The endosomal Na(+)/H(+) exchanger contributes to multivesicular body formation by regulating the recruitment of ESCRT-0 Vps27p to the endosomal membrane.

Multivesicular bodies (MVBs) are late endosomal compartments containing luminal vesicles (MVB vesicles) that are formed by inward budding of the endosomal membrane. In budding yeast, MVBs are an important cellular mechanism for the transport of membrane proteins to the vacuolar lumen. This process requires a class E subset of vacuolar protein sorting (VPS) genes. VPS44 (allelic to NHX1) encodes an endosome-localized Na(+)/H(+) exchanger. The function of the VPS44 exchanger in the context of vacuolar protein transport is largely unknown. Using a cell-free MVB formation assay system, we demonstrated that Nhx1p is required for the efficient formation of MVB vesicles in the late endosome. The recruitment of Vps27p, a class E Vps protein, to the endosomal membrane was dependent on Nhx1p activity and was enhanced by an acidic pH at the endosomal surface. Taken together, we propose that Nhx1p contributes to MVB formation by the recruitment of Vps27p to the endosomal membrane, possibly through Nhx1p antiporter activity.

Na+/H+ exchanger isoform 6 (NHE6/SLC9A6) is involved in clathrin-dependent endocytosis of transferrin.

In mammalian cells, nine conserved isoforms of the Na(+)/H(+) exchanger (NHE) are known to be important for pH regulation of the cytoplasm and organellar lumens. NHE1-5 are localized to the plasma membrane, whereas NHE6-9 are localized to distinct organelles. NHE6 is localized predominantly in endosomal compartments but is also found in the plasma membrane. To investigate the role of NHE6 in endocytosis, we established NHE6-knockdown HeLa cells and analyzed the effect of this knockdown on endocytotic events. The expression level of NHE6 in knockdown cells was decreased to ∼15% of the level seen in control cells. Uptake of transferrin was also decreased. No effect was found on the endocytosis of epidermal growth factor or on the cholera toxin B subunit. Moreover, in the NHE6-knockdown cells, transferrin uptake was found to be affected in the early stages of endocytosis. Microscopic analysis revealed that, at 2 min after the onset of endocytosis, colocalization of NHE6, clathrin, and transferrin was observed, which suggests that NHE6 was localized to endocytotic, clathrin-coated vesicles. In addition, in knockdown cells, transferrin-positive endosomes were acidified, but no effect was found on cytoplasmic pH. In cells overexpressing wild-type NHE6, increased transferrin uptake was observed, but no such increase was seen in cells overexpressing mutant NHE6 deficient in ion transport. The luminal pH in transferrin-positive endosomes was alkalized in cells overexpressing wild-type NHE6 but normal in cells overexpressing mutant NHE6. These observations suggest that NHE6 regulates clathrin-dependent endocytosis of transferrin via pH regulation.

Dual functional significance of calcineurin homologous protein 1 binding to Na(+)/H(+) exchanger isoform 1.

Calcineurin homologous protein 1 (CHP1) binds to the hydrophilic tail of the Na(+)/H(+) exchanger isoform 1 (NHE1). Previous gene knockout of CHP1 revealed that the loss of CHP1 caused a decrease in the total amount of NHE1, suggesting the destabilization of NHE1 molecules without CHP1 (Matsushita et al., Am J Physiol Cell Physiol 293: C246-C254, 2007). However, Pang et al. (J Biol Chem 276: 17367-17372, 2001) reported that NHE1 without a CHP1 binding site was found in the plasma membrane, suggesting no requirement of CHP1 binding for plasma membrane localization of NHE1. Here, the functional significance of CHP1 binding to NHE1 was examined to resolve these contradictory results. In CV1 cells, which overexpressed wild-type NHE1, overexpression of CHP1 caused an increase in both the total amount of NHE1 and the colocalization of NHE1 and CHP1 at the plasma membrane. This provided new visual evidence of the localization of NHE1 from endoplasmic reticulum to the plasma membrane upon CHP1 binding. An immunoprecipitation assay showed that the expression of CHP1 reduced the ubiquitination of NHE1 and/or its associated proteins. Mutant NHE1s without CHP1 binding site exhibited a modest localization to the plasma membrane. After reaching the plasma membrane, these mutant NHE1s exhibited shorter half-lives than the wild-type NHE1 with CHP1. The results suggest a dual functional significance of CHP1 and its binding region: 1) binding of CHP1 stabilizes NHE1 and increases its plasma membrane localization by masking a NHE1 disposal signal, and 2) CHP1 binding is required for the antiporter activity.

