Kinetic studies on Na+/K+-ATPase and inhibition of Na+/K+-ATPase by ATP

Na+/K+-ATPase (EC 3.6.1.3) is an important membrane-bound enzyme. In this paper, kinetic studies on Na+/K+-ATPase were carried out under mimetic physiological conditions. By using microcalorimeter, a thermokinetic method was employed for the first time. Compared with other methods, it provided accurate measurements of not only thermodynamic data (deltarHm) but also the kinetic data (Km and Vmax). At 310.15K and pH 7.4, the molar reaction enthalpy (deltarHm) was measured as -40.514 +/- 0.9kJmol(-1). The Michaelis constant (Km) was determined to be 0.479 +/- 0.020 mM and consistent with literature data. The reliability of the thermokinetic method was further confirmed by colorimetric studies. Furthermore, a simple and reliable kinetic procedure was presented for ascertaining the true substrate for Na+/K+-ATPase and determining the effect of free ATP. Results showed that the MgATP complex was the real substrate with a Km value of about 0.5mM and free ATP was a competitive inhibitor with a Ki value of 0.253 mM.     

Interactions of K+ ATP channel blockers with Na+/K+-ATPase

Two K⁺ _ATP channel blockers, 5-hydroxydecanoate (5-HD) and glyburide, are often used to study cross-talk between Na⁺/K⁺-ATPase and these channels. The aim of this work was to characterize the effects of these blockers on purified Na⁺/K⁺-ATPase as an aid to appropriate use of these drugs in studies on this cross-talk. In contrast to known dual effects (activating and inhibitory) of other fatty acids on Na⁺/K⁺-ATPase, 5-HD only inhibited the enzyme at concentrations exceeding those that block mitochondrial K⁺ _ATP channels. 5-HD did not affect the ouabain sensitivity of Na⁺/K⁺-ATPase. Glyburide had both activating and inhibitory effects on Na⁺/K⁺-ATPase at concentrations used to block plasma membrane K⁺ _ATP channels. The findings justify the use of 5-HD as specific mitochondrial channel blocker in studies on the relation of this channel to Na⁺/K⁺-ATPase, but question the use of glyburide as a specific blocker of plasma membrane K⁺ _ATP channels, when the relation of this channel to Na⁺/K⁺-ATPase is being studied.     

The acceleration of Na+,K+-ATPase activity by ATP and ATP analogues

Since Na+,K+-ATPase (EC 3.6.1.3) of pig kidney modified with a fluorescent sulfhydryl reagent, N-[p-(2-benzimidazolyl) phenyl]maleimide, at Cys-964 of the alpha-chain showed ATP-dependent, reversible, and dynamic fluorescence changes (Nagai, M., Taniguchi, K., Kangawa, K., Matsuo, S., Nakamura, S., and Iida, S. (1986) J. Biol. Chem. 261, 13197-13202), we studied the conformational change during Na+,K+-ATPase reaction using the modified enzyme. The addition of K+ to the enzyme increased the fluorescence intensity to 2% in the presence of 160 mM Na+ and 3 mM Mg2+ (K0.5 = 16.4 mM). Addition of low concentrations of ATP immediately increased the intensity to 3.2% (K0.5 less than 0.1 microM) to accumulate fully K+-bound enzyme in the presence of 43 mM K+ with Na+ and Mg2+, but further addition of higher concentrations of ATP diminished the increase (K0.5 = 120 microM). After exhaustion of ATP, the fluorescence intensity decreased to -0.4% (K0.5 = 0.3 microM) and -2% (K0.5 = 20 microM), respectively, in the presence of low and high concentrations of ADP produced from ATP. High concentrations of ATP accelerated Na+,K+-ATPase activity with a simultaneous increase in the amount of ADP-sensitive phosphoenzyme irrespective of the modification. Adenylyl imidodiphosphate and ADP accelerated Na+,K+-ATPase activity in the presence of 2.7 microM ATP by decreasing the extent of the fluorescence without affecting the amount of phosphoenzyme, irrespective of the modification. These data suggest that Na+,K+-ATPase activity was accelerated due to the acceleration of the breakdown of K+-bound enzyme by high concentrations of ATP and ATP analogues.     

