Control of protein function through oxidation and reduction of persulfidated states

Irreversible oxidation of Cys residues to sulfinic/sulfonic forms typically impairs protein function. We found that persulfidation (CysSSH) protects Cys from irreversible oxidative loss of function by the formation of CysSSO_1-3H derivatives that can subsequently be reduced back to native thiols. Reductive reactivation of oxidized persulfides by the thioredoxin system was demonstrated in albumin, Prx2, and PTP1B. In cells, this mechanism protects and regulates key proteins of signaling pathways, including Prx2, PTEN, PTP1B, HSP90, and KEAP1. Using quantitative mass spectrometry, we show that (i) CysSSH and CysSSO₃H species are abundant in mouse liver and enzymatically regulated by the glutathione and thioredoxin systems and (ii) deletion of the thioredoxin-related protein TRP14 in mice altered CysSSH levels on a subset of proteins, predicting a role for TRP14 in persulfide signaling. Furthermore, selenium supplementation, polysulfide treatment, or knockdown of TRP14 mediated cellular responses to EGF, suggesting a role for TrxR1/TRP14-regulated oxidative persulfidation in growth factor responsiveness.

Mechanisms of nitrogen oxide-mediated disruption of metalloprotein function: an examination of the copper-responsive yeast transcription factor Ace1

Nitric oxide (NO) has been found to inhibit the copper-responsive yeast transcription factor Ace1 in an oxygen-dependent manner. However, the mechanism responsible for NO-dependent inhibition of Ace1 remains unestablished. In the present study, the chemical interaction of nitrogen oxide species with Ace1 was examined using a yeast reporter system. Exposure of yeast to various nitrogen oxides, under a variety of conditions, revealed that the oxygen-dependent inhibition of Ace1 is due to the reaction of NO with O(2). The nitrosating nitrogen oxide species N(2)O(3) is likely to be the disrupter of Ace1 activity. Considering the similarity of metal-thiolate ligation in Ace1 with other mammalian metalloproteins such as metallothionein, metal chaperones, and zinc-finger proteins, these results help to understand the biochemical interactions of NO with those mammalian metalloproteins.

Nitric oxide inhibits ornithine decarboxylase via S-nitrosylation of cysteine 360 in the active site of the enzyme

Ornithine decarboxylase is the initial and rate-limiting enzyme in the polyamine biosynthetic pathway. Polyamines are found in all mammalian cells and are required for cell growth. We previously demonstrated that N-hydroxyarginine and nitric oxide inhibit tumor cell proliferation by inhibiting arginase and ornithine decarboxylase, respectively, and, therefore, polyamine synthesis. In addition, we showed that nitric oxide inhibits purified ornithine decarboxylase by S-nitrosylation. Herein we provide evidence for the chemical mechanism by which nitric oxide and S-nitrosothiols react with cysteine residues in ornithine decarboxylase to form an S-nitrosothiol(s) on the protein. The diazeniumdiolate nitric oxide donor agent 1-diethyl-2-hydroxy-2-nitroso-hydrazine acts through an oxygen-dependent mechanism leading to formation of the nitrosating agents N(2)O(3) and/or N(2)O(4). S-Nitrosoglutathione inhibits ornithine decarboxylase by an oxygen-independent mechanism likely by S-transnitrosation. In addition, we provide evidence for the S-nitrosylation of 4 cysteine residues per ornithine decarboxylase monomer including cysteine 360, which is critical for enzyme activity. Finally S-nitrosylated ornithine decarboxylase was isolated from intact cells treated with nitric oxide, suggesting that nitric oxide may regulate ornithine decarboxylase activity by S-nitrosylation in vivo.

Nitroxyl anion exerts redox-sensitive positive cardiac inotropy in vivo by calcitonin gene-related peptide signaling

Nitroxyl anion (NO(-)) is the one-electron reduction product of nitric oxide (NO( small middle dot)) and is enzymatically generated by NO synthase in vitro. The physiologic activity and mechanism of action of NO(-) in vivo remains unknown. The NO(-) generator Angeli's salt (AS, Na(2)N(2)O(3)) was administered to conscious chronically instrumented dogs, and pressure-dimension analysis was used to discriminate contractile from peripheral vascular responses. AS rapidly enhanced left ventricular contractility and concomitantly lowered cardiac preload volume and diastolic pressure (venodilation) without a change in arterial resistance. There were no associated changes in arterial or venous plasma cGMP. The inotropic response was similar despite reflex blockade with hexamethonium or volume reexpansion, indicating its independence from baroreflex stimulation. However, reflex activation did play a major role in the selective venodilation observed under basal conditions. These data contrasted with the pure NO donor diethylamine/NO, which induced a negligible inotropic response and a more balanced veno/arterial dilation. AS-induced positive inotropy, but not systemic vasodilatation, was highly redox-sensitive, being virtually inhibited by coinfusion of N-acetyl-l-cysteine. Cardiac inotropic signaling by NO(-) was mediated by calcitonin gene-related peptide (CGRP), as treatment with the selective CGRP-receptor antagonist CGRP(8-37) prevented this effect but not systemic vasodilation. Thus, NO(-) is a redox-sensitive positive inotrope with selective venodilator action, whose cardiac effects are mediated by CGRP-receptor stimulation. This fact is evidence linking NO(-) to redox-sensitive cardiac contractile modulation by nonadrenergic/noncholinergic peptide signaling. Given its cardiac and vascular properties, NO(-) may prove useful for the treatment of cardiovascular diseases characterized by cardiac depression and elevated venous filling pressures.

On the acidity and reactivity of HNO in aqueous solution and biological systems

The gas phase and aqueous thermochemistry and reactivity of nitroxyl (nitrosyl hydride, HNO) were elucidated with multiconfigurational self-consistent field and hybrid density functional theory calculations and continuum solvation methods. The pK(a) of HNO is predicted to be 7.2 +/- 1.0, considerably different from the value of 4.7 reported from pulse radiolysis experiments. The ground-state triplet nature of NO(-) affects the rates of acid-base chemistry of the HNO/NO(-) couple. HNO is highly reactive toward dimerization and addition of soft nucleophiles but is predicted to undergo negligible hydration (K(eq) = 6.9 x 10(-5)). HNO is predicted to exist as a discrete species in solution and is a viable participant in the chemical biology of nitric oxide and derivatives.

