Kidney vacuolar H+ -ATPase: physiology and regulation

The vacuolar H(+)-ATPase is a multisubunit protein consisting of a peripheral catalytic domain (V(1)) that binds and hydrolyzes adenosine triphosphate (ATP) and provides energy to pump H(+) through the transmembrane domain (V(0)) against a large gradient. This proton-translocating vacuolar H(+)-ATPase is present in both intracellular compartments and the plasma membrane of eukaryotic cells. Mutations in genes encoding kidney intercalated cell-specific V(0) a4 and V(1) B1 subunits of the vacuolar H(+)-ATPase cause the syndrome of distal tubular renal acidosis. This review focuses on the function, regulation, and the role of vacuolar H(+)-ATPases in renal physiology. The localization of vacuolar H(+)-ATPases in the kidney, and their role in intracellular pH (pHi) regulation, transepithelial proton transport, and acid-base homeostasis are discussed.     

Actin binding activity of subunit B of vacuolar H+-ATPase is involved in its targeting to ruffled membranes of osteoclasts.

Adeno-associated virus was used to transduce primary mouse osteoclasts with the B1 isoform of vacuolar H(+)-ATPase. B1, which is not normally expressed in osteoclasts, was correctly targeted to ruffled membranes of resorbing osteoclasts. Mutant subunit B1 that lacked a functional actin-binding site did not accumulate in ruffled membranes. INTRODUCTION: The B1 "kidney" and B2 "brain" isoforms of subunit B of vacuolar H(+)-ATPase (V-ATPase) have actin binding sites that mediate interactions between the intact enzyme and filamentous-actin. Accumulating data support the hypothesis that the actin binding activity in subunit B is required for targeting of V-ATPases to the ruffled plasma membrane of osteoclasts. This study was designed to directly test this hypothesis. MATERIALS AND METHODS: Osteoclasts express B2, but not B1. Adeno-associated virus vectors were used to transduce mouse osteoclasts with wildtype B1 or B1(mut), a full-length B subunit that contained minor alterations that disrupted actin-binding activity. Immunofluorescence was performed using polyclonal antibodies specific for subunit E, B2, and B1 of V-ATPase. Immunoprecipitations were performed using an anti-E subunit antibody. Microfilaments were detected with phalloidin and actin rings were stained with phalloidin or anti-vinculin antibodies. Images were collected using a confocal microscope. RESULTS: Immunoprecipitations of transduced osteoclasts suggested that both B1 and B1(mut) assembled with endogenous V-ATPase subunits to form intact enzyme in osteoclasts. Both B1 and B1(mut) were localized like endogenous V-ATPase subunits in unactivated osteoclasts. Wildtype B1 associated with the detergent-insoluble cytoskeleton and was transported to ruffled membranes of resorbing osteoclasts. In contrast, B1(mut) failed to associate with the actin cytoskeleton and was not transported efficiently to ruffled membranes. CONCLUSIONS: The B1 isoform of B subunit contains the necessary information for targeting to the ruffled membranes of osteoclasts even though it is not normally expressed in osteoclasts. The actin binding activity of B1 is involved in proper ruffled membrane targeting.     

The effect of kidney transplantation on distal tubular vacuolar H+-ATPase

BACKGROUND: The presence of vacuolar (v)H+-ATPase in distal tubule alpha-intercalated cells is essential for hydrogen excretion and maintenance of acid-base homeostasis. Loss of vH+-ATPase after kidney transplantation could cause posttransplant distal renal tubular acidosis (dRTA). METHOD: Immunostaining of the kidney specific vH+-ATPase of cortical collecting duct cells (CCT) was performed in 37 kidney biopsies taken immediately prior to transplantation and after engraftment (median [range]: 10 [1-181] months). Apical or intracytoplasmatic staining intensity was classified as grade 0 (absent), grade 1 (weak), or grade 2 (strong), and positive cells expressed as percentage of all CCT cells. In addition, kidney biopsies were scored for damage by the Banff schema. Serum and urinary pH, anion gap, and serum potassium were obtained for the diagnoses of dRTA. RESULTS: Fourteen transplant recipients had dRTA type I, 5 had rate-limited RTA, six had type IV dRTA, and 12 had no RTA. In pretransplant biopsies, 40% [3-77%] of CCT cells were positive for vH+-ATPase but only 17% [0-39%] after transplantation (P<0.0001). The loss of vH+-ATPase expression was similar in patients with dRTA type I (-21%), type IV (-25%), rate limited RTA (-21%), or no RTA (-29%). The decrease affected predominantly the apical proton pump expression. The individual loss of vH+-ATPase expression was not related to the time elapsed since transplantation, immunosuppressive drugs, acute transplant rejection, or tubulointerstitial changes. CONCLUSION: Kidney transplantation leads to a general decrease of distal tubular vH+-ATPase expression. Loss of proton pump activity occurs unrelated to immunosuppressive therapy or transplant related histologic changes.     

