Molecular cloning and characterization of a novel form of the human vacuolar H+-ATPase e-subunit: an essential proton pump component

Several of the 13 subunits comprising mammalian H(+)-ATPases have multiple alternative forms, encoded by separate genes and with differing tissue expression patterns. These may play an important role in the intracellular localization and activity of H(+)-ATPases. Here we report the cloning of a previously uncharacterized human gene, ATP6V0E2, encoding a novel H(+)-ATPase e-subunit designated e2. We demonstrate that in contrast to the ubiquitously expressed gene encoding the e1 subunit (previously called e), this novel gene is expressed in a more restricted tissue distribution, particularly kidney and brain. We show by complementation studies in a yeast strain deficient for the ortholog of this subunit, that either form of the e-subunit is essential for proper proton pump function. The identification of this novel form of the e-subunit lends further support to the hypothesis that subunit differences may play a key role in the structure, site and function of H(+)-ATPases within the cell.     

The amino-terminal domain of the E subunit of vacuolar H(+)-ATPase (V-ATPase) interacts with the H subunit and is required for V-ATPase function

Vacuolar H(+)-ATPases (V-ATPases) are highly conserved proton pumps that couple hydrolysis of cytosolic ATP to proton transport out of the cytosol. Although it is generally believed that V-ATPases transport protons by a rotary catalytic mechanism analogous to that used by F(1)F(0)-ATPases, the structure and subunit composition of the central or peripheral stalk of the multisubunit complex are not well understood. We searched for proteins that bind to the E subunit of V-ATPase using the yeast two-hybrid assay and identified the H subunit as an interacting partner. Physical association between the E and H subunits of V-ATPase was confirmed in vitro by precipitation assays. Deletion mapping analysis revealed that a 78-amino acid fragment at the amino terminus of the E subunit was sufficient for binding to the H subunit. Expression of the amino-terminal fragments of the E subunits from human and yeast as dominant-negative mutants resulted in dramatic decreases in bafilomycin A(1)-sensitive ATP hydrolysis and proton transport activities of V-ATPase. Our data demonstrate the physiological significance of the interaction between the E and H subunits of V-ATPase and extend previous studies on the arrangement of subunits on the peripheral stalk of V-ATPase.     

CDC50 proteins are critical components of the human class-1 P4-ATPase transport machinery

Members of the P(4) subfamily of P-type ATPases catalyze phospholipid transport and create membrane lipid asymmetry in late secretory and endocytic compartments. P-type ATPases usually pump small cations and the transport mechanism involved appears conserved throughout the family. How this mechanism is adapted to flip phospholipids remains to be established. P(4)-ATPases form heteromeric complexes with CDC50 proteins. Dissociation of the yeast P(4)-ATPase Drs2p from its binding partner Cdc50p disrupts catalytic activity (Lenoir, G., Williamson, P., Puts, C. F., and Holthuis, J. C. (2009) J. Biol. Chem. 284, 17956-17967), suggesting that CDC50 subunits play an intimate role in the mechanism of transport by P(4)-ATPases. The human genome encodes 14 P(4)-ATPases while only three human CDC50 homologues have been identified. This implies that each human CDC50 protein interacts with multiple P(4)-ATPases or, alternatively, that some human P(4)-ATPases function without a CDC50 binding partner. Here we show that human CDC50 proteins each bind multiple class-1 P(4)-ATPases, and that in all cases examined, association with a CDC50 subunit is required for P(4)-ATPase export from the ER. Moreover, we find that phosphorylation of the catalytically important Asp residue in human P(4)-ATPases ATP8B1 and ATP8B2 is critically dependent on their CDC50 subunit. These results indicate that CDC50 proteins are integral part of the P(4)-ATPase flippase machinery.     

