The purpose of the present study was to determine the lead structure in cardiac glycosides at the receptor level, i.e. the minimal structural requirement for specific and powerful receptor recognition. Accordingly 73 digitalis-like acting steroids were characterized as to the concentration effecting half-maximum inhibition of Na,K-ATPase from human cardiac muscle under standardized turnover conditions. Since the Ki value equaled the apparent KD value, K'D was expressed in terms of the apparent standard Gibbs energy change delta G degrees' of steroid interaction with Na,K-ATPase. This allowed the use of the extrathermodynamic approach as a rational way of correlating in a quantitative manner, the potency and structure of the various steroidal compounds. The results of the present analysis taken in conjunction with relevant findings reported in the literature, favour the following conclusions. Cassaine, canrenone, prednisolone- and progesterone-3,20-bisguanylhydrazone, and chlormadinol acetate are compounds that are not congeneric with digitalis. The butenolide ring of cardenolides or the analogous side-chains at C17 beta of 5 beta, 14 beta-androstane-3 beta, 14-diol are not pharmacophoric substructures, but merely amplifiers of the interaction energy of the steroid lead. All modifications of the structure, geometry and spatial relationship between the steroid nucleus and butenolide side chain of digitoxigenin all at once weaken the close fit interaction with the steroid and butenolide binding subsites of the enzyme in such way that the cardenolide derivatives interact with the receptor binding site area in whatever orientation that will minimize the Gibbs energy of the steroid-receptor-solvent system. The "butenolide carbonyl oxygen distance model" (Ahmed et al. 1983) for the interpretation of the differences in potency of the cardenolide derivatives describes the change in interaction energy through structural modification as a function of the entire molecule. 5 beta, 14 beta-androstane-3 beta, 14-diol, the steroid nucleus of cardiac glycosides of the digitalis type, is the minimum structure for specific receptor recognition and the key structure for inducing protein conformational change and thus Na,K-ATPase inhibition. It is also the structural requirement for maximum contributions of the butenolide substituent at C17 beta and the sugar substituent at C3 beta-OH to the overall interaction energy, i.e. this steroid nucleus is the lead structure.(ABSTRACT TRUNCATED AT 400 WORDS)
A novel highly efficient and general route to various 3- and 5-substituted 2-alkoxystyrenes, required for the preparation of Hoveyda-Grubbs catalysts, is described.
The biological activity of bicyclic beta-lactam antibiotics depends strongly on the absolute configuration of the bridgehead carbon atom. Frelek and co-workers proposed an empirical helicity rule relating the configuration of the bridgehead carbon atom to the sign of the 220 nm band in the electronic circular dichroism (CD) spectrum of beta-lactams. Here we use synthetic organic chemistry, CD spectroscopy, and time-dependent density functional theory (TDDFT) to investigate the validity of this structure-property relationship for eight model compounds. For conformationally flexible beta-lactams, substantial thermal effects are found which must be included in calculations. To this end, we combine TDDFT calculations of CD with full quantum-mechanical Born-Oppenheimer molecular dynamics (MD) simulations for the first time. The CD spectra are sampled with ground-state density functional trajectories of up to 60 ps. The MD simulations show a surprisingly high sensitivity of the CD to the molecular conformation. On the other hand, the relation between CD and thermally averaged structural parameters is much less complex. While the helicity rule does not seem to hold for individual conformers, it is confirmed by the calculations for seven out of eight systems studied if thermally averaged CD spectra and structures are considered. Since thermal effects on CD can be larger than typical inherent inaccuracies of TDDFT, our results emphasize the need for a systematic treatment of conformational dynamics in CD calculations even for moderately flexible systems. Temperature-dependent CD measurements are very useful for this purpose. Our results also suggest that CD spectroscopy may be used as a sensitive probe of conformational dynamics if combined with electronic structure calculations.
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