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+.     

The effect of pH, of ATP and of modification with pyridoxal 5-phosphate on the conformational transition between the Na+-form and the K+-form of the (Na+ +K+)-ATPase

An increase in pH decreases the Na+ concentration (Na+ +K+ = 150 mM) necessary for half-maximum activation of the (Na+ +K+)-ATPase at non-saturating concentrations of ATP just as an increase in the concentration of ATP at a given pH. It also decreases the concentration of Na+ necessary for transformation from the K+-form to the Na+-form at equilibrium conditions (Na+ +K+ = 150 mM). An increase in pH increases the rate of the transformation from the K+-form to the Na+-form of the system and decreases the rate of the reverse reaction. The pH effect on the conformation suggests that the K+-form is a protonated form and the Na+-form a deprotonated one. The similarity between the effect of an increase in pH with non-saturating concentrations of ATP and that of an increase in ATP at a given pH suggests that ATP exerts its effect on the transformation from the K+ - to the Na+-form by a decrease in pK values of the system, i.e., by releasing protons, a Bohr effect. Enzyme modified by reaction with pyridoxal 5-phosphate terminated by NaBH4 behaves at a given pH as if it were non-modified enzyme but at a higher pH. The 'pH effect' is seen after modification by pyridoxal 5-phosphate in the presence of ATP, of Na+ without and with ATP, of K+ with ATP but not in the presence of K+ alone. The modification has also a 'pH effect' on the rate of the transformation from the K+ -form to the Na+ -form and on the reverse reaction. There are at least two different pyridoxal 5-phosphate-reactive groups (amino groups), one which can be protected by ATP and which is of importance for activity and another which is not protected by ATP and which is of importance for the pH effect on the conformation. The effect of a protonation-deprotonation of amino groups on the conformation is explained by an involvement of the amino groups in salt bridge formation in between and inside the polypeptide chains, a hemoglobin-like situation. The protonated K+ -form is then a tense T-structure with a high K+, low Na+ affinity and the deprotonated Na+ -form a relaxed, R-structure with high Na+, low K+ affinity. ATP facilitates deprotonation by decreasing pK values. Oligomycin has 'pH effect' on the K0.5 for Na+ under equilibrium and steady-state conditions, but oligomycin has no effect on the rate of the transformation from the K+ -form to the Na+ -form, but gives a pronounced decrease of the rate of the reverse reaction, indicating that oligomycin does not react with the K+ -form but with the Na+ -form of the system and prevents the protonation, the E1 to E2 transformation.     

Effect of membrane potential and internal pH on active sodium-potassium transport and on ATP content in high-potassium sheep erythrocytes.

Ouabain-sensitive Na+ and K+ fluxes and ATP content were determined in high potassium sheep erythrocytes at different values of membrane potential and internal pH. Membrane potential was adjusted by suspending erythrocytes in media containing different concentrations of MgCl2 and sucrose. Concomitantly either the external pH was changed sufficiently to maintain a constant internal pH or the external pH was kept constant with a resultant change of internal pH. The erythrocytes were preincubated before the flux experiment started in a medium which produced increased ATP content in order to avoid substrate limitation of the pump. It was found that an increased cellular pH reduced the rates of active transport of Na+ and K+ without significantly altering the ratio of pumped Na+/K+. This reduction was not due to limitation in the supply of ATP although ATP content decreased when internal pH increased. Changes of membrane potential in the range between -10 and +60 mV at constant internal pH did not affect the rates of active transport of Na+ or K+.     

