Collateral fitness effects of mutations

Mehlhoff, Jacob D.; Stearns, Frank W.; Rohm, Dahlia; Wang, Buheng; Tsou, Erh-Yeh; Dutta, Nisita; Hsiao, Meng-Hsuan; Gonzalez, Courtney E.; Rubin, Alan F.; Ostermeier, Marc

doi:10.1073/pnas.1918680117

Cited by 38 publications

(27 citation statements)

References 63 publications

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“…2019 ). Recently, the fraction of mutations leading to deleterious effects through all possible nonfunctional mechanisms, referred to as collateral effects, was estimated to be approximately 40% for the TEM-1 protein in E. coli ( Mehlhoff et al. 2020 ).…”

Section: Discussionmentioning

confidence: 99%

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The Relationship between the Misfolding Avoidance Hypothesis and Protein Evolutionary Rates in the Light of Empirical Evidence

Usmanova

Plata

Vitkup

2021

Genome Biology and Evolution

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For more than a decade, the misfolding avoidance hypothesis (MAH) and related theories have dominated evolutionary discussions aimed at explaining the variance of the molecular clock across cellular proteins. In this study, we use various experimental data to further investigate the consistency of the MAH predictions with empirical evidence. We also critically discuss experimental results that motivated the MAH development and that are often viewed as evidence of its major contribution to the variability of protein evolutionary rates. We demonstrate, in Escherichia coli and Homo sapiens, the lack of a substantial negative correlation between protein evolutionary rates and Gibbs free energies of unfolding, a direct measure of protein stability. We then analyze multiple new genome-scale data sets characterizing protein aggregation and interaction propensities, the properties that are likely optimized in evolution to alleviate deleterious effects associated with toxic protein misfolding and misinteractions. Our results demonstrate that the propensity of proteins to aggregate, the fraction of charged amino acids, and protein stickiness do correlate with protein abundances. Nevertheless, across multiple organisms and various data sets we do not observe substantial correlations between proteins’ aggregation- and stability-related properties and evolutionary rates. Therefore, diverse empirical data support the conclusion that the MAH and similar hypotheses do not play a major role in mediating a strong negative correlation between protein expression and the molecular clock, and thus in explaining the variability of evolutionary rates across cellular proteins.

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Section: Discussionmentioning

confidence: 99%

“…And this assumption is quite unlikely as protein sites of collateral mutations substantially overlap with functionally sensitive sites, and collateral effects are often smaller in magnitude compared with functional effects ( Stiffler et al. 2015 ; Mehlhoff et al. 2020 ).…”

Section: Discussionmentioning

confidence: 99%

The Relationship between the Misfolding Avoidance Hypothesis and Protein Evolutionary Rates in the Light of Empirical Evidence

Usmanova

Plata

Vitkup

2021

Genome Biology and Evolution

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“…In order to test this model and better understand the genotype-phenotype-fitness map, we face the difficult task of identifying which phenotypes are affected by the adaptive mutations and then determining how these phenotypes contribute to fitness. This is a challenging problem as the possible number of phenotypes one can measure is effectively infinite, for example the expression level of every gene or the quantity of every metabolite ( Coombes et al, 2019 ; Mehlhoff et al, 2020 ). Further, many measurable phenotypes are related in complex ways ( Geiler-Samerotte et al, 2020 ).…”

Section: Introductionmentioning

confidence: 99%

Fitness variation across subtle environmental perturbations reveals local modularity and global pleiotropy of adaptation

Kinsler

Geiler-Samerotte

Petrov

2020

eLife

103

208

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Building a genotype-phenotype-fitness map of adaptation is a central goal in evolutionary biology. It is difficult even when adaptive mutations are known because it is hard to enumerate which phenotypes make these mutations adaptive. We address this problem by first quantifying how the fitness of hundreds of adaptive yeast mutants responds to subtle environmental shifts. We then model the number of phenotypes these mutations collectively influence by decomposing these patterns of fitness variation. We find that a small number of inferred phenotypes can predict fitness of the adaptive mutations near their original glucose-limited evolution condition. Importantly, inferred phenotypes that matter little to fitness at or near the evolution condition can matter strongly in distant environments. This suggests that adaptive mutations are locally modular—affecting a small number of phenotypes that matter to fitness in the environment where they evolved—yet globally pleiotropic—affecting additional phenotypes that may reduce or improve fitness in new environments.

