Renal and intestinal absorptive defects in mice lacking the NHE3 Na+/H+ exchanger.

NHE3 is one of five plasma membrane Na+/H+ exchangers and is encoded by the mouse gene Slc9a3. It is expressed on apical membranes of renal proximal tubule and intestinal epithelial cells and is thought to play a major role in NaCl and HCO3- absorption. As the distribution of NHE3 overlaps with that of the NHE2 isoform in kidney and intestine, the function and relative importance of NHE3 in vivo is unclear. To analyse its physiological functions, we generated mice lacking NHE3 function. Homozygous mutant (Slc9a3-/-) mice survive, but they have slight diarrhoea and blood analysis revealed that they are mildly acidotic. HCO3- and fluid absorption are sharply reduced in proximal convoluted tubules, blood pressure is reduced and there is a severe absorptive defect in the intestine. Thus, compensatory mechanisms must limit gross perturbations of electrolyte and acid-base balance. Plasma aldosterone is increased in NHE3-deficient mice, and expression of both renin and the AE1 (Slc4a1) Cl-/HCO3- exchanger mRNAs are induced in kidney. In the colon, epithelial Na+ channel activity is increased and colonic H+,K+-ATPase mRNA is massively induced. These data show that NHE3 is the major absorptive Na+/H+ exchanger in kidney and intestine, and that lack of the exchanger impairs acid-base balance and Na+-fluid volume homeostasis.

Novel amiloride-sensitive sodium-dependent proton secretion in the mouse proximal convoluted tubule.

The proximal convoluted tubule (PCT) reabsorbs most of the filtered bicarbonate. Proton secretion is believed to be mediated predominantly by an apical membrane Na(+)/H(+) exchanger (NHE). Several NHE isoforms have been cloned, but only NHE3 and NHE2 are known to be present on the apical membrane of the PCT. Here we examined apical membrane PCT sodium-dependent proton secretion of wild-type (NHE3(+/+)/NHE2(+/+)), NHE3(-/-), NHE2(-/-), and double-knockout NHE3(-/-)/NHE2(-/-) mice to determine their relative contribution to luminal proton secretion. NHE2(-/-) and wild-type mice had comparable rates of sodium-dependent proton secretion. Sodium-dependent proton secretion in NHE3(-/-) mice was approximately 50% that of wild-type mice. The residual sodium-dependent proton secretion was inhibited by 100 microM 5-(N-ethyl-N-isopropyl) amiloride (EIPA). Luminal sodium-dependent proton secretion was the same in NHE3(-/-)/NHE2(-/-) as in NHE3(-/-) mice. These data point to a previously unrecognized Na(+)-dependent EIPA-sensitive proton secretory mechanism in the proximal tubule that may play an important role in acid-base homeostasis.

Na(+)-dependent transporters mediate HCO(3)(-) salvage across the luminal membrane of the main pancreatic duct.

To study the roles of Na(+)-dependent H(+) transporters, we characterized H(+) efflux mechanisms in the pancreatic duct in wild-type, NHE2(-/-), and NHE3(-/-) mice. The pancreatic duct expresses NHE1 in the basolateral membrane, and NHE2 and NHE3 in the luminal membrane, but does not contain NHE4 or NHE5. Basolateral Na(+)-dependent H(+) efflux in the microperfused duct was inhibited by 1.5 microM of the amiloride analogue HOE 694, consistent with expression of NHE1, whereas the luminal activity required 50 microM HOE 694 for effective inhibition, suggesting that the efflux might be mediated by NHE2. However, disruption of NHE2 had no effect on luminal transport, while disruption of the NHE3 gene reduced luminal Na(+)-dependent H(+) efflux by approximately 45%. Notably, the remaining luminal Na(+)-dependent H(+) efflux in ducts from NHE3(-/-) mice was inhibited by 50 microM HOE 694. Hence, approximately 55% of luminal H(+) efflux (or HCO(3)(-) influx) in the pancreatic duct is mediated by a novel, HOE 694-sensitive, Na(+)-dependent mechanism. H(+) transport by NHE3 and the novel transporter is inhibited by cAMP, albeit to different extents. We propose that multiple Na(+)-dependent mechanisms in the luminal membrane of the pancreatic duct absorb Na(+) and HCO(3)(-) to produce a pancreatic juice that is poor in HCO(3)(-) and rich in Cl(-) during basal secretion. Inhibition of the transporters during stimulated secretion aids in producing the HCO(3)(-)-rich pancreatic juice.

