毛翼管鼻蝠性二型特征及其在湖北和浙江的分布新纪录
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摘要
哺乳动物的性别二态性(Sexual dimorphism)是动物中的一种普遍现象,常表现为雄性个体大于雌性个体,而在蝙蝠中则表现出雌性个体体型大于雄性的偏雌性二型现象,其具体的驱动机制仍未明确。本文对采集于广东、广西、江西、湖南、海南、湖北和浙江的32只毛翼管鼻蝠(Harpiocephalus harpia)进行头骨与翼型在两性特征上的多元统计分析,尝试探讨其性二型驱动机制。结果表明:毛翼管鼻蝠雌雄在头骨中与牙齿及咀嚼力相关的区域存在明显分化,而翼型(含翼指标和翼面积)在整体和局部特征上均无显著性差异,该结果提示雌雄可能存在食性上的分化,更倾向于"资源竞争假说"而非"大母蝠优势假说"。本研究于2017年7~10月分别在湖北(3雄,2雌)和浙江(2雄,5雌)采集12只毛翼管鼻蝠,为二省翼手目分布新纪录,该发现丰富和完善了我国翼手目分布信息。上述标本保存于广州大学华南生物多样性保护与利用重点实验室。
Sexual dimorphism is a widespread phenomenon within mammals, and males are generally lager than females. In contrast bats reveal a characteristic female-biased sexual dimorphism, females are larger than males, but its driving mechanism is still unclear. In order to explore the mechanism of sexual dimorphism within Harpiocephalus harpia, 32 specimens were sampled during bats surveys from seven sites in Guangdong, Guangxi, Jiangxi, Hunan, Hainan, Hubei and Zhejiang Provinces. All specimens were deposited in Key Laboratory of Conservation and Application in Biodiversity of South China, Guangzhou University. Through multivariate statistical analysis of craniodental and wing characteristics, we examined absolute differences and relative differences after controlling for disparities in forearm length. Significant differences between sexes were evident only in skull, in the teeth and zygomatic breadth. Comparisons of the rest of the craniodental indince, wing measurements and estimated wing areas were not siginficant. The result favors a"Resource Competition Hypothesis" rather than a"Big Mother Hypothesis". In addition, 12 specimens of H. harpia were collected from Hubei(3 males, 2 females) in July and from Zhejiang(2 males, 5 females) in August, 2017, represent new distribution records from the provinces, which adds to the accumulation of basic biological data of the rare species in China.
Sexual dimorphism is a widespread phenomenon within mammals, and males are generally lager than females. In contrast bats reveal a characteristic female-biased sexual dimorphism, females are larger than males, but its driving mechanism is still unclear. In order to explore the mechanism of sexual dimorphism within Harpiocephalus harpia, 32 specimens were sampled during bats surveys from seven sites in Guangdong, Guangxi, Jiangxi, Hunan, Hainan, Hubei and Zhejiang Provinces. All specimens were deposited in Key Laboratory of Conservation and Application in Biodiversity of South China, Guangzhou University. Through multivariate statistical analysis of craniodental and wing characteristics, we examined absolute differences and relative differences after controlling for disparities in forearm length. Significant differences between sexes were evident only in skull, in the teeth and zygomatic breadth. Comparisons of the rest of the craniodental indince, wing measurements and estimated wing areas were not siginficant. The result favors a"Resource Competition Hypothesis" rather than a"Big Mother Hypothesis". In addition, 12 specimens of H. harpia were collected from Hubei(3 males, 2 females) in July and from Zhejiang(2 males, 5 females) in August, 2017, represent new distribution records from the provinces, which adds to the accumulation of basic biological data of the rare species in China.
引文
Altringham J. 1996. Bats Biology and Behaviour. New York: Oxford University Press, 262.
Amadon D. 1959. The significance of sexual dimorphism in size among birds. Proceeding of the American Philosophical Society, 103: 531-536.
Andersson M, Lwasa Y. 1996. Sexual selection. Trends in Ecology & Evolution, 11(2): 8-53.
Bergmann C. 1847.ber die Verh?tnisse der W?rme?konomie der Thiere zu ihrer Gr?sse. G?ttinger Studien, 3(1): 595-708.
Chen B C, Yu W H, Wu Y, Li F,Xu Z X, Zhang Q P. 2015. New record and sexual dimorphism of Harpiocephalus hapia in Guangxi and Jiangxi, China. Sichuan Journal of Zoology, 34(2): 211-215. (in Chinese)
Darwin C. 1959. On the origin of species by means of natural selection, or the preservation of favored races in the struggle for life. American Anthropologist, 61(1): 176-177.