Saccharomyces cerevisiae glucose signalling regulator Mth1p regulates the organellar Na+/H+ exchanger Nhx1p.

Organelle-localized NHEs (Na+/H+ exchangers) are found in cells from yeast to humans and contribute to organellar pH regulation by exporting H+ from the lumen to the cytosol coupled to an H+ gradient established by vacuolar H+-ATPase. The mechanisms underlying the regulation of organellar NHEs are largely unknown. In the present study, a yeast two-hybrid assay identified Mth1p as a new binding protein for Nhx1p, an organellar NHE in Saccharomyces cerevisiae. It was shown by an in vitro pull-down assay that Mth1p bound to the hydrophilic C-terminal half of Nhx1p, especially to the central portion of this region. Mth1p is known to bind to the cytoplasmic domain of the glucose sensor Snf3p/Rgt2p and also functions as a negative transcriptional regulator. Mth1p was expressed in cells grown in a medium containing galactose, but was lost (possibly degraded) when cells were grown in medium containing glucose as the sole carbon source. Deletion of the MTH1 gene increased cell growth compared with the wild-type when cells were grown in a medium containing galactose and with hygromycin or at an acidic pH. This resistance to hygromycin or acidic conditions was not observed for cells grown with glucose as the sole carbon source. Gene knockout of NHX1 increased the sensitivity to hygromycin and acidic pH. The increased resistance to hygromycin was reproduced by truncation of the Mth1p-binding region in Nhx1p. These results implicate Mth1p as a novel regulator of Nhx1p that responds to specific extracellular carbon sources.

A membrane-proximal region in the C-terminal tail of NHE7 is required for its distribution in the trans-Golgi network, distinct from NHE6 localization at endosomes.

Mammalian Na(+)/H(+) exchanger (NHE) isoform NHE6 is localized in sorting/recycling endosomes, whereas NHE7 is localized in the trans-Golgi network (TGN) and mid-trans-Golgi stacks. The mechanism targeting each NHE to a specific organelle is largely unknown, although the targeting is thought to be important for pH control in the lumen of various organelles. NHE6 and NHE7 exhibit distinct localization despite conserved amino acid sequences. To specify the intramolecular region involved in the specific localization, we examined the intracellular localization of chimeric NHE6 and NHE7 constructs. NHEs are composed of an N-terminal transmembrane domain (TM) and a C-terminal hydrophilic tail domain (Ct). Exchange of the Ct between the isoforms suggested that the Ct is required for the specific localization. We further split the Ct into three regions, and chimeras with various combinations of these small regions indicated that the most membrane-proximal region among the three contributes to the specific localization. Mutant forms of NHE7 with sequential alanine substitutions in the most membrane-proximal region, between residues 530 and 589, showed that two regions (residues 553-559 and 563-568) are required for NHE7-like localization. However, NHE6 with alanine substitutions in the membrane-proximal region exhibited no apparent change in localization. These results suggest that two membrane proximal regions (residues 533-559 and 563-568) play an important role in targeting NHE7 to the TGN.

Intermolecular cross-linking of monomers in Helicobacter pylori Na+/H+ antiporter NhaA at the dimer interface inhibits antiporter activity.

We have previously shown that HPNhaA (Helicobacter pylori Na+/H+ antiporter) forms an oligomer in a native membrane of Escherichia coli, and conformational changes of oligomer occur between monomers of the oligomer during ion transport. In the present study, we use Blue-native PAGE to show that HPNhaA forms a dimer. Cysteine-scanning mutagenesis of residues 55-61 in a putative beta-sheet region of loop1 and subsequent functional analyses revealed that the Q58C mutation resulted in an intermolecular disulfide bond. G56C, I59C and G60C were found to be cross-linked by bifunctional cross-linkers. Furthermore, the Q58E mutant did not form a dimer, possibly due to electrostatic repulsion between monomers. These results imply that Gln-58 and the flanking sequence in the putative beta-sheet of the monomer are located close to the identical residues in the dimer. The Q58C mutant of NhaA was almost inactive under non-reducing conditions, and activity was restored under reducing conditions. This result showed that cross-linking at the dimer interface reduces transporter activity by interfering with the flexible association between the monomers. A mutant HPNhaA protein with three amino acid substitutions at residues 57-59 did not form a dimer, and yet was active, indicating that the monomer is functional.

