Cytoplasmic location of amino acids 359-440 of the Neurospora crassa plasma membrane H(+)-ATPase.

The topographic location of the region comprising amino acids 359-440 of the Neurospora crassa plasma membrane H(+)-ATPase has been elucidated using reconstituted proteoliposomes and protein chemical techniques. Proteoliposomes containing H(+)-ATPase molecules oriented predominantly with their cytoplasmic surface facing outward were cleaved with trypsin and the resulting digest was subjected to centrifugation on a glycerol step gradient to separate the released and liposome-bound peptides. The released peptides were recovered in the upper regions of the step gradient, whereas the liposome-bound peptides were recovered near the 40% glycerol interface. The released peptides present in the upper fractions were reduced, 14C-carboxy-methylated, and then separated by high performance liquid chromatography. Two radioactive cysteine-containing peptides with retention times of about 162 and 182 min were identified as H(+)-ATPase peptides comprising residues Leu363-Lys379 and Leu388-Arg414, respectively, by comparison to standards prepared from the purified ATPase. This information thus establishes a cytoplasmic location for residues 359-418 in the H(+)-ATPase polypeptide chain. It also infers a cytoplasmic location for residues 419-440, since this stretch of amino acids is too short to cross the membrane and return between regions known to be cytoplasmically located. These results and the results of other recent experiments establish the topographical location of nearly all of the 919 residues in the H(+)-ATPase molecule.     

Identification of the membrane-embedded regions of the Neurospora crassa plasma membrane H(+)-ATPase.

Reconstituted proteoliposomes containing functional Neurospora crassa plasma membrane H(+)-ATPase molecules oriented predominantly with their cytoplasmic surface exposed were treated with trypsin and then subjected to Sepharose CL-6B column chromatography to remove the liberated peptides. The peptides remaining associated with the liposomes were then separated from the phospholipid by Sephadex LH-60 column chromatography and analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Six H(+)-ATPase peptides with approximate molecular masses of 7, 7.5, 8, 10, 14, and 21 kDa were found to be tightly associated with the liposomal membrane. Amino acid sequencing of the 7-, 7.5-, and 21-kDa peptides in the LH-60 eluate identified them as H(+)-ATPase fragments beginning at residues 99 or 100, 272, and 660, respectively. After further purification, the approximately 10- and 14-kDa peptides were also similarly identified as beginning at residues 272 and 660. The approximately 8-kDa fragment was purified further but could not be sequenced, presumably indicating NH2-terminal blockage. To identify which of the liposome-associated peptides are embedded in the membrane, H(+)-ATPase molecules in the proteoliposomes were labeled from the hydrophobic membrane interior with 3-(trifluoromethyl)-3-(m-[125I]iodophenyl)diazirine and cleaved with trypsin, after which the membrane-associated peptides were purified and assessed for the presence of label. The results indicate that the approximately 7-, 7.5-, and 21-kDa peptides are in contact with the lipid bilayer whereas the approximately 8-kDa peptide is not. Taken together with the results of our recent analyses of the peptides released from the proteoliposomes, this information establishes the transmembrane topography of nearly all of the 919 residues in the H(+)-ATPase molecule.     

Probing the structure of the Neurospora crassa plasma membrane H+-ATPase

The structure of the Neurospora crassa plasma membrane H⁺-ATPase has been investigated using a variety of chemical and physicochemical techniques. The transmembrane topography of the H⁺-ATPase has been elucidated by a direct, protein chemical approach. Reconstituted proteoliposomes containing purified H⁺-ATPase molecules oriented predominantly with their cytoplasmic surface facing outward were treated with trypsin, and the numerous peptides released were purified by HPLC and subjected to amino acid sequence analysis. In this way, seventeen released peptides were unequivocally identified as located on the cytoplasmic side of the membrane, and numerous intervening segments could be inferred to be cytoplasmically located by virtue of the fact that they are too short to cross the membrane and return between sequences established to be cytoplasmically located. Additionally, three large membrane-embedded segments of the H⁺-ATPase were isolated using our recently developed methods for purifying hydrophobic peptides, and identified by amino acid sequence analysis. This information established the topographical location of virtually all of the 919 residues in the H⁺-ATPase molecule, allowing the formulation of a reasonably detailed model for the transmembrane topography of the H⁺-ATPase polypeptide chain. Separate studies of the cysteine chemistry of the H⁺-ATPase have demonstrated the existence of a single disulfide bridge in the molecule, linking the NH₂- and COON-terminal membrane-embedded domains. And, analyses of the circular dichroism and infrared spectra of the purified H⁺-ATPase have elucidated the secondary structure composition of the molecule. A first-generation model for the tertiary structure of the H⁺-ATPase based on this information and other considerations is presented.     

