Abstract

Molecular sequences are shaped by selection, where the strength of selection relative to drift is determined by effective population size (Ne). Populations with high Ne are expected to undergo stronger purifying selection, and consequently to show a lower substitution rate for selected mutations relative to the substitution rate for neutral mutations (ω). However, computational models based on biophysics of protein stability have suggested that ω can also be independent of Ne. Together, the response of ω to changes in Ne depends on the specific mapping from sequence to fitness. Importantly, an increase in protein expression level has been found empirically to result in decrease of ω, an observation predicted by theoretical models assuming selection for protein stability. Here, we derive a theoretical approximation for the response of ω to changes in Ne and expression level, under an explicit genotype-phenotype-fitness map. The method is generally valid for additive traits and log-concave fitness functions. We applied these results to protein undergoing selection for their conformational stability and corroborate out findings with simulations under more complex models. We predict a weak response of ω to changes in either Ne or expression level, which are interchangeable. Based on empirical data, we propose that fitness based on the conformational stability may not be a sufficient mechanism to explain the empirically observed variation in ω across species. Other aspects of protein biophysics might be explored, such as protein–protein interactions, which can lead to a stronger response of ω to changes in Ne.

Highlights

  • Molecular sequences differ across species due to the particular history of nucleotide substitutions along their respective lineages

  • In the original biophysical model, protein stability is determined by the difference in free energy between the folded and unfolded conformations, called ∆G and measured in kcal/mol

  • In the context of directional selection under a given genotypephenotype-fitness map, we derive an approximation for the equilibrium phenotype at equilibrium (Charlesworth, 2013)

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Summary

Introduction

Molecular sequences differ across species due to the particular history of nucleotide substitutions along their respective lineages These substitutions in turn are the result of the interplay between evolutionary forces such as mutation and selection, whose relative forces are determined by the amount of random genetic drift. These forces have effects at different levels: mutations are carried by molecular sequences, selection is mediated at the level of individuals, while random genetic drift is a population sampling effect. They jointly contribute to the long-term molecular evolutionary process. Population genetics theory implies that the strength of drift, due to the Laboratoire de Biométrie et Biologie Évolutive UMR 5558, F-69622 Villeurbanne, France

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