Determinants of Cation Permeation and Drug Sensitivity in Predicted Transmembrane Helix 9 and Adjoining Exofacial Re-entrant Loop 5 of Na+/H+ Exchanger NHE1

Mammalian Na⁺/H⁺ exchangers (NHEs) regulate numerous physiological processes and are involved in the pathogenesis of several diseases, including tissue ischemia and reperfusion injuries, cardiac hypertrophy and failure, and cancer progression. Hence, NHEs are being targeted for pharmaceutical-based clinical therapies, but pertinent information regarding the structural elements involved in cation translocation and drug binding remains incomplete. Molecular manipulations of the prototypical NHE1 isoform have implicated several predicted membrane-spanning (M) helices, most notably M4, M9, and M11, as important determinants of cation permeation and drug sensitivity. Here, we have used substituted-cysteine accessibility mutagenesis and thiol-modifying methanethiosulfonate (MTS) reagents to further probe the involvement of evolutionarily conserved sites within M9 (residues 342–363) and the adjacent exofacial re-entrant loop 5 between M9 and M10 (EL5; residues 364–415) of a cysteine-less variant of rat NHE1 on its kinetic and pharmacological properties. MTS treatment significantly reduced the activity of mutants containing substitutions within M9 (H353C, S355C, and G356C) and EL5 (G403C and S405C). In the absence of MTS, mutants S355C, G403C, and S405C showed modest to significant decreases in their apparent affinities for Na⁺_o and/or H⁺_i. In addition, mutations Y370C and E395C within EL5, whereas failing to confer sensitivity to MTS, nevertheless, reduced the affinity for Na⁺_o, but not for H⁺_i. The Y370C mutant also exhibited higher affinity for ethylisopropylamiloride, a competitive antagonist of Na⁺_o transport. Collectively, these results further implicate helix M9 and EL5 of NHE1 as important elements involved in cation transport and inhibitor sensitivity, which may inform rational drug design.     

Asymmetric organization of the pore region of the epithelial sodium channel

Epithelial sodium channels (ENaCs) are composed of three homologous subunits that have regions preceding the second transmembrane domain (also referred as pre-M2) that form part of the channel pore. To identify residues within this region of the beta-subunit that line the pore, we systematically mutated residues Gln(523)-Ile(536) to cysteine. Wild type and mutant mouse ENaCs were expressed in Xenopus oocytes, and a two-electrode voltage clamp was used to examine the properties of mutant channels. Cysteine substitutions of 9 of 13 residues significantly altered Li(+) to Na(+) current ratios, whereas only cysteine replacement of beta Gly(529) resulted in K(+)-permeable channels. Besides beta G525C, large increases in the inhibitory constant of amiloride were observed with mutations at beta Gly(529) and beta Ser(531) within the previously identified 3-residue tract that restricts K(+) permeation. Cysteine substitution preceding (beta Phe(524) and beta Gly(525)), within (beta Gly(530)) or following (beta Leu(533)) this 3-residue tract, resulted in enhanced current inhibition by external MTSEA. External MTSET partially blocked channels with cysteine substitutions at beta Gln(523), beta Phe(524), and beta Trp(527). MTSET did not inhibit alpha beta G525C gamma, although previous studies showed that channels with cysteine substitutions at the corresponding sites within the alpha- and gamma-subunits were blocked by MTSET. Our results, placed in context with previous observations, suggest that pore regions from the three ENaC subunits have an asymmetric organization.     

Glutamate 346 of human Na+-H+ exchanger NHE1 is crucial for modulating both the affinity for Na+ and the interaction with amiloride derivatives