Direct evidence for the cytoplasmic location of the NH2- and COOH-terminal ends of the Neurospora crassa plasma membrane H+-ATPase

Reconstituted proteoliposomes containing Neurospora plasma membrane H+-ATPase molecules oriented predominantly with their cytoplasmic portion facing outward have been used to determine the location of the NH2 and COOH termini of the H+-ATPase relative to the lipid bilayer. Treatment of the proteoliposomes with trypsin in the presence of the H+-ATPase ligands Mg2+, ATP, and vanadate produces approximately 97-, 95-, and 88-kDa truncated forms of the H+-ATPase similar to those already known to result from cleavage at Lys24, Lys36, and Arg73 at the NH2-terminal end of the molecule. These results establish that the NH2-terminal end of the H+-ATPase polypeptide chain is located on the cytoplasmic side of the membrane. Treatment of the same proteoliposome preparation with trypsin in the absence of ligands releases approximately 50 water-soluble peptides from the proteoliposomes. Separation of the released peptides by high performance liquid chromatography and spectral analysis of the purified peptides identified only a few peptides with the properties expected of a COOH-terminal, tryptic undecapeptide with the sequence SLEDFVVSLQR, and NH2-terminal amino acid sequence analysis identified this peptide among the possible candidates. Quantitative considerations indicate that this peptide must have come from H+-ATPase molecules oriented with their cytoplasmic portion facing outward, and could not have originated from a minor population of H+-ATPase molecules of reverse orientation. These results directly establish that the COOH-terminal end of the H+-ATPase is also located on the cytoplasmic side of the membrane. These findings are important for elucidating the topography of the membrane-bound H+-ATPase and are possibly relevant to the topography of other aspartyl-phosphoryl-enzyme intermediate ATPases as well.     

Monomers of the Neurospora plasma membrane H+-ATPase catalyze efficient proton translocation

Liposomes prepared by sonication of asolectin were fractionated by glycerol density gradient centrifugation, and the small liposomes contained in the upper region of the gradients were used for reconstitution of purified, radiolabeled Neurospora plasma membrane H+-ATPase molecules by our previously published procedures. The reconstituted liposomes were then subjected to two additional rounds of glycerol density gradient centrifugation, which separate the H+-ATPase-bearing proteoliposomes from ATPase-free liposomes by virtue of their greater density. The isolated H+-ATPase-bearing proteoliposomes in two such preparations exhibited a specific H+-ATPase activity of about 11 mumol of Pi liberated/mg of protein/min, which was approximately doubled in the presence of nigericin plus K+, indicating that a large percentage of the H+-ATPase molecules in both preparations were capable of generating a transmembrane protonic potential difference sufficient to impede further proton translocation. Importantly, quantitation of the number of 105,000-dalton ATPase monomers and liposomes in the same preparations by radioactivity determination and counting of negatively stained images in the electron microscope indicated ATPase monomer to liposome ratios of 0.97 and 1.06. Because every liposome in the preparations must have had at least one ATPase monomer, these ratios indicate that very few of the liposomes had more than one, and simple calculations show that the great majority of active ATPase molecules in the preparations must have been present as proton-translocating monomers. The results thus clearly demonstrate that 105,000-dalton monomers of the Neurospora plasma membrane H+-ATPase can catalyze efficient ATP hydrolysis-driven proton translocation.     

