Hostname: page-component-cd9895bd7-7cvxr Total loading time: 0 Render date: 2024-12-23T12:12:34.342Z Has data issue: false hasContentIssue false

Genetics and the last stand of the Sumatran rhinoceros Dicerorhinus sumatrensis

Published online by Cambridge University Press:  09 May 2013

Benoît Goossens*
Affiliation:
Organisms and Environment Division, Cardiff School of Biosciences, Cardiff University, Cardiff, UK.
Milena Salgado-Lynn
Affiliation:
Organisms and Environment Division, Cardiff School of Biosciences, Cardiff University, Cardiff, UK.
Jeffrine J. Rovie-Ryan
Affiliation:
Ex-Situ Conservation Division, Department of Wildlife and National Parks, Kuala Lumpur, Malaysia
Abdul H. Ahmad
Affiliation:
Institute for Tropical Biology and Conservation, Universiti Malaysia Sabah, Kota Kinabalu, Sabah, Malaysia
Junaidi Payne
Affiliation:
Borneo Rhino Alliance, Kota Kinabalu, Sabah, Malaysia
Zainal Z. Zainuddin
Affiliation:
Borneo Rhino Alliance, Kota Kinabalu, Sabah, Malaysia
Senthilvel K. S. S. Nathan
Affiliation:
Sabah Wildlife Department, Wisma Muis, Kota Kinabalu, Sabah, Malaysia
Laurentius N. Ambu
Affiliation:
Sabah Wildlife Department, Wisma Muis, Kota Kinabalu, Sabah, Malaysia
*
(Corresponding author) E-mail [email protected]
Rights & Permissions [Opens in a new window]

Abstract

The Sumatran rhinoceros Dicerorhinus sumatrensis is on the brink of extinction. Although habitat loss and poaching were the reasons of the decline, today's reproductive isolation is the main threat to the survival of the species. Genetic studies have played an important role in identifying conservation priorities, including for rhinoceroses. However, for a species such as the Sumatran rhinoceros, where time is of the essence in preventing extinction, to what extent should genetic and geographical distances be taken into account in deciding the most urgently needed conservation interventions? We propose that the populations of Sumatra and Borneo be considered as a single management unit.

Type
Rhinoceros conservation
Copyright
Copyright © Fauna & Flora International 2013 

The rhinos…are unaware of their precarious existence. Their fate depends wholly on us, on our commitment to protect them forever. E. Dinerstein (Reference Dinerstein2003)

Introduction

With as few as 216 wild individuals worldwide (Ahmad Zafir et al., Reference Ahmad Zafir, Payne, Mohamed, Lau, Sharma and Alfred2011), the Sumatran rhinoceros Dicerorhinus sumatrensis is on the brink of extinction. Following a recent report by WWF on the fate of the Javan rhinoceros Rhinoceros sondaicus in Vietnam (Brook et al., Reference Brook, Van Coeverden de Groot, Mahood and Long2011), are we to witness the loss of another rhinoceros species? Genetic studies have played an important role in identifying conservation priorities (Moritz, Reference Moritz1994, Reference Moritz2002; De Salle & Amato, Reference DeSalle and Amato2004; Caballero et al., Reference Caballero, Rodríguez-Ramilo, Ávila and Fernández2009; Frankham, Reference Frankham2009; Laikre, Reference Laikre2010), including for species of rhinoceros (Ashley et al., Reference Ashley, Melnick and Western1990; Dinerstein & McCracken, Reference Dinerstein and McCracken1990; Amato et al., Reference Amato, Wharton, Zainuddin and Powell1995; Morales et al., Reference Morales, Andau, Supriatna, Zainuddin and Melnick1997; Harley et al., Reference Harley, Baumgarten, Cunningham and O'Ryan2005; Fernando et al., Reference Fernando, Polet, Foead, Ng, Pastorini and Melnick2006; Scott, Reference Scott2008; Kim, Reference Kim2009; Willerslev et al., Reference Willerslev, Gilbert, Binladen, Ho, Campos and Ratan2009). However, for a species such as the Sumatran rhinoceros, where time is of the essence in preventing extinction, to what extent should genetic and geographical distances be taken into account in deciding the most urgently needed human interventions?