Protons as substitutes for sodium and potassium in the sodium pump reaction

The role of protons as substitutes for Na+ and/or K+ in the sodium pump reaction was examined using inside-out membrane vesicles derived from human red cells. Na+-like effects of protons suggested previously (Blostein, R. (1985) J. Biol. Chem. 260, 829-833) were substantiated by the following observations: (i) in the absence of extravesicular (cytoplasmic) Na+, an increase in cytoplasmic [H+] increased both strophanthidin-sensitive ATP hydrolysis (nu) and the steady-state level of phosphoenzyme, EP, and (ii) as [H+] is increased, the Na+/ATP coupling ratio is decreased. K+-like effects of protons were evidenced in the following results: (i) an increase in nu, decrease in EP, and hence increase in EP turnover (nu/EP) occur when intravesicular (extracellular) [H+] is increased; (ii) an increase in the rate of Na+ influx into K+(Rb+)-free inside-out vesicles and (iii) a decrease in Rb+/ATP coupling occur when [H+] is increased. Direct evidence for H+ being translocated in place of cytoplasmic Na+ and extracellular K+ was obtained by monitoring pH changes using fluorescein isothiocyanate-dextran-filled vesicles derived from 4',4-diisothiocyano-2',2-stilbene disulfonate-treated cells. With the initial pHi = pHo = pH 6.2, a strophanthidin-sensitive decrease in pHi was observed following addition of ATP provided the vesicles contained K+. This pH gradient was abolished following addition of Na+. With alkali cation-free inside-out vesicles, a strophanthidin-sensitive increase in pH was observed upon addition of both ATP and Na+. The foregoing changes in pHi were not affected by the addition of tetrabutylammonium to dissipate any membrane potential and were not observed at pH 6.8. These ATP-dependent cardiac glycoside-sensitive proton movements indicate Na,K-ATPase mediated Na+/H+ exchange in the absence of extracellular K+ as well as H+/K+ exchange in the absence of cytoplasmic Na+.     

The ATPases of Propionigenium modestum and Bacillus alcalophilus. Strategies for ATP synthesis under low energy conditions.

In Propionigenium modestum, ATP synthesis is coupled via delta mu Na+ to the decarboxylation of (S)-methylmalonyl-CoA. The low energy yield of this reaction implies that approx. 4 decarboxylation cycles are necessary to synthesize 1 molecule of ATP. Theoretical considerations in accord with experimental results suggest ATP synthesis in P. modestum at delta mu Na+ = -110 mV. Other anaerobic bacteria synthesize ATP at a delta mu H+ of similar size and alkaliphilic bacteria at pH 10.3 have a delta mu H+ of only -103 mV. In these cases, the H+(Na+) to ATP stoichiometry must be at least 4.     

Sodium-coupled ATP synthesis in the bacterium Vitreoscilla.

The bacterium Vitreoscilla generates an electrical potential gradient due to sodium ion (delta psi Na+) across its membrane via respiratory-driven primary Na+ pump(s). The role of the delta psi Na+ as a driving force for ATP synthesis was, therefore, investigated. In respiring starved cells pulsed with 100 mM external Na+ [( Na+]o) there was a 167% net increase in cellular ATP concentration over basal levels compared with 0, 56, 78, and 78% for no addition, choline, Li+, and K+ controls, respectively. Doubling the [Na+]o to 200 mM boosted the net increase to 244% but a similar doubling of the choline caused only an increase to 78%. When the initial condition was intracellular Na+ ([Na+]i) = [Na+]o = 100 mM, there was a 94% net increase in cellular ATP compared with only 18 and 11% for Li+ and K+ controls, respectively, indicating that Nai+ may be the only cation tested that the cells extruded to generate the electrochemical gradient required to drive ATP synthesis. The Na(+)-dependent ATP synthesis was inhibited completely by monensin (12 microM), but only transiently by the protonophore 3,5-di-tert-butyl-4-hydroxybenzaldehyde (100 microM), further evidence that the Na+ gradient and not a H+ gradient was driving the ATP synthesis. ATP synthesis in response to an artificially imposed H+ gradient (delta pH approximately 3) in the absence of an added cation, or in the presence of Li+, K+, or choline, yielded similar delta ATP/delta pH ratios of 0.98-1.22. In the presence of Na+, however, this ratio dropped to 0.23, indicating that Na+ inhibited H(+)-coupling to ATP synthesis and possibly that H+ and Na+ coupling to ATP synthesis share a common catalyst. The above evidence adds to previous findings that under normal growth conditions Na+ is probably the main coupling cation for ATP synthesis in Vitreoscilla.     

