Wendy W. K. Mok

The role of metabolism in bacterial persistence

Bacterial persisters are phenotypic variants with extraordinary tolerances toward antibiotics. Persister survival has been attributed to inhibition of essential cell functions during antibiotic stress, followed by reversal of the process and resumption of growth upon removal of the antibiotic. Metabolism plays a critical role in this process, since it participates in the entry, maintenance, and exit from the persister phenotype. Here, we review the experimental evidence that demonstrates the importance of metabolism to persistence, highlight the successes and potential of targeting metabolism in the search for anti-persister therapies, and discuss the current methods and challenges to understand persister physiology.

RNA Futile Cycling in Model Persisters Derived from MazF Accumulation

ABSTRACT Metabolism plays an important role in the persister phenotype, as evidenced by the number of strategies that perturb metabolism to sabotage this troublesome subpopulation. However, the absence of techniques to isolate high-purity populations of native persisters has precluded direct measurement of persister metabolism. To address this technical challenge, we studied Escherichia coli populations whose growth had been inhibited by the accumulation of the MazF toxin, which catalyzes RNA cleavage, as a model system for persistence. Using chromosomally integrated, orthogonally inducible promoters to express MazF and its antitoxin MazE, bacterial populations that were almost entirely tolerant to fluoroquinolone and β-lactam antibiotics were obtained upon MazF accumulation, and these were subjected to direct metabolic measurements. While MazF model persisters were nonreplicative, they maintained substantial oxygen and glucose consumption. Metabolomic analysis revealed accumulation of all four ribonucleotide monophosphates (NMPs). These results are consistent with a MazF-catalyzed RNA futile cycle, where the energy derived from catabolism is dissipated through continuous transcription and MazF-mediated RNA degradation. When transcription was inhibited, oxygen consumption and glucose uptake decreased, and nucleotide triphosphates (NTPs) and NTP/NMP ratios increased. Interestingly, the MazF-inhibited cells were sensitive to aminoglycosides, and this sensitivity was blocked by inhibition of transcription. Thus, in MazF model persisters, futile cycles of RNA synthesis and degradation result in both significant metabolic demands and aminoglycoside sensitivity. IMPORTANCE Metabolism plays a critical role in controlling each stage of bacterial persistence (shutdown, stasis, and reawakening). In this work, we generated an E. coli strain in which the MazE antitoxin and MazF toxin were artificially and independently inducible, and we used this strain to generate model persisters and study their metabolism. We found that even though growth of the model persisters was inhibited, they remained highly metabolically active. We further uncovered a futile cycle driven by continued transcription and MazF-mediated transcript degradation that dissipated the energy derived from carbon catabolism. Interestingly, the existence of this futile cycle acted as an Achilles’ heel for MazF model persisters, rendering them vulnerable to killing by aminoglycosides. Metabolism plays a critical role in controlling each stage of bacterial persistence (shutdown, stasis, and reawakening). In this work, we generated an E. coli strain in which the MazE antitoxin and MazF toxin were artificially and independently inducible, and we used this strain to generate model persisters and study their metabolism. We found that even though growth of the model persisters was inhibited, they remained highly metabolically active. We further uncovered a futile cycle driven by continued transcription and MazF-mediated transcript degradation that dissipated the energy derived from carbon catabolism. Interestingly, the existence of this futile cycle acted as an Achilles’ heel for MazF model persisters, rendering them vulnerable to killing by aminoglycosides.

