Large-effect Mutations Generate Trade-off Between Predatory and Locomotor Ability During Arms Race Coevolution with Deadly Prey

Overview

Journal Evol Lett

Publisher Oxford University Press

Specialty Biology

Date 2018 Oct 5

PMID 30283691

Citations 13

Authors

Michael T J Hague

Gabriela Toledo

Shana L Geffeney

Charles T Hanifin

Edmund D Brodie Jr

Edmund D Brodie 3rd

Affiliations

Soon will be listed here.

Abstract

Adaptive evolution in response to one selective challenge may disrupt other important aspects of performance. Such evolutionary trade-offs are predicted to arise in the process of local adaptation, but it is unclear if these phenotypic compromises result from the antagonistic effects of simple amino acid substitutions. We tested for trade-offs associated with beneficial mutations that confer tetrodotoxin (TTX) resistance in the voltage-gated sodium channel (Na1.4) in skeletal muscle of the common garter snake (). Separate lineages in California and the Pacific Northwest independently evolved TTX-resistant changes to the pore of Na1.4 as a result of arms race coevolution with toxic prey, newts of the genus . Snakes from the California lineage that were homozygous for an allele known to confer large increases in toxin resistance (Na1.4) had significantly reduced crawl speed compared to individuals with the ancestral TTX-sensitive channel. Heterologous expression of native snake Na1.4 proteins demonstrated that the same Na1.4 allele confers a dramatic increase in TTX resistance and a correlated decrease in overall channel excitability. Our results suggest the same mutations that accumulate during arms race coevolution and beneficially interfere with toxin-binding also cause changes in electrophysiological function of the channel that may affect organismal performance. This trade-off was only evident in the predator lineage where coevolution has led to the most extreme resistance phenotype, determined by four critical amino acid substitutions. If these biophysical changes also translate to a fitness cost-for example, through the inability of to quickly escape predators-then pleiotropy at this single locus could contribute to observed variation in levels of TTX resistance across the mosaic landscape of coevolution.

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