Conserved Metabolic Regulator ArcA Responds to Oxygen Availability, Iron Limitation, and Cell Envelope Perturbations during Bacteremia

Abstract: Bacteremia, a systemic infection associated with severe clinical outcomes, is often caused by Gram-negative facultative anaerobes. ArcAB, a two-component regulatory system that represses aerobic respiration, is a key mediator of metabolic adaptation for such bacteria. Using targeted mutational analysis informed by global genetic screens, we identified thearcAgene as promoting fitness ofKlebsiella pneumoniae,Citrobacter freundii, andSerratia marcescensbut notEscherichia coliin a murine model of bacteremia. Engi… Show more

“…ArcA is a global gene regulator of aerobic respiration that contributes to the maintenance of a proton motive force when oxygen is available. In a recent study [119], we constructed deletion mutants in the aerobic respiration control sensor arcA across four species and confirmed that ArcA is a bacteremia-fitness factor in K. pneumoniae, C. freundii, and S. marcescens but not E. coli. ArcA is conserved across the Enterobacterales and clearly contributes to fitness in a murine bacteremia model [119].…”

“…In a recent study [119], we constructed deletion mutants in the aerobic respiration control sensor arcA across four species and confirmed that ArcA is a bacteremia-fitness factor in K. pneumoniae, C. freundii, and S. marcescens but not E. coli. ArcA is conserved across the Enterobacterales and clearly contributes to fitness in a murine bacteremia model [119]. Because this regulator, along with ArcB, mediates transition from aerobic to anaerobic growth, mutants in arcA do not grow well under anaerobic conditions.…”

A novel method for integrating genomic and Tn-Seq data to identify commonin vivofitness mechanisms across multiple bacterial species

“…ArcA is a global gene regulator of aerobic respiration that contributes to the maintenance of a proton motive force when oxygen is available. In a recent study [119], we constructed deletion mutants in the aerobic respiration control sensor arcA across four species and confirmed that ArcA is a bacteremia-fitness factor in K. pneumoniae, C. freundii, and S. marcescens but not E. coli. ArcA is conserved across the Enterobacterales and clearly contributes to fitness in a murine bacteremia model [119].…”

“…In a recent study [119], we constructed deletion mutants in the aerobic respiration control sensor arcA across four species and confirmed that ArcA is a bacteremia-fitness factor in K. pneumoniae, C. freundii, and S. marcescens but not E. coli. ArcA is conserved across the Enterobacterales and clearly contributes to fitness in a murine bacteremia model [119]. Because this regulator, along with ArcB, mediates transition from aerobic to anaerobic growth, mutants in arcA do not grow well under anaerobic conditions.…”

A novel method for integrating genomic and Tn-Seq data to identify commonin vivofitness mechanisms across multiple bacterial species