Type genus: Notopteris Gray, 1859.

Contents: Contains one genus, Notopteris Gray, 1859, and two species: N. macdonaldi Gray, 1859, and N. neocaledonica Trouessart, 1908.

Synonyms: Notopterini Koopman and Jones, 1970 (unavailable and preoccupied; see below).

Description and Diagnosis: A moderately sized pteropodid (FA 60 –72 mm) with a long tail (subequal in length to the forearm) and wing membranes that meet at the middorsal line, giving a naked-backed appearance. Dental formula i2/2, c1/1, p2/2, m2/3 × 2 = 28, although upper i1 is often lost in adults; anterior lower premolar larger than any other lower premolar or molar; premaxillae well developed and coossified anteriorly, facial process of premaxilla approximately 2× wider dorsally than ventrally; infraorbital canal long; metacarpal formula III< IV≤V; terminal phalanx of digit III subequal to or longer than metacarpal of that digit; no claw on second digit of wing; tibia length approximately half that of forearm; tongue long, approximately 1.5× length of the mandible; no obvious sexual dimorphism.

Comments: Koopman and Jones (1970) coined the name “Notopterini” for a tribe of pteropodids including Notopteris and Melonycteris, but they did not make this name available under the rules of the International Commission on Zoological Nomenclature (ICZN) because this taxon was not identified as new and the authors failed to provide a description or diagnosis indicating the characters purported to differentiate this taxon. As reviewed by Baker et al. (2016), the current Code (ICZN, 1999) is unambiguous about what is required for a family-group name (including subfamilies and tribes) to be available. In addition to requirements for publication, the name must be a noun in the nominative plural formed from the stem of an available generic name (articles 11.7.1 and 13.2) or the whole genus name (art. 29.1), which must be cited in the description (art. 16.2); and the name must end with an appropriate family-group name suffix (arts. 11.7.1.3 and 29.2). For all names published after 1930, the name must be accompanied by a description or definition that states in words characters that are purported to differentiate the taxon (art. 13.1.1) or a bibliographic reference to such a statement (art. 13.1.2); it may include a diagnosis to differentiate it from related and similar groups (recommendation 13A). And, as with all taxonomic names, family-group names are required to conform to the principle of homonymy (arts. 52, 53.1, 55), which notes that when two or more taxa are distinguished from each other, they must not be denoted by the same name.

The rules for formation of family-group names are straightforward and involve application of appropriate suffixes (-idae for a family name, -inae for a subfamily name, and –ini to the name of a tribe) to the Greek or Latin stem of a genus name (ICZN, 1999: art. 29). In the case of Notopteris, the Greek stem is composed of two parts: noto- (Greek for “back”) and pter(Greek for “wing”) forming notopter- (back wing). The appropriately formed family group names for this taxon would thus be Notopteridae, Notopterinae, and Notopterini, the latter of which was used by Koopman and Jones (1970) for the pteropodid bat group including Notopteris and Melonycteris (the latter presumably including Nesonycteris). In grouping these taxa together those authors were apparently following Andersen (1912), who did not propose a formal name for this group but variously referred to it as the “Notopterine section” of the Macroglossinae (Andersen, 1912: lxii), or as the “Notopterides” (Andersen, 1912: lxv). Bergmans (1997) noted this history and attributed authorship of the Tribe Notopterini to Andersen (1912), but this was incorrect – authorship of the formal family-group name Notopterini as applied to bats dates to Koopman and Jones (1970), a fact noted by Koopman (1994).