Unique oxidative mechanisms for the reactive nitrogen oxide species, nitroxyl anion

The nitroxyl anion (NO-) is a highly reactive molecule that may be involved in pathophysiological actions associated with increased formation of reactive nitrogen oxide species. Angeli's salt (Na2N2O3; AS) is a NO- donor that has been shown to exert marked cytotoxicity. However, its decomposition intermediates have not been well characterized. In this study, the chemical reactivity of AS was examined and compared with that of peroxynitrite (ONOO-) and NO/N2O3. Under aerobic conditions, AS and ONOO- exhibited similar and considerably higher affinities for dihydrorhodamine (DHR) than NO/N2O3. Quenching of DHR oxidation by azide and nitrosation of diaminonaphthalene were exclusively observed with NO/N2O3. Additional comparison of ONOO- and AS chemistry demonstrated that ONOO- was a far more potent one-electron oxidant and nitrating agent of hydroxyphenylacetic acid than was AS. However, AS was more effective at hydroxylating benzoic acid than was ONOO-. Taken together, these data indicate that neither NO/N2O3 nor ONOO- is an intermediate of AS decomposition. Evaluation of the stoichiometry of AS decomposition and O2 consumption revealed a 1:1 molar ratio. Indeed, oxidation of DHR mediated by AS proved to be oxygen-dependent. Analysis of the end products of AS decomposition demonstrated formation of NO2- and NO3- in approximately stoichiometric ratios. Several mechanisms are proposed for O2 adduct formation followed by decomposition to NO3- or by oxidation of an HN2O3- molecule to form NO2-. Given that the cytotoxicity of AS is far greater than that of either NO/N2O3 or NO + O2, this study provides important new insights into the implications of the potential endogenous formation of NO- under inflammatory conditions in vivo.

The role of oxygen and reduced oxygen species in nitric oxide-mediated cytotoxicity: studies in the yeast Saccharomyces cerevisiae model system

The cytotoxicity of nitric oxide (NO) is well established, yet the mechanism(s) of its cytotoxicity is (are) still undefined and a matter of significant interest and speculation. Many of the previously proposed mechanisms for NO-mediated cytotoxicity involve interactions between NO and molecular oxygen (O(2)) and/or O(2)-derived species such as O(-)(2) and H(2)O(2). The yeast Saccharomyces cerevisiae represents a useful model system for evaluating the role of O(2) and O(2)-derived species in NO-mediated cytotoxicity. This study examines the contribution of O(2) and O(2)-derived species to NO-mediated cytotoxicity in the yeast S. cerevisiae. NO-mediated cytotoxicity was determined to be O(2)-dependent. However, this O(2) dependence was only minimally due to the generation of O(2)-derived species such as O(-)(2) and/or H(2)O(2).

Effects of nitric oxide on the copper-responsive transcription factor Ace1 in Saccharomyces cerevisiae: cytotoxic and cytoprotective actions of nitric oxide

Previous studies indicate that nitric oxide (NO) can serve as a regulator/disrupter of metal-metabolizing systems in cells and, indeed, this function may represent an important physiological and/or pathophysiological role for NO. In order to address possible mechanisms of this aspect of NO biology, the effect of NO on copper metabolism and toxicity in the yeast Saccharomyces cerevisiae was examined. Exposure of S. cerevisiae to NO resulted in an alteration of the activity of the copper-responsive transcription factor Acel. Low concentrations of the NO donor DEA/NO were found to slightly enhance copper-mediated activation of Acel. Since Acel regulates the expression of genes responsible for the protection of S. cerevisiae from metal toxicity, the effect of NO on the toxicity of copper toward S. cerevisiae was also examined. Interestingly, low concentrations of NO were also found to protect S. cerevisiae against the toxicity of copper. The effect of NO at high concentrations was, however, opposite. High concentrations of DEA/NO inhibited copper-mediated Acel activity. Correspondingly, high concentrations of DEA/NO (1 mM) dramatically enhanced copper toxicity. An intermediate concentration of DEA/NO (0.5 mM) exhibited a dual effect, enhancing toxicity at lower copper concentrations (<0.5 mM) and protecting at higher (> or =0.5 mM) copper concentrations. Thus, it is proposed that the ability of NO to both protect against (at low concentrations) and enhance (at high concentration) copper toxicity in S. cerevisiae is, at least partially, a result of its effect on Acel. The results of this study have implications for the role of NO as a mediator of metal metabolism.

The interaction of nitric oxide (NO) with the yeast transcription factor Ace1: A model system for NO-protein thiol interactions with implications to metal metabolism

Nitric oxide (NO) was found to inhibit the copper-dependent induction of the yeast CUP1 gene. This effect is attributable to an inhibition of the copper-responsive CUP1 transcriptional activator Ace1. A mechanism is proposed whereby the metal binding thiols of Ace1 are chemically modified via NO- and O(2)-dependent chemistry, thereby diminishing the ability of Ace1 to bind and respond to copper. Moreover, it is proposed that demetallated Ace1 is proteolytically degraded in the cell, resulting in a prolonged inhibition of copper-dependent CUP1 induction. These findings indicate that NO may serve as a disrupter of yeast copper metabolism. More importantly, considering the similarity of Ace1 to other mammalian metal-binding proteins, this work lends support to the hypothesis that NO may regulate/disrupt metal homeostasis under both normal physiological and pathophysiological circumstances.

Opposite effects of nitric oxide and nitroxyl on postischemic myocardial injury

Recent experimental evidence suggests that reactive nitrogen oxide species can contribute significantly to postischemic myocardial injury. The aim of the present study was to evaluate the role of two reactive nitrogen oxide species, nitroxyl (NO(-)) and nitric oxide (NO(.)), in myocardial ischemia and reperfusion injury. Rabbits were subjected to 45 min of regional myocardial ischemia followed by 180 min of reperfusion. Vehicle (0.9% NaCl), 1 micromol/kg S-nitrosoglutathione (GSNO) (an NO(.) donor), or 3 micromol/kg Angeli's salt (AS) (a source of NO(-)) were given i.v. 5 min before reperfusion. Treatment with GSNO markedly attenuated reperfusion injury, as evidenced by improved cardiac function, decreased plasma creatine kinase activity, reduced necrotic size, and decreased myocardial myeloperoxidase activity. In contrast, the administration of AS at a hemodynamically equieffective dose not only failed to attenuate but, rather, aggravated reperfusion injury, indicated by an increased left ventricular end diastolic pressure, myocardial creatine kinase release and necrotic size. Decomposed AS was without effect. Co-administration of AS with ferricyanide, a one-electron oxidant that converts NO(-) to NO(.), completely blocked the injurious effects of AS and exerted significant cardioprotective effects similar to those of GSNO. These results demonstrate that, although NO(.) is protective, NO(-) increases the tissue damage that occurs during ischemia/reperfusion and suggest that formation of nitroxyl may contribute to postischemic myocardial injury.

The reductive metabolism of nitric oxide in hepatocytes: possible interaction with thiols

Nitric oxide (NO) is both an endogenously generated species and the active species released from a variety of important drugs. Due to its endogenous generation and use as a therapeutic agent, the metabolism and fate of NO is of interest and concern. To date, most attention regarding the metabolism and fate of NO has been paid to its oxidized metabolites. Due to the reducing environment of cells, we considered that NO may also undergo reductive metabolism as well. Therefore, we have examined the reductive metabolism of NO by hepatocytes. Generation of nitrous oxide (N(2)O) was used as an indication of NO reduction. Indeed, we observed that NO could be reduced to N(2)O by the cytosolic fraction of hepatocytes. The N(2)O production was partially inhibited by the thiol modifying agent, N-ethylmaleimide and thiol consumption was observed during N(2)O formation. Thus, our results indicate that NO reduction is feasible and likely occurs via a thiol-dependent process.

