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High-throughput laboratory evolution reveals evolutionary constraints in Escherichia coli

Tomoya Maeda, Junichiro Iwasawa, Hazuki Kotani, Natsue Sakata, Masako Kawada, Takaaki Horinouchi, Aki Sakai, Kumi Tanabe, Chikara Furusawa

2020Nature Communications94 citationsDOIOpen Access PDF

Abstract

Understanding the constraints that shape the evolution of antibiotic resistance is critical for predicting and controlling drug resistance. Despite its importance, however, a systematic investigation of evolutionary constraints is lacking. Here, we perform a high-throughput laboratory evolution of Escherichia coli under the addition of 95 antibacterial chemicals and quantified the transcriptome, resistance, and genomic profiles for the evolved strains. Utilizing machine learning techniques, we analyze the phenotype-genotype data and identified low dimensional phenotypic states among the evolved strains. Further analysis reveals the underlying biological processes responsible for these distinct states, leading to the identification of trade-off relationships associated with drug resistance. We also report a decelerated evolution of β-lactam resistance, a phenomenon experienced by certain strains under various stresses resulting in higher acquired resistance to β-lactams compared to strains directly selected by β-lactams. These findings bridge the genotypic, gene expression, and drug resistance gap, while contributing to a better understanding of evolutionary constraints for antibiotic resistance.

Topics & Concepts

BiologyEscherichia coliAntibiotic resistancePhenotypeDrug resistanceComputational biologyTranscriptomeGeneGeneticsExperimental evolutionGenotypeResistance (ecology)GenomicsBacterial geneticsEvolutionary biologyAntibioticsGene expressionGenomeEcologyEvolution and Genetic DynamicsGenomics and Phylogenetic StudiesRNA and protein synthesis mechanisms
High-throughput laboratory evolution reveals evolutionary constraints in Escherichia coli | Litcius