Increased permeability and subsequent resealing of the host cell membrane early after infection of Escherichia coli with bacteriophage T1.

The addition of T1 to cells growing at 37 degrees C in a minimal medium at 0.4 mM Mg2+ rapidly induced an irreversible loss of K+ and Mg2+ and uptake of Na+ by the cells. Both the ATP pool of the cells and the transmembrane proton motive force were reduced. These cells did not lyse from within, since viral DNA replication and the maturation of the 36,000-molecular-weight phage head protein were inhibited. By contrast, cells lysed when infected at 5.4 mM Mg2+. In these cells, T1 initially induced K+ efflux and Na+ influx and lowered the cytoplasmic ATP concentration. After a few minutes, the cation gradients and ATP pool were restored to levels close to that of control cells. At 5.4 mM Mg2+, the shutoff of host protein synthesis was delayed and coincided with the restoration of the ATP pool. In an ATP synthase-negative mutant, infection with T1 did not affect the cytoplasmic ATP concentration but inhibited host protein synthesis with the same rate as it did in wild-type cells.     

Binding of Na+ ions to the Na,K-ATPase increases the reactivity of an essential residue in the ATP binding domain

Treatment of the canine renal Na,K-ATPase with N-(2-nitro-4-isothiocyanophenyl)-imidazole (NIPI), a new imidazole-based probe, results in irreversible loss of enzymatic activity. Inactivation of 95% of the Na,K-ATPase activity is achieved by the covalent binding of 1 molecule of [3H]NIPI to a single site on the alpha-subunit of the Na,K-ATPase. The reactivity of this site toward NIPI is about 10-fold greater when the enzyme is in the E1Na or sodium-bound form than when it is in the E2K or potassium-bound form. K+ ions prevent the enhanced reactivity associated with Na+ binding. Labeling and inactivation of the enzyme is prevented by the simultaneous presence of ATP or ADP (but not by AMP). The apparent affinity with which ATP prevents the inactivation by NIPI at pH 8.5 is increased from 30 to 3 microM by the presence of Na+ ions. This suggests that the affinity with which native enzyme binds ATP (or ADP) at this pH is enhanced by Na+ binding to the enzyme. Modification of the single sodium-responsive residue on the alpha-subunit of the Na,K-ATPase results in loss of high affinity ATP binding, without affecting phosphorylation from Pi. Modification with NIPI probably alters the adenosine binding region without affecting the region close to the phosphorylated carboxyl residue aspartate 369. Tightly bound (or occluded) Rb+ ions are not displaced by ATP (4 mM) in the inactivated enzyme. Thus modification of a single residue simultaneously blocks ATP acting with either high or low affinity on the Na,K-ATPase. These observations suggest that there is a single residue on the alpha-subunit (probably a lysine) which drastically alters its reactivity as Na+ binds to the enzyme. This lysine residue is essential for catalytic activity and is prevented from reacting with NIPI when ATP binds to the enzyme. Thus, the essential lysine residue involved may be part of the ATP binding domain of the Na,K-ATPase.     

The influence of cellular amino acids and the Na+ : K+ pump on the membrane potential of the Ehrlich ascites tumor cell.

The membrane potential of the Ehrlich ascites tumor cell was shown to be influenced by its amino acid content and the activity of the Na+ :K+ pump. The membrane potential (monitored by the fluorescent dye, 3,3'-dipropylthiodicarbocyanine iodide) varied with the size of the endogenous amino acid pool and with the concentration of accumulated 2-aminoisobutyrate. When cellular amino acid content was high, the cells were hyperpolarized; as the pool declined in size, the cells were depolarized. The hyperpolarization seen with cellular amino acid required cellular Na+ but not cellular ATP. Na+ efflux was more rapid from cells containing 2-aminoisobutyrate than from cells low in internal amino acids. These observations indicate that the hyperpolarization recorded in cells with high cellular amino acid content resulted from the electrogenic co-efflux of Na+ and amino acids. Cellular ATP levels were found to decline rapidly in the presence of the dye and hence the influence of the pump was seen only if glucose was added to the cells. When the cells contained normal Na+ (approx. 30mM), the Na+ :K+ pump was shown to have little effect on the membrane potential (the addition of ouabain had little effect on the potential). When cellular Na+ was raised to 60mM, the activity of the pump changed the membrane potential from the range -25 to -30 mV to -44 to -63 mV. This hyperpolarization required external K+ and was inhibited by ouabain.     