Nitric oxide inhibits ornithine decarboxylase by S-nitrosylation

Ornithine decarboxylase (ODC) is the initial enzyme in the polyamine synthetic pathway, and polyamines are required for cell proliferation. We have shown previously that nitric oxide (NO) inhibits ODC activity in Caco-2 cells and in crude cell lysate preparations. In this study we examined the mechanism by which NO inhibits the activity of purified ODC. NO, in the form of S-nitrosocysteine (CysNO), S-nitrosoglutathione (GSNO), or 1, 1-diethyl-2-hydroxy-2-nitroso-hydrazine (DEA/NO), inhibited enzyme activity in a concentration-dependent manner. CysNO (1 microM) inhibited ODC activity by approximately 90% and 3 microM GSNO by more than 70%. DEA/NO was less potent, inhibiting enzyme activity by 70% at a concentration of 30 microM. Inhibition of enzyme activity by CysNO, GSNO, or DEA/NO was reversible by addition of dithiothreitol or glutathione. Cuprous ion (Cu (I)) also reversed the inhibitory effect of these NO donor agents. The data presented here support the hypothesis that NO inhibits ODC activity via S-nitrosylation of a critical cysteine residue(s) on ODC.

Reaction of organic nitrate esters and S-nitrosothiols with reduced flavins: a possible mechanism of bioactivation

Organic nitrate esters, such as glyceryl trinitrate and isosorbide dinitrate, are a class of compounds used to treat a variety of vascular ailments. Their effectiveness relies on their ability to be bioactivated to nitric oxide (NO) which, in turn, relaxes vascular smooth muscle. Although there have been many biological studies that indicate that NO can be formed from organic nitrate esters in a biological environment, the chemical mechanism by which this occurs has yet to be established. Previous studies have implicated both flavins and thiols in organic nitrate ester bioactivation. Thus, we examined the chemical interactions of flavins and thiols with organic nitrate esters as a means of determining the role these species may play in NO production. Based on these studies we concluded that a reasonable chemical mechanism for organic nitrate ester bioactivation involves reduction to the organic nitrite ester followed by conversion to a nitrosothiol. The release of NO from nitrosothiols can occur via a variety of processes including reaction with dihydroflavins and NADH.

NG-hydroxy-L-arginine and nitric oxide inhibit Caco-2 tumor cell proliferation by distinct mechanisms

The objective of this study was to elucidate the role and mechanism of nitric oxide (NO) synthase (NOS) in modulating the growth of the Caco-2 human colon carcinoma cell line. The two novel observations reported here are, first, that NG-hydroxy-L-arginine (NOHA) inhibits Caco-2 tumor cell proliferation, likely by inhibiting arginase activity, and, second, that NO causes cytostasis by mechanisms that might involve inhibition of ornithine decarboxylase (ODC) activity. Both arginase and ODC are enzymes involved in the conversion of arginine to polyamines required for cell proliferation. Cell growth was monitored by cell count, cell protein analysis, and DNA synthesis. NOHA (1-30 microM) and NO in the form of DETA/NO (1-30 microM) inhibited cell proliferation by 30-85%. The cytostatic effect of NOHA was prevented by addition of excess ornithine, putrescine, spermidine, or spermine to cell cultures, whereas the cytostatic effect of NO (DETA/NO) and alpha-difluoromethylornithine (ODC inhibitor) was unaffected by ornithine but was prevented by putrescine, spermidine, or spermine. The cytostatic effect of NOHA appeared to be independent of its conversion to NO, and the effect of NO appeared to be independent of cGMP. NOHA inhibited urea production by Caco-2 cells and inhibited arginase catalytic activity (85% at 3 microM), whereas NO (DEA/NO and SNAP) inhibited ODC activity (>/=60% at 30 microM) without affecting arginase activity. Coculture of Caco-2 cells with lipopolysaccharide/cytokine-activated rat aortic endothelial cells markedly slowed Caco-2 cell proliferation, and this was blocked by NOS inhibitors. These observations that NOHA and NO may inhibit sequential steps in the arginine-polyamine pathway suggest a novel biological role for NOS in the inhibition of cell proliferation of certain tumor cells and possibly other cell types.

Reaction between S-nitrosothiols and thiols: generation of nitroxyl (HNO) and subsequent chemistry

S-Nitrosothiols have been implicated to play key roles in a variety of physiological processes. The potential physiological importance of S-nitrosothiols prompted us to examine their reaction with thiols. We find that S-nitrosothiols can react with thiols to generate nitroxyl (HNO) and the corresponding disulfide. Further reaction of HNO with the remaining S-nitrosothiol and thiol results in the generation of other species including NO, sulfinamide, and hydroxylamine. Mechanisms are proposed that rationalize the observed products.

Amplified nitric oxide production by pulmonary alveolar macrophages of newborn rats

Oxygen (O2)-dependent and O2-independent antimicrobial mechanisms are used by alveolar macrophages (AM) to maintain lung sterility, but these mechanisms are underdeveloped in neonatal AM. Nitric oxide (NO(.)), a more recently described antimicrobial and immunomodulating molecule, has not been studied in neonatal AM. Lavaged AM from 3-day-old, 10-day-old, maternal and adult rats were treated with or without lipopolysaccharide (LPS) and/or interferon-γ (IFN-γ) and NO(.) synthase activity was measured as its L-arginine metabolites: NO2(-), NO3(-), and citrulline. Superoxide anion (O2(.-)) production by suspended macrophages, initiated by either opsonized zymosan or phorbol, was used as a marker of O2-dependent antimicrobial activity. Lysozyme content of AM was measured as a component of O2-independent antimicrobial activity. Unstimulated 3-day-old macrophages generated >10-fold more NO2(-) + NO3(-) than did 10-day-old, maternal or adult AM. Twenty hours after LPS and IFN-γ stimulation, 3-day-old AM produced > 2 times more NO2(-) and NO3(-) than did the more mature macrophages. Basal and stimulated O2(.-) release was similar among 3-day-old, 10-day-old and adult AM, while lysozyme concentrations were > 4-fold higher in adult macrophages compared to AM from 3-day-old pups. Rather than having a role in NO(.)-dependent antimicrobial activity, we propose that newborn AM have amplified NO(.) production to modulate their own differentiation and replication after birth. The age-dependent differences in NO(.) synthase expression by AM may lend insight into the regulation of this important enzyme.

