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Evolutionary Responses to Acquiring a Multidrug Resistance Plasmid Are Dominated by Metabolic Functions across Diverse Escherichia coli Lineages

Laura Carrilero, Steven Dunn, Robert A. Moran, Alan McNally, Michael A. Brockhurst

2023mSystems30 citationsDOIOpen Access PDF

Abstract

Plasmids drive the spread of antimicrobial resistance genes between bacterial genomes. However, the evolutionary processes allowing plasmids to be assimilated by diverse bacterial genomes are poorly understood, especially in clinical pathogens. Using experimental evolution with diverse E. coli lineages and a clinical multidrug resistance plasmid, we show that although plasmids drove unique evolutionary paths per lineage, there was a surprising degree of convergence in the functions targeted by mutations across lineages, dominated by metabolic functions. Remarkably, these same metabolic functions show higher evolutionary rates in MDR-lineages in nature and in some cases, like anaerobic metabolism, their expression is directly manipulated by the plasmid. Interactions with other mobile elements resident in the genomes accelerated adaptation by disrupting genes and regulatory sequences that they inserted into. Beyond their role in horizontal gene transfer, plasmids are an important selective force driving the evolution of bacterial genomes and core cellular functions.

Topics & Concepts

PlasmidEscherichia coliMultiple drug resistanceBiologyMicrobiologyGeneticsResistance (ecology)Evolutionary biologyDrug resistanceGeneEcologyAntibiotic Resistance in BacteriaDrug Transport and Resistance MechanismsBacterial Genetics and Biotechnology
Evolutionary Responses to Acquiring a Multidrug Resistance Plasmid Are Dominated by Metabolic Functions across Diverse Escherichia coli Lineages | Litcius