Studies on (Na+ + K+)-activated ATPase. XLV. Magnesium induces two low-affinity non-phosphorylating nucleotide binding sites per molecule

Does binding of ouabain to human alpha1-subunit of Na+, K+-ATPase affect the ATPase activity of adjacent rat alpha1-subunit?

To ascertain whether ouabain binding to human alpha1-subunit influences coexpression of rat alpha1-subunit, the ouabain-sensitive profiles of Na+,K+-ATPase activity and 86Rb+ uptake activity and ouabain binding capacity were measured in HeLa cells stably expressing rat alpha1-subunit. The ouabain-sensitive profile of ATPase and 86Rb+ uptake activity seemed to be the sum of two components, one with high and one with low apparent affinity to ouabain, which were similar to that observed in HeLa and NRK-52E cells derived from human and rat, respectively. The ATPase activity with low sensitivity to ouabain increased in simple proportion to the amount of the rat alpha1 mRNA derived from transfected cDNA, which was determined by the reverse transcription-polymerase chain reaction method. The turnover number of the human Na+,K+-ATPase activity obtained from the ratio of the Na+,K+-ATPase activity to the ouabain binding capacity is about 150/sec. The expression of the rat alpha1-subunit had no effect on the turnover numbers of the Na+,K+-ATPase activity with high affinity to ouabain estimated from the ouabain binding capacity as the active site concentration. These results suggested that the ouabain bound to human alpha1-subunit did not inhibit the ATPase activity of the coexpressing rat alpha1 in these cells.

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

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

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.

Phosphate inhibition of the human red cell sodium pump: simultaneous binding of adenosine triphosphate and phosphate

1. The Na+-K+ exchange carried out by the Na+ pump of human red cell ghosts and the Na+ + K+-dependent adenosine triphosphatase (Na+,K+-ATPase) activity of human red cell membranes are inhibited by MgPO4 rather than by free phosphate; similarly, the substrate for the K+-K+ exchange carried out by the pump is MgPO4 rather than free phosphate. 2. Inhibition of the Na+, K+-ATPase activity by MgPO4 is only partially competitive (mixed type) with ATP, and MgPO4 inhibition of the Na+-K+ exchange measured in Na+-free solutions and in K+-free ghosts which contain ATP at relatively high concentration is partially uncompetitive (mixed type) with external K+. 3. When measurements were made in K+-free ghosts and Na+-free solutions, or when Na+,K+-ATPase activity was measured at high ATP concentrations, inhibition by MgPO4 was non-competitive with cell Na+. This observation is not consistent with the Albers-Post reaction mechanism of the Na+ pump, and suggests the presence of an alternative reaction pathway in which ATP combines with the enzyme before phosphate is released. 4. MgPO4 monotonically inhibited the uncoupled Na+ efflux which occurs in solutions free of both Na+ and K+. The uncoupled efflux seemed to be more sensitive to MgPO4 inhibition than the Na+-K+ exchange. 5. Trinitrophenyladenosine-5'-tetraphosphate stimulated the K+-K+ exchange in the presence of MgPO4, and the characteristics of stimulation by TNP adenosine tetraphosphate were little different from the characteristics of stimulation by trinitrophenyladenosine-5'-triphosphate or -5'-diphosphate. The nucleotide binding site at which K+-K+ exchange is stimulated must be able to accommodate a nucleotide with a linear array of four phosphate groups.

Distinction between the intermediates in Na+-ATPase and Na+,K+-ATPase reactions. II. Exchange and hydrolysis kinetics at micromolar nucleotide concentrations

