Sodium-activated Adenosine Triphosphatase Activity of the Erythrocyte Membrane

On the functional use of the membrane compartmentalized pool of ATP by the Na+ and Ca++ pumps in human red blood cell ghosts

Previous evidence established that a sequestered form of adenosine triphosphate (ATP pools) resides in the membrane/cytoskeletal complex of red cell porous ghosts. Here, we further characterize the roles these ATP pools can perform in the operation of the membrane's Na(+) and Ca(2+) pumps. The formation of the Na(+)- and Ca(2+)-dependent phosphointermediates of both types of pumps (E(Na)-P and E(Ca)-P) that conventionally can be labeled with trace amounts of [gamma-(3)P]ATP cannot occur when the pools contain unlabeled ATP, presumably because of dilution of the [gamma-(3)P]ATP in the pool. Running the pumps forward with either Na(+) or Ca(2+) removes pool ATP and allows the normal formation of labeled E(Na)-P or E(Ca)-P, indicating that both types of pumps can share the same pools of ATP. We also show that the halftime for loading the pools with bulk ATP is 10-15 minutes. We observed that when unlabeled "caged ATP" is entrapped in the membrane pools, it is inactive until nascent ATP is photoreleased, thereby blocking the labeled formation of E(Na)-P. We also demonstrate that ATP generated by the membrane-bound pyruvate kinase fills the membrane pools. Other results show that pool ATP alone, like bulk ATP, can promote the binding of ouabain to the membrane. In addition, we found that pool ATP alone functions together with bulk Na(+) (without Mg(2+)) to release prebound ouabain. Curiously, ouabain was found to block bulk ATP from entering the pools. Finally, we show, with red cell inside-outside vesicles, that pool ATP alone supports the uptake of (45)Ca by the Ca(2+) pump, analogous to the Na(+) pump uptake of (22)Na in this circumstance. Although the membrane locus of the ATP pools within the membrane/cytoskeletal complex is unknown, it appears that pool ATP functions as the proximate energy source for the Na(+) and Ca(2+) pumps.

Different approaches to the mechanism of the sodium pump

The way in which the sodium pump uses energy from the hydrolysis of ATP to perform osmotic and electrical work is not yet understood. We attempt to bring together the results of a number of different approaches to this problem. One approach has been to correlate biochemical changes and ionic fluxes, both when the pump operates normally and when it operates in various abnormal 'modes' in particular unphysiological conditions. A second approach has been to expose fragments of cell membrane to (gamma-32P)ATP and to study the properties of components of the membrane that become labelled. It is now clear that 32P can be transferred to the beta-carboxy group of an aspartyl residue in a pump polypeptide, but there is controversy about the interrelations of different forms of this polypeptide and its role, if any, in the normal functioning of the pump. A third approach has been to attempt to purify the pump and to determine the properties of the pure enzyme. It seems that the pump contains a polypeptide (molecular weight about 100,000), which bears the phosphorylation site, and a smaller glycopeptide, but there is disagreement about the molecular ratios. The results of these and other approaches cannot yet be fitted into a satisfactory model for the sodium pump, but we shall consider some of the problems involved in this task.

Mechanism responsible for oligomycin-induced occlusion of Na+ within Na/K-ATPase

The mechanism whereby oligomycin occludes Na+ within Na/K-ATPase was investigated to study Na+ and K+ transport mechanisms. Oligomycin stimulated Na+ binding to Na/K-ATPase but inhibited Na-K and Na-Na exchange. The oligomycin concentration required to stimulate Na+ binding to half-maximal was 4.5 microM, which was close to the concentration that reduced Na-Na and Na-K exchange and ATPase activity to half-maximal, suggesting that Na/K-ATPase possesses an oligomycin binding site responsible for stimulating Na+ binding and reducing ion exchange and ATPase activity. In contrast, neither K+ binding nor K+ transport was affected by oligomycin. Limited tryptic digestion of Na/K-ATPase showed that, unlike Na+, K+, and ouabain, oligomycin treatment did not result in a specific digestion pattern. Oligomycin appeared to inhibit ouabain binding in a noncompetitive manner, whereas it did not affect ATP binding. Na/K-ATPase isoforms with low and high sensitivities to ouabain were equally sensitive to oligomycin. These results suggest that the oligomycin binding site is located on the extracellular side of Na/K-ATPase, at a different position from the ouabain binding site, and this antibiotic did not induce a conformational change of Na/K-ATPase. We propose that oligomycin interacts with the Na+ occlusion site from the extracellular side of Na/K-ATPase, which delays Na+ release to the extracellular side without inducing a conformational change, suggesting that the pathways responsible for Na+ and K+ transport differ.

