Your search keyword '"Csorba, Gabor"' showing total 8 results

1. A new genus and species of vespertilionid bat from the Indomalayan Region

Author

Ruedi, Manuel, Eger, Judith L., Lim, Burton K., and Csorba, Gábor

Published

2018

2. Out of Southeast Asia: A new species of thick-thumbed bat (Chiroptera: Vespertilionidae: Glischropus) from Meghalaya, north-eastern India

Author

Saikia, Uttam, Ruedi, Manuel, and Csorba, Gabor

Subjects

Chiroptera, Mammalia, Animalia, Animals, India, Animal Science and Zoology, Biodiversity, Vespertilionidae, Chordata, Asia, Southeastern, Ecology, Evolution, Behavior and Systematics, Taxonomy

Abstract

Thick-thumbed bats of the genus Glischropus are currently composed of four recognized species from Southeast Asia, two of which were described in recent times. Among these species, G. aquilus is endemic to Sumatra, G. javanus is restricted to western Java, whereas G. bucephalus is widely distributed north to the Isthmus of Kra and G. tylopus is widespread south to this zoogeographic boundary. Two recently collected Glischropus specimens from Meghalaya state in north-eastern India extend the known distribution range of the genus westward into South Asia by ca. 1000 km. Morphological examination of these specimens and comparison with all known species in this genus revealed marked differences in colouration, dental characters and bacular traits. We therefore describe the Meghalaya specimens as a new species. The discovery of the new species from a forest patch adjacent to Nongkhyllem Wildlife Sanctuary from where another specialized bamboo-dwelling species (Eudiscopus denticulus) was reported recently also underscore the importance of the area from a conservation point of view.

Published

2022

3. Glischropus meghalayanus Saikia & Ruedi & Csorba 2022, n. sp

Author

Saikia, Uttam, Ruedi, Manuel, and Csorba, Gabor

Subjects

Chiroptera, Mammalia, Glischropus, Animalia, Biodiversity, Vespertilionidae, Chordata, Glischropus meghalayanus, Taxonomy