Darwin C R. 1871. The Descent of Man and Selection in Relation to Sex. John Murray, London.
Das P K. 1986. Taxonomic status of Harpiocephalus harpia madrassius Thomas 1923 (Chiroptera, Vespertilionidae) with comments on other described forms under the genus Harpiocephalus Gray 1842. The Journal of the Bombay Natural History Society, 83: 311-316.
Earhart C M, Johnson N K. 1970.Size dimorphism and food habits of north American Owls. Condor, 72(3): 251-264.
Flanders J,Inouemurayama M, Rossiter S J, Hill D A. 2016. Female philopatry and limited male-biased dispersal in the Ussuri tube-nosed bat, Murina ussuriensis. J Mammalogy, 97(2): 545-553.
Freeman P W. 1998.Form, function, and evolution in skulls and teeth of bats. In: Kunz T H ed. Bat Biology and Conservation. Washington D C: Smithsonian Institution Press, 140-156.
Gong L X,Gu H, Sun C N, Ma Q, Jiang T L, Feng J. 2018. Two new records of the Chiroptera in Guizhou Province (China) and their echolocation calls. Chinese Journal of Zoology, 53(3): 329-338. (in Chinese)
Heiberger R M. 2018. HH: Statistical Analysis and Data Display: Heiberger and Holland. R package version 3.1-35. URL: https://cran.r-project.org/package=HH.
Husar S L. 1976. Behavioral character displacement: evidence of food partitioning in insectivorous bats. Journal of Mammalogy, 57(2): 331-338.
Hu Y F, Li F, Wu Y, Li Y C, Yu W H. 2018.New record of Harpiocephalus harpia in Hainan Province. Journal of Zhejiang Forestry Science and Technology, 38(3): 85-88. (in Chinese)
Jiang Z G, Ma Y, Wu Y, Wang Y X, Zhou K Y, Liu S Y,Feng Z J, Li L L. 2015. China’s Mammal Diversity and Geographic Distribution. Beijing: Science Press. (in Chinese)
Kuo H C, Chen S F, Rossiter S J. 2013. Development and characterisation of microsatellite loci for Murina gracilis (Vespertilionidae) and cross-species amplification in two other congeneric species. Conservation Genetics Resources, 5(4): 1-4.
Kuo H C, Chen S F, Fang Y P, Cotton J A, Parker J D, Csorba G, Lim B K, Eger J L, Chen C H, Chou C H, Rossiter S J. 2015. Speciation processes in putative island endemic sister bat species: false impressions from mitochondrial DNA and microsatellite data. Molecular Ecology, 24(23): 5910-5926.
Lin L K, Harada M,Motokawa M. 2006. Updating the occurrence of Harpiocephalus harpia (Chiroptera: Vespertilionidae) and its karyology in Taiwan. Mammalia, 70(1/2): 170-172.
Matveev V A. 2005. Checklist of Cambodian bats (Chiroptera), with new records and remarks on taxonomy. Russian Journal of Theriology, 4(1): 43-62.
Norberg U M. 1998. Morphological adaptations for flight in bats. In: Kunz T H, Racey P A eds.Bat Biology and Conservation. Washington D C: Smithsonian Institution Press, 93-108.
Norberg U M, Rayner J M V. 1987. Ecological morphology and flight in bats (Mammalia; Chiroptera): wing adaptations, flight performance, foraging strategy and echolocation. Philosophical Transactions of the Royal Society of London, 316(1179): 335-427.
Pincheiradonoso D, Hunt J. 2015. Fecundity selection theory: concepts and evidence. Biological Reviews, 92(1): 341-356.
Ralls K. 1976.Mammals in which females are larger than males. Quarterly Review of Biology, 51(2): 245-276.
R Development Core Team. 2010. R: A language and environment for statistical computing, R Foundation for Statistical Computing, Vienna, Austria. ISBN 3-900051-07-0.Available: http://www.R-project.org.
Rensch B. 1950. Die Abhngigkeit der relativen Sexualdifferenz von der K?rpegre. Bonner zoologische Beitrge: Herausgeber: Zoologisches Forschungsinstitut und Museum Alexander Koenig, Bonn, 1: 58-69.
