Inhibition of myocardial Ca2+ channels by three dihydropyridines with different structural features: potential‐dependent blockade by Ro 18–3981

Abstract

Inhibition of myocardial Ca2+ channels was investigated for three dihydropyridines with different structural features: Ro 18-3981, darodipine (PY 108-068) and nifedipine. Ro 18-3981 contains a sulphamoyl acetyl side-chain. In voltage-clamps experiments with isolated cardiac myocytes of guinea-pig, Ro 18-3981 caused a concentration-dependent inhibition of the Ca2+ current, which was influenced by the membrane holding potential. A markedly greater inhibition by Ro 18-3981 was observed when myocytes were depolarized (to +10 mV) from a holding potential (Vh) of -20 mV (IC50 = 2.3 nm) than at -50 mV (IC50 = 100 nM). The three dihydropyridines caused a concentration-dependent reduction in contractile force of isolated, electrically-stimulated left atria of the guinea-pig. Elevation of the extracellular K+ concentration from 5.9 to 24 mM resulted in a significant reduction in negative inotropic IC50 values for Ro 18-3981 (137 fold), darodipine (8 fold) and nifedipine (20 fold). The affinity of these drugs for the high-affinity (+)-[3H]-PN 200-110 binding site was determined in guinea-pig cardiac membranes. The KD value of Ro 18-3981 (1.0 nM) was similar to the IC50 value for blockade of ICa at a Vh of -20 mV (2.3 nM), i.e. at a level of near-maximal depolarization. Thus, structurally-different dihydropyridines exert potential-dependent inhibition of myocardial Ca2+ channel activity consistent with the modulated receptor hypothesis. These results demonstrate that blockade of myocardial excitation-contraction coupling by Ca2+ entry blockers is also potential-dependent.