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2010 | 12 | 2 |
Tytuł artykułu

Karyotypic variation in rhinolophid and hipposiderid bats (Chiroptera: Rhinolophidae, Hipposideridae)

Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
According to current phylogenetic hypotheses, the bats of the families Rhinolophidae and Hipposideridae are sister groups nested within the clade of Pteropodiformes. A conservative nature of karyotypic evolution was previously reported within the two families. Karyotypes with diploid number (2n) varying between 58 and 62 chromosomes were assumed to prevail among the rhinolophid species, whereas, karyotypes with 32 chromosomes were found in most of the hipposiderid bats. However, divergent lower or higher 2n numbers have been recorded in some species in both families. Variation is documented in the present paper by examination of non-differentially stained karyotypes in 10 species belonging to genera Rhinolophus and Hipposideros from western Africa and southern India. Among the species studied, the karyotypes with a 2n of 32, 36, 52, 56, 58, and 62, and with relatively stable number of autosomal arms (FNa = 60, 62, 64) were recorded.
Słowa kluczowe
Wydawca
-
Rocznik
Tom
12
Numer
2
Opis fizyczny
p.393-400,ref.
Twórcy
autor
  • Department of Zoology, Faculty of Science, Charles University, Viničná 7, CZ-12844 Praha 2, Czech Republic
  • Department of Applied Zoology, Mangalore University, Mangalagangotri -574 199, Karnataka, India
autor
  • Institute of Vertebrate Biology, Academy of Sciences, Květná 8, CZ-60365 Brno, Czech Republic
autor
  • Institute of Vertebrate Biology, Academy of Sciences, Květná 8, CZ-60365 Brno, Czech Republic
Bibliografia
  • 1. K. Ando , and T. A. Uchida . 1974. Karyotype analysis in Chiroptera. II. Phylogenetic relationships in the genus Rhinolophus. Scientific Bulletin of the Faculty of Agriculture, Kyushu University, 28: 119–129. Google Scholar
  • 2. K. Ando , T. Tagawa , and T. A. Uchida . 1980. Karyotypes of Taiwanese and Japanese bats belonging to the families Rhinolophidae and Hipposideridae. Cytologia, 45: 423–432. Google Scholar
  • 3. K. Ando , F. Yasuzumi , T. Tagawa , and T. A. Uchida . 1983. Further study on the karyotypic evolution in the genus Rhinolophus (Mammalia: Chiroptera). Caryologia, 36: 101–111. Google Scholar
  • 4. L. Ao , X. G. Mao, W. H. Nie , X. M. Gu , Q. Feng , J. H. Wang , W. T. Su , Y. X. Wang , M. Volleth , and F. Yang . 2007. Karyotypic evolution and phylogenetic relationships in the order Chiroptera as revealed by G-banding comparison and chromosome painting. Chromosome Research, 15: 257–267. Google Scholar
  • 5. R. J. Baker 1970. Karyotypic trends in bats. Pp. 65–96, in Biology of bats ( W. A. Wimsatt , ed. ). Academic Press, New York, 1: xii + 406 pp. Google Scholar
  • 6. P. J. J. Bates , and D. L. Harrison . 1997. Bats of Indian subcontinent. Harrison Zoological Museum, Sevenoaks, Kent, xiv + 268 pp . Google Scholar
  • 7. W. Bogdanowicz 1992. Phenetic relationships among bats of the family Rhinolophidae. Acta Theriologica, 37: 213–240. Google Scholar
