Effects of cytochrome P450 inhibitors on potassium currents and mechanical activity in rat portal vein

Abstract

1 The effects of the cytochrome P450 inhibitors, proadifen, clotrimazole and 17-octadecynoic acid (17-ODYA) on K-currents in freshly-isolated single cells derived from rat portal vein and on mechanical activity in whole veins were studied. 2 When cells were stepped from −90 mV to a series of test potentials (from −80 to +50 mV), a delayed rectifier current (I_K(V)) and an A-type current (I_K(A)) could be identified. Proadifen (10 μm), clotrimazole (30 μm) and 17-ODYA (5 μm) each inhibited I_K(A) but had little effect on I_K(A). 3 When cells were held at −10 mV to inactivate the time-dependent K-currents, I_K(V) and I_K(A), levcromakalim (3 μm) induced a time-independent outward K-current (I_K(ATP)) which was totally inhibited by clotrimazole (30 μm) and almost fully inhibited by proadifen (10 μm). 17-ODYA (5 μm) had no effect on I_K(ATP) and exerted only a minor inhibitory action on this current at 20 μm. 4 17-ODYA (5 μm) potentiated current flow through the large conductance, Ca-sensitive K-channel (BK_Ca). In contrast, proadifen (10 μm) had no effect on I_BK(Ca) whereas clotrimazole (30 μm) exerted a small but significant inhibitory action. 5 Proadifen (10 μm) and clotrimazole (30 μm) each inhibited the magnitude but increased the frequency of spontaneous contractions in whole portal veins. 17-ODYA (5 μm) had no effect on spontaneous contractions but these were inhibited when the concentration of 17-ODYA was increased to 50 μm. 6 The spasmolytic effect of levcromakalim on spontaneous contractions was antagonized by proadifen (10–30 μm) in a concentration-dependent manner but 17-ODYA (up to 50 μm) was without effect. 7 These results in portal vein show that cytochrome P450 inhibitors exert profound effects on a variety of K-channel subtypes. This suggests that enzymes dependent on this cofactor may be important regulators of K-channel activity in smooth muscle. The relevance of these findings for the identification of the pathway involved in the synthesis of the endothelium-derived hyperpolarizing factor is discussed.