Na+/H+ exchange in Ehrlich ascites tumor cells. Regulation by extracellular ATP and 12-O-tetradecanoylphorbol 13-acetate

The effects of extracellular ATP and/or the phorbol ester 12-O-tetradecanoylphorbol-13-acetate (TPA) on the intracellular pH of Ehrlich ascites tumor cells were measured using both distribution of [14C]5,5-dimethyloxazolidine-2,4-dione, and the fluorescent indicator 5(6)-carboxyfluorescein. Micromolar concentrations of extracellular ATP induce a biphasic change in the intracellular pH characterized by a rapid acidification of 0.04 pH units followed by an alkalinization of 0.11 pH units. Concurrently with the alkalinization, an increase in the total cellular [Na+] from 37.5 to 45.0 mM is observed. The pH change is half-maximally activated by 0.5-2.5 microM extracellular ATP. The intracellular alkalinization, but not the initial acidification, phase requires extracellular Na+, with half-maximal alkalinization in the presence of 24-32 mM Na+, and is inhibited by amiloride. Exposure of Ehrlich ascites tumor cells to TPA alone produces a slight alkalinization of approximately 0.04 pH units. Conversely, preincubation of the cells with TPA partially inhibits the ATP-induced changes in intracellular pH. Under identical conditions TPA also inhibits the ATP-induced increase in the cytosolic [Ca2+]. The half-maximal dose for both effects is produced by 3-10 nM TPA. These data indicate that extracellular ATP triggers the activation of Na+/H+ exchange. Furthermore, activation of protein kinase C mediates at least part of the Na+/H+ exchange, although a second mechanism may also exist.     

The membrane ATPase of alkalophilic Bacillus firmus RAB is an F1-type ATPase

At the optimal pH for growth (pH 10.5), alkalophilic Bacillus firmus RAB, an obligate aerobe, exhibits normal rates of oxidative phosphorylation despite the low transmembrane proton electrochemical gradient, about -60 mV (delta psi = -180 mV and delta pH = +120 mV). This bioenergetic problem might be resolved by use of an Na+ coupled ATP synthase; otherwise an F1F0-ATPase must be able to utilize low driving forces in this organism. The ATPase activity was extracted from everted membrane vesicles by low ionic strength treatment and purified to homogeneity by hydrophobic interaction chromatography and sucrose density gradient centrifugation. The ATPase preparation had the characteristic F1-ATPase subunit structure, with Mr values of 51,500 (alpha), 48,900 (beta), 34,400 (gamma), 23,300 (delta), and 14,500 (epsilon); the identity of the alpha and beta subunits was confirmed by immunoblotting with anti-beta of Escherichia coli and anti-B. firmus RAB F1. Methanol and octyl glucoside, agents that stimulated the low basal membrane ATPase activity 10- to 12-fold, dramatically elevated the MgATPase activity of the purified F1, more than 150-fold, to 50 mumol min-1 mg protein-1. Anti-F1 inhibited membrane ATPase activity greater than or equal to 80%. The membranes exhibited no Na+-stimulated or vanadate-sensitive ATPase activity when prepared in the absence or presence of Na+ or ATP. These findings, which are consistent with previous studies, establish that in alkalophilic bacteria, ATP hydrolysis, and presumably ATP synthesis is catalyzed by an F1F0-ATPase rather than a Na+ ATPase.     

