Oxidation of hydrogen sulfide and methanethiol to thiosulfate by rat tissues: a specialized function of the colonic mucosa.

Colonic bacteria release large quantities of the highly toxic thiols hydrogen sulfide (H(2)S) and methanethiol (CH(3)SH). These gases rapidly permeate the colonic mucosa, and tissue damage would be expected if the mucosa could not detoxify these compounds rapidly. We previously showed that rat cecal mucosa metabolizes these thiols via conversion to thiosulfate. The purpose of the present study in rats was to determine if this conversion of thiols to thiosulfate is (a) a generalized function of many tissues, or (b) a specialized function of the colonic mucosa. The tissues studied were mucosa from the cecum, right colon, mid-colon, ileum, and stomach; liver; muscle; erythrocytes; and plasma. The metabolic rate was determined by incubating homogenates of the various tissues with H(2)(35)S and CH(3)(35)SH and measuring the rate of incorporation of (35)S into thiosulfate and sulfate. The detoxification activity of H(2)S (expressed as nmol/mg per min) that resulted in thiosulfate production was at least eight times greater for cecal and right colonic mucosa than for the non-colonic tissues. Thiosulfate production from CH(3)SH was at least five times more rapid for cecal and right colonic mucosa than for the non-colonic tissues. We conclude that colonic mucosa possesses a specialized detoxification system that allows this tissue to rapidly metabolize H(2)S and CH(3)SH to thiosulfate. Presumably, this highly developed system protects the colon from what otherwise might be injurious concentrations of H(2)S and CH(3)SH. Defects in this detoxification pathway possibly could play a role in the pathogenesis of various forms of colitis.

Cigarette smoke-induced endothelium dysfunction: role of superoxide anion.

OBJECTIVES: Cigarette smoking is strongly associated with coronary artery disease and atherosclerosis. While smoking has been shown to impair endothelium-dependent vasorelaxation, the mechanisms involved are not completely understood. We investigated the role of superoxide anion and vasoconstricting prostanoids in cigarette smoke induced endothelial dysfunction. METHODS: Endothelial function was assessed in rat aortic rings exposed to cigarette smoke-treated Krebs buffer, by measuring agonist stimulated endothelium-dependent vasorelaxation. Treatment with superoxide dismutase (SOD) as well as ifetroban, thromboxane A2/prostaglandin endoperoxide H2 (TxA2/PGH2) receptor blocker and indomethacin (cyclooxygenase inhibitor) was used to investigate the role of superoxide anion and vasoconstricting eicosanoids on cigarette smoke-induced endothelial dysfunction. The effect of cigarette smoke on endothelial nitric oxide synthase (eNOS) catalytic activity was measured by conversion of L-arginine to L-citrulline in rat aortas and rat endothelial cell homogenates supplemented with eNOS cofactors. RESULTS: Relaxations to receptor-dependent agonists, acetylcholine and adenosine diphosphate (ADP), as well as to a receptor-independent agonist, A23187 (Ca2+ ionophore) were significantly impaired by cigarette smoke. Cigarette smoke did not impair relaxations to sodium nitroprusside, indicating preserved guanylate cyclase activity. Further, cigarette smoke did not affect eNOS catalytic activity in homogenates from either endothelial cells or aortas previously exposed to cigarette-smoketreated Krebs buffer. Treatment with SOD or ifetroban and in a lesser degree by indomethacin prevented cigarette-smoke-induced endothelial dysfunction. CONCLUSIONS: Taken together, our results suggest that cigarette smoking causes an increase in vascular superoxide production which results in decreased nitric oxide (NO) bioactivity and concomitantly increases production of cyclooxygenase dependent and independent vasoconstricting eicosanoids.

N-Terminal dipeptides of D(-)-penicillamine as sequestration agents for acetaldehyde.

Since acetaldehyde (AcH), a toxic oxidation product of ethanol, may play an etiologic role in the initiation of alcoholic liver disease, we had earlier pioneered the development of beta, beta-disubstituted-beta-mercapto-alpha-amino acids as AcH-sequestering agents. We now report the synthesis of a series of N-terminal dipeptides of D(-)-penicillamine, prepared from the synthon 3-formyl-2,2,5,5-tetramethylthiazolidine-4S-carboxylic acid (3), a cyclized N-protected derivative of D(-)-penicillamine. These dipeptides were equally or more effective than penicillamine in trapping AcH in a cell-free system. In experiments using a hepatocyte culture system, two of the dipeptides, D-penicillamylglycine (6a) and D-penicillamyl-beta-alanine (6d), at 1/20 the molar concentration of ethanol, lowered the concentration of ethanol-derived AcH by 79% and 84%, respectively, at 2 h. The presence of cyanamide (an inhibitor of aldehyde dehydrogenase) in the incubation medium resulted in a 45-fold increase in ethanol-derived AcH; nevertheless, dipeptides 6a and 6c (D-penicillamyl-alpha-aminoisobutyric acid) were able to reduce this AcH level by approximately one-third.