Thermus thermophilus membrane-associated ATPase. Indication of a eubacterial V-type ATPase

An ATPase with Mr of 360,000 was purified from plasma membranes of a thermophilic eubacterium Thermus thermophilus, and was characterized. ATP hydrolytic activity of the purified enzyme was extremely low, 0.07 mumol of Pi released mg-1 min-1, and it was stimulated up to 30-fold by bisulfite. The following properties of the enzyme indicate that it is not a usual F1-ATPase but that it belongs to the V-type ATPase family, another class of ATPases found in membranes of archaebacteria and eukaryotic endomembranes. Among its four kinds of subunits with approximate Mr values of 66,000 (alpha), 55,000 (beta), 30,000 (gamma), and 12,000 (delta), the alpha subunit had a similar molecular size to the catalytic subunits of the V-type ATPases but was significantly larger than the alpha subunit of F1-ATPases. ATP hydrolytic activity was not affected by azide, an inhibitor of F1-ATPases, but was inhibited by nitrate, an inhibitor of the V-type ATPase. N-terminal amino acid sequences determined for the purified alpha and beta subunits showed much higher similarity to those of the V-type ATPases than those of F1-ATPases. Thus the distribution of the V-type ATPase in the prokaryotic kingdom may not be restricted to archaebacteria.     

Inhibition of the coated vesicle proton pump and labeling of a 17,000-dalton polypeptide by N,N'-dicyclohexylcarbodiimide

N,N'-Dicyclohexylcarbodiimide (DCCD) inhibits 100% of proton transport and 80-85% of (Mg2+)-ATPase activity in clathrin-coated vesicles. Half-maximum inhibition of proton transport is observed at 10 microM DCCD after 30 min. Although treatment of the coated vesicle (H+)-ATPase with DCCD has no effect on ATP hydrolysis in the detergent-solubilized state, sensitivity of proton transport and ATPase activity to DCCD is restored following reconstitution into phospholipid vesicles. In addition, treatment of the detergent-solubilized enzyme with DCCD followed by reconstitution gives a preparation that is blocked in both proton transport and ATP hydrolysis. These results suggest that although the coated vesicle (H+)-ATPase can react with DCCD in either a membrane-bound or detergent-solubilized state, inhibition of ATPase activity is only manifested when the pump is present in sealed membrane vesicles. To identify the subunit responsible for inhibition of the coated vesicle (H+)-ATPase by DCCD, we have labeled the partially purified enzyme with [14C]DCCD. A single polypeptide of molecular weight 17,000 is labeled. The extremely hydrophobic nature of this polypeptide is indicated by its extraction with chloroform:methanol. The 17,000-dalton protein can be labeled to a maximum stoichiometry of 0.99 mol of DCCD/mol of protein with 100% inhibition of proton transport occurring at a stoichiometry of 0.15-0.20 mol of DCCD/mol of protein. Amino acid analysis of the chloroform:methanol extracted 17,000-dalton polypeptide reveals a high percentage of nonpolar amino acids. The similarity in properties of this protein and the DCCD-binding subunit of the coupling factor (H+)-ATPases suggests that the 17,000-dalton polypeptide may function as part of a proton channel in the coated vesicle proton pump.     

Molecular dissection of the C-terminal regulatory domain of the plant plasma membrane H+-ATPase AHA2: mapping of residues that when altered give rise to an activated enzyme.

The plasma membrane H+-ATPase is a proton pump belonging to the P-type ATPase superfamily and is important for nutrient acquisition in plants. The H+-ATPase is controlled by an autoinhibitory C-terminal regulatory domain and is activated by 14-3-3 proteins which bind to this part of the enzyme. Alanine-scanning mutagenesis through 87 consecutive amino acid residues was used to evaluate the role of the C-terminus in autoinhibition of the plasma membrane H+-ATPase AHA2 from Arabidopsis thaliana. Mutant enzymes were expressed in a strain of Saccharomyces cerevisiae with a defective endogenous H+-ATPase. The enzymes were characterized by their ability to promote growth in acidic conditions and to promote H+ extrusion from intact cells, both of which are measures of plasma membrane H+-ATPase activity, and were also characterized with respect to kinetic properties such as affinity for H+ and ATP. Residues that when altered lead to increased pump activity group together in two regions of the C-terminus. One region stretches from K863 to L885 and includes two residues (Q879 and R880) that are conserved between plant and fungal H+-ATPases. The other region, incorporating S904 to L919, is situated in an extension of the C-terminus unique to plant H+-ATPases. Alteration of residues in both regions led to increased binding of yeast 14-3-3 protein to the plasma membrane of transformed cells. Taken together, our data suggest that modification of residues in two regions of the C-terminal regulatory domain exposes a latent binding site for activatory 14-3-3 proteins.     

