Immunolocalization of the vacuolar-type (H+)-ATPase from clathrin-coated vesicles.

Proton-translocating ATPases of the vacuolar class (V-ATPases) are found in a variety of animal cell compartments that participate in vesicular membrane transport, including clathrin-coated vesicles, endosomes, the Golgi apparatus, and lysosomes. The exact structural relationship that exists among the V-ATPases of these intracellular compartments is not currently known. In the present study, we have localized the V-ATPase by light and electron microscopy, using monoclonal antibodies that recognize the V-ATPase present in clathrin-coated vesicles. Localization using light microscopy and fluorescently labeled antibodies reveals that the V-ATPase is concentrated in the juxtanuclear region, where extensive colocalization with the Golgi marker wheat germ agglutinin is observed. The V-ATPase is also present in approximately 60% of endosomes and lysosomes fluorescently labeled using alpha 2-macroglobulin as a marker for the receptor-mediated endocytic pathway. Localization using transmission electron microscopy and colloidal gold-labeled antibodies reveals that the V-ATPase is present at and near the plasma membrane, alone or in association with clathrin. These results provide evidence that the V-ATPases of plasma membrane, endosomes, lysosomes, and the Golgi apparatus are immunologically related to the V-ATPase of clathrin-coated vesicles.

Structure, function and regulation of the vacuolar (H+)-ATPases.

The vacuolar (H+)-ATPases (or V-ATPases) function to acidify intracellular compartments in eukaryotic cells, playing an important role in such processes as receptor-mediated endocytosis, intracellular membrane traffic, protein degradation and coupled transport. V-ATPases in the plasma membrane of specialized cells also function in renal acidification, bone resorption and cytosolic pH maintenance. The V-ATPases are composed of two domains. The V1 domain is a 570-kDa peripheral complex composed of 8 subunits (subunits A-H) of molecular weight 70-13 kDa which is responsible for ATP hydrolysis. The V0 domain is a 260-kDa integral complex composed of 5 subunits (subunits a-d) which is responsible for proton translocation. The V-ATPases are structurally related to the F-ATPases which function in ATP synthesis. Biochemical and mutational studies have begun to reveal the function of individual subunits and residues in V-ATPase activity. A central question in this field is the mechanism of regulation of vacuolar acidification in vivo. Evidence has been obtained suggesting a number of possible mechanisms of regulating V-ATPase activity, including reversible dissociation of V1 and V0 domains, disulfide bond formation at the catalytic site and differential targeting of V-ATPases. Control of anion conductance may also function to regulate vacuolar pH. Because of the diversity of functions of V-ATPases, cells most likely employ multiple mechanisms for controlling their activity.

Comparison of the coated-vesicle and synaptic-vesicle vacuolar (H+)-ATPases.

The V-ATPases are a novel class of ATP-dependent proton pumps responsible for acidification of intracellular compartments in eukaryotic cells. They play an important role in receptor-mediated endocytosis, intracellular membrane traffic, macromolecular processing and degradation and coupled transport, as well as functioning in the plasma membrane of certain specialized cell types. The V-ATPases are multisubunit complexes that are organized into a peripheral V1 complex responsible for ATP hydrolysis and an integral V0 domain responsible for proton translocation. Regulation of vacuolar acidification is critical to its role in membrane traffic and other cellular processes. We are currently investigating several mechanisms of regulation of vacuolar acidification, including disulfide bond formation between cysteine residues located at the catalytic site, control of assembly of the peripheral and integral domains, and differential targeting of V-ATPases to different intracellular destinations using their interaction with organelle-specific adaptin complexes.

Carbohydrate loading--a review.

The purpose of carbohydrate loading is to supersaturate with glycogen the muscles to be used in competition. The competition should be longer than 30 to 60 min. to fully utilize the glycogen stores. An exhausting exercise is first performed to deplete the glycogen stores, and a high-fat, high-protein diet is followed for three days to keep the glycogen stores low. After depletion of the muscles, a high-carbohydrate diet is followed for two to three days to restore and supersaturate the muscles with glycogen. The most important point to impress on the athlete is the nutritional adequacy of the entire diet. Though the technique of carbohydrate loading is a dietary manipulation emphasizing the intake of carbohydrate, the diet can be adequate with sound dietary planning.

