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Query: UMLS:C0016382 (flushing)
 6,387 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

In Escherichia coli, nitrosative mutagenesis may occur during nitrate or nitrite respiration. The endogenous nitrosating agent N2O3 (dinitrogen trioxide, nitrous anhydride) may be formed either by the condensation of nitrous acid or by the autooxidation of nitric oxide, both of which are metabolic by-products. The purpose of this study was to determine which of these two agents is more responsible for endogenous nitrosative mutagenesis. An nfi (endonuclease V) mutant was grown anaerobically with nitrate or nitrite, conditions under which it has a high frequency of A:T-to-G:C transition mutations because of a defect in the repair of hypoxanthine (nitrosatively deaminated adenine) in DNA. These mutations could be greatly reduced by two means: (i) introduction of an nirB mutation, which affects the inducible cytoplasmic nitrite reductase, the major source of nitric oxide during nitrate or nitrite metabolism, or (ii) flushing the anaerobic culture with argon (which should purge it of nitric oxide) before it was exposed to air. The results suggest that nitrosative mutagenesis occurs during a shift from nitrate/nitrite-dependent respiration under hypoxic conditions to aerobic respiration, when accumulated nitric oxide reacts with oxygen to form endogenous nitrosating agents such as N2O3. In contrast, mutagenesis of nongrowing cells by nitrous acid was unaffected by an nirB mutation, suggesting that this mutagenesis is mediated by N2O3 that is formed directly by the condensation of nitrous acid.
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PMID:Evidence for mutagenesis by nitric oxide during nitrate metabolism in Escherichia coli. 1642 85

The reaction of deoxyhemoglobin with nitrite was characterized in the presence of dithionite using hemoglobin in solution or bound to the cytoplasmic domain of band 3 (CDB3). Deoxyhemoglobin was generated by predeoxygenation (nitrogen flushing followed by addition of dithionite), or transiently, by rapidly mixing oxyhemoglobin with nitrite and dithionite simultaneously. Wavelength-dependent kinetic studies confirmed the formation of nitrosyl hemoglobin. Furthermore, the rate of reaction was independent of dithionite concentration, indicating that dithionite does not reduce nitrite to nitric oxide directly. Model simulation studies showed that superoxide anion generated by dithionite reduction of molecular oxygen was not a factor in the reaction kinetics. CDB3-bound hemoglobin reacted faster with nitrite than did hemoglobin in solution. This difference was most pronounced for predeoxygenated hemoglobin and least pronounced for rapidly deoxygenated hemoglobin. The smaller difference observed in the rapid deoxygenation experiment was associated with much faster kinetics compared to the predeoxygenation experiment. Model simulation studies showed, and literature evidence indicates, that faster kinetics in the rapid deoxygenation experiment were related to the initial presence of R-state Hb(II)O 2 alphabeta dimers, both in dilute solution and when bound to CDB3. Thus, rapidly deoxygenated CDB3-bound hemoglobin alphabeta dimers react 5-fold faster with nitrite than predeoxygenated tetrameric hemoglobin in solution. Faster nitrite reductase kinetics for CDB3-bound hemoglobin suggests the possibility of preferential nitric oxide generation at the inner surface of the erythrocyte membrane, thus coupling the release of oxygen from hemoglobin to the production and successful release of nitric oxide from the erythrocyte, and the regulation of blood flow.
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PMID:Kinetics of reaction of nitrite with deoxy hemoglobin after rapid deoxygenation or predeoxygenation by dithionite measured in solution and bound to the cytoplasmic domain of band 3 (SLC4A1). 1846 75