Properties of two different Na+/H+ antiport systems in alkaliphilic Bacillus sp. strain C-125.

Na+/H+ antiport was studied in alkaliphilic Bacillus sp. strain C-125, its alkali-sensitive mutant 38154, and a transformant (pALK2) with recovered alkaliphily. The transformed was able to maintain an intracellular pH (pHin) that was lower than that of external milieu and contained an electrogenic Na+/H+ antiporter driven only by delta psi (membrane potential, interior negative). The activity of this delta psi-dependent Na+/H+ antiporter was highly dependent on pHin, increasing with increasing pHin, and was found only in cells grown at alkaline pH. On the other hand, the alkali-sensitive mutant, which had lost the ability to grow above pH 9.5, lacked the delta psi-dependent Na+/H+ antiporter and showed defective regulation of pHin at the alkaline pH range. However, this mutant, like the parent strain, still required sodium ions for growth and for an amino acid transport system. Moreover, another Na+/H+ antiporter, driven by the imposed delta pH (pHin > extracellular pHout), was active in this mutant strain, showing that the previously reported delta pH-dependent antiport activity is probably separate from delta psi-dependent antiporter activity. The delta pH-dependent Na+/H+ antiporter was found in cells grown at either pH 7 or pH 9. This latter antiporter was reconstituted into liposomes by using a dilution method. When a transmembrane pH gradient was applied, downhill sodium efflux was accelerated, showing that the antiporter can be reconstituted into liposomes and still retain its activity.     

Roles of K+ and Na+ in pH homeostasis and growth of the marine bacterium Vibrio alginolyticus.

The marine bacterium Vibrio alginolyticus, containing 470 mM-K+ and 70 mM-Na+ inside its cells, was able to regulate the cytoplasmic pH (pH(in)) in the narrow range 7.6-7.8 over the external pH (pH(out)) range 6.0-9.0 in the presence of 400 mM-Na+ and 10 mM-K+. In the absence of external K+, however, pHin was regulated only at alkaline pH(out) values above 7.6. When the cells were incubated in the presence of unusually high K+ (400 mM) and 4 mM Na+, the pH(in) was regulated only at acidic pH(out) values below 7.6. These results could be explained by postulating a K+/H+ antiporter as the regulator of pH(in) over the pH(out) range 6.0-9.0. When Na(+)-loaded/K(+)-depleted cells were incubated in 400 mM-Na+ in the absence of K+, an inside acidic delta pH was generated at pH(out) values above 7.0. After addition of diethanolamine the inside acidic delta pH collapsed transiently and then returned to the original value concomitant with the extrusion of Na+, suggesting the participation of a Na+/H+ antiporter for the generation of an inside acidic delta pH. In the presence of 400 mM-K+, at least 5 mM-Na+ was required to support cell growth at pH(out) below 7.5. An increase in Na+ concentration allowed the cells to grow at a more alkaline pH(out). Furthermore, cells containing more Na+ inside could more easily adapt to grow at alkaline pH(out). These results indicated the importance of Na+ in acidification of the cell interior via a Na+/H+ antiporter in order to support cell growth at alkaline pH(out) under conditions where the activity of a K+/H+ antiporter is marginal.     

Isolation and Properties of Enterococcus hirae Mutants Defective in the Potassium/Proton Antiport System

A K+/H+ antiporter regulates cytoplasmic pH in Enterococcus hirae growing at alkaline pH. Mutants defective in this antiport activity were alkaline pH sensitive. One mutant, Pop1, lacked both K+/methylamine exchange at pH 9.5 and concomitant acidification of cytoplasmic pH. Pop1 grew well at pHs below 8 but did not at pHs above 9, conditions under which cytoplasmic pH was not fully acidified.     

Bioenergetic properties of alkalophilic Bacillus sp. strain C-59 on an alkaline medium containing K2CO3.

Alkalophilic Bacillus sp. strain C-59 could grow well on an alkaline medium containing K2CO3, as well as Na2CO3, but did not grow on K+-depleted medium. Right-side-out membrane vesicles, energized in the absence of Na+, however, could not take up [14C]methylamine actively, while vesicles equilibrated with 10 mM NaCl actively took up [14C]methylamine. The uptake of [14C]serine was also stimulated by the addition of Na+, and the imposition of a sodium gradient caused transient uptake. These results indicated that an Na+/H+ antiporter was involved in pH homeostasis and generation of an electrochemical sodium gradient in strain C-59 even though a growth requirement for Na+ was not evident. The efflux of 22Na+ from 22Na+-loaded vesicles was more rapid at pH 9.5 than at pH 7 in the presence of an electron donor. On the other hand, vesicles at pH 7 showed more rapid efflux than at pH 9.5 when the antiporter was energized by a valinomycin-mediated K+ diffusion potential (inside negative).     

