Nyctalus plancyi and Falsistrellus petersi (Chiroptera: Vespertilionidae) from Northern Luzon, Philippines: Ecology, Phylogeny, and Biogeographic Implications

• Autorzy: Heaney L.R. , Balete D. S. , Alviola P. , Rickart E. A. , Ruedi M.
• Języki publikacji: EN

Abstrakty

EN

We report the first records of Nyctalus plancyi from the Philippines, on the basis of three specimens taken in high-elevation mossy forest in the Central Cordillera of northern Luzon. We also report three new specimens of Falsistrellus petersi in the same areas, previously a poorly known species within the Philippines, and provide the first genetic data on the phylogenetic position of the genus. Analysis of sequence data from the mitochondrial gene cytochrome b shows ca. 4% divergence of the Philippine N. plancyi from a sample from China. Combined sequence data from cytochrome b and the nuclear gene RAG2 confirm that JV. plancyi is related to Pipistrellus. They further show that F. petersi is related to Hypsugo and Vespertilio, and Philetor brachypterus is related to Tylonycteris, with all of these taxa being members of the Vespertilionini, not the Pipistrellini. Nyctalus plancyi is the first mammal species documented to have colonized the main, oceanic body of the Philippines from the north (i.e., Taiwan or mainland China), rather than from the south (Borneo, Sulawesi, or New Guinea).

• Wydawca: -
• Czasopismo: Acta Chiropterologica
• Rocznik: 2012
• Tom: 14
• Numer: 2
• Opis fizyczny: p.265-278,ref.

Twórcy

autor

Heaney L.R.

• Department of Zoology, Field Museum of Natural History, 1400 S Lake Shore Drive, Chicago, IL 60605, USA

autor

Balete D. S.

• Department of Zoology, Field Museum of Natural History, 1400 S Lake Shore Drive, Chicago, IL 60605, USA

autor

Alviola P.

• Museum of Natural History, University of the Philippines at Los Baños, College, Laguna 4031, Philippines

autor

Rickart E. A.

• Natural History Museum of Utah, 301 Wakara Way, Salt Lake City, UT 84108, USA

autor

Ruedi M.

• Department of Mammalogy and Ornithology, Natural History Museum of Geneva, Geneva, Switzerland

