Stimulating Transcription in Antibiotic-Tolerant Escherichia coli Sensitizes It to Fluoroquinolone and Nonfluoroquinolone Topoisomerase Inhibitors.

Antibiotic tolerant bacteria and persistent cells that remain alive after a course of antibiotic treatment can foster the chronicity of infections and the development of antibiotic resistance. Elucidating how bacteria overcome antibiotic action and devising strategies to bolster a new drug's activity can allow us to preserve our antibiotic arsenal. Here, we investigate strategies to potentiate the activities of topoisomerase inhibitors against nongrowing Escherichia coli that are often recalcitrant to existing antibiotics. We focus on sensitizing bacteria to the fluoroquinolone (FQ) levofloxacin (Levo) and to the spiropyrimidinetrione zoliflodacin (Zoli)-the first antibiotic in its class of compounds in clinical development. We found that metabolic stimulation either alone or in combination with inhibiting the AcrAB-TolC efflux pump sensitized stationary-phase E. coli to Levo and Zoli. We demonstrate that the added metabolites increased proton motive force generation and ATP production in stationary-phase cultures without restarting growth. Instead, the stimulated bacteria increased transcription and translation, which rendered the populations more susceptible to topoisomerase inhibitors. Our findings illuminate potential vulnerabilities of antibiotic-tolerant bacteria that can be leveraged to sensitize them to new and existing classes of topoisomerase inhibitors. These approaches enable us to stay one step ahead of adaptive bacteria and safeguard the efficacy of our existing antibiotics.

Single-Cell Technologies to Study Phenotypic Heterogeneity and Bacterial Persisters.

Antibiotic persistence is a phenomenon in which rare cells of a clonal bacterial population can survive antibiotic doses that kill their kin, even though the entire population is genetically susceptible. With antibiotic treatment failure on the rise, there is growing interest in understanding the molecular mechanisms underlying bacterial phenotypic heterogeneity and antibiotic persistence. However, elucidating these rare cell states can be technically challenging. The advent of single-cell techniques has enabled us to observe and quantitatively investigate individual cells in complex, phenotypically heterogeneous populations. In this review, we will discuss current technologies for studying persister phenotypes, including fluorescent tags and biosensors used to elucidate cellular processes; advances in flow cytometry, mass spectrometry, Raman spectroscopy, and microfluidics that contribute high-throughput and high-content information; and next-generation sequencing for powerful insights into genetic and transcriptomic programs. We will further discuss existing knowledge gaps, cutting-edge technologies that can address them, and how advances in single-cell microbiology can potentially improve infectious disease treatment outcomes.

The AcrAB-TolC Efflux Pump Impacts Persistence and Resistance Development in Stationary-Phase Escherichia coli following Delafloxacin Treatment.

Bacteria have a repertoire of strategies to overcome antibiotics in clinical use, complicating our ability to treat and cure infectious diseases. In addition to evolving resistance, bacteria within genetically clonal cultures can undergo transient phenotypic changes and tolerate high doses of antibiotics. These cells, termed persisters, exhibit heterogeneous phenotypes; the strategies that a bacterial population deploys to overcome one class of antibiotics can be distinct from those needed to survive treatment with drugs with another mode of action. It was previously reported that fluoroquinolones, which target DNA topoisomerases, retain the capacity to kill nongrowing bacteria that tolerate other classes of antibiotics. Here, we show that in Escherichia coli stationary-phase cultures and colony biofilms, persisters that survive treatment with the anionic fluoroquinolone delafloxacin depend on the AcrAB-TolC efflux pump. In contrast, we did not detect this dependence on AcrAB-TolC in E. coli persisters that survive treatment with three other fluoroquinolone compounds. We found that the loss of AcrAB-TolC activity via genetic mutations or chemical inhibition not only reduces delafloxacin persistence in nongrowing E. coli MG1655 or EDL933 (an E. coli O157:H7 strain), but it limits resistance development in progenies derived from delafloxacin persisters that were given the opportunity to recover in nutritive medium following antibiotic treatment. Our findings highlight the heterogeneity in defense mechanisms that persisters use to overcome different compounds within the same class of antibiotics. They further indicate that efflux pump inhibitors can potentiate the activity of delafloxacin against stationary-phase E. coli and block resistance development in delafloxacin persister progenies.