Nitric oxide formation from nitrite

F.B. Jensen, Nitric oxide formation from the reaction of nitrite with carp and rabit hemoglobin at intermediate oxygen saturations. FEBS J. 275, 3375-3387 (2008)... 

Fig. 11.1 Induction of the nitric oxide formation from nitrite by polyphenols in the gastric compartment.

Nitric oxide generation from L-arginine and nitric oxide donors and the formation of cGMP. L-NMMA inhibits nitric oxide synthase. Some of the nitric oxide donors such as furoxans and organic nitrates and nitrites require a thiol cofactor such as cysteine or glutathione to form nitric oxide. 

It follows from the above that MPO may catalyze the formation of chlorinated products in media containing chloride ions. Recently, Hazen et al. [172] have shown that the same enzyme catalyzes lipid peroxidation and protein nitration in media containing physiologically relevant levels of nitrite ions. It was found that the interaction of activated monocytes with LDL in the presence of nitrite ions resulted in the nitration of apolipoprotein B-100 tyrosine residues and the generation of lipid peroxidation products 9-hydroxy-10,12-octadecadienoate and 9-hydroxy-10,12-octadecadienoic acid. In this case there might be two mechanisms of MPO catalytic activity. At low rates of nitric oxide flux, the process was inhibited by catalase and MPO inhibitors but not SOD, suggesting the MPO initiation. 

Ru(edta)(H20)] reacts very rapidly with nitric oxide (171). Reaction is much more rapid at pH 5 than at low and high pHs. The pH/rate profile for this reaction is very similar to those established earlier for reaction of this ruthenium(III) complex with azide and with dimethylthiourea. Such behavior may be interpreted in terms of the protonation equilibria between [Ru(edtaH)(H20)], [Ru(edta)(H20)], and [Ru(edta)(OH)]2- the [Ru(edta)(H20)] species is always the most reactive. The apparent relative slowness of the reaction of [Ru(edta)(H20)] with nitric oxide in acetate buffer is attributable to rapid formation of less reactive [Ru(edta)(OAc)] [Ru(edta)(H20)] also reacts relatively slowly with nitrite. Laser flash photolysis studies of [Ru(edta)(NO)]-show a complicated kinetic pattern, from which it is possible to extract activation parameters both for dissociation of this complex and for its formation from [Ru(edta)(H20)] . Values of AS = —76 J K-1 mol-1 and A V = —12.8 cm3 mol-1 for the latter are compatible with AS values between —76 and —107 J K-1mol-1 and AV values between —7 and —12 cm3 mol-1 for other complex-formation reactions of [Ru(edta) (H20)]- (168) and with an associative mechanism. In contrast, activation parameters for dissociation of [Ru(edta)(NO)] (AS = —4JK-1mol-1 A V = +10 cm3 mol-1) suggest a dissociative interchange mechanism (172). 

In summary, there is still much to understand about the nitrite reduction reaction. The crystal structures have shown how nitrite can bind to the di heme iron and protons can be provided to one of its oxygen atoms from two histidine residues. However, as yet no rapid reaction study has detected the release of product nitric oxide rather than the formation of the inhibitory dead-end ferrous di heme-NO complex. It is also not clear why the rate of interheme electron transfer is so slow over 11 A when nitrite or nitric oxide is the ligand to the d heme. 

By comparison with other areas of consumer products, relatively little is known about the possible presence of N-nitroso derivatives in pharmaceuticals. Eisenbrand et, have reported on the presence of dimethylnitrosamine in all 68 samples of aminopyrine analyzed in Germany (23). They suggested that DMN could have been formed in various drug formulations by two main routes. One was by the in situ reaction of aminopyrine with nitric oxides in the air, and the other involved the synthetic process used in the manufacturing process itself (23). The levels of DMN found ranged from less than 10 ppb to just under 400 ppb. It has been found for several years that animals fed aminopyrine and sodium nitrite in their diets show the formation of malignant tumors (24, 25). In view of the presence of substantial amounts of DMN in the... 

Four routes to form peroxynitrite from nitric oxide. The reaction of nitric oxide with superoxide is only one mechanism leading to the formation of peroxynitrite. Supetoxide could also reduce the nitrosyidioxyl radical. If nitric oxide is directly reduced to nitroxyl anion, it will react with molecular oxygen to form peroxynitrite. At acidic pH, nitrite may form nitrous acid and nitrosonium ion, which reacts with hydrogen peroxide to form peroxynitrite. 

Interleukin 1-induced formation of iron-nitrosyl complexes by rat islets. Rat islets were incubated fot 18 hr in the presence or absence of 5 U/ml lL-1, 0.5 mM NMMA, or lL-1 and NMMA. The islets were isolated and the fotmation of nitric oxide was examined by EPR spectroscopy as described previously (Corbett et al., 1991a). IL-1 induces the formation of a g = 2.04 featute that is characteristic of the fotmation of iton-nittosyl complexes, and NMMA ptevents the formation of this axial g = 2.04 iton-nittosyl feature. Also shown is the simultaneous formation of nitrite by the same islets used for EPR spectroscopy. Repnxluced with permission from ]. Biol. Chem. (Corbett et al., 1991a), from the American Society for Biochemistry and Molecular Biology. 

If jS-cell production of nitric oxide participates in IDDM, human islets must produce nitric oxide in response to cytokines. We have shown that a combination of cytokines (lL-1, IFN, and TNF) induce the formation of nitric oxide by isolated human islets (Corbett et al., 1993b). The formation of nitric oxide has been demonstrated by cytokine-induced cGMP accumulation, nitrite formation, and EPR-detectable iron-nitrosyl complex formation (Fig. 12), all of which were prevented by NMMA. The cytokine combination of IFN and lL-1 are required for nitrite production, while TTSIF potentiates IL-1 and IFN-induced nitrite formation by human islets. The cytokine combination of lL-1, TNF, and IFN also influences the physiological function of insulin secretion by human islets. Low concentrations of this cytokine combination slightly stimulate insulin secretion, while high concentrations inhibit insulin secretion, similar to the concentration-dependent effects of lL-1 on rat islet function. NMMA partially prevents the inhibitory effects of this cytokine combination on insulin secretion from human islets, suggesting that nitric oxide may participate in )3-cell dysfunction associated with IDDM. 

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