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Himalayan wolf

February 16, 2024

The Himalayan wolf (Canis lupus chanco)[4] is a canine of debated taxonomy.[3] It is distinguished by its genetic markers, with mitochondrial DNA indicating that it is genetically basal to the Holarctic grey wolf, genetically the same wolf as the Tibetan and Mongolian wolf,[5][6][3] and has an association with the African wolf (Canis lupaster).[7][6][3] No striking morphological differences are seen between the wolves from the Himalayas and those from Tibet.[8] The Himalayan wolf lineage can be found living in Ladakh in the Himalayas, the Tibetan Plateau,[9][10] and the mountains of Central Asia[10] predominantly above 4,000 m (13,000 ft) in elevation because it has adapted to a low-oxygen environment, compared with other wolves that are found only at lower elevations.[9]

Himalayan wolf
Himalayan wolf in the Upper Mustang region of Annapurna Conservation Area in Nepal
Scientific classification
Domain: Eukaryota
Kingdom: Animalia
Phylum: Chordata
Class: Mammalia
Order: Carnivora
Family: Canidae
Genus: Canis
Species:
C. lupus
Subspecies:
C. l. chanco
Trinomial name
Canis lupus chanco
Gray, 1863[2]
Himalayan wolf distribution (red dots in highlands) compared with the holarctic grey wolf (blue dots in lowlands)[3]

Some authors have proposed the reclassification of this lineage as a separate species.[11][12] In 2019, a workshop hosted by the IUCN/SSC Canid Specialist Group noted that the Himalayan wolf's distribution included the Himalayan range and the Tibetan Plateau. The group recommends that this wolf lineage be known as the "Himalayan wolf" and be classified as Canis lupus chanco until a genetic analysis of the holotypes is available. The Himalayan wolf lacks a proper morphological analysis.[4] The wolves in India and Nepal are listed on CITES Appendix I as endangered due to international trade.[13]

Taxonomy edit

Canis chanco was the scientific name proposed by John Edward Gray in 1863, who described a skin of a wolf that was shot in Chinese Tartary.[2] This specimen was classified as a wolf subspecies Canis lupus chanco by St. George Jackson Mivart in 1880.[14] In the 19th and 20th centuries, several zoological specimens were described:

  • Canis niger by Philip Sclater in 1874 was a wolf specimen collected near Hanle in Kashmir.[15]
  • Lupus filchneri by Paul Matschie in 1907 was a wolf skin from Xining in China's Qinghai province.[16] It had been collected by Wilhelm Filchner during an expedition to China and Tibet in 1903–1905.[17]
  • Lupus karanorensis by Matschie in 1907 was a skin and a skull of a wolf that was shot in an oasis near Dunhuang in China in 1894.[16]
  • Lupus tschiliensis by Matschie in 1907 was a skull of a wolf specimen that was shot in the coastal region of China's Zhili province.[16]
  • Canis lupus coreanus by Yoshio Abe in 1923 was a wolf specimen from the vicinity of Seoul in the Korean Peninsula.[18]

In 1938, Glover Morrill Allen classified these specimens as synonyms for C. l. chanco.[19] In 1941, Reginald Pocock corroborated this assessment after reviewing wolf skins and skulls in the collection of the Natural History Museum, London.[20] In 2005, W. Christopher Wozencraft also listed C. l. niger, C. l. filchneri, C. l. karanorensis, and C. l. tschiliensis as synonyms for C. l. chanco.[21]

Canis himalayensis was proposed by Aggarwal et al. in 2007 for wolf specimens from the Indian Himalayas that differed in mitochondrial DNA from specimens collected in other parts of India.[11] In April 2009, Canis himalayensis was proposed as a distinct wolf species through the Nomenclature Specialist on the CITES Animals Committee. The proposal was based on one study that relied on only a limited number of museum and zoo samples that may not have been representative of the wild population.[8][22] The committee recommended against this proposal, but suggested that the name be entered into the CITES species database as a synonym for Canis lupus. The committee stated that the classification was for conservation purposes only, and did not "reflect the latest state of taxonomic knowledge".[23][24] Further fieldwork was called for.[8] This genetic lineage shows a 3.9% divergence in the mDNA cytochrome b gene when compared with the Holarctic grey wolf, which may justify it being classified as a distinct species.[3] In 2019, a workshop hosted by the IUCN/SSC Canid Specialist Group noted that the Himalayan wolf's distribution included the Himalayan range and the Tibetan Plateau. The group determined that the earliest available Latin name is Canis chanco Gray, 1863, but the geographic location of the holotype is unclear. The group recommends that this wolf lineage be known as the "Himalayan wolf" and classified as Canis lupus chanco until a genetic analysis of the holotypes is available.[4]

In 2020, more recent research on the Himalayan wolf genome indicates that it warrants species-level recognition under the Unified Species Concept, the Differential Fitness Species Concept, and the Biological Species Concept. It was identified as an evolutionary significant unit that warranted assignment onto the IUCN Red List for its protection.[9]

Characteristics edit

 
Himalayan wolf profile

The Himalayan wolf has a thick, woolly fur that is dull earthy-brown on the back and tail, and yellowish-white on the face, tummy, and limbs. It has closely spaced black speckles on the muzzle, below the eyes, and on the upper cheeks and ears.[25]

Larger than the Indian and common European wolves,[26][27] it reaches 110 to 180 cm (45 to 70 in) in length, 68 to 76 cm (27 to 30 in) tall at the shoulder, and weighs around 30 to 55 kg (66 to 121 lb) on average.[8][20][28]

The heart of the Himalayan wolf can withstand the low oxygen level at high elevations. It has a strong selection for RYR2, a gene that initiates cardiac excitation.[29]

Phylogeography edit

 
Wolf in Changtang, Tibet

The mitochondrial DNA of 27 wolves from the Himalayas and the Tibetan Plateau was compared in 2004. Results indicate that five related haplotypes formed a clade that is basal to all other wolves. This clade included one sample from Ladakh, nine from the Spiti Valley in Himachal Pradesh, four from Nepal, and two from Tibet. The Himalayan wolf clade diverged from other canids 800,000 years ago. Seven wolves from Kashmir did not fall into this clade.[30] The mtDNA of 18 captive wolves in the Padmaja Naidu Himalayan Zoological Park was analysed in 2007. Results showed that they shared a common female ancestor.[11] As this study was based on captive-bred zoo specimens that had descended from only two females, these samples were not considered to be representative. Additionally, the wolf population in the Kashmir Valley is known to have recently arrived in that area.[8][25] Subsequent genetic research showed that wolf samples from Tibet are genetically basal to the Holarctic gray wolf.[31][32][33][34] Its MT-ND4L gene commences with the base pairs GTG, whereas all other canids commence with ATG.[35] Results of whole genome sequencing showed that it is the most genetically divergent wolf.[36]

Analysis of scat samples from two wolves collected in upper Dolpo in Nepal matched the Himalayan wolf.[22] Fecal remains of four wolves collected in the upper Mustang region of the Annapurna Conservation Area also fell within the Himalayan wolf clade but formed a separate haplotype from those previously studied.[25]

The Himalayan wolf population in Tibet declined over the past 25,000 years and suffered a historical population bottleneck. Glaciation during the Last Glacial Maximum may have caused habitat loss, genetic isolation, and ancient inbreeding. The population in Qinghai had grown, though, showing a gene flow of 16% from Chinese indigenous dogs and 2% of the dingo's genome. It probably recolonised the Tibetan Plateau.[36] The Himalayan wolf contrasts with the wolves living at lower elevations in Inner Mongolia, Mongolia, and Xinjiang province. Some wolves in China and Mongolia also fall within the Himalayan wolf clade, indicating a common maternal ancestor and a wide distribution.[5] There was evidence of hybridization with the grey wolf at Sachyat-Ertash in the Issyk-Kul region of Kyrgyzstan, and of introgression from either the grey wolf or the dog into the Himalayan wolf in Nepal.[3]

A genomic study on China's wolves included museum specimens of wolves from southern China that were collected between 1963 and 1988. The wolves in the study formed three clades: north Asian wolves that included those from northern China and eastern Russia, wolves from the Tibetan Plateau, and a unique population from southern China. One specimen located as far southeast as Jiangxi province shows evidence of being admixed between Tibetan-related wolves and other wolves in China.[37]

 
Wolves in the Padmaja Naidu Himalayan Zoological Park in Darjeeling
Phylogenetic tree of Canis lupus with timing in years[a]
250,000
120,000
80,000
31,000

Dog  

Holarctic gray wolf  

Late Pleistocene wolf 

Indian plains wolf  

Himalayan wolf  

DNA sequences can be mapped to reveal a phylogenetic tree that represents evolutionary relationships, with each branch point representing the divergence of two lineages from a common ancestor. On this tree, the term “basal” is used to describe a lineage that forms a branch diverging nearest to the common ancestor.[38]

Relationship to the Indian lowland wolf edit

In 2021, a study compared both the mitochondrial DNA and the nuclear DNA (from the cell nucleus) from the wolves of the Himalayas with those of the wolves from the lowlands of the Indian subcontinent. The genomic analyses indicate that the Himalayan wolf and the Indian lowland wolf were genetically distinct from one another. These wolves were also genetically distinct from – and genetically basal to – the other wolf populations across the northern hemisphere. These other wolves form a single mitochondrial clade, indicating that they originated from a single expansion from one region within the last 100,000 years. However, the study indicated that the Himalayan wolf had separated from this lineage 496,000 years ago, and the Indian lowland wolf 200,000 years ago.[39]

