Assembly and Regulation of the Yeast Vacuolar H+-ATPase

The yeast vacuolar proton-translocating ATPase (V-ATPase) is an excellent model for V-ATPases in all eukaryotic cells. Activity of the yeast V-ATPase is reversibly down-regulated by disassembly of the peripheral (V₁) sector, which contains the ATP-binding sites, from the membrane (V₀) sector, which contains the proton pore. A similar regulatory mechanism has been found in Manduca sexta and is believed to operate in other eukaryotes. We are interested in the mechanism of reversible disassembly and its implications for V-ATPase structure. In this review, we focus on (1) characterization of the yeast V-ATPase stalk subunits, which form the interface between V₁ and V₀, (2) potential mechanisms of silencing ATP hydrolytic activity in disassembled V₁ sectors, and (3) the structure and function of RAVE, a recently discovered complex that regulates V-ATPase assembly.     

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 foracidification of intracellular compartments in eukaryotic cells. This reviewfocuses on the the V-ATPases from clathrin-coated vesicles and yeastvacuoles. The V-ATPase of clathrin-coated vesicles is a precursor to thatfound in endosomes and synaptic vesicles, which function in receptorrecycling, intracellular membrane traffic, and neurotransmitter uptake. Theyeast vacuolar ATPase functions to acidify the central vacuole and to drivevarious coupled transport processes across the vacuolar membrane. TheV-ATPases are composed of two functional domains. The V₁ domain isa 570-kDa peripheral complex composed of eight subunits of molecular weight70—14 kDa (subunits A—H) that is responsible for ATP hydrolysis.The V₀ domain is a 260-kDa integral complex composed of fivesubunits of molecular weight 100—17 kDa (subunits a, d, c, c8 and c9)that is responsible for proton translocation. Using chemical modification andsite-directed mutagenesis, we have begun to identify residues that play arole in ATP hydrolysis and proton transport by the V-ATPases. A centralquestion in the V-ATPase field is the mechanism by which cells regulatevacuolar acidification. Several mechanisms are described that may play a rolein controlling vacuolar acidification in vivo. One mechanisminvolves disulfide bond formation between cysteine residues located at thecatalytic nucleotide binding site on the 70-kDa A subunit, leading toreversible inhibition of V-ATPase activity. Other mechanisms includereversible assembly and dissociation of V₁ and V₀domains, changes in coupling efficiency of proton transport and ATPhydrolysis, and regulation of the activity of intracellular chloride channelsrequired for vacuolar acidification.     

Subunit Composition, Structure, and Distribution of Bacterial V-Type ATPases

The overall structure of V-ATPase complexes resembles that of F-type ATPases, but the stalk region is different and more complex. Database searches followed by sequence analysis of the five water-soluble stalk region subunits C–G revealed that (i) to date V-ATPases are found in 16 bacterial species, (ii) bacterial V-ATPases are closer to archaeal A-ATPases than to eukaryotic V-ATPases, and (iii) different groups of bacterial V-ATPases exist. Inconsistencies in the nomenclature of types and subunits are addressed. Attempts to assign subunit positions in V-ATPases based on biochemical experiments, chemical cross-linking, and electron microscopy are discussed. A structural model for prokaryotic and eukaryotic V-ATPases is proposed. The prokaryotic V-ATPase is considered to have a central stalk between headpiece and membrane flanked by two peripheral stalks. The eukaryotic V-ATPases have one additional peripheral stalk.     

Characterization of a Red Beet Protein Homologous to the Essential 36-Kilodalton Subunit of the Yeast V-Type ATPase

V-type proton-translocating ATPases (V-ATPases) (EC 3.6.1.3) are electrogenic proton pumps involved in acidification of endomembrane compartments in all eukaryotic cells. V-ATPases from various species consist of 8 to 12 polypeptide subunits arranged into an integral membrane proton pore sector (V₀) and a peripherally associated catalytic sector (V₁). Several V-ATPase subunits are functionally and structurally conserved among all species examined. In yeast, a 36-kD peripheral subunit encoded by the yeast (Saccharomyces cerevisiae) VMA6 gene (Vma6p) is required for stable assembly of the V₀ sector as well as for V₁ attachment. Vma6p has been characterized as a nonintegrally associated V₀ subunit. A high degree of sequence similarity among Vma6p homologs from animal and fungal species suggests that this subunit has a conserved role in V-ATPase function. We have characterized a novel Vma6p homolog from red beet (Beta vulgaris) tonoplast membranes. A 44-kD polypeptide cofractionated with V-ATPase upon gel-filtration chromatography of detergent-solubilized tonoplast membranes and was specifically cross-reactive with anti-Vma6p polyclonal antibodies. The 44-kD polypeptide was dissociated from isolated tonoplast preparations by mild chaotropic agents and thus appeared to be nonintegrally associated with the membrane. The putative 44-kD homolog appears to be structurally similar to yeast Vma6p and occupies a similar position within the holoenzyme complex.     

