A cation/proton antiport activity in Acholeplasma laidlawii

Sealed membrane vesicles of Acholeplasma laidlawii were obtained by controlled lysis of carotenoid-rich intact cells. An imposed delta pH was created by loading membrane vesicles or intact Acholeplasma laidlawii cells with 0.25 M NH4Cl and diluting them into 0.25 M choline chloride. The passive efflux of NH3 from the membrane vesicles or cells resulted in the creation of a delta pH (inside acid) that could be visualized by the quenching of the fluorescence of the weak base acridine orange. Whereas with isolated membrane vesicles, the fluorescence was dequenched by the addition of Na+, with intact cells, K+ in addition to Na+ was required. These results strongly suggest a Na+/H+ exchange activity that in intact Acholeplasma laidlawii cells is K+-dependent. The possible role of the Na+/H+ exchange activity in pH homeostasis at the more alkaline pH range, as well as in the extrusion of excess Na+ from the cells is discussed.     

Effects of K+ and other monovalent cations on yeast mitochondria.

In mitochondria from Saccharomyces cerevisiae and in the presence of ethanol or NADH, K+ or Na+ increased the rate of O2 uptake in states 3 and uncoupled as well as in sonicated mitochondria. The respiratory control, the ADP:O ratio and the synthesis of ATP also increased. ATP hydrolysis by sonicated mitochondria increased depending on the cation added as follows: K+ = NH4+ = Rb+ Na+ Li+. This correlated with the ionic radii of the cations. Monovalent cations increased the activity of: 1) F1F0ATPase which was sensitive to cation size and 2) complex I of the respiratory chain, which seemed to regulate the rate of oxidative phosphorylation, but did not discriminate between K+ or Na+.     

Guanidinium derivatives act as high affinity antagonists of Na+ ions in occlusion sites of Na+,K(+)-ATPase.

We have screened various alkyl- and arylguanidinium derivatives as possible competitors of Na+ or Rb+ for the cation sites on renal Na+,K(+)-ATPase. Alkyl-monoguanidinium or alkylbisguanidinium (BisG) compounds (chain lengths of C3 to C10) competitively inhibit the occlusion of Rb+ and Na+ with an order of affinities C10 greater than C8 greater than C6 greater than C4 greater than C3. BisG compounds are approximately twice as effective as the equivalent alkylmonoguanidinium compounds. In media of high ionic strength, affinities of tens of micromolar are observed, e.g. 26 microM for BisG 8. m-(mXBG)- and p-xylylenebisguanidinium were synthesized and were found to compete with Rb+ or Na+ with intrinsic affinities of 7.7 and 8.2 microM, respectively. The hydrophobicity rather than the degree of proximity of the guanidinium groups in all BisG compounds appears to determine the binding affinity. A systematic search has been made of conditions in occlusion assays for which the inhibitor affinities are highest. When the pH is raised from 7.0 to 8.5, a 5-fold increase in affinity is observed, suggesting that the guanidinium derivatives compete with protons at sites of pKa approximately 7.5. Replacing Tris-HCl with choline chloride-containing media raised apparent affinities approximately 2-fold. All guanidinium derivatives stabilize the E1 conformation of fluorescein-labeled Na+,K(+)-ATPase, acting as competitive Na+ analogues. In media containing only 1 mM Tris-HCl, pH 8.55, very high affinities were observed for binding to the fluorescein-labeled enzyme (e.g. 0.08 microM for mXBG). In very low ionic strength medium, the inhibition was still competitive with Rb+ ions. However, there was also evidence for nonspecific adsorption to the membranes. The following findings show that mXBG, a typical guanidinium derivative, behaves as a Na(+)-like antagonist. (a) It inhibits Na+,K(+)-ATPase activity, competing strongly with Na+ but only weakly with K+ ions. (b) It inhibits phosphorylation from ATP, competing with Na+ ions. (c) Like Na+ ions, it blocks phosphorylation from inorganic phosphate. Based on these results, we propose that the guanidinium group binds to a relatively wide vestibule at the cytoplasmic surface; but, unlike Na+ or K+ ions, it cannot pass into a narrower region of the cation transport path within the membrane. Therefore, it blocks the occlusion and active transport of cations. In the future, high affinity guanidinium derivatives may serve the purpose of locating cation-binding domains of the pump protein after being converted to reactive affinity or photoaffinity covalent labels.     

