James J Cali, Dongping Ma, Katarina Bohm, Dieter H Klaubert
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引用次数: 0
Abstract
Background: Adverse drug-drug interactions (DDI) may occur when one drug accelerates or slows a second drug's metabolism by, respectively, inducing or inhibiting a cytochrome P450 (CYP) that metabolizes that second drug. We developed an in vivo method employing urinalysis to complement in vitro CYP induction and inhibition measurements widely used to predict DDIs.
Research design and methods: Focusing on Cyp3a enzymes, the major mammalian drug metabolizers, we applied luciferin-IPA, a selective Cyp3a probe substrate to mice after Cyp3a inducers and inhibitor treatments. Cyp3a converts the probe to a metabolite that is eliminated in urine and drives light output when mixed with a luciferase reaction mixture. We hypothesized that urine from an initial renal elimination phase would, respectively, drive elevated or reduced light output as a reflection of Cyp3a induction or inhibition.
Results: Luciferase mixed with urine from Cyp3a-induced mice showed enhanced signals, while a Cyp3a inhibitor diminished induced and basal signals versus vehicle.
Conclusions: A Cyp3a-selective luminogenic probe substrate enables rapid urinalysis-based testing for detecting Cyp3a induction and inhibition and predicting Cyp3a-dependent DDIs. The study serves as a proof of concept for using caged luciferins for in vivo enzyme activity tests with a readily accessible sample type.
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