Regardless of issues of availability and authorship, yet another problem exists with the use of Notopterini as a family-group name in Chiroptera: it is preoccupied by Notopteridae Bleeker, 1859, a family of osteoglossiform fishes commonly known as knifefishes. Notopteridae Bleeker, 1859, is based on Notopterus Lacépède, 1800, which has the same Greek stem as Notopteris Gray, 1859. To avoid homonymy, any family-group names based on the stem notopter- can be applied only to fishes including Notopterus based on the principle of priority (which applies to family-group names and covers homonyms as well as synonyms; ICZN, 1999: arts. 23.1, 23.4) because these names were used in fishes prior to their use in bats. Homonymy from similar but not identical generic names that share the same stem is recognized by the Code (arts. 29.3, 29.6, 55.3), and recommendation 29A explicitly offers a preferred means of addressing this problem: authors are advised to use the entire generic name as the stem in formulating a new family-group taxon. In the case of bats, notopteris- thus would be the appropriate stem for formation of new family-group names. We thus propose Notopterisinae as a new family-group name for the clade including the type genus Notopteris. The new subfamily Notopterisinae differs from prior concepts (e.g., Notopterini Koopman and Jones, 1970) additionally in being restricted to only the genus Notopteris.

Type genus: Macroglossus F. Cuvier, 1824.

Contents: Includes two genera, Macroglossus F. Cuvier, 1824, and Syconycteris Matschie, 1899, and five species classified into two genera: M. sobrinus Andersen, 1911, M. minimus (E. Geoffroy, 1810), Syconycteris australis (Peters, 1867), S. hobbit Ziegler, 1982, and S. carolinae Rozendaal, 1984.

Synonyms: Macroglossinae Harris, 1939 (preoccupied; see below).

Diagnosis: Small to small-medium (in adults, interspecific ranges of head-body length 49–97 mm, forearm 37–61 mm, body weight 13–47 g; Giannini et al., 2019), long-snouted nectarivorous pteropodids with tail, uropatagium, and calcar rudimentary (Macroglossus) or absent (Syconycteris), rostrum long, strongly deflected ventrally with respect to the basicranial axis; dentition generally weak; tongue greatly elongated with long, unfringed filiform papillae on tip.

Comments: As in the case of Notopteris developed above, the widely used subfamily name Macroglossinae is preoccupied as it designates sphingid lepidopterans of subfamily Macroglossinae Harris, 1839, tribe Macroglossini Harris, 1839, and subtribe Macroglossina Harris, 1839, referred to genus Macroglossum Scopoli, 1777. We applied the same concept as in Notopteris (see above), providing a replacement name by changing the name of this subfamily to Macroglossusinae, using the entire genus name Macroglossus as valid stem and adding the suffix -inae, again following recommendation 29A of the Code. The content is now restricted to genera Macroglossus and Syconycteris to the exclusion of other nectar-feeding pteropodids previously thought to be closely related: the “macroglossine section” of Andersen (1912) that formerly included Eonycteris (relocated to Rousettinae), Melonycteris and Nesonycteris (relocated to Pteropodinae), and Notopteris (placed on a family of its own; see above).

Type genus: Melonycteris Dobson, 1877.

Contents: Includes two genera, Melonycteris Dobson, 1877, and Nesonycteris Thomas, 1887, and three species: M. melanops Dobson, 1877, Nesonycteris fardoulisi (Flannery, 1995), and N. woodfordi (Thomas, 1887).

Description and Diagnosis: Small to moderately sized pteropodids (FA 42 –63 mm) with vestigial anterior upper and lower premolars; dental formula i2/1–2, c1/1, p3/3, m2/3 × 2 = 32–34; middle lower premolar smaller than either molar; premaxillae well developed and in simple contact (or not in contact) anteriorly; facial process of premaxilla approximately 2–3× wider dorsally than ventrally; infraorbital canal long; metacarpal formula III< IV≤V; terminal phalanx of digit III subequal to or longer than metacarpal of that digit; claw present on digit II of wing in some species; tibia much less than half the length of the forearm; tail absent.

Comments: This tribe is equivalent to the genus Melonycteris as recognized by many authors (e.g., Flannery, 1995; Simmons and Cirranello, 2019). We treat Nesonycteris as a genus distinct from Melonycteris; see comments under Nesonycteris below.

Type genus: Pteralopex Thomas, 1888.

