Role In Acid-base Homeostasis Research Articles

Renal NHE1 is required for regulation of intracellular pH in principal cells and type B intercalated cells

The sodium-hydrogen exchanger isoform 1 (NHE1) is a plasma membrane transporter with roles in transepithelial Na+/H+ transport, intracellular pH (pHi) and cell volume regulation. Within the kidney, NHE1 is previously documented to be expressed in all nephron segments. However, recent transcriptomic and proteomic analyses, and our staining results in mice, consistently find no expression of NHE1 in the proximal tubule or thick ascending limb, but in the distal nephron, including distal convoluted tubule, connecting tubule, and collecting duct (principal and intercalated cells, PC and IC, respectively). We hypothesized that basolateral NHE1 in IC (co-labelling with H+-ATPase B1 subunit, labeling all 3 types of IC: type A, B, and non-A-non-B) plays an important role in acid-base homeostasis. Due to lack of a suitable animal model, we generated kidney-specific NHE1 knockout (NHE1KS-KO) mice. NHE1KS-KO mice completely lack renal NHE1 protein expression compared to their control littermates (n=6 male mice/genotype). No differences were observed in body weight, food and water intake (determined in their home cages) or concentrations of blood Na+, K+, Ca2+, pH or HCO3-. Urine analysis showed no significant differences in electrolytes, minerals of pH. To mechanistically determine the role of NHE1 for pHi regulation in IC and PC we used confocal microscopy of acutely-split open cortical collecting ducts. This method allows for the analysis of a vast number of PC/IC simultaneously. To study the role of NHE1 we employed a NH4Cl pre-pulse (40 mM) and measured pHi recovery after switching back to a physiological solution. Intracellular pH recovery in PC (n=171) was significantly slower (~50%) in NHE1KS-KO mice compared to controls (n=85). Similar to PC, pHi recovery in type B IC of NHE1KS-KO mice (n=38) was significantly slower (~35%) compared to controls (n=40). No differences in type A IC were observed between NHE1KS-KO mice (n=35) and controls (n=29). Inhibition of ClC-K2 via NPPB (Cl-channel blocker) was used to confirm cell types: PC did not respond with a change in pHi but NPPB increased pHi in type A and decreased pHi in type B ICs. In summary, our results identify for the first time an important role of NHE1 for pHi regulation particularly in PCs and type B ICs. Funding to Dr. Rieg was provided by the NIDDK grant 1R01DK110621, VA Merit Review Award IBX004968A, AHA Transformational Research Award 19TPA34850116, and NIDDK Diabetic Complications Consortium grants DK076169 and DK115255. DK095029 and DK117865 (both to O. Pochynyuk). Dr. Thomas was supported by an AHA postdoctoral grant (828731), V. Tomilin by an AHA Career Development Award 19CDA34660148. This is the full abstract presented at the American Physiology Summit 2023 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.

CryoEM structures of anion exchanger 1 capture multiple states of inward- and outward-facing conformations

Anion exchanger 1 (AE1, band 3) is a major membrane protein of red blood cells and plays a key role in acid-base homeostasis, urine acidification, red blood cell shape regulation, and removal of carbon dioxide during respiration. Though structures of the transmembrane domain (TMD) of three SLC4 transporters, including AE1, have been resolved previously in their outward-facing (OF) state, no mammalian SLC4 structure has been reported in the inward-facing (IF) conformation. Here we present the cryoEM structures of full-length bovine AE1 with its TMD captured in both IF and OF conformations. Remarkably, both IF-IF homodimers and IF-OF heterodimers were detected. The IF structures feature downward movement in the core domain with significant unexpected elongation of TM11. Molecular modeling and structure guided mutagenesis confirmed the functional significance of residues involved in TM11 elongation. Our data provide direct evidence for an elevator-like mechanism of ion transport by an SLC4 family member.

Evaluation of urinary acidification in children: Clinical utility.