Binding of manganese ions to the Na+/K+-ATPase during phosphorylation by ATP

The aim of the present work was to study the Mg2+-Na+/K+-ATPase interaction that was proposed to lead to the formation of a stable Mg-enzyme complex during phosphorylation from ATP. Instead of Mg we used Mn, which can replace Mg as essential activator of Na+/K+-ATPase activity. The amounts of steady-state Mn bound to the enzyme were estimated at 0 degree C on the basis of the 54Mn remaining in the effluent after passing the reaction mixture through a cation exchange resin column. As a function of the MnCl2 concentration, the amount of Mn retained by the enzyme in the absence and presence of ATP showed a saturable and a linear component; the slope of the linear component was the same in both instances (0.016 nmol/mg per microM). The ATP-dependent Mn binding could be adjusted to a hyperbolic function with a Km of 0.76 microM. The ratio [ATP-dependent E-Mn]/[E-P] measured at 5 microM MnCl2 and 5 microM ATP was not different from 1.0, both in native (Mn-E2-P) as well as in a chymotrypsin treated enzyme (Mn-E1-P). When the Mn.E-P complex was allowed to react with KCl (E2-P form) or ADP (E1-P form), the enzyme was dephosphorylated and simultaneously lost the strongly bound Mn in such a way that the ratio [ATP-dependent E-Mn]/[E-P] remained 1:1. These results show the existence of strongly bound Mn ions to Na+/K+-ATPase during phosphorylation by ATP. That binding is (i) of high affinity for Mn, (ii) probably on a single site, and (iii) with a stoichiometry Mn-Pi of 1:1.     

Kinetics of oligomycin inhibition and activation of Na+/K(+)-ATPase.

Oligomycin inhibition of the maximal hydrolysis activity of ox brain Na+/K(+)-ATPase was studied at varying NaCl concentrations and it was found that for a given amount of live enzyme, the observed inhibition of a particular total oligomycin concentration decreased as the amount of added, (heat-) denatured enzyme increased. In the present article we derive a scale factor for the oligomycin concentration, i.e., the fraction of the total concentration of oligomycin which is free in solution, as a function of the enzyme concentration used. This fraction decreased linearly with the protein concentration and may attain quite small values. We also study the Na(+)-dependence of the hydrolysis rate at saturating substrate concentrations ([Mg2+] = [ATP] = 3 mM), in the presence as well as the absence of KCl, at various concentrations of oligomycin. These data may be explained if it is assumed that the sole effect of oligomycin is to confer upon the enzyme an increased affinity for Na+, i.e., oligomycin merely enhances the inhibitory effect of Na+ on the (maximal) activity seen at high Na(+)-concentrations. The increased Na(+)-affinity in the presence of oligomycin should result in activation of the hydrolysis rate measured under conditions where Na(+)-activation is predominant, i.e., at low Na(+)-concentration and sub-saturating substrate concentrations. This prediction is verified for both Na(+)-ATPase and for Na+/K(+)-ATPase. This proposed action of oligomycin seems to be corroborated also by other evidence discussed in the text.     

Stimulation of rat renal Na+, K+-ATPase activity by thyroid hormones

The effect of thyroid hormones (T4, T3 and reverse T3) on rat renal Na+,K+-ATPase activity was investigated by a cytochemical technique. T3 caused stimulation of Na+,K+-ATPase activity in the renal medulla but not in the renal cortex. There was a peak in enzyme activity after cultured renal segments had been exposed to T3 for 11 min and this time of maximal stimulation did not vary with the concentration of T3. A rectilinear response in Na+,K+-ATPase activity was observed over T3 concentration range 10 pmol l-1 to 100 nmol l-1; at higher T3 concentrations, Na+,K+-ATPase activity was inhibited. The enzyme response was totally blocked by specific T3 antiserum. Addition of T4 and reverse T3 (100 fmol l-1 -1 mmol l-1) failed to stimulate Na+,K+-ATPase activity in any part of the kidney. Plasma (neat and diluted 1:10) stimulated the enzyme in parallel with the dose response curve and the stimulatory effect was abolished by prior addition of specific T3 antiserum.     

