[1].Distribution and Movement Tendencies of Short-Tailed Viper Snakes (Gloydius saxatilis) by Altitude[J].Asian Herpetological Research,2017,8(1):39-47.[doi:10.16373/j.cnki.ahr.160126]
 Min Seock DO#,Ki-Baek NAM# and Jeong-Chil YOO*.Distribution and Movement Tendencies of Short-Tailed Viper Snakes (Gloydius saxatilis) by Altitude[J].Asian Herpetological Reserch(AHR),2017,8(1):39-47.[doi:10.16373/j.cnki.ahr.160126]

Distribution and Movement Tendencies of Short-Tailed Viper Snakes (Gloydius saxatilis) by Altitude()

Asian Herpetological Research[ISSN:2095-0357/CN:51-1735/Q]



Distribution and Movement Tendencies of Short-Tailed Viper Snakes (Gloydius saxatilis) by Altitude
Min Seock DO# Ki-Baek NAM# and Jeong-Chil YOO*
Department of Biology, Kyung Hee University, Seoul 130-701, Republic of Korea
altitudinal preference translocation radio-tracking Viperidae South Korea
The distribution pattern of reptiles in mountainous regions is generally related to altitude. The distribution of viperine species can be limited by elevation. Short-tailed viper snakes (Gloydius saxatilis) of South Korea are found mostly in high elevation mountainous areas, but few studies have evaluated how their distribution relates to elevation gradient. This study was conducted from 2012 to 2013 to investigate the altitudinal distribution of short-tailed viper snakes in mountainous areas and to discover their movement patterns in Cheon-ma Mountain County Park in South Korea. A translocation method utilizing radio-tracking technology was employed to confirm whether their distribution was influenced by altitude. The results showed that most short-tailed vipers were observed in middle and high altitude areas (from 400 m to 800 m), but none were observed in low altitude areas (from 200 m to 400 m). According to the results of the translocation and tracking experiments, the individuals of the translocated group showed a significantly broader home range than those of the control group. In addition, all individuals of the translocated group moved vertically, while most of the control group moved horizontally. Therefore, all translocated individuals tended to move back toward their original habitat, a high elevation area. Consequently, we concluded that the distribution of short-tailed viper snakes was limited by altitude.