Contents: Contains three genera, Pteralopex Thomas, 1888, Mirimiri Helgen, 2007, and Desmalopex Miller, 1907, and eight species: Pteralopex anceps K. Andersen, 1909, P. atrata Thomas, 1888, P. flanneryi Helgen, 2005, P. pulchra Flannery, 1991, and P. taki Parnaby, 2002; Mirimiri acrodonta (Hill and Beckon, 1978); and Desmalopex leucopterus (Temminck, 1853) and D. microleucopterus Esselstyn et al., 2008.

Description and Diagnosis: Large to very large flying-fox-like pteropodids (FA 116–171 mm); dental formula i2/2, c1/1, p3/3, m2/3 × 2 = 34; upper molar teeth subquadrate to quadrate in occlusal view; premaxillae well developed and either in simple contact or co ossified anteriorly; postorbital process very long, often contacts zygoma to completely enclose the orbit posteriorly; second phalanx of digit IV of wing longer than first phalanx; claw present on digit II of wing.

Comments: The recent segregation of the Fijian monkey-faced bat in a genus of its own (Mirimiri) is strongly supported here by the very long branch separating the two Pteralopex species included in this study (P. atrata and P. taki) and Mirimiri acrodonta; mutual synapomorphies are listed in Helgen (2005). In addition, the relationship between Desmalopex (formerly in Pteropus) and monkey-faced bats (Pteralopex + Mirimiri) is also strongly supported (see also Almeida et al., 2014, 2018). Therefore, inclusion of the three genera in this new tribe is confirmed.

Type genus: Harpyionycteris Thomas, 1896.

Contents: Includes two genera, Harpyionycteris Thomas, 1896 and Boneia Jentink, 1879, and three species: Harpyionycteris whiteheadi Thomas, 1896, H. celebensis Miller and Hollister, 1921, and Boneia bidens Jentink, 1879.

Diagnosis: No morphological diagnostic characters have been identified for this tribe. However, Harpyionycteris + Boneia compose a well-supported group (fig. 1).

Comments: This new tribe is one of two tribes (see also below) recognized here within the subfamily Harpyionycterinae Miller, 1907, whose contents were established by Giannini et al. (2009) as including Harpyionycteris, Boneia, Dobsonia, and Aproteles. Previously, Boneia was treated as a subgenus of Rousettus (e.g., Bergmans, 1994, 1997; Bergmans and Rozendaal, 1988), or as a valid genus associated with Rousettus (e.g., Andersen, 1912; Koopman, 1993) on the basis of morphological similarity. However, Boneia has been consistently recovered in phylogenetic analyses as sister to Harpyionycteris (Giannini et al., 2009, Almeida et al., 2011, Amador et al., 2018), a result reproduced herein as well, which is the basis of recognizing this tribe within Harpyionycterinae. Harpyionycteris has long been considered an early offshoot of the pteropodid tree chiefly due to its unusually multicuspidate dentition resembling a (primitive mammalian) tribosphenic pattern (e.g., Slaughter, 1970). Significantly, Andersen (1912) nevertheless noted the close affinity with Dobsonia, which was first confirmed phylogenetically only recently (in Giannini et al., 2006). Therefore, the dentition and other characters such as the procumbent premaxilla, mandibular symphysis, and incisors of Harpyionycteris have been interpreted as uniquely derived traits of this genus (Giannini et al., 2006). Hassanin et al. (2016) used Boneini as a tribe-level name for a group whose membership corresponds to that of Harpyionycterinae Miller, 1907, as modified by Giannini et al. (2009), and Boneini is therefore considered a junior synonym.

Type genus: Dobsonia Palmer, 1898.

Contents: Includes two genera, Dobsonia Palmer, 1898, and Aproteles Menzies, 1977, and 14 species: Dobsonia anderseni Thomas, 1914, D. beauforti Bergmans, 1975, D. chapmani Rabor, 1952, D. crenulata K. Andersen, 1909, D. emersa Bergmans and Sarbini, 1985, D. exoleta K. Andersen, 1909, D. inermis K. Andersen, 1909, D. minor (Dobson, 1879), D. moluccensis (Quoy and Gaimard, 1830), D. pannietensis (De Vis, 1905), D. peronii (E. Geoffroy Saint-Hilaire, 1810), D. praedatrix K. Andersen, 1909, D. viridis (Heude, 1896); and Aproteles bulmerae Palmer, 1977.

