Sidedness of the ATP-Na+-K+ interactions with the Na+ pump in squid axons

Using dialysed squid axons we have been able to control internal and external ionic compositions under conditions in which most of the Na⁺ efflux goes through the Na⁺ pump. We found that (i) internal K⁺ had a strong inhibitory effect on Na⁺ efflux; this effect was antagonized by ATP, with low affinity, and by internal Na⁺, (ii) a reduction in ATP levels from 3 mM to 50 μM greatly increased the apparent affinity for external K⁺, but reduced its effectiveness compared with other monovalent cations, as an activator of Na⁺ efflux, and (iii) the relative effectiveness of different K⁺ congeners as external activator of the Na⁺ efflux, though affected by the ATP concentration, was not affected by the Na⁺/⁺ ratio inside the cells. These results are consistent with the idea that the same conformation of the (Na⁺ + K⁺)-ATPase can be reached by interaction with external K⁺ after phosphorylation and with internal K⁺ before rephosphorylation. They also stress a nonphosphorylating regulatory role of ATP.     

Modulation of Ca2+-mediated K+-gating of erythrocyte ghosts by external Ca-EGTA

Using 86Rb+ as a marker for K+ permeability, we find that extracellular Ca-EGTA influences the rate of 86Rb+ efflux from erythrocyte ghosts preloaded with 86Rb+ and "buffered" Ca2+. At an internal free Ca2+, where the rate of 86Rb+ efflux is minimal and uninfluenced by either external EGTA or external Ca2+, external Ca-EGTA at 0.2-0.5 mM can raise the flux rate to as high as can be attained by raising internal Ca2+, in the presence of an excess externally either of Ca2+ or of EGTA. Higher concentrations of Ca-EGTA (up to 1-2 mM) diminish the flux rate. External Ca-EDTA or Mg-EDTA can substitute for Ca-EGTA in enhancing and suppressing flux rate. The peak rate is insensitive to external free Ca2+ but depends on internal Ca2+; internal Mg-EDTA does not substitute for internal Ca-EGTA. Thus, the erythrocyte membrane is asymmetric with respect to its interaction with Ca2+ and Ca-EGTA. Also, 22Na+ does not substitute for 86Rb+. The peak rate of 86Rb+ flux produced by external Ca-EGTA is diminished by chlorpromazine (0.1 mM) and augmented by 1-propranolol (25 microM), in the same way as the rate produced by increasing internal Ca2+. The results suggest that external Ca-EGTA enhances the affinity of internal Ca2+ for its receptor(s) which operate the K+-gate at the inner surface of the membrane. At external concentrations of Ca-EGTA above 1-2 mM, 86Rb+ flux rate again rises with increase of Ca-EGTA. This phenomenon does not depend upon internal Ca2+, is not affected by chlorpromazine or by 1-propranolol, and is associated with an enhanced permeability to 22Na+, inulin, and haemoglobin.     

Calcium transport mechanisms in dog red blood cells studied from measurements of initial flux rates

Ca2+ efflux from dog red blood cells loaded with Ca2+ using the A23187 ionophore could be separated into two main components: (1) Mg- and ATP-dependent (active transport) and (2) dependent on external Na (K1/2 around 15 mM); at 80 microM internal free Ca the relative magnitudes of these fluxes were 70% and 30% respectively. The Na-dependent Ca2+ efflux had the following additional properties: (i) it was partially inhibited by ATP depletion or preincubation with vanadate, but it was not affected by Mg2+ depletion; (ii) it failed to be stimulated by external monovalent cations other than Na: (iii) it was stimulated by reduction in the internal Na+ concentration. Both active and Na-dependent Ca2+ efflux remained unchanged in hypotonic solutions or in solutions with alkaline pH (8.5). In cells containing ATP and Mg2+, external Ca2+ inhibited Ca2+ efflux (K1/2 around 1 mM); on the other hand, in Mg-free dog red cells external Ca2+ stimulated Ca2+ efflux (K1/2 about 30 microM). In Mg-depleted red cells incubated in the absence of external Na2+, Ca2+ influx as a function of external Ca2+ followed a monotonically saturable function (K1/2 around 20 microM): addition of Na resulted in (i) inhibition of Ca2+ influx and (ii) a sigmoid relationship between flux and external Ca2+. Intracellular Ca2+ stimulated the external Na-dependent Ca2+ efflux along a sigmoid curve (K1/2 around 30 microM); on the other hand the Ca pump had a biphasic response to internal Ca2+: stimulation at low internal Ca2+ (K1/2 between 1 and 10 microM), followed by a decline at internal Ca2+ concentrations higher than 50 microM.     