  • 8. W. Bogdanowicz , and R. D. Owen . 1998. In the Minotaur's labyrinth: the phylogeny of the bat family Hipposideridae. Pp. 27–42, in Bats: phylogeny, morphology, echolocation, and conservation biology ( T. H. Kunz and P. A. Racey , eds. ). Smithsonian Institution Press, Washington, D.C., xiv + 365 pp. Google Scholar
  • 9. R. C. Choudhury , and C. Patro . 1993. Karyotypic characteristics of an Indian microchiroptera Hipposideros fulvus pallidus Anderson. Asian Journal of Experimental Sciences, 7: 19–23. Google Scholar
  • 10. G. B. Corbet , and J. E. Hill . 1992. The mammals of Indo-Malayan region. A systematic review. Oxford University Press, London, 243 pp. Google Scholar
  • 11. G. Csorba , P. Ujhelyi , and N. Thomas . 2003. Horseshoe bats of the World. Alana Books, Shropshire, xxxii +160 pp . Google Scholar
  • 12. B. Đulić 1980/1981. Chromosomes of three species of Indian Microchiroptera. Myotis, 18/19: 76–82. Google Scholar
  • 13. B. Đulić , and F. A. Mutere . 1974. The chromosomes of two bats from East Africa: Rhinolophus clivosus Cretzschmar, 1828 and Hipposideros caffer (Sundevall, 1846). Periodicum Biologorum, 76: 31–34. Google Scholar
  • 14. B. Đulić , and F. A. Mutere . 1977. Chromosomes of some East African bats. Säugetierkundliche Mitteilungen, 25: 231–233. Google Scholar
  • 15. X. M. Gu 2002a. A study on the karyotype, G-bands and C-bands of Hipposideros armiger. Journal of Guizhou Normal University (Natural Science), 3: 9–11. Google Scholar
  • 16. X. M. Gu 2002b. The karyotype analysis of Hipposideros armiger. Chinese Journal of Zoology, 37: 19–21. Google Scholar
  • 17. X. M. Gu 2006. The karyotypes of six species of bats from Guizhou. Chinese Journal of Zoology, 41: 112–116. Google Scholar
  • 18. X. M. Gu , Y. Y. Tu , D. C. Jiang , H. J. Yang , and Y. Wang . 2003. Karyotypic analysis of five Rhinolophus species from Guizhou. Chinese Journal of Zoology, 38: 18–22. [In Chinese with English summary]. Google Scholar
  • 19. S. M. Handa , and S. Kaur . 1980. Chromosome studies on three species of Hipposideros (Hipposideridae: Chiroptera). Caryologia, 33: 537–549. Google Scholar
  • 20. M. Harada 1973. Chromosomes of nine Chiropteran species in Japan (Chiroptera). La Chromosomo, 91: 2885–2895. [In Japanese with English summary]. Google Scholar
  • 21. M. Harada , and T. Kobayashi . 1980. Studies on the small mammal fauna of Sabah, East Malaysia II. Karyological analysis of some Sabahan mammals (Primates, Rodentia, Chiroptera). Contributions from the Biological Laboratory, Kyoto University, 26: 83–95. Google Scholar
  • 22. M. Harada , M. Minezawa , S. Takada , S. Yenbutra , P. Nunpakdee , and S. Ohtani . 1982. Karyological analysis of 12 species of bats from Thailand. Caryologia, 35: 269–278. Google Scholar
  • 23. M. Harada , S. Yenbutra , T. Yoshida , and S. Takada . 1985a. Cytogenetical study of Rhinolophus bats (Chiroptera, Mammalia) from Thailand. Proceedings of the Japanese Academy, 61: 455–458. Google Scholar
  • 24. M. Harada , S. Yenbutra , K. Tsuchiya , and S. Takada . 1985b. Karyotypes of seven species of bats from Thailand (Chiroptera: Mammalia). Experientia, 41: 1610–1611. Google Scholar
  • 25. C. S. Hood , D. A. Schlitter , J. L. Georgudaki , S. Yenbutra , and R. J. Baker . 1988. Chromosomal studies of bats (Mammalia: Chiroptera) from Thailand. Annals of Carnegie Museum, 57: 99–109. Google Scholar