Impacts of Global Transcriptional Regulators on Persister Metabolism

ABSTRACT Bacterial persisters are phenotypic variants with an extraordinary capacity to tolerate antibiotics, and they are hypothesized to be a main cause of chronic and relapsing infections. Recent evidence has suggested that the metabolism of persisters can be targeted to develop therapeutic countermeasures; however, knowledge of persister metabolism remains limited due to difficulties associated with isolating these rare and transient phenotypic variants. By using a technique to measure persister catabolic activity, which is based on the ability of metabolites to enable aminoglycoside (AG) killing of persisters, we investigated the role of seven global transcriptional regulators (ArcA, Cra, cyclic AMP [cAMP] receptor protein [CRP], DksA, FNR, Lrp, and RpoS) on persister metabolism. We found that removal of CRP resulted in a loss of AG potentiation in persisters for all metabolites tested. These results highlight a central role for cAMP/CRP in persister metabolism, as its perturbation can significantly diminish the metabolic capabilities of persisters and effectively eliminate the ability of AGs to eradicate these troublesome bacteria.

Aminoglycoside-enabled elucidation of bacterial persister metabolism.

Bacterial persisters are cells with an impressive, yet transient, tolerance toward extraordinary concentrations of antibiotics. Persisters are believed to impose a significant burden on the healthcare system because of their role in the proclivity of infections to relapse. During antibiotic challenge, these rare, phenotypic variants enter a dormant state where antibiotic primary targets are rendered inactive, allowing them to survive. Once the antibiotic is removed, persisters reawaken and resume growth, leading to repopulation of the environment. Metabolism plays a pivotal role in coordinating the entry, maintenance, and exit from the persister state. However, the low abundance, transient nature, and similarity of persisters to other cell types have prevented their isolation, which is needed for direct metabolic measurements. In this unit, we describe a technique known as the aminoglycoside (AG) potentiation assay, which can be used to rapidly and specifically measure the breadth of persister metabolism in heterogeneous populations.

An Orphan Riboswitch Unveils Guanidine Regulation in Bacteria

In this issue, Nelson and colleagues (2017) determined that guanidine, the prevalent protein denaturant, is the long-lost ligand sensed by the ykkC class of riboswitches, and identified that members of its regulon are involved in guanidine detoxification and export.

Non-Monotonic Survival of Staphylococcus aureus with Respect to Ciprofloxacin Concentration Arises from Prophage-Dependent Killing of Persisters.

Staphylococcus aureus is a notorious pathogen with a propensity to cause chronic, non-healing wounds. Bacterial persisters have been implicated in the recalcitrance of S. aureus infections, and this motivated us to examine the persistence of S. aureus to ciprofloxacin, a quinolone antibiotic. Upon treatment of exponential phase S. aureus with ciprofloxacin, we observed that survival was a non-monotonic function of ciprofloxacin concentration. Maximal killing occurred at 1 µg/mL ciprofloxacin, which corresponded to survival that was up to ~40-fold lower than that obtained with concentrations ≥ 5 µg/mL. Investigation of this phenomenon revealed that the non-monotonic response was associated with prophage induction, which facilitated killing of S. aureus persisters. Elimination of prophage induction with tetracycline was found to prevent cell lysis and persister killing. We anticipate that these findings may be useful for the design of quinolone treatments.

Small Size, Big Impact: Bacterial Functional Nucleic Acids and Their Applications

Genome mining efforts carried out across diverse bacterial genomes over the past two decades have paid off handsomely, leading to the discovery of a plethora of regulatory RNAs. These RNAs include riboswitches—a class of ligand responsive gene regulating elements—and small RNAs (sRNA)—short RNA or protein targeting sequences. Together, this ensemble of RNAs orchestrates and fine-tunes metabolic, stress response, and virulence pathways. These RNAs are key players in genetic networks. Searches for novel regulatory RNAs and their subsequent characterization remain an exciting area of research. Due to the ingenuity of their design and important functions they execute, recent research has also focused on engineering synthetic mimics of naturally occurring riboswitches and sRNAs and exploring these elements as potential therapeutics. In this chapter, we will present an overview on the discovery, general properties, and key functions of riboswitches and sRNAs annotated in different bacterial genomes. We will examine these RNAs as possible targets for novel antimicrobials. We will also discuss efforts in creating synthetic riboswitches and sRNAs, as well as the possibility of using them in biotechnology and as ammunition in our continued fight against multidrug-resistant pathogens.

