Light-induced glutamate transport in Halobacterium halobium envelope vesicles. II. Evidence that the driving force is a light-dependent sodium gradient.

Illumination of cell envelope vesicles from H. halobium causes the development of protonmotive force and energizes the uphill transport of glutamate. Although the uncoupler, p-trifluoromethoxycarbonyl cyanide phenylhydrazone (FCCP), and the membrane-permeant cation, triphenylmethylphosphonium (TPMP+), are inhibitory to the effect of light, the time course and kinetics of the production of the energized state for transport, and its rate of decay after illumination, are inconsistent with the idea that glutamate accumulation is driven directly by the protonmotive force. Similarities between the light-induced transport and the Na+-gradient-induced transport of glutamate in these vesicles suggest that the energized state for the amino acid uptake in both cases consists of a transmembrane Na+ gradient (Na+out/Na+in greater than 1). Rapid efflux of 22Na from the envelope vesicles is induced by illumination. FCCP and TPMP+ inhibit the light-induced efflux of Na+ but accelerate the post-illumination relaxation of the Na+ gradient created, suggesting electrogenic antiport of Na+ with another cation, or electrogenic symport with an anion. The light-induced protonmotive force in the H. halobium cell envelope vesicles is thus coupled to Na+ efflux and thereby indirectly to glutamate uptake as well.     

DCCD-sensitive Na+-transport in the membrane vesicles of Halobacterium halobium

The effects of N,N'-dicyclohexylcarbodiimide (DCCD) and various ionophores on light-induced 22Na+-transport were studied in right-side-out membrane vesicles from Halobacterium halobium R1M1. The light-induced Na+ efflux was inhibited at the same DCCD concentration (greater than 40 nmol/mg protein) as required for inhibition of the Na+-dependent membrane potential (delta phi) formation. This supports our previous indication that the DCCD-sensitive, Na+-dependent transformation of pH-gradient (delta pH) into delta phi is mediated by Na+/H+-antiporter (Murakami, N. and Konishi, T. (1985) J. Biochem. 98, 897-907). FCCP or a combination of valinomycin and triphenyltin (TPT) inhibits the light-induced Na+ efflux in accordance with the notion of protonmotive force (delta mu H+)-driven antiporter. However, a marked lag in initiation of the Na+ efflux occurred in the presence of valinomycin, TPMP+, or a small amount of FCCP, suggesting that a gating step is involved in the Na+ efflux. On the other hand, the delta pH-dissipating ionophore TPT did not cause the lag. A simultaneous determination of delta phi, delta pH, and Na+ efflux rate at the initial stage of illumination revealed that the antiporter is gated by delta phi rather than delta mu H+.     

Light-dependent cation gradients and electrical potential in Halobacterium halobium cell envelope vesicles.

Vesicles can be prepared from Halobacterium halobium cell envelopes, which contain properly oriented bacteriorhodopsin and which extrude H+ during illumination. The pH difference that is generated across the membranes is accompanied by an electrical potential of 90-100 mV (interior negative) and the movements of other cations. Among these is the efflux of Na+, which proceeds against its electrochemical potential. The relationship between the size and direction of the light-induced pH gradient and the rate of depletion of Na+ from the vesicles, as well as other evidence, suggest that the active Na+-extrusion is facilitated by a membrane component that exchanges H+ for Na+ with a stoichiometry greater than 1. The gradients of H+ and Na+ are thus coupled to one another. The Na+-gradient (Na+out greater than Na+in), which arises during illumination, plays a major role in energizing the active transport of amino acids.     

Mechanism of function of dicyclohexylcarbodiimide-sensitive Na+/H+-antiporter in Halobacterium halobium: pH effect

The regulatory roles of medium pH, a transmembrane pH gradient (delta pH), and an electrical potential (delta phi) on the activation of the N,N'-dicyclohexylcarbodiimide-sensitive Na+/H+-antiporter were studied in the membrane vesicle of Halobacterium halobium in the dark. Neither delta pH nor delta phi independently activated the antiporter but a combination could. The initial rate of Na+ extrusion did not proportionally relate to the size of delta microH+ imposed. The delta microH+-coupled Na+ efflux in the presence of delta phi (-140 mV) increased as external pH decreased, regardless of the size of delta pH, suggesting the existence of one external H+-binding site (apparent pKa 4.6) whose protonation determines primarily the Na+/H+-exchange activity. On the other hand, the dependence of the Na+ efflux on cytoplasmic pH varied with the size of delta pH imposed and the apparent pKa for the cytoplasmic H+ increased with elevating delta pH. The resulting pKa difference across the membrane seems to be the key mechanism for the facilitation of Na+-coupled H+ influx. In other words, delta pH modulates Na+/H+-exchange activity through manipulating the H+ affinity on the cytoplasmic regulatory site. The Na+ extrusion was gated by the threshold delta phi of -100 mV regardless of the size of existing delta pH. delta phi acts on the protonated antiporter and converts it into an active state which becomes delta pH reactive.     