The kidney plays a fundamental role in acid-base homeostasis by reabsorbing the filtered bicarbonate and by generating new bicarbonate, to replace that consumed in the buffering of non-volatile acids, a process that leads to the acidification of urine and the excretion of ammonium (NH4 +). Therefore, urine pH (UpH) and urinary NH4 + (UNH4 +) are valuable parameters to assess urinary acidification. The adaptation of automated plasma NH4 + quantification methods to measure UNH4 + has proven to be an accurate and feasible technique, with diverse potential indications in clinical practice. Recently, reference values for spot urine NH4 +/creatinine ratio in children have been published. UpH and UNH4 +, aside from their classical application in the study of metabolic acidosis, have shown to be useful in the identification of incomplete distal renal tubular acidosis (dRTA), an acidification disorder, without overt metabolic acidosis, extensively described in adults, and barely known in children, in whom it has been found to be associated to hypocitraturia, congenital kidney abnormalities and growth impairment. In addition, a low UNH4 + in chronic kidney disease (CKD) is a risk factor for glomerular filtration decay and mortality in adults, even in the absence of overt metabolic acidosis. We here emphasize on the need of measuring UpH and UNH4 + in pediatric population, establishing reference values, as well as exploring their application in metabolic acidosis, CKD and disorders associated with incomplete dRTA, including growth retardation of unknown cause.

Admission Serum Bicarbonate Predicts Adverse Clinical Outcomes in Hospitalized Cirrhotic Patients.

A low serum bicarbonate (SB) level is predictive of adverse outcomes in kidney injury, infection, and aging. Because the liver plays an important role in acid-base homeostasis and lactic acid metabolism, we speculated that such a relationship would exist for patients with cirrhosis. To assess the prognostic value of admission SB on adverse hospital outcomes, clinical characteristics were extracted and analyzed from a large electronic health record system. Patients were categorized based on admission SB (mEq/L) into 7 groups based on the reference range (22–25) into mildly (18–21), moderately (14–17), and severely (<14) decreased groups and mildly (26–29), moderately (30–33), and severely (>30) increased groups, and the relationship of SB category with the frequency of complications (acute kidney injury/hepatorenal syndrome, portosystemic encephalopathy, gastrointestinal bleeding, ascites, and spontaneous bacterial peritonitis) and hospital metrics (length of stay [LOS], admission to an intensive care unit [ICU], and mortality) was assessed. A total of 2,693 patients were analyzed. Mean SB was 22.9 ± 4.5 mEq/L. SB was within the normal range (22–25 mEq/L) in 1,072 (39.8%) patients, and 955 patients (36%) had a low SB. As the SB category decreased, the incidence of complications progressively increased (p < 0.001). Increased MELD-Na score and low serum albumin also correlated with frequency of complications (p < 0.001). As the SB category decreased, LOS, ICU admission, and mortality progressively increased (p < 0.001). On multivariate analysis, the association of decreased SB with higher odds of complications, LOS, ICU admission, and mortality persisted. Conclusion. Low admission SB in patients with cirrhosis is associated with cirrhotic complications, longer LOS, increased ICU admissions, and increased hospital mortality.

Slc4a8 in the Kidney: Expression, Subcellular Localization and Role in Acid Base Homeostasis and Salt Reabsorption

BackgroundThe sodium‐dependent bicarbonate transporter Slc4a8 (a.k.a NDCBE) mediates the co‐transport of sodium and bicarbonate in exchange for chloride. It is abundantly detected in the brain, with low expression levels in the kidney. The cell distribution and subcellular localization of Slc4a8 in the kidney and its role in acid/base and electrolyte homeostasis has been the subject of conflicting reports. There are no conclusive localization or functional studies to pinpoint the location and demonstrate the function of Slc4a8 in the kidney.MethodsMolecular techniques, including in situ hybridization and RT‐PCR, were performed on kidney sections and tagged epitopes were used to examine the membrane targeting of Slc4a8 in polarized kidney cells. Crispr/Cas9 was used to generate and examine Slc4a8 KO mice.ResultIn situ hybridization and Zonal distribution studies showed no expression for Slc4a8 (NDCBE) in the cortex or in cortical collecting ducts (CCD). Slc4a8 was predominantly detected in the outer and inner medullary collecting ducts (OMCD and IMCD), and was targeted to the basolateral membrane of osmotically tolerant MDCK cells when confocal microscopy images were acquired. Slc4a8 KO mice did not show any abnormal salt or bicarbonate wasting under baseline conditions or in response to bicarbonate loading, salt restriction or furosemide‐induced diuresis.ConclusionsSlc4a8 (NDCBE) is absent in the CCD and is predominantly localized on the basolateral membrane of medullary collecting duct cells. Further, Slc4a8 deletion does not cause any acid base or electrolyte abnormality in pathophysiologic states such as furosemide‐induced salt wasting or salt restriction. We suggest that Slc4a8 is likely involved in intracellular pH and volume regulation in medullary collecting duct cells.Support or Funding InformationMerit Review 5 I01 BX001000‐06 award from the Department of Veterans Affairs, and funds from the Center on Genetics of Transport and Epithelial Biology at the University of Cincinnati.

