Standing Genetic Variation Fuels Rapid Evolution of Herbicide Resistance in Blackgrass

Overview

Journal Proc Natl Acad Sci U S A

Specialty Science

Date 2023 Apr 12

PMID 37043536

Authors

Sonja Kersten

Jiyang Chang

Christian D Huber

Yoav Voichek

Christa Lanz

Timo Hagmaier

Patricia Lang

Ulrich Lutz

Insa Hirschberg

Jens Lerchl

Aimone Porri

Yves Van de Peer

Karl Schmid

Detlef Weigel

Fernando A Rabanal

Affiliations

Soon will be listed here.

Abstract

Repeated herbicide applications in agricultural fields exert strong selection on weeds such as blackgrass (), which is a major threat for temperate climate cereal crops. This inadvertent selection pressure provides an opportunity for investigating the underlying genetic mechanisms and evolutionary processes of rapid adaptation, which can occur both through mutations in the direct targets of herbicides and through changes in other, often metabolic, pathways, known as non-target-site resistance. How much target-site resistance (TSR) relies on de novo mutations vs. standing variation is important for developing strategies to manage herbicide resistance. We first generated a chromosome-level reference genome for for population genomic studies of herbicide resistance and genome-wide diversity across Europe in this species. Next, through empirical data in the form of highly accurate long-read amplicons of alleles encoding acetyl-CoA carboxylase (ACCase) and acetolactate synthase (ALS) variants, we showed that most populations with resistance due to TSR mutations-23 out of 27 and six out of nine populations for and , respectively-contained at least two TSR haplotypes, indicating that soft sweeps are the norm. Finally, through forward-in-time simulations, we inferred that TSR is likely to mainly result from standing genetic variation, with only a minor role for de novo mutations.

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