Two classes of site for ATP in the Ca2+-ATPase from human red cell membranes.

(1) The response of the Ca2+-ATPase activity from human red cell membranes to ATP concentrations can be represented by the sum of two Michaelis-like curves: one with a Km of 2.5 micrometer and the other with a Km of 145 micrometer. (2) The maximum Ca2+-ATPase activity elicited by occupation of the site with lower Km represents about 10% of the activity attainable at non-limiting ATP concentrations. (3) 30--50% of the Ca2+-ATPase activity with lower Km remains in the absence of Mg2+ . Mg2+ increases V and the maximum effect of Ca2+, having no effect on the apparent affinities for ATP and Ca2+. (4) The large increase in Ca2+-ATPase activity which results from the occupation of the site with higher Km only takes place when Mg2+ is present. (5) Results are compatible with the idea that the Ca2+-ATPase from human red cell membranes has two classes of site for ATP binding, both of which are occupied when the enzyme catalyzes the hydrolysis of ATP at maximum rate. (6) The properties of the high affinity site suggest that this is the catalytic site of the Ca2+-ATPase. It is proposed that binding of ATP at the low affinity site regulates the turnover of the system.

Radiation inactivation of (Na+ + K+)-ATPase. A small target size for the K+-occluding mechanism.

Radiation inactivation of partially purified (Na+ + K+)-ATPase (ATP phosphohydrolase, EC 3.6.1.3) from pig kidney outer medulla shows that the target size for Rb+ occlusion by the enzyme (in the absence of phosphorylation) is much smaller than the target size for p-nitrophenyl phosphatase activity, which is itself smaller than the reported target size for (Na+ + K+)-ATPase activity.

Inhibition of the sodium pump by cardioactive DPI 201-106.

The effects of DPI 201-106 were examined on contractions of papillary muscles from the right ventricle of feline heart, on [3H]-ouabain binding and Na+, K+-ATPase activity in feline ventricular membrane particles and on ouabain-sensitive 86Rb uptake in human erythrocytes. DPI 201-106 partially inhibited the Na+ pump at concentrations that caused pronounced positive inotropic effects.

Metabolism and excretion of 2-ethoxyethanol in the adult male rat.

The routes of 14C excretion following the administration of a single oral 230 mg/kg body weight dose of 2-ethoxyethanol [ethanol-1,2-14C] or 2-ethoxyethanol [ethoxy-1-14C] to male Sprague-Dawley rats were investigated. Elimination of the 14C by the urinary route accounted for 76 to 80% of the dose within 96 hr. The main pathway of biotransformation is oxidation to the corresponding acid, with some subsequent conjugation of the acid metabolite with glycine. The major metabolites, ethoxyacetic acid and N-ethoxy-acetyl glycine, representing 73 to 76% of the administered dose, were eliminated in the urine. The major difference in the metabolic profiles of the two radiochemicals was in the rate and amount of 14CO2 expired via the lung. Of the administered 14C, 11.7% of the ethoxy-labeled and 4.6% of the ethanol-labeled compounds were eliminated as CO2. The biological half-time was 9.9 +/- 1.5 hr for the ethoxy-labeled compound and 12.5 +/- 1.9 hr for the ethanol label. After administration of the ethanol-labeled compound, the only radiolabeled component found in the rat testes was identified as ethoxyacetic acid. Results of this study suggest that the reported testicular effects in the rat may be a result of tissue levels of ethoxyacetic acid.

Occlusion of cobalt ions within the phosphorylated forms of the Na+-K+ pump isolated from dog kidney.

