Comparative studies of some semisynthetic K-strophanthins with natural cardiac glycosides

Influence of extracellular K+ concentration on the time-course of Na+/K+-ATPase inhibition by cardiac glycosides with fast and low binding kinetics

The magnitude of the K+ antagonism of cardiac glycoside binding to Na+/K+-ATPase prepared from porcine heart, was estimated from the enzyme activities determined in the presence of different concentrations of K+ ([K+]), ouabain, and alpha-methyl-digitoxigenin-glucoside, the latter showing a 30 fold greater dissociation rate than ouabain. An increase of [K+] (3-20 mmol/l) prolonged the half-lives of Na+/K+-ATPase inhibition and caused a rightward shift of the cardiac glycoside's dose-response curves by the same factor, almost maximal (4 fold) at 14 mmol/l K+. These data could be verified from the cardiac glycoside-elevated intravesicular Na+ concentrations of rat brain vesicles. These concentrations declined rapidly in brain vesicles treated with alpha-methyl-digitoxigenin-glucoside but not with ouabain after K+ was increased from 3.5 to 14 mM. The results suggest that the magnitude of the K+ antagonism under physiological conditions is only limited by the lifespan of the cardiac glycoside-binding E2P enzyme conformation reduced by K+.

Two functional Na+/K(+)-ATPase isoforms in the left ventricle of guinea pig heart

Guinea pig left ventricular muscle contains two distinct molecular forms of the Na+/K(+)-ATPase catalytic alpha subunit. Sarcolemmal vesicles highly enriched in Na+/K(+)-ATPase were isolated by a new procedure that yielded specific activities of 60-100 mumol Pi.h-1.mg-1. SDS/PAGE of isolated sarcolemma after reduction and alkylation of the sulfhydryl groups and identification on immunoblots with specific anti-(alpha subunit) antibodies indicated the presence of two major polypeptides of 100 kDa and 103 kDa, respectively. The two alpha subunits were functional: the dose/response curves of Na+/K(+)-ATPase activity with ouabain, dihydroouabain and digitoxigenin were biphasic, revealing the presence of high-affinity [concentration of drug causing 50% inhibition (IC50) = 10 nM] and low-affinity (IC50 = 2 microM) forms with proportional contributions of 55% and 45%, respectively. The involvement of the high-affinity form in the positive inotropic effect of digitalis and of the low-affinity sites in both inotropy and toxicity are consistent with the literature data on rodents.