Chromaffin granule H(+)-ATPase has F1-like structure.

Isolated H(+)-ATPase from chromaffin granules was reconstituted into liposomes and the resultant proteoliposomes were further purified by Ficoll density gradient centrifugation. Studies by electron microscopy showed that proteoliposomes had particle structures (average diameter, about 10 nm) on their outer surface. These particles could be removed from the proteoliposomes by cold treatment. Immuno-electron microscopy showed that these particles were recognized by antibodies against the hydrophilic sector of the enzyme. These results indicate that the H(+)-ATPase has a peripheral membrane structure similar to that of F1-ATPase.     

Assessing hydrophobic regions of the plasma membrane H(+)-ATPase from Saccharomyces cerevisiae.

The hydrophobic, photoactivatable probe TID [3-trifluoromethyl-3-(m-[125I]iodophenyl)diazirine] was used to label the plasma membrane H(+)-ATPase from Saccharomyces cerevisiae. The H(+)-ATPase accounted for 43% of the total label associated with plasma membrane protein and incorporated 0.3 mol of [125I]TID per mol of 100 kDa polypeptide. The H(+)-ATPase was purified by octyl glucoside extraction and glycerol gradient centrifugation, and was cleaved by either cyanogen bromide digestion or limited tryptic proteolysis to isolate labeled fragments. Cyanogen bromide digestion resulted in numerous labeled fragments of mass less than 21 kDa. Seven fragments suitable for microsequence analysis were obtained by electrotransfer to poly(vinylidene difluoride) membranes. Five different regions of amino-acid sequence were identified, including fragments predicted to encompass both membrane-spanning and cytoplasmic protein structure domains. Most of the labeling of the cytoplasmic domain was concentrated in a region comprising amino acids 347 to 529. This catalytic region contains the site of phosphorylation and was previously suggested to be hydrophobic in character (Goffeau, A. and De Meis, L. (1990) J. Biol. 265, 15503-15505). Complementary labeling information was obtained from an analysis of limited tryptic fragments enriched for hydrophobic character. Six principal labeled fragments, of 29.6, 20.6, 16, 13.1, 11.4 and 9.7 kDa, were obtained. These fragments were found to comprise most of the putative transmembrane region and a portion of the cytoplasmic region that overlapped with the highly labeled active site-containing cyanogen bromide fragment. Overall, the extensive labeling of protein structure domains known to lie outside the bilayer suggests that [125I]TID labeling patterns cannot be unambiguously interpreted for the purpose of discerning membrane-embedded protein structure domains. It is proposed that caution should be applied in the interpretation of [125I]TID labeling patterns of the yeast plasma membrane H(+)-ATPase and that new and diverse approaches should be developed to provide a more definitive topology model.     

The amino and carboxyl termini of the Neurospora plasma membrane H+-ATPase are cytoplasmically located

Based on hydropathy analysis, the P-type cation translocating ATPases are believed to have similar topological arrangements in the membrane, but little independent evidence exists for their precise pattern of transmembrane folding. As a first step toward defining the topology of the Neurospora plasma membrane H+-ATPase, we have mapped the orientation of the amino and carboxyl termini. In three different types of experiments, both termini of the H+-ATPase were shown to be exposed at the cytoplasmic surface of the plasma membrane: 1) antibodies specific for the amino and carboxyl termini bound to permeabilized but not intact cells; 2) inside-out plasma membrane vesicles were approximately 100-fold more effective than intact cells in competing for antibody binding; and 3) trypsin, which is known to proteolyze three sites at the amino terminus and one site at the carboxyl terminus of the purified Neurospora H+-ATPase (Mandala, S. M., and Slayman, C. W. (1988) J. Biol. Chem. 263, 15122-15128), was found in the present study to cleave the same sites in inside-out plasma membrane vesicles but not in intact cells. These results indicate that the ATPase polypeptide traverses the membrane an even number of times, in support of a previously published topological model (Hager, K. M., Mandala, S. M., Davenport, J. W., Speicher, D. W., Benz, E. J., Jr., and Slayman, C. W. (1986) Proc. Natl. Acad. Sci. U. S. A. 83, 7693-7697).     