Diagnosis: Midsized to large pteropodids uniquely characterized by the combination of wings that originate from the spine, thus giving the appearance of bare-backed bats, and the dental formula I 0–1/0, C 1/1, P 2/3, M 2/3. Other bare-backed bats (Rousettus spinalatus and Notopteris spp.) always exhibit at least one lower incisor, but in addition these species greatly differ in numerous other cranial and dental features as they belong in different subfamilies.

Comments: Bergmans (1997) attributed the authorship of this tribe to Andersen (1912). Besides the extensive description of Dobsonia in Andersen (1912), to our knowledge there is no proper diagnosis of this tribe as currently composed (Dobsonia plus the more recently described Aproteles), only the mention of its constituent genera by Bergmans (1997), and hence the diagnosis provided above. Dobsonia and Aproteles are quite alike and differ chiefly in dental formula, with Aproteles completely lacking incisors, both upper and lower, and Dobsonia species lacking the claw on index finger (present in Aproteles). Aproteles is monotypic and contains the critically endangered, New Guinea highlands endemic, A. bulmerae, while Dobsonia is more speciose and geographically widespread, albeit the distribution of the genus is centered also in New Guinea. First discovered as a subfossil dated 12000 years old, some evidence suggests that Aproteles has been in decline perhaps for millennia, probably due to hunting by humans both prehistorically (as first encountered as food remains in archaeological sites), and currently in its limited range (Flannery, 1995). Competition for caves with Dobsonia species may be an additional cause of decline (Bonaccorso, 1998); our tree shows that Dobsonia species are all considerably younger than its sister Aproteles, thus contributing some support to this hypothesis.

Type species: Pteropus gambianus Ogilby, 1835.

Contents: Includes 11 species: Epomophorus angolensis Gray, 1970, E. anselli Bergmans and van Strien, 2004, E. crypturus Peters, 1852, E. dobsonii Bocage, 1889, E. gambianus (Ogilby, 1835), E. grandis (Sanborn, 1950), E. labiatus (Temminck, 1837), E. minor Dobson, 1879, E. wahlbergi (Sundevall, 1846), E. pusillus Peters, 1867, and E. intermedius (Hayman, 1963).

Synonyms: Micropteropus Matschie, 1899.

Emended diagnosis: Typical epomophorine pteropodids with epaulettes in adult males and tufts of white hairs medially and laterally on the ears in both sexes; five to six thickened palatal ridges present; and postdental palate deeply concave.

Comments: Epomophorus minimus Claessen and De Vree, 1991, is provisionally considered a junior synonym of E. minor Dobson, 1879, pending thorough revision of small-sized Epomophorus in the minor-minimus-labiatus complex, of which E. anselli may also be part. Our revised definition of Epomophorus contains species historically assigned to this genus, along with species subsequently transferred to Epomops (i.e., dobsonii), species included in Micropteropus as subgenus of Epomophorus (i.e., pusillus), and species originally described in Micropteropus (i.e., grandis, intermedius). Therefore, in this treatment Epomophorus contains, in addition to its typical species, all three species previously assigned to Micropteropus (thus considered a junior synonym at the genus level), as well as the form dobsonii (formerly in Epomops). This broadly defined, inclusive Epomophorus is justified based on findings that the aforementioned species nest within the smallest clade containing the typical Epomophorus species in all recent phylogenies (Almeida et al., 2016; Amador et al., 2018; Nesi et al., 2011, 2013), including this study. This arrangement is supported by our reinterpretation of palatal-ridge patterns (discussed further below), which provides a clear synapomorphy for this redefined Epomophorus.

