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21 - Analysis of demographic and genetic trends for developing a captive breeding masterplan for the giant panda

Published online by Cambridge University Press:  09 August 2009

Jonathan D. Ballou
Affiliation:
National Zoological Park
Philip S. Miller
Affiliation:
Conservation Breeding Specialist Group
Zhong Xie
Affiliation:
Chinese Association of Zoological Gardens
Rongping Wei
Affiliation:
China Conservation and Research Center for the Giant Panda
Hemin Zhang
Affiliation:
China Conservation and Research Center for the Giant Panda
Anju Zhang
Affiliation:
Chengdu Giant Panda Breeding Research Foundation
Shiquiang Huang
Affiliation:
Beijing Zoo
Shan Sun
Affiliation:
Laboratory of Genomic Diversity
Victor A. David
Affiliation:
Laboratory of Genomic Diversity
Stephen J. O'Brien
Affiliation:
Laboratory of Genomic Diversity
Kathy Traylor-Holzer
Affiliation:
Conservation Breeding Specialist Group
Ulysses S. Seal
Affiliation:
Conservation Breeding Specialist Group
David E. Wildt
Affiliation:
National Zoological Park
David E. Wildt
Affiliation:
Smithsonian National Zoological Park, Washington DC
Anju Zhang
Affiliation:
Chengdu Research Base of Giant Panda Breeding
Hemin Zhang
Affiliation:
Wildlife Conservation and Research Center for Giant Pandas
Donald L. Janssen
Affiliation:
Zoological Society of San Diego
Susie Ellis
Affiliation:
Conservation Breeding Specialist Group
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Summary

INTRODUCTION

The foundation of any managed breeding programme for animals living in captivity is a studbook. This is the chronological listing of animals in the historical captive population detailing birth and death dates, gender, parentage, locations, transfers and local identification numbers (Glatston, 1986). Analyses of these data provide critical information on past trends in population size, age-specific reproductive and survival rates, age structure, numbers of founders, degree of inbreeding, loss of genetic diversity and other measures useful for evaluating temporal changes in a captive population. This information then becomes the basis for making management recommendations to enhance the demographic and genetic security of the captive population (Ballou & Foose, 1996). Demographic security is needed to ensure that an adequate number of breeding-aged animals are available to reproduce at the rates needed to grow or maintain the population at its desired size. Genetic diversity is required for the population to remain healthy and to adapt to changing environments (i.e. experience natural selection).

The 2001 International Studbook for the Giant Panda contains detailed life history information on 542 giant pandas that have lived in zoos around the world (Xie & Gipps, 2001). The first entry, giant panda Studbook (SB) Number 1, is Su Lin, a wild-caught female who arrived at Brookfield Zoo on 2 February 1937 (see Chapter 1). A quick scan of the studbook leaves one with the impression that the captive population's dynamics are dominated by entry and subsequent death of wild-caught animals without sustainable reproduction.

Type
Chapter
Information
Giant Pandas
Biology, Veterinary Medicine and Management
, pp. 495 - 519
Publisher: Cambridge University Press
Print publication year: 2006