Effects of ATP on the intermediary steps of the reaction of the (Na+ + K+)-ATPase. IV. Effect of ATP on K0.5 for Na+ and on hydrolysis at different pH and temperature.

The pH optimum for (Na+ + K+)-ATPase (ATP phosphohydrolase, EC 3.6.1.3) depends on the combination of monovalent cations, on the ATP concentration and on temperature. ATP decreases the Na+ concentration necessary for half maximum activation, K0.5 for Na+ (Na+ + K+ = 150 mM), and the effect is pH and temperature dependent. At a low ATP concentration a decrease in pH leads to an increase in K0.5 for Na+, while at the high ATP concentration it leads to a decrease. K0.5 for ATP for hydrolysis decreases with an increase in pH. The fractional stimulation by K+ in the presence of Na+ decreases with the ATP concentration, and at a low ATP concentration K+ becomes inhibitory, this being most pronounced at 0 degrees C. The results suggest that (a) ATP at a given pH has two different effects: it increases the Na+ relative to K+ affinity on the internal site (K0.5 for ATP at pH 7.4, 37 degrees C, is less than 10 microM); it increases the molar activity in the presence of Na+ + K+ (K0.5 for ATP at pH 7.4, 37 degrees , is 127 microM), (b) binding of the cations to the external as well as the internal sites leads to pK changes (Bohr effect) which are different for Na+ and for K+, i.e. the selectivity for Na+ relative to K+ depends both on ATP and on the degree of protonation of certain groups on the system, (c) ATP involves an extra dissociable group in the determination of the selectivity of the internal site, and thereby changes the effect of an increase in protonation of the system from a decrease to an increase in selectivity for Na+ relative to K+.     

The ATP dependence of a ouabain-sensitive sodium efflux activated by external sodium, potassium and lithium in human red cells.

The stimulation of ouabain-sensitive Na+ efflux by external Na+, K+ and Li+ was studied in control and ATP-depleted human red cells. In the presence of 5 mM Na+, with control and depleted cells, Li+ stimulated with a lower apparent affinity than K+, and gave a smaller maximal activation than K+. The ability of Na+, K+ and Li+ to activate Na+ efflux was a function of the ATP content of the cells. Relative to K+ both Na+ and Li+ became more effective activators when the ATP was reduced to about one tenth of the control values. At this low ATP concentration Na+ was absolutely more effective than K+.     

In squid axons intracellular Mg2+ is essential for ATP-dependent Na+ efflux in the absence and presence of strophanthidin

The effect on Na+ efflux of removal of intracellular Mg2+ was studied in squid giant axons dialyzed without internal Ca2+. In the absence of Mg2i+, ATP was unable to stimulate any efflux of Na+ above the baseline of about 1 pmol . cm-2 . s-1. This behavior was observed in otherwise normal axons and in axons poisoned with 50 microM strophanthidin in the sea water. Reinstatement of 4 mM MgCl2 in excess to ATP in the dialysis solution brought about the usual response of Na+ efflux to ATP, external K+ and strophanthidin. The present experiments show that, regardless of the mechanism for the ATP-dependent Na+ efflux in strophanthidin-poisoned axons, this type of flux shares with the active Na+ extrusion the need for the simultaneous presence of intracellular ATP and Mg2+.     

(Na+, K+)-activated adenosinetriphosphatase of axonal membranes, cooperativity and control. Steady-state analysis.