Increased sensitivity to K+ deprivation in colonic H,K-ATPase-deficient mice.

Previous studies using isolated tissues suggest that the colonic H, K-ATPase (cHKA), expressed in the colon and kidney, plays an important role in K+ conservation. To test the role of this pump in K+ homeostasis in vivo, we generated a cHKA-deficient mouse and analyzed its ability to retain K+ when fed a control or K+-free diet. When maintained on a control diet, homozygous mutant (cHKA-/-) mice exhibited no deficit in K+ homeostasis compared to wild-type (cHKA+/+ greater, similar mice. Although fecal K+ excretion in cHKA-/- mice was double that of cHKA+/+ mice, fecal K+ losses were low compared with urinary K+ excretion, which was similar in both groups. When maintained on a K+-free diet for 18 d, urinary K+ excretion dropped over 100-fold, and to similar levels, in both cHKA-/- and cHKA+/+ mice; fecal K+ excretion was reduced in both groups, but losses were fourfold greater in cHKA-/- than in cHKA+/+ mice. Because of the excess loss of K+ in the colon, cHKA-/- mice exhibited lower plasma and muscle K+ than cHKA+/+ mice. In addition, cHKA-/- mice lost twice as much body weight as cHKA+/+ mice. These results demonstrate that, during K+ deprivation, cHKA plays a critical role in the maintenance of K+ homeostasis in vivo.

Targeted disruption of the murine Na+/H+ exchanger isoform 2 gene causes reduced viability of gastric parietal cells and loss of net acid secretion.

Multiple isoforms of the Na+/H+ exchanger (NHE) are expressed at high levels in gastric epithelium, but the physiological role of individual isoforms is unclear. To study the function of NHE2, which is expressed in mucous, zymogenic, and parietal cells, we prepared mice with a null mutation in the NHE2 gene. Homozygous null mutants exhibit no overt disease phenotype, but the cellular composition of the oxyntic mucosa of the gastric corpus is altered, with parietal and zymogenic cells reduced markedly in number. Net acid secretion in null mutants is reduced slightly relative to wild-type levels just before weaning and is abolished in adult animals. Although mature parietal cells are observed, and appear morphologically to be engaged in active acid secretion, many of the parietal cells are in various stages of degeneration. These results indicate that NHE2 is not required for acid secretion by the parietal cell, but is essential for its long-term viability. This suggests that the unique sensitivity of NHE2 to inhibition by extracellular H+, which would allow upregulation of its activity by the increased interstitial alkalinity that accompanies acid secretion, might enable this isoform to play a specialized role in maintaining the long-term viability of the parietal cell.

Variant form of diffuse corporal gastritis in NHE2 knockout mice.

Mice lacking the NHE2 Na+/H+ gene develop gastritis of the glandular mucosa as early as the tenth day of life, achieving maximal intensity of inflammation from 17 to 19 days after birth and maximal atrophy at one year. We assessed the effects of this process in such mice to 16 months of age. The stomach of NHE2 null mutants was examined at 10, 17 to 20, 24 to 35 and 49 to 70 days, and at 12 to 16 months. The NHE2 wild-type (+/+) and NHE2 heterozygous (+/-) mice were compared with the NHE2 homozygous mutant mice (-/-). The stomach of the mutant mice at all ages was characterized by a substantially reduced number of parietal cells. The 10-day-old mouse stomach had a transmural infiltrate of primarily neutrophils. With increasing age, neutrophils were replaced by lymphocytes and plasma cells in the glandular mucosa of the mutant mice. Young adult 49- to 70-day-old mice had surface cell hyperplasia and expansion of the replicating cell population. Hyperplasia of enterochromaffin-like cells and antral gastrin cells accompanied profound fundic gland and surface cell hyperplasia, and became progressively more severe with increasing age of the NHE2-/- mice. Neoplasms were not found in the mutant or control mice. This gastritis differs from that of autoimmune gastritis in that it is transmural, begins in infancy, and is associated with a predominantly neutrophilic infiltrate in its early stages. Some of the histologic changes in the adult mice can be explained on the basis of prolonged achlorhydria. This mouse may be a suitable model for prolonged effects of achlorhydria.

