Fitness Effects of Altering Gene Expression Noise in

Overview

Journal Elife

Specialty Biology

Date 2018 Aug 21

PMID 30124429

Citations 35

Authors

Fabien Duveau

Andrea Hodgins-Davis

Brian Ph Metzger

Bing Yang

Stephen Tryban

Elizabeth A Walker

Tricia Lybrook

Patricia J Wittkopp

Affiliations

Soon will be listed here.

Abstract

Gene expression noise is an evolvable property of biological systems that describes differences in expression among genetically identical cells in the same environment. Prior work has shown that expression noise is heritable and can be shaped by selection, but the impact of variation in expression noise on organismal fitness has proven difficult to measure. Here, we quantify the fitness effects of altering expression noise for the gene in . We show that increases in expression noise can be deleterious or beneficial depending on the difference between the average expression level of a genotype and the expression level maximizing fitness. We also show that a simple model relating single-cell expression levels to population growth produces patterns consistent with our empirical data. We use this model to explore a broad range of average expression levels and expression noise, providing additional insight into the fitness effects of variation in expression noise.

Citing Articles

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Plasticity and environment-specific relationships between gene expression and fitness in Saccharomyces cerevisiae.

Siddiq M, Duveau F, Wittkopp P Nat Ecol Evol. 2024; 8(12):2184-2194.

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Stress-Induced Constraint on Expression Noise of Essential Genes in E. coli.

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Genome-wide analyses of variance in blood cell phenotypes provide new insights into complex trait biology and prediction.

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Plasticity and environment-specific relationships between gene expression and fitness in .

Siddiq M, Duveau F, Wittkopp P bioRxiv. 2024; .

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