1. The ATP sites. Homotropic interactions between ATP sites have been studied in a very large range of Na+ and K+ concentrations. The ( Na+, K+)-activated ATPase displays Michaelis-Menten kinetics for ATP under standard concentration conditions of Na+ (100 mM) and K+ (10 mM). The steady-state kinetics behavior changes at very low concentrations of K+ where negative cooperativity is observed. The existence of a high affinity and a low affinity site for ATP was clearly demonstrated from the study of the ATP stimulated hydrolysis of p-nitrophenylphosphate in the presence of Na+ and K+. The ratio of apparent affinities of high and low affinity sites for ATP is 86 at pH 7.5. 2. The Na+ sites. The binding of Na+ to its specific stimulatory sites (internal sites) is characterized by positive cooperativity with a Hill coefficient n(H(Na+))=2.0. Homotropic interactions between Na+ sites are unaffected by variations of the K+ concentration. 3. The K+ sites. (a) Binding of K+ to the (external) stimulatory site of the ATPase has been analyzed by following the (Na+, K+)-ATPase activity as well as the p-nitrophenylphosphatase activity in the presence of Na+ and K+ (with or without ATP). Binding is characterized by a Hill coefficient of 1.0 and a K(0.5(K+))=0.1 to 0.8 mM. The absence of positive or negative cooperativity persists between 5 mM and 100 mM Na+. (b) The analysis of the p-nitrophenylphosphatase or of the 2, 4 dinitrophenylphosphatase activity in the presence of K+ alone indicates the existence of low affinity sites for K+ with positive homotropic interactions. The characteristics of stimulation in that case are, K(0.5)=5 mM, n(H)=1.9. The properties of this family of site(s) are the following: firstly, saturation of the low affinity site(s) by K+ prevents ATP binding to its high affinity internal site. Secondly, saturation of the low affinity sites for K+ prevents binding of Na+ to its internal sites. Thirdly, this family of sites disappears in the presence of ATP, p-nitrophenylphosphate or of both substrates, when Na+ binds to its internal sites. Na+ binding to its specific stimulatory sites provokes the formation of the high affinity type of site for K+. 4. Mg2+ stimulation of the (Na+, K+)-ATPase is characterized by a Hill coefficient n(H(Mg2+))=1.0 and a K(0.5(Mg2+))=1 mM stimulation is essentially a V effect. Heterotropic effects between binding of Mg2+ and substrate to their respective sites are small. Heterotropic interactions between the Ms2+, Na+ and K+ sites are also small. 5. The fluidity of membrane lipids also controls the (Na+, K+)-ATPase activity. Phase transitions or separations in the membrane hardly affect recognition properties of substrates, Na+, K+ and Mg2+ for their respective sites on both sides of the membrane. Only the rate of the catalytic transformation is affected.     

Interaction of external H+ with the Na+-H+ exchanger in renal microvillus membrane vesicles

We examined the effects of external H+ on the kinetics of Na+-H+ exchange in microvillus membrane vesicles isolated from the rabbit renal cortex. The initial rate of Na+ influx into vesicles with internal pH 6.0 was optimal at external pH 8.5 and was progressively inhibited as external pH was reduced to 6.0. A plot of 1/V versus [H+]o was linear and yielded apparent KH = 35 nM (apparent pK 7.5). In vesicles with internal pH 6.0 studied at external pH 7.5 or 6.6, apparent KNa was 13 or 54 mM, Ki for inhibition of Na+ influx by external Li+ was 1.2 or 5.2 mM, Ki for inhibition by external NH4+ was 11 or 50 mM, and Ki for inhibition by external amiloride was 7 or 25 microM, respectively. These findings were consistent with competition between each cation and H+ at a site with apparent pK 7.3-7.5. Lastly, stimulation of 22Na efflux by external Na+ (i.e. Na+-Na+ exchange) was inhibited as external pH was reduced from 7.5 to 6.0, also consistent with competition between external H+ and external Na+. Thus, in contrast with internal H+, which interacts at both transport and activator sites, external H+ interacts with the renal microvillus membrane Na+-H+ exchanger at a single site, namely the external transport site, where H+, Na+, Li+, NH4+, and amiloride all compete for binding.     

Effects of ATP and protons on the Na : K selectivity of the (Na+ + K+)-ATPase studied by ligand effects on intrinsic and extrinsic fluorescence