The chemistry and tumoricidal activity of nitric oxide/hydrogen peroxide and the implications to cell resistance/susceptibility

The mechanism of cytotoxicity of the NO donor 3-morpholino-sydnonimine toward a human ovarian cancer cell line (OVCAR) was examined. It was found that the NO-mediated loss of cell viability was dependent on both NO and hydrogen peroxide (H2O2). Somewhat surprisingly, superoxide (O2) and its reaction product with NO, peroxynitrite (-OONO), did not appear to be di- rectly involved in the observed NO-mediated cytotoxicity against this cancer cell line. The toxicity of NO/H2O2 may be due to the production of a potent oxidant formed via a trace metal-, H202-, and NO-dependent process. Because the combination of NO and H2O2 was found to be particularly cytotoxic, the effect of NO on cellular defense mechanisms involving H2O2 degradation was investigated. It was found that NO was able to inhibit catalase activity but had no effect on the activity of the glutathione peroxidase (GSHPx)-glutathione reductase system. It might therefore be expected that cells that utilize primarily the GSHPx-glutathione reductase system for degrading H2O2 would be somewhat resistant to the cytotoxic effects of NO. Consistent with this idea, it was found that ebselen, a compound with GSHPx-like activity, was able to protect cells against NO toxicity. Also, lowering endogenous GSHPx activity via selenium depletion resulted in an increased susceptibility of the target cells to NO-mediated toxicity. Thus, a possible NO/H2O2/metal-mediated mechanism for cellular toxicity is presented as well as a possible explanation for cell resistance/susceptibility to this NO-initiated process.

Oxidation of N-hydroxyguanidine by nitric oxide and the possible generation of vasoactive species

It has been reported previously that the N-hydroxyguanidine function of N-hydroxy-L-arginine can react with nitric oxide (NO) to generate other species that can act as potent vasodilators with different biological lifetimes than NO. The identities of these species have yet to be determined. Therefore, we have studied the reaction between NO and N-hydroxyguanidine and determined that N-hydroxyguanidine is capable of reducing NO to yield nitrous oxide (N2O) and possibly other nitroso species. It is likely that at least some of the N2O formation in these reactions is due to the initial generation of nitroxyl (HNO). Since HNO has been shown to be a potent vasorelaxant, it is possible that some of the non-NO-mediated biological activity alluded to in previous studies was due to HNO and that other nitroso-species generated in the reaction may also contribute to the overall pharmacological activity by release of either NO or HNO.

Gender differences in atherosclerosis: possible role of nitric oxide

The mechanism by which women in the reproductive age group are protected from developing coronary heart disease (CHD) as compared with men of similar age is not known. To elucidate whether there is a gender difference in the rate of atherosclerosis formation, we investigated the rate of development of atherosclerosis in both male and female rabbits fed an identical diet consisting of 2% cholesterol for 10 and 15 weeks. The extent of atherosclerosis was correlated with the amount of basal and stimulated release of nitric oxide (NO) from endothelium-intact aortic rings obtained from these animals. Under identical dietary conditions, the female rabbits fed a high cholesterol diet (HCD) for 10 weeks developed very little atherosclerosis (10% surface involvement) as compared with male rabbits (42% surface involvement). However, no significant gender differences in atherosclerosis were observed after 15 weeks of the HCD. The serum cholesterol, high and low density lipoprotein (HDL and LDL) cholesterol were similar in animals fed the HCD for 10 and 15 weeks. The basal release of NO from endothelium-intact aortic rings was significantly greater in control females as compared with males. The magnitude of endothelium-dependent relaxation of aortic rings obtained from both male and female rabbits fed the HCD were impaired to a similar extent, and this impairment correlated with the duration of hyperlipidemia but not with the extent of atherosclerosis. The arginine content of aortic rings were not different between males (257 +/- 52 nmol/g wet weight) and females (345 +/- 62 nmol/g wet weight) or between control and hyperlipidemic groups (males 312 +/- 69; females 301 +/- 65 nmol/g wet weight). Although the precise mechanism for the slower rate of development of atherosclerosis in the female rabbits as compared with males is not clear, the greater basal release of NO in females before they were fed a hyperlipidemic diet, as well as other factors, may be involved. The impairment of endothelium-dependent relaxation in hyperlipidemic animals is not due to a decrease in the availability of arginine, the substrate for NO.

Neuronal nitric oxide synthase self-inactivates by forming a ferrous-nitrosyl complex during aerobic catalysis

Neuronal NO synthase (NOS) is a flavin-containing hemeprotein that generates NO from L-arginine, NADPH, and O2. NO has recently been proposed to autoinhibit NOS. We have investigated whether a NOS heme-NO complex forms during aerobic steady-state catalysis. Visible and resonance Raman spectra recorded during steady-state NO synthesis by NOS showed that the majority of enzyme (70-90%) was present as its ferrous-nitrosyl complex. Ferrous-nitrosyl NOS formed only in the coincident presence of NADPH, L-arginine, and O2. Its level remained constant during NO synthesis until the NADPH was exhausted, after which the complex decayed to regenerate ferric resting NOS. Stopped-flow measurements revealed that the buildup of the ferrous-NO complex was rapid (< 2 s) and caused a 10-fold decrease in the rate of NADPH consumption by NOS. Complex formation and decay could occur several times with no adverse affect on its subsequent formation or on NOS catalytic activity. Neither enzyme dilution nor NO scavengers (superoxide and oxyhemoglobin) diminished formation of ferrous-nitrosyl NOS or prevented the catalytic inhibition attributed to its formation. The ferrous-nitrosyl complex also formed in unfractionated cell cytosol containing neuronal NOS upon initiating NO synthesis. We conclude that a majority of neuronal NOS is converted quickly to a catalytically inactive ferrous-nitrosyl complex during NO synthesis independent of the external NO concentration. Thus, NO binding to the NOS heme may be a fundamental feature of catalysis and functions to down-regulate NO synthesis by neuronal NOS.

Prodrugs of nitroxyl as potential aldehyde dehydrogenase inhibitors vis-a-vis vascular smooth muscle relaxants

The synthesis and the chemical/biological properties of N-hydroxysaccharin (1) (2-hydroxy-1,2-benzisothiazol-3(2H)-one 1,1-dioxide), a nitroxyl prodrug, are described. When treated with 0.1 M aqueous NaOH, 1 liberated nitroxyl (HN=O), a known inhibitor of aldehyde dehydrogenase (AlDH), in a time-dependent manner. Nitroxyl was measured gas chromatographically as its dimerization/dehydration product N2O. Under these conditions, Piloty's acid (benzenesulfohydroxamic acid) also gave rise to HNO. However, whereas Piloty's acid liberated finite quantities of nitroxyl when incubated in physiological phosphate buffer, pH 7.4, formation of nitroxyl from 1 was minimal. This was reflected in the differential inhibition of yeast AlDH (IC50 = 48 and > 1000 microM) and the differential relaxation of preconstricted rabbit aortic rings in vitro (EC50 = 1.03 and 14.0 microM) by Piloty's acid and 1, respectively. The O-acetyl derivative of 1, viz., N-acetoxysaccharin (13a), was much less active in both assays. It is concluded that N-hydroxysaccharin (1) is relatively stable at physiological pH and liberates nitroxyl appreciably only at elevated pH's. As a consequence, neither 1 nor its O-methyl (8a) and O-benzyl (8b) derivatives were effective AlDH inhibitors in vivo when administered to rats at 1.0 mmol/kg.