Bibliografia

• 1. P. A. Alviola , M. R. M. Duya , M. V. Duya , L. R. Heaney , and E. A. Rickart . 2011. Mammalian diversity patterns on Mt. Palali, Caraballo Mountains, Luzon. Fieldiana Life and Earth Sciences, 2: 61–74. Google Scholar
• 2. D. S. Balete , L. R. Heaney , and R. I. Crombie . 1995. First records of Hipposideros lekaguli Thonglongya and Hill 1974 from the Philippines. Asia Life Sciences, 4: 89–94. Google Scholar
• 3. D. S. Balete , L. R. Heaney , M. J. Veluz , and E. A. Rickart . 2009. Diversity patterns of small mammals in the Zambales Mts., Luzon, Philippines. Mammalian Biology, 74: 456–466. Google Scholar
• 4. D. S. Balete , P. A. Alviola , M. R. M. Duya , M. V. Duya , L. R. Heaney , and E. A. Rickart . 2011. The mammals of the Mingan Mountains, Luzon: evidence for a new center of mammalian endemism. Fieldiana Life and Earth Sciences, 2: 75–87. Google Scholar
• 5. P. J. J. Bates , and D. L. Harrison . 1997. Bats of the Indian Subcontinent. Harrison Zoological Museum, Sevenoaks, Kent, 258 pp. Google Scholar
• 6. M. L Bird, D. Taylor, and C. Hunt. 2005. Palaeoenvironments of insular Southeast Asia during the Last Glacial Period: a savanna corridor in Sundaland? Quaternary Science Reviews, 24: 2228–2242. Google Scholar
• 7. R. D. Bradley and R. J. Baker . 2001. A test of the genetic species concept: cytochrome b sequences and mammals. Journal of Mammalogy, 82: 960–973. Google Scholar
• 8. G. Corbet , and J. E. Hill . 1992. The mammals of the Indomalayan Region. Oxford University Press, Oxford, 488 pp. Google Scholar
• 9. J. Cui , N. I. J. Han , D. Streicker , G. Li , X. C. Tang , Z. L. Shi , Z. H. Hu , G. P. Zhao , A. Fontanet , Y. Guan , et al. 2007. Evolutionary relationships between bat coronaviruses and their hosts. Emerging Infectious Diseases, 13: 1526–1532. Google Scholar
• 10. M. R. M. Duya , M. V. Duya , P. A. Alviola , D. S. Balete , and L. R. Heaney . 2007. Report on a survey of the mammals of the Sierra Madre Range, Luzon Island, Philippines. Banwa, 4: 41–68. Google Scholar
• 11. M. R. M. Duya , M. V. Duya , P. A. Alviola , D. S. Balete , and L. R. Heaney . 2011. Diversity of small mammals in montane and mossy forests on Mount Cetaceo, Cagayan Province, Luzon. Fieldiana Life and Earth Sciences, 2: 88–95. Google Scholar
• 12. J. A. Esselestyn 2007. A new species of stripe-faced fruit bat (Chiroptera: Pteropodidae: Styloctenium) from the Philippines. Journal of Mammalogy, 88: 951–958. Google Scholar
• 13. J. A. Esselstyn , and C. H. Oliveros . 2010. Colonization of the Philippines from Taiwan: a multi-locus test of the biogeographic and phylogenetic relationships of isolated populations of shrews. Journal of Biogeography, 37: 1504–1514. Google Scholar
• 14. J. A. Esselstyn , P. Widmann , and L. R. Heaney . 2004. The mammals of Palawan Island, Philippines. Proceedings of the Biological Society of Washington, 117: 285–316. Google Scholar
• 15. J. A. Esselstyn , H. J. D. Garcia , M. G. Saulog , and L. R. Heaney . 2008. A new species of Desmalopex (Pteropodidae) from the Philippines, with a phylogenetic analysis of the Pteropodini. Journal of Mammalogy, 89: 815–825. Google Scholar
• 16. J. A. Esselstyn , R. M. Timm , and R. M. Brown . 2009. Do geological or climatic processes drive speciation in dynamic archipelagos? The tempo and mode of diversification in Southeast Asian shrews. Evolution, 63: 2595–2610. Google Scholar
• 17. J. A. Esselstyn , C. H. Oliveros , R. G. Moyle , A. T Peterson , J. A. Mcguire , and R. M. Brown . 2010. Integrating phylogenetic and taxonomic evidence illuminates complex biogeographic patterns along Huxley's modification of Wallace's Line. Journal of Biogeography, 37: 2054–2066. Google Scholar
• 18. J. A. Esselstyn, S. P. Maher, and R. M. Brown. 2011. Species interactions during diversification and community assembly in an island radiation of shrews. PLoS ONE, 6(7): e21885. Google Scholar
• 19. J. A. Esselstyn, J. L. Sedlock, F. A. Anwarali Khan, B. J. Evans, and L. R. Heaney. 2012. Single-locus species delimitation: a test of the mixed Yule-coalescent model, with an empirical application to Philippine round-eared bats. Proceedings of the Royal Society, 279B: 3678–3686. Google Scholar
• 20. T. Flannery 1995. Mammals of the South-West Pacific and Moluccan Islands. Cornell University Press, Ithaca, 464 pp. Google Scholar