Since its appearance in the Eocene, the family Rhinocerotidae has comprised > 40 genera (Guerin, Reference Guerin1989; Cerdeño, Reference Cerdeño1998). Nowadays it includes only four genera, with a total of five species (but see Groves et al., Reference Groves, Fernando and Robovský2010). Comparisons of mitochondrial (mt) DNA sequences (including whole mt genomes) of contemporary Asian, African and fossil rhinoceros DNA suggest that the Sumatran rhinoceros is the most primitive extant species of the family and the closest related living species to the ancient woolly rhinoceros Coelodonta antiquititas (Morales & Melnick, Reference Morales and Melnick1994; Cerdeño, Reference Cerdeño1998; Tougard et al., Reference Tougard, Delefosse, Hänni and Montgelard2001; Orlando et al., Reference Orlando, Leonard, Thenot, Laudet, Guerin and Hänni2003; Willerslev et al., Reference Willerslev, Gilbert, Binladen, Ho, Campos and Ratan2009). Formerly existing across South-east Asia, including Thailand and Myanmar, the Sumatran rhinoceros is now Critically Endangered, with a decreasing population trend (IUCN, 2011), and confined to a few disjunct populations in Indonesia (Sumatra) and Malaysia (Borneo). The situation has been described as a problem of political endemism (Moritz, Reference Moritz2002). In the mid 1980s the governments of Indonesia and Malaysia, and international conservation organizations, supported management plans that included greater protection of wild populations and habitats, a controversial captive-breeding programme, and research (Khan, Reference Khan1989; Rabinowitz, Reference Rabinowitz1995; Foose & van Strien, Reference Foose and van Strien1997; Dinerstein, Reference Dinerstein2003). Today, there are 10 individuals in captivity: one female in Cincinnati Zoo and one male in Los Angeles Zoo (USA), two males (including a calf) and three females in the Sumatran Rhino Sanctuary at Way Kambas (Sumatra, Indonesia) and one male and two females at the Borneo Rhino Sanctuary (Sabah, Malaysia).

Genetics and management

The geographical delimitation of the subspecies of rhinoceros on Sumatra was previously unclear and the question arose as to whether the populations in Peninsular Malaysia, Sumatra and Borneo (Fig. 1) should be treated as different management units, to preserve genetic diversity (Foose & van Strien, Reference Foose and van Strien1997). The issue persisted even after the 2009 meeting of the Sumatran Rhino Global Management and Propagation Board (responsible for management of the captive population of Sumatran rhinoceros; GMPB Technical Committee, 2009). However, in 1995 Amato et al. had already confirmed Groves’ division of taxa, grouping individuals from Sumatra and Peninsular Malaysia as a single taxon (Groves, Reference Groves1965, Reference Groves1967, Reference Groves and Ryder1993). Almost in parallel, Morales et al. (Reference Morales, Andau, Supriatna, Zainuddin and Melnick1997) analysed the phylogeographic structure of D. s. harrissoni and D. s. sumatrensis. Both studies highlighted the differentiation of the Bornean population as a separate evolutionary unit. However, for Amato et al. (Reference Amato, Wharton, Zainuddin and Powell1995) the genetic differentiation was not enough evidence to support more than one conservation unit for the Sumatran rhinoceros, whereas Morales et al. (Reference Morales, Andau, Supriatna, Zainuddin and Melnick1997) advocated for the treatment of D. s. harrissoni (Borneo) and D. s. sumatrensis (Pensinsular Malaysia and Sumatra) as distinct management units. Morales et al. (Reference Morales, Andau, Supriatna, Zainuddin and Melnick1997) argued that an average genetic divergence of 1% between the rhinoceros populations of Sumatra and Borneo justified treating them as separate conservation units. However, a range of 0–4% has been observed between other mammalian conspecifics (Avise & Lansman, Reference Avise, Lansman, Nei and Koehn1983), and 0–2% has been observed among members of the same local population (Nei, Reference Nei1972). A recent study requested by the GMPB shows a close relationship between the three populations (Borneo, Peninsular Malaysia, and Sumatra; J. Rovie-Ryan et al., unpubl. data).