Altered motor activity of alternative splice variants of the mammalian kinesin-3 protein KIF1B.

Several mammalian kinesin motor proteins exist as multiple isoforms that arise from alternative splicing of a single gene. However, the roles of many motor protein splice variants remain unclear. The kinesin-3 motor protein KIF1B has alternatively spliced isoforms distinguished by the presence or absence of insertion sequences in the conserved amino-terminal region of the protein. The insertions are located in the loop region containing the lysine-rich cluster, also known as the K-loop, and in the hinge region adjacent to the motor domain. To clarify the functions of these alternative splice variants of KIF1B, we examined the biochemical properties of recombinant KIF1B with and without insertion sequences. In a microtubule-dependent ATPase assay, KIF1B variants that contained both insertions had higher activity and affinity for microtubules than KIF1B variants that contained no insertions. Mutational analysis of the K-loop insertion revealed that variants with a longer insertion sequence at this site had higher activity. However, the velocity of movement in motility assays was similar between KIF1B with and without insertion sequences. Our results indicate that splicing isoforms of KIF1B that vary in their insertion sequences have different motor activities.

Saccharomyces cerevisiae Na+/H+ antiporter Nha1p associates with lipid rafts and requires sphingolipid for stable localization to the plasma membrane.

The plasma membrane-type Na+/H+ antiporter Nha1p from budding yeast plays an important role in intracellular Na+ and pH homeostasis by mediating the exchange of Na+ for H+ across the plasma membrane. However, the mechanism of intracellular targeting of Nha1p to the plasma membrane remains unknown. Here, we found that Nha1p exists predominantly in detergent-resistant membrane fractions (DRMs) following density gradient centrifugation. When ergosterol was extracted from membranes, Nha1p was transferred to a detergent-soluble fraction, suggesting that Nha1p associates with ergosterol-containing DRMs, also known as lipid rafts. Density gradient centrifugation of cell extracts of yeast mutants that were defective in different stages of the secretory pathway revealed that, unlike previously identified raft proteins, the association of Nha1p with DRMs occurs mainly at the plasma membrane. In lcb1-100 cells, which are temperature-sensitive for sphingolipid synthesis, newly synthesized Nha1p failed to localize to the plasma membrane at the non-permissive temperature. Rather, Nha1p was distributed in an intracellular punctate pattern. The addition of phytosphingosine or the inhibition of endocytosis in lcb1-100 cells restored the targeting of Nha1p to the plasma membrane. The results of the current study suggest that sphingolipids are required for the stable localization of Nha1p to the plasma membrane.

Cell surface levels of organellar Na+/H+ exchanger isoform 6 are regulated by interaction with RACK1.

In mammalian cells, four Na(+)/H(+) exchangers (NHE6 - NHE9) are localized to intracellular compartments. NHE6 and NHE9 are predominantly localized to sorting and recycling endosomes, NHE7 to the trans-Golgi network, and NHE8 to the mid-trans-Golgi stacks. The unique localization of NHEs may contribute to establishing organelle-specific pH values and ion homeostasis in cells. Mechanisms underlying the regulation and targeting of organellar NHEs are largely unknown. We identified an interaction between NHE9 and RACK1 (receptor for activated C kinase 1), a cytoplasmic scaffold protein, by yeast two-hybrid screening using the NHE9 C terminus as bait. The NHE9 C terminus is exposed to the cytoplasm, verifying that the interaction is topologically possible. The binding region was further delineated to the central region of the NHE9 C terminus. RACK1 also bound NHE6 and NHE7, but not NHE8, in vitro. Endogenous association between NHE6 and RACK1 was confirmed by co-immunoprecipitation and co-localization in HeLa cells. The luminal pH of the recycling endosome was elevated in RACK1 knockdown cells, accompanied by a decrease in the amount of NHE6 on the cell surface, although the total level of NHE6 was not significantly altered. These results indicate that RACK1 plays a role in regulating the distribution of NHE6 between endosomes and the plasma membrane and contributes to maintaining luminal pH of the endocytic recycling compartments.

Functional assembly of the Na+/H+ antiporter of Helicobacter pylori from partial fragments in vivo.