Revelle W. 2012. Psych: Procedures for Personality and Psychological Research. Evanston: Northwestern University. Available: http://cran.r-project.org/web/packages/psych.
Sand H,Cederlund G, Danell K. 1995. Geographical and latitudinal variation in growth patterns and adult body size of swedish moose (Alces alces). Oecologia, 102(4): 433.
Schoener T W. 1967. The ecological significance of sexual dimorphism in size in the Lizard Anolis conspersus. Science, 155(3761): 474.
Selander R K. 1966. Sexual dimorphism and differential niche utilization in Birds. Condor, 68(2): 113-151.
Sheng H L. 2005.Atlas of Mammals of China. Zhengzhou: Henan Science and Technology Publishing House, 140-142. (in Chinese)
Shine R. 1989. Ecological causes for the evolution of sexual dimorphism: a review of the evidence.Quarterly Review of Biology, 64(4): 419-461.
Simmons N B. 2005. Order Chiroptera.In: Wilson D E, Reeder D M eds. Mammal Species of the World: A Taxonomic and Geographic Reference, 3rd edn.The Johns Hopkins University Press, Baltimore, 312-529.
Stevens R D, Johnson M E,Mcculloch E S. 2013. Absolute and relative secondary-sexual dimorphism in wing morphology: a multivariate test of the ‘Big Mother’ Hypothesis. Acta Chiropterologica, 15(1): 163-170.
Stevens R D, Platt R N. 2015. Patterns of secondary sexual size dimorphism in new world Myotis and a test of Rensch’s rule. Journal of Mammalogy, 96(6): 1128-1134.
Ulian C M V, Rossi M N. 2017. Intraspecific variation in body size and sexual size dimorphism, and a test of Rensch’s rule in bats. Acta Zoologica, 98(4): 377-386.
VanValkenburgh B. 2007. Déjà vu: the evolution of feeding morphologies in the Carnivora. Integrative and Comparative Biology, 47: 147-163.
Wang Y X. 2003.A Complete Checklist of Mammal Species and Subspecies in China a Taxonomic and Geographic Reference. Beijing: China Forestry Publishing House. (in Chinese)
Wu H, Jiang T L, Huang X B, Lin H J, Wang H W, Wang L, Niu H X, Feng J. 2014. A test of Rensch’s rule in greater horseshoe bat (Rhinolophus ferrumequinum) with female-biased sexual size dimorphism. PLoS ONE, 9(1): e86085.
Wu H, Jiang T L,Feng J. 2014. Sexual size dimorphism in animals and the relative research in bats. Acta Theriologica Sinica, 34(3): 313-322. (in Chinese)
Wu H, Jiang T L, Huang X B,Feng J. 2018. Patterns of sexual size dimorphism in horseshoe bats: testing Rensch’s rule and potential causes. Scientific Rep, 8(1): 2616.
Yang Q S, Xia L,Feng Z J, Ma Y, Quan G Q, Wu Y. 2007. A guide to the measurement of Mammal Skull Ⅴ: Insectivora and Chiroptera. Chinese Journal of Zoology, 42(2): 56-62. (in Chinese)
Yu W H, Hu Y F,Guo W J, Li F, Wang X Y, Li Y C, Wu Y. 2017. New discovery of Harpiocephalus harpia in Hunan Province and its potential distribution area in China. Journal of Guangzhou University (Natural Science Edition), 16(3): 16-20. (in Chinese)
Zheng X Q. 2010. A Photographic Guide to the Bats of Taiwan. Taiwan: Endemic Species Research Institude, C. O. A. Press, 98-99. (in Chinese)
Zhou Q,Xu Z X, Yu W H, Li F, Chen B C, Gong Y N, Harada M, Motokawa M, Li Y C, Wu Y. 2014. The occurrence of bat Harpiocephalus harpia from Nanlin, Guangdong and its karyotypes, echolocation calls. Chinese Journal of Zoology, 49(1): 41-45. (in Chinese)
Smith A T,解焱. 2009. 中国兽类野外手册. 长沙: 湖南教育出版社, 352.
王应祥. 2003. 中国哺乳动物种和亚种分类名录与分布大全. 北京: 中国林业出版社, 59.
杨奇森, 夏霖, 冯祚建, 马勇, 全国强, 吴毅. 2007. 兽类头骨测量标准Ⅴ: 食虫目、翼手目. 动物学杂志, 42(2): 56-62.