Fig. 1 The distribution of the Sumatran rhinoceros Dicerorhinus sumatrensis subspecies in Sumatra, Peninsular Malaysia and Sabah. The priority areas are Danum Valley Conservation Area (1), Tabin Wildlife Reserve (2), Bukit Barisan Selatan National Park (3) and Way Kambas National Park (4). Areas identified by the IUCN Asian Rhino Specialist Group as requiring scientifically defensible population estimates to confirm conservation status are Royal Belum State Park (5), Taman Negara National Park (6), Endau Rompin National Park (7) and Gunung Leuser National Park (8) (Ahmad Zafir et al., Reference Ahmad Zafir, Payne, Mohamed, Lau, Sharma and Alfred2011).

The three genetic studies (Amato et al., Reference Amato, Wharton, Zainuddin and Powell1995; Morales et al., Reference Morales, Andau, Supriatna, Zainuddin and Melnick1997; J. Rovie-Ryan et al., unpubl. data) were based solely on mtDNA but reliance on mtDNA in phylogenetics has been contentious since 2005 when it became clear that individual genes and species phylogenetic trees are not always congruent (Ballard & Rand, Reference Ballard and Rand2005; Hurst & Jiggins, Reference Hurst and Jiggins2005; Rubinoff & Holland, Reference Rubinoff and Holland2005, Wiens et al., Reference Wiens, Kuczynski and Stephens2010). In the case of the family Rhinocerotidae there are difficulties in satisfactorily resolving the rhinoceros phylogeny even using the whole mitochondrial genome (Morales & Melnick, Reference Morales and Melnick1994; Tougard et al., Reference Tougard, Delefosse, Hänni and Montgelard2001; Orlando et al., Reference Orlando, Leonard, Thenot, Laudet, Guerin and Hänni2003; Fernando et al., Reference Fernando, Polet, Foead, Ng, Pastorini and Melnick2006; Willerslev et al., Reference Willerslev, Gilbert, Binladen, Ho, Campos and Ratan2009), and resolution may not be achieved without additional analyses of substantial amounts of nuclear DNA (Willerslev et al., Reference Willerslev, Gilbert, Binladen, Ho, Campos and Ratan2009). However, the subspecies’ genetic differences, as shown by mtDNA in the three separate studies, seem to be minimal. In our roles as biologists, wildlife managers, veterinarians and geneticists closely involved in ongoing efforts to prevent the extinction of the Sumatran rhinoceros in Sabah (northern Borneo, Malaysia) we strongly believe that the observed differences do not justify keeping the Sumatran and Bornean populations as separate management units. This is now even more so, in view of (1) the low and declining number of individuals in each Bornean and Sumatran wild population, (2) that at least two of the 10 individuals in captivity are too old to breed, and (3) that three of those are closely-related males.

A study of the Javan rhinoceros showed that it had low genetic diversity and that there was a critical need for population expansion for the species to survive (Fernando et al., Reference Fernando, Polet, Foead, Ng, Pastorini and Melnick2006). Despite clear results demonstrating that the Ujung Kulon (Indonesia) and Cat Tien (Vietnam) populations represented separate evolutionary significant units it was argued that demographic considerations should override genetic issues in the short term. The Indonesian and Vietnamese governments were urged to exchange Javan rhinoceroses before it was too late. No action was taken and, in Cat Tien National Park, the last individual in Vietnam was found dead in April 2010 (Brook et al., Reference Brook, Van Coeverden de Groot, Mahood and Long2011).

In addition to the low genetic differentiation between the geographical populations of the Sumatran rhinoceros, the family Rhinocerotidae is chromosomally conservative. All species have a karyotype of 2n = 82 despite sharing a common ancestor more than 15 million years ago (Houck et al., Reference Houck, Ryder, Vahala, Kock and Oosterhuis1994). This chromosomal conservation reduces concerns about cytogenetic incompatibility between the populations of Sumatra and Borneo. The shared karyotype coupled with the degree of sequence divergence make outbreeding depression a less likely outcome if individuals, or their gametes, are translocated as part of a conservation management plan.