The ATP hydrolysis rate and the ADP-ATP exchange rate of (Na+ + K+)-ATPase from ox brain were measured at 10 microM Mg2+free and at micromolar concentrations of free ATP and ADP. (1) In the absence of K+, substrate inhibition of the hydrolysis rate was observed. It disappeared at low Na+ and diminished at increasing concentrations of ADP. This was interpreted in terms of free ATP binding to E1P. In support of this interpretation, free ATP was found to competitively inhibit ADP-ATP exchange. (2) In the presence of K+, substrate activation of the hydrolysis rate was observed. Increasing (microM) concentrations of ADP did not give rise to competitive inhibition in contrast to the situation in the absence of K+ (cf. 1, above). This was interpreted to show that at micromolar substrate, some low-affinity, high-turnover Na+ + K+ activity is possible, provided the Mg2+ concentration is low. (3) While small concentrations of K+ increased the hydrolysis rate (cf. 2) they decreased the rate of ADP-ATP exchange. To elucidate this phenomenon, parallel measurements of exchange and hydrolysis rates were performed over a wide range of ATP and ADP concentrations, with and without K+. If, in the presence and absence of K+, ADP (and ATP competing) are binding to the same phosphorylated intermediate for the backward reaction, it places quantitative restrictions on the ratio of rate constants with and without K+. The results did not conform to these restrictions, and the discrepancy is taken as evidence for the necessity for a bicyclic scheme for the action of the (Na+ + K+)-ATPase. (4) An earlier statement concerning the nature of the phosphoenzyme obtained in the presence of Na+ and K+ is amended.

(Na+ + K+)-ATPase: on the number of the ATP sites of the functional unit

Questions concerning the number of the ATP sites of the functional unit of (Na+ + K+)-ATPase (i.e., the sodium pump) have been at the center of the controversies on the mechanisms of the catalytic and transport functions of the enzyme. When the available data pertaining to the number of these sites are examined without any assumptions regarding the reaction mechanism, it is evident that although some relevant observations may be explained either by a single site or by multiple ATP sites, the remaining data dictate the existence of multiple sites on the functional unit. Also, while from much of the data it is clear that the multiple sites of the unit enzyme represent the interacting catalytic sites of an oligomer, it is not possible to rule out the existence of a distinct regulatory site for ATP in addition to the interacting catalytic sites. Regardless of the ultimate fate of the regulatory site, any realistic approach to the resolution of the kinetic mechanism of the sodium pump should include the consideration of the established site-site interactions of the oligomer.

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.

Eosin, a fluorescent marker for the high-affinity ATP site of (K+ + H+)-ATPase

Eosin has been used as a fluorescent probe for studying conformational states in (K+ + H+)-ATPase. The eosin fluorescence level is increased by Mg2+ (K0.5 = 0.2 mM). This increase is counteracted by K+ (I0.5 = 1.3 mM) and choline (I0.5 = 17.2 mM) and by ATP. Binding studies with eosin indicate that the increase and decrease in fluorescence is due to changes in binding of eosin to the enzyme. The Mg2+-induced specific binding has a Kd of 0.7 microM and a maximal capacity of 3.5 nmol per mg enzyme, which is equivalent to 2.5 site per phosphorylation site. These experiments and the fact that eosin competitively inhibits (K+ + H+)-ATPase towards ATP, suggest that eosin binds to ATP binding sites.

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.

Effects of ATP and monovalent cations on Mg2+ inhibition of (Na,K)-ATPase

The hydrolysis of ATP catalyzed by purified (Na,K)-ATPase from pig kidney was more sensitive to Mg2+ inhibition when measured in the presence of saturating Na+ and K+ concentrations [(Na,K)-ATPase] than in the presence of Na+ alone, either at saturating [(Na,Na)-ATPase] or limiting [(Na,0)-ATPase] Na+ concentrations. This was observed at two extreme concentrations of ATP (3 mM where the low-affinity site is involved and 3 microM where only the catalytic site is relevant), although Mg2+ inhibition was higher at low ATP concentration. In the case of (Na,Na)-ATPase activity, inhibition was barely observed even at 10 mM free Mg2+ when ATP was 3 mM. When (Na,K)-ATPase activity was measured at different fixed K+ concentrations the apparent Ki for Mg2+ inhibition was lower at higher monovalent cation concentration. When K+ was replaced by its congeners (Rb+, NH+4, Li+), Mg2+ inhibition was more pronounced in those cases in which the dephosphorylating cation forms a tighter enzyme-cation complex after dephosphorylation. This effect was independent of the ATP concentration, although inhibition was more marked at lower ATP for all the dephosphorylating cations. The K0.5 for ATP activation at its low-affinity site, when measured in the presence of different dephosphorylating cations, increased following the sequence Rb+ greater than K+ greater than NH+4 greater than Li+ greater than none. The K0.5 values were lower with 0.05 mM than with 10 mM free Mg2+ but the order was not modified. The trypsin inactivation pattern of (Na,K)-ATPase indicated that Mg2+ kept the enzyme in an E1 state. Addition of K+ changed the inactivation into that observed with the E2 enzyme form. On the other hand, K+ kept the enzyme in an E2 state and addition of Mg2+ changed it to an E1 form. The K0.5 for KCl-induced E1-to-E2 transformation (observed by trypsin inactivation profile) in the presence of 3 mM MgCl2 was about 0.9 mM. These results concur with two mechanisms for free Mg2+ inhibition of (Na,K)-ATPase: "product" and dead-end. The first would result from Mg2+ interaction with the enzyme in the E2(K) occluded state whereas the second would be brought about by a Mg2+-enzyme complex with the enzyme in an E1 state.