Ionic permeability of K, Na, and Cl in potassium-depolarized nerve. Dependency on pH, cooperative effects, and action of tetrodotoxin.

The passive ionic membrane conductances (gj) and permeabilities (Pj) of K, Na, and Cl of crayfish (Procambarus clarkii) medial giant axons were determined in the potassium-depolarized axon and compared with that of the resting axon. Passive ionic conductances and permeabilities were found to be potassium dependent with a major conductance transition occurring around an external K concentration of 12-15 mM (Vm = -60 to -65 mV). The results showed that K, Na, and Cl conductances increased by 6.2, 6.9, and 27-fold, respectively, when external K was elevated from 5.4 to 40 mM. Permeability measurements indicated that K changed minimally with K depolarization while Na and Cl underwent an order increase in permeability. In the resting axon (K0 = 5.4 mM, pH = 7.0) PK = 1.33 X 10(-5), PCl = 1.99 X 10(-6), PNa = 1.92 X 10(-8) while in elevated potassium (K0 = 40 mM, pH 7.0), PK = 1.9 X 10(-5), PCl = 1.2 X 10(-5), and PNa = 2.7 X 10(-7) cm/s. When membrane potential is reduced to 40 mV by changes in internal ions, the conductance changes are initially small. This suggests that resting channel conductances depend also on ion environments seen by each membrane surface in addition to membrane potential. In elevated potassium, K, Na, and Cl conductances and permeabilities were measured from pH 3.8 to 11 in 0.2 pH increments. Here a cooperative transition in membrane conductance or permeability occurs when pH is altered through the imidazole pK (approximately pH 6.3) region. This cooperative conductance transition involves changes in Na and Cl but not K permeabilities. A Hill coefficient n of near 4 was found for the cooperative conductance transition of both the Na and Cl ionic channel which could be interpreted as resulting from 4 protein molecules forming each of the Na and Cl ionic channels. Tetrodotoxin reduces the Hill coefficient n to near 2 for the Na channel but does not affect the Cl channel. In the resting or depolarized axon, crosslinking membrane amino groups with DIDS reduces Cl and Na permeability. Following potassium depolarization, buried amino groups appear to be uncovered. The data here suggest that potassium depolarization produces a membrane conformation change in these ionic permeability regulatory components. A model is proposed where membrane protein, which forms the membrane ionic channels, is oriented with an accessible amino terminal group on the axon exterior. In this model the ionizable groups on protein and phospholipid have varied associations with the different ionic channel access sites for K, Na, and Cl, and these groups exert considerable control over ion permeation through their surface potentials.     

Pyridoxal 5'-phoshate schiff base in Citrobacter freundii tyrosinephenol-lyase. Ionic and tautomeric equilibria.

Spectral properties of the internal Schiff base in tyrosine phenol-lyase have been investigated in the presence of an activating cation K+ and a cation-inhibitor Na+. The holoenzyme absorption spectra in the pH range 6.5-8.7 were recorded in the presence of K+. No apparent pKa value of the coenzyme chromophore was found in this pH range, indicating that the internal Schiff base does not change its ionic form on going from pH 6.5 to 8.7. To determine the ionic state and tautomeric composition of the Schiff base in tyrosine phenol-lyase, the absorption and circular dichroism spectra were analyzed using lognormal distribution curves. The predominant form of the internal Schiff base is that with protonated pyridinium and aldimine nitrogen atoms and deprotonated 3'-hydroxy group, i.e. the ketoenamine. This form is in prototropic equilibrium with its enolimine tautomer. The internal aldimine ionic form is changed upon replacement of K+ with Na+. This replacement leads to a significant decrease in the pKa value of pyridinium nitrogen of the pyridoxal-P.     