Substitution of transmembrane residues with hydrogen-bonding potential in the alpha subunit of Na,K-ATPase reveals alterations in ouabain sensitivity.

The role of H-bonding amino acids as determinants of ouabain affinity in the Na,K-ATPase was examined. Site-directed mutagenesis was used to substitute 21 conserved amino acid residues in the sheep alpha-subunit transmembrane regions. The amino acids were changed from residues which possess side chains capable of forming H-bonds with specific cardiac glycoside moieties such as the lactone ring or sugar(s) to residues unable to participate in H-bonding. The effect of each of these amino acid replacements on the affinity of the Na,K-ATPase for ouabain was initially assessed by screening the altered enzymes for the ability to confer ouabain resistance when expressed in otherwise sensitive HeLa cells. Three of the substitutions (Tyr-108 to Ala, Cys-104 to Ala, and Cys-104 to Phe) were able to confer resistance to the normally sensitive HeLa cells. Stable cell lines, each expressing one of the altered enzymes, were further characterized in terms of ouabain-inhibitable cell growth and Na,K-ATPase activity. Cell lines expressing the alpha 1-isoform substitution Y108A, C104A, or C104F contained a Na,K-ATPase activity which gave an I50 value for enzyme inhibition 9-, 6-, and 150-fold greater, respectively, than the endogeneous HeLa or sheep enzyme. These data show that Tyr-108 and Cys-104 of the alpha subunit are determinants of ouabain affinity. Cys-104 has also been shown to be a determinant of ouabain sensitivity in Xenopus laevis [Canessa, C. M., Horisberger, J.-D., Louvard, D., & Rossier, B. C. (1992) EMBO J. 11, 1681-1687].(ABSTRACT TRUNCATED AT 250 WORDS)

Lessons from genetically engineered animal models VIII. Absorption and secretion of ions in the gastrointestinal tract.

Absorption and secretion of ions in gastrointestinal and other epithelial tissues require the concerted activities of ion pumps, channels, symporters, and exchangers, which operate in coupled systems to mediate transepithelial transport. Our understanding of the identities, membrane locations, and biochemical activities of epithelial ion transporters has advanced significantly in recent years, but major gaps and uncertainties remain in our understanding of their physiological functions. Increasingly, this problem is being addressed by the analysis of mutant mouse models developed by gene targeting. In this review, we discuss gene knockout studies of the secretory isoform of the Na(+)-K(+)-2Cl(-) cotransporter, isoforms 1, 2, and 3 of the Na(+)/H(+) exchanger, and the colonic H(+)-K(+)-ATPase. This approach is leading to a clearer understanding of the functions of these transporters in the living animal.

Three N-terminal variants of the AE2 Cl-/HCO3- exchanger are encoded by mRNAs transcribed from alternative promoters.

Multiple AE2 Cl-/HCO3- exchanger mRNAs have been identified in rat. To determine the genetic basis for these mRNAs and whether they encode different variants of the exchanger, we used both rapid amplification of cDNA ends and S1 nuclease protection protocols and examined the organization of the gene. mRNAs encoding three N-terminal variants of AE2 (AE2a, AE2b, and AE2c) were identified and shown to be transcribed from alternative promoters. The AE2a transcription unit consists of 23 exons, with exons 1 and 2 containing 5'-untranslated sequence and the first 17 codons. The first exon of AE2b is located in intron 2; it contains 5'-untranslated sequence and an alternative 3-amino acid N-terminal coding sequence and is spliced to exon 3. The first exon of AE2c is located in intron 5; it consists of 5'-untranslated sequence and is spliced to exon 6, which contains the translation initiation codon corresponding to Met-200 of AE2a. Northern analysis shows that AE2a is expressed in all tissues, AE2b exhibits a more restricted distribution with highest levels in stomach, and AE2c is expressed only in stomach. Thus, the use of alternative promoters leads to the production of three N-terminal variants of AE2 that exhibit tissue-specific patterns of expression.