Light-driven primary sodium ion transport in halobacterium halobium membranes

Light-induced sodium extrusion from H halobium cell envelope vesicles proceeds largely through an uncoupler-sensitive pathway involving bacteriorhodopsin and a proton/sodium antiporter. Vesicles from bacteriorhodopsin-negative strains also extrude sodium ions during illumination, but this transport is not sensitive to uncouplers and has been proposed to involve a light-energized primary sodium pump. Proton uptake in such vesicles is passive, and under steady-state illumination the large electrical potential (negative inside) is just balanced by a pH difference (acid inside), so that the protonmotive force is near zero. Action spectra indicated that this effect of illumination is attributable to a pigment absorbing near 585 nm (of 568 for bacteriorhodopsin). Bleaching of the vesicles by prolonged illumination with hydroxylamine results in inactivation of the transport; retinal addition causes partial return of the activity. Retinal addition also causes the appearance of an absorption peak at 588 nm, while the absorption of free retinal decreases. The 588 nm pigment is present in very small quantities (0.13 nmole/mg protein), and behaves differently from bacteriorhodopsin in a number of respects. Vesicles can be prepared from bacteriorhodopsin-containing H halobium strains in which primary transport for both protons and sodium can be observed. Both pumps appear to cause the outward transport of the cations. The observations indicate the existence of a second retinal protein, in addition to bacteriorhodopsin, in H halobium, which is associated with primary sodium translocation. The initial proton uptake normally observed during illumination of whole H halobium cells may therefore be a passive flux in response to the primary sodium extrusion.     

Cation/proton antiport systems in Escherichia coli. Solubilization and reconstitution of delta pH-driven sodium/proton and calcium/proton antiporters

Uptake of 22Na+ and 45Ca2+ into everted membrane vesicles from Escherichia coli was measured with imposed transmembrane pH gradients, acid interior, as driving force. Vesicles loaded with 0.5 M KCl were diluted into 0.5 M choline chloride to create a potassium gradient. Addition of nigericin to produce K+/H+ exchange resulted in formation of a pH gradient. This imposed gradient was capable of driving 45Ca2+ accumulation. In another method vesicles loaded with 0.5 M NH4Cl were diluted into 0.5 M choline chloride, creating an ammonium diffusion potential. A gradient of H+ was produced by passive efflux of NH3. With an ammonium gradient as driving force, everted vesicles accumulated both 45Ca2+ and 22Na+. The data suggest that 22Na+ uptake was via the sodium/proton antiporter and 45Ca2+ via the calcium/proton antiporter. Uptake of both cations required alkaline pHout. A minimum pH gradient of 0.9 unit was needed for transport of either ion, suggesting gating of the antiporters. Octyl glucoside extracts of inner membrane were reconstituted with E. coli phospholipids in 0.5 M NH4Cl. NH4+-loaded proteoliposomes accumulated both 22Na+ and 45Ca2+, demonstrating that the sodium/proton and calcium/proton antiporters could be solubilized and reconstituted in a functional form.     

On the glutamate transport through cell envelope vesicles of Halobacterium halobium

Glutamate uptake by envelope vesicles of Halobacterium halobium was measured. Previous authors showed that the glutamate uptake needs the illumination as well as Na+ gradient across the membrane. The latter is considered to be the driving force for the uptake. No satisfactory explanation for the necessity of the illumination has not been given. We found that in the absence of Cl- in the medium, only Na+ gradient was enough to induce the glutamate uptake, i.e. no illumination was needed. Glutamate uptake was measured with various strains of H. halobium. We found that the envelope vesicles prepared from strains containing no bacteriorhodopsin showed the glutamate uptake in the dark and in the presence of Cl- in the medium provided only that Na+ gradient is imposed.     

