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.     

Regulation of Na+,K+ pump activity by nerve growth factor in chick embryo dorsal root ganglion cells

Nerve growth factor (NGF) is required for the growth and development of sensory and sympathetic neurons. Incubation of chick dorsal root ganglionic cells without NGF resulted in a decrease of active (Na+,K+-pump-mediated) K+ influx over a period of several hours. Addition of NGF to NGF-deprived cells caused 1) a return of the active K+ influx to the values occurring in cells continuously exposed to NGF, preceded by 2) a very rapid, but transient overstimulation of the Na+,K+-pump-mediated K+ influx. Restoration of normal Na+,K+-pump activity occurred at NGF concentrations of 1 biological unit/ml or greater, whereas the NGF concentration in the 1-100 biological unit/ml range affected the rapidity with which the pump restoration took place. The transient pump behavior was only observed in NGF-deprived cells and could not be elicited in NGF-supported steady-state cells or in cells having already received delayed NGF once. This transient Na+,K+-pump behavior was exclusively displayed in conjunction with a high intracellular Na+ concentration. Decreasing the external Na+ concentration below 70 mM reduced the hyperstimulation response to NGF, until at 10 mM Na+ the delayed presentation of NGF caused no overshoot at all. The effect of NGF on the Na+,K+-pump was specific for the NGF molecule and could not be mimicked by other proteins.     

Effects of altering the ATP/ADP ratio on pump-mediated Na/K and Na/Na exchanges in resealed human red blood cell ghosts

Resealed human red blood cell ghosts were prepared to contain a range of ADP concentrations at fixed ATP concentrations and vice versa. ATP/ADP ratios ranging from approximately 0.2 to 50 were set and maintained (for up to 45 min) in this system. ATP and ADP concentrations were controlled by the addition of either a phosphoarginine- or phosphocreatine-based regenerating system. Ouabain-sensitive unidirectional Na efflux was determined in the presence and absence of 15 mM external K as a function of the nucleotide composition. Na/K exchange was found to increase to saturation with ATP (K 1/2 approximately equal to 250 microM), whereas Na/Na exchange (measured in K-free solutions) was a saturating function of ADP (K 1/2 approximately equal to 350 microM). The elevation of ATP from approximately 100 to 1,800 microM did not appreciably affect Na/Na exchange. In the presence of external Na and a saturating concentration of external K, increasing the ADP concentration at constant ATP was found to decrease ouabain-sensitive Na/K exchange. The decreased Na/K exchange that still remained when the ADP/ATP ratio was high was stimulated by removal of external Na. Assuming that under normal substrate conditions the reaction cycle of the Na/K pump is rate-limited by the conformational change associated with the release of occluded K [E2 X (K) X ATP----E1 X ATP + K], increasing ADP inhibits the rate of these transformations by competition with ATP for the E2(K) form. A less likely alternative is that inhibition is due to competition with ATP at the high-affinity site (E1). The acceleration of the Na/K pump that occurs upon removing external Na at high levels of ADP evidently results from a shift in the forward direction of the transformation of the intermediates involved with the release of occluded Na from E1P X (Na). Thus, the nucleotide composition and the Na gradient can modulate the rate at which the Na/K pump operates.     

Passive transport of Rb+ by hog gastric (H+,K+)-ATPase

Gastric vesicles enriched in (H+,K+)-ATPase were prepared from hog fundic mucosa and studied for their ability to transport K+ using 86Rb+ as tracer. In the absence of ATP, the vesicles elicited a rapid uptake of 86Rb+ (t 1/2 = 45 +/- 9 s at 30 degrees C) which accounted for both transport and binding. Transport was osmotically sensitive and was the fastest phase. It was not limited by anion permeability (C1- was equivalent to SO2-4) but rather by availability of either H+ or K+ as intravesicular countercation suggesting a Rb+-K+ or a Rb+-H+ exchange. Selectivity was K+ greater than Rb+ greater than Cs+ much greater than Na+,Li+. The capacity of vesicles which catalyzed the fast transport of K+ was 83 +/- 4% of maximal vesicular capacity of the fraction. Addition of ATP decreased both rate and extent of 86Rb+ uptake (by 62 and 43%, respectively with 1 mM ATP) with an apparent Ki of 30 microM. Such an effect was not seen on 22Na+ transport. ATP inhibition of transport did not require the presence of Mg2+, and inhibition was also produced by ADP even in the presence of myokinase inhibitor. On the other hand, 86Rb+ uptake was as strongly inhibited by 200 microM vanadate in the presence of Mg2+. Efflux studies suggested that ATP inhibition was originally due to a decrease of vesicular influx with little or no modification of efflux. Since ATP, ADP, and vanadate are known modulators of the (H+,K+)-ATPase, we propose that, in the absence of ATP, (H+,K+)-ATPase passively exchanges K+ for K+ or H+ and that ATP, ADP, and vanadate regulate this exchange.     

