2 clypeus length (figs. 13–15). Sternum lateral margin infracoxal grooves present, with anterior and posterior openings (fig. 19). Mouthparts: Cheliceral paturon posterior surface with a row of three long setae (fig. 19); with promarginal tooth and denticles on both margins (fig. 25). Endite with median lobe bearing dense scopula and lateral lobe with serrula and three stout setae (figs. 26, 27). ABDOMEN: Pedicel tube of medium length (fig. 208), dorsal extension of epigastric scute about one pedicel diameter (fig. 207). Spinnerets: ALS with three subequal spigots; PMS with two subequal spigots; PLS with four subequal spigots (figs. 40–43). LEGS: Tarsi I–IV superior claws examined in detail: tarsal proclaws and retroclaws with faces striate; tarsi I, II superior claws with three large teeth on lateral surfaces and three small teeth on median surfaces of both proclaw and retroclaw; tarsi III, IV superior claws with three teeth on lateral surfaces of proclaw and retroclaw, lacking teeth on median surfaces; tarsi I–IV lacking inferior claw (figs. 74–78); tarsal claws III, IV each with three modified clawlike setae (figs. 77, 78). Trichobothria examined with SEM: trichobothrial base longitudinally narrowed, aperture internal texture not gratelike; hood covered by numerous low closely spaced ridges, usually in transverse orientation but radially arranged in proximal half of some bothria; both types of ridges occur on tibial trichobothria (figs. 62–64). Tarsal organ with 2 sensilla on palp and tarsi III, IV; 3 sensilla on tarsi I, II (figs. 57–61). GENITALIA: Epigastric region with sperm pore small, rebordered (figs. 34–36). Palp (figs. 85–97, 220–227, 481, map 3) bulb pale orange, more than 2 times as long as cymbium; embolar complex (figs. 93–97) distal, compressed, retrolaterally concave, with hyaline ventral prong (BVP) and dorsal embolus, apex transversely expanded with median opening and lateral prongs, prolateral prong (EPP) with groove connecting embolar opening (fig. 98).
Female (PBI_OON 01999)
Total length 1.71 (1.71–1.96), carapace length 0.82 (0.80–0.84), width 0.66 (0.64–0.68), N = 11. CEPHALOTHORAX: Clypeus shorter than eye region length (fig. 18), anteriorly narrowed to about 0.49 times its maximum width. Eyes (figs. 16–18, 215) as in male. Sternum microsculpture covering entire surface (figs. 21–23). Chelicerae (figs. 28, 29) and labium (fig. 29) as in male. Endites lacking anteromedian projection and anterolateral knob, three setae near serrula not stout (figs. 29, 30). ABDOMEN: Pedicel tube of medium length (fig. 218) and epigastric scutum dorsal extension (fig. 217), both slightly shorter than in male. Dorsal scutum covering more than 0.7 of abdomen (figs. 211, 212), not fused to epigastric scutum (figs. 37, 38, 217, 218). Postepigastric scutum short, extending only to posterior spiracles, with small lateral sclerites, internally with short posteriorly directed lateral apodemes (figs. 108, 116, 213). Spinnerets: ALS with three spigots, median slightly larger; PMS with three subequal spigots; PLS with six subequal spigots (figs. 44–47). LEGS (figs. 466, 467): With fine transverse ridges delineating regions of muscle attachment (figs. 54, 55) and slit sensilla (figs. 51–53). Tarsal claws as in male except: tarsus IV superior claws with three teeth on lateral surfaces and one large apical tooth on median surfaces of both proclaw and retroclaw (figs. 79–84). Trichobothria (figs. 70–73) as in male. Tarsal organ (figs. 65–69) as in male. GENITALIA: Ventral view (figs. 100–107, 228–234, map 4): epigynal area with median depression enclosing small round hole (copulatory opening) (figs. 101, 103, 105), with a pair of slitlike openings at base of apodemes (fig. 104), with sigmoid tube (receptaculum) and a pair of paramedian apodemes visible through cuticle (figs. 228, 234). Dorsal view (figs. 108–116, 235): receptaculum sigmoid, reaching posteriorly slightly beyond postepigastric scutum; with pair of lateral apodemes. The receptaculum varies considerably in size, degree of sinuation, and direction of curvature (figs. 228–235).