Epomophorus, as defined and diagnosed here, exhibits 5–6 thickened palatal ridges in all 11 species, with the following variation among species. The other three genera in tribe Epomophorini (Hypsignathus, Epomops and Nanonycteris) bear just three such thickened ridges. Typical Epomophorus (E. gambianus, E. crypturus, E. wahlbergi, E. angolensis, E. labiatus, E. minor, E. minimus, and E. anselli) all have the typical pattern of six thickened palatal ridges, with some interspecific variation that includes ridges with or without a median notch, and ridges whose location varies with respect to the dentition (e.g., one versus two postdental ridges; Bergmans, 1997). Species previously referred to Micropteropus (pusillus, grandis, and intermedius) all have six thickened palatal ridges, of which the first is large, undivided, and hastate, while the next five ridges are divided by a deep, continuous median groove; furthermore, ridges two through six are in close contact in intermedius and pusillus (see Bergmans, 1988, 1997). Epomophorus dobsonii has five ridges, but the second one is incipiently split; we observe that this may be the result either of fusion (of formerly separate ridges two and three) or of a division of the second ridge (Bergmans, 1997). In addition, E. dobsonii lacks the typical condition of the pterygoid bone seen in Epomops (the genus to which it was referred to for most of its taxonomic history), namely, a pterygoid bone not rolled up to form a deep cavity as is typically present in Epomops buettikoferi and E. franqueti (this trait was figured in Bergmans, 1989: figs. 6, 12). Instead, the pterygoid in Epomophorous dobsonii resembles that of other epomophorines including all Epomophorus (Bergmans, 1989: fig. 9). The condition of the postdental palate in E. dobsonii and all species previously referred to Micropteropus also matches typical Epomophorus, which have deeply concave postdental palate (see Bergmans, 1988, 1989, 1997; Giannini and Simmons, 2005), as opposed to palate only weakly concave in Epomops (Bergmans, 1989).

Type species: Nesonycteris woodfordi Thomas, 1887.

Contents: Includes two species: Nesonycteris fardoulisi (Flannery, 1993) and N. woodfordi Thomas, 1887.

Synonyms: None.

Diagnosis: Nesonycteris species lack a claw on the second digit (present in Melonycteris), lack the first lower incisor (present in Melonycteris), and present dorsal and ventral body fur similarly light orange brown (Melonycteris has a dark brown venter and orange dorsum).

Comments: Nesonycteris is often included in Melonycteris (e.g., Flannery, 1993; Simmons and Cirranello, 2019), but the phylogenetic results reported here recovered the two species of Nesonycteris forming a strongly supported clade that is sister to Melonycteris and separated by a very long branch dated with a point estimate of their split at 10 mybp. Moreover, Melonycteris and Nesonycteris each exhibit apomorphies (see Diagnosis above) that, together with our phylogenetic results, warrant recognition of two genera.

Type species: Pachysoma ecaudatus Temminck, 1837.

Contents: Includes four species: Megaerops ecaudatus (Temminck, 1837), M. kusnotoi Hill and Boeadi, 1978, M. niphanae Yenbutra and Felten, 1983, and M. albicollis (Francis, 1989). It does not include the form wetmorei, transferred to Ptenochirus as P. wetmorei.

Synonyms: None; included as a subgenus of Pachysoma (= Cynopterus).

Emended diagnosis: Cynopterine genus with tail generally absent (extremely short, up to 4 mm only in some western Malaysian specimens of M. albicollis), rostrum short and deep, extremely deep in type species, with upper incisors unequal (I2 about one half of I1), upper canine relatively short and with mesial surface convex (without mesial groove), single lower incisor represented by i2 (see Giannini and Simmons, 2007), lower canine very short.

