Critically Endangered Arabian leopards Panthera pardus nimr in Israel: estimating population parameters using molecular scatology

Inbar Perez; Eli Geffen; Ofer Mokady

doi:10.1017/S0030605306000846

Abstract

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The Critically Endangered Arabian leopard Panthera pardus nimr faces severe reduction in population size and is on the brink of extinction. This situation is, to a large extent, a result of human activity. The small populations of this subspecies are restricted to a few areas in the Arabian Peninsula, Israel and Jordan. Information required for conservation of this subspecies, including reliable population estimates and the range of individuals, is currently unavailable. To estimate population size and assign gender to individuals in the population in Israel we used molecular markers in leopard DNA extracted from scats collected in intensive surveys throughout the Judean Desert and the Negev Highlands. This non-invasive mode of sampling, combined with the availability of high-resolution markers (microsatellites) and sex-specific DNA-sequences, was successful in identifying both individuals and gender. The results indicated the existence of a male and two females in the Judean Desert, and four males and one female in the Negev Highlands. Although the non-invasive procedure we used may underestimate the leopard's true population size, continuous monitoring of population size and sex composition of this small population using scatology is a key component for the management of this species. These data, especially if used in conjunction with similar data from other countries within the subspecies' range, will assist in the establishment of conservation plans for the Arabian leopard.

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Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

BROMAGHIN, JEFFREY F. 2007. The genetic mark–recapture likelihood function of capwire. Molecular Ecology, Vol. 16, Issue. 23, p. 4883.

Mondol, Samrat R, Navya Athreya, Vidya Sunagar, Kartik Selvaraj, Velu Mani and Ramakrishnan, Uma 2009. A panel of microsatellites to individually identify leopards and its application to leopard monitoring in human dominated landscapes. BMC Genetics, Vol. 10, Issue. 1,

HARRIS, RICHARD B. WINNIE, JOHN AMISH, STEPHEN J. BEJA‐PEREIRA, ALBANO GODINHO, RAQUEL COSTA, VǍNIA and LUIKART, GORDON 2010. Argali Abundance in the Afghan Pamir Using Capture–Recapture Modeling From Fecal DNA. The Journal of Wildlife Management, Vol. 74, Issue. 4, p. 668.

STENGLEIN, J. L. DE BARBA, M. AUSBAND, D. E. and WAITS, L. P. 2010. Impacts of sampling location within a faeces on DNA quality in two carnivore species. Molecular Ecology Resources, Vol. 10, Issue. 1, p. 109.

Janečka, Jan E. Munkhtsog, Bariushaa Jackson, Rodney M. Naranbaatar, Galsandorj Mallon, David P. and Murphy, William J. 2011. Comparison of noninvasive genetic and camera-trapping techniques for surveying snow leopards. Journal of Mammalogy, Vol. 92, Issue. 4, p. 771.

Dutta, Trishna Sharma, Sandeep Maldonado, Jesús E. Wood, Thomas C. and Seidensticker, John 2012. A reliable method for individual identification and gender determination of wild leopards (Panthera pardus fusca) using non-invasive samples. Conservation Genetics Resources, Vol. 4, Issue. 3, p. 665.

Dutta, Trishna Sharma, Sandeep Maldonado, Jesús E. Wood, Thomas C. Panwar, H. S. Seidensticker, John and Austin, Jeremy 2013. Fine‐scale population genetic structure in a wide‐ranging carnivore, the leopard (Panthera pardus fusca)in centralIndia. Diversity and Distributions, Vol. 19, Issue. 7, p. 760.

Mukesh Sharma, Lalit K Kumar, Ved P Charoo, Samina A Mohan, Nipun Goyal, Surendra P and Sathyakumar, Sambandam 2013. Loss of genetic diversity and inbreeding in Kashmir red deer (Cervus elaphus hanglu) of Dachigam National Park, Jammu & Kashmir, India. BMC Research Notes, Vol. 6, Issue. 1,

Kerth, Gerald Gusset, Markus Garbely, Jari König, Barbara Gabanapelo, Tefo and Schiess-Meier, Monika 2013. Genetic sexing of stock-raiding leopards: not only males to blame. Conservation Genetics Resources, Vol. 5, Issue. 4, p. 1101.

