Electrophysiological analysis of the mutated Na,K-ATPase cation binding pocket

Na,K-ATPase mediates net electrogenic transport by extruding three Na+ ions and importing two K+ ions across the plasma membrane during each reaction cycle. We mutated putative cation coordinating amino acids in transmembrane hairpin M5-M6 of rat Na,K-ATPase: Asp776 (Gln, Asp, Ala), Glu779 (Asp, Gln, Ala), Asp804 (Glu, Asn, Ala), and Asp808 (Glu, Asn, Ala). Electrogenic cation transport properties of these 12 mutants were analyzed in two-electrode voltage-clamp experiments on Xenopus laevis oocytes by measuring the voltage dependence of K+-stimulated stationary currents and pre-steady-state currents under electrogenic Na+/Na+ exchange conditions. Whereas mutants D804N, D804A, and D808A hardly showed any Na+/K+ pump currents, the other constructs could be classified according to the [K+] and voltage dependence of their stationary currents; mutants N776A and E779Q behaved similarly to the wild-type enzyme. Mutants E779D, E779A, D808E, and D808N had in common a decreased apparent affinity for extracellular K+. Mutants N776Q, N776D, and D804E showed large deviations from the wild-type behavior; the currents generated by mutant N776D showed weaker voltage dependence, and the current-voltage curves of mutants N776Q and D804E exhibited a negative slope. The apparent rate constants determined from transient Na+/Na+ exchange currents are rather voltage-independent and at potentials above -60 mV faster than the wild type. Thus, the characteristic voltage-dependent increase of the rate constants at hyperpolarizing potentials is almost absent in these mutants. Accordingly, dislocating the carboxamide or carboxyl group of Asn776 and Asp804, respectively, decreases the extracellular Na+ affinity.     

Structural and functional features of the transmembrane domain of the Na,K-ATPase beta subunit revealed by tryptophan scanning

In oligomeric P2-ATPases such as Na,K- and H,K-ATPases, beta subunits play a fundamental role in the structural and functional maturation of the catalytic alpha subunit. In the present study we performed a tryptophan scanning analysis on the transmembrane alpha-helix of the Na,K-ATPase beta1 subunit to investigate its role in the stabilization of the alpha subunit, the endoplasmic reticulum exit of alpha-beta complexes, and the acquisition of functional properties of the Na,K-ATPase. Single or multiple tryptophan substitutions in the beta subunits transmembrane domain had no significant effect on the structural maturation of alpha subunits expressed in Xenopus oocytes nor on the level of expression of functional Na,K pumps at the cell surface. Furthermore, tryptophan substitutions in regions of the transmembrane alpha-helix containing two GXXXG transmembrane helix interaction motifs or a cysteine residue, which can be cross-linked to transmembrane helix M8 of the alpha subunit, had no effect on the apparent K(+) affinity of Na,K-ATPase. On the other hand, substitutions by tryptophan, serine, alanine, or cysteine, but not by phenylalanine of two highly conserved tyrosine residues, Tyr(40) and Tyr(44), on another face of the transmembrane helix, perturb the transport kinetics of Na,K pumps in an additive way. These results indicate that at least two faces of the beta subunits transmembrane helix contribute to inter- or intrasubunit interactions and that two tyrosine residues aligned in the beta subunits transmembrane alpha-helix are determinants of intrinsic transport characteristics of Na,K-ATPase.     

Residues within transmembrane domains 4 and 6 of the Na,K-ATPase alpha subunit are important for Na+ selectivity

The Na,K- and H,K-ATPases are plasma membrane enzymes responsible for the active exchange of extracellular K(+) for cytoplasmic Na(+) or H(+), respectively. At present, the structural determinants for the specific function of these ATPases remain poorly understood. To investigate the cation selectivity of these ATPases, we constructed a series of Na,K-ATPase mutants in which residues in the membrane spanning segments of the alpha subunit were changed to the corresponding residues common to gastric H,K-ATPases. Thus, mutants were created with substitutions in transmembrane domains TM1, TM4, TM5, TM6, TM7, and TM8 independently or together (designated TMAll). The function of each mutant was assessed after coexpression with the beta subunit in Sf-9 cells using baculoviruses. The enzymatic properties of TM1, TM7, and TM8 mutants were similar to the wild-type Na,K-ATPase, and while TM5 showed modest changes in apparent affinity for Na(+), TM4, TM6, and TMAll displayed an abnormal activity. This resulted in a Na(+)-independent hydrolysis of ATP, a 2-fold higher K(0.5) for Na(+) activation, and the ability to function at low pH. These results suggest a loss of discrimination for Na(+) over H(+) for the enzymes. In addition, TM4, TM6, and TMAll mutants exhibited a 1.5-fold lower affinity for K(+) and a 4-5-fold decreased sensitivity to vanadate. Altogether, these results provide evidence that residues in transmembrane domains 4 and 6 of the alpha subunit of the Na,K-ATPase play an important role in determining the specific cation selectivity of the enzyme and also its E1/E2 conformational equilibrium.     

