Effect on the equilibrium between the Na+-form and the K+-form of the (Na+ + K+)-ATPase of modification of the enzyme with pyridoxal 5-phosphate

An increase in pH shifts the equilibrium between the K+-form and the Na+-form of the (Na+ + K+)-ATPase towards the Na+-form. pK for the proton effect on the equilibrium is decreased by modification of the enzyme with pyridoxal 5-phosphate. The reactivity of the enzyme towards pyridoxal 5-phosphate is increased by an increase in pH. Modification by pyridoxal 5-phosphate of epsilon-amino groups on lysine, which has a pK of about 8 with the enzyme in the K+-form and of about 7.4 in the Na+-form, shifts the equilibrium between E1Na+ and E2 towards E2, and the equilibrium between E2(K+occ) and E2 towards E2, but has no effect on the overall equilibrium between E1Na+ and E2(K+occ). An additional modification of epsilon-amino groups on lysine, which has a pK of 9.5-10 with the enzyme in the K+-form and of about 7.7 with the enzyme in the Na+-form, shifts the equilibrium between E2(K+occ) and E1Na+ towards E1Na+; this is due to a shift in the equilibrium between E2(K+occ) and E2 towards E2, but with no effect on the equilibrium between E1Na+ and E2. The results show that the transition from the K+-form to the Na+-form decreases the pK of lysine epsilon-amino groups on the enzyme, and that the protonation of these groups influences the equilibrium between the two conformations.     

Modification of gastric (H+ + K+)-ATPase with pyridoxal 5'-phosphate

Pig gastric membrane vesicles enriched in (H+ + K+)-ATPase were covalently modified with pyridoxal 5'-phosphate (PLP). The modification resulted in inhibition of K+-dependent ATP hydrolysis, formation of phosphoenzyme and ATP-driven H+-uptake catalyzed by (H+ + K+)-ATPase. ATP, ADP, and adenyl-5'-yl imidodiphosphate were protective ligands, whereas Mg2+ and K+ were not. Specific PLP-binding of about 4.5 nmol/mg membrane protein was necessary for complete inhibition of the enzyme activity, indicating that the stoichiometry of PLP-binding to the enzyme was about 1:1. Limited proteolysis of the enzyme modified with [3H]PLP by trypsin suggests that PLP specifically modifies the lysine residue located in the 16-kDa fragment of the enzyme cleaved by trypsin. These results suggested that PLP binds to a specific lysine residue in the nucleotide-binding site or a region in its vicinity and inhibits the substrate binding or phosphorylation step of (H+ + K+)-ATPase.     

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.     

Coexistence of two ATP sites on the ouabain-complexed (Na+ + K+)-ATPase

When the effects of varying concentrations of ATP on the dissociation rate of the ouabain-enzyme complex were studied, the dissociation rate constant increased with increasing ATP concentrations up to 1 mM, and then decreased with further rise in ATP; indicating that ATP binds to two distinct sites on the complex. ADP and AMP-PNP had similar biphasic effects. GTP, CTP, UTP, and AMP-PCP reduced the dissociation rate. AMP and Pi had no effects. Increase in dissociation rate caused by 0.5 mM ATP was not abolished by saturating CTP, indicating the binding of CTP to only one of the two ATP sites. The data suggest the existence of separate catalytic and regulatory sites, with different affinities and nucleotide specificities.     

Mathematical modelling of ATP, K+ and Na+ interactions with (Na+ + K+)-ATPase occurring under equilibrium conditions.

The controlling effect of ATP, K+ and Na+ on the rate of (Na+ + K+)-ATPase inactivation by 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole (NBD-C1) is used for the mathematical modelling of the interaction of the effectors with the enzyme under equilibrium conditions. 1. Of a series of conceivable interaction models, designed without conceptual restrictions to describe the effector control of inactivation kinetics, only one fits the experimental data described in a preceding paper. 2. The model is characterized by the coexistence of two binding sites for ATP and the coexistence of two separate binding sites for K+ and Na+ on the enzyme-ATP complex. On the basis of this model, the effector parameters fitting the experimental data most closely are estimated by means of nonlinear least-squares fits. 3. The apparent dissociation constants for ATP fo the enzyme-ATP complex or of the enzyme-(ATP)2 complex are computed to lie near 0.0024 mM and 0.34 mM, respectively, irrespective of whether K+ and Na+ were absent or K+ and K+ plus Na+, respectively, were present in the experiments. 4. The origin of the high and the low affinity site for binding of ATP to the (Na+ + K+)-ATPase molecule is traced back to the coexistence of two catalytic centres which, although primarily equivalent as to the reactivity of their thiol groups with NBD-C1, are induced into anticooperative communication by ATP binding and thus show an induced geometric asymmetry. 5. On the basis of the interaction model outlined under item 2 the apparent dissociation constant for K+ or Na+ in the (K+ + Na+)-liganded enzyme-ATP complex are computed to be 1.7 mM and 3.5 mM, respectively. 6. The conclusions concerning the coexistence of two primarily equivalent but anticooperatively interacting catalytic centres and the coexistence of two separate ionophoric centres for Na+ and K+ correspond to the appropriate basic postulates of the flip-flop concept of (Na+ + K+)-ATPase mechanism.     