Structure, function and regulation of the coated vesicle V-ATPase.

The coated vesicle V-ATPase plays an important role in both receptor-mediated endocytosis and intracellular membrane traffic by providing the acidic environment required for ligand-receptor dissociation and receptor recycling. The coated vesicle V-ATPase is a macromolecular complex of relative molecular mass 750,000 composed of nine subunits arranged in two structural domains. The peripheral V1 domain, which has a relative molecular mass of 500,000, has the subunit structure 73(3)58(3)40(1)34(1)33(1) and possesses all the nucleotide binding sites of the V-ATPase. The integral Vo domain of relative molecular mass 250,000 has a subunit composition of 100(1)38(1)19(1)17(6) and possesses the pathway for proton conduction across the membrane. Reassembly studies have allowed us to probe the role of specific subunits in the V-ATPase complex while chemical labeling studies have allowed us to identify specific residues which play a critical role in catalysis. From both structural analysis and sequence homology, the vacuolar-type H(+)-ATPases resemble the F-type H(+)-ATPases. Unlike the F1 and Fo domains of the F-type ATPases, however, the V1 and Vo domains do not appear to function independently. The possible relevance of these observations to the regulation of vacuolar acidification is discussed.

Structure and properties of the coated vesicle (H+)-ATPase.

Clathrin-coated vesicles play an important role in both receptor-mediated endocytosis and intracellular membrane traffic in eukaryotic cells. The coated vesicle (H+)-ATPase functions to provide the acidic environment within endosomes and other intracellular compartments necessary for receptor recycling and intracellular membrane traffic. The coated vesicle (H+)-ATPase is composed of nine different subunits which are divided into two distinct domains. The peripheral V1 domain, which has the structure 73(3):58(3):40(1):34(1):33(1), possesses the nucleotide binding sites of the (H+)-ATPase. The integral V0 domain, which has the composition 100(1):38(1):19(1):17(6), contains the pathway for proton conduction across the membrane. Topographical analysis indicates a structure for the coated vesicle (H+)-ATPase very similar to that of the F-type ATPases. Reassembly studies have allowed us to probe the function of particular subunits in this complex and the activity properties of the separate domains. These studies have led to insights into possible mechanisms of regulating vacuolar acidification.

Structure, mechanism and regulation of the clathrin-coated vesicle and yeast vacuolar H(+)-ATPases.

The vacuolar H(+)-ATPases (or V-ATPases) are a family of ATP-dependent proton pumps that carry out acidification of intracellular compartments in eukaryotic cells. This review is focused on our work on the V-ATPases of clathrin-coated vesicles and yeast vacuoles. The coated-vesicle V-ATPase undergoes trafficking to endosomes and synaptic vesicles, where it functions in receptor recycling and neurotransmitter uptake, respectively. The yeast V-ATPase functions to acidify the central vacuole and is necessary both for protein degradation and for coupled transport processes across the vacuolar membrane. The V-ATPases are multisubunit complexes composed of two functional domains. The V(1) domain is a 570 kDa peripheral complex composed of eight subunits of molecular mass 73-14 kDa (subunits A-H) that is responsible for ATP hydrolysis. The V(o) domain is a 260 kDa integral complex composed of five subunits of molecular mass 100-17 kDa (subunits a, d, c, c' and c") that is responsible for proton translocation. To explore the function of individual subunits in the V-ATPase complex as well as to identify residues important in proton transport and ATP hydrolysis, we have employed a combination of chemical modification, site-directed mutagenesis and in vitro reassembly. A central question concerns the mechanism by which vacuolar acidification is controlled in eukaryotic cells. We have proposed that disulfide bond formation between conserved cysteine residues at the catalytic site of the V-ATPase plays an important role in regulating V-ATPase activity in vivo. Other regulatory mechanisms that are discussed include reversible dissociation and reassembly of the V-ATPase complex, changes in the tightness of coupling between proton transport and ATP hydrolysis, differential targeting of V-ATPases within the cell and control of the Cl(-) conductance that is necessary for vacuolar acidification.

Structure and properties of the clathrin-coated vesicle and yeast vacuolar V-ATPases.

