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Sharma, K. M. C., Thomas. Johannson, Orjan. Ud Din, Jaffar. Bayarjargal, A. (2010). Snow Leopards and Telemetry: Experiences and Challenges. Telemetry in Wildlife Science, 13(No. 1), 1–5.
Abstract: The snow leopard Panthera uncia is one of the least studied felids in the world. Little is know about various aspects of the ecology of the snow leopard, which is cryptic in nature and found across 12 countries in Central Asia. Most research on snow leopards has been based on non-invasive methods such as sign surveys for presence (e.g. Jackson and Hunter 1996), scat analyses for diet (e.g. Chundawat and Rawat 1992; Oli et al., 2008, 2010) for population estimation, and studies based on human interviews (Mehta and Heinen 2001; Mishra and Bagchi 2006).
Despite this plethora of studies employing non-invasive techniques, several crucial questions about snow leopard ecology remain unanswered. Information about the animal’s home range, dispersal, corridors, pattern of habitat use, movement patterns, hunting frequency, behavior and intra – specific interactions is not available yet. In order to design population monitoring studies using camera traps or DNA analyses, one needs a good understanding of snow leopard ecology, including the home range and movement patterns (Williams et al., 2002). Telemetry is still the best available method and perhaps much less invasive than direct observations for studying the biology and ecology of cryptic animals.
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Snow Leopard Conservation Fund, S. L. T., Panthera. (2010). Mining and Snow Leopard Conservation: Tost- Tosonbumba Mountains of Gurvantes Soum, South Gobi Mongolia.
Abstract: The Tost-Tosonbumba Mountains of South Gobi represent one of the most impressive habitats for the endangered snow leopard Panthera Uncia, supporting amongst the highest population density of this rare cat reported so far from across it's global range. A prestigious multi-institutional internal research collaboration was initiated in Tost-Tosonbumba in 2008 with the establishment of a sate of the art research station. Yet, lying outside any protected area, this important snow leopard population and its habitat face direct and urgent threats due to mining. Initiation of mining in the region would (i) severely impact an important snow leopard population and destroy much of its habitat, (ii) compromise the possibility of genetic exchange of snow leopards over a much larger landscape (iii) lay to waste ten years of effort with local communities that have involved improving livelihoods and seeking their co-operation in snow leopard conservation and (iv) squander the opportunity for Mongolia to continue a prestigious one of a kind, long-term international collaborative program on snow leopard research. It is critical that mining licenses in snow leopard habitats of the region be immediately revoked, and the local communities be supported in their efforts to develop the Tost-Tosonbumba Mountains into a local protected area.
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Kinoshita, K., Inada, S., Seki, K., Sasaki, A., Hama, N., Kusunoki, H. (2011). Long-Term Monitoring of Fecal Steroid Hormones in Female Snow Leopards (Panthera uncia) during Pregnancy or Pseudopregnancy. PLoS ONE, 6(5), e19314. doi:10.1371/journal.pone.0019314.
Abstract: Knowledge of the basic reproductive physiology of snow leopards is required urgently in order to develop a suitable management conditions under captivity. In this study, the long-term monitoring of concentrations of three steroid hormones in fecal matter of three female snow leopards was performed using enzyme immunoassays: (1) estradiol-17β, (2) progesterone and (3) cortisol metabolite. Two of the female animals were housed with a male during the winter breeding season, and copulated around the day the estradiol-17β metabolite peaked subsequently becoming pregnant. The other female was treated in two different ways: (1) first housed with a male in all year round and then (2) in the winter season only. She did not mate with him on the first occasion, but did so latter around when estradiol-17β metabolite peaked, and became pseudopregnant. During pregnancy, progesterone metabolite concentrations increased for 92 or 94 days, with this period being approximately twice as long as in the pseudopregnant case (31, 42, 49 and 53 days). The levels of cortisol metabolite in the pseudopregnant female (1.35 µg/g) were significantly higher than in the pregnant females (0.33 and 0.24 µg/g) (P<0.05). Similarly, during the breeding season, the levels of estradiol-17β metabolite in the pseudopregnant female (2.18 µg/g) were significantly higher than those in the pregnant females (0.81 and 0.85 µg/g) (P<0.05). Unlike cortisol the average levels of estradiol-17β during the breeding season were independent of reproductive success.
The hormone levels may also be related to housing conditions and the resulting reproductive success in female leopards. The female housed with a male during the non-breeding season had high levels of cortisol metabolites and low levels of estradiol-17β in the breeding season, and failed to become pregnant. This indicates that housing conditions in snow leopards may be an important factor for normal endocrine secretion and resulting breeding success.
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Sharma, K., McCarthy, T. (2011). Counting cats: toward a framework for evaluating snow leopard (Panthera uncia) conservation efforts.