Role of protein conformation changes and transphosphorylations in the function of Na+/K(+)-transporting adenosine triphosphatase: an attempt at an integration into the Na+/K+ pump mechanism

The particular aim of the review on some basic facets of the mechanism of Na+/K(+)-transporting ATPase (Na/K-ATPase) has been to integrate the experimental findings concerning the Na(+)- and K(+)-elicited protein conformation changes and transphosphorylations into the perspective of an allosterically regulated, phosphoryl energy transferring enzyme. This has led the authors to the following summarizing evaluations. 1. The currently dominating hypothesis on a link between protein conformation changes ('E1 in equilibrium with E2') and Na+/K+ transport (the 'Albers-Post scheme') has been constructed from a variety of partial reactions and elementary steps, which, however, do not all unequivocally support the hypothesis. 2. The Na(+)- and K(+)-elicited protein conformation changes are inducible by a variety of other ligands and modulatory factors and therefore cannot be accepted as evidence for their direct participation in effecting cation translocation. 3. There is no evidence that the 'E1 in equilibrium with E2' protein conformation changes are moving Na+ and K+ across the plasma membrane. 4. The allosterically caused ER in equilibrium with ET ('E1 in equilibrium with E2') conformer transitions and the associated cation 'occlusion' in equilibrium with 'de-occlusion' processes regulate the actual catalytic power of an enzyme ensemble. 5. A host of experimental variables determines the proportion of functionally competent ER enzyme conformers and incompetent ET conformers so that any enzyme population, even at the start of a reaction, consists of an unknown mixture of these conformers. These circumstances account for the occurrence of contradictory observations and apparent failures in their comparability. 6. The modelling of the mechanism of the Na/K-ATPase and Na+/K+ pump from the results of reductionistically designed experiments requires the careful consideration of the physiological boundary conditions. 7. Na+ and K+ ligandation of Na/K-ATPase controls the geometry and chemical reactivity of the catalytic centre in the cycle of E1 in equilibrium with E2 state conversions. This is possibly effected by hinge-bending, concerted motions of three adjacent, intracellularly exposed peptide sequences, which shape open and closed forms of the catalytic centre in lock-and-key responses. 8. The Na(+)-dependent enzyme phosphorylation with ATP and the K(+)-dependent hydrolysis of the phosphoenzyme formed are integral steps in the transport mechanism of Na/K-ATPase, but the translocations of Na+ and K+ do not occur via a phosphate-cation symport mechanism.(ABSTRACT TRUNCATED AT 400 WORDS)

A non-specific Ca2+ (or Mg2+)-stimulated ATPase in rat heart sarcoplasmic reticulum

ATPase activity in rat heart sarcoplasmic reticulum was stimulated in a concentration-dependent manner by both Ca2+ and Mg2+ in the complete absence of the other cation. Increasing concentrations of Mg2+ produced an apparent inhibition of the Ca2(+)-dependent ATP hydrolysis. CDTA (trans-1,2-diaminocyclo-hexane-N,N,N',N'-tetraacetate) had no effect on these responses. The results indicate the presence of a low affinity non-specific divalent cation-stimulated ATPase in rat heart sarcoplasmic reticulum. However, sarcoplasmic reticulum vesicles transported Ca2+ with a high affinity (K0.5 Ca2+ = 0.41 microM) suggesting the presence of a high affinity Ca2(+)-transporting ATPase. Calmodulin did not stimulate rat heart sarcoplasmic reticulum ATPase activity over a range of Ca2+ and Mg2+ concentrations and failed to stimulate membrane phosphorylation and Ca2+ transport into sarcoplasmic reticulum vesicles. Calmodulin antagonists trifluoperazine and compound 48/80 did not affect the ATPase activity. Catalytic subunit of cAMP-dependent protein kinase was also ineffective in stimulating the ATPase activity. These results suggest the presence of an ATPase activity in rat heart sarcoplasmic reticulum with different properties from the high affinity Ca2(+)-pumping ATPase previously characterized in dog heart and other species.

