Reintroductions Translocations Continue to be an important tool

Reintroductions & Translocations Continue to be an important tool in wildlife management

Wildlife Reintroductions • Does habitat remain? – – How much? Connected? Management? Competition / Predation / Diseases

Wildlife Reintroductions • Viable Population? – PVA • VORTEX • RAMAS

Wildlife Reintroductions • Viable Population? – PVA • VORTEX • RAMAS • Incorporate GIS

Wildlife Reintroductions • Genetic Considerations – Why should you care? – Genetic swamping?

Genetic Considerations: Why Should You Care? • Genetic variation is the underlying basis for adaptation to future environmental change • Loss of genetic variation is often a direct consequence of species reintroduction • Understanding how genetic loss occurs can help to prevent management actions that decrease the genetic diversity of reintroduced wildlife species

Wildlife Reintroductions • Genetic Considerations – Inbreeding – Did we release highly related individuals?

Wildlife Reintroductions • Genetic Considerations – Founder Effect

Founder Effect • The reduction in overall genetic diversity experienced as a consequence of population establishment from a limited sample of individuals – Most reintroductions and natural colonization events exhibit Founder Effects – The magnitude of the effect depends upon the number of animals translocated or colonizing an area

Wildlife Reintroductions • Genetic Considerations – Genetic Bottleneck

Bottleneck • An event in which a population drops significantly in size and then recovers • Events such as habitat loss, over harvest, or reintroduction can create bottlenecks and the magnitude of the effect on genetic diversity depends upon: – Number of individuals at lowest point – Length of time population remains depressed

Genetic Drift • Random fluctuations in gene frequencies due to temporal variance in survival and reproduction – Small populations drift more rapidly than large ones – Higher reproductive and survival rates can slow the rate of genetic drift – Genetic drift can result in loss of genetic diversity as well as increases in the frequency of rare alleles

Inbreeding • Mating of closely related individuals • Anytime genes that are alike by descent (i. e. , from a shared ancestor) come together within individuals – Enhanced by slow population growth rates – Affected by mating system – Influenced by the relatedness of the initial population founders (e. g. reintroductions)

Hypothetical Source Population Different Colors Represent Copies of Different G

Trap and Transplant Reintroduced Population Loss of From Alleles • Small Samples Source Due to Original • Incomplete Sampling of Genes Sampling Event • Sampling of Related Groups

Founder Effects Loss of Alleles Due to • Differential Survival of Founders Post-Release • Differential Survival of Offspring Stochastic Processes • Differential Reproductive Contributions

Loss of Alleles • Inefficient Transfer of Genes Due to Stochastic • Unequal Contributions And Reproductive Deterministic • Differential Survival Processes • Mating of Closely Related Individuals Over Generations 10 10 Generation Bottleneck Genetic Drift Inbreeding