Prevention of the Disrupted Enamel Phenotype in Slc4a4-Null Mice Using Explant Organ Culture Maintained in a Living Host Kidney Capsule

Slc4a4-null mice are a model of proximal renal tubular acidosis (pRTA). Slc4a4 encodes the electrogenic sodium base transporter NBCe1 that is involved in transcellular base transport and pH regulation during amelogenesis. Patients with mutations in the SLC4A4 gene and Slc4a4-null mice present with dysplastic enamel, amongst other pathologies. Loss of NBCe1 function leads to local abnormalities in enamel matrix pH regulation. Loss of NBCe1 function also results in systemic acidemic blood pH. Whether local changes in enamel pH and/or a decrease in systemic pH are the cause of the abnormal enamel phenotype is currently unknown. In the present study we addressed this question by explanting fetal wild-type and Slc4a4-null mandibles into healthy host kidney capsules to study enamel formation in the absence of systemic acidemia. Mandibular E11.5 explants from NBCe1^−/− mice, maintained in host kidney capsules for 70 days, resulted in teeth with enamel and dentin with morphological and mineralization properties similar to cultured NBCe1^+/+ mandibles grown under identical conditions. Ameloblasts express a number of proteins involved in dynamic changes in H⁺/base transport during amelogenesis. Despite the capacity of ameloblasts to dynamically modulate the local pH of the enamel matrix, at least in the NBCe1^−/− mice, the systemic pH also appears to contribute to the enamel phenotype. Extrapolating these data to humans, our findings suggest that in patients with NBCe1 mutations, correction of the systemic metabolic acidosis at a sufficiently early time point may lead to amelioration of enamel abnormalities.     

Mutation of Aspartate 555 of the Sodium/Bicarbonate Transporter SLC4A4/NBCe1 Induces Chloride Transport