Admixture with an unknown wolf-like canid edit

The Tibetan mastiff breed was able to adapt to the extreme highland conditions of the Tibetan Plateau very quickly, comparably to other mammals such as the yak, Tibetan antelope, snow leopard, and wild boar. The Tibetan mastiff's ability to avoid hypoxia in high elevations due to its higher hemoglobin levels compared to low-altitude dogs, was due to prehistoric interbreeding with the wolves of Tibet.[40][41]

In 2020, a genomic analysis indicates that the wolves of the Himalayas and the Tibetan plateau are closely related. These wolves have an admixed history which includes gray wolves, dogs, and a ghost population of an unknown wolf-like canid. This ghost population is deeply-diverged from modern Holarctic wolves and dogs, has contributed 39% to the Himalayan wolf's nuclear genome, and contributed the EPAS1 allele which can be found in both Himalayan wolves and dogs which allows them to live in high altitudes.[42]

Domestic dogs exhibit diverse coat colours and patterns. In many mammals, different colour patterns are the result of the regulation of the Agouti gene, which can cause hair follicles to switch from making black or brown pigments to yellow or nearly white pigments. The most common coat pattern found in modern wolves is agouti, in which the upperside of the body has banded hairs and the underside exhibits lighter shading. The colour yellow is dominant to the colour black and is found in dogs across much of the world and the dingo in Australia.[43]

In 2021, a study of whole genome sequences taken from dogs and wolves focused on the genetic relationships between them based on coat colour. The study found that most dog colour haplotypes were similar to most wolf haplotypes, however dominant yellow in dogs was closely related to white in arctic wolves from North America. This result suggests a common origin for dominant yellow in dogs and white in wolves but without recent gene flow, because this clade was found to be basal to the golden jackal and genetically distinct from all other canids. The most recent common ancestor of the golden jackal and the wolf lineage dates back to 2 million YBP. The study proposes that 35,000 YBP there was genetic introgression into the Late Pleistocene grey wolf from a ghost population of an extinct canid which had diverged from the grey wolf lineage over 2 million YBP. This colour diversity could be found 35,000 YBP in wolves and 9,500 YBP in dogs. A closely related haplotype exists among those wolves of Tibet which possess yellow shading in their coats. The study explains the colour relationships between modern dogs and wolves, white wolves from North America, yellow dogs, and yellowish wolves from Tibet. The study concludes that during the Late Pleistocene, natural selection laid the genetic foundation for modern coat colour diversity in dogs and wolves.[43]

Relationship with the African golden wolf edit

 
Wolves in the Padmaja Naidu Himalayan Zoological Park in Darjeeling

In 2011, the Himalayan, Indian and African wolves were proposed to represent ancient wolf lineages, with the African wolf having colonised Africa prior to the Northern Hemisphere radiation of the Holarctic gray wolf.[33]

Two studies of the mitochondrial genome of both modern and extinct gray wolves (Canis lupus) have been conducted, but these excluded the genetically divergent lineages of the Himalayan wolf and the Indian wolf. The ancient specimens were radiocarbon dated and stratigraphically dated, and together with DNA sequences, a time-based phylogenetic tree was generated for wolves. The study inferred that the most recent common ancestor for all other Canis lupus specimens – modern and extinct – was 80,000 years before present.[44][45] An analysis of the Himalayan wolf mitochondrial genome indicates that the Himalayan wolf diverged between 740,000 and 691,000 years ago from the lineage that would become the Holarctic gray wolf.[3]

Between 2011 and 2015, two mDNA studies found that the Himalayan wolf and Indian gray wolf were genetically closer to the African golden wolf than they were to the Holarctic gray wolf.[33][7] From 2017, two studies based on mDNA, and X-chromosome and Y-chromosome markers taken from the cell nucleus, indicate that the Himalayan wolf is genetically basal to the Holarctic gray wolf. Its degree of divergence from the Holarctic gray wolf is similar to the degree of divergence of the African wolf from the Holarctic wolf. The Himalayan wolf shares a maternal lineage with the African wolf. It possesses a unique paternal lineage that falls between the gray wolf and the African wolf.[6][3] The results of these two studies imply that the Himalayan wolf distribution range extends from the Himalayan range north across the Tibetan Plateau up to the Qinghai Lake region in China’s Qinghai Province.[6]

In 2018, whole genome sequencing was used to compare members of the genus Canis. The African golden wolf was found to be the descendant of a genetically admixed canid of 72% gray wolf and 28% Ethiopian wolf ancestry.[46] The Ethiopian wolf does not share the single-nucleotide polymorphisms that confer hypoxia adaptation with the Himalayan wolf. The adaptation of the Ethiopian wolf to living in high elevations may occur at other single-nucleotide polymorphism locations. This indicates that the Ethiopian wolf's adaptation has not been inherited by descent from a common ancestor shared with the Himalayan wolf.[3]

Distribution and habitat edit

 
Pin Valley National Park located in Himachal Pradesh

In China, the Himalayan wolf lives on the Tibetan Plateau in the provinces of Gansu, Qinghai, Tibet,[47][48] and western Sichuan.[9]

In northern India, it occurs in the Union Territory of Ladakh and in the Lahaul and Spiti region in northeastern Himachal Pradesh.[20] In 2004, the Himalayan wolf population in India was estimated to consist of 350 individuals ranging across an area of about 70,000 km2 (27,000 sq mi).[30] Between 2005 and 2008, it was sighted in the alpine meadows above the treeline northeast of Nanda Devi National Park in Uttarakhand.[49] In 2013, a wolf was photographed by a camera trap installed at an elevation around 3,500 m (11,500 ft) near the Sunderdhunga Glacier in Uttarakhand's Bageshwar district.[50]

In Nepal, it was recorded in Api Nampa Conservation Area, Upper Dolpa, Humla, Manaslu, Upper Mustang, and the Kanchenjunga Conservation Area.[51][52] The Nepal Himalayas provide an important habitat refuge for the Himalayan wolf.[3]

Behaviour and ecology edit

The howls of the Himalayan wolf have lower frequencies, unmodulated frequencies, and are shorter in duration compared to Holarctic wolf howls. The Himalayan and North African wolves have the most acoustically distinct howls and differ significantly from each other and the Holarctic wolves.[53]

Prey edit

Himalayan wolves prefer wild over domestic prey. It usually prefers the smaller Tibetan gazelle over the larger white-lipped deer, and the plains-dwelling Tibetan gazelle over the cliff-dwelling blue sheep. Supplementary diet includes the small Himalayan marmot, big-eared pika and woolly hare. Himalayan wolves avoid livestock where wild prey is available, but habitat encroachment and the depletion of wild prey populations is expected to lead to conflict with herders. To protect them, securing healthy wild prey populations through setting aside wildlife habitat reserves and refuges is essential.[54] Other recorded prey species are Bactrian deer, Yarkand deer, Tibetan red deer, Siberian roe deer, Siberian ibex, Tibetan wild ass, Przewalski's horse, wild yak, markhor, argali and urial.[55]

Historical sources indicate that wolves occasionally killed children in Ladakh and Lahaul.[20] Within the proposed Gya-Miru Wildlife Sanctuary in Ladakh, the intensity of livestock depredation assessed in three villages found that Tibetan wolves were the most prevalent predators, accounting for 60% of the total livestock losses, followed by the snow leopard and Eurasian lynx. The most frequent prey were domestic goats (32%), followed by sheep (30%), yaks (15%), and horses (13%). The wolves killed horses significantly more, and goats less, than would be expected from their relative abundance.[56]

Conservation edit

 
Wolves in the Padmaja Naidu Himalayan Zoological Park, Darjeeling

The wolf in Bhutan, India, Nepal, and Pakistan is listed on CITES Appendix I.[13] In India, the wolf is protected under Schedule I of the Wildlife Protection Act, 1972, which prohibits hunting; a zoo needs a permission from the government to acquire a wolf. It is listed as endangered in Jammu and Kashmir, Himachal Pradesh, and Uttarakhand, where a large portion of the wolf population lives outside the protected area network.[8] Lack of information about its basic ecology in this landscape is an obstacle for developing a conservation plan.[57] In Nepal, it is protected under Schedule I of the National Parks and Wildlife Conservation Act, 2029 (1973) prohibiting hunting it.[58] In China, the wolf is listed as vulnerable in the Red List of China’s Vertebrates, and hunting it is banned.[59][60]

In captivity edit

In 2007, 18 Himalayan wolves were kept for breeding in two Indian zoos. They were captured in the wild and were kept at the Padmaja Naidu Himalayan Zoological Park in West Bengal, and in the Kufri Zoo in Himachal Pradesh.[11]

Notes edit

  1. ^ For a full set of supporting references refer to the note (a) in the phylotree at Evolution of the wolf#Wolf-like canids

