Abstract
Evolution by natural selection occurs when the frequencies of genetic variants change because individuals differ in Darwinian fitness components such as survival or reproductive success. Differential fitness has been demonstrated in field studies of many organisms, but it remains unclear how well we can quantitatively predict allele frequency changes from fitness measurements. Here, we characterize natural selection on millions of Single Nucleotide Polymorphisms (SNPs) across the genome of the annual plant Mimulus guttatus. We use fitness estimates to calibrate population genetic models that effectively predict allele frequency changes into the next generation. Hundreds of SNPs experienced “male selection” in 2013 with one allele at each SNP elevated in frequency among successful male gametes relative to the entire population of adults. In the following generation, allele frequencies at these SNPs consistently shifted in the predicted direction. A second year of study revealed that SNPs had effects on both viability and reproductive success with pervasive trade-offs between fitness components. SNPs favored by male selection were, on average, detrimental to survival. These trade-offs (antagonistic pleiotropy and temporal fluctuations in fitness) may be essential to the long-term maintenance of alleles. Despite the challenges of measuring selection in the wild, the strong correlation between predicted and observed allele frequency changes suggests that population genetic models have a much greater role to play in forward-time prediction of evolutionary change.
Highlights
Natural selection is routinely strong enough to measure within wild populations
Field experiments later demonstrated selection on allozymes [3] and structural variants such as inversions [4,5,6], but the set of loci amenable to direct study has greatly expanded with quantitative trait locus (QTL) mapping [7]
QTLs link genotype to phenotype in way that can provide a “mechanistic” understanding of selection in terms of the processes that maintain polymorphism and the environmental drivers of selection
Summary
Natural selection is routinely strong enough to measure within wild populations. Classic experiments on conspicuous polymorphisms were the first to establish fitness differences among genotypes [1,2]. Experiments predicting individual fitness from individual genomes have been conducted in a variety of organisms using both “common gardens,” where sequenced individuals are transplanted into natural settings [16,17,18,19], as well as by monitoring of native individuals in situ [20,21,22]. These studies yield varying results on the importance of different selection components, but in aggregate, suggest that selection is a pervasive force on ecological time scales
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