Formation of nitrogen oxides and citrulline upon oxidation of N omega-hydroxy-L-arginine by hemeproteins

Oxidative denitrification of N omega-hydroxy-L-arginine by the superoxide radical anion

The superoxide radical anion (O2-.) produced during the catalytic activity of nitric oxide synthase (NOS) and cytochrome P-450 has been implicated in the oxidative denitrification of hydroxyguanidines ( > C = NOH). The reactivity of the radiolytically generated O2-. radical with N omega-hydroxy-L-arginine (NHA) is pH dependent and appears to parallel the prototropic equilibrium of the hydroxyguanidino group ( > C = NOH reversible > C = NO(-)+H+; pK = 8). The N omega-hydroxyguanidino group is more reactive towards O2-. when deprotonated but exhibits negligible reactivity when protonated. Based on a model, the rate constant for the reaction of the O2-. with NHA was estimated as kappa (O2-.+ > C = NO-) approximately 200-500 M-1.s-1, which is probably too low to compete with O2-. reactions with NO- or superoxide dismutase, which occur many orders of magnitude faster. The oxidative elimination of NO from NHA by O2-. was not accompanied by the formation of L-citrulline. Since only 21% of NHA will exist in the deprotonated > C = NO- form at physiological pH, it is unlikely that oxidative denitrification of NHA by cytochrome P-450 or NOS-derived O2-. radicals will prove a major free-radical pathway to NO. and L-citrulline.

Cytokine-mediated production of nitric oxide in isolated rat hepatocytes is dependent on cytochrome P-450III activity

To investigate the role of the cytochrome P-450 system in NO synthesis, cytochrome P-450IIIA, IIE and IA activities were specifically inhibited by cimetidine (IIIA), clotrimazole (IIIA), benzoflavone (IA) and disulfiram (IIE) in a model of cultured rat hepatocytes. Cytokine-induced NO synthesis was significantly decreased in the presence of cimetidine and clotrimazole. Kinetic analysis revealed a non-competitive mode of inhibition (Ki = 21 mM, cimetidine; Ki = 13 microM, clotrimazole). Reverse transcriptase-PCR and immunoblot analysis revealed no significant change in steady state levels of iNOS mRNA and protein expression with P-450IIIA inhibition. Purified iNOS enzyme activity was not altered. These data suggest that cytokine-mediated hepatocyte synthesis of NO is dependent upon P-450IIIA activity, which functions in a post-translational capacity.

Inhibition of arginase by NG-hydroxy-L-arginine in alveolar macrophages: implications for the utilization of L-arginine for nitric oxide synthesis

The hypothesis was investigated that the nitric oxide (NO) synthase intermediate, NG-hydroxy-L-arginine (HOArg), is an arginase inhibitor in rabbit or rat alveolar macrophages. Exogenously applied HOArg strongly inhibited the arginase activity present in these cells (IC50 > or = 15 microM), and attenuated L-[3H]arginine transport (IC50 > or = 500 microM) in rabbit alveolar macrophages. Moreover, up to 37 microM HOArg were detected in the conditioned medium, but not in the lysate, of rat alveolar macrophages exposed to bacterial lipopolysaccharide for 18 h. HOArg may thus be a potent endogenous arginase inhibitor in these cells which increases the availability of L-arginine for NO biosynthesis.

Effect of hydrogen peroxide and catalase on rat cerebellum nitric oxide synthase

The effect of H2O2 and catalase on isolated rat cerebellum nitric oxide (NO) synthase activity was determined by measuring the conversion of L-[3H]arginine to L-[3H]citrulline. H2O2 (1-5 mM) markedly increased NO synthase activity in the presence of endogenous catalase (72 +/- 4 U/mL). This effect of H2O2 was further increased by exogenous catalase (200 U/mL). Exogenous catalase (0.1 to 1000 U/mL) by itself had no significant effect on NO synthase activity. Nitroblue tetrazolium chloride, an electron acceptor, inhibited NO synthase activity in a concentration-dependent manner. This study suggests that H2O2 is not directly involved in NO synthesis and that the H2O2/catalase stimulation of NO synthase activity may be due to the excess oxygen produced by the H2O2/catalase system.

Exogenous NG-hydroxyl-L-arginine causes nitrite production in vascular smooth muscle cells in the absence of nitric oxide synthase activity

Nitric oxide (NO) production from exogenous NG-hydroxy-L-arginine (OH-L-Arg) was investigated in rat aortic smooth muscle cells in culture by measuring nitrite accumulation in the culture medium. As well, the interaction between OH-L-Arg and L-arginine uptake via the y+ cationic amino acid transporter was studied. In cells without NO-synthase activity, OH-L-Arg (1-1000 microM) induced a dose-dependent nitrite production with a half-maximal effective concentration (EC50) of 18.0 +/- 1.5 microM (n = 4-7). This nitrite accumulation was not inhibited by the NO-synthase inhibitor NG-nitro-L-arginine methyl ester, L-NAME (300 microM). In contrast, it was abolished by miconazole (100 microM), an inhibitor of cytochrome P450. Incubation of vascular smooth muscle cells with LPS (10 micrograms/ml) induced an L-NAME inhibited nitrite accumulation, but did not enhance the OH-L-Arg induced nitrite production. OH-L-Arg and other cationic amino acids, L-lysine and L-ornithine, competitively inhibited [3H]-L-arginine uptake in rat aortic smooth muscle cells, with inhibition constants of 195 +/- 23 microM (n = 12), 260 +/- 40 microM (n = 5) and 330 +/- 10 microM (n = 5), respectively. These results show that OH-L-Arg is recognized by the cationic L-amino acid carrier present in vascular smooth muscle cells can be oxidized to NO and nitrite in these cells in the absence of NO-synthase, probably by cytochrome P450 or by a reaction involving a cytochrome P450 by-product.

