Na+-like effect of imidazole on the phosphorylation of (Na+ + K+)-ATPase

Na+/K+-ATPase: More than an Electrogenic Pump

The sodium pump, or Na+/K+-ATPase (NKA), is an essential enzyme found in the plasma membrane of all animal cells. Its primary role is to transport sodium (Na+) and potassium (K+) ions across the cell membrane, using energy from ATP hydrolysis. This transport creates and maintains an electrochemical gradient, which is crucial for various cellular processes, including cell volume regulation, electrical excitability, and secondary active transport. Although the role of NKA as a pump was discovered and demonstrated several decades ago, it remains the subject of intense research. Current studies aim to delve deeper into several aspects of this molecular entity, such as describing its structure and mode of operation in atomic detail, understanding its molecular and functional diversity, and examining the consequences of its malfunction due to structural alterations. Additionally, researchers are investigating the effects of various substances that amplify or decrease its pumping activity. Beyond its role as a pump, growing evidence indicates that in various cell types, NKA also functions as a receptor for cardiac glycosides like ouabain. This receptor activity triggers the activation of various signaling pathways, producing significant morphological and physiological effects. In this report, we present the results of a comprehensive review of the most outstanding studies of the past five years. We highlight the progress made regarding this new concept of NKA and the various cardiac glycosides that influence it. Furthermore, we emphasize NKA's role in epithelial physiology, particularly its function as a receptor for cardiac glycosides that trigger intracellular signals regulating cell-cell contacts, proliferation, differentiation, and adhesion. We also analyze the role of NKA β-subunits as cell adhesion molecules in glia and epithelial cells.

Electrostatic Stabilization Plays a Central Role in Autoinhibitory Regulation of the Na+,K+-ATPase

The Na⁺,K⁺-ATPase is present in the plasma membrane of all animal cells. It plays a crucial role in maintaining the Na⁺ and K⁺ electrochemical potential gradients across the membrane, which are essential in numerous physiological processes, e.g., nerve, muscle, and kidney function. Its cellular activity must, therefore, be under tight metabolic control. Consideration of eosin fluorescence and stopped-flow kinetic data indicates that the enzyme's E2 conformation is stabilized by electrostatic interactions, most likely between the N-terminus of the protein's catalytic α-subunit and the adjacent membrane. The electrostatic interactions can be screened by increasing ionic strength, leading to a more evenly balanced equilibrium between the E1 and E2 conformations. This represents an ideal situation for effective regulation of the Na⁺,K⁺-ATPase's enzymatic activity, because protein modifications, which perturb this equilibrium in either direction, can then easily lead to activation or inhibition. The effect of ionic strength on the E1:E2 distribution and the enzyme's kinetics can be mathematically described by the Gouy-Chapman theory of the electrical double layer. Weakening of the electrostatic interactions and a shift toward E1 causes a significant increase in the rate of phosphorylation of the enzyme by ATP. Electrostatic stabilization of the Na⁺,K⁺-ATPase's E2 conformation, thus, could play an important role in regulating the enzyme's physiological catalytic turnover.

Extracellular allosteric Na(+) binding to the Na(+),K(+)-ATPase in cardiac myocytes

Whole-cell patch-clamp measurements of the current, Ip, produced by the Na(+),K(+)-ATPase across the plasma membrane of rabbit cardiac myocytes show an increase in Ip over the extracellular Na(+) concentration range 0-50 mM. This is not predicted by the classical Albers-Post scheme of the Na(+),K(+)-ATPase mechanism, where extracellular Na(+) should act as a competitive inhibitor of extracellular K(+) binding, which is necessary for the stimulation of enzyme dephosphorylation and the pumping of K(+) ions into the cytoplasm. The increase in Ip is consistent with Na(+) binding to an extracellular allosteric site, independent of the ion transport sites, and an increase in turnover via an acceleration of the rate-determining release of K(+) to the cytoplasm, E2(K(+))2 → E1 + 2K(+). At normal physiological concentrations of extracellular Na(+) of 140 mM, it is to be expected that binding of Na(+) to the allosteric site would be nearly saturated. Its purpose would seem to be simply to optimize the enzyme's ion pumping rate under its normal physiological conditions. Based on published crystal structures, a possible location of the allosteric site is within a cleft between the α- and β-subunits of the enzyme.

Alternative cycling modes of the Na(+)/K(+)-ATPase in the presence of either Na(+) or Rb(+)

A comprehensive study of the interaction between Na(+) and K(+) with the Na(+)/K(+)-ATPase requires dissecting the incidence of alternative cycling modes on activity measurements in which one or both of these cations are absent. With this aim, we used membrane fragments containing pig-kidney Na(+)/K(+)-ATPase to perform measurements, at 25°C and pH=7.4, of ATPase activity and steady-state levels of (i) intermediates containing occluded Rb(+) at different [Rb(+)] in media lacking Na(+), and (ii) phosphorylated intermediates at different [Na(+)] in media lacking Rb(+). Most relevant results are: (1) Rb(+) can be occluded through an ATPasic cycling mode that takes place in the absence of Na(+) ions, (2) the kinetic behavior of the phosphoenzyme formed by ATP in the absence of Na(+) is different from the one that is formed with Na(+), and (3) binding of Na(+) to transport sites during catalysis is not at random unless rapid equilibrium holds.