Immunocytochemical localization of vacuolar H+-ATPase and Cl−-HCO 3 − anion exchanger (erythrocyte band-3 protein) in avian osteoclasts: Effect of calcium-deficient diet on polar expression of the H+-ATPase pump

Osteoclasts attach to the bone surface and resorb bone by secreting protons into an isolated subosteoclastic compartment. Previous studies have shown the presence of a vacuolar type H⁺-ATPase, and a functional Cl⁻-HCO ₃ ⁻ anion exchanger in the osteoclast. In the present studies, using a monoclonal antibody to the 31-kDa subunit of H⁺-ATPase and a rabbit antiserum to the erythrocyte band-3 protein (Cl⁻-HCO ₃ ⁻ anion exchanger) we have immunocytochemically localized the respective pumps in bone sections obtained from chickens fed a normal or a calcium-deficient diet for 4 weeks. Our results indicate that although H⁺-ATPase is either evenly distributed throughout the osteoclast or is more polarized at its ruffled membrane juxtaposed to the bone surface, the band-3 protein immunoreactivity is always localized to the plasma membrane which is not attached to the bone surface (basolateral membrane). Four weeks of a calcium-deficient diet resulted in a significant increase in the percentage of osteoclasts that were polarized for the H⁺-ATPase pump at their ruffled membrane, and a trend toward increased total number of osteoclasts, although the latter did not reach statistical significance (P =0.09). These changes were not accompanied by a significant increase in the intensity of staining for H⁺-ATPase. Band-3 protein immunoreactivity was always prominent, limited to the basolateral membrane, and did not alter with calcium-deficient diet or with changes in the degree of H⁺-ATPase polarization. Parts of this work have been presented in the American Society of Nephrology in November 1992     

A new regulator of the vacuolar H(+)-ATPase in the kidney

Xu et al. identify Slc26a11, a novel member of the Slc26 anion exchanger family, as an electrogenic (Cl(-))(n)/HCO(3)(-) exchanger. Functional characterization of this transporter suggests that Slc26a11 mediates classical electroneutral Cl(-)/HCO(3)(-) exchange but also exhibits an electrogenic Cl(-) conductance. In the kidney, Slc26a11 colocalizes with the vacuolar H(+)-ATPase in intercalated cells, emphasizing the cooperation of the proton pump with chloride transporters.     

The connecting tubule is the main site of the furosemide-induced urinary acidification by the vacuolar H+-ATPase

Final urinary acidification is achieved by electrogenic vacuolar H(+)-ATPases expressed in acid-secretory intercalated cells (ICs) in the connecting tubule (CNT) and the cortical (CCD) and initial medullary collecting duct (MCD), respectively. Electrogenic Na(+) reabsorption via epithelial Na(+) channels (ENaCs) in the apical membrane of the segment-specific CNT and collecting duct cells may promote H(+)-ATPases-mediated proton secretion by creating a more lumen-negative voltage. The exact localization where this supposed functional interaction takes place is unknown. We used several mouse models performing renal clearance experiments and assessed the furosemide-induced urinary acidification. Increasing Na(+) delivery to the CNT and CCD by blocking Na(+) reabsorption in the thick ascending limb with furosemide enhanced urinary acidification and net acid excretion. This effect of furosemide was abolished with amiloride or benzamil blocking ENaC action. In mice deficient for the IC-specific B1 subunit of the vacuolar H(+)-ATPase, furosemide led to only a small urinary acidification. In contrast, in mice with a kidney-specific inactivation of the alpha subunit of ENaC in the CCD and MCD, but not in the CNT, furosemide alone and in combination with hydrochlorothiazide induced normal urinary acidification. These results suggest that the B1 vacuolar H(+)-ATPase subunit is necessary for the furosemide-induced acute urinary acidification. Loss of ENaC channels in the CCD and MCD does not affect this acidification. Thus, functional expression of ENaC channels in the CNT is sufficient for furosemide-stimulated urinary acidification and identifies the CNT as a major segment in electrogenic urinary acidification.     