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Padmanabhan, S. (2011). Rinchen Wangchuk – (1969-2011). Sanctuary Asia, .
Abstract: On March 26, 2011, the world of conservation became poorer by the passing away of Rinchen Wangchuk, the Founder and Director of the Snow Leopard Conservancy-India Trust (SLC-IT) in Leh. Rinchen had been ill for the past three years, having been diagnosed with a deteriorating neurological condition for which traditional medical systems and allopathy have no cure yet. Over the past decade, Rinchen, affectionately referred to as the “snow leopard man” by friends, had played a pivotal role in Ladakh, having initiated one of the most successful community-based initiatives that had changed local people’s perceptions of predators like the snow leopard and Tibetan wolf from “pests” to a valued asset.
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Karmacharya, D. (2011). Field Protocol – Scat Collection for Genetic Analysis.
Abstract: Project funded by Snow Leopard Conservation Grant Program. Center for Molecular Genetics, Nepal.
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Simms, A., Moheb, Z., Salahudin, Ali, H., Ali, I. & Wood, T. (2011). Saving threatened species in Afghanistan: snow leopards in the Wakhan Corridor. International Journal of Environmental Studies, 68(3), 299–312.
Abstract: The Wakhan Corridor in northeast Afghanistan is an area known for relatively abundant wildlife and it appears to represent Afghanistan’s most important snow leopard landscape. The Wildlife Conservation Society (WCS) has been working in Wakhan since 2006. Recent camera trap surveys have documented the presence of snow leopards at 16 different locations in the landscape. These are the first camera trap records of snow leopards in Afghanistan. Threats to snow leopards in the region include the fur trade, retaliatory killing by shepherds and the capture of live animals for pets. WCS is developing an integrated management approach for this species, involving local governance, protection by a cadre of rangers, education, construction of predator-proof livestock corrals, a livestock insurance program, tourism and research activities. This management approach is expected to contribute significantly to the conservation of snow leopards and other wildlife species in the Wakhan.
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Kanderian, N., Lawson, D., Zahler, P. (2011). Current status of wildlife and conservation in Afghanistan. International Journal of Environmental Studies, 68(3), 281–298.
Abstract: Afghanistan’s position in latitude, geography and at the intersection of three biogeographic realms has resulted in a surprising biodiversity. Its wildlife includes species such as the snow leopard, Asiatic black bear, Marco Polo sheep, markhor and greater flamingo. Principal threats include high levels of deforestation, land encroachment and hunting for food and trade. Continuing security issues have also made it difficult to monitor species abundance and population trends. Over the last decade, however, survey efforts have provided the first collection of species and habitat data since the late 1970s. Initial findings are enabling the Government and rural communities to begin implementing important conservation measures. This process has included policy development and protected area planning, promoting alternative livelihoods and responsible community management, and continuing research into the status of biodiversity in the field.
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WWF Russia & WWF Mongolia Programme Office. (2011). Altai-Sayan Ecoregion WWF Newsletter April-June 2011 (Vol. April-June).
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Janeč, & ka, J. E., Munkhtsog, B., Jackson, R.M., Naranbaatar, G., Mallon, D.P. & Murphy, W.J. (2011). Comparison of noninvasive genetic and camera-trapping techniques for surveying snow leopards. Journal of Mammalogy, 92(4), 771–783.
Abstract: The endangered snow leopard (Panthera uncia) is widely but sparsely distributed throughout the mountainous regions of central Asia. Detailed information on the status and abundance of the snow leopard is limited because of the logistical challenges faced when working in the rugged terrain it occupies, along with its secretive nature. Camera-trapping and noninvasive genetic techniques have been used successfully to survey this felid. We compared noninvasive genetic and camera-trapping snow leopard surveys in the Gobi Desert of Mongolia. We collected 180 putative snow leopard scats from 3 sites during an 8-day period along 37.74 km of transects. We then conducted a 65-day photographic survey at 1 of these sites, approximately 2 months after scat collection. In the site where both techniques were used noninvasive genetics detected 5 individuals in only 2 days of fieldwork compared to 7 individuals observed in the 65-day camera-trapping session. Estimates of population size from noninvasive genetics ranged between 16 and 19 snow leopards in the 314.3-km2 area surveyed, yielding densities of 4.9–5.9 individuals/100 km2. In comparison, the population estimate from the 65-day photographic survey was 4 individuals (adults only) within the 264-km2 area, for a density estimate of 1.5 snow leopards/100 km2. Higher density estimates from the noninvasive genetic survey were due partly to an inability to determine age and exclude subadults, reduced spatial distribution of sampling points as a consequence of collecting scats along linear transects, and deposition of scats by multiple snow leopards on common sites. Resulting differences could inflate abundance estimated from noninvasive genetic surveys and prevent direct comparison of densities derived from the 2 approaches unless appropriate adjustments are made to the study design.
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