The role of Na,K-ATPase alpha subunit serine 775 and glutamate 779 in determining the extracellular K+ and membrane potential-dependent properties of the Na,K-pump

The roles of Ser775 and Glu779, two amino acids in the putative fifth transmembrane segment of the Na,K-ATPase alpha subunit, in determining the voltage and extracellular K+ (K+(o)) dependence of enzyme-mediated ion transport, were examined in this study. HeLa cells expressing the alpha1 subunit of sheep Na,K-ATPase were voltage clamped via patch electrodes containing solutions with 115 mM Na+ (37 degrees C). Na,K-pump current produced by the ouabain-resistant control enzyme (RD), containing amino acid substitutions Gln111Arg and Asn122Asp, displayed a membrane potential and K+(o) dependence similar to wild-type Na,K-ATPase during superfusion with 0 and 148 mM Na+-containing salt solutions. Additional substitution of alanine at Ser775 or Glu779 produced 155- and 15-fold increases, respectively, in the K+(o) concentration that half-maximally activated Na,K-pump current at 0 mV in extracellular Na+-free solutions. However, the voltage dependence of Na,K-pump current was unchanged in RD and alanine-substituted enzymes. Thus, large changes in apparent K+(o) affinity could be produced by mutations in the fifth transmembrane segment of the Na,K-ATPase with little effect on voltage-dependent properties of K+ transport. One interpretation of these results is that protein structures responsible for the kinetics of K+(o) binding and/or occlusion may be distinct, at least in part, from those that are responsible for the voltage dependence of K+(o) binding to the Na,K-ATPase.     

Residues of the fourth transmembrane segments of the Na,K-ATPase and the gastric H,K-ATPase contribute to cation selectivity

We have generated protein chimeras to investigate the role of the fourth transmembrane segments (TM4) of the Na,K- and gastric H, K-ATPases in determining the distinct cation selectivities of these two pumps. Based on a helical wheel analysis, three residues of TM4 of the Na,K-ATPase were changed to their H,K-counterparts. A construct carrying three mutations in TM4 (L319F, N326Y, and T340S) and two control constructs were heterologously expressed in Xenopus laevis oocytes and in the pig kidney epithelial cell line LLC-PK(1). Biochemical ATPase assays demonstrated a large sodium-independent ATPase activity at pH 6.0 for the pump carrying the TM4 substitutions, whereas the control constructs exhibited little or no activity in the absence of sodium. Furthermore, at pH 6.0 the K(1/2)(Na(+)) shifted to 1.5 mM for the TM4 construct compared with 9.4 and 5.9 mM for the controls. In contrast, at pH 7.5 all three constructs had characteristics similar to wild type Na,K-ATPase. Large increases in K(1/2)(K(+)) were observed for the TM4 construct compared with the control constructs both in two-electrode voltage clamp experiments in Xenopus oocytes and in ATPase assays. ATPase assays also revealed a 10-fold shift in vanadate sensitivity for the TM4 construct. Based on these findings, it appears that the three identified TM4 residues play an important role in determining both the specific cation selectivities and the E(1)/E(2) conformational equilibria of the Na,K- and H,K-ATPase.     

