Dicellophilus pulcher, (KISHIDA, 1928)

DICELLOPHILUS PULCHER ( KISHIDA, 1928)

Mecistocephalus pulcher Kishida, 1928 View in CoL . Original description: Kishida, 1928: 300. Type locality: Ichigome, Subashiri, Mt. Fuji (translated from Japanese) ( Japan). Type material: number of specimens unknown, at least one adult female; repository unknown; probably lost.

= Dicellophilus latifrons Takakuwa, 1934 View in CoL . Original description: Takakuwa, 1934c: 355. Type locality: ‘Kaybara (Hyogo), Masudo (bei Tokyo), Komono (Miye), Ikao (Gumma), Ōta (Gumma), Odawara (Kanagawa), Suwa (Nagano)’ [= Kaibara; Masudo, near Tokyo; Komono; Ikao; Ota, in Gumma-ken; Odawara, in Kanagawa-ken; Suwa, in Nagano-ken ( Japan)]. Type material: number of specimens unknown, including a female; apparently originally retained in the personal collection of Y. Takakuwa, Tokyo; probably lost. Synonymy by Shinohara, 1983: 6.

= Dicellophilus japonicus Verhoeff, 1934 View in CoL . Original description: Verhoeff, 1934: 32. Type locality: ‘Umgebung von Tokyo’ [= near Tokyo ( Japan)]. Type material: holotype female, 51-mm long, originally deposited in the Zoologische Staatssammlung München (code number ZSMA 20030254). Synonymy by Shinohara, 1983: 6.

= Tygarrup monoporus Shinohara, 1961 View in CoL . Original description: Shinohara, 1961: 212. Type locality: ‘Manazuru’ [= Manazuru ( Japan)]. Type material: holotype female, 17-mm long, probably in the private collection of K. Shinohara. Synonymy by Uliana et al., 2007: 28.

Main references for morphology: Kishida, 1928: 300 (original description); Takakuwa, 1934c: 355 (redescription as D. latifrons View in CoL ); Takakuwa, 1934b: 878 (diagnosis as D. latifrons View in CoL ); Kishida, 1947: 935 (diagnosis); Verhoeff, 1934: 32 (redescription as D. japonicus View in CoL ); Takakuwa et al., 1940: 82 (key and redescription as D. latifrons View in CoL ); Shinohara, 1961: 212 (redescription as T. monoporus View in CoL ); Uliana et al., 2007: 27 (redescription).

Diagnosis: A Dicellophilus species with 41 leg-bearing segments. Antennae about three times as long as the maximum width of the head, strongly tapering (width of the terminal article less than half of the width of article I); terminal article more than two times as long as wide, and less than 1.5 times as long as article XIII. The longest setae on the antennae are shorter than 200 Mm ( Fig. 5E View Figure 5 ). Sensilla on the antennal tip ( Fig. 8D View Figure 8 ) usually with a crown-like projection at about mid-length. Head ( Fig. 5A View Figure 5 ) ~1.2–1.4 times as long as wide. Lateral margins of the cephalic plate markedly convex, evidently converging only in the posterior part. Frontal line ( Fig. 5C View Figure 5 ) uniformly rounded. Clypeus ( Figs 5D View Figure 5 , 8E View Figure 8 ): lateral margins converging backwards; a wide subtriangular posteromedial area without setae, also without a distinctly isolated posteromedian pair of setae. Non-areolate part of the buccae ( Fig. 5D View Figure 5 ) extending forwards, distinctly beyond the labrum. Mandible with between five and seven pectinate lamellae. Coxosternum of maxillae I ( Figs 5B View Figure 5 , 9D View Figure 9 ) less than three times as wide as medially long. Medial projection of maxillae I about two times as long as wide; distal hyaline part enlarged, subtriangular; hyaline scales present on the dorsal surface ( Fig. 5H View Figure 5 ). Distal hyaline part of the telopodite of maxillae I distinctly longer than the basal chitinous part. Distal article of the telopodite of maxillae II subconical, tapering gradually along most of its length, ~1.5 times as long as wide ( Fig. 5B View Figure 5 ). Condylar processes ( Fig. 5I View Figure 5 ) of the forcipular coxosternum well developed. Forcipular article I about as long as wide, the tubercle relatively small, not or only slightly projecting beyond the distal margin of the article ( Figs 5F View Figure 5 , 9E View Figure 9 ). Forcipular tarsungulum with evident basal tubercle ( Fig. 9L View Figure 9 ), the dorso-internal margin evidently crenulated, with variably spaced notches ( Fig. 9J, K View Figure 9 ). Sternum of the last leg-bearing segment ( Figs 5G View Figure 5 , 9F View Figure 9 ) longer than wide. Posterior end of coxopleura indistinctly pointed.