Role of Adaptor Proteins and Clathrin in the Trafficking of Human Kidney Anion Exchanger 1 (kAE1) to the Cell Surface

Kidney anion exchanger 1 (kAE1) plays an important role in acid-base homeostasis by mediating chloride/bicarbornate (Cl-/HCO3-) exchange at the basolateral membrane of α-intercalated cells in the distal nephron. Impaired intracellular trafficking of kAE1 caused by mutations of SLC4A1 encoding kAE1 results in kidney disease - distal renal tubular acidosis (dRTA). However, it is not known how the intracellular sorting and trafficking of kAE1 from trans-Golgi network (TGN) to the basolateral membrane occurs. Here, we studied the role of basolateral-related sorting proteins, including the mu1 subunit of adaptor protein (AP) complexes, clathrin and protein kinase D, on kAE1 trafficking in polarized and non-polarized kidney cells. By using RNA interference, co-immunoprecipitation, yellow fluorescent protein-based protein fragment complementation assays and immunofluorescence staining, we demonstrated that AP-1 mu1A, AP-3 mu1, AP-4 mu1 and clathrin (but not AP-1 mu1B, PKD1 or PKD2) play crucial roles in intracellular sorting and trafficking of kAE1. We also demonstrated colocalization of kAE1 and basolateral-related sorting proteins in human kidney tissues by double immunofluorescence staining. These findings indicate that AP-1 mu1A, AP-3 mu1, AP-4 mu1 and clathrin are required for kAE1 sorting and trafficking from TGN to the basolateral membrane of acid-secreting α-intercalated cells.

The Murine Cl-/HCO3- Exchanger Ae3 (Slc4a3) is Not Required for Acid-Base Balance but is Involved in Magnesium Handling by the Kidney

Background: The Slc4 family of bicarbonate transporters consists of several members, many of which are highly expressed in the kidney and play an important role in acid-base homeostasis. Among them are Ae1 (Slc4a1) and Ae2 (Slc4a2). Another member, Ae3 (Slc4a3), is suggested to be expressed in the kidney, however, its localization and impact on renal function is still unknown. Ae3 has also been implicated in the central control of breathing. Aims: Here, we analyzed the expression of Ae3 transcripts in isolated nephron segments and investigated systemic and renal acid-base homeostasis and renal electrolyte handling in the absence of Ae3, using a knock out mouse model. Methods: qPCR was used to localize Ae3 transcripts in the murine nephron, metabolic studies and whole body plethysmography to assess the role of Ae3 in renal functions. Results: Two Ae3 transcripts, the brain variant bAe3 and the cardiac variant cAe3, are expressed at low levels in the murine kidney. Although differentially distributed, they localize mostly to the distal nephron and renal collecting duct system. At baseline and after an acid challenge, mice deficient for Ae3 did not show major disturbances in renal acid-base excretion. Respiratory responses in whole body plethysmography to acid loading and CO2 and O2 challenges were normal. No major differences in renal electrolyte handling were discovered except for small changes in magnesium, potassium and sodium excretion after 7 days of acid loading. We therefore challenged mice with diets with high and low magnesium diets and found no differences in renal magnesium excretion but elevated expression of the Trpm6 magnesium channel in Ae3 KO mice. In conclusion, Ae3 is expressed in murine kidney at very low levels. Conclusions: Ae3 plays no role in systemic acid-base homeostasis but may modify renal magnesium handling inducing a higher expression of Trpm6.