Abstract

Glischropus meghalayanus n. sp. (Figs. 1–6; Table 1) Holotype. V /M/ERS/682, adult male, in alcohol, skull and baculum extracted. Collected by Uttam Saikia, 1 st July 2020. Type locality. Forest at Lailad, adjacent to Nongkhyllem Wildlife Sanctuary, in Ri-Bhoi district of Meghalaya, India (25°56’13” N, 91°46’24” E, 210 m a.s.l.) External measurements of the holotype (in mm). HB= 40.0, TL= 41.0, E= 9.5, Tr= 4.2, FA= 32.5, 3 MT = 32.9, 4 MT = 31.4, 5 MT = 31.4, TB= 15.4, HF= 7.3, body mass= 4 g. Paratype. V /M/ERS/683, adult male, in alcohol, skull (slightly damaged) and baculum (slightly damaged) extracted. The paratype was collected by Uttam Saikia from the same locality as the holotype on the 1 st July, 2020. External measurements of the paratype (in mm). HB= 38.0, TL= 39.0, E= 9.9, Tr= 4.3, FA= 33.7, 3 MT = 33.6, 4 MT = 32.9, 5 MT = 32.6, TB= 15.1, HF= 7.1, body mass= 4 g. Etymology. The specific epithet meghalayanus is derived from the Meghalaya state in north-eastern India from where it was discovered and also in honour of the 50 th anniversary of statehood in 2022. The proposed English name is Meghalaya thick-thumbed bat. Diagnosis. A medium sized Glischropus with a forearm length of 32.5 mm and 33.7 mm, (Table 1). Dorsal fur dark brown with well demarcated beige coloured ventral fur. The skull has an elevated frontal region, globose braincase; the second incisor reaches at least two third the height of first; the baculum shaft is narrow, elongated, and strongly curved when viewed laterally. Description. Forearm length of the holotype and the paratype is 32.5 mm and 33.7 mm, respectively, which are almost equal to the length of the third metacarpals. The head-body and tail lengths are subequal. The dorsal fur is dark brown while the ventral fur is beige; there is a clear demarcation between the two. Individual dorsal hairs are unicoloured throughout whereas the ventral hairs are dark at the base and lighter at the tips. The overall appearance, including the head shape, ear and tragus, is strikingly similar to that of smaller pipistrelles. However, unlike in Pipistrellus, oval-shaped thumb pads (ca. 2.7 mm long) and fleshy callosities at the base of the toes are present (Fig. 1). Thumb pads and foot soles were pinkish in live individuals but quickly turned white after preservation in alcohol. They are not as well developed as in other bamboo specialized species like Eudiscopus. The muzzle and chin are pinkish, ears dark brown. The wing membrane is dark brown and attaches to the base of the toes. The tail membrane is slightly lighter in colour and the calcar extends almost half the length of the free edge of tail membrane; calcar lobe is elongated. The terminal caudal vertebra protrudes out of the tail membrane. The penis is dorso-ventrally flattened, pendulous, 5.5 mm in length; the proximal half is mostly naked, whereas the distal half is strongly hirsute with whitish hairs (Fig. 1). The baculum is 2.38–2.46 mm long with paired basal lobes; the shaft is narrow and terminates in a deeply bifurcated tip. In lateral view, the baculum has a double curved silhouette. The cranium has an elevated frontal region and a roundish braincase. The narial emargination is V-shaped, sagittal crest is absent and lamboid crest is poorly developed. The zygomatic arches are thin and straight. The first (I 2) and the second incisor (I 3) have similar crown area; I 3 lies almost fully laterally to I 2. The first incisor is only weakly bifid; the second incisor reaches about two third the height of the first incisor. The first upper premolar has a basal area equal to the first incisor; it is intruded from the toothrow and is largely obscured in lateral view (Fig. 2). The lower molars are nyctalodont. Dental formula is 2123/3123= 34. Comparison with similar species. As attempts to obtain sequence data from the alcohol-preserved tissues of G. meghalayanus n. sp. were unsuccessful, our comparisons are necessarily restricted to morphological features. A dental formula with 34 teeth, the labially directed concavity of the second upper incisor, and thickened pads at the base of thumbs are characteristics of the genus Glischropus. G. meghalayanus n. sp. can be distinguished from all its congeners by a suite of external, cranial, and dental characters. In contrast to all the species under this genus, the dark brown dorsal fur of the new species is demarcated from the beige ventral