Dual mechanisms of allosteric acceleration of the Na(+),K(+)-ATPase by ATP

Investigations of the E2 --> E1 conformational change of Na(+),K(+)-ATPase from shark rectal gland and pig kidney via the stopped-flow technique have revealed major differences in the kinetics and mechanisms of the two enzymes. Mammalian kidney Na(+),K(+)-ATPase appears to exist in a diprotomeric (alphabeta)(2) state in the absence of ATP, with protein-protein interactions between the alpha-subunits causing an inhibition of the transition, which occurs as a two-step process: E2:E2 --> E2:E1 --> E1:E1. This is evidenced by a biphasicity in the observed kinetics. Binding of ATP to the E1 or E2 states causes the kinetics to become monophasic and accelerate, which can be explained by an ATP-induced dissociation of the diprotomer into separate alphabeta protomers and relief of the preexisting inhibition. In the case of enzyme from shark rectal gland, the observed kinetics are monophasic at all ATP concentrations, indicating a monoprotomeric enzyme; however, an acceleration of the E2 --> E1 transition by ATP still occurs, to a maximum rate constant of 182 (+/- 6) s(-1). This indicates that ATP has two separate mechanisms whereby it accelerates the E2 --> E1 transition of Na(+),K(+)-ATPase alphabeta protomers and (alphabeta)(2) diprotomers.

Evidence that antioxidants prevent the inhibition of Na+,K(+)-ATPase activity induced by octanoic acid in rat cerebral cortex in vitro

The objective of the present study was to investigate the in vitro effects of octanoic acid, which accumulates in medium-chain acyl-CoA dehydrogenase (MCAD) deficiency and in Reye syndrome, on key enzyme activities of energy metabolism in the cerebral cortex of young rats. The activities of the respiratory chain complexes I-IV, creatine kinase, and Na+,K(+)-ATPase were evaluated. Octanoic acid did not alter the electron transport chain and creatine kinase activities, but, in contrast, significantly inhibited Na+,K(+)-ATPase activity both in synaptic plasma membranes and in homogenates prepared from cerebral cortex. Furthermore, decanoic acid, which is also increased in MCAD deficiency, and oleic acid strongly reduced Na+,K(+)-ATPase activity, whereas palmitic acid had no effect. We also examined the effects of incubating glutathione and trolox (alpha-tocopherol) alone or with octanoic acid on Na+,K(+)-ATPase activity. Tested compounds did not affect Na+,K(+)-ATPase activity by itself, but prevented the inhibitory effect of octanoic acid. These results suggest that inhibition of Na+,K(+)-ATPase activity by octanoic acid is possibly mediated by oxidation of essential groups of the enzyme. Considering that Na+,K(+)-ATPase is critical for normal brain function, it is feasible that the significant inhibition of this enzyme activity by octanoate and also by decanoate may be related to the neurological dysfunction found in patients affected by MCAD deficiency and Reye syndrome.

Rate limitation of the Na(+),K(+)-ATPase pump cycle

The kinetics of Na(+)-dependent phosphorylation of the Na(+),K(+)-ATPase by ATP were investigated via the stopped-flow technique using the fluorescent label RH421 (saturating [ATP], [Na(+)], and [Mg(2+)], pH 7.4, and 24 degrees C). The well-established effect of buffer composition on the E(2)-E(1) equilibrium was used as a tool to investigate the effect of the initial enzyme conformation on the rate of phosphorylation of the enzyme. Preincubation of pig kidney enzyme in 25 mM histidine and 0.1 mM EDTA solution (conditions favoring E(2)) yielded a 1/tau value of 59 s(-1). Addition of MgCl(2) (5 mM), NaCl (2 mM), or ATP (2 mM) to the preincubation solution resulted in increases in 1/tau to values of 129, 167, and 143 s(-1), respectively. The increases can be attributed to a shift in the enzyme conformational equilibrium before phosphorylation from the E(2) state to an E(1) or E(1)-like state. The results thus demonstrate conclusively that the E(2) --> E(1) transition does in fact limit the rate of subsequent reactions of the pump cycle. Based on the experimental results, the rate constant of the E(2) --> E(1) transition under physiological conditions could be estimated to be approximately 65 s(-1) for pig kidney enzyme and 90 s(-1) for enzyme from rabbit kidney. Taking into account the rates of other partial reactions, computer simulations show these values to be consistent with the turnover number of the enzyme cycle (approximately 48 s(-1) and approximately 43 s(-1) for pig and rabbit, respectively) calculated from steady-state measurements. For enzyme of the alpha(1) isoform the E(2) --> E(1) conformational change is thus shown to be the major rate-determining step of the entire enzyme cycle.

Charge translocation by the Na+/K+-ATPase investigated on solid supported membranes: cytoplasmic cation binding and release

In the preceding publication (. Biophys. J. 76:000-000) a new technique was described that was able to produce concentration jumps of arbitrary ion species at the surface of a solid supported membrane (SSM). This technique can be used to investigate the kinetics of ion translocating proteins adsorbed to the SSM. Charge translocation of the Na+/K+-ATPase in the presence of ATP was investigated. Here we describe experiments carried out with membrane fragments containing Na+/K+-ATPase from pig kidney and in the absence of ATP. Electrical currents are measured after rapid addition of Na+. We demonstrate that these currents can be explained only by a cation binding process on the cytoplasmic side, most probably to the cytoplasmic cation binding site of the Na+/K+-ATPase. An electrogenic reaction of the protein was observed only with Na+, but not with other monovalent cations (K+, Li+, Rb+, Cs+). Using Na+ activation of the enzyme after preincubation with K+ we also investigated the K+-dependent half-cycle of the Na+/K+-ATPase. A rate constant for K+ translocation in the absence of ATP of 0.2-0.3 s-1 was determined. In addition, these experiments show that K+ deocclusion, and cytoplasmic K+ release are electroneutral.