Speculations on the evolution of ion transport mechanisms.

Primate cells evolved a plasma membrane to restrict the loss of important molecules. The osmotic problems that then arose were solved in one of several ways. Of major importance was the evolution of specific ion pumps, to actively extrude those salts whose inward diffusion would have led to swelling and lysis. In addition, these pumps allowed the cell to store energy in the form of ion gradients across the membrane. Thus, even in the earliest stages, the evolution of ion transport systems coincided with the development of mechanisms which catalyzes the energy transformations. It is postulated that an "ATP"-driven proton pump was one of the first ion transport systems. Such a proton pump would extrude hydrogen ions from the cell, establishing both a transmembrane pH gradient (alkaline inside) and a membrane potential (negative inside). This difference in electrochemical potential for protons (the proton-motive force) could then drive a variety of essential membrane functions, such as the active transport of ions and nutrients. A second major advance was the evolution of an ion transport system that converted light energy into a form which could be used by the cell. The modern model for this is the "purple membrane" of Halobacterium halobium, which catalyzes the extrusion of protons after the capture of light. The protonmotive force generated by such a light-driven proton pump could then power net synthesis of ATP by a reversal of the ATP-driven proton pump. A third important evolutionary step associated with ion transport was the development of a system to harness energy released by biological oxidations. Again, the solution of this problem was to conserve energy as a protonmotive force by coupling the activity of a respiratory chain to the extrusion of protons. Finally, with the development of animal cells a more careful regulation of internal and external pH was required. Thus, an ATP-driven Na+-K+ pump replaced the proton-translocating ATPase as the major ion pump found in plasma membranes.     

Cation coupling to melibiose transport in Salmonella typhimurium.

Melibiose transport in Salmonella typhimurium was investigated. Radioactive melibiose was prepared and the melibiose transport system was characterized. Na+ and Li+ stimulated transport of melibiose by lowering the Km value without affecting the Vmax value; Km values were 0.50 mM in the absence of Na+ or Li+ and 0.12 mM in the presence of 10 mM NaCl or 10 mM LiCl. The Vmax value was 140 nmol/min per mg of protein. Melibiose was a much more effective substrate than methyl-beta-thiogalactoside. An Na+-melibiose cotransport mechanism was suggested by three types of experiments. First, the influx of Na+ induced by melibiose influx was observed with melibiose-induced cells. Second, the efflux of H+ induced by melibiose influx was observed only in the presence of Na+ or Li+, demonstrating the absence of H+-melibiose cotransport. Third, either an artificially imposed Na+ gradient or membrane potential could drive melibiose uptake in cells. Formation of an Na+ gradient in S. typhimurium was shown to be coupled to H+ by three methods. First, uncoupler-sensitive extrusion of Na+ was energized by respiration or glycolysis. Second, efflux of H+ induced by Na+ influx was detected. Third, a change in the pH gradient was elicited by imposing an Na+ gradient in energized membrane vesicles. Thus, it is concluded that the mechanism for Na+ extrusion is an Na+/H+ antiport. The Na+/H+ antiporter is a transformer which converts an electrochemical H+ gradient to an Na+ gradient, which then drives melibiose transport. Li+ was inhibitory for the growth of cells when melibiose was the sole carbon source, even though Li+ stimulated melibiose transport. This suggests that high intracellular Li+ may be harmful.     

Light-induced membrane potential and pH gradient in Halobacterium halobium envelope vesicles.

Illumination of envelope vesicles prepared from Halobacterium halobium cells causes translocation of protons from inside to outside, due to the light-induced cycling of bacteriorhodopsin. This process results in a pH gradient across the membranes, an electrical potential, and the movements of K+ and Na+. The electrical potential was estimated by following the fluorescence of a cyanine dye, 3,3'-dipentyloxadicarbocyanine. Illumination of H. halobium vesicles resulted in a rapid, reversible decrease of the dye fluorescence, by as much as 35%. This effect was not seen in nonvesicular patches of purple membrane. Observation of maximal fluorescence decreases upon ilumination of vesicles required an optimal dye/membrane protein ratio. The pH optimum for the lightinduced fluorescence decrease was 6.0. The decrease was linear with actinic light intensity up to about 4 X 10(5) ergs cn-2 s-1. Valinomycin, gramicidin, and triphenylmethylphosphonium ion all abolished the fluorescence changes. However, the light-induced pH change was enhanced by these agents. Conversely, buffered vesicles showed no pH change but gave the same or larger fluorescence changes. Thus, we have identified the fluorescence decrease with a light-induced membrane potential, inside negative. By using valinomycin-K+-induced membrane potentials, we calibrated the fluorescence decrease with calculated Nernst diffusion potentials. We found a linear dependence between potential and fluorescence decrease of 3 mV/%, up to 90 mV. When the envelope vesicles were illuminated, the total proton-motive force generated was dependent on the presence of Na+ and K+ and their concentration gradients across the membrane. In general, K+ appeared to be more permeable than Na+ and, thus, permitted development of greater pH gradients and lower electrical potentials. By calculating the total proton-motive force from the sum of the pH and potential terms, we found that the vesicles can produce proton-motive forces near--200 mV.     

