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Small RNA regulation of an essential process induces bacterial resistance to aminoglycosides during oxidative stress
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International audience. Abstract Fe-S clusters are essential cofactors involved in many reactions across all domains of life. In Escherichia coli and other enterobacteria, Fe-S cluster synthesis involves two machineries: Isc and Suf. While Isc functions as a housekeeping system, Suf is activated under stress conditions such as iron starvation or oxidative stress. Interestingly, cells functioning under Suf show reduced entry of aminoglycosides, leading to resistance to these antibiotics. The transcriptional regulator IscR, itself an Fe-S cluster containing protein, controls the transition between Isc and Suf machineries. Noteworthy, IscR has a critical impact on the virulence of various bacterial pathogens by regulating both Fe-S biogenesis and other pathways directly linked to host adaptation. Here, we discovered that two small regulatory RNAs (sRNAs), FnrS and OxyS, control iscR expression by base-pairing to the 5’ UTR of the iscR mRNA. Remarkably, these sRNAs act in opposite ways and in opposite conditions: FnrS, expressed in anaerobiosis, represses the expression of iscR while OxyS, expressed during oxidative stress, activates it. Using an E. coli strain experiencing protracted oxidative stress, we further demonstrate that iscR expression is rapidly and significantly enhanced in the presence of OxyS. Strikingly, we further show that OxyS induces resistance to aminoglycosides during oxidative stress through this unexpected regulation of Fe-S clusters biogenesis, revealing a new role for this sRNA. Significance Statement This study sheds light on the regulatory mechanisms controlling the synthesis of essential Fe-S clusters in bacteria, revealing unexpected roles for two small RNAs (FnrS and OxyS) in modulating the expression of the transcriptional regulator IscR. The findings suggest that this regulatory network could lead bacterial resistance to aminoglycoside antibiotics during oxidative stress, a condition associated with chronic infections. Ultimately, this work highlights the importance of understanding the intricate regulatory networks controlling bacterial metabolism and adaptation to stress, which could have significant implications for public health.
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