|An adult male Himalayan tahr in Kedarnath Wildlife Sanctuary, Uttarakhand, India.|
| Hemitragus jemlahicus|
The Himalayan tahr (Hemitragus jemlahicus) is a large ungulate native to the Himalayas in southern Tibet, northern India and Nepal. It is listed as Near Threatened on the IUCN Red List, as the population is declining due to hunting and habitat loss.
The Himalayan tahr has been introduced to New Zealand and South Africa.
Taxonomy and etymology
The word "tahr" comes from the Nepali language and was first used in English writing in 1835. Tahrs belong to the order Artiodactyla, which denotes an even-toed ungulate mammal. Close relatives to the Himalayan tahr also associated to the Caprinae subfamily include sheep and goats.
The Himalayan tahr has a small head, small pointed ears, large eyes, and horns that vary between males and females. Their horns reach a maximum length of 46 centimetres (18 in). Himalayan tahrs are sexually dimorphic, with females being smaller in weight and in size and having smaller horns. The horn is curved backwards, preventing injury during mating season when headbutting is a common mating ritual among males. The average male tahr usually weighs around 73 kg with females averaging 36 kg and is shorter in height than in length The exterior of a tahr is well adapted to the harsh climate of the Himalayans. They sport thick, reddish wool coats and thick undercoats, indicative of the conditions of their habitat. Their coats thin with the end of winter and becomes lighter in color. This shedding is presumably an adaptation that allows their internal body temperatures to adjust to the harsh temperatures of the Himalayan Mountains.
As a member of the ungulate group of mammals, the Himalayan tahr possesses an even number of toes. They have adapted the unique ability to grasp both smooth and rough surfaces that are typical of the mountainous terrain on which they reside. This useful characteristic also helps their mobility. The hooves of the tahr have a rubber-like core which allows for gripping smooth rocks while keratin at the rim of their hooves allow increased hoof durability, which is important for traversing the rocky ground. This adaptation allows for confident and swift maneuvering of the terrain.
Tahrs are polygynous, and males are subject to stiff competition for access to females. Young reproductive males roam and mate opportunistically (when larger males are not present), while more mature males (more than four years old) will engage in ritualistic behavior and fighting to secure mates. During mating season, reproductive males lose much of their fat reserves, while females and nonreproductive males do not, indicating a substantial cost to these behaviors. Factors that contribute to which males dominate include size, weight, and testosterone levels. Interestingly, coat color can have an effect; Himalayan tahrs with lighter coats are more likely to gain access to estrous females Himalayan tahrs have precocious young which can stand soon after birth. Females have a gestation period of 180–242 days, usually with a litter size of only one kid. This indicates sexual selection can be extremely important to the fitness of males.
The herbivorous diets of the Himalayan tahrs leave them spending most of their time grazing on grasses and browsing on leaves and some fruits. Their short legs allow them to balance while reaching for the leaves of shrubs and small trees. The tahr consumes more woody plants than herb species with as much as 75% of the tahr diet consisting of natural grasses. The tahr, like most members of the bovid family, are ruminants and have complex digestive systems . A multichambered stomach allows the tahr to repeatedly regurgitate its food, chew it, and obtain nutrients from otherwise indigestible plant tissues.
Ecology in native habitat
The Himalayan tahr is adapted to life in a cool climate with rocky terrain, which allows them to be found in mountainous areas. In the Himalayas, they are mainly found on slopes ranging from 2,500 to 5,000 m. Himalayan tahr can eat a wide variety of plants. They most often inhabit locations in where vegetation is exposed for browsing and grazing. During the winter (when snow covers vegetation at higher elevations), they are found on lower-altitude slopes.
During the rut, male Himalayan tahrs often compete with other males for access to females. Factors that contribute to reproductive success include large body size, large horn size, and high aggression. Coat color is a factor that determines rank among Himalayan tahrs, and males with light coats mate more often. In addition, the horns of the male are often used in the ritual process to court female tahrs (either for display purposes or, less often, for direct combat), although these horns can also serve as a defense mechanisms against potential predators.
Other ungulate herbivores with overlapping natural ranges include bharal, argali, and goral. Removal experiments (in which one of the hypothesized competitors is removed, and the effect on the other species is observed) have not been conducted to determine empirically that competition is actually occurring, but the animals do share food resources. Competition can occur when two or more species share a limited resource, such as particular food sources, in a given area. Since the Himalayan tahr and the other ungulates are eating the same foods, competition possibly is occurring among them.
