Abstract

Treatment of rats with para-aminophenol (PAP) (300 mg/kg ip) produced decreases in renal nonprotein sulfhydryl (NPSH) content, oxygen consumption, and adenine nucleotide concentrations 2-4 hr following administration. In contrast, incubation of rat renal tubules with up to 1 mm PAP for 4 hr produced inconsistent changes in renal tubules. This discrepancy suggested that extrarenal metabolism of PAP may be involved in PAP bioactivation and nephrotoxicity. We designed the present studies to test the hypothesis that hepatic metabolism of PAP potentiates the effects of PAP on renal tubules. Incubation of renal tubules with 0.5 mm PAP and 10 mg protein from hepatic postmitochondrial supernatant (S9 fraction) in the absence of glutathione (GSH) for 4 hr did not alter renal oxygen consumption or adenine nucleotide metabolite concentrations. We observed no changes when we incubated tubules with 0.5 mm PAP and 1 mm GSH in the absence of hepatic S9 fraction. However, incubation of renal tubules with 0.5 mm PAP, 1 mm GSH, and 10 mg hepatic S9 protein for 4 hr significantly decreased renal oxygen consumption and adenosine triphosphate and total nucleotide concentrations. These data suggest that the effects of PAP in renal tubules may be potentiated by enzymatic metabolism of PAP, possibly involving oxidation and GSH conjugation. From experiments using hepatic microsomes or cytosol instead of S9 fraction, we found that changes were produced when we incubated tubules with PAP in the presence of hepatic microsomes, but not cytosol. These data suggest that hepatic microsomal metabolism of PAP may contribute to the production of changes in renal tubules in vitro. PAP-induced changes in renal proximal tubules were prevented when we included a beta-nicotinamide adenine dinucleotide phosphate (NADPH) generating system in the incubation medium. The protective effect of NADPH persisted when microsomes were inactivated by incubation with 1-aminobenzotriazole, a cytochrome P450 inhibitor. These data suggest that cytochrome P450-dependent oxidation is not involved in the production or prevention of PAP-induced changes in renal tubules. The enzyme(s) responsible for PAP bioactivation and the mechanism(s) by which NADPH protects renal tubules from PAP-induced decrements in oxygen consumption and adenine nucleotide concentrations are currently unclear.

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