Abstract |
Bats (Chiroptera) are the least studied group of mammals in the Daurian steppe (Inner Asia: Mongolia, Russia and China). We surveyed the bat fauna of the Daurian steppe and some ecological features of bat species in 2008–2019. We recorded six bat species in this region, of which Vespertilio murinus, V. sinensis and Myotis davidii are the most abundant. Myotis davidii tended to hide in the rocks near fresh water sources. Unlike Vespertilio, М. davidii avoided settling in human constructions. Vespertilio species can live farther from water sources compared to М. davidii. The sex ratio of collected adult V. murinus, V. sinensis, M. davidii was female-based. This indicates that these species do not hibernate in the Daurian steppe region. Our results show the important role of the studied region for these migratory bat species, as it is a breeding territory. At the beginning of the XXI century, many lakes and rivers dried up partially or completely in Dauria. In the Russian part of the Daurian steppe, we observed an increase in the V. sinensis population and a decrease in the populations of M. petax and M. davidii. We speculate that the change in the bat community is a consequence of the reduction in the number of water bodies in Dauria, especially in the Mongolian part (Dornod aimag). |
References |
Adams R.A. 2010. Bat reproduction declines when conditions mimic climate change projections for western North America. Ecology 91(8): 2437–2445. DOI: 10.1890/09-0091.1 Amorim F., Jorge I., Beja P., Rebelo H. 2018. Following the water? Landscape-scale temporal changes in bat spatial distribution in relation to Mediterranean summer drought. Ecology and Evolution 8(11): 5801–5814. DOI: 10.1002/ece3.4119 Ariunbold J. 2016. Cave bat species in Mongolia. In: International Symposium of Science Museums. South Korea. P. 235–237. Bazhenov Yu.A. 2013. New data on bats in Daurian steppes. Plecotus et al. 15–16: 59–63. [In Russian] Botvinkin A.D. 2002. Bats in Baikal region (biology, observation methods, conservation). Irkutsk: Vremya stranstviy. 208 р. [In Russian] Botvinkin A.D., Ivushkin V.E., Ivushkina L.E. 2011. New findings of the porti-coloured bat in the Baikal Region. Plecotus et al. 14: 55–59. [In Russian] Boyles J., Cryan P., McCracken G., Kunz T. 2011. Economic Importance of Bats in Agriculture. Science 332(6025): 41–42. DOI: 10.1126/science.1201366 Golyatina M.A., Vakhnina I.L., Kurganovich K.A. 2018. Dynamics of the number and areas of the water surface of lakes Eastern Transbaikalia. In: Kulagin's readings: technology and technologies of production processes. Chita: Transbaikal State University. P. 120–124. [In Russian] IUCN. 2020. The IUCN Red List of Threatened Species. Version 2020-2. Available from: https://www.iucnredlist.org Kirilyuk V.E., Tkachuk T.E., Kirilyuk O.K. 2012. The influence of climate change on habitats and biota in the Dauria. In: Adaptation to climate change in the river basins of Dauria: ecology and water management. Chita: Express publishing house. P. 46–62. [In Russian] Kruskop S.V., Borissenko A.V. 1996. A new subspecies of Myotis mystacinus (Vespertilionidae, Chiroptera) from East Asia. Acta Theriologica 41(3): 331–335. DOI: 10.4098/AT.arch.96-32 Korine C., Adams R., Russo D., Fisher-Phelps M., Jacobs D. 2016. Bats and Water: Anthropogenic Alterations Threaten Global Bat Populations. In: C. Voigt, T. Kingston (Eds.): Bats in the Anthropocene: Conservation of Bats in a Changing World. Cham: Springer. P. 215–241. DOI: 10.1007/978-3-319-25220-9 Kunz T.H., Braun de Torrez E., Bauer D., Lobova T., Fleming T.H. 2011. Ecosystem services provided by bats. Annals of the New York Academy of Sciences 1223(1): 1–38. DOI: 10.1111/j.1749-6632.2011.06004.x Lundy M., Montgomery I., Russ J. 2010. Climate change-linked range expansion of Nathusius' pipistrelle bat, Pipistrellus nathusii (Keyserling & Blasius, 1839). Journal of Biogeography 37(12): 2232–2242. DOI: 10.1111/j.1365-2699.2010.02384.x Luo B., Santana S.E., Pang Y., Wang M., Xiao Y., Feng J. 2019. Wing morphology predicts geographic range size in Vespertilionid bats. Scientific Reports 9(1): 4526. DOI: 10.1038/s41598-019-41125-0 Mongolian Red Book. Ulaanbaatar: Ministry of Environment and Green Development of Mongolia, 2013. 535 p. Monhnast D. 2014. Bat Diversity and Conservation in Mongol Daguur SPA Region in the North-Eastern Mongolia. In: Proceedings of the International Conference for the 20th anniversary of the DIPA. Ulaanbaatar: Wildlife Conservation Society. P. 75–77. Nekipelov N. 1960. Distribution of mammals in Southeastern Transbaikalia and population size of some species. In: Biological Collection of Works. Irkutsk: Irkutsk State University. P. 3–48. [In Russian] Norberg U., Rayner J. 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. Series B, Biological Sciences 316: 337–419. DOI: 10.1098/rstb.1987.0030 Nyambayar B., Ariunbold J., Sukhchuluun G. 2010. A contribution to the bats inhabiting arid steppe habitats in Central Mongolia. Exploration into the Biological Resources of Mongolia 11: 329–340. Obyazov V. 2012. Climate change and the hydrological regime of rivers and lakes in the Dauria ecoregion. In: Adaptation to climate change in the river basins of Dauria: ecology and water management. Chita: Express publishing house. P. 24–45. [In Russian] Pyzhjanov S.V., Pyzhjanova M.S. 2010. Modern status of common cormorant at Baikal and Khubsugul (Mongolia). The Bulletin of Irkutsk State University. Series «Biology. Ecology» 1: 60–63. [In Russian] Pyzhjanov S.V., Pyzhjanova M.S., Tupitsyn I.I. 2016. Problem of big cormorant protection on Baikal in a view of its area natural dynamics. Proceedings of Samara Scientific Centre RAS 2: 182–185. [In Russian] R Core Team. 2020. R: a language and environment for statistical computing. Vienna, Austria: R Foundation for Statistical Computing. Available from http://www.r-project.org Razgour O., Persey M., Shamir U., Korine C. 2018. The role of climate, water and biotic interactions in shaping biodiversity patterns in arid environments across spatial scales. Diversity and Distributions 24(10): 1440–1452. DOI: 10.1111/ddi.12773 Red Data Book of Zabaikalsky Krai. Animals. Novosibirsk: Novosibirsk Publishing House, 2012. 344 p. [In Russian] Rosina V.V., Kirilyuk V.E. 2000. Finds of bats in the Daursky State Nature Reserve and in the surrounding areas. Plecotus et al. 3: 108–113. [In Russian] Sherwin H.A., Montgomery W.I., Lundy M.G. 2013. The impact and implications of climate change for bats. Mammal Review 43(3): 171–182. DOI: 10.1111/j.1365-2907.2012.00214.x Sosnina M., Kurganovich K. 2015. Assessment of lake Barun-Torey water surface changes for the period 1976–2014 using LANDSAT remote sensing data. In: Water resources and water use. Chita: Transbaikal State University. P. 23–31. [In Russian] Wu J. 2016. Detection and attribution of the effects of climate change on bat distributions over the last 50 years. Climatic Change 134(4): 681–696. DOI: 10.1007/s10584-015-1543-7 |