The binding of ouabain to Na + -K + -dependent ATPase treated with phospholipase

Stability of [3H]ouabain binding to the (Na+ + K+)-ATPase solubilized with C12E8

The (Na+ + K+)-ATPase from dog kidney and partially purified membranes from HK dog erythrocytes were labeled with [3H]ouabain, solubilized with C12E8 and analyzed by HPLC through a TSK-GEL G3000SW column in the presence of C12E8, Mg2+, HPO4(2-) and glycerol at 20-23 degrees C. The peaks of [3H]ouabain bound to the enzyme from dog kidney and HK dog erythrocyte membranes corresponded to each other with apparent molecular weights of 470 000-490 000. In addition, these bindings of [3H]ouabain to the (Na+ + K+)-ATPase were observed to be stable at 20-23 degrees C for at least 18 h after the solubilization.

Mode of inhibitory action of melittin on Na+-K+-ATPase activity of the rat synaptic membrane

The effects of melittin from bee venom, cardiotoxin from Formosan cobra venom, and ouabain on Na+-K+-ATPase activity of the synaptic membrane isolated from rat cerebral cortex were studied. Melittin was the most potent in inhibiting Na+-K+-ATPase activity. Mg2+-ATPase was less susceptible than Na+-K+-ATPase to the inhibitory action of toxins. High K+ (30 mM) reversed the inhibitory action of melittin on Na+-K+-ATPase but did not affect that of cardiotoxin. A comparison between the effects of ouabain and melittin was studied, using double-reciprocal plots of Na+-K+-ATPase activity against K+. It was shown that both were competitive with K+ for binding to the K+ site. Moreover, a median-effect plot revealed that ouabain and melittin antagonized each other when inhibiting Na+-K+-ATPase. Phosphatidylcholine (PC) was the only one of the phospholipids tested capable of protecting Na+-K+-ATPase from the inhibitory action of melittin but not that of ouabain. However, the inhibitory action of cardiotoxin on this enzyme was decreased by phosphatidylserine and sphingomyelin, in addition to PC. All of these findings suggest that the melittin polypeptide potently inhibits Na+-K+-ATPase, possibly by binding to the K+ site.

Role of sulfatide on phosphoenzyme formation and ouabain binding of the (Na+ + K+)ATPase

A microsomal fraction rich in (Na+ + K+)ATPase activity has been isolated from the outer medulla of pig kidney. The ability of this preparation to form phosphoenzyme on incubation with [gamma-32P]ATP and to bind [3H]ouabain was studied when its sulfatide was hydrolyzed by arylsulfatase treatment. The K+-dependent hydrolysis of the Na+-dependent phosphorylated intermediate as well as the ouabain binding were inactivated in direct relation to the breakdown of sulfatide. Both characteristics of the (Na+ + K+)ATPase preparation, lost by arylsulfatase treatment, were partially restored by the sole addition of sulfatide. These experiments indicate that sulfatide may play a role in sodium ion transport either in the conformational transition of the K+-insensitive phosphointermediate, E1P, to the K+-sensitive intermediate, E2P, or in the configuration of the high-affinity binding site for K+ of the E2P form. In addition, this glycolipid may have a specific role in the proteolipidic subunit that binds ouabain.

Variation in sensitivity of the cardiac glycoside receptor characteristics of (Na+ + K+)-ATPase to lipolysis and temperature

1. The rate of binding of [3H]ouabain to untreated membrane preparations of [Na+ +K+]-ATPase is a timperature--dependent process displaying a thermal transition close to 25degreesC. The apparent energies of activation which can be calculated above and below this transition are similar to, but not identical with, those previously reported for activation of the enzyme by cations. 2. Treatment of the enzyme preparation with detergents or lipolysis with phospholipase A eliminates the thermal transition resulting in linear Arrhenius plots. 3. The number of sites available for [3H]ouabain binding is not temperature dependent as the amount of [3H]ouabain bound at equillbrium is not changed between 10 and 37 degrees C. 4. Treatment of the enzyme with phospholipase A results in time-dependent changes in the number of binding sites for [3H]ouabain at equilibrium. 5. Treatment of the membrane enzyme preparations with detergents reveals additional [3H]ouabain binding sites which are extremely sensitive to lipolysis with phospholipase A. 6. There are a number of [3H]ouabain binding sites which remain resistant to lipolysis by phospholipase A in either untreated or detergent-treated membrane preparations. 7. It is suggested that [3H]ouabain binding sites exist in the membrane in at least two different environments, one of which is resistant the other sensitive to attack by phopholipase A.

The (Na++K+) activated enzyme system and its relationship to transport of sodium and potassium

It seems to be the membrane bound (Na++K+)-activated enzyme system which transforms the energy from a hydrolysis of ATP into a vectorial movement of sodium out and potassium into the cell against electrochemical gradients, i.e. this systems seems to be the transport system for sodium and potassium (see, for example, review by Skou, 1972; Hokin & Dahl, 1972).

Isolation and characterization of the components of the sodium pump

A satisfactory understanding of the functions of the sodium pump, the system responsible for the active transport of sodium and potassium, require the isolation and characterization of its protein and lipid components which are integrated in the structure of the cell membrane. The enzyme system (Na++ K+)-ATPase, is located in membrane fragments and behaves in the test tube like the transport system in the intact cell membrane (Skou,1957) Purified preparations of this enzyme will contain some, if not all, of the components of the sodium pump.

Reconstitution of the sodium pump from protein and phosphatidylserine: features of ouabain binding

1. A study has been made of ATP splitting and ouabain binding to the sodium pump reconstituted from protein and phosphatidylserine.2. Ouabain was bound to protein alone, but when phosphatidylserine was added, binding was increased threefold. The stimulation resembled the course of activation of sodium-dependent ATPase activity.3. EGTA partly simulated the activation of ATPase by phosphatidylserine but did not enhance binding.4. The dissociation constant for the enzyme-ouabain complex was 3.5 x 10(-8)M. The turnover number (2,000 molecules of ATP per minute) and the number of receptor sites (3.8 x 10(13) per mg protein) were calculated.5. The results provide further evidence of the involvement of phosphatidylserine in the action of the sodium pump.