References edit

  1. ^ Werhahn, G.; Hennelly, M.; Lyngdoh, S.J.; Habib, B.; Viranta, S.; Shrotriya, S. (2023). "Canis lupus ssp. chanco". IUCN Red List of Threatened Species. 2023: e.T223987824A223987841. doi:10.2305/IUCN.UK.2023-1.RLTS.T223987824A223987841.en. Retrieved 7 January 2024.
  2. ^ a b Gray, J. E. (1863). "Notice of the Chanco or Golden Wolf (Canis chanco) from Chinese Tartary". Proceedings of the Zoological Society of London: 94.
  3. ^ a b c d e f g h i j Werhahn, G.; Senn, H.; Ghazali, M.; Karmacharya, D.; Sherchan, A. M.; Joshi, J.; Kusi, N.; López-Bao, J. V.; Rosen, T.; Kachel, S.; Sillero-Zubiri, C.; MacDonald, D. W. (2018). "The unique genetic adaptation of the Himalayan wolf to high-altitudes and consequences for conservation". Global Ecology and Conservation. 16: e00455. doi:10.1016/j.gecco.2018.e00455. hdl:10651/50748. e00455.
  4. ^ a b c Alvares, F.; Bogdanowicz, W.; Campbell, L.A.D.; Godinho, R.; Hatlauf, J.; Jhala, Y.V.; Kitchener, A. C.; Koepfli, K.-P.; Krofel, M.; Moehlman, P. D.; Senn, H.; Sillero-Zubiri, C.; Viranta, S.; Werhahn, G. (2019). Old World Canis spp. with taxonomic ambiguity: Workshop conclusions and recommendations, 28th–30th May 2019 (PDF) (Report). Vairão, Portugal: IUCN/SSC Canid Specialist Group, Centro de Investigação em Biodiversidade e Recursos Genéticos. (PDF) from the original on 8 March 2021. Retrieved 6 March 2020.
  5. ^ a b Ersmark, E.; Klütsch, C. F. C.; Chan, Y. L.; Sinding, M.-H. S.; Fain, S. R.; Illarionova, N. A.; Oskarsson, M.; Uhlén, M.; Zhang, Y.-P.; Dalén, L.; Savolainen, P. (2016). "From the Past to the Present: Wolf Phylogeography and Demographic History Based on the Mitochondrial Control Region". Frontiers in Ecology and Evolution. 4. doi:10.3389/fevo.2016.00134. S2CID 19954938.
  6. ^ a b c d Werhahn, G.; Senn, H.; Kaden, J.; Joshi, J.; Bhattarai, S.; Kusi, N.; Sillero-Zubiri, C.; MacDonald, D. W. (2017). "Phylogenetic evidence for the ancient Himalayan wolf: Towards a clarification of its taxonomic status based on genetic sampling from western Nepal". Royal Society Open Science. 4 (6): 170186. Bibcode:2017RSOS....470186W. doi:10.1098/rsos.170186. PMC 5493914. PMID 28680672.
  7. ^ a b Koepfli, K.-P.; Pollinger, J.; Godinho, R.; Robinson, J.; Lea, A.; Hendricks, S.; Schweizer, R. M.; Thalmann, O.; Silva, P.; Fan, Z.; Yurchenko, A. A.; Dobrynin, P.; Makunin, A.; Cahill, J. A.; Shapiro, B.; Álvares, F.; Brito, J. C.; Geffen, E.; Leonard, J. A.; Helgen, K. M.; Johnson, W. E.; O'Brien, S. J.; Van Valkenburgh, B.; W., R. K. (2015). "Genome-wide Evidence Reveals that African and Eurasian Golden Jackals Are Distinct Species". Current Biology. 25 (16): 2158–2165. doi:10.1016/j.cub.2015.06.060. PMID 26234211. S2CID 16379927.
  8. ^ a b c d e f Shrotriya, S.; Lyngdoh, S.; Habib, B. (2012). "Wolves in Trans-Himalayas: 165 years of taxonomic confusion" (PDF). Current Science. 103 (8). (PDF) from the original on September 23, 2015. Retrieved June 27, 2014.
  9. ^ a b c d Werhahn, G.; Liu, Y.; Meng, Y.; Cheng, C.; Lu, Z.; Atzeni, L.; Deng, Z.; Kun, S.; Shao, X.; Lu, Q.; Joshi, J.; Man Sherchan, A.; Karmacharya, D.; Kumari Chaudhary, H.; Kusi, N.; Weckworth, B.; Kachel, S.; Rosen, T.; Kubanychbekov, Z.; Karimov, K.; Kaden, J.; Ghazali, M.; MacDonald, D. W.; Sillero-Zubiri, C.; Senn, H. (2020). "Himalayan wolf distribution and admixture based on multiple genetic markers". Journal of Biogeography. 47 (6): 1272–1285. Bibcode:2020JBiog..47.1272W. doi:10.1111/jbi.13824.
  10. ^ a b Joshi, Bheemdutt; Lyngdoh, Salvador; Singh, Sujeet Kumar; Sharma, Reeta; Kumar, Vinay; Tiwari, Ved Prakash; Dar, S. A.; Maheswari, Aishwarya; Pal, Ranjana; Bashir, Tawqir; Reshamwala, Hussain Saifee; Shrotriya, Shivam; Sathyakumar, S.; Habib, Bilal; Kvist, Laura; Goyal, Surendra Prakash (2020). "Revisiting the Woolly wolf (Canis lupus chanco) phylogeny in Himalaya: Addressing taxonomy, spatial extent and distribution of an ancient lineage in Asia". PLOS ONE. 15 (4): e0231621. Bibcode:2020PLoSO..1531621J. doi:10.1371/journal.pone.0231621. PMC 7162449. PMID 32298359.
  11. ^ a b c d Aggarwal, R. K.; Kivisild, T.; Ramadevi, J.; Singh, L. (2007). "Mitochondrial DNA coding region sequences support the phylogenetic distinction of two Indian wolf species". Journal of Zoological Systematics and Evolutionary Research. 45 (2): 163–172. doi:10.1111/j.1439-0469.2006.00400.x. Note: this is the final, peer-reviewed version of Aggarwal (2003)
  12. ^ Aggarwal, R. K. (2007). "Molecular Genetic Studies on highly Endangered Species". In Pandit, M. W. S.; Shivaji, L. S. (eds.). You Deserve, We Conserve: A Biotechnological Approach to Wildlife Conservation. New Delhi: I K International Publishing House. pp. 54–57. ISBN 978-81-89866-24-2.
  13. ^ a b "Species+: Canis lupus". CITES Secretariat and UNEP-WCMC. 2010. from the original on 2017-12-05. Retrieved 2021-03-27.
  14. ^ Mivart, S. G. (1890). "The Common Wolf". Dogs, jackals, wolves, and foxes : a monograph of the Canidæ. London: E. H. Porter and Dulau & Co. p. 8.
  15. ^ Sclater, P. L. (November 1874). "On the Black Wolf of Thibet". Proceedings of the Zoological Society of London: 654–655.
  16. ^ a b c Matschie, P. (1907). "Über Chinesische Säugetiere". In Filchner, W. (ed.). Wissenschaftliche Ergebnisse der Expedition Filchner nach China und Tibet, 1903-1905. Berlin: Ernst Siegfried Mittler und Sohn. pp. 134–242.
  17. ^ Filchner, W. (1913). Wissenschaftliche Ergebnisse der Expedition Filchner nach China und Tibet, 1903–1905 [Scientific results of the expedition Filchner to China and Tibet, 1903–1905]. Vol. Band 4. Berlin: Ernst Siegfried Mittler und Sohn.
  18. ^ Abe, Y. (1923). "Nukutei ni tsuite" [On Nuketei]. Dobutsugaku Zasshi (Zoological Magazine). 35: 320–326.
  19. ^ Allen, G.M. (1938). "Canis lupus chanco Gray. The Wolf". The Mammals of China and Mongolia. Natural History of Central Asia. Vol. XI, Part I (First ed.). New York: The American Museum of Natural History. pp. 342–345.
  20. ^ a b c d Pocock, R. I. (1941). "Canis lupus chanco Gray. The Woolly Wolf". Fauna of British India. Vol. Mammals Volume 2. London: Taylor and Francis. pp. 86–90.
  21. ^ Wozencraft, W. C. (2005). "Subspecies Canis lupus chanco". In Wilson, D. E.; Reeder, D. M. (eds.). Mammal Species of the World: A Taxonomic and Geographic Reference (3rd ed.). Johns Hopkins University Press. p. 576. ISBN 978-0-8018-8221-0. OCLC 62265494.
  22. ^ a b Subba, S.A. (2012). (PDF) (Report). Rufford Small Grants Foundation. Archived from the original (PDF) on 2016-03-04. Retrieved 2015-11-19.
  23. ^ CITES (2009). "Nomenclatural Matters: Twenty-fourth meeting of the Animals Committee Geneva, (Switzerland), 20–24 April 2009, AC24 Doc. 13 Rev. 1 Annex 1" (PDF). p. 3. (PDF) from the original on 4 March 2016. Retrieved 1 August 2015.
  24. ^ CITES. "Canis lupus". Checklist of CITES species. CITES. from the original on 2013-11-15. Retrieved 2017-03-26.
  25. ^ a b c Chetri, M.; Jhala, Y.; Jnawali, Shant R.; Subedi, N.; Dhaka l, M.; Yumnam, B. (2016). "Ancient Himalayan wolf (Canis lupus chanco) lineage in Upper Mustang of the Annapurna Conservation Area, Nepal". ZooKeys (582): 143–156. Bibcode:2016ZooK..582..143C. doi:10.3897/zookeys.582.5966. PMC 4857050. PMID 27199590. from the original on 2022-01-09. Retrieved 2018-01-15.
  26. ^ "tibetanwolvesmith".
  27. ^ Jerdon, T. C. (1874). "The Indian wolf". The mammals of India: a natural history of all the animals known to inhabit continental India. London: John Wheldon. pp. 140–141.
  28. ^ "tibetanwolvestuff".
  29. ^ Zhang, W.; Fan, Z.; Han, E.; Hou, R.; Zhang, L.; Galaverni, M.; Liu, H.; Silva, P.; Li, P.; Pollinger, J.P.; Du, L.; Zhang, X.; Yue, B.; Wayne, R.K.; Zhang, Z. (2014). "Hypoxia adaptations in the Grey wolf (Canis lupus chanco) from Qinghai-Tibet Plateau". PLOS Genetics. 10 (7): e1004466. doi:10.1371/journal.pgen.1004466. PMC 4117439. PMID 25078401. e1004466.
  30. ^ a b Sharma, D. K.; Maldonado, J. E.; Jhala, Y. V.; Fleischer, R. C. (2004). "Ancient wolf lineages in India". Proceedings of the Royal Society B: Biological Sciences. 271 (Supplement 3): S1–S4. doi:10.1098/rsbl.2003.0071. PMC 1809981. PMID 15101402.