Effects of sodium and potassium ions on the elementary steps in the reaction of Na+-K+-dependent ATPase1.

The effects of Na+ and K+ ions on the elementary steps in the reaction of Na+-K+-dependent ATPase (EC 3.6.1.3) were investigated in 0.5-600mM NaCL and 0-10mM KCL, at a fixed concentration (1mM) OF MgCL2, AT PH 8.5 and at 15 degrees. The data were analyzed on the basis of the reaction mechanism in which a phosphorylated intermediate, E ADP P (abbreviated as EP), is formed via two kinds of enzyme-substrate comples, E1ATP and E2ATP, and EP is in equilibrium with E2ATP, and is hydrolyzed to produce P1 and ADP. The following results were obtained: 1. The rate od E2ATP-formation, vf, increased with increase in the Na+ concentration, reached a maximum level, and then decreased with further increase in the Na+ concentration at various K+ concentrations. The value of vf was given as (see article). 2. The reciprocal of the equilibrium constants, K2, of the step E1ATPEQUILIBRIUM E ADP P in the presence of low concentrations of Na+ was larger than that in the presence of high concrntrations of Na+, indicating that the equilibrium shifted markedly toward E2ATP at low concentrations of Na+. The relation of K3 with Na concentration was rather complicated on varying the concentration of K+. However, generally speaking, it increased with increase in the K+ concentration. 3. The decomposition of EP was markedly activated by even low concentrations of K+, and inhibited by high concentrations of Na+. The inhibition by Na+ was partially suppressed by K+. The rate constant of EP-decomposition, vo/(EP), was given by (see article) where (vo/(EP) K+EQUALS0 was the value of vo/[EP] in the absence of K+.     

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.     

Kinetic mechanism of inhibition of the Na+-pump and some of its partial reactions by external Na+ (Na+o)

The effects of external Na+ on the activity of the Na+-pump are complex. The first-order rate constant for Na+-efflux is reduced in the presence of very low external Na+ concentrations, and this inhibition is reversed when the Na+ level is raised. The same pattern has been observed for Na+-ATPase activity; however, it is not apparent from the current reaction mechanisms at which site (or sites) external Na+ binds to cause inhibition. In this paper, the effect of external Na+ on Na+-pump activity was studied by simulation, using a model similar to the Post-Albers scheme. Curves similar to those experimentally observed were obtained assuming that: (i) after phosphorylation, three Na+ ions are translocated and consecutively released to the external medium with decreasing dissociation constants; (ii) external Na+, with low affinity, binds to the K+o (external) sites stimulating dephosphorylation. These assumptions also permit one to explain the experimental observation that external Na+ (with both high and low affinities) competes with K+, inhibiting the K+ influx due to the Na+-pump, and the kinetically similar behavior of Na+-ATPase and ATP/ADP exchange reactions at low variable Na+ concentrations. The experimental evidence available that supports the present hypothesis is discussed.     

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.     

Mechanisms and consequences of Na+,K+-pump regulation by insulin and leptin.

Hormonal control of the Na+,K+-pump modulates membrane potential in mammalian cells, which in turn drives ion coupled transport processes and maintains cell volume and osmotic balance. Na+,K+-pump regulation is particularly important in the musculoskeletal, cardiovascular and renal systems. Decreased Na+,K+-pump activity can result in a rise in intracellular Na+ concentrations which in turn increase Na+/Ca2+ exchange, thereby raising intracellular Ca2+ levels. In cardiac and skeletal muscle, this could interfere with normal contractile activity. Similarly, in vascular smooth muscle the result would be resistance to vasodilation. Inhibition of the Na+,K+-pump can also reduce the driving force for renal tubular Na+ reabsorption, elevating Na+ excretion. By virtue of decreasing the membrane potential, thus allowing more efficient depolarization of nerve endings and by increasing intracellular Ca2+, inhibition of the Na+,K+-pump can increase nervous tone. The ability of insulin to stimulate the Na+,K+-pump in various cells and tissues, and the physiological significance thereof, have been well documented. Much less is known about the effect of leptin on the Na+,K+-pump. We have shown that leptin inhibits Na+,K+-pump function in 3T3-L1 fibroblasts. Defects in insulin and leptin action are associated with diabetes and obesity, respectively, both of which are commonly associated with cardiovascular complications. In this review we discuss the mechanisms of Na+,K+-pump regulation by insulin and leptin and highlight how, when they fail, they may contribute to the pathophysiology of hypertension associated with diabetes and obesity.     

