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Bottleneck size and selection level reproducibly impact evolution of antibiotic resistance

Authors :
Niels Mahrt
Gunther Jansen
Sören Franzenburg
Sven Künzel
Camilo Barbosa
Hinrich Schulenburg
Alexandra Tietze
Source :
Nature Ecology & Evolution
Publication Year :
2021
Publisher :
Springer Science and Business Media LLC, 2021.

Abstract

During antibiotic treatment, the evolution of bacterial pathogens is fundamentally affected by bottlenecks and varying selection levels imposed by the drugs. Bottlenecks—that is, reductions in bacterial population size—lead to an increased influence of random effects (genetic drift) during bacterial evolution, and varying antibiotic concentrations during treatment may favour distinct resistance variants. Both aspects influence the process of bacterial evolution during antibiotic therapy and thereby treatment outcome. Surprisingly, the joint influence of these interconnected factors on the evolution of antibiotic resistance remains largely unexplored. Here we combine evolution experiments with genomic and genetic analyses to demonstrate that bottleneck size and antibiotic-induced selection reproducibly impact the evolutionary path to resistance in pathogenic Pseudomonas aeruginosa, one of the most problematic opportunistic human pathogens. Resistance is favoured—expectedly—under high antibiotic selection and weak bottlenecks, but—unexpectedly—also under low antibiotic selection and severe bottlenecks. The latter is likely to result from a reduced probability of losing favourable variants through drift under weak selection. Moreover, the absence of high resistance under low selection and weak bottlenecks is caused by the spread of low-resistance variants with high competitive fitness under these conditions. We conclude that bottlenecks, in combination with drug-induced selection, are currently neglected key determinants of pathogen evolution and outcome of antibiotic treatment.<br />Strong population bottlenecks in combination with weak antibiotic selection consistently favours the evolution of resistance across independently performed Pseudomonas aeruginosa evolution experiments.

Details

ISSN :
2397334X
Volume :
5
Database :
OpenAIRE
Journal :
Nature Ecology & Evolution
Accession number :
edsair.doi.dedup.....d3568623773caeb94f2e696586cc35ca
Full Text :
https://doi.org/10.1038/s41559-021-01511-2