Angiotensin II stimulates vacuolar H+ -ATPase activity in renal acid-secretory intercalated cells from the outer medullary collecting duct

Final urinary acidification is mediated by the action of vacuolar H(+)-ATPases expressed in acid-secretory type A intercalated cells (A-IC) in the collecting duct. Angiotensin II (AngII) has profound effects on renal acid-base transport in the proximal tubule, distal tubule, and collecting duct. This study investigated the effects on vacuolar H(+)-ATPase activity in A-IC in freshly isolated mouse outer medullary collecting ducts. AngII (10 nM) stimulated concanamycin-sensitive vacuolar H(+)-ATPase activity in A-IC in freshly isolated mouse outer medullary collecting ducts via AT(1) receptors, which were also detected immunohistochemically in A-IC. AngII increased intracellular Ca(2+) levels transiently. Chelation of intracellular Ca(2+) with BAPTA and depletion of endoplasmic reticulum Ca(2+) stores prevented the stimulatory effect on H(+)-ATPase activity. The effect of AngII on H(+)-ATPase activity was abolished by inhibitors of small G proteins and phospholipase C, by blockers of Ca(2+)-dependent and -independent isoforms of protein kinase C and extracellular signal-regulated kinase 1/2. Disruption of the microtubular network and cleavage of cellubrevin attenuated the stimulation. Finally, AngII failed to stimulate residual vacuolar H(+)-ATPase activity in A-IC from mice that were deficient for the B1 subunit of the vacuolar H(+)-ATPase. Thus, AngII presents a potent stimulus for vacuolar H(+)-ATPase activity in outer medullary collecting duct IC and requires trafficking of stimulatory proteins or vacuolar H(+)-ATPases. The B1 subunit is indispensable for the stimulation by AngII, and its importance for stimulation of vacuolar H(+)-ATPase activity may contribute to the inappropriate urinary acidification that is seen in patients who have distal renal tubular acidosis and mutations in this subunit.     

Immunolocalization of NBC3 and NHE3 in the rat epididymis: colocalization of NBC3 and the vacuolar H+-ATPase

In the male reproductive tract, the epididymis plays an important role in mediating transepithelial bicarbonate transport and luminal acidification. In the proximal vas deferens, a significant component of luminal acidification is Na+-independent, and mediated by specific cells that possess apical vacuolar proton pumps. In contrast, luminal acidification in the cauda epididymidis is an Na+-dependent process. The specific apical Na+-dependent H+/base transport process(es) responsible for luminal acidification have not been identified. A potential clue as to the identity of these apical Na+-dependent H+/base transporter(s) is provided by similarities between the transport properties of the epididymis and the mammalian nephron. Specifically, the H+/base transport properties of caput epididymidis resemble the mammalian renal proximal tubule, whereas the distal epididymis and vas deferens have characteristics in common with renal collecting duct intercalated cells. Given the known expression of the Na+/H+ antiporter, NHE3, in the proximal tubule, and of the electroneutral sodium bicarbonate cotransporter, NBC3, in renal intercalated cells, we determined the localization of NHE3 and NBC3 in various regions of rat epididymis. NBC3 was highly expressed on the apical membrane of apical (narrow) cells in caput epididymidis, and light (clear) cells in corpus and cauda epididymidis. The number of cells expressing apical NBC3 was highest in cauda epididymidis. The localization of NBC3 in the epididymis was identical to the vacuolar H+-ATPase. The results indicate that colocalization of NBC3 and the vacuolar H+-ATPase is not restricted to kidney intercalated cells. Moreover, the close association of the two transporters appears to be a more generalized phenomenon in cells that express high levels of vacuolar H+-ATPase. Unlike NBC3, NHE3 was most highly expressed on the apical membrane of all epithelial cells in caput epididymidis, with less expression in the corpus, and no expression in the cauda. These results suggest that apical NBC3 and NHE3 potentially play an important role in mediating luminal H+/base transport in epididymis.     

