Some characteristics of hamster liver and lung microsomal aryl hydrocarbon (biphenyl and benzo(a)pyrene) hydroxylation reactions

Abstract

Aryl hydrocarbon hydroxylation (AHH) reactions were compared using liver and lung microsomes of corn oil- and 3-methylcholanthrene (3-MC)-treated hamsters, employing benzo(a)pyrene (BAP) and biphenyl as substrates. The predominant AHH activity of liver and lung microsomes from corn oil- or 3-MC-treated hamsters was biphenyl 4-hydroxylase. Biphenyl 2-hydroxylase and BAP-hydroxylase activities were approximately 50 per cent as active as biphenyl 4-hydroxylase in liver and approximately 1–3 per cent as active as biphenyl 4-hydroxylase in lung microsomes. Biphenyl 4-hydroxylase activity was 70–80 per cent as active in lung as in liver microsomes. Treatment with 3-MC in vivo induced the biphenyl 4-hydroxylation reaction in liver but not in lung microsomes, the biphenyl 2-hydroxylation reaction both in lung and liver microsomes, and the BAP hydroxylation reaction in lung but not in liver microsomes. Biphenyl 2- and 4-hydroxylase activities of liver microsomes displayed similar sensitivities to inhibition by a number of chemical inhibitors in vitro. Inhibition of biphenyl hydroxylation reactions by metyrapone or carbon monoxide did not distinguish between lung or liver microsomal mono-oxygenases of corn oil- or 3-MC-treated hamsters. While small differences were expressed by inhibition with ethylmorphine, large differences became apparent through inhibition studies with BAP or α-naphthoflavone. It is concluded that the major aromatic hydroxylase activity of lung microsomes from corn oil- or 3-MC-treated hamsters resembles the constitutive (uninduced) AHH of the liver microsomes and that the minor aromatic hydroxylase activity of lung microsomes from corn oil- or 3-MC-treated hamsters resembles the induced AHH of the liver microsomes.