The effect of pH and of ATP on the Na : K selectivity of the (Na+ + K+)-ATPase has been tested under equilibrium conditions. The Na+ : K+-induced change in intrinsic tryptophan fluorescence and in fluorescence of eosin maleimide bound to the system has been used as a tool. 1 mol of eosin maleimide per mol of enzyme gives no loss in either ATPase or phosphatase activity and the fluorescence in the presence of Na+ is about 30% higher than in the presence of K+. Choline, protonated Tris, protonated histidine and Mg2+ have an 'Na+' effect on the extrinsic fluorescence, while Rb+, Cs+ and NH4+ have a 'K+' effect. Choline and protonated Tris have an Na+ effect on intrinsic fluorescence. A close correlation between the effect of Na+ compared to K+ on the fluorescence change and on Na+ activation of hydrolysis indicates that the observed changes in fluorescence are due to an effect of Na+ and of K+ on the internal sites of the system. The equilibrium between the two conformations, which are reflected by the difference in fluorescence with Na+ and K+, respectively, is highly influenced by the concentration of protons. At a given Na+ : K+ ratio, an increase in the proton concentration shifts the equilibrium towards the 'K+' fluorescence form while a decrease shifts the equilibrium towards the 'Na+' fluorescence form, i.e., protons increase the apparent affinity for K+ and vice versa, K+ increases pK values of importance for the Na+ : K+ selectivity. Conversely, a decrease in protons increases the apparent affinity for Na+ and vice versa, Na+ decreases the pK. ATP decreases the apparent pK for the protonation-deprotonation, i.e., ATP facilitates the deprotonation which accompanies Na+ binding. The results suggest two effects of ATP for the hydrolysis in the presence of Na+ and K+ : (i) at low ATP concentrations (K0.5 < 10 microM) on the K+-Na+ exchange on the internal sites and (ii) at higher, substrate, concentrations on the activation by K+ on the external sites.     

A one-to-one Mg2+:Mn2+ exchange in rat erythrocytes

Mg2+ efflux in rat erythrocytes was stimulated by increases in external Na+ concentration following a Michaelian-like function with an apparent dissociation constant (KNa) of 11 +/- 3 mM (mean +/- S.D. of three experiments) and a variable maximal rate ranging from 150 to 1200 mumol (liter (1) cells X h)-1. Na+-stimulated Mg2+ efflux was inhibited by quinidine and by ATP depletion. In the absence of external Na+, Mg2+ efflux was stimulated by increases in external Mn2+ concentration following a Michaelian-like function with an apparent dissociation constant (KMn) of 35 +/- 15 microM (mean +/- S.D. of four experiments) and a variable maximal rate ranging from 350 to 1400 mumol (1 cells X h)-1. Mn2+-stimulated Mg2+ efflux was inhibited by quinidine, by ATP depletion, and by increasing the external Na+ concentration. Quinidine-sensitive (or ATP-dependent) Mg2+ efflux exhibited very similar values when compared with quinidine-sensitive (or ATP-dependent) Mn2+ influx. Mn2+ efflux in rat erythrocytes (loaded with total internal Mn2+ contents of 230-450 mumol/l cells) was stimulated by increases in external Na+ concentration and inhibited by quinidine. In the absence of external Na+, Mn2+ efflux was stimulated by increases in external Mg2+ concentration following a Michaelian-like function with an apparent dissociation constant (KMg) of about 35 +/- 5 microM (mean +/- range of two experiments) and a maximal rate of about 60-100 mumol (1 cells X h)-1. In conclusion, the Na+-stimulated Mg2+ carrier of rat erythrocytes may catalyze a one-to-one and reversible Mn2+:Mg2+ exchange in the absence of external Na+.     

ATPase and phosphatase activities from human red cell membranes. III. Stimulation of K+-activated phosphatase by phospholipase C.

Treatment of red cell membranes with pure phospholipase C inactivates (Na+ + K+)-ATPase activity and Na+-dependent phosphorylation but increases K+-dependent phosphatase activity. When phospholipase A2 replaces phospholipase C, all activities are lost. Activation of K+-dependent phosphatase by treatment with phospholipase C is caused by an increase in the maximum rate of hydrolysis of p-nitrophenylphosphate and in the maximum activating effect of K+, the apparent affinities for substrate and cofactors being little affected. After phospholipase C treatment K+-dependent phosphatase is no longer sensitive to ouabain but becomes more sensitive to N-ethylmaleimide. In treated membranes Na+ partially replaces K+ as an activator of the phosphatase. Although ATP still inhibits phosphatase activity, neither ATP, nor ATP+Na+ are able to modify the apparent affinity for K+ of K+-dependent phosphatase in these membranes.     

