diethyl-maleate and styrene-oxide

Conjugation with glutathione (GSH) is a mechanism of detoxification of acrylamide (ACR); hence, prior depletion of GSH might be expected to exacerbate ACR's neurotoxicity. GSH levels in female rats were reduced by ip administration of styrene oxide (SO; 250 mg/kg), diethylmaleate (DEM; 0.5 ml/kg), or 2-vinylpyridine (VP; 100 mg/kg) 1.5 or 2 hr prior to a single dose of ACR (100 mg/kg). The time course of GSH depletion following treatment with SO/ACR, DEM/ACR, or VP/ACR showed that all three regimens were equally effective in reducing GSH in liver, cerebellum, cerebral cortex, and hippocampus. GSH levels in the liver were reduced to 4-22% of control levels between 2 and 4 hr after treatment and to 38-57% of control levels in all brain regions between 4 and 8 hr. ACR alone (100 mg/kg) reduced both brain and liver GSH to about 60% of normal. The administration of a second dose of ACR (also 100 mg/kg) 12 hr later further depleted brain and liver GSH to 33% of control. Brains were examined 2, 4, 7, 14, and 30 days after treatment by light and electron microscopy. The administration of SO plus ACR (in either order) produced lesions consisting of pyknotic granule cells confined to the anterior portions of the cerebellum and some of the small neurons of lamina II and III of the cerebral cortex. Electron microscopy revealed condensation of the granule cell chromatin and dissolution of the cytoplasm with the formation of large pericellular spaces. The granule cell lesion was not produced when the time between SO and ACR injections was either 4 or 24 hr. No pathology was observed following treatment with DEM/ACR, VP/ACR, ACR/ACR, vehicle (peanut oil), SO, or ACR alone. It appears that the neurotoxicity in animals treated with SO plus ACR is not directly the result of reduced cellular GSH levels per se, but may involve other detoxification pathways of ACR and SO.

Topics: Acrylamide; Acrylamides; Animals; Cerebellum; Drug Synergism; Epoxy Compounds; Female; Ganglia, Spinal; Glutathione; Glutathione Transferase; Maleates; Necrosis; Pyridines; Rats; Rats, Sprague-Dawley

Binding of aflatoxin B1 (AFB1) to DNA and AFB1-glutathione conjugation during the metabolism of AFB1 have been examined with freshly isolated hepatocytes from male Fischer rats and Syrian hamsters. Even though there was no significant difference in cytochrome P450 and glutathione contents, there were marked differences in the metabolism of AFB1 (33 nM) in hepatocytes from these two species. Thus, AFB1-DNA binding was six-fold higher in the rat than in hamster hepatocytes, whereas AFB1-glutathione conjugation was 12-fold higher in hamster than in rat hepatocytes. The addition of 0.5 mM diethylmaleate had no significant effect in rats, whereas its presence produced a nine-fold increase in AFB1-DNA binding with 85% inhibition of thiol conjugation in hamster hepatocytes. Styrene oxide (1 mM) produced 50% and 25-fold increases in AFB1-DNA binding in rat and hamster hepatocytes, respectively, with corresponding decreases in thiol conjugation. Triethyltin bromide (50 microM) inhibited both processes by 50% in rat hepatocytes, whereas it produced a nine-fold increase in AFB1-DNA binding with a concomitant decrease in thiol conjugation in hamster hepatocytes. These results suggest that glutathione S-transferases play a more significant role in modulating AFB1-DNA binding in hamster than in rat hepatocytes.

Topics: Aflatoxin B1; Aflatoxins; Animals; Carcinogens; Cricetinae; DNA; Epoxy Compounds; Glutathione; In Vitro Techniques; Liver; Maleates; Rats; Species Specificity; Triethyltin Compounds