A multifaceted cellular damage repair and prevention pathway promotes high level tolerance to β-lactam antibiotics

Abstract: 18Bactericidal antibiotics are powerful drugs due to their ability to not only inhibit essential 19 bacterial functions, but to convert them into toxic (and potentially lethal) processes. 20However, many important bacterial pathogens are remarkably tolerant against 21 bactericidal drugs, due to inducible stress responses that repair antibiotic-induced 22 damage. The mechanistic details of how stress responses promote whole population 23 tolerance in important human pathogens are unknown. The two-component syst… Show more

“…Intriguingly, V. cholerae accumulates high intracellular iron levels upon β-lactam exposure and this is exacerbated in the vxrAB mutant. 128 Further, β-lactam exposure resulted in induction of the Fur iron starvation response, likely due to direct oxidation of its Fe 2+ corepressor by β-lactam-induced H 2 O 2 production. 128 It thus appears that VxrAB's role in tolerance is at least partially to tone down an out-of-control iron starvation response that would otherwise overload β-lactam-stressed cells with iron, causing downstream toxic events like the generation of ROS.…”

“…128 Further, β-lactam exposure resulted in induction of the Fur iron starvation response, likely due to direct oxidation of its Fe 2+ corepressor by β-lactam-induced H 2 O 2 production. 128 It thus appears that VxrAB's role in tolerance is at least partially to tone down an out-of-control iron starvation response that would otherwise overload β-lactam-stressed cells with iron, causing downstream toxic events like the generation of ROS. Consistent with this model, deleting iron transporters partially restored high tolerance levels to a vxrAB mutant.…”

“…Thus, not surprisingly, exposure to such agents results in various sequelae that reflect distinct cellular responses as well as purely physical consequences of massive cell wall damage. Exposure to β-lactams has been tied to the generation of reactive oxygen species (ROS), 125 or not; 126,127 activation of iron uptake; 128 changes in TCA cycle intermediate concentrations; 129 induction of the heat shock response; 130,131 induction of the SOS DNA damage response; 132,133 RNA degradation; 116,134 and stringent response (SR) induction. 135 In principle, any or all of these processes may contribute to some degree to β-lactam-mediated cell death (or tolerance, as shall be considered later), but their detailed contributions have remained poorly understood.…”

“…Consistent with this model, deleting iron transporters partially restored high tolerance levels to a vxrAB mutant. 128 The VxrAB system thus aptly illustrates the complex physiological consequences of β-lactam exposure and tolerance pathways, where cells not only have to overcome cell wall loss, but also remediate toxic iron influx and potentially downstream accumulation of toxic ROS.…”

Understanding tolerance to cell wall–active antibiotics

“…Intriguingly, V. cholerae accumulates high intracellular iron levels upon β-lactam exposure and this is exacerbated in the vxrAB mutant. 128 Further, β-lactam exposure resulted in induction of the Fur iron starvation response, likely due to direct oxidation of its Fe 2+ corepressor by β-lactam-induced H 2 O 2 production. 128 It thus appears that VxrAB's role in tolerance is at least partially to tone down an out-of-control iron starvation response that would otherwise overload β-lactam-stressed cells with iron, causing downstream toxic events like the generation of ROS.…”

“…128 Further, β-lactam exposure resulted in induction of the Fur iron starvation response, likely due to direct oxidation of its Fe 2+ corepressor by β-lactam-induced H 2 O 2 production. 128 It thus appears that VxrAB's role in tolerance is at least partially to tone down an out-of-control iron starvation response that would otherwise overload β-lactam-stressed cells with iron, causing downstream toxic events like the generation of ROS. Consistent with this model, deleting iron transporters partially restored high tolerance levels to a vxrAB mutant.…”

“…Thus, not surprisingly, exposure to such agents results in various sequelae that reflect distinct cellular responses as well as purely physical consequences of massive cell wall damage. Exposure to β-lactams has been tied to the generation of reactive oxygen species (ROS), 125 or not; 126,127 activation of iron uptake; 128 changes in TCA cycle intermediate concentrations; 129 induction of the heat shock response; 130,131 induction of the SOS DNA damage response; 132,133 RNA degradation; 116,134 and stringent response (SR) induction. 135 In principle, any or all of these processes may contribute to some degree to β-lactam-mediated cell death (or tolerance, as shall be considered later), but their detailed contributions have remained poorly understood.…”

“…Consistent with this model, deleting iron transporters partially restored high tolerance levels to a vxrAB mutant. 128 The VxrAB system thus aptly illustrates the complex physiological consequences of β-lactam exposure and tolerance pathways, where cells not only have to overcome cell wall loss, but also remediate toxic iron influx and potentially downstream accumulation of toxic ROS.…”

Understanding tolerance to cell wall–active antibiotics

“…Similar to L-forms, the activity of cell wall lytic enzymes is required for spheroplast formation [ 20 ]. Recovery from the spheroplast state requires cell envelope stress responses, cell wall synthesis functions, and likely, a reduction in the formation of ROS [ 23 ]. The key difference between spheroplasts and L-forms is that the former do not divide.…”

Antibiotic tolerance

RNA-mediated control of cell shape modulates antibiotic resistance in Vibrio cholerae