Bioenergetics of methanogenesis from acetate by Methanosarcina barkeri.

Methane formation from acetate by resting cells of Methanosarcina barkeri was accompanied by an increase in the intracellular ATP content from 0.9 to 4.0 nmol/mg of protein. Correspondingly, the proton motive force increased to a steady-state level of -120 mV. The transmembrane pH gradient however, was reversed under these conditions and amounted to +20 mV. The addition of the protonophore 3,5,3',4'-tetrachlorosalicylanilide led to a drastic decrease in the proton motive force and in the intracellular ATP content and to an inhibition of methane formation. The ATPase inhibitor N,N'-dicyclohexylcarbodiimide stopped methanogenesis, and the intracellular ATP content decreased. The proton motive force decreased also under these conditions, indicating that the proton motive force could not be generated from acetate without ATP. The overall process of methane formation from acetate was dependent on the presence of sodium ions; upon addition of acetate to cell suspensions of M. barkeri, a transmembrane Na+ gradient in the range of 4:1 (Na+ out/Na+ in) was established. Possible sites of involvement of the Na+ gradient in the conversion of acetate to methane and carbon dioxide are discussed. Na+ is not involved in the CO dehydrogenase reaction.     

Extracellular ATP induces ion fluxes and inhibits growth of Friend erythroleukemia cells

Extracellular ATP (1 mM) inhibited the growth of Friend virus-infected murine erythroleukemia cells (MEL cells) but had no effect on dimethyl sulfoxide-induced differentiation. ATP (1 mM) also caused changes in the permeability of MEL cells to ions. There was an increased influx of 45Ca2+ from a basal level of 5 pmol/min to 18 pmol/min/10(6) cells to achieve a 2-fold increase in steady-state Ca2+ as measured at isotopic equilibration. Ca2+ influx was blocked by diisothiocyanostilbene disulfonate (DIDS), an inhibitor of anion transport. ATP also stimulated Cl- uptake, and this flux was inhibited by DIDS. The ratio of ATP stimulated Cl- to Ca2+ uptake was 1.6:1. K+ and Na+ influx were also stimulated by ATP, but phosphate uptake was inhibited; the Na+ influx dissipated the Na+ gradient and thus inhibited nutrient uptake. ATP-stimulated K+ influx was ouabain inhibitable; however, the total cellular K+ decreased due to an ATP-stimulated ouabain-resistant K+ efflux. Na+ influx and Ca2+ influx occurred by separate independent routes, since Na+ influx was not inhibited by DIDS. The effects observed were specific for ATP *K1/2 MgATP = 0.7 mM) since AMP, GTP, adenosine, and the slowly hydrolyzable ATP analogue adenyl-5'-yl imidodiphosphate were without effect. The major ionic changes in the cell were a decrease in K+ and increase in Na+; cytoplasmic pH and free Ca2+ did not change appreciably. These ATP-induced changes in ion flux are considered to be responsible for growth inhibition.     

Early stimulation of ATP turnover by EGF + insulin. Relation to external pH and Na+/H+ exchange system

We previously shown a rapid increase in ATP turnover after addition of epidermal growth factor and insulin to quiescent 3T3 cell cultures. Here, the relationship between this increase in ATP turnover and the activation by growth factors of Na+/H+ and Na+/K+ exchange systems was studied. Our results show that alkalinization of the medium enhances ATP turnover but they do not support the assumption that stimulation by growth factors of the Na+/H+ exchange induces an increase in ATP turnover since this increase was not inhibited by amiloride. Conversely, when ATP synthesis was abolished, the increase, in intracellular pH, by growth factors, was significantly decreased.     

