The Precision and Power of Population Branch Statistics in Identifying the Genomic Signatures of Local Adaptation

Overview

Journal bioRxiv

Date 2024 May 27

PMID 38798330

Authors

Max Shpak

Kadee N Lawrence

John E Pool

Affiliations

Soon will be listed here.

Abstract

Population branch statistics, which estimate the branch lengths of focal populations with respect to two outgroups, have been used as an alternative to F-based genome-wide scans for identifying loci associated with local selective sweeps. In addition to the original population branch statistic (PBS), there are subsequently proposed branch rescalings: normalized population branch statistic (PBSn1), which adjusts focal branch length with respect to outgroup branch lengths at the same locus, and population branch excess (PBE), which also incorporates median branch lengths at other loci. PBSn1 and PBE have been proposed to be less sensitive to allele frequency divergence generated by background selection or geographically ubiquitous positive selection rather than local selective sweeps. However, the accuracy and statistical power of branch statistics have not been systematically assessed. To do so, we simulate genomes in representative large and small populations with varying proportions of sites evolving under genetic drift or background selection (approximated using variable ), local selective sweeps, and geographically parallel selective sweeps. We then assess the probability that local selective sweep loci are correctly identified as outliers by F and by each of the branch statistics. We find that branch statistics consistently outperform F at identifying local sweeps. When background selection and/or parallel sweeps are introduced, PBSn1 and especially PBE correctly identify local sweeps among their top outliers at a higher frequency than PBS. These results validate the greater specificity of rescaled branch statistics such as PBE to detect population-specific positive selection, supporting their use in genomic studies focused on local adaptation.

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