Kinetic analysis of ouabain binding to native and mutated forms of Na,K-ATPase and identification of a new region involved in cardiac glycoside interactions.

Cardiac glycosides inhibit the Na,K-ATPase by binding to the catalytic alpha subunit of the enzyme. Site-directed mutagenesis of the H1-H2 domain has demonstrated the importance of this region in determining cardiac glycoside affinity. In this study, random mutagenesis was used to identify an amino acid, arginine 880, in the COOH-terminal portion of the alpha subunit which influences the sensitivity of the enzyme to ouabain. This residue is predicted to reside in the H7-H8 extracellular loop. Conversion of arginine 880 to a proline causes a 10-fold increase in the dissociation rate constant and a 2-fold increase in the association rate constant for [3H]ouabain binding. This results in an enzyme with a KD for ouabain 5-fold higher than the wild-type sheep alpha 1 isoform. These data are compatible with arginine 880 comprising a portion of the ouabain binding site. Furthermore, if arginine 880 is at the physical binding site, then this finding lends support to models that place this amino acid extracellularly since cardiac glycosides interact with the extracellular surface of the Na,K-ATPase. The ouabain binding characteristics of substitution R880P were compared with those of several different Na,K-ATPases, each of which contains a single amino acid substitution in the H1-H2 region of the alpha subunit. The substituted enzymes, C104A, Y108A, E116Q, P118K, and Y124F, vary considerably in their rates of dissociation (1-4-fold increase in the dissociation rate constant). In addition, the rate of association of [3H]ouabain binding to substitution P118K is 2-fold slower than that of the wild-type enzyme. These results suggest that the H1-H2 domain may participate directly in ouabain binding as well as be involved in conformational changes, both of which could affect the sensitivity of the enzyme to ouabain.

Mouse down-regulated in adenoma (DRA) is an intestinal Cl(-)/HCO(3)(-) exchanger and is up-regulated in colon of mice lacking the NHE3 Na(+)/H(+) exchanger.

Mutations in human DRA cause congenital chloride diarrhea, thereby raising the possibility that it functions as a Cl(-)/HCO(3)(-) exchanger. To test this hypothesis we cloned a cDNA encoding mouse DRA (mDRA) and analyzed its activity in cultured mammalian cells. When expressed in HEK 293 cells, mDRA conferred Na(+)-independent, electroneutral Cl(-)/CHO(3)(-) exchange activity. Removal of extracellular Cl(-) from medium containing HCO(3)(-) caused a rapid intracellular alkalinization, whereas the intracellular pH increase following Cl(-) removal from HCO(3)(-)-free medium was reduced greater than 7-fold. The intracellular alkalinization in Cl(-)-free, HCO(3)(-)-containing medium was unaffected by removal of extracellular Na(+) or by depolarization of the membrane by addition of 75 mM K(+) to the medium. Like human DRA mRNA, mDRA transcripts were expressed at high levels in cecum and colon and at lower levels in small intestine. The expression of mDRA mRNA was modestly up-regulated in the colon of mice lacking the NHE3 Na(+)/H(+) exchanger. These results show that DRA is a Cl(-)/HCO(3)(-) exchanger and suggest that it normally acts in concert with NHE3 to absorb NaCl and that in NHE3-deficient mice its activity is coupled with those of the sharply up-regulated colonic H(+),K(+)-ATPase and epithelial Na(+) channel to mediate electrolyte and fluid absorption.

Micropuncture analysis of single-nephron function in NHE3-deficient mice.