The role of thiols in the apparent activation of rat brain nitric oxide synthase (NOS)

The role of thiols on the activation and/or stabilization of rat brain nitric oxide synthase (NOS) has been investigated. It was found that thiols are not necessary for stabilizing or protecting the protein during purification but are required during enzyme turnover for maximum activity. In the complete absence of thiols but with added tetrahydrobiopterin, the enzyme retained a low basal activity. Thiol addition to a thiol-deplete preparation of the enzyme resulted in a 4 to 7-fold increase in activity when measured after 15 min. High concentrations of dihydropteridine reductase also caused an apparent activation of NOS and was capable of replacing thiols. The data presented is consistent with a cofactor role for thiols. The possibility that they serve as reducing agents for the regeneration of tetrahydrobiopterin from dihydrobiopterins is discussed.

Inhibition of constitutive and inducible nitric oxide synthase: potential selective inhibition

Nitric oxide (NO) is a molecule that has been shown to be involved in a diverse array of physiological events. A variety of disease states and disorders are, in fact, due to either an over- or an underproduction of NO. As a result of the ubiquity and diversity of NO-mediated phenomenon, pharmacological manipulation is difficult. NO biosynthesis is the result of an oxidation of a terminal nitrogen on the amino acid arginine by a class of enzymes generally referred to as the nitric oxide synthases (NOSs). Since the various isoforms of NOS are distributed in cells and tissues according to their function, there is the possibility that manipulation of NO levels can be accomplished by designing specific pharmacological agents targeted at a single NOS isoform. Thus, this review discusses general inhibition of the NOSs by a variety of agents and then focuses on the possibility of developing agents for specific isoform inhibition.

The protective effect of tetrahydrobiopterin on the nitric oxide-mediated inhibition of purified nitric oxide synthase

The nitric oxide synthases (NOS) are a class of enzymes responsible for the generation of NO via an oxygen and NADPH dependent oxidation of the amino acid arginine. These enzymes are ironheme proteins which contain FAD and FMN and, enigmatically, require tetrahydrobiopterin (BH4). NOS has recently been shown to be subject to inhibition by its product, NO. Preliminary data by us indicate that a possible role for BH4 is to prevent and/or reverse the NO-mediated inhibition of NOS. The objective of this study was to elucidate the mechanism by which BH4 protects NOS against NO inhibition. Protection of NOS from NO inhibition was observed by both BH4 and the BH4 regeneration system, dihydropteridine reductase (DHPR)/NADH. NO, rather than an oxidation product, appears to be the inhibitory species. Protection by BH4 is not likely due to a simple chemical reaction between BH4 and NO or its oxidation product, NO2. The results are consistent with a protective mechanism by which BH4 may act as a nonstoichiometric reducing agent for a redox active enzyme component, such as the ironheme, to prevent NO ligation.

Chemistry of nitric oxide: biologically relevant aspects

This discussion of NO chemistry has addressed only certain aspects that may be of biological relevance. It is not meant to be a comprehensive in-depth treatment of general NO chemistry. For more information regarding the chemistry of NO and related nitrogen oxides, the reader is referred to a number of reviews (Ragsdale, 1973; Schwartz and White, 1983; Vosper, 1975; McCleverty, 1979; Gilbert and Thomas, 1972; Bonner and Hughes, 1988). Hopefully, it has become evident that an appreciation and knowledge of the chemistry of NO are key to understanding its physiological utility as well as its toxicology. It appears that Nature exploits a variety of the unique chemical aspects of NO in order to attain the needed physiological specificity. For example, the specific activation of guanylate cyclase by NO is most likely due to its unique binding properties to iron hemes. Also, the inherent lack of reactivity of NO makes it a fairly innocuous species unless it is coupled with other radical species, such as O2-. This chemical property thus allows NO to be utilized as a physiological messenger molecule and, under certain conditions, as a cytotoxic effector molecule as well.

Inhibition of purified nitric oxide synthase from rat cerebellum and macrophage by L-arginine analogs

The inhibition of nitric oxide synthase (NOS) activity by a variety of L-arginine-related compounds has been investigated. The inhibitory properties of NG-amino-, NG-methyl-, NG-hydroxy-, NG-ethyl-, NG-allyl-, NG, NG-dimethyl-, NG-methoxy-L-arginine, and several other L-arginine derivatives were compared in NOS purified from both macrophage and rat cerebellum. Also, these compounds were tested for their potential as alternate substrates by determining their ability to elicit NADPH consumption by NOS. NG-Methoxy-L-arginine appears to be an alternate substrate for NOS, whereas most other L-arginine analogs, except for the biosynthetic intermediate NG-hydroxy-L-arginine, do not elicit significant enzyme turnover.

Formation of free nitric oxide from l-arginine by nitric oxide synthase: direct enhancement of generation by superoxide dismutase

Although nitric oxide (NO) appears to be one of the oxidation products of L-arginine catalyzed by NO synthase (NOS; EC 1.14.13.39), past studies on the measurement of NO in cell-free enzymatic assays have not been based on the direct detection of the free NO molecule. Instead, assays have relied on indirect measurements of the stable NO oxidation products nitrite and nitrate and on indirect actions of NO such as guanylate cyclase activation and oxyhemoglobin oxidation. Utilizing a specific chemiluminescence assay, we report here that the gaseous product of L-arginine oxidation, catalyzed by both inducible macrophage and constitutive neuronal NOS, is indistinguishable from authentic NO on the basis of their physicochemical properties. NO gas formation by NOS was dependent on L-arginine, NADPH, and oxygen and inhibited by NG-methyl-L-arginine and cyanide anion. Superoxide dismutase (SOD) caused a marked, concentration-dependent increase in the production of free NO by mechanisms that were unrelated to the dismutation of superoxide anion or activation of NOS. These observations indicate that free NO is formed as a result of NOS-catalyzed L-arginine oxidation and that SOD enhances the generation of NO without directly affecting NO itself. SOD appears to elicit a novel biological action, perhaps accelerating the conversion of an intermediate in the L-arginine-NO pathway such as nitroxyl (HNO) to NO.

Nitric oxide inhibits neuronal nitric oxide synthase by interacting with the heme prosthetic group. Role of tetrahydrobiopterin in modulating the inhibitory action of nitric oxide

The objective of this study was to elucidate the mechanism by which nitric oxide (NO) inhibits NO synthase. Previous studies revealed that NO inhibits unpurified preparations of NO synthase. In the present study, the mechanism by which NO inhibits purified neuronal NO synthase from rat cerebellum was examined. The rate of L-citrulline formation from L-arginine was non-linear despite the presence of excess substrate and cofactors and was further inhibited by 30% by 200 units/ml superoxide dismutase. In contrast, 30 microM oxyhemoglobin increased NO synthase activity by 2-fold and made the reaction rate linear. These observations were consistent with the hypothesis that enzymatically generated NO inhibits NO synthase activity. Exogenous NO (0.1-10 microM) (but not NO2, nitrite, or nitrate) also inhibited NO synthase, and enzyme inhibition was not competitive with L-arginine. NO synthase inhibition by NO and other heme ligands supports the view that heme is involved in the catalytic activity of NO synthase. Oxyhemoglobin prevented but could not reverse enzyme inhibition by NO. NO synthase inhibition by NO was markedly diminished and reversed, however, by tetrahydrobiopterin (50 microM) or a tetrahydrobiopterin-regenerating system, and the latter made the reaction rate linear. In contrast, NO synthase inhibition by NO was markedly enhanced by heme oxidants (10 microM methylene blue; 3 microM ferricyanide), and these oxidants directly inhibited NO synthase activity. These observations suggest that NO interacts with enzyme-bound ferric heme to inhibit NO synthase activity. In support of this view, NO inhibited enzyme activity in the absence of turnover, when the heme iron is in the ferric state, and this inhibition was reversed by tetrahydrobiopterin. Therefore, the oxidation state of heme iron appears to be one important determinant for the inhibitory action of NO, and tetrahydrobiopterin may increase NO synthase activity by diminishing the inhibitory action of NO.