Functional assembly of the Helicobacter pylori Na+/H+ antiporter (HPNhaA) from partial fragments was studied. Expression plasmids encoding a series of complementary N- and C-terminal fragment pairs containing the transmembrane domains (TMs) were constructed by inserting a stop or a start codon into each of the loop regions of NhaA. HPNhaA fragments alone or complementary fragment pairs were expressed in DeltanhaA Escherichia coli, and fragment integration into the membrane and antiporter activity were measured. TM1-10, TM1-11, TM2-12, TM6-12, and TM10-12 were found in the membrane fraction, while the other fragments were not. While no single fragment displayed antiporter activity, simultaneous expression of fragments in certain pairs, such as TM1-2 + TM3-12, TM1-8 + TM9-12, or TM1-11 + TM12, reconstituted antiporter activity. With the exception of TM12, all of the fragments in the pairs were detected in the membrane. No single fragments expressed alone for these pairs were found in the membrane, except for TM1-11, suggesting that the interaction between the fragments in these pairs stabilized the fragments and enabled reconstitution of HPNhaA. We also found that the simultaneous expression of three complementary fragments (TM1-2 + TM3-8 + TM9-12) reconstituted HPNhaA activity. Other pairs that were found in the membrane (TM1-5 + TM6-12, TM1-10 + TM11-12, and TM1 + TM2-12) did not reconstitute antiporter activity, suggesting that they may not have the proper conformation. These results revealed that the ability to reconstitute antiporter activity depends on the split position in the loop regions and the interaction between complementary fragment pairs. We propose that formation of the active HPNhaA molecule is initiated by the interaction of short-lived intermediates and maintained by the increased stability of the intermediates within the resulting complex.

Loss of calcineurin homologous protein-1 in chicken B lymphoma DT40 cells destabilizes Na+/H+ exchanger isoform-1 protein.

NHE1/SLC9A1 is a ubiquitous isoform of vertebrate Na(+)/H(+) exchangers (NHEs) functioning in maintaining intracellular concentrations of Na(+) and H(+) ions. Calcineurin homologous protein-1 (CHP1) binds to the hydrophilic region of NHE1 and regulates NHE1 activity but reportedly does not play a role in translocating NHE1 from the endoplasmic reticulum to the plasma membrane. However, an antiport function of NHE1 requiring CHP1 remains to be clarified. Here we established CHP1-deficient chicken B lymphoma DT40 cells by gene targeting to address CHP1 function. CHP1-deficient cells showed extensive decreases in Na(+)/H(+) activities in intact cells. Although NHE1 mRNA levels were not affected, NHE1 protein levels were significantly reduced not only in the plasma membrane but in whole cells. The expression of a CHP1 transgene in CHP1-deficient cells rescued NHE1 protein expression. Expression of mutant forms of CHP1 defective in Ca(2+) binding or myristoylation also partially decreased NHE1 protein levels. Knockdown of CHP1 also caused a moderate decrease in NHE1 protein in HeLa cells. These data indicate that CHP1 primarily plays an essential role in stabilization of NHE1 for reaching of NHE1 to the plasma membrane and its exchange activity.

Structure-function relationship of the fifth transmembrane domain in the Na+/H+ antiporter of Helicobacter pylori: Topology and function of the residues, including two consecutive essential aspartate residues.

We examined the structure-function relationships of residues in the fifth transmembrane domain (TM5) of the Na+/H+ antiporter A (NhaA) from Helicobacter pylori (HP NhaA) by cysteine scanning mutagenesis. TM5 contains two aspartate residues, Asp-171 and Asp-172, which are essential for antiporter activity. Thirty-five residues spanning the putative TM5 and adjacent loop regions were replaced by cysteines. Cysteines replacing Val-162, Ile-165, and Asp-172 were labeled with NEM, suggesting that these three residues are exposed to a hydrophilic cavity within the membrane. Other residues in the putative TM domain, including Asp-171, were not labeled. Inhibition of NEM labeling by the membrane impermeable reagent AMS suggests that Val-162 and Ile-165 are exposed to a water filled channel open to the cytoplasmic space, whereas Asp-172 is exposed to the periplasmic space. D171C and D172C mutants completely lost Na+/H+ and Li+/H+ antiporter activities, whereas other Cys replacements did not result in a significant loss of these activities. These results suggest that Asp-171 and Asp-172 and the surrounding residues of TM5 provide an essential structure for H+ binding and Na+ or Li+ exchange. A168C and Y183C showed markedly decreased antiporter activities at acidic pH, whereas their activities were higher at alkaline pH, suggesting that the conformation of TM5 also plays a crucial role in the HP NhaA-specific acidic pH antiporter activity.

