SNP-level F_ST outperforms window statistics for detecting soft sweeps in local adaptation

Abstract

Local adaptation can lead to elevated genetic differentiation at the targeted genetic variant and nearby sites. Selective sweeps come in different forms, and depending on the initial and final frequencies of a favored variant, very different patterns of genetic variation may be produced. If local selection favors an existing variant that had already recombined onto multiple genetic backgrounds, then the width of elevated genetic differentiation (high F_ST) may be too narrow to detect using a typical windowed genome scan, even if the targeted variant becomes highly differentiated. We therefore used a simulation approach to investigate the power of SNP-level F_ST (specifically, the maximum SNP F_ST value within a window) to detect diverse scenarios of local adaptation, and compared it against whole-window F_ST and the Comparative Haplotype Identity statistic. We found that SNP F_ST had superior power to detect complete or mostly complete soft sweeps, but lesser power than window-wide statistics to detect partial hard sweeps. To investigate the relative enrichment and nature of SNP F_ST outliers from real data, we applied the two F_ST statistics to a panel of Drosophila melanogaster populations. We found that SNP F_ST had a genome-wide enrichment of outliers compared to demographic expectations, and though it yielded a lesser enrichment than window F_ST, it detected mostly unique outlier genes and functional categories. Our results suggest that SNP F_ST is highly complementary to typical window-based approaches for detecting local adaptation, and merits inclusion in future genome scans and methodologies.