Other Material Examined
MADAGASCAR: Fianarantsoa Province: Ranomafana N.P., 21°12′S, 47°27′E, forest, 1–30 Apr 1992 (V. Roth, B. Roth, S. Kariko, CASENT 9029651, PBI_OON 03231), 1♀; Ranomafana N.P., Maharira, 09 Apr 1992 (Emile, Kariko-Roth Coll., MCZ 53653, MCZ 53656, PBI_OON 00028216, PBI_OON 00028217), 2♀; Trail F, 325 m, 18 May 1992 (Emile, Kariko-Roth Coll., MCZ 53652, PBI_OON 00028212), 1♀; Trail L, 1050 m, 15 Apr 1992 (Emile, Kariko-Roth Coll., MCZ 53626, PBI_OON 00028214), 2♀; Trail M, 15 May 1992 (Albert, Kariko-Roth Coll., MCZ 53657, PBI_OON 00028215), 1♀; across footbridge at campsite, 26 Mar 1992 (S. Kariko, V. Roth, MCZ 53646, PBI_OON 00028213) 6♀; Talatakely, P.N. Ranomafana, 21°14.9′S, 47°25.6′E, sifting leaf litter, 5–18 Apr 1998 (C. Griswold, D. Ubick, CASENT 9029647, PBI_OON 03227), 1♂, 2♀; 19–30 Apr 1998 (C. Griswold, D. Ubick, CASENT 9029649, PBI_OON 03229), 1♀; pitfall trap, 13–27 Apr 1998 (Griswold et al., CASENT 9029650, PBI_OON 03230), 1♂; 21°15.3′S, 47°25.9′E, pitfall trap, 9–26 Apr 1998 (Griswold et al., CASENT 9029644, PBI_OON 03224), 2♂, 3♀; 21°15′S, 47°26′E, 915–1000 m, 30 Oct–20 Nov 1998 (V. Lee, K. Ribardo, CASENT 9029648, PBI_OON 03228), 1♂; 21°15.8′S, 47°25.2′E, 940–985 m, pitfall trap, 1–21 Nov 1998 (V. Lee, K. Ribardo, CASENT 9029646, PBI_OON 03226), 1♂; 21°15.5′S, 47°25.4 E, 1050 m, montane rainforest, 24 Dec 2005–14 Jan 2006 (H. Wood, J. Miller, et al., HW009, CASENT 9019096, PBI_OON 03433), 2♂, 2♀; Vatoharanana 1100, −21.29, 47.43333, 1100 m, montane rainforest, pitfall trap, 27–31 Mar 2003 (Fisher, Griswold et al., BLF8402, CASENT 9011546, PBI_OON 03232), 2♂, 1♀; sifted litter, leaf mold, rotten wood, 27–31 Mar 2003 (Fisher, Griswold et al., BLF8400, CASENT 9011421, PBI_OON 02216), 1♀; Vatoharanana 1200, 21°16.7′S, 47°26.1′E, 1200 m, primary rainforest understory, 15–29 Apr 1998 (Griswold et al., CASENT 9025683, PBI_OON 01999), 4♂, 3♀; sifting leaf litter, 15 Apr 1998 (C. Griswold, D. Ubick, CASENT 9029652, PBI_OON 03233), 1♀; 7 km SW Ranomafana, 21.12°N, 47.27°E, 1000 m, 20–24 Mar 1990 (W. Steiner, USNM, PBI_OON 00027793), 1♀.
Distribution
Known only from Ranomafana National Park, Madagascar.
Malagiella valterova, new species
Figures 236–Figs. 246–255Figs. 256–263267, 473, 483, 487; maps 1–Map 2Map 34; table 1
Type
Male holotype and female allotype from sifted litter along Tatamaly River, 21°30′42″S, 47°24′36″E, 1075 m, 2 km W Andrambovato, Fianarantsoa Province, Madagascar (3–5 Jun 2005, B. Fisher), deposited in CAS (CASENT 9030812, PBI_OON 03461).
Etymology
This species is named after Darrell Ubick's late father, “Valter” Ubick, in remembrance of many years of companionship, and is given in Croatian genitive.
Diagnosis
The male of this species most closely resembles M. ranomafana, from which it differs by its longer palpal patella and bulb-cymbium (fig. 483), and by the slightly longer ventral abdominal scute (fig. 239). The female differs from others in the group in having a widely sinuous receptaculum, W/L ca. 0.7 (figs. 264–267).
Male (PBI_OON 03461)
Total length 1.55, carapace length 0.78, width 0.62. CEPHALOTHORAX: Carapace as in M. ranomafana (figs. 237, 238, 241, 242). Clypeus as in M. ranomafana, but slightly longer (figs. 238, 241). Eyes as in M. ranomafana, eye area width 0.5 carapace width; length subequal to clypeus length. Sternum as in M. ranomafana (figs. 240, 473). ABDOMEN (figs. 239, 243–245) as in M. ranomafana. ABDOMEN: Ventral scute (fig. 239) slightly longer than in M. ranomafana. GENITALIA: Epigastric region with sperm pore small, rebordered (fig. 263). Palp (figs. 256–262, 483) slightly larger than in M. ranomafana.
Female (PBI_OON 03461)
Total length 1.70, carapace length 0.80, width 0.66. CEPHALOTHORAX (figs. 246–248, 251, 252): Clypeus shorter than eye region length (fig. 248). Eye area 1.6 clypeus length (figs. 247, 248, 251). ABDOMEN (figs. 249, 253–255): Dorsal scutum slightly longer than in M. ranomafana. GENITALIA: Ventral view: receptaculum slender and strongly sinuous, W/L about 0.7 (figs. 264–267, map 4).