  31. ^ Leonard, J. A.; Vilà, C.; Fox-Dobbs, K.; Koch, P. L.; Wayne, R. K.; Van Valkenburgh, B. (2007). "Megafaunal Extinctions and the Disappearance of a Specialized Wolf Ecomorph" (PDF). Current Biology. 17 (13): 1146–1150. doi:10.1016/j.cub.2007.05.072. PMID 17583509. S2CID 14039133. (PDF) from the original on 2016-12-28. Retrieved 2015-08-27.
  32. ^ Pilot, M.; Branicki, W.; Jędrzejewski, W.; Goszczyński, J.; Jędrzejewska, B.; Dykyy, I.; Shkvyrya, M.; Tsingarska, E. (2010). "Phylogeographic history of grey wolves in Europe". BMC Evolutionary Biology. 10: 104. Bibcode:2010BMCEE..10..104P. doi:10.1186/1471-2148-10-104. PMC 2873414. PMID 20409299.
  33. ^ a b c Rueness, E. K.; Asmyhr, M. G.; Sillero-Zubiri, C.; MacDonald, D. W.; Bekele, A.; Atickem, A.; Stenseth, N. C. (2011). "The Cryptic African Wolf: Canis aureus lupaster is Not a Golden Jackal and is Not Endemic to Egypt". PLOS ONE. 6 (1): e16385. Bibcode:2011PLoSO...616385R. doi:10.1371/journal.pone.0016385. PMC 3027653. PMID 21298107.
  34. ^ Miklosi, A. (2015). "Evolution of the Wolf". Dog Behaviour, Evolution, and Cognition. Oxford Biology (2 ed.). Oxford University Press. pp. 106–107. ISBN 978-0199545667. from the original on 2023-02-10. Retrieved 2017-08-31.
  35. ^ Zhao, C.; Zhang, H.; Zhang, J.; Chen, L.; Sha, W.; Yang, X.; Liu, G. (2014). "The complete mitochondrial genome sequence of the Tibetan wolf (Canis lupus laniger)". Mitochondrial DNA. 27 (1): 7–8. doi:10.3109/19401736.2013.865181. PMID 24438245. S2CID 207746075.
  36. ^ a b Fan, Z.; Silva, P.; Gronau, I.; Wang, S.; Armero, A. S.; Schweizer, R. M.; Ramirez, O.; Pollinger, J.; Galaverni, M.; Ortega Del-Vecchyo, D.; Du, L.; Zhang, W.; Zhang, Z.; Xing, J.; Vilà, C.; Marques-Bonet, T.; Godinho, R.; Yue, B.; Wayne, R. K. (2016). "Worldwide patterns of genomic variation and admixture in gray wolves". Genome Research. 26 (2): 163–173. doi:10.1101/gr.197517.115. PMC 4728369. PMID 26680994.
  37. ^ Wang, Guo-Dong; Zhang, Ming; Wang, Xuan; Yang, Melinda A.; Cao, Peng; Liu, Feng; Lu, Heng; Feng, Xiaotian; Skoglund, Pontus; Wang, Lu; Fu, Qiaomei; Zhang, Ya-Ping (2019). "Genomic Approaches Reveal an Endemic Subpopulation of Gray Wolves in Southern China". iScience. 20: 110–118. Bibcode:2019iSci...20..110W. doi:10.1016/j.isci.2019.09.008. PMC 6817678. PMID 31563851.
  38. ^ Reece, J. B.; Meyers, N.; Urry, L. A.; Cain, M. L.; Wasserman, S. A.; Minorsky, P. V.; Jackson, R. B. & Cooke, B. N. (2015). "Phylogeny and the tree of life". Campbell Biology Australian and New Zealand version (10 ed.). Australia: Pierson. pp. 561–562. ISBN 9781486007042.
  39. ^ Hennelly, Lauren M.; Habib, Bilal; Modi, Shrushti; Rueness, Eli K.; Gaubert, Philippe; Sacks, Benjamin N. (2021). "Ancient divergence of Indian and Tibetan wolves revealed by recombination-aware phylogenomics". Molecular Ecology. 30 (24): 6687–6700. Bibcode:2021MolEc..30.6687H. doi:10.1111/mec.16127. PMID 34398980. S2CID 237147842.
  40. ^ Miao, B.; Wang, Z.; Li, Y. (2016). "Genomic Analysis Reveals Hypoxia Adaptation in the Tibetan Mastiff by Introgression of the Grey Wolf from the Tibetan Plateau". Molecular Biology and Evolution. 34 (3): 734–743. doi:10.1093/molbev/msw274. PMID 27927792. S2CID 47507546. from the original on 2021-10-20. Retrieved 2020-03-10.
  41. ^ Signore, A. V.; Yang, Y.-Z.; Yang, Q.-Y.; Qin, G.; Moriyama, H.; Ge, R.-L.; Storz, J. F. (2019). "Adaptive Changes in Hemoglobin Function in High-Altitude Tibetan Canids Were Derived via Gene Conversion and Introgression". Molecular Biology and Evolution. 36 (10): 2227–2237. doi:10.1093/molbev/msz097. PMC 6759075. PMID 31362306.
  42. ^ Wang, Ming-Shan; Wang, Sheng; Li, Yan; Jhala, Yadvendradev; Thakur, Mukesh; Otecko, Newton O.; Si, Jing-Fang; Chen, Hong-Man; Shapiro, Beth; Nielsen, Rasmus; Zhang, Ya-Ping; Wu, Dong-Dong (2020). "Ancient Hybridization with an Unknown Population Facilitated High-Altitude Adaptation of Canids". Molecular Biology and Evolution. 37 (9): 2616–2629. doi:10.1093/molbev/msaa113. PMID 32384152.
  43. ^ a b Bannasch, Danika L.; et al. (2021). "Dog colour patterns explained by modular promoters of ancient canid origin". Nature Ecology & Evolution. 5 (10): 1415–1423. Bibcode:2021NatEE...5.1415B. doi:10.1038/s41559-021-01524-x. PMC 8484016. PMID 34385618.
  44. ^ Thalmann, O.; et al. (2013). "Complete Mitochondrial Genomes of Ancient Canids Suggest a European Origin of Domestic Dogs". Science. 342 (6160): 871–4. Bibcode:2013Sci...342..871T. doi:10.1126/science.1243650. PMID 24233726. S2CID 1526260.
  45. ^ Koblmüller, S.; Vilà, C.; Lorente-Galdos, B.; Dabad, M.; Ramirez, O.; Marques-Bonet, T.; Wayne, R. K.; Leonard, J. A. (2016). "Whole mitochondrial genomes illuminate ancient intercontinental dispersals of grey wolves (Canis lupus)". Journal of Biogeography. 43 (9): 1728–1738. Bibcode:2016JBiog..43.1728K. doi:10.1111/jbi.12765. S2CID 88740690.
  46. ^ Gopalakrishnan, S.; Sinding, M.-H. S.; Ramos-Madrigal, J.; Niemann, J.; Samaniego Castruita, J. A.; Vieira, F. G.; Carøe, C.; Montero, M. d M.; Kuderna, L.; Serres, A.; González-Basallote, V. M.; Liu, Y.-H.; Wang, G.-D.; Marques-Bonet, T.; Mirarab, S.; Fernandes, C.; Gaubert, P.; Koepfli, K.-P.; Budd, J.; Rueness, E. K.; Heide-Jørgensen, M. P.; Petersen, B.; Sicheritz-Ponten, T.; Bachmann, L.; Wiig, Ø.; Hansen, A. J.; Gilbert, M. T. P. (2018). "Interspecific Gene Flow Shaped the Evolution of the Genus Canis". Current Biology. 28 (21): 3441–3449.e5. doi:10.1016/j.cub.2018.08.041. PMC 6224481. PMID 30344120.
  47. ^ Wozencraft, W. C. (2008). "Canidae". In Smith, A. T.; Xie, Y. (eds.). A Guide to the Mammals of China (First ed.). Princeton, Oxfordshire: Princeton University Press. pp. 416–418. ISBN 978-0691099842.
  48. ^ Wang, Y. (2003). A Complete Checklist of Mammal Species and Subspecies in China (A Taxonomic and Geographic Reference). Beijing, China: China Forestry Publishing House. ISBN 978-7503831317.
  49. ^ Bhattacharya, T. S. (2010). (PDF). Journal of Threatened Taxa. 2 (12): 1345–1348. doi:10.11609/jott.o2423.1345-8. Archived from the original (PDF) on 2012-11-01.
  50. ^ "Snow Leopard, Tibetan Wolf sighted" 2018-11-01 at the Wayback Machine. The Pioneer, 15 February 2014.
  51. ^ Arnold, C. (2016). . National Geographic. Archived from the original on 29 April 2016. Retrieved 29 April 2016.
  52. ^ Werhahn, G.; Kusi, N.; Sillero-Zubiri, C.; MacDonald, D. W. (2017). "Conservation implications for the Himalayan wolf Canis (lupus) himalayensis based on observations of packs and home sites in Nepal". Oryx. 53 (4): 1–7. doi:10.1017/S0030605317001077.
  53. ^ Hennelly, L.; Habib, B.; Root-Gutteridge, H.; Palacios, V.; Passilongo, D. (2017). "Howl variation across Himalayan, North African, Indian, and Holarctic wolf clades: tracing divergence in the world's oldest wolf lineages using acoustics". Current Zoology. 63 (3): 341–348. doi:10.1093/cz/zox001. PMC 5804178. PMID 29491993.
  54. ^ Werhahn, G.; Kusi, N.; Li, X.; Chen, C.; Zhi, L.; Lázaro Martín, R.; Sillero-Zubiri, C.; MacDonald, D. W. (2019). "Himalayan wolf foraging ecology and the importance of wild prey". Global Ecology and Conservation. 20: e00780. doi:10.1016/j.gecco.2019.e00780. e00780.
  55. ^ Lyngdoh, S. B.; Habib, B.; Shrotriya, S. (2019). "Dietary spectrum in Himalayan wolves: comparative analysis of prey choice in conspecifics across high-elevation rangelands of Asia" (PDF). Down to Earth. (PDF) from the original on 24 October 2020. Retrieved 7 August 2020.
  56. ^ Namgail, T.; Fox, J.L.; Bhatnagar, Y.V. (2007). "Carnivore-Caused Livestock Mortality in Trans-Himalaya". Environmental Management. 39 (4): 490–496. doi:10.1007/s00267-005-0178-2. PMID 17318699. S2CID 30967502.
  57. ^ Habib, B.; Shrotriya, S.; Jhala, Y. V. (2013). "Ecology and Conservation of Himalayan Wolf". Technical Report No. TR – 2013/01. Wildlife Institute of India: 46. doi:10.13140/RG.2.2.36012.87685.
  58. ^ Ministry of Forests (1973). National Parks and Wildlife Conservation Act 2029 (1973) (PDF). Kathmandu, Nepal: Government of Nepal. (PDF) from the original on 2018-09-20. Retrieved 2018-12-25.
  59. ^ Xu, Y.; Yang, B.; Dou, L. (2015). "Local villagers' perceptions of wolves in Jiuzhaigou County, western China". PeerJ. 3: e982. doi:10.7717/peerj.982. PMC 4465947. PMID 26082870. e982.
  60. ^ Fang, H.; Ping, X. (2016). "Red List of China's Vertebrates". Biodiversity Science. 24 (5): 500–551. doi:10.17520/biods.2016076.Canis lupus status=NT (Near Threatened)