Cooperative regulation of the Na+/H(+)-antiporter in Halobacterium halobium by delta pH and delta phi

The contributions of the transmembrane pH gradient (delta pH) and electrical potential (delta phi) to the delta mu H(+)-driven Na+ efflux (mediated by the N,N'-dicyclohexylcarbodiimide-sensitive Na+/H(+)-antiporter) were investigated in membrane vesicles of Halobacterium halobium. Kinetic analysis in the dark revealed that two different Na(+)-binding sites are located asymmetrically across the membrane: One, accessible from the external medium, has a Kd (half-maximal stimulation of Na+ efflux) of about less than 50 mM, and the Na+ binding to the site is a prerequisite for the antiporter activation by delta mu H+. The other cytoplasmic site is the Na+ transport site. The Km for the cytoplasmic Na+ decreased as the delta pH increased, while the Vmax remained essentially constant in the presence of defined delta phi (140 mV). On the other hand, delta phi elevation above the gating potential (approximately 100 mV) increased the Vmax without changes in the Km in the presence of a fixed delta pH. It was also noted that the Km value in the absence of delta phi was completely different from and far higher than that observed in the presence of delta phi (greater than 100 mV), indicating the existence of two distinct conformations in the antiporter, resting and delta phi gated; the latter state may be reactive only to delta pH. On the basis of the present data and the previous data on the pH effect (N. Murakami and T. Konishi, 1989 Arch. Biochem. Biophys. 271, 515-523), a model for the delta pH-delta phi regulation of the antiporter activation is proposed.     

A proton gradient, not a sodium gradient, is the driving force for active transport of lactate in rabbit intestinal brush-border membrane vesicles.

An inward-directed H+ gradient markedly stimulated lactate uptake in rabbit intestinal brush-border membrane vesicles, and uphill transport against a concentration gradient could be demonstrated under these conditions. Uptake of lactate was many-fold greater in the presence of a H+ gradient than in the presence of a Na+ gradient. Moreover, there was no evidence for uphill transport of lactate in the presence of a Na+ gradient. The H+-gradient-dependent stimulation of lactate uptake was not due to the effect of a H+-diffusion potential. The uptake process in the presence of a H+ gradient was saturable [Kt (concn. giving half-maximal transport) for lactate 12.7 +/- 4.5 mM] and was inhibited by many monocarboxylates. It is concluded that a H+ gradient, not a Na+ gradient, is the driving force for active transport of lactate in rabbit intestinal brush-border membrane vesicles.     

Na+ for H+ exchange in rabbit erythrocytes

The effect of a transmembrane pH gradient on the ouabain, bumetanide, and phloretin resistant H+ efflux was studied in rabbit erythrocytes. Proton equilibration was reduced by the use of DIDS (125 microM) and acetazolamide (1 mM). H+ efflux from acid loaded erythrocytes (pHi = 6.1) was measured in a K+ (145 mM) medium, pH0 = 8.0, in the presence and absence of 60 microM 5,N,N-dimethyl-amiloride (DMA). The H+ efflux rate in a K+-containing medium was 116.38 +/- 4.5 mmol/l cell X hr. Substitution of Nao+ for Ko+ strongly stimulated H+ efflux to 177.89 +/- 7.9 mmol/l cell X hr. The transtimulation of H+ efflux by Nao+ was completely abolished by DMA falling to values not different from controls with an ID50 of about 8.6 X 10(-7) M. The sequence of substrate selectivities for the external transport site were Na greater than greater than greater than Li greater than choline, Cs, K, and Glucamine. The transport system has no specific anion requirement, but is inhibited by NO3-. The DMA sensitive H+ efflux was a saturable function of [Na+]o, with an apparent Km and Vmax of about 14.75 +/- 1.99 mM and 85.37 +/- 7.68 mmol/l cell X hr, respectively. However, the Nao+-dependent and DMA-sensitive H+ efflux was sigmoidally activated by [H+]i, suggesting that Hi+ interacts at both transport and modifier sites. An outwardly directed H+ gradient (pHi 6.1, pH = 8.0) also promoted DMA sensitive Na+ entry (61.2 +/- 3.0 mmol/l cell X hr) which was abolished when pHo was reduced to 6.0. The data is therefore consistent with the presence of a Na+/H+ exchange system in rabbit erythrocytes.     