Sodium/proton antiport is required for growth of Escherichia coli at alkaline pH

Evidence is presented indicating that Escherichia coli requires the Na+/H+ antiporter and external sodium (or lithium) ion to grow at high pH. Cells were grown in plastic tubes containing medium with a very low Na+ content (5-15 microM). Normal cells grew at pH 7 or 8 with or without added Na+, but at pH 8.5 external Na was required for growth. A mutant with low antiporter activity failed to grow at pH 8.5 with or without Na+. On the other hand, another mutant with elevated antiporter activity grew at a higher pH than normal (pH 9) in the presence of added Na+ or Li+. Amiloride, an inhibitor of the antiporter, prevented cells from growing at pH 8.5 (plus Na+), although it had no effect on growth in media of lower pH values.     

Characterization and mapping of a major Na+/H+ antiporter gene of Escherichia coli.

Using in vivo assays, we show that the Na+/H+ antiporter activity of the Escherichia coli mutant HIT-1 is reduced dramatically compared with activity in wild-type cells. An isogenic nhaA (formerly antA) deletion strain, however, is not significantly different from wild type in this respect. We call the locus affecting Na+/H+ antiporter activity of the HIT-1 mutant nhaB. The nhaB activity exhibits no pH dependence in the range between 7.0 and 8.5, whereas that of the nhaA gene increases considerably at pH levels above 8.0. Mutants with defects in nhaB grow normally on agar media containing 0.5 M NaCl, but nhaA mutants are sensitive to 0.5 M NaCl. We have mapped the nhaB mutation of HIT-1 to 25.6 min on the E. coli map. It is unlinked to the nhaA region, which is located at about 0.5 min. Since a cell with a mutation in nhaB alone is essentially Na+/H+ antiporter negative up to pH 8.0, we conclude that nhaB is required for the major Na+/H+ antiporter activity in the usual physiological pH range.     

The use of fluorescamine as a permeant probe to localize phosphatidylethanolamine in intact friend erythroleukaemic cells

The marine bacterium, Vibrio alginolyticus, regulates the cytoplasmic pH at about 7.8 over the pH range 6.0-9.0. By the addition of diethanolamine (a membrane-permeable amine) at pH 9.0, the internal pH was alkalized and simultaneously the cellular K+ was released. Following the K+ exit, the internal pH was acidified until 7.8, where the K+ exit leveled off. The K+ exit was mediated by a K+/H+ antiporter that is driven by the outwardly directed K+ gradient and ceases to function at the internal pH of 7.8 and below. The Na+-loaded cells assayed in the absence of KCl generated inside acidic delta pH at alkaline pH due to the function of an Na+/H+ antiporter, but the internal pH was not maintained at a constant value. At acidic pH range, the addition of KCl to the external medium was necessary for the alkalization of cell interior. These results suggested that in cooperation with the K+ uptake system and H+ pumps, the K+/H+ antiporter functions as a regulator of cytoplasmic pH to maintain a constant value of 7.8 over the pH range 6.0-9.0.     

Sodium ATPase and sodium/proton antiporter are not obligatory for sodium homeostasis of Enterococcus hirae at acid pH

Enterococcus hirae grows in a broad pH range from 5 to 11. An E. hirae mutant 7683 lacking the activities of two sodium pumps, Na+-ATPase and Na+/H+ antiporter, does not grow in high Na+ medium at pH above 7.5. We found that 7683 grew normally in high Na+ medium at pH 5.5. Although an energy-dependent sodium extrusion at pH 5.5 was missing, the intracellular levels of Na+ and K+ were normal in this mutant. The Na+ influx rates of 7683 and two other strains at pH 5.5 were much slower than those at pH 7.5. These results suggest that Na+ elimination of this bacterium at acid pH is achieved by a decrease in Na+ entry and a normal K+ uptake.     

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.     

Inhibition of cardiac sarcolemmal Na+/H+ antiporter by opioids.