fur. The skull profile with a distinctly elevated frontal region and globose braincase is very similar to G. aquilus and G. bucephalus (Fig. 3). The new species, however, can be distinguished from both these two species by the following characters: a wider post-dental palatal width (PDW) of 2.9-2.98 mm (against 2.32 in G. aquilus and 2.19-2.40 mm in G. bucephalus), the first upper incisor is unicuspid (vs clearly bicuspid), and the second upper incisor reaches about two thirds the height of the first incisor (vs less than half its height in G. aquilus and G. bucephalus; Fig. 4). G. meghalayanus n. sp. can be further told apart cranially from the morphologically most closely resembling G. bucephalus by the more elongated rostral part and clearly less abruptly elevated frontal region. G. meghalayanus n. sp. can also be cranially differentiated from G. aquilus by the posteriorly narrowing V-shaped narial emargination (vs broad U-shaped in G. aquilus). The skull profile of another congener, G. tylopus, is distinctly flatter without any elevated frontal region and the second upper incisor lies postero-laterally to the first (in G. meghalayanus n. sp., they lie at the same level in a straight line; Fig 5). The baculum of G. meghalayanus n. sp. has a distinct double curved lateral profile, and the length of the bone is 2.38–2.46 mm (it is 1.21 mm in G. tylopus and 2.03–2.32 mm in G. bucephalus) (Fig. 6, Table 1). Distribution. All Glischropus species known so far are reportedly distributed in the Southeast Asian region, from Myanmar and east to the Maluku archipelago. The present discovery of G. meghalayanus n. sp. constitutes the first record of this genus from India and South Asia, and therefore represents a significant (ca. 1000 km) westward range extension for the genus from the westernmost reported locality i.e. Kayah (Karenni) state in eastern Myanmar (Blanford 1888 -91: 602) (Fig. 7). G. meghalayanus n. sp. is currently known only from the type locality, i.e. forests at Lailad, in Ri-Bhoi district of Meghalaya, India. Wing morphology. Based on mean wing measurements of the two adult male specimens caught in Meghalaya, we calculated a moderate aspect ratio (6.61) and low wing loading (4.83), coupled with relatively high tip-shape index (1.68). These wing characteristics suggest low flight speed and high manoeuvrability (Norberg and Rayner 1987) and imply that this species can be classified as an ‘edge-space aerial forager’ (Denzinger and Schnitzler 2013). This is akin to Tylonycteris and Eudiscopus bats which are adapted to a fair degree of clutter like bamboo forests (Saikia et al. 2021). Echolocation calls could also help infer the foraging ecology of these bats, but unfortunately, no recording could be obtained prior or after capture. Ecological notes. The two specimens of G. meghalayanus n. sp. were caught in a mist-net set at one of the entrances of a tunnel-like, closed canopy forest with predominant bamboo growths of Dendrocalamus and Bambusa spp. (Fig. 8). The general forest habitats found in the area belong to the Tropical semi-evergreen type (Champion and Seth 1968). Bats were caught on the inner side of the net facing the tunnel indicating that they were emerging from inside the forest patch. The area was predominantly occupied by bamboo forest and the modifications like fleshy callosities in the thumbs and soles of the bats also indicate a roosting preference inside bamboo internodes. This was exactly the same spot where two specimens of another bamboo specialist, Eudiscopus denticulus, were caught in the same night (Saikia et al. 2021). It may also be noted that another bamboo dwelling bat Tylonycteris sp. was also caught by the senior author in a nearby area during the summer of 2016, indicating extremely high diversity of bamboo-dwelling bats in the area. The present collection locality lies just outside the boundary of Nongkhyllem Wildlife Sanctuary which encompasses similar habitats. These bats are therefore highly likely to be occurring in the Sanctuary area as well, which enjoys some degrees of protection. However, dense forests such as those existing around the type locality of G. meghalayanus n. sp. are under increasing pressure due to high demands for firewood and timber for construction. Further surveys of bats in such high-diversity region are therefore urgently needed to identify areas that are in immediate needs for conservation actions.