Close-Up and Genomic Views of the Yeast Vacuolar H<Superscript>+</Superscript>-ATPase

The yeast V-ATPase has emerged as an excellent model for other eukaryotic V-ATPases. In this review, recent biochemical and genomic studies of the yeast V-ATPase are described, with a focus on: 1) the role of V₁ subunit H in coupling ATP hydrolysis and proton pumping and 2) identification of the full set of yeast haploid deletion mutants that exhibit the pH and calcium-sensitive growth characteristic of loss of V-ATPase activity. The combination of “close-up” biochemical views of V-ATPase structure and mechanism and “geomic” views of its functional reach promises to provide new insights into the physiological of V-ATPases.     

Biosynthesis and Regulation of the Yeast Vacuolar H+-ATPase

The yeast V-ATPase is highly similar to V-ATPases of higher organismsand has proved to be a biochemically and genetically accessible model formany aspects of V-ATPase function. Like other V-ATPases, the yeast enzymeconsists of a complex of peripheral membrane proteins, the V₁sector, attached to a complex of integral membrane subunits, theV₀ sector. Multiple pathways for biosynthetic assembly of theenzyme appear to be available to cells containing a full complement ofsubunits and enzyme activity may be further controlled during biosynthesis bya protease activity localized to the late Golgi apparatus. Surprisingly, theassembled V-ATPase is not a static structure. Instead, fully assembledV₁V₀ complexes appear to exist in a dynamic equilibriumwith inactive cytosolic V₁ and membrane-bound V₀complexes and this equilibrium can be rapidly shifted in response to changesin carbon source. The reversible disassembly of the yeast V-ATPase may be anovel regulatory mechanism, common to V-ATPases, that works in vivoin coordination with many other regulatory mechanisms.     

Subunit C of the Vacuolar-Type ATPase from the Vanadium-Rich Ascidian Ascidia sydneiensis samea Rescued the pH Sensitivity of Yeast vma5 Mutants

A vanadium-accumulating ascidian, Ascidia sydneiensis samea, expresses vacuolar-type H⁺-ATPases (V-ATPases) on the vacuole membrane of the vanadium-containing blood cells known as vanadocytes. Previously, we showed that the contents of their vacuoles are extremely acidic and that a V-ATPase-specific inhibitor, bafilomycin A₁, neutralized the contents of the vacuoles. To understand the function of V-ATPase in vanadocytes, we isolated complementary DNA encoding subunit C of V-ATPase from vanadocytes because this subunit has been known to be responsible for the assembly of V-ATPases and to regulate the ATPase activity of V-ATPases. The cloned cDNA was 1443 nucleotides in length, and encoded a putative 384 amino acid protein. By expressing the ascidian cDNA for subunit C under the control of a galactose-inducible promoter, the pH-sensitive phenotype of the corresponding vma5 mutant of a budding yeast was rescued. This result showed that the ascidian cDNA for subunit C functioned in yeast cells. Received August 11, 2000; accepted March 5, 2001.     

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.     

Defective assembly of a hybrid vacuolar H-ATPase containing the mouse testis-specific E1 isoform and yeast subunits

Mammalian vacuolar-type proton pumping ATPases (V-ATPases) are diverse multi-subunit proton pumps. They are formed from membrane V_o and catalytic V₁ sectors, whose subunits have cell-specific or ubiquitous isoforms. Biochemical study of a unique V-ATPase is difficult because ones with different isoforms are present in the same cell. However, the properties of mouse isoforms can be studied using hybrid V-ATPases formed from the isoforms and other yeast subunits. As shown previously, mouse subunit E isoform E1 (testis-specific) or E2 (ubiquitous) can form active V-ATPases with other subunits of yeast, but E1/yeast hybrid V-ATPase is defective in proton transport at 37 °C (Sun-Wada, G.-H., Imai-Senga, Y., Yamamoto, A., Murata, Y., Hirata, T., Wada, Y., and Futai, M., 2002, J. Biol. Chem. 277, 18098-18105). In this study, we have analyzed the properties of E1/yeast hybrid V-ATPase to understand the role of the E subunit. The proton transport by the defective hybrid ATPase was reversibly recovered when incubation temperature of vacuoles or cells was shifted to 30 °C. Corresponding to the reversible defect of the hybrid V-ATPase, the V_o subunit a epitope was exposed to the corresponding antibody at 37 °C, but became inaccessible at 30 °C. However, the V₁ sector was still associated with V_o at 37 °C, as shown immunochemically. The control yeast V-ATPase was active at 37 °C, and its epitope was not accessible to the antibody. Glucose depletion, known to dissociate V₁ from V_o in yeast, had only a slight effect on the hybrid at acidic pH. The domain between Lys26 and Val83 of E1, which contains eight residues not conserved between E1 and E2, was responsible for the unique properties of the hybrid. These results suggest that subunit E, especially its amino-terminal domain, plays a pertinent role in the assembly of V-ATPase subunits in vacuolar membranes.     