Regulatory interaction of ATP Na+ and Cl- in the turnover cycle of the NaK2Cl cotransporter

To probe the mechanism by which intracellular ATP, Na+, and Cl- influence the activity of the NaK2Cl cotransporter, we measured bumetanide-sensitive (BS) 86Rb fluxes in the osteosarcoma cell line UMR- 106-01. Under physiological gradients of Na+, K+, and Cl-, depleting cellular ATP by incubation with deoxyglucose and antimycin A (DOG/AA) for 20 min at 37 degrees C reduced BS 86Rb uptake from 6 to 1 nmol/mg protein per min. Similar incubation with 0.5 mM ouabain to inhibit the Na+ pump had no effect on the uptake, excluding the possibility that DOG/AA inhibited the uptake by modifying the cellular Na+ and K+ gradients. Loading the cells with Na+ and depleting them of K+ by a 2-3- h incubation with ouabain or DOG/AA increased the rate of BS 86Rb uptake to approximately 12 nmol/mg protein per min. The unidirectional BS 86Rb influx into control cells was approximately 10 times faster than the unidirectional BS 86Rb efflux. On the other hand, at steady state the unidirectional BS 86Rb influx and efflux in ouabain-treated cells were similar, suggesting that most of the BS 86Rb uptake into the ouabain-treated cells is due to K+/K+ exchange. The entire BS 86Rb uptake into ouabain-treated cells was insensitive to depletion of cellular ATP. However, the influx could be converted to ATP-sensitive influx by reducing cellular Cl- and/or Na+ in ouabain-treated cells to impose conditions for net uptake of the ions. The BS 86Rb uptake in ouabain-treated cells required the presence of Na+, K+, and Cl- in the extracellular medium. Thus, loading the cells with Na+ induced rapid 86Rb (K+) influx and efflux which, unlike net uptake, were insensitive to cellular ATP. Therefore, we suggest that ATP regulates a step in the turnover cycle of the cotransporter that is required for net but not K+/K+ exchange fluxes. Depleting control cells of Cl- increased BS 86Rb uptake from medium-containing physiological Na+ and K+ concentrations from 6 to approximately 15 nmol/mg protein per min. The uptake was blocked by depletion of cellular ATP with DOG/AA and required the presence of all three ions in the external medium. Thus, intracellular Cl- appears to influence net uptake by the cotransporter. Depletion of intracellular Na+ was as effective as depletion of Cl- in stimulating BS 86Rb uptake.(ABSTRACT TRUNCATED AT 400 WORDS)     

Changes in the composition of two molecular species of ethanolamine plasmalogen in normal human myelin during development

The effect of external and internal K+ on Na+o-dependent Ca2+ efflux was studied in dialyzed squid axons under constant membrane potential. With axons clamped at their resting potentials, external K+ (up to 70 mM) has no effect on Na+-Ca2+ exchange. Removal of Ki+ causes a marked inhibition in the Na+o-dependent Ca2+ efflux component. Internal K+ activates the Na+-Ca2+ exchange with low affinity (K 1/2 = 90 mM). Activation by Ki+ is similar in the presence or in the absence of Na+i, thus ruling out a displacement of Na+i from its inhibitory site. Axons dialyzed with ATP also show a dependency of Ca2+ efflux on Ki+. The present results demonstrate that Ki+ is an important cofactor (partially required) for the proper functioning of the forward Na+-Ca2+ exchange.     

Characterization of a Mg2+-stabilized state of the (Na+ and K+)--stimulated adenosine triphosphatase using a fluorescent reporter group

A Mg2+-induced change of the (Na+ and K+)-stimulated adenosine triphosphatase (Na+,K+)-ATPase) from Electrophorus electricus was investigated by kinetics and fluorescence techniques. Binding of Mg2+ to a low affinity site(s) caused inhibition of (Na+,K+)-ATPase activity, an effect which was antagonized by both Na+ and ATP. Mg2+ also caused inhibition of K+-dependent dephosphorylation of the enzyme without inhibiting either (Na+)-ATPase activity or Na+-dependent phosphorylation. Mg2+ also induced a 5 to 6% enhancement in the fluorescence intensity of enzyme labeled with the fluorescent sulfhydryl reagent, 2-(4-maleimidylanilino)naphthalene-6-sulfonate. As in the case of Mg2+ inhibition of activity, the affinity for Mg2+ as an inducing agent for this effect was significantly reduced by both Na+ and ATP, suggesting that the same change was being monitored in both cases. The Mg2+ effect was reduced by both Na+ and ATP, suggesting that the same change was being monitored in both cases. The Mg2+ effect was reduced in magnitude by ouabain and prevented by oligomycin, specific inhibitors of the enzyme. In addition, K+ (and cations that substitute for K+ in supporting activity) induced a 3 to 4% enhancement in fluorescence intensity in the presence of Na+, Mg2+, and ATP, although the K+ and Mg2+ effects appeared to be different on the basis of their excitation spectra. The K+ effect was inhibited by ouabain and occurred with a rate greater than the rate of turnover of the enzyme, permitting its involvement in the catalytic cycle.     