The genetic diversity of the Sumatran rhinoceros is probably also low (Amato et al., Reference Amato, Wharton, Zainuddin and Powell1995; Morales et al., Reference Morales, Andau, Supriatna, Zainuddin and Melnick1997; J. Rovie-Ryan et al., unpubl. data), and evidence is starting to accumulate that the Bornean population may have reduced reproductive fitness (S. Nathan, pers. comm.) possibly indicating inbreeding depression (Crnokrak & Roff, Reference Crnokrak and Roff1999). Where no unrelated individuals of the same taxon are available, individuals from another subspecies can, in extremis, be used to alleviate inbreeding depression (Frankham et al., Reference Frankham, Ballou and Briscoe2002; Tallmon et al., Reference Tallmon, Luikart and Waples2004; Allendorf & Luikart, Reference Allendorf and Luikart2007). Members of the American Association of Zoological Parks and Aquariums have concluded that mixing of subspecies is appropriate when the extinction of the smallest population would jeopardise the higher taxon (Ryder, Reference Ryder1986), as is the case of the Sumatran rhinoceros and the population of Sabah. From a genetic perspective, the worst situation is where a threatened species exists as a single, inbred population, with no subspecies or related species with which to hybridize. In a few cases, some taxa might only be recovered through the use of intentional hybridization, yet this is least likely to result in outbreeding depression when there is limited genetic divergence between populations (Allendorf & Luikart, Reference Allendorf and Luikart2007).

Genetic rescue

To alleviate or prevent deleterious genetic consequences in isolated fragments, gene flow can be re-established by genetic rescue: moving individuals (translocation) or gametes (usually sperm, or pollen for plants) (Frankham et al., Reference Frankham, Ballou and Briscoe2002; Hogg et al., Reference Hogg, Forbes, Steele and Luikart2006; Allendorf & Luikart, Reference Allendorf and Luikart2007; Hedrick & Fredrickson, Reference Hedrick and Fredrickson2009). The classic example of genetic rescue (or genetic restoration, see Hedrick, Reference Hedrick2005) by intentional hybridization comes from the Florida panther Puma concolor coryi. A population of < 50 inbred individuals was augmented with individuals from another subspecies (P. c. stanleyana) and in only 4 years the Florida panther no longer had a high risk of extinction (Hedrick, Reference Hedrick1995; Maehr et al., Reference Maehr, Lacy, Land, Bass, Hoctor, Beissinger and McCullough2002), with numbers increasing by 14% per year between 1996 and 2003 (Johnson et al. Reference Johnson, Onorato, Roelke, Land, Cunningham and Belden2010). Translocation of individuals among populations may be costly, especially for large animals, and carries the risks of injury, disease transmission and behavioural disruption when individuals are released (Frankham et al., Reference Frankham, Ballou and Briscoe2002; Tallmon et al., Reference Tallmon, Luikart and Waples2004; Bouzat et al., Reference Bouzat, Johnson, Toepfer, Simpson, Esker and Westemeier2008). The 1989 Asian Rhino Action Plan (Khan, Reference Khan1989) placed great emphasis on ex situ programmes for Asian Rhinoceros. Success was achieved in India and Nepal but not for the Sumatran rhinoceros. Foose & van Strien (Reference Foose and van Strien1997) demonstrated a 60% mortality of the captured animals during the 1980s.

Genome resource banking

A viable alternative for the genetic restoration of the Sumatran rhinoceros is genome resource banking (systematic banking of genome resources using cryopreservation) (Johnston & Lacy, Reference Johnston and Lacy1995; Holt & Pickard, Reference Holt and Pickard1999). This procedure can facilitate managed gene flow into isolated populations without the risks of translocating individuals (Allendorf & Luikart, Reference Allendorf and Luikart2007). Genome resource banking coupled with artificial insemination or in vitro fertilization can reduce translocation costs and also equalize sex ratios of breeders by inseminating females with semen from males other than the local dominant, or sole, male (Fickel et al., Reference Fickel, Wagener and Ludwig2007). The first successful artificial insemination in a white rhinoceros was performed in 2007 using fresh semen (Hildebrandt et al., Reference Hildebrandt, Hermes, Walzer, Sós, Molnar and Mezösi2007). In 2009 the frozen and then thawed semen of a white rhinoceros was used successfully in an artificial insemination, thus proving resource banking useful (Hermes et al., Reference Hermes, Göritz, Saragusty, Sós, Molnar and Reid2009). Implementation of such procedures may now be key for preventing the extinction of the Sumatran rhinoceros.