A NHE1 variant that exhibits very high resistance to (3-methyl sulfonyl-4-piperidinobenzoyl) guanidine methane sulfonate (HOE694), a potent inhibitor of Na(+)-H(+) exchangers, was selected and characterized. Sequencing of the coding region corresponding to the N-terminal domain of this variant revealed the presence of only one mutation located within membrane-spanning segment 9 (M9). This base pair change replaces a glutamate (Glu) with an aspartate (Asp). We reproduced this amino acid change in wild-type NHE1 and found that this mutation alone is responsible for the huge decrease in sensitivity to the HOE694 compound and to ethylisopropylamiloride (EIPA). We found that the NHE1-Glu(346)Asp mutant was more than 2000-fold more resistant to HOE694 and up to 300-fold more resistant to EIPA than wild-type NHE1, with the size, rather than the charge, of the amino acid in position 346 having the greatest effect. Interestingly, its affinity for Na(+) was at least 4-fold lower than that of wild-type NHE1. Mutation of amino acids in the vicinity of Glu(346) did not change the sensitivity of mutated NHE1 proteins to inhibitors. We suggest there is a direct interaction of Glu(346) or involvement of Glu(346) in a coordination site with NHE inhibitors and with Na(+).     

Eight amino acids form the ATP recognition site of Na(+)/K(+)-ATPase

Point mutations of a part of the H(4)-H(5) loop (Leu(354)-Ile(604)) of Na(+)/K(+)-ATPase have been used to study the ATP and TNP-ATP binding affinities. Besides the previously reported amino acid residues Lys(480), Lys(501), Gly(502), and Cys(549), we have found four more amino acid residues, viz., Glu(446), Phe(475), Gln(482), and Phe(548), completing the ATP-binding pocket of Na(+)/K(+)-ATPase. Moreover, mutation of Arg(423) has also resulted in a large decrease in the extent of ATP binding. This residue, localized outside the binding pocket, seems to play a key role in supporting the proper structure and shape of the binding site, probably due to formation of a hydrogen bond with Glu(472). On the other hand, only some minor effects were caused by mutations of Ile(417), Asn(422), Ser(445), and Glu(505).     

Designing of substrates and inhibitors of bovine alpha-chymotrypsin with synthetic phenylalanine analogues in position P(1)

The primary specificity residue of a substrate or an inhibitor, called the P(1) residue, is responsible for the proper recognition by the cognate enzyme. This residue enters the S(1) pocket of the enzyme and establishes contacts (up to 50%) inside the proteinase substrate cavity, strongly affecting its specificity. To analyze the influence on bovine alpha-chymotrypsin substrate activity, aromatic non-proteinogenic amino acid residues in position P(1) with the sequence Ac-Phe-Ala-Thr-X-Anb(5,2)-NH(2) were introduced: L-pyridyl alanine (Pal), 4-nitrophenylalanine - Phe(p-NO(2)), 4-aminophenylalanine - Phe(p-NH(2)), 4-carboxyphenylalanine Phe(p-COOH), 4-guanidine phenylalanine - Phe(p-guanidine), 4-methyloxycarbonyl-phenylalanine - Phe(p-COOMe), 4-cyanophenylalanine - Phe(p-CN), Phe, Tyr. The effect of the additional substituent at the phenyl ring of the Phe residue was investigated. All peptides contained an amide of 5-amino-2-nitrobenzoic acid, which served as a chromophore. Kinetic parameters (k(cat), K(M) and k(cat)/K(M)) of the peptides synthesized with bovine alpha-chymotrypsin were determined. The highest value of the specificity constant k(cat)/K(M), reaching 6.0 x 10(5) [M(-1)xs(-1)], was obtained for Ac-Phe-Ala-Thr-Phe(p-NO(2))-Anb(5,2)-NH(2). The replacement of the acetyl group with benzyloxycarbonyl moiety yielded a substrate with the value of k(cat) more than three times higher. Peptide aldehydes were synthesized with selected residues (Phe, Pal, Tyr, Phe(p-NO(2)) in position P(1) and potent chymotrypsin inhibitors were obtained. The dissociation constant (K(i)) with the experimental enzyme determined for the most active peptide, Tos-Phe-Ala-Thr-Phe(p-NO(2))-CHO, amounted to 1.12 x 10(-8) M.     

Gastrointestinal distribution and kinetic characterization of the sodium-hydrogen exchanger isoform 8 (NHE8).