External links edit

  • "Canis lupus himalayensis". NCBI.NLM.NIH.gov. National Center for Biotechnology Information, U.S. National Institutes of Health.

February 16, 2024
himalayan, wolf, canis, lupus, chanco, canine, debated, taxonomy, distinguished, genetic, markers, with, mitochondrial, indicating, that, genetically, basal, holarctic, grey, wolf, genetically, same, wolf, tibetan, mongolian, wolf, association, with, african, . The Himalayan wolf Canis lupus chanco 4 is a canine of debated taxonomy 3 It is distinguished by its genetic markers with mitochondrial DNA indicating that it is genetically basal to the Holarctic grey wolf genetically the same wolf as the Tibetan and Mongolian wolf 5 6 3 and has an association with the African wolf Canis lupaster 7 6 3 No striking morphological differences are seen between the wolves from the Himalayas and those from Tibet 8 The Himalayan wolf lineage can be found living in Ladakh in the Himalayas the Tibetan Plateau 9 10 and the mountains of Central Asia 10 predominantly above 4 000 m 13 000 ft in elevation because it has adapted to a low oxygen environment compared with other wolves that are found only at lower elevations 9 Himalayan wolfHimalayan wolf in the Upper Mustang region of Annapurna Conservation Area in NepalConservation statusVulnerable IUCN 3 1 1 Scientific classificationDomain EukaryotaKingdom AnimaliaPhylum ChordataClass MammaliaOrder CarnivoraFamily CanidaeGenus CanisSpecies C lupusSubspecies C l chancoTrinomial nameCanis lupus chancoGray 1863 2 Himalayan wolf distribution red dots in highlands compared with the holarctic grey wolf blue dots in lowlands 3 Some authors have proposed the reclassification of this lineage as a separate species 11 12 In 2019 a workshop hosted by the IUCN SSC Canid Specialist Group noted that the Himalayan wolf s distribution included the Himalayan range and the Tibetan Plateau The group recommends that this wolf lineage be known as the Himalayan wolf and be classified as Canis lupus chanco until a genetic analysis of the holotypes is available The Himalayan wolf lacks a proper morphological analysis 4 The wolves in India and Nepal are listed on CITES Appendix I as endangered due to international trade 13 Contents 1 Taxonomy 2 Characteristics 3 Phylogeography 3 1 Relationship to the Indian lowland wolf 3 2 Admixture with an unknown wolf like canid 3 3 Relationship with the African golden wolf 4 Distribution and habitat 5 Behaviour and ecology 5 1 Prey 6 Conservation 6 1 In captivity 7 Notes 8 References 9 External linksTaxonomy editCanis chanco was the scientific name proposed by John Edward Gray in 1863 who described a skin of a wolf that was shot in Chinese Tartary 2 This specimen was classified as a wolf subspecies Canis lupus chanco by St George Jackson Mivart in 1880 14 In the 19th and 20th centuries several zoological specimens were described Canis niger by Philip Sclater in 1874 was a wolf specimen collected near Hanle in Kashmir 15 Lupus filchneri by Paul Matschie in 1907 was a wolf skin from Xining in China s Qinghai province 16 It had been collected by Wilhelm Filchner during an expedition to China and Tibet in 1903 1905 17 Lupus karanorensis by Matschie in 1907 was a skin and a skull of a wolf that was shot in an oasis near Dunhuang in China in 1894 16 Lupus tschiliensis by Matschie in 1907 was a skull of a wolf specimen that was shot in the coastal region of China s Zhili province 16 Canis lupus coreanus by Yoshio Abe in 1923 was a wolf specimen from the vicinity of Seoul in the Korean Peninsula 18 In 1938 Glover Morrill Allen classified these specimens as synonyms for C l chanco 19 In 1941 Reginald Pocock corroborated this assessment after reviewing wolf skins and skulls in the collection of the Natural History Museum London 20 In 2005 W Christopher Wozencraft also listed C l niger C l filchneri C l karanorensis and C l tschiliensis as synonyms for C l chanco 21 Canis himalayensis was proposed by Aggarwal et al in 2007 for wolf specimens from the Indian Himalayas that differed in mitochondrial DNA from specimens collected in other parts of India 11 In April 2009 Canis himalayensis was proposed as a distinct wolf species through the Nomenclature Specialist on the CITES Animals Committee The proposal was based on one study that relied on only a limited number of museum and zoo samples that may not have been representative of the wild population 8 22 The committee recommended against this proposal but suggested that the name be entered into the CITES species database as a synonym for Canis lupus The committee stated that the classification was for conservation purposes only and did not reflect the latest state of taxonomic knowledge 23 24 Further fieldwork was called for 8 This genetic lineage shows a 3 9 divergence in the mDNA cytochrome b gene when compared with the Holarctic grey wolf which may justify it being classified as a distinct species 3 In 2019 a workshop hosted by the IUCN SSC Canid Specialist Group noted that the Himalayan wolf s distribution included the Himalayan range and the Tibetan Plateau The group determined that the earliest available Latin name is Canis chanco Gray 1863 but the geographic location of the holotype is unclear The group recommends that this wolf lineage be known as the Himalayan wolf and classified as Canis lupus chanco until a genetic analysis of the holotypes is available 4 In 2020 more recent research on the Himalayan wolf genome indicates that it warrants species level recognition under the Unified Species Concept the Differential Fitness Species Concept and the Biological Species Concept It was identified as an evolutionary significant unit that warranted assignment onto the IUCN Red List for its protection 9 Characteristics edit nbsp Himalayan wolf profileThe Himalayan wolf has a thick woolly fur that is dull earthy brown on the back and tail and yellowish white on the face tummy and limbs It has closely spaced black speckles on the muzzle below the eyes and on the upper cheeks and ears 25 Larger than the Indian and common European wolves 26 27 it reaches 110 to 180 cm 45 to 70 in in length 68 to 76 cm 27 to 30 in tall at the shoulder and weighs around 30 to 55 kg 66 to 121 lb on average 8 20 28 The heart of the Himalayan wolf can withstand the low oxygen level at high elevations It has a strong selection for RYR2 a gene that initiates cardiac excitation 29 Phylogeography edit nbsp Wolf in Changtang TibetThe mitochondrial DNA of 27 wolves from the Himalayas and the Tibetan Plateau was compared in 2004 Results indicate that five related haplotypes formed a clade that is basal to all other wolves This clade included one sample from Ladakh nine from the Spiti Valley in Himachal Pradesh four from Nepal and two from Tibet The Himalayan wolf clade diverged from other canids 800 000 years ago Seven wolves from Kashmir did not fall into this clade 30 The mtDNA of 18 captive wolves in the Padmaja Naidu Himalayan Zoological Park was analysed in 2007 Results showed that they shared a common female ancestor 11 As this study was based on captive bred zoo specimens that had descended from only two females these samples were not considered to be representative Additionally the wolf population in the Kashmir Valley is known to have recently arrived in that area 8 25 Subsequent genetic research showed that wolf samples from Tibet are genetically basal to the Holarctic gray wolf 31 32 33 34 Its MT ND4L gene commences with the base pairs GTG whereas all other canids commence with ATG 35 Results of whole genome sequencing showed that it is the most genetically divergent wolf 36 Analysis of scat samples from two wolves collected in upper Dolpo in Nepal matched the Himalayan wolf 22 Fecal remains of four wolves collected in the upper Mustang region of the Annapurna Conservation Area also fell within the Himalayan wolf clade but formed a separate haplotype from those previously studied 25 The Himalayan wolf population in Tibet declined over the past 25 000 years and suffered a historical population bottleneck Glaciation during the Last Glacial Maximum may have caused habitat loss genetic isolation and ancient inbreeding The population in Qinghai had grown though showing a gene flow of 16 from Chinese indigenous dogs and 2 of the dingo s genome It probably recolonised the Tibetan Plateau 36 The Himalayan wolf contrasts with the wolves living at lower elevations in Inner Mongolia Mongolia and Xinjiang province Some wolves in China and Mongolia also fall within the Himalayan wolf clade indicating a common maternal ancestor and a wide distribution 5 There was evidence of hybridization with the grey wolf at Sachyat Ertash in the Issyk Kul region of Kyrgyzstan and of introgression