TY - JOUR
T1 - Adaptive Resistance Mutations at Suprainhibitory Concentrations Independent of SOS Mutagenesis
AU - Gutiérrez, Ricardo
AU - Ram, Yoav
AU - Berman, Judith
AU - De Sousa, Keyla Carstens Marques
AU - Nachum-Biala, Yaarit
AU - Britzi, Malka
AU - Elad, Daniel
AU - Glaser, Gad
AU - Covo, Shay
AU - Harrus, Shimon
N1 - Publisher Copyright: © 2021 The Author(s) 2021. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution.
PY - 2021/10/1
Y1 - 2021/10/1
N2 - Emergence of resistant bacteria during antimicrobial treatment is one of the most critical and universal health threats. It is known that several stress-induced mutagenesis and heteroresistance mechanisms can enhance microbial adaptation to antibiotics. Here, we demonstrate that the pathogen Bartonella can undergo stress-induced mutagenesis despite the fact it lacks error-prone polymerases, the rpoS gene and functional UV-induced mutagenesis. We demonstrate that Bartonella acquire de novo single mutations during rifampicin exposure at suprainhibitory concentrations at a much higher rate than expected from spontaneous fluctuations. This is while exhibiting a minimal heteroresistance capacity. The emerged resistant mutants acquired a single rpoB mutation, whereas no other mutations were found in their whole genome. Interestingly, the emergence of resistance in Bartonella occurred only during gradual exposure to the antibiotic, indicating that Bartonella sense and react to the changing environment. Using a mathematical model, we demonstrated that, to reproduce the experimental results, mutation rates should be transiently increased over 1,000-folds, and a larger population size or greater heteroresistance capacity is required. RNA expression analysis suggests that the increased mutation rate is due to downregulation of key DNA repair genes (mutS, mutY, and recA), associated with DNA breaks caused by massive prophage inductions. These results provide new evidence of the hazard of antibiotic overuse in medicine and agriculture.
AB - Emergence of resistant bacteria during antimicrobial treatment is one of the most critical and universal health threats. It is known that several stress-induced mutagenesis and heteroresistance mechanisms can enhance microbial adaptation to antibiotics. Here, we demonstrate that the pathogen Bartonella can undergo stress-induced mutagenesis despite the fact it lacks error-prone polymerases, the rpoS gene and functional UV-induced mutagenesis. We demonstrate that Bartonella acquire de novo single mutations during rifampicin exposure at suprainhibitory concentrations at a much higher rate than expected from spontaneous fluctuations. This is while exhibiting a minimal heteroresistance capacity. The emerged resistant mutants acquired a single rpoB mutation, whereas no other mutations were found in their whole genome. Interestingly, the emergence of resistance in Bartonella occurred only during gradual exposure to the antibiotic, indicating that Bartonella sense and react to the changing environment. Using a mathematical model, we demonstrated that, to reproduce the experimental results, mutation rates should be transiently increased over 1,000-folds, and a larger population size or greater heteroresistance capacity is required. RNA expression analysis suggests that the increased mutation rate is due to downregulation of key DNA repair genes (mutS, mutY, and recA), associated with DNA breaks caused by massive prophage inductions. These results provide new evidence of the hazard of antibiotic overuse in medicine and agriculture.
KW - Bartonella
KW - antibiotic resistance
KW - evolution
KW - rifampicin
KW - slow-growing bacteria
UR - http://www.scopus.com/inward/record.url?scp=85117740130&partnerID=8YFLogxK
U2 - https://doi.org/10.1093/molbev/msab196
DO - https://doi.org/10.1093/molbev/msab196
M3 - مقالة
C2 - 34175952
SN - 0737-4038
VL - 38
SP - 4095
EP - 4115
JO - Molecular Biology and Evolution
JF - Molecular Biology and Evolution
IS - 10
ER -