Kinetic mechanism of inhibition of the Na+-pump and some of its partial reactions by external Na+ (Na+o)

The effects of external Na+ on the activity of the Na+-pump are complex. The first-order rate constant for Na+-efflux is reduced in the presence of very low external Na+ concentrations, and this inhibition is reversed when the Na+ level is raised. The same pattern has been observed for Na+-ATPase activity; however, it is not apparent from the current reaction mechanisms at which site (or sites) external Na+ binds to cause inhibition. In this paper, the effect of external Na+ on Na+-pump activity was studied by simulation, using a model similar to the Post-Albers scheme. Curves similar to those experimentally observed were obtained assuming that: (i) after phosphorylation, three Na+ ions are translocated and consecutively released to the external medium with decreasing dissociation constants; (ii) external Na+, with low affinity, binds to the K+o (external) sites stimulating dephosphorylation. These assumptions also permit one to explain the experimental observation that external Na+ (with both high and low affinities) competes with K+, inhibiting the K+ influx due to the Na+-pump, and the kinetically similar behavior of Na+-ATPase and ATP/ADP exchange reactions at low variable Na+ concentrations. The experimental evidence available that supports the present hypothesis is discussed.

Occlusion of Na+ by the Na,K-ATPase in the presence of oligomycin

Oligomycin occludes Na+ in an E1-form of the Na,K-ATPase. The rate constants for the release of Na+ from the E1-form and for the transition to the E2-form are about 0.5 s-1. The effect of oligomycin is not seen using other cations which also have a Na+-like effect on the enzyme conformation. The inhibitory effect of oligomycin on the ADP-ATP dependent Na:Na exchange but not on the accompanying ADP-ATP exchange can be explained from a decrease in the rate of release of Na+ from an E1 approximately phosphoform with Na+ occluded, E'1 approximately P (Na3), i.e. with Na+ in the membrane phase, to an E"1 approximately PNa3 form with Na+ not occluded. E"1 approximately PNa3 is at a step before formation of E2-P, and disappears at a high rate when ADP reacts with E"1 approximately P (Na3).

Phosphorylation and dephosphorylation of the Ca2+ pump of human red cells in the presence of monovalent cations

(1) In the presence of calcium ions, K+ increases the rate and the steady state level of phosphorylation of human red cell membranes by [gamma-32P)ATP. The effect of K+ is mimicked by Rb+, NH4+ and Cs+. Electrophoresis experiments suggest that the phosphorus taken up by the membranes in the presence of K+ is bound to the phosphoenzyme of the Ca2+-ATPase. (2) (Ca2+ + K+)-dependent phosphorylation requires Ca2+ and ATP with the same apparent affinity as the phosphorylation of the Ca2+ pump and the effect of K+ on phosphorylation is exerted with the same apparent affinity as that for the activation of the Ca2+-ATPase by K+. (3) The rate of hydrolysis of phosphoenzyme made in the presence of K+ is higher than that made in its absence and K+ increases the ratio Ca2+-ATPase activity/Ca2+-dependent phosphoenzyme concentration. (4) Results suggest that monovalent cations activate the Ca2+ pump because they increase the level and the turnover of the phosphoenzyme of the Ca2+-ATPase.

Effects of ATP and protons on the Na : K selectivity of the (Na+ + K+)-ATPase studied by ligand effects on intrinsic and extrinsic fluorescence

The effect of pH and of ATP on the Na : K selectivity of the (Na+ + K+)-ATPase has been tested under equilibrium conditions. The Na+ : K+-induced change in intrinsic tryptophan fluorescence and in fluorescence of eosin maleimide bound to the system has been used as a tool. 1 mol of eosin maleimide per mol of enzyme gives no loss in either ATPase or phosphatase activity and the fluorescence in the presence of Na+ is about 30% higher than in the presence of K+. Choline, protonated Tris, protonated histidine and Mg2+ have an 'Na+' effect on the extrinsic fluorescence, while Rb+, Cs+ and NH4+ have a 'K+' effect. Choline and protonated Tris have an Na+ effect on intrinsic fluorescence. A close correlation between the effect of Na+ compared to K+ on the fluorescence change and on Na+ activation of hydrolysis indicates that the observed changes in fluorescence are due to an effect of Na+ and of K+ on the internal sites of the system. The equilibrium between the two conformations, which are reflected by the difference in fluorescence with Na+ and K+, respectively, is highly influenced by the concentration of protons. At a given Na+ : K+ ratio, an increase in the proton concentration shifts the equilibrium towards the 'K+' fluorescence form while a decrease shifts the equilibrium towards the 'Na+' fluorescence form, i.e., protons increase the apparent affinity for K+ and vice versa, K+ increases pK values of importance for the Na+ : K+ selectivity. Conversely, a decrease in protons increases the apparent affinity for Na+ and vice versa, Na+ decreases the pK. ATP decreases the apparent pK for the protonation-deprotonation, i.e., ATP facilitates the deprotonation which accompanies Na+ binding. The results suggest two effects of ATP for the hydrolysis in the presence of Na+ and K+ : (i) at low ATP concentrations (K0.5 < 10 microM) on the K+-Na+ exchange on the internal sites and (ii) at higher, substrate, concentrations on the activation by K+ on the external sites.