Inhibition of rat liver arginase by an intermediate in NO biosynthesis, NG-hydroxy-L-arginine: implications for the regulation of nitric oxide biosynthesis by arginase

NG-hydroxy-L-arginine, an intermediate in the biosynthesis of nitric oxide (NO), has been found to be a uniquely potent competitive inhibitor of rat liver arginase. Among previously reported inhibitors of arginase and the eight arginine analogs tested herein, only NG-hydroxy-L-arginine was found to be strongly inhibitory. Significantly, the Ki (42 microM) for inhibition of rat liver arginase by NG-hydroxy-L-arginine was found to be 20-40-fold lower than the KM (1-1.7 mM) for its natural substrate, L-arginine. Since NG-hydroxy-L-arginine is the only known intermediate in the biosynthesis of NO from L-arginine, this finding may have significant implications for the regulation of NO levels in tissues or cells, such as liver or macrophages, which synthesize both NO and contain arginase.

Involvement of nitroxyl (HNO) in the cyanamide-induced vasorelaxation of rabbit aorta

Relaxation of precontracted rabbit aortic rings in vitro by cyanamide, a clinically used alcohol deterrent drug, required catalase and H2O2, suggesting that a bioactivation mechanism was involved. Since the oxidation of cyanamide by catalase/H2O2 had been shown previously to lead to nitroxyl (HNO) generation via the intermediate N-hydroxycyanamide, and aortic ring relaxation was inhibited by the catalase inhibitor, 3-aminotriazole, HNO appears to be responsible for the vasorelaxation mediated by cyanamide. This was further supported by the observation that N,O-dibenzoyl-N-hydroxycyanamide (DBHC), a derivative of N-hydroxycyanamide that releases HNO in the absence of catalase/H2O2, was a potent vasorelaxant, with an EC50 of 4.2 +/- 1.3 x 10(-6) M.

The effect of nonionic detergents on the activity and/or stability of rat brain nitric oxide synthase

The results of this study indicate that the addition of low concentrations of a nonionic detergent such as those represented by the Tween, Brij, or Triton classes causes an apparent activation of nitric oxide synthase. It is possible that this apparent activation is due to the ability of these detergents to stabilize the protein. The stabilizing influence of the detergents may be a result of inhibiting the dissociation of the dimeric protein into monomers or the dissociation of an essential cofactor or prosthetic group from the active enzyme. Regardless of the mechanism of action, the addition of low concentrations of nonionic detergents results in longer and increased nitric oxide synthase activity and may be an important tool for those involved in enzymological studies of nitric oxide synthase.

Conversion of nitroxyl (HNO) to nitric oxide (NO) in biological systems: the role of physiological oxidants and relevance to the biological activity of HNO

Nitroxyl (HNO) and nitric oxide (NO) are chemically related compounds in that NO is the one-electron oxidation product of HNO. Previous studies from this laboratory indicated that HNO elicits pharmacological effects that are similar to those elicited by NO, namely, vascular smooth muscle relaxation and stimulation of cyclic GMP formation. The objective of the present study was to determine whether HNO could be converted to NO under physiological conditions and thereby account for the pharmacological actions of HNO. Utilizing the method of chemiluminescence detection, HNO was found to be readily converted to NO by a variety of ubiquitous biological oxidants including oxygen, superoxide dismutase, methemoglobin and flavins. The potency of HNO as a vasorelaxant using isolated rabbit aortic rings was markedly increased 30-fold by superoxide dismutase, whereas the potency of the NO-donor compound, S-nitroso-N-acetylpenicillamine (SNAP), was increased only 2-fold. These data indicate that the ready conversion of HNO to NO may account for the biological activity of HNO. Thus, HNO and HNO-donor compounds represent good sources of NO.

Peracid oxidation of an N-hydroxyguanidine compound: a chemical model for the oxidation of N omega-hydroxyl-L-arginine by nitric oxide synthase

Arginine is oxidized by a class of enzymes called the nitric oxide synthases (NOS) to generate citrulline and, presumably, nitric oxide (.NO). N-Hydroxylation of a guanidinium nitrogen of arginine to generate N-hydroxyarginine (NOHA) has been shown to be a step in the biosynthesis of .NO. In an effort to elucidate the mechanism by which further oxidation of NOHA occurs, the oxidation of a model N-hydroxyguanidine compound by several peracids was studied in depth. This oxidative chemistry is a possible model for the enzymatic process since the corresponding urea (or citrulline equivalent product) is obtained along with an oxidized nitrogen species. The oxidized nitrogen product was, however, not .NO but rather HNO. .NO generation in this chemical system and in the enzymatic process would require another one-electron oxidation. The mechanistic details of this are further discussed.

Oxidation of nitric oxide in aqueous solution to nitrite but not nitrate: comparison with enzymatically formed nitric oxide from L-arginine

Nitric oxide (NO) in oxygen-containing aqueous solution has a short half-life that is often attributed to a rapid oxidation to both NO2- and NO3-. The chemical fate of NO in aqueous solution is often assumed to be the same as that in air, where NO is oxidized to NO2 followed by dimerization to N2O4. Water then reacts with N2O4 to form both NO2- and NO3-. We report here that NO in aqueous solution containing oxygen is oxidized primarily to NO2- with little or no formation of NO3-. In the presence of oxyhemoglobin or oxymyoglobin, however, NO and NO2- were oxidized completely to NO3-. Methemoglobin was inactive in this regard. The unpurified cytosolic fraction from rat cerebellum, which contains constitutive NO synthase activity, catalyzed the conversion of L-arginine primarily to NO3- (NO2-/NO3- ratio = 0.25). After chromatography on DEAE-Sephacel or affinity chromatography using 2',5'-ADP-Sepharose 4B, active fractions containing NO synthase activity catalyzed the conversion of L-arginine primarily to NO2- (NO2-/NO3- ratio = 5.6) or only to NO2-, respectively. Unpurified cytosol from activated rat alveolar macrophages catalyzed the conversion of L-arginine to NO2- without formation of NO3-. Addition of 30 microM oxyhemoglobin to all enzyme reaction mixtures resulted in the formation primarily of NO3- (NO2-/NO3- ratio = 0.09 to 0.20). Cyanide ion, which displaces NO2- from its binding sites on oxyhemoglobin, inhibited the formation of NO3-, thereby allowing NO2- to accumulate. These observations indicate clearly that the primary decomposition product of NO in aerobic aqueous solution is NO2- and that further oxidation to NO3- requires the presence of additional oxidizing species such as oxyhemoproteins.