Simultaneous bindings of ATP and vanadate to (Na+ + K+)-ATPase. Implications for the reaction mechanism of the enzyme

Inhibition of (Na+ + K+)-dependent adenosine triphosphatase phosphatase by vanadate is thought to occur through the tight binding of vanadate to the same site from which Pi is released. To see if ATP binds to [48V] vanadate-enzyme complex, just as it does to the phosphoenzyme, the effects of Na+, K+, and ATP on the dissociation rate of the complex at 10 degrees C were studied. The rate constant was increased by Na+, and this increase was blocked by K+, indicating that either Na+ or K+ binds to the complex. ATP alone, or in combination with K+, had no effect on the rate constant. In the presence of Na+, however, ATP caused a further increase in the rate constant. The value of K0.5 of Na+ was the same in the presence or absence of ATP; K0.5 of ATP (0.2 mM) did not seem to change significantly when Na+ concentration was varied, and K0.5 of K+, at a constant Na+ concentration, was the same in the presence or absence of ATP. The data indicate that ATP binds to the enzyme-vanadate complex regardless of the presence or absence of Na+ or K+, but it affects the dissociation rate only when Na+ is bound simultaneously. The value of K0.5 of Na+ decreased as pH was increased in the range of 6.5-7.8, but K0.5 of ATP was independent of pH. Demonstration of ATP binding to the enzyme-vanadate complex provides further support for the suggestion that the oligomeric enzyme contains a low-affinity regulatory site for ATP that is distinct from the interacting high-affinity catalytic sites.     

Effect of magnesium-dependent cell membrane alterations on the transport of K+ in Ehrlich ascites tumour cells

Mg-deficiency or Mg-loading of tumour cells changes the permeability of the cell membrane. The influence of this change on the K+ transport across the membrane was investigated using 86Rb+ and K+ analog. The time course of the influx and efflux rates were estimated by means of a mathematical approach for a two-compartment system with inconstant pool sizes. The comparison of the two states of the cells demonstrates that in Mg-deficient cells the passive K+ efflux is significantly enhanced (40%). This in turn stimulates the active counter transport mediated by the (Na+-K+)-ATPase, raising the ATP consumption by about 30%. However, the enzyme is not able to maintain the cellular K+ content under these conditions. After a short transient increase due to the initially enhanced influx the passive net efflux prevails. Differences in the electrophoretic mobility of the two states of the cells confirm Mg-dependent changes of the cell membrane structure.     

Kinetic properties of electrogenic Na+/H+ antiport in membrane vesicles from an alkalophilic Bacillus sp.

The effects of imposed proton motive force on the kinetic properties of the alkalophilic Bacillus sp. strain N-6 Na+/H+ antiport system have been studied by looking at the effect of delta psi (membrane potential, interior negative) and/or delta pH (proton gradient, interior alkaline) on Na+ efflux or H+ influx in right-side-out membrane vesicles. Imposed delta psi increased the Na+ efflux rate (V) linearly, and the slope of V versus delta psi was higher at pH 9 than at pH 8. Kinetic experiments indicated that the delta psi caused a pronounced increase in the Vmax for Na+ efflux, whereas the Km values for Na+ were unaffected by the delta psi. As the internal H+ concentration increased, the Na+ efflux reaction was inhibited. This inhibition resulted in an increase in the apparent Km of the Na+ efflux reaction. These results have also been observed in delta pH-driven Na+ efflux experiments. When Na(+)-loaded membrane vesicles were energized by means of a valinomycin-induced inside-negative K+ diffusion potential, the generated acidic-interior pH gradients could be detected by changes in 9-aminoacridine fluorescence. The results of H+ influx experiments showed a good coincidence with those of Na+ efflux. H+ influx was enhanced by an increase of delta psi or internal Na+ concentration and inhibited by high internal H+ concentration. These results are consistent with our previous contentions that the Na+/H+ antiport system of this strain operates electrogenically and plays a central role in pH homeostasis at the alkaline pH range.     