In our routine screening of chemicals that would inhibit cardiac sarcolemmal Na+/H+ antiporter, we discovered that some of the opioids produced inhibition of cardiac sarcolemmal Na+/H+ antiporter in micromolar concentrations. Using U-50,488H, a selective kappa-opioid agonist, we characterized the nature of interaction between opioids and the Na+/H+ antiporter. The inhibitory effect of U-50,488H on Na+/H+ antiporter was immediate and reversible, and was not mediated through the interaction with the opioid receptors but due to the direct interaction of U-50,488H with the Na+/H+ antiporter. The kinetic data show that in the presence of U-50,488H the Km for Na+ was increased from 2.5 +/- 0.2 to 5.0 +/- 0.3 mM, while the Vmax (52.0 +/- 5.0 nmol.mg-1.min-1) remained the same. These results suggest that U-50,488H and Na+ compete for the same site on the antiporter. When testing the effect of U-50,488H on other transport systems of cardiac sarcolemma, we found that U-50,488H also inhibited Na+/Ca2+ antiporter and Na+/K+ pump but at much higher concentrations suggesting that U-50,488H shows some degree of selectivity for cardiac sarcolemmal Na+/H+ antiporter. When we compared the inhibitory potency of U-50,488H with amiloride and its analog, namely 5-(N,N-hexamethylene)amiloride, we found that U-50,488H (IC50 = 100 +/- 15 microM) was threefold more potent than amiloride (IC50 = 300 +/- 20 microM) but it was three-fold less potent than the amiloride analog (IC50 = 30 +/- 10 microM) in inhibiting cardiac sarcolemmal Na+/H+ antiporter. These results show that although U-50,488H is more potent than amiloride, the inhibitory characteristics of U-50,488H on cardiac sarcolemmal Na+/H+ antiporter are similar to amiloride.     

Insights into the biochemistry of the ubiquitous NhaP family of cation/H+ antiporters

Na+/H+ antiporters are integral membrane proteins that exchange Na+ for H+ across the cytoplasmic or organellar membranes of virtually all living cells. They are essential for control of cellular pH, volume homeostasis, and regulation of Na+ levels. Na+/H+ antiporters have become increasingly characterized and are now becoming important drug targets. The recently identified NhaP family of Na+/H+ antiporters, from the CPA1 superfamily, contains proteins with a surprisingly broad collective range of transported cations, exchanging protons for alkali cations such as Na+, Li+, K+, or Rb+ as well as for Ca2+ and, possibly, NH4+. Questions about ion selectivity and the physiological impact of each particular NhaP antiporter are far from trivial. For example, Vc-NhaP2 from Vibrio cholerae has recently been shown to function in vivo as a specific K+/H+ antiporter while retaining the ability to exchange H+ for Na+ and bind (but not exchange with H+) Li+ in a competitive manner. These and other findings reviewed in this communication make antiporters of the NhaP type attractive systems to study intimate molecular mechanisms of cation exchange. In an evolutionary perspective, the NhaP family seems to be a phylogenetic entity undergoing active divergent evolution. In this minireview, to rationalize peculiarities of the cation specificity in the NhaP family, the "size-exclusion principle" and the idea of "ligand shading" are discussed.     

Microbial volatile organic compound emissions from Stachybotrys chartarumgrowing on gypsum wallboard and ceiling tile

In neutralophilic bacteria, monovalent metal cation/H+ antiporters play a key role in pH homeostasis. In Escherichia coli, only four antiporters (NhaA, NhaB, MdfA and ChaA) are identified to function in maintenance of a stable cytoplasmic pH under conditions of alkaline stress. We hypothesised that the multidrug resistance protein MdtM, a recently characterised homologue of MdfA and a member of the major facilitator superfamily, also functions in alkaline pH homeostasis. Assays that compared the growth of an E. coli ΔmdtM deletion mutant transformed with a plasmid encoding wild-type MdtM or the dysfunctional MdtM D22A mutant at different external alkaline pH values (ranging from pH 8.5 to 10) revealed a potential contribution by MdtM to alkaline pH tolerance, but only when millimolar concentrations of sodium or potassium was present in the growth medium. Fluorescence-based activity assays using inverted vesicles generated from transformants of antiporter-deficient (ΔnhaA, ΔnhaB, ΔchaA) E. coli TO114 cells defined MdtM as a low-affinity antiporter that catalysed electrogenic exchange of Na+, K+, Rb+ or Li+ for H+. The K+/H+ antiport reaction had a pH optimum at 9.0, whereas the Na+/H+ exchange activity was optimum at pH 9.25. Measurement of internal cellular pH confirmed MdtM as contributing to maintenance of a stable cytoplasmic pH, acid relative to the external pH, under conditions of alkaline stress. Taken together, the results support a role for MdtM in alkaline pH tolerance. MdtM can therefore be added to the currently limited list of antiporters known to function in pH homeostasis in the model organism E. coli.     

