4.5 Article

Effects of Synonymous Mutations beyond Codon Bias: The Evidence for Adaptive Synonymous Substitutions from Microbial Evolution Experiments

Journal

GENOME BIOLOGY AND EVOLUTION
Volume 13, Issue 9, Pages -

Publisher

OXFORD UNIV PRESS
DOI: 10.1093/gbe/evab141

Keywords

synonymous mutations; positive selection; distribution of fitness effects; experimental evolution

Funding

  1. Natural Sciences and Engineering Research Council (NSERC) of Canada [RGPIN-2019-05622]

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Synonymous mutations are not always neutral, as they can drive adaptive evolution through impacts on gene expression and protein folding. Site-directed mutagenesis experiments show that the fitness effects of synonymous mutations are more similar to nonsynonymous mutations, especially for beneficial mutations. Experimental evolution studies also demonstrate that synonymous mutations can impact fitness through various mechanisms beyond just being neutral.
Synonymous mutations are often assumed to be neutral with respect to fitness because they do not alter the encoded amino acid and so cannot be seen by natural selection. Yet a growing body of evidence suggests that synonymous mutations can have fitness effects that drive adaptive evolution through their impacts on gene expression and protein folding. Here, we review what microbial experiments have taught us about the contribution of synonymous mutations to adaptation. A survey of site-directed mutagenesis experiments reveals the distributions of fitness effects for nonsynonymous and synonymous mutations are more similar, especially for beneficial mutations, than expected if all synonymous mutations were neutral, suggesting they should drive adaptive evolution more often than is typically observed. A review of experimental evolution studies where synonymous mutations have contributed to adaptation shows they can impact fitness through a range of mechanisms including the creation of illicit RNA polymerase binding sites impacting transcription and changes to mRNA folding stability that modulate translation. We suggest that clonal interference in evolving microbial populations may be the reason synonymous mutations play a smaller role in adaptive evolution than expected based on their observed fitness effects. We finish by discussing the impacts of falsely assuming synonymous mutations are neutral and discuss directions for future work exploring the role of synonymous mutations in adaptive evolution.

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