Breakdown of Na+/K+-exchanging ATPase phosphoenzymes formed from ATP and from inorganic phosphate during Na+-ATPase activity.

The reactivity towards Na+ and K+ of Na+/K+-ATPase phosphoenzymes formed from ATP and Pi during Na+-ATPase turnover and that obtained from Pi in the absence of ATP, Na+ and K+ was studied. The phosphoenzyme formed from Pi in the absence of cycling and with no Na+ or K+ in the medium showed a biphasic time-dependent breakdown. The fast component, 96% of the total EP, had a decay rate of about 4 s(-1) in K+-free 130 mm Na+, and was 40% inhibited by 20 mm K+. The slow component, about 0.14 s(-1), was K+ insensitive. Values for the time-dependent breakdown of the phosphoenzymes obtained from ATP and from Pi during Na+-ATPase activity were indistinguishable from each other. In K+-free medium containing 130 mm Na+, the decays followed a single exponential with a rate constant of 0.45 s(-1). The addition of 20 mm K+ markedly increased the decays and made them biphasic. The fast components had a rate of approximately 220 s-1 and accounted for 92-93% of the total phosphoenzyme. The slow components decayed at a rate of about 47-53 s(-1). A second group of experiments examined the reactivity towards Na+ of the E2P forms obtained with ATP and Pi when the enzyme was cycling. In both cases, the rate of dephosphorylation was a biphasic function of [Na+]: inhibition at low [Na+], with a minimum at about 5 mm Na+, followed by recovery at higher [Na+]. Although qualitatively similar, the phosphoenzyme formed from Pi showed slightly less inhibition and more pronounced recovery. These results indicate that forward and backward phosphorylation during Na+-ATPase turnover share the same intermediates.     

Captopril inhibits ouabain-sensitive Na+/K+-ATPase

Captopril has been reported to inhibit ouabain-sensitive Na+/K+-ATPase activity in erythrocyte membrane fragments. We investigated the effect of captopril on two physiological measures of Na+/K+ pump activity: 22Na+ efflux from human erythrocytes and K+-induced relaxation of rat tail artery segments. Captopril inhibited 22Na+ efflux from erythrocytes in a concentration-dependent fashion, with 50% inhibition of total 22Na+ efflux at a concentration of 4.8 X 10(-3) M. The inhibition produced by captopril (5 X 10(-3) M) and ouabain (10(-4) M) was not greater than that produced by ouabain alone (65.3 vs. 66.9%, respectively), and captopril inhibited 50% of ouabain-sensitive 22Na+ efflux at a concentration of 2.0 X 10(-3) M. Inhibition by captopril of ouabain-sensitive 22Na efflux was not explained by changes in intracellular sodium concentration, inhibition of angiotensin-converting enzyme or a sulfhydryl effect. Utilizing rat tail arteries pre-contracted with norepinephrine (NE) or serotonin (5HT) in K+-free solutions, we demonstrated dose-related inhibition of K+-induced relaxation by captopril (10(-6) to 10(-4) M). Concentrations above 10(-4) M did not significantly inhibit K+-induced relaxation but did decrease contractile responses to NE, although not to 5HT. Inhibition of K+-induced relaxation by captopril was not affected by saralasin, teprotide or indomethacin. We conclude that captopril can inhibit membrane Na+/K+-ATPase in intact red blood cells and vascular smooth muscle cells. The mechanism of pump suppression is uncertain, but inhibition of ATPase should be considered when high concentrations of captopril are employed in physiological studies.     