Substitution of glutamic 779 with alanine in the Na,K-ATPase alpha subunit removes voltage dependence of ion transport

The effects of changing Glu-779, located in the fifth transmembrane segment of the Na,K-ATPase alpha subunit, on the phosphorylation characteristics and ion transport properties of the enzyme were investigated. HeLa cells were transfected with cDNA coding the E779A substitution in an ouabain-resistant sheep alpha1 subunit (RD). Steady state phosphorylation stimulated by Na+ concentrations less than 20 mM or by imidazole were similar for RD and E779A enzymes, an indication that phosphorylation and Na+ occlusion were not altered by this mutation. With E779A enzyme, higher Na+ concentrations reduced the level of phosphoenzyme and stimulated Na-ATPase activity in the absence of K+. These effects were a consequence of Na+ increasing the rate of protein dephosphorylation. In voltage-clamped HeLa cells expressing E779A enzyme, a prominent electrogenic Na+-Na+ exchange was observed in the absence of extracellular K+. Thus, increased Na-ATPase activity and Na+-dependent dephosphorylation result from Na+ acting as a K+ congener with low affinity at extracellular binding sites. These data suggest that E779A does not directly participate in ion binding but does affect the connection between extracellular ion binding and intracellular enzyme dephosphorylation. In cells expressing control RD enzyme, Na,K-pump current was dependent on membrane potential and extracellular K+ concentration. However, Na,K-pump current in cells expressing E779A enzyme was voltage independent at all extracellular K+ tested. These results indicate that Glu-779 may be part of the access channel determining the voltage dependence of ion transport by the Na, K-ATPase.

The influence of beta subunit structure on the interaction of Na+/K(+)-ATPase complexes with Na+. A chimeric beta subunit reduces the Na+ dependence of phosphoenzyme formation from ATP

High-affinity ouabain binding to Na+/K(+)-ATPase (sodium- and potassium-transport adenosine triphosphatase (EC 3.6.1.37)) requires phosphorylation of the alpha subunit of the enzyme either by ATP or by inorganic phosphate. For the native enzyme (alpha/beta 1), the ATP-dependent reaction proceeds about 4-fold more slowly in the absence of Na+ than when saturating concentrations of Na+ are present. Hybrid pumps were formed from either the alpha 1 or the alpha 3 subunit isoforms of Na+/K(+)-ATPase and a chimeric beta subunit containing the transmembrane segment of the Na+/K(+)-ATPase beta 1 isoform and the external domain of the gastric H+/K(+)-ATPase beta subunit (alpha/NH beta 1 complexes). In the absence of Na+, these complexes show a rate of ATP-dependent ouabain binding from approximately 75-100% of the rate seen in the presence of Na+ depending on buffer conditions. Nonhydrolyzable nucleotides or treatment of ATP with apyrase abolishes ouabain binding, demonstrating that ouabain binding to alpha/NH beta 1 complexes requires phosphorylation of the protein. Buffer ions inhibit ouabain binding by alpha/NH beta 1 in the absence of Na+ rather than promote ouabain binding, indicating that they are not substituting for sodium ions in the phosphorylation reaction. The pH dependence of ATP-dependent ouabain binding in the presence or absence of Na+ is similar, suggesting that protons are probably not substituting for Na+. Hybrid alpha/NH beta 1 pumps also show slightly higher apparent affinities (2-3-fold) for ATP, Na+, and ouabain; however, these are not sufficient to account for the increase in ouabain binding in the absence of Na+. In contrast to phosphoenzyme formation and ouabain binding by alpha/NH beta 1 complexes in the absence of Na+, ATPase activity, measured as release of phosphate from ATP, requires Na+. These data suggest that the transition from E1P to E2P during the catalytic cycle does not occur when the sodium binding sites are not occupied. Thus, the chimeric beta subunit reduces or eliminates the role of Na+ in phosphoenzyme formation from ATP, but Na+ binding or release by the enzyme is still required for ATP hydrolysis and release of phosphate.

Monoclonal antibody to phosphatidylserine inhibits Na+/K(+)-ATPase activity

A monoclonal IgG, directed to phosphatidylserine (PS1G3), partially (40-50%) inhibited Na+/K(+)-ATPase activity (forward running reaction cycle) without affecting the K0.5 values for Na+,K+ and MgATP. The Hill or interaction coefficients (nH) for Na+ and K+ for this reaction were reduced from 3.0 to 1.6 and from 1.6 to 0.8, respectively. The K(+)-stimulated p-nitrophenylphosphatase activity (p-NPPase), which is a partial reaction sequence of the Na+/K(+)-ATPase system (but in the backward running mode), was inhibited more strongly (about 70%) due to an increase in K+/substrate antagonism. In this system K0.5 and nH values for both p-nitrophenyl phosphate (p-NPP) and K+ were increased by the mAb. At the maximally inhibitory concentration of PS1G3 the Vmax of the p-NPPase was also reduced. Partial reactions, which were inhibited by PS1G3, are: (1) the Na(+)-activated phosphorylation (non-competitive vs. Na+), (2) the Rb+ occlusion (competitive vs. Rb+). Partial reactions not harmed by PS1G3 are: (3) the K(+)-dependent dephosphorylation, (4) the K(+)-dependent E1 + K+<-->E2K transition. We conclude that PtdSer is involved in cation occlusion, possibly by forming part of the access gate.

