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Laboratory Evolution Reveals Transcriptional Mechanisms Underlying Thermal Adaptation of <i>Escherichia coli</i>

Kevin Rychel, Ke Chen, Edward Catoiu, Connor A. Olson, Troy E. Sandberg, Ye Gao, Sibei Xu, Ying Hefner, Richard Szubin, Arjun Patel, Adam M. Feist, Bernhard Ø. Palsson

2025Genome Biology and Evolution6 citationsDOIOpen Access PDF

Abstract

Adaptive laboratory evolution is able to generate microbial strains, which exhibit extreme phenotypes, revealing fundamental biological adaptation mechanisms. Here, we use adaptive laboratory evolution to evolve Escherichia coli strains that grow at temperatures as high as 45.3 °C, a temperature lethal to wild-type cells. The strains adopted a hypermutator phenotype and employed multiple systems-level adaptations that made global analysis of the DNA mutations difficult. Given the challenge at the genomic level, we were motivated to uncover high-temperature tolerance adaptation mechanisms at the transcriptomic level. We employed independently modulated gene set (iModulon) analysis to reveal five transcriptional mechanisms underlying growth at high temperatures. These mechanisms were connected to acquired mutations, changes in transcriptome composition, sensory inputs, phenotypes, and protein structures. They are as follows: (i) downregulation of general stress responses while upregulating the specific heat stress responses, (ii) upregulation of flagellar basal bodies without upregulating motility and upregulation fimbriae, (iii) shift toward anaerobic metabolism, (iv) shift in regulation of iron uptake away from siderophore production, and (v) upregulation of yjfIJKL, a novel heat tolerance operon whose structures we predicted with AlphaFold. iModulons associated with these five mechanisms explain nearly half of all variance in the gene expression in the adapted strains. These thermotolerance strategies reveal that optimal coordination of known stress responses and metabolism can be achieved with a small number of regulatory mutations and may suggest a new role for large protein export systems. Adaptive laboratory evolution with transcriptomic characterization is a productive approach for elucidating and interpreting adaptation to otherwise lethal stresses.

Topics & Concepts

BiologyDownregulation and upregulationTranscriptomeAdaptation (eye)Experimental evolutionOperonGeneGeneticsPhenotypeRegulation of gene expressionCell biologyMotilityTranscriptional regulationGene expressionMutantComputational biologyAdaptive evolutionGene regulatory networkMutationIn silicoNegative selectionCellular adaptationMolecular evolutionStringent responseEvolution and Genetic DynamicsProtein Structure and DynamicsRNA and protein synthesis mechanisms
Laboratory Evolution Reveals Transcriptional Mechanisms Underlying Thermal Adaptation of <i>Escherichia coli</i> | Litcius