Reaction of nitroxyl, an aldehyde dehydrogenase inhibitor, with N-acetyl-L-cysteine.

Nitroxyl (HNO) is the aldehyde dehydrogenase (AIDH) inhibitor produced by catalase action on cyanamide. Incubation of N-acetyl-L-cysteine (NAC), a reagent with a free sulfhydryl group, with Piloty's acid (a nitroxyl generator) suggested that NAC was acting as a competitive "trap" for nitroxyl. Elucidation of the structure of this reaction product should give an insight as to how nitroxyl interacts with AIDH, a sulfhydryl enzyme. We now present evidence that the product formed is N-acetyl-L-cysteinesulfinamide (NACS). We have synthesized NACS and showed that this synthetic product was identical to the product formed in the trapping experiment. Both had identical RT values by reverse phase HPLC and identical RF values by TLC using three different solvent systems. The structural identification of this nitroxyl trapped product as a sulfinamide now allows the chemical confirmation of the active-site cysteine residue of AIDH as Cys-302.

Detoxification of hydrogen sulfide and methanethiol in the cecal mucosa.

Colonic bacteria liberate large quantities of the highly toxic gases hydrogen sulfide (H(2)S) and methanethiol (CH(3)SH). The colonic mucosa presumably has an efficient means of detoxifying these compounds, which is thought to occur through methylation of H(2)S to CH(3)SH and CH(3)SH to dimethylsulfide (CH(3)SCH(3)). We investigated this detoxification pathway by incubating rat cecal mucosal homogenates with gas containing H(2)S, CH(3)SH, or CH(3)SCH(3). Neither CH(3)SH nor CH(3)SCH(3) was produced during H(2)S catabolism, whereas catabolism of CH(3)SH liberated H(2)S but not CH(3)SCH(3). Thus, H(2)S and CH(3)SH are not detoxified by methylation to CH(3)SCH(3). Rather, CH(3)SH is demethylated to H(2)S, and H(2)S is converted to nonvolatile metabolites. HPLC analysis of the homogenate showed the metabolite to be primarily thiosulfate. Analysis of cecal venous blood obtained after intracecal instillation of H(2)(35)S revealed that virtually all absorbed H(2)S had been oxidized to thiosulfate. The oxidation rate of H(2)S by colonic mucosa was 10,000 times greater than the reported methylation rate. Conversion to thiosulfate appears to be the mechanism whereby the cecal mucosa protects itself from the injurious effects of H(2)S and CH(3)SH, and defects in this detoxification possibly could play a role in colonic diseases such as ulcerative colitis.

Diethylcarbamoylating/nitroxylating agents as dual action inhibitors of aldehyde dehydrogenase: a disulfiram-cyanamide merger.

Benzenesulfohydroxamic acid (Piloty's acid) was functionalized on the hydroxyl group with the N,N-diethylcarbamoyl group, and the hydroxylamine nitrogen was substituted with acetyl (1a), pivaloyl (1b), benzoyl (1c), and ethoxycarbonyl (1d) groups. Only compound 1d inhibited yeast aldehyde dehydrogenase (AlDH) in vitro (IC(50) 169 microM). When administered to rats, 1d significantly raised blood acetaldehyde levels following ethanol challenge, thus serving as a diethylcarbamoylating/nitroxylating, dual action inhibitor of AlDH in vivo. A more potent dual action agent was N-(N, N-diethylcarbamoyl)-O-methylbenzenesulfohydroxamic acid (5c), which was postulated to release diethylcarbamoylnitroxyl (9), a highly potent diethylcarbamoylating/nitroxylating agent, following metabolic O-demethylation in vivo. The dual action inhibition of AlDH exhibited by 1d, and especially 9, constitutes a merger of the mechanism of action of the alcohol deterrent agents, disulfiram and cyanamide.

Generation of nitric oxide and possibly nitroxyl by nitrosation of sulfohydroxamic acids and hydroxamic acids.