Binding of ethylenediamine to phosphatidylserine is inhibitory to Na+/K(+)-ATPase

Covalent linkage of ethylenediamine with the Na+/K(+)-ATPase complex from rabbit kidney outer medulla by the use of the water-soluble carbodiimide, N-ethyl,N'-(3-dimethylaminopropyl)carbodiimide, resulted in a 73% reaction with phosphatidylserine and only 27% with carboxylic groups in the proteic component of the enzyme. Condensation products from the reaction between phosphatidylserine and ethylenediamine, N-(O-phosphatidylseryl)ethylenediamine, N,N'-bis(O-phosphatidylseryl)ethylenediamine and its intermediary product O-phosphatidyl-[N,N'-bis(seryl)]ethylenediamine, were synthesised. Symmetrically substituted ethylenediamine was the most likely condensation product of ethylenediamine with endogenous phosphatidylserine. The synthesised lipids were incorporated in proteoliposomes containing Na+/K(+)-ATPase and only the addition of the phospholipid phosphatidylcholine. The ratio of phospholipid to protein was 52 (w/w). These proteoliposomes were perforated by the addition of 0.5% cholate and both the Na(+)-dependent phosphorylation level and its dependence on Na+, Mg2+ and ATP were measured. Phosphatidylcholine alone increased the half-maximal activation concentration for Na+ ([Na+]0.5) from 0.2 to 1-2 mM, for Mg2+ from 0.1 to 0.8 microM and for ATP from 0.02 to 0.3 microM. The Ki for K+ (in the absence of Na+) was unaffected: 12.8 microM vs. 12.5 microM in the non-reconstituted system. Replacing 10 mol% of phosphatidylcholine by phosphatidylethanolamine: or phosphatidylserine had no significant effect on [Na+]0.5: 1.1 and 0.7 mM, respectively. Replacing 5 mol% phosphatidylcholine by the bis(phosphatidylseryl) substituent of ethylenediamine further increased [Na+]0.5 to 13.7 mM, while half-maximal activation concentrations for Mg2+ and ATP were unaltered. The mono-phosphatidylseryl derivatives of ethylenediamine, each 5 mol%, also increased [Na+]0.5, but to a lesser extent (3.2-3.8 mM). In addition to their competitive effects, the phosphatidylseryl-substituted ethylenediamine compounds exerted a slowly-increasing non-competitive inhibition, not only in phosphorylation, but also in overall ATPase activity, which was reduced, although not abolished, by exogenous protein (bovine serum albumin). A detergent-like action in the usual sense is unlikely since liposomes containing these lipids remained intact. These studies prove that phospholipids are not only required for optimal activity of this transport enzyme, but in excess or in compositions deviating from the normal, may also be inhibitory.

Autoregulation of the phosphointermediate of Na+/K(+)-ATPase by the amino-terminal domain of the alpha-subunit

Chymotryptic cleavage of the alpha-subunit of the canine kidney Na+/K(+)-ATPase in the presence of Na+ abolishes ATPase activity and yields an 83 kDa peptide from Ala 267 to the COOH-terminus. To test the proposal that E1 to E2 conformational transition is blocked in this modified enzyme, we have made a detailed comparison of its phosphorylation with that of the native enzyme by ATP. While phosphorylation of alpha is dependent on Na+ and prevented by K+, that of the 83 kDa peptide is modestly stimulated by Na+; and only this stimulation, but not the Na(+)-independent phosphorylation is inhibited by K+. Ouabain, which inhibits alpha-phosphorylation by ATP, activates Na(+)-independent phosphorylation of the 83 kDa peptide by ATP, and inhibits the Na(+)-stimulation of this process. While there is a ouabain-stimulated phosphorylation of alpha by Pi, the 83 kDa peptide is not phosphorylated by Pi with or without ouabain. In its sensitivity to ADP, and insensitivity to K+, the phosphopeptide is similar to the E1P of the native enzyme; however, the spontaneous decomposition rate of the phosphopeptide is orders of magnitude lower than that of the native EP. Na+ has no effect on the spontaneous decomposition of the phosphopeptide; but at high Na+ concentrations (K0.5 = 350 mM) the ADP sensitivity of the phosphopeptide is reduced. The phosphopeptide, like the native EP, is acid-stable, alkaline-labile, and sensitive to hydroxylamine and molybdate. The chymotrypsin-treated enzyme catalyzes an ADP-ATP exchange activity that is stimulated by Na+. The Na(+)-independent part of this exchange, unlike that of the native enzyme, is activated by ouabain. Our findings establish that (a) the phosphorylation process and its control by Na+, K+ and ouabain are autoregulated by the NH2-terminal domain of the alpha-subunit; and (b) the often repeated assumption that the primary role of this domain is in the regulation of E1-E2 transitions is not valid.