吴慧, 江廷磊, 冯江. 2014. 蝙蝠体型性别二态性研究现状与展望. 兽类学报, 34(3): 313-322.
余文华, 胡宜锋, 郭伟健, 黎舫, 王晓云, 李玉春, 吴毅. 2017. 毛翼管鼻蝠在湖南的新发现及中国适生分布区预测. 广州大学学报(自然科学版), 16(3): 16-20.
陈柏承, 余文华, 吴毅, 李锋, 徐忠鲜, 张秋萍, 原田正史, 本川雅治, 彭红元, 王英永, 李玉春. 2015. 毛翼管鼻蝠在广西和江西分布新纪录及其性二型现象. 四川动物, 34(2): 211-215.
周全, 徐忠鲜, 余文华, 李锋, 陈柏承, 龚粤宁, 原田正史, 本川雅治, 李玉春, 吴毅. 2014. 广东省南岭发现毛翼管鼻蝠及其核型与回声定位声波特征. 动物学杂志, 49(1): 41-45.
郑锡奇.2010.台湾蝙蝠图鉴.台湾:农业委员会特有生物研究保育中心.98-99.
胡宜峰, 黎舫, 吴毅, 李玉春, 余文华. 2018. 海南省蝙蝠新记录——毛翼管鼻蝠. 浙江林业科技, 38(3): 85-88.
龚立新, 顾浩, 孙淙南, 马青, 江廷磊, 冯江. 2018. 贵州发现毛翼管鼻蝠和华南菊头蝠及其回声定位声波特征. 动物学杂志, 53(3): 329-338.
盛和林. 2005. 中国哺乳动物图鉴. 郑州: 河南科学技术出版社, 140-142.
蒋志刚, 马勇, 吴毅, 王应祥, 周开亚, 刘少英, 冯祚建, 李立立. 2015. 中国哺乳动物多样性及地理分布. 北京: 科学出版社, 136.
Amadon D. 1959. The significance of sexual dimorphism in size among birds. Proceeding of the American Philosophical Society, 103: 531-536.
Andersson M, Lwasa Y. 1996. Sexual selection. Trends in Ecology & Evolution, 11(2): 8-53.
Bergmann C. 1847.ber die Verh?tnisse der W?rme?konomie der Thiere zu ihrer Gr?sse. G?ttinger Studien, 3(1): 595-708.
Chen B C, Yu W H, Wu Y, Li F,Xu Z X, Zhang Q P. 2015. New record and sexual dimorphism of Harpiocephalus hapia in Guangxi and Jiangxi, China. Sichuan Journal of Zoology, 34(2): 211-215. (in Chinese)
Darwin C. 1959. On the origin of species by means of natural selection, or the preservation of favored races in the struggle for life. American Anthropologist, 61(1): 176-177.
Darwin C R. 1871. The Descent of Man and Selection in Relation to Sex. John Murray, London.
Das P K. 1986. Taxonomic status of Harpiocephalus harpia madrassius Thomas 1923 (Chiroptera, Vespertilionidae) with comments on other described forms under the genus Harpiocephalus Gray 1842. The Journal of the Bombay Natural History Society, 83: 311-316.
Earhart C M, Johnson N K. 1970.Size dimorphism and food habits of north American Owls. Condor, 72(3): 251-264.
Flanders J,Inouemurayama M, Rossiter S J, Hill D A. 2016. Female philopatry and limited male-biased dispersal in the Ussuri tube-nosed bat, Murina ussuriensis. J Mammalogy, 97(2): 545-553.
Freeman P W. 1998.Form, function, and evolution in skulls and teeth of bats. In: Kunz T H ed. Bat Biology and Conservation. Washington D C: Smithsonian Institution Press, 140-156.
Gong L X,Gu H, Sun C N, Ma Q, Jiang T L, Feng J. 2018. Two new records of the Chiroptera in Guizhou Province (China) and their echolocation calls. Chinese Journal of Zoology, 53(3): 329-338. (in Chinese)
Heiberger R M. 2018. HH: Statistical Analysis and Data Display: Heiberger and Holland. R package version 3.1-35. URL: https://cran.r-project.org/package=HH.
Husar S L. 1976. Behavioral character displacement: evidence of food partitioning in insectivorous bats. Journal of Mammalogy, 57(2): 331-338.