Diazeniumdiolates (NONOates) and sulfohydroxamic acids are chemical entities that spontaneously generate nitric oxide (NO) and nitroxyl (HNO), respectively, at physiological pH and temperature. By combining the functional aspects of the NONOates with the hydroxamic acids and sulfohydroxamic acids, hybrid NONOate-type compounds that could theoretically generate nitroxyl or nitric oxide can be rationalized. Although the instability of these compounds, viz., the N-nitrosohydroxamic acids and the N-nitrososulfohydroxamic acids, precluded their chemical characterization by actual isolation, their transient existence was deduced by identification of the products of their decomposition. Thus, treatment of benzohydroxamic acid (BHA) with limiting or excess nitrous acid (from NaNO(2) and H(3)PO(4)) gave rise to quantitative generation of N(2)O, possibly via HNO, based on the limiting reactant. Nitrosation of N-t-butyloxycarbonyl hydroxylamine gave similar results. The organic acid produced from BHA was identified as benzoic acid. No nitric oxide was detected from these reactions. In contrast, treatment of Piloty's acid (benzenesulfohydroxamic acid) and methanesulfohydroxamic acid (MSHA) with nitrous acid under the same conditions as above gave 36% of the theoretical quantity of NO from Piloty's acid and 47% of NO from MSHA, although finite quantities of HNO (measured as N(2)O) were also formed. The organic acid produced from Piloty's acid was identified by reverse-phase HPLC as the redox product, benzenesulfinic acid.

Impact of M49, Mrp, Enn, and C5a peptidase proteins on colonization of the mouse oral mucosa by Streptococcus pyogenes.

Resistance to phagocytosis is a hallmark of virulent Streptococcus pyogenes (group A streptococcus). Surface-bound C5a peptidase reduces recruitment of phagocytes to the site of infection, and hyaluronic acid capsules and/or the M protein limit the uptake of streptococci. In this study the relative impact of M and M-like proteins and the C5a peptidase on the virulence of a serotype M49 strain was assessed. The capacities of isogenic strains with an insertion mutation in emm49; with a deletion mutation in scpA49 (C5a peptidase gene); and with a deletion that removes all three M-like genes, mrp49, emm49, and enn49, to colonize mice and resist phagocytosis were compared. Experiments confirmed results obtained in an earlier study, which showed that the M49 protein was not required for in vitro resistance to phagocytosis, and also showed that the M protein was not required for colonization of mice. Failure to produce all three M-like proteins, M49, Mrp, and Enn49, significantly reduced the ability of these streptococci to resist phagocytosis in vitro but did not significantly alter the persistence of streptococci on the oral mucosa. In vitro experiments indicate that M+ streptococci are phagocytized by polymorphonuclear leukocytes that have been activated with phorbol-12-myristate 13-acetate or recombinant human C5a. This observation may explain the finding that expression of M49 protein is not essential for short-term colonization of the mouse oral mucosa.

Mechanisms of inhibition of aldehyde dehydrogenase by nitroxyl, the active metabolite of the alcohol deterrent agent cyanamide.

Nitroxyl, produced in the bioactivation of the alcohol deterrent agent cyanamide, is a potent inhibitor of aldehyde dehydrogenase (AIDH); however, the mechanism of inhibition of AlDH by nitroxyl has not been described previously. Nitroxyl is also generated from Angeli's salt (Na2N2O3) at physiological pH, and, indeed, Angeli's salt inhibited yeast AlDH in a time- and concentration-dependent manner, with IC50 values under anaerobic conditions with and without NAD+ of 1.3 and 1.8 microM, respectively. Benzaldehyde, a substrate for AlDH, competitively blocked the inhibition of this enzyme by nitroxyl in the presence of NAD+, but not in its absence, in accord with the ordered mechanism of this reaction. The sulfhydryl reagents dithiothreitol (5 mM) and reduced glutathione (10 mM) completely blocked the inhibition of AlDH by Angeli's salt. These thiols were also able to partially restore activity to the nitroxyl-inhibited enzyme, the extent of reactivation being dependent on the pH at which the inactivation occurred. This pH dependency indicates the formation of two inhibited forms of the enzyme, with an irreversible form predominant at pH 7.5 and below, and a reversible form predominant at pH 8.5 and above. The reversible form of the inhibited enzyme is postulated to be an intra-subunit disulfide, while the irreversible form is postulated to be a sulfinamide. Both forms of the inhibited enzyme are derived via a common N-hydroxysulfenamide intermediate produced by the addition of nitroxyl to active site cysteine thiol(s).

