diethyl-maleate and bromobenzene

Potential mechanisms of 4-bromobenzene-induced developmental toxicity were evaluated using frog embryo teratogenesis assay-Xenopus (FETAX). Early X, laevis embryos were exposed to 4-bromobenzene in two separate definitive concentration-response tests with and without an exogenous metabolic activation system (MAS) or selectively inhibited MAS. The MAS was treated with carbon monoxide (CO) to modulate P-450 activity, cyclohexene oxide (CHO) to modulate epoxide hydrolase activity, and diethyl maleate (DM) to modulate glutathione conjugation. Addition of the intact MAS, and particularly the CHO- and DM-inhibited MASs, dramatically increased the embryo lethal potential of 4-bromobenzene. Addition of the CO-inhibited MAS decreased the developmental toxicity of activated 4-bromobenzene to levels approximating that of the parent compound. Results from these studies suggested that a highly toxic arene oxide intermediate of 4-bromobenzene formed as the result of mixed function oxidase (MFO)-mediated metabolism may play an important role in the development toxicity of 4-bromobenzene in vitro. Furthermore, both epoxide hydrolase and glutathione conjugation appeared to be responsible for activated 4-bromobenzene detoxification.

Topics: Abnormalities, Drug-Induced; Animals; Aroclors; Biotransformation; Bromobenzenes; Carbon Monoxide; Carcinogens; Chlorodiphenyl (54% Chlorine); Cyclohexanes; Cyclohexenes; Female; Male; Maleates; Pregnancy; Rats; Rats, Sprague-Dawley; Teratogens; Xenopus

The mechanisms of the liver damage produced by three glutathione (GSH) depleting agents, bromobenzene, allyl alcohol and diethylmaleate, was investigated. The change in the antioxidant systems represented by alpha-tocopherol (vitamin E) and ascorbic acid were studied under conditions of severe GSH depletion. With each toxin liver necrosis was accompanied by lipid peroxidation that developed only after severe depletion of GSH. The hepatic level of vitamin E was decreased whenever extensive lipid peroxidation developed. In the case of bromobenzene intoxication, vitamin E decreased before the onset of lipid peroxidation. Changes in levels of the ascorbic and dehydroascorbic acid indicated a redox cycling of vitamin C with the oxidative stress induced by all the three agents. Such a change of the redox state of vitamin C (increase of the oxidized over the reduced form) may be an index of oxidative stress preceding lipid peroxidation in the case of bromobenzene. In the other cases, such a change is likely to be a consequence of lipid peroxidation. Experiments carried out with vitamin E deficient or supplemented diets indicated that the pathological phenomena occurring as a consequence of GSH depletion depend on hepatic levels of vitamin E. In vitamin E deficient animals, lipid peroxidation and liver necrosis appeared earlier than in animals fed the control diet. Animals fed a vitamin E supplemented diet had an hepatic vitamin E level double that obtained with a commercial pellet diet. In such animals, bromobenzene and allyl alcohol had only limited toxicity and diethylmaleate none in spite of comparable hepatic GSH depletion. Thus, vitamin E may largely modulate the expression of the toxicity by GSH depleting agents.

Topics: 1-Propanol; Animals; Antioxidants; Ascorbic Acid; Bromobenzenes; Chromatography, High Pressure Liquid; Glutathione; Lipid Peroxidation; Liver; Male; Maleates; Malondialdehyde; Mice; Necrosis; Propanols; Time Factors; Vitamin E

Glutathione in tissues forms an intense fluorophore with a solution of o-phthalaldehyde at room temperature. We have studied the loss of glutathione from tissue sections and find that it is not measurable from thick sections. The fluorescence spectra of the induced fluorophore between glutathione and o-phthalaldehyde are identical in model and tissue sections, while depletion of hepatic glutathione by diethyl maleate produces a comparable fall in fluorescence measured biochemically or histochemically. This simple method is specific as interfering substances, such as spermine and spermidine, produce very weak fluorescence under the conditions employed.