The Na/H exchanger isoform 3 (NHE3) is expressed in the proximal tubule and thick ascending limb and contributes to the reabsorption of fluid and electrolytes in these segments. The contribution of NHE3 to fluid reabsorption was assessed by micropuncture in homozygous (Nhe3-/-) and heterozygous (Nhe3+/-) knockout mice, and in their wild-type (WT, Nhe3+/+) littermates. Arterial pressure was lower in the Nhe3-/- mice (89 +/- 6 mmHg) compared with Nhe3+/+ (118 +/- 4) and Nhe3+/- (108 +/- 5). Collections from proximal and distal tubules demonstrated that proximal fluid reabsorption was blunted in both Nhe3+/- and Nhe3-/- mice (WT, 4. 2 +/- 0.3; Nhe3+/-, 3.4 +/- 0.2; and Nhe3-/-, 2.6 +/- 0.3 nl/min; P < 0.05). However, distal delivery of fluid was not different among the three groups of mice (WT, 3.3 +/- 0.4 nl/min; Nhe3+/-, 3.3 +/- 0.2 nl/min; and Nhe3-/-, 3.0 +/- 0.4 nl/min; P < 0.05). In Nhe3-/- mice, this compensation was largely attributable to decreased single-nephron glomerular filtration rate (SNGFR): 10.7 +/- 0.9 nl/min in the Nhe3+/+ vs. 6.6 +/- 0.8 nl/min in the Nhe3-/-, measured distally. Proximal-distal SNGFR differences in Nhe3-/- mice indicated that much of the decrease in SNGFR was due to activation of tubuloglomerular feedback (TGF), and measurements of stop-flow pressure confirmed that TGF is intact in Nhe3-/- animals. In contrast to Nhe3-/- mice, normalization of early distal flow rate in Nhe3+/- mice was not related to decreased SNGFR (9.9 +/- 0.7 nl/min), but rather, to increased fluid reabsorption in the loop segment (Nhe3+/+, 2.6 +/- 0.2; Nhe3+/-, 3.6 +/- 0.5 nl/min). We conclude that NHE3 is a major Na/H exchanger isoform mediating Na+ and fluid reabsorption in the proximal tubule. In animals with NHE3 deficiency, normalization of fluid delivery to the distal tubule is achieved through alterations in filtration rate and/or downstream transport processes.

Renal salt wasting in mice lacking NHE3 Na+/H+ exchanger but not in mice lacking NHE2.

To study the role of Na+/H+ exchanger isoform 2 (NHE2) and isoform 3 (NHE3) in sodium-fluid volume homeostasis and renal Na+ conservation, mice with Nhe2 (Nhe2-/-) and/or Nhe3 (Nhe3-/-) null mutations were fed a Na+-restricted diet, and urinary Na+ excretion, blood pressure, systemic acid-base and electrolyte status, and renal function were analyzed. Na+ -restricted Nhe2-/- mice, on either a wild-type or Nhe3 heterozygous mutant (Nhe3+/-) background, did not exhibit excess urinary Na+ excretion. After 15 days of Na+ restriction, blood pressure, fractional excretion of Na+, and the glomerular filtration rate (GFR) of Nhe2-/-Nhe3+/- mice were similar to those of Nhe2+/+ and Nhe3+/- mice, and no metabolic disturbances were observed. Nhe3-/- mice maintained on a Na+-restricted diet for 3 days exhibited hyperkalemia, urinary salt wasting, acidosis, sharply reduced blood pressure and GFR, and evidence of hypovolemic shock. These results negate the hypothesis that NHE2 plays an important renal function in sodium-fluid volume homeostasis; however, they demonstrate that NHE3 is critical for systemic electrolyte, acid-base, and fluid volume homeostasis during dietary Na+ restriction and that its absence leads to renal salt wasting.

Comparison of the effects of potassium on ouabain binding to native and site-directed mutants of Na,K-ATPase.