Isolation and characterization of a cDNA encoding the putative distal colon H+,K(+)-ATPase. Similarity of deduced amino acid sequence to gastric H+,K(+)-ATPase and Na+,K(+)-ATPase and mRNA expression in distal colon, kidney, and uterus.

A series of Northern blot hybridization experiments using probes derived from the rat gastric H+,K(+)-ATPase cDNA and the human ATP1AL1 gene revealed the presence of a 4.3-kilobase mRNA in colon that seemed likely to encode the distal colon H+,K(+)-ATPase, the enzyme responsible for K+ absorption in mammalian colon. A rat colon library was then screened using a probe from the ATP1AL1 gene, and cDNAs containing the entire coding sequence of a new P-type ATPase were isolated and characterized. The deduced polypeptide is 1036 amino acids in length and has an Mr of 114,842. The protein exhibits 63% amino acid identity to the gastric H+,K(+)-ATPase alpha-subunit and 63% identity to the three Na+,K(+)-ATPase alpha-subunit isoforms, consistent with the possibility that it is a K(+)-transporting ATPase. Northern blot analyses show that the 4.3-kilobase mRNA is expressed at high levels in distal colon; at much lower levels in proximal colon, kidney, and uterus; and at trace levels in heart and forestomach. The high mRNA levels in distal colon and the similarity of the colon pump to both gastric H+,K(+)- and Na+,K(+)-ATPases suggest that it is the distal colon H+,K(+)-ATPase. Furthermore, expression of its mRNA in kidney raises the possibility that the enzyme also corresponds to the H+,K(+)-ATPase that seems to play a role in K+ absorption and H+ secretion in the distal nephron.     

Structure of a plasma membrane H+-ATPase gene from the plant Arabidopsis thaliana

Physiological and biochemical studies have suggested that the plant plasma membrane H+-ATPase controls many important aspects of plant physiology, including growth, development, nutrient transport, and stomata movements. We have started the genetic analysis of this enzyme by isolating both genomic and cDNA clones of an H+-ATPase gene from Arabidopsis thaliana. The cloned gene is interrupted by 15 introns, and there is partial conservation of exon boundaries with respect to animal (Na+/K+)- and Ca2+-ATPases. In general, the relationship between exons and the predicted secondary and transmembrane structure of different ATPases with phosphorylated intermediate support a somewhat degenerate correspondence between exons and structural modules. The predicted amino acid sequence of the plant H+-ATPase is more closely related to fungal and protozoan H+-ATPases than to bacterial K+-ATPases or to animal (Na+/K+)-, (H+/K+)-, and Ca2+-ATPases. There is evidence for the existence of at least three isoforms of the plant H+-ATPase gene. These results open the way for a molecular approach to the structure and function of the plant proton pump.     

The COOH termini of NBC3 and the 56-kDa H+-ATPase subunit are PDZ motifs involved in their interaction