The vacuolar (H+)-ATPase: subunit arrangement and in vivo regulation

The V-ATPases are responsible for acidification of intracellular compartments and proton transport across the plasma membrane. They play an important role in both normal processes, such as membrane traffic, protein degradation, urinary acidification, and bone resorption, as well as various disease processes, such as viral infection, toxin killing, osteoporosis, and tumor metastasis. V-ATPases contain a peripheral domain (V₁) that carries out ATP hydrolysis and an integral domain (V₀) responsible for proton transport. V-ATPases operate by a rotary mechanism involving both a central rotary stalk and a peripheral stalk that serves as a stator. Cysteine-mediated cross-linking has been used to localize subunits within the V-ATPase complex and to investigate the helical interactions between subunits within the integral V₀ domain. An essential property of the V-ATPases is the ability to regulate their activity in vivo. An important mechanism of regulating V-ATPase activity is reversible dissociation of the complex into its component V₁ and V₀ domains. The dependence of reversible dissociation on subunit isoforms and cellular environment has been investigated. Qi and Wang contributed equally to this work.     

Function, structure and regulation of the vacuolar (H+)-ATPases

The vacuolar ATPases (or V-ATPases) are ATP-driven proton pumps that function to both acidify intracellular compartments and to transport protons across the plasma membrane. Intracellular V-ATPases function in such normal cellular processes as receptor-mediated endocytosis, intracellular membrane traffic, prohormone processing, protein degradation and neurotransmitter uptake, as well as in disease processes, including infection by influenza and other viruses and killing of cells by anthrax and diphtheria toxin. Plasma membrane V-ATPases are important in such physiological processes as urinary acidification, bone resorption and sperm maturation as well as in human diseases, including osteopetrosis, renal tubular acidosis and tumor metastasis. V-ATPases are large multi-subunit complexes composed of a peripheral domain (V₁) responsible for hydrolysis of ATP and an integral domain (V₀) that carries out proton transport. Proton transport is coupled to ATP hydrolysis by a rotary mechanism. V-ATPase activity is regulated in vivo using a number of mechanisms, including reversible dissociation of the V₁ and V₀ domains, changes in coupling efficiency of proton transport and ATP hydrolysis and changes in pump density through reversible fusion of V-ATPase containing vesicles. V-ATPases are emerging as potential drug targets in treating a number of human diseases including osteoporosis and cancer.     