Binding of unsaturated fatty acids to Na+, K(+)-ATPase leading to inhibition and inactivation

The effects of free fatty acids on the mechanism of action of Na+, K(+)-ATPase were studied. Unsaturated free fatty acids (palmitoleic acid, oleic acid, linoleic acid and arachidonic acid) inhibited the Na+, K(+)-ATPase activity within a narrow range, while saturated and methylated fatty acids had little or no effect. The following effects of oleic acid were found: (1) The affinity for K+ on the overall ATPase and the p-nitrophenylphosphatase reaction as well as the maximal activities were decreased. (2) The Na(+)-ATPase activity was also inhibited but the '0'-ATPase activity was hardly changed. (3) The steady-state ATP phosphorylation level in the presence of Na+ was not influenced. (4) The dephosphorylation rate constant of the phosphointermediate was slightly decreased, resulting in elevated phosphorylation levels in the absence of Na+. (5) The inhibitory effect of ATP on the dephosphorylation rate was not affected. (6) The K+ sensitivity of the phosphoenzyme in the presence as well as in the absence of Na+ was decreased. (7) Ouabain binding was inhibited. Both the affinity and the number of binding sites were lowered. In addition it was found that Na+, K(+)-ATPase binds oleic acid linearly with the fatty acid concentration up to more than 100 mol oleic acid per mol alpha beta oligomer of Na+, K(+)-ATPase. Prolonged incubation with oleic acid led to irreversible inactivation of the enzyme. This inactivation was dependent on the reaction conditions: ligands, temperature, enzyme concentration, time and fatty acid concentration. The combined presence of inactivation (long term effects) and the effects on the (K(+)-activated) dephosphorylation (short term effects) explain the mixed type inhibition of free fatty acids as observed in assays for K(+)-activated ATPase, K(+)-activated p-nitrophenylphosphatase and ouabain binding. It also explains the sharp inhibition curve in the Na+, K(+)-ATPase activity test.

Phosphorylation of Na+, K(+)-ATPase by ATP in the presence of K+ and dimethylsulfoxide but in the absence of Na+

Purified Na+, K(+)-ATPase was phosphorylated by [gamma-32P]ATP in a medium containing dimethylsulfoxide and 5 mM Mg2+ in the absence of Na+ and K+. Addition of K+ increased the phosphorylation levels from 0.4 nmol phosphoenzyme/mg of protein in the absence of K+ to 1.0 nmol phosphoenzyme/mg of protein in the presence of 0.5 mM K+. Higher velocities of enzyme phosphorylation were observed in the presence of 0.5 mM K+. Increasing K+ concentrations up to 100 mM lead to a progressive decrease in the phosphoenzyme (EP) levels. Control experiments, that were performed to determine the contribution to EP formation from the Pi inevitably present in the assays, showed that this contribution was of minor importance except at high (20-100 mM) KCl concentrations. The pattern of EP formation and its KCl dependence is thus characteristic for the phosphorylation of the enzyme by ATP. In the absence of Na+ and with 0.5 mM K+, optimal levels (1.0 nmol EP/mg of protein) were observed at 20-40% dimethylsulfoxide and pH 6.0 to 7.5. Addition of Na+ up to 5 mM has no effect on the phosphoenzyme level under these conditions. At 100 mM Na+ or higher the full capacity of enzyme phosphorylation (2.2 nmol EP/mg of protein) was reached. Phosphoenzyme formed from ATP in the absence of Na+ is an acylphosphate-type compound as shown by its hydroxylamine sensitivity. The phosphate radioactivity was incorporated into the alpha-subunit of the Na+, K(+)-ATPase as demonstrated by acid polyacrylamide gel electrophoresis followed by autoradiography.

Sidedness of the effect of amines on the steady-state phosphorylation level of reconstituted Na+/K+-ATPase

The sidedness of the effects of several amines on the steady-state phosphorylation level of rabbit kidney Na+/K+-ATPase has been studied with the enzyme incorporated in phosphatidylcholine-cholesterol containing proteoliposomes. The presence of ouabain prevented phosphorylation of non-incorporated or rightside-out incorporated enzyme, so that only the inside-out incorporated Na+/K+-ATPase molecules were studied. Addition of either Na+ or several amines to the extracellular side of the enzyme led to an enhancement of the steady-state phosphorylation level obtained with optimal concentrations of Na+, Mg2+ and ATP at the cytosolic side. The series imidazole greater than Na+ greater than triallylamine greater than Tris greater than ethylenediamine showed a decrease in affinity. Histidine, sorbitol and choline chloride had no effect at the extracellular side. This means that in addition to the well-known cytosolic ligands either Na+ or a positively charged amine buffer has to be present extracellularly in order to obtain an optimal phosphorylation level. At the cytoplasmic side the tested amines exerted different effects. (i) Imidazole and triallylamine enhanced the steady-state phosphorylation level when the extracellular conditions were optimal (saturating amine concentration). (ii) Tris and ethylenediamine decreased the steady-state phosphorylation level and (iii) histidine had no effect. The cytoplasmic effects of the amine compounds correlate with those described by Schuurmans Stekhoven et al. (Biochim. Biophys. Acta 937 (1988) 161-171) for the unsided preparation. The extracellular effects, however, are apparently masked in experiments with fragmented enzyme preparations and are assumed to be potentiating effects which make the enzyme ready for phosphorylation upon a cytoplasmic trigger (e.g. Na+).