Hu Y F, Li F, Wu Y, Li Y C, Yu W H. 2018.New record of Harpiocephalus harpia in Hainan Province. Journal of Zhejiang Forestry Science and Technology, 38(3): 85-88. (in Chinese)
Jiang Z G, Ma Y, Wu Y, Wang Y X, Zhou K Y, Liu S Y,Feng Z J, Li L L. 2015. China’s Mammal Diversity and Geographic Distribution. Beijing: Science Press. (in Chinese)
Kuo H C, Chen S F, Rossiter S J. 2013. Development and characterisation of microsatellite loci for Murina gracilis (Vespertilionidae) and cross-species amplification in two other congeneric species. Conservation Genetics Resources, 5(4): 1-4.
Kuo H C, Chen S F, Fang Y P, Cotton J A, Parker J D, Csorba G, Lim B K, Eger J L, Chen C H, Chou C H, Rossiter S J. 2015. Speciation processes in putative island endemic sister bat species: false impressions from mitochondrial DNA and microsatellite data. Molecular Ecology, 24(23): 5910-5926.
Lin L K, Harada M,Motokawa M. 2006. Updating the occurrence of Harpiocephalus harpia (Chiroptera: Vespertilionidae) and its karyology in Taiwan. Mammalia, 70(1/2): 170-172.
Matveev V A. 2005. Checklist of Cambodian bats (Chiroptera), with new records and remarks on taxonomy. Russian Journal of Theriology, 4(1): 43-62.
Norberg U M. 1998. Morphological adaptations for flight in bats. In: Kunz T H, Racey P A eds.Bat Biology and Conservation. Washington D C: Smithsonian Institution Press, 93-108.
Norberg U M, Rayner J M V. 1987. Ecological morphology and flight in bats (Mammalia; Chiroptera): wing adaptations, flight performance, foraging strategy and echolocation. Philosophical Transactions of the Royal Society of London, 316(1179): 335-427.
Pincheiradonoso D, Hunt J. 2015. Fecundity selection theory: concepts and evidence. Biological Reviews, 92(1): 341-356.
Ralls K. 1976.Mammals in which females are larger than males. Quarterly Review of Biology, 51(2): 245-276.
R Development Core Team. 2010. R: A language and environment for statistical computing, R Foundation for Statistical Computing, Vienna, Austria. ISBN 3-900051-07-0.Available: http://www.R-project.org.
Rensch B. 1950. Die Abhngigkeit der relativen Sexualdifferenz von der K?rpegre. Bonner zoologische Beitrge: Herausgeber: Zoologisches Forschungsinstitut und Museum Alexander Koenig, Bonn, 1: 58-69.
Revelle W. 2012. Psych: Procedures for Personality and Psychological Research. Evanston: Northwestern University. Available: http://cran.r-project.org/web/packages/psych.
Sand H,Cederlund G, Danell K. 1995. Geographical and latitudinal variation in growth patterns and adult body size of swedish moose (Alces alces). Oecologia, 102(4): 433.
Schoener T W. 1967. The ecological significance of sexual dimorphism in size in the Lizard Anolis conspersus. Science, 155(3761): 474.
Selander R K. 1966. Sexual dimorphism and differential niche utilization in Birds. Condor, 68(2): 113-151.
Sheng H L. 2005.Atlas of Mammals of China. Zhengzhou: Henan Science and Technology Publishing House, 140-142. (in Chinese)
Shine R. 1989. Ecological causes for the evolution of sexual dimorphism: a review of the evidence.Quarterly Review of Biology, 64(4): 419-461.
Simmons N B. 2005. Order Chiroptera.In: Wilson D E, Reeder D M eds. Mammal Species of the World: A Taxonomic and Geographic Reference, 3rd edn.The Johns Hopkins University Press, Baltimore, 312-529.
Stevens R D, Johnson M E,Mcculloch E S. 2013. Absolute and relative secondary-sexual dimorphism in wing morphology: a multivariate test of the ‘Big Mother’ Hypothesis. Acta Chiropterologica, 15(1): 163-170.
Stevens R D, Platt R N. 2015. Patterns of secondary sexual size dimorphism in new world Myotis and a test of Rensch’s rule. Journal of Mammalogy, 96(6): 1128-1134.
Ulian C M V, Rossi M N. 2017. Intraspecific variation in body size and sexual size dimorphism, and a test of Rensch’s rule in bats. Acta Zoologica, 98(4): 377-386.
VanValkenburgh B. 2007. Déjà vu: the evolution of feeding morphologies in the Carnivora. Integrative and Comparative Biology, 47: 147-163.