from either the grey wolf or the dog into the Himalayan wolf in Nepal 3 A genomic study on China s wolves included museum specimens of wolves from southern China that were collected between 1963 and 1988 The wolves in the study formed three clades north Asian wolves that included those from northern China and eastern Russia wolves from the Tibetan Plateau and a unique population from southern China One specimen located as far southeast as Jiangxi province shows evidence of being admixed between Tibetan related wolves and other wolves in China 37 nbsp Wolves in the Padmaja Naidu Himalayan Zoological Park in DarjeelingPhylogenetic tree of Canis lupus with timing in years a 250 000 120 000 80 000 31 000 Dog nbsp Holarctic gray wolf nbsp Late Pleistocene wolf nbsp Indian plains wolf nbsp Himalayan wolf nbsp DNA sequences can be mapped to reveal a phylogenetic tree that represents evolutionary relationships with each branch point representing the divergence of two lineages from a common ancestor On this tree the term basal is used to describe a lineage that forms a branch diverging nearest to the common ancestor 38 Relationship to the Indian lowland wolf edit In 2021 a study compared both the mitochondrial DNA and the nuclear DNA from the cell nucleus from the wolves of the Himalayas with those of the wolves from the lowlands of the Indian subcontinent The genomic analyses indicate that the Himalayan wolf and the Indian lowland wolf were genetically distinct from one another These wolves were also genetically distinct from and genetically basal to the other wolf populations across the northern hemisphere These other wolves form a single mitochondrial clade indicating that they originated from a single expansion from one region within the last 100 000 years However the study indicated that the Himalayan wolf had separated from this lineage 496 000 years ago and the Indian lowland wolf 200 000 years ago 39 Admixture with an unknown wolf like canid edit The Tibetan mastiff breed was able to adapt to the extreme highland conditions of the Tibetan Plateau very quickly comparably to other mammals such as the yak Tibetan antelope snow leopard and wild boar The Tibetan mastiff s ability to avoid hypoxia in high elevations due to its higher hemoglobin levels compared to low altitude dogs was due to prehistoric interbreeding with the wolves of Tibet 40 41 In 2020 a genomic analysis indicates that the wolves of the Himalayas and the Tibetan plateau are closely related These wolves have an admixed history which includes gray wolves dogs and a ghost population of an unknown wolf like canid This ghost population is deeply diverged from modern Holarctic wolves and dogs has contributed 39 to the Himalayan wolf s nuclear genome and contributed the EPAS1 allele which can be found in both Himalayan wolves and dogs which allows them to live in high altitudes 42 Domestic dogs exhibit diverse coat colours and patterns In many mammals different colour patterns are the result of the regulation of the Agouti gene which can cause hair follicles to switch from making black or brown pigments to yellow or nearly white pigments The most common coat pattern found in modern wolves is agouti in which the upperside of the body has banded hairs and the underside exhibits lighter shading The colour yellow is dominant to the colour black and is found in dogs across much of the world and the dingo in Australia 43 In 2021 a study of whole genome sequences taken from dogs and wolves focused on the genetic relationships between them based on coat colour The study found that most dog colour haplotypes were similar to most wolf haplotypes however dominant yellow in dogs was closely related to white in arctic wolves from North America This result suggests a common origin for dominant yellow in dogs and white in wolves but without recent gene flow because this clade was found to be basal to the golden jackal and genetically distinct from all other canids The most recent common ancestor of the golden jackal and the wolf lineage dates back to 2 million YBP The study proposes that 35 000 YBP there was genetic introgression into the Late Pleistocene grey wolf from a ghost population of an extinct canid which had diverged from the grey wolf lineage over 2 million YBP This colour diversity could be found 35 000 YBP in wolves and 9 500 YBP in dogs A closely related haplotype exists among those wolves of Tibet which possess yellow shading in their coats The study explains the colour relationships between modern dogs and wolves white wolves from North America yellow dogs and yellowish wolves from Tibet The study concludes that during the Late Pleistocene natural selection laid the genetic foundation for modern coat colour diversity in dogs and wolves 43 Relationship with the African golden wolf edit nbsp Wolves in the Padmaja Naidu Himalayan Zoological Park in DarjeelingIn 2011 the Himalayan Indian and African wolves were proposed to represent ancient wolf lineages with the African wolf having colonised Africa prior to the Northern Hemisphere radiation of the Holarctic gray wolf 33 Two studies of the mitochondrial genome of both modern and extinct gray wolves Canis lupus have been conducted but these excluded the genetically divergent lineages of the Himalayan wolf and the Indian wolf The ancient specimens were radiocarbon dated and stratigraphically dated and together with DNA sequences a time based phylogenetic tree was generated for wolves The study inferred that the most recent common ancestor for all other Canis lupus specimens modern and extinct was 80 000 years before present 44 45 An analysis of the Himalayan wolf mitochondrial genome indicates that the Himalayan wolf diverged between 740 000 and 691 000 years ago from the lineage that would become the Holarctic gray wolf 3 Between 2011 and 2015 two mDNA studies found that the Himalayan wolf and Indian gray wolf were genetically closer to the African golden wolf than they were to the Holarctic gray wolf 33 7 From 2017 two studies based on mDNA and X chromosome and Y chromosome markers taken from the cell nucleus indicate that the Himalayan wolf is genetically basal to the Holarctic gray wolf Its degree of divergence from the Holarctic gray wolf is similar to the degree of divergence of the African wolf from the Holarctic wolf The Himalayan wolf shares a maternal lineage with the African wolf It possesses a unique paternal lineage that falls between the gray wolf and the African wolf 6 3 The results of these two studies imply that the Himalayan wolf distribution range extends from the Himalayan range north across the Tibetan Plateau up to the Qinghai Lake region in China s Qinghai Province 6 In 2018 whole genome sequencing was used to compare members of the genus Canis The African golden wolf was found to be the descendant of a genetically admixed canid of 72 gray wolf and 28 Ethiopian wolf ancestry 46 The Ethiopian wolf does not share the single nucleotide polymorphisms that confer hypoxia adaptation with the Himalayan wolf The adaptation of the Ethiopian wolf to living in high elevations may occur at other single nucleotide polymorphism locations This indicates that the Ethiopian wolf s adaptation has not been inherited by descent from a common ancestor shared with the Himalayan wolf 3 Distribution and habitat edit nbsp Pin Valley National Park located in Himachal PradeshIn China the Himalayan wolf lives on the Tibetan Plateau in the provinces of Gansu Qinghai Tibet 47 48 and western Sichuan 9 In northern India it occurs in the Union Territory of Ladakh and in the Lahaul and Spiti region in northeastern Himachal Pradesh 20 In 2004 the Himalayan wolf population in India was estimated to consist of 350 individuals ranging across an area of about 70 000 km2 27 000 sq mi 30 Between 2005 and 2008 it was sighted in the alpine meadows above the treeline northeast of Nanda Devi National Park in Uttarakhand 49 In 2013 a wolf was photographed by a camera trap installed at an elevation around 3 500 m 11 500 ft near the Sunderdhunga Glacier in Uttarakhand s Bageshwar district 50 In Nepal it was recorded in Api Nampa Conservation Area Upper Dolpa Humla Manaslu Upper Mustang and the Kanchenjunga Conservation Area 51 52 The Nepal Himalayas provide an important habitat refuge for the Himalayan wolf 3 Behaviour and ecology editThe howls of the Himalayan wolf have lower frequencies unmodulated frequencies and are shorter in duration compared to Holarctic wolf howls The Himalayan and North African wolves have the most acoustically distinct howls and differ significantly from each other and the Holarctic wolves 53 Prey edit Himalayan wolves prefer wild over domestic prey It usually prefers the smaller Tibetan