Distribution
Known only from the type locality.
Malagiella andringitra, new species
Figures 268–Figs. 278–287Figs. 288–295300, 472, 482, 487; maps 1–Map 2Map 34; table 1
Type
Male holotype and female allotype sifted from leaf litter in rainforest, 38 km S Ambalavo, 22°12′S, 46°58′E, 1680 m, Res. Andringitra, Fianarantsoa Province, Madagascar (23 Oct 1993, B. Fisher), deposited in CAS (♂ holotype: CASENT 9029653, PBI_OON 03234; ♀ allotype CASENT 9029669, PBI_OON 03376).
Diagnosis
The male differs from others in the group by the large bulb-cymbium (about 0.7 patella-tibia length; but about 0.5 in other species) and the presence of a shallow dorsal groove proximally on the bulb (fig. 482). The female differs in having a smaller dorsal scute (fig. 279) and the epigynal region weakly sclerotized and the receptaculum short and relatively straight (W/L about 0.25) (figs. 296, 297).
Male (PBI_OON 03234). Total length 1.53, carapace length 0.74, width 0.62. CEPHALOTHORAX: Carapace (figs. 269, 270, 274) as in M. ranomafana. Eyes as in M. ranomafana, but slightly smaller; eye area about 0.5 carapace width, length subequal to clypeus length (figs. 269, 273). Sternum (figs. 272, 472) as in M. ranomafana. ABDOMEN (figs. 269, 271, 275–277) as in M. valterova, but with slightly smaller book lung covers. GENITALIA: Epigastric region with sperm pore small, rebordered (fig. 271). Palp with bulb-cymbium large, about 0.7 patella-tibia length; bulb with dorsal depression (figs. 288–295, 482, map 3).
Female (PBI_OON 03376). Total length 1.82 (1.80–1.82), carapace length 0.78, width 0.68 (0.66–0.68), N = 2. CEPHALOTHORAX (figs. 278–280, 283, 284): Clypeus sloping forward in lateral view, shorter than eye row length (fig. 280). Eye area about 1.3 clypeus length (figs. 280, 283). ABDOMEN (figs. 281, 285–287): Pedicel tube short (fig. 286), scutum dorsal extension slightly less than pedicel diameter (fig. 286). Dorsal scutum smaller than carapace, covering about 0.6 abdomen length and width (fig. 279). Postepigastric scutum weakly sclerotized. LEGS: patella plus tibia I longer than carapace (fig. 280). GENITALIA: Epigynal region weakly sclerotized, receptaculum short and relatively straight, W/L about 0.25 (figs. 296–300, map 4).
Other Material Examined
MADAGASCAR: Fianarantsoa Province: Res. Andringitra, 38 km S Ambalavo, 22°12′S, 46°58′E, 1680 m, rainforest, sifting leaf litter, 23 Oct 1993 (B. Fisher, CASENT 9029654, PBI_OON 03375), 1♀.
Distribution
Known only from the type locality in Res. Andringitra, Madagascar.
Malagiella fisheri, new species
Figures 301–Figs. 311–320328, 474, 485, 487; maps 1–Map 2Map 34; table 1
Type
Male holotype and female allotype from sifting leaf litter in rainforest, at 28.5 km S Midongy-Sud, Mount Papango, 23°50.1′S, 46°57.8′E, 940 m, P.N. Befotaka-Midongy, Fianarantsoa Province, Madagascar (13–15 Nov 2006, Fisher et al.), deposited in CAS (CASENT 9030777, PBI_OON 03452).
Etymology
This species is named after Brian Fisher, collector of this and several other species of Malagiella, in honor of his impressive sampling program of the Malagasy fauna.
Diagnosis
The male of this species differs from other Malagiella in lacking sternal bristles (fig. 474) and in having a huge palpal patella (figs. 321–324, 485). The female differs from others in having a distinctly procurved posterior margin of the PES (figs. 327, 328) and a slightly curved receptaculum (W/L about 0.3).
Male (PBI_OON 03452)
Total length 1.62, carapace length 0.82, width 0.69. CEPHALOTHORAX: Eye area about 0.5 carapace width; subequal to clypeus length (figs. 302, 303, 306). Sternum lacking stiff bristles found in other species (figs. 305, 474), median concavity absent. ABDOMEN (figs. 304, 308–310): as in M. valterova. GENITALIA (figs. 321–326): Palp with patella greatly enlarged (fig. 485), about five times femur length, but less than four times in other species (figs. 481–484, 485).
Female (PBI_OON 03452)
Total length 1.70 (1.70–1.86), carapace length 0.80 (0.78–0.80), width 0.70 (0.68–0.70), N = 2. CEPHALOTHORAX (figs. 311–313): Clypeus shorter than eye region length. Eye area about 1.8 clypeus length (fig. 313). ABDOMEN (figs. 314, 318–320): Pedicel tube (fig. 337) shorter than in male. GENITALIA: Postepigastric scutum with posterior margin procurved, receptaculum only slightly curved, W/L about 0.3 (figs. 327, 328).