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References

Ballou, J. D. and Foose, T. J. (1996). Demographic and genetic management of captive populations. In Wild Mammals in Captivity, ed. Kleiman, D. G., Allen, M., Thompson, K., Lumpkin, S. and Harris, H.. Chicago, IL: University of Chicago Press, pp. 263–83.Google Scholar
Ballou, J. D. and Lacy, R. C. (1995). Identifying genetically important individuals for management of genetic diversity in captive populations. In Population Management for Survival and Recovery ed. Ballou, J. D., Gilpin, M. and Foose, T.. New York, NY: Columbia University Press, pp. 76–111.Google Scholar
Ballou, J. D., Kleiman, D. G., Mallinson, J. J. C., Rylands, A. B., Valladares-Padua, C. and Leus, K. (2002). History, management and conservation role of the captive lion tamarin populations. In The Conservation Program of the Lion Tamarins, ed. Kleiman, D. G. and Rylands, A. B., pp. 117–132. Washington, DC: Smithsonian Institution Press.Google Scholar
Caughley, G. (1977). Analysis of Vertebrate Populations. New York, NY: John Wiley & Sons.Google Scholar
Foose, T. J. (1989). Species survival plans: the role of captive propagation in conservation strategies. In Conservation Biology and the Black-Footed Ferret, ed. Seal, U. S., Thorne, E. T., Bogan, M. A. and Anderson, S. H.. New Haven, CT: Yale University Press, pp. 210–22.Google Scholar
Frankham, R., Hemmer, H., Ryder, O. A., et al. (1986). Selection in captive populations. Zoo Biology, 5, 127–38.CrossRefGoogle Scholar
Gage, T. B. (2001). Age-specific fecundity of mammalian populations: a test of three mathematical models. Zoo Biology, 20, 487–99.CrossRefGoogle Scholar
Glatston, A. R. (1986). Studbooks: the basis of breeding programs. International Zoo Yearbook, 25, 162–7.CrossRefGoogle Scholar
Hosmer, D. W. Jr., and Lemeshow, S. (1999). Applied Survival Analysis. New York, NY:John Wiley & Sons.Google Scholar
Hutchins, M. and Wiese, R. J. (1991). Beyond genetic and demographic management: the future of the Species Survival Plan and related AAZPA conservation efforts. Zoo Biology, 10, 285–92.CrossRefGoogle Scholar
ISIS. (1994). SPARKS (Single Species Animal Record Keeping System). Apple Valley, MN: International Species Information System.
Keller, L. F. and Waller, D. M. (2002). Inbreeding effects in wild populations. Trends in Ecology and Evolution, 17, 230–41.CrossRefGoogle Scholar
Lacy, R. C. (1989). Analysis of founder representation in pedigrees: founder equivalents and founder genome equivalents. Zoo Biology, 8, 111–23.CrossRefGoogle Scholar
Lacy, R. C. (1995). Clarification of genetic terms and their use in the management of captive populations. Zoo Biology, 14, 565–77.CrossRefGoogle Scholar
Lacy, R. C. (1997). Importance of genetic variation to the viability of mammalian populations. Journal of Mammalogy, 78, 320–35.CrossRefGoogle Scholar
Lacy, R. C. and Ballou, J. (2002). Simpop: software to simulate genetic management in pedigreed populations. Brookfield, IL: Chicago Zoological Society.Google Scholar
Lacy, R., Ballou, J., Starfield, A., Thompson, E. and Thomas, A. (1995). Pedigree analyses. In Population Management for Survival and Recovery, ed. Ballou, J. D., Gilpin, M. and Foose, T.. New York, NY: Columbia University Press, pp. 57–75.Google Scholar
Miller, P. S. and Lacy, R. C. (1999). VORTEX: A Stochastic Simulation of the Extinction Process. Version 8 User's Manual. Apple Valley, MN: IUCN–World Conservation Union/SSC Conservation Breeding Specialist Group.
Pollak, J., Lacy, R. C. and Ballou, J. D. (2002) PM2000: Population Management Software. Ithaca, NY: Cornell University.Google Scholar
Princée, F. P. G. (2001). Genetic management of small animal populations. Lutra, 44, 103–12.Google Scholar
Ralls, K. and Ballou, J. D. (1992). Managing genetic diversity in captive breeding and reintroduction programs. Transactions of the 57th North American Wildlife and Natural Resources Conference, 263–82.
Ralls, K. and Ballou, J. D.(2004) Genetic management of California condors. The Condor, 106, 215–28.
Ralls, K., Ballou, J. D. and Templeton, , , A. R. (1988). Estimates of lethal equivalents and the cost of inbreeding in mammals. Conservation Biology, 2, 185–93.CrossRefGoogle Scholar
Russell, W. C., Thorne, E. T., Oakleaf, R. and Ballou, J. D. (1994). The genetic basis of black-footed ferret reintroduction. Conservation Biology, 8, 263–6.CrossRefGoogle Scholar
SAS. (2001). SAS/STAT User's Guide, Version 8.02. Cary, NC: SAS Institute.
Soulé, M., Gilpin, M., Conway, W. and Foose, T. (1986). The millennium ark: how long a voyage, how many staterooms, how many passengers?, ed. K. Ralls and J. D. Ballou. (Proceedings of the Workshop on Genetic Management of Captive Populations.) Zoo Biology, 5, 101–13.
Wisely, S., Buskirk, S. W., Fleming, M. A., McDonald, D. B. and Ostrander, E. A. (2002). Genetic diversity and fitness in black-footed ferrets before and during a bottleneck. Journal of Heredity, 93, 231–7.CrossRefGoogle ScholarPubMed
Xie, Z. and Gipps, J. (2001). The 2001 International Studbook for the Giant Panda (Ailuropoda melanoleuca). Beijing: Chinese Association of Zoological Gardens.Google Scholar

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