• 21. C. M. Francis 2008. A guide to the mammals of Southeast Asia. Princeton University Press, Princeton, 392 pp. Google Scholar
• 22. C. M. Francis , and J. E. Hill . 1986. A review of the Bornean Pipistrellus (Mammalia: Chiroptera). Mammalia, 50: 43–55. Google Scholar
• 23. C. M. Francis, A. V. Borisenko, N. V. Ivanova, J. L. Eger, B. K. Lim, A. Guillen-Servent, S. V. Kruskop, I. Mackie, and P. D. N. Hebert. 2010. The role of DNA barcodes in understanding and conservation of mammal diversity in Southeast Asia. PLoS ONE, 5(9): el2575. Google Scholar
• 24. R. Hall 1998. The plate tectonics of Cenozoic SE Asia and the distribution of land and sea. Pp. 99–131, in Biogeography and geological evolution of SE Asia ( R. Hall and J. D. Holloway, eds.). Backhuys Publishers, Leiden, 417 pp. Google Scholar
• 25. R. Hall 2002. Cenozoic geological and plate tectonic evolution of SE Asia and the SW Pacific: computer-based reconstructions, model and animations. Journal of Asian Earth Sciences, 20: 353–431. Google Scholar
• 26. L. R. Heaney , and E. A. Rickart . 1990. Correlations of clades and clines: geographic, elevational, and phylogenetic distribution patterns among Philippine mammals. Pp. 321–332, in Vertebrates in the tropics ( G. Peters and R. Hutterer, eds.). Museum Alexander Koenig, Bonn, 424 pp. Google Scholar
• 27. L. R. Heaney , and T. E. Roberts . 2009. New perspectives on the long-term biogeographic dynamics and conservation of Philippine fruit bats. Pp. 17–58, in Ecology, evolution, and conservation of island bats ( T. H. Fleming and P. A. Racey, eds.). University of Chicago Press, Chicago, 560 pp. Google Scholar
• 28. L. R. Heaney , D. S. Balete , G. V. Gee , M. V. Lepiten-Tabao , E. A. Rickart , and B. R. Tabaranza JR . 2005. Preliminary report on the mammals of Balbalasang, Kalinga Province, Luzon. Sylvatrop, 13 (2003): 51–62. Google Scholar
• 29. L. R. Heaney , D. S. Balete , J. Sarmiento , and P. A. Alviola . 2006. Losing diversity and courting disaster: the mammals of Mt. Data National Park. Haring Ibon, 25: 15–23. Google Scholar
• 30. L. R. Heaney, M. L. Dolar, D. S. Balete, J. A. Esselstyn, E. A. Rickart, and J. L. Sedlock. 2010. Synopsis of Philippine mammals. Available at http://fieldmuseum.org/explore/synopsis-philippine-mammals . Google Scholar
• 31. L. R. Heaney , E. A. Rickart , D. S. Balete , M. V. Duya , M. R. M. Duya , and S. Steppan . 2011. Seven new species and a new subgenus of forest mice (Rodentia: Muridae: Apomys) from Luzon Island. Fieldiana Life and Earth Sciences, 2: 1–60. Google Scholar
• 32. K. M. Helgen , D. Kock , R. K. Salve , C. Gomez , N. R. Ingle , and M. H. Sinaga . 2007. Taxonomy and natural history of the Southeast Asian fruit-bat genus Dyacopterus. Journal of Mammalogy, 88: 302–318. Google Scholar
• 33. J. E. Hill , and D. L. Harrison . 1987. The baculum in the Vespertilioninae (Chiroptera: Vespertilionidae) with a systematic review, a synopsis of Pipistrellus and Eptesicus and the description of a new genus and subgenus. Bulletin of the British Museum (Natural History), Zoology Series, 52: 225–305. Google Scholar
• 34. N. Hollister 1913. A review of the Philippine land mammals in the United States National Museum. Proceedings of the United States National Museum, 46: 299–341. Google Scholar
• 35. S. R. Hoofer, and R. A. Van Den Bussche. 2003. Molecular phylogenetics of the chiropteran family Vespertilionidae. Acta Chiropterologica, 5 (Supplement): 1–63. Google Scholar
• 36. J. P. Huelsenbeck , and F. Ronquist . 2001. MrBAYES: Bayesian inference of phylogenetic trees. Bioinformatics Applications Note, 17: 754–755. Google Scholar
• 37. R. Hutterer , T. Ivanova , C. Meyer-Cords , and L. Rodrigues . 2005. Bat migrations in Europe. A review of banding data and literature. Federal Agency for Nature Conservation, Bonn, 162 pp. Google Scholar
• 38. C IbáñEz , J. L. García-mudarra , M. Ruedi , B. Stadelmann , and J. Juste . 2006. The Iberian contribution to cryptic diversity in European bats. Acta Chiropterologica, 8: 277–297. Google Scholar
• 39. N. R. Ingle 1993. Vertical stratification of bats in a Philippine rainforest. Asia Life Sciences, 2: 215–222. Google Scholar
• 40. N. R. Ingle 2003. Seed dispersal by wind, birds, and bats between Philippine montane rainforest and successional vegetation. Oecologia, 134: 251–261. Google Scholar
