Does equalization of family sizes reduce genetic adaptation to captivity?

Richard Frankham; Heidi Manning; Sienna H Margan; David A. Briscoe

doi:10.1111/j.1469-1795.2000.tb00120.x

Abstract

Genetic adaptation to captive environments is likely to reduce the reproductive fitness of endangered species when they are reintroduced into natural environments. Equalization of family sizes is predicted to halve genetic adaptation to captivity as it removes selection among families and is recommended in captive management of threatened species. This prediction was evaluated by comparing the reproductive fitnesses of replicate populations of Drosophila maintained using either equal (EFS) or variable family sizes (VFS) for 25 generations in captivity under uncrowded conditions on a medium containing CuSO4. After 25 generations, EFS populations produced 8.8% more offspring per pair than their outbred base population on CuSO4 medium, while VFS produced 17.5% more. Consequently, the rate of genetic adaptation to captivity in EFS was about half that in VFS, as predicted. In simulated ‘wild’ conditions (crowded, competitive conditions on medium lacking CuSO4), both treatments showed much lower reproductive fitness than their outbred base population, the reductions being 38% in EFS populations and 43% in VFS populations. Surprisingly, reproductive fitness of the two treatments did not differ significantly under these conditions. These results raise doubts about the ability of equalization of family sizes to reduce genetic deterioration that adversely affects reintroduction success for captive populations of endangered species.

Crossref Citations

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van Heezik, Yolanda and Ostrowski, Stéphane 2001. Conservation breeding for reintroductions: assessing survival in a captive flock of houbara bustards. Animal Conservation, Vol. 4, Issue. 3, p. 195.

Eldridge, Mark D. B. Browning, Teena L. and Close, Robert L. 2001. Provenance of a New Zealand brush‐tailed rock‐wallaby (Petrogale penicillata) population determined by mitochondrial DNA sequence analysis. Molecular Ecology, Vol. 10, Issue. 10, p. 2561.

Reed, David H. Lowe, Edwin H. Briscoe, David A. and Frankham, Richard 2003. FITNESS AND ADAPTATION IN A NOVEL ENVIRONMENT: EFFECT OF INBREEDING, PRIOR ENVIRONMENT, AND LINEAGE. Evolution, Vol. 57, Issue. 8, p. 1822.

FIUMERA, ANTHONY C. PORTER, BRADY A. LOONEY, GREG ASMUSSEN, MARJORIE A. and AVISE, JOHN C. 2004. Maximizing Offspring Production While Maintaining Genetic Diversity in Supplemental Breeding Programs of Highly Fecund Managed Species. Conservation Biology, Vol. 18, Issue. 1, p. 94.

Aguilar, Ruth Dong, Yuemei Warr, Emma and Dimopoulos, George 2005. Anopheles infection responses; laboratory models versus field malaria transmission systems. Acta Tropica, Vol. 95, Issue. 3, p. 285.

FRANKHAM, R. 2005. Stress and adaptation in conservation genetics. Journal of Evolutionary Biology, Vol. 18, Issue. 4, p. 750.

McDougall, P. T. Réale, D. Sol, D. and Reader, S. M. 2006. Wildlife conservation and animal temperament: causes and consequences of evolutionary change for captive, reintroduced, and wild populations. Animal Conservation, Vol. 9, Issue. 1, p. 39.

O’Brien, John McCracken, Gary F. Say, Ludovic and Hayden, Thomas J. 2007. Rodrigues fruit bats (Pteropus rodricensis, Megachiroptera: Pteropodidae) retain genetic diversity despite population declines and founder events. Conservation Genetics, Vol. 8, Issue. 5, p. 1073.

Wedekind, Claus Rudolfsen, Geir Jacob, Alain Urbach, Davnah and Müller, Rudolf 2007. The genetic consequences of hatchery-induced sperm competition in a salmonid. Biological Conservation, Vol. 137, Issue. 2, p. 180.

FRANKHAM, RICHARD 2008. Genetic adaptation to captivity in species conservation programs. Molecular Ecology, Vol. 17, Issue. 1, p. 325.

Smith, Steve and Hughes, Jane 2008. Microsatellite and mitochondrial DNA variation defines island genetic reservoirs for reintroductions of an endangered Australian marsupial, Perameles bougainville. Conservation Genetics, Vol. 9, Issue. 3, p. 547.

Fraser, Dylan J. 2008. How well can captive breeding programs conserve biodiversity? A review of salmonids. Evolutionary Applications, Vol. 1, Issue. 4, p. 535.

Kozfkay, Christine C. Campbell, Matthew R. Heindel, Jeff A. Baker, Danny J. Kline, Paul Powell, Madison S. and Flagg, Thomas 2008. A genetic evaluation of relatedness for broodstock management of captive, endangered Snake River sockeye salmon, Oncorhynchus nerka. Conservation Genetics, Vol. 9, Issue. 6, p. 1421.

Smith, Steve McRae, Peter and Hughes, Jane 2009. Faecal DNA analysis enables genetic monitoring of the species recovery program for an arid-dwelling marsupial. Australian Journal of Zoology, Vol. 57, Issue. 2, p. 139.

Williams, Sara E. and Hoffman, Eric A. 2009. Minimizing genetic adaptation in captive breeding programs: A review. Biological Conservation, Vol. 142, Issue. 11, p. 2388.

Santos, Marta Fragata, Inês Santos, Josiane Simões, Pedro Marques, Ana Lima, Margarida and Matos, Margarida 2010. Playing Darwin. Part B. 20 years of domestication in Drosophila subobscura. Theory in Biosciences, Vol. 129, Issue. 2-3, p. 97.

Simões, Pedro Pascual, Marta Coelho, Maria Manuela and Matos, Margarida 2010. Divergent evolution of molecular markers during laboratory adaptation in Drosophila subobscura. Genetica, Vol. 138, Issue. 9-10, p. 999.

Aguilar, R. Simard, F. Kamdem, C. Shields, T. Glass, G. E. Garver, L. S. and Dimopoulos, G. 2010. Genome‐wide analysis of transcriptomic divergence between laboratory colony and fieldAnopheles gambiaemosquitoes of the M and S molecular forms. Insect Molecular Biology, Vol. 19, Issue. 5, p. 695.

Ivy, Jamie A. and Lacy, Robert C. 2010. Molecular Approaches in Natural Resource Conservation and Management. p. 267.

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Does equalization of family sizes reduce genetic adaptation to captivity?

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