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.

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

A high basal level of phosphorylation (approx. 70% of the optimal Na+-dependent phosphorylation level) is observed in 50 mM imidazole-HCl (pH 7.0), in the absence of added Na+ and K+ and the presence of 10-100 microM Mg2+. In 50 mM Tris-HCl (pH 7.0) the basal level is only 5%, irrespective of the Mg2+ concentration. Nevertheless, imidazole is a less effective activator of phosphorylation than Na+ (Km imidazole-H+ 5.9 mM, Km Na+ 2 mM under comparable conditions). Imidazole-activated phosphorylation is strongly pH dependent, being optimal at pH less than or equal to 7 and minimal at pH greater than or equal to 8, while Na+-activated phosphorylation is optimal at pH 7.4. This suggests that imidazole-H+ is the activating species. Imidazole facilitates Na+-stimulated phosphorylation. The Km for Na+ decreases from 0.63 mM at 5 mM imidazole-HCl to 0.21 mM at 50 mM imidazole-HCl (pH 7; 0.1 mM Mg2+ in all cases). Imidazole-activated phosphorylation is more sensitive to inhibition by K+ (I50 = 12.5 microM) than Na+-activated phosphorylation (I50 = 180 microM). Mg2+ antagonizes activation by imidazole-H+ and also inhibition by K+. The Ki value for Mg2+ (approx. 0.3 mM) is the same for the two antagonistic effects. Tris buffer (pH 7.0) inhibits imidazole-activated phosphorylation with an I50 value of 30 mM in 50 mM imidazole-HCl (pH 7.0) plus 0.1 mM Mg2+. We conclude that imidazole-H+, but not Tris-H+, can replace Na+ as an activator of ATP-dependent phosphorylation, primarily by shifting the E2----E1 transition to the right, leading to a phosphorylating E1 conformation which is different from that in Tris buffer.

Model of anion and monovalent cation transport as neutral ion pairs through lipophilic water channels of the Na,K ATPase complex

A model of anion and monovalent cation transport through a lipophilic water channel of the Na,K ATPase complex is presented. Literature data for the Na,K ATPase cation binding sites are combined with data for the anion binding sites of Band 3 to obtain adjacent cation and anion combining sites at the inner and outer channel mouths. Cations and anions form neutral ion pairs or undissociated acids at these sites and then partition much more favorably into lipophilic channel water, passing through the channel in diffusive fashion. Cation movements in an "uphill" direction occur without an enzyme translocating moiety and its specific energetic requirement. The pertinent factors are the exclusion of unpaired cations by the tight channel and the site selectivity or pickup ratios for Na/K at each side which dominate over bulk and transmembrane concentration ratios. ATP hydrolysis provides phosphate for ion pairing.