Beack N. K., Shim J. H. 1999. Snake. Jisungsa Press, Seoul, Korea (In Korean)
Beyer H. L. 2004. Hawth’s analysis tools for ArcGIS, Version 2.10. Available online at http://www.spatialecology.com/htools. Accessed September, 17. 2008
Butler H., Malone B., Clemann N. 2005. The effects of translocation on the spatial ecology of tiger snakes (Notechis scutatus) in a suburban landscape. Wildl Res, 32: 165–171
Blanchard F. N., Finster E. B. 1933. A method of marking living snakes for future recognition, with a discussion of some problems and results. Ecosphere, 14(4): 334–347
Brown J. H. 2001. Mammals on mountainsides: elevational patterns of diversity. Glob Ecol Biogeogr, 10: 101–109
Brown J. R., Bishop C. A., Brooks R. J. 2010. Effectiveness of short-distance translocation and its effects on western rattlesnakes. J Wildlife Manage, 73: 419–425
Chettri B., Bhupathy S., Acharya B. K. 2010. Distribution pattern of reptiles along an eastern Himalayan elevation gradient, India. Acta Oecol, 36: 16–22
Do M. S., Shim J. H., Choi Y. M., Yoo J. C. 2014. Effect of weight of radio-transmitters on survival of Red-tongue viper snake (Gloydius ussuriensis) and Short-tailed viper snake (Gloydius saxatilis) in the radio-transmitter implantation. J of Wetland Research, 16(1): 85–92 (In Korean with English abstract)
Do M. S., Yoo J. C. 2014. Distribution pattern according to altitude and habitat type of Red-tongue viper snake (Gloydius ussuriensis) in Cheon-ma Mountain. J of Wetland Research, 16(2): 193–204 (In Korean with English abstract)
Do M. S., Lee J. W., Jang H. J., Kim D. I., Yoo J. C. 2016. Interspecific competition and spatial ecology of three species of vipers in Korea: An application of ecological niche-based models and GIS. Korean J Environ Ecol, 30(2): 173–184 (In Korean with English abstract)
Duvall D., Schuett G. W. 1997. Straight-line movement and competitive mate searching in prairie rattlesnakes, Crotalus viridis viridis. Anim Behav, 54: 329–334
Gloyd H. K. 1972. The Korean snakes of the genus Agkistrodon (crotalidea). Proc Biol Soc Wash, 85(49): 557–578
Gloyd H. K., Conant R. 1989. Snake of the Agkistrodon complex (a monographic review). Society for the study of amphibians and reptiles, Ithaca, New York, USA
Harlan J. R. 1976. Plant and animal distribution in relation to domestication. Phil Trans R Soc Lond B, 273: 13–25
Hayne D. W. 1949. Calculation of size of home range. J Mammal, 30: 1–18
Hooge P. N., Eichenlaub W. M., Solomon E. K. 2001. Using GIS to analyze animal movements in the marine environment. In: Kruse G.H., Bez N., Booth A., Dorn W., Hills S., Lipicus R.N., Pelletier D., Roy C., Smith S.J., Witherell D. (Eds.), Spatial Processes and Management of Marine Populations. University of Alaska Sea Grant, Fairbanks, pp. 37–51
Jul D. M., On S. S. 2002. Atlas of reptiles of China. Hanam scientific technique publishing company, China (In Chinese)
Kenward R. 2000. A manual for wildlife radio tagging. Academic Press, London
Kim B. S. 2010. A study on the ecology of the Ussuri mamushi Gloydius ussuriensis from Jeju island, Korea. Ph. D Thesis, Jeju national university (in Korean with English abstract)
Kim J. Y. 2013. Morphological variation and distribution of three wild rodent species along altitudinal and latitudinal gradients in the Baedudaegan Mountains in Korea. Master’s Thesis, Kangwon National University, Korea (In Korean with English abstract)
Lee K. J., Lee S. D., Hong S. H. 2002. Forest Ecosystems of Choenmasan County Park, J Ecol Environ, 2002(1): 65–69 (In Korean with English abstract)
Lee J. H., Jang H. J., Suh J. H. 2011. Ecological guidebook of herpetofauna in Korea. National Institute of Environmental Research, Incheon, Korea (In Korean)
Lee S. W. 2014. 2013 the 19th Basic statistic of Namyangju city. Namyangju city hall, Korea (In Korean)
Lomolino M. V. 2001. Elevation gradients of species-density: historical and prospective views. Glob Ecol Biogeogr, 10: 3–13
Luiselli L. 2006. Resource partitioning and interspecific competition in snakes: the search for general geographical and guild patterns. Oikos, 114: 193–211
Luiselli L., Filppi E., Lena E. D. 2007. Ecological Relationship between Sympatric Vipera aspis and Vipera ursinii in High-Altitude Habitats of Central Italy. J Herpetol, 41(3): 378–384
