Interaction of the Calcium Channel Activating ³H-Bay K 8644 and Inhibiting ³H-Verapamil with Specific Receptor Sites on Cultured Beating Myocardial Cells

Abstract

Binding properties of the calcium channel activating dihydropyridine (DHP), ³H-BAY K 8644, and the inhibiting ³H-verapamil were demonstrated in monolayer cultures of beating cardiac cells. ³H-BAY K 8644 specific binding was dependent on the presence of extracellular calcium, the affinity was modulated by Ca²⁺, but Hill coefficients remained unaffected. BAY K 8644 stimulated myocardial contractility in resting and beating myocytes. In contrast to ß-adrenoceptor agonists, however, cellular levels of cyclic AMP and cyclic GMP in cultured myocytes remained unchanged by the compound. Dihydropyridine derivatives of both the calcium channel activating BAY K 8644 as well as the Ca²⁺ entry blocking DHPs of the nifedipine or nimodipine type yielded very low affinity to other receptors measured in brain and heart membranes. ³H-BAY K 8644 binding sites proved to be highly specific for various potently displacing DHP derivatives and discriminated between optical isomers (stereoselectivity) with inhibition constants (K_i) in the nanomolar range. The heterogeneous shapes of the competition curves also imply interactions of these compounds with different (sub-)sites of the DHP receptor that represents one locus of interaction in regulating transmembranal Ca²⁺ currents. The other specific site of action for the potent diphenylalkylamines, clearly different to the DHP receptor was characterized with ³H-verapamil. The equilibrium dissociation constant, K_d in cultured myocytes ranged between 16-25 nM, and binding capacity, B_max amounted to about 1.85 pmol/mg of protein. The different mode of competitions indicates the involvement of more than one ³H-verapamil binding site. The interrelation of the structurally heterogeneous channel modulators with the differently radiolabelled receptor (sub-)sites located in or near by the calcium channel may represent new approaches in investigating the nature of action of these potent compounds.