1. Co2+ ions can replace Mg2+ ions as co-factors for the Na+-K+ pump purified from dog kidney outer medulla. The evidence comes from (a) measurement of ouabain-sensitive Na+,K+-ATPase activity, (b) measurement of ATP-dependent 22Na uptake catalysed by the Na+-K+ pump reconstituted into phospholipid vesicles, (c) measurements of phosphorylation of the Na+-K+ pump either in the presence of ATP and sodium ions or in the presence of inorganic phosphate, and (d) measurement of occlusion of rubidium ions through the route involving phosphorylation and dephosphorylation. 2. Purified Na+,K+-ATPase incubated in the presence of ATP, Na+ ions and [60Co]CoCl2, can carry occluded Co2+ ions through a cation-exchange resin. The enzyme fails to occlude the divalent cation (i) if ADP replaces ATP, (ii) if the enzyme is heat-inactivated, (iii) if the enzyme is inactivated by treatment with fluorescein isothiocyanate, (iv) if K+ replaces Na+ in the incubation medium, (v) if Na+ ions are omitted, and (vi) if Mg2+ ions are added in a sufficient concentration. 3. The amount of occluded Co2+ ions is unaffected by pre-treatment of the Na+,K+-ATPase with oligomycin, which stabilizes the phosphoenzyme in the E1P form. 4. The addition of K+ ions to Na+,K+-ATPase that has been phosphorylated in the presence of ATP, Na+ ions and [60Co]CoCl2 releases the occluded Co2+ ions from the enzyme. Under those conditions, K+ ions accelerate the hydrolysis of the phosphoenzyme, and become occluded in the resulting dephosphoenzyme. 5. The stoichiometry of Co2+ ion occlusion is about one occluded Co2+ ion per phosphorylation site. 6. These results support the hypothesis that, in the normal working of the Na+-K+ pump, Mg2+ ions are trapped in the phosphorylated forms of the enzyme, and are released by a K+-dependent dephosphorylation reaction.

Stimulation and inhibition by ATP and orthophosphate of the potassium-potassium exchange in resealed red cell ghosts.

The potassium:potassium (K-K) exchange through the sodium pump has been measured as the ouabain-sensitive 86Rb uptake by Na-free ghosts resealed to contain various concentrations of ATP, orthophosphate and K. The exchange is activated by increasing either internal or external K+ (Rb+) ion concentration. The activation curves can be described by simple Michaelis kinetics as: exchange = Vmax [K]/(Kapp + [K]). Increasing ATP concentration increases the apparent affinity for external K ions but decreases the apparent affinity for internal K (Ki+). Increasing [ATP] from 1 microM to 1 mM typically increases the Kapp for Ki+ from less than 1 mM to about 30 mM. Increasing ATP first activates the exchange but, after an optimal concentration is reached, further increase of ATP inhibits. The value of ATP concentration which gives the maximum flux depends on the internal and external K+ concentrations. The higher [Ki], the greater the optimal ATP concentration. Increasing external K (Rb) decreases the optimal ATP concentration. Increasing the concentration of orthophosphate (Pi) activates the exchange at high ATP but inhibits at low ATP concentration. A concentration of Pi which stimulates the exchange at high external K (Rb) can inhibit at low external K (Rb). These findings are in agreement with a consecutive or ping-pong model of the K-K exchange. We suggest that previous experiments have not shown the inhibitory effects of ATP and Pi because of the particular range of concentrations investigated.

Evidence for the ordered release of rubidium ions occluded within individual protomers of dog kidney Na+,K+-ATPase.

1. When magnesium and orthophosphate are added to Na+,K+-ATPase containing occluded rubidium ions, and suspended in a medium containing free rubidium ions, only 50% of the occluded rubidium is released rapidly. This is because the release of occluded rubidium is ordered, and the replacement (by rubidium ions from the medium) of the first occluded rubidium ions to leave slows the departure of the remaining occluded ions. 2. Since the Na+,K+-ATPase probably exists in the membrane as a structural dimer, the ordered release might represent either the ordered emptying of the two halves of the dimer, or the ordered release of the two rubidium ions thought to be contained in each promoter. 3. The present experiments were designed to decide between these possibilities by examining the behaviour of Na+,K+-ATPase in which about half of the protomers had been randomly inactivated by pre-treatment either with fluorescein isothiocyanate or with alpha-chymotrypsin. 4. The results show that the release of rubidium ions from each protomer is ordered.