Tahr are preyed upon by Himalayan Snow Leopards. The snow leopards also eat the other ungulate species in the area, which could result in apparent competition between the Himalayan tahr and one or more of the other herbivores. Apparent competition can occur when two species share a predator. If an increase in one of the prey species increases the predator population, this can translate into increased predation on the other prey species. This is called apparent competition, because the effect was indirect from the two prey species via the predator species rather than by direct competition of the two prey species for some shared resource.
Introduction as an invasive species
The tahr was introduced into Argentina in 2006 by private individuals, presumably for hunting purposes. The importation has been deemed successful, but it is too soon to determine whether it will be detrimental to the environment.
Tahrs was first introduced to New Zealand for sport and have since expanded rapidly into neighboring areas. They currently occupy a portion of the Southern Alps and are still being hunted as a sport.
The Himalayan tahr was introduced to South Africa when in the 1930s, two Himalayan tahrs escaped from a zoo in Cape Town. Subsequent populations of tahrs have descended from the original escaped pair and spread quickly over the Cape Peninsular mountain range. Most of the population has been culled to make way for the reintroduction of the indigenous antelope, the klipspringer.
The Himalayan tahr is present in New Mexico which would probably indicate it can also be found in other southwestern states. According to the New Mexico Department of Game and Fish news release dated May 28, 2014, "Only one Wildlife Management Area, Water Canyon, allows hunting for nongame species as a management tool for the non-native Himalayan tahr, a large ungulate related to the wild goat."
Success as an invasive species
A key factor contributing to the success of the Himalayan tahr as an invasive species is their mobility. During the night, they move to locations with lower elevations to have better access to resources such as food and water, whereas during the day, they move to locations with higher elevation to rest and avoid predators. This mobile behavior not only allows them to seek refuge from predators, but also allows them to have access to resources over a large area.
Another key characteristic that allows Himalayan tahr to be successful as an invasive species is their digestive tract. Their digestive system allows them to consume a wide variety of vegetation ranging from easy-to-digest leaves/grasses to woody shrubs and other “tough” vegetation not as easily digested by other species. This flexibility in diet not only allows Himalayan tahr to have a competitive advantage for resource use in their environment among other species, but it also allows them to be less hindered by abiotic disruptions and other natural disasters. In other words, their ability to digest a large range of vegetation allows the Himalayan tahr to have a bigger fundamental niche, and as a result, increases their success as an invasive species.
Impact as an invasive species
A negative impact the Himalayan tahrs have on their environment is increased herbivory on the native vegetation of the ecosystem, which can make it harder for other herbivores to find food. The increased herbivory can also lead to a decrease in soil nutrients, such as oxygen, nitrates, and ammonia, resulting in positive feedback loop, making it harder for plants to grow at all. Consequently, the natural fauna of the ecosystem is heavily affected. For example, endangered camelids were forced to adapt and move to higher elevations due to the increased herbivory from the Himalayan tahr. This increase has also resulted in poor soil quality in many environments occupied by the Himalayan tahr and has severely limited the presence of certain plant species. The lack of certain vegetation, in turn, may affect animal species that rely on them as a food source.
Data on the rapid expansion of the tahr are documented by government agencies. Over a time span of 16 years, the Himalayan tahr reached up to 33 tahr/km2 in New Zealand - twice the initial population (2*N0). Without regulated hunting or the presence of natural barriers, the Himalayan tahr can pose a large threat to the indigenous fauna and flora populations within the area.
In 1930, the tahr was denied protection by the Animals Protection and Game Act (1921–22) and was thus recognized as a danger to the environment (although the species is still considered to be endangered in the Himalayas by the World Conservation Union). Since 1937, various government operations have been undertaken to reduce tahr population and/or keep it at fixed numbers. The control of tahr remains ecologically and economically significant because of their widespread destruction of native flora and fauna and their valuable capture for hunters, respectively.
Control by hunting
In 1993, New Zealand’s Department of Conservation prepared the Himalayan Tahr Control Plan which lists “aerial game recovery operations, recreational and safari hunting as primary means of control”. Under the plan, the area of the tahr distribution was divided into two exclusion zones and seven management units. The exclusion zones set boundaries on the area that the tahr inhabits, with the official control operations to be employed to prevent them from spreading beyond those zones. The management unit has a fixed maximum density, which varies from 1-2.5 tahr/km2 and is considered to be low enough to have a minimal negative impact on the ecosystem and, even, restore native vegetation. Under these conditions, the plan aimed to keep tahr numbers below 10,000 throughout the South Island. Since then, New Zealand’s Department of Conservation has been actively advertising tahr hunting and has created 59 tahr-hunting areas. Hunting remains primary means of control of the invasive species; government operations have killed more than 24,000 tahrs by shooting since 1993. As a primary method of tahr population control (although hard to quantify), hunting seems to be an efficient strategy because a large number of people take part in it. In general, hunting is a good method of biological control because it has a direct impact on tahr population and minimal indirect consequences on the surrounding ecology.