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“…Our empirical model can also provide a quantitative understanding of the mechanisms underlying mutational epistasis, i.e., the non-additive interaction between mutational effects (Domingo et al, 2019;Starr and Thornton, 2016). Epistasis is a key phenomenon in protein evolution that dictates the shape and ruggedness of fitness landscapes, which subsequently affect important evolutionary phenomenon such as robustness (Bershtein et al, 2013(Bershtein et al, , 2006Hartl et al, 1985;Lundin et al, 2018;Tokuriki and Tawfik, 2009), evolvability (Dean, 1995;DePristo et al, 2005;Lunzer et al, 2005;Mehlhoff et al, 2020;Sarkisyan et al, 2016;Stiffler et al, 2015;Tokuriki and Tawfik, 2009;Yang et al, 2019) and evolutionary contingency (Baier et al, 2019;Starr et al, 2017;Starr and Thornton, 2016). One form of epistasis, defined as 'nonspecific epistasis', is known to be highly prevalent and strongly influences the accessibility of mutations.…”

Section: The Molecular Basis For Nonspecific Epistasismentioning

confidence: 99%

“…In this model, the fitness conferred by variants with biochemical traits above a certain selection 'threshold' would saturate or plateau, while fitness rapidly decreases for variants below the threshold of the trait. Such models have been widely recognized conceptually, and provide molecular explanations for important evolutionary phenomenon such as nonspecific epistasis (Bershtein et al, 2006;Dasmeh and Serohijos, 2018;Diss and Lehner, 2018;Kemble et al, 2019;Pokusaeva et al, 2019), mutational robustness (Bershtein et al, 2013(Bershtein et al, , 2006Hartl et al, 1985;Lundin et al, 2018;Tokuriki and Tawfik, 2009) and evolvability (Dean, 1995;DePristo et al, 2005;Lunzer et al, 2005;Mehlhoff et al, 2020;Sarkisyan et al, 2016;Stiffler et al, 2015;Tokuriki and Tawfik, 2009). However, quantitative and experimental studies of the threshold model are rare, as most reports contain just a handful of data points and each landscape is confined to the scope of a single level of selection pressure (Bershtein et al, 2013;Dean, 1995;Hartl et al, 1985;Lunzer et al, 2005;Pokusaeva et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

Environmental selection and epistasis in an empirical phenotype-environment-fitness landscape

Chen

Fowler

Tokuriki

2021

Preprint

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The fitness landscape, a function that maps genotypic and phenotypic changes to their effects on fitness, is an invaluable concept in evolutionary biochemistry. Though widely discussed, measurements of phenotype-fitness landscapes in proteins remain scarce. Here, we quantify all single mutational effects on fitness and phenotype (antibiotic resistance level) of VIM-2 β-lactamase (5600 variants) across a 64-fold range of ampicillin concentrations by deep mutational scanning. We then construct a phenotype-fitness landscape that takes variations in environmental selection pressure into account (a phenotype-environment-fitness landscape). We found that a simple, empirical landscape accurately models the ~39,000 mutational data points, which suggests the evolution of VIM-2 can be predicted based on the selection environment. Our landscape provides new quantitative knowledge on the evolution of the β-lactamases and proteins in general, particularly their evolutionary dynamics under sub-inhibitory antibiotic concentrations, as well as the mechanisms and environmental dependence of nonspecific epistasis.

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Collateral fitness effects of mutations

Cited by 38 publications

References 63 publications

The Relationship between the Misfolding Avoidance Hypothesis and Protein Evolutionary Rates in the Light of Empirical Evidence

The Relationship between the Misfolding Avoidance Hypothesis and Protein Evolutionary Rates in the Light of Empirical Evidence

Fitness variation across subtle environmental perturbations reveals local modularity and global pleiotropy of adaptation

Environmental selection and epistasis in an empirical phenotype-environment-fitness landscape

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