Na+/K+-ATPase activity of different types of striated muscles

Na+/K+-ATPase activity was determined in striated muscles with different aerobic capacities. The underlying hypothesis was that different aerobic capacities are reflective of different contractile activity which imposes greater demands on sarcolemmal ion translocation and may thus set Na pumping capacity. The added ion translocation demands required during exercise-training on Na+/K+-ATPase activity in different muscle fiber types may require an adaptation of this enzyme. The highest and lowest Na+/K+-ATPase activity was in the heart and white gastrocnemius muscle (WG), respectively. A high linear correlation existed between Na+/K+-ATPase activity and succinate dehydrogenase activity in the six muscles studied. Exercise-training did not increase Na+/K+-ATPase activity in any of the muscles, but did increase the aerobic capacity, except in the heart and WG. It was concluded that Na+/K+-ATPase activity has a high positive correlation with the aerobic capacity of striated muscles in the rat and that the Na pump capacity does not adapt to exercise-training of 1 hr X day-1 as does aerobic capacity.     

Na+/K+-ATPase activity in rat erythrocytes after prolonged starvation

Na⁺/K⁺-ATPase (sodium, potassium adenosine triphosphatase, EC 3.6.3.9) activity has been studied in whole erythrocytes from rats over time of total food deprivation for 1, 3, 5, 7–8, and 10–12 days with free access to water. Changes in Na⁺/K⁺-ATPase activity have been found to be phase-specific, i.e., associated with periods of certain metabolism level. After the hunger state and accommodation to endogenous nutrition (phases 0-I), from the 3rd to the 7th–8th day a period of compensated accommodation begins (phase II characterized by a stable euglycemic state, while the level of plateau of protein losses and hormonal stimulation are achieved). The Na⁺/K⁺-ATPase activity changes during the phase II were insignificant (p > 0.05), but potassium loss was observed in erythrocytes and blood plasma from the 5th day of starvation onwards. The phase III (the 10th–12th days) is an onset of the terminal period characterized by the lower activities of Na⁺/K⁺-ATPase (ouabain-sensitive activity) and Mg²⁺-ATPase (ouabain-independent activity) and by reduced sodium plasma levels that previously had remained virtually unchanged. There are considered possible causes of the observed decrease in the Na⁺/K⁺-ATPase activity during prolonged starvation, such as aging of the circulating erythrocyte population (the absence of reticulocytes and young erythrocytes), depletion of cell energy resources (hypoglycemia and glycopenia), effect of endogenous ouabain, and endotoxemia.     

Activation of the Na+/K+-ATPase by interleukin-2

Activated B61.SF.1 and CTLL-2 T lymphocyte clones which are strictly dependent on interleukin-2 (IL-2) for growth were used to study the activation of Na+/K+-ATPase. 50% of [3H]thymidine maximal incorporation was obtained when the extracellular concentration of Na+ or K+ was reduced to 50 or 2 mM, respectively. 'Quiescent' CTL clones stimulated with IL-2 showed an increase of 48-380% in ouabain-sensitive 86Rb uptake. Furthermore, this stimulation was completely inhibited by a monoclonal antibody PC.61 directed at the IL-2 receptor. The activation of the pump was dependent on the dose of IL-2, took place at the same doses of IL-2 that were required to stimulate cell proliferation and was linear for at least 30 min.     

Comparison of Na+/K(+)-ATPase pump currents activated by ATP concentration or voltage jumps.

Using the giant patch technique, we combined two fast relaxation methods on excised patches from guinea pig cardiomyocytes to compare the rate constants of the involved reaction steps. Experiments were done in the absence of intra- or extracellular K+. Fast ATP concentration jumps were generated by photolysis of caged ATP at pH 6.3 with laser flash irradiation at a wavelength of 308 nm and 10 ns duration, as described previously. Transient outward currents with a fast rising phase, followed by a slower decay and a small stationary current, were obtained. Voltage pulses were applied to the same patch in the presence or absence of intracellular ATP. Subtraction of the voltage jump-induced currents in the absence of ATP from those taken in the presence of ATP yielded monoexponential transient current signals, which were dependent on external Na+ but did not differ between intracellular pH (pHi) values 6.3 or 7.4. Rate constants showed a characteristic voltage dependence, i.e., saturating at positive potentials (approximately 200 s-1, 24 degrees C) and exponentially rising with increasing negative potentials. Rate constants of the fast component from transient currents obtained after an ATP concentration jump agree well with rate constants from currents obtained after a voltage jump to zero or positive potentials (pHi 6.3), and the two exhibit the same activation energy of approximately 80 kJ.mol-1. For a given membrane patch, the amount of charge that is moved across the plasma membrane is roughly the same for each of the two relaxation techniques.     

