Biology Theses and Dissertations

Permanent URI for this collection

https://hdl.handle.net/1794/3957

Browse

Browsing Biology Theses and Dissertations by Subject "Adaptation"

Now showing 1 - 2 of 2
  • Thumbnail Image
    ItemOpen Access
    The Origins and Maintenance of Genomic Variation in the Threespine Stickleback (Gasterosteus aculeatus)
    (University of Oregon, 2017-09-06) Nelson, Thomas; Cresko, William
    Genetic variation is the raw material of evolution. The sources of this variation within a population, and its maintenance within a species, have been mysterious since the birth of the field of evolutionary genetics. In this work, I study divergently adapted freshwater and marine populations of the threespine stickleback (Gasterosteus aculeatus) as an evolutionary model to track the origin of adaptive genetic variation and to describe the evolutionary processes maintaining variation across the genome. The stickleback is a small fish with a large geographic range encompassing the northern half of the Northern Hemisphere and composed of coastal marine habitats, freshwater lakes, and river systems. Populations of stickleback adapt rapidly to changes in habitat, and fossil evidence suggests that similar adaptive transitions have been ongoing in this lineage for at least ten million years. In this work, I develop a significant extension of restriction site-associated DNA sequencing (RAD-seq) to generate phased haplotype information to estimate gene tree topologies and divergence times at thousands of loci simultaneously. I find anciently derived clades of variation associated with marine and freshwater habitats in genomic regions involved in recent adaptive divergence; some divergence times extend to over ten million years ago. This history of adaptive divergence has had profound effects on genetic variation elsewhere in the genome: chromosomes harboring freshwater-adaptive variants retain anciently derived variation in linked genomic regions, while marine chromosomes have much more recent ancestry. I present a conceptual model of asymmetric selective and demographic processes to explain this result, which will form a nucleus for future research in this species. Lastly, by incorporating genome-wide recombination rates estimated from multiple genetic maps, I describe a recombination landscape that is favorable to the maintenance of marine-freshwater genomic divergence. Low recombination rates in key chromosomal regions condense widespread divergence of the physical genome, encompassing many megabases, into a small number of Mendelian loci. Combined, my results demonstrate the interconnectedness of evolutionary processes taking place on ecological and geological timescales. The genetic variation available for adaptive evolution today is a product of the long-term evolutionary history of a species.
  • Thumbnail Image
    ItemOpen Access
    Using Natural Populations of Threespine Stickleback to Identify the Genomic Basis of Skeletal Variation
    (University of Oregon, 2017-09-27) Alligood, Kristin; Streisfeld, Matthew
    Across vertebrates, skeletal shapes are diverse, and much of this variation appears to be adaptive. In contrast, the early developmental programs of these structures are highly conserved across vertebrates. The question then becomes where in the conserved genetic programs of skeletal development does variation lie to direct diversity? In threespine stickleback, rapid changes in head and body shape have been documented during repeated and independent invasions of oceanic fish into freshwater habitats in regions deglaciated approximately 13,000 years ago. However, recent research indicates that similar phenotypic and genetic divergence can occur in decades. A remaining challenge is to link stickleback population genomic variation to causal genes that underlie such rapid phenotypic evolution. Here I use genome wide association studies (GWAS) in natural populations of stickleback to uncover genomic regions that contribute to variation of two dermal bone derived traits, lateral plate number and opercle shape. The decrease of lateral plate body armor and change in opercle bone shape, important for feeding mechanics, are classically associated with freshwater divergence. GWAS has recently begun to be used in natural populations but is still under scrutiny for performance among different populations. Using a population of phenotypically variable stickleback in Oregon, GWAS proved an effective method to uncover genomic regions and genetic variants known to contribute to lateral plate number and opercle shape, as well as new genomic regions and candidate genes not previously implicated in phenotypic variation. Although successful, using similar methods on decades old stickleback populations in Alaska revealed the challenges that accompany controlling population structure created by strong natural selection. Together, I found that although lateral plate number and opercle shape rapidly evolve in a coordinated fashion during adaptation from marine to freshwater environments, phenotypic variation is largely driven by independent genetic architectures. However, in very rapidly evolving populations, despite this independence of genetic architecture, the genetic variants contributing to the traits co-localize to similar genomic regions. This finding could be either biological or methodological which highlights the promise and limitations of using GWAS to identify genetic variation that gives rise to phenotypic diversity. This dissertation includes unpublished co-authored material.