The main differential characters in respect to the other Dicellophilus species are presented in Table 3.

Notes on taxonomy: The name M. pulcher was introduced by Kishida (1928) for a species previously indicated by the same author as Mecistocephalus sp. ( Kishida, 1927) . The name remained almost completely overlooked by subsequent authors, even though Takakuwa et al. (1940) commented on its possible identity with D. latifrons Takakuwa, 1934 , and Shinohara (1983) confirmed this view, however, without adopting the older name as valid. Dicellophilus pulcher was resurrected definitively as the valid name for the species by Uliana et al. (2007) within a comprehensive revision of Japanese mecistocephalids. Even though the type material of M. pulcher is probably lost (K. Ishii, H. Ono, K. Shinohara & N. Tsurusaki, pers. comm.), the identity of the species can be confidently recognized based on the original accounts and illustrations provided by Kishida (1927, 1928). It is worth noting that in introducing the name M. pulcher, Kishida (1928: 300) cited it as ‘ Mecistocephalus pulcher Kishida, 1925 ’, probably referring to the year when the species was collected, and not to a previous publication, as the name was not used in Kishida (1927).

Dicellophilus latifrons Takakuwa, 1934 View in CoL was described by Takakuwa (1934b, c) from a series of specimens from different localities. Other specimens were later identified, and it has been used as the valid name for the species in all major publications dealing with Japanese geophilomorphs (e.g. Takakuwa et al., 1940; Attems, 1947; Murakami, 1993; Shinohara, 1999; Bonato et al., 2003), until Uliana et al. (2007) recognized it as a junior synonym of D. pulcher View in CoL , and adopted D. pulcher View in CoL as the valid name of the species. Based on the original papers by Takakuwa (1934b, c), it seems that the type material was retained in the personal collection of Y. Takakuwa, but at present the collection is impossible to locate, and is believed to have been lost during World War II (K. Ishii, H. Ono, K. Shinohara & N. Tsurusaki, pers. comm.).

Dicellophilus japonicus Verhoeff, 1934 View in CoL was described by Verhoeff (1934) from a single specimen, but it was only used rarely in the literature ( Verhoeff, 1937; Attems, 1947; Kishida, 1947) because it was recognized as obviously being identical to D. latifrons View in CoL , and indeed it has been recognized as a junior synonym of D. latifrons View in CoL since 1938 ( Takakuwa et al. 1938b, 1940).

Tygarrup monoporus Shinohara (1961) View in CoL was described by Shinohara (1961) from a single specimen. Even though no other specimens were identified, it was maintained as a valid species of Tygarrup View in CoL by subsequent authors ( Titova, 1983; Murakami, 1993) until Uliana et al. (2007), based on the original description and illustrations provided by Shinohara (1961), recognized that the holotype was actually a juvenile D. pulcher View in CoL . The type material was apparently retained in the private collection of K. Shinohara, Chiba (H. Ono, pers. comm.).

Notes on morphology: Previous published accounts of the species were found to be inaccurate in some morphological characters: invariantly separate labral side pieces were suggested by Verhoeff (1934) as distinguishing D. latifrons View in CoL from D. carniolensis View in CoL , where they often touch each other, but we found that the distance between the labral side pieces is variable in both species; small setae were described as being present on the buccae of D. latifrons View in CoL by Takakuwa (1934c), but actually the buccae are invariantly devoid of setae in this, as in all other species, of Dicellophilus View in CoL ; the basal article of the telopodite of the maxillae II was described as peculiarly shaped in D. japonicus View in CoL by Verhoeff (1934), but we found that it is similarly shaped in all species of Dicellophilus View in CoL ; the basal tubercle of the tarsungulum was sometimes described as being inconspicuous ( Verhoeff, 1934; Takakuwa et al., 1940; Shinohara, 1961), but it is actually more evident than in D. carniolensis View in CoL ; the number of leg-bearing segments was given as 43 for D. japonicus View in CoL by Attems (1947), followed by Mikoš (1991), but this is evidently erroneous, as revealed by the original description of the species ( Takakuwa, 1934c); coxal macropores were described as being relatively larger in adult D. latifrons View in CoL than in adult D. carniolensis View in CoL , by Verhoeff (1934), but their conspicuousness is actually similar in all species.