To understand the mechanism for ion transport through the sodium/bicarbonate transporter SLC4A4 (NBCe1), we examined amino acid residues, within transmembrane domains, that are conserved among electrogenic Na/HCO₃ transporters but are substituted with residues at the corresponding site of all electroneutral Na/HCO₃ transporters. Point mutants were constructed and expressed in Xenopus oocytes to assess function using two-electrode voltage clamp. Among the mutants, D555E (charge-conserved substitution of the aspartate at position 555 with a glutamate) produced decreasing HCO₃⁻ currents at more positive membrane voltages. Immunohistochemistry showed D555E protein expression in oocyte membranes. D555E induced Na/HCO₃-dependent pH recovery from a CO₂-induced acidification. Current-voltage relationships revealed that D555E produced an outwardly rectifying current in the nominally CO₂/HCO₃⁻-free solution that was abolished by Cl⁻ removal from the bath. In the presence of CO₂/HCO₃⁻, however, the outward current produced by D555E decreased only slightly after Cl⁻ removal. Starting from a Cl⁻-free condition, D555E produced dose-dependent outward currents in response to a series of chloride additions. The D555E-mediated chloride current decreased by 70% in the presence of CO₂/HCO₃⁻. The substitution of Asp⁵⁵⁵ with an asparagine also produced a Cl⁻ current. Anion selectivity experiments revealed that D555E was broadly permissive to other anions including NO₃⁻. Fluorescence measurements of chloride transport were done with human embryonic kidney HEK 293 cells expressing NBCe1 and D555E. A marked increase in chloride transport was detected in cells expressing D555E. We conclude that Asp⁵⁵⁵ plays a role in HCO₃⁻ selectivity.The electrogenic Na/HCO₃ cotransporter NBCe1 (SLC4A4) is one of the SLC4A gene family members transporting HCO₃⁻ across the plasma membrane (1–3). NBCe1 plays a role in transepithelial HCO₃⁻ movement and pH_i regulation in many tissues (4–6). NBCe1 is responsible for HCO₃⁻ reabsorption in the proximal tubules of the kidney (7). The proximal tubule cells reclaim HCO₃⁻ from the lumen through a series of reactions involving titration of HCO₃⁻ by H⁺ secretion via the apical Na/H exchanger, production of CO₂, and regeneration of HCO₃⁻ and H⁺ in the tubule cells. HCO₃⁻ then moves to the interstitium via the basolateral NBCe1. The essential feature driving this basolateral Na⁺/HCO₃⁻ exit is the stoichiometry of 1:3 Na⁺:HCO₃⁻, which makes the equilibrium potential for NBCe1 more positive than the resting membrane potential of the proximal tubule cells (8). The stoichiometry of 1Na⁺:1HCO₃⁻ or 1Na⁺:2HCO₃⁻ causes both ions to move into cells in other tissues such as pancreas, brain, and cardiovascular tissues (9, 10).Despite the importance of NBCe1 for basolateral HCO₃⁻ reabsorption in the proximal tubules, the mechanism of electrogenic Na/HCO₃ transport via the transporter is not well understood. Ion movement depends on loading ions at their translocation or binding sites that likely reside within the membrane field at some distance from the bath solution (11). This implies that the transmembrane domains (TMs)2 of NBCe1 and amino acid residues within TMs play critical roles in ion transport.Sequence analysis of different SLC4A proteins shows similar hydropathy plots, predicting that these proteins share structural elements of transport function (12). Such similarities have facilitated structure/function studies to define molecular domains or motifs responsible for conferring Na/HCO₃ transport of NBCe1. Abuladze et al. (13) performed a large scale mutagenesis on acidic and basic amino acids in non-TMs and found many residues affecting Na⁺-dependent base flux. McAlear et al. (14) identified amino acids in TM8 involving ion translocation. By a systematic approach of chimeric transporters between NBCe1 and the electroneutral Na/HCO₃ cotransporter NBCn1 (SLC4A7) (15), we and our colleagues (16) demonstrated that electrogenic Na/HCO₃ transport of NBCe1 requires interactions between the regions TM1–5 and TM6–13 of the protein. Zhu et al. (17) recently proposed TM1 as a domain lining the ion translocation pathway. On the other hand, Chang et al. (18) reported that the cytoplasmic N-terminal domain might contribute to HCO₃⁻ permeation.In the present study, we searched amino acid residues that are highly conserved among electrogenic Na/HCO₃ transporters but not among electroneutral Na/HCO₃ transporters and examined their role in electrogenic Na/HCO₃ transport. Nine candidate residues in human renal NBCe1-A (5, 19) were selected and mutated by replacement with the amino acids at the corresponding sites of NBCn1. Mutant transporters were expressed in Xenopus oocytes and assessed via two-electrode voltage clamp. Our data show that Asp⁵⁵⁵ of NBCe1 plays an important role in HCO₃⁻ selectivity.     

IRBIT: A regulator of ion channels and ion transporters

IRBIT (also called AHCYL1) was originally identified as a binding protein of the intracellular Ca^2 + channel inositol 1,4,5-trisphosphate (IP₃) receptor and functions as an inhibitory regulator of this receptor. Unexpectedly, many functions have subsequently been identified for IRBIT including the activation of multiple ion channels and ion transporters, such as the Na⁺/HCO₃⁻ co-transporter NBCe1-B, the Na⁺/H⁺ exchanger NHE3, the Cl⁻ channel cystic fibrosis transmembrane conductance regulator (CFTR), and the Cl⁻/HCO₃⁻ exchanger Slc26a6. The characteristic serine-rich region in IRBIT plays a critical role in the functions of this protein. In this review, we describe the evolution, domain structure, expression pattern, and physiological roles of IRBIT and discuss the potential molecular mechanisms underlying the coordinated regulation of these diverse ion channels/transporters through IRBIT. This article is part of a Special Issue entitled: Calcium signaling in health and disease. Guest Editors: Geert Bultynck, Jacques Haiech, Claus W. Heizmann, Joachim Krebs, and Marc Moreau.     