Rodgers, Torrey W. and Janečka, Jan E. 2013. Applications and techniques for non-invasive faecal genetics research in felid conservation. European Journal of Wildlife Research, Vol. 59, Issue. 1, p. 1.

Stein, Andrew B. and Hayssen, Virginia 2013. Panthera pardus(Carnivora: Felidae). Mammalian Species, Vol. 900, Issue. , p. 30.

Moore, Deborah L. and Vigilant, Linda 2014. A population estimate of chimpanzees (Pan troglodytes schweinfurthii) in the Ugalla region using standard and spatially explicit genetic capture–recapture methods. American Journal of Primatology, Vol. 76, Issue. 4, p. 335.

Garrote, Germán de Ayala, Ramón Pérez and Tellería, José Luis 2014. A comparison of scat counts and camera-trapping as means of assessing Iberian lynx abundance. European Journal of Wildlife Research, Vol. 60, Issue. 6, p. 885.

Roques, S. Furtado, M. Jácomo, A. T. A. Silveira, L. Sollmann, R. Tôrres, N. M. Godoy, J. A. and Palomares, F. 2014. Monitoring jaguar populationsPanthera oncawith non-invasive genetics: a pilot study in Brazilian ecosystems. Oryx, Vol. 48, Issue. 3, p. 361.

Khorozyan, Igor 2014. Morphological variation and sexual dimorphism of the common leopard (Panthera pardus) in the Middle East and their implications for species taxonomy and conservation. Mammalian Biology, Vol. 79, Issue. 6, p. 398.

Rodgers, Torrey W. Giacalone, Jacalyn Heske, Edward J. Janečka, Jan E. Phillips, Christopher A. and Schooley, Robert L. 2014. Comparison of Noninvasive Genetics and Camera Trapping for Estimating Population Density of Ocelots (Leopardus Pardalis) on Barro Colorado Island, Panama. Tropical Conservation Science, Vol. 7, Issue. 4, p. 690.

Mondol, Samrat Kumar, N. Samba Gopalaswamy, Arjun Sunagar, Kartik Karanth, K. Ullas and Ramakrishnan, Uma 2015. Identifying species, sex and individual tigers and leopards in the Malenad-Mysore Tiger Landscape, Western Ghats, India. Conservation Genetics Resources, Vol. 7, Issue. 2, p. 353.

Giotto, Nina Gerard, Jean-François Ziv, Alon Bouskila, Amos Bar-David, Shirli and Crowther, Mathew S. 2015. Space-Use Patterns of the Asiatic Wild Ass (Equus hemionus): Complementary Insights from Displacement, Recursion Movement and Habitat Selection Analyses. PLOS ONE, Vol. 10, Issue. 12, p. e0143279.

SOROKIN, Pavel A. ROZHNOV, Vyatcheslav V. KRASNENKO, Anna U. LUKAREVSKIY, Victor S. NAIDENKO, Sergey V. and HERNANDEZ‐BLANCO, Jose A. 2016. Genetic structure of the Amur tiger (Panthera tigris altaica) population: Are tigers in Sikhote‐Alin and southwest Primorye truly isolated?. Integrative Zoology, Vol. 11, Issue. 1, p. 25.

Zanin, Marina Adrados, Begoña González, Noa Roques, Severine Brito, Daniel Chávez, Cuauhtemoc Rubio, Yamel and Palomares, Francisco 2016. Gene flow and genetic structure of the puma and jaguar in Mexico. European Journal of Wildlife Research, Vol. 62, Issue. 4, p. 461.

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Critically Endangered Arabian leopards Panthera pardus nimr in Israel: estimating population parameters using molecular scatology

Abstract

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This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

Critically Endangered Arabian leopards Panthera pardus nimr in Israel: estimating population parameters using molecular scatology

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