The V-ATPases are a family of ATP-dependent proton pumps responsible for acidification of intracellular compartments in eukaryotic cells. This review focuses on the the V-ATPases from clathrin-coated vesicles and yeast vacuoles. The V-ATPase of clathrin-coated vesicles is a precursor to that found in endosomes and synaptic vesicles, which function in receptor recycling, intracellular membrane traffic, and neurotransmitter uptake. The yeast vacuolar ATPase functions to acidify the central vacuole and to drive various coupled transport processes across the vacuolar membrane. The V-ATPases are composed of two functional domains. The V1 domain is a 570-kDa peripheral complex composed of eight subunits of molecular weight 70-14 kDa (subunits A-H) that is responsible for ATP hydrolysis. The V0 domain is a 260-kDa integral complex composed of five subunits of molecular weight 100-17 kDa (subunits a, d, c, c' and c") that is responsible for proton translocation. Using chemical modification and site-directed mutagenesis, we have begun to identify residues that play a role in ATP hydrolysis and proton transport by the V-ATPases. A central question in the V-ATPase field is the mechanism by which cells regulate vacuolar acidification. Several mechanisms are described that may play a role in controlling vacuolar acidification in vivo. One mechanism involves disulfide bond formation between cysteine residues located at the catalytic nucleotide binding site on the 70-kDa A subunit, leading to reversible inhibition of V-ATPase activity. Other mechanisms include reversible assembly and dissociation of V1 and V0 domains, changes in coupling efficiency of proton transport and ATP hydrolysis, and regulation of the activity of intracellular chloride channels required for vacuolar acidification.

The vacuolar H+-ATPase of clathrin-coated vesicles is reversibly inhibited by S-nitrosoglutathione.

It has been previously demonstrated that the vacuolar H+-ATPase (V-ATPase) of clathrin-coated vesicles is reversibly inhibited by disulfide bond formation between conserved cysteine residues at the catalytic site on the A subunit (Feng, Y., and Forgac, M. (1994) J. Biol. Chem. 269, 13224-13230). Proton transport and ATPase activity of the purified, reconstituted V-ATPase are now shown to be inhibited by the nitric oxide-generating reagent S-nitrosoglutathione (SNG). The K0.5 for inhibition by SNG following incubation for 30 min at 37 degreesC is 200-400 microM. As with disulfide bond formation at the catalytic site, inhibition by SNG is reversed upon treatment with 100 mM dithiothreitol and is partially protected in the presence of ATP. Also as with disulfide bond formation, treatment of the V-ATPase with SNG protects activity from subsequent inactivation by N-ethylmaleimide, as demonstrated by restoration of activity by dithiothreitol following sequential treatment of the V-ATPase with SNG and N-ethylmaleimide. Moreover, inhibition by SNG is readily reversed by dithiothreitol but not by the reduced form of glutathione, suggesting that the disulfide bond formed at the catalytic site of the V-ATPase may not be immediately reduced under intracellular conditions. These results suggest that SNG inhibits the V-ATPase through disulfide bond formation between cysteine residues at the catalytic site and that nitric oxide (or nitrosothiols) might act as a negative regulator of V-ATPase activity in vivo.

Characterization of a Mg2+-stabilized state of the (Na+ and K+)--stimulated adenosine triphosphatase using a fluorescent reporter group.

A Mg2+-induced change of the (Na+ and K+)-stimulated adenosine triphosphatase (Na+,K+)-ATPase) from Electrophorus electricus was investigated by kinetics and fluorescence techniques. Binding of Mg2+ to a low affinity site(s) caused inhibition of (Na+,K+)-ATPase activity, an effect which was antagonized by both Na+ and ATP. Mg2+ also caused inhibition of K+-dependent dephosphorylation of the enzyme without inhibiting either (Na+)-ATPase activity or Na+-dependent phosphorylation. Mg2+ also induced a 5 to 6% enhancement in the fluorescence intensity of enzyme labeled with the fluorescent sulfhydryl reagent, 2-(4-maleimidylanilino)naphthalene-6-sulfonate. As in the case of Mg2+ inhibition of activity, the affinity for Mg2+ as an inducing agent for this effect was significantly reduced by both Na+ and ATP, suggesting that the same change was being monitored in both cases. The Mg2+ effect was reduced by both Na+ and ATP, suggesting that the same change was being monitored in both cases. The Mg2+ effect was reduced in magnitude by ouabain and prevented by oligomycin, specific inhibitors of the enzyme. In addition, K+ (and cations that substitute for K+ in supporting activity) induced a 3 to 4% enhancement in fluorescence intensity in the presence of Na+, Mg2+, and ATP, although the K+ and Mg2+ effects appeared to be different on the basis of their excitation spectra. The K+ effect was inhibited by ouabain and occurred with a rate greater than the rate of turnover of the enzyme, permitting its involvement in the catalytic cycle.