Novel regulation of Na, K-ATPase by Src tyrosine kinases in cortical neurons

The Na+, K+-ATPase or Na+, K+-pump plays a critical role in ion homeostasis and many cellular events. The Na+, K+-pump activity is regulated by serine/threonine phosphorylation, the role of tyrosine kinases in the regulation, however, is obscure. We now present novel evidence showing that tyrosine phosphorylation activates the Na+, K+-pump in cortical neurons. The electrogenic activity of the Na+, K+-pump was measured using whole-cell voltage clamp. A tonic activity was revealed by an inward current induced by the specific inhibitor ouabain or strophanthidin; an outward current due to activation of the pump was triggered by raising extracellular K+. The inward and outward currents were attenuated by the tyrosine kinase inhibitor genistein, herbimycin A, or lavendustin A, while blocking tyrosine phosphatases increased the pump current. Down-regulation of the pump current was also seen with the Src inhibitor PP1 and intracellularly applied anti-Lyn or anti-Yes antibody. Consistently, intracellular application of Lyn kinase up-regulated the pump current. Immunoprecipitation and western blotting showed tyrosine phosphorylation and a direct interaction between Lyn and the alpha3 subunit of the Na+, K+-pump. The tyrosine phosphorylation of the alpha3 subunit was reduced by serum deprivation. These data suggest that the Na+, K+-ATPase activity in central neurons is regulated by specific Src tyrosine kinases via a protein-protein mechanism and may play a role in apoptosis.     

Transient state in the phosphorylation of sodium- and potassium- transport adenosine triphosphatase by adenosine triphosphate

The rate of phosphorylation of sodium and potassium ion-transport adenosine triphosphatase by 10 microM [gamma-32P]ATP was much slower with Ca2+ than with Mg2+ (0.13-10 mM) in the presence of 16 to 960 mM Na+ at 0 degrees C and pH 7.4. In the presence of a fixed concentration of Mg2+ or Ca2+, the rate became slower with increasing Na+ concentration. When the Na+ concentration was fixed, the rate became slower with decreasing divalent cation concentration. Sodium ions appear to antagonize the divalent cation in the phosphorylation to slow its rate. In the presence of 1 mM Ca2+ and 126 or 270 mM Na+, the rate was slow enough to permit the manual addition of a chasing solution at various times before the phosphorylation reached the steady state. Therefore, we studied the time-dependent change of the sensitivity to ADP or to K+ of the phosphoenzyme by a chase with unlabeled ATP containing ADP or K+ during the time range from the transient to the steady state of the phosphorylation. The ADP sensitivity decreased and the K+ sensitivity increased with the progress of the phosphorylation. With 270 mM Na+, the phosphoenzyme found at 1 s, when its amount was 5.5% of the maximum level, was virtually completely sensitive to ADP. Under these conditions, it was concluded that the form of the phosphoenzyme initially produced from the enzyme.ATP complex has ADP sensitivity and that the phosphoenzyme acquires K+ sensitivity later. The initially produced ADP-sensitive phosphoenzyme partially lost its normal instability and sensitivity upon adding a chelating agent, probably because of dissociation of a divalent cation from the phosphoenzyme.     

Characterization of the phosphorylated intermediate of the K+-translocating Kdp-ATPase from Escherichia coli

During ATP hydrolysis the K+-translocating Kdp-ATPase from Escherichia coli forms a phosphorylated intermediate as part of the catalytic cycle. The influence of effectors (K+, Na+, Mg2+, ATP, ADP) and inhibitors (vanadate, N-ethylmaleimide, bafilomycin A1) on the phosphointermediate level and on the ATPase activity was analyzed in purified wild-type enzyme (apparent Km = 10 microM) and a KdpA mutant ATPase exhibiting a lower affinity for K+ (Km = 6 mM). Based on these data we propose a minimum reaction scheme consisting of (i) a Mg2+-dependent protein kinase, (ii) a Mg2+-dependent and K+-stimulated phosphoprotein phosphatase, and (iii) a K+-independent basal phosphoprotein phosphatase. The findings of a K+-uncoupled basal activity, inhibition by high K+ concentrations, lower ATP saturation values for the phosphorylation than for the overall ATPase reaction, and presumed reversibility of the phosphoprotein formation by excess ADP indicated similarities in fundamental principles of the reaction cycle between the Kdp-ATPase and eukaryotic E1E2-ATPases. The phosphoprotein was tentatively characterized as an acylphosphate on the basis of its alkali-lability and its sensitivity to hydroxylamine. The KdpB polypeptide was identified as the phosphorylated subunit after electrophoretic separation at pH 2.4, 4 degrees C of cytoplasmic membranes or of purified ATPase labeled with [gamma-32P]ATP.     