Measurement of steady-state Ca2+ pump current caused by purified Ca2(+)-ATPase of sarcoplasmic reticulum incorporated into a planar bilayer lipid membrane

The electrogenicity and some molecular properties of the sarcoplasmic reticulum Ca2+ pump protein were studied by measuring steady-state Ca2+ pump currents. Ca2(+)-ATPase protein was solubilized from rabbit skeletal muscle sarcoplasmic reticulum membrane preparations and purified by liquid chromatography. The purified Ca(+)-ATPase molecules were reconstituted into proteoliposomes and then incorporated by fusion into a planar bilayer lipid membrane. Short circuit currents across the planar membrane were detected when the ATPase molecules were activated by addition of ATP under optimal ionic conditions. Thus, the electrogenicity of the Ca2+ pump molecules was directly demonstrated. The amplitude of the pump current was dependent on the ATP concentration, and the relation was described by a Michaelis-Menten-type equation. The Michaelis constant was calculated to be 0.69 +/- 0.16 mM, which agrees well with the dissociation constant for a low affinity ATP-binding site deduced previously from the kinetics of ATP hydrolysis and from ATP binding.     

Chimeric domain analysis of the compatibility between H(+), K(+)-ATPase and Na(+),K(+)-ATPase beta-subunits for the functional expression of gastric H(+),K(+)-ATPase.

Gastric H(+),K(+)-ATPase consists of alpha-subunit with 10 transmembrane domains and beta-subunit with a single transmembrane domain. We constructed cDNAs encoding chimeric beta-subunits between the gastric H(+),K(+)-ATPase and Na(+),K(+)-ATPase beta-subunits and co-transfected them with the H(+),K(+)-ATPase alpha-subunit cDNA in HEK-293 cells. A chimeric beta-subunit that consists of the cytoplasmic plus transmembrane domains of Na(+),K(+)-ATPase beta-subunit and the ectodomain of H(+),K(+)-ATPase beta-subunit assembled with the H(+),K(+)-ATPase alpha-subunit and expressed the K(+)-ATPase activity. Therefore, the whole cytoplasmic and transmembrane domains of H(+),K(+)-ATPase beta-subunit were replaced by those of Na(+),K(+)-ATPase beta-subunit without losing the enzyme activity. However, most parts of the ectodomain of H(+),K(+)-ATPase beta-subunit were not replaced by the corresponding domains of Na(+), K(+)-ATPase beta-subunit. Interestingly, the extracellular segment between Cys(152) and Cys(178), which contains the second disulfide bond, was exchangeable between H(+),K(+)-ATPase and Na(+), K(+)-ATPase, preserving the K(+)-ATPase activity intact. Furthermore, the K(+)-ATPase activity was preserved when the N-terminal first 4 amino acids ((67)DPYT(70)) in the ectodomain of H(+),K(+)-ATPase beta-subunit were replaced by the corresponding amino acids ((63)SDFE(66)) of Na(+),K(+)-ATPase beta-subunit. The ATPase activity was abolished, however, when 4 amino acids ((76)QLKS(79)) in the ectodomain of H(+),K(+)-ATPase beta-subunit were replaced by the counterpart ((72)RVAP(75)) of Na(+),K(+)-ATPase beta-subunit, indicating that this region is the most N-terminal one that discriminates the H(+),K(+)-ATPase beta-subunit from that of Na(+), K(+)-ATPase.     