Prodrugs of nitroxyl and nitrosobenzene as cascade latentiated inhibitors of aldehyde dehydrogenase.

The prototypic aromatic C-nitroso compound, nitrosobenzene (NB), was shown previously to mimic the effect of nitroxyl (HN=O), the putative active metabolite of cyanamide, in inhibiting aldehyde dehydrogenase (AlDH). To minimize the toxicity of NB in vivo, pro-prodrug forms of NB, which were designed to be bioactivated either by an esterase intrinsic to AlDH or the mixed function oxidase enzymes of liver microsomes, were prepared. Accordingly, the prodrug N-benzenesulfonyl-N-phenylhydroxylamine (3) was further latentiated by conversion to its O-acetyl (1a), O-methoxycarbonyl (1b), O-ethoxycarbonyl (1c), and O-methyl (2) derivatives. Similarly, pro-prodrug forms of nitroxyl were prepared by derivatization of the hydroxylamino moiety of methanesulfohydroxamic acid with N, O-bis-acetyl (7a), N,O-bis-methoxycarbonyl (7b), N, O-bis-ethoxycarbonyl (7c), and N-methoxycarbonyl-O-methyl (7d) groups. It was expected that the bioactivation of these prodrugs would initiate a cascade of nonenzymatic reactions leading to the ultimate liberation of NB or nitroxyl, thereby inhibiting AlDH. Indeed, the ester pro-prodrugs of both series were highly active in inhibiting yeast AlDH in vitro with IC50 values ranging from 21 to 64 microM. However, only 7d significantly raised ethanol-derived blood acetaldehyde levels when administered to rats, a reflection of the inhibition of hepatic mitochondrial AlDH-2.

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.

Utility of a nitric oxide electrode for monitoring the administration of nitric oxide in biologic systems.

Amperometric techniques for the detection of nitric oxide (NO) are commercially available, but their sensitivity and specificity are not well described. We evaluated the sensitivity and specificity of a Clark-style, platinum NO electrode. The electrode has a lower limit of detection for NO of <25 pmol/ml in vitro and is linear over the range from 25 pmol/ml to 4 nmol/ml. The electrode is specific for NO so long as the protective membrane that covers the electrode is intact. Any defect in this membrane results in the detection of other redox agents such as hydrogen peroxide. Because of its ease of handling, specificity, and sensitivity, the NO electrode is a useful tool for quantification of administered NO in vitro and in various biologic systems.

Use of measurements of ethanol absorption from stomach and intestine to assess human ethanol metabolism.

Controversy exists concerning the site (stomach vs. liver) and magnitude of first-pass metabolism of ethanol. We quantitated gastric and total ethanol absorption rates in five male subjects and utilized these measurements to evaluate first-pass metabolism. Gastric emptying of ethanol (0.15 g/kg) was determined via a gamma camera and gastric absorption from the ratio of gastric ethanol to [14C]polyethylene glycol. Gastric absorption accounted for 30% and 10% of ethanol administered with food and water, respectively. With food, estimated gastric mucosal ethanol concentrations fell from 19 to 5 mM over 2 h. Calculations using these concentrations and kinetic data for gastric alcohol dehydrogenase showed <2% of the dose underwent gastric metabolism. Application of observed ethanol absorption rates to a model of human hepatic ethanol metabolism indicated that only 30% and 4% of the dose underwent first-pass metabolism when administered with food and water, respectively. We conclude that virtually all first-pass ethanol metabolism occurs in the liver and first-pass metabolism accounts for only a small fraction of total clearance.

Novel prodrugs of cyanamide that inhibit aldehyde dehydrogenase in vivo.