• 41. N. R. Ingle , and L. R. Heaney . 1992. A key to the bats of the Philippine Islands. Fieldiana Zoology (N.S.), 69: 1–44. Google Scholar
• 42. S. A. Jansa , F. K. Barker , and L. R. Heaney . 2006. The pattern and timing of diversification of Philippine endemic rodents: evidence from mitochondrial and nuclear gene sequences. Systematic Biology, 55: 73–88. Google Scholar
• 43. D. J. Kitchener , N. Caputi , and B. Jones . 1986. Revision of Australo-Papuan Pipistrellus and of Falsistrellus (Microchiroptera: Vespertilionidae). Records of the Western Australian Museum, 12: 435–196. Google Scholar
• 44. J. B. Lack , Z. P. Roehrs , C. E. Stanley , M. Ruedi , and R. A. Van Den Bussche . 2010. Molecular phylogenetics of Myotis indicate familial-level divergence for the genus Cistugo (Chiroptera). Journal of Mammalogy, 91: 976–992. Google Scholar
• 45. B. L. Lawrence 1939. Collections from the Philippine islands. Mammals. Bulletin of the Museum of Comparative Zoology, 86: 28–73. Google Scholar
• 46. G. S. Miller 1907. The families and genera of bats. United States National Museum Bulletin, 57: 1–282 + 14 plates. Google Scholar
• 47. A. H. G. Mitchell , F. Hernandez , and A. P. Dela Cruz . 1986. Cenozoic evolution of the Philippine Archipelago. Journal of Southeast Asian Earth Sciences, 1: 3–22. Google Scholar
• 48. J. A. A. Nylander 2004. MrModeltest v.2. Distributed by the author, Uppsala University, Sweden. Google Scholar
• 49. J. Payne , C. M. Francis , and K. Phillipps . 1985. A field guide to the mammals of Borneo. Sabah Society, Kota Kinabalu, 332 pp. Google Scholar
• 50. E. Petit, and F. Mayer. 1999. Male dispersal in the noctule bat (Nyctalus noctula): where are the limits? Proceedings of the Royal Society of London, 266B: 1717–1722. Google Scholar
• 51. E. Petit , and F. Mayer . 2000. A population genetic analysis of migration: the case of the noctule bat (Nyctalus noctula). Molecular Ecology, 9: 683–690. Google Scholar
• 52. P. J. Piper , J. Ochoa , E. Robles , H. Lewis , and V. Paz . 2011. The palaeozoology of Palawan Island, Philippines. Quaternary International, 233: 142–158. Google Scholar
• 53. A. Rambaut, and A. J. Drummond. 2009. Tracer v1.5. Available from http://beast.bio.ed.ac.uk/Tracer . Google Scholar
• 54. E. A. Rickart , J. A. Mercier , and L. R. Heaney . 1999. Cytogeography of Philippine bats. Proceedings of the Biological Society of Washington, 112: 453–469. Google Scholar
• 55. E. A. Rickart, D. S. Balete, R. J. Rowe, and L. R. Heaney. 2011a. Mammals of the northern Philippines: tolerance for habitat disturbance and resistance to invasive species in an endemic fauna. Diversity and Distributions, 17: 530–541. Google Scholar
• 56. E. A. Rickart, L. R. Heaney, D. S. Balete, and B. R. Tabaranza JR. 2011b. Small mammal diversity along an elevational gradient in northern Luzon, Philippines. Mammalian Biology, 76: 12–21. Google Scholar
• 57. T E. Roberts 2006a. History, ocean channels, and distance determine phylogeographic patterns in three widespread Philippine fruit bats (Pteropodidae). Molecular Ecology, 15: 2183–2199. Google Scholar
• 58. T E. Roberts 2006b. Multiple levels of allopatric divergence in the endemic Philippine fruit bat Haplonycteris fischeri (Pteropodidae). Biological Journal of the Linnean Society, 88: 329–349. Google Scholar
• 59. Z. P. Roehrs , J. B. Lack , and R. A. Van Den Bussche . 2010. Tribal phylogenetic relationships within Vespertilioninae (Chiroptera: Vespertilionidae) based on mitochondrial and nuclear sequence data. Journal of Mammalogy, 91: 1073–1092. Google Scholar
• 60. Z. P. Roehrs , J. B. Lack , and R. A. Van Den Bussche . 2011. A molecular phylogenetic reevaluation of the tribe Nycticeiini (Chiroptera: Vespertilionidae). Acta Chiropterologica, 13: 17–31. Google Scholar
• 61. M. Ruedi , and F. Mayer . 2001. Molecular systematics of bats of the genus Myotis (Vespertilionidae) suggests deterministic ecomorphological convergences. Molecular Phylogenetics and Evolution, 21: 436–448. Google Scholar
• 62. M. Ruedi , and G. F. Mccracken . 2009. Genetics and evolution: phylogeographic analysis of bats. Pp. 739–756, in Ecological and behavioral methods for the study of bats, 2nd edition ( T H. Kunz and S. Parsons, eds.). The Johns Hopkins University Press, Baltimore, 920 pp. Google Scholar