The mother-cell-membrane adenosine triphosphatase of sporulating Clostridium pasteurianum

1. Sporulation of Clostridium pasteurianum effects several changes in its proton-translocating cell-membrane H(+)-ATPase. Notable among these are the acquisition of susceptibility to activation by trypsin and a changed protein subunit composition. 2. A protein was isolated from the mother-cell membrane that inhibited the ATP phosphohydrolase activity of purified vegetative-cell-membrane H(+)-ATPase [BF(0)F(1) complex, which consists of soluble ATPase (BF(1)) and the proton-channel component (BF(0))] and rendered it susceptible to trypsin activation. 3. This trypsin-sensitive inhibitor protein had a molecular weight of 10000 and on sodium dodecyl sulphate/polyacrylamide-gel electrophoresis was indistinguishable from the novel protein subunit e of the mother-cell-membrane ATPase 4. In bacteriorhodopsin-containing everted membrane vesicles, the specific ATP synthetase activity of the mother-cell-membrane ATPase was significantly greater than that of the vegetative-cell-membrane ATPase. 5. Treatment with trypsin-sensitive inhibitor protein of artificial proteoliposomes containing bacteriorhodopsin and vegetative-cell-membrane H(+)-ATPase (BF(0)F(1)) significantly increased the specific ATP synthetase activity of this enzyme. 6. The ATP synthetase activity of crude cell-membrane preparations from cultures of Clostridium pasteurianum increased during that period in the course of sporulation when the membrane ATP phosphohydrolase was both most rapidly decreasing in specific activity and acquiring its susceptibility to activation by trypsin.     

Studies on the purified Na+,Mg(2+)-ATPase from Acholeplasma laidlawii B membranes: a differential scanning calorimetric study of the protein-phospholipid interactions

The purified Na+,Mg2(+)-ATPase from the Acholeplasma laidlawii B plasma membrane was reconstituted with dimyristoyl phosphatidylcholine and the lipid thermotropic phase behavior of the proteoliposomes formed was investigated by differential scanning calorimetry. The effect of this ATPase on the host lipid phase transition is markedly dependent on the amount of protein incorporated. At low protein/lipid ratios, the presence of increasing quantities of ATPase in the proteoliposomes increases the temperature and enthalpy while decreasing the cooperativity of the dimyristoyl phosphatidylcholine gel to liquid-crystalline phase transition. At higher protein/lipid ratios, the incorporation of increasing amounts of this enzyme does not further alter the temperature and cooperativity of the phospholipid chain-melting transition, but progressively and markedly decreases the transition enthalpy. Plots of lipid phase transition enthalpy versus protein concentration suggest that at the higher protein/lipid ratios each ATPase molecule removes approximately 1000 dimyristoyl phosphatidylcholine molecules from participation in the cooperative gel to liquid-crystalline phase transition of the bulk lipid phase. These results indicate that this integral transmembrane protein interacts in a complex, concentration-dependent manner with its host phospholipid and that such interactions involve both hydrophobic interactions with the lipid bilayer core and electrostatic interactions with the lipid polar head groups at the bilayer surface.     

Subunit composition of vacuolar membrane H(+)-ATPase from mung bean

The vacuolar H(+)-ATPase from mung bean hypocotyls was solubilized from the membrane with lysophosphatidycholine and purified by QAE-Toyopearl column chromatography. The purified ATPase was active only in the presence of exogenous phospholipid and was inhibited by nitrate, dicyclohexyl carbodiimide and Triton X-100, but not by vanadate or azide. Dodecyl sulfate/polyacrylamide gel electrophoresis of the purified ATPase yielded ten polypeptides of molecular masses of 68 kDa, 57 kDa, 44 kDa, 43 kDa, 38 kDa, 37 kDa 32 kDa, 16 kDa, 13 kDa and 12 kDa. All polypeptides remained in the peak activity fraction after glycerol density gradient centrifugation. Nine of them, excluding the 43-kDa polypeptide, comigrated in a polyacrylamide gradient gel in the presence of 0.1% Triton X-100. The 16-kDa polypeptide could be labeled with [14C]dicyclohexylcarbodiimide. The amino-terminal amino acid sequence of the isolated 68-kDa polypeptide generally agreed with that deduced from the cDNA for the carrot 69-kDa subunit [Zimniak, L., Dittrich, P., Gogarten, J. P., Kibak, H. & Taiz, L. (1988) J. Biol. Chem. 263, 9102-9112]. Thus, mung bean vacuolar H(+)-ATPase seems to consist of nine distinct subunits.     

