Metabolic flux regulates growth transitions and antibiotic tolerance in uropathogenicEscherichia coli

Abstract

AbstractReducing growth and limiting metabolism are strategies that allow bacteria to survive exposure to environmental stress and antibiotics. During infection, uropathogenicEscherichia coli(UPEC) may enter a quiescent state that enables them to reemerge after completion of successful antibiotic treatment. Many clinical isolates, including the well characterized UPEC strain CFT073, also enter a metabolite-dependent, quiescent state in vitro that is reversible with cues, including peptidoglycan-derived peptides and amino acids. Here, we show that quiescent UPEC is antibiotic tolerant and demonstrate that metabolic flux in the tricarboxylic acid (TCA) cycle regulates the UPEC quiescent state via succinyl-CoA. We also demonstrate that the transcriptional regulator complex IHF and the FtsZ-interacting protein ZapE, which is important forE. colidivision during stress, are essential for UPEC to enter the quiescent state. Notably, in addition to engaging FtsZ and late-stage cell division proteins, ZapE also interacts directly with TCA cycle enzymes in bacterial two hybrid assays. We report direct interactions between succinate dehydrogenase complex subunit SdhC, the late-stage cell division protein FtsN, and ZapE. These interactions likely enable communication between oxidative metabolism and the cell division machinery in UPEC. Moreover, these interactions are conserved in anE. coliK-12 strain. This work suggests that there is coordination among the two fundamental and essential pathways that regulate overall growth, quiescence, and antibiotic susceptibility.ImportanceUropathogenicEscherichia coli(UPEC) are the leading cause of urinary tract infections (UTIs). Upon invasion into bladder epithelial cells, UPEC establish quiescent intracellular reservoirs that may lead to antibiotic tolerance and recurrent UTIs. Here, we demonstrate using an in vitro system that quiescent UPEC cells are tolerant to ampicillin and have decreased metabolism characterized by succinyl-CoA limitation. We identify the global regulator the IHF complex and the cell division protein ZapE as critical regulators of quiescence and antibiotic tolerance. Lastly, we show ZapE interacts with components of both the cell division machinery and the TCA cycle, and this interaction is conserved in non-pathogenicE. coli, establishing a novel link between cell division and metabolism.