Dwight S. Fullerton

Cardiac glycosides: 5. Stereoselective syntheses of digitoxigenin α-D, β-D, α-L, and β-L-glucosides

Abstract As part of a continuing study of cardiac g1ycos1des, 1,2 stereoselective syntheses of the four possible glucosides of digitoxigenin were developed via the thermodynamically produced tetra-O-benzyl-D- and L-glucosyl α-trichloroacetaimidates 2 α and 11 α, and the kinetically produced β-trichloroacetaimidates 2 β and 11 β. A 58%:19% isolated yield ratio of α-D and β-D benzyl protected glycosides 6 and 3 could be obtained in 30 minutes reaction at −10°. Halide ion catalysis with a 2:1 excess of tetra-O-benzyl-α-D-glucopyranosyl bromide for 14 days in methylene chloride at room temperature gave a 39%:11% ratio of 6 and 3 , along with 43% of recovered digitoxigenin. Debenzylation of the D-glucosides required milder conditions (20% Pd/C, atmospheric pressure, 45 min-1 hr) than the L-glucosides (40% Pd/C, 2 hr) but yields were typically 80% for both groups.

Digitalis receptor sugar binding site characteristics: A model based upon studies of Na+, K+-ATPase preparations with differing digitalis sensitivities

The structure-activity relationships of the genin moieties of digitalis glycosides are commonly elucidated by determining the inhibitory potency of a variety of genins toward the plasma membrane Na+, K+-ATPase; qualitatively these relationships appear to be fairly independent of the specific Na+, K+-ATPase preparation utilized for the analysis. To determine whether this is the case with regard to the sugar moieties of glycosides, the inhibitory effects of 12 monoglycosides of digitoxigenin toward four Na+, K+-ATPase preparations of different origin were measured. It was found that while recognition of the major structural determinants of sugar activity appeared to be independent of enzyme source, recognition of the minor structural determinants of activity showed some source dependence. It was also observed that the intrinsic sensitivity to sugar potentiation may be source dependent and unrelated to intrinsic sensitivity to inhibition by digitoxigenin. These observations are compatible with a model of the Na+, K+-ATPase sugar binding site(s) in which intrinsic sensitivity to sugar attachment as well as recognition characteristics (for sugar structural features) both determine the extent to which a sugar moiety may contribute to the activity of monoglycosides. Further, in these studies one of the Na+, K+-ATPase preparations employed was obtained from rat brain, a tissue known to contain a mixture of ouabain sensitive and insensitive isoforms. We have observed that the rigorous purification techniques employed appear to have selectively removed from or denatured the less ouabain sensitive al isoform found in this enzyme preparation.

Cardenolide analogues. 3. A fast thin layer chromatographic separation of cardenolide diastereomers.

Cardenolide diasteromeric mixtures may be analytically separated on 2.5 x 6.5 cm x 0.25 mm pre-coated silical gel 60 F-250 (EM) tlc plates (cut from 20 x 20 cm plates). Three successive developments in mixtures of CH2Cl2-EtOAc-MeOH achieve complete separation of diastereomers in less than 15 minutes, and 2--6 micrograms of sample is sufficient. This procedure facilitated the separation of several diastereomeric mixtures, including 20(R) and 20(S)-20,22-dihydrocardenolides. A single development produces separations sufficient for separating starting materials and products of common cardenolide types of reactions.

The inotropic activity of digitalis genins is dependent upon C(17) side-group carbonyl oxygen position.

The inotropic potencies of four digitalis genins were studied utilizing cat left atrial strips. The genin concentration required to induce a 50% increase of isometric tension (T50) was found to closely correlate with the degree of displacement (D) of the C(17) side-group carbonyl oxygen from the position of that atom in digitoxigenin. The line of regression was: log T50 = 0.54D - 6.85, r2 = 0.98, P less than 0.008. These observations were related to recently reported cat ventricular Na+, K+ -ATPase inhibitory potencies of the same genins [expressed as 50% inhibitory (I50) concentrations]. I50 correlated strongly with T50: log I50 = 0.78 log T50 - 1.68, r2 = 0.99, P less than 0.003. Thus, the activity of digitalis genins towards their receptor in intact cardiac tissue is closely related to genin carbonyl oxygen position as well as to Na+, K+ -ATPase inhibitory activity. These results further support our earlier conclusions, based upon isolated Na+, K+ -ATPase studies, that the digitalis genin C(17) side-group carbonyl oxygen position versus activity relationship is biologically relevant and may prove to be a useful unifying structural model in the further elucidation of the mechanism of digitalis-receptor interactions.

Cardiac glycosides: 2. Synthesis of glucose and galactose analogs.

Five cardioactive steroid genins 1a to 5a of widely varying C17 beta-side groups were converted by modified Koenigs-Knorr reactions into the corresponding beta-D-glucosides 1c to 5c and beta-D-galactosides 1e to 5e. The genins included digitoxigenin (3 beta, 14-dihydroxy-5 beta, 14 beta-card-20-(22)-enolide, 1a); (20R)-20, 22-dihydrodigitoxigenin (3 beta, 14-dihydroxy-5 beta, 14 beta, 20R-cardanolde, 2a); 3 beta, 14-dihydroxy-22-methylene-5 beta, 14 beta, 20S-cardanolide (3a); methyl 3 beta, 14-dihydroxy-5 beta, 14 beta-pregn-20(E)-ene-21-carboxylate (4a); and methyl 3 beta, 14-dihydroxy-21-methylene-5 beta, 14 beta-pregnane-21-carboxylate (5a).