AHCYL2 (long-IRBIT) as a potential regulator of the electrogenic Na-HCO3 cotransporter NBCe1-B

Although AHCYL2 (long-IRBIT) is highly homologous to IRBIT, which regulates ion-transporting proteins including the electrogenic Na⁺-HCO₃⁻ cotransporter NBCe1-B, its functions are poorly understood. Here, we found that AHCYL2 interacts with NBCe1-B in bovine parotid acinar cells using yeast two-hybrid, immunofluorescence confocal microscopy and co-immunoprecipitation analyses. Whole-cell patch-clamp experiments revealed that co-expression of AHCYL2 reduces the apparent affinity for intracellular Mg²⁺ in inhibition of NBCe1-B currents specifically in a HCO₃⁻-deficient cellular condition. Our data unveil AHCYL2 as a potential regulator of NBCe1-B in mammalian cells. We propose that cytosolic ionic condition appropriate for AHCYL2 to function might be different from IRBIT.     

Effect of Prediabetes on Membrane Bicarbonate Transporters in Testis and Epididymis

The formation of competent spermatozoa is a complex event that depends on the establishment of adequate environments throughout the male reproductive tract. This includes the control of bicarbonate (HCO₃ ^?) concentration, which plays an essential role in the maintenance of extracellular and intracellular pH (pH_i) values. Diabetes mellitus alters pH_i regulation in mammalian cells, mainly by altering the activity of ion transporters, particularly HCO₃ ^?-dependent mechanisms. Yet, little is known about the effects of this pathology and its prodromal stage, prediabetes, on the membrane transport mechanisms of male reproductive tract cells. Herein, we analyzed protein and mRNA levels of the most relevant HCO₃ ^? transporters of the SLC4 family [anion exchanger 2 (AE2), Na⁺-driven Cl^?/HCO₃ ^? exchanger (NDCBE), electrogenic Na⁺/HCO₃ ^? cotransporter 1 (NBCe1), electroneutral Na⁺/HCO₃ ^? cotransporter 1 (NBCn1)] in the testis and epididymis of a prediabetic animal model. Firstly, we identified the HCO₃ ^? transporters of the SLC4 family, in both testicular and epididymal tissue. Secondly, although no alterations were detected in protein expression, mRNA levels of NBCe1, NBCn1 and NDCBE were significantly increased in the testis of prediabetic rats. On the other hand, in the epididymis, prediabetes caused an increase of AE2 and a decrease of NDCBE protein levels. These alterations may be translated into changes of HCO₃ ^? transepithelial epididymal fluxes in vivo, which may represent a threat for sperm survival. Moreover, these results provide evidence of the molecular mechanism that may be responsible for the significant increase in abnormal sperm morphology already reported in prediabetic rats.     

Slc26a9—Anion Exchanger,Channel and Na<Superscript>+</Superscript> Transporter

The SLC26 gene family encodes anion transporters with diverse functional attributes: (a) anion exchanger, (b) anion sensor, and (c) anion conductance (likely channel). We have cloned and studied Slc26a9, a paralogue expressed mostly in lung and stomach. Immunohistochemistry shows that Slc26a9 is present at apical and intracellular membranes of lung and stomach epithelia. Using expression in Xenopus laevis oocytes and ion-sensitive microelectrodes, we discovered that Slc26a9 has a novel function not found in any other Slc26 proteins: cation coupling. Intracellular pH and voltage measurements show that Slc26a9 is a nCl⁻-HCO₃⁻ exchanger, suggesting roles in gastric HCl secretion or pulmonary HCO₃⁻ secretion; Na⁺ electrodes and uptakes reveal that Slc26a9 has a cation dependence. Single-channel measurements indicate that Slc26a9 displays discrete open and closed states. These experiments show that Slc26a9 has three discrete physiological modes: nCl⁻-HCO₃⁻ exchanger, Cl⁻ channel, and Na⁺-anion cotransporter. Thus, the Slc26a9 transporter channel is uniquely suited for dynamic and tissue-specific physiology or regulation in epithelial tissues. Min-Hwang Chang, Consuelo Plata, and Kambiz Zandi-Nejad have contributed equally to this work.     