Interrelationship of dietary Mg intake and electrolyte homeostasis in hamsters: I. Severe Mg deficiency, electrolyte homeostasis, and myocardial necrosis

Epidemiological studies indicate a strong relationship between dietary Mg intake and the incidence of sudden cardiac death. The mechanism by which dietary Mg leads to an increased incidence of cardiovascular disease is unknown but may involve alteration of electrolyte balance. In the present study, tissue electrolyte levels and myocardial pathology were investigated in adult hamsters fed a diet containing no added Mg. Control animals were fed the same diet supplemented with Mg or standard laboratory chow. Hamsters were killed after 4, 8, 12, or 18 days on the test diet, and levels of Na, K, Ca, and Mg were measured in the serum, myocardium, bone, and kidney. The earliest change induced by the test diet was a decrease of the serum Mg and an increase in the Na concentration of the myocardium and other tissues. Following the rise in myocardial Na, the myocardial Ca rose, attaining a fourfold increase by 18 days. K fell in heart and kidney, but not significantly. Although there was no significant change in myocardial Mg, foci of myocardial necrosis, considered to be typical of acute severe Mg deficiency, were found. Myocardial necrosis and the increase in myocardial Ca occurred in parallel. Because of the pattern of observed changes in electrolyte levels, and the potential role of Ca in myocardial injury, the occurrence of myocardial necrosis in these Mg-deficient hamsters is attributable to the increased level of myocardial Ca, rather than to any change in intracellular Mg levels. It is postulated that reduced extracellular Mg levels increase [Na]i through reduction of sarcolemmal (Na+ + K+)-ATPase activity. This would lead to an increase in [Ca]i through Na-Ca exchange.

Amino group modification of (Na+ + K+)-ATPase

The effects of three amino group reagents on the activity of (Na+ + K+)-ATPase and its component K+-stimulated p-nitrophenylphosphatase activity from rabbit kidney outer medulla have been studied. All three reagents cause inactivation of the enzyme. Modification of amino groups with trinitrobenzene sulfonic acid yields kinetics of inactivation of both activities, which depend on the type and concentration of the ligands present. In the absence of added ligands, or with either Na+ of Mg2+ present, the enzyme inactivation process follows complicated kinetics. In the presence of K+, Rb+, or Tl+, protection occurs due to a change of the kinetics of inactivation toward a first-order process. ATP protects against inactivation at a much lower concentration in the absence than in the presence of Mg2+ (P50 6 microM vs. 1.2 mM). Under certain conditions (100 microM reagent, 0.2 M triethanolamine buffer, pH 8.5) modification of only 2% of the amino groups is sufficient to obtain 50% inhibition of the ATPase activity. Modification of amino groups with ethylacetimidate causes a nonspecific type of inactivation of (Na+ + K+)-ATPase. Mg2+ and K+ have no effects, and ATP only a minor effect, on the degree of modification. The K+-stimulated p-nitrophenylphosphatase activity is less inhibited than the (Na+ + K+)-ATPase activity. Half-inhibition of the (Na+ + K+)-ATPase is obtained only after 25% modification of the amino groups. Modification of amino groups with acetic anhydride also causes nonspecific inactivation of (Na+ + K+)-ATPase. Mg2+ has no effect, and ATP has only a slight protecting effect. The K+-stimulated p-nitrophenylphosphatase activity is inhibited in parallel with the (Na+ + K+)-ATPase activity. Half-inactivation of the (Na+ + K+)-ATPase activity is obtained after 20% modification of the amino groups.

Thiophosphorylation of (Na + K+)-ATPase yields an ADP-sensitive phosphointermediate