The pha2 gene cluster involved in Na+ resistance and adaption to alkaline pH in Sinorhizobium fredii RT19 encodes a monovalent cation/proton antiporter

Sinorhizobium fredii RT19 can tolerate up to 0.6 M NaCl, whereas all its pha2-disrupted mutants, constructed by Tn5 mutagenesis, failed to grow in even the presence of 0.1 M NaCl. No growth difference was detected in pha2 mutants at a pH<7.5 in the presence or absence of K+, but growth reduction was observed in the presence of K+ when pH>7.5. The pha2 gene cluster was able to completely restore the growth of the pha2 mutants of S. fredii RT19 in 0.6 M NaCl. Measurement of monovalent cation intracellular content suggested that pha2 was involved in both Na+ (Li+) and K+ efflux. The pha2 mutants exhibited K+/H+, but no apparent Na+(Li+)/H+ antiporter activity in everted membrane vesicles. Taken together, these results indicated that the pha2 cluster of S. fredii RT19 encodes a monovalent cation/proton antiporter involved in resistance to Na+ and adaption to pH, which was very different from the pha1 cluster of Sinorhizobium meliloti, which encodes a K+/H+ antiporter.     

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.     

质膜Na^＋／H^＋逆向转运蛋白与植物耐盐性

土壤盐碱化是造成农作物减产的主要原因之一。质膜Na^＋／H^＋逆向转运蛋白能够介导植物根部Na^＋的外排和体内Na^＋的长距离运输, 并能够调控细胞K＋的稳态平衡及细胞内pH值和Ca^2＋的转运, 因此其在植物耐盐性方面具有重要作用。该文概述了植物质膜Na^＋／H^＋逆向转运蛋白的分子结构、功能、表达调控及其与植物耐盐性关系等方面的研究进展, 并对今后有关该蛋白的主要研究方向作了分析和展望。     

Na+/H+ antiporters

Na+/H+ antiports or exchange reactions have been found widely, if not ubiquitously, in prokaryotic and eukaryotic membranes. In any given experimental system, the multiplicity of ion conductance pathways and the absence of specific inhibitors complicate efforts to establish that the antiport observed actually results from the activity of a specific secondary porter which catalyzes coupled exchanged of the two ions. Nevertheless, a large body of evidence suggests that at least some prokaryotes possess a delta psi-dependent, mutable Na+/H+ antiporter which catalyzes Na+ extrusion in exchange for H+; in other bacterial species, the antiporter my function electroneutrally, at least at some external pH values. The bacterial Na+/H+ antiporter constitutes a critical limb of Na+ circulation, functioning to maintain a delta mu Na+ for use by Na+-coupled bioenergetic processes. The prokaryotic antiporter is also involved in pH homeostasis in the alkaline pH range. Studies of mutant strains that are deficient in Na+/H+ antiporter activity also indicate the existence of a relationship, e.g., a common subunit or regulatory factor, between the Na+/H+ antiporter and Na+/solute symporters in several bacterial species. In eukaryotes, an electroneutral, amiloride-sensitive Na+/H+ antiport has been found in a wide variety of cell and tissue types. Generally, the normal direction of the antiport appears to be that of Na+ uptake and H+ extrusion. The activity is thus implicated as part of a complex system for Na+ circulation, e.g., in transepithelial transport, and might have some role in acidification in the renal proximal tubule. In many experimental systems, the Na+/H+ antiport appears to influence intracellular pH. In addition to a role in general pH homeostasis, such Na+-dependent changes in intracellular pH could be part of the early events in a variety of differentiating and proliferative systems. Reconstitution and structural studies, as well as detailed analysis of gene loci and products which affect the antiport activity, are in their very early stages. These studies will be important in further clarification of the precise structural nature and role(s) of the Na+/H+ antiporters. In neither prokaryotes nor eukaryotes systems is there yet incontrovertible evidence that a specific protein carrier, that catalyzes Na+/H+ antiport, is actually responsible for any of the multitude of effects attributed to such antiporters. The Na+-H+ exchange might turn out to be side reactions of other porters or the additive effects of several conductance pathways; or, as appears most likely in at least some bacteria and in renal tissue, the antiporter may be a discrete, complex carr     

Halotolerant cyanobacterium Aphanothece halophytica contains an Na(+)/H(+) antiporter, homologous to eukaryotic ones, with novel ion specificity affected by C-terminal tail