Mechanism of Na(+)-dependent citrate transport in Klebsiella pneumoniae.

Citrate transport via CitS of Klebsiella pneumoniae has been shown to depend on the presence of Na+. This transport system has been expressed in Escherichia coli, and uptake of citrate in E. coli membrane vesicles via this uptake system was found to be an electrogenic process, although the pH gradient is the main driving force for citrate uptake (M. E. van der Rest, R. M. Siewe, T. Abee, E. Schwartz, D. Oesterhelt, and W. N. Konings, J. Biol. Chem. 267:8971-8976, 1992). Analysis of the affinity constants for the different citrate species at different pH values of the medium indicates that H-citrate2- is the transported species. Since the electrical potential across the membrane is a driving force for citrate transport, this indicates that transport occurs in symport with at least three monovalent cations. Citrate efflux is stimulated by Na+ concentrations of up to 5 mM but inhibited by higher Na+ concentrations. Citrate exchange, however, is stimulated by all Na+ concentrations, indicating sequential events in which Na+ binds before citrate for translocation followed by a release of Na+ after release of citrate. CitS has, at pH 6.0 and in the presence of 5 mM citrate on both sides of the membrane, an apparent affinity (K(app)) for Na+ of 200 microM. The Na+/citrate stoichiometry was found to be 1. It is postulated that H-citrate2- is transported via CitS in symport with one Na+ and at least two H+ ions.     

Role of Na+ cycle in cell volume regulation of Mycoplasma gallisepticum.

The mechanism for the extrusion of Na+ from Mycoplasma gallisepticum cells was examined. Na+ efflux from cells was studied by diluting 22Na+-loaded cells into an isoosmotic NaCl solution and measuring the residual 22Na+ in the cells. Uphill 22Na+ efflux was found to be glucose dependent and linear with time over a 60-s period and showed almost the same rate in the pH range of 6.5 to 8.0. 22Na+ efflux was markedly inhibited by dicyclohexylcarbodiimide (DCCD, 10 microM), but not by the proton-conducting ionophores SF6847 (0.5 microM) or carbonyl cyanide m-chlorophenylhydrazone (CCCP, 10 microM) over the entire pH range tested. An ammonium diffusion potential and a pH gradient were created by diluting intact cells or sealed membrane vesicles of M. gallisepticum loaded with NH4Cl into a choline chloride solution. The imposed H+ gradient (inside acid) was not affected by the addition of either NaCl or KCl to the medium. Dissipation of the proton motive force by CCCP had no effect on the growth of M. gallisepticum in the pH range of 7.2 to 7.8 in an Na+-rich medium. Additionally, energized M. gallisepticum cells were stable in an isoosmotic NaCl solution, even in the presence of proton conductors, whereas nonenergized cells tended to swell and lyse. These results show that in M. gallisepticum Na+ movement was neither driven nor inhibited by the collapse of the electrochemical gradient of H+, suggesting that in this organism Na+ is extruded by an electrogenic primary Na+ pump rather than by an Na+-H+ exchange system energized by the proton motive force.     

