The evolutionary history of Nebraska deer mice: local adaptation in the face of strong gene flow

Pfeifer, Susanne; Laurent, Stefan; Sousa, Vitor C.; Linnen, Catherine R.; Foll, Matthieu; Excoffier, Laurent; Hoekstra, Hopi E.; Jensen, Jeffrey D.

doi:10.1101/152694

Cited by 39 publications

(43 citation statements)

References 69 publications

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“…Our results suggest that the early stage of adaptation to novel strong selection such as introduced malaria may occur via changes in multiple genes that each confers tolerance, only some of which are common across populations. Similar patterns have been found in experimental evolution studies (Elena & Lenski, ; Notley‐McRobb & Ferenci, , ) and in natural populations (Pfeifer et al., ). Parallel evolution is less common when multiple traits confer the same phenotypic function (Thompson et al., ); it is likely that over time, some of these changes will replace others as a result of gene flow (Caprio & Tabashnik, ) and variation in fitness of particular mutations in different environments and genetic backgrounds.…”

Section: Discussionsupporting

confidence: 84%

“…We still lack a complete understanding of when molecular adaptation should be parallel versus divergent, although some patterns are beginning to emerge (Rosenblum, Parent, & Brandt, ). For phenotypes with multiple physiological or molecular mechanisms, such as tolerance to a pathogen, there are likely multiple genomic solutions that confer adaptation (Pfeifer et al., ). In such cases, the first variant to appear in a population should rapidly increase in frequency, independent of the alleles in other populations, leading to differences among populations in the genomic basis of convergent phenotypes.…”

Section: Introductionmentioning

confidence: 99%

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Parallel evolution of gene classes, but not genes: Evidence from Hawai'ian honeycreeper populations exposed to avian malaria

2018

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Adaptation in nature is ubiquitous, yet characterizing its genomic basis is difficult because population demographics cause correlations with nonadaptive loci. Introduction events provide opportunities to observe adaptation over known spatial and temporal scales, facilitating the identification of genes involved in adaptation. The pathogen causing avian malaria, Plasmodium relictum, was introduced to Hawai'i in the 1930s and elicited extinctions and precipitous population declines in native honeycreepers. After a sharp initial population decline, the Hawai'i ‘amakihi (Chlorodrepanis virens) has evolved tolerance to the parasite at low elevations where P. relictum exists, and can sustain infection without major fitness consequences. High‐elevation, unexposed populations of ‘amakihi display little to no tolerance. To explore the genomic basis of adaptation to P. relictum in low‐elevation ‘amakihi, we genotyped 125 ‘amakihi from the island of Hawai'i via hybridization capture to 40,000 oligonucleotide baits containing SNPs and used the reference ‘amakihi genome to identify genes potentially under selection from malaria. We tested for outlier loci between low‐ and high‐elevation population pairs and identified loci with signatures of selection within low‐elevation populations. In some cases, genes commonly involved in the immune response (e.g., major histocompatibility complex) were associated with malaria presence in the population. We also detected several novel candidate loci that may be implicated in surviving malaria infection (e.g., beta‐defensin, glycoproteins and interleukin‐related genes). Our results suggest that rapid adaptation to pathogens may occur through changes in different immune genes, but in the same classes of genes, across populations.

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Section: Discussionsupporting

confidence: 84%

Section: Introductionmentioning

confidence: 99%

Parallel evolution of gene classes, but not genes: Evidence from Hawai'ian honeycreeper populations exposed to avian malaria

2018

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“…As such, the cryptic coloration literature may serve as an informative roadmap outlining the avenues of future research. In that literature, genome-wide polymorphism data from light (derived-state) and dark (ancestral-state) mouse populations were next utilized to fit a demographic history including population size change, structure, and migration, and simulation was used to assess the fit of the model to the data and to characterize sweep-detection performance under the relevant demographic history (Pfeifer et al 2018). Utilizing this model as the appropriate null distribution for characterizing the expected performance of summary statistics under neutrality compared to selection, well-supported candidate loci were identified.…”