We examined the effect of K+ on Mg(2+)- and P(i)-supported [3H]ouabain binding to Na,K-ATPases, including partially purified enzyme from sheep kidney and wild-type and mutant sheep alpha 1 isoforms (C104A, Y108A, E116Q, P118K, Y124F, R880P, R880L, and N122D) expressed in NIH3T3 cells. In the presence of increasing concentrations of K+, [3H]ouabain binding to these enzymes decreases but never reaches nonspecific binding levels, consistent with the concept that ouabain is still able to bind to the K(+)-complexed enzyme but with reduced affinity. A partially competitive model for K+ inhibition of ouabain binding is proposed which satisfactorily fits the binding data. The model is consistent with the sequential binding of two K+ ions to the enzyme. Ki values (approximately 1.0 mM) for K+ obtained from this model are comparable to the apparent K+ affinities of the rat alpha isoforms determined by measuring the K+ dependence of Na,K-ATPase activity [E. A. Jewell and J. B. Lingrel (1991) J. Biol. Chem. 266, 16925-16930]. This is consistent with the concept that K+ inhibition of Mg2+ plus P(i) supported ouabain binding is mediated by K+ binding to the same high-affinity binding sites present in the native enzyme under physiological conditions. While the mutants exhibit binding constants for ouabain which vary more than 30-fold from that of the wild-type enzyme, their affinities for K+ differ less than twofold from that of the native enzyme. Our results suggest that the ouabain and K+ binding sites are not the same and are differentially affected by mutations of the enzyme. The system described here should prove useful in the analysis of cation binding to other mutants of the Na,K-ATPase, especially those carrying amino acid replacements which result in an inactive enzyme.

Targeted disruption of the Nhe1 gene prevents muscarinic agonist-induced up-regulation of Na(+)/H(+) exchange in mouse parotid acinar cells.

The onset of salivary gland fluid secretion in response to muscarinic stimulation is accompanied by up-regulation of Na(+)/H(+) exchanger (NHE) activity. Although multiple NHE isoforms (NHE1, NHE2, and NHE3) have been identified in salivary glands, little is known about their specific function(s) in resting and secreting acinar cells. Mice with targeted disruptions of the Nhe1, Nhe2, and Nhe3 genes were used to investigate the contribution of these proteins to the stimulation-induced up-regulation of NHE activity in mouse parotid acinar cells. The lack of NHE1, but not NHE2 or NHE3, prevented intracellular pH recovery from an acid load in resting acinar cells, in acini stimulated to secrete with the muscarinic agonist carbachol, and in acini shrunken by hypertonic addition of sucrose. In HCO(3)(-)-containing solution, the rate of intracellular pH recovery from a muscarinic agonist-stimulated acid load was significantly inhibited in acinar cells from mice lacking NHE1, but not in cells from NHE2- or NHE3-deficient mice. These data demonstrate that NHE1 is the major regulator of intracellular pH in both resting and muscarinic agonist-stimulated acinar cells and suggest that up-regulation of NHE1 activity has an important role in modulating saliva production in vivo.

Mechanism of proximal tubule bicarbonate absorption in NHE3 null mice.

NHE3 is the predominant isoform responsible for apical membrane Na(+)/H(+) exchange in the proximal tubule. Deletion of NHE3 by gene targeting results in an NHE3(-/-) mouse with greatly reduced proximal tubule HCO(-)(3) absorption compared with NHE3(+/+) animals (P. J. Schultheis, L. L. Clarke, P. Meneton, M. L. Miller, M. Soleimani, L. R. Gawenis, T. M. Riddle, J. J. Duffy, T. Doetschman, T. Wang, G. Giebisch, P. S. Aronson, J. N. Lorenz, and G. E. Shull. Nature Genet. 19: 282-285, 1998). The purpose of the present study was to evaluate the role of other acidification mechanisms in mediating the remaining component of proximal tubule HCO(-)(3) reabsorption in NHE3(-/-) mice. Proximal tubule transport was studied by in situ microperfusion. Net rates of HCO(-)(3) (J(HCO3)) and fluid absorption (J(v)) were reduced by 54 and 63%, respectively, in NHE3 null mice compared with controls. Addition of 100 microM ethylisopropylamiloride (EIPA) to the luminal perfusate caused significant inhibition of J(HCO3) and J(v) in NHE3(+/+) mice but failed to inhibit J(HCO3) or J(v) in NHE3(-/-) mice, indicating lack of activity of NHE2 or other EIPA-sensitive NHE isoforms in the null mice. Addition of 1 microM bafilomycin caused a similar absolute decrement in J(HCO3) in wild-type and NHE3 null mice, indicating equivalent rates of HCO(-)(3) absorption mediated by H(+)-ATPase. Addition of 10 microM Sch-28080 did not reduce J(HCO3) in either wild-type or NHE3 null mice, indicating lack of detectable H(+)-K(+)-ATPase activity in the proximal tubule. We conclude that, in the absence of NHE3, neither NHE2 nor any other EIPA-sensitive NHE isoform contributes to mediating HCO(-)(3) reabsorption in the proximal tubule. A significant component of HCO(-)(3) reabsorption in the proximal tubule is mediated by bafilomycin-sensitive H(+)-ATPase, but its activity is not significantly upregulated in NHE3 null mice.