The fourth transmembrane segment of the Na,K-ATPase alpha subunit: a systematic mutagenesis study

The Na,K-ATPase is a major ion-motive ATPase of the P-type family responsible for many aspects of cellular homeostasis. To determine the structure of the pathway for cations across the transmembrane portion of the Na,K-ATPase, we mutated 24 residues of the fourth transmembrane segment into cysteine and studied their function and accessibility by exposure to the sulfhydryl reagent 2-aminoethyl-methanethiosulfonate. Accessibility was also examined after treatment with palytoxin, which transforms the Na,K-pump into a cation channel. Of the 24 tested cysteine mutants, seven had no or a much reduced transport function. In particular cysteine mutants of the highly conserved "PEG" motif had a strongly reduced activity. However, most of the non-functional mutants could still be transformed by palytoxin as well as all of the functional mutants. Accessibility, determined as a 2-aminoethyl-methanethiosulfonate-induced reduction of the transport activity or as inhibition of the membrane conductance after palytoxin treatment, was observed for the following positions: Phe(323), Ile(322), Gly(326), Ala(330), Pro(333), Glu(334), and Gly(335). In accordance with a structural model of the Na,K-ATPase obtained by homology modeling with the two published structures of sarcoplasmic and endoplasmic reticulum calcium ATPase (Protein Data Bank codes 1EUL and 1IWO), the results suggest the presence of a cation pathway along the side of the fourth transmembrane segment that faces the space between transmembrane segments 5 and 6. The phenylalanine residue in position 323 has a critical position at the outer mouth of the cation pathway. The residues thought to form the cation binding site II ((333)PEGL) are also part of the accessible wall of the cation pathway opened by palytoxin through the Na,K-pump.     

Cysteine-scanning mutagenesis study of the sixth transmembrane segment of the Na,K-ATPase alpha subunit

The accessibility of the residues of the sixth transmembrane segment (TM) of the Bufo marinus Na,K-ATPase alpha subunit was explored by cysteine scanning mutagenesis. Methanethiosulfonate reagents reached only the two most extracellular positions (T803, D804) in the native conformation of the Na,K-pump. Palytoxin induced a conductance in all mutants, including D811C, T814C and D815C which showed no active electrogenic transport. After palytoxin treatment, four additional positions (V805, L808, D811 and M816) became accessible to the sulfhydryl reagent. We conclude that one side of the sixth TM helix forms a wall of the palytoxin-induced channel pore and, probably, of the cation pathway from the extracellular side to one of their binding sites.     

Identification of conserved prolyl residue important for transport activity and the substrate specificity range of yeast plasma membrane Na+/H+ antiporters

Yeast plasma membrane Na+/H+ antiporters are divided according to their substrate specificity in two distinct subfamilies. To identify amino acid residues responsible for substrate specificity determination (recognition of K+), the Zygosaccharomyces rouxii Sod2-22 antiporter (non-transporting K+) was mutagenized and a collection of ZrSod2-22 mutants that improved the KCl tolerance of a salt-sensitive Saccharomyces cerevisiae strain was isolated. Several independent ZrSod2-22 mutated alleles contained the replacement of a highly conserved proline 145 with a residue containing a hydroxyl group (Ser, Thr). Site-directed mutagenesis of Pro145 proved that an amino acid with a hydroxyl group at this position is enough to enable ZrSod2-22p to transport K+. Simultaneously, the P145(S/T) mutation decreased the antiporter transport activity for both Na+ and Li+. Replacement of Pro145 with glycine resulted in a ZrSod2-22p with extremely low activity only for Na+, and the exchange of a charged residue (Asp, Lys) for Pro145 completely stopped the activity. Mutagenesis of the corresponding proline in the S. cerevisiae Nha1 antiporter (Pro146) confirmed that this proline of the fifth transmembrane domain is a critical residue for antiporter function. This is the first evidence that a non-polar amino acid residue is important for the substrate specificity and activity of yeast Nha antiporters.     

Cation selectivity of gastric H,K-ATPase and Na,K-ATPase chimeras.

Chimeras of the catalytic subunits of the gastric H,K-ATPase and Na, K-ATPase were constructed and expressed in LLC-PK1 cells. The chimeras included the following: (i) a control, H85N (the first 85 residues comprising the cytoplasmic N terminus of Na,K-ATPase replaced by the analogous region of H,K-ATPase); (ii) H85N/H356-519N (the N-terminal half of the cytoplasmic M4-M5 loop also replaced); and (iii) H519N (the entire front half replaced). The latter two replacements confer a decrease in apparent affinity for extracellular K+. The 356-519 domain and, to a greater extent, the H519N replacement confer increased apparent selectivity for protons relative to Na+ at cytoplasmic sites as shown by the persistence of K+ influx when the proton concentration is increased and the Na+ concentration decreased. The pH and K+ dependence of ouabain-inhibitable ATPase of membranes derived from the transfected cells indicate that the H519N and, to a lesser extent, the H356-519N substitution decrease the effectiveness of K+ to compete for protons at putative cytoplasmic H+ activation sites. Notable pH-independent behavior of H85N/H356-519N at low Na+ suggests that as pH is decreased, Na+/K+ exchange is replaced largely by (Na+ + H+)/K+ exchange. With H519N, the pH and Na+ dependence of pump and ATPase activities suggest relatively active H+/K+ exchange even at neutral pH. Overall, this study provides evidence for important roles in cation selectivity for both the N-terminal half of the M4-M5 loop and the adjacent transmembrane helice(s).     