Specific effects of spermine on Na+,K+-adenosine triphosphatase

Specific effects of spermine on Na+,K+-ATPase were observed using an enzyme partially purified from rabbit kidney microsomes by extraction with deoxycholate. 1. Spermine competed with K+ for K+-dependent, ouabain-sensitive nitrophenylphosphatase. The K1 for spermine was 0.075 mm in the presence of 1 mM Mg2+ and 5 mM p-nitrophenylphosphate at pH 7.5. 2. spermine activated Na+,K+-ATPase over limited concentration ranges of K+ and Na+ in the presence of 0.05 mM ATP. The spermine concentration required for half maximal activation was 0.055 mM in the presence of 1 mM K+, 10 mM Na+, 1 mM Mg2+, and 0.05 mM ATP. 3. The activation of Na+,K4-ATPase was not due to substitution of spermine for K+, Na+, or Mg2+. 4. When the concentration of K+ or Na+ was extremely low, or in excess, spermine did not activate Na+,K+-ATPase, but inhibited it slightly. 5. Plots of 1/v vs. 1/[ATP] at various concentrations of spermine showed that spermine decreased the Km for ATP without changing the Vmax. 6. Plots of 1/v vs. 1/[ATP] at concentrations of K+ from 0.05 mM to 0.5 mM showed that K+ increased the Km for ATP with increase in the Vmax in the presence of 0.2 mM spermine similarly to that in the absence of spermine. The contradictory effects of spermine on this enzyme system suggest that the K+-dependent monophosphatase activity does not reflect the second half (the dephosphorylation step) of the Na+,K+-ATPase catalytic cycle.     

Rapid release of 42K and 86Rb from an occluded state of the Na,K-pump in the presence of ATP or ADP

We have measured the time course of release of 42K and 86Rb from an occluded state of the Na,K-pump using a rapid filtration apparatus. We have found that at 20 degrees C and in the presence of ATP, 42K is released with a rate constant of approximately 45 s-1 and 86Rb with a rate constant of approximately 20 s-1; both ATP and ADP are effective at a low affinity site (Kd approximately 0.3 and 1 mM, respectively) with the rate of deocclusion being only half as great in ADP as in ATP. Mg2+ stimulates 2-fold at low concentrations probably by forming MgATP, and free Mg2+ is strongly inhibitory at high concentrations (Kd approximately 10 mM). Mg2+ also decreases the affinity for ATP, and the data are consistent with mixed type inhibition; from the analysis the dissociation constant is approximately 1 mM for the inhibitory Mg2+ and the Rb+-occluded form without ATP. The rate of 42K or 86Rb release increases monotonically with pH while ATPase activity decreases above pH 8, so that deocclusion is not rate-limiting in the overall cycle at high pH. This is reflected by a convergence of the rate of Na,K-ATPase and Na,Rb-ATPase activities at high pH and by a decrease in the observed steady-state level of the occluded 86Rb intermediate at high pH. K+, Rb+, Na+, and Cs+, but not Li+, increase the rate of 42K and 86Rb release at constant ionic strength, presumably at sites other than the transport sites. The spontaneous rate of deocclusion is only approximately 0.1 s-1 at low ionic strength in the absence of nucleotides, and it is increased markedly by all cations tested except Li+. Overall the data are consistent with deocclusion as a rate-limiting step in the Na,K-pump cycle.     

Cis-allosteric effects of cytoplasmic Na+/K+ discrimination at varying pH. Low-affinity multisite inhibition of cytoplasmic K+ in reconstituted Na+/K(+)-ATPase engaged in uncoupled Na(+)-efflux.