Assembly and targeting of peripheral and integral membrane subunits of the yeast vacuolar H(+)-ATPase.

Previous purification and characterization of the yeast vacuolar proton-translocating ATPase (H(+)-ATPase) have indicated that it is a multisubunit complex consisting of both integral and peripheral membrane subunits (Uchida, E., Ohsumi, Y., and Anraku, Y. (1985) J. Biol. Chem. 260, 1090-1095; Kane, P. M., Yamashiro, C. T., and Stevens, T. H. (1989) J. Biol. Chem. 264, 19236-19244). We have obtained monoclonal antibodies recognizing the 42- and 100-kDa polypeptides that were co-purified with vacuolar ATPase activity. Using these antibodies we provide further evidence that the 42-kDa polypeptide, a peripheral membrane protein, and the 100-kDa polypeptide, an integral membrane protein, are genuine subunits of the yeast vacuolar H(+)-ATPase. The synthesis, assembly, and targeting of three of the peripheral subunits (the 69-, 60-, and 42-kDa subunits) and two of the integral membrane subunits (the 100- and 17-kDa subunits) were examined in mutant yeast cells containing chromosomal deletions in the TFP1, VAT2, or VMA3 genes, which encode the 69-, 60-, and 17-kDa subunits, respectively. The steady-state levels of the various subunits in whole cell lysates and purified vacuolar membranes were assessed by Western blotting, and the intracellular localization of the 60- and 100-kDa subunits was also examined by immunofluorescence microscopy. The results suggest that the assembly and/or the vacuolar targeting of the peripheral subunits of the yeast vacuolar H(+)-ATPase depend on the presence of all three of the 69-, 60-, and 17-kDa subunits. The 100-kDa subunit can be transported to the vacuole independently of the peripheral membrane subunits as long as the 17-kDa subunit is present; but in the absence of the 17-kDa subunit, the 100-kDa subunit appears to be both unstable and incompetent for transport to the vacuole.     

The ATP binding site of the yeast plasma membrane proton-translocating ATPase

Photoaffinity labeling of the active site of the yeast plasma membrane H(+)-ATPase has been studied with 2-azido-AMP and 2-azido-ATP. The ATPase activity of the enzyme decreases as the time of photolysis of the photoactive nucleotides in the presence of the enzyme increases. The covalent incorporation of [alpha-32P]2-azido-AMP into the enzyme and the inhibition of ATPase activity have comparable time courses. ATP protects the ATPase from incorporation of and photoinactivation by 2-azido-ATP or 2-azido-AMP. In the dark, 2-azido-ATP inhibits the ATPase at concentrations comparable to the apparent Michaelis constant for MgATP. After photolysis and proteolysis of the protein, three overlapping peptides labeled by the nucleotide analogues were purified by reversed-phase high performance liquid chromatography and sequenced. The peptides are derived from a region of the ATPase that is highly conserved in related cation pumps forming a phosphorylated intermediate during the catalytic cycle. Labeling with both nucleotide analogues occurs in peptides containing residues from aspartate 560 to lysine 566. The amino acids in this region conform to a consensus sequence for ATP binding derived from phosphofructokinase.     

Purification of the lactose:H+ carrier of Escherichia coli and characterization of galactoside binding and transport

