BackgroundFor wide-ranging species, intraspecific variation can occur as a result of reproductive isolation from local adaptive differences or from physical barriers to movement. Cutthroat trout (Oncorhynchus clarkii), a widely distributed fish species from North America, has been divided into numerous putative subspecies largely based on its isolation in different watersheds. In this study, we examined mtDNA sequence variation of cutthroat trout to determine the major phylogenetic lineages of this polytypic species. We use these data as a means of testing whether geographic isolation by watershed boundaries can be a primary factor organizing intraspecific diversification.ResultsWe collected cutthroat trout from locations spanning almost the entire geographic range of this species and included samples from all major subspecies of cutthroat trout. Based on our analyses, we reveal eight major lineages of cutthroat trout, six of which correspond to subspecific taxonomy commonly used to describe intraspecific variation in this species. The Bonneville cutthroat trout (O. c. utah) and Yellowstone cutthroat trout (O. c. bouvieri) did not form separate monophyletic lineages, but instead formed an intermixed clade. We also document the geographic distribution of a Great Basin lineage of cutthroat trout; a group typically defined as Bonneville cutthroat trout, but it appears more closely related to the Colorado River lineage of cutthroat trout.ConclusionOur study indicates that watershed boundaries can be an organizing factor isolating genetic diversity in fishes; however, historical connections between watersheds can also influence the template of isolation. Widely distributed species, like cutthroat trout, offer an opportunity to assess where historic watershed connections may have existed, and help explain the current distribution of biological diversity across a landscape.
In this study, I examined the population genetic structure of subpopulations of pumas (Puma concolor) in Idaho and surrounding states. Patterns of genetic diversity, population structure, levels of inbreeding, and the relationship between genetic differentiation and dispersal distance within and between 15 subpopulations of pumas were compared. Spatial analyses revealed that the Snake River plain was an important barrier to movement between northern and southern regions of Idaho. In addition, subpopulations south of the Snake River plain exhibited lower levels of genetic diversity, higher levels of inbreeding, and a stronger pattern of isolation by distance relative to subpopulations north of the Snake River plain. Lower levels of diversity and restricted gene flow are likely the result of historically lower population sizes in conjunction with more recent changes in habitat use and available dispersal corridors for movement. The subdivision of puma populations north and south of the Snake River plain, along with the patterns of genetic diversity within regions, indicate that landscape features are affecting the population genetic structure of pumas in Idaho. These results indicate that information about the effects of landscape features on the distribution of genetic diversity should be considered when designing plans for the management and conservation of pumas.
We investigated temporal and spatial genetic variation in Pacific herring Clupea pallasii collections from six sites in Puget Sound (PS) and the southern Strait of Georgia (SOG), using 12 microsatellite loci. Loci were highly variable with up to 70 alleles per locus (mean ϭ 30.67 alleles), and observed heterozygosity was high (mean ϭ 0.823). Analysis of molecular variance (AMOVA) indicated significant structure, with over twice as much variance among sites as among collection years, although among-site variance was mainly due to Cherry Point and Squaxin Pass collections. In an AMOVA excluding Cherry Point and Squaxin Pass, only temporal variance was significant. With the exception of the Cherry Point and Squaxin Pass collections, pairwise genotypic and F ST tests show some differences among collection years within a site and some genetic overlap among most PS and SOG collections. The Cherry Point and Squaxin Pass collections had no differences in genotypic distributions among collection years, and in cluster analyses the Cherry Point and Squaxin Pass collections each formed groups separate from other PS and SOG collections. Cherry Point herring have a later spawning time than other PS and SOG herring, and Squaxin Pass is physically isolated in southern Puget Sound. We hypothesize that spawn timing differences and spatial isolation generated genetic structure among some Pacific herring in PS and SOG. We suspect that, as in the case of Atlantic herring C. harengus, population genetic structure in Pacific herring in PS and southern SOG is a combination of a larval retention model and a metapopulation model. Because Cherry Point and Squaxin Pass herring are genetically and behaviorally differentiated from other PS and SOG herring populations, this unique variation should be preserved through careful management.
We used 13 microsatellite loci to examine population structure in rainbow trout Oncorhynchus mykiss collected from 20 tributaries and 3 main stems in the greater Spokane River drainage. Populations displayed some excess homozygosity and linkage disequilibrium, which was more pronounced in upper tributary collections and probably the result of small effective population sizes or structuring within tributaries. In general, population structure followed geographic structure; collections from creeks within sub‐drainages were the most closely related, and collections from different tributaries were genetically distinct. Comparisons with cutthroat trout O. clarkii indicated little to no introgression. Comparisons with steelhead (anadromous rainbow trout), coastal rainbow trout O. mykiss irideus, and inland rainbow trout from hatcheries suggested introgression by hatchery fish into some wild populations. Introgression was suspected in populations from stocked tributaries and tributaries that lacked barriers to escaped hatchery fish. Populations from tributaries above barriers that had not been stocked were genetically distinct from hatchery fish and appeared to be native inland redband trout O. mykiss gairdneri.
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