Wang Y X. 2003.A Complete Checklist of Mammal Species and Subspecies in China a Taxonomic and Geographic Reference. Beijing: China Forestry Publishing House. (in Chinese)
Wu H, Jiang T L, Huang X B, Lin H J, Wang H W, Wang L, Niu H X, Feng J. 2014. A test of Rensch’s rule in greater horseshoe bat (Rhinolophus ferrumequinum) with female-biased sexual size dimorphism. PLoS ONE, 9(1): e86085.
Wu H, Jiang T L,Feng J. 2014. Sexual size dimorphism in animals and the relative research in bats. Acta Theriologica Sinica, 34(3): 313-322. (in Chinese)
Wu H, Jiang T L, Huang X B,Feng J. 2018. Patterns of sexual size dimorphism in horseshoe bats: testing Rensch’s rule and potential causes. Scientific Rep, 8(1): 2616.
Yang Q S, Xia L,Feng Z J, Ma Y, Quan G Q, Wu Y. 2007. A guide to the measurement of Mammal Skull Ⅴ: Insectivora and Chiroptera. Chinese Journal of Zoology, 42(2): 56-62. (in Chinese)
Yu W H, Hu Y F,Guo W J, Li F, Wang X Y, Li Y C, Wu Y. 2017. New discovery of Harpiocephalus harpia in Hunan Province and its potential distribution area in China. Journal of Guangzhou University (Natural Science Edition), 16(3): 16-20. (in Chinese)
Zheng X Q. 2010. A Photographic Guide to the Bats of Taiwan. Taiwan: Endemic Species Research Institude, C. O. A. Press, 98-99. (in Chinese)
Zhou Q,Xu Z X, Yu W H, Li F, Chen B C, Gong Y N, Harada M, Motokawa M, Li Y C, Wu Y. 2014. The occurrence of bat Harpiocephalus harpia from Nanlin, Guangdong and its karyotypes, echolocation calls. Chinese Journal of Zoology, 49(1): 41-45. (in Chinese)
Smith A T,解焱. 2009. 中国兽类野外手册. 长沙: 湖南教育出版社, 352.
王应祥. 2003. 中国哺乳动物种和亚种分类名录与分布大全. 北京: 中国林业出版社, 59.
杨奇森, 夏霖, 冯祚建, 马勇, 全国强, 吴毅. 2007. 兽类头骨测量标准Ⅴ: 食虫目、翼手目. 动物学杂志, 42(2): 56-62.
吴慧, 江廷磊, 冯江. 2014. 蝙蝠体型性别二态性研究现状与展望. 兽类学报, 34(3): 313-322.
余文华, 胡宜锋, 郭伟健, 黎舫, 王晓云, 李玉春, 吴毅. 2017. 毛翼管鼻蝠在湖南的新发现及中国适生分布区预测. 广州大学学报(自然科学版), 16(3): 16-20.
陈柏承, 余文华, 吴毅, 李锋, 徐忠鲜, 张秋萍, 原田正史, 本川雅治, 彭红元, 王英永, 李玉春. 2015. 毛翼管鼻蝠在广西和江西分布新纪录及其性二型现象. 四川动物, 34(2): 211-215.
周全, 徐忠鲜, 余文华, 李锋, 陈柏承, 龚粤宁, 原田正史, 本川雅治, 李玉春, 吴毅. 2014. 广东省南岭发现毛翼管鼻蝠及其核型与回声定位声波特征. 动物学杂志, 49(1): 41-45.
郑锡奇.2010.台湾蝙蝠图鉴.台湾:农业委员会特有生物研究保育中心.98-99.
胡宜峰, 黎舫, 吴毅, 李玉春, 余文华. 2018. 海南省蝙蝠新记录——毛翼管鼻蝠. 浙江林业科技, 38(3): 85-88.
龚立新, 顾浩, 孙淙南, 马青, 江廷磊, 冯江. 2018. 贵州发现毛翼管鼻蝠和华南菊头蝠及其回声定位声波特征. 动物学杂志, 53(3): 329-338.
盛和林. 2005. 中国哺乳动物图鉴. 郑州: 河南科学技术出版社, 140-142.
蒋志刚, 马勇, 吴毅, 王应祥, 周开亚, 刘少英, 冯祚建, 李立立. 2015. 中国哺乳动物多样性及地理分布. 北京: 科学出版社, 136.