The electroneutralsodium bicarbonate cotransporter 3 (NBC3) coimmunoprecipitates fromrenal lysates with the vacuolar H⁺-ATPase. In renal type Aand B intercalated cells, NBC3 colocalizes with the vacuolarH⁺-ATPase. The involvement of the COOH termini of NBC3 andthe 56-kDa subunit of the proton pump in the interaction of theseproteins was investigated. The intact and modified COOH termini of NBC3 and the 56-kDa subunit of the proton pump were synthesized, coupled toSepharose beads, and used to pull down kidney membrane proteins. Boththe 56- and the 70-kDa subunits of the proton pump, as well as a PDZdomain containing protein Na⁺/H⁺ exchangerregulatory factor 1 (NHERF-1), were bound to the intact 18 amino acidNBC3 COOH terminus. A peptide truncated by five COOH-terminal aminoacids did not bind these proteins. Replacement of the COOH-terminalleucine with glycine blocked binding of both the proton pump subunitsbut did not affect binding of NHERF-1. The 18 amino acid COOH terminusof the 56-kDa subunit of the proton pump bound NHERF-1 and NBC3, butthe truncated and modified peptide did not. A complex of NBC3, the56-kDa subunit of the proton pump, and NHERF-1 was identified in ratkidney. The data indicate that the COOH termini of NBC3 and the 56-kDasubunit of the vacuolar proton pump are PDZ-interacting motifs that arenecessary for the interaction of these proteins. NHERF-1 is involved inthe interaction of NBC3 and the vacuolar proton pump.

     

Syntaxin isoform specificity in the regulation of renal H+-ATPase exocytosis

Intercalated and inner medullary collecting duct (IMCD) cells of the kidney mediate the transport of H+ by a plasma membrane H+-ATPase. The rate of H+ transport in these cells is regulated by exocytic insertion of H+-ATPase-laden vesicles into the apical membrane. We have shown that the exocytic insertion of proton pumps (H+-ATPase) into the apical membrane of rat IMCD cells, in culture, involves SNARE proteins (syntaxin (synt), SNAP-23, and VAMP). The membrane fusion complex observed in IMCD cells with the induction of proton pump exocytosis not only included these SNAREs but also the H+-ATPase. Based on these observations, we suggested that the targeting of these vesicles to the apical membrane is mediated by an interaction between the H+-ATPase and a specific t-SNARE. To evaluate this hypothesis, we utilized a "pull-down" assay in which we identified, by Western analysis, the proteins in a rat kidney medullary homogenate that complexed with glutathione S-transferase (GST) fusion syntaxin isoforms attached to Sepharose 4B-glutathione beads. The syntaxin isoforms employed were 1A, 1B, 2, 4, 5, and also 1A that was truncated to exclude the H3 SNARE binding domain (synt-1ADeltaH3). All full-length syntaxin isoforms formed complexes with SNAP-23 and VAMP. Neither GST nor synt-1ADeltaH3 formed complexes with these SNAREs. H+-ATPase (subunits E, a, and c) bound to syntaxin-1A and to a lesser extent to synt-1B but not to synt-1ADeltaH3 or synt-2, -4, and -5. In cultured IMCD cells transfected to express syntaxin truncated for the membrane binding domain (synt-DeltaC), expression of synt-1ADeltaC, but not synt-4DeltaC, inhibited H+-ATPase exocytosis. In conclusion, because all full-length syntaxins examined bound VAMP-2 and SNAP-23, but only non-H3-truncated syntaxin-1 bound H+-ATPase, and synt-1ADeltaC expression by intact IMCD cells inhibited H+-ATPase exocytosis, it is likely that the H+-ATPase binds directly to the H3 domain of syntaxin-1 and not through VAMP-2 or SNAP-23. Interaction between the syntaxin-1A and H+-ATPase is important in the targeted exocytosis of the proton pump to the apical membrane of intercalated cells.     

Interaction between aldolase and vacuolar H+-ATPase: evidence for direct coupling of glycolysis to the ATP-hydrolyzing proton pump

