Evolution Under Thermal Stress Affects 's Resistance to Antibiotics

Overview

Journal bioRxiv

Date 2024 Mar 11

PMID 38464198

Authors

Austin Bullivant

Natalie Lozano-Huntelman

Kevin Tabibian

Vivien Leung

Dylan Armstrong

Henry Dudley

Van M Savage

Alejandra Rodriguez-Verdugo

Pamela J Yeh

Affiliations

Soon will be listed here.

Abstract

Exposure to both antibiotics and temperature changes can induce similar physiological responses in bacteria. Thus, changes in growth temperature may affect antibiotic resistance. Previous studies have found that evolution under antibiotic stress causes shifts in the optimal growth temperature of bacteria. However, little is known about how evolution under thermal stress affects antibiotic resistance. We examined 100+ heat-evolved strains of that evolved under thermal stress. We asked whether evolution under thermal stress affects optimal growth temperature, if there are any correlations between evolving in high temperatures and antibiotic resistance, and if these strains' antibiotic efficacy changes depending on the local environment's temperature. We found that: (1) surprisingly, most of the heat-evolved strains displayed a decrease in optimal growth temperature and overall growth relative to the ancestor strain, (2) there were complex patterns of changes in antibiotic resistance when comparing the heat-evolved strains to the ancestor strain, and (3) there were few significant correlations among changes in antibiotic resistance, optimal growth temperature, and overall growth.

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