Project description:Persisters are rare phenotypic variants that can survive bactericidal doses of antibiotics and resume growth after the conclusion of treatment. They are suspected to be culprits of recurrent infections, and are distinct from resistant mutants because they are genetically identical to bacteria that die from treatment. Persisters to fluoroquinolones (FQs) experience DNA damage from treatment in stationary-phase culture, which suggests that FQs can corrupt their primary target, DNA gyrase, even in these super-tolerant cells. Since DNA damage from FQs originates from its stabilization of DNA gyrase in complexes with cleaved DNA, we hypothesized that the characteristics of FQ-stabilized DNA gyrase cleavage sites (GCS), such as the abundance, and/or location, might be influential to persistence. To test this hypothesis, we measured genome-wide distributions of GCS after treatment with a panel of FQs.We found drug-specific effects on the location and abundances of GCSs and discovered a negative correlation between the number of GCSs and FQ persister levels. Further, additional experiments and analyses suggested that persister levels are not governed by cleavage to a single specific site, but rather survival is a more complex function with respect to GCSs. Together, these findings demonstrate that there are drug specific differences in GCSs that correlate with persister levels, and suggest that the ability of an FQ to stabilize DNA-gyrase complexes at more sites will improve its bactericidal ability.

Project description:Persisters are rare phenotypic variants that can survive bactericidal doses of antibiotics and resume growth after the conclusion of treatment. They are suspected to be culprits of recurrent infections, and are distinct from resistant mutants because they are genetically identical to bacteria that die from treatment. Persisters to fluoroquinolones (FQs) experience DNA damage from treatment in stationary-phase culture, which suggests that FQs can corrupt their primary target, DNA gyrase, even in these super-tolerant cells. Since DNA damage from FQs originates from its stabilization of DNA gyrase in complexes with cleaved DNA, we hypothesized that the characteristics of FQ-stabilized DNA gyrase cleavage sites (GCS), such as the abundance, and/or location, might be influential to persistence. To test this hypothesis, we measured genome-wide distributions of GCS after treatment with a panel of FQs.We found drug-specific effects on the location and abundances of GCSs and discovered a negative correlation between the number of GCSs and FQ persister levels. Further, additional experiments and analyses suggested that persister levels are not governed by cleavage to a single specific site, but rather survival is a more complex function with respect to GCSs. Together, these findings demonstrate that there are drug specific differences in GCSs that correlate with persister levels, and suggest that the ability of an FQ to stabilize DNA-gyrase complexes at more sites will improve its bactericidal ability.

Project description:Fluoroquinolone-induced gyrase cleavage sites

Project description:The effects of three fluoroquinolones, two aminocoumarins and two cystobactamids, all inhibiting bacterial gyrase, on Pseudomonas aeruginosa PA14 at sub-inhibitory concentrations were captured by untargeted metabolomics.

Project description:Targeting bacterial gyrase with cystobactamid, fluoroquinolone and aminocoumarin antibiotics induces distinct molecular signatures in Pseudomonas aeruginosa

Project description:DNA gyrase is an essential enzyme whose activity is required for DNA replication and chromosome maintenance. Inhibition of gyrase results in multiple physiological effects including changes in DNA superhelicity, replication arrest and DNA damage. Using genetic, genomic, statistical and biochemical techniques, we have untangled the contribution of individual effects, assessed their relative significance and concluded that: i) DNA replication is required for the formation of spatial transcriptional domains; ii) transcriptional response to gyrase inhibition is coordinated between at least two modules involved in DNA maintenance, relaxation and damage response; iii) genes whose transcriptional response to gyrase inhibition does not depend on the activity of topoisomerase I can be classified on the basis of the GC excess in their upstream and coding sequences into, respectively, activated and repressed by gyrase inhibition; iv) relaxation by topoisomerase I dominates the transcriptional response upon gyrase inhibition, followed by the effects of replication and RecA. Keywords: time course

Project description:The design of novel antibiotics relies on a profound understanding of their mechanism of action. While it has been shown that cellular effects of antibiotics cluster according to their molecular targets, we investigated whether compounds binding to different sites of the same target can be differentiated by their transcriptome or metabolome signatures. The effects of three fluoroquinolones, two aminocoumarins, and two cystobactamids, all inhibiting bacterial gyrase, on Pseudomonas aeruginosa at subinhibitory concentrations could be distinguished clearly by RNA sequencing as well as metabolomics. We observed a strong (2.8- to 212-fold) induction of autolysis-triggering pyocins in all gyrase inhibitors, which correlated with extracellular DNA (eDNA) release. Gyrase B-binding aminocoumarins induced the most pronounced changes, including a strong downregulation of phenazine and rhamnolipid virulence factors. Cystobactamids led to a downregulation of a glucose catabolism pathway. The study implies that clustering cellular mechanisms of action according to the primary target needs to take class-dependent variances into account. IMPORTANCE Novel antibiotics are urgently needed to tackle the growing worldwide problem of antimicrobial resistance. Bacterial pathogens possess few privileged targets for a successful therapy: the majority of existing antibiotics as well as current candidates in development target the complex bacterial machinery for cell wall synthesis, protein synthesis, or DNA replication. An important mechanistic question addressed by this study is whether inhibiting such a complex target at different sites with different compounds has similar or differentiated cellular consequences. Using transcriptomics and metabolomics, we demonstrate that three different classes of gyrase inhibitors can be distinguished by their molecular signatures in P. aeruginosa. We describe the cellular effects of a promising, recently identified gyrase inhibitor class, the cystobactamids, in comparison to those of the established gyrase A-binding fluoroquinolones and the gyrase B-binding aminocoumarins. The study results have implications for mode-of-action discovery approaches based on target-specific reference compounds, as they highlight the intraclass variability of cellular compound effects.

Project description:Antibiotics in low concentrations may have an array of effects. We have exposed growing P. aeruginosa cells to different classes of antibiotics in order to investigate this hypothesis. We have used DNA microarrays to investigate the effect of low concentrations of antibiotics (azithromycin, ceftazidime and ciprofloxacin) on the gene expression of P. aeruginosa aiming to elucidate general trends. Keywords: Treatment with antibiotics

Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:We studied the transcriptomic response of S. pneumoniae to moxifloxacin, a fluoroquinolone that inhibits DNA gyrase. At 10 × MIC, 30 and 140 responsive genes were detected at 15 and 30 minutes, respectively. Several pathways leading to an increase in pyruvate showed up-regulation. These included 2 genes introducing P-sugars into the glycolysis and 3 out of 7 genes of the glycolysis pathway, which converts fructose-6P to pyruvate. In addition, an increase in acetyl-coA would be expected from the down-regulation of the genes coding for the acetyl-coA carboxylase, and in turn, to a further increase in pyruvate by the up-regulation of formate acetyltransferase. Since pyruvate is converted to hydrogen peroxide (H2O2) by pyruvate oxidase (SpxB), its increase would lead to an equivalent increase in the intracellular amount of H2O2, and in turn, in those of hydroxyl radicals resulting from the Fenton reaction, which damage DNA, lipids and proteins. We observed similar increases in the production of H2O2 and hydroxyl radicals under moxifloxacin treatment. These reactive oxygen species contributed to the lethality of the drug, as showed by the attenuation of its lethality in a strain lacking SpxB. These results support the production of redox alterations by fluoroquinolones and are in agreement with our previous findings showing that levofloxacin, an inhibitor of topoisomerase IV, triggers the transcriptional activation of iron transport genes. Both fluoroquinolones stimulate the Fenton reaction in their mechanism of action, by increasing the amounts of any of their two components: iron by levofloxacin or H2O2 by moxifloxacin.