Abstract
Phenotypic resistance describes a bacterial population that becomes transiently resistant to an antibiotic without requiring a genetic change. We here investigated the role of the small regulatory RNA (sRNA) RyhB, a key contributor to iron homeostasis, in the phenotypic resistance of Escherichia coli to various classes of antibiotics. We found that RyhB induces phenotypic resistance to gentamicin, an aminoglycoside that targets the ribosome, when iron is scarce. RyhB induced resistance is due to the inhibition of respiratory complexes Nuo and Sdh activities. These complexes, which contain numerous Fe-S clusters, are crucial for generating a proton motive force (pmf) that allows gentamicin uptake. RyhB regulates negatively the expression of nuo and sdh, presumably by binding to their mRNAs and, as a consequence, inhibiting their translation. We further show that Isc Fe-S biogenesis machinery is essential for the maturation of Nuo. As RyhB also limits levels of the Isc machinery, we propose that RyhB may also indirectly impact the maturation of Nuo and Sdh. Notably, our study shows that respiratory complexes activity levels are predictive of the bacterial sensitivity to gentamicin. Altogether, these results unveil a new role for RyhB in the adaptation to antibiotic stress, an unprecedented consequence of its role in iron starvation stress response.
Highlights
The emergence and spread of bacterial multi-resistance to antibiotics has become a major health issue in the last decades, urging for the development of new anti-bacterial molecules and for a better understanding of the molecular mechanisms at work behind bacterial resistance [1,2]
We show that RyhB, a bacterial small regulatory RNA, decreases the sensitivity of Escherichia coli to the antibiotic gentamicin when iron is scarce, an environmental situation prevalent during host-pathogen interactions. This phenotypic resistance is related to the activity of the respiratory complexes Nuo and Sdh, which are producing the proton motive force allowing antibiotic uptake
RyhB is involved in sensitivity to the aminoglycoside gentamicin
Summary
The emergence and spread of bacterial multi-resistance to antibiotics has become a major health issue in the last decades, urging for the development of new anti-bacterial molecules and for a better understanding of the molecular mechanisms at work behind bacterial resistance [1,2]. In E. coli, Fe–S clusters are formed and brought to target proteins thanks to two dedicated biogenesis systems: the so called “housekeeping” Isc machinery, which homologs are found in mitochondria of eukaryotic organisms, and the stress-responsive Suf system, in which homologs are found in chloroplasts of plants [10,11]. These systems are responsible for the maturation of more than 150 Fe-S cluster containing proteins in E. coli, notably numerous proteins contained in the main respiratory complexes I (Nuo) and II (Sdh) [12,13,14]. Overall this study predicted that an environmental signal that induces the switch from Isc to Suf should induce a transient resistance to aminoglycosides
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