Diethylthiocarbamic acid methyl ester. A potent inhibitor of aldehyde dehydrogenase found in rats treated with disulfiram or diethyldithiocarbamic acid methyl ester.

Rats were treated with disulfiram (Antabuse, DSF) or its metabolite diethyldithiocarbamic acid methyl ester (Me-DDC) and challenged with ethanol. The blood pressure response to ethanol was followed and blood was analyzed for DSF, Me-DDC and diethyldithiocarbamic acid (DDC). The rat liver aldehyde dehydrogenase (ALDH) isozyme activities were measured 2 hr after the ethanol challenge. Both treatments produced a significant fall in the blood pressure when challenged with ethanol, probably caused by a marked decrease in hepatocyte low Km and high Km activities. The mean plasma concentration ranges of Me-DDC and DDC were found to be 49-1241 nmol/l and 182-841 nmol/l, respectively, whereas DSF was undetectable. In addition, it was found that inactivation of hepatocyte low Km ALDH activity was dependent on preoxidation of Me-DDC by the microsomal cytochrome P-450 mixed function oxidases. Me-DDC was found to be oxidized under aerobic conditions in the presence of NADP to form diethylthiocarbamic acid methyl ester (Me-DTC). The structure was confirmed from its MS/EI fragmentation spectrum. Me-DTC was found to be a potent inhibitor of low Km ALDH when added to rat liver homogenate. The compound was also identified as a metabolite in rat blood collected from the DSF and Me-DDC treated rats, and in blood from human alcoholics on DSF treatment. Me-DTC appears to be more selective for the low Km isozymes whereas the opposite seems to be the case for the hydrolytic product, DTC.

The relationship of carbon disulfide metabolism to development of toxicity.

The metabolism of CS2 proceeds by two distinct metabolic pathways, direct reaction with amine or thiol functions of cellular constituents, and microsomal oxidation to reactive intermediates that covalently bind to cell macromolecules. Reaction with amines or thiols may alter protein function by two primary mechanisms: formation of dithiocarbamate metabolites capable of inactivating metalloenzymes by chelation of metal ions such as copper and zinc, and direct reaction with such functional groups on proteins. Both of these mechanisms may contribute to CS2-induced neurotoxicity. Formation of reactive intermediates catalyzed by microsomal metabolism is clearly important in mediating CS2-induced hepatotoxicity. Its role in catalyzing neurotoxicity is less certain, however, since the mixed function oxidase activity of the central and peripheral systems has not been well characterized.

1-thiocarbamoyl-2-imidazolidinone, a metabolite of niridazole in Schistosoma mansoni.

Niridazole, a nitro heterocyclic antischistosomal drug, is extensively metabolized to unknown metabolites by Schistosoma mansoni. We report that 1-thiocarbamoyl-2-imidazolidinone was isolated by high pressure liquid chromatography and identified by high resolution electron impact mass spectroscopy as a niridazole metabolite in schistosomes. After a 20-h in vitro incubation in 30 ml of medium containing 10 micrograms ml-1 [14C]niridazole (5.2 Ci mol-1), 100 S. mansoni worm pairs contained approximately 275 ng of 1-thiocarbamoyl-2-imidazolidinone. This amount represented 4% of the total metabolized fraction of niridazole in the parasite. Incubation of schistosomes with 1-thiocarbamoyl-2-[2 14C]imidazolidinone (2.7 Ci mol-1) indicated that this metabolite was not taken up. However, schistosomes released an average of 44 ng ml-1 or 1% of the total 1-thiocarbamoyl-2-imidazolidinone found in the worm back into 1 ml of medium during incubation. No host oxidative metabolites of niridazole were found in the parasites.