Structural characterization of the ATP-hydrolyzing portion of the coated vesicle proton pump.

The ATP-hydrolyzing portion of the proton pump from clathrin-coated vesicles (isolated from calf brain) was solubilized with three nondenaturing detergents (cholate, octyl glucoside, and Triton X-100). The hydrodynamic properties of the solubilized (Mg2+)-ATPase were then determined by sedimentation analysis in H2O and D2O and gel filtration on Sepharose 4B. The coated vesicle (Mg2+)-ATPase migrated under all conditions as a single peak of activity. In cholate, the sedimentation coefficient (S20,w), Stokes radius (a), and partial specific volume (vc) were 8.25 (+/- 0.20) S, 68 (+/- 2) A, and 0.71 (+/- 0.03) cm3/g, respectively. In octyl glucoside and Triton X-100 these values were respectively 7.90 (+/- 0.20) and 7.45 (+/- 0.20) S, 68 (+/- 3) and 101 (+/- 5) A, and 0.74 (+/- 0.03) and 0.75 (+/- 0.03) cm3/g. Application of the Svedberg equation to these data gave a molecular weight for the protein-detergent complex of 217,000 +/- 21,000 (cholate), 234,000 +/- 26,000 (octyl glucoside), and 337,000 +/- 40,000 (Triton X-100). Assuming the protein binds one micelle of detergent, these values correspond to a protein molecular weight of 215,000 +/- 21,000 (cholate), 226,000 +/- 26,000 (octyl glucoside), and 247,000 +/- 40,000 (Triton X-100). The cholate-solubilized, gradient-purified (Mg2+)-ATPase, when combined with a 100,000 g pellet fraction, could be reconstituted by dialysis into phospholipid vesicles which displayed ATP-dependent proton uptake.(ABSTRACT TRUNCATED AT 250 WORDS)

Assembly of the peripheral domain of the bovine vacuolar H(+)-adenosine triphosphatase.

The biosynthesis and assembly of the peripheral sector (V1) of the vacuolar proton-translocating adenosine triphosphatase (V-ATPase) was studied in a bovine kidney epithelial cell line. Monolayer cultures of cells were metabolically radiolabeled with Tran35S-label and the V-ATPase subsequently immunoprecipitated using a monoclonal antibody raised against the bovine brain-coated vesicle proton pump. The V-ATPase immunoprecipitated from the bovine kidney cell line has a subunit composition very similar to that of the bovine brain-coated vesicle proton pump and the V-ATPase prepared from other kidney tissues. Radiolabeling the cells for increasing times showed that the V1 or peripheral portion of the V-ATPase is assembled within 10-15 min; the intact V1V0 complex is also detectable within 10-15 min. Fractionation of the cells into cytosolic and membrane components prior to immunoprecipitation revealed that there is a significant pool of V1 in the cytosol; a similar complex is also found in bovine brain cytosol. Pulse-chase studies suggest that this cytosolic pool is not an obligate precursor for membrane-bound V1V0 and does not exchange with the membrane V1 population at later times. No qualitative differences in assembly were observed when pulse-chase studies were performed at 15 degrees C or in the presence of brefeldin A. This suggests that assembly of V1V0 is probably completed in the endoplasmic reticulum prior to distribution of the enzyme throughout the cell, with a cytosolic pool of V1 of unknown function existing in parallel with the fully assembled complex.

The coated vesicle vacuolar (H+)-ATPase associates with and is phosphorylated by the 50-kDa polypeptide of the clathrin assembly protein AP-2.