Ionic fluxes induced by topical misoprostol in canine gastric mucosa

We studied the dose response of ionic fluxes in canine chambered gastric segment mucosa to increasing doses of topical misoprostol (0.1, 1, 10, 100, and 1000 micrograms). The fluxes were also correlated with the simultaneous changes in focal gastric mucosal blood flow measured by laser-Doppler flowmetry. After misoprostol administration, there was a dose-dependent increase in focal gastric mucosal blood flow (Emax = 8.23 +/- 3.25 V at 10 micrograms; ED50 = 1.05 micrograms), pH, and the outputs of ions (Na+, K+, Cl-, and HCO3-) and fluid (Emax for pH and fluxes greater than or equal to 1000 micrograms). ED50 values for these outputs ranged from 215.40 to 340 micrograms (mean +/- SE = 279.08 +/- 24.27 micrograms). H+ output showed a dose-dependent decrease to zero at the 10-micrograms dose, the dose at and after which net HCO3- secretion became obvious. The slopes of the dose-response curves for the fluxes of fluid, Na+, K+, Cl-, and HCO3- were significantly different (p less than 0.01) from the slope of the curve for mucosal blood flow changes. There were no correlations between the changes in these fluxes and blood flow changes. Na+ and Cl- were the predominant cation (98.84%) and anion (98.19%), respectively, in the misoprostol-induced secretion. Misoprostol stimulates a composite alkaline gastric nonparietal secretion, predominantly Na+ and Cl-, but also containing K+ and HCO3-. Our results suggest different mechanisms for the effects on nonparietal secretion and focal gastric mucosal blood flow.(ABSTRACT TRUNCATED AT 250 WORDS)     

A membrane potential-sensitive Na+-H+ exchange system in flagella isolated from sea urchin spermatozoa

Sea urchin sperm motility is activated by a Na+-dependent increase of internal pH. A flagellar preparation was used in the present study to investigate this ionic mechanism. Using 22Na and a pH electrode, the stoichiometry of Na+ uptake to H+ release in the isolated flagella was found to be 1.09 +/- 0.11. Reversing the Na+ gradient induced reacidification of the intraflagellar pH as measured by [14C]methylamine, while reversal of the H+ gradient resulted in a Na+ efflux. Furthermore, a parallel inhibition of both ionic movements was observed with increasing external [K+]. These results indicate that Na+ and H+ are coupled through an exchanger. Measurements of the membrane potential (psi) with [3H]tetraphenylphosphonium showed depolarization by K+, suggesting its inhibitory effect on the exchanger is through changes in psi. This is further supported by the following experiments. (a) Cs+ by itself had little effect on either psi or the Na+/H+ exchange, but in the presence of the ionophore valinomycin it depolarized psi and inhibited the exchange. (b) Tetraphenylphosphonium a highly permeant cation, at 2.5 mM caused depolarization and inhibition of the exchange, and these effects were reversible by repolarization of psi with valinomycin. The inhibitory effect of depolarization was not due to the electrogenicity of the exchange since both directions of the exchange were inhibited. It is proposed that the flagellar exchange is basically a electroneutral process but has a charged regulatory component (a gate or a conformational change) which confers the observed potential sensitivity.     