Marshall J. C., Manning J. V., Kingsbury B. A. 2006. Movement and microhabitat selection of the eastern massasauga in a fen habitat. Herpetologica, 62: 141–150
Martínez-Freiría F., Sillero N., Lizana M., Brito J. C. 2008. GIS-based niche models identify environmental correlates sustaining a contact zone between three species of European vipers. Divers Distrib, 14: 452–461
McCain C. M. 2007a. Could temperature and water availability drive elevational diversity? A global case study for bats. Glob Ecol Biogeogr, 16: 1–13
McCain C. M. 2007b. Area and mammalian elevational diversity. Ecology, 88: 76–86
National Geographic Information Institute. 2014. Internet references. Ministry of Land, Retrieved from http://www.ngii.go.kr/kor/board/view.do?rbsIdx=31&key=%EC%82%B0&keyField=search1&idx=619
Nowak E. M. 1998. Implications of nuisance rattlesnake relocation at Montezuma Castle National Monument. Sonoran Herpetologist, 11: 2–5
Orians G. H., Wittenberger J. F. 1991. Spatial and temporal scales in habitat selection. Am Nat, 137: 29–49
Orlov N. L., Murphy R. W., Papenfuss T. J. 2000. List of snake of Tam-dao mountain ridge (Tokin, Vietnam). Russ J Herpetol, 7(1): 69–80
R core Team. 2013. R: A language and environment for statistical computing. Available at www. R-project.org. Accessed November 29. 2015
Randin F. C., Engler R., Normand S., Zappaz M., Klaus E. N., Immermann Z., Pearman P. B., Vittoz P., Thuiller W., Antoine G. 2009. Climate change and plant distribution: local models predict high-elevation persistence. Glob Chang Biol, 15: 1557–1569
Rahbek C. 1995. The elevational gradient of species richness: A uniform pattern? Ecography, 18: 200–205
Reinert R., Cundall D. 1982. An improved surgical implantation method for radio-tracking for snakes. Copeia, 3: 702–705
Reinert H. K., Zappalorti R. T. 1988. Timber rattlesnakes (Crotalus horridus) of the Pine Barrens: Their movement patterns and habitat preference. Copeia, 1988(4): 964–978
Reinert H. K. 1991. Translocation as a conservation strategy for amphibians and reptiles: Some comments, concerns, and observations? Herpetologica, 47: 357–363
Reinert H. K., Rupert R. R. 1999. Impacts of translocation on behavior and survival of Timber Rattlesnakes, Crotalus horridus. J Herpetol, 33: 45–61
Reo J. H., Frank M. R., Gibson S. E., Attum O., Kingsbury B. A. 2010. No place like home an experimental comparison of reintroduction strategies using snakes. J Appl Ecol, 47: 1253–1261
Saint Girons H. 1975. Coexistence de Vipera aspiset de Vipera berusen Loire-Atlantique: un problème de competition interspéci?que. Rev Ecol Terre Vie, 29: 590–613 (In French)
Sealy J. 1997. Short-distance translocation of timber rattlesnake in a North Carolina state park, successful conservation and management program. Sonoran Herpetologist, 10: 94–99
Seaman D. E., Powell R. A. 1996. An evaluation of the accuracy of kernel density estimators for home range analysis. Ecology, 77: 2075-2085
Secor S. M. 1994. Ecological significance of movements and activity range for the sidewinder, Crotalus cerastes. Copeia, 1994(3): 631–645
Shine R. L., Sun M. F., Kearney M. 2003. A radiotelemetric study of movements and thermal biology of insular Chinese pit-viper (Gloydius shedaoensis, Viperidae). Oikos, 100: 342–352
Tang C. Q., Ohsawa M. 1997. Zonal Transition of Evergreen, Deciduous, and Coniferous Forests Along the Altitudinal Gradient on a Humid Subtropical Mountain, Mt. Emei, Sichuan, China. Plant Ecol, 133(1): 63–78
Wasko D. K., Sasa M. 2012. Food resources influence spatial ecology, habitat selection, and foraging behavior in an Ambush-hunting snake (Viperidea: Bothrops asper): An experimental study. Zoology, 115(3): 179–187
Webb J. K., Shine R. 1997. Out on a limb: conservation implications of tree-hollow use by a threatened snake species (Hoplocephalus bungaroides: Serpentes, Elapidae). Biol Conserv, 81: 21–23
Whitaker P. B., Shine R. 2003. A radiotelemetric study of movement and shelter-site selection by free-ranging brownsnake (Pseudonaja textilis, Elapidae). Herpetol Monogr, 17: 130–144
Yang S. Y., Kang Y. J. 1999. Amphibians and reptiles of namyangju and gapyeong area. 2rd Natural Environment Survey, Ministry of Environment, Korea (In Korean)

更新日期/Last Update: 2017-03-25