Modulation of cyclophosphamide-based cytochrome P450 gene therapy using liver P450 inhibitors.

The sensitivity of tumors to cyclophosphamide (CPA) and other anticancer prodrugs can be substantially enhanced by transduction of tumors with a prodrug-activating mammalian cytochrome P450 (CYP) enzyme in combination with the flavoenzyme P450 reductase. This gene therapy strategy provides for intratumoral prodrug activation, but is also associated with a high level of hepatic prodrug activation, which reduces the extent of intratumoral prodrug activation and contributes to systemic drug toxicity. To address this issue, five P450 inhibitors were tested for their ability to block liver CYP2C-catalyzed CPA activation selectively, i.e., without inhibiting the corresponding intratumoral activation of CPA catalyzed by a transduced CYP2B enzyme. In vitro studies revealed that the P450 inhibitors 1-aminobenzotriazole and DDEP were preferentially inhibitory toward CYP2C-dependent liver microsomal CPA activation, whereas the P450 inhibitor SKF-525A inhibited CYP2C- and CYP2B-dependent CPA activation without P450 form selectivity. By contrast, the P450 inhibitors chloramphenicol and metyrapone preferentially inhibited CYP2B-dependent CPA activation. Rat pharmacokinetic studies confirmed the inhibitory action of these compounds in vivo, with up to a 4-fold decrease in C(max) and a 7-fold increase in apparent half-life of the activated CPA metabolite, 4-hydroxy-CPA, seen in the case of 1-aminobenzotriazole. Although the rate of hepatic CPA activation could thus be decreased substantially by P450 inhibitor treatment, the net extent of hepatic CPA activation was only modestly decreased, as judged by plasma area-under-the-curve values for 4-hydroxy-CPA. Moreover, P450 inhibitor treatment did not decrease CPA's host toxicity and did not enhance the tumor growth delay response to CPA in rats bearing CYP2B1-transduced gliosarcomas. These findings are discussed in the context of P450-based gene therapy strategies and ongoing efforts to enhance anticancer drug activity by increasing the exposure of P450-expressing tumors to the P450-activated prodrug CPA.