Extracellular ATP stimulates an amiloride-sensitive sodium influx in human lymphocytes

Extracellular ATP has been shown to increase the Na+ permeability of human lymphocytes by 3 to 12-fold. The kinetics of this ATP-induced response were studied by measuring 22Na+ influx into chronic lymphocytic leukemic lymphocytes incubated in low-sodium media without divalent cations. ATP-stimulated uptake of 22Na-ions was linear over 4 min incubation and this influx component showed a sigmoid dependence on ATP concentration. Hill analysis yielded a K1/2 of 160 microM and a n value of 2.5. The nucleotide ATP-gamma-S (1-2 mM) gave 30% of the permeability increase produced by ATP, but UTP (2 mM) and dTTP (2 mM) had no effect on 22Na influx. The amiloride analogs 5-(N-ethyl-N-isopropyl) amiloride and 5-(N,N-hexamethylene) amiloride, which are potent inhibitors of Na(+)-H+ countertransport, abolished 72-95% of the ATP-stimulated 22Na+ influx. However, the involvement of Na(+)-H+ countertransport in the ATP-stimulated Na+ influx was excluded by three lines of evidence. Sodium influx was stimulated 7-fold by extracellular ATP but only 2.4-fold by hypertonic conditions which are known to activate Na(+)-H+ countertransport. Addition of ATP to lymphocytes produced no change in intracellular pH when these cells were suspended in isotonic NaCl media. Finally ATP caused a membrane depolarization of lymphocytes which is inconsistent with stimulation of electroneutral Na(+)-H+ exchange. These data suggest that ATP acts cooperatively to induce the formation of membrane channels which allow increased Na+ influx by a pathway which is partially inhibited by amiloride and its analogs.     

Variable stoichiometry in reconstituted shark Na,K-ATPase engaged in uncoupled efflux

In liposomes with reconstituted shark Na,K-ATPase produced to contain no internal K+ or Na+ addition of external Na+ and ATP induce an uncoupled Na+ efflux on inside-out oriented pumps which is electrogenic and accompanied by hydrolysis of ATP (Cornelius, F. (1989) Biochem. Biophys. Res. Commun. 160, 801-807). At saturating cytoplasmic Na+ the net-charge translocated per ATP molecule split is compatible with a coupling ratio of Nacyt transported per ATP split of 3:1 at pH greater than or equal to 7.0. However, this ratio decreases to 1.5:1 below pH 7.0. At non-saturating cytoplasmic Na+ the 3:1 stoichiometry is attained at pH 7.0-7.5, whereas outside this range of pH the net-charge translocated per ATP molecule split decreases.     

Kinetics of Na-ATPase activity by the Na,K pump. Interactions of the phosphorylated intermediates with Na+, Tris+, and K+

To determine the biochemical events of Na+ transport, we studied the interactions of Na+, Tris+, and K+ with the phosphorylated intermediates of Na,K-ATPase from ox brain. The enzyme was phosphorylated by incubation at 0 degrees C with 1 mM Mg2+, 25 microM [32P]ATP, and 20-600 mM Na+ with or without Tris+, and the dephosphorylation kinetics of [32P]EP were studied after addition of (1) 1 mM ATP, (2) 2.5 mM ADP, (3) 1 mM ATP plus 20 mM K+, and (4) 2.5 mM ADP plus Na+ up to 600 mM. In dephosphorylation types 2-4, the curves were bi- or multiphasic. "ADP-sensitive EP" and "K+-sensitive EP" were determined by extrapolation of the slow phase of the curves to the ordinate and their sum was always larger than Etotal. These results required a minimal model consisting of three consecutive EP pools, A, B, and C, where A was ADP sensitive and both B and C were K+ sensitive. At high [Na+], B was converted rapidly to A (type 4 experiment). The seven rate coefficients were dependent on [Na+], [Tris+], and [K+], and to explain this we developed a comprehensive model for cation interaction with EP. The model has the following features: A, B, and C are equilibrium mixtures of EP forms; EP in A has two to three Na ions bound at high-affinity (internal) sites, pool B has three, and pool C has two to three low-affinity (external) sites. The putative high-affinity outside Na+ site may be on E2P in pool C. The A leads to B conversion is blocked by K+ (and Tris+). We conclude that pool A can be an intermediate only in the Na-ATPase reaction and not in the normal operation of the Na,K pump.