PHENYLPROPANOLAMINE POTENTIATION OF ACETAMINOPHEN-INDUCED HEPATOTOXICITY - EVIDENCE FOR A GLUTATHIONE-DEPENDENT MECHANISM

Pretreatment of male ICR mice with the adrenergic agonist phenylpropanolamine (200 mg/kg, ip) resulted in a marked potentiation of hepatotoxicity produced by acetaminophen (400 mg/kg, ip). Enhanced liver necrosis with phenylpropanolamine pretreatment was evident both by measurement of serum aminotransferase activity and by histopathologic examination. Several lines of experimental evidence suggest this interaction is a result of the hepatic glutathione depression produced by α-adrenergic compounds, which adds to the glutathione depression caused by toxic, or nearly toxic, doses of acetaminophen. First, the potentiation of acetaminophen hepatotoxicity was time-dependent, being observed only when phenylpropanolamine was administered as a 3-hr pretreatment and not when given 1 hr before, with, or 3 hr after acetaminophen. The 3-hr interval between phenylpropanolamine and acetaminophen doses corresponds to the characteristic lag period required for α-adrenergic agents (including phenylpropanolamine) to produce significant and maximal effects on hepatic glutathione content. Second, dose response relationships for phenylpropanolamine and acetaminophen were such that increased toxicity was observed only when the interaction was sufficient to lower hepatic glutathione concentrations below a level regarded as critical in preventing acetaminophen-induced hepatotoxicity. Third, when animals were pretreated with two nonadrenergic depletors of hepatic glutathione, diethylmaleate (125 mg/kg, ip) or the glutathione synthesis inhibitor buthionine sulfoximine (222 mg/kg, ip), at doses producing glutathione depletion approximating that observed with the adrenergic agents, acetaminophen hepatotoxicity was potentiated to the same extent. From these observations it is postulated that a variety of adrenergic compounds known to deplete hepatic glutathione by a moderate 30-50% may potentiate the hepatotoxicity of acetaminophen and possibly other hepatotoxic compounds for which glutathione conjugation is an important detoxification pathway. © 1994 Academic Press. All rights reserved. © 1994 Academic Press. All rights reserved.