Effects of soybean lipoxygenase on Na+/K+-ATPase activity in vitro

Oxidized metabolites of polyunsaturated fatty acids produced by lipoxygenase are among the endogenous regulators of Na+/K+-ATPase. The direct effect of lipoxygenase on Na+/K+-ATPase activity was assessed in vitro using soybean lipoxygenase. Treatment of 4.2 microg/mL Na+/K+-ATPase (from dog kidneys) with 4.2 microg/mL of soybean lipoxygenase caused 20+/-2% inhibition of ATPase activity. A 10-fold increase in lipoxygenase concentration (41.6 microg/mL) led to 30+/-0.3% inhibition. In the presence of 12 microg/mL phenidone (a lipoxygenase inhibitor) and 15.4 microg/mL glutathione (a tripeptide containing a cysteine residue) inhibition of Na+/K+-ATPase activity was blocked and an increase in ATPase activity was observed. The presence of lipoxygenase enhanced the inhibition of Na+/K+-ATPase activity caused by 20 ng/mL ouabain (31+/-2 vs. 19+/-2) but had little or no effect with higher concentrations of ouabain. These findings suggest that lipoxygenase may regulate Na+/K+-ATPase by acting directly on the enzyme.     

Pump current and Na+/K+ coupling ratio of Na+/K+-ATPase in reconstituted lipid vesicles

A method is described for studying the coupling ratio of the Na+/K+ pump, i.e., the ratio of pump-mediated fluxes of Na+ and K+, in a reconstituted system. The method is based on the comparison of the pump-generated current with the rate of K+ transport. Na+/K+-ATPase from kidney is incorporated into the membrane of artificial lipid vesicles; ATPase molecules with outward-oriented ATP-binding site are activated by addition of ATP to the medium. Using oxonol VI as a potential-sensitive dye for measuring transmembrane voltage, the pump current is determined from the change of voltage with time t. In a second set of experiments, the membrane is made selectively K+-permeable by addition of valinomycin, so that the membrane voltage U is equal to the Nernst potential of K+. Under this condition, dU/dt reflects the change of intravesicular K+ concentration and thus the flux of K+. Values of the Na+/K+ coupling ratio determined in this way are close to 1.5 in the experimental range (10-75 mM) of extravesicular (cytoplasmic) Na+ concentrations.     

Modulation of pig kidney Na+/K+-ATPase activity by cholesterol: role of hydration

Cholesterol is known to affect the activity of membrane-bound enzymes, including Na(+)/K(+)-ATPase. To gain insight into the mechanism of cholesterol's effect, we have used various hydrophobic fluorescent probes which insert into different regions of the membrane bilayer and report on the degree of hydration of their environment. Specifially, we have measured the generalized polarization of Laurdan and the lifetime of DPH and derivatives of DPH inserted into membranes from pig kidneys enriched in Na(+)/K(+)-ATPase. Spectral measurements were also carried out on these membranes after modification of their cholesterol content. The generalized polarization of Laurdan increased with increasing cholesterol, showing an abrupt modification at the native cholesterol content. The fluorescence lifetimes of DPH and the DPH derivatives were analyzed using a distribution model. The center value of these lifetime distributions and their widths also changed with increasing cholesterol. One DPH derivative, DPH-PC, showed a minimum value for the lifetime center at the native cholesterol concentration, whereas the other derivatives showed a maximum value for the lifetime center at that cholesterol concentration. DPH-PC is known to sense the protein-lipid interface, whereas the other derivatives sense the bulk lipid phase. These data suggest that hydration at the protein-lipid interface is maximal at the native cholesterol concentration as is the enzymatic activity. Hydration at the protein-lipid interface is therefore proposed to be required for activity. These results are in agreement with current models of membrane dynamics and thermodynamics of protein function.     

