Browsing by Subject "conservation genetics"
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Item Open Access Amplicon sequencing of 42 nuclear loci supports directional gene flow between South Pacific populations of a hydrothermal vent limpet.(Ecology and evolution, 2019-06) Plouviez, Sophie; LaBella, Abigail Leavitt; Weisrock, David W; von Meijenfeldt, FA Bastiaan; Ball, Bernard; Neigel, Joseph E; Van Dover, Cindy LIn the past few decades, population genetics and phylogeographic studies have improved our knowledge of connectivity and population demography in marine environments. Studies of deep-sea hydrothermal vent populations have identified barriers to gene flow, hybrid zones, and demographic events, such as historical population expansions and contractions. These deep-sea studies, however, used few loci, which limit the amount of information they provided for coalescent analysis and thus our ability to confidently test complex population dynamics scenarios. In this study, we investigated population structure, demographic history, and gene flow directionality among four Western Pacific hydrothermal vent populations of the vent limpet Lepetodrilus aff. schrolli. These vent sites are located in the Manus and Lau back-arc basins, currently of great interest for deep-sea mineral extraction. A total of 42 loci were sequenced from each individual using high-throughput amplicon sequencing. Amplicon sequences were analyzed using both genetic variant clustering methods and evolutionary coalescent approaches. Like most previously investigated vent species in the South Pacific, L. aff. schrolli showed no genetic structure within basins but significant differentiation between basins. We inferred significant directional gene flow from Manus Basin to Lau Basin, with low to no gene flow in the opposite direction. This study is one of the very few marine population studies using >10 loci for coalescent analysis and serves as a guide for future marine population studies.Item Open Access Using Landscape Genomics to Conserve Adaptive Capacity: A Case Study with a Southern Appalachian Salamander(2017) Forester, BrennaLandscape genomics is an emerging field that investigates how environmental features drive patterns of neutral and adaptive genetic variation across landscapes. Importantly, landscape genomics can provide insight into the adaptive potential of wild populations of non-model species, since these analyses do not require prior genomic information or the use of manipulative experiments such as reciprocal transplants. However, a fundamental challenge in landscape genomics is detecting genetic markers under selection from large genomic data sets. This analytical step is particularly important since partitioning these data into neutral and adaptive components of genetic diversity provides the information upon which management decisions are based.
Difficulties with the partitioning step include distinguishing neutral demographic signals from signals of selection, detecting selection across heterogeneous landscapes, and detecting signals of selection that are derived from multilocus adaptive processes. To address these issues, I used two different sets of landscape genetic simulations to test a suite of genotype-environment association (GEA) analyses across a range of landscape heterogeneities, selection strengths, dispersal abilities, demographic histories, sample sizes, sampling designs, and genetic architectures. I found that multivariate GEA methods showed a superior combination of low false positive and high true positive rates across simulation scenarios, providing a powerful tool for investigating the genetic basis of local adaptation and improving management actions.
I then applied a multivariate GEA approach to a reduced representation genomic data set for Weller's salamander (Plethodon welleri). This endemic, fully terrestrial, forest-dwelling salamander is a species of conservation concern across its small range in the Southern Appalachian Mountains. Its restriction to mountaintop habitats makes it particularly vulnerable to ongoing habitat fragmentation and climate change. I developed and illustrated the use of an “adaptive dissimilarity” index to characterize the scope of adaptive variation across the Weller’s salamander range. In combination with other metrics including neutral genetic variation, population differentiation, and effective population size, I addressed a series of conservation scenarios that were improved by the explicit consideration of differences in adaptive genetic variation among populations. These scenarios included: (1) site prioritization to ensure evolutionary resiliency across the species range; (2) genetic rescue to increase genetic diversity and population fitness while minimizing the risk of outbreeding depression; and (3) assisted gene flow to maximize adaptive potential in response to rapid climate change. These analyses are helping us better understand the capacity of species to adapt to changing conditions and what management actions will be most effective to conserve biodiversity under global change. These efforts must be part of the broader effort to stem the biodiversity crisis by conserving not just genetic diversity, but also the ecological and evolutionary processes that sustain it.