Effect of Simultaneously Replacing Putative TM6 and TM12 of Human NBCe1-A with Those from NBCn1 on Surface Abundance in <Emphasis Type="Italic">Xenopus</Emphasis> Oocytes

HCO₃ ⁻ translocation across the plasma membrane via the electrogenic Na/HCO₃ ⁻ cotransporter NBCe1 plays an important role in intracellular pH regulation and transepithelial HCO₃ ⁻ transport. However, the structural determinants of transporter function remain largely unknown. A previous study showed that the putative fourth extracellular loop (EL4) plays an essential role in determining the electrogenicity of NBCe1. In the present study, we generated eight new chimeras of human NBCe1-A and NBCn1-A. All possess the putative NBCe1 EL4 and are electrogenic. Chimera O, in which the putative sixth transmembrane segment (TM6) and EL5 through the C terminus (Ct) of NBCe1 was replaced by corresponding NBCn1 sequence, produces the smallest hyperpolarization (1–2 mV) when CO₂/HCO₃ ⁻ is added to the extracellular solution. Biotinylation experiments show that O has a very low abundance at the plasma membrane. However, chimeras in which we simultaneously replaced the putative TM6 and smaller subdomains of the EL5-Ct region for the NBCn1 sequence were strongly electrogenic except for chimera T, in which we replaced TM6 and TM12 of NBCe1 with the corresponding regions of NBCn1. T exhibited greatly reduced transporter surface expression compared to wild-type NBCe1-A, while retaining at least some electrogenic character. We hypothesize that putative TM6 and TM12 are part of a functional unit and that if the two TMs are replaced by those of the same transporter type, high surface expression would require that the surrounding TMs are also from the same transporter type.     

Standardized,systemic phenotypic analysis of Slc12a1I299F mutant mice

Background

Type I Bartter syndrome is a recessive human nephropathy caused by loss-of-function mutations in the SLC12A1 gene coding for the Na⁺-K⁺-2Cl⁻ cotransporter NKCC2. We recently established the mutant mouse line Slc12a1^I299F exhibiting kidney defects highly similar to the late-onset manifestation of this hereditary human disease. Besides the kidney defects, low blood pressure and osteopenia were revealed in the homozygous mutant mice which were also described in humans. Beside its strong expression in the kidney, NKCC2 has been also shown to be expressed in other tissues in rodents i.e. the gastrointestinal tract, pancreatic beta cells, and specific compartments of the ear, nasal tissue and eye.

Results

To examine if, besides kidney defects, further organ systems and/or metabolic pathways are affected by the Slc12a1^I299F mutation as primary or secondary effects, we describe a standardized, systemic phenotypic analysis of the mutant mouse line Slc12a1^I299F in the German Mouse Clinic. Slc12a1^I299F homozygous mutant mice and Slc12a1^I299F heterozygous mutant littermates as controls were tested at the age of 4–6 months. Beside the already published changes in blood pressure and bone metabolism, a significantly lower body weight and fat content were found as new phenotypes for Slc12a1^I299F homozygous mutant mice. Small additional effects included a mild erythropenic anemia in homozygous mutant males as well as a slight hyperalgesia in homozygous mutant females. For other functions, such as immunology, lung function and neurology, no distinct alterations were observed.

Conclusions

In this systemic analysis no clear primary effects of the Slc12a1^I299F mutation appeared for the organs other than the kidneys where Slc12a1 expression has been described. On the other hand, long-term effects additional and/or secondary to the kidney lesions might also appear in humans harboring SLC12A1 mutations.     