S-Methylisothiourea (4), when administered to rats followed by a subsequent dose of ethanol, gave rise to a 119-fold increase in ethanol-derived blood acetaldehyde (AcH) levels-a consequence of the inhibition of hepatic aldehyde dehydrogenase (A1DH)-when compared to control animals not receiving 4. The corresponding O-methylisourea was totally inactive under the same conditions, suggesting that differential metabolism may be a factor in this dramatic difference between the pharmacological effects of O-methylisourea and 4 in vivo. The S-n-butyl- and S-isobutylisothioureas (8 and 9, respectively) at doses equimolar to that of 4 were nearly twice as effective in raising ethanol-derived blood AcH, while S-allylisothiourea (10) was slightly less active. However, blood ethanol levels of all experimental groups were indistinguishable from controls. Pretreatment of the animals with 1-benzylimidazole, a known inhibitor of the hepatic mixed function oxidases, followed sequentially by either 8, 9, or 10 plus ethanol, reduced blood AcH levels by 66-88%, suggesting that the latter compounds were being oxidatively metabolized to a common product that led to the inhibition of AcH metabolism. In support of this, when 8 was incubated in vitro with rat liver microsomes coupled to catalase and yeast A1DH, the requirement for microsomal activation for the inhibition of A1DH activity was clearly indicated. We suggest that S-oxidation is involved and that the S-oxides produced in vivo inhibited A1DH directly, or spontaneously released cyanamide, an inhibitor of A1DH. Indeed, incubation of 8 with rat liver microsomes and NADPH gave rise to cyanamide as metabolite, identified as its dansylated derivative. Cyanamide formation was minimal in the absence of coenzyme. Extending the side chain was detrimental, since S-benzylisothiourea (11) and S-n-hexadecylisothiourea (12) were toxic, the latter producing extensive necrosis of the liver and kidneys when administered to rats.

Expression of endothelin-B receptors by glia in vivo is increased after CNS injury in rats, rabbits, and humans.

Previous studies have demonstrated that neonatal cultures of astrocytes express functional endothelin (ET) receptors. To determine if similar ET receptors are expressed by adult glia we used 125I-ET-1 to examine the expression of ET receptors both in vivo in the normal and transected optic nerves of the rabbit and rat and in vitro in cultures of astrocytes, microglia, or oligodendrocytes. Additionally, we examined the expression of ET receptors in the human optic nerve. Moderate levels of ET(B) receptors were identified in the rabbit and rat forebrain, whereas in the normal rabbit, rat, and human optic nerves a low density of ET(B) receptors was observed, mainly in association with glial fibrillary acidic protein + (GFAP+) astrocytes. After unilateral optic nerve transection, or damage to the retina, the density of glial ET(B) receptors in the optic nerve is significantly increased in all species examined. Thus, at 7 days posttransection there is a significant increase in ET(B) receptors, and by 90 days posttransection the density of ET(B) receptors in the rabbit or rat optic nerve was among the highest of any area in the central nervous system (CNS). Primary cultures of astrocytes or microglia, but not oligodendrocytes, express 125I-ET-1 binding sites. These data demonstrate that in the normal CNS, astrocytes express low but detectable levels of ET(B) receptors, and, after CNS injury, both astrocytes and microglia express high levels of ET(B) receptors. ET(B) receptors provide a therapeutic target for regulating glial proliferation and the release of neurotrophic factors from glia that occur in response to neuronal injury.

First-pass metabolism of ethanol is negligible in rat gastric mucosa.

Controversy exists concerning whether first-pass metabolism of imbibed ethanol occurs in the gastric mucosa or liver. We assessed ethanol metabolism in rat gastric mucosa by determining to what extent intact [14C]ethanol in body water plus hepatic metabolism could account for [14C]ethanol absorbed from the pylorus-ligated stomach. Intact [14C]ethanol in systemic body water accounted for 84 +/- 1.9% of the [14C]ethanol absorbed from the stomach over a 30-min period. Assuming a 15 ml/min hepatic blood flow, the predicted hepatic metabolism of [14C]ethanol over the 30 min of the study was 18% of the dose. The sum of intact [14C]ethanol and predicted hepatic metabolism accounted for 100% of the ethanol absorbed from the stomach. We conclude that negligible metabolism of ethanol occurred in the gastric mucosa.

Mechanism for the inhibition of aldehyde dehydrogenase by nitric oxide.

The inhibition of Saccharomyces cerevisiae aldehyde dehydrogenase (AlDH) by gaseous nitric oxide (NO) in solution and by NO generated from diethylamine nonoate was time and concentration dependent. The presence of oxygen significantly reduced the extent of inhibition by NO, indicating that NO itself rather than an oxidation product of NO such as N2O3 is the inhibitory species under physiological conditions. A cysteine residue at the active site of the enzyme was implicated in this inhibition based on the following observations: a) NAD+ and NADP+, but not reduced cofactors, significantly enhanced inhibition of AlDH by NO; b) the aldehyde substrate, benzaldehyde, blocked inhibition; and c) inhibition was accompanied by loss of free sulfhydryl groups on the enzyme. Activity of the NO-inactivated enzyme was readily restored by treatment with dithiothreitol (DTT), but not with GSH. This difference was attributed, in part, to a redox process leading to the formation of a cyclic DTT disulfide. Based on the chemistry deduced from model systems, the reaction of NO with AlDH sulfhydryls was shown to produce intramolecular disulfides and N2O. These disulfides were shown to be intrasubunit disulfides by nonreducing SDS-PAGE analysis of the NO- inhibited enzyme. Following complete inhibition of AlDH by NO, four of the eight titratable (Ellman's reagent) sulfhydryl groups of AlDH were found to be oxidized to disulfides. These results suggest that a) the sulfhydryl group of active site Cys-302 and a proximal cysteine are oxidized to form an intrasubunit disulfide by NO; b) only two of the four subunits of AlDH are catalytically active; and c) NO preferentially oxidizes sulfhydryl groups of the catalytically active subunits. A detailed mechanism for the inhibition of AlDH by NO is presented.

