The nitric oxide reductase of enterohaemorrhagic Escherichia coli plays an important role for the survival within macrophages

In enterohaemorrhagic Escherichia coli (EHEC) O157, there are two types of anaerobic nitric oxide (NO) reductase genes, an intact gene (norV) and a 204 bp deletion gene (norVs). Epidemiological analysis has revealed that norV-type EHEC are more virulent than norVs-type EHEC. Thus, to reveal the role of NO reductase during EHEC infection, we constructed isogenic norV-type and norVs-type EHEC mutant strains. Under anaerobic conditions, the norV-type EHEC was protected from NO-mediated growth inhibition, while the norVs-type EHEC mutant strain was not, suggesting that NorV of EHEC was effective in the anaerobic detoxification. We then investigated the role of NO reductase within macrophages. The norV-type EHEC produced a lower NO level within macrophages compared with the norVs-type EHEC. Moreover, the norV-type EHEC resulted in higher levels of Shiga toxin 2 (Stx2) within macrophages compared with the norVs-type EHEC. Finally, the norV-type EHEC showed a better level of survival than the norVs-type EHEC. These data suggest that the intact norV gene plays an important role for the survival of EHEC within macrophages, and is a direct virulence determinant of EHEC.     

Flavohemoglobin detoxifies nitric oxide in aerobic, but not anaerobic, Escherichia coli. Evidence for a novel inducible anaerobic nitric oxide-scavenging activity.

Nitric-oxide dioxygenase (NOD) and reductase (NOR) activities of flavohemoglobin (flavoHb) have been suggested as mechanisms for NO metabolism and detoxification in a variety of microbes. Mechanisms of NO detoxification were tested in Escherichia coli using flavoHb-deficient mutants and overexpressors. flavoHb showed negligible anaerobic NOR activity and afforded no protection to the NO-sensitive aconitase or the growth of anoxic E. coli, whereas the NOD activity and the protection afforded with O(2) were substantial. A NO-inducible, O(2)-sensitive, and cyanide-resistant NOR activity efficiently metabolized NO and protected anaerobic cells from NO toxicity independent of the NOR activity of flavoHb. flavoHb possesses nitrosoglutathione and nitrite reductase activities that may account for the protection it affords against these agents. NO detoxification by flavoHb occurs most effectively via O(2)-dependent NO dioxygenation.     

Binding of NorR to three DNA sites is essential for promoter activation of the flavorubredoxin gene, the nitric oxide reductase of Escherichia coli

NorR is a nitric oxide sensor that in Escherichia coli regulates the gene encoding for flavorubredoxin, an enzyme involved in nitrosative detoxification. The present work shows that although purified NorR can bind independently to each of three binding sites in the flavorubredoxin gene promoter, the presence of all sites is required for in vivo nitric oxide-dependent induction of the flavorubredoxin gene. Furthermore, trimerization of NorR upon binding to the three sites was observed by protein cross-linking experiments. These results reveal the importance of the multiple DNA binding sites present on NorR-dependent promoters and suggest that the functional form of NorR is a trimer.