The lactose carrier, a galactoside:H+ symporter in Escherichia coli, has been purified from cytoplasmic membranes by pre-extraction of the membranes with 5-sulfosalicylate, solubilization in dodecyl-O-beta-D-maltoside, Ecteola-column chromatography, and removal of residual impurities by anti-impurity antibodies. Subsequently, the purified carrier was reincorporated into E. coli phospholipid vesicles. Purification was monitored by tracer N-[3H]ethylmaleimide-labeled carrier and by binding of the substrate p-nitrophenyl-alpha-D-galactopyranoside. All purified carrier molecules were active in substrate binding and the purified protein was at least 95% pure by several criteria. Substrate binding to the purified carrier in detergent micelles and in reconstituted proteoliposomes yielded a stoichiometry close to one molecule substrate bound per polypeptide chain. Large unilamellar proteoliposomes (1-5-micron diameter) were prepared from initially small reconstituted vesicles by freeze-thaw cycles and low-speed centrifugation. These proteoliposomes catalyzed facilitated diffusion and active transport in response to artificially imposed electrochemical proton gradients (delta mu H+) or one of its components (delta psi or delta pH). Comparison of the steady-state level of galactoside accumulation and the nominal value of the driving gradients yielded cotransport stoichiometries up to 0.7 proton/galactoside, suggesting that the carrier protein is the only component required for active galactoside transport. The half-saturation constants for active uptake of lactose (KT = 200 microM) or beta-D-galactosyl-1-thio-beta-D-galactoside (KT = 50-80 microM) by the purified carrier were found to be similar to be similar to those measured in cells or cytoplasmic membrane vesicles. The maximum rate for active transport expressed as a turnover number was similar in proteoliposomes and cytoplasmic membrane vesicles (kcat = 3-4 s-1 for lactose) but considerably smaller than in cells (kcat = 40-60 s-1). Possible reasons for this discrepancy are discussed.     

Isolation and characterization of gastric microsomal glycoproteins. Evidence for a glycosylated beta-subunit of the H+/K(+)-ATPase.

Detergent-solubilization of hog gastric microsomal membrane proteins followed by affinity chromatography using wheat germ agglutinin or Ricinus communis I agglutinin resulted in the isolation of five glycoproteins with the apparent molecular masses on sodium dodecyl sulfate polyacrylamide gels of (in kDa): 60-80 (two glycoproteins sharing this molecular mass); 125-150; and 190-210. In the nonionic detergent Nonidet P-40 (NP-40), the 94 kDa H+/K(+)-ATPase was recovered exclusively in the lectin-binding fraction; however, in the cationic detergent dodecyltrimethylammonium bromide, most of the ATPase was recovered in the nonbinding fraction. Detection of glycoproteins either by periodic acid-dansyl hydrazine staining of carbohydrate in polyacrylamide gels or by Western blots probed with lectins indicated that the majority of the ATPase molecules are not glycosylated. In addition, in the absence of microsomal glycoproteins, the NP-40-solubilized ATPase does not bind to a lectin column. Taken together, these results suggest that the recovery of NP-40-solubilized ATPase in the lectin-binding fraction is due to its noncovalent interaction with a gastric microsomal glycoprotein. Immunoprecipitation of the ATPase from NP-40-solubilized microsomal membrane proteins resulted in the co-precipitation of a single 60-80 kDa glycoprotein. Characterization of the 60-80 kDa glycoprotein associated with the ATPase revealed that: it is a transmembrane protein; it has an apparent core molecular mass of 32 kDa; and, it has five asparagine-linked oligosaccharide chains. Given its similarity to the glycosylated beta-subunit of the Na+/K(+)-ATPase, this 60-80 kDa gastric microsomal glycoprotein is suggested to be a beta-subunit of the H+/K(+)-ATPase.     

Role of transmembrane segment M8 in the biogenesis and function of yeast plasma-membrane H(+)-ATPase

Of the four transmembrane helices (M4, M5, M6, and M8) that pack together to form the ion-binding sites of P(2)-type ATPases, M8 has until now received the least attention. The present study has used alanine-scanning mutagenesis to map structure-function relationships throughout M8 of the yeast plasma-membrane H(+)-ATPase. Mutant forms of the ATPase were expressed in secretory vesicles and at the plasma membrane for measurements of ATP hydrolysis and ATP-dependent H(+) pumping. In secretory vesicles, Ala substitutions at a cluster of four positions near the extracytoplasmic end of M8 led to partial uncoupling of H(+) transport from ATP hydrolysis, while substitution of Ser-800 (close to the middle of M8) by Ala increased the apparent stoichiometry of H(+) transport. A similar increase has previously been reported following the substitution of Glu-803 by Gln (Petrov, V. et al., J. Biol. Chem. 275:15709-15718, 2000) at a position known to contribute directly to Ca(2+) binding in the Ca(2+)-ATPase of sarcoplasmic reticulum (Toyoshima, C., et al., Nature 405: 647-655, 2000). Four other mutations in M8 interfered with H(+)-ATPase folding and trafficking to the plasma membrane; based on homology modeling, they occupy positions that appear important for the proper bundling of M8 with M5, M6, M7, and M10. Taken together, these results point to a key role for M8 in the biogenesis, stability, and physiological functioning of the H(+)-ATPase.     