Vacuolar H(+)-ATPases (V-ATPases) are essential for acidification of intracellular compartments and for proton secretion from the plasma membrane in kidney epithelial cells and osteoclasts. The cellular proteins that regulate V-ATPases remain largely unknown. A screen for proteins that bind the V-ATPase E subunit using the yeast two-hybrid assay identified the cDNA clone coded for aldolase, an enzyme of the glycolytic pathway. The interaction between E subunit and aldolase was confirmed in vitro by precipitation assays using E subunit-glutathione S-transferase chimeric fusion proteins and metabolically labeled aldolase. Aldolase was isolated associated with intact V-ATPase from bovine kidney microsomes and osteoclast-containing mouse marrow cultures in co-immunoprecipitation studies performed using an anti-E subunit monoclonal antibody. The interaction was not affected by incubation with aldolase substrates or products. In immunocytochemical assays, aldolase was found to colocalize with V-ATPase in the renal proximal tubule. In osteoclasts, the aldolase-V-ATPase complex appeared to undergo a subcellular redistribution from perinuclear compartments to the ruffled membranes following activation of resorption. In yeast cells deficient in aldolase, the peripheral V(1) domain of V-ATPase was found to dissociate from the integral membrane V(0) domain, indicating direct coupling of glycolysis to the proton pump. The direct binding interaction between V-ATPase and aldolase may be a new mechanism for the regulation of the V-ATPase and may underlie the proximal tubule acidification defect in hereditary fructose intolerance.     

Cloning of cDNA encoding a 32-kDa protein. An accessory polypeptide of the H+-ATPase from chromaffin granules

The purified H+-ATPase from chromaffin granules is composed of several polypeptides, one of which has an apparent molecular weight of 39,000. Immunoblots with the antibody against this protein and various membrane preparations showed that similar or even identical polypeptides may be associated with the H+-ATPases from synaptic vesicle, kidney microsomes, and lysosomes. A cDNA library was constructed from bovine adrenal medulla, and the cDNA encoding the polypeptide was isolated and sequenced. Search in DNA and protein data banks revealed no significant homology to known genes. Hydrophobicity plot revealed no obvious transmembrane segments with the exception of one stretch of hydrophobic and neutral amino acid starting at leucine 16. The cDNA was shown to encode the entire polypeptide by the virtue of an amino acid sequence corresponding to the N terminus of the open reading frame and by subunit and site-specific antibodies. The cDNA was cloned into an expression vector, transcribed by T7 polymerase, and translated by reticulocyte lysate. Even though the cDNA encodes a protein with a molecular weight of 31,495, the translation product comigrated on sodium dodecyl sulfate gels with the subunit of the purified H+-ATPase. In line with several other subunits of vacuolar H+-ATPases, no signal sequence was detected in the translated gene. Northern blots revealed the presence of a single mRNA of about 1.6 kb in bovine adrenal medulla. However, liver, lung, and kidney may contain additional mRNA of about 1.7 kb.     

Cytosolic Concentration of Ca2+ Regulates the Plasma Membrane H+-ATPase in Guard Cells of Fava Bean

Opening of the stomata is driven by the light-activated plasma membrane proton pumping ATPase, although the activation and inactivation mechanism of the enzyme is not known. In this study, we show that the H+-ATPase in guard cells is reversibly inhibited by Ca2+ at physiological concentrations. Isolated microsomal membranes of guard cell protoplasts from fava bean exhibited vanadate-sensitive, ATP-dependent proton pumping. The activity was inhibited almost completely by 1 [mu]M Ca2+ with a half-inhibitory concentration at 0.3 [mu]M and was restored immediately by the addition of 1,2-bis(2-aminophenoxy)ethane N,N,N[prime],N[prime]-tetraacetic acid, a calcium chelating reagent. Similar reversible inhibition by Ca2+ was shown by the generation of electrical potential in the membranes. Activity of ATP hydrolysis was inhibited similarly by Ca2+ in the same membrane preparations. The addition of 1,2-bis(2-aminophenoxy)ethane N,N,N[prime],N[prime]-tetraacetic acid and EGTA, Ca2+ chelators, to epidermal peels of fava bean induced stomatal opening in the dark, and the opening was suppressed by vanadate. This suggests that the lowered cytosolic Ca2+ activated the proton pump in vivo and that the activated pump elicited stomatal opening. Inhibition of H+-ATPase by Ca2+ may depolarize the membrane potential and could be a key step in the process of stomatal closing through activation of the anion channels. Furthermore, similar inhibition of the proton pumping and ATP hydrolysis by Ca2+ was found in isolated plasma membranes of mesophyll cells of fava bean. These results suggest that Ca2+ regulates the activity of plasma membrane H+-ATPases in higher plant cells, thereby modulating stomatal movement and other cellular processes in plants.     