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.     

Lack of immunological cross reactivity between the transport enzymes (Na+ + K+)-ATPase and (K+ + H+)-ATPase

Goat antisera against (Na⁺ + K⁺)-ATPase and its isolated subunits and against (K⁺ + H⁺)-ATPase have been prepared in order to test for immune cross-reactivity between the two enzymes, whose catalytic subunits show great chemical similarity. None of the (Na⁺ + K⁺)-ATPase antisera cross-reacted with (K⁺ + H⁺)-ATPase or inhibited its enzyme activity. The same was true for the (K⁺ + H⁺)-ATPase antiserum with regard to (Na⁺ + K⁺)-ATPase and its subunits and its enzyme activity. So not withstanding the chemical similarity of their subunits, there is no immunological cross-reactivity between these two plasma membrane ATPases.Number LIII in the series Studies on (Na⁺ + K⁺)-Activated ATPase.     

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+.     

Activation of (Na+ + K+)-ATPase

Enzymes catalyze essential chemical reactions needed for living processes. (Na+ +K+)-ATPase (NKA) is one of the key enzymes that control intracellular ion homeostasis and regulate cardiac function. Little is known about activation of NKA and its biological impact. Here we show that native activity of NKA is markedly elevated when protein-protein interaction occurs at the extracellular DVEDSYGQQWTYEQR (D-R) region in the alpha-subunit of the enzyme. The apparent catalytic turnover of NKA is approximately twice as fast as the controls for both ouabain-resistant and ouabain-sensitive enzymes. Activation of NKA not only markedly protects enzyme function against denaturing, but also directly affects cellular activities by regulating intracellular Ca2+ transients and inducing a positive inotropic effect in isolated rat cardiac myocytes. Immunofluorescent labeling indicates that the D-R region of NKA is not a conventional digitalis-binding site. Our findings uncover a novel activation site of NKA that is capable of promoting the catalytic function of the enzyme and establish a new concept that activating of NKA mediates cardiac contraction.     

Allosteric effect of ATP on Na(+),K(+)-ATPase conformational kinetics

The kinetics of the E2 --> E1 conformational change of unphosphorylated Na+,K+-ATPase was investigated via the stopped-flow technique using the fluorescent label RH421 (pH 7.4, 24 degrees C). The enzyme was pre-equilibrated in a solution containing 25 mM histidine and 0.1 mM EDTA to stabilize the E2 conformation. When rabbit enzyme was mixed with 130 mM NaCl alone or with 130 mM NaCl and varying concentrations of Na2ATP simultaneously, a fluorescence decrease was observed. In the absence of ATP, the fluorescence decrease followed a biexponential time course, but at ATP concentrations after mixing of >or=50 microM, the fluorescence transient could be adequately fitted by a single exponential. On the basis of the agreement between theoretical simulations and experimental traces, we propose that in the absence of bound ATP the conformational transition occurs as a two step reversible process within a protein dimer, E2:E2 --> E2:E1 --> E1:E1. In the presence of 130 mM NaCl, the sum of the forward and backward rate constants for the E2:E2 --> E2:E1 and E2:E1 --> E1:E1 transitions were found to be 10.4 (+/-1.0) and 0.49 (+/-0.02) s-1, respectively. At saturating concentrations of ATP, however, the transition occurs in a single reversible step with the sum of its forward and backward rate constants equal to 35.2 (+/-0.3) s-1. It was found that ATP acting at a high affinity site (Kd approximately 0.25 microM), stimulated the reverse reaction, E1ATP --> E2ATP, in addition to its known allosteric low affinity (Kd approximately 71 microM) stimulation of the forward reaction, E2ATP --> E1ATP.     