Control by poisoning
In 1960, sodium monofluoroacetate (also known as compound 1080) was used to poison tahrs. This derivative of fluoroacetic acid is commonly used in many countries such as Mexico, Australia, the United States, and New Zealand as a pesticide. Compound 1080 is highly water-soluble and is diluted by rainwater and broken down by aquatic microorganisms. Water samples after baiting operations did not reveal dangerous levels of the compound. In the soil, sodium monofluoroacetate is converted by bacteria and fungi to metabolic products, shown to be nonhazardous to the environment.
According to Australia’s Department of Primary Industries, Parks, Water, and Environment, mammals (particularly cats and dogs) are the most susceptible to compound 1080 poisoning. Fish, birds, and amphibians generally are highly tolerant to the poison. Although compound 1080 is a strong enough pesticide to eradicate the entire tahr population, political pressures from hunter groups hinder its use. Opposition by the general public also contributes to the decreased use of 1080 with concerns that the accumulation of 1080 at higher levels of the food chain will pose danger to mammals such as dogs, deer and pigs.
Current control method
The success of the Tahr Control Plan, as well as the future of tahr in New Zealand, can be seen from the report prepared by Kenneth F.D. Hughey and Karen M. Wason, which presents survey results conducted among farmers living within tahr distribution. As they demonstrate, roughly 80% of farmers view tahrs as a resource, not as a threat. The respondents indicated they place conservational and commercial value (live animal/meat, hunting, farming) on tahrs. Thirty six percent of these farmers also reported to having earned at least $1,000 a year in profit from having tahrs on their property, with the highest earnings being above $50,000 (Table 5.5 of that study), usually as a result of allowing professionally guided hunters on their property. Also, a 1988 study showed that hunters spent $851 per person per year on hunting, with expenses being greatest for big-game targets, such as the Himalayan tahr. The fact that the tahr is no longer viewed by general public as an unwanted species may indicate their numbers are now successfully reduced to an acceptable range. This reflects the Department of Conservation’s efforts to promote tahr hunting, consistent monitoring for the trends in tahr population, and official control operations. In New Zealand alone, an estimated $840M have been spent on alien species per year (0.9% of GNP), 25% being towards vertebrate mammals. Of these total costs, $400 M have been dedicated to defense against the invasive species. If conditions maintain, “the total cost of alien vertebrates in New Zealand may therefore exceed $270 million per year”. However, as shown above, these costs may come along with some negative environmental effects on native ecosystems.
- Bhatnagar, Y. V. & Lovari, S. (2008). "Hemitragus jemlahicus". IUCN Red List of Threatened Species. Version 2016.2. International Union for Conservation of Nature.
- Ropiquet, A.; Hassanin, A. (2005). "Molecular evidence for the polyphyly of the genus Hemitragus (Mammalia, Bovidae)". Molecular Phylogenetics and Evolution. 36 (1): 154–168. doi:10.1016/j.ympev.2005.01.002.
- Grubb, P. (16 November 2005). Wilson, D.E.; Reeder, D.M., eds. Mammal Species of the World: A Taxonomic and Geographic Reference (3rd ed.). Johns Hopkins University Press. ISBN 978-0-8018-8221-0. OCLC 62265494.
- Simpson, J. A., and E. S. C. Weiner. The Oxford English Dictionary. 20 vols. 2nd ed. New York: Oxford University Press, 1989.
- Theodor, Jessica M (2001). "Artiodactyla (Even-Toed Ungulates Including Sheep and Camels)". Encyclopedia of Life Sciences. doi:10.1038/npg.els.0001570.
- Pohle, H. (1944). "Hemitragus jemlahicus schaeferi sp. n., die östliche Form des Thars". Zoologischer Anzeiger. 144 (9/10): 184–91.
- "Himalayan tahr", http://www.ultimateungulate.com/tahrhim.html, (Nov. 2001).
- Smith, A. T., Yan Xie, Hoffman, R., Lunde, D., MacKinnon, J., Wilson, D. E. and Wozencraft, W. C. 2008. A Guide to the Mammals of China. Princeton University Press, Princeton, New Jersey.