Enzymatic Activity of Renal H-K-ATPase in the Outer Medullary Collecting Duct of Transgenic Mice

The H-K-ATPase (HKA), a potassium-dependent proton transporter in the outer medullary collecting duct (OMCD) plays an important role in acid-base homeostasis. The OMCD contains two HKA isoforms; gastric (HKAα1), dominant under normal dietary conditions (ND), and colonic (HKAα2), induced under a K-free diet (KD). The enzymatic activity (EA) of HKA in the OMCD is incompletely understood. The focus of the present study is elucidating the EA of the HKA in HKAα1 and HKAα2 knockout (KO) mice under ND and KD. KO mice were subjected to ND or KD for 10 days. Ten OMCD tubules were extracted, half placed in potassium-free media (Solution 2), half in potassium-containing media (Solution 3). Fluorescence measurements are based on the hydrolysis of ATP to ADP, coupled with the oxidation of NADH. ADP is determined by a decrease in NADH fluorescence. In K presence, NADH fluorescence of HKAα1 KO mice read 13.5 ± 0.7 ppm for ND and 10.3 ± 0.2 ppm for KD, indicating stimulation of the colonic isoform. HKAα2 KO mice averaged 6.8 ± 0.3 ppm for ND and 5.4 ± 0.3 ppm for KD in solution 2 (p p α2 isoform. A significant difference in ATP production in HKAα2 KO mice is likely due to enhanced EA of H-ATPase under potassium depletion.

The Function of Vacuolar ATPase (V-ATPase) a Subunit Isoforms in Invasiveness of MCF10a and MCF10CA1a Human Breast Cancer Cells

The vacuolar H(+) ATPases (V-ATPases) are ATP-driven proton pumps that transport protons across both intracellular and plasma membranes. Previous studies have implicated V-ATPases in the invasiveness of various cancer cell lines. In this study, we evaluated the role of V-ATPases in the invasiveness of two closely matched human breast cancer lines. MCF10a cells are a non-invasive, immortalized breast epithelial cell line, and MCF10CA1a cells are a highly invasive, H-Ras-transformed derivative of MCF10a cells selected for their metastatic potential. Using an in vitro Matrigel assay, MCF10CA1a cells showed a much higher invasion than the parental MCF10a cells. Moreover, this increased invasion was completely sensitive to the specific V-ATPase inhibitor concanamycin. MCF10CA1a cells expressed much higher levels of both a1 and a3 subunit isoforms relative to the parental line. Isoforms of subunit a are responsible for subcellular localization of V-ATPases, with a3 and a4 targeting V-ATPases to the plasma membrane of specialized cells. Knockdown of either a3 alone or a3 and a4 together using isoform-specific siRNAs inhibited invasion by MCF10CA1a cells. Importantly, overexpression of a3 but not the other a subunit isoforms greatly increased the invasiveness of the parental MCF10a cells. Similarly, overexpression of a3 significantly increased expression of V-ATPases at the plasma membrane. These studies suggest that breast tumor cells employ particular a subunit isoforms to target V-ATPases to the plasma membrane, where they function in tumor cell invasion.

Renal ammonia metabolism and transport.

Renal ammonia metabolism and transport mediates a central role in acid-base homeostasis. In contrast to most renal solutes, the majority of renal ammonia excretion derives from intrarenal production, not from glomerular filtration. Renal ammoniagenesis predominantly results from glutamine metabolism, which produces 2 NH4(+) and 2 HCO3(-) for each glutamine metabolized. The proximal tubule is the primary site for ammoniagenesis, but there is evidence for ammoniagenesis by most renal epithelial cells. Ammonia produced in the kidney is either excreted into the urine or returned to the systemic circulation through the renal veins. Ammonia excreted in the urine promotes acid excretion; ammonia returned to the systemic circulation is metabolized in the liver in a HCO3(-)-consuming process, resulting in no net benefit to acid-base homeostasis. Highly regulated ammonia transport by renal epithelial cells determines the proportion of ammonia excreted in the urine versus returned to the systemic circulation. The traditional paradigm of ammonia transport involving passive NH3 diffusion, protonation in the lumen and NH4(+) trapping due to an inability to cross plasma membranes is being replaced by the recognition of limited plasma membrane NH3 permeability in combination with the presence of specific NH3-transporting and NH4(+)-transporting proteins in specific renal epithelial cells. Ammonia production and transport are regulated by a variety of factors, including extracellular pH and K(+), and by several hormones, such as mineralocorticoids, glucocorticoids and angiotensin II. This coordinated process of regulated ammonia production and transport is critical for the effective maintenance of acid-base homeostasis.