1) Treatment of (Na+ + K+)-ATPase from rabbit kidney outer medulla with the gamma-35S labeled thio-analogue of ATP in the presence of Na+ + Mg2+ and the absence of K+ leads to thiophosphorylation of the enzyme. The Km value for [gamma-S]ATP is 2.2 microM and for Na+ 4.2 mM at 22 degrees C. Thiophosphorylation is a sigmoidal function of the Na+ concentration, yielding a Hill coefficient nH = 2.6. (2) The thio-analogue (Km = 35 microM) can also support overall (Na+ + K+)-ATPase activity, but Vmax at 37 degrees C is only 1.13 mumol X (mg protein)-1 X h-1 or 0.09% of the specific activity for ATP (Km = 0.43 mM). (3) The thiophosphoenzyme intermediate, like the natural phosphoenzyme, is sensitive to hydroxylamine, indicating that it also is an acylphosphate. However, the thiophosphoenzyme, unlike the phosphoenzyme, is acid labile at temperatures as low as 0 degree C. The acid-denatured thiophosphoenzyme has optimal stability at pH 5-6. (4) The thiophosphorylation capacity of the enzyme is equal to its phosphorylation capacity, indicating the same number of sites. Phosphorylation by ATP excludes thiophosphorylation, suggesting that the two substrates compete for the same phosphorylation site. (5) The (apparent) rate constants of thiophosphorylation (0.4 s-1 vs. 180 s-1), spontaneous dethiophosphorylation (0.04 s-1 vs. 0.5 s-1) and K+-stimulated dethiophosphorylation (0.54 s-1 vs. 230 s-1) are much lower than those for the corresponding reactions based on ATP. (6) In contrast to the phosphoenzyme, the thiophosphoenzyme is ADP-sensitive (with an apparent rate constant in ADP-induced dethiophosphorylation of 0.35 s-1, Km ADP = 48 microM at 0.1 mM ATP) and is relatively K+-insensitive. The Km for K+ in dethiophosphorylation is 0.9 mM and in dephosphorylation 0.09 mM. The thiophosphoenzyme appears to be for 75-90% in the ADP-sensitive E1-conformation.

Hydrolysis of adenylyl imidodiphosphate in the presence of Na+ + Mg2+ by (Na+ + K+)-activated ATPase

Contrary to what has usually been assumed, (Na+ + K+)-ATPase slowly hydrolyses AdoPP[NH]P in the presence of Na+ + Mg2+ to ADP-NH2 and Pi. The activity is ouabain-sensitive and is not detected in the absence of either Mg2+ or Na2+. The specific activity of the Na+ + Mg2+ dependent AdoPP[NH]P hydrolysis at 37 degrees C and pH 7.0 is 4% of that for ATP under identical conditions and only 0.07% of that for ATP in the presence of K+. The activity is not stimulated by K+, nor can K+ replace Na+ in its stimulatory action. This suggests that phosphorylation is rate-limiting. Stimulation by Na+ is positively cooperative with a Hill coefficient of 2.4; half-maximal stimulation occurs at 5-9 mM. The Km value for AdoPP[NH]P is 17 microM. At 0 degrees C and 21 degrees C the specific activity is 2 and 14%, respectively, of that at 37 degrees C. AMP, ADP and AdoPP[CH2]P are not detectably hydrolysed by (Na+ + K+)-ATPase in the presence of Na+ + Mg2+. In addition, AdoPP[NH]P undergoes spontaneous, non-enzymatic hydrolysis at pH 7.0 with rate constants at 0, 21 and 37 degrees C of 0.0006, 0.006 and 0.07 h-1, respectively. This effect is small compared to the effect of enzymatic hydrolysis under comparable conditions. Mg2+ present in excess of AdoPP[NH]P reduces the rate constant of the spontaneous hydrolysis to 0.005 h-1 at 37 degrees C, indicating that the MgAdoPP[NH]P complex is virtually stable to spontaneous hydrolysis, as is also the case for its enzymatic hydrolysis. A practical consequence of these findings is that AdoPP[NH]P binding studies in the presence of Na+ + Mg2+ with enzyme concentrations in the mg/ml range are not possible at temperatures above 0 degrees C. On the other hand, determination of affinity in the (Na+ + K+)-ATPase reaction by competition with ATP at low protein concentrations (microgram/ml range) remains possible without significant hydrolysis of AdoPP[NH]P even at 37 degrees C.

