Studies on (K+ + H+)-ATPase III. Binding of adenylyl imidodiphosphate

Kinetics of transient pump currents generated by the (H,K)-ATPase after an ATP concentration jump

(H,K)-ATPase containing membranes from hog stomach were attached to black lipid membranes. Currents induced by an ATP concentration jump were recorded and analyzed. A sum of three exponentials (tau 1(-1) approximately 400 sec-1, tau 2(-1) approximately 100 sec-1, tau 3(-1) approximately 10 sec-1; T = 300 K, pH 6, MgCl2 3 mM, no K+) was fitted to the transient signal. The dependence of the resulting time constants and the peak current on electrolyte composition, ATP conversion rate, temperature, and membrane conductivity was recorded. The results are consistent with a reaction scheme similar to that proposed by Albers and Post for the NaK-ATPase. Based on this model the following assignments were made: tau 2 corresponds to ATP binding and exchange with caged ATP. tau 1 describes the phosphorylation reaction E1 x ATP-->E1P. The third, slowest time constant tau 3 is tentatively assigned to the E1P-->E2P transition. This is the first electrogenic step and is accelerated at high pH and by ATP via a low affinity binding site. The second electrogenic step is the transition from E2K to E1H. The E2K<==>E1H equilibrium is influenced by potassium with an apparent K0.5 of 3 mM and by the pH. Low pH and low potassium concentration stabilize the E1 conformation.

The basal Mg2(+)-dependent ATPase activity is not part of the (H(+)+K+)-transporting ATPase reaction cycle

Purified gastric (H(+)+K+)-transporting ATPase [(H(+)+K+)-ATPase] from the parietal cells always contains a certain amount of basal Mg2(+)-dependent ATPase (Mg2(+)-ATPase) activity. lin-Benzo-ATP (the prefix lin refers to the linear disposition of the pyrimidine, benzene and imidazole rings in the 'stretched-out' version of the adenine nucleus), an ATP analogue with a benzene ring formally inserted between the two rings composing the adenosine moiety, is an interesting substrate not only because of its fluorescent behaviour, but also because of its geometric properties. lin-Benzo-ATP was used in the present study to elucidate the possible role of the basal Mg2(+)-ATPase activity in the gastric (H(+)+K+)-ATPase preparation. With lin-benzo-ATP the enzyme can be phosphorylated such that a conventional phosphoenzyme intermediate is formed. The rate of the phosphorylation reaction, however, is so low that this reaction with subsequent dephosphorylation cannot account for the much higher rate of hydrolysis of lin-benzo-ATP by the enzyme. This apparent kinetic discrepancy indicates that lin-benzo-ATP is not a substrate for the (H(+)+K+)-ATPase reaction cycle. This idea was further supported by the finding that lin-benzo-ATP was unable to catalyse H+ uptake by gastric-mucosa vesicles. The breakdown of lin-benzo-ATP by the (H(+)+K+)-ATPase preparation must be due to a hydrolytic activity which is not involved in the ion-transporting reaction cycle of the (H(+)+K+)-ATPase itself. Comparison of the basal Mg2(+)-ATPase activity (with ATP as substrate) with the hydrolytic activity of (H(+)+K+)-ATPase using lin-benzo-ATP as substrate and the effect of the inhibitors omeprazole and SCH 28080 support the notion that lin-benzo-ATP is not hydrolysed by the (H(+)+K+)-ATPase, but by the basal Mg2(+)-ATPase, and that the activity of the latter enzyme is not involved in the (H(+)+K+)-transporting reaction cycle (according to the Albers-Post formalism) of (H(+)+K+)-ATPase.

Studies on (K+ + H+)-ATPase. VI. Determination on the molecular size by radiation inactivation analysis

(1) A (K+ + H+)-ATPase containing membrane fraction, isolated from pig gastric mucosa, has been further purified by means of zonal electrophoresis, leading to a 20% increase in specific activity and an increase in ratio of (K+ + H+)-ATPase to basal Mg2+-ATPase activity from 9 to 20. (2) The target size of (Na+ + K+)-ATPase, determined by radiation inactivation analysis, is 332 kDa, in excellent agreement with the earlier value of 327 kDa obtained from the subunit composition and subunit molecular weights. This shows that the Kepner-Macey factor of 6.4 X 10(11) is valid for membrane-bound ATPases. (3) The target size of (K+ + H+)-ATPase is 444 kDa, which, in connection with a subunit molecular weight of 110000, suggests a tetrameric assembly of the native enzyme. The ouabain-insensitive K+-stimulated p-nitrophenylphosphatase activity has a target size of 295 kDa. (4) In the presence of added Mg2+ the target sizes of the (K+ + H+)-ATPase and its phosphatase activity are decreased by about 15%, while that for the (Na+ + K+)-ATPase is not significantly changed. This observation is discussed in terms of a Mg2+-induced tightening of the subunits composing the (K+ + H+)-ATPase molecule.

Studies on (K+ + H+)-ATPase. IV. Effects of phospholipase C treatment

(1) The total phospholipid content of a gradient purified (K+ + H+)-ATPase preparation from pig gastric mucosa is 105 mumol per 100 mg protein, and consists of 29% sphingomyelin, 29% phosphatidylcholine, 28% phosphatidylethanolamine, 10% phosphatidylserine and 4% phosphatidylinositol. The cholesterol content corresponds to 50 mumol per 100 mg protein. (2) Treatment with phospholipase C (from Clostridium welchii and Bacillus cereus) results in an immediate decrease of the phosphate content. Up to 50% of the phospholipids are hydrolyzed by each phospholipase C preparation alone, without further hydrolysis by increased phospholipase concentration or prolonged incubation time. Combined treatment with the two phospholipase C preparations, sequentially or simultaneously, hydrolyzes up to 65% of the phospholipids. (3) The (K+ + H+)-ATPase and K+ stimulated p-nitrophenylphosphatase activities are decreased proportionally with the total phospholipid content, indicating that these enzyme activities are dependent on phospholipids. (4) Phospholipase C treatment does not change optimal pH, Km value for ATP and temperature dependence of the gastric (K+ + H+)-ATPase, but slightly decreases the Ka value for K+. (5) Phospholipase C treatment lowers the AdoPP[NH]P binding and phosphorylation capacities, suggesting that inactivation occurs primarily on the substrate binding level. (6) Most of the results can be understood by assuming that hydrolysis of the phospholipids by phospholipase C leads to aggregation of the membrane protein molecules and complete inactivation of the aggregated ATPase molecules.