Cytosolic sodium regulation in mouse cortical astrocytes and its dependence on potassium and bicarbonate

Sodium plays a major role in different astrocytic functions, including maintenance of ion homeostasis and uptake of neurotransmitters and metabolites, which are mediated by different Na⁺-coupled transporters. In the current study, the role of an electrogenic sodium-bicarbonate cotransporter (NBCe1), a sodium-potassium-chloride transporter 1 (NKCC1) and sodium-potassium ATPase (Na⁺-K⁺-ATPase) for the maintenance of [Na⁺]_i was investigated in cultured astrocytes of wild-type (WT) and of NBCe1-deficient (NBCe1-KO) mice using the Na⁺-sensitive dye, asante sodium green-2. Our results suggest that cytosolic Na⁺ was higher in the presence of CO₂/HCO₃⁻ (15 mM) than CO₂/HCO₃⁻-free, HEPES-buffered solution in WT, but not in NBCe1-KO astrocytes (12 mM). Surprisingly, there was a strong dependence of cytosolic [Na⁺] on the extracellular [HCO₃⁻] attributable to NBCe1 activity. Pharmacological blockage of NKCC1 with bumetanide led to a robust drop in cytosolic Na⁺ in both WT and NBCe1-KO astrocytes by up to 6 mM. There was a strong dependence of the cytosolic [Na⁺] on the extracellular [K⁺]. Inhibition of the Na⁺-K⁺-ATPase led to larger increase in cytosolic Na⁺, both in the absence of K⁺ as compared with the presence of ouabain and in NBCe1-KO astrocytes as compared with WT astrocytes. Our results show that cytosolic Na⁺ in mouse cortical astrocytes can vary considerably and depends greatly on the concentrations of HCO₃⁻ and K⁺, attributable to the activity of the Na⁺-K⁺-ATPase, of NBCe1 and NKCC1.     

Slc26a9 Is Inhibited by the R-region of the Cystic Fibrosis Transmembrane Conductance Regulator via the STAS Domain