The ionic composition of the contractile vacuole fluid of Paramecium mirrors ion transport across the plasma membrane

In vivo K+, Na+, Ca2+, Cl- and H+ activities in the cytosol and the contractile vacuole fluid, the overall cytosolic osmolarity, the fluid segregation rate per contractile vacuole and the membrane potential of the contractile vacuole complex of Paramecium multimicronucleatum were determined in cells adapted to 24 or 124 mosm l(-1) solutions containing as the monovalent cation(s): 1) 2 mmol l(-1) K+; 2) 2 mmol l(-1) Na+; 3) 1 mmol l(-1) K+ plus 1 mmol l(-1) Na+; or 4) 2 mmol l(-1) choline. In cells adapted to a given external osmolarity i) the fluid segregation rate was the same if adapted to either K+ or Na+, twice as high when adapted to solutions containing both K+ and Na+, and reduced by 50% or more in solutions containing only choline, ii) the fluid of the contractile vacuole was always hypertonic to the cytosol while the sum of the ionic activities measured in the fluid of the contractile vacuole was the same in cells adapted to either K+ or Na+, at least 25% higher in cells adapted to solutions containing both K+ and Na+, and was reduced by 55% or more in solutions containing only choline, iii) the cytosolic osmolarity was the same in cells adapted to K+ alone, to Na+ alone or to both K+ and Na+, whereas it was significantly lower in cells adapted to choline. At a given external osmolarity, a positive relationship between the osmotic gradient across the membrane of the contractile vacuole complex and the fluid segregation rate was observed. We conclude that both the plasma membrane and the membrane of the contractile vacuole complex play roles in fluid segregation. The presence of external Na+ moderated K+ uptake and caused the Ca2+ activity in the contractile vacuole fluid to rise dramatically. Thus, Ca2+ can be eliminated through the contractile vacuole complex when Na+ is present externally. The membrane potential of the contractile vacuole complex remained essentially the same regardless of the external ionic conditions and the ionic composition of the fluid of the contractile vacuole. Notwithstanding the large number of V-ATPases in the membrane of the decorated spongiome, the fluid of the contractile vacuole was found to be only mildly acidic, pH 6.4.     

Nucleotide-binding kinetics of Na,K-ATPase: cation dependence

Correlation between the Na,K-ATPase affinity to ADP and the cation (its nature and concentration) present in the medium was investigated. In buffer with low ionic strength (I approximately 1 mM) high-affinity ADP binding was not observed, while a stepwise increase in the concentrations of added cation (Na(+), Tris(+), imidazole(+), N-methylglucamine(+), choline(+)) induced an increase in the ADP affinity. The effect was fully saturated at 30-50 mM for all of the cations tested. The maximal affinity for ADP was slightly higher in the presence of Na(+), Tris(+), or imidazole(+) than in the presence of N-methylglucamine(+) or choline(+) (equilibrium dissociation constant K(d) 0.2-0.3 vs 0.7 microM). The ADP dissociation rates from its complex with enzyme in the presence of Na(+) or Tris(+) were similar, implying identity of the nucleotide-binding enzyme conformations, which therefore are assigned to E(1). The ability to compete with K(+) clearly distinguished Na(+) from other cations, which speaks against the sole involvement of the transport sites in the induction of the ADP-binding E(1) conformation. Since the cations are similar in their mode of induction of the high ADP affinity but they demonstrate a pronounced difference in ability to compete with K(+), their effects cannot be combined within any scheme with only one type of cation-binding sites. We suggest that the high affinity toward nucleotide is induced by cation interactions within the protein or lipid and that these nucleotide-domain-related sites coexist with the transport sites, which bind only Na(+) or K(+).     

Spectrophotometric determination of reaction stoichiometry and equilibrium constants of metallochromic indicators. II. The Ca2+-arsenazo III complexes

The analytical method described in the preceding article was applied to spectrophotometric Ca2+-titrations of the metallochromic indicator arsenazo III (Ar). At various reactant concentrations it was determined that Ar forms 1:1,1:2 and 2 : 1 complexes with calcium. The equilibrium constants and extinction coefficients at 602 nm were determined. Corrected to zero ionic strength at 293 K and pH 7.0, the reactions Ca + Ar = CaAr, CaAr + Ar = CaAr2 and CaAr + Ca = Ca2Ar are associated with dissociation equilibrium constants k(11) = 1.6 x 10(-6)M, K12 = 3.2 x 10(-4)M and K21 = 5.8 x 10(-3)M. respectively. The extinction coefficient of unbound indicator is (602) = 9.6 (+/-0.3) x 10(3) cm(-1) M(-1). Arscnazo III complexes with monovalent ions like Na+ and K+ : at zero ionic strength, the dissociation constant of the Na+-Ar complex is about 0.1 M.     