Protein chemistry of the Neurospora crassa plasma membrane H+-ATPase

A highly effective procedure for fragmenting the Neurospora crassa plasma membrane H+-ATPase and purifying the resulting peptides is described. The enzyme is cleaved with trypsin to form a limit digest containing both hydrophobic and hydrophilic peptides, and the hydrophobic and hydrophilic peptides are then separated by extraction with an aqueous ammonium bicarbonate solution. The hydrophilic peptides are fractionated by Sephadex G-25 column chromatography into three pools, and the individual peptides in each pool are purified by high-performance liquid chromatography. The hydrophobic peptides are dissolved in neat trifluoroacetic acid (TFA), diluted with chloroform-methanol (1:1), and the hydrophobic peptide solution thus obtained is then fractionated by Sephadex LH-60 column chromatography in chloroform-methanol (1:1) containing 0.1% TFA. The recoveries in all of the above procedures are greater than 90%. The N-terminal amino acid sequences of three of the hydrophobic H+-ATPase peptides purified by this methodology have been determined, which establishes the position of these peptides in the 100,000 Da polypeptide chain by reference to the published gene sequence, and documents the sequencability of the hydrophobic peptides purified in this way. This methodology should facilitate the identification of a variety of amino acid residues important for the structure and function of the H+-ATPase molecule. Moreover, the overall strategy for working with the protein chemistry of the H+-ATPase should be applicable to other amphiphilic integral membrane proteins as well.     

Vacuolar H(+)-ATPase localized in plasma membranes of malaria parasite cells, Plasmodium falciparum, is involved in regional acidification of parasitized erythrocytes

Recent biochemical studies involving 2',7'-bis-(2-carboxyethyl)-5, 6-carboxylfluorescein (BCECF)-labeled saponin-permeabilized and parasitized erythrocytes indicated that malaria parasite cells maintain the resting cytoplasmic pH at about 7.3, and treatment with vacuolar proton-pump inhibitors reduces the resting pH to 6.7, suggesting proton extrusion from the parasite cells via vacuolar H(+)-ATPase (Saliba, K. J., and Kirk, K. (1999) J. Biol. Chem. 274, 33213-33219). In the present study, we investigated the localization of vacuolar H(+)-ATPase in Plasmodium falciparum cells infecting erythrocytes. Antibodies against vacuolar H(+)-ATPase subunit A and B specifically immunostained the infecting parasite cells and recognized a single 67- and 55-kDa polypeptide, respectively. Immunoelectron microscopy indicated that the immunological counterpart of V-ATPase subunits A and B is localized at the plasma membrane, small clear vesicles, and food vacuoles, a lower extent being detected at the parasitophorus vacuolar membrane of the parasite cells. We measured the cytoplasmic pH of both infected erythrocytes and invading malaria parasite cells by microfluorimetry using BCECF fluorescence. It was found that a restricted area of the erythrocyte cytoplasm near a parasite cell is slightly acidic, being about pH 6.9. The pH increased to pH 7.3 upon the addition of either concanamycin B or bafilomycin A(1), specific inhibitors of vacuolar H(+)-ATPase. Simultaneously, the cytoplasmic pH of the infecting parasite cell decreased from pH 7.3 to 7.1. Neither vanadate at 0.5 mm, an inhibitor of P-type H(+)-ATPase, nor ethylisopropylamiloride at 0.2 mm, an inhibitor of Na(+)/H(+)-exchanger, affected the cytoplasmic pH of erythrocytes or infecting parasite cells. These results constitute direct evidence that plasma membrane vacuolar H(+)-ATPase is responsible for active extrusion of protons from the parasite cells.