In liposomes with reconstituted shark Na+/K(+)-ATPase the effect of cytoplasmic K+ was investigated in the absence of extracellular alkali ions. During such conditions the Na+/K(+)-ATPase is engaged in the so called uncoupled Na+ efflux mode in which cytoplasmic Na+ activates and binds to the enzyme and becomes translocated without countertransport of K+ as in the physiological Na+/K+ exchange mode. In this uncoupled flux mode only low-affinity inhibition by K+cyt is found to be present. The inhibition pattern is consistent with a model in which cytoplasmic K+ exhibit mixed inhibition of Na+ activation, probably by binding at the three cytoplasmic loading sites on E1ATP (E1A). With determined intrinsic binding constants for cytoplasmic Na+ to this form of KS1, KS2, KS3 = 40 mM, 2 mM, 2 mM the inhibition pattern can be simulated assuming three K+cyt sites with equal affinity for Ki = 40 mM, similar to KS1 for the first Na+cyt site. The discrimination between cytoplasmic Na+ and K+ is therefore enhanced by allosteric interaction initiated from the cis-side due to binding of the first Na+, as opposed to K+, which induces the positive cooperatively in the successive Na+ bindings. pH is found to influence the pattern of K+cyt inhibition: A lowering of the pH potentiates the K+cyt inhibition, whereas at increased pH the inhibition is decreased and transformed into a pure competitive competition.     

Ligand binding to (Na,K)-ATPase labeled with 5-iodoacetamidofluorescein

The equilibrium binding of sodium, potassium, and adenine nucleotides to dog kidney (Na,K)-ATPase was studied by measuring changes in the fluorescence of enzyme labeled with 5-iodoacetamidofluorescein (5-IAF). The intensity of the fluorescence emission at 520 nm of the bound fluorescein (excited at 490 nm) is increased by ATP, adenyl-5'-yl imidodiphosphate (AMP-PNP), ADP (but not AMP), and Na+, and decreased by K+, Rb+, NH+4, and LI+. Thus the fluorescence effects correlate with the ability of these groups of ligands to stabilize E1 and E2 conformations, respectively. The Na+-induced increase in fluorescence has two components: a slow, high-affinity increase of approximately 7% (K0.5 = 0.16 mM) with positive cooperativity; and a large (approximately 15%), rapid, low-affinity (K0.5 = 34 mM) increase that is not cooperative. The K0.5 for the high-affinity effect is decreased by oligomycin and increased by K+. ATP effects on the fluorescence follow Michaelis-Menten kinetics and are of high affinity (K0.5 = 0.12 microM); K+ increases the K0.5 for ATP, AMP-PNP, and ADP but does not induce cooperative behavior. K+ itself decreases the fluorescence signal by about 9%, with high affinity (K0.5 = 5 microM), showing Michaelis-menten behavior in the absence of other ligands, while with ATP, Na+, or Mg2+ present, K+ effects are cooperative and of lower affinity.     

Substrate inhibition of the (Na+, K+)-ATPase in the presence of excess Mg2+.

1. High concentrations of ATP inhibit completely the activity of (Na+, K+)-ATPase (ATP phosphohydrolase, EC 3.6.1.3) prepared from sheep brain. 2. The inhibition depends on the concentration of total ATP, i.e. complexed ATP+ free ATP. 3. The inhibition by high ATP concentrations persists in the absence of K+, and is then independent of the Na+ concentration between 2 and 140 mM Na+. 4. Raising the K+ concentration at 20 mM Na+ increases the ATP concentration required for the maximal hydrolysis rate. 5. The Hill number for the inhibition process is about three. 6. The inhibition by ATP is temperature-dependent, in that as the temperature is increased, higher ATP concentrations are required for inhibition.     

Properties of the conversion of an enzyme-ATP complex to a phosphorylated intermediate in the reaction of Na+-K+-dependent ATPase1.