Route,mechanism, and implications of proton import during Na+/K+ exchange by native Na+/K+-ATPase pumps

A single Na⁺/K⁺-ATPase pumps three Na⁺ outwards and two K⁺ inwards by alternately exposing ion-binding sites to opposite sides of the membrane in a conformational sequence coupled to pump autophosphorylation from ATP and auto-dephosphorylation. The larger flow of Na⁺ than K⁺ generates outward current across the cell membrane. Less well understood is the ability of Na⁺/K⁺ pumps to generate an inward current of protons. Originally noted in pumps deprived of external K⁺ and Na⁺ ions, as inward current at negative membrane potentials that becomes amplified when external pH is lowered, this proton current is generally viewed as an artifact of those unnatural conditions. We demonstrate here that this inward current also flows at physiological K⁺ and Na⁺ concentrations. We show that protons exploit ready reversibility of conformational changes associated with extracellular Na⁺ release from phosphorylated Na⁺/K⁺ pumps. Reversal of a subset of these transitions allows an extracellular proton to bind an acidic side chain and to be subsequently released to the cytoplasm. This back-step of phosphorylated Na⁺/K⁺ pumps that enables proton import is not required for completion of the 3 Na⁺/2 K⁺ transport cycle. However, the back-step occurs readily during Na⁺/K⁺ transport when external K⁺ ion binding and occlusion are delayed, and it occurs more frequently when lowered extracellular pH raises the probability of protonation of the externally accessible carboxylate side chain. The proton route passes through the Na⁺-selective binding site III and is distinct from the principal pathway traversed by the majority of transported Na⁺ and K⁺ ions that passes through binding site II. The inferred occurrence of Na⁺/K⁺ exchange and H⁺ import during the same conformational cycle of a single molecule identifies the Na⁺/K⁺ pump as a hybrid transporter. Whether Na⁺/K⁺ pump–mediated proton inflow may have any physiological or pathophysiological significance remains to be clarified.     

Gramicidin A directly inhibits mammalian Na+/K+-ATPase

The linear pentadecapeptide gramicidin A forms an ion channel in the lipid bilayer to selectively transport monovalent cations. Nevertheless, we have surprisingly found that gramicidin A directly inhibits mammalian Na(+)/K(+)-ATPase. Gramicidin A inhibited ATP hydrolysis by Na(+)/K(+)-ATPase from porcine cerebral cortex at the IC(50) value of 8.1 microM, while gramicidin S was approximately fivefold less active. The synthetic gramicidin A analog lacking N-terminal formylation and C-terminal ethanolamine exhibited a weaker inhibitory effect on the ATP-hydrolyzing activity of Na(+)/K(+)-ATPase than gramicidin A, indicating that these end modifications are necessary for gramicidin A to inhibit Na(+)/K(+)-ATPase activity. Moreover, Lineweaver-Burk analysis showed that gramicidin A exhibits a mixed type of inhibition. In addition to the most well-studied ionophore activity, our present study has disclosed a novel biological function of gramicidin A as a direct inhibitor of mammalian Na(+)/K(+)-ATPase activity.     

Low-affinity Na+ sites on (Na+ +K+)-ATPase modulate inhibition of Na+-ATPase activity by vanadate

Na+-ATPase activity is extremely sensitive to inhibition by vanadate at low Na+ concentrations where Na+ occupies only high-affinity activation sites. Na+ occupies low-affinity activation sites to reverse inhibition of Na+-ATPase and (Na+, K+)-ATPase activities by vanadate. This effect of Na+ is competitive with respect to both vanadate and Mg2+. The apparent affinity of the enzyme for vanadate is markedly increased by K+. The principal effect of K+ may be to displace Na+ from the low-affinity sites at which it activates Na+-ATPase activity.