Cation sidedness in the phosphorylation step of Na+/K+-ATPase

Na+/K+ -ATPase, reconstituted into phospholipid vesicles, has been used to study the localisation of binding sites of ligands involved in the phosphorylation reaction. Inside-out oriented Na+/K+ -ATPase molecules are the only population in this system, which can be phosphorylated, as the rightside-out oriented as well as the non-incorporated enzyme molecules are inhibited by ouabain. In addition, the right-side-out oriented Na+/K+ -ATPase molecules have their ATP binding site intravesicularly and are thus not accessible to substrate added to the extravesicular medium. Functional binding sites for the following ligands have been demonstrated: (i) Potassium, acting at the extracellular side with high affinity (stimulating the dephosphorylation rate of the E2P conformation) and low affinity (inducing the non-phosphorylating E2K complex). (ii) Potassium, acting at the cytoplasmic side with both high and low affinity. The latter sites are also responsible for the formation of an E2K complex and complete with Na+ for its binding sites. (iii) Sodium at the cytoplasmic side responsible for stimulation of the phosphorylation reaction. (iv) Sodium (and amine buffers) at the extracellular side enhancing the phosphorylation level of Na+/K+ -ATPase where choline chloride has no effect. (v) Magnesium at the cytoplasmic side, stimulating the phosphorylation reaction and inhibiting it above optimal concentrations.

Ethylenediamine as active site probe for Na+/K+-ATPase

(1) Ethylenediamine is an inhibitor of Na+- and K+-activated processes of Na+/K+-ATPase, i.e. the overall Na+/K+-ATPase activity, Na+-activated ATPase and K+-activated phosphatase activity, the Na+-activated phosphorylation and the Na+-free (amino-buffer associated) phosphorylation. (2) The I50 values (I50 is the concentration of inhibitor that half-maximally inhibits) increase with the concentration of the activating cations and the half-maximally activating cation concentrations (Km values) increase with the inhibitor concentration. (3) Ethylenediamine is competitive with Na+ in Na+-activated phosphorylation and with the amino-buffer (triallylamine) in Na+-free phosphorylation. Significant, though probably indirect, effects can also be noted on the affinity for Mg2+ and ATP, but these cannot account for the inhibition. (4) Inhibition parallels the dual protonated or positively charged ethylenediamine concentration (charge distance 3.7 A). (5) Direct investigation of interaction with activating cations (Na+, K+, Mg+, triallylamine) has been made via binding studies. All these cations drive ethylenediamine from the enzyme, but K+ and Mg+ with the highest efficiency and specificity. Ethylenediamine binding is ouabain-insensitive, however. (6) Ethylenediamine neither inhibits the transition to the phosphorylation enzyme conformation, nor does it affect the rate of dephosphorylation. Hence, we provisionally conclude that ethylenediamine inhibits the phosphoryl transfer between the ATP binding and phosphorylation site through occupation of cation activation sites, which are 3-4 A apart.

Some total and partial reactions of Na+/K+-ATPase using ATP and acetyl phosphate as a substrate

Acetyl phosphate, as a substrate of (Na+ + K+)-ATPase, was further characterized by comparing its effects with those of ATP on some total and partial reactions carried out by the enzyme. In the absence of Mg2+ acetyl phosphate could not induce disocclusion (release) of Rb+ from E2(Rb); nor did it affect the acceleration of Rb+ release by non-limiting concentrations of ADP. In K+-free solutions and at pH 7.4 sodium ions were essential for ATP hydrolysis by (Na+ + K+)-ATPase; when acetyl phosphate was the substrate a hydrolysis (inhibited by ouabain) was observed in the presence and absence of Na+. In liposomes with (Na+ + K+)-ATPase incorporated and exposed to extravesicular (intracellular) Na+, acetyl phosphate could sustain a ouabain-sensitive Rb+ efflux; the levels of that flux were similar to those obtained with micromolar concentrations of ATP. When the liposomes were incubated in the absence of extravesicular Na+ a ouabain-sensitive Rb+ efflux could not be detected with either substrate. Native (Na+ + K+)-ATPase was phosphorylated at 0 degrees C in the presence of NaCl (50 mM for ATP and 10 mM for acetyl phosphate); after phosphorylation had been stopped by simultaneous addition of excess trans-1,2-diaminocyclohexane-N,N,N',N' tetraacetic acid and 1 M NaCl net synthesis of ATP by addition of ADP was obtained with both phosphoenzymes. The present results show that acetyl phosphate can fuel the overall cycle of cation translocation by (Na+ + K+)-ATPase acting only at the catalytic substrate site; this takes place via the formation of phosphorylated intermediates which can lead to ATP synthesis in a way which is indistinguishable from that obtained with ATP.

Phosphorylation of (Na+ + K+)-ATPase; stimulation and inhibition by substituted and unsubstituted amines

(1) In view of a previously established stimulation of steady-state phosphorylation of (Na+ + K+)-ATPase by imidazole and its inhibition by tris(hydroxymethyl)aminomethane, the effect of (structure, chemical composition and charge of) a number of primary, secondary and tertiary amines (including imidazole derivatives) has been investigated. (2) Primary amines are predominantly inhibitory and diamines are more inhibitory than monoamines. The strongest inhibition is exerted by ethylenediamine (I50 in 50 mM imidazole = 25 microM, vs. 60 mM for n-propylamine). Increasing the distance between the two amino groups from 3.7 to 8.7 A increases the I50 180-fold. The optimal distance of 3-4 A indicates a similar distance between two ligand(presumably Na+)-binding sites on the enzyme. (3) Screening or substitution of the central N-atom decreases inhibition by the nitrogen compound. Triple substitution by propyl or allyl groups leads to maximal activation, amounting to about 90% of the Na+-activation level. Triethyl substitution gives suboptimal activation and tributyl substitution leads to inhibition. Substitution by polar or negatively charged carboxyl groups diminishes or even abolishes inhibition and also diminishes or abolishes activation. (4) Although occasionally positive charge is not required for inhibition, it is prerequisite for activation. Within certain families of compounds (e.g., ethylenediamine and imidazole derivatives) inhibition or activation increases with pKa, hence with positive charge. (5) The above data are interpreted in terms of inhibition, which is competitive to Na+, being governed by Coulomb interaction. Activation, on the other hand, is predominantly determined by lipophilic (van der Waals or pi-pi electron) interactions, excluding water from the phosphorylation site, hence decreasing phosphoenzyme hydrolysis and increasing the phosphoenzyme level. The requirement of charge (though hidden by substitution) implies weak additional electrostatic interaction.