Cytochrome P450 dependent N-hydroxylation of a guanidine (debrisoquine), microsomal catalysed reduction and further oxidation of the N-hydroxy-guanidine metabolite to the urea derivative. Similarity with the oxidation of arginine to citrulline and nitric oxide

The microsomal N-hydroxylation of the strongly basic guanidinium group (debrisoquine) to N-hydroxyguanidine (N-hydroxydebrisoquine) and the retroreduction of the N-hydroxyguanidine are demonstrated for the first time. The reduction of the N-hydroxyguanidine by liver homogenates and hepatocytes is catalysed by a microsomal NADH-dependent system that is strongly inhibited by hydroxylamine or N-methylhydroxylamine. In the presence of these alternate substrates for the reductase the microsomal catalysed N-hydroxylation of debrisoquine is readily characterized. The oxidation was inhibited by antibodies against NADPH cytochrome P450 reductase and the role of the P450 monooxygenase was further verified by studies with partially purified and purified P450 2C3 reconstituted systems. The transformation of N-hydroxydebrisoquine to the corresponding urea derivative was also detected in in vitro experiments with microsomal fractions and enriched P450 fractions as well as with flavin-containing monooxygenase (FMO). Experiments with catalase, superoxide dismutase and H2O2 have shown that the H2O2 or O2-, respectively, formed from the respective enzyme and the substrate, apparently participated in the reaction. Whereas the N-hydroxylation of the guanidine involves the usual monooxygenase activity of cytochrome P450 the resultant N-hydroxyguanidine decouples monooxygenases (cytochrome P450, FMO) and the H2O2 and, above all, O2- thus formed transform the N-hydroxyguanidine further to the corresponding urea derivative. The possibility for the N-hydroxylation of non-physiological guanidines to N-hydroxyguanidines and subsequent oxidative conversion to the respective urea is comparable to the physiological transformation of arginine to citrulline via N-hydroxyarginine with the liberation of nitric oxide (endothelial derived relaxing factor) and could, therefore, contribute to the efficacy of drugs containing guanidine and similar functional groups.

Trypanosoma cruzi upregulates nitric oxide release by IFN-gamma-preactivated macrophages, limiting cell infection independently of the respiratory burst

The relationship between nitric oxide (N = O) produced by mouse peritoneal macrophages (MPM) and Trypanosoma cruzi infection is still poorly understood. The conditions of MPM activation by gamma-interferon (IFN-gamma) to trigger a N = O-dependent trypanocidal activity, as well as the effect of parasite infection or of reactive oxygen species (ROS) inhibitors on the N = O release were studied. T. cruzi infection occurring after a previous 24 h MPM activation induced an enhancement of nitrite levels (the stable degradation product of N = O) in cell supernatants; both the percentage of infected MPM and the number of amastigotes per infected cell were decreased in comparison to infected but non-activated MPM. Addition of superoxide dismutase or catalase to non-infected but activated MPM increased the nitrite levels; these were not detectable when L-arginine inhibitors were added together with ROS inhibitors. The latter had no effect on infection nor on nitrite levels when infection occurred after pre-activation, and induced only a weak nitrite release when infection took place before MPM activation. Altogether, these results support the involvement of N = O in the inhibition of T. cruzi infection by IFN-gamma-preactivated macrophages, together with the upregulation of N = O release by T. cruzi infection independently of the respiratory burst.

Biotransformation of benzamidine and benzamidoxime in vivo

After administration of benzamidine (1) or benzamidoxime (2), respectively, to rats and rabbits, plasma from rats and rabbits as well as urine from rats were examined for the presence of benzamidoxime (2) or benzamidine (1). Some of the samples were worked-up directly and the others after enzymatic pretreatment with beta-glucuronidase or arylsulfatase, respectively. HPLC analysis was employed for the detection of the metabolites. After administration of 1, an in vivo N-hydroxylation of an amidine to an amidoxime was demonstrated for the first time. The metabolite 2 could only be detected after enzymatic cleavage of the glucuronide or sulfate, respectively, and only in plasma at a low concentration. After administration of benzamidoxime (2), on the other hand, benzamidine (1) was detected in very high concentrations in all biological samples. Benzamidine was present in the free state but indications for glucuronidization and sulfatation were also detectable. These investigations suggest that the benzamidoxime (2) formed by an in vivo N-hydroxylation undergoes ready retro-reduction but that further transformations of the metabolite 2, such as conjugation to a glucuronide or a sulfate, respectively, prevent complete back reaction. Furthermore, benzamide (3) could be detected as a transformation product in urine after administration of either 1 or 2.