Other Material Examined
MADAGASCAR: Fianarantsoa Province: P.N. Befotaka-Midongy, Papango 27.7 km S Midongy-Sud, Mount Papango, 23°50.5′S, 46°57.5′E, 1250 m, montane rainforest, sifting leaf litter, 17–19 Nov 2006 (B. Fisher et al., CASENT 9030776, PBI_OON 03442), 1♀.
Diagnosis
Members of this group differ from those of the ranomafana group in being smaller, light brown species, with reduced carapace reticulation (figs. 117–124). Eyes are typically smaller, although somewhat larger in M. nikina (figs. 394, 398), with eye area width usually less than 0.4 cephalon width (figs. 120, 124) and eye area length about 0.5 clypeus length in males (figs. 117, 119, 347) or subequal to greater than clypeus length in females (figs. 121, 123, 360). Male abdomen with dorsal and ventral scutes narrow (figs. 145, 352), with contact zone rounded (figs. 142–146). Both males and females differ from the somatically similar toliara group in lacking lateral spines on hind tibiae and metatarsi and from the ranomafana group in having the tibia IV with a pair of ventroapical spines (fig. 469).
Species Included
Malagiella ambalavo, M. goodmani, M. nikina, M. ranavalona, and M. vohiparara.
Malagiella ranavalona, new species
Type
Female holotype from forêt autour du Palais de la Reine Ranavalona, env., Ambohimanga, 20 km N Antananarivo, 1400 m, Antananarivo Province, Madagascar (9 Dec 1989, B. Hauser), deposited in NHMB (Bern-Mad-89/59, PBI_OON 03637).
Diagnosis
This species differs from others in the group by the moderately sinuous receptaculum, W/L = 0.76 (figs. 339–344).
Female (PBI_OON 03637)
Total length 1.61 (1.50–1.61), carapace length 0.60, width 0.49, N = 2. CEPHALOTHORAX (figs. 329–331, 333–335): Eyes small, subequal; eye area about 0.40 carapace width, subequal to clypeus length (figs. 331, 334). ABDOMEN (figs. 332, 336–338): Pedicel tube short (fig. 337), scutum dorsal extension short, about 0.3 pedicel diameters. Dorsal scutum weakly sclerotized, pale orange, covering about 0.5 abdomen length, 0.3 abdomen width (fig. 330). LEGS: Patella plus tibia I nearly as long as carapace. Leg spination (in addition to typical pattern): tibia IV v0-0-2. GENITALIA: Postepigastric scutum weakly sclerotized; receptaculum moderately sinuous, W/L = 0.76 (figs. 341–344).
Other Material Examined
MADAGASCAR: Antananarivo Province: Ambohimanga, 20 km N Antananarivo, forêt autour du Palais de la Reine Ranavalona, env., 1400 m, 9 Dec 1989 (C. Lienhard, NHMB Bern-Mad-89/60, PBI_OON 03919), 1♀.
Distribution
Known only from the type locality in central Madagascar.
Malagiella vohiparara, new species
Figures 117–Figs. 125–132Figs. 133–141Figs. 142–148Figs. 149–156Figs. 157–164Figs. 165–172Figs. 173–178184, 345–Figs. 355–364Figs. 365–372378, 464, 468, 469, 476, 479, 484, 487; maps 1–Map 2Map 34; table 1
Type
Male holotype, female allotype, male paratype, and 3 female paratypes from sifted leaf litter at P.N. Ranomafana, 2.3 km N Vohiparara, 21°12.8′S, 47°23.0′E, 1100 m, Fianarantsoa Province, Madagascar (28 Apr 1998, C. Griswold, D. Ubick), deposited in CAS (CASENT 9029655, PBI_OON 03078).
Diagnosis
The male of this species differs from other Malagiella by the combination of small size and the absence of lateral spines on the hind legs. The female differs from others in its species group in having a widely sinuous receptaculum, W/L = 1.0–1.2 (figs. 182–184, 375–378; map 4).