Recently, a cyanobacterium Synechocystis sp. PCC 6803 has been shown to contain an Na(+)/H(+) antiporter gene homologous to plants (SOS1 and AtNHX1 from Arabidopsis) and mammalians (NHEs from human) but not to Escherichia coli (nhaA and nhaB). Here, we examined whether a halotolerant cyanobacterium Aphanothece halophytica has homologous genes. It turned out that A. halophytica contains an Na(+)/H(+) antiporter homologous to plants, mammalians, and some bacteria (nhaP from Pseudomonas and synnhaP from Synechocystis) but with novel ion specificity. Its gene product, ApNhaP (Na(+)/H(+) antiporter from Aphanothece halophytica), exhibited the Na(+)/H(+) antiporter activity over a wide pH range between 5 and 9 and complemented the Na(+)-sensitive phenotype of the antiporter-deficient E. coli mutant. The ApNhaP had virtually no activity for the Li(+)/H(+) antiporter but showed high Ca(2+)/H(+) antiporter activity at alkaline pH. The ApNhaP complemented the Ca(2+)-sensitive phenotype of the E. coli mutant but not the Li(+)-sensitive phenotype. The replacement of a long C-terminal tail of ApNhaP with that of Synechocystis altered the ion specificity of the antiporter. These results suggest that the ion specificity of an Na(+)/H(+) antiporter is partly determined by the structural properties of the C-terminal tail, which was well exemplified in the case of A. halophytica.     

Roles of NhaA,NhaB, and NhaD Na+/H+ antiporters in survival of Vibrio cholerae in a saline environment

Vibrio cholerae, the causative agent of cholera, is a normal inhabitant of aquatic environments, where it survives in a wide range of conditions of pH and salinity. In this work, we investigated the role of three Na+/H+ antiporters on the survival of V. cholerae in a saline environment. We have previously cloned the Vc-nhaA gene encoding the V. cholerae homolog of Escherichia coli. Here we identified two additional antiporter genes, designated Vc-nhaB and Vc-nhaD, encoding two putative proteins of 530 and 477 residues, respectively, highly homologous to the respective antiporters of Vibrio species and E. coli. We showed that both Vc-NhaA and Vc-NhaB confer Na+ resistance and that Vc-NhaA displays an antiport activity in E. coli, which is similar in magnitude, kinetic parameters, and pH regulation to that of E. coli NhaA. To determine the roles of the Na+/H+ antiporters in V. cholerae, we constructed nhaA, nhaB, and nhaD mutants (single, double, and triple mutants). In contrast to E. coli, the inactivation of the three putative antiporter genes (Vc-nhaABD) in V. cholerae did not alter the bacterial exponential growth in the presence of high Na+ concentrations and had only a slight effect in the stationary phase. In contrast, a pronounced and similar Li+-sensitive phenotype was found with all mutants lacking Vc-nhaA during the exponential phase of growth and also with the triple mutant in the stationary phase of growth. By using 2-n-nonyl-4-hydroxyquinoline N-oxide, a specific inhibitor of the electron-transport-linked Na+ pump NADH-quinone oxidoreductase (NQR), we determined that in the absence of NQR activity, the Vc-NhaA Na+/H+ antiporter activity becomes essential for the resistance of V. cholerae to Na+ at alkaline pH. Since the ion pump NQR is Na+ specific, we suggest that its activity masks the Na+/H+ but not the Li+/H+ antiporter activities. Our results indicate that the Na+ resistance of the human pathogen V. cholerae requires a complex molecular system involving multiple antiporters and the NQR pump.     

Identification and characterization of Vnx1p, a novel type of vacuolar monovalent cation/H+ antiporter of Saccharomyces cerevisiae

We identified and characterized Vnx1p, a novel vacuolar monovalent cation/H+ antiporter encoded by the open reading frame YNL321w from Saccharomyces cerevisiae. Despite the homology of Vnx1p with other members of the CAX (calcium exchanger) family of transporters, Vnx1p is unable to mediate Ca2+ transport but is a low affinity Na+/H+ and K+/H+ anti-porter with a Km of 22.4 and 82.2 mm for Na+ and K+, respectively. Sequence analyses of Vnx1p revealed the absence of key amino acids shown to be essential for Ca2+/H+ exchange. vnx1Delta cells displayed growth inhibition when grown in the presence of hygromycin B or NaCl. Vnx1p activity was found in the vacuoles and shown to be dependent on the electrochemical potential gradient of H+ generated by the action of the V-type H+-ATPase. The presence of Vnx1p at the vacuolar membrane was further confirmed with cells expressing a VNX1::GFP chimeric gene. Similar to Nhx1p, the prevacuolar compartment-bound Na+/H+ antiporter, the vacuole-bound Vnx1p appears to play roles in the regulation of ion homeostasis and cellular pH.