Pharmacological properties of voltage-dependent calcium channels in functional microvessels isolated from rat brain

Abstract

Voltage-operated calcium channels were studied in rat intracerebral microvessels. The contractile reactivity to KCI-depolarization was assessed by the measurement of internal diameter of superfused microvessels. Dihydropyridine receptor sites associated with calcium channels were identified and characterized using ³H(+)PN 200-110 [isopropyl-4-(2,1,3-benzodiazol-4-yl)-1,4-dihydro-2,6-dimethyl-5-methoxycarbonyl-pyridine-3-carboxylate]. Depolarization induced by high-KCI solution produced a marked reduction of the internal diameter of cerebral microvessels which was associated with the appearance of rhythmic activity. The vessel contraction was reversible and abolished by nimodipine. Binding studies with ³H(+)PN 200-110 revealed the existence of a single class of specific, stereoselective and voltage-dependent binding sites which bound (+)PN 200-110 with a K _D of 88 ± 6.6 pmol l⁻¹ at 37°C in microvessels incubated in NaCl medium. When microvessels were incubated in KCI-medium, the apparent K _D value was reduced to 35 ± 2 pmol l⁻¹. B _max was not significantly changed. The effect of KCI was not related to concomitant changes in the Na concentration. The potency of various dihydropyridine derivatives in inhibiting ³H(+)PN 200-110 binding was in agreement with their pharmacological potency in smooth muscle preparations. The effect of PN 200-110 and of nimodipine was stereoselective. K _i values of PN 200-110 and of nimodipine were increased in depolarized preparations, while nifedipine's potency was unchanged. Verapamil was only a partial inhibitor of ³H(+)PN 200-110 binding. The effect of diltiazem was stereoselective: the (+)-cis isomer enhanced the binding and the (−)-cis isomer of diltiazem poorly inhibited the binding of PN 200-110. Results showed that isolated cerebral microvessels possess functional voltage-operated calcium channels, which contain potential-modulated receptors for dihydropyridine calcium entry blockers with characteristics similar to those described in other tissues.