NHE8 is a newly identified NHE isoform expressed in rat intestine. To date, the kinetic characteristics and the intestinal segmental distribution of this NHE isoform have not been studied. This current work was performed to determine the gene expression pattern of the NHE8 transporter along the gastrointestinal tract, as well as its affinity for Na(+), H(+), and sensitivity to known NHE inhibitors HOE694 and S3226. NHE8 was differentially expressed along the GI tract. Higher NHE8 expression was seen in stomach, duodenum, and ascending colon in human, while higher NHE8 expression was seen in jejunum, ileum and colon in adult mouse. Moreover, the expression level of NHE8 is much higher in the stomach and jejunum in young mice compared with adult mice. To evaluate the functional characterictics of NHE8, the pH indicator SNARF-4 was used to monitor the rate of intra-cellular pH (pH(i)) recovery after an NH(4)Cl induced acid load in NHE8 cDNA transfected PS120 cells. The NHE8 cDNA transfected cells exhibited a sodium-dependent proton exchanger activity having a Km for pH(i) of approximately pH 6.5, and a Km for sodium of approximately 23 mM. Low concentration of HOE694 (1 microM) had no effect on NHE8 activity, while high concentration (10 microM) significantly reduced NHE8 activity. In the presence of 80 microM S3226, the NHE8 activity was also inhibited significantly. In conclusion, our work suggests that NHE8 is expressed along the gastrointestinal tract and NHE8 is a functional Na(+)/H(+) exchanger with kinetic characteristics that differ from other apically expressed NHE isoforms.     

Proline-rich motifs of the Na+/H+ exchanger 2 isoform. Binding of Src homology domain 3 and role in apical targeting in epithelia

The NHE2 isoform of the Na+/H+ exchanger (NHE) displays two proline-rich sequences in its C-terminal region that resemble SH3 (Src homology 3)-binding domains. We investigated whether these regions (743PPSVTPAP750, termed Pro-1, and 786VPPKPPP792, termed Pro-2) can bind to SH3 domains and whether they are essential for NHE2 function and targeting. A fusion protein containing the Pro-1 region showed promiscuous binding to SH3 domains of several proteins in vitro, whereas a Pro-2 fusion bound preferentially to domains derived from kinases. In contrast, cytoplasmic regions of NHE1, NHE3, or NHE4 failed to interact. When expressed in antiporter-deficient cells, truncated NHE2 lacking both Pro-rich regions catalyzed Na+/H+ exchange, retained sensitivity to intracellular ATP, and was activated by hyperosmolarity, resembling full-length NHE2. The role of the Pro-rich regions in subcellular targeting was examined by transfection of epitope-tagged forms of NHE2 in porcine renal epithelial LLC-PK1 cells. Both full-length and Pro-2-truncated NHE2 localized almost exclusively to the apical membrane. By contrast, a mutant devoid of both Pro-1 and Pro-2 was preferentially sorted to the basolateral surface but also accumulated intracellularly. These observations indicate that the region encompassing Pro-1 is essential for appropriate subcellular targeting of NHE2.     

NHE1 inhibition by amiloride- and benzoylguanidine-type compounds. Inhibitor binding loci deduced from chimeras of NHE1 homologues with endogenous differences in inhibitor sensitivity

