Whole-genome duplication increases genetic diversity and load in outcrossing Arabidopsis arenosa

Article

Vlcek, Jakub; Hamala, Tuomas; Cobo, Cristina Vives; Curran, Emma; Sramkova, Gabriela; Slotte, Tanja; Schmickl, Roswitha; Yant, Levi; Kolar, Filip

Charles University Prague; Czech Academy of Sciences; Biology Centre of the Czech Academy of Sciences; Natural Resources Institute Finland (Luke); University of Nottingham; Stockholm University; Czech Academy of Sciences; Institute of Botany of the Czech Academy of Sciences; Swedish University of Agricultural Sciences

PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA

0027-14992

10.1073/pnas.2501739122

2025-08-05

Genetic variation underpins evolutionary change, but mutation accumulation increases genetic load. Various factors affect the extent of load, such as population size and breeding system, but other important determinants remain unexplored. In particular, wholegenome duplication (WGD)-a pervasive macromutation occurring broadly across Eukaryotes-remains poorly understood in terms of its impact on neutral and selective processes within populations. Using iterative forward simulations and empirical analysis of 632 short-and 16 long-read sequenced individuals of Arabidopsis arenosa (in 23 diploid and 42 natural autotetraploid populations), we measure the effects of WGD on genome-wide diversity and mutation load. Our simulations show how genetic variation gradually rises in autotetraploids due to increased mutational target size. Moreover, mutation load increases due to relaxed purifying selection as ploidies rise, when deleterious mutations are masked by additional chromosome copies. Empirical data confirm these patterns, showing significant increases in nucleotide diversity, ratios of nonsynonymous to synonymous SNPs, and numbers of indels and large structural variants in A. arenosa autotetraploids. However, a rather modest increase in load proxies together with a broad distribution and niche of autotetraploids suggests load accumulation has not yet limited their successful expansion. Overall, we demonstrate a complex interplay between neutral processes and purifying selection in shaping genetic variation following WGD and highlight ploidy as an important determinant of mutation load, genetic diversity, and therefore adaptive potential in natural populations.