Structure of the 5th transmembrane segment of the Na,K-ATPase alpha subunit: a cysteine-scanning mutagenesis study

To study the structure of the pathway of cations across the Na, K-ATPase, we applied the substituted cysteine accessibility method to the putative 5th transmembrane segment of the alpha subunit of the Na,K-ATPase of the toad Bufo marinus. Only the most extracellular amino acid position (A(796)) was accessible from the extracellular side in the native Na,K-pump. After treatment with palytoxin, six other positions (Y(778), L(780), S(782), P(785), E(786) and L(791)), distributed along the whole length of the segment, became readily accessible to a small-size methanethiosulfonate compound (2-aminoethyl methanethiosulfonate). The accessible residues are not located on the same side of an alpha-helical model but the pattern of reactivity would rather suggest a beta-sheet structure for the inner half of the putative transmembrane segment. These results demonstrate the contribution of the 5th transmembrane segment to the palytoxin-induced channel and indicate which amino acid positions are exposed to the pore of this channel.     

Stabilization of the H,K-ATPase M5M6 membrane hairpin by K+ ions. Mechanistic significance for p2-type atpases.

The integral membrane protein, the gastric H,K-ATPase, is an alpha-beta heterodimer, with 10 putative transmembrane segments in the alpha-subunit and one such segment in the beta-subunit. All transmembrane segments remain within the membrane domain following trypsinization of the intact gastric H,K-ATPase in the presence of K+ ions, identified as M1M2, M3M4, M5M6, and M7, M8, M9, and M10. Removal of K+ ions from this digested preparation results in the selective loss of the M5M6 hairpin from the membrane. The release of the M5M6 fragment is directed to the extracellular phase as evidenced by the accumulation of the released M5M6 hairpin inside the sealed inside out vesicles. The stabilization of the M5M6 hairpin in the membrane phase by the transported cation as well as loss to the aqueous phase in the absence of the transported cation has been previously observed for another P2-type ATPase, the Na, K-ATPase (Lutsenko, S., Anderko, R., and Kaplan, J. H. (1995) Proc. Natl. Acad. Sci. U. S. A. 92, 7936-7940). Thus, the effects of the counter-transported cation on retention of the M5M6 segment in the membrane as compared with the other membrane pairs may be a general feature of P2-ATPase ion pumps, reflecting a flexibility of this region that relates to the mechanism of transport.     

Conformational transitions of the H,K-ATPase studied with sodium ions as surrogates for protons

Following a recent demonstration that H,K-ATPase can active transport Na+ at a low rate (Polvani, C., Sachs, G., and Blostein, R. (1989) J. Biol. Chem. 264, 17854-17859), we have looked for and found effects of Na+ ions on the conformational state of gastric H,K-ATPase labeled with fluorescein isothiocyanate. Na+ ions reverse the K(+)-induced quench of the fluorescein fluorescence and somewhat enhance fluorescence in the absence of K+ ions. Equilibrium titrations of the cation effects show that Na+ and K+ ions are strictly competitive with apparent dissociation constants of KNa+ = 62 mM (n = 2) and KK+ = 6.6 mM (n = 2). The observations demonstrate that Na+ ions bind to and stabilize the high fluorescence E1 form of the protein while K+ ions stabilize the low fluorescence E2 form. Elevation of pH from 6.4 to 8.0 increased the apparent affinity of the Na+ ions from approximately 62 to 10.2 mM, consistent with competition between protons and Na+. The action of Na+ to stabilize the E1 form was used to measure the rate of the E2K----E1Na transition with a stopped-flow fluorimeter. The rate at pH 6.4 and 20 degrees C is 18.1 s-1. In addition the rate of the reverse conformational transition E1K----E2K has been measured at several K+ concentrations. From the hyperbolic dependence on K+ concentration a maximal rate of 211 +/- 32 s-1 and intrinsic K+ dissociation constant on E1 of 64.6 +/- 3.3 mM have been estimated. The kinetic and equilibrium data are self-consistent and thus support the proposed action of Na+ and K+ ions. Compared with Na,K-ATPase, the H,K-ATPase exhibits a lower affinity for Na+ on E1 and a much faster rate of the E2K----E1Na transition, but a similar affinity for K+ ions on E1 and rate of the transition E1K----E2K. The significance of the similarities and differences in cation specificity and rates of conformational changes of Na,K- and H,K-ATPases is discussed.     