The interaction of the ubiquitous Na(+)/H(+) exchanger, NHE1, with its commonly used inhibitors, amiloride- and benzoylguanidine (Hoechst type inhibitor (HOE))-type compounds, is incompletely understood. We previously cloned NHE1 from Amphiuma tridactylum (AtNHE1) and Pleuronectes americanus (PaNHE1). Although highly homologous to the amiloride- and HOE-sensitive human NHE1 (hNHE1), AtNHE1 is insensitive to HOE-type and PaNHE1 to both amiloride- and HOE-type compounds. Here we generated chimeras to "knock in" amiloride and HOE sensitivity to PaNHE1, and we thereby identified several NHE1 regions involved in inhibitor interaction. The markedly different inhibitor sensitivities of hNHE1, AtNHE1, and PaNHE1 could not be accounted for by differences in transmembrane (TM) region 9. Replacing TM10 through the C-terminal tail of PaNHE1 with the corresponding region of AtNHE1 partially restored sensitivity to amiloride and the related compound 5'-(N-ethyl-N-isopropyl)amiloride (EIPA) but not to HOE694. This effect was not due to the tail region, but it was dependent on TM10-11, because replacing only this region with that of AtNHE1 also partially restored amiloride and EIPA but not HOE sensitivity. The converse mutant (TM10-11 of AtNHE1 replaced with those of PaNHE1) exhibited even higher amiloride and EIPA sensitivity and was also HOE-sensitive. Replacing an LFFFY motif in TM region 4 of PaNHE1 with the corresponding residues of hNHE1 (VFFLF) or AtNHE1 (TFFLF) greatly increased sensitivity to both amiloride- and HOE-type compounds, despite the fact that AtNHE1 is HOE694-insensitive. Gain of amiloride sensitivity appeared to correlate with increased Na(+)/H(+) exchange rates. It is concluded that regions within TM4 and TM10-11 contribute to amiloride and HOE sensitivity, with both regions imparting partial inhibitor sensitivity to NHE1.     

The differential amino acid requirement within osteopontin in α4 and α9 integrin-mediated cell binding and migration

Osteopontin (OPN) contains at least two major integrin recognition domains, Arg159-Gly-Asp161 (RGD) and Ser162-Val-Val-Tyr-Gly-Leu-Arg168 (SVVYGLR), recognized by αvβ3 and α5β1 and α4 and α9 integrins, respectively. OPN is specifically cleaved by thrombin and matrix metalloproteinase (MMP)-3 or MMP-7 at a position of Arg168/Ser169 (R/S) and Gly166/Leu167 (G/L), respectively. We in this study examined the requirement of residues within SVVYGLR for the α4 and α9 integrin recognition and how MMP-cleavage influences the integrin recognition. The residues, Val164, Tyr165, and Leu167 are critical for α4 and α9 integrin recognition in both cell adhesion and cell migration. The residue Arg168 is additionally required for α9 integrin recognition in cell adhesion and this explains why α9 integrin binds to only thrombin cleaved form of OPN. α4 integrin is able to bind to SVVYG (MMP-cleaved form of RAA OPN-N half), while α9 integrin is not, supporting the above notion that Arg168 is additionally required for α9 integrin-mediated cell adhesion. The residue Val163 is important for α4, but not for α9 integrin recognition in cell migration. Importantly, we found that the replacement of Arg168 by Ala (R168A mutant) induces the augmentation of cell migration via α4 and α9 integrins.     

Mutational analysis of the intramembranous H10 loop of yeast Nhx1 reveals a critical role in ion homoeostasis and vesicle trafficking

Yeast Nhx1 [Na+(K+)/H+ exchanger 1] is an intracellular Na+(K+)/H+ exchanger, localizing to the late endosome where it is important for ion homoeostasis and vesicle trafficking. Phylogenetic analysis of NHE (Na+/H+ exchanger) sequences has identified orthologous proteins, including HsNHE6 (human NHE6), HsNHE7 and HsNHE9 of unknown physiological role. These appear distinct from well-studied mammalian plasma membrane isoforms (NHE1-NHE5). To explore the differences between plasma membrane and intracellular NHEs and understand the link between ion homoeostasis and vesicle trafficking, we examined the consequence of replacing residues in the intramembranous H10 loop of Nhx1 between transmembrane segments 9 and 10. The critical role for the carboxy group of Glu355 in ion transport is consistent with the invariance of this residue in all NHEs. Surprisingly, residues specifically conserved in the intracellular isoforms (such as Phe357 and Tyr361) could not be replaced with closely similar residues (leucine and phenylalanine) found in the plasma membrane isoforms without loss of function, revealing unexpected side chain specificity. The trafficking phenotypes of all Nhx1 mutants, including hygromycin-sensitivity and missorting of carboxypeptidase Y, were found to directly correlate with pH homoeostasis defects and could be proportionately corrected by titration with weak base. The present study demonstrates the importance of the H10 loop of the NHE family, highlights the differences between plasma membrane and intracellular isoforms and shows that trafficking defects are tightly coupled with pH homoeostasis.     