gazelle over the larger white lipped deer and the plains dwelling Tibetan gazelle over the cliff dwelling blue sheep Supplementary diet includes the small Himalayan marmot big eared pika and woolly hare Himalayan wolves avoid livestock where wild prey is available but habitat encroachment and the depletion of wild prey populations is expected to lead to conflict with herders To protect them securing healthy wild prey populations through setting aside wildlife habitat reserves and refuges is essential 54 Other recorded prey species are Bactrian deer Yarkand deer Tibetan red deer Siberian roe deer Siberian ibex Tibetan wild ass Przewalski s horse wild yak markhor argali and urial 55 Historical sources indicate that wolves occasionally killed children in Ladakh and Lahaul 20 Within the proposed Gya Miru Wildlife Sanctuary in Ladakh the intensity of livestock depredation assessed in three villages found that Tibetan wolves were the most prevalent predators accounting for 60 of the total livestock losses followed by the snow leopard and Eurasian lynx The most frequent prey were domestic goats 32 followed by sheep 30 yaks 15 and horses 13 The wolves killed horses significantly more and goats less than would be expected from their relative abundance 56 Conservation edit nbsp Wolves in the Padmaja Naidu Himalayan Zoological Park DarjeelingThe wolf in Bhutan India Nepal and Pakistan is listed on CITES Appendix I 13 In India the wolf is protected under Schedule I of the Wildlife Protection Act 1972 which prohibits hunting a zoo needs a permission from the government to acquire a wolf It is listed as endangered in Jammu and Kashmir Himachal Pradesh and Uttarakhand where a large portion of the wolf population lives outside the protected area network 8 Lack of information about its basic ecology in this landscape is an obstacle for developing a conservation plan 57 In Nepal it is protected under Schedule I of the National Parks and Wildlife Conservation Act 2029 1973 prohibiting hunting it 58 In China the wolf is listed as vulnerable in the Red List of China s Vertebrates and hunting it is banned 59 60 In captivity edit In 2007 18 Himalayan wolves were kept for breeding in two Indian zoos They were captured in the wild and were kept at the Padmaja Naidu Himalayan Zoological Park in West Bengal and in the Kufri Zoo in Himachal Pradesh 11 Notes edit For a full set of supporting references refer to the note a in the phylotree at Evolution of the wolf Wolf like canidsReferences edit Werhahn G Hennelly M Lyngdoh S J Habib B Viranta S Shrotriya S 2023 Canis lupus ssp chanco IUCN Red List of Threatened Species 2023 e T223987824A223987841 doi 10 2305 IUCN UK 2023 1 RLTS T223987824A223987841 en Retrieved 7 January 2024 a b Gray J E 1863 Notice of the Chanco or Golden Wolf Canis chanco from Chinese Tartary Proceedings of the Zoological Society of London 94 a b c d e f g h i j Werhahn G Senn H Ghazali M Karmacharya D Sherchan A M Joshi J Kusi N Lopez Bao J V Rosen T Kachel S Sillero Zubiri C MacDonald D W 2018 The unique genetic adaptation of the Himalayan wolf to high altitudes and consequences for conservation Global Ecology and Conservation 16 e00455 doi 10 1016 j gecco 2018 e00455 hdl 10651 50748 e00455 a b c Alvares F Bogdanowicz W Campbell L A D Godinho R Hatlauf J Jhala Y V Kitchener A C Koepfli K P Krofel M Moehlman P D Senn H Sillero Zubiri C Viranta S Werhahn G 2019 Old World Canis spp with taxonomic ambiguity Workshop conclusions and recommendations 28th 30th May 2019 PDF Report Vairao Portugal IUCN SSC Canid Specialist Group Centro de Investigacao em Biodiversidade e Recursos Geneticos Archived PDF from the original on 8 March 2021 Retrieved 6 March 2020 a b Ersmark E Klutsch C F C Chan Y L Sinding M H S Fain S R Illarionova N A Oskarsson M Uhlen M Zhang Y P Dalen L Savolainen P 2016 From the Past to the Present Wolf Phylogeography and Demographic History Based on the Mitochondrial Control Region Frontiers in Ecology and Evolution 4 doi 10 3389 fevo 2016 00134 S2CID 19954938 a b c d Werhahn G Senn H Kaden J Joshi J Bhattarai S Kusi N Sillero Zubiri C MacDonald D W 2017 Phylogenetic evidence for the ancient Himalayan wolf Towards a clarification of its taxonomic status based on genetic sampling from western Nepal Royal Society Open Science 4 6 170186 Bibcode 2017RSOS 470186W doi 10 1098 rsos 170186 PMC 5493914 PMID 28680672 a b Koepfli K P Pollinger J Godinho R Robinson J Lea A Hendricks S Schweizer R M Thalmann O Silva P Fan Z Yurchenko A A Dobrynin P Makunin A Cahill J A Shapiro B Alvares F Brito J C Geffen E Leonard J A Helgen K M Johnson W E O Brien S J Van Valkenburgh B W R K 2015 Genome wide Evidence Reveals that African and Eurasian Golden Jackals Are Distinct Species Current Biology 25 16 2158 2165 doi 10 1016 j cub 2015 06 060 PMID 26234211 S2CID 16379927 a b c d e f Shrotriya S Lyngdoh S Habib B 2012 Wolves in Trans Himalayas 165 years of taxonomic confusion PDF Current Science 103 8 Archived PDF from the original on September 23 2015 Retrieved June 27 2014 a b c d Werhahn G Liu Y Meng Y Cheng C Lu Z Atzeni L Deng Z Kun S Shao X Lu Q Joshi J Man Sherchan A Karmacharya D Kumari Chaudhary H Kusi N Weckworth B Kachel S Rosen T Kubanychbekov Z Karimov K Kaden J Ghazali M MacDonald D W Sillero Zubiri C Senn H 2020 Himalayan wolf distribution and admixture based on multiple genetic markers Journal of Biogeography 47 6 1272 1285 Bibcode 2020JBiog 47 1272W doi 10 1111 jbi 13824 a b Joshi Bheemdutt Lyngdoh Salvador Singh Sujeet Kumar Sharma Reeta Kumar Vinay Tiwari Ved Prakash Dar S A Maheswari Aishwarya Pal Ranjana Bashir Tawqir Reshamwala Hussain Saifee Shrotriya Shivam Sathyakumar S Habib Bilal Kvist Laura Goyal Surendra Prakash 2020 Revisiting the Woolly wolf Canis lupus chanco phylogeny in Himalaya Addressing taxonomy spatial extent and distribution of an ancient lineage in Asia PLOS ONE 15 4 e0231621 Bibcode 2020PLoSO 1531621J doi 10 1371 journal pone 0231621 PMC 7162449 PMID 32298359 a b c d Aggarwal R K Kivisild T Ramadevi J Singh L 2007 Mitochondrial DNA coding region sequences support the phylogenetic distinction of two Indian wolf species Journal of Zoological Systematics and Evolutionary Research 45 2 163 172 doi 10 1111 j 1439 0469 2006 00400 x Note this is the final peer reviewed version of Aggarwal 2003 Aggarwal R K 2007 Molecular Genetic Studies on highly Endangered Species In Pandit M W S Shivaji L S eds You Deserve We Conserve A Biotechnological Approach to Wildlife Conservation New Delhi I K International Publishing House pp 54 57 ISBN 978 81 89866 24 2 a b Species Canis lupus CITES Secretariat and UNEP WCMC 2010 Archived from the original on 2017 12 05 Retrieved 2021 03 27 Mivart S G 1890 The Common Wolf Dogs jackals wolves and foxes a monograph of the Canidae London E H Porter and Dulau amp Co p 8 Sclater P L November 1874 On the Black Wolf of Thibet Proceedings of the Zoological Society of London 654 655 a b c Matschie P 1907 Uber Chinesische Saugetiere In Filchner W ed Wissenschaftliche Ergebnisse der Expedition Filchner nach China und Tibet 1903 1905 Berlin Ernst Siegfried Mittler und Sohn pp 134 242 Filchner W 1913 Wissenschaftliche Ergebnisse der Expedition Filchner nach China und Tibet 1903 1905 Scientific results of the expedition Filchner to China and Tibet 1903 1905 Vol Band 4 Berlin Ernst Siegfried Mittler und Sohn Abe Y 1923 Nukutei ni tsuite On Nuketei Dobutsugaku Zasshi Zoological Magazine 35 320 326 Allen G M 1938 Canis lupus chanco Gray The Wolf The Mammals of China and Mongolia Natural History of Central Asia Vol XI Part I First ed New York The American Museum of Natural History pp 342 345 a b c d Pocock R I 1941 Canis lupus chanco Gray The Woolly Wolf Fauna of British India Vol Mammals Volume 2 London Taylor and Francis pp 86 90 Wozencraft W C 2005 Subspecies Canis lupus chanco In Wilson D E Reeder D M eds Mammal Species of the World A Taxonomic and Geographic Reference 3rd ed Johns Hopkins University Press p 576 ISBN 978 0 8018 8221 0 OCLC 62265494 a b Subba S A 2012 Assessing the genetic status distribution prey selection and conservation issues of Himalayan wolf Canis himalayensis in Trans Himalayan Dolpa Nepal PDF Report Rufford Small Grants Foundation Archived from the original PDF on 2016 03 04 Retrieved 2015 11 19 CITES 2009 Nomenclatural Matters Twenty fourth meeting of the Animals Committee Geneva Switzerland 20 24 April 2009 AC24 Doc 13 Rev 1 Annex 1 PDF p 3 Archived PDF from the original on 4 March 2016 Retrieved 1 August 2015 CITES Canis lupus Checklist of CITES species CITES Archived from the original on 2013 11 15 Retrieved 2017 03 26 a b c Chetri M Jhala Y Jnawali Shant R Subedi N Dhaka l M Yumnam B 2016 Ancient Himalayan wolf Canis lupus chanco lineage in