Founder effects shape linkage disequilibrium and genomic diversity of a partially clonal invader

Author ORCID

Ben Flanagan 0000-0002-0204-6139

Stacy Krueger-Hadfield 0000-0002-7324-7448

Erik Sotka 0000-0001-5167-8549

Publication Date

2-17-2021

Abstract

Genomic variation of an invasive species may be affected by complex demographic histories and evolutionary changes during invasions. Here, we describe the relative influence of bottlenecks, clonality, and population expansion in determining genomic variability of the widespread red macroalga Agarophyton vermiculophyllum. Its introduction from mainland Japan to the estuaries of North America and Europe coincided with shifts from predominantly sexual to partially clonal reproduction and rapid adaptive evolution. A survey of 62,285 SNPs for 351 individuals from 35 populations, aligned to 24 chromosome-length scaffolds indicate that linkage disequilibrium (LD), observed heterozygosity (Ho), Tajima's D, and nucleotide diversity (Pi) were greater among non-native than native populations. Evolutionary simulations indicate LD and Tajima's D were consistent with a severe population bottleneck. Also, the increased rate of clonal reproduction in the non-native range could not have produced the observed patterns by itself but may have magnified the bottleneck effect on LD. A bottleneck or clonality limitedly impact Ho and Pi, rather, the increased Ho and Pi in the non-native range is possibly due to elevated marker diversity in the genetic source populations. We refined the previous invasion source region to a ~50km section of northeastern Honshu Island. Outlier detection methods failed to reveal any consistently differentiated loci shared among invaded regions, likely because of the complex A. vermiculophyllum demographic history. Our results reinforce the importance of demographic history, specifically founder effects, in driving genomic variation of invasive populations, even when localized adaptive evolution and reproductive system shifts are observed.

Keywords

Forward evolutionary simulations, Haplodiplontic, Agarophyton vermiculophyllum

Repository

Dryad

Distribution License

CC0 1.0 Universal - No copyright; this work is in the public domain

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