Monitorização de eletrólitos urinários em pacientes críticos: estudo preliminar observacional

Intensive care unit survivors and non-survivors have distinct acid-base profiles. The kidney's regulation of urinary electrolytes and the urinary strong ion difference plays a major role in acid-base homeostasis. The aim of this study was to evaluate the potential utility of daily spot urinary electrolyte measurement in acid-base and renal function monitoring. We prospectively recorded daily plasma acid-base parameters and traditional markers of renal function in parallel with spot urinary electrolyte measurements in patients with urinary catheters admitted to our intensive care unit. Patients who remained in the intensive care unit for at least 4 days with a urinary catheter were included in the study. Of the 50 patients included in the study, 22% died during their intensive care unit stay. The incidence of acute kidney injury was significantly higher in non-survivors during the 4-day observation period (64% vs. 18% in survivors). Urinary chloride and sodium were lower and urinary strong ion difference was higher on day 1 in patients who developed acute kidney injury among both survivors and non-survivors. Both groups had similar urine output, although non-survivors had persistently higher urinary strong ion difference on all days. Survivors had a progressive improvement in metabolic acid-base profile due to increases in the plasma strong ion difference and decreases in weak acids. These changes were concomitant with decreases in urinary strong ion difference. In non-survivors, acid-base parameters did not significantly change during follow-up. Daily assessment of spot urinary electrolytes and strong ion difference are useful components of acid-base and renal function evaluations in critically ill patients, having distinct profiles between intensive care unit survivors and non-survivors.

Effect of hypokalemia on renal expression of the ammonia transporter family members, Rh B Glycoprotein and Rh C Glycoprotein, in the rat kidney

Hypokalemia is a common electrolyte disorder that increases renal ammonia metabolism and can cause the development of an acid-base disorder, metabolic alkalosis. The ammonia transporter family members, Rh B glycoprotein (Rhbg) and Rh C glycoprotein (Rhcg), are expressed in the distal nephron and collecting duct and mediate critical roles in acid-base homeostasis by facilitating ammonia secretion. In the current studies, the effect of hypokalemia on renal Rhbg and Rhcg expression was examined. Normal Sprague-Dawley rats received either K(+)-free or control diets for 2 wk. Rats receiving the K(+)-deficient diet developed hypokalemia and metabolic alkalosis associated with significant increases in both urinary ammonia excretion and urine pH. Rhcg expression increased in the outer medullary collecting duct (OMCD). In OMCD intercalated cells, hypokalemia resulted in more discrete apical Rhcg expression and a marked increase in apical plasma membrane immunolabel. In principal cells, in the OMCD, hypokalemia increased both apical and basolateral Rhcg immunolabel intensity. Cortical Rhcg expression was not detectably altered by immunohistochemistry, although there was a slight decrease in total expression by immunoblot analysis. Rhbg protein expression was decreased slightly in the cortex and not detectably altered in the outer medulla. We conclude that in rat OMCD, hypokalemia increases Rhcg expression, causes more polarized apical expression in intercalated cells, and increases both apical and basolateral expression in the principal cell. Increased plasma membrane Rhcg expression in response to hypokalemia in the rat, particularly in the OMCD, likely contributes to the increased ammonia excretion and thereby to the development of metabolic alkalosis.