The intracellular distal tail of the Na+/H+ exchanger NHE1 is intrinsically disordered: implications for NHE1 trafficking

Intrinsic disorder is important for protein regulation, yet its role in regulation of ion transport proteins is essentially uninvestigated. The ubiquitous plasma membrane carrier protein Na(+)/H(+) Exchanger isoform 1 (NHE1) plays pivotal roles in cellular pH and volume homeostasis, and its dysfunction is implicated in several clinically important diseases. This study shows, for the first time for any carrier protein, that the distal part of the C-terminal intracellular tail (the cdt, residues V686-Q815) from human (h) NHE1 is intrinsically disordered. Further, we experimentally demonstrated the presence of a similar region of intrinsic disorder (ID) in NHE1 from the teleost fish Pleuronectes americanus (paNHE1), and bioinformatic analysis suggested ID to be conserved in the NHE1 family. The sequential variation in structure propensity as determined by NMR, but not the amplitude, was largely conserved between the h- and paNHE1cdt. This suggests that both proteins contain molecular recognition features (MoRFs), i.e., local, transiently formed structures within an ID region. The functional relevance of the most conserved MoRF was investigated by introducing a point mutation that significantly disrupted the putative binding feature. When this mutant NHE1 was expressed in full length NHE1 in AP1 cells, it exhibited impaired trafficking to the plasma membrane. This study demonstrated that the distal regulatory domain of NHE1 is intrinsically disordered yet contains conserved regions of transient structure. We suggest that normal NHE1 function depends on a protein recognition element within the ID region that may be linked to NHE1 trafficking via an acidic ER export motif.     

Mitogen-activated protein kinase-dependent activation of the Na+/H+ exchanger is mediated through phosphorylation of amino acids Ser770 and Ser771

We investigated regulation of the type 1 isoform of the Na(+)/H(+) exchanger by phosphorylation. Four specific groups of serine and threonine residues in the regulatory carboxyl-terminal tail were mutated to alanine residues: group 1, S693A; group 2, T718A and S723A/S726A/S729A; group 3, S766A/S770A/S771A; and group 4, T779A and S785A. The proteins were expressed in Na(+)/H(+) exchanger-deficient cells, and the activity was characterized. All of the mutants had proper expression, localization, and normal basal activity relative to wild type NHE1. Sustained intracellular acidosis was used to activate NHE1 via an ERK-dependent pathway that could be blocked with the MEK inhibitor U0126. Immunoprecipitation of (32)P-labeled Na(+)/H(+) exchanger from intact cells showed that sustained intracellular acidosis increased Na(+)/H(+) exchanger phosphorylation in vivo. This was blocked by U0126. The Na(+)/H(+) exchanger activity of mutants 1 and 2 was stimulated similar to wild type Na(+)/H(+) exchanger. Mutant 4 showed a partially reduced level of activation. However, mutant 3 was not stimulated by sustained intracellular acidosis, and loss of stimulation of activity correlated to a loss of sustained acidosis-mediated phosphorylation in vivo. Mutation of the individual amino acids within mutant 3, Ser(766), Ser(770), and Ser(771), showed that Ser(770) and Ser(771) are responsible for mediating increases in NHE1 activity through sustained acidosis. Both intact Ser(770) and Ser(771) were required for sustained acidosis-mediated activation of NHE1. Our results suggest that amino acids Ser(770) and Ser(771) mediate ERK-dependent activation of the Na(+)/H(+) exchanger in vivo.     