Oligomerization of the Saccharomyces cerevisiae Na+/H+ antiporter Nha1p: implications for its antiporter activity.

The Na(+)/H(+) antiporter (Nha1p) from the budding yeast Saccharomyces cerevisiae plays an important role in intracellular pH and Na(+) homeostasis. Here, we show by co-precipitation of differently tagged Nha1p proteins expressed in the same cell that the yeast Nha1p l forms an oligomer. In vitro cross-linking experiments then revealed that Nha1p-FLAG is present in the membranes as a dimer. Differently tagged Nha1p proteins were also co-precipitated from sec18-1 mutant cells in which ER-to-Golgi traffic is blocked under non-permissive temperatures, suggesting that Nha1p may already dimerize in the ER membrane. When we over-expressed a mutant Nha1p with defective antiporter activity in cells that also express the wild-type Nha1p-EGFP fusion protein, we found impaired cell growth in highly saline conditions, even though the wild-type protein was appropriately expressed and localized correctly. Co-immunoprecipitation assays then showed the inactive Nha1p-FLAG mutant interacted with the wild-type Nha1p-EGFP protein. These results support the notion that Nha1p exists in membranes as a dimer and that the interaction of its monomers is important for its antiporter activity.

Characterization of the ion transport activity of the budding yeast Na+/H+ antiporter, Nha1p, using isolated secretory vesicles.

The Saccharomyces cerevisiae Nha1p, a plasma membrane protein belonging to the monovalent cation/proton antiporter family, plays a key role in the salt tolerance and pH regulation of cells. We examined the molecular function of Nha1p by using secretory vesicles isolated from a temperature sensitive secretory mutant, sec4-2, in vitro. The isolated secretory vesicles contained newly synthesized Nha1p en route to the plasma membrane and showed antiporter activity exchanging H+ for monovalent alkali metal cations. An amino acid substitution in Nha1p (D266N, Asp-266 to Asn) almost completely abolished the Na+/H+ but not K+/H+ antiport activity, confirming the validity of this assay system as well as the functional importance of Asp-266, especially for selectivity of substrate cations. Nha1p catalyzes transport of Na+ and K+ with similar affinity (12.7 mM and 12.4 mM), and with lower affinity for Rb+ and Li+. Nha1p activity is associated with a net charge movement across the membrane, transporting more protons per single sodium ion (i.e., electrogenic). This feature is similar to the bacterial Na+/H+ antiporters, whereas other known eukaryotic Na+/H+ antiporters are electroneutral. The ion selectivity and the stoichiometry suggest a unique physiological role of Nha1p which is distinct from that of other known Na+/H+ antiporters.

Four Na+/H+ exchanger isoforms are distributed to Golgi and post-Golgi compartments and are involved in organelle pH regulation.

Four isoforms of the Na+/H+ exchanger (NHE6-NHE9) are distributed to intracellular compartments in human cells. They are localized to Golgi and post-Golgi endocytic compartments as follows: mid- to trans-Golgi, NHE8; trans-Golgi network, NHE7; early recycling endosomes, NHE6; and late recycling endosomes, NHE9. No significant localization of these NHEs was observed in lysosomes. The distribution of these NHEs is not discrete in the cells, and there is partial overlap with other isoforms, suggesting that the intracellular localization of the NHEs is established by the balance of transport in and out of the post-Golgi compartments as the dynamic membrane trafficking. The overexpression of NHE isoforms increased the luminal pH of the compartments in which the protein resided from the mildly acidic pH to the cytosolic pH, suggesting that their in vivo function is to regulate the pH and monovalent cation concentration in these organelles. We propose that the specific NHE isoforms contribute to the maintenance of the unique acidic pH values of the Golgi and post-Golgi compartments in the cell.

A conserved domain in the tail region of the Saccharomyces cerevisiae Na+/H+ antiporter (Nha1p) plays important roles in localization and salinity-resistant cell-growth.