(Na,K)-ATPase-mediated cation pumping in cultured rat hepatocytes. Rapid modulation by alanine and taurocholate transport and characterization of its relationship to intracellular sodium concentration

(Na,K)-ATPase is thought to maintain the transmembrane electrochemical sodium gradient which powers secondary active sodium-coupled transport of a variety of solutes including amino acids and bile acids. However, little is known regarding the effect of sodium-coupled solute transport on intracellular sodium concentration ( [Na]ic) and on (Na,K)-ATPase-mediated cation pumping in the intact cell. In order to address this question, we have measured 22Na uptake rate, steady state 22Na content, and ouabain-suppressible 86Rb uptake rate in primary cultures of adult rat hepatocytes under a variety of conditions. Compared with control conditions (sodium uptake rate = 6.00 +/- 0.40 nmol X min-1 X mg-1; [Na]ic = 11.96 +/- 0.54 mM; cation pumping = 2.53 +/- 0.18 nmol X min-1 X mg-1), cation pumping was increased by taurocholate (less than or equal to 158%), alanine (less than or equal to 246%), monensin (less than or equal to 400%), and cold exposure (less than or equal to 525%), and this increase was accompanied by increases in Na uptake and [Na]ic. In contrast, preincubation in low sodium medium decreased all three variables. These changes in cation pumping were blocked in the absence of extracellular sodium and were not accompanied by changes in ouabain-suppressible ATP hydrolysis measured in cell homogenate. An overall plot of cation pumping versus [Na]ic yielded a sigmoid-shaped curve. Values for KNa (17.8 +/- 1.4 mM) and Vmax (8.98 +/- 0.62 nmol X min-1 X mg-1) for cation pumping were estimated assuming three sodium sites per pump unit. These findings indicate that: 1) uptake of alanine and taurocholate is associated with a rapid increase in (Na,K)-ATPase cation pumping; 2) this increase probably results from an increase in pumping per pump unit rather than an increase in the total number of pump units, and it appears to be mediated via an increase in sodium influx and [Na]ic; 3) [Na]ic under control conditions is close to the apparent KNa of cation pumping, implying that substrate availability may be the mechanism whereby sodium uptake is tightly linked to (Na,K)-ATPase cation pumping in intact hepatocytes.     

Effects of polyamines on partial reactions of membrane (Na+ + K+)-ATPase.

Spermine and spermidine inhibit the (Na+ + K+)-ATPase (ATP phosphohydrolase, EC 3.6.1.3) reaction so that the effect increases as the ionic content due to Na+ and K+ in the reaction is reduced. Several other amines inhibit (Na+ + K+)-ATPase to varying degress and methylglyoxal-bis-(guanylhydrazone) was the most potent inhibitor among those tested. The inhibition by polyamines of the ATPase is uncompetitive with respect to Mg2+ and ATP activation of the reaction. Various naturally occurring polyamines and other amines inhibited Na+ activation of (Na+ + K+)-ATPase as well as Na+-dependent phosphoenzyme formation in an apparently competitive manner with respect to Na+. Likewise, K+-activation of (Na+ + K+)-ATPase as well as K+-p-nitrophenyl phosphatase was inhibited in an apparently competitive manner with respect to K+. Both the cation charge and structure (e.g., aliphatic chain length) may contribute to the inhibitory effects of the amines; however, Na+ sites appear to be more sensitive to cation charge than the aliphatic chain length of the amine, whereas the opposite appears to be true for K+ sites. The results do not indicate a specific effect of polyamines on (Na+ + K+)-ATPase or its partial reactions.     

Cation exchanges of yeast in the absence of magnesium.