HCO-3 reabsorption in renal collecting duct of NHE-3-deficient mouse: a compensatory response.

Mice with a targeted disruption of Na+/H+ exchanger NHE-3 gene show significant reduction in HCO-3 reabsorption in proximal tubule, consistent with the absence of NHE-3. Serum HCO-3, however, is only mildly decreased (P. Schulties, L. L. Clarke, P. Meneton, M. L. Miller, M. Soleimani, L. R. Gawenis, T. M. Riddle, J. J. Duffy, T. Doetschman, T. Wang, G. Giebisch, P. S. Aronson, J. N. Lorenz, and G. E. Shull. Nature Genet. 19: 282-285, 1998), indicating possible adaptive upregulation of HCO-3-absorbing transporters in collecting duct of NHE-3-deficient (NHE-3 -/-) mice. Cortical collecting duct (CCD) and outer medullary collecting duct (OMCD) were perfused, and total CO2 (net HCO-3 flux, JtCO2) was measured in the presence of 10 microM Schering 28080 (SCH, inhibitor of gastric H+-K+-ATPase) or 50 microM diethylestilbestrol (DES, inhibitor of H+-ATPase) in both mutant and wild-type (WT) animals. In CCD, JtCO2 increased in NHE-3 mutant mice (3.42 +/- 0.28 in WT to 5.71 +/- 0.39 pmol. min-1. mm tubule-1 in mutants, P < 0.001). The SCH-sensitive net HCO-3 flux remained unchanged, whereas the DES-sensitive HCO-3 flux increased in the CCD of NHE-3 mutant animals. In OMCD, JtCO2 increased in NHE-3 mutant mice (8.8 +/- 0.7 in WT to 14.2 +/- 0.6 pmol. min-1. mm tubule-1 in mutants, P < 0.001). Both the SCH-sensitive and the DES-sensitive HCO-3 fluxes increased in the OMCD of NHE-3 mutant animals. Northern hybridizations demonstrated enhanced expression of the basolateral Cl-/HCO-3 exchanger (AE-1) mRNA in the cortex. The gastric H+-K+-ATPase mRNA showed upregulation in the medulla but not the cortex of NHE-3 mutant mice. Our results indicate that HCO-3 reabsorption is enhanced in CCD and OMCD of NHE-3-deficient mice. In CCD, H+-ATPase, and in the OMCD, both H+-ATPase and gastric H+-K+-ATPase contribute to the enhanced compensatory HCO-3 reabsorption in NHE-3-deficient animals.

Membrane-limited expression and regulation of Na+-H+ exchanger isoforms by P2 receptors in the rat submandibular gland duct.

1. Cell-specific reverse transcriptase-polymerase chain reaction (RT-PCR), immunolocalization and microspectrofluorometry were used to identify and localize the Na+-H+ exchanger (NHE) isoforms expressed in the submandibular gland (SMG) acinar and duct cells and their regulation by basolateral and luminal P2 receptors in the duct. 2. The molecular and immunofluorescence analysis showed that SMG acinar and duct cells expressed NHE1 in the basolateral membrane (BLM). Duct cells also expressed NHE2 and NHE3 in the luminal membrane (LM). 3. Expression of NHE3 was unequivocally established by the absence of staining in SMG from NHE3 knockout mice. NHE3 was expressed in the LM and in subluminal regions of the duct. 4. Measurement of the inhibition of NHE activity by the amiloride analogue HOE 694 (HOE) suggested expression of NHE1-like activity in the BLM and NHE2-like activity in the LM of the SMG duct. Several acute and chronic treatments tested failed to activate NHE activity with low affinity for HOE as expected for NHE3. Hence, the physiological function and role of NHE3 in the SMG duct is not clear at present. 5. Activation of P2 receptors resulted in activation of an NHE-independent, luminal H+ transport pathway that markedly and rapidly acidified the cells. This pathway could be blocked by luminal but not basolateral Ba2+. 6. Stimulation of P2U receptors expressed in the BLM activated largely NHE1-like activity, and stimulation of P2Z receptors expressed in the LM activated largely NHE2-like activity. 7. The interrelation between basolateral and luminal NHE activities and their respective regulation by P2U and P2Z receptors can be used to co-ordinate membrane transport events in the LM and BLM during active Na+ reabsorption by the SMG duct.