SLC26 proteins function as anion exchangers, channels, and sensors. Previous cellular studies have shown that Slc26a3 and Slc26a6 interact with the R-region of the cystic fibrosis transmembrane conductance regulator (CFTR), (R)CFTR, via the Slc26-STAS (sulfate transporter anti-sigma) domain, resulting in mutual transport activation. We recently showed that Slc26a9 has both nCl⁻-HCO₃⁻ exchanger and Cl⁻ channel function. In this study, we show that the purified STAS domain of Slc26a9 (a9STAS) binds purified (R)CFTR. When Slc26a9 and (R)CFTR fragments are co-expressed in Xenopus oocytes, both Slc26a9-mediated nCl⁻-HCO₃⁻ exchange and Cl⁻ currents are almost fully inhibited. Deletion of the Slc26a9 STAS domain (a9-ΔSTAS) virtually eliminated the Cl⁻ currents with only a modest affect on nCl⁻-HCO₃⁻ exchange activity. Co-expression of a9-ΔSTAS and the (R)CFTR fragment did not alter the residual a9-ΔSTAS function. Replacing the Slc26a9 STAS domain with the Slc26a6 STAS domain (a6-a9-a6) does not change Slc26a9 function and is no longer inhibited by (R)CFTR. These data indicate that the Slc26a9-STAS domain, like other Slc26-STAS domains, binds CFTR in the R-region. However, unlike previously reported data, this binding interaction inhibits Slc26a9 ion transport activity. These results imply that Slc26-STAS domains may all interact with (R)CFTR but that the physiological outcome is specific to differing Slc26 proteins, allowing for dynamic and acute fine tuning of ion transport for various epithelia.Slc26 genes and proteins have attracted the attention of physiologists and geneticists. Why? Slc26a1 (Sat-1) was characterized as a Na⁺-independent SO₄²⁻ transporter (1). Given the transport characteristics of the founding member of the gene family, Slc26 proteins were assumed to be sulfate transporters. Disease phenotypes, clone characterization, and family additions demonstrate that the Slc26 proteins are anion transporters or channels (2–4). These proteins have varied tissue expression patterns. At one extreme, Slc26a5 in mammals is found in the hair cells of the inner ear (5), whereas Slc26a2 (DTDST) is virtually ubiquitous in epithelial tissues (2).Several Slc26 proteins are found in the epithelia of the lung, intestine, stomach, pancreas, and kidney, usually in apical membranes. Interestingly these are also tissues and membranes in which the cystic fibrosis transmembrane conductance regulator (CFTR)⁵ has been found functionally or by immunohistochemistry. Ko and co-workers (6–8) examined the distribution of Slc26a3 and Slc26a6 in HCO₃⁻ secretory epithelia, and asked if an interaction might occur between these Slc26 proteins and CFTR. In particular, these studies indicate that in expression systems, there is a reciprocal-stimulatory interaction of the STAS (sulfate transporter anti-sigma) domains of Slc26a3 and Slc26a6 with the regulatory region (R-region) of CFTR. These investigators hypothesized that this stimulatory interaction could account for the differences in pancreatic insufficiency and sufficiency observed in cystic fibrosis patients. Nevertheless, knock-out Slc26a6 mouse studies reveal more complicated cell and tissue physiology (see “Discussion”).Slc26a9 has been reported to be a Cl⁻-HCO₃⁻ exchanger (9, 10) or a large Cl⁻ conductance (3, 11, 12). Loriol and co-workers (12) indicated that SLC26A9 has a Cl⁻ conductance that may be stimulated by HCO₃⁻. Two other groups have indicated that the Cl⁻ conductance is not affected by the presence of HCO₃⁻ (10, 11). We have recently demonstrated that Slc26a9 functions as both an electrogenic nCl⁻-HCO₃⁻ exchanger and a Cl⁻ channel (10). Dorwart and colleagues (11) found that WNK kinases inhibited the SLC26A9 Cl⁻ conductance but that this effect was independent of kinase activity. One group has a preliminary report indicating that WNK3 decreased Cl⁻ uptake, whereas WNK4 increased Cl⁻ uptake via Slc26a9 expressed in Xenopus oocytes (13).Slc26a9 and CFTR are also co-expressed in several tissues. Slc26a9 protein has been localized to epithelia of the stomach and lung (9, 10, 14), although mRNA is also detectable in brain, heart, kidney, small intestine, thymus, and ovary (10). The R-region of CFTR was previously shown to increase the activity of Slc26a3 and Slc26a6 by interaction with STAS domains (6, 15, 16). Because Slc26a9 displays several different modes of ion transport, we asked if the R-region of CFTR would also increase the activity of Slc26a9. Our results indicate that the R-region of CFTR does interact with the STAS domain of Slc26a9. However, in the case of Slc26a9 this apparently similar interaction results in inhibition of Slc26a9 ion transport.     

The cardiac electrogenic sodium/bicarbonate cotransporter (NBCe1) is activated by aldosterone through the G protein-coupled receptor 30 (GPR 30)

The sodium/bicarbonate cotransporter (NBC) transports extracellular Na⁺ and HCO₃^? into the cytoplasm upon intracellular acidosis, restoring the acidic pH_i to near neutral values. Two different NBC isoforms have been described in the heart, the electroneutral NBCn1 (1Na⁺:1HCO₃^?) and the electrogenic NBCe1 (1Na⁺:2HCO₃^?). Certain non-genomic effects of aldosterone (Ald) were due to an orphan G protein-couple receptor 30 (GPR30). We have recently demonstrated that Ald activates GPR30 in adult rat ventricular myocytes, which transactivates the epidermal growth factor receptor (EGFR) and in turn triggers a reactive oxygen species (ROS)- and PI3K/AKT-dependent pathway, leading to the stimulation of NBC. The aim of this study was to investigate the NBC isoform involved in the Ald/GPR30-induced NBC activation. Using specific NBCe1 inhibitory antibodies (a-L3) we demonstrated that Ald does not affect NBCn1 activity. Ald was able to increase NBCe1 activity recorded in isolation. Using immunofluorescence and confocal microscopy analysis we showed in this work that both NBCe1 and GPR30 are localized in t-tubules. In conclusion, we have demonstrated that NBCe1 is the NBC isoform activated by Ald in the heart.     