Inhibition of S-nitrosation of reduced glutathione in aerobic solutions of nitric oxide by phosphate and other inorganic anions.

Reduced glutathione is nitrosated in aerobic solutions of nitric oxide under physiological conditions; however, the extent of S-nitrosation was found to be dependent on the inorganic anions present. Of nine anions tested, the bifunctional anions, arsenate, phosphate, and pyrophosphate (40 mM), inhibited the S-nitrosation reaction from 20 to 40%, whereas SO4(2-), H3BO3, SCN-, NO3-, Cl-, and acetate inhibited this reaction < or = 15%. A mechanism of inhibition is presented that involves the catalytic hydrolysis of N2O3 by the bifunctional anions; however, using [18O]phosphate as inhibitor, only 10% of the theoretically produced N2O3 was found to be hydrolyzed to nitrite via this mechanism as calculated from the loss of 18O from phosphate. We conclude that this mechanism accounts for only a minor part of the increased inhibition of S-nitrosation by these bifunctional anions.

Induction of endothelial cell injury by cigarette smoke.

Cigarette smoke contains different populations of free radicals which may be responsible for endothelial cell (EC) injury of smokers. The purpose of this study was to examine the effects of gas-phase cigarette smoke on EC endothelium-derived relaxing factor (EDRF)/NO-guanylate cyclase (GC)-cGMP pathway and on EC detachment-type injury after incubation with smoke. Furthermore, we examined whether different kind of antioxidants can prevent smoke-caused EC injury. We measured cGMP pathway using direct (sodium nitroprusside, SNP) and indirect (A23187, the calcium ionophore and bradykinin, BK) activators of GC. Directly and indirectly stimulated EC cGMP production dose-dependently decreased and EC detachment increased after incubation with smoke. Externally added thiols (glutathione, GSH; D-Penicillamine, DP; N-acetylcysteine, NAC) protected EC from damage of cGMP production and cell detachment. Other antioxidants (catalase, deferoxamine and superoxide dismutase) were ineffective. These results suggest that the thiol containing GC in EC is destroyed or inactivated or thiol like species responsible for activation of GC is incomplete in EC after incubation with smoke. It is also possible that externally added thiols bind an unknown component of smoke and this way, EC is protected. EC injury may contribute to vascular diseases associated with cigarette smoking.

Nitrosyl cyanide, a putative metabolic oxidation product of the alcohol-deterrent agent cyanamide.

When incubated with catalase/glucose-glucose oxidase, 13C-labeled cyanamide gave rise not only to 13C-labeled cyanide, but also to 13C-labeled CO2. Moreover, a time-dependent formation of nitrite was observed when cyanamide was oxidized in this system. These results suggested that the initial product of cyanamide oxidation, viz. N-hydroxycyanamide, was being further oxidized by catalase/H2O2 to nitrosyl cyanide (O = N-C = N). Theoretically, nitrosyl cyanide can hydrolyze to the four end-products detected in the oxidative metabolism of cyanamide in vitro, viz. nitroxyl, cyanide, nitrite, and CO2. Accordingly, both unlabeled and 13C-labeled nitrosyl cyanide were synthesized by the low temperature (-40 to -50 degrees) nitrosylation of K-(18-crown-6)cyanide with nitrosyl tetrafluoroborate. The product, a faint blue liquid at this temperature, was transferred as a gas to phosphate-buffered solution, pH 7.4, where it was solvolyzed. Analysis of the headspace by gas chromatography showed the presence of N2O, the dimerization/dehydration product of nitroxyl, while cyanide was detected in the aqueous solution, as measured colorimetrically. [13C]CO2 was analyzed by GC/MS. An oxidative biotransformation pathway for cyanamide that accounts for all the products detected and involving both N-hydroxycyanamide and nitrosyl cyanide as tandem intermediates is proposed.