Upper Mustang of the Annapurna Conservation Area Nepal ZooKeys 582 143 156 Bibcode 2016ZooK 582 143C doi 10 3897 zookeys 582 5966 PMC 4857050 PMID 27199590 Archived from the original on 2022 01 09 Retrieved 2018 01 15 tibetanwolvesmith Jerdon T C 1874 The Indian wolf The mammals of India a natural history of all the animals known to inhabit continental India London John Wheldon pp 140 141 tibetanwolvestuff Zhang W Fan Z Han E Hou R Zhang L Galaverni M Liu H Silva P Li P Pollinger J P Du L Zhang X Yue B Wayne R K Zhang Z 2014 Hypoxia adaptations in the Grey wolf Canis lupus chanco from Qinghai Tibet Plateau PLOS Genetics 10 7 e1004466 doi 10 1371 journal pgen 1004466 PMC 4117439 PMID 25078401 e1004466 a b Sharma D K Maldonado J E Jhala Y V Fleischer R C 2004 Ancient wolf lineages in India Proceedings of the Royal Society B Biological Sciences 271 Supplement 3 S1 S4 doi 10 1098 rsbl 2003 0071 PMC 1809981 PMID 15101402 Leonard J A Vila C Fox Dobbs K Koch P L Wayne R K Van Valkenburgh B 2007 Megafaunal Extinctions and the Disappearance of a Specialized Wolf Ecomorph PDF Current Biology 17 13 1146 1150 doi 10 1016 j cub 2007 05 072 PMID 17583509 S2CID 14039133 Archived PDF from the original on 2016 12 28 Retrieved 2015 08 27 Pilot M Branicki W Jedrzejewski W Goszczynski J Jedrzejewska B Dykyy I Shkvyrya M Tsingarska E 2010 Phylogeographic history of grey wolves in Europe BMC Evolutionary Biology 10 104 Bibcode 2010BMCEE 10 104P doi 10 1186 1471 2148 10 104 PMC 2873414 PMID 20409299 a b c Rueness E K Asmyhr M G Sillero Zubiri C MacDonald D W Bekele A Atickem A Stenseth N C 2011 The Cryptic African Wolf Canis aureus lupaster is Not a Golden Jackal and is Not Endemic to Egypt PLOS ONE 6 1 e16385 Bibcode 2011PLoSO 616385R doi 10 1371 journal pone 0016385 PMC 3027653 PMID 21298107 Miklosi A 2015 Evolution of the Wolf Dog Behaviour Evolution and Cognition Oxford Biology 2 ed Oxford University Press pp 106 107 ISBN 978 0199545667 Archived from the original on 2023 02 10 Retrieved 2017 08 31 Zhao C Zhang H Zhang J Chen L Sha W Yang X Liu G 2014 The complete mitochondrial genome sequence of the Tibetan wolf Canis lupus laniger Mitochondrial DNA 27 1 7 8 doi 10 3109 19401736 2013 865181 PMID 24438245 S2CID 207746075 a b Fan Z Silva P Gronau I Wang S Armero A S Schweizer R M Ramirez O Pollinger J Galaverni M Ortega Del Vecchyo D Du L Zhang W Zhang Z Xing J Vila C Marques Bonet T Godinho R Yue B Wayne R K 2016 Worldwide patterns of genomic variation and admixture in gray wolves Genome Research 26 2 163 173 doi 10 1101 gr 197517 115 PMC 4728369 PMID 26680994 Wang Guo Dong Zhang Ming Wang Xuan Yang Melinda A Cao Peng Liu Feng Lu Heng Feng Xiaotian Skoglund Pontus Wang Lu Fu Qiaomei Zhang Ya Ping 2019 Genomic Approaches Reveal an Endemic Subpopulation of Gray Wolves in Southern China iScience 20 110 118 Bibcode 2019iSci 20 110W doi 10 1016 j isci 2019 09 008 PMC 6817678 PMID 31563851 Reece J B Meyers N Urry L A Cain M L Wasserman S A Minorsky P V Jackson R B amp Cooke B N 2015 Phylogeny and the tree of life Campbell Biology Australian and New Zealand version 10 ed Australia Pierson pp 561 562 ISBN 9781486007042 Hennelly Lauren M Habib Bilal Modi Shrushti Rueness Eli K Gaubert Philippe Sacks Benjamin N 2021 Ancient divergence of Indian and Tibetan wolves revealed by recombination aware phylogenomics Molecular Ecology 30 24 6687 6700 Bibcode 2021MolEc 30 6687H doi 10 1111 mec 16127 PMID 34398980 S2CID 237147842 Miao B Wang Z Li Y 2016 Genomic Analysis Reveals Hypoxia Adaptation in the Tibetan Mastiff by Introgression of the Grey Wolf from the Tibetan Plateau Molecular Biology and Evolution 34 3 734 743 doi 10 1093 molbev msw274 PMID 27927792 S2CID 47507546 Archived from the original on 2021 10 20 Retrieved 2020 03 10 Signore A V Yang Y Z Yang Q Y Qin G Moriyama H Ge R L Storz J F 2019 Adaptive Changes in Hemoglobin Function in High Altitude Tibetan Canids Were Derived via Gene Conversion and Introgression Molecular Biology and Evolution 36 10 2227 2237 doi 10 1093 molbev msz097 PMC 6759075 PMID 31362306 Wang Ming Shan Wang Sheng Li Yan Jhala Yadvendradev Thakur Mukesh Otecko Newton O Si Jing Fang Chen Hong Man Shapiro Beth Nielsen Rasmus Zhang Ya Ping Wu Dong Dong 2020 Ancient Hybridization with an Unknown Population Facilitated High Altitude Adaptation of Canids Molecular Biology and Evolution 37 9 2616 2629 doi 10 1093 molbev msaa113 PMID 32384152 a b Bannasch Danika L et al 2021 Dog colour patterns explained by modular promoters of ancient canid origin Nature Ecology amp Evolution 5 10 1415 1423 Bibcode 2021NatEE 5 1415B doi 10 1038 s41559 021 01524 x PMC 8484016 PMID 34385618 Thalmann O et al 2013 Complete Mitochondrial Genomes of Ancient Canids Suggest a European Origin of Domestic Dogs Science 342 6160 871 4 Bibcode 2013Sci 342 871T doi 10 1126 science 1243650 PMID 24233726 S2CID 1526260 Koblmuller S Vila C Lorente Galdos B Dabad M Ramirez O Marques Bonet T Wayne R K Leonard J A 2016 Whole mitochondrial genomes illuminate ancient intercontinental dispersals of grey wolves Canis lupus Journal of Biogeography 43 9 1728 1738 Bibcode 2016JBiog 43 1728K doi 10 1111 jbi 12765 S2CID 88740690 Gopalakrishnan S Sinding M H S Ramos Madrigal J Niemann J Samaniego Castruita J A Vieira F G Caroe C Montero M d M Kuderna L Serres A Gonzalez Basallote V M Liu Y H Wang G D Marques Bonet T Mirarab S Fernandes C Gaubert P Koepfli K P Budd J Rueness E K Heide Jorgensen M P Petersen B Sicheritz Ponten T Bachmann L Wiig O Hansen A J Gilbert M T P 2018 Interspecific Gene Flow Shaped the Evolution of the Genus Canis Current Biology 28 21 3441 3449 e5 doi 10 1016 j cub 2018 08 041 PMC 6224481 PMID 30344120 Wozencraft W C 2008 Canidae In Smith A T Xie Y eds A Guide to the Mammals of China First ed Princeton Oxfordshire Princeton University Press pp 416 418 ISBN 978 0691099842 Wang Y 2003 A Complete Checklist of Mammal Species and Subspecies in China A Taxonomic and Geographic Reference Beijing China China Forestry Publishing House ISBN 978 7503831317 Bhattacharya T S 2010 Sighting of Tibetan Wolf Canis lupus chanko in the Greater Himalayan range of Nanda Devi Biosphere Reserve Uttarakhand India a new record PDF Journal of Threatened Taxa 2 12 1345 1348 doi 10 11609 jott o2423 1345 8 Archived from the original PDF on 2012 11 01 Snow Leopard Tibetan Wolf sighted Archived 2018 11 01 at the Wayback Machine The Pioneer 15 February 2014 Arnold C 2016 Woolly Wolf Spotted in Nepal Is Likely a New Species National Geographic Archived from the original on 29 April 2016 Retrieved 29 April 2016 Werhahn G Kusi N Sillero Zubiri C MacDonald D W 2017 Conservation implications for the Himalayan wolf Canis lupus himalayensis based on observations of packs and home sites in Nepal Oryx 53 4 1 7 doi 10 1017 S0030605317001077 Hennelly L Habib B Root Gutteridge H Palacios V Passilongo D 2017 Howl variation across Himalayan North African Indian and Holarctic wolf clades tracing divergence in the world s oldest wolf lineages using acoustics Current Zoology 63 3 341 348 doi 10 1093 cz zox001 PMC 5804178 PMID 29491993 Werhahn G Kusi N Li X Chen C Zhi L Lazaro Martin R Sillero Zubiri C MacDonald D W 2019 Himalayan wolf foraging ecology and the importance of wild prey Global Ecology and Conservation 20 e00780 doi 10 1016 j gecco 2019 e00780 e00780 Lyngdoh S B Habib B Shrotriya S 2019 Dietary spectrum in Himalayan wolves comparative analysis of prey choice in conspecifics across high elevation rangelands of Asia PDF Down to Earth Archived PDF from the original on 24 October 2020 Retrieved 7 August 2020 Namgail T Fox J L Bhatnagar Y V 2007 Carnivore Caused Livestock Mortality in Trans Himalaya Environmental Management 39 4 490 496 doi 10 1007 s00267 005 0178 2 PMID 17318699 S2CID 30967502 Habib B Shrotriya S Jhala Y V 2013 Ecology and Conservation of Himalayan Wolf Technical Report No TR 2013 01 Wildlife Institute of India 46 doi 10 13140 RG 2 2 36012 87685 Ministry of Forests 1973 National Parks and Wildlife Conservation Act 2029 1973 PDF Kathmandu Nepal Government of Nepal Archived PDF from the original on 2018 09 20 Retrieved 2018 12 25 Xu Y Yang B Dou L 2015 Local villagers perceptions of wolves in Jiuzhaigou County western China PeerJ 3 e982 doi 10 7717 peerj 982 PMC 4465947 PMID 26082870 e982 Fang H Ping X 2016 Red List of China s Vertebrates Biodiversity Science 24 5 500 551 doi 10 17520 biods 2016076 Canis lupus status NT Near Threatened External links edit Canis lupus himalayensis NCBI NLM NIH gov National Center for Biotechnology Information U S National Institutes of Health Retrieved from https en wikipedia org w index php title Himalayan wolf amp oldid 1205314960, wikipedia, wiki, book, books, library,

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