Fluorescent labeling of (Na+ + K+)-ATPase by 5-iodoacetamidofluorescein

5-Iodoacetamidofluorescein (5-IAF) covalently labels dog kidney (Na+ + K+)-ATPase with approximately 2 moles incorporated per mole of enzyme. ATPase and K+-phosphatase activities are fully retained after reaction, and the kinetic parameters for Na+, K+, Mg2+, ATP and p-nitrophenyl phosphate are likewise not significantly affected. The fluorescence of the bound 5-IAF is increased by ATP, Na+, and Mg2+, and decreased by K+. These fluorescence changes likely reflect ligand-induced stabilization of the E1 or E2 states of the enzyme.     

Effects of an ATP site affinity analog on some conformational and enzymatic properties of the canine kidney (Na+ + K+)-ATPase

We have shown previously that the canine kidney Na+,K+ pump [Na+ + K+)-ATPase) reacts with the ATP affinity analog p-fluorosulfonylbenzoyladenosine (FSBA). At 20 degrees C, we find the time-course of this reaction to be that predicted for a first-order reaction accompanied by competing solvolysis of the reagent. The FSBA-inactivated (Na+ + K+)-ATPase retains the ability to move between the E1 and E2 conformations that predominate in Na+ and K+ medium, respectively. Therefore, FSBA reaction with the enzyme does not interfere significantly with either its alkali metal cation binding or its conformational freedom. The ability of ATP to influence the enzyme's conformation by binding to the high-affinity nucleotide site is decreased, however, in proportion to the degree of inhibition of enzyme activity by FSBA. In addition, the ability of the enzyme to shift from the E1 to the E2 conformation through the (ATP + Na+)-dependent phosphorylation cycle is inhibited by FSBA treatment, as shown by the decreased ability of these substrates to stimulate the K+-dependent p-nitrophenylphosphatase activity. Both of these effects are consistent with specific reaction of FSBA with the ATP binding site of the enzyme. An additional effect of FSBA treatment is that it causes loss of p-nitrophenylphosphatase activity, but to a lesser extent than (Na+ + K+)-ATPase or Na+-ATPase activity. Binding of p-nitrophenylphosphate to the enzyme is apparently unaffected by FSBA treatment, since the Km for p-nitrophenylphosphate is not changed.     

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

The effects of three amino group reagents on the activity of (Na⁺+K⁺)-ATPase³ and its component K⁺-stimulatedp-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⁺ (P ₅₀ 6 µM vs. 1.2 mM). Under certain conditions (100 µM 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⁺-stimulatedp-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⁺-stimulatedp-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.This article is No. 52 in the series Studies on (Na⁺+K⁺)-Activated ATPase.     

Circular dichroism of the two major conformational states of mammalian (Na+ + K+)-ATPase

No alteration in the circular dichroic spectrum of fully active, membrane-bound (Na+ + K+)-ATPase is observed when the protein is cycled between the two major conformational states, E1 and E2. This finding is in agreement with the infrared study by Chetverin and Brazhnikov (J. Biol. Chem. 260 (1985) 7817) and demonstrates that any difference in secondary structure between the two conformers must be less than 2%.     

Inactivation of Rb+ and Na+ occlusion on (Na+,K+)-ATPase by modification of carboxyl groups