Previously, we proposed the following reaction machanism for the transport ATPase (EC 3.6.1.3) reaction in the presence of high concentrations of Mg2+ and Na+:(see article). Some kinetic and thermodynamic properties of steps 3 and 4 were investigated, and the following results were obtained. 1. When the reaction was started by adding ATP to the enzyme in the presence of 50 mM Na+ and 0.5 mM K+ or in the presence of 50mM Na+ and 0.5mM Rb+, the amount of E ADP P increased with time and maintained a constant level after reaching a maximum. We could not observe the initial burst of EP formation, which was observed by Post er al. in the presence of 8 mM Na+ and 0.01 mM Rb+. 2. The existence of quasi-equilibrium between E2ATP and E ADP P in the presence of low concentrations of Na+ was suggested by the fact that the values of the reciprocal of the equilibrium constant, K3 of step 3 obtained by the following three methods were almost the same. a) The value of 1+K3 was estimated from the ratio of vo/[EP] to kd, where vo is the rate of ATP hydrolysis in the steady state, [EP] the concentration of EP, and kd the first-order rate constant of EP disappearance after stopping EP formation. b) This value was also calculated from the ratio of the amount of P1 liberated to that of decrease in EP after stopping EP formation. c) The value of K3 was also calculated from the initial rapid decrease in EP on adding K+ and EDTA, assuming that the rapid decrease was due to a shift of the equilibrium toward E2ATP on adding K+. For example, the value of K3 with 10mM NaCL and 0.5mM KCL was 7--11. Although ATP formation due to a shift of the equilibrium toward E2ATP by a K+ jump in the presence of a low concentration of Na+ was observed at 0 degrees, the amount of ATP formed by a K+ jump at 15 degrees was less than the value expected from the shift of the equilibrium. 3. The values of delta H degrees and delta S degrees of step 3 were estimated in the presence of a sufficient amount of Na+ and in the absence of K+. They were +4--+5 kcal mole minus 1 and +15--+16 entropy units mole minus1, respectively. On the basis of kinetic studies of the elementary steps and the overall reaction of Na+-K+-dependent ATPase [EC 3.6.1.3], we (1--4) showed that a phosphorylated intermediate, EP, is formed via two kinds of enzyme-substrate complex, E1ATP and E2ATP, that the EP is in K+-dependent quasi-equilibrium with E2ATP, and that in the presence of high concentration of Mg2+, EP is in a high-energy state and contains bound ADP, E ADP P.(see article).     

Effects of glycyrrhizin and glycyrrhetinic acid on (Na+ + K+)-ATPase of renal basolateral membranes in vitro

Studies were made on the direct effects of glycyrrhizin and its aglycone, glycyrrhetinic acid on the activities of (Na+ + K+)-ATPase and (Ca2+ + Mg2+)-ATPase, a membrane bound Na+ and Ca2+-extrusion pump enzyme of the basolateral membranes (BLM) of canine kidney. Glycyrrhetinic acid inhibited the activity of the Na+-pump enzyme dose-dependently (IC50 = 1.5 x 10(-4) M), but had no effect on that of the Ca2+-pump enzyme of kidney BLM and homogenates. Glycyrrhizin also inhibited the Na+-pump enzyme activity but had less effect (IC50 = 2 x 10(-3) M). The effects of these compounds were due to competitive inhibition with ATP binding to the enzyme (Ki = 12 microM) and so were different from that of ouabain, which inhibits the Na+-pump by binding to its extracellular K+-binding site. The direct effect of glycyrrhetinic acid on the membrane may be important role in the multiple actions of licorice.     

Interaction of sodium and potassium ions with Na+,K(+)-ATPase. IV. Affinity change for K+ and Na+ of Na+,K(+)-ATPase in the cycle of the ATP hydrolysis reaction

The Kd for ouabain-sensitive K+ or Rb+ binding to Na+,K(+)-ATPase was determined by the centrifugation method with radioactive K+ and Rb+ in the presence of various combinations of Na+, ATP, adenylylimidodiphosphate (AMPPNP), adenylyl-(beta,gamma-methylene)diphosphonate (AMPPCP), Pi, and Mg2+. From the results of the K+ binding experiments, Kd for Na+ was estimated by using an equation describing the competitive inhibition between the K+ and Na+ binding. 1) The Kd for K+ binding was 1.9 microM when no ligand was present. Addition of 2 mM Mg2+ increased the Kd to 15-17 microM. In the presence of 2 mM Mg2+, addition of 3 mM AMPPCP with or without 3 mM Na+ increased the Kd to 1,000 or 26 microM, respectively. These Kds correspond to those for K+ of Na.E1.AMPPCPMg or E1.AMPPCPMg, respectively. 2) Addition of 4 mM ATP with or without 3 mM Na+ decreased the Kd from 15-17 microM to 5 or 0.8 microM, respectively. Because the phosphorylated intermediate was observed but ATPase activity was scarcely observed in the K+ binding medium containing 3 mM ATP and 2 mM Mg2+ in the absence of Na+ as well as in the presence of Na+ at 0 degrees C, it is suggested that K+ binds to E2-P.Mg under these ligand conditions. 3) The Kd for Na+ of the enzyme in the presence of 3 mM AMPPCP or 4 mM ATP with Mg2+ was estimated to be 80 or 570 microM, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)