Cloning, localization, and functional expression of the electrogenic Na+ bicarbonate cotransporter (NBCe1) from zebrafish

Mutations in the electrogenic Na+/nHCO3- cotransporter (NBCe1, SLC4A4) cause severe proximal renal tubular acidosis, glaucoma, and cataracts in humans, indicating NBCe1 has a critical role in acid-base homeostasis and ocular fluid transport. To better understand the homeostatic roles and protein ontogeny of NBCe1, we have cloned, localized, and downregulated NBCe1 expression in zebrafish, and examined its transport characteristics when expressed in Xenopus oocytes. Zebrafish NBCe1 (zNBCe1) is 80% identical to published mammalian NBCe1 cDNAs. Like other fish NBCe1 clones, zebrafish NBCe1 is most similar to the pancreatic form of mammalian NBC (Slc4a4-B) but appears to be the dominant isoform found in zebrafish. In situ hybridization of embryos demonstrated mRNA expression in kidney pronephros and eye by 24 h postfertilization (hpf) and gill and brain by 120 hpf. Immunohistochemical labeling demonstrated expression in adult zebrafish eye and gill. Morpholino knockdown studies demonstrated roles in eye and brain development and caused edema, indicating altered fluid and electrolyte balance. With the use of microelectrodes to measure membrane potential (Vm), voltage clamp (VC), intracellular pH (pH(i)), or intracellular Na+ activity (aNa(i)), we examined the function of zNBCe1 expressed in Xenopus oocytes. Zebrafish NBCe1 shared transport properties with mammalian NBCe1s, demonstrating electrogenic Na+ and HCO3- transport as well as similar drug sensitivity, including inhibition by 4,4'-diiso-thiocyano-2,2'-disulfonic acid stilbene and tenidap. These data indicate that NBCe1 in zebrafish shares many characteristics with mammalian NBCe1, including tissue distribution, importance in systemic water and electrolyte balance, and electrogenic transport of Na+ and HCO3-. Thus zebrafish promise to be useful model system for studies of NBCe1 physiology.

Comparison of pH-dependence of Carbonic Anhydrase Activity in vitro and in Living Cells

Carbonic anhydrase (CA) plays an important role in acid-base homeostasis. It catalyses carbonic buffering, increases intracellular H+-mobility and facilitates the activity of pHi regulatory transporters. In vitro, CA activity is known to be inhibited by a fall of pH. This observation has been largely overlooked when considering mechanisms of pHi regulation. There is no information, however, on the pH-sensitivity of CA in intact cells. We have therefore investigated the pH-sensitivity of CA both in vitro, and in situ in living cells. In vitro CA activity was assessed from the time-course of pH change after addition of CO2-saturated water to a buffered solution (pH 8.0-6.5) containing purified bovine CA2, membrane fragments of HCT116 cells stably transfected with CA9, or cardiac homogenates from rat ventricle. In situ CA activity was assessed from the rate of CO2-induced fall of pHi in rat superfused ventricular myocytes, AM-loaded with the pH-fluorophore, carboxy-SNARF-1. The pH-sensitivity was estimated by fitting a kinetic algorithm to the pH time-course data. Results show that both in vitro and in situ CA-activity displays strong pH-dependence, activity declining with a fall of pH. Apparent pK and Hill coefficient (nH) values for in vitro pH-dependence were 7.00 and 1.10 respectively for purified CA2, 6.85 & 1.73 for CA9, and 7.15 and 0.80 for cardiac homogenates. The intracellular pKa and nH values for generic cardiac CA were 7.20 and 2.50. These results imply that the enzyme's contribution to both intracellular and extracellular pH-regulation may vary dynamically over the physiological pH range. Work funded by British Heart Foundation, Cancer Research UK, and Royal Society.

Acid-Base Disturbances in Gastrointestinal Disease

Disruption of normal gastrointestinal function as a result of infection, hereditary or acquired diseases, or complications of surgical procedures uncovers its important role in acid-base homeostasis. Metabolic acidosis or alkalosis may occur, depending on the nature and volume of the unregulated losses that occur. Investigation into the specific pathophysiology of gastrointestinal disorders has provided important new insights into the normal physiology of ion transport along the gut and has also provided new avenues for treatment. This review provides a brief overview of normal ion transport along the gut and then discusses the pathophysiology and treatment of the metabolic acid-base disorders that occur when normal gut function is disrupted.

