In vivo and in vitro studies of the hepatotoxic effects of 4-chlorophenol in mice.

4-Chlorophenol (4-CP) was studied for its toxicological effect on liver by using both in vivo and in vitro approaches. Male mice were administered 4-CP, 1.5 mmol/kg body weight, i.p., and were killed at 10, 20, 30 and 50 min after drug injection. Either i.p. or oral 4-CP administration significantly lowered total liver thiol levels by 20-30% after 30 min and 3 hr respectively. This time-dependent effect of 4-CP after i.p. treatment was enhanced when mice were pretreated with hepatic microsomal enzyme inducers (phenobarbital, 40 mg/kg body weight, b.i.d., 7 days; and beta-naphthoflavone, 80 mg/kg body weight once daily, 4 days). Further, the microsomal cytochrome P-450 inhibitor, SKF 525-A, 75 mg/kg body weight injected i.p. to mice 30 min prior to 4-CP administration, blocked the reduction of liver thiol content produced by 4-CP. The results suggest that a chemically reactive intermediate of 4-CP may be formed in liver which is responsible for the observed decrease in liver thiol content. Other investigations were done to characterize the in vitro irreversible binding of [14C]4-CP. [14C]4-CP was bound irreversibly to mouse liver microsomal proteins in a concentration-dependent manner. Binding was NADPH dependent and gave a maximal binding of 12.0 nmol/mg protein/20 min and an apparent binding constant of 0.222 mM. [14C]-Binding of 4-CP was increased by 155 and 127% in liver microsomes of phenobarbital- and beta-naphthoflavone. SKF 525-A, and CO:O2 (4:1, v/v)] and selected nucleophilic compounds (glutathione, L-cysteine or L-lysine) significantly reduced [14C]4-CP binding to mouse liver microsomes. An epoxide hydrolase inhibitor, cyclohexene oxide, did not alter the extent of irreversible binding, whereas scavengers of superoxide anions or agents that are reported to reduce accumulation of active semiquinone and quinone species (L-ascorbic acid, superoxide dismutase or epinephrine) decreased the binding of [14C]4-CP to mouse liver microsomal proteins by 56, 31 and 92% respectively. The data suggest that semiquinone and quinone species of 4-CP may be the chemically reactive intermediates leading to the in vivo reduction of liver thiol levels. Since 4-CP is a minor contaminant and possible metabolite of clofibrate and chemically related hypolipidemic agents, 4-CP and its metabolites may be partly responsible for some of the hepatotoxic effects seen after long-term administration of this therapeutic class of drugs.

Metabolism of 4'-(9-acridinylamino)methanesulfon-m-anisidide by rat liver microsomes.

4'-(9-Acridinylamino)methanesulfon-m-anisidide (m-AMSA) is metabolized by a hepatic microsomal enzyme system composed of rat liver microsomes, a reduced nicotinamide adenine dinucleotide phosphate-generating system, cytosolic protein (or glutathione), and oxygen. Omission of any one of the components, or incubation under an atmosphere of CO or N2, results in inhibition of the reaction. Also, the addition of inhibitors of microsomal metabolism (alpha-naphthoflavone, metyrapone, or SKF 525-A) decreases m-AMSA metabolism. Metabolism of m-AMSA is more rapid with microsomes prepared from rats pretreated with phenobarbital or 3-methylcholanthrene. Two microsomal oxidation products of m-AMSA were isolated and identified as N1'-methanesulfonyl-N4'-(9-acridinyl)-3'-methoxy-2',5'-cyclohex adiene-1', 4'-dimine (m-AQDI) and 3'-methoxy-4'-(9-acridinylamino-2',5'-cyclohexadien-1'-one (m-AQI). m-AQDI reacts with glutathione to form a product previously identified in in vivo studies as the principal rat biliary metabolite and which is not cytotoxic to cultured L1210 cells. Thus, the end result of the microsomal metabolism of m-AMSA is detoxification. However, the two primary oxidation products (m-AQDI and m-AQI) are considerably more cytotoxic to L1210 cells in vitro than is m-AMSA. The concentration of m-AMSA required to produce a 5-log kill is 1.0 microgram/ml compared to 0.01 microgram/ml for m-AQDI and m-AQI. These results indicate that m-AMSA might undergo bioactivation to form the active cytotoxic species of the drug.

The disposition and metabolism of tiazofurin in rodents, rabbits, and dogs.

The pharmacokinetics and metabolism of tiazofurin (2-beta-D-ribofuranosylthiazole-4-carboxamide) have been examined in the mouse, rat, rabbit, and dog using tritiated drug as a marker. In all four species, tiazofurin, given as a single bolus iv injection, is removed from the circulation in a triphasic manner, with a generally prolonged terminal half-life. In all cases, the mean concentration of unchanged drug prevailing during this terminal phase was well within the cytotoxic range (IC50 vs. P388 cells is 2 microM in vitro). Urinary excretion accounted for between approximately 40 and 90% of the administered dose in all four species, with only minor quantities (less than 3%) of drug-derived radioactivity detected in the feces. The metabolism of tiazofurin was examined in mice and rats: although no evidence was uncovered for hydroxylation of tiazofurin at carbon atom 5 of the thiazole ring, phosphorylation of the drug at its 5'-hydroxyl was demonstrable in nearly every organ of both species, but, liver, striated muscles, and kidney were the only tissues catalyzing the synthesis of thiazole-4-carboxamide adenine dinucleotide to any prominent degree. This synthesis did not appear to be a saturated process, even at doses as high as 8000 mg/m2. Since rodent skeletal muscle accumulated high concentrations of tiazofurin phosphates in vivo, it is suggested that musculature may serve as a reservoir for the drug, and contribute to its rather protracted terminal half-life in plasma.

Evidence for the nonenzymatic and irreversible binding of cytembena to rat liver microsomes in vitro.

Characteristics of the irreversible binding of cytembena (CYT) to rat liver microsomal proteins have been investigated in vitro. Binding of [14C]CYT to rat liver microsomal proteins remained unchanged in the presence of SKF-525A or after heat denaturation and was not dependent upon the presence of pyridine nucleotide (NADPH or NADH). Ethacrynic acid, cysteine, dithiothreitol, and lysine were found to block the irreversible binding of [14C]CYT to microsomal proteins in a dose-dependent manner. The rank order of effectiveness as inhibitors of CYT binding was ethacrynic acid greater than cysteine greater than dithiothreitol greater than lysine. In other studies, CYT was shown to preferentially form adducts with cysteine rather than lysine or glycine. Using structural analogs and metabolites of CYT, it was found that 4-methoxybenzoylacrylic acid and beta-benzoylacrylic acid were effective competitors of [14C]CYT binding to liver microsomal proteins. By contrast, 4-methoxybenzoylpropionic acid, 5-(4-methoxyphenyl)dihydro-2(3H)furanone and 4-hydroxy-4-(4-methoxyphenyl)butyric acid were ineffective as inhibitors of the irreversible binding of CYT. These data suggest that sulfhydryl groups are involved in the nonenzymatic binding of CYT and that the presence of a carbon-carbon double bond in CYT, in debrominated metabolites or structural analogs, is requisite for an interference of the binding of CYT to microsomal proteins.