Modulation of the Na,K-pump function by beta subunit isoforms

To study the role of the Na,K-ATPase beta subunit in the ion transport activity, we have coexpressed the Bufo alpha 1 subunit (alpha 1) with three different isotypes of beta subunits, the Bufo Na,K-ATPase beta 1 (beta 1NaK) or beta 3 (beta 3NaK) subunit or the beta subunit of the rabbit gastric H,K-ATPase (beta HK), by cRNA injection in Xenopus oocyte. We studied the K+ activation kinetics by measuring the Na,K- pump current induced by external K+ under voltage clamp conditions. The endogenous oocyte Na,K-ATPase was selectively inhibited, taking advantage of the large difference in ouabain sensitivity between Xenopus and Bufo Na,K pumps. The K+ half-activation constant (K1/2) was higher in the alpha 1 beta 3NaK than in the alpha 1 beta 1NaK groups in the presence of external Na+, but there was no significant difference in the absence of external Na+. Association of alpha 1 and beta HK subunits produced active Na,K pumps with a much lower apparent affinity for K+ both in the presence and in the absence of external Na+. The voltage dependence of the K1/2 for external K+ was similar with the three beta subunits. Our results indicate that the beta subunit has a significant influence on the ion transport activity of the Na,K pump. The small structural differences between the beta 1NaK and beta 3NaK subunits results in a difference of the apparent affinity for K+ that is measurable only in the presence of external Na+, and thus appears not to be directly related to the K+ binding site. In contrast, association of an alpha 1 subunit with a beta HK subunit results in a Na,K pump in which the K+ binding or translocating mechanisms are altered since the apparent affinity for external K+ is affected even in the absence of external Na+.     

The conformation of H,K-ATPase determines the nucleoside triphosphate (NTP) selectivity for active proton transport

The gastric H,K-ATPase is related to other cation transport ATPases, for example, Na,K-ATPase and Ca-ATPase, which are called E1-E2 ATPases in recognition of conformational transitions during their respective transport and catalytic cycles. Generally, these ATPases cannot utilize NTPs other than ATP for net ion transport activity. For example, under standard assay conditions, rates of NTP hydrolysis and H+ pumping by the H,K-ATPase for CTP are about 10% of those for ATP and undetectable with GTP, ITP, and UTP. However, we observed that H,K-ATPase will catalyze NTP/ADP phosphate exchange at similar rates for all of these NTPs, suggesting that a common phosphoenzyme intermediate is formed. The present study was undertaken to evaluate the specificity of nucleotides to power the H,K-ATPase and several of its partial reactions, including NTP/ADP exchange, K+-catalyzed phosphatase activity, and proton pumping. Results demonstrate that under conditions that promote the conformational change of the K+ bound form of the enzyme, K.E2, to E1, all NTPs tested support K+-stimulated NTPase activity and H+ pumping up to 30-50% of that with ATP. These conditions include (1) the presence of ADP as well as the NTP energy source and (2) reduced K+ concentration on the cytoplasmic side to approximately 0. These data conform to structural models for E1-E2 ATPases whereby adenosine binding promotes the K.E2 to E1 conformational change and K+ deocclusion.     

Extracellular domains,transmembrane segments,and intracellular domains interact to determine the cation selectivity of Na,K- and gastric H,K-ATPase

