The genetic basis of the fitness costs of antimicrobial resistance: a meta‐analysis approach

The evolution of antibiotic resistance carries a fitness cost, expressed in terms of reduced competitive ability in the absence of antibiotics. This cost plays a key role in the dynamics of resistance by generating selection against resistance when bacteria encounter an antibiotic‐free environment....

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Veröffentlicht in:	Evolutionary applications 2015-03, Vol.8 (3), p.284-295
Hauptverfasser:	Vogwill, Tom, MacLean, R. Craig
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Sprache:	eng
Schlagworte:	adaptation Antibiotic resistance Antibiotics Antimicrobial agents Antimicrobial resistance Costs Drug resistance Epistasis fitness cost Genetic diversity Meta-analysis microbes Multidrug resistance Mutation Original plasmid Plasmids Reproductive fitness RNA polymerase
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creator	Vogwill, Tom MacLean, R. Craig
description	The evolution of antibiotic resistance carries a fitness cost, expressed in terms of reduced competitive ability in the absence of antibiotics. This cost plays a key role in the dynamics of resistance by generating selection against resistance when bacteria encounter an antibiotic‐free environment. Previous work has shown that the cost of resistance is highly variable, but the underlying causes remain poorly understood. Here, we use a meta‐analysis of the published resistance literature to determine how the genetic basis of resistance influences its cost. We find that on average chromosomal resistance mutations carry a larger cost than acquiring resistance via a plasmid. This may explain why resistance often evolves by plasmid acquisition. Second, we find that the cost of plasmid acquisition increases with the breadth of its resistance range. This suggests a potentially important limit on the evolution of extensive multidrug resistance via plasmids. We also find that epistasis can significantly alter the cost of mutational resistance. Overall, our study shows that the cost of antimicrobial resistance can be partially explained by its genetic basis. It also highlights both the danger associated with plasmidborne resistance and the need to understand why resistance plasmids carry a relatively low cost.
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subjects	adaptation Antibiotic resistance Antibiotics Antimicrobial agents Antimicrobial resistance Costs Drug resistance Epistasis fitness cost Genetic diversity Meta-analysis microbes Multidrug resistance Mutation Original plasmid Plasmids Reproductive fitness RNA polymerase
title	The genetic basis of the fitness costs of antimicrobial resistance: a meta‐analysis approach
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