Section: Discussionmentioning

confidence: 99%

Recent population genomic insights into the genetic basis of arsenic tolerance in humans: the difficulties of identifying positively selected loci in strongly bottlenecked populations

Apata

Pfeifer

2019

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Recent advances in genomics have enabled researchers to shed light on the evolutionary processes driving human adaptation, by revealing the genetic architectures underlying traits ranging from lactase persistence, to skin pigmentation, to hypoxic response, to arsenic tolerance. Complicating the identification of targets of positive selection in modern human populations is their complex demographic history, characterized by population bottlenecks and expansions, population structure, migration, and admixture. In particular, founder effects and recent strong population size reductions, such as those experienced by the indigenous peoples of the Americas, have severe impacts on genetic variation that can lead to the accumulation of large allele frequency differences between populations due to genetic drift rather than natural selection. While distinguishing the effects of demographic history from selection remains challenging, neglecting neutral processes can lead to the incorrect identification of candidate loci. We here review the recent population genomic insights into the genetic basis of arsenic tolerance in Andean populations, and utilize this example to highlight both the difficulties pertaining to the identification of local adaptations in strongly bottlenecked populations, as well as the importance of controlling for demographic history in selection scans.

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“…Studies of this nature ideally require sampling regimes that allow genetic variation to be contrasted among conspecific populations distributed across defined environmental gradients (Frichot, Schoville, Bouchard, & Francois, ). Most have been carried out in terrestrial systems where habitat heterogeneity is relatively easy to measure and is often well described, with many demonstrating evidence of selection resulting from environmental variation at various spatial scales (Buehler et al, ; Jordan, Hoffmann, Dillon, & Prober, ; Pfeifer et al, ; Termignoni‐Garcia et al, ). In contrast, information on the heterogeneity of marine habitats, particularly benthic habitats, is limited for many coastlines, hindering effective sampling to test for adaptive genetic diversity within marine species.…”

Section: Introductionmentioning

confidence: 99%

Local and regional scale habitat heterogeneity contribute to genetic adaptation in a commercially important marine mollusc (Haliotis rubra) from southeastern Australia

et al. 2019

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Characterising adaptive genetic divergence among conspecific populations is often achieved by studying genetic variation across defined environmental gradients. In marine systems this is challenging due to a paucity of information on habitat heterogeneity at local and regional scales and a dependency on sampling regimes that are typically limited to broad longitudinal and latitudinal environmental gradients. As a result, the spatial scales at which selection processes operate and the environmental factors that contribute to genetic adaptation in marine systems are likely to be unclear. In this study we explore patterns of adaptive genetic structuring in a commercially-harvested abalone species (Haliotis rubra) from southeastern Australia, using a panel of genome-wide SNP markers (5,239 SNPs), and a sampling regime informed by marine LiDAR bathymetric imagery and 20-year hindcasted oceanographic models. Despite a lack of overall genetic structure across the sampling distribution, significant genotype associations with heterogeneous habitat features were observed at local and regional spatial scales, including associations with wave energy, ocean current, sea surface temperature, and geology. These findings provide insights into the potential resilience of the species to changing marine climates and the role of migration and selection on recruitment processes, with implications for conservation and fisheries management. This study points to the spatial scales at which selection processes operate in marine systems and highlights the benefits of geospatially-informed sampling regimes for overcoming limitations associated with marine population genomic research.

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The evolutionary history of Nebraska deer mice: local adaptation in the face of strong gene flow

Cited by 39 publications

References 69 publications

Parallel evolution of gene classes, but not genes: Evidence from Hawai'ian honeycreeper populations exposed to avian malaria

Parallel evolution of gene classes, but not genes: Evidence from Hawai'ian honeycreeper populations exposed to avian malaria

Recent population genomic insights into the genetic basis of arsenic tolerance in humans: the difficulties of identifying positively selected loci in strongly bottlenecked populations

Local and regional scale habitat heterogeneity contribute to genetic adaptation in a commercially important marine mollusc (Haliotis rubra) from southeastern Australia

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