Regulation of renal amino acid transporters during metabolic acidosis

The kidney plays a major role in acid-base homeostasis by adapting the excretion of acid equivalents to dietary intake and metabolism. Urinary acid excretion is mediated by the secretion of protons and titratable acids, particularly ammonia. NH(3) is synthesized in proximal tubule cells from glutamine taken up via specific amino acid transporters. We tested whether kidney amino acid transporters are regulated in mice in which metabolic acidosis was induced with NH(4)Cl. Blood gas and urine analysis confirmed metabolic acidosis. Real-time RT-PCR was performed to quantify the mRNAs of 16 amino acid transporters. The mRNA of phosphoenolpyruvate carboxykinase (PEPCK) was quantified as positive control for the regulation and that of GAPDH, as internal standard. In acidosis, the mRNA of kidney system N amino acid transporter SNAT3 (SLC38A3/SN1) showed a strong induction similar to that of PEPCK, whereas all other tested mRNAs encoding glutamine or glutamate transporters were unchanged or reduced in abundance. At the protein level, Western blotting and immunohistochemistry demonstrated an increased abundance of SNAT3 and reduced expression of the basolateral cationic amino acid/neutral amino acid exchanger subunit y(+)-LAT1 (SLC7A7). SNAT3 was localized to the basolateral membrane of the late proximal tubule S3 segment in control animals, whereas its expression was extended to the earlier S2 segment of the proximal tubule during acidosis. Our results suggest that the selective regulation of SNAT3 and y(+)LAT1 expression may serve a major role in the renal adaptation to acid secretion and thus for systemic acid-base balance.

H +-ATPase activity in selective disruption of H +-K +-ATPase alpha 1 gene of mice under normal and K-depleted conditions

The outer medullary collecting duct (OMCD) plays an important role in acid-base homeostasis by two luminal proton ATPases, H(+)-ATPase and H(+)-K(+)-ATPase (HKA), both of which are in the intercalated cells (ICs) of OMCD. We showed previously that HKAalpha1 (gastric H(+)-K(+)-ATPase) activity is the essential H(+)-K(+)-ATPase activity under normal conditions, and that HKAalpha2 (colonic H(+)-K(+)-ATPase) is induced and mediates increased proton-secretion under K-depleted conditions. To better understand the role of H(+)-ATPase (potassium-independent) in acid secretion and the relationship between H(+)-ATPase and a specific HKA isoform, we examined H(+)-ATPase activity in the H(+)-K(+)-ATPasealpha1 knockout (KO) mice under normal and K-depleted conditions. Mice were fed a potassium-free diet and studied after 7 days. Segments of the OMCD were perfused in vitro, and intracellular pH (pH(i)) was measured by ratiometric fluorescence microscopy using the pH-sensitive indicator BCECF-AM. The isolated OMCD tubules obtained from mice fed a potassium-free diet were examined by fluorescent immunocytochemistry with an antibody to the 31-kDa subunit of H(+)-ATPase (E-11) and were compared with those obtained from a normal diet. In the absence of Na(+) and K(+), the H(+)-ATPase-mediate pH(i) recovery rates were 6.7 +/- 1.1 x 10(-4) units/s (n = 7 ICs) in wild-type (WT) mice and increased to 8.7 +/- 1.8 x 10(-4) (P < 0.05; n = 6) in HKAalpha1 KO mice. K-independent proton transport activity was significantly inhibited by the H(+)-ATPase inhibitor bafilomycin A(1) (BAF, 10 nM) with luminal applied in both WT and KO mice. Comparison of the results indicated upregulation of BAF-sensitive H(+)-ATPase activity in KO mice. To determine the intracellular localization of H(+)-ATPase in the intercalated cells of OMCD, we dissected the OMCD and performed fluorescent immunocytochemistry with the H(+)-ATPase antibody in the WT and KO mice. In the WT mice, on normal diet, H(+)-ATPase staining distributed diffusely throughout the intercalated cells and was slightly polarized to the apical plasma membrane in the KO mice, consistent with increase in the H(+)-ATPase-mediate pH(i) recovery in the KO mice. One week of a potassium-free diet resulted in a significant increase in the degree of H(+)-ATPase polarization at the apical plasma membrane in both WT and KO mice. Hypokalemia stimulates H(+)-ATPase in the intercalated cells of OMCD of both WT and KO mice. The enhanced activity of H(+)-ATPase plays an important role in compensatory proton secretion in the HKAalpha1 KO mice under normal conditions.