Pb2+ and imidazole-activated phosphorylation by ATP of (Na+ + K+)-ATPase

In order to study whether Pb2+ and imidazole increase the ATP phosphorylation level of (Na+ + K+)-ATPase by the same mechanism, the effects of both compounds on phosphorylation and dephosphorylation reactions of the enzyme have been studied. Imidazole in the presence of Mg2+ increases steady-state phosphorylation of (Na+ + K+)-ATPase by decreasing, in a competitive way, the K+-sensitivity of the formed phospho-enzyme (E-P . Mg). If Pb2+ is present during phosphorylation, the rate of phosphorylation increases and a K+- and ADP-insensitive phosphointermediate (E-P . Pb) is formed. Pb2+ has no effect on the K+-sensitivity of E-P . Mg and EDTA is unable to affect the K+-insensitivity of E-P . Pb. These effects indicate that Pb2+ acts before or during phosphorylation with the enzyme. Binding of Na+ to E-P . Pb does not restore K+-sensitivity either. However, increasing Na+ during phosphorylation in the presence of Pb2+ leads to formation of the K+-sensitive intermediate (E-P . Mg), indicating that E-P . Pb is formed via a side path of the Albers-Post scheme. ATP and ADP decrease the dephosphorylation rate of both E-P . Mg and E-P . Pb. Above optimal concentration, Pb2+ also decreases the steady-state phosphorylation level both in the absence and in the presence of Na+. This inhibitory effect of Pb2+ is antagonized by Mg2+.

Buffer, pH, and ionic strength effects on the (Na+ + K+)-ATPase

A dog kidney (Na+ + K+)-ATPase preparation also catalyzes K+-independent and K+-activated phosphatase reactions with p-nitrophenyl phosphate as substrate. K+-independent activity increases with declining pH over the range 7.5 to 5.8, whereas the other two activities decrease. The increased K+-independent activity is similar with imidazole, histidine, and several Good buffers, and is thus attributable to free H+, probably by affecting enzyme conformations rather than by changing affinity for Mg2+ or substrate or by H+ occupying specific K+-sites. The decrease in K+-phosphatase and (Na+ + K+)-ATPase activities with pH also occurs similarly with those buffers, and is not due to changes in apparent affinity for substrate or for cation activators. However, the Good buffers Pipes and ADA inhibit the K+-independent phosphatase reaction strongly, the K+-activated reaction moderately, and the (Na+ + K+)-ATPase reaction little; both contain two acidic groups, unlike the other buffers tested. Inhibition of the phosphatase reaction by Pipes is associated with a decreased apparent affinity for K+ and an increased sensitivity to inhibition by Na+ and ADP, consistent with Pipes hindering conformational transitions to the E2 enzyme forms required for phosphatase hydrolytic activity.

Nucleotide specificity of the E2K----E1K transition in (Na+ + K+)-ATPase as probed with tryptic inactivation and fragmentation

The nucleotide specificity for the E2K----E1K conformational transition in (Na+ + K+)-ATPase as the key step for overall hydrolytic activity and coupled cation transport has been investigated. Use has been made of tryptic inactivation, which is biexponential in time for the enzyme in the presence of Na+ with or without nucleotides (E1 conformation) and monoexponential in the presence of K+ (E2 conformation). ATP, AdoPP[NH]P and CTP in order of decreasing effectivity induce the biphasic tryptic inactivation pattern in the presence of K+. Their order of effectivity is inversely related to the rate constant of the second (slow) phase of inactivation. In the presence of K+ and either ITP or GTP tryptic inactivation remains monoexponential, indicating that these nucleotides cannot drive the E2K----E1K transition. Tryptic inactivation has been compared with tryptic fragmentation of the alpha-subunit (apparent mol. wt. 94 kDa) of (Na+ + K+)-ATPase. In the E1 conformation (Na+ present) a 71 kDa fragment is formed during the second phase of inactivation. In the E2 conformation (K+ present) the alpha-subunit is split to fragments of 41 and 52 kDa. In the presence of K+ and ATP, ADP, AdoPP[NH]P or CTP the 71 kDa fragment is formed in amounts which decrease in the order ATP approximately equal to ADP greater than AdoPP[NH]P greater than CTP. In the presence of K+ and AMP, ITP or GTP the 71 kDa fragment is absent and only the E2 fragments are formed. From these and literature data we arrive at a specificity order for the E2K----E1K transition of ATP greater than ADP greater than AdoPP[NH]P greater than CTP greater than ITP = GTP = AMP. The same order holds for K+ transport in the K+-K+ exchange and for overall hydrolytic activity (Na+ + K+ present) with the natural nucleoside triphosphates as substrates. This marks the E2K----E1K transition as the step in the reaction mechanism that determines nucleotide specificity for (Na+ + K+)-activated hydrolysis and coupled cation transport.