Studies on the Proton Pumping Activity of H+-ATPase in Tonoplast Vesicles of Populus euphratica

Tonoplast-enriched vesicles were prepared from suspension-cultured Populus euphratica Oliv. cells by differential centrifugation and discontinuous sucrose density gradient centrifugation. The properties of the proton pumping activity of H+-ATPases in tonoplast vesicles were studied by acridine orange fluorescent quenching measured at 22 ℃. The proton pumping activity of ATPase was ATP-dependent with apparent Michaelis-Menten Constant (Km) for ATP about 0.65 mmol/L. The optimal pH for H+-ATPases activity was 7.5. The proton pumping activity of H+-ATPase could be initiated by some divalent cations, Mg2+ being highly efficient, much more than Fe2+; and Ca2+, Cu2+ and Zn2+ were inefficient under the experimental condition. The proton translocation could be stimulated by halide anions, with potencies decreasing in the order Cl-> Br->I->F-. The proton pumping activity was greatly inhibited by N-ethylmaleimide (NEM), N,N′-dicyclohexylcarbodiimide (DCCD), NO-3 and Bafilomycin A1, but not by orthovanadate and azide. These results demonstrated that the H+-ATPase in the tonoplast of Populus euphratica belonged to vacuolar type ATPase. This work was the first time that tonoplast-enriched vesicles were isolated from Populus euphratica cells.     

A hybrid between Na+,K+-ATPase and H+,K+-ATPase is sensitive to palytoxin, ouabain, and SCH 28080

Na(+),K(+)-ATPase is inhibited by cardiac glycosides such as ouabain, and palytoxin, which do not inhibit gastric H(+),K(+)-ATPase. Gastric H(+),K(+)-ATPase is inhibited by SCH28080, which has no effect on Na(+),K(+)-ATPase. The goal of the current study was to identify amino acid sequences of the gastric proton-potassium pump that are involved in recognition of the pump-specific inhibitor SCH 28080. A chimeric polypeptide consisting of the rat sodium pump alpha3 subunit with the peptide Gln(905)-Val(930) of the gastric proton pump alpha subunit substituted in place of the original Asn(886)-Ala(911) sequence was expressed together with the gastric beta subunit in the yeast Saccharomyces cerevisiae. Yeast cells that express this subunit combination are sensitive to palytoxin, which interacts specifically with the sodium pump, and lose intracellular K(+) ions. The palytoxin-induced K(+) efflux is inhibited by the sodium pump-specific inhibitor ouabain and also by the gastric proton pump-specific inhibitor SCH 28080. The IC(50) for SCH 28080 inhibition of palytoxin-induced K(+) efflux is 14.3 +/- 2.4 microm, which is similar to the K(i) for SCH 28080 inhibition of ATP hydrolysis by the gastric H(+),K(+)-ATPase. In contrast, palytoxin-induced K(+) efflux from cells expressing either the native alpha3 and beta1 subunits of the sodium pump or the alpha3 subunit of the sodium pump together with the beta subunit of the gastric proton pump is inhibited by ouabain but not by SCH 28080. The acquisition of SCH 28080 sensitivity by the chimera indicates that the Gln(905)-Val(930) peptide of the gastric proton pump is likely to be involved in the interactions of the gastric proton-potassium pump with SCH 28080.     