This paper demonstrates and characterizes inactivation by N,N'-dicyclohexylcarbodiimide (DCCD) of Rb+ and Na+ occlusion in pig kidney (Na+,K+)-ATPase. Rb+ and Na+ occlusion dependent on oligomycin are measured with a manual assay. Parallel measurement of phosphorylation (by Pi plus ouabain) and Na+ or Rb+ occlusion lead to stoichiometries of 3 Na+ or 2 Rb+ per pump molecule. Inactivation of cation occlusion by DCCD shows the following features: (a) Rb+ and Na+ occlusion are inactivated with identical rates and (b) DCCD concentration dependence shows first-order kinetics and also proportionality to the ratio of DCCD to protein, (c) Rb+ and Na+ occlusion are equally protected from DCCD, by Rb+ ions with high affinity (or Na+ ions with lower affinity), (d) inactivation is only slightly pH-dependent between 6 and 8.5 but (e) is significantly accelerated by several hydrophobic amines while a water-soluble nucleophile, glycine ethyl ester has no effect, and (f) inactivation is exactly correlated with inactivation of (Na+,K+)-ATPase activity of ATP-dependent Na+/K+ exchange in reconstituted vesicles and with the magnitude of E1Na+----E2(Rb+) conformational transitions measured with fluorescence probes. The simplest hypothesis to explain the results is that DCCD modifies one (or a small number of) critical carboxyl residues in a non-aqueous cation binding domain and so blocks occlusion of 2 Rb+ or 3 Na+ ions. The results suggest further that Na+ and K+(Rb+) bind to the same sites and are transported sequentially on the same trans-membrane segments. A second effect of the DCCD treatment is a 4-8-fold shift of the conformational equilibrium E2(Rb+)----E1Rb+ toward E1Rb+. This is detected by (a) reduction in apparent Rb+ affinity for Rb+ occlusion or Rb+/Rb+ exchange in vesicles and (b) direct demonstration of an increased rate of E2(K+)----E1Na+ and decreased rate of E1Na+----E2(K+). This effect is not protected against by Rb+ ions and probably reflects modification of a second group of residues. Modification of (Na+,K+)-ATPase by carbodiimides is complex. Depending on the nature of the carbodiimide (water- or lipid-soluble), ratio of carbodiimide to protein, and perhaps source of the enzyme, inactivation might result either from modification of critical carboxyls, as suggested by this work, or from internal cross-linking as proposed by Pedemonte, C. H. and Kaplan, J. H. ((1986) J. Biol. Chem. 261, 3632-3639).     

Ligand-dependent reactivity of (Na+ + K+)-ATPase with showdomycin

Showdomycin inhibited pig brain (Na+ + K+)-ATPase with pseudo first-order kinetics. The rate of inhibition by showdomycin was examined in the presence of 16 combinations of four ligands, i.e., Na+, K+, Mg2+ and ATP, and was found to depend on the ligands added. Combinations of ligands were divided into five groups in terms of the magnitude of the rate constant; in the order of decreasing rate constants these were: (1) Na+ + Mg2+ + ATP, (2) Mg2+, Mg2+ + K+, K+ and none, (3) Na+ + Mg2+, Na+, K+ + Na+ and Na+ + K+ + Mg2+, (4) Mg2+ + K+ + ATP, K+ + ATP and Mg2+ + ATP, (5) K+ + Na + + ATP, Na+ + ATP, Na+ + K+ + Mg2+ + ATP and ATP. The highest rate was obtained in the presence of Na+, Mg2+ and ATP. The apparent concentrations of Na+, Mg2+ and ATP for half-maximum stimulation of inhibition (KS0.5) were 3 mM, 0.13 mM and 4 MicroM, respectively. The rate was unchanged upon further increase in Na+ concentration from 140 to 1000 mM. The rates of inhibition could be explained on the basis of the enzyme forms present, including E1, E2, ES, E1-P and E2-P, i. e., E2 has higher reactivity with showdomycin than E1, while E2-P has almost the same reactivity as E1-P. We conclude that the reaction of (Na+ + K+)- ATPase proceeds via at least four kinds of enzyme form (E1, E2, E1 . nucleotide and EP), which all have different conformations.     

The effect of K+ on the equilibrium between the E2 and the K+-occluded E2 conformation of the (Na+ + K+)-ATPase

The rate of the transition from the E2 form to the E1 form of (Na+ + K+)-ATPase (ATP phosphohydrolase, EC 3.6.1.3) has been monitored by the fluorescence changes of eosin. The equilibrium between E1 and E2 is poised towards E2 in the absence of added cations. A stopped-flow tracing of the transition from E2 in the presence of 2 microM K+ (contamination) to E1 (in 150 mM Na+) is multiexponential with a large, rapidly decaying component (t 1/2 about 50 ms) and a smaller component which has a t 1/2 of about 2 s. KCl in microM concentrations decreases the amplitude of the rapidly decaying component and increases the amplitude of the slow component. The stopped-flow tracings can be satisfactorily fitted by a sum of three exponentials. An apparent Kd for K+ of about 5 microM is obtained for the conversion of the rapidly decaying component to the slowly decaying component. The experiments show that the E2 form is a mixture of at least two enzyme conformations. One E2 conformation - without K+ bound, (E2) - is transferred rapidly to the E1 conformation when Na+ is added, whereas the other E2-conformation--with K+ bound with an apparent high affinity, Kocc E2--is transferred slowly to the E1 conformation.