Published

2022

4. Kerivoula furva Kuo & Soisook & Ho & Csorba & Wang & Rossiter 2017, sp. n

Author

Kuo, Hao-Chih, Soisook, Pipat, Ho, Ying-Yi, Csorba, Gabor, Wang, Chun-Neng, and Rossiter, Stephen J.

Subjects

Chiroptera, Mammalia, Kerivoula furva, Animalia, Biodiversity, Vespertilionidae, Kerivoula, Chordata, Taxonomy

Abstract

Kerivoula furva sp. n. (Figs. 1–6, Tables 1–2) Holotype NMNS 17595, adult ♀, dry skin, skull and postcranial skeleton, collected by Yi-Wen Chen, 29 Mar 2009. Type locality TAIWAN, Yilan County, Yuanshan Township, 3 km East of Shuanglianpi, 24°45.21’N, 121°39.63’E, 180 m a.s.l. Paratypes NMNS 17657, adult ♀, dry skin, skull and postcranial skeleton and NMNS 19136, adult ♀, dry skin, skull and postcranial skeleton, both from the type locality; THU 07.X.25.9, adult ♀, dry skin and skull and THU 07.X.25.11, adult ♂, dry skin and skull, both from TAIWAN, Yilan County, Yuanshan Township, Shuanglianpi, 24°45.04’N, 121°38.05’E, around 500 m a.s.l.; HNHM 2016.8.1, adult ♂, in alcohol with skull extracted, collected at TAIWAN, Taoyuan City, Fuxing District, 2.5 km SE of Xiao Wulai, 24°47.01’N, 121°24.07’E, 650 m a.s.l.; TESRI B1398, adult ♀, dry skin, skull and postcranial skeleton, TESRI B1399, adult ♀, dry skin, skull and postcranial skeleton, TESRI B1400, adult ♀, dry skin, skull and postcranial skeleton and TESRI B1401, adult ♀, dry skin, skull and postcranial skeleton, the above four from TAIWAN, Taichung City, Heping District, Wushikeng Low Altitude Experimental Station of TESRI, 24°16.42’N, 120°57.059’E., 1056 m a.s.l.; HNHM 2005.66.1, adult ♂, in alcohol with skull extracted, collected at TAIWAN, Tainan City, Dongshan District, Gaoyuan Village; NMNS 13946, adult ♂, dry skin, skull in THU (B040017), NMNS 13947, adult ♂, dry skin, skull in THU (B040018), NMNS 13948, adult ♀, dry skin, skull in THU (B030041) and NMNS 13952, juvenile ♂, dry skin, skull in THU (B030028), the above four from TAIWAN, Kaohsiung City, Taoyuan District, Meilan Logging Road, 23°17.24’N, 120°49.46’E, 920 m a.s.l.; NMNS 10806, adult ♂, dry skin, skull in THU (B040007) and NMNS 14039, adult ♀, dry skin, skull in THU (B030025), both from TAIWAN, Kaohsiung City, Taoyuan District, Meilong Logging Road, 23°5.70’N, 120°44.28’E, around 800 m a.s.l.; Field number PS160206.3 (to be subsequently deposited in the Zoological Collection of the University of Mandalay), adult ♀, in alcohol with skull extracted, collected from MYANMAR, Kachin, Putao Township, Wang Hlaing Dam Village, 27.479°N, 97.169°E, 863 m a.s.l. Referred specimens BMNH 21.1.6.32, adult ♀, INDIA, Meghalaya, Jaintia Hills; BMNH 50.432, adult ♂, and BMNH 50.438, adult ♀, both from MYANMAR, Kachin, Nam Tamai; Field number PS160206.1 (to be subsequently deposited in the Zoological Collection of the University of Mandalay), adult ♂, from MYAN- MAR, Kachin, Putao Township, Wang Hlaing Dam Village. The two specimens from CHINA, Hainan (IBHG 08279 and IBHG 08280, both ♀) which are consistently supported by morphological, karyotypic and molecular evidence to have a close relationship with K. furva sp. n. in Taiwan (Wu et al., 2012) are considered to belong to this new species. In addition, the following specimens from CHINA which formed the COI lineage K. hardwickii D along with K. furva sp. n. in Taiwan (Fig. 1a) are also assigned to this new species: ROM MAM 116079, ♀, Guangxi, Jing Xin County Provincial Nature Reserve; ROM MAM 114918, ♂, ROM MAM 114944, ♀, both from Hunan, Shuhuangshan Nature Reserve; ROM MAM 114961, ♂, ROM MAM 114962, ♀, ROM MAM 114963, ♀, ROM MAM 114964, ♀, ROM MAM 115009, ♀, ROM MAM 115041, ♀, ROM MAM 115042, ♀, ROM MAM 115047, ♂, from Hunan, Daweishan National Park. The assignments of the ROM specimens to K. furva sp. n. are solely informed from a mitochondrial gene, and thus required further verification based on morphological or nuclear gene data (see Discussion). Etymology The proposed English name is ‘Dark woolly bat’. The name refers to the very dark pelage of the new species. Diagnosis Kerivoula furva sp. n. has a darkest dorsal pelage among the Asian Kerivoula species, with dorsal hairs that are broadly uniformly coloured throughout their length. Its body size is comparable to that of K. titania and K. hardwickii s. str., however, compared to the former, K. furva sp. n. has a proportionally shorter tibia and a proportionally wider postorbital constriction, whereas compar- ed to K. hardwickii s. str., it has a proportionally lower braincase height. Kerivoula furva sp. n. and K. depressa have skulls that are similar in shape while the former taxon has a slightly larger skull than the latter. Kerivoula furva sp. n. has a generally larger and more flattened skull compared to K. krauensis. Description A medium-sized Kerivoula, with a body mass of 4–7 g and a forearm length of 30.9–37.5 mm (Tables 1 and 2). The ear is 14.3–15.2 mm in length (n = 4); it is funnel shaped and has a fold extending from the base of the pinna to the half of the posterior border. The edge of the pinna is darkly pigmented, contrasting strongly with