Human nongastric H+-K+-ATPase: transport properties of ATP1al1 assembled with different beta-subunits

To investigate whether nongastric H+-K+-ATPases transport Na+ in exchange for K+ and whether different beta-isoforms influence their transport properties, we compared the functional properties of the catalytic subunit of human nongastric H+-K+-ATPase, ATP1al1 (AL1), and of the Na+-K+-ATPase alpha1-subunit (alpha1) expressed in Xenopus oocytes, with different beta-subunits. Our results show that betaHK and beta1-NK can produce functional AL1/beta complexes at the oocyte cell surface that, in contrast to alpha1/beta1 NK and alpha1/betaHK complexes, exhibit a similar apparent K+ affinity. Similar to Na+-K+-ATPase, AL1/beta complexes are able to decrease intracellular Na+ concentrations in Na+-loaded oocytes, and their K+ transport depends on intra- and extracellular Na+ concentrations. Finally, controlled trypsinolysis reveals that beta-isoforms influence the protease sensitivity of AL1 and alpha1 and that AL1/beta complexes, similar to the Na+-K+-ATPase, can undergo distinct K+-Na+- and ouabain-dependent conformational changes. These results provide new evidence that the human nongastric H+-K+-ATPase interacts with and transports Na+ in exchange for K+ and that beta-isoforms have a distinct effect on the overall structural integrity of AL1 but influence its transport properties less than those of the Na+-K+-ATPase alpha-subunit.     

The 40-kDa subunit enhances but is not required for activity of the coated vesicle proton pump.

We have previously demonstrated reassembly of a functional vacuolar (H+)-ATPase from clathrin-coated vesicles using the dissociated peripheral domain (V1) and the membrane-bound integral domain (V0) (Puopolo, K., and Forgac, M. (1990) J. Biol. Chem. 265, 14836-14841). We have used this reassembly procedure to test the function of the 40-kDa subunit of the coated vesicle (H+)-ATPase. In the absence of V0, a fraction of the peripheral subunits reassemble into a V1 subcomplex which contains the 73-kDa A subunit, the 58-kDa B subunit, and the 34- and 33-kDa subunits but lacks the 40-kDa subunit. This subcomplex, which sediments with a mass of approximately 500 kDa, can be separated from the remaining monomeric subunits (and the 40-kDa subunit) by density gradient sedimentation. When dissociated with 0.36 M KI, 2.5 mM ATP, and 2.5 mM MgSO4, and added to membranes from which V1 has been dissociated, this V1(-40 kDa) subcomplex is able to reassemble with V0 to give a (H+)-ATPase with a proton pumping activity approximately half that obtained in the presence of the 40-kDa subunit. The undissociated subcomplex is not competent for assembly of a functional (H+)-ATPase. Interestingly, the monomeric fraction obtained from density gradient sedimentation contains the 40-kDa subunit but lacks the 34-kDa subunit. This monomeric fraction is nevertheless also able to assemble with V0 to give a functional proton pump. The V1V0 complexes assembled in the absence of either the 40- or 34-kDa subunits, while active, are not stable to detergent solubilization and immunoprecipitation, suggesting that both of these subunits play a role in stabilization of the (H+)-ATPase complex. Evidence for interaction between the 40- and 33-kDa subunits is also presented.     

Knockdown of V-ATPase subunit A (atp6v1a) impairs acid secretion and ion balance in zebrafish (Danio rerio)

In the skin of zebrafish embryo, the vacuolar H(+)-ATPase (V-ATPase, H(+) pump) distributed mainly in the apical membrane of H(+)-pump-rich cells, which pump internal acid out of the embryo and function similarly to acid-secreting intercalated cells in mammalian kidney. In addition to acid excretion, the electrogenic H(+) efflux via the H(+)-ATPases in the gill apical membrane of freshwater fish was proposed to act as a driving force for Na(+) entry through the apical Na(+) channels. However, convincing molecular physiological evidence in vivo for this model is still lacking. In this study, we used morpholino-modified antisense oligonucleotides to knockdown the gene product of H(+)-ATPase subunit A (atp6v1a) and examined the phenotype of the mutants. The H(+)-ATPase knockdown embryos revealed several abnormalities, including suppression of acid-secretion from skin, growth retardation, trunk deformation, and loss of internal Ca(2+) and Na(+). This finding reveals the critical role of H(+)-ATPase in embryonic acid -secretion and ion balance, as well.