• 63. M. Ruedi , J. Biswas , and G. Csorba . 2012. Bats from the wet: two new species of tube-nosed bats (Chiroptera: Vespertilionidae) from Meghalaya, India. Revue Suisse de Zoologie, 119: 111–135. Google Scholar
• 64. T Sakai , Y Kikkawa , K. Tsuchiya , M. Harada , M. Kanoe , M. Yoshiyuki , and H. Yonekawa . 2003. Molecular phylogeny of Japanese Rhinolophidae based on variations in the complete sequence of the mitochondrial cytochrome b gene. Genes & Genetic Systems, 78: 179–189. Google Scholar
• 65. P. Salgueiro , M. Ruedi , M. M. Coelho , and J. M. Palmeirim . 2007. Genetic divergence and phylogeography in the genus Nyctalus (Mammalia, Chiroptera): implications for population history of the insular bat Nyctalus azoreum. Genetica, 130: 169–181. Google Scholar
• 66. P. Salgueiro , J. M. Palmeirim , M. Ruedi , and M. M. Coelho . 2008. Gene flow and population structure of the endemic Azorean bat (Nyctalus azoreum) based on microsatellites: implications for conservation. Conservation Genetics, 9: 1163–1171. Google Scholar
• 67. C. C. Sanborn 1952. Philippine Zoological Expedition 1946– 1947. Mammals. Fieldiana Zoology, 33: 89–158. Google Scholar
• 68. J. L. Sedlock , N. R. Ingle , and D. S. Balete . 2011. Enhanced sampling of bat assemblages: a field test on Mount Banahaw, Luzon. Fieldiana Life and Earth Sciences, 2: 96–102. Google Scholar
• 69. J. L. Sedlock, and S. E. Weyandt. 2009. Genetic divergence between morphologically and acoustically cryptic bats: novel niche partitioning or recent contact? Journal of Zoology (London), 279: 388–395. Google Scholar
• 70. J. L. Sedlock , S. E. Weyandt , L. Corcoran , M. Damerow , S.-H. Hwa , and B. Pauli . 2008. Bat diversity in tropical forest and agro-pastoral habitats within a protected area in the Philippines. Acta Chiropterologica, 10: 349–358. Google Scholar
• 71. N. B. Simmons 2005. Order Chiroptera. Pp. 312–529, in Mammal species of the World ( D. E. Wilson and D. M. Reeder, eds.). The Johns Hopkins University Press, Baltimore, 2142 pp. Google Scholar
• 72. B. Stadelmann, G. Herrera, J. Arroyo-Cabrales, and M. Ruedi. 2004a. Molecular systematics of the piscivorous bat Myotis (Pizonyx) vivesi. Journal of Mammalogy, 85: 133–139. Google Scholar
• 73. B. Stadelmann, D. Jacobs, C. Schoeman, and M. Ruedi. 2004b). Phylogeny of African Myotis bats (Chiroptera, Vespertilionidae) inferred from cytochrome b sequences. Acta Chiropterologica, 6: 177–192. Google Scholar
• 74. B. Stadelmann , T H. Kunz , L. K. Lin , and M. Ruedi . 2007. Molecular phylogeny of New World Myotis (Chiroptera, Vespertilionidae) inferred from mitochondrial and nuclear DNA genes. Molecular Phylogenetics and Evolution, 43: 32–48. Google Scholar
• 75. S. Steppan , C. Zawadzki , and L. R. Heaney . 2003. Molecular phylogeny of the endemic Philippine rodent Apomys and the dynamics of diversification in an oceanic archipelago. Biological Journal of the Linnean Society, 80: 699–715. Google Scholar
• 76. K. Tamura , D. Peterson , N. Peterson , G. Stecher , M. Nei , and S. Kumar . 2011. MEGA5: molecular evolutionary genetics analysis using maximum likelihood, evolutionary distance, and maximum parsimony methods. Molecular Biology and Evolution, 28: 2731–2739. Google Scholar
• 77. E. H. Taylor 1934. Philippine land mammals. Monographs of the Bureau of Science, Manila, 30: 1–548 + 25 pls. Google Scholar
• 78. A. Thabah , G. Li , Y. N. Wang , B. Liang , K. L. Hu , S. Y. Zhang , and G. Jones . 2007. Diet, echolocation calls, and phylogenetic affinities of the great evening bat (Ia io; Vespertilionidae): another carnivorous bat. Journal of Mammalogy, 88: 728–735. Google Scholar
• 79. R. G. Trujillo , J. C. Patton , D. A. Schlitter , and J. W. Bickham . 2009. Molecular phylogenetics of the bat genus Scotophilus (Chiroptera: Vespertilionidae): perspectives from paternally and maternally inherited genomes. Journal of Mammalogy, 90: 548–560. Google Scholar
• 80. M. Volleth , and K.-G. Heller . 1994. Phylogenetic relationships of vespertilionid genera (Mammalia: Chiroptera) as revealed by karyological analysis. Zeitschrift für Zoologische Systematik und Evolutionsforschung, 32: 11–34. Google Scholar
• 81. D. E. Wilson 2008. Chiroptera. Pp. 327–387, in A guide to the mammals of China ( A. T. Smith and Xie Yan, eds.). Princeton University Press, Princeton, 544 pp. Google Scholar

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