  • 26. T. C. Hsu , and K. Benirschke . 1967–1977. An atlas of mammalian chromosomes, Volumes 1–10. Springer Verlag, Berlin. Google Scholar
  • 27. J. M. Hutcheon , and J. A. W. Kirsch . 2006. A moveable face: deconstructing Microchiroptera and a new classification of extant bats. Acta Chiropterologica, 8: 1–10. Google Scholar
  • 28. G. Jones , and E. C. Teeling . 2006. The evolution of echolocation in bats. Trends in Ecology and Evolution, 21: 149–156. Google Scholar
  • 29. A. Karataş , M. Sözen , and F. Matur . 2006. Karyology of some bat species (Chiroptera: Rhinolophidae, Molossidae) from Turkey. Mammalian Biology, 71: 159–163. Google Scholar
  • 30. J. Kingdon 1997. The Kingdon field guide to African mammals. A&C Black Publishers, London, 450 pp. Google Scholar
  • 31. X. Mao , W. Nie , J. Wang , W. Su , L. Ao , Q. Feng , Y. Wang , M. Volleth , and F. Yang . 2007. Karyotype evolution in Rhinolophus bats (Rhinolophidae, Chiroptera) illuminated by cross-species chromosome painting and G-banding comparison. Chromosome Research, 15: 835–847. Google Scholar
  • 32. K. N. Naidu , and M. E. Gururaj . 1984. Karyotypes of Rhinolophus luctus (ord: Chiroptera). Current Science, 53: 825–826. Google Scholar
  • 33. R. L. Peterson , and D. W. Nagorsen . 1975. Chromosomes of fifteen species of bats (Chiroptera) from Kenya and Rhodesia. Life Sciences Occasional Papers, Royal Ontario Museum, 27: 1–14. Google Scholar
  • 34. E. Puerma , M. J. Acosta , M. J. L. Barragán , S. Martínez , J. A. Marchal , M. Bullejos , and A. Sánchez . 2008. The karyotype and 5S rRNA genes from Spanish individuals of the bat species Rhinolophus hipposideros (Rhinolophidae: Chiroptera). Genetica, 134: 287–295. Google Scholar
  • 35. M. B. Qumsiyeh , D. A. Schlitter , and A. M. Disi . 1986. New records and karyotypes of small mammals from Jordan. Zeitschrift für Säugetierkunde, 51: 139–146. Google Scholar
  • 36. I. L. Rautenbach 1986. Karyotypical variation in Southern African Rhinolophidae (Chiroptera) and non-geographic morphometric variation in Rhinolophus denti Thomas, 1904. Cimbebasia, 8A: 129–139. Google Scholar
  • 37. I. L. Rautenbach , G. N. Bronner , and D. A. Schlitter . 1993. Karyotypic data and attendant systematic implications for the bats of southern Africa. Koedoe, 36: 87–104. Google Scholar
  • 38. S. P. Ray-Chaudhuri , and S. Pathak . 1966. Studies on the chromosomes of bats: list of worked out Indian species of Chiroptera. Mammalian Chromosome Newsletter, 22: 206. Google Scholar
  • 39. S. P. Ray-Chaudhuri , S. Pathak , and T. Sharma . 1971. Karyotypes of five Indian species of Microchiroptera. Caryologia, 24: 239–245. Google Scholar
  • 40. E. A. Rickart , J. A. Mercier , and L. R. Heaney . 1999. Cytogeography of Philippine bats (Mammalia: Chiroptera). Proceedings of the Biological Society of Washington, 112: 453–169. Google Scholar
  • 41. D. R. Rosevear 1965. The bats of West Africa. British Museum of Natural History London, 418 pp. Google Scholar
  • 42. M. Sasaki , and K. Hattori . 1970. Karyotypes of three species of bats. Mammalian Chromosome Newsletter, 11: 22–24. Google Scholar
  • 43. N. B. Simmons 2005. Order Chiroptera. Pp. 312–529, in Mammal species of the World: a taxonomic and geographic reference, 3rd edition ( D. E. Wilson and D. M. Reeder , eds. ). The Johns Hopkins University Press, Baltimore, 2142 pp. Google Scholar