Red cell sodium fluxes catalysed by the sodium pump in the absence of K+ and ADP

In the absence of extracellular Na+ or K+, the sodium pump catalyses an ouabain-sensitive "uncoupled" Na+ efflux1-4. With red cell ghosts Glynn and Karlish5 showed that this Na+ efflux is accompanied by ATP hydrolysis and that extracellular sodium ions, at low concentrations, inhibit this efflux as well as the associated ATP hydrolysis. At higher concentrations, extracellular sodium ions restore the hydrolysis of ATP3,6 but it is not known whether there is an associated increase in Na+ efflux and, perhaps, an influx. To answer this question we have used inside-out red cell membrane vesicles which are specially suitable for controlling the composition of the medium at the two membrane surfaces while measuring 22Na+ fluxes in both directions. We report here that the sodium pump can operate in a mode in which influx and efflux of sodium are associated with ATP hydrolysis. This mode is different from the Na-Na exchange described by Garrahan and Glynn7, and Glynn and Hoffman8, which requires ADP as well as ATP9 and is probably associated with ADP-ATP exchage rather than ATP hydrolysis10,11.

Effects of ATP on the intermediary steps of the reaction of the (Na+ + K+)-ATPase. IV. Effect of ATP on K0.5 for Na+ and on hydrolysis at different pH and temperature

The pH optimum for (Na+ + K+)-ATPase (ATP phosphohydrolase, EC 3.6.1.3) depends on the combination of monovalent cations, on the ATP concentration and on temperature. ATP decreases the Na+ concentration necessary for half maximum activation, K0.5 for Na+ (Na+ + K+ = 150 mM), and the effect is pH and temperature dependent. At a low ATP concentration a decrease in pH leads to an increase in K0.5 for Na+, while at the high ATP concentration it leads to a decrease. K0.5 for ATP for hydrolysis decreases with an increase in pH. The fractional stimulation by K+ in the presence of Na+ decreases with the ATP concentration, and at a low ATP concentration K+ becomes inhibitory, this being most pronounced at 0 degrees C. The results suggest that (a) ATP at a given pH has two different effects: it increases the Na+ relative to K+ affinity on the internal site (K0.5 for ATP at pH 7.4, 37 degrees C, is less than 10 microM); it increases the molar activity in the presence of Na+ + K+ (K0.5 for ATP at pH 7.4, 37 degrees , is 127 microM), (b) binding of the cations to the external as well as the internal sites leads to pK changes (Bohr effect) which are different for Na+ and for K+, i.e. the selectivity for Na+ relative to K+ depends both on ATP and on the degree of protonation of certain groups on the system, (c) ATP involves an extra dissociable group in the determination of the selectivity of the internal site, and thereby changes the effect of an increase in protonation of the system from a decrease to an increase in selectivity for Na+ relative to K+.

Properties of (Mg2 + Ca2+)-ATPase of erythrocyte membranes prepared by different procedures: influence of Mg2+, Ca2+, ATP, and protein activator

Erythrocyte membranes prepared by three different procedures showed (Mg2+ + Ca2+)-ATPase activities differing in specific activity and in affinity for Ca2+. The (Mg2+ + Ca2+)-ATPase activity of the three preparations was stimulated to different extents by a Ca2+-dependent protein activator isolated from hemolysates. The Ca2+ affinity of the two most active preparations was decreased as the ATP concentration in the assay medium was increased. Lowering the ATP concentration from 2 mM to 2-200 microM or lowering the Mg:ATP ratio to less than one shifted the (Mg2+ + Ca2+)-ATPase activity in stepwise hemolysis membranes from mixed "high" and "low" affinity to a single high Ca2+ affinity. Membranes from which soluble proteins were extracted by EDTA (0.1 mM) in low ionic strength, or membranes prepared by the EDTA (1-10 mM) procedure, did not undergo the shift in the Ca2+ affinity with changes in ATP and MgCl2 concentrations. The EDTA-wash membranes were only weakly activated by the protein activator. It is suggested that the differences in properties of the (Mg2+ + Ca2+)-ATPase prepared by these three procedures reflect differences determined in part by the degree of association of the membrane with a soluble protein activator and changes in the state of the enzyme to a less activatable form.

