Interaction of nitric oxide with glutathione or cysteine generates reactive oxygen species causing DNA single strand breaks.

It was found that reactive oxygen species (ROS) were generated in the interactions of nitric oxide (NO) with glutathione (GSH) or cysteine (CySH) under aerobic conditions. When supercoiled DNA was incubated with a mixture of NO/GSH, NO/CySH, NOC-7 (a NO donor)/GSH or NOC-7/CySH under aerobic conditions, DNA single-strand breaks were observed on agarose gel electrophoresis. The strand breaks were inhibited by common ROS scavengers: superoxide dismutase+catalase, the spin trapping agent 5,5-dimethyl-1-pyrroline-N oxide (DMPO), ethanol, and EDTA. The strand breaks were also caused by incubation with a mixture of S-nitrosoglutathione (GSNO) with GSH or CySH, which was inhibited by ROS scavengers. In the reaction of NO/GSH, GSNO rapidly formed and then gradually decreased, and in the reaction of GSNO/GSH, GSNO was gradually decreased. The decrease inf GSNO was accelerated in the presence of superoxide+catalase. Hydroxyl radical was detected in the mixtures of NO with GSH or CySH under aerobic conditions, and thiyl radicals were detected in the mixtures of GSNO with GSH or CySH under anaerobic conditions as examined in electron spin resonance studies using DMPO as a spin trap. The results indicate that the interaction of NO with thiols in the presence of O2 generates ROS that caused DNA single-strand breaks.

Is nitric oxide (NO) an antioxidant or a prooxidant for lipid peroxidation?

Antioxidant and prooxidant effects of nitric oxide (NO) on lipid peroxidation in aqueous and non-aqueous media were examined. In an aqueous solution, NO did not induce peroxidation of unoxidized methyl linoleate (ML) and suppressed the radical initiator-induced oxidation of ML. NO suppressed the Fe(II) ion-induced oxidation of mouse liver microsomes. NO reduced the O2 consumption during the radical initiator-induced oxidation of linoleic acid in an aqueous medium. NO conversion into NO2- in an aqueous medium was not affected by unoxidized ML and was slightly reduced by peroxidizing ML. On the other hand, as well as pure NO2, NO induced peroxidation of unoxidized ML in n-hexane in a dose-dependent fashion. NO did not suppress the radical initiator-induced oxidation of ML in n-hexane. Nitrogen oxide species (NO2 or N2O3) formed by autoxidation was dramatically lost in n-hexane in the presence of unoxidized ML. The results indicated that NO terminated lipid peroxidation in an aqueous medium, whereas NO induced lipid peroxidatiton in a non-aqueous medium. Hence, NO showed both antioxidant and prooxidant effects on lipid peroxidation depending on the solvents.