the paler central part (Fig. 4a). The tragus is long and pointed, and curves slightly outwards at the tip. In some individual bats examined, the tip of the tragus is dark while in others the tragus is pale in colour throughout its length. The dorsal pelage varies from black brown to black grey. Individual dorsal hairs are dark brown and are broadly uniform in colour except for the tips, which are even darker (Fig. 4b). The ventral pelage is greyish brown. Individual ventral hairs have distinct dark brown bases; those on the chest and along the middle line of the abdomen have medium brown tips while those along the flanks of the abdomen have pale grey tips (Fig. 4c). Some individual bats have grey-tipped hairs over the entire ventral surface. The base of the thumb swells to form an oval, fleshy pad. The insertion point of the wing membrane is at the base of the first toe. The skull has a GTL of 14.07–15.45 mm (Table 2). The narial emargination is two-fold longer than its width, while the anterior palatal emargination is approximately the same long as its width (Fig. 5a–b). The sagittal crest is absent. The braincase is broadened and flattened. The basioccipital pits are welldeveloped, and widen anteriorly and taper posteriorly beyond the front one-third of the cochleae (Fig. 5b). The C–M 3 is 5.52–6.11 mm (Table 2; see Fig. 5c–d for qualitative characters of the upper dentition). The first upper incisor (I 2) has a height approximately two-thirds that of the upper canine. The second upper incisor (I 3) has a height half that of I 2, while the crown areas of these two are about the same. The upper canine has a height surpassing that of the other teeth in the upper toothrow, and has a length that is approximately equal to its width. The first upper premolar (P 2) and the second upper premolar (P 3) are both slightly shorter than their respective widths; the latter tooth has a height and a crown area approximately 80% and 90% the respective dimensions of the former tooth. The third upper premolar (P 4) has a length along its labial bor- der longer than that along its lingual border, making this tooth somewhat triangular in shape. P 4 has its height and crown area 30–40% and 70% larger than respective dimensions of P 2; P 4 has its height twothirds that of the upper canine while having its crown area 10% larger than that of the latter tooth. The first and second upper molars (M 1 and M 2, respectively) both have typical W-shaped cusp structure, with para-, meso- and metastyle all well developed. The third upper molar (M 3) has reduced mesostyle and metacone and has the metastyle absent. The mandible has a MDL of 9.59–10.86 mm and has a C–M 3 of 5.86–6.44 mm (Table 2; see Fig. 5e–f for qualitative characters of the lower dentition). The first and second lower incisors (I 1 and I 2, respectively) are tricuspid. The third lower incisor (I 3) is unicuspid, whilst it has a large cingular cusp on the lingual posterior border in addition to another smaller one on the labial posterior border. The lower canine has a large cingular cusp on its lingual anterior border, which is higher than I 3. The first, second and third lower premolars (P 2, P 3 and P 4, respectively) are similar to each other in both height and crown area except for P 3, which has a comparatively smaller (90%) crown area. The three lower premolars have heights of ca. 75% of the lower canine. The first and second lower molar (M 1 and M 2, respectively) both have well developed talonids which have widths exceeding those of the trigonids of corresponding teeth. The third lower molar (M 3) has a reduced talonid whose width is smaller than that of the trigonid of the same tooth. Comparisons While Wu et al. (2012) referred to K. furva sp. n. as K. titania, the former species is distinct in having a proportionally shorter tibia. In K. furva sp. n. the ratio of the tibia to the forearm (TIB /FA) ranged 0.48–0.51 (n =13) for museum specimens and 0.48–0.55 (n =159) for live individuals caught in the field. In comparison, the reported TIB /FA for K. titania ranges 0.55–0.57 (n =6) for museum specimens. In the cranium, K. furva sp. n. has a proportionally larger POC than K. titania (Fig. 2 and Fig. 6 bottom row). External measurements include forearm length (FA) and length of tibia (TIB); craniodental measurements include greatest length of skull (GTL), condylobasal length (CBL), condylocanine length (CCL), zygomatic breadth (ZB), greatest width of the braincase (GBB), braincase height (BH), postorbital constriction (POC), maxillary toothrow length (C–M 3), posterior palatal width (M 3 –M 3), mandible length (MDL) and mandibular toothrow length (C–M); a — Data from Miller (1906 a); b — with an ambiguous reclassification in DAPC (Fig. 3); c — data from Tate (1941); d — data from Francis et 3 al. (2007); e — data from Douangboubpha et al. (2016); f — data from Struebig et al. (2016) Fig. 5. The skull of K. furva sp. n. (paratype, ESRI B1398), showing (a–b) dorsal and basal views of the cranium, (c) occlusal view of the left upper toothrow, (d–e) lateral