囊泡型H+-ATPase B1 亚基的突变对大鼠内髓集合管细胞H+-ATPase结构和泵氢功能的影响

目的 研究致遗传性远端肾小管酸中毒（dRTA）的囊泡型H+-ATPase B1 亚基（ATP6V1B1）的点突变对大鼠内髓集合管（IMCD）细胞H+-ATPase结构和泵氢功能的影响。 方法 模拟致人类遗传性dRTA的 B1亚基点突变构建野生型（WT）和7种突变型（M)质粒,转染大鼠IMCD细胞并筛选稳定表达绿色荧光蛋白（GFP）-B1 M和GFP-B1 WT的IMCD细胞系。应用免疫荧光、免疫蛋白印迹法、ATP-NADH 耦合实验和快速酸负荷后不依赖钠的细胞内pH的变化,来观察GFP-B1 M和GFP-B1 WT在细胞内的分布,及其与H+-ATPase其他（E、H和c）亚基结合能力对ATP酶活性和H+-ATPase 泵氢功能的影响。 结果 GFP-B1 WT在转染细胞中呈囊泡样分布,与H+-ATPase的分布一致;而GFP-B1 M 则为弥散分布。免疫沉淀结果显示只有GFP-B1 WT融合蛋白能和其他的H+-ATPase 亚基（E、H和c）结合形成复合物,而 GFP-B1 M融合蛋白无此作用。ATP酶活性只有在GFP-B1 WT转染细胞株的免疫沉淀产物中存在,在GFP-B1 M转染细胞株的免疫沉淀产物中不存在。在GFP-B1 M 转染的IMCD细胞快速酸负荷后H+-ATPase介导的钠不依赖pHi 的恢复受到显著抑制[pHi的恢复率（pH U/min）在L81P、R124W、M174R、P275R、G316E、P346R、G364S GFP-B1M转染的IMCD细胞分别为0.007±0.002、0.004±0.002、0.002±0.002、0.003±0.002、0.006±0.004、0.009±0.004、0.015±0.006,P < 0.05,n = 5]。而GFP-B1 WT转染的IMCD细胞pHi的恢复率与未转染IMCD细胞相似[（0.040±0.006） pH U/min],且能被1 μmol/L巴弗洛霉素（H+-ATPase特异性抑制剂）所抑制。 结论 遗传性dRTA囊泡型H+-ATPase B1 亚基点突变影响GFP-B1融合蛋白与其他亚基正常结合组装形成完整的H+-ATPase,并抑制H+-ATPase 的泌酸功能。     

Angiotensin II activates H+-ATPase in type A intercalated cells

We reported previously that angiotensin II (AngII) increases net Cl(-) absorption in mouse cortical collecting duct (CCD) by transcellular transport across type B intercalated cells (IC) via an H(+)-ATPase-and pendrin-dependent mechanism. Because intracellular trafficking regulates both pendrin and H(+)-ATPase, we hypothesized that AngII induces the subcellular redistribution of one or both of these exchangers. To answer this question, CCD from furosemide-treated mice were perfused in vitro, and the subcellular distributions of pendrin and the H(+)-ATPase were quantified using immunogold cytochemistry and morphometric analysis. Addition of AngII in vitro did not change the distribution of pendrin or H(+)-ATPase within type B IC but within type A IC increased the ratio of apical plasma membrane to cytoplasmic H(+)-ATPase three-fold. Moreover, CCDs secreted bicarbonate under basal conditions but absorbed bicarbonate in response to AngII. In summary, angiotensin II stimulates H(+) secretion into the lumen, which drives Cl(-) absorption mediated by apical Cl(-)/HCO(3)(-) exchange as well as generates more favorable electrochemical gradient for ENaC-mediated Na(+) absorption.     

Localization of H+-ATPase and carbonic anhydrase II in ameloblasts at maturation

The localization of vacuolar-type H⁺-ATPase and carbonic anhydrase II (CA II) in rat incisor enamel organs at maturation was examined by light and electron microscopy. The immunoreactivity for both vacuolar-type H⁺-ATPase and CA II was intense on the ruffled border of ruffle-ended ameloblasts (RA), but moderate at the distal end of smooth-ended ameloblasts (SA). Immuno-gold particles indicated that CA II was not confined to the ruffled border of RA alone, but also distributed in the cytoplasm of RA and SA. These findings suggest that RA may secrete protons produced by CA II via the ruffled border into enamel by active transport of vacuolar-type H⁺-ATPase. Secreted protons may activate hydrolytic enzymes to degrade the organic components of enamel matrix. Vacuolar-type H⁺-ATPase on vesicles of SA suggests that a specific configuration of ruffled borders in RA may be formed by the fusion of vesicle membranes in the distal end of cytoplasm of SA.     