Conclusion

It has been 18 months since the Sumatran Rhino Global Management and Propagation Board decided that further genetic studies are not necessary to reach a decision to treat the captive populations (Way Kambas in Sumatra, Borneo Rhino Sanctuary in Borneo, and Cincinnatti Zoo in the USA) as a single population following the predictions of a population viability analysis (GMPB 2011, unpubl. data) and the genetic arguments advanced here, and to combine efforts to improve gamete transfer (through genome resource banking) between captive Sumatran rhinoceroses. Perhaps the recent capture of Puntung, a young wild female, in Sabah (Borneo Post Online, 2011) will boost government endorsement of the need to exchange gametes between countries. Actions to initiate genome resource banking and artificial insemination or in vitro fertilization are underway in Borneo (S. Nathan, pers. comm.; Sabah Wildlife Department, 2011). Any further prevarication in the use of all possible techniques to boost reproduction in the Sumatran rhinoceros, including the mixing of gametes between populations considered to be separate subspecies, will mean the eventual extinction of populations of Sumatran rhinoceros in Borneo and Sumatra, duplicating the tragedy of the extinction of the Javan rhinoceros population in Vietnam. By agreeing to exchange the animals’ gametes, the Indonesian and Malaysian governments will have made an historical step towards the survival of one of the most charismatic, ancient and enigmatic large mammals.

Biographical sketches

The team has a common interest in bringing the Sumatran rhinoceros back from the brink of extinction. Benoît Goossens and Milena Salgado-Lynn focus their research on biodiversity responses to habitat fragmentation and degradation. They integrate approaches such as landscape ecology, geographical information systems, animal behaviour, wildlife disease, parasitology and population genetics to understand animal adaptation to landscape disturbance. Jeffrine Rovie-Ryan is a population geneticist. Abdul Ahmad is chairman of the Borneo Rhino Alliance and has a special interest in the ecology and conservation of large mammals. Junaidi Payne is a wildlife ecologist with more than 30 years of experience in tropical ecology and wildlife conservation. Zainal Zainuddin is a wildlife veterinarian working for BORA and managing the Borneo Rhino Sanctuary in Tabin Wildlife Reserve. Senthilvel Nathan is the Chief Wildlife Veterinarian of Sabah Wildlife Department and is currently studying the conservation genetics of the proboscis monkey. Laurentius Ambu's main interest is in sustainable management of wildlife populations.

