A Life-history Allele of Large Effect Shortens Developmental Time in a Wild Insect Population

Overview

Journal Nat Ecol Evol

Publisher Springer Nature

Specialty Biology

Date 2023 Nov 13

PMID 37957313

Authors

Shixiong Cheng

Chris G C Jacobs

Elisa A Mogollon Perez

Daipeng Chen

Joep T van de Sanden

Kevin M Bretscher

Femke Verweij

Jelle S Bosman

Amke Hackmann

Roeland M H Merks

Joost van den Heuvel

Maurijn van der Zee

Affiliations

Soon will be listed here.

Abstract

Developmental time is a key life-history trait with large effects on Darwinian fitness. In many insects, developmental time is currently under strong selection to minimize ecological mismatches in seasonal timing induced by climate change. The genetic basis of responses to such selection, however, is poorly understood. To address this problem, we set up a long-term evolve-and-resequence experiment in the beetle Tribolium castaneum and selected replicate, outbred populations for fast or slow embryonic development. The response to this selection was substantial and embryonic developmental timing of the selection lines started to diverge during dorsal closure. Pooled whole-genome resequencing, gene expression analysis and an RNAi screen pinpoint a 222 bp deletion containing binding sites for Broad and Tramtrack upstream of the ecdysone degrading enzyme Cyp18a1 as a main target of selection. Using CRISPR/Cas9 to reconstruct this allele in the homogenous genetic background of a laboratory strain, we unravel how this single deletion advances the embryonic ecdysone peak inducing dorsal closure and show that this allele accelerates larval development but causes a trade-off with fecundity. Our study uncovers a life-history allele of large effect and reveals the evolvability of developmental time in a natural insect population.

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PMID: 39780588 PMC: 11720646. DOI: 10.1098/rstb.2023.0321.

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