views of the cranium and the mandible, and (f) occlusal view of the left lower toothrow. Scale bars = 5 mm Among phylogenetically close relatives (i.e., K. hardwickii complex), K. kachinensis is a diagnostically larger-sized species compared to K. furva sp. n. (Fig. 2 and Table 2). Kerivoula hardwickii s. str. and K. furva sp. n. broadly overlap in both body and skull size (Fig. 2 and Table 2), while the former species has a proportionally larger BH than the latter one (Figs. 2–3 and Fig. 6 middle row). Kerivoula depressa has a smaller skull size compared to K. furva sp. n. (Fig. 2 and Table 2). Kerivoula krauensis is smaller than K. furva sp. n. in general, with more extreme differences between the two on TIB and on lengths of the skull (Table 2). In addition, the braincase of K. krauensis is domed like that of K. hardwickii s. str. compared to the flat skull of K. furva sp. n. The ratio of BH to C–M 3 in K. furva sp. n. is smaller than that of K. hardwickii s. str. (Fig. 6 middle right panel) and, based on a measurement reported by Douangboubpha et al. (2016), is much smaller than that of K. krauensis (1.10). The dorsal pelage of K. furva sp. n. is clearly distinguishable from that of all congeneric species described above. Kerivoula hardwickii s. str. was described to have “dark bases of the fur on the upperparts …with the majority of the hair pale grey or brown” (Francis et al., 2007: 5–6), while K. depressa was described as having “upperparts between buff and cream-buff” (Miller, 1906 a: 65). The dorsal hairs of K. kachinensis have darker grey bases and paler grey-brown upper segments (Bates et al., 2004; Soisook et al., 2007), those of K. titania have light grey middle segments above black bases (Bates et al., 2007), and those of K. krauensis are dark brown with shiny golden-brown tips (Francis et al., 2007; Struebig et al., In press). In comparison, K. furva sp. n. has a diagnostically darker dorsal pelage that shows virtually no colour distinction between the root and the middle section of individual hairs. Echolocation Kerivoula furva sp. n. produced echolocation calls in groups consisting of 4.4–9.8 pulses and with repetition rates among bouts of 5.0–9.3 Hz 0.66 0.62 0.58 0.54 fur T fur C dep har tita Myanmar boundary, dep for K. depressa, har for K. hardwickii and tita for K. titania (Table 3). Within bouts, individual pulses had peak frequencies at 141.8–163.3 kHz, sweeping down from 182.4–222.1 (maximum frequency) to 105.7– 118.3 (minimum frequency) kHz, and were characterized by durations of 1.4–2.0 ms and repetition rates of 50–83.8 Hz. Further details of parameters for echolocation calls are presented in Table 3. In general, K. furva sp. n. emitted individual calls that were typical to its genus (see Kingston et al., 1999; Schmieder et al., 2012), characterized by very broad bandwidths (69.4–103.9 kHz), extremely high frequencies and very high repetition rates, all of which are considered to be specializations for foraging in cluttered environments such as dense vegetation (also see Siemers and Schnitzler, 2000, 2004; Schnitzler and Kalko, 2001). Distribution and ecological notes Currently known from Taiwan, Meghalaya in India, Kachin in Myanmar (this study), Hainan of SE China (Wu et al., 2012) and probably also from Hunan and Guangxi of SE China (Fig. 1). Kerivoula furva sp. n. has a wide range in Taiwan where it occurs in montane and hilly areas with elevations of et al., 2014). In such areas, K. furva sp. n. has been found in broadleaf evergreen forests with low to medium-level disturbance, including forests mixed with betel palm plantations, banana orchards or bamboo stands. In Myanmar, two individuals of K. furva sp. n. were captured in a lowland degraded forest at a foothill. This forest mainly comprises bamboo and banana with some secondary growth trees, and is located between a village and a primary evergreen forest. By analysing arthropod fragments in feces, Chiang (2006) reported the diet of K. furva sp. n. to be composed principally of spiders (order Araneae), followed by cockroaches (Blattodea). Chiang (2006) suggested K. furva sp. n. as a gleaner given that its diet comprised arthropods with no or poor flying ability. Liao (2013) demonstrated in a behavioural experiment that K. furva sp. n. can perform aerial hawking in addition to glean prey from the substrate with the interfemoral membrane. Liao’s (2013) second experiment indicated that K. furva sp. n. can hunt using prey-generated sound. It was reported that K. furva sp. n. roosted in bamboo internodes or in furled young leaves of banana plants (Chang et al., 2010; Cheng et al., 2010), with individuals roosting either solitarily or in small colonies composed of two to ten bats. Little is known of their reproductive phenology, however, females were recorded as pregnant from mid-April to mid-May (n = 8) and lactating from mid-May to early July (n = 27) (H. C. Kuo, personal observation). Genetics Conventional, G-banded and C-banded karyotypes were reported in Wu et al. (2012) for Hainanese and Taiwanese