Mutational analysis of potential pore-lining amino acids in TM IV of the Na(+)/H(+) exchanger

The Na(+)/H(+) exchanger isoform 1 (NHE1) is an integral membrane protein that regulates intracellular pH by extruding an intracellular H(+) in exchange for one extracellular Na(+). In this study we examined the effect of site-specific mutagenesis on the pore-lining amino acid Phe161 and effects of mutagenesis on the charged amino acids Asp159 and Asp172. There was no absolute requirement for a carboxyl side chain at amino acid Asp159 or Asp172. Mutation of Asp159 to Asn or Gln maintained or increased the activity of the protein. Similarly, for Asp172, substitution with a Gln residue maintained activity of the protein, even though substitution with an Asn residue was inhibitory. The Asp172Glu mutant possessed normal activity after correction for its aberrant expression and surface targeting. Replacement of Phe161 with a Leu demonstrated that it was not irreplaceable in NHE1 function. However, the mutation Phe161lys inhibited NHE1 function, while the Phe161Ala mutation caused altered NHE1 targeting and expression levels. Our results show that these three amino acids, while being important in NHE1 function, are not irreplaceable. This study demonstrates that multiple substitutions at a single amino acid residue may be necessary to get a clearer picture membrane protein function.     

Kinetic and pharmacological properties of human brain Na(+)/H(+) exchanger isoform 5 stably expressed in Chinese hamster ovary cells

The recently cloned Na(+)/H(+) exchanger isoform 5 (NHE5) is expressed predominantly in brain, yet little is known about its functional properties. To facilitate its characterization, a full-length cDNA encoding human NHE5 was stably transfected into NHE-deficient Chinese hamster ovary AP-1 cells. Pharmacological analyses revealed that H(+)(i)-activated (22)Na(+) influx mediated by NHE5 was inhibited by several classes of drugs (amiloride compounds, 3-methylsulfonyl-4-piperidinobenzoyl guanidine methanesulfonate, cimetidine, and harmaline) at half-maximal concentrations that were intermediate to those determined for the high affinity NHE1 and the low affinity NHE3 isoforms, but closer to the latter. Kinetic analyses showed that the extracellular Na(+) dependence of NHE5 activity followed a simple hyperbolic relationship with an apparent affinity constant (K(Na)) of 18.6 +/- 1.6 mM. By contrast to other NHE isoforms, NHE5 also exhibited a first-order dependence on the intracellular H(+) concentration, achieving half-maximal activation at pH 6.43 +/- 0.08. Extracellular monovalent cations, such as H(+) and Li(+), but not K(+), acted as effective competitive inhibitors of (22)Na(+) influx by NHE5. In addition, the transport activity of NHE5 was highly dependent on cellular ATP levels. Overall, these functional features distinguish NHE5 from other family members and closely resemble those of an amiloride-resistant NHE isoform identified in hippocampal neurons.     

Mutations of Arg440 and Gly455/Gly456 oppositely change pH sensing of Na+/H+ exchanger 1

To identify important amino acid residues involved in intracellular pH (pH(i)) sensing of Na(+)/H(+) exchanger 1, we produced single-residue substitution mutants in the region of the exchanger encompassing the putative 11th transmembrane segment (TM11) and its adjacent intracellular (intracellular loop (IL) 5) and extracellular loops (extracellular loop 6). Substitution of Arg(440) in IL5 with other residues except positively charged Lys caused a large shift in pH(i) dependence of (22)Na(+) uptake to an acidic side, whereas substitution of Gly(455) or Gly(456) within the highly conserved glycine-rich sequence of TM11 shifted pH(i) dependence to an alkaline side. The observed alkaline shift was larger with substitution of Gly(455) with residues with increasing sizes, suggesting the involvement of the steric effect. Interestingly, mutation of Arg(440) (R440D) abolished the ATP depletion-induced acidic shift in pH(i) dependence of (22)Na(+) uptake as well as the cytoplasmic alkalinization induced by various extracellular stimuli, whereas with that of Gly(455) (G455Q) these functions were preserved. These mutant exchangers did not alter apparent affinities for extracellular transport substrates Na(+) and H(+) and the inhibitor 5-(N-ethyl-N-isopropyl)amiloride. These results suggest that positive charge at Arg(440) is required for normal pH(i) sensing, whereas mutation-induced perturbation of the TM11 structure may be involved in the effects of Gly mutations. Thus, both Arg(440) in IL5 and Gly residues in the conserved segment of TM11 appear to constitute important elements for proper functioning of the putative "pH(i) sensor" of Na(+)/H(+) exchanger 1.     