Modification of the conformational equilibria in the sodium and potassium dependent adenosinetriphosphatase with glutaraldehyde

Glutaraldehyde treatment of electroplax membrane preparations of Na,K-ATPase leads to irreversible changes in the enzymic behavior of the protein, which are not due to modification of the active site. When the glutaraldehyde treatment is carried out in a medium containing K+ and without Na+, the "K+-modified enzyme" so produced shows the following changes in enzymic properties: The steady-state phosphorylation by ATP and the rate of ATP-ADP exchange are decreased to approximately 40% of control, while Na,K-ATPase activity decreases to approximately 15% of control. Phosphatase activity is decreased very little, but the potassium activation parameters of the reaction are changed, from K0.5 approximately equal to 5 mM and nH = 1.9 in control to K0.5 approximately equal to 0.5 mM and nH = 1 in K+-modified enzyme. KI(app) for nucleotide inhibition of phosphatase activity is increased significantly. Changes in the cation dependence of the ATPase reaction are also observed. All of these effects can be explained by assuming that the cross-linking of surface groups in protein subunits when they are in conformation E2 shifts the intrinsic conformational equilibrium of the enzyme toward E2. We considered the simplest mathematical model for the coupling between K+ binding and the conformational equilibrium, with equivalent potassium sites that must be simultaneously in the same state. If one assumes that the potassium activation of phosphatase activity in the K+-modified enzyme reflects the affinity for K+ of E2, the behavior of the phosphatase activity in the native enzyme can be fit if there are only two potassium sites, whose affinity is 80-fold higher in E2 than in E1, and the equilibrium constant for E2 in equilibrium E1 is about 250. The same sites can explain the activation of dephosphorylation during ATP hydrolysis. Independent of the model chosen, potassium ions must be required for the catalytic action of form E2 and cannot be merely "allosteric activators". The enzyme modified with glutaraldehyde in a medium containing Na+ also has interesting properties, but their rationalization is less straightforward. The Na,K-ATPase activity is inhibited more than the "partial reactions", as in the K+-modified enzyme. We suggest that this is a generally expected result of modifications of the enzyme.

Properties of the Mg2+-induced low-affinity nucleotide binding site of (Na+ + K+)-activated ATPase

The Mg2+-induced low-affinity nucleotide binding by (Na+ + K+)-ATPase has been further investigated. Both heat treatment (50-65 degrees C) and treatment with N-ethylmaleimide reduce the binding capacity irreversibly without altering the Kd value. The rate constant of inactivation is about one-third of that for the high-affinity site and for the (Na+ + K+)-ATPase activity. Thermodynamic parameters (delta H degree and delta S degree) for the apparent affinity in the ATPase reaction (Km ATP) and for the true affinity in the binding of AdoPP[NH]P (Kd and Ki) differ greatly in sign and magnitude, indicating that one or more reaction steps following binding significantly contribute to the Km value, which thus is smaller than the Kd value. Ouabain does not affect the capacity of low-affinity nucleotide binding, but only increases the Kd value to an extent depending on the nucleotide used. GTP and CTP appear to be most sensitive, ATP and ADP intermediately sensitive and AdoPP[NH]P and AMP least sensitive to ouabain. Ouabain reduces the high-affinity nucleotide binding capacity without affecting the Kd value. The nucleotide specificity of the low-affinity binding site is the same for binding (competition with AdoPP[NH]P) and for the ATPase activity (competition with ATP): AdoPP[NH]P greater than ATP greater than ADP greater than AMP. The low-affinity nucleotide binding capacity is preserved in the ouabain-stabilized phosphorylated state, and the Kd value is not increased more than by ouabain alone. It is inferred that the low-affinity site is located on the enzyme, more specifically its alpha-subunit, and not on the surrounding phospholipids. It is situated outside the phosphorylation centre. The possible functional role of the low-affinity binding is discussed.

[Use of SDS and saponin detergents for the demonstration and purification of (Na+K+)ATPase in sheep kidney]

Incubation of membrane fragments from sheep kidney outer medulla in detergents such as SDS or saponin revealed increased specific (NA+) ATPase activity. Measurement of enzyme phosphorylation from [gamma 32P] ATP showed irreversible alteration of EP to (Na+) ATPase activity ratio when SDS is used as unmasking agent. These results were found with unmasked and purified enzyme.