We have previously reported that three residues of the fourth transmembrane segment (TM4) of the Na,K- and gastric H,K-ATPase alpha-subunits appear to play a major role in the distinct cation selectivities of these pumps [Mense, M., et al. (2000) J. Biol. Chem. 275, 1749-1756]. Substituting these three residues in the Na,K-ATPase sequence with their H,K-ATPase counterparts (L319F, N326Y, T340S) and replacing the TM3-TM4 ectodomain sequence with that of the H,K-ATPase alpha-subunit result in a pump that exhibits 50% of its maximal ATPase activity in the absence of Na(+) when the assay is performed at pH 6.0. This effect is not seen when the ectodomain alone is replaced. To gain more insight into the contributions of the three residues to establishing the selectivity of these pumps for Na(+) ions versus protons, we generated Na,K-ATPase constructs in which these residues are replaced by their H,K-ATPase counterparts either singly or in combinations. Surprisingly, none of the point mutants nor even the triple mutant was able to hydrolyze ATP at pH 6.0 at a rate greater than 20% of their respective V(max)s. For the point mutants L319F and N326Y, protons seem to competitively inhibit ATP hydrolysis at pH 6.0, based on the low apparent affinity for Na(+) ions at pH 6.0 compared to pH 7.5. It would appear, therefore, that the cation selectivity of Na,K- and H,K-ATPase is generated through a cooperative effort between residues of transmembrane segments and the flanking loops that connect these transmembrane domains. This view is further supported by homology modeling of the Na,K-ATPase based on the crystal structure of the SERCA pump.     

FXYD proteins: novel regulators of Na,K-ATPase

Members of the FXYD protein family are small membrane proteins which are characterized by an FXYD motif, two conserved glycines and a serine residue. FXYD proteins show a tissue-specific distribution. Recent evidence suggests that 6 out of 7 FXYD proteins, FXYD1 (phospholemman), FXYD2 (gamma subunit of Na,K-ATPase), FXYD3 (Mat-8), FXYD4 (CHIF), FXYD5 (Ric) and FXYD7 associate with Na,K-ATPase and modulate its transport properties e.g. its Na+ and/or its K+ affinity in a distinct way. These results highlight the complex regulation of Na+ and K+ transport which is necessary to ensure proper tissue functions such as renal Na+-reabsorption, muscle contractility and neuronal excitability. Moreover, mutation of a conserved glycine residue into an arginine residue in FXYD2 has been linked to cases of human hypomagnesemia indicating that dysregulation of Na,K-ATPase by FXYD proteins may be implicated in pathophysiological states. A better characterization of this novel regulatory mechanism of Na,K-ATPase may help to better understand its role in physiological and pathophysiological conditions.     

Do H+ ions obscure electrogenic Na+ and K+ binding in the E1 state of the Na,K-ATPase?

In contrast to other P-type ATPases, the Na,K-ATPase binding and release of ions on the cytoplasmic side, to the state called E1, is not electrogenic with the exception of the third Na+. Since the high-resolution structure of the closely related SR Ca-ATPase in state E1 revealed the ion-binding sites deep inside the transmembrane part of the protein, the missing electrogenicity in state E1 can be explained by an obscuring counter-movement of H+ ions. Evidence for such a mechanism is presented by analysis of pH effects on Na+ and K+ binding and by electrogenic H+ movements in the E1 conformation of the Na,K-ATPase.     

Enzymatic properties of separated isozymes of the Na,K-ATPase. Substrate affinities, kinetic cooperativity, and ion transport stoichiometry

There are two isozymes of the Na,K-ATPase, which can be purified separately from rat renal medulla and brainstem axolemma. Here the basic kinetic properties of the two Na,K-ATPases have been compared in conditions permitting enzyme turnover. The two isozymes are half-maximally activated at different concentrations of ATP, the axolemma Na,K-ATPase having the higher affinity. They are half-maximally activated by Na+ and K+ at very similar concentrations but show differences in cooperativity toward Na+. The affinities of both isozymes for ATP and Na+ are affected in a qualitatively similar way by variations in the concentration of K+. Both isozymes transport 22Na+ and 42K+ in a ratio close to 3:2 in artificial lipid vesicles. The two isozymes differ most strikingly in the inhibition of ATPase activity by ouabain. The axolemma Na,K-ATPase has a high affinity for ouabain with positive cooperativity, while the renal medulla Na,K-ATPase has a lower affinity with negative cooperativity. It is likely that the cooperativity differences are due to kinetic effects, reflecting different rates of conformation transitions during enzyme turnover. The functional result of the contrasting cooperativities is that the difference in sensitivity to ouabain is amplified.     