We have previously noted a 50-kDa polypeptide (p50) co-purifying with preparations of the bovine brain clathrin-coated vesicle vacuolar (H+)-ATPase (V-ATPase) (Zhang, J., Myers, M., and Forgac, M. (1992) J. Biol. Chem. 267, 9773-9778). We show that p50 is also immunoprecipitated with the V-ATPase, further suggesting its specific association with the proton pump. To determine the identity of this 50-kDa polypeptide and the stoichiometry of its association with the V-ATPase, we performed N-terminal amino acid sequencing and quantitative amino acid analysis of the gel-purified protein. These results revealed the unknown polypeptide to be the 50-kDa subunit of the clathrin assembly protein AP-2 (AP50); we estimate the stoichiometry of association is one AP50 per V-ATPase complex. AP50 is an N-ethylmaleimide (NEM)-inhibitable autokinase and incubation of purified V-ATPase with [gamma-32P]ATP resulted in the NEM-sensitive phosphorylation of AP50 and the B subunit of the V-ATPase. The same phosphorylation pattern is seen if the labeling reaction is done with intact clathrin-coated vesicles and the V-ATPase subsequently immunoprecipitated from the solubilized vesicles. This represents the first report of phosphorylation of one of the V-ATPase subunits. The functional significance of this phosphorylation for regulation or targeting of the V-ATPase in vivo remains to be determined.

Cysteine 254 of the 73-kDa A subunit is responsible for inhibition of the coated vesicle (H+)-ATPase upon modification by sulfhydryl reagents.

The vacuolar class of (H+)-ATPases are highly sensitive to sulfhydryl reagents, such as N-ethylmaleimide. The cysteine residue which is responsible for inhibition of the coated vesicle (H+)-ATPase upon modification by N-ethylmalemide is located in subunit A and is able to form a disulfide bond with the cysteine moiety of cystine through an exchange reaction. This unique property distinguishes this cysteine residue from the remaining cysteine residues of the (H+)-ATPase. Using this reaction, we selectively labeled the cystine-reactive cysteine residue of subunit A with fluorescein-maleimide. After complete digestion of the labeled subunit A by V8 protease, a single labeled fragment of molecular mass 3.9 kDa was isolated and the amino-terminal sequence was determined. This fragment contains 2 cysteine residues, Cys240 and Cys254. Since Cys254 is conserved among all vacuolar (H+)-ATPases whereas Cys240 is not, it is likely that Cys254 is the residue which is responsible for the sensitivity of the vacuolar (H+)-ATPase to sulfhydryl reagents.

Three-dimensional structure of the vacuolar ATPase proton channel by electron microscopy.

Vacuolar ATPases are ATP hydrolysis-driven proton pumps found in the endomembrane system of eucaryotic cells where they are involved in pH regulation. We have determined the three-dimensional structure of the proton channel domain of the vacuolar ATPase from bovine brain clathrin-coated vesicles by electron microscopy at 21 A resolution. The model shows an asymmetric protein ring with two small openings on the luminal side and one large opening on the cytoplasmic side. The central hole on the luminal side is covered by a globular protein, while the cytoplasmic opening is covered by two elongated proteins arranged in a collar-like fashion.

Functional reassembly of the coated vesicle proton pump.

We have shown previously that treatment of the coated vesicle proton-translocating adenosine triphosphatase (H(+)-ATPase) with chaotropic agents results in the release of a set of peripheral polypeptides which includes the 73-, 58-, 40-, 34-, and 33-kDa subunits (Adachi, I., Puopolo, K., Marquez-Sterling, N., Arai, H., and Forgac, M. (1990) J. Biol. Chem. 265, 967-973), with a coordinate loss of H(+)-ATPase activity. In the present paper we report the functional reassembly of the coated vesicle proton pump following dissociation of the peripheral subunits. Reassembly was demonstrated by restoration of ATP-driven proton transport using both native membranes and reconstituted vesicles and by Western blot analysis using a monoclonal antibody specific for the 73-kDa subunit. Reassembly occurs by attachment of a peripheral subcomplex containing the 73-, 58-, 34-, and 33-kDa subunits together with the 40-kDa polypeptide. The reassembled H(+)-ATPase, like the native proton pump, is inhibited by N-ethylmaleimide, 7-chloro-4-nitrobenz-2-oxa-1,3-diazole, and N,N'-dicyclohexylcarbodiimide. Reassociation shows a biphasic time dependence, with restoration of 50-60% of the starting proton transport activity in the 1st h followed by recovery of a further 20-30% of the activity after 24 h. Reassembly also shows a marked dependence on protein concentration but, unlike solubilization of the intact H(+)-ATPase complex, does not require the presence of glycerol. Despite the ability of nucleotides to promote dissociation of the peripheral complex by chaotropic agents, reassociation is not blocked by the presence of 1 mM ATP. These results thus provide the first evidence for functional reassembly of a vacuolar H(+)-ATPase complex and should be useful in further analysis of the role of individual subunits in the assembly and activity of these ATP-driven proton pumps.