Demonstration of a Na+/H+ exchange activity in purified canine cardiac sarcolemmal vesicles

Purified canine cardiac sarcolemmal membrane vesicles exhibit a sodium ion for proton exchange activity (Na+/H+ exchange). Na+/H+ exchange was demonstrated both by measuring rapid 22Na uptake into sarcolemmal vesicles in response to a transmembrane H+ gradient and by following H+ transport in response to a transmembrane Na+ gradient with use of the probe acridine orange. Maximal 22Na uptake into the sarcolemmal vesicles (with starting intravesicular pH = 6 and extravesicular pH = 8) was approximately 20 nmol/mg protein. The extravesicular Km of the Na+/H+ exchange activity for Na+ was determined to be between 2 and 4 mM (intravesicular pH = 5.9, extravesicular pH = 7.9), as assessed by measuring the concentration dependence of the 22Na uptake rate and the ability of extravesicular Na+ to collapse an imposed H+ gradient. All results suggested that Na+/H+ exchange was reversible and tightly coupled. The Na+/H+ exchange activity was assayed in membrane subfractions and found most concentrated in highly purified cardiac sarcolemmal vesicles and was absent from free and junctional sarcoplasmic reticulum vesicles. 22Na uptake into sarcolemmal vesicles mediated by Na+/H+ exchange was dependent on extravesicular pH, having an optimum around pH 9 (initial internal pH = 6). Although the Na+/H+ exchange activity was not inhibited by tetrodotoxin or digitoxin, it was inhibited by quinidine, quinacrine, amiloride, and several amiloride derivatives. The relative potencies of the various inhibitors tested were found to be: quinacrine greater than quinidine = ethylisopropylamiloride greater than methylisopropylamiloride greater than dimethylamiloride greater than amiloride. The Na+/H+ exchange activity identified in purified cardiac sarcolemmal vesicles appears to be qualitatively similar to Na+/H+ exchange activities recently described in intact cell systems. Isolated cardiac sarcolemmal vesicles should prove a useful model system for the study of Na+/H+ exchange regulation in myocardial tissue.     

Transport in halobacterium halobium: Light-induced cation-gradients,amino acid transport kinetics,and properties of transport carriers

Cell envelope vesicles prepared from H. halobium contain bacteriorhodopsin and upon illumination protons are ejected. Coupled to the proton motive force is the efflux of Na⁺. Measurements of ²²Na flux, exterior pH change, and membrane potential, ΔΨ (with the dye 3,3′-dipentyloxadicarbocyanine) indicate that the means of Na⁺ transport is sodium/proton exchange. The kinetics of the pH changes and other evidence suggests that the antiport is electrogenic (H⁺/Na⁺ > 1). The resulting large chemical gradient for Na⁺ (outside > inside), as well as the membrane potential, will drive the transport of 18 amino acids. The 19th, glutamate, is unique in that its accumulation is indifferent to ΔΨ: this amino acid is transported only when a chemical gradient for Na⁺ is present. Thus, when more and more NaCl is included in the vesicles glutamate transport proceeds with longer and longer lags. After illumination the gradient of H⁺ collapses within 1 min, while the large Na⁺ gradient and glutamate transporting activity persists for 10–15 min, indicating that proton motive force is not necessary for transport. A chemical gradient of Na⁺, arranged by suspending vesicles loaded with KCl in NaCl, drives glutamate transport in the dark without other sources of energy, with V_max and K_m comparable to light-induced transport. These and other lines of evidence suggest that the transport of glutamate is facilitated by symport with Na⁺, in an electrically neutral fashion, so that only the chemical component of the Na⁺ gradient is a driving force. The transport of all amino acids but glutamate is bidirectional. Actively driven efflux can be obtained with reversed Na⁺ gradients (inside > outside), and passive efflux is considerably enhanced by intravesicle Na⁺. These results suggest that the transport carriers are functionally symmetrical. On the other hand, noncompetitive inhibition of transport by cysteine (a specific inhibitor of several of the carriers) is only obtained from the vesicle exterior and only for influx: these results suggest that in some respects the carriers are asymmetrical. A protein fraction which binds glutamate has been found in cholate-solubilized H. halobium membranes, with an apparent molecular weight of 50,000. When this fraction (but not the others eluted from an Agarose column) is reconstituted with soybean lipids to yield lipoprotein vesicles, facilitated transport activity is regained. Neither binding nor reconstituted transport depend on the presence of Na⁺. The kinetics of the transport and of the competitive inhibition by glutamate analogs suggest that the protein fraction responsible is derived from the intact transport system.     

Kinetic properties of electrogenic Na+/H+ antiport in membrane vesicles from an alkalophilic Bacillus sp.