Male (PBI_OON 03078) (figs. 117–120, 125–128, 133–139, 142–152, 157–172, 345–354, 365–372, 476, 484; map 3)
Total length 1.32 (1.26–1.32), carapace length 0.64 (0.60–0.66), width 0.55 (0.52–0.56), N = 9. CEPHALOTHORAX: Carapace orange-brown, broadly oval in dorsal view, pars cephalica strongly elevated in lateral view (figs. 117, 347), anteriorly narrowed to about 0.64 times its maximum width, surface and sides of elevated portion of pars cephalica finely reticulate (fig. 118); lateral margin undulate, smooth; nonmarginal pars cephalica setae dark, present in U-shaped row (figs. 117–120). Clypeus length more than twice eye area length (fig. 117). Eyes medium sized, eye area width 0.36 carapace width, length 0.45 clypeus length (figs. 117, 120). Sternum infracoxal groove with opening only at posterior end (fig. 125) with median longitudinal groove weakly represented (fig. 126); sternal bristles long, straight (fig. 125). Mouthparts: Chelicerae with promarginal tooth and patch of largely retromarginal denticles (figs. 135, 136). Endites distally excavated, serrula present in single row (fig. 128); distomedian part with projection bearing dense scopula (fig. 127), distolateral part with swelling bearing serrula and three stout setae (figs. 127, 128). ABDOMEN: Cylindrical, slightly compressed (figs. 352, 354). Book lung covers large, ovoid (fig. 370). Dorsal scutum strongly sclerotized, narrowed to 0.6 carapace width; fusion with epigastric scutum a rounded junction (figs. 142–144). Postepigastric scutum broadly rounded, extending to about 0.6 abdomen length. Spinnerets (fig. 149): ALS with three spigots (fig. 150), PMS with two spigots (fig. 151), PLS with three spigots (fig. 152). LEGS: Spination: femur I p0-1-0; tibiae: I v4-4-0, II v4-2-1, IV v0-0-2 (weak). GENITALIA: Epigastric region with sperm pore small, unmodified (fig. 148). Palpal bulb with dorsobasal indentation (figs. 157, 158, 365, 366, 371, 372), embolus sharply bent ventrally (figs. 159, 160); ventral prong long (fig. 169); embolar opening small (fig. 170), closer to retrolateral prong (fig. 172).
Female (PBI_OON 03078) (figs. 121–124, 129–132, 140–141, 153–156, 173–184, 355–364, 373–378, 464, 468, 469, 479; map 1, 2, 4)
Total length 1.36 (1.36–1.48), carapace length 0.66 (0.66–0.70), width 0.58 (0.55–0.59), N = 4. CEPHALOTHORAX: Carapace similar to male but with lower cephalon, much shorter clypeus (figs. 121–124), and anteriorly narrowed to about 0.46 maximum width (fig. 124). Eyes medium sized; eye area about 0.45 carapace width, length 0.5 clypeus length (figs. 121, 124). Sternum with infracoxal groove opening only at posterior end (fig. 130). Mouthparts: endites without distal modifications (fig. 132). ABDOMEN: Pedicel tube short (fig. 363); scutum dorsal extension shorter than in male, about 0.4 pedicel diameters (fig. 362). Dorsal scutum covering about 0.7 abdomen length, 0.5 abdomen width. Spinnerets (fig. 153): ALS with three spigots (fig. 154), PMS with three spigots (fig. 155), PLS with five spigots (fig. 156). LEGS: Spination as in male (figs. 468, 469). GENITALIA: Postepigastric scutum weakly sclerotized, externally with round copulatory opening (figs. 176, 177), receptaculum strongly sinuous, W/L = 1.0–1.2 (figs. 182–184, 375–378; map 4), enclosed in chitinized membrane (figs. 179–181), rigidly attached to postepigastric scutum (figs. 182–184).
Other Material Examined
MADAGASCAR: Fianarantsoa Province: Talatakely, P.N. Ranomafana, 21°14.9′S, 47°25.6′E, pitfall trap, 13–27 Apr 1998 (Griswold et al., CASENT 9029666, PBI_OON 03380), 2♂; P.N. Ranomafana, 2.3 km N Vohiparara, 21°12.8′S, 47°23.0′E, 1100 m, 18 Apr 1998 (Griswold et al., CASENT 9029665, PBI_OON 03381), 1♂; pitfall trap, 10–28 Apr 1998 (Griswold et al., CASENT 9029668, PBI_OON 03378), 5♂; sifting leaf litter, 18 Apr 1998 (C. Griswold, D. Ubick, CASENT 9029664, PBI_OON 03382), 2♀; 11 Apr 1998 (C. Griswold, D. Ubick (CASENT 9029667, PBI_OON 03379), 1♀; Vohiparara, 3.6 km W Ranomafana, 21°14.243′S, 47°23.842′E, 1137 m, evergreen secondary forest, sifting litter, 13 Jan 2009 (D. Andriamalala, C. Griswold, G. Hormiga, A. Saucedo, N. Scharff, H. Wood, AMNH, PBI_OON 35162), 1♀; same data (AMNH, PBI_OON 35163), 1♂1♀.
Type
Female holotype from sifted litter in rainforest, at 40 km S Ambalavo, 22°13′S, 46°58′E, 1275 m, Res. Andringitra, Fianarantsoa Province, Madagascar (15 Oct 1993, B. Fisher), deposited in CAS (CASENT 9029657, PBI_OON 03223).
Diagnosis
This species is most similar to M. vohiparara, but differs in being slightly smaller, having reduced eyes (fig. 384) and a less sinuous receptaculum, W/L = 0.9 (figs. 389–392).