Topics: Aldehydes; Animals; Bromobenzenes; Fluorescent Antibody Technique; Glutathione; Histocytochemistry; Liver; Male; Maleates; Mice; o-Phthalaldehyde; Spectrometry, Fluorescence; Spermidine; Spermine

The mechanisms of bromobenzene and iodobenzene hepatotoxicity in vivo were studied in mice. Both the intoxications caused a progressive decrease in hepatic glutathione content. In both instances liver necrosis was evident only when the hepatic glutathione depletion reached a threshold value (3.5-2.5 nmol/mg protein). The same threshold value was evident for the occurrence of lipid peroxidation. Similar results were obtained in a group of mice sacrificed 15-20 hours after the administration of diethylmaleate, a drug which is mainly conjugated with hepatic glutathione without previous metabolism. The correlation between lipid peroxidation and liver necrosis was much more significant than that between covalent binding and liver necrosis. This fact supports the view that lipid peroxidation is the major candidate for the liver cell death produced by bromobenzene intoxication. Moreover, a dissociation of liver necrosis from covalent binding was observed in experiments in which Trolox C (a lower homolog of vitamin E) was administered after bromobenzene poisoning. The treatment with Trolox C, in fact, almost completely prevented both liver necrosis and lipid peroxidation, while not changing at all the extent of the covalent binding of bromobenzene metabolites to liver protein.

Topics: Alanine Transaminase; Animals; Aspartate Aminotransferases; Bromobenzenes; Chemical and Drug Induced Liver Injury; Chromans; Glutathione; Iodobenzenes; Lipid Peroxides; Liver; Liver Diseases; Male; Maleates; Mice; Necrosis; Proteins; Rats; Rats, Inbred Strains

Bromobenzene-3,4-oxide can be detected in venous blood of rats by trapping it as the corresponding 35[S]glutathione conjugates. More bromobenzene-3,4-oxide is detected in venous blood of rats treated with phenobarbital and diethyl maleate than in venous blood of rats treated with phenobarbital alone. The half-life of bromobenzene-3,4-oxide in venous blood was about 13.5 s. Bromobenzene-3,4-oxide may contribute to the extrahepatic covalent binding and presumably the toxicity observed after bromobenzene administration. The present technique may be used to determine in blood, the presence or absence of other reactive metabolites that form glutathione conjugates.

Topics: Animals; Bromobenzenes; Half-Life; Male; Maleates; Phenobarbital; Rats; Rats, Inbred Strains

NMRI Albino mice, in which the hepatic glutathione (GSH) content was decreased by nearly 50% by either the administration of a pure glucose diet or by starvation, were intoxicated with aryl halides, bromobenzene, and iodobenzene (13 and 9 mmol/kg body weight, respectively, p.o.). After both intoxications, the hepatic glutathione content decreased rapidly to very low values, and liver necrosis, as assessed by serum transaminase levels, occurred in about 45 or 60% of the animals (in the case of bromobenzene or iodobenzene, respectively) after a lag phase of 9 or 6 hr. In both instances liver necrosis was evident only when the hepatic GSH depletion reached a threshold value (3.5-2.5 nmols/mg protein). The same threshold value was evident for the occurrence of lipid peroxidation (measured as both carbonyl functions and conjugated dienes in liver phospholipids). The possibility that the depletion in hepatic GSH level is capable of inducing lipid peroxidation and necrosis could be supported by the fact that similar results were obtained after the administration of inethylmaleate (12 mmol/kg, p.o.), a drug which is expected to conjugate directly with GSH without previous metabolism. The covalent binding of reactive metabolites to cellular macromolecules was determined in the case of bromobenzene poisoning. A dissociation between liver necrosis and covalent binding was observed in experiments in which Trolox C, a lower homolog of vitamin E, was administered (270 mumol/kg) 9 and 13 hr after bromobenzene poisoning. The treatment with Trolox C, in fact, almost completely prevented both liver necrosis and lipid peroxidation, while the extent of the covalent binding of bromobenzene metabolites to liver proteins was not altered.

Topics: Animals; Bromobenzenes; Glutathione; Iodobenzenes; Lipid Peroxides; Liver; Male; Maleates; Mice; Mice, Inbred Strains; Necrosis