Environmental Mg2+ was found to influence the K+/Na+ exchange rate of metabolizing yeast. Addition of EDTA increased the exchange rate and Mg2+ reversed the effect of EDTA. Yeast starved in the absence of Mg2+ exchanged cellular K+ or Na+ for external H+ when maintained at acidic pH. The exchange rate depended on cellular pH and showed the same kinetics for both K+ and Na+. At acidic pH, the presence of external cations neither inhibited H+ absorption nor changed the cation/H+ 1 : 1 stoichiometry. At neutral pH, external cations inhibited H+ influx but did not change the cation efflux. The K+/Na+ exchange is discussed as electrically coupled and the K+/H+ and Na+/H+ exchanges as electroneutral antiports.     

Ion specificity of cardiac sarcolemmal Na+/H+ antiporter

In bovine cardiac sarcolemmal vesicles, an outward H+ gradient stimulated the initial rate of amiloride-sensitive uptake of 22Na+, 42K+, or 86Rb+. Release of H+ from the vesicles was stimulated by extravesicular Na+, K+, Rb+, or Li+ but not by choline or N-methylglucamine. Uptakes of Na+ and Rb+ were half-saturated at 3 mM Na+ and 3 mM Rb+, but the maximal velocity of Na+ uptake was 1.5 times that of Rb+ uptake. Na+ uptake was inhibited by extravesicular K+, Rb+, or Li+, and Rb+ uptake was inhibited by extravesicular Na+ or Li+. Amiloride-sensitive uptake of Na+ or Rb+ increased with increase in extravesicular pH and decrease in intravesicular pH. In the absence of pH gradient, there were stimulations of Na+ uptake by intravesicular Na+ and K+ and of Rb+ uptake by intravesicular Rb+ and Na+. Similarly, there were trans stimulations of Na+ and Rb+ efflux by extravesicular alkali cations. The data suggest the existence of a nonselective antiporter catalyzing either alkali cation/H+ exchange or alkali cation/alkali cation exchange. Since increasing Na+ caused complete inhibition of Rb+/H+ exchange, but saturating K+ caused partial inhibitions of Na+/H+ exchange and Na+/Na+ exchange, the presence of a Na(+)-selective antiporter is also indicated. Although both antiporters may be involved in pH homeostasis, a role of the nonselective antiporter may be in the control of Na+/K+ exchange across the cardiac sarcolemma.     

Evidence for tryptophan residues in the cation transport path of the Na(+),K(+)-ATPase

A family of aryl isothiouronium derivatives was designed as probes for cation binding sites of Na(+),K(+)-ATPase. Previous work showed that 1-bromo-2,4,6-tris(methylisothiouronium)benzene (Br-TITU) acts as a competitive blocker of Na(+) or K(+) occlusion. In addition to a high-affinity cytoplasmic site (K(D) < 1 microM), a low-affinity site (K(D) approximately 10 microM) was detected, presumably extracellular. Here we describe properties of Br-TITU as a blocker at the extracellular surface. In human red blood cells Br-TITU inhibits ouabain-sensitive Na(+) transport (K(D) approximately 30 microM) in a manner antagonistic with respect to extracellular Na(+). In addition, Br-TITU impairs K(+)-stimulated dephosphorylation and Rb(+) occlusion from phosphorylated enzyme of renal Na(+),K(+)-ATPase, consistent with binding to an extracellular site. Incubation of renal Na(+),K(+)-ATPase with Br-TITU at pH 9 irreversibly inactivates Na(+),K(+)-ATPase activity and Rb(+) occlusion. Rb(+) or Na(+) ions protect. Preincubation of Br-TITU with red cells in a K(+)-free medium at pH 9 irreversibly inactivates ouabain-sensitive (22)Na(+) efflux, showing that inactivation occurs at an extracellular site. K(+), Cs(+), and Li(+) ions protect against this effect, but the apparent affinity for K(+), Cs(+), or Li(+) is similar (K(D) approximately 5 mM) despite their different affinities for external activation of the Na(+) pump. Br-TITU quenches tryptophan fluorescence of renal Na(+),K(+)-ATPase or of digested "19 kDa membranes". After incubation at pH 9 irreversible loss of tryptophan fluorescence is observed and Rb(+) or Na(+) ions protect. The Br-TITU appears to interact strongly with tryptophan residue(s) within the lipid or at the extracellular membrane-water interface and interfere with cation occlusion and Na(+),K(+)-ATPase activity.     