Selective Assembly of V-ATPase Subunit Isoforms in Mouse Kidney

The kidney plays vital roles in acid-base homeostasis, and the reabsorption of water, ions, and proteins. These processes are achieved through acidification of urine and endosomes of proximal tubule epithelial cells. Multisubunit vacuolar-type proton ATPase (V-ATPase) is one of the major acidification-machinery proteins that localizes to the apical or basolateral plasma membranes of intercalated cells in collecting ducts and the endosomal region at the base of brush border microvilli in proximal tubules. Multiple subunit isoforms of V-ATPase, which are expressed in kidney, have been identified. One obvious question is whether the pumps at different locations in the kidney have their own unique subunit identities. We have used a combination of methods to study this enzyme in kidney including immunocytochemical staining and immunoprecipitation analyses. The subunit isoforms of V-ATPase exhibited selective association/assembly in kidney: kidney-specific isoforms predominantly formed the intercalated cell proton pump, whereas the pump located in the brush border comprised ubiquitously expressed counterparts.

PH sensing in the two-pore domain K+ channel, TASK2.

TASK2 is a member of the two-pore domain K(+) channel family that plays a role in acid-base homeostasis; TASK2 knockout animals have plasma electrolyte patterns typical of the human clinical condition of renal tubular acidosis. It is expressed preferentially in epithelia, including the proximal tubules of the kidney. In common with the other TASK channels, TASK2 is sensitive to changes in extracellular pH, although the molecular mechanism of such pH sensing is not understood. We have examined the role of charged residues in the extracellular domains in pH sensing using a mutational approach. Mutant channels were expressed in CHO cells and studied by whole-cell and single-channel patch clamp. Neutralization of no single amino acid in isolation gave complete loss of pH sensitivity. However, the combined removal of five charged amino acids in the large extracellular loop linking the first transmembrane and pore domains, the M1-P1 loop, resulted in an essentially pH-insensitive channel, stabilized in the open state. Wild-type channels contain two such loops, but a concatemeric construct, comprised of one wild-type subunit and one containing the five mutations, was fully pH-sensitive, indicating that only one M1-P1 loop is required to yield a fully pH-sensitive channel, demonstrating a regulatory role of this distinctive structure in two-pore domain K(+) channels. Thus, pH sensing in TASK2 channels is conferred by the combined action of several charged residues in the large extracellular M1-P1 loop.

Novel Schering and ouabain-insensitive potassium-dependent proton secretion in the mouse cortical collecting duct.

The intercalated (IC) cells of the cortical collecting duct (CCD) are important to acid-base homeostasis by secreting acid and reabsorbing bicarbonate. Acid secretion is mediated predominantly by apical membrane Schering (SCH-28080)-sensitive H(+)-K(+)- ATPase (HKA) and bafilomycin-sensitive H(+)-ATPase. The SCH-28080-sensitive HKA is believed to be the gastric HKA (HKAg). Here we examined apical membrane potassium-dependent proton secretion in IC cells of wild-type HKAg (+/+) and HKAg knockout (-/-) mice to determine relative contribution of HKAg to luminal proton secretion. The results demonstrated that HKAg (-/-) and wild-type mice had comparable rates of potassium-dependent proton secretion, with HKAg (-/-) mice having 100% of K(+)-dependent H(+) secretion vs. wild-type mice. Potassium-dependent proton secretion was resistant to ouabain and SCH-28080 in HKAg knockout mice but was sensitive to SCH-28080 in wild-type animals. Northern hybridizations did not demonstrate any upregulation of colonic HKA in HKAg knockout mice. These data indicate the presence of a previously unrecognized K(+)-dependent SCH-28080 and ouabain-insensitive proton secretory mechanism in the cortical collecting tubule that may play an important role in acid-base homeostasis.