Female (PBI_OON 03223)
Total length 1.41, carapace length 0.68, width 0.54. CEPHALOTHORAX: Carapace anteriorly narrowed to about 0.47 times its maximum width (fig. 380), surface of elevated portion of pars cephalica smooth, sides smooth (fig. 381). Clypeus sloping forward in lateral view, subequal to eye area length (fig. 382). Eyes small, PME reduced and irregular, difficult to see; eye row width 0.43 carapace width; length 0.93 clypeus length (figs. 380, 384). ABDOMEN: Book lung covers ovoid (fig. 386). Pedicel tube short (fig. 387), scutum dorsal extension about 0.2 pedicel diameters (fig. 404). Dorsal scutum covering about 0.75 abdomen length, about 0.5 abdomen width (fig. 380). Dense patch of setae anterior to spinnerets present, but weak (fig. 382). LEGS: Pale orange; patella plus tibia I nearly as long as carapace (fig. 381). Leg spination: femur I p0-1-0; tibiae: I v4-4-0, II v4-2-0, IV v0-0-2 (weak). GENITALIA: Receptaculum strongly sinuous, W/L = 0.9 (figs. 389–392).
Distribution
Known only from the type locality, Res. Andringitra, Madagascar.
Malagiella nikina, new species
Type
Female holotype from sifted litter in rainforest, 43 km S Ambalavo, 22°14′S, 47°00′E, 825 m, Massif Andringitra, Fianarantsoa Province, Madagascar (4 Oct 1993, B. Fisher), deposited in CAS (CASENT 9029662, PBI_OON 03384).
Etymology
This species is named for Darrell Ubick's mother, Nikie Ubick, for maintaining cultural ties, and is given in Croatian genitive.
Diagnosis
This species resembles M. vohiparara, from which it differs in being slightly larger, and having a longer dorsal scute (fig. 401), larger eyes (fig. 394), and a less sinuous receptaculum, W/L = 0.2–0.4 (figs. 403–410, map 4).
Male. Unknown.
Female (PBI_OON 3386)
Total length 1.48 (1.48–1.64), carapace length 0.74 (0.64–0.74), width 0.60 (0.56–0.62), N = 4. CEPHALOTHORAX (figs. 393–395, 398, 399): Carapace anteriorly narrowed to about 0.49 times its maximum width, surface and sides of elevated portion of pars cephalica finely reticulate (figs. 394, 395, 398, 399). Clypeus subequal to eye area length (fig. 395). Eyes well developed, medium large; eye area width 0.43 carapace width, length 1.5 clypeus length (figs. 394, 398). ABDOMEN (figs. 396, 400–402): Pedicel tube short (fig. 401), scutum dorsal extension about 0.45 pedicel diameter (fig. 400). Dorsal scutum strongly sclerotized; covering 0.6–0.8 abdomen length (figs. 394, 401), 0.5–0.7 abdomen width (figs. 394, 400). Dense patch of setae anterior to spinnerets present, but weak (fig. 396). LEGS: Spines (in addition to typical pattern) tibia IV v0-0-2, spines weak, shorter than segment length. GENITALIA: Postepigastric scutum weakly sclerotized, receptaculum slightly sinuous, W/L = 0.2–0.4 (figs. 403–410, map 4).
Other Material Examined
MADAGASCAR: Fianarantsoa Province: Massif Andringitra, 43 km S Ambalavo, 22°14′S, 47°00′E, 825 m, rainforest, sifted litter, 4 Oct 1993 (B. Fisher, CASENT 9029660, PBI_OON 03386), 1♀; (PBI_OON 03385, CASENT 9029661), 1♀; 8.0 km NE Ivohibe, 22°25.3′S, 46°53.9′E, 1200 m, forest, pitfall trap, 3–9 Nov 1997 (B. Fisher, CASENT 9029663, PBI_OON 03383), 1♀.
Distribution
Known only from the two localities in the vicinity of Andringitra, Madagascar.
Malagiella goodmani, new species
Type
Female holotype from 15 km NW Eminiminy, 24°34.2′S, 46°43.9′E, 1500 m, Toliara Province, Madagascar (17–27 Nov 1995, S. Goodman), deposited in FMNH (FMNH-INS 0000 033 748, PBI_OON 03920).
Etymology
This species is named after Steve Goodman, collector of the species, in honor of his work on the Malagasy biota.
Diagnosis
This species may be distinguished from others in the group by the short and straight receptaculum, with W/L about 0.3 (figs. 423–428).
Female (PBI_OON 10247)
Total length 1.48 (1.40–1.48), carapace length 0.64 (0.63–0.64), width 0.54 (0.52–0.54), N = 2. CEPHALOTHORAX: Carapace anteriorly narrowed to 0.49 times its maximum width (fig. 412), surface and sides of elevated portion of pars cephalica finely reticulate (figs. 412, 413, 416, 417). Clypeus subequal to eye area length (fig. 413). Eyes well developed, medium sized; eye row width 0.45 carapace width; length 1.1 clypeus length (figs. 412, 413, 416). ABDOMEN: Pedicel tube short (fig. 419), scutum dorsal extension about 0.25 pedicel diameter (fig. 418). Dorsal scutum covering about 0.7 abdomen length, 0.45 abdomen width (fig. 412). GENITALIA: Postepigastric scutum weakly sclerotized, receptaculum broad and straight (figs. 423–428).