specimens, showing diploid chromosome number (2n) = 32 and fundamental number (FN) = 51–52. The diploid chromosome number differed from those of K. hardwickii, K. intermedia, K. lanosa, K. lenis, K. minuta and K. papillosa (reviewed in Wu et al., 2012). Phylogenetic analyses conducted in this study based on partial sequences of the mitochondrial COI gene and of the nuclear RAG2 gene consistently recovered close relationships among K. furva sp. n., K. hardwickii s. lato and K. kachinensis, to the exclusion of other congeneric species (Fig. 1). Kerivoula krauensis may also belong to this complex based on the COI -based phylogeny. Recently, Kuo et al. (2014) investigated the phylogeography of K. furva sp. n. across its range in Taiwan. Based on genotyping individuals at nine autosomal microsatellite loci, the authors found strong genetic differentiation among populations across the island, with evidence of restricted East-West gene flow, indicating that the Central Mountain Range acts as a barrier to movement. No such p hylogeographic structure was observed when studying haplotypes of the COI gene, although this appears to reflect this species’ recent colonization history on Taiwan (Kuo et al., 2014)., Published as part of Kuo, Hao-Chih, Soisook, Pipat, Ho, Ying-Yi, Csorba, Gabor, Wang, Chun-Neng & Rossiter, Stephen J., 2017, A taxonomic revision of the Kerivoula hardwickii complex (Chiroptera: Vespertilionidae) with the description of a new species, pp. 19-39 in Acta Chiropterologica 19 (1) on pages 27-33, DOI: 10.3161/15081109ACC2017.19.1.002, http://zenodo.org/record/3944802, {"references":["WU, Y., Y. C. LI, L. K. LIN, M. HARADA, Z. CHEN, and M. MOTOKAWA. 2012. New records of Kerivoula titania (Chiroptera: Vespertilionidae) from Hainan Island and Taiwan. Mammal Study, 37: 69 - 72.","MILLER, G. S. 1906 a. Seven new Malayan bats. Proceedings of the Biological Society of Washington, 19: 61 - 65.","TATE, G. H. H. 1941. Results of the Archbold expeditions. No. 40. Notes on vespertilionid bats. Bulletin of the American Museum of Natural History, 78: 567 - 597.","DOUANGBOUBPHA, B., S. BUMRUNGSRI, C. SATASOOK, W. WANNA, P. SOISOOK, and P. J. J. BATES. 2016. Morphology, genetics and echolocation calls of the genus Kerivoula (Chiroptera: Vespertilionidae: Kerivoulinae) in Thailand. Mammalia, 80: 21 - 47.","FRANCIS, C. M., T. KINGSTON, and A. ZUBAID. 2007. A new species of Kerivoula (Chiroptera: Vespertilionidae) from peninsular Malaysia. Acta Chiropterologica, 9: 1 - 12.","BATES, P. J. J., M. J. STRUEBIG, S. J. ROSSITER, T. KINGSTON, SAI SEIN LIN OO, and KHIN MYA MYA. 2004. A new species of Kerivoula (Chiroptera: Vespertilionidae) from Myanmar (Burma). Acta Chiropterologica, 6: 219 - 226.","SOISOOK, P., S. BUMRUNGSRI, A. DEJTARADOL, C. M. FRANCIS, G. CSORBA, A. GUILLEN- SERVENT, and P. J. J. BATES. 2007. First records of Kerivoula kachinensis (Chiroptera: Vespertilionidae) from Cambodia, Lao PDR and Thailand. Acta Chiropterologica, 9: 339 - 345.","BATES, P. J. J., M. J. STRUEBIG, B. D. HAYES, N. M. FUREY, KHIN MYA MYA, V. D. THONG, P. D. TIEN, N. T. SON, D. L. HARRISON, C. M. FRANCIS, et al. 2007. A new species of Kerivoula (Chiroptera: Vespertilionidae) from Southeast Asia. Acta Chiropterologica, 9: 323 - 337.","KINGSTON, T., G. JONES, Z. AKBAR, and T. H. KUNZ. 1999. Echolocation signal design in Kerivoulinae and Murininae (Chiroptera: Vespertilionidae) from Malaysia. Journal of Zoology (London), 249: 359 - 374.","SCHMIEDER, D. A., T. KINGSTON, R. HASHIM, and B. M. SIEMERS. 2012. Sensory constraints on prey detection performance in an ensemble of vespertilionid understorey rain forest bats. Functional Ecology, 26: 1043 - 1053.","SIEMERS, B. M., and H. - U. SCHNITZLER. 2000. Natterer's bat (Myotis nattereri Kuhl, 1818) hawks for prey close to vegetation using echolocation signals of very broad bandwidth. Behavioral Ecology and Sociobiology, 47: 400 - 412.","SIEMERS, B. M., and H. - U. SCHNITZLER. 2004. Echolocation signals reflect niche differentiation in five sympatric congeneric bat species. Nature, 429: 657 - 661.","SCHNITZLER, H. - U., and E. K. V. KALKO. 2001. Echolocation by insect-eating bats. Bioscience, 51: 557 - 569.","KUO, H. - C., S. - F. CHEN, Y. - P. FANG, J. FLANDERS, and S. J. ROSSITER. 2014. Comparative rangewide phylogeography of four endemic Taiwanese bat species. Molecular Ecology, 23: 3566 - 3586.","CHIANG, C. - L. 2006. Diet and foraging strategies of Taiwanese woolly bat (Kerivoula sp.) at Bailan, Hsinchu. M. Sci. Thesis, National Taiwan University, Taipei, 45 pp.","LIAO, W. - C. 2013. Detecting and gleaning prey by Murina and Kerivoula bats. M. Sci. Thesis, National Taiwan University, Taipei, 39 pp.","CHANG, Y. - C., C. - H. CHOU, Y. - W. CHEN, C. - L. LAN, and L. - K. LIN. 2010. [Furled young banana leaves as roost for the Taiwanese woolly bat (Kerivoula sp.)]. Nature Conservation Quarterly, 72: 3 - 7. [In Chinese].","CHENG, H. - C., Y. - P. FANG, and C. - H. CHOU. 2010. A photographic guide to the bats of Taiwan. Endemic Species Research Institute, Nantou, Taiwan, 144 pp."]}

