Catalase inhibition by nitric oxide potentiates hydrogen peroxide to trigger catastrophic chromosome fragmentation in Escherichia coli

Hydrogen peroxide (H₂O₂, HP) is a universal toxin that organisms deploy to kill competing or invading cells. Bactericidal action of H₂O₂ presents several questions. First, the lethal H₂O₂ concentrations in bacterial cultures are 1000x higher than, for example, those calculated for the phagosome. Second, H₂O₂-alone kills bacteria in cultures either by mode-one, via iron-mediated chromosomal damage, or by mode-two, via unknown targets, but the killing mode in phagosomes is unclear. Third, phagosomal H₂O₂ toxicity is enhanced by production of nitric oxide (NO), but in vitro studies disagree: some show NO synergy with H₂O₂ antimicrobial action, others instead report alleviation. To investigate this “NO paradox,” we treated Escherichia coli with various concentrations of H₂O₂-alone or H₂O₂+NO, measuring survival and chromosome stability. We found that all NO concentrations make sublethal H₂O₂ treatments highly lethal, via triggering catastrophic chromosome fragmentation (mode-one killing). Yet, NO-alone is not lethal, potentiating H₂O₂ toxicity by blocking H₂O₂ scavenging in cultures. Catalases represent obvious targets of NO inhibition, and catalase-deficient mutants are indeed killed equally by H₂O₂-alone or H₂O₂+NO treatments, also showing similar levels of chromosome fragmentation. Interestingly, iron chelation blocks chromosome fragmentation in catalase-deficient mutants without blocking H₂O₂-alone lethality, indicating mode-two killing. In fact, mode-two killing of WT cells by much higher H₂O₂ concentrations is transiently alleviated by NO, reproducing the “NO paradox.” We conclude that NO potentiates H₂O₂ toxicity by promoting mode-one killing (via catastrophic chromosome fragmentation) by otherwise static low H₂O₂ concentrations, while transiently suppressing mode-two killing by immediately lethal high H₂O₂ concentrations.