ATP inactivates hydrolysis of the K+-sensitive phosphoenzyme of kidney Na+,K+-transport ATPase and activates that of muscle sarcoplasmic reticulum Ca2+-transport ATPase

In order to characterize low affinity ATP-binding sites of renal (Na+,K+) ATPase and sarcoplasmic reticulum (Ca2+)ATPase, the effects of ATP on the splitting of the K+-sensitive phosphoenzymes were compared. ATP inactivated the dephosphorylation in the case of (Na+,K+)ATPase at relatively high concentrations, while activating it in the case of (Ca2+)ATPase. When various nucleotides were tested in place of ATP, inactivators of (Na+,K+)ATPase were found to be activators in (Ca2+)ATPase, with a few exceptions. In the absence of Mg2+, the half-maximum concentration of ATP for the inhibition or for the activation was about 0.35 mM or 0.25 mM, respectively. These values are comparable to the previously reported Km or the dissociation constant of the low affinity ATP site estimated from the steady-state kinetics of the stimulation of ATP hydrolysis or from binding measurements. By increasing the concentration of Mg2+, but not Na+, the effect of ATP on the phosphoenzyme of (Na+,K+)ATPase was reduced. On the other hand, Mg2+ did not modify the effect of ATP on the phosphoenzyme of (Ca2+)ATPase. During (Na+,K+)ATPase turnover, the low affinity ATP site appeared to be exposed in the phosphorylated form of the enzyme, but the magnesium-complexed ATP interacted poorly with the reactive K+-sensitive phosphoenzyme, which has a tightly bound magnesium, probably because of interaction between the divalent cations. In the presence of physiological levels of Mg2+ and K+, ATP appeared to bind to the (Na+,K+)ATPase only after the dephosphorylation, while it binds to the (Ca2+)-ATPase before the dephosphorylation to activate the turnover.     

Interactions between K+ and ATP binding to the (Na+ + K+)-dependent ATPase.

K+ appears to decrease the affinity of the (Na+ + K+)-dependent ATPase (ATP phosphohydrolase, EC 3.6.1.3) for its substrate, Mg2+ - ATP, and Mg2+ - ATP, in turn, appears to decrease the affinity of the enzyme for K+. These antagonisms have been investigated in terms of a quantitative model defining the magnitude of the effects as well as identifying the class of K+ sites on the enzyme involved. K+ increased the apparent Km for Mg2+ - ATP, an effect that was antagonized competitively by Na+. The data can be fitted to a model in which Mg2+ - ATP binding is prevented by occupancy of alpha-sites on the enzyme by K+ (i.e. sites of moderate affinity for K+ accessible on the "free" non-phosphorylated enzyme, in situ on the external membrane surface). By contrast, occupancy of these alpha-sites by Na+ has no effect on Mg2+ - ATP binding to the enzyme. On the other hand, Mg2+ - ATP decreased the apparent affinity of the enzyme for K+ at the alpha-sites, in terms of (i) the KD for K+ measured by K+-accelerated inactivation of the enzyme by F-, and (ii) the concentration of K+ for half-maximal activation of the K+-dependent phosphatase reaction (which reflects the terminal hydrolytic steps of the overall ATPase reaction). These data fit the same quantitative model. Although this formulation does not support schemes in which ATP binding effects the release of transported K+ from discharge sites, it is consistent with observations that K+ can inhibit the enzyme at low substrate concentrations, and that Li+, which has poor efficacy when occupying these alpha-sites, can stimulate enzymatic activity at high K+ concentrations by displacing the inhibitory K+.     