Subunit Interactions and Requirements for Inhibition of the Yeast V1-ATPase

Disassembly of the yeast V-ATPase into cytosolic V₁ and membrane V₀ sectors inactivates MgATPase activity of the V₁-ATPase. This inactivation requires the V₁ H subunit (Parra, K. J., Keenan, K. L., and Kane, P. M. (2000) J. Biol. Chem. 275, 21761–21767), but its mechanism is not fully understood. The H subunit has two domains. Interactions of each domain with V₁ and V₀ subunits were identified by two-hybrid assay. The B subunit of the V₁ catalytic headgroup interacted with the H subunit N-terminal domain (H-NT), and the C-terminal domain (H-CT) interacted with V₁ subunits B, E (peripheral stalk), and D (central stalk), and the cytosolic N-terminal domain of V₀ subunit Vph1p. V₁-ATPase complexes from yeast expressing H-NT are partially inhibited, exhibiting 26% the MgATPase activity of complexes with no H subunit. The H-CT domain does not copurify with V₁ when expressed in yeast, but the bacterially expressed and purified H-CT domain inhibits MgATPase activity in V₁ lacking H almost as well as the full-length H subunit. Binding of full-length H subunit to V₁ was more stable than binding of either H-NT or H-CT, suggesting that both domains contribute to binding and inhibition. Intact H and H-CT can bind to the expressed N-terminal domain of Vph1p, but this fragment of Vph1p does not bind to V₁ complexes containing subunit H. We propose that upon disassembly, the H subunit undergoes a conformational change that inhibits V₁-ATPase activity and precludes V₀ interactions.V-ATPases are ubiquitous proton pumps responsible for compartment acidification in all eukaryotic cells (1, 2). These pumps couple hydrolysis of cytosolic ATP to proton transport into the lysosome/vacuole, endosomes, Golgi apparatus, clathrin-coated vesicles, and synaptic vesicles. Through their role in organelle acidification, V-ATPases are linked to cellular functions as diverse as protein sorting and targeting, zymogen activation, cytosolic pH homeostasis, and resistance to multiple types of stress (3). They are also recruited to the plasma membrane of certain cells, where they catalyze proton export (4, 5).V-ATPases are evolutionarily related to ATP synthases of bacteria and mitochondria and consist of two multisubunit complexes, V₁ and V₀, which contain the sites for ATP hydrolysis and proton transport, respectively. Like the ATP synthase (F-ATPase), V-ATPases utilize a rotational catalytic mechanism. ATP binding and hydrolysis in the three catalytic subunits of the V₁ sector generate sequential conformational changes that drive rotation of a central stalk (6–8). The central stalk subunits are connected to a ring of proteolipid subunits in the V₀ sector that bind protons to be transported. The actual transport is believed to occur at the interface of the proteolipids and V₀ subunit a. Rotational catalysis will be productive in proton transport only if V₀ subunit a is held stationary, whereas the proteolipid ring rotates (8). This “stator function” resides in a single peripheral stalk in F-ATPases (9, 10), but is distributed among up to three peripheral stalks in V-ATPases (11–13). The peripheral stator stalks link V₀ subunit a to the catalytic headgroup and ensures that there is rotation of the central stalk complex relative to the V₀ a subunit and catalytic headgroup.Eukaryotic V-ATPases are highly conserved in both their overall structure and the sequences of individual subunits. Although homologs of most subunits of eukaryotic V-ATPases are present in archaebacterial V-ATPases (also known as A-ATPases), the C and H subunits are unique to eukaryotes. Both subunits have been localized at the interface of the V₁ and V₀ sectors, suggesting that they are positioned to play a critical role in structural and functional interaction between the two sectors (14–16). The yeast C and H subunits are the only eukaryotic V-ATPase subunits for which x-ray crystal structures are available (17, 18). The structure of the C subunit revealed an elongated “dumbbell-shaped” molecule, with foot, head, and neck domains (18). The structure of the H subunit indicated two domains. The N-terminal 348 amino acids fold into a series of HEAT repeats and are connected by a 4-amino acid linker to a C-terminal domain containing amino acids 352–478 (17). These two domains have partially separable functions in the context of the assembled V-ATPase (19). Complexes containing only the N-terminal domain of the H subunit (H-NT)² supported some ATP hydrolysis but little or no proton pumping in isolated vacuolar vesicles (19, 20). The C-terminal domain (H-CT) assembled with the rest of the V-ATPase in the absence of intact subunit H, but supported neither ATPase nor proton pumping activity (19). However, co-expression of the H-NT and H-CT domains results in assembly of both sectors with the V-ATPase and allows increased ATP-driven proton pumping in isolated vacuolar vesicles. These results suggest that the H-NT and H-CT domains play distinct and complementary roles even when the two domains are not covalently attached.In addition to their role as dedicated proton pumps, eukaryotic V-ATPases are also distinguished from F-ATPases and archaeal V-ATPases in their regulation. Eukaryotic V-ATPases are regulated in part by reversible disassembly of the V₁ complex from the V₀ complex (1, 21, 22). In yeast, disassembly of previously assembled complexes occurs in response to glucose deprivation, and reassembly is rapidly induced by glucose readdition to glucose-deprived cells. Disassembly down-regulates pump activity, and both the disassembled sectors are inactivated. Inhibition of ATP hydrolysis in free V₁ sectors is particularly critical, because release of an active ATPase into the cytosol could deplete cytosolic ATP stores. This inhibition is dependent in part on the H subunit. V₁ complexes isolated from vma13Δ mutants, which lack the H subunit gene (V₁(-H) complexes) have MgATPase activity. Consistent with a physiological role for H subunit inhibition of V₁, heterozygous diploids containing elevated levels of free V₁ complexes without subunit H have severe growth defects (23). V₁ complexes containing subunit H have no MgATPase activity, but retain some CaATPase activity, suggesting a role for nucleotides in inhibition (24, 25). Consistent with such a role, both the CaATPase activity of native V₁ and the MgATPase activity of V₁(-H) complexes are lost within a few minutes of nucleotide addition (24).A number of points of interaction between the H subunit and the V₁ and V₀ complexes have been identified through two-hybrid assays, binding of expressed proteins, and cross-linking experiments. These experiments have indicated that the H subunit binds to V₁ subunits E and G of the V-ATPase peripheral stalks (26, 27), the catalytic subunit (V₁ subunit A) (28), regulatory V₁ subunit B (15), and the N-terminal domain of subunit a (28). Recently, Jeffries and Forgac (29) have found that cysteines introduced into the C-terminal domain of subunit H can be cross-linked to subunit F in isolated V₁ sectors via a 10-Å cross-linking reagent.In this work, we examine both the subunit-subunit interactions and functional roles of the H-NT and H-CT domains in inhibition of V₁-ATPase activity. When expressed in yeast cells lacking subunit H, H-NT can be isolated with cytosolic V₁ complexes, but H-CT cannot. We find that both of these domains contribute to inhibition of ATPase activity, but that stable binding to V₁ and full inhibition of activity requires both domains. We also find that the H-CT can bind to the cytosolic N-terminal domain of V₀ subunit Vph1p (Vph1-NT) in isolation, but does not support tight binding of Vph1-NT to isolated V₁ complexes.     