The gamma-Na+,K+-ATPase subunit assembles selectively with alpha1/beta1-Na+,K+-ATPase but not with the colonic H+,K+-ATPase

BACKGROUND: The ubiquitous Na+-pump (Na+,K+-ATPase) assembles as a heterodimer of composition alpha/beta in some nephron segments, while in other segments it may exist as a heterotrimer of composition alpha/beta/gamma. The gamma-subunit has been reported to increase the affinity of the Na+-pump for adenosine 5'-triphosphate (ATP), and decrease affinity for both Na+ and K+. The alpha-subunit of the colonic H+,K+-ATPase (cHK) shares 75% sequence similarity with alpha1-Na+,K+-ATPase (alpha1) and assembles with beta1-Na+,K+-ATPase (beta1) in distal colon and renal medulla. Differences in pharmacological properties have been ascribed to when heterologously expressed function has been compared to function in vitro. The purpose of this study was to determine if cHK might associate with the gamma-subunit of the Na+,K+-ATPase (gamma) as a possible explanation for these variations in function. METHODS: An antibody specific for the gamma was used in coimmunoprecipitation experiments to determine if the gamma assembles stably in vitro with cHK and beta1 in rat renal medulla or distal colon. RESULTS: Our results demonstrate that the gamma-subunit assembles specifically with the Na+-pump, but not with cHK. Furthermore, the gamma-subunit assembly was specific for rat kidney and was not observed in distal colon. CONCLUSION: Since the gamma-subunit did not assemble with the cHK/beta1 complex, gamma-subunit assembly cannot explain those variations in ex vivo and in vitro pharmacologic properties ascribed to cHK.     

NH4+ secretion in inner medullary collecting duct in potassium deprivation: role of colonic H+-K+-ATPase

NH4+ secretion in inner medullary collecting duct in potassium deprivation: Role of colonic H+-K+-ATPase. BACKGROUND: In K+ deprivation (KD), gastric (g) H+-K+-ATPase (HKA) is suppressed, whereas colonic (c) HKA is induced in the terminal inner medullary collecting duct (IMCD). We hypothesized that in KD, cHKA is induced and can mediate the secretion of NH4+. METHODS: Rats were sacrificed after 2, 3, 6, or 14 days on regular (NML) or K+-free (KD) diet. mRNA expression of HKA isoforms in terminal inner medulla was examined and correlated with NH4+ secretion in perfused IMCD in vitro. RESULTS: Urinary NH4+ excretion increased after K+-free diet for six days. In terminal inner medulla, cHKA expression was strongly induced, whereas gHKA expression was decreased. NH4+ secretion increased by 62% in KD (JtNH4+ 0.57 vs. 0.92 pmol/min/mm tubule length, P < 0.001). Ouabain (1 mM) in perfusate inhibited NH4+ secretion in KD by 45% (P < 0.002) but not in NML. At luminal pH 7.7, which inhibits NH3 diffusion, NH4+ secretion in IMCD was 140% higher in KD (0.36 vs. 0.15, P < 0.03) and was sensitive to ouabain. ROMK-1 mRNA expression was induced in parallel with cHKA in inner medulla. CONCLUSIONS: These data suggest that in KD, cHKA replaces gHKA and mediates enhanced secretion of NH4+ (and H+) into the lumen facilitated by K+ recycling through ROMK-1.     

Nongastric H+,K+-ATPase: cell biologic and functional properties.

Several members of the H+,K+-ATPase family of ion pumps participate in renal K transport. This class of P-type ATPases includes the gastric H+,K+-ATPase as well as a number of nongastric H+,K+-ATPase isoforms. Physiological studies suggest that these enzymes operate predominantly at the apical surfaces of tubule epithelial cells. Although much has been learned about the pattern of H+,K+-ATPase isoform expression and its response to stress, the functional and cell biologic attributes of these pumps remain largely unelucidated. We have studied the properties of renal H+,K+-ATPases both in vitro and in situ. Our analysis of ion fluxes driven by a nongastric H+,K+-ATPase isoform suggests that it exchanges Na (rather than H) for K under normal circumstances. Thus, the individual H+,K+-ATPase isoforms may make diverse contributions to renal cation transport. We find that the activities of renal H+,K+-ATPases in situ are regulated by endocytosis, which is mediated by an endocytosis signal in the cytoplasmic tail of the gastric H+,K+-ATPase beta-subunit. Transgenic mice expressing a version of this protein in which the signal has been disabled show constitutively active renal K resorption. The identities of the H+,K+-ATPase isoforms that are normally subject to endocytic regulation and the nature of the participating epithelial cell machinery have yet to be established.