Patterns of Fitness and Gene Expression Epistasis Generated by Beneficial Mutations in the rho and rpoB Genes of Escherichia coli during High-Temperature Adaptation.

IF 11 1区 生物学 Q1 BIOCHEMISTRY & MOLECULAR BIOLOGY
Andrea González-González, Tiffany N Batarseh, Alejandra Rodríguez-Verdugo, Brandon S Gaut
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Abstract

Epistasis is caused by genetic interactions among mutations that affect fitness. To characterize properties and potential mechanisms of epistasis, we engineered eight double mutants that combined mutations from the rho and rpoB genes of Escherichia coli. The two genes encode essential functions for transcription, and the mutations in each gene were chosen because they were beneficial for adaptation to thermal stress (42.2 °C). The double mutants exhibited patterns of fitness epistasis that included diminishing returns epistasis at 42.2 °C, stronger diminishing returns between mutations with larger beneficial effects and both negative and positive (sign) epistasis across environments (20.0 °C and 37.0 °C). By assessing gene expression between single and double mutants, we detected hundreds of genes with gene expression epistasis. Previous work postulated that highly connected hub genes in coexpression networks have low epistasis, but we found the opposite: hub genes had high epistasis values in both coexpression and protein-protein interaction networks. We hypothesized that elevated epistasis in hub genes reflected that they were enriched for targets of Rho termination but that was not the case. Altogether, gene expression and coexpression analyses revealed that thermal adaptation occurred in modules, through modulation of ribonucleotide biosynthetic processes and ribosome assembly, the attenuation of expression in genes related to heat shock and stress responses, and with an overall trend toward restoring gene expression toward the unstressed state.

高温适应过程中大肠杆菌 rho 和 rpoB 基因有益突变产生的适应性和基因表达表观模式。
外显性是由影响适存性的突变之间的遗传相互作用引起的。为了描述表观遗传的特性和潜在机制,我们设计了八个结合了大肠杆菌 rho 和 rpoB 基因突变的双突变体。这两个基因编码转录的基本功能,选择每个基因的突变是因为它们有利于适应热应激(42.2°C)。双突变体表现出适应性外显的模式,包括在42.2°C时的递减回报外显,在具有较大有益效应的突变之间的较强递减回报,以及在不同环境(20.0°C和37.0°C)下的负外显和正(符号)外显。通过评估单突变体和双突变体之间的基因表达,我们发现了数百个具有基因表达外显性的基因。以前的研究推测,共表达网络中高度连接的中心基因具有较低的表观性,但我们发现情况恰恰相反:中心基因在共表达和蛋白质相互作用网络中都具有较高的表观性。我们假设中枢基因的上位性升高反映了它们富集了 Rho 终止的靶标,但事实并非如此。总之,基因表达和共表达分析表明,热适应是通过调节核糖核苷酸生物合成过程和核糖体组装、减弱与热休克和应激反应有关的基因的表达以及使基因表达恢复到非应激状态的总体趋势等模块实现的。
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来源期刊
Molecular biology and evolution
Molecular biology and evolution 生物-进化生物学
CiteScore
19.70
自引率
3.70%
发文量
257
审稿时长
1 months
期刊介绍: Molecular Biology and Evolution Journal Overview: Publishes research at the interface of molecular (including genomics) and evolutionary biology Considers manuscripts containing patterns, processes, and predictions at all levels of organization: population, taxonomic, functional, and phenotypic Interested in fundamental discoveries, new and improved methods, resources, technologies, and theories advancing evolutionary research Publishes balanced reviews of recent developments in genome evolution and forward-looking perspectives suggesting future directions in molecular evolution applications.
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