References

Ahmad Zafir, A.W., Payne, J., Mohamed, A., Lau, C.F., Sharma, D.S.K., Alfred, R. et al. (2011) Now or never: what will it take to save the Sumatran rhinoceros Dicerorhinus sumatrensis from extinction? Oryx, 45, 225233.CrossRefGoogle Scholar
Allendorf, F.W. & Luikart, G. (2007) Conservation and the Genetics of Populations. Blackwell Publishing, Oxford, UK.Google Scholar
Amato, G., Wharton, D., Zainuddin, Z.Z. & Powell, J.R. (1995) Assessment of conservation units for the Sumatran rhinoceros (Dicerorhinus sumatrensis). Zoo Biology, 14, 395402.CrossRefGoogle Scholar
Ashley, M.V., Melnick, D.J. & Western, D. (1990) Conservation genetics of the black rhinoceros (Diceros bicornis), I: evidence from the mitochondrial DNA of three populations. Conservation Biology, 4, 7177.CrossRefGoogle Scholar
Avise, J.C. & Lansman, R.A. (1983) Polymorphism of mitochondrial DNA in populations of higher animals. In Evolution of Genes and Proteins (eds Nei, M. & Koehn, R.K.), pp. 147164. Sinauer, Sunderland, USA.Google Scholar
Ballard, J.W.O. & Rand, D.M. (2005) The population biology of mitochondrial DNA and its phylogenetic implications. Annual Review of Ecology, Evolution, and Systematics, 36, 621642.CrossRefGoogle Scholar
Borneo Post Online (2011) Christmas miracle, healthy female rhino found in Tabin. Borneo Post, 25 December. Http://www.theborneopost.com/2011/12/25/christmas-miracle-healthy-female-rhino-found-in-tabin [accessed 15 March 2013].Google Scholar
Bouzat, J.L., Johnson, J.A., Toepfer, J.E., Simpson, S.A., Esker, T.L. & Westemeier, R.L. (2008) Beyond the beneficial effects of translocations as an effective tool for the genetic restoration of isolated populations. Conservation Genetics, 10, 191201.CrossRefGoogle Scholar
Brook, S., Van Coeverden de Groot, P., Mahood, S. & Long, B. (2011) Extinction of the Javan Rhinoceros (Rhinoceros sondaicus) from Vietnam. WWF-Vietnam.Google Scholar
Caballero, A., Rodríguez-Ramilo, S.T., Ávila, V. & Fernández, J. (2009) Management of genetic diversity of subdivided populations in conservation programmes. Conservation Genetics, 11, 409419.CrossRefGoogle Scholar
Cerdeño, E. (1998) Diversity and evolutionary trends of the family Rhinocerotidae (Perissodactyla). Palaeogeography, Palaeoclimatology, Palaeoecology, 141, 1334.CrossRefGoogle Scholar
Crnokrak, P. & Roff, D.A. (1999) Inbreeding depression in the wild. Heredity, 83, 260270.CrossRefGoogle ScholarPubMed
DeSalle, R. & Amato, G. (2004) The expansion of conservation genetics. Nature Reviews Genetics, 5, 702712.CrossRefGoogle ScholarPubMed
Dinerstein, E. (2003) The Return of the Unicorns: The Natural History and Conservation of the Greater One-Horned Rhinoceros. Columbia University Press, New York, USA.CrossRefGoogle Scholar
Dinerstein, E. & McCracken, G.F. (1990) Endangered greater one-horned rhinoceros carry high levels of genetic variation. Conservation Biology, 4, 417422.CrossRefGoogle Scholar
Fernando, P., Polet, G., Foead, N., Ng, L.S., Pastorini, J. & Melnick, D.J. (2006) Genetic diversity, phylogeny and conservation of the Javan rhinoceros (Rhinoceros sondaicus). Conservation Genetics, 7, 439448.CrossRefGoogle Scholar
Fickel, J., Wagener, A. & Ludwig, A. (2007) Semen cryopreservation and the conservation of endangered species. European Journal of Wildlife Research, 53, 8189.CrossRefGoogle Scholar
Foose, T.J. & van Strien, N.J. (1997) Asian Rhinos—Status Survey and Conservation Action Plan. IUCN, Gland, Switzerland, and Cambridge, UK.Google Scholar
Frankham, R. (2009) Where are we in conservation genetics and where do we need to go? Conservation Genetics, 11, 661663.CrossRefGoogle Scholar
Frankham, R., Ballou, J.D. & Briscoe, D.A. (2002) Introduction to Conservation Genetics. Cambridge University Press, Cambridge, UK.CrossRefGoogle Scholar