The Saccharomyces cerevisiae Na(+)/H(+) antiporter Nha1p has a two-domain structure consisting of an N-terminal integral membrane region and a C-terminal cytoplasmic region. We previously identified six distinct cytoplasmic domains (C1-C6) conserved among yeast species and here we performed detailed structure-function analysis of the C1 domain (16 residues). Deletion of the C1 domain causes extensive inhibition of cell-growth under high salinity conditions. Mutants with single residue deletions or various amino acid substitutions affecting the C1 domain were analyzed with respect to salinity-dependent growth and Nha1p localization. The C1 domain was found to consist of two subdomains: (i) The first three N-proximal residues, which in conjunction with the integral membrane region play a crucial role in the targeting of Nha1p to the cytoplasmic membrane, and (ii) the portion between Leu-439 and Thr-449, which is not required for localization, but in which four residues (Gly-440, Arg-441, His-442, and Ile-446) affect salinity-sensitive cell-growth by possibly influencing the antiporter activity. Based on the overall similarity of the two-domain structure of Nha1p to that of mammalian Na(+)/H(+) antiporters, the functional importance of domains proximal to the membrane region is discussed.

A novel membrane protein capable of binding the Na+/H+ antiporter (Nha1p) enhances the salinity-resistant cell growth of Saccharomyces cerevisiae.

The Na+/H+ antiporter Nha1p of Saccharomyces cerevisiae plays an important role in maintaining intracellular pH and Na+ homeostasis. Nha1p has a two-domain structure composed of integral membrane and hydrophilic tail regions. Overexpression of a peptide of approximately 40 residues (C1+C2 domains) that is localized in the juxtamembrane area of its cytoplasmic tail caused cell growth retardation in highly saline conditions, possibly by decreasing Na+/H+ antiporter activity. A multicopy suppressor gene of this growth retardation was identified from a yeast genome library. The clone encodes a novel membrane protein denoted as COS3 in the genome data base. Overexpression or deletion of COS3 increases or decreases salinity-resistant cell growth, respectively. However, in nha1Delta cells, overexpression of COS3 alone did not suppress the growth retardation. Cos3p and a hydrophilic portion of Cos3p interact with the C1+C2 peptide in vitro, and Cos3p is co-precipitated with Nha1p from yeast cell extracts. Cos3p-GFP mainly resides at the vacuole, but overexpression of Nha1p caused a portion of the Cos3p-GFP proteins to shift to the cytoplasmic membrane. These observations suggest that Cos3p is a novel membrane protein that can enhance salinity-resistant cell growth by interacting with the C1+C2 domain of Nha1p and thereby possibly activating the antiporter activity of this protein.

Structurally and functionally conserved domains in the diverse hydrophilic carboxy-terminal halves of various yeast and fungal Na+/H+ antiporters (Nha1p).

Genes encoding the Na(+)/H(+) antiporter (Nha1p) from Candida tropicalis (C.t.), Hansenula anomala (H.a.) (also named Pichia anomala), and Aspergillus nidulans (A.n.) were cloned, and the nucleotide sequences were determined. The deduced primary sequences revealed highly conserved hydrophobic regions and rather diverse hydrophilic regions. Among the seven known Nha1p sequences, Schizosaccharomyces pombe (S.p.) Nha1p is exceptional in lacking the hydrophilic region. Within the diverse hydrophilic regions, we found six conserved regions (C1-C6). Expression of C.t. Nha1p in Saccharomyces cerevisiae (S.c.) cells lacking NHA1 and ENA1 (Na(+)-ATPase) complemented the salinity-sensitive phenotype, suggesting that C.t. Nha1p is functionally related to S.c. Nha1p. Expression of various truncated forms of the C-terminal half of S.c. and C.t. Nha1p showed essentially the same phenotype for both species: deletion of the C4-C6 region caused cell growth to be more resistant to high salinity than the wild type, suggesting an inhibitory function of these domains on the antiporter activity. However, complete loss of C1-C6 caused a severe growth defect under conditions of high salinity, suggesting a defect in antiporter activity. The DeltaC2-C6 form of C.t. Nha1p, containing only C1, restored the retarded cell growth at high salinity more than the control vector alone, but to a value lower than the wild type. These results suggest an essential role for C1 and an activating role of the C2-C3 region in the functional expression of Nha1. High expression of the DeltaC2-C6 form of S.c. Nha1p was toxic for yeast cells, although low expression was not, suggesting that the overexpression of C1 is toxic. The results in this study suggest that the diverse hydrophilic region of yeast and fungal Nha1p has six conserved domains with conserved functions in terms of expression of Nha1p activity.