Metabolic activation of n-butyraldoxime by rat liver microsomal cytochrome P450. A requirement for the inhibition of aldehyde dehydrogenase

Disposition of butanal oxime in rat following oral, intravenous and dermal administration

1. The disposition of [1-14C]butanal oxime (BOX) was determined in the rat after oral, i.v. and dermal administration. 2. Oral doses of [14C]BOX (2 and 20 mg/kg) were predominantly excreted in the urine (> 42%) and converted to 14CO2 (> 30%) and about 10% of the dose remained in the tissues 72 h post-dosing. 3. Eight and 16% of a 2 and 20 mg/kg dermal dose of BOX, respectively, were absorbed, due in part to rapid volatilization from the surface of the skin. 4. Oral doses of BOX were transformed into several polar and/or anionic metabolites that include sulphate conjugates and a significant amount of thiocyanate. 5. The effect of inhibitors on the metabolism of BOX was investigated using 1-aminobenzotriazole (ABT; an inhibitor of diverse cytochrome P450s) and trans-1,2-dichloroethylene (DCE; an inhibitor of CYP2E1). No thiocyanate anion was detected in the urine of rat treated with DCE or ABT. ABT markedly increased the production of 14CO2 and excretion as volatile metabolites. DCE had no effect on 14CO2 excretion, but increased exhalation of radiolabel. ABT also effectively blocked the expression of toxic effects attributable to cyanide in rat given near-lethal doses of BOX. 6. The data are consistent with two distinct pathways of metabolism for BOX, (1) reduction to an imine, hydrolysis and subsequent conversion of butyraldehyde to 14CO2 and (2) CYP3A-catalysed dehydration of BOX to butyronitrile followed by CYP2E1-catalysed release of cyanide.

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.

Characterization of the in vivo inhibition of rat hepatic microsomal aldehyde dehydrogenase activity by metyrapone

Microsomal aldehyde dehydrogenase (mALDH; EC 1.2.1.3) has been proposed to catalyze the oxidation of various aldehydic products of lipid peroxidation, but the regulation of the enzyme has not been characterized. Metyrapone administration (100 mg/kg, i.p.) produced a rapid decline in the rates of mALDH-catalyzed decanal dehydrogenation; other xenobiotics were generally without effect. Thus, a 22% decrease in activity was detected 2 hr following metyrapone administration, and 52% of the activity remained at 6 hr. The decrease in microsomal decanal dehydrogenation was also dose-dependent with 70, 43, and 12% of the control activity remaining following pretreatment with 25, 100, and 250 mg/kg metyrapone, respectively. This disease in microsomal decanal dehydrogenase activity occurred without a change in mALDH immunoreactive protein, and metyrapone did not inhibit the activity in vitro. The kinetic analysis revealed similar decreases in the maximal reaction velocities (Vmax) for both decanal and NAD in the metyrapone-treated group (200 +/- 10 and 190 +/- 20 nmol NADH produced/min/mg protein, respectively) compared with the untreated group (330 +/- 10 and 350 +/- 20 nmol NADH produced/min/mg protein, respectively), but the Michaelis constants (Km) were unchanged. These data are consistent with the in vivo inactivation of a portion of the mALDH enzyme. A possible consequence of the in vivo inhibition of this enzyme by metyrapone could be the accumulation of toxic aldehydes in the vicinity of the microsomal membrane following lipid peroxidation.