Reinstatement of the ATP high energy paradigm.

The paradigm that the hydrolysis of ATP releases high Gibbs energy able to perform work has increasingly been questioned over the last two decades. Results from theoretical and experimental studies have been interpreted to indicate that the synthesis of ATP from ADP and P(i) does not require energy supply and that binding of ATP per se can transmit utilizable energy to an enzyme. As has recently been concluded, all this has led to a change of the ATP high energy paradigm in bioenergetics.

Modeling of the three-dimensional structure of the digitalis intercalating matrix in Na+/K(+)-ATPase protodimer.

Based on the knowledge that the digitalis receptor site in Na+/K(+)-ATPase is the interface between two interacting alpha-subunits of the protodimer (alpha beta)2, the present review makes an approach towards modeling the three-dimensional structure of the digitalis intercalating matrix by exploiting the information on: the primary structure and predicted membrane topology of the catalytic alpha-subunit; the determinants of the secondary, tertiary and quaternary structure of the membrane-spanning protein domains; the impact of mutational amino acid substitutions on the affinity of digitalis compounds, and the structural characteristics in potent representatives. The designed model proves its validity by allowing quantitative interpretations of the contributions of distinct amino acid side chains to the special bondings of the three structural elements of digitalis compounds.

Potential suitability of Na+/K(+)-transporting ATPase in pre-screens for anti-cancer agents.

Twenty-five compounds [digitalis (generic name for cardenolides, bufadienolides and their glycosides) representatives and derivatives, various steroids as well as some customary carcinostatics] have been compared in terms of their potency to suppress the proliferation of Ehrlich mouse ascites carcinoma (EMAC) cells and to inhibit the activity of Na/K-ATPase from EMAC cells and from human cardiac muscle. The inhibitor susceptibilities of the Na/K-ATPase isoforms of EMAC and cardiac muscle are very different, in favour of the cardiac muscle with the digitalis-like acting steroids, whereas they are quite similar with the digitalis-unlike acting compounds. Whereas the K0.