Kinetic studies on the (Na+ + K+)-dependent ATPase evidence for coexisting sites for Na+, K+ and Mg2+

Na+-ATPase activity of a dog kidney (Na+ + K+)-ATPase enzyme preparation was inhibited by a high concentration of NaCl (100 mM) in the presence of 30 microM ATP and 50 microM MgCl2, but stimulated by 100 mM NaCl in the presence of 30 microM ATP and 3 mM MgCl2. The K0.5 for the effect of MgCl2 was near 0.5 mM. Treatment of the enzyme with the organic mercurial thimerosal had little effect on Na+ -ATPase activity with 10 mM NaCl but lessened inhibition by 100 mM NaCl in the presence of 50 microM MgCl2. Similar thimerosal treatment reduced (Na+ + K+)-ATPase activity by half but did not appreciably affect the K0.5 for activation by either Na+ or K+, although it reduced inhibition by high Na+ concentrations. These data are interpreted in terms of two classes of extracellularly-available low-affinity sites for Na+: Na+-discharge sites at which Na+-binding can drive E2-P back to E1-P, thereby inhibiting Na+-ATPase activity, and sites activating E2-P hydrolysis and thereby stimulating Na+-ATPase activity, corresponding to the K+-acceptance sites. Since these two classes of sites cannot be identical, the data favor co-existing Na+-discharge and K+-acceptance sites. Mg2+ may stimulate Na+-ATPase activity by favoring E2-P over E1-P, through occupying intracellular sites distinct from the phosphorylation site or Na+-acceptance sites, perhaps at a coexisting low-affinity substrate site. Among other effects, thimerosal treatment appears to stimulate the Na+-ATPase reaction and lessen Na+-inhibition of the (Na+ + K+)-ATPase reaction by increasing the efficacy of Na+ in activating E2-P hydrolysis.

Effect of magnesium ions on the high-affinity binding of eosin to the (Na+ + K+)-ATPase

(1) The fluorescence of eosin Y in the presence of (Na+ + K+)-ATPase is enhanced by Mg2+. The enhancement by Mg2+ is larger than that obtained with Na+ (Skou, J.C. and Esmann, M. (1981) Biochim. Biophys. Acta 647, 232-240). Mg2+ shifts the excitation maximum from 518 to 524 nm, the emission maximum from 538 to 542 nm. Also a shoulder appears at about 490 nm on the excitation curve, as was also observed with Na+. (2) The Mg2+-dependent enhancement of fluorescence can be reversed by K+ as well as by ATP. In the presence of Mg2+ + Pi (i.e. under conditions of phosphorylation), the fluorescence enhancement can be reversed by ouabain. With Mg2+ and a low concentration of K+ (i.e. conditions for vanadate binding), the enhancement of fluorescence can be reversed by vanadate. (3) There is a low-affinity binding of eosin which increases with the Mg2+ concentration. This is observed as a slight increase in the fluorescence when the excitation wavelength is above 520 nm. The low-affinity binding is K+-, ATP-, ouabain- and vanadate-insensitive. (4) Scatchard analysis of the binding experiments suggests that there are two high-affinity eosin-binding sites per 32P-labelling site in the presence of 5 mM Mg2+ both of which are ouabain-, vanadate- and ATP-sensitive. With 5 mM Mg2+ + 0.25 Pi, the Kd values are 0.14 microM and 1.3 microM, respectively. With 5 mM Mg2+, 150 mM Na+, the Kd values are 0.45 microM and 3.2 microM, respectively. With 5 mM Mg2+, the addition of K+ gives a pronounced decrease in affinity but does not decrease the number of binding sites (which remains at two per 32P-labelling site). With 5 mM Mg2+ + 150 mM K+, the affinities of the two binding sites become identical, at a Kd of 17 microM. (5) The rate of conformational transitions was measured using the stopped-flow method. The rate of the transition from the Mg2+-form to the K+-form is high. Oligomycin has only a small (if any) effect on the rate. Addition of Na+ in the presence of Mg2+ does not appreciably change the rate of conversion to the K+-form, giving a rate constant of about 110 s-1. However, the addition of oligomycin in the presence of Mg2+ + Na+ had a profound effect: the rate of conversion to the K+-form was decreased by a factor of 2000 to about 0.063 s-1. This suggests that the conformation with Mg2+ alone is different from the conformation with Na+ alone. (6) The effects of K+, ouabain, vanadate and ATP on the high-affinity binding of eosin suggest that the two eosin molecules bound per 32P-labelling site are bound to ATP sites.