Glutathione transferase benzo pyrene-4,5-oxide

Comparison of the reactivities of benzene oxides, naphthalene oxides, phenanthrene oxides, and arene oxides derived from benzo [a] pyrene and 7,12-dimethylbenz[a] anthracene with hepatic glutathione S-epoxide transferase showed that benzene oxides without electron-withdrawing groups are poor substrates as also are polycyclic arene oxides. Only naphthalene oxide was a good substrate. 

The oxidation of naphthalene was one of the earliest examples of an epoxide as an intermediate in aromatic hydroxylation. As shown in Figure 7.3, the epoxide can rearrange nonenzymatically to yield predominantly 1-naphthol, or interact with the enzyme epoxide hydrolase to yield the dihydrodiol, or interact with glutathione S-transferase to yield the glutathione conjugate, which is ultimately metabolized to a mercapturic acid. These reactions are also of importance in the metabolism of other xenobiotics that contain an aromatic nucleus, such as the insecticide carbaryl and the carcinogen benzo(a)pyrene. 

The assay method described by Eaton and Stapleton (1989), measures the activities of both cytosolic glutathione 5-transferase and microsomal epoxide hydrolase toward benzo[a]pyrene-4,5-oxide as a substrate. These enzymes are important in the biotransformation of many epoxide xenobiotics, including potentially carcinogenic arene oxides. 

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