Other Material Examined
MADAGASCAR: Toliara Province: R.N.I. d'Andohahela, parcel 1, 8 km NW Eminiminy, 24°37.6′S, 46°45.9′E, 440 m, 19–28 Oct 1995 (S. Goodman, FMNH-INS 0000 033 745, PBI_OON 10247), 1♀.
Diagnosis
Members of this group are easily recognized by the extremely small size (figs. 431, 442), pale coloration, and the presence of lateral spines on hind tibiae and metatarsi (fig. 471). Eyes are small, with eye row width less than 0.4 cephalon width (fig. 430) and eye row length about one-half clypeus length in the male (fig. 435) or subequal to clypeus length in the female (fig. 445). Male abdomen with dorsal and ventral scutes very narrow, contact zone at fusion broadly rounded (figs. 432, 433, 438), and sperm pore large (fig. 432).
Species Included
Malagiella toliara.
Malagiella toliara, new species
Figures 185–199, 429–Figs. 440–449Figs. 450–457462, 465, 470, 471, 477, 480, 486, 487; maps 1–Map 2Map 34; table 1
Type
Male holotype and female allotype from sifted litter, leaf mold, rotten wood, in gallery forest, at Andranomite, 23.5242° S, 44.12133° E, 75 m, Toliara Province, Madagascar (27 Feb–3 Mar 2002, Fisher-Griswold Arthropod Team), deposited in CAS (BLF5850, CASENT 9010327, PBI_OON 03221).
Diagnosis
This species can be distinguished from other Malagiella by its small size (males = 1.1, with >1.2 in other species; females = 1.3, with ≥ 1.4 in other species) (figs. 431, 442), pale coloration, small eyes (figs. 435, 445), and the apparent absence of carapace sculpturing (figs. 430, 441). The female has a narrow DS (0.25 abdomen width (fig. 441), which is > 0.30 in other species) and widely sinuous epigynal ducts, with W = L (figs. 458–462). The male has a short VS, with distance from sperm pore to posterior edge being much shorter than to anterior edge (fig. 432) and a short palpal patella (patella-tibia L/cymbium-bulb L = 1.3 (figs. 450–453), which is 1.5–2.2 in other species).
Male (PBI_OON 03221)
Total length 1.12 (1.10–1.12), carapace length 0.60, width 0.44 (0.44–0.46), N = 2. CEPHALOTHORAX: Carapace pale orange, elongate oval in dorsal view (fig. 430), pars cephalica slightly elevated in lateral view, anteriorly narrowed to about 0.5 times its maximum width (fig. 430), surface of elevated portion of pars cephalica smooth, sides smooth (fig. 431); lateral margin straight; nonmarginal pars cephalica setae present in U-shaped row (setae rubbed off of available specimens, but bases visible). Clypeus twice the length of eye area. Eyes well developed, small; eye row width 0.26 carapace width, length 0.6 clypeus length (figs. 430, 435). Sternum with long bristles (figs. 434, 477). ABDOMEN: Shape cylindrical, somewhat compressed (figs. 432, 433, 437–439), strongly overhanging cephalothorax (fig. 431). Book lung covers large, ovoid (fig. 438). Pedicel tube short (fig. 438), scutum dorsal extension about 1.6 pedicel diameter. Dorsal scutum weakly sclerotized, pale orange, covering about 0.5 abdomen length and about 0.5 abdomen width (fig. 433). Postepigastric scutum short, covering (together with epigastric scutum) about 0.6 abdomen length, fused to epigastric scutum (figs. 432, 438). LEGS: Spination: femur I p0-1-0; tibiae: I, II v4-4-0, IV p1-1-0, r1-1-0, v0-0-2; metatarsi: I, II v2-2-0, III p0-1-0, r0-1-0, IV p1-0-0, r1-1-0. GENITALIA: Epigastric region with sperm pore large (fig. 432). Palpal patella 3.0 times femur length (figs. 450–457, 486, map 3), tarsus seamlessly fused to bulb (figs. 191, 192), bulb with dorsobasal indentation (figs. 185–188, 450, 451), bulb-cymbium about 0.7 tibia-patella length; embolus less sharply bent ventrally (figs. 185, 486), embolar opening small (fig. 192), closer to retrolateral prong (fig. 193).