Involvement of nitric oxide in the endothelium-dependent relaxation induced by hydrogen peroxide in the rabbit aorta

1. The effects of hydrogen peroxide (H2O2, 0.1-1 mM) on the tone of the rings of rabbit aorta precontracted with phenylephrine (0.2-0.3 microM) were studied. 2. H2O2 induced a concentration-dependent relaxation of both the intact and endothelium-denuded rings. However, in the presence of intact endothelium, H2O2-induced responses were 2-3 fold larger than in its absence, demonstrating the existence of endothelium-independent and endothelium-dependent components of the vasorelaxant action of H2O2. 3. The endothelium-dependent component of H2O2-induced relaxation was prevented by NG-nitro-L-arginine methyl ester (L-NAME, 30 microM) or NG-monomethyl-L-arginine (300 microM), inhibitors of nitric oxide synthase (NOS), in a manner that was reversible by L-, but not by D-arginine (2mM). The inhibitors of NOS did not affect the responses of denuded rings. 4. Methylene blue (10 microM), an inhibitor of soluble guanylate cyclase, blocked H2O2-induced relaxation of both the intact and denuded rings. 5. H2O2 (1 mM) enhanced the efflux of cyclic GMP from both the endothelium-intact and denuded rings. The effect of H2O2 was 4 fold greater in the presence of intact endothelium and this endothelium-dependent component was abolished after the inhibition of NOS by L-NAME (30 microM). 6. In contrast to the effects of H2O2, the vasorelaxant action of stable organic peroxides, tert-butyl hydroperoxide or cumene hydroperoxide, did not have an endothelium-dependent component. Moreover, they did not potentiate the efflux of cyclic GMP from the rings of rabbit aorta. 7. Exogenous donors of NO, specifically, 3-morpholinosydnonimine (SIN-1), glyceryl trinitrate or sodium nitroprusside were used to decrease the tone of denuded rings to the level induced by endogenous NO released from intact endothelium. This procedure did not influence the vasorelaxant activity of H202, showing that H202 does not potentiate the vasorelaxant action of NO within the smooth muscle.8. Thus, H202-induced relaxation in the rabbit aorta has both endothelium-dependent and independent components. The endothelium-dependent component of the relaxant action of H202 is due to enhanced endothelial synthesis of NO.

Brain nitric oxide synthase is a haemoprotein

Brain nitric oxide (NO) synthase showed pyridine haemochrome spectra typical of ferroprotoporphyrin IX-containing enzymes. The haem content of purified NO synthase was in the range 0.7-0.9 mol/mol of 160 kDa subunit. In the presence of CO, NO, KCN and miconazole, the L-citrulline-forming activity of NO synthase was markedly diminished, demonstrating that enzyme-bound haem is involved in enzymic NO synthesis.

Cytochrome P450 catalyzes the oxidation of N omega-hydroxy-L-arginine by NADPH and O2 to nitric oxide and citrulline

Rat liver microsomes catalyze the oxidative denitration of N omega-hydroxy-L-arginine (NOHA) by NADPH and O2 with formation of citrulline and nitrogen oxides like NO and NO2-. Besides NO2- and citrulline, whose simultaneous formation is linear for at least 20 min, the formation of NO could be detected under the form of its P450 and P420-Fe(II) complexes by UV-visible and EPR spectroscopy. Classical inhibitors of NO-synthases, like N omega-methyl-and N omega-nitro-arginine, fail to inhibit the microsomal oxidation of NOHA to citrulline and NO2-. On the contrary classical inhibitors of hepatic cytochromes P450 like CO, miconazole, dihydroergotamine and troleandomycin, strongly inhibit this monooxygenase reaction. These results show that the oxygenation of NOHA by NADPH and O2 with formation of citrulline and NO can be efficiently catalyzed by cytochromes P450 (with rates up to 1.5 turnovers per min for the cytochromes of the 3A subfamily).

Formation of nitric oxide by cytochrome P450-catalyzed oxidation of aromatic amidoximes

Rat liver microsomes catalyze the oxidation of para-hexyloxy-benzamidoxime 1 to the corresponding arylamide 2 and NO2-, by NADPH and O2. Involvement of cytochromes P450 as catalysts of this reaction was shown by the strong inhibitory effects of CO and miconazole and the spectacular increase of the activity upon treatment of rats with dexamethasone, a specific inducer of cytochromes P450 of the 3A subfamily. Formation of NO during oxidation of 1 was shown by detection of the formation of cytochrome P450- and cytochrome P420-Fe(II)-NO complexes by visible and EPR spectroscopy. The formation of these complexes should be responsible, at least in part, for the fast decrease of the rate of microsomal oxidation of 1 with time. These results suggest that exogenous compounds containing amidine or amidoxime functions could act as precursors of NO in vivo after in situ oxidation by cytochromes P450.