Distribution: The species occurs along most of the island of Honshu, from the Chugoku Mountains in the west to the Ou Mountains in the north ( Fig. 10 View Figure 10 ). It has been recorded from around three dozen localities (reviewed by Uliana et al., 2007).

Notes on distribution: Titova (1983) suggested that T. monoporus (currently a junior synonym of D. pulcher ; see above) could also occur in eastern China, but no evidence to support this claim was presented.

PHYLOGENY

The analysis of the data set ( Table 1), including all four out-group taxa, and weighting characters equally, yielded a single most-parsimonious tree (42 steps; consistency index, CI = 0.71; retention index, RI = 0.79; Fig. 11 View Figure 11 ). After successive weighting, a single most-parsimonious tree with identical topology was found (24.3 steps; CI = 0.89; RI = 0.93). Analyses performed including the single out-group species separately were based on 11–14 parsimonyinformative characters, depending on the out-group species. In all cases a single most-parsimonious tree was obtained, both weighting characters equally (depending on the out-group species, 19–32 steps; excluding uninformative characters, CI = 0.80–1.00; RI = 0.75–1.00) and after successive weighting (19–26 steps; excluding uninformative characters, CI = 1.00; RI = 1.00). The topology for the in-group was found to correspond with that obtained from the analysis including all four out-group taxa ( Fig. 11 View Figure 11 ). In all analyses, high bootstrap values were obtained for all nodes: the Bremer index values, estimated from 2946 trees, 42–142-steps long, range from 2 to 7 ( Fig. 11 View Figure 11 ).

The monophyly of the genus Dicellophilus is confirmed and supported by three unambiguous, nonhomoplastic synapomorphies: margin of the labral side pieces uniformly concave (character 11: 1) and bearing hair-like projections (character 13: 1), and each coxopleuron with one distinct macropore (character 29: 1). It is also supported by two other characters: mandibles covered with hair-like projections (character 14: 1), but this is homoplastic with respect to the out-group Proterotaiwanella ; and foraminal processes and associated grooves reaching the posterolateral corners of the coxosternum of maxillae II (character 19: 0), but this is a reversal.

The relationships among the species of Dicellophilus are resolved confidently, with D. carniolensis emerging as the most basal lineage, and D. pulcher closely related to the sister species D. anomalus and D. limatus ( Fig. 11 View Figure 11 ).

The monophyly of the clade D. anomalus + D. limatus + D. pulcher is supported by two unambiguous, non-homoplastic synapomorphies: terminal antennal article elongate (character 1: 1); and medial projections of maxillae I bearing subtriangular distal parts (character 15: 1). It is also supported by four other character changes: medial projections of maxillae I bearing hyaline scales (character 16: 0), but this a reversal; distal parts of the telopodites of maxillae I elongate (character 17: 1); terminal articles of the telopodites of maxillae II subconical (character 21: 1); however, both the latter characters are homoplastic with respect to the out-group Anarrup ; and forcipular condylar processes distinctly elongate (character 25: 1), but this is homoplastic with respect to the outgroup Proterotaiwanella .

The monophyly of the clade D. anomalus + D. limatus is supported by four unambiguous, nonhomoplastic synapomorphies: antennal setae very elongate (character 2: 1); frontal line forming an evident angle pointing forwards (character 4: 1); clypeus bearing a distinctly isolated posteromedian pair of setae (character 8: 1); and coxosternum of maxillae II elongate along the lateral margins (character 18: 1). It is also supported by three other characters, although they appear to be reversals: relatively elongate cephalic plate with lateral margins evidently converging on most of their length (character 3: 0); tubercle of the forcipular trochanteropraefemur relatively large (character 26: 0); and sternum of the last leg-bearing segment wider than long (character 28: 0).

All character changes listed above have been reconstructed under both the AccTran and DelTran options.