Structural and functional analysis of extracellular loop 4 of the Nhe1 isoform of the Na(+)/H(+) exchanger

The mammalian Na(+)/H(+) exchanger isoform 1 (NHE1) is a ubiquitously expressed plasma membrane protein. It regulates intracellular pH by removing a single intracellular H(+) in exchange for one extracellular Na(+). The membrane domain of NHE1 comprises the 500 N-terminal amino acids and is made of 12 transmembrane segments. The extracellular loops of the transmembrane segments are thought to be involved in cation coordination and inhibitor sensitivity. We have characterized the structure and function of amino acids 278-291 representing extracellular loop 4. When mutated to Cys, residues F277, F280, N282 and E284 of EL4 were sensitive to mutation and reaction with MTSET inhibiting NHE1 activity. In addition they were found to be accessible to extracellular applied MTSET. A peptide of the amino acids of EL4 was mostly unstructured suggesting that it does not provide a rigid structured link between TM VII and TM VIII. Our results suggest that EL4 makes an extension upward from TM VII to make up part of the mouth of the NHE1 protein and is involved in cation selectivity or coordination. EL4 provides a flexible link to TM VIII which may either allow movement of TM VII or allow TM VIII to not be adjacent to TM VII.     

Increased tolerance to oxygen and glucose deprivation in astrocytes from Na(+)/H(+) exchanger isoform 1 null mice

The ubiquitously expressed Na(+)/H(+) exchanger isoform 1 (NHE1) functions as a major intracellular pH (pH(i)) regulatory mechanism in many cell types, and in some tissues its activity may contribute to ischemic injury. In the present study, cortical astrocyte cultures from wild-type (NHE1(+/+)) and NHE1-deficient (NHE1(-/-)) mice were used to investigate the role of NHE1 in pH(i) recovery and ischemic injury in astrocytes. In the absence of HCO(3)(-), the mean resting pH(i) levels were 6.86 +/- 0.03 in NHE1(+/+) astrocytes and 6.53 +/- 0.04 in NHE1(-/-) astrocytes. Removal of extracellular Na(+) or blocking of NHE1 activity by the potent NHE1 inhibitor HOE-642 significantly reduced the resting level of pH(i) in NHE1(+/+) astrocytes. NHE1(+/+) astrocytes exhibited a rapid pH(i) recovery (0.33 +/- 0.08 pH unit/min) after NH(4)Cl prepulse acid load. The pH(i) recovery in NHE1(+/+) astrocytes was reversibly inhibited by HOE-642 or removal of extracellular Na(+). In NHE1(-/-) astrocytes, the pH(i) recovery after acidification was impaired and not affected by either Na(+)-free conditions or HOE-642. Furthermore, 2 h of oxygen and glucose deprivation (OGD) led to an approximately 80% increase in pH(i) recovery rate in NHE1(+/+) astrocytes. OGD induced a 5-fold rise in intracellular [Na(+)] and 26% swelling in NHE1(+/+) astrocytes. HOE-642 or genetic ablation of NHE1 significantly reduced the Na(+) rise and swelling after OGD. These results suggest that NHE1 is the major pH(i) regulatory mechanism in cortical astrocytes and that ablation of NHE1 in astrocytes attenuates ischemia-induced disruption of ionic regulation and swelling.     

Functional analysis of acidic amino acids in the cytosolic tail of the Na+/H+ exchanger

The mammalian Na(+)/H(+) exchanger is a membrane protein with a C-terminal regulatory cytosolic domain and an N-terminal membrane domain. Na(+)/H(+) exchanger isoform 1 (NHE1) possesses a conserved amino acid sequence of seven consecutive acidic residues in the distal region of the cytosolic tail. We examined the structural and functional role of this acidic sequence. In human NHE1, varying mutations of the sequence (753)EEDEDDD(759) resulted in defective NHE1 activity. Mutation of the core acid sequence, (755)DED(757), or of the entire sequence caused a decrease in the activity of NHE1 in response to acute acid load. This was not due to changes in Na(+) affinity but rather due to decreased maximum velocity of the protein and delayed activation. Mutation of the target sequence did not affect the ability of the cytoplasmic domain to bind carbonic anhydrase II or tescalcin but did affect calmodulin binding. Mutation of the acidic domain also caused altered sensitivity to trypsin and changes in size of the protein in gel-filtration chromatography and sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Our results demonstrate that the acidic sequence is critical in maintaining proper conformation of the cytosolic domain, calmodulin binding, and in maintenance of Na(+)/H(+) exchanger activity.     