Structural and Functional Characterization of the C-terminal Transmembrane Region of NBCe1-A

NBCe1-A and AE1 both belong to the SLC4 HCO₃⁻ transporter family. The two transporters share 40% sequence homology in the C-terminal transmembrane region. In this study, we performed extensive substituted cysteine-scanning mutagenesis analysis of the C-terminal region of NBCe1-A covering amino acids Ala⁸⁰⁰–Lys⁹⁶⁷. Location of the introduced cysteines was determined by whole cell labeling with a membrane-permeant biotin maleimide and a membrane-impermeant 2-((5(6)-tetramethylrhodamine)carboxylamino) ethyl methanethiosulfonate (MTS-TAMRA) cysteine-reactive reagent. The results show that the extracellular surface of the NBCe1-A C-terminal transmembrane region is minimally exposed to aqueous media with Met⁸⁵⁸ accessible to both biotin maleimide and TAMRA and Thr⁹²⁶–Ala⁹²⁹ only to TAMRA labeling. The intracellular surface contains a highly exposed (Met⁸¹³–Gly⁸²⁸) region and a cryptic (Met⁸⁸⁷–Arg⁹⁰⁴) connecting loop. The lipid/aqueous interface of the last transmembrane segment is at Asp⁹⁶⁰. Our data clearly determined that the C terminus of NBCe1-A contains 5 transmembrane segments with greater average size compared with AE1. Functional assays revealed only two residues in the region of Pro⁸⁶⁸–Leu⁹⁶⁷ (a functionally important region in AE1) that are highly sensitive to cysteine substitution. Our findings suggest that the C-terminal transmembrane region of NBCe1-A is tightly folded with unique structural and functional features that differ from AE1.     

Interplay between Disulfide Bonding and N-Glycosylation Defines SLC4 Na+-coupled Transporter Extracellular Topography

The extracellular loop 3 (EL-3) of SLC4 Na⁺-coupled transporters contains 4 highly conserved cysteines and multiple N-glycosylation consensus sites. In the electrogenic Na⁺-HCO₃⁻ cotransporter NBCe1-A, EL-3 is the largest extracellular loop and is predicted to consist of 82 amino acids. To determine the structural-functional importance of the conserved cysteines and the N-glycosylation sites in NBCe1-A EL-3, we analyzed the potential interplay between EL-3 disulfide bonding and N-glycosylation and their roles in EL-3 topological folding. Our results demonstrate that the 4 highly conserved cysteines form two intramolecular disulfide bonds, Cys⁵⁸³-Cys⁵⁸⁵ and Cys⁶¹⁷-Cys⁶⁴², respectively, that constrain EL-3 in a folded conformation. The formation of the second disulfide bond is spontaneous and unaffected by the N-glycosylation state of EL-3 or the first disulfide bond, whereas formation of the first disulfide bond relies on the presence of the second disulfide bond and is affected by N-glycosylation. Importantly, EL-3 from each monomer is adjacently located at the NBCe1-A dimeric interface. When the two disulfide bonds are missing, EL-3 adopts an extended conformation highly accessible to protease digestion. This unique adjacent parallel location of two symmetrically folded EL-3 loops from each monomer resembles a domain-like structure that is potentially important for NBCe1-A function in vivo. Moreover, the formation of this unique structure is critically dependent on the finely tuned interplay between disulfide bonding and N-glycosylation in the membrane processed NBCe1-A dimer.     

