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Lutz, H., Isenbugel, E., & Lehmann, R. (1994). Retrovirus serology in snow leopards and other wild felids in European zoos. In J.L.Fox, & D.Jizeng (Eds.), (pp. 203–208). Usa: Islt.
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Uchitelskaya gazeta. (1984). Return of snow leopard. January 3 1984.
Abstract: 10 snow leopards have settled in western extremities of the Hissar ridge. Almost 25 years ago, disturbed by anthropogenic activity, this rarest fauna representative abandoned the area being threatened. In a habitat usual for this species have now been created the Kyzylsu and Miraki nature reserves and the species is now rendering the highlands inhabitable again. Wild boar, Turkestan lynx, long-tailed marmot, snow leopard and black vulture, a total of 200 animal and bird species, can be found now in this area.
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Satunin K.A. (1905). Review of the Mammals in Trans Caspian region (Vol. Vol. 25, issue. 3.).
Abstract: Snow leopard Pardus uncia Schreber recorded in Trans Caspian region (in Sumbar rive) very rare and occasionally.
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Shnitnikov V.N. (1934). Rocks and taluses. Alpine meadows. Economic value of local animals (Vol. Part. 1. South Kazakhstan.).
Abstract: It reviews fauna of rocks, taluses, and alpine meadows of South Kazakhstan. The most typical mammal of rocks and taluses are picas (I¤hotona rutila and I. macrotis), ibex (¥…dr… sibirica), and snow leopard (Felis irbis). Besides, snow leopard, along with Tien Shan bear (Ursus l†u¤Œn¢o), ibex, mountain wolf (¥uŒn alpinus) and others, is met in the alpine meadow zone. Zoo-export of snow leopards to the zoos does not result in extermination of the animals but generates income. Various animal species are subject to trade as zoos do not limit their collections with some specific species or groups; quite the contrary they are interested in obtaining each species. Valuable animals exported from Kazakhstan are tiger, snow leopard, Tien-Shan bear, argali, and mountain wolf. The latter costs 1,000 roubles in gold, and argali even 1,500 roubles.
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Shnitnikov V.N. (1936). Rocks and taluses. Snow leopard, Irbis Felis irbis Shreb.
Abstract: In Semerechie, snow leopard is not a rare species. In 1931, 53 snow leopards were hunted in southern Semerechie. In the past, at the markets of Central Tien Shan one could buy skins or live snow leopards, which were in demand abroad. Probably, number of snow leopards in Semerechie has increased. Now, it can be found not only in remote areas but in the vicinity of settlements (snow leopards, for instance, were observed some 20 30 km from Almaty, and 60 km from Frunze). Snow leopard preys mainly on ibex (¥…dr… sibiri¤…), snow-cock (O†traogallus himalauenses), and numerous argali – in some areas. The animal will never attack a man, even if wounded.
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Yanushevich A.I., C. Y. N. (1969). Sary Chelek nature reserve.
Abstract: It provides data concerning location, climate, landscapes, altitude zoning, flora and fauna of the Sary Chelek nature reserve. Currently in nature reserve recorded 41 mammals, 157 birds, 5 reptiles, 2 amphibians and 5 fishes. Snow leopard, wild ibex, argali and dhole inhabited in alpine zone. Number of ibex is 400 individuals.
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Anonymous. (2000). Save the Snow Leopard. (Road and Gas Pipeline Project Threatens Ecology of Siberia). The Ecologist, 30(4), 14.
Abstract: An interregional organisation called Siberian Accord plans to construct a road and gas pipeline to China, This association, which has vast political powers, exists to create favorable conditions for investing in Siberia.
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Karanth, K. U., Nichols, J.D., Seidensticker, J., Dinerstein, E., David Smith, J.L., McDougal, C., Johnsingh, A.J.T., Chundawat, R.S., Thapar, V. (2003). Science deficiency in conservation practice: the monitoring of tiger populations in India. Animal Conservation, 6, 141–146.
Abstract: Conservation practices are supposed to get refined by advancing scientific knowledge. We study this phenomenon in the context of monitoring tiger populations in India, by evaluating the ‘pugmark census method’ employed by wildlife managers for three decades. We use an analytical framework of modern animal population sampling to test the efficacy of the pugmark censuses using scientific data on tigers and our field observations. We identify three critical goals for monitoring tiger populations, in order of increasing sophistication: (1) distribution mapping, (2) tracking relative abundance, (3) estimation of absolute abundance. We demonstrate that the present census-based paradigm does not work because it ignores the first two simpler goals, and targets, but fails to achieve, the most difficult third goal. We point out the utility and ready availability of alternative monitoring paradigms that deal with the central problems of spatial sampling and observability. We propose an alternative sampling-based approach that can be tailored to meet practical needs of tiger monitoring at different levels of refinement.
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Roth, T. L., Armstrong, D. L., Barrie, M. T., & Wildt, D. E. (1997). Seasonal effects on ovarian responsiveness to exogenous gonadotrophins and successful artificial insemination in the snow leopard (Uncia uncia). Reprod Fertil Dev, 9(3), 285–295.
Abstract: Ovaries of the seasonally-breeding snow leopard (Uncia uncia) were examined to determine whether they were responsive to exogenous gonadotrophins throughout the year. The potential of laparoscopic artificial insemination (AI) also was assessed for producing offspring. During the non-breeding, pre-breeding, breeding and post-breeding seasons, females (n = 20) were treated with a standardized, dual- hormone regimen given intramuscularly (600 I.U. of equine chorionic gonadotrophin followed 80-84 h later with 300 I.U. of human chorionic gonadotrophin (hCG)). Laparoscopy was performed 45-50 h after administration of hCG, and all ovarian structures were described. Females with fresh corpora lutea (CL) were inseminated, and anovulatory females were subjected to follicular aspiration to examine oocyte quality. Snow leopards responded to exogenous gonadotrophins throughout the year. Mean number of total ovarian structures (distinct follicles mature in appearance plus CL) did not differ (P > or = 0.05) with season, but the proportion of CL: total ovarian structures was greater (P < 0.01) for the breeding season compared with all other seasons. The proportion of females ovulating was greater (P < 0.05) during the breeding and post-breeding seasons than during the pre-breeding and non- breeding seasons respectively. No Grade-1 quality oocytes were recovered from follicles of anovulatory females. Serum concentrations of oestradiol-17 beta appeared elevated in all females, and neither oestradiol-17 beta concentrations nor progesterone concentrations differed (P > or = 0.05) among seasons. Of 15 females artificially inseminated, the only one that was inseminated in the non-breeding season became pregnant and delivered a single cub. This is the first successful pregnancy resulting from AI in this endangered species.
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Formozov A.N. (1990). Seasonal migrations of mammals due to snow cover. Distribution of the Felidae family species.
Abstract: It describes vertical migrations of ungulates (ibex, wild sheep) in the Semerechie, Altai, Sayans, Tuva, seasonal migrations of steppe ungulates (kulan and saiga), and migrations of predators (lynx, leopard, irbis, tiger, dhole, wolf, glutton) following ungulates during winters with thick snow cover. Shorter local migrations related to uneven snow cover are typical for corsac, fox, and wolf. An analysis of the Felidae family species distribution showed that northern border of the cat family species habitat is connected with borders of 20 30 cm thick snow cover rather than with landscape contours or typical habitats. With the exception of lynx, this can be referred to the large cat family species such as irbis, leopard, and tiger.
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