Chromium(III)ATP inactivating (Na+ + K+)-ATPase supports Na+-Na+ and Rb+-Rb+ exchanges in everted red blood cells but not Na+,K+ transport

The chromium(III) complex of ATP, an MgATP complex analogue, inactivates (Na+ + K+)-ATPase by forming a stable chromo-phosphointermediate. The rate constant k2 of inactivation at 37 degrees C of the beta, gamma-bidentate of CrATP is enhanced by Na+ (K0.5 = 1.08 mM), imidazole (K0.5 = 15 mM) and Mg2+ (K0.5 = 0.7 mM). These cations did not affect the dissociation constant of the enzyme-chromium-ATP complex. The inactive chromophosphoenzyme is reactivated slowly by high concentrations of Na+ at 37 degrees C. The half-maximal effect on the reactivation was reached at 40 mM NaCl, when the maximally observable reactivation was studied. However, 126 mM NaCl was necessary to see the half-maximal effect on the apparent reactivation velocity constant. K+ ions hindered the reactivation with a Ki of 70 microM. Formation of the chromophosphoenzyme led to a reduction of the Rb+ binding sites and of the capacity to occlude Rb+. The beta, gamma-bidentate of chromium(III)ATP (Kd = 8 microM) had a higher than the alpha, beta, gamma-tridentate of chromium(III)ATP (Kd = 44 microM) or the cobalt tetramine complex of ATP (Kd = 500 microM). The beta, gamma-bidentate of the chromium(III) complex of adenosine 5'-[beta, gamma-methylene]triphosphate also inactivated (Na+ + K+)ATPase. Although CrATP could not support Na+, K+ exchange in everted vesicles prepared from human red blood cells, it supported the Na+-Na+ and Rb+-Rb+ exchange. It is concluded that CrATP opens up Na+ and K+ channels by forming a relatively stable modified enzyme-CrATP complex. This stable complex is also formed in the presence of the chromium complex of adenosine 5'-[beta, gamma-methylene]triphosphate. Because the beta, gamma-bidentate of chromium ATP is recognized better than the alpha, beta, gamma-tridentate, it is concluded that the triphosphate site recognizes MgATP with a straight polyphosphate chain and that the Mg2+ resides between the beta- and the gamma-phosphorus. The enhancement of inactivation by Mg2+ and Na+ may be caused by conformational changes at the triphosphate site.

Sodium and buffer cations inhibit dephosphorylation of (Na+ + K+)-ATPase

Effects of various cations on the dephosphorylation of (Na+ + K+)-ATPase, phosphorylated by ATP in 50 mM imidazole buffer (pH 7.0) at 22 degrees C without added Na+, have been studied. The dephosphorylation in imidazole buffer without added K+ is extremely sensitive to K+-activation (Km K+ = 1 microM), less sensitive to Mg2+-activation (Km Mg2+ = 0.1 mM) and Na+-activation (Km Na+ = 63 mM). Imidazole and Na+ effectively inhibit K+-activated dephosphorylation in linear competitive fashion (Ki imidazole 7.5 mM, Ki Na+ 4.6 mM). The Ki for Na+ is independent of the imidazole concentration, indicating different and non-interacting inhibitory sites for Na+ and imidazole. Imidazole inhibits Mg2+-activated dephosphorylation just as effective as K+-activated dephosphorylation, as judged from the Ki values for imidazole in the two processes. Tris buffer and choline chloride, like imidazole, inhibit dephosphorylation in the presence of residual K+ (less than 1 microM), but less effectively in terms of I50 values and extent of inhibition. Tris inhibits to the same extent as choline. This indicates different inhibitory sites for Tris or choline and for imidazole. These findings indicate that high steady-state phosphorylation levels in Na+-free imidazole buffer are due to the induction of a phosphorylating enzyme conformation and to the inhibition of (K+ + Mg2+)-stimulated dephosphorylation.

Free protons do not substitute for sodium ions in buffer-mediated phosphorylation of (Na+ + K+)-ATPase

In view of our recent finding of imidazole-activation of the phosphorylation of (Na+ + K+)-ATPase and the suggestion by others of an activating role of protons, in lieu of sodium ions, in the overall hydrolytic and phosphorylation processes of the enzyme, we have investigated the effect of pH on the phosphorylation process. No indication of proton activation is found. Rather, phosphorylation at low pH in the absence of Na+ is dependent on the buffer concentration. Imidazole-H+ stimulated phosphorylation at pH 5 reaches the same maximal steady-state level as Na+-stimulated phosphorylation. Low pH also elicits Tris-H+ stimulated phosphorylation, but due to a simultaneous inhibitory effect of this buffer the maximal steady-state level is no more than 50% of the Na+-stimulated phosphorylation level. Protons inhibit rather than activate phosphorylation. Upon decreasing the pH from 7 to 5, we observe for all ligands, whether activating or inhibiting phosphorylation (ATP, Na+, protonated imidazole, Mg2+ and K+), a decrease in affinity (largest for Mg2+) and a decrease in the maximal steady-state phosphorylation capacity. The effects of Na+ and imidazole-H+ on the phosphorylation step have been compared with those on the E2----E1 conformational change, which leads to the phosphorylation step. The different pH-dependence of the affinities for Na+ and protonated buffer in the E2----E1 transition suggests that there are separate activation sites with different pK values for Na+ and the buffer cation. The above findings rule out a role of free protons as a substitution for Na+ in the phosphorylation process.