Slc26a7 Chloride Channel Activity and Localization in Mouse Reissner’s Membrane Epithelium

Several members of the SLC26 gene family have highly-restricted expression patterns in the auditory and vestibular periphery and mutations in mice of at least two of these (SLC26A4 and SLC26A5) lead to deficits in hearing and/or balance. A previous report pointed to SLC26A7 as a candidate gene important for cochlear function. In the present study, inner ears were assayed by immunostaining for Slc26a7 in neonatal and adult mice. Slc26a7 was detected in the basolateral membrane of Reissner’s membrane epithelial cells but not neighboring cells, with an onset of expression at P5; gene knockout resulted in the absence of protein expression in Reissner’s membrane. Whole-cell patch clamp recordings revealed anion currents and conductances that were elevated for NO₃ ⁻ over Cl⁻ and inhibited by I⁻ and NPPB. Elevated NO₃ ⁻ currents were absent in Slc26a7 knockout mice. There were, however, no major changes to hearing (auditory brainstem response) of knockout mice during early adult life under constitutive and noise exposure conditions. The lack of Slc26a7 protein expression found in the wild-type vestibular labyrinth was consistent with the observation of normal balance. We conclude that SLC26A7 participates in Cl⁻ transport in Reissner’s membrane epithelial cells, but that either other anion pathways, such as ClC-2, possibly substitute satisfactorily under the conditions tested or that Cl⁻ conductance in these cells is not critical to cochlear function. The involvement of SLC26A7 in cellular pH regulation in other epithelial cells leaves open the possibility that SLC26A7 is needed in Reissner’s membrane cells during local perturbations of pH.     

Differences in the Pathogenicity of the p.H723R Mutation of the Common Deafness-Associated SLC26A4 Gene in Humans and Mice

Mutations in the SLC26A4 gene are a common cause of human hereditary hearing impairment worldwide. Previous studies have demonstrated that different SLC26A4 mutations have different pathogenetic mechanisms. By using a genotype-driven approach, we established a knock-in mouse model (i.e., Slc26a4^{tm2Dontuh/tm2Dontuh} mice) homozygous for the common p.H723R mutation in the East Asian population. To verify the pathogenicity of the p.H723R allele in mice, we further generated mice with compound heterozygous mutations (i.e., Slc26a4^{tm1Dontuh/tm2Dontuh}) by intercrossing Slc26a4^+/tm2Dontuh mice with Slc26a4^{tm1Dontuh/tm1Dontuh} mice, which segregated the c.919-2A>G mutation with an abolished Slc26a4 function. Mice were then subjected to audiologic assessments, a battery of vestibular evaluations, inner ear morphological studies, and noise exposure experiments. The results were unexpected; both Slc26a4^{tm2Dontuh/tm2Dontuh} and Slc26a4^{tm1Dontuh/tm2Dontuh} mice showed normal audiovestibular phenotypes and inner ear morphology, and they did not show significantly higher shifts in hearing thresholds after noise exposure than the wild-type mice. The results indicated not only the p.H723R allele was non-pathogenic in mice, but also a single p.H723R allele was sufficient to maintain normal inner ear physiology in heterozygous compound mice. There might be discrepancies in the pathogenicity of specific SLC26A4 mutations in humans and mice; therefore, precautions should be taken when extrapolating the results of animal studies to humans.     

The Sodium Bicarbonate Cotransporter (NBCe1) Is Essential for Normal Development of Mouse Dentition

Proximal renal tubular acidosis (pRTA) is a syndrome caused by abnormal proximal tubule reabsorption of bicarbonate resulting in metabolic acidosis. Patients with mutations to the SLC4A4 gene (coding for the sodium bicarbonate cotransporter NBCe1), have pRTA, growth delay, ocular defects, and enamel abnormalities. In an earlier report, we provided the first evidence that enamel cells, the ameloblasts, express NBCe1 in a polarized fashion, thereby contributing to trans-cellular bicarbonate transport. To determine whether NBCe1 plays a critical role in enamel development, we studied the expression of NBCe1 at various stages of enamel formation in wild-type mice and characterized the biophysical properties of enamel in NBCe1^−/− animals. The enamel of NBCe1^−/− animals was extremely hypomineralized and weak with an abnormal prismatic architecture. The expression profile of amelogenin, a known enamel-specific gene, was not altered in NBCe1^−/− animals. Our results show for the first time that NBCe1 expression is required for the development of normal enamel. This study provides a mechanistic model to account for enamel abnormalities in certain patients with pRTA.