Sodium-coupled ATP synthesis in the bacterium Vitreoscilla.

The bacterium Vitreoscilla generates an electrical potential gradient due to sodium ion (delta psi Na+) across its membrane via respiratory-driven primary Na+ pump(s). The role of the delta psi Na+ as a driving force for ATP synthesis was, therefore, investigated. In respiring starved cells pulsed with 100 mM external Na+ [( Na+]o) there was a 167% net increase in cellular ATP concentration over basal levels compared with 0, 56, 78, and 78% for no addition, choline, Li+, and K+ controls, respectively. Doubling the [Na+]o to 200 mM boosted the net increase to 244% but a similar doubling of the choline caused only an increase to 78%. When the initial condition was intracellular Na+ ([Na+]i) = [Na+]o = 100 mM, there was a 94% net increase in cellular ATP compared with only 18 and 11% for Li+ and K+ controls, respectively, indicating that Nai+ may be the only cation tested that the cells extruded to generate the electrochemical gradient required to drive ATP synthesis. The Na(+)-dependent ATP synthesis was inhibited completely by monensin (12 microM), but only transiently by the protonophore 3,5-di-tert-butyl-4-hydroxybenzaldehyde (100 microM), further evidence that the Na+ gradient and not a H+ gradient was driving the ATP synthesis. ATP synthesis in response to an artificially imposed H+ gradient (delta pH approximately 3) in the absence of an added cation, or in the presence of Li+, K+, or choline, yielded similar delta ATP/delta pH ratios of 0.98-1.22. In the presence of Na+, however, this ratio dropped to 0.23, indicating that Na+ inhibited H(+)-coupling to ATP synthesis and possibly that H+ and Na+ coupling to ATP synthesis share a common catalyst. The above evidence adds to previous findings that under normal growth conditions Na+ is probably the main coupling cation for ATP synthesis in Vitreoscilla.     

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.     

Duplex-tetraplex equilibrium between a hairpin and two interacting hairpins of d(A-G)10 at neutral pH.

d(A-G)10 forms two helical structures at neutrality, at low ionic strength a single-hairpin duplex, and at higher ionic strength a double-hairpin tetraplex. An ionic strength-dependent equilibrium between these forms is indicated by native PAGE, which also reveals additional single-stranded species below 0.3 M Na+, probably corresponding to partially denatured states. The equilibrium also depends upon oligomer concentration: at very low concentrations, d(A-G)10 migrates faster than the random coil d(C-T)10, probably because it is a more compact single hairpin; at high concentrations, it co-migrates with the linear duplex d(A-G)10 x d(C-T)10, probably because it is a two-hairpin tetraplex. Molecular weights measured by equilibrium sedimentation in 0.1 M Na+, pH 7, reveal a mixture of monomer and dimer species at 1 degree C, but only a monomer at 40 degrees C; in 0.6 M Na+, pH 7, only a dimer species is observed at 4 degrees C. That the single- and double-stranded species are hairpin helices, is indicated by preferential S1 nuclease cleavage at the center of the oligomer(s), i.e., the loop of the hairpin(s). The UV melting transition below 0.3 M Na+ or K+, exhibits a dTm/dlog[Na+/K+] of 33 or 36 degrees C, respectively, consistent with conversion of a two-hairpin tetraplex to a single-hairpin duplex with extrahelical residues. When [Na+/K+] > or = 0.3 M, dTm/dlog [Na+/K+] is 19 or 17 degrees C, respectively, consistent with conversion of a two-hairpin tetraplex directly to single strands. A two-hairpin structure stabilized by G-tetrads is indicated by differential scanning calorimetry in 0.15 M Na+/5 mM Mg2+, with deltaH of formation per mole of the two-hairpin tetraplex of -116.9 kcal or -29.2 kcal/mol of G-tetrad.     

