CYP2C11 and CYP2B1 are major cytochrome P450 forms involved in styrene oxidation in liver and lung microsomes from untreated rats, respectively

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The contribution of cytochrome P450s (P450s) to the formation of styrene glycol from styrene in rat liver microsomes was investigated using monoclonal antibodies to P450s. Anti-CYP2E1 inhibited the formation to a similar extent in ethanol-treated microsomes and in control microsomes in terms of percentage inhibition, whereas to a greater extent in the former than the latter in terms of net inhibition, and only at low substrate concentration. Anti-CYP2C11/6 also inhibited the formation in control and in ethanol-treated microsomes at both low and high concentrations of styrene, and the net degree of inhibition was greater than that obtained with anti-CYP2El, even in ethanol-treated microsomes where CYP2E1 was induced. Anti-CYP2B1/2 and anti-CYPlA1/2 inhibited the formation only in phenobarbital (PB)- and 3-methylcholanthrene (MC)-induced microsomes, respectively. These results suggest that (1) at least four P450s, CYP2C11/6, CYP2E1, CYP2B1/2 and CYP1A1/2, contribute to the metabolism of styrene, (2) CYP2C11/6, which probably corresponds to CYP2C11, is the major form of P450 responsible for the metabolism in untreated rat liver microsomes, and also in those treated with ethanol. Anti-CYP2El inhibited styrene oxidation more prominently in microsomes from styrene-treated rats than in those from control rats at a low substrate concentration. Although styrene treatment did not influence the total metabolism of styrene in liver microsomes at a high substrate concentration, inhibition of the metabolism by anti-CYP2C11/6 decreased with increasing styrene dose, whereas that by antiCYP2B1/2 increased, suggesting that styrene treatment increases CYP2B1/2 but decreases CYP2C11/ 6 in rat liver, and the major form of P450 which mediates styrene oxidation is CYP2B1/2 after the treatment. Only anti-CYP2B1/2, which probably corresponds to CYP2B1, inhibited styrene oxidation in lung microsomes from untreated and even styrene-treated rats. Thus, the major form of P450 responsible for the metabolism of styrene is different in each tissue.