An Na+-stimulated Mg2+-transport system in human red blood cells

The initial rate of net Mg2+ efflux was measured in human red blood cells by atomic absorption. In fresh erythrocytes incubated in Na+,K+-Ringer's medium this rate was 7.3 +/- 2.8 mumol/l cells per h (mean +/- S.D. of 14 subjects) with an energy of activation of 13 200 cal/mol. Cells with total Mg2+ contents ([ Mg]i) ranging from 1.8 to 24 mmol/l cells were prepared by using a modified p-chloromercuribenzenesulphonate method. Mg2+ efflux was strongly stimulated by increases in [Mg]i and in external Na+ concentrations ([ Na]o). A kinetic analysis of Mg2+ efflux as a function of [Mg]i and [Na]o revealed the existence of two components: an Na+-stimulated Mg2+ efflux, which exhibited a Michaelian-like dependence of free internal Mg2+ content (apparent dissociation constant = 2.6 +/- 1.4 mmol/l cells; mean +/- S.D. of six subjects) and on external Na+ concentration (apparent dissociation constant = 20.5 +/- 1.9 mM; mean +/- S.D. of four subjects) and a variable maximal rate ranging from 35 to 370 mumol/l cells per h, and an Na+-independent Mg2+ efflux, which showed a linear dependence on internal Mg2+ content with a rate constant of (6.6 +/- 0.7) X 10(-3) h-1. Fluxes catalyzed by the Na+-stimulated Mg2+ carrier were partially dependent on the ATP content of the cells and completely inhibited by quinidine (IC50 = 50 microM) and by Mn2+ (IC50 = 0.5-1.0 mM).     

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.     

Stimulation of p-nitrophenylphosphatase activity of Na+/K+-ATPase by NaCl with oligomycin or ATP

It is known that the addition of NaCl with oligomycin or ATP stimulates ouabain-sensitive and K+-dependent p-nitrophenylphosphatase (pNPPase) activity of Na+/K+-ATPase. We investigated the mechanism of the stimulation. The combination of oligomycin and NaCl increased the affinity of pNPPase activity for K+. When the ratio of Na+ to Rb+ was 10 in the presence of oligomycin, Rb+-binding and pNPPase activity reached a maximal level and Na+ was occluded. Phosphorylation of Na+/K+-ATPase by p-nitrophenylphosphate (pNPP) was not affected by oligomycin. Because oligomycin stabilizes the Na+-occluded E1 state of Na+/K+-ATPase, it seemed that the Na+-occluded E1 state increased the affinity of the phosphoenzyme formed from pNPP for K+. On the other hand, the combination of ATP and NaCl also increased the affinity of pNPPase for K+ and activated ATPase activity. Both activities were affected by the ligand conditions. Oligomycin noncompetitively affected the activation of pNPPase by NaCl and ATP. Nonhydrolyzable ATP analogues could not substitute for ATP. As NaE1P, which is the high-energy phosphoenzyme formed from ATP with Na+, is also the Na+-occluded E1 state, it is suggested that the Na+-occluded E1 state increases the affinity of the phosphoenzyme from pNPP for K+ through the interaction between alpha subunits. Therefore, membrane-bound Na+/K+-ATPase would function as at least an (alphabeta)2-diprotomer with interacting alpha subunits at the phosphorylation step.     

Extracellular Ca2+ ameliorates NaCl-induced K+ loss from Arabidopsis root and leaf cells by controlling plasma membrane K+ -permeable channels

Calcium can ameliorate Na+ toxicity in plants by decreasing Na+ influx through nonselective cation channels. Here, we show that elevated external [Ca2+] also inhibits Na+ -induced K+ efflux through outwardly directed, K+ -permeable channels. Noninvasive ion flux measuring and patch-clamp techniques were used to characterize K+ fluxes from Arabidopsis (Arabidopsis thaliana) root mature epidermis and leaf mesophyll under various Ca2+ to Na+ ratios. NaCl-induced K+ efflux was not related to the osmotic component of the salt stress, was inhibited by the K+ channel blocker TEA+, was not mediated by inwardly directed K+ channels (tested in the akt1 mutant), and resulted in a significant decrease in cytosolic K+ content. NaCl-induced K+ efflux was partially inhibited by 1 mm Ca2+ and fully prevented by 10 mm Ca2+. This ameliorative effect was at least partially attributed to a less dramatic NaCl-induced membrane depolarization under high Ca2+ conditions. Patch-clamp experiments (whole-cell mode) have demonstrated that two populations of Ca2+ -sensitive K+ efflux channels exist in protoplasts isolated from the mature epidermis of Arabidopsis root and leaf mesophyll cells. The instantaneously activating K+ efflux channels showed weak voltage dependence and insensitivity to external and internal Na+. Another population of K+ efflux channels was slowly activating, steeply rectifying, and highly sensitive to Na+. K+ efflux channels in roots and leaves showed different Ca2+ and Na+ sensitivities, suggesting that these organs may employ different strategies to withstand salinity. Our results suggest an additional mechanism of Ca2+ action on salt toxicity in plants: the amelioration of K+ loss from the cell by regulating (both directly and indirectly) K+ efflux channels.