Published

2017

5. A Taxonomic Revision of the Kerivoula hardwickii Complex (Chiroptera: Vespertilionidae) with the Description of a New Species.

Author

Kuo, Hao-Chih, Soisook, Pipat, Ho, Ying-Yi, Csorba, Gabor, Wang, Chun-Neng, and Rossiter, Stephen J.

Subjects

VESPERTILIONIDAE, BAT classification, ANIMAL species, MITOCHONDRIAL DNA, NUCLEAR DNA, MAMMALS

Abstract

Since its discovery, the taxonomic status of the only species of Kerivoula (Chiroptera: Vespertilionidae: Kerivoulinae) to be found on Taiwan has been confused. Previous studies have assigned this species to either Kerivoula hardwickii or K. titania, both of which occur on continental SE Asia. This uncertainty supports repeated suggestions in the literature that specimens of K. hardwickii collected and/or sampled across SE Asia are likely to represent multiple cryptic taxa. To address these issues, we combined new and existing data from the genus Kerivoula on Taiwan and continental Asia, and performed diagnostic analyses in steps. First, phylogenetic reconstructions based on mitochondrial and nuclear DNA revealed a well-supported group comprising all taxa currently recognized as K. hardwickii, together with the Taiwanese Kerivoula and Kerivoula kachinensis to the exclusion of all other congeneric species. Second, focusing on all members of this monophyletic clade (i.e., K. hardwickii complex) together with K. titania, we used multivariate statistical methods to separate taxa based on morphometric data. Our results provide strong evidence that among these bats, the Taiwanese Kerivoula is a new species that also occurs on continental Asia, for which we provide a formal description and name. In addition, we show that the subspecies K. hardwickii depressa should be elevated to species status. We discuss our findings and the caveats of this and similar studies. [ABSTRACT FROM AUTHOR]

Published

2017

6. A review of the Murina cyclotis complex (Chiroptera: Vespertilionidae) with descriptions of a new species and subspecies.

Author

SOISOOK, PIPAT, KARAPAN, SUNATE, SATASOOK, CHUTAMAS, THONG, VU DINH, KHAN, FAISAL ALI ANWARALI, MARYANTO, IBNU, CSORBA, GABOR, FUREY, NEIL, AUL, BANDANA, and BATES, PAUL J. J.

Subjects

VESPERTILIONIDAE, BIOLOGICAL classification, BATS, ZOOGEOGRAPHY, BAT sounds, NATURAL history museums

Abstract

The article presents the study on the taxonomy Murina cyclotis complex from the order, chiroptera, and scientific name, vespertilionidae, with regards to its species and subspecies as of December 2013. The study involved an examination of Murina specimens from various collections including the collection of England-based Natural History Museum. It describes a cryptic species of the cyclotis-complex from Thailand and provides an overview of each taxon's zoogeography, and echolocation.

Published

2013

7. Revealing cryptic bat diversity: three new Murina and redescription of M. tubinaris from Southeast Asia.

Author

CSORBA, GABOR, NGUYEN TRUONG SON, SAVENG, ITH, and FUREY, NEIL M.

Subjects

*BATS, *VESPERTILIONIDAE, *ANIMAL morphology, *ANIMAL classification

Abstract

Based on a series of specimens collected in Cambodia and Vietnam, this paper describes 3 new species of tube-nosed bats belonging to the Murina "suilla-group" (Vespertilionidae: Murininae). We provide detailed accounts of their external and craniodental morphology, including a suite of standard measurements, and compare the new taxa with all other members of the group currently recognized in Southeast Asia. The 1st new species was previously included in M. tubinaris (Scully, 1881) but is considered distinct due to differences in external and craniodental features. This new species is widespread in continental Southeast Asia and relatively well represented in museum collections, whereas the other new species are known only from a few specimens collected at scattered localities. The new taxa are known only from forested areas, which highlights the incompleteness of existing knowledge and strong potential for further discoveries in the region. [ABSTRACT FROM AUTHOR]

Published

2011

8. First records of Kerivoula kachinensis (Chiroptera: Vespertilionidae) from Cambodia, Lao PDR and Thailand

Author

Soisook, Pipat, Bumrungsri, Sara, Dejtaradol, Ariya, Francis, Charles M., Csorba, Gabor, Guillén-Servent, Antonio, and Bates, Paul J. J.

Published

2007