Occlusion of rubidium ions by the sodium-potassium pump: its implications for the mechanism of potassium transport.

1. The occlusion of rubidium ions by Na, K-ATPase has been investigated by suspending enzyme prepared from pig kidney outer medulla in media containing low concentrations of (86)Rb, forcing the suspensions rapidly through small columns of cation-exchange resin, and measuring the amounts of radioactivity emerging from the columns.2. When the suspension media contained 2 mM-ATP or ADP, or 15 mM-NaCl, the amounts of radioactivity emerging from the columns were greatly (and similarly) reduced, presumably because both nucleotides and sodium ions stabilized the enzyme in the E(1) form. (See p. 19 for definition of E(1) and E(2)). The extra radioactivity carried through the columns when nucleotides and sodium were absent was taken as a measure of the amount of rubidium occluded within the enzyme (in the E(2) form) when it emerged from the resin.3. By varying the flow rate, and therefore the time spent by the enzyme on the resin, and relating this to the amount of radioactivity emerging from the columns, we have been able to estimate the rate constant for the conformational change (E(2) --> E(1)) that allows the occluded rubidium ions to escape. At 20 degrees C, and in the absence of nucleotides, it is about 0.1 S(-1).4. The rate constant for rubidium release was the same in a sodium-containing as in a potassium-containing medium. The opposite effects of sodium and potassium ions on the poise of the equilibrium between the E(1) and the E(2) forms of the enzyme must, therefore, be due solely to opposite effects of these ions on the rate of conversion of E(1) to E(2).5. The rate constant for rubidium release was greatly increased by ATP and by ADP. Both nucleotides appeared to act at low-affinity sites and without phosphorylating the enzyme.6. Orthovanadate, in the presence of magnesium ions, stabilized the enzyme in the occluded-rubidium (E(2)Rb) form.7. Ouabain, in the presence of magnesium ions, prevented the occlusion of rubidium ions.8. We have measured the amount of rubidium occluded by the enzyme as a function of rubidium concentration, and estimate that at saturating rubidium concentrations about three rubidium ions can be occluded per phosphorylation site (or per ouabain-binding site).9. We have found that the occluded-rubidium form of the enzyme can also be formed by allowing rubidium ions to catalyse the hydrolysis of phosphoenzyme generated by the addition of ATP to enzyme suspended in a high-sodium medium.10. The properties of the occluded-rubidium form of the enzyme, and of the two routes that can lead to its formation, suggest that an analagous occluded-potassium form plays a central role in the transport of potassium ions through the sodium-potassium pump. This hypothesis is supported by a detailed consideration of the probable magnitudes of the rate constants of the individual reactions making up the two routes.

Inhibition of the sodium pump by inorganic phosphate in resealed red cell ghosts.

1. Ouabain-sensitive Rb influx was measured into K-free resealed red cell ghosts. The effects of inorganic phosphate (Pi) were examined. 2. Phosphate decreased the magnitude of the influx. Increasing Pi lowered the apparent affinity for both ATP and external rubidium ions. The effects of Pi on the affinity for external Rb were greatest at low ATP concentrations. 3. In the nominal absence of phosphate, increasing ATP from 1 to 100 microM had little effect on the Rb influx from solutions of low (1 microM) rubidium concentrations. In the presence of Pi, ATP increased Rb uptake markedly, even from solutions of low Rb concentration. 4. The above interactions between Pi, ATP and external Rb are consistent with a consecutive scheme for the Na pump in which phosphate is released after potassium binds at the external surface and before ATP binds to release potassium ions to the internal solution. 5. Previous failures to find an effect of phosphate on either the affinity for ATP or that for external potassium (rubidium) ions are shown to be equally consistent with the model. The lack of change of apparent affinity is shown to result from the restricted range of concentrations used in these previous experiments.