Basal release of nitric oxide from aortic rings is greater in female rabbits than in male rabbits: implications for atherosclerosis

Estradiol is known to exert a protective effect against the development of atherosclerosis, but the mechanism of this hormonal action is unknown. One of the early events in the development of atherosclerosis is the adhesion of macrophages to endothelial cells, and nitric oxide (NO) inhibits this process. We show that basal release of NO is greater with endothelium-intact aortic rings from female rabbits than those from males. Oophorectomy diminishes both circulating estradiol concentration and basal release of NO to levels seen in male rabbits. These data establish that basal NO release from endothelium-intact aortic rings depends on circulating estradiol concentration and offer an explanation for the protective effect of estradiol against the development of atherosclerosis.

The pharmacological activity of nitroxyl: a potent vasodilator with activity similar to nitric oxide and/or endothelium-derived relaxing factor

Chemical oxidation of N-hydroxy-L-arginine (NOHA) and other N-hydroxyguanidines has been previously shown to generate either nitric oxide (NO) or nitroxyl (HNO), depending on the oxidative conditions. Because N-hydroxy-L-arginine has been demonstrated to be a biosynthetic intermediate in the oxidative conversion of arginine to endothelium-derived relaxing factor, the possible formation of HNO through a biological process was considered. This study, therefore, explores the biological activity of HNO as a possible effector molecule, and the results indicate that HNO is capable of eliciting vasorelaxation in both rabbit aorta and bovine intrapulmonary artery by a guanylate cyclase-dependent pathway. The pharmacological properties of HNO were very similar to those of endothelium-derived relaxing factor, and the possible relationship between HNO and endothelium-derived relaxing factor is discussed.

N,O-diacylated-N-hydroxyarylsulfonamides: nitroxyl precursors with potent smooth muscle relaxant properties

N,O-Diacylated-N-hydroxyarylsulfonamides are capable of slowly releasing nitroxyl (HNO) by simple, non-enzymatic hydrolysis in Krebs solution at 37 degrees C. Release of nitric oxide (NO) was not seen. These compounds were also found to elicit vasorelaxation in rabbit thoracic aorta in vitro, presumably as a result of their ability to release HNO. This effect was enhanced by the addition of superoxide dismutase (SOD). Thus, these results are consistent with previous work indicating that HNO is a potent vasorelaxant.

Chemical oxidation of N-hydroxyguanidine compounds. Release of nitric oxide, nitroxyl and possible relationship to the mechanism of biological nitric oxide generation

N omega-Hydroxy-L-arginine was found to cause vasodilation in arginine-depleted rabbit aorta. It is, therefore, likely to be a biosynthetic intermediate in the conversion of arginine to nitric oxide in this tissue. N-Hydroxyalkylguanidine compounds, including N omega-hydroxy-L-arginine were oxidized with various oxidizing agents and examined for their ability to release nitric oxide. All oxidizing agents tested were capable of oxidizing the N-hydroxyguanidine function but only lead tetra-acetate (Pb(OAc)4) and potassium ferricyanide/hydrogen peroxide (K3FeCN6/H2O2) were capable of generating significant amounts of nitric oxide. Oxidation with K3FeCN6, lead oxide (PbO2) and silver carbonate (Ag2CO3) resulted instead in the release of nitrous oxide (N2O) presumably through the initial release of nitroxyl (HNO).

Inhibition of cytochrome P-450 2E1 by diallyl sulfide and its metabolites

Diallyl sulfide, a major flavor ingredient from garlic, was previously shown to inhibit chemically induced carcinogenesis and cytotoxicity in animal model systems. It modulated cytochrome P-450 compositions by inactivating P-450 2E1 and inducing P-450 2B1. The present studies examined the inhibition of P-450 2E1 mediated p-nitrophenol hydroxylase activity by diallyl sulfide and its putative metabolites diallyl sulfoxide and diallyl sulfone (DASO2). Each compound displayed competitive inhibition of p-nitrophenol hydroxylase activity in incubations using liver microsomes from acetone-pretreated male Sprague-Dawley rats. Preincubation of the microsomes with DASO2 inactivated p-nitrophenol hydroxylase activity in a process that was time- and NADPH-dependent and saturable, exhibited pseudo-first-order kinetics, was protected by alternate substrate, was accompanied by a loss of microsomal P-450-CO binding spectrum, and was unaffected by exogenous nucleophile. The Ki value for DASO2 was 188 microM and the maximal rate of inactivation was 0.32 min-1. DASO2 was ineffective in the inactivation of ethoxyresorufin dealkylase, pentoxyresorufin dealkylase, or benzphetamine demethylase activity. Purified P-450 2E1 in a reconstituted system was inactivated in a time- and NADPH-dependent manner by DASO2. The metabolic conversion of diallyl sulfide to the sulfoxide and sulfone was observed in vivo and in vitro. The results suggest that diallyl sulfide inhibits the metabolism of P-450 2E1 substrates by competitive inhibition mechanisms and by inactivating P-450 2E1 via a suicide-inhibitory action of DASO2.

Determination of the mechanism of demethylenation of (methylenedioxy)phenyl compounds by cytochrome P450 using deuterium isotope effects

The mechanism of demethylenation of (methylenedioxy)benzene (MDB), (methylenedioxy)amphetamine (MDA), and (methylenedioxy)methamphetamine (MDMA) by purified rabbit liver cytochrome P450IIB4 has been investigated by using deuterium isotope effects. A comparison of the magnitude and direction of the observed kinetic isotope effects indicates that the three compounds are demethylenated by different mechanisms. The different mechanisms of demethylenation have been proposed on the basis of comparisons of the observed biochemical isotope effects with the isotope effects from purely chemical systems.

Transformation of dopamine and alpha-methyldopamine by NG108-15 cells: formation of thiol adducts

The catecholamines, alpha-methyldopamine (alpha-MeDA) and dopamine (DA), have been implicated in 3,4-(methylenedioxy)amphetamine (MDA) toxicity. The toxicity and metabolic fate of alpha-MeDA, a metabolite of MDA, and DA, a neurotransmitter released by MDA administration, were examined in NG108-15 cells. Both catechols were found to accumulate intracellularly into NG108-15 cells. alpha-MeDA was about 4 times more toxic than DA in the cells. The depletion of glutathione (GSH) by buthionine sulfoximine (BSO) resulted in a drastic increase (10 times) in the alpha-MeDA mediated toxicity while the toxicity of DA was enhanced by 2 times. DA was largely metabolized to dihydroxyphenylacetic acid (DOPAC) and, to a smaller extent, formed an adduct with GSH. alpha-MeDA was primarily metabolized to a GSH adduct. alpha-MeDA was also metabolized to a product which was identified as the cysteinyl adduct. These adducts were identified by HPLC coelution with authentic standards. The GSH and cysteinyl adducts are presumably formed through conjugation of the thiols with intermediary quinone oxidation products of DA and alpha-MeDA. Previous studies indicate that alpha-MeDA is significantly more toxic than DA, especially under conditions of GSH depletion. The results of this study suggest that alpha-MeDA toxicity may occur through cytoplasmic accumulation and oxidation to a reactive quinone species followed by reaction with vital thiol functions or generation of reactive oxygen species. Cytoplasmic DA levels, on the other hand, appear to be significantly lower due to MAO metabolism and vesicular storage, and therefore, DA appears less likely to form conjugates with thiol groups or participate in possible redox cycling.