The effects of imposed proton motive force on the kinetic properties of the alkalophilic Bacillus sp. strain N-6 Na+/H+ antiport system have been studied by looking at the effect of delta psi (membrane potential, interior negative) and/or delta pH (proton gradient, interior alkaline) on Na+ efflux or H+ influx in right-side-out membrane vesicles. Imposed delta psi increased the Na+ efflux rate (V) linearly, and the slope of V versus delta psi was higher at pH 9 than at pH 8. Kinetic experiments indicated that the delta psi caused a pronounced increase in the Vmax for Na+ efflux, whereas the Km values for Na+ were unaffected by the delta psi. As the internal H+ concentration increased, the Na+ efflux reaction was inhibited. This inhibition resulted in an increase in the apparent Km of the Na+ efflux reaction. These results have also been observed in delta pH-driven Na+ efflux experiments. When Na(+)-loaded membrane vesicles were energized by means of a valinomycin-induced inside-negative K+ diffusion potential, the generated acidic-interior pH gradients could be detected by changes in 9-aminoacridine fluorescence. The results of H+ influx experiments showed a good coincidence with those of Na+ efflux. H+ influx was enhanced by an increase of delta psi or internal Na+ concentration and inhibited by high internal H+ concentration. These results are consistent with our previous contentions that the Na+/H+ antiport system of this strain operates electrogenically and plays a central role in pH homeostasis at the alkaline pH range.     

Calcium transport into the vacuole of oat roots. Characterization of H+/Ca2+ exchange activity

Calcium (Ca2+) is sequestered into vacuoles of oat root cells through a H+/Ca2+ antiport system that is driven by the proton-motive force of the tonoplast H+-translocating ATPase. The antiport has been characterized directly by imposing a pH gradient in tonoplast-enriched vesicles. The pH gradient was imposed by diluting K+-loaded vesicles into a K+-free medium. Nigericin induced a K+/H+ exchange resulting in a pH gradient of 2 (acid inside). The pH gradient was capable of driving 45Ca2+ accumulation. Ca2+ uptake was tightly coupled to H+ loss as increasing Ca2+ levels progressively dissipated the steady state pH gradient. Ca2+ uptake displayed saturation kinetics with a Km(app) for Ca2+ of 10 microM. The relative affinity of the antiporter for transport of divalent cations was Ca2+ greater than Sr2+ greater than Ba2+ greater than Mg2+. La3+ or Mn2+ blocked Ca2+ uptake possibly by occupying the Ca2+-binding site. Ruthenium red (I50 = 40 microM) and N,N'-dicyclohexylcarbodiimide (I50 = 3 microM) specifically inhibited the H+/Ca2+ antiporter. When driven by pH jumps, the H+/Ca2+ exchange generated a membrane potential, interior positive, as shown by [14C]SCN accumulation. Furthermore, Ca2+ uptake was stimulated by an imposed negative membrane potential. The results support a simple model of one Ca2+ taken up per H+ lost. The exchange transport can be reversed, as a Ca2+ gradient (Ca2+in greater than Ca2+out) was effective in forming a pH gradient (acid inside). We suggest that the H+/Ca2+ exchange normally transports Ca2+ into the vacuole; however, under certain conditions, Ca2+ may be released into the cytoplasm via this antiporter.     

Proton motive force and Na+/H+ antiport in a moderate halophile.

The influence of pH on the proton motive force of Vibrio costicola was determined by measuring the distributions of triphenylmethylphosphonium cation (membrane potential, delta psi) and either dimethyloxazolidinedione or methylamine (osmotic component, delta pH). As the pH of the medium was adjusted from 5.7 to 9.0, the proton motive force steadily decreased from about 170 to 100 mV. This decline occurred, despite a large increase in the membrane potential to its maximum value at pH 9.0, because of the loss of the pH gradient (inside alkaline). The cytoplasm and medium were of equal pH at 7.5; membrane permeability properties were lost at the pH extremes of 5.0 and 9.5. Protonophores and monensin prevented the net efflux of protons normally found when an oxygen pulse was given to an anaerobic cell suspension. A Na+/H+ antiport activity was measured for both Na+ influx and efflux and was shown to be dissipated by protonophores and monensin. These results strongly favor the concept that respiratory energy is used for proton efflux and that the resulting proton motive force may be converted to a sodium motive force through Na+/H+ antiport (driven by delta psi). A role for antiport activity in pH regulation of the cytosol can also explain the broad pH range for optimal growth, extending to the alkaline extreme of pH 9.0.