The (Na + K+)-dependent ATPase. Mode of inhibition of ADP/ATP exchange activity by MgC12

Na+-dependent ADP/ATP exchange activity, of a (Na++K+)-dependent ATPase preparation from eel electric organ, was measured in terms of the incorporation of 14C into ATP during incubations with labeled ATP and [14C]ADP. Estimates of initial rates of exchange were possible by keeping changes in nucleotide concentrations, from both exchange and extraneous hydrolytic processes, to less than 10%. Under these conditions, increases in MgC12 concentration, from 0.2 to 3 mM, generally inhibited this exchange activity. The concentrations of free Mg2+, Mg-ATP, and Mg-adp present, with a range of MgC12, ATP, and ADP concentrations, were calculated from measured dissociation constants. Inhibition was associated with Mg-ATP as well as with Mg2+, at concentrations from 0.4 to 1 mM (Mg-ADP, in the same concentration range, probably inhibited also). The affinity of the enzyme for these inhibitors is in fair correspondence with demonstrated affinties for Mg2+, Mg-atp, and Mg-ADP at low affinity substrate sites, measured kinetically. These observations are considered in terms of a dimeric enzyme with high and low affinity substrates sites: ADP/ATP exchange being catalyzed at the high affinity sites, with inhibition occurring through occupancy by Mg2+, Mg-ATP, or Mg-ADP, of the low affinity sites, thereby pulling the reaction process away from those steps involved in exchange.

The ATP dependence of a ouabain-sensitive sodium efflux activated by external sodium, potassium and lithium in human red cells

The stimulation of ouabain-sensitive Na+ efflux by external Na+, K+ and Li+ was studied in control and ATP-depleted human red cells. In the presence of 5 mM Na+, with control and depleted cells, Li+ stimulated with a lower apparent affinity than K+, and gave a smaller maximal activation than K+. The ability of Na+, K+ and Li+ to activate Na+ efflux was a function of the ATP content of the cells. Relative to K+ both Na+ and Li+ became more effective activators when the ATP was reduced to about one tenth of the control values. At this low ATP concentration Na+ was absolutely more effective than K+.

Interaction of two mechanisms regulating alkali cations in HeLa cells

The alkali cation content of HeLa cells is independent of culture density and of whether the cells are grown in suspension or attached to the culture vessel. With a cell doubling time of 28 hours, the cell K content turns over approximately once per hour. Following partial blockade of the alkali-cation transport system with ouabain, two distinct but interrelated mechanisms operate in the cellular response: (a) an increase in intracellular Na stimulates the pump so that the short-term alteration in electrolyte compostition is less than would be expected from the fraction of pump sites inhibited, and (b) there is a cycloheximide-sensitive recovery in transport capacity reflecting a restoration of functional transport sites to their normal density on the cell surface. Experimental manipulations that mimic the effect of ouabain lead to a stimulation of transport, but they do not result in an increase in the number of ouabain-binding sites on the surface. The data are consistent with a four-to-six hour turn-over of transport sites at the surface, but there is no evidence for a speicific induction of the transport system within this short-term recovery period.

Ca-2+-stimulated membrane phosphorylation and ATPase activity of the human erythrocyte

1. Human erythrocyte membranes were preincubated with ethyleneglycolbis-(beta-aminoethyl)-N,N' tetraacetate (EGTA) and subsequently labelled for short periods with micromolar concentrations of [8-3-H, gamma-32-P]ATP. Under these conditions, and at temperatures smaller than or equal to 22 degrees C, both ATP hydrolysis and membrane phosphorylation were stimulated by Ca-2+. 2. The properties of the Ca-2+-stimulated ATP hydrolysis and associated phosphorylation of a 150 000 molecular weight protein component, previously described (Knauf, P. A., Proverbio, F. and Hoffman, J. F. (1974) J. Gen. Physiol. 63, 324-336), have been studied. The behavior of the phosphorylated component, ECaP, has properties consistent with its role as a phosphorylated intermediate of Ca-2+-ATPase activity, including: (1) similar dependence of the steady-state level of ECaP and Ca-2+-ATPase on ATP concentration; (2) rapid turnover apparent upon the addition of excess non-radioactive ATP; and (3) good correlation between the steady-state levels of Ca-2+-dependent phosphorylation and Ca-2+-ATPase activity in separate preparations possessing variable specific activity. Addition of excess EGTA to ECaP caused only partial dephosphorylation. Sensitivity of Ca-2+-stimulated ATP hydrolysis and associated phosphorylation to micromolar concentrations of Ca-2+ implicates this activity in the "high-affinity" Ca-2+-pump system of the human erythrocyte (Schatzmann, H. J. (1973) J. Physiol. London 235, 551-569).

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).