GMPB Technical Committee (2009) Sumatran Rhino Global Management and Propagation Board Meeting 4 & 5 March 2009. Bogor, Indonesia. Http://www.rhinoresourcecenter.com/pdf_files/130/1300587412.pdf [accessed 22 April 2013].Google Scholar
Groves, C.P. (1965) Description of a new subspecies of rhinoceros, from Borneo, Didermocerus sumatrensis harrissoni. Saugetiere Mitteil, 13, 128131.Google Scholar
Groves, C.P. (1967) On the rhinoceroses of South-east Asia. Saugetiere Mitteil, 15, 221237.Google Scholar
Groves, C.P. (1993) Testing rhinoceros subspecies by multivariate analysis. In Rhinoceros Biology and Conservation (ed. Ryder, O.A.), pp. 92100. San Diego Zoological Society, San Diego, USA.Google Scholar
Groves, C.P., Fernando, P. & Robovský, J. (2010) The sixth rhino: a taxonomic re-assessment of the Critically Endangered northern white rhinoceros. PLOS ONE, 5, e9703.CrossRefGoogle Scholar
Guerin, C. (1989) La famille des Rhinocerotidae (Mammalia, Perissodactyla): systématique, histoire, évolution, paléoécolgie. Cranium, 2, 314.Google Scholar
Harley, E.H., Baumgarten, I., Cunningham, J. & O'Ryan, C. (2005) Genetic variation and population structure in remnant populations of black rhinoceros, Diceros bicornis, in Africa. Molecular Ecology, 14, 29812990.CrossRefGoogle ScholarPubMed
Hedrick, P.W. (1995) Gene flow and genetic restoration: the Florida panther as a case study. Conservation Biology, 9, 9961007.CrossRefGoogle ScholarPubMed
Hedrick, P.W. (2005) ‘Genetic restoration:’ a more comprehensive perspective than ‘genetic rescue’. Trends in Ecology & Evolution, 20, 109.CrossRefGoogle ScholarPubMed
Hedrick, P.W. & Fredrickson, R. (2009) Genetic rescue guidelines with examples from Mexican wolves and Florida panthers. Conservation Genetics, 11, 615626.CrossRefGoogle Scholar
Hermes, R., Göritz, F., Saragusty, J., Sós, E., Molnar, V., Reid, C.E. et al. (2009) First successful artificial insemination with frozen-thawed semen in rhinoceros. Theriogenology, 71, 393399.CrossRefGoogle ScholarPubMed
Hildebrandt, T.B., Hermes, R., Walzer, C., Sós, E., Molnar, V., Mezösi, L. et al. (2007) Artificial insemination in the anoestrous and the postpartum white rhinoceros using GnRH analogue to induce ovulation. Theriogenology, 67, 14731484.CrossRefGoogle ScholarPubMed
Hogg, J.T., Forbes, S.H., Steele, B.M. & Luikart, G. (2006) Genetic rescue of an insular population of large mammals. Proceedings of the Royal Society of London B, 273, 14911499.Google ScholarPubMed
Holt, W.V. & Pickard, A.R. (1999) Role of reproductive technologies and genetic resource banks in animal conservation. Reviews of Reproduction, 4, 143150.CrossRefGoogle ScholarPubMed
Houck, M., Ryder, O., Vahala, J., Kock, R. & Oosterhuis, J. (1994) Diploid chromosome number and chromosomal variation in the white rhinoceros (Ceratotherium simum). Journal of Heredity, 85, 3034.Google ScholarPubMed
Hurst, G.D.D. & Jiggins, F.M. (2005) Problems with mitochondrial DNA as a marker in population, phylogeographic and phylogenetic studies: the effects of inherited symbionts. Proceedings of the Royal Society of London B, 272, 15251534.Google ScholarPubMed
IUCN (2011) IUCN Red List of Threatened Species v. 2011.2. http://www.iucnredlist.org [accessed 2 January 2012].Google Scholar
Johnson, W.E., Onorato, D.P., Roelke, M.E., Land, E.D., Cunningham, M., Belden, R.C. et al. (2010) Genetic restoration of the Florida panther. Science, 329, 16411645.CrossRefGoogle ScholarPubMed
Johnston, L. & Lacy, R. (1995) Genome resource banking for species conservation: selection of sperm donors. Cryobiology, 32, 6877.CrossRefGoogle ScholarPubMed
Khan, M. (1989) Asian Rhinos: An Action Plan for their Conservation. IUCN, Gland, Switzerland.Google Scholar
Kim, M.H. (2009) The utility of DNA microsatellite markers in conservation of a Namibian population of the black rhinoceros (Diceros bicornis). MSc thesis. Queen's University, Ontario, Canada.Google Scholar