Female (PBI_OON 03221)
Total length 1.34, carapace length 0.60, width 0.46. CEPHALOTHORAX: Carapace elongate oval in dorsal view, anteriorly narrowed to about 0.45 times its maximum width (fig. 441). Clypeus subequal to eye area length. Eyes small: eye row width 0.33 carapace width (fig. 445); length 1.1 clypeus length (figs. 441, 442). Female palp spines absent (figs. 465, 480). ABDOMEN: Pedicel tube short (fig. 448), scutum dorsal extension about 0.2 pedicel diameter (fig. 447). Dorsal scutum covering about 0.7 abdomen length, about 0.25 abdomen width (fig. 441). Dense patch of setae anterior to spinnerets present (fig. 448). LEGS: Spination: femur I p0-1-0; tibiae: I, II v4-2-2, IV pv0-0-1; metatarsi: I, II v2-2-0, III p0-1-0, r0-1-0, IV p1-1-0, r0-1-0 (figs. 470, 471). GENITALIA: Postepigastric scutum weakly sclerotized (fig. 443). Receptaculum strongly sinuous, W = L (figs. 458–461).
Acknowledgments
Funding for this project came from the Research/Education divisions at California Academy of Sciences (CAS), the Exline-Frizzell and Lindsay Funds (CAS), the Schlinger Foundation and the US National Science Foundation (NSF). Griswold (CEG) acknowledges NSF grants DEB 9296271: Systematics and Biogeography of Afromontane Spiders and DEB-0613775 “PBI: Collaborative Research: The Megadiverse, Microdistributed Spider Family Oonopidae,” to CEG, DEB-0072713: “Terrestrial Arthropod Inventory of Madagascar” (to Brian Fisher and CEG), and EAR-0228699: “Assembling the Tree of Life: Phylogeny of Spiders” (W. Wheeler, PI).
We thank the many members of the Fisher/Griswold Arthropod Survey team who were responsible for collecting and processing most of the specimens studied: Daniela Andriamalala, Lantoniaina Andriamampianina, Rija Andriamasimanana, Dylan Berge, Lisa Joy Boutin, Alison Cameron, Randriambololona Tantely Nirina (Coco), Brian Fisher, Jen Jacobs, Joel Ledford, Vincent Lee, Jeremy Miller, Gary Ouellette, Pascal Rabeson, Jean-Jacques Rafanomezantsoa, Marie Jeanne Raherilalao, Maminiaina Rajaonarivo, Balsama Rajemison, Jean Claude Rakotonirina, Chrislain Ranaivo, Nicole Rasoamanana, Hanitriniana Rasoazanamavo, Helian Ratsirarson, Domoina Razafindratandra, Keve Ribardo, Alma Saucedo, Corrie Saux, Diana Silva, Brinda Vavy, and Hannah Wood.
Thanks go to other collectors of these rare spiders, especially to Vince and Barbara Roth for their pioneering collecting efforts of Malagasy spiders; also to Steve Goodman, B. Hauser, Gustavo Hormiga, S. Kariko, Scott Larcher, C. Lienhard, Nikolaj Scharff, and the Frontier Project.
We thank Benjamin Andriamihaja, Directeur Général of the Madagascar Institut pour la Conservation des Ecosystèmes Tropicaux (MICET) for help with logistics and especially Harin'Hala Hasinjaka (Rin'ha) of that institute and Balsama Rajemison for arranging the permits.
Thanks go to Petra Sierwald (FMNH), Christian Kropf, and Yvonne Kranz-Baltensperger (NHMB) and Daniela Andriamalala and Gustavo Hormiga (GWU) who made specimens available from their institutions, as did Norm Platnick of material from both the AMNH and MNHN. Other important samples of Malagasy oonopids were loaned by Rudy Jocqué and Wouter Fannes (MRAC). Many thanks to Anthea Carmichael for help in databasing and image uploading. Appreciation for the interesting discussions goes to the entire PBI group, and especially to B. Baehr, A. Bonaldo, C. Grismado, M. Harvey, F. Álvarez-Padilla, R. Ott, W. Fannes, and M. Burger.
Many thanks to the good folks at the GIS Unit of the Royal Botanic Gardens Kew, Justin Moat, Patricia Malcolm-Tompkins, and Aaron P. Davis, for their helpful assistance and permission to use their Map of Remaining Madagascar Primary Vegetation.
Final thanks go to the reviewers, Jason Bond, Mike Draney, and Norm Platnick, for their detailed observations and helpful suggestions for improving the manuscript, and to Suzanne Ubick for gracefully tolerating my lengthy absences.
REFERENCES
Appendices
Index of Specific Names
ambalavo, Malagiella, 10, 82
andringitra, Malagiella, 9, 79
cubanus, Oonops, 5
fisheri, Malagiella, 10, 79
goodmani, Malagiella, 7, 83
key to Malagiella species, 54
nikina, Malagiella, 10, 82
paquini, Camptoscaphiella, 4
peltifer, Ischnothyreus, 8
ranavalona, Malagiella, 10, 80
ranomafana, Malagiella, 5, 59
toliara, Malagiella, 8, 83
tubulatus, Oonops, 5
valterova, Malagiella, 10, 78
vohiparara, Malagiella, 7, 81