Adaptive and nonadaptive causes of heterogeneity in genetic differentiation across the Mimulus guttatus genome

Genetic diversity becomes structured among populations over time due to genetic drift and divergent selection. Although population structure is often treated as a uniform underlying factor, recent resequencing studies of wild populations have demonstrated that diversity in many regions of the genome...

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Veröffentlicht in:	Molecular ecology 2021-12, Vol.30 (23), p.6486-6507
Hauptverfasser:	Colicchio, Jack M., Hamm, Lauren N., Verdonk, Hannah E., Kooyers, Nicholas J., Blackman, Benjamin K.
Format:	Artikel
Sprache:	eng
Schlagworte:	Adaptation Adaptation, Physiological Association analysis balancing selection Chromosome Inversion Chromosomes Climate Climate adaptation Climate change Differentiation Divergence Drought resistance Genetic diversity Genetic Drift Genetic Variation Genomes genomic heterogeneity Genomics genotype‐environment association analysis Heterogeneity Humans local adaptation Metabolism Mimulus - genetics Mimulus guttatus monkeyflowers Polymorphism, Genetic Population genetics Population structure Population studies Populations Selection, Genetic
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container_issue	23
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container_title	Molecular ecology
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creator	Colicchio, Jack M. Hamm, Lauren N. Verdonk, Hannah E. Kooyers, Nicholas J. Blackman, Benjamin K.
description	Genetic diversity becomes structured among populations over time due to genetic drift and divergent selection. Although population structure is often treated as a uniform underlying factor, recent resequencing studies of wild populations have demonstrated that diversity in many regions of the genome may be structured quite dissimilar to the genome‐wide pattern. Here, we explored the adaptive and nonadaptive causes of such genomic heterogeneity using population‐level, whole genome resequencing data obtained from annual Mimulus guttatus individuals collected across a rugged environment landscape. We found substantial variation in how genetic differentiation is structured both within and between chromosomes, although, in contrast to other studies, known inversion polymorphisms appear to serve only minor roles in this heterogeneity. In addition, much of the genome can be clustered into eight among‐population genetic differentiation patterns, but only two of these clusters are particularly consistent with patterns of isolation by distance. By performing genotype‐environment association analysis, we also identified genomic intervals where local adaptation to specific climate factors has accentuated genetic differentiation among populations, and candidate genes in these windows indicate climate adaptation may proceed through changes affecting specialized metabolism, drought resistance, and development. Finally, by integrating our findings with previous studies, we show that multiple aspects of plant reproductive biology may be common targets of balancing selection and that variants historically involved in climate adaptation among populations have probably also fuelled rapid adaptation to microgeographic environmental variation within sites.
doi_str_mv	10.1111/mec.16087
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By performing genotype‐environment association analysis, we also identified genomic intervals where local adaptation to specific climate factors has accentuated genetic differentiation among populations, and candidate genes in these windows indicate climate adaptation may proceed through changes affecting specialized metabolism, drought resistance, and development. 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subjects	Adaptation Adaptation, Physiological Association analysis balancing selection Chromosome Inversion Chromosomes Climate Climate adaptation Climate change Differentiation Divergence Drought resistance Genetic diversity Genetic Drift Genetic Variation Genomes genomic heterogeneity Genomics genotype‐environment association analysis Heterogeneity Humans local adaptation Metabolism Mimulus - genetics Mimulus guttatus monkeyflowers Polymorphism, Genetic Population genetics Population structure Population studies Populations Selection, Genetic
title	Adaptive and nonadaptive causes of heterogeneity in genetic differentiation across the Mimulus guttatus genome
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