Laikre, L. (2010) Genetic diversity is overlooked in international conservation policy implementation. Conservation Genetics, 11, 349354.CrossRefGoogle Scholar
Maehr, D.S., Lacy, R.C., Land, E.D., Bass, O.K. & Hoctor, T.S. (2002) Evolution of population viability assessments for the Florida panther: A multiperspective approach. In Population Viability Analysis (eds Beissinger, S.R. & McCullough, D.R.), pp. 284311. University of Chicago Press, Chicago, USA.Google Scholar
Morales, J.C., Andau, P.M., Supriatna, J., ZainuddinZ,Z. Z,Z. & Melnick, D.J. (1997) Mitochondrial DNA variability and conservation genetics of the Sumatran rhinoceros. Conservation Biology, 11, 539543.CrossRefGoogle Scholar
Morales, J.C. & Melnick, D.J. (1994) Molecular systematics of the living rhinoceros. Molecular Phylogenetics and Evolution, 2, 129134.Google Scholar
Moritz, C. (1994) Defining ‘Evolutionarily Significant Units’ for conservation. Trends in Ecology & Evolution, 9, 373375.CrossRefGoogle ScholarPubMed
Moritz, C. (2002) Strategies to protect biological diversity and the evolutionary processes that sustain it. Systematic Biology, 51, 238254.CrossRefGoogle Scholar
Nei, M. (1972) Genetic distance between populations. American Naturalist, 106, 283292.CrossRefGoogle Scholar
Orlando, L., Leonard, J.A., Thenot, A., Laudet, V., Guerin, C. & Hänni, C. (2003) Ancient DNA analysis reveals woolly rhino evolutionary relationships. Molecular Phylogenetics and Evolution, 28, 485499.CrossRefGoogle ScholarPubMed
Rabinowitz, A. (1995) Helping a species go extinct: the Sumatran rhino in Borneo. Conservation Biology, 9, 482488.CrossRefGoogle Scholar
Rubinoff, D. & Holland, B. (2005) Between two extremes: mitochondrial DNA is neither the panacea nor the nemesis of phylogenetic and taxonomic inference. Systematic Biology, 54, 952961.CrossRefGoogle ScholarPubMed
Ryder, O. (1986) Species conservation and systematics: the dilemma of subspecies. Trends in Ecology & Evolution, 1, 910.CrossRefGoogle Scholar
Sabah Wildlife Department (2011) Rhinoceros Action Plan. Kota Kinabalu, Sabah, Malaysia.Google Scholar
Scott, C.A. (2008) Microsatellite variability in four contemporary rhinoceros species: implications for conservation. MSc thesis. Queen's University, Ontario, Canada.Google Scholar
Tallmon, D.A., Luikart, G. & Waples, R.S. (2004) The alluring simplicity and complex reality of genetic rescue. Trends in Ecology & Evolution, 19, 489496.CrossRefGoogle ScholarPubMed
Tougard, C., Delefosse, T., Hänni, C. & Montgelard, C. (2001) Phylogenetic relationships of the five extant Rhinoceros species (Rhinocerotidae, Perissodactyla) based on mitochondrial cytochrome b and 12S rRNA genes. Molecular Phylogenetics and Evolution, 19, 3444.CrossRefGoogle ScholarPubMed
Wiens, J.J., Kuczynski, C.A. & Stephens, P.R. (2010) Discordant mitochondrial and nuclear gene phylogenies in emydid turtles: implications for speciation and conservation. Biological Journal of the Linnean Society, 99, 445461.CrossRefGoogle Scholar
Willerslev, E., Gilbert, M.T.P., Binladen, J., Ho, S.Y.W., Campos, P.F., Ratan, A. et al. (2009) Analysis of complete mitochondrial genomes from extinct and extant rhinoceroses reveals lack of phylogenetic resolution. BMC Evolutionary Biology, 9, 95.CrossRefGoogle ScholarPubMed
Figure 0

Fig. 1 The distribution of the Sumatran rhinoceros Dicerorhinus sumatrensis subspecies in Sumatra, Peninsular Malaysia and Sabah. The priority areas are Danum Valley Conservation Area (1), Tabin Wildlife Reserve (2), Bukit Barisan Selatan National Park (3) and Way Kambas National Park (4). Areas identified by the IUCN Asian Rhino Specialist Group as requiring scientifically defensible population estimates to confirm conservation status are Royal Belum State Park (5), Taman Negara National Park (6), Endau Rompin National Park (7) and Gunung Leuser National Park (8) (Ahmad Zafir et al., 2011).