Comments: Simmons (2005) recognized four species of Megaerops: M. ecaudatus, M. niphanae, M. kusnotoi, and M. wetmorei, the latter with two distinct subspecies, the Philippine M. w. wetmorei and the Sundaic M. w. albicollis Francis, 1989. Recently, Giannini (2019) recognized albicollis as a separate, valid species of Megaerops, and transferred typical wetmorei to Ptenochirus, as P. wetmorei. Here we provide additional justification for these changes. On the basis of three specimens (two from Borneo and one from peninsular Malaysia), Francis (1989) described a distinct cynopterine taxon, Megaerops wetmorei albicollis, noting, however, that “differences [with respect to M. w. wetmorei from Mindanao] seem sufficient to warrant taxonomic recognition, but because of the geographic separation and the small number of specimens available, I consider it most appropriate to recognize them at the subspecific level” (Francis, 1989: 2878). We believe that Francis's intuition was correct about the species-level status of this new taxon. New specimens have expanded the previously known distribution to Sumatra and confirmed the distinctiveness of albicollis (see Maharadatunkamsi and Maryanto, 2002). Furthermore, Francis (1989) correctly specified a number of external and craniodental characters that distinguish albicollis from wetmorei. It turns out that these differences largely serve to distinguish Megaerops from Ptenochirus at the genus level, which is in line with the consistent recovery of wetmorei grouping in Ptenochirus and separate from Megaerops in phylogenetic analyses (e.g., Almeida et al., 2009; this study). These observations led Giannini (2019) to recognize albicollis as a valid species within Megaerops (as M. albicollis, new combination) with Sundaic distribution as typical of Megaerops, and to include wetmorei in the Philippine Ptenochirus (as monotypic P. wetmorei) with a distribution in Mindanao only. Megaerops albicollis has not been included in any phylogeny to date, but it is similar to other Megaerops in craniodental characters and in the uniform light-brown, creamy pelage, particularly apparent in M. niphanae, from which it can be distinguished by the distinctive, ample white ruff (the species epithet means “white collar”). By contrast, the pelage pattern of Ptenochirus wetmorei is typical of Ptenochirus species, i.e., dark gray head, dark muzzle, rusty ruff, and grayish-brown to rusty-brown body pelage. The tail is absent in Megaerops except in some specimens of albicollis (up to 4 mm; see Francis 1989, Giannini 2019). Craniodental characters of M. albicollis are typical of Megaerops and distinct from Ptenochirus, as follows: rostrum short, deep, and wide (vs. longer, shallower, and narrower in Ptenochirus); palate wide and semicircular (vs. narrow with slightly divergent tooth rows in Ptenochirus); dentition weak, with upper canine and premolars almost vertical, short (vs. dentition generally stronger, with noticeably longer, procumbent upper canines, and premolars with longer, shorter main cusp in Ptenochirus). These differences are schematically illustrated by Francis (1989: fig. 2).

Type species: Ptenochirus jagori (Peters, 1861).

Contents: Includes three species: Ptenochirus jagori (Peters, 1861), P. minor (Yoshiyuki, 1979), and P. wetmorei (Taylor, 1934). Ptenochirus as thus recognized does not include albicollis, currently treated as Megaerops albicollis but originally described as Megaerops wetmorei albicollis Francis, 1999 (see details above).

Synonyms: None; described by Peters as a subgenus of Pachysoma (= Cynopterus).

Diagnosis: As in Andersen (1912), a cynopterine genus with upper incisors unequal (inner incisors considerably bulkier and longer than minute outer incisors), upper canine with deep anteromedial (i.e., mesial) groove (inconspicuous in P. wetmorei), single lower incisor representing i2 (see also Giannini and Simmons, 2007), tail always present (range across species 3–18 mm), head pelage significantly darker than body pelage, rusty brown ruff.

Comments: Ptenochirus wetmorei was originally described in Megaerops chiefly because it lacks a tail, which is characteristic of Megaerops among cynopterine genera (see Taylor, 1934). Ptenochirus wetmorei indeed appears intermediate between typical Ptenochirus and Megaerops in some morphological aspects (very short tail, upper canine with barely noticeable or lacking groove), but a closer relationship of this form to Ptenochirus jagori (and P. minor) than to Megaerops species was found in the first comprehensive study of cynopterine relationships by Almeida et al. (2009), a finding replicated in this study.