Effect of ionic strength and pH on the activity of pyruvate dehydrogenase complex from pig kidney cortex.

The activity of pyruvate dehydrogenase complex (PDC) purified from pig kidney cortex is sensitive to changes in ionic strength (mu). At low ionic strength (mu = 0.04 M) the specific activity of PDC was 12.22 mumol/min/mg, whereas at high ionic strength (mu = 0.15 M) the measured activity of the complex decreased to 4.88 mumol/min/mg. The optimum activity of PDC was achieved within a small range of ionic strength, mu = 0.035-0.040 M. Increasing the ionic strength from mu = 0.05 to mu = 0.15 M decreased the s0.5 for pyruvate from 125 to 72 microM and increased the Hill coefficient from 1.0 to 1.3. The effect of pH on PDC activity also was dependent upon ionic strength. At pH 7.2 the activity of PDC at mu = 0.05 and mu = 0.15 M was 90 and 55% of the maximal activity, respectively. Furthermore, the effects of Na+, K+, HCO3-, Cl-, and HPO4(2-) on PDC activity were dependent on ionic strength and pH. The addition of K+ (80 mM) at mu = 0.10 and mu = 0.15 M increased the activity of PDC by 12 and 42%, respectively. Lowering the pH from 8.2 to 7.5 resulted in a decrease in the s0.5 for pyruvate from 179 to 110 microM and from 110 to 35 microM in the presence and absence of K+ (80 mM), Na+ (20 mM), Cl- (20 mM), HCO3- (20 mM), and HPO4(2-) (10 mM), respectively. The observed changes in the properties of PDC in response to changes in ionic strength likely was a result of changes in the intramolecular electrostatic interactions within the complex. In this regard it was determined using two-dimensional agarose gel electrophoresis of the intact multienzyme complex that increasing the ionic strength to which PDC is exposed decreased the measured radius of PDC and may have decreased the electronegative surface charge of the complex.     

Definitive assignment of proton selectivity and attoampere unitary current to the M2 ion channel protein of influenza A virus

The viral ion channel protein M2 supports the transit of influenza virus and its glycoproteins through acidic compartments of the cell. M2 conducts endosomal protons into the virion to initiate uncoating and, by equilibrating the pH at trans-Golgi membranes, preserves the native conformation of acid-sensitive viral hemagglutinin. The exceptionally low conductance of the M2 channel thwarted resolution of single channels by electrophysiological techniques. Assays of liposome-reconstituted M2 yielded the average unitary channel current of the M2 tetramer--1.2 aA (1.2 x 10(-18) A) at neutral pH and 2.7 to 4.1 aA at pH 5.7--which activates the channel. Extrapolation to physiological temperature predicts 4.8 and 40 aA, respectively, and a unitary conductance of 0.03 versus 0.4 fS. This minute activity, below previous estimates, appears sufficient for virus reproduction, but low enough to avert abortive cytotoxicity. The unitary permeability of M2 was within the range reported for other proton channels. To address the ion selectivity of M2, we exploited the coupling of ionic influx and efflux in sealed liposomes. Metal ion fluxes were monitored by proton counterflow, employing a pH probe 1,000 times more sensitive than available Na+ or K+ probes. Even low-pH-activated M2 did not conduct Na+ and K+. The proton selectivity of M2 was estimated to be at least 3 x 10(6) (over sodium or potassium ions), in agreement with electrophysiological studies. The stringent proton selectivity of M2 suggests that the cytopathology of influenza virus does not involve direct perturbation of cellular sodium or potassium gradients.