Timing of DNA damage responses impacts persistence to fluoroquinolones

Significance Bacterial persisters are able to survive high concentrations of antibiotics that kill their genetically identical kin. Their tolerances are thought to arise from decreased activity of cellular processes, which limits damage from antibiotics. However, persistence to fluoroquinolones in growth-inhibited populations is not as cut-and-dried, with survivors of treatment exhibiting similar DNA damage as cells that die. In this article, we use a model system of persistence to reveal that the timing of events, such as DNA repair, following fluoroquinolone treatment is critical to survival and show that the same is true for WT populations. These data highlight the importance of processes following antibiotic treatments to persister phenotypes and establish that timing matters for genetically susceptible bacteria struggling to survive fluoroquinolone treatments. Bacterial persisters are subpopulations of phenotypic variants in isogenic cultures that can survive lethal doses of antibiotics. Their tolerances are often attributed to reduced activities of antibiotic targets, which limit corruption and damage in persisters compared with bacteria that die from treatment. However, that model does not hold for nongrowing populations treated with ofloxacin, a fluoroquinolone, where antibiotic-induced damage is comparable between cells that live and those that die. To understand how those persisters achieve this feat, we employed a genetic system that uses orthogonal control of MazF and MazE, a toxin and its cognate antitoxin, to generate model persisters that are uniformly tolerant to ofloxacin. Despite this complete tolerance, MazF model persisters required the same DNA repair machinery (RecA, RecB, and SOS induction) to survive ofloxacin treatment as their nongrowing, WT counterparts and exhibited similar indicators of DNA damage from treatment. Further investigation revealed that, following treatment, the timing of DNA repair was critical to MazF persister survival because, when repair was delayed until after growth and DNA synthesis resumed, survival was compromised. In addition, we found that, with nongrowing, WT planktonic and biofilm populations, stalling the resumption of growth and DNA synthesis after the conclusion of fluoroquinolone treatment with a prevalent type of stress at infection sites (nutrient limitation) led to near complete survival. These findings illustrate that the timing of events, such as DNA repair, following fluoroquinolone treatment is important to persister survival and provide further evidence that knowledge of the postantibiotic recovery period is critical to understanding persistence phenotypes.

Biased inheritance protects older bacteria from harm

Asymmetric distribution of an efflux pump makes older bacteria less sensitive to antibiotics In clonal bacterial cultures, where all cells are genetically identical, individual bacteria can nevertheless express different traits, giving rise to a diverse and complex population of phenotypic variants. This phenotypic heterogeneity allows single organisms to survive in conditions that are lethal for most of the population, such as assault with antibiotics (1). The survivors can then live on and regenerate the population when conditions become favorable again. To prevent this type of antibiotic failure, a greater understanding of the mechanisms that underlie phenotypic heterogeneity is essential. On page 311 of this issue, Bergmiller et al. (2) uncover such a mechanism.

Aminoglycoside-Enabled Elucidation of Bacterial Persister Metabolism: Aminoglycoside Elucidation of Persister Metabolism

Bacterial persisters are cells with an impressive, yet transient, tolerance toward extraordinary concentrations of antibiotics. Persisters are believed to impose a significant burden on the healthcare system because of their role in the proclivity of infections to relapse. During antibiotic challenge, these rare, phenotypic variants enter a dormant state where antibiotic primary targets are rendered inactive, allowing them to survive. Once the antibiotic is removed, persisters reawaken and resume growth, leading to repopulation of the environment. Metabolism plays a pivotal role in coordinating the entry, maintenance, and exit from the persister state. However, the low abundance, transient nature, and similarity of persisters to other cell types have prevented their isolation, which is needed for direct metabolic measurements. In this unit, we describe a technique known as the aminoglycoside (AG) potentiation assay, which can be used to rapidly and specifically measure the breadth of persister metabolism in heterogeneous populations.