Electrogenic sodium-sodium exchange carried out by Na,K-ATPase containing the amino acid substitution Glu779Ala

Na,K-ATPase containing the amino acid substitution glutamate to alanine at position 779 of the alpha subunit (Glu779Ala) supports a high level of Na-ATPase and electrogenic Na+-Na+ exchange activity in the absence of K+. In microsomal preparations of Glu779Ala enzyme, the Na+ concentration for half maximal activation of Na-ATPase activity was 161 +/- 14 mM (n = 3). Furthermore, enzyme activity with 800 mM Na+ was found to be similar in the presence and absence of 20 mM K+. These results showed that Na+, with low affinity, could stimulate enzyme turnover as effectively as K+. To gain further insight into the mechanism of this enzyme activity, HeLa cells expressing Glu779Ala enzyme were voltage clamped with patch electrodes containing 115 mM Na+ during superfusion in K+-free solutions. Electrogenic Na+-Na+ exchange was observed as an ouabain-inhibitable outward current whose amplitude was proportional to extracellular Na+ (Na+(o)) concentration. At all Na+(o) concentrations tested (3-148 mM), exchange current was maximal at negative membrane potentials (V(M)), but decreased as V(M) became more positive. Analyzing this current at each V(M) with a Hill equation showed that Na+-Na+ exchange had a high-affinity, low-capacity component with an apparent Na+(o) affinity at 0 mV (K0(0.5)) of 13.4 +/- 0.6 mM and a low-affinity, high-capacity component with a K0(0.5) of 120 +/- 13 mM (n = 17). Both high- and low-affinity exchange components were V(M) dependent, dissipating 30 +/- 3% and 82 +/- 6% (n = 17) of the membrane dielectric, respectively. The low-affinity, but not the high-affinity exchange component was inhibited with 2 mM free ADP in the patch electrode solution. These results suggest that the high-affinity component of electrogenic Na+-Na+ exchange could be explained by Na+(o) acting as a low-affinity K+ congener; however, the low-affinity component of electrogenic exchange appeared to be due to forward enzyme cycling activated by Na+(o) binding at a Na+-specific site deep in the membrane dielectric. A pseudo six-state model for the Na,K-ATPase was developed to simulate these data and the results of the accompanying paper (Peluffo, R.D., J.M. Argüello, and J.R. Berlin. 2000. J. Gen. Physiol. 116:47-59). This model showed that alterations in the kinetics of extracellular ion-dependent reactions alone could explain the effects of Glu779Ala substitution on the Na,K-ATPase.     

Deceleration of the E1P-E2P transition and ion transport by mutation of potentially salt bridge-forming residues Lys-791 and Glu-820 in gastric H+/K+-ATPase

A lysine residue within the highly conserved center of the fifth transmembrane segment in P_IIC-type ATPase α-subunits is uniquely found in H,K-ATPases instead of a serine in all Na,K-ATPase isoforms. Because previous studies suggested a prominent role of this residue in determining the electrogenicity of non-gastric H,K-ATPase and in pK_a modulation of the proton-translocating residues in the gastric H,K-ATPases as well, we investigated its functional significance for ion transport by expressing several Lys-791 variants of the gastric H,K-ATPase in Xenopus oocytes. Although the mutant proteins were all detected at the cell surface, none of the investigated mutants displayed any measurable K⁺-induced stationary currents. In Rb⁺ uptake measurements, replacement of Lys-791 by Arg, Ala, Ser, and Glu substantially impaired transport activity and reduced the sensitivity toward the E₂-specific inhibitor {"type":"entrez-protein","attrs":{"text":"SCH28080","term_id":"1053015931","term_text":"SCH28080"}}SCH28080. Furthermore, voltage clamp fluorometry using a reporter site in the TM5/TM6 loop for labeling with tetra-methylrhodamine-6-maleimide revealed markedly changed fluorescence signals. All four investigated mutants exhibited a strong shift toward the E₁P state, in agreement with their reduced {"type":"entrez-protein","attrs":{"text":"SCH28080","term_id":"1053015931","term_text":"SCH28080"}}SCH28080 sensitivity, and an about 5–10-fold decreased forward rate constant of the E₁P ↔ E₂P conformational transition, thus explaining the E₁P shift and the reduced Rb⁺ transport activity. When Glu-820 in TM6 adjacent to Lys-791 was replaced by non-charged or positively charged amino acids, severe effects on fluorescence signals and Rb⁺ transport were also observed, whereas substitution by aspartate was less disturbing. These results suggest that formation of an E₂P-stabilizing interhelical salt bridge is essential to prevent futile proton exchange cycles of H⁺ pumping P-type ATPases.