Ouabain binding to (Na+ plus K+)-ATPase. Effects of nucleotide analogues and ethacrynic acid

[3H]Ouabain binding and Na+, K+-ATPase in resealed human red cell ghosts

The interaction of the cardiac glycoside [3H]ouabain with the Na+, K+ pump of resealed human erythrocyte ghosts was investigated. Binding of [3H]ouabain to high intracellular Na+ ghosts was studied in high extracellular Na+ media, a condition determined to produce maximal ouabain binding rates. Simultaneous examination of both the number of ouabain molecules bound per ghost and the corresponding inhibition of the Na+, K+-ATPase revealed that one molecule of [3H]ouabain inhibited one Na+, K+-ATPase complex. Intracellular magnesium or magnesium plus inorganic phosphate produced the lowest ouabain binding rate. Support of ouabain binding by adenosine diphosphate (ADP) was negligible, provided synthesis of adenosine triphosphate (ATP) through the residual adenylate kinase activity was prevented by the adenylate kinase inhibitor Ap5A. Uridine 5'-triphosphate (UTP) alone did not support ouabain binding after inhibition of the endogenous nucleoside diphosphokinase by trypan blue and depletion of residual ATP by the incorporation of hexokinase and glucose. ATP acting solely at the high-affinity binding site of the Na+, K+ pump (Km approximately 1 microM) promoted maximal [3H]ouabain binding rates. Failure of 5'-adenylyl-beta-gamma-imidophosphate (AMP-PNP) to stimulate significantly the rate of ouabain binding suggests that phosphorylation of the pump was required to expose the ouabain receptor.

The effect of sodium on inorganic phosphate- and p-nitrophenyl phosphate-facilitated ouabain binding to (Na+ + K+)-activated ATPase

The effect of the hydrolysis product Pi and the artificial substrate p-nitrophenyl phosphate (p-nitrophenyl-P) on ouabain binding to (Na+ + K+)-activated ATPase was investigated. The hypothesis that (Mg2+ + p-nitrophenyl-P)-supported ouabain binding might be due to Pi release and thus (Mg2+ + Pi)-supported could not be confirmed. The enzyme . ouabain complexes obtained with different substrates were characterized according to their dissociation rates after removal of the ligands facilitating binding. The character of the enzyme . ouabain complex is determined primarily by the monovalent ion present during ouabain binding, but, qualitatively at least, it is immaterial whether binding was obtained with p-nitrophenyl phosphate or Pi. The presence or absence of Na+ during binding has a special influence upon the character of the enzyme . ouabian complex. Without Na+ and in the presence of Tris ions the complex obtained with (Mg2+ + Pi) and that obtained with (Mg2+ + p-nitrophenyl-P) behaved in a nearly identical manner, both exhibiting a slow decay. High Na+ concentration diminished the level of Pi-supported ouabain binding, having almost no effect on p-nitrophenyl phosphate-supported binding. Both enzyme . ouabain complexes, however, now resembled the form obtained with (Na+ + ATP), as judged from their dissociation rates and the K+ sensitivity of their decay. The complexes obtained at a high Na+ concentration underwent a very fast decay which could be slowed considerably after adding a low concentration of K+ to the resuspension medium. The most stable enzyme . ouabain complex was obtained in the presence of Tris ions only, irrespective of whether p-nitrophenyl phosphate of Pi facilitated complex formation. The presence of K+ gave rise to a complex whose dissociation rate was intermediate between those of the complexes obtained in the presence of Tris and a high Na+ concentration. It is proposed that the different ouabain dissociation rates reflect different reactive states of the enzyme. The resemblance between the observations obtained in phosphorylation and ouabain binding experiments is pointed out.

Membrane (Na+ + K+)-ATPase of canine brain, heart and kidney. Tissue-dependent differences in kinetic properties and the influence of purification procedures

Effects of commonly used purification procedures on the yield and specific activity of (Na+ + K+)-ATPase (Mg2+-dependent, Na+ + K+-activated ATP phosphohydrolase, EC 3.6.1.3), the turnover number of the enzyme, and the kinetic parameters for the ATP-dependent ouabain-enzyme interaction were compared in canine brain, heart and kidney. Kinetic parameters were estimated using a graphical analysis of non-steady state kinetics. The protein recovery and the degree of increase in specific activity of (Na+ + K+)-ATPase and the ratio between (Na+ + K+)-ATPase and Mg2+-ATPase activities during the successive treatments with deoxycholate, sodium iodide and glycerol were dependent on the source of the enzyme. A method which yields highly active (Na+ + K+)-ATPase preparations from the cardiac tissue was not suitable for obtaining highly active enzyme preparations from other tissues. Apparent turnover numbers of the brain (Na+ + K+)-ATPase preparations were not significantly affected by the sodium iodide treatment, but markedly decreased by deoxycholate or glycerol treatments. Similar glycerol treatment, however, failed to affect the apparent turnover number of cardiac enzymes preparations. Cerebral and cardiac enzyme preparations obtained by deoxycholate, sodium iodide and glycerol treatments had lower affinity for ouabain than renal enzyme preparations, primarily due to higher dissociation rate constants for the ouabain.enzyme complex. This tissue-dependent difference in ouabain sensitivity seems to be an artifact of the purification procedure, since less purified cerebral or cardiac preparations had lower dissociation rate constants. Changes in apparent association rate constants were minimal during the purfication procedure. These results indicate that the presentyl used purification procedures may alter the properties of membrane (Na+ + K+)-ATPase and affect the interaction between cardiac glycosides and the enzyme. The effect of a given treatment depends on the source of the enzyme. For the in vitro studies involving purified (Na+ + K+)-ATPase preparations, the influence of the methods used to obtain the enzyme preparation should be carefully evaluated.

Effect of ATP analogs of DNA synthesis in isolated nuclei

Optimal synthesis of DNA in Ehrlich ascites cell nuclei is shown to be dependent upon the presence of both ATP and ADP. ATP can be replaced only by dATP. An ATP regenerating system is less effective than ATP alone or ATP in combination with ADP. ATP does not stimulate DNA synthesis primarily by maintenance of deoxyribonucleotide triphosphate levels. When the inhibition of DNA synthesis by high ATP levels is taken into account, the ATP analogs adenosine 5'-(alpha,beta-methylene)triphosphate, adenosine 5'-(beta, gamma-methylene)-triphosphate, and adenosine 5'-(beta, gamma-imino)triphosphate can neither substitute for ATP nor inhibit the ATP stimulation of DNA synthesis. Adenosine 5'-(3-thio)triphosphate, however, is a competitive inhibitor of DNA synthesis.

The migrating thermodynamic quantum hypothesis for cytoplasmic streaming, sodium pumping and other cell biological phenomena, deduced from biofunctional considerations of the ultrastructure of brush border microvilli

An attempt is made to reconcile experimental data dealing with, inter alia, cytoplasmic streaming in Characean algae, contraction in actomyosin systems. Na+- and -K+-simtulated ATPase activity and the ultrastructure of brush border microvilli. It is postulated that myosin molecules transfer energy from ATP to an actin-containing filament and that a high energy conformation is subsequently propagated along the filament. At regularly spaced intervals corresponding to the length of an actin-tropomyosin subunit, the propagation of high energy involves rejection of a pressure pulse in the direction of cytoplasmic streaming. Proteins in solution capable of storing the thermodynamic energy represented by the pressure pulse will either migrate in the opposite direction or conserve the quantized cytoplasmic flow generated by the actin-containing filaments. At sites where actin filaments are attached to the plasma membrane the high energy is propagated in another direction leading to expulsion of sodium ions and neutralization of the vectorial pressure pulse.