Role of sodium/hydrogen exchanger isoform NHE3 in fluid secretion and absorption in mouse and rat cholangiocytes.

Na+/H+ exchanger (NHE) isoforms play important roles in intracellular pH regulation and in fluid absorption. The isoform NHE3 has been localized to apical surfaces of epithelia and in some tissues may facilitate the absorption of NaCl. To determine whether the apical isoform NHE3 is present in cholangiocytes and to examine whether it has a functional role in cholangiocyte fluid secretion and absorption, immunocytochemical studies were performed in rat liver with NHE3 antibodies and functional studies were obtained in isolated bile duct units from wild-type and NHE3-/- mice after stimulation with forskolin, using videomicroscopic techniques. Our results indicate that NHE3 protein is present on the apical membranes of rat cholangiocytes and on the canalicular membrane of hepatocytes. Western blots also detect NHE3 protein in rat cholangiocytes and isolated canalicular membranes. After stimulation with forskolin, duct units from NHE3-/- mice fail to absorb the secreted fluid from the cholangiocyte lumen compared with control animals. Similar findings were observed in isolated bile duct units from wild-type mice and rats in the presence of the Na+/H+ exchanger inhibitor 5-(N-ethyl-N-isopropyl)-amiloride. In contrast, we could not demonstrate absorption of fluid from the canalicular lumen of mouse or rat hepatocyte couplets after stimulation of secretion with forskolin. These findings indicate that NHE3 is located on the apical membrane of rat cholangiocytes and that this NHE isoform can function to absorb fluid from the lumens of isolated rat and mouse cholangiocyte preparations.

Profiling of renal tubule Na+ transporter abundances in NHE3 and NCC null mice using targeted proteomics.

The Na+-H+ exchanger NHE3 and the thiazide-sensitive Na+-Cl- cotransporter NCC are the major apical sodium transporters in the proximal convoluted tubule and the distal convoluted tubule of the kidney, respectively. We investigated the mechanism of compensation that allows maintenance of sodium balance in NHE3 knockout mice and in NCC knockout mice. We used a so-called 'targeted proteomics' approach, which profiles the entire renal tubule with regard to changes in Na+ transporter and aquaporin abundance in response to the gene deletions. Specific antibodies to the Na+ transporters and aquaporins expressed along the nephron were utilized to determine the relative abundance of each transporter. Semiquantitative immunoblotting was used which gives an estimate of the percentage change in abundance of each transporter in knockout compared with wild-type mice. In NHE3 knockout mice three changes were identified which could compensate for the loss of NHE3-mediated sodium absorption. (a) The proximal sodium-phosphate cotransporter NaPi-2 was markedly upregulated. (b) In the collecting duct, the 70 kDa form of the y-subunit of the epithelial sodium channel, ENaC, exhibited an increase in abundance. This is thought to be an aldosterone-stimulated form of y-ENaC. (c) Glomerular filtration was significantly reduced. In the NCC knockout mice, amongst all the sodium transporters expressed along the renal tubule, only the 70 kDa form of the y-subunit of the epithelial sodium channel, ENaC, exhibited an increase in abundance. In conclusion, both mouse knockout models demonstrated successful compensation for loss of the deleted transporter. More extensive adaptation occurred in the case of the NHE3 knockout, presumably because NHE3 is responsible for much more sodium absorption in normal mice than in NCC knockout mice.