Characterization of modeled inhibitory binding sites on isoform one of the Na+/H+ exchanger

Mammalian Na⁺/H⁺ exchanger isoform one (NHE1) is a plasma membrane protein responsible for pH regulation in mammalian cells. Excess activity of the protein promotes heart disease and is a trigger of metastasis in cancer. Inhibitors of the protein exist but problems in specificity have delayed their clinical application. Here we examined amino acids involved in two modeled inhibitor binding sites (A, B) in human NHE1. Twelve mutations (Asp159, Phe348, Ser351, Tyr381, Phe413, Leu465, Gly466, Tyr467, Leu468, His473, Met476, Leu481) were made and characterized. Mutants S351A, F413A, Y467A, L468A, M476A and L481A had 40–70% of wild type expression levels, while G466A and H473A expressed 22% ~ 30% of the wild type levels. Most mutants, were targeted to the cell surface at levels similar to wild type NHE1, approximately 50–70%, except for F413A and G466A, which had very low surface targeting. Most of the mutants had measurable activity except for D159A, F413A and G466A. Resistance to inhibition by EMD87580 was elevated in mutants F438A, L465A and L468A and reduced in mutants S351A, Y381A, H473A, M476A and L481A. All mutants with large alterations in inhibitory properties showed reduced Na⁺ affinity. The greatest changes in activity and inhibitor sensitivity were in mutants present in binding site B which is more closely associated with TM4 and C terminal of extracellular loop 5, and is situated between the putative scaffolding domain and transport domain. The results help define the inhibitor binding domain of the NHE1 protein and identify new amino acids involved in inhibitor binding.     

Calcineurin B homologous protein 3 promotes the biosynthetic maturation, cell surface stability, and optimal transport of the Na+/H+ exchanger NHE1 isoform

Calcineurin B homologous protein (CHP) 1 and 2 are Ca(2+)-binding proteins that modulate several cellular processes, including cytoplasmic pH by positively regulating plasma membrane-type Na(+)/H(+) exchangers (NHEs). Recently another CHP-related protein, termed tescalcin or CHP3, was also shown to interact with the ubiquitous NHE1 isoform, but seemingly suppressed its activity. However, the precise physical and functional nature of this association was not examined in detail. In this study, biochemical and cellular studies were undertaken to further delineate this relationship. Glutathione S-transferase-NHE1 fusion protein pulldown assays revealed that full-length CHP3 binds directly to the proximal juxtamembrane C-terminal region (amino acids 505-571) of rat NHE1 in the same region that binds CHP1 and CHP2. The interaction was further validated by coimmunoprecipitation and coimmunolocalization experiments using full-length CHP3 and wild-type NHE1 in transfected Chinese hamster ovary AP-1 cells. Simultaneous mutation of four hydrophobic residues within this region ((530)FLDHLL(535)) to either Ala, Gln, or Arg (FL-A, FL-Q, or FL-R) abrogated this interaction both in vitro and in intact cells. The NHE1 mutants were sorted properly to the cell surface but showed markedly reduced (FL-A) or minimal (FL-R and FL-Q) activity. Interestingly, and contrary to an earlier finding, ectopic coexpression of CHP3 up-regulated the cell surface activity of wild-type NHE1. This stimulation was not observed with the CHP3 binding-defective mutants. Mechanistically, overexpression of CHP3 did not alter the H(+) sensitivity of wild-type NHE1 but rather promoted its biosynthetic maturation and half-life at the cell surface, thereby increasing the steady-state abundance of functional NHE1 protein.