- Forsyth, David M.; Duncan, Richard P.; Tustin, Ken G.; Gaillard, Jean-Michel (2005). "A Substantial Energetic Cost to Male Reproduction in a Sexually Dimorphic Ungulate". Ecology. 86 (8): 2154–2163. doi:10.1890/03-0738.
- Lovari, S.; Pellizzi, B.; Boesi, R.; Fusani, L. (2009). "Mating Dominance Amongst Male Himalayan Tahr: Blonds Do Better". Behavioural Processes. 81 (1): 20–25. doi:10.1016/j.beproc.2008.12.008.
- UCN 2012. IUCN Red List of Threatened Species: Hemitragus Jemlahicus (Himalayan Tahr). Version 2012.2 Accessed February 24, 2013. http://www.iucnredlist.org/details/9919/0.
- Watson, Michael(2007). "Aspects of the feeding ecology of Himalayan tahr (Hemitragus jemlacicus), some comparisons with chamois (Rupicapra rupicapra rupicapra) and implications for tahr management in New Zealand" . Lincoln University.
- Clauss, M., Hummel, J., Vercammen, F., Streich, W. J., (30 June 2005) Observations on the Macroscopic Digestive Anatomy of the Himalayan Tahr (hemitragus jemlahicus). Anatomia, Histologia, Embryologia.
- Himalayan tahr (Hemitragus jemlahicus). Arkive. http://www.arkive.org/himalayan-tahr/hemitragus-jemlahicus/
- Ale, Som B. "Ecology of the Snow Leopard and the Himalayan Tahr in Sagarmatha (Mt. Everest) National Park, Nepal." University of Illinois, 2007. http://www.carnivoreconservation.org/files/thesis/ale_2007_phd.pdf.
- DPIPWE (2011) Pest Risk Assessment: Himalayan tahr (Hemitragus jemlahicus). Department of Primary Industries, Parks, Water and Environment. Hobart, Tasmania.
- Christe, A. H. C., Andrews, J. R. H., (July 1964) Introduced Ungulates in New Zealand- Himalayan Tahr. Tuatara: Volume 12, Issue 2.
- Dickinson, Peter. "Zoo News Digest: The Return of the Tahr." Zoo News Digest. 1 Feb. 2010. Web. 12 Mar. 2013.
- Flueck, Werner (2009). "The Slippery Slope of exporting invasive species: the case of Himalayan tahr arriving in South America". Biological Invasions. 12: 1467–1475. doi:10.1007/s10530-009-9590-5.
- Andrews, J.R.H.; Christie, A. H.C. (1964). "Introduced ungulates in New Zealand: (a) Himalayan Tahr". Journal of the Biological Society. 12: 69–77.
- 2001. Himalayan Tahr. Blue Planet Biomes. http://www.blueplanetbiomes.org/himalayan_tahr.htm
- Himalayan Thar Control Plan. Canterbury Conservancy Conservation Management Series No 2. Department of Conservation, Christchurch, New Zealand.
- Poison 1080. Department of Primary Industries, Parks, Water, and Environment. <http://www.dpiw.tas.gov.au/inter/nsf/WebPages/RPIO-4ZM7CX?open>.
- Suren, A.; Lambert, P. (2006). "Do toxic baits containing sodium fluroacetate (1080) affect fish and invertebrate communities when they fall into streams?". New Zealand Journal of Marine and Freshwater Research. 40 (4): 531–546. doi:10.1080/00288330.2006.9517443.
- Eason, C. T.; Wright, G. R.; Fitzgerald, H. (1992). "Sodium Monofluoroacetate (1080) Water-Residue Analysis after Large-Scale Possum Control". New Zealand Journal of Ecology. 16 (1): 47–49.
- Clout, M. N. 2002. Ecological and economic costs of alien species in New Zealand. Pages 190-193 in D. Pimentel, editor. Biological Invasions. CRC Pres
- K. F.D. Hughey, Wason K. M. 2005. Management of HImalayan Tahr in New Zealand. High Country Farmer Perspectives and Implications. Lincoln University.
- Nugent, G (1992). "Big-game, small-game, and gamebird hunting in New Zealand: Hunting effort, harvest, and expenditure in 1988". New Zealand Journal of Zoology. 19.
|Wikimedia Commons has media related to Himalayan Tahr.|
- ARKive – Images and movies of the Himalayan tahr (Hemitragus jemlahicus)
- Fact sheet on the Himalayan tahr