Objective

Threatened, endangered, and at-risk species (TER-S) often exist as scattered metapopulations because of habitat fragmentation. Metapopulations often exhibit extinction-recolonization and source-sink dynamics. Sustainable metapopulations may be maintained through smaller, interconnected habitat patches if sufficient opportunities for dispersal occur between them. This concept is significant for the Department of Defense (DoD) because setting aside large tracts of undisturbed lands for conservation may impair the ability of a DoD installation to perform its mission. Genetic analyses can identify potential source and sink populations and, when combined with geographic information system (GIS) and landscape analyses, also can identify potential dispersal corridors necessary for sustaining metapopulations as well as habitats that are critical foci of genetic biodiversity and a priority for conservation. In particular, gopher tortoise (Gopherus polyphemus) populations are of concern. A large proportion of the remaining populations of these species reside on DoD lands.

The objective of this project was to conduct initial spatially explicit metapopulation genetic, landscape genetic, and phylogeographic analyses to determine relative levels of genetic diversity and gene flow for gopher tortoises on Camp Shelby, Mississippi. These data could then be used as a basis for a more intensive study of the metapopulation genetics of this species in relation to landscape structure, population demographics, and fitness components. Specific objectives included determining if (1) gopher tortoise populations were spatially structured, (2) the levels of genetic diversity and gene flow were affected by military activity and habitat quality, and (3) patterns of genetic diversity followed an "isolation by distance" model (i.e., if a correlation between geographic distance and genetic relatedness exists).