  • 44. K. S. Sreepada , K. N. Naidu , and M. E. Gururaj . 1993. Trends of karyotypic evolution in the genus Hipposideros (Chiroptera: Mammalia). Cytobios, 75: 49–57. Google Scholar
  • 45. E. C. Teeling , M. S. Springer , O. Madsen , P. Bates , S. J. O'Brien , and W. J. Murphy . 2005. A molecular phylogeny for bats illuminates biogeography and the fossil record. Science, 307: 580–584. Google Scholar
  • 46. G. Topál , and G. Csorba . 1992. The subspecific division of Rhinolophus luctus Temminck, 1835, and the taxonomic status of R. beddomei Andersen, 1905 (Mammalia, Chiroptera). Miscellanea Zoologica Hungarica, 7: 101–116. Google Scholar
  • 47. K. Tsuchiya 1971. Chromosomes of two insectivorous bat species from Japan (Chiroptera). Journal of the Mammalogical Society of Japan, 5: 114–116. Google Scholar
  • 48. P. Vallo , A. Guillén-Servent , P. Benda , D. B. Pires , and P. Koubek . 2008. Variation of mitochondrial DNA in the Hipposideros caffer complex (Chiroptera: Hipposideridae) and its taxonomic implications. Acta Chiropterologica, 10: 193–206. Google Scholar
  • 49. V. Van Cakenberghe , and E. C. J. Seamark (eds.). 2009. African Chiroptera report 2009. African Chiroptera Project, Pretoria, 2976 pp. http://www.africabats.org Google Scholar
  • 50. M. Volleth , K.-G. Heller , R. A. Pfeiffer , and H. Hameister . 2002. A comparative ZOO-FISH analysis in bats elucidates the phylogenetic relationships between Megachiroptera and five Microchiroptera families. Chromosome Research, 10: 477–497. Google Scholar
  • 51. Y. Wu , and M. Harada . 2005. Karyology of five species of the Rhinolophus (Chiroptera: Rhinolophidae) from Guangdong, China. Acta Theriologica Sinica, 25: 163–167. Google Scholar
  • 52. Y. Wu , and M. Harada . 2006. Karyology of seven species of bats (Mammalia: Chiroptera) from Guangdong, China. Acta Theriologica Sinica, 26: 403–406. Google Scholar
  • 53. Y. Wu , M. Harada , and Y. Li . 2004. Karyology of seven species bats from Sichuan, China. Acta Theriologica Sinica, 24: 30–35. Google Scholar
  • 54. Y. Wu , H. Y. Shi , H. Liu , and M. Harada . 2006. Further study on karyology of bats (Mammalia: Chiroptera) from Sichuan, China. Journal of Guangzhou University (Natural Science Edition), 5: 20–24. Google Scholar
  • 55. M. Yoshiyuki , and M. Harada . 1995. Taxonomic status of Rhinolophus formosae Sandborn, 1939 (Mammalia, Chiroptera, Rhinolophidae) from Taiwan. Special Bulletin of the Japanese Society of Coleopterology, Tokyo, 4: 497–504. Google Scholar
  • 56. W. Zhang 1985. A study on the karyotypes in four species of bats (Rhinolophus). Acta Theriologica Sinica, 5: 95–101. Google Scholar
  • 57. W. Zhang , and M. Wan . 1992. Chromosomal analysis of Taphozous melanopogon and Hipposideros armiger. Acta Theriologica Sinica, 12: 306–307. Google Scholar
  • 58. J. Zima , M. Volleth , I. Horáček , J. Červený , A. Červená , K. Průcha , and M. Macholán . 1992. Comparative karyology of rhinolophid bats (Chiroptera: Rhinolophidae). Pp. 229–236, in Prague studies in mammalogy ( I. Horáček and V. Vohralík , eds. ). Charles University Press, Praha, xxii + 245 pp. Google Scholar
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