Microtubules are involved in glucose-dependent dissociation of the yeast vacuolar [H+]-ATPase in vivo.

The vacuolar [H(+)]-ATPases (V-ATPases) are composed of a peripheral V(1) domain and a membrane-embedded V(0) domain. Reversible dissociation of the V(1) and V(0) domains has been observed in both yeast and insects and has been suggested to represent a general regulatory mechanism for controlling V-ATPase activity in vivo. In yeast, dissociation of the V-ATPase is triggered by glucose depletion, but the signaling pathways that connect V-ATPase dissociation and glucose metabolism have not been identified. We have found that nocodazole, an agent that disrupts microtubules, partially blocked dissociation of the V-ATPase in response to glucose depletion in yeast. By contrast, latrunculin, an agent that disrupts actin filaments, had no effect on glucose-dependent dissociation of the V-ATPase complex. Neither nocodazole nor latrunculin blocked reassembly of the V-ATPase upon re-addition of glucose to the medium. The effect of nocodazole appears to be specifically through disruption of microtubules since glucose-dependent dissociation of the V-ATPase was not blocked by nocodazole in yeast strains bearing a mutation in tubulin that renders it resistant to nocodazole. Because nocodazole has been shown to arrest cells in the G(2) phase of the cell cycle, it was of interest to determine whether nocodazole exerted its effect on dissociation of the V-ATPase through cell cycle arrest. Glucose-dependent dissociation of the V-ATPase was examined in four yeast strains bearing temperature-sensitive mutations that arrest cells in different stages of the cell cycle. Because dissociation of the V-ATPase occurred normally at both the permissive and restrictive temperatures in these mutants, the results suggest that in vivo dissociation is not dependent upon cell cycle phase.

A novel mechanism for regulation of vacuolar acidification.

We have recently demonstrated that Cys-254 of the 73-kDa A subunit of the clathrin-coated vesicle (H+)-ATPase is responsible for sensitivity of the enzyme to sulfhydryl reagents (Feng, Y., and Forgac, M. (1992) J. Biol. Chem. 267, 5817-5822). In the present study we observe that for the purified enzyme, disulfide bond formation causes inactivation of proton transport which is reversed by dithiothreitol (DTT). DTT also restores activity of the oxidized enzyme following treatment with N-ethylmaleimide (NEM). These results indicate that disulfide bond formation between the NEM-reactive cysteine (Cys-254) and a closely proximal cysteine residue leads to inactivation of the (H+)-ATPase. To test whether sulfhydryl-disulfide bond interchange may play a role in regulating vacuolar acidification in vivo, we have determined what fraction of the (H+)-ATPase is disulfide-bonded in native clathrin-coated vesicles. Vesicles were isolated under conditions that prevent any change in the oxidation state of the sulfhydryl groups. NEM treatment of vesicles causes nearly complete loss of activity while subsequent treatment with DTT restores 50% of the activity of the fully reduced vesicles. By contrast, treatment of fully reduced vesicles with NEM leads to inactivation which is not reversed by DTT. These results indicate that a significant fraction of the clathrin-coated vesicle (H+)-ATPase exists in an inactive, disulfide-bonded state and suggest that sulfhydryl-disulfide bond interconversion may play a role in controlling vacuolar (H+)-ATPase (V-ATPase) activity in vivo.