N omega-hydroxy-L-arginine: a novel arginine analog capable of causing vasorelaxation in bovine intrapulmonary artery

This study describes the effects of N omega-hydroxy-L-arginine (NOHA) on endothelium dependent and endothelium independent relaxation of bovine pulmonary artery. These results are consistent with the hypothesis that NOHA is a biosynthetic intermediate in the production of nitric oxide from arginine. N omega-Hydroxy-L-arginine causes both endothelium dependent and endothelium independent vasorelaxation, similar to that of arginine. This NOHA elicited relaxation was also inhibitable by N-methylarginine, N-nitroarginine and N-aminoarginine.

Modulation of rat hepatic microsomal monooxygenase enzymes and cytotoxicity by diallyl sulfide

Diallyl sulfide (DAS) and other organosulfur compounds inhibit chemically induced carcinogenic and toxic responses in rodent model systems. A possible mechanism of action is the inhibition of the hepatic cytochrome P450IIE1-dependent bioactivation of the procarcinogens and protoxicants. Previous work showed competitive inhibition by DAS of N-nitrosodimethylamine (NDMA) demethylase activity in vitro, and a reduction in the microsomal level of P450IIE1 after in vivo treatment with DAS. The present studies demonstrated a time- and dose-dependent decrease of hepatic microsomal P450IIE1 activity, induction of P450IIB1 and pentoxyresorufin dealkylase activity, and moderate induction of ethoxyresorufin dealkylase activity by oral DAS treatment. DAS treatment elevated P450IIB1 mRNA but had no effect on P450IIE1 mRNA. Treatment with putative metabolites of DAS, diallyl sulfoxide and diallyl sulfone, led to similar modulations in monooxygenase activities, but the decrease of P450IIE1 activity by the sulfone occurred more rapidly. In studies in vitro, diallyl sulfone caused a metabolism-dependent inactivation of P450IIE1, but such inactivation was not observed with DAS or diallyl sulfoxide. The profile of microsomal testosterone metabolism after DAS treatment indicated an enhancement of P450IIB1-dependent 16 beta-hydroxylase activity, and a decrease in 6 beta-hydroxytestosterone production possibly related to a lower level of P450IIIA1 or IIIA2. When rats were subjected to a 48-hr fast and DAS treatment, the starvation-induced microsomal P450IIE1 level was decreased by DAS. Inhibition of hepatotoxicity due to exposure to P450IIE1 substrates, CCl4 and NDMA, by DAS was observed under a variety of treatment schedules.

Shear stress-induced release of nitric oxide from endothelial cells grown on beads

An in vitro bioassay system was developed to study endothelium-mediated, shear stress-induced, or flow-dependent generation of endothelium-derived relaxing factor (EDRF). Monolayers of aortic endothelial cells were grown on a rigid and large surface area of microcarrier beads and were packed in a small column perfused with Krebs bicarbonate solution. The perfusate was allowed to superfuse three endothelium-denuded target pulmonary arterial strips arranged in a cascade. Fluid shear stress caused a flow-dependent release of EDRF from the endothelial cells. The action of EDRF was abolished by oxyhemoglobin and methylene blue, and the generation of EDRF in response to shear stress was markedly inhibited or abolished by NG-nitro-L-arginine, by NG-amino-L-arginine, by calcium-free extracellular medium, and by depleting endothelial cells of endogenous L-arginine. Addition of L-arginine to arginine-deficient but not arginine-containing endothelial cells rapidly restored the capacity of shear stress and bradykinin to generate EDRF. These observations indicate that fluid shear stress causes the generation of EDRF with properties of nitric oxide from aortic endothelial cells and that the bioassay system described may be useful for studying the mechanism of mechanochemical coupling that leads to nitric oxide generation.

Comparative studies of N-hydroxylation and N-demethylation by microsomal cytochrome P-450

The N-hydroxylation of representative aromatic amines by rabbit liver microsomes was mediated by cytochrome P-450 as demonstrated by the sensitivity to carbon monoxide and other cytochrome P-450 inhibitors. The rate of N-hydroxylation was increased by induction with phenobarbital. Involvement of isozyme LM2 (P-50IIB1) was demonstrated in reconstituted systems. Aromatic N-hydroxylation was substantially faster and more efficient than aliphatic N-hydroxylation, while N-demethylation of aromatic and aliphatic dimethylamines was comparable in rate and efficiency. Aliphatic N-hydroxylation showed no rate increase with increasing pH despite the predicted increase in the concentration of the neutral substrate. The relative rates of N-hydroxylation and N-demethylation were compared for a series of para-substituted aromatic amines. The rate of demethylation of para-substituted N,N-dimethylanilines, as measured both by product formation and by NADPH consumption, correlated with the electronic parameter sigma and with the Hansch lipophilicity parameter pi. N-Hydroxylation of a similar series of anilines did not show a dependence on the electronic parameter but was dependent on the lipophilicity parameter. The differing dependence on the electronic parameter suggests that there are different rate-determining processes of N-oxidation for these two reactions.

Nitric oxide and cyclic GMP formation upon electrical field stimulation cause relaxation of corpus cavernosum smooth muscle

In the presence of functional adrenergic and cholinergic blockade, electrical field stimulation relaxes corpus cavernosum smooth muscle by unknown mechanisms. We report here that electrical field stimulation of isolated strips of rabbit corpus cavernosum promotes the endogenous formation and release of nitric oxide (NO), nitrite, and cyclic GMP. Corporal smooth muscle relaxation in response to electrical field stimulation, in the presence of guanethidine and atropine, was abolished by tetrodotoxin and potassium-induced depolarization, and was markedly inhibited by NG-nitro-L-arginine, NG-amino-L-arginine, oxyhemoglobin, and methylene blue, but was unaffected by indomethacin. The inhibitory effects of NG-substituted analogs of L-arginine were nearly completely reversed by addition of excess L-arginine but not D-arginine. Corporal smooth muscle relaxation elicited by electrical field stimulation was accompanied by rapid and marked increases in tissue levels of nitrite and cyclic GMP, and all responses were nearly abolished by NG-nitro-L-arginine. These observations indicate that penile erection may be mediated by NO generated in response to nonadrenergic-noncholinergic neurotransmission.