Structure and Regulation of the V-ATPases

The V-ATPases are ATP-dependent proton pumps present in both intracellular compartments and the plasma membrane. They function in such processes as membrane traffic, protein degradation, renal acidification, bone resorption and tumor metastasis. The V-ATPases are composed of a peripheral V₁ domain responsible for ATP hydrolysis and an integral V₀ domain that carries out proton transport. Our recent work has focused on structural analysis of the V-ATPase complex using both cysteine-mediated cross-linking and electron microscopy. For cross-linking studies, unique cysteine residues were introduced into structurally defined sites within the B and C subunits and used as points of attachment for the photoactivated cross-linking reagent MBP. Disulfide mediated cross-linking has also been used to define helical contact surfaces between subunits within the integral V₀ domain. With respect to regulation of V-ATPase activity, we have investigated the role that intracellular environment, luminal pH and a unique domain of the catalytic A subunit play in controlling reversible dissociation in vivo.     

Probing Subunit-Subunit Interactions in the Yeast Vacuolar ATPase by Peptide Arrays

Background

Vacuolar (H⁺)-ATPase (V-ATPase; V₁V_o-ATPase) is a large multisubunit enzyme complex found in the endomembrane system of all eukaryotic cells where its proton pumping action serves to acidify subcellular organelles. In the plasma membrane of certain specialized tissues, V-ATPase functions to pump protons from the cytoplasm into the extracellular space. The activity of the V-ATPase is regulated by a reversible dissociation mechanism that involves breaking and re-forming of protein-protein interactions in the V₁-ATPase - V_o-proton channel interface. The mechanism responsible for regulated V-ATPase dissociation is poorly understood, largely due to a lack of detailed knowledge of the molecular interactions that are responsible for the structural and functional link between the soluble ATPase and membrane bound proton channel domains.

Methodology/Principal Findings

To gain insight into where some of the stator subunits of the V-ATPase associate with each other, we have developed peptide arrays from the primary sequences of V-ATPase subunits. By probing the peptide arrays with individually expressed V-ATPase subunits, we have identified several key interactions involving stator subunits E, G, C, H and the N-terminal domain of the membrane bound a subunit.

Conclusions

The subunit-peptide interactions identified from the peptide arrays complement low resolution structural models of the eukaryotic vacuolar ATPase obtained from transmission electron microscopy. The subunit-subunit interaction data are discussed in context of our current model of reversible enzyme dissociation.     

Plasmalemmal vacuolar-type H+-ATPase in cancer biology

Vacuolar-type H⁺-adenosine triphosphatase (V-ATPase) is one of the most fundamental enzymes in nature. V-ATPases are responsible for the regulation of proton concentration in the intracellular acidic compartments. It has similar structure with the mitochondrial F₀F₁-ATP synthase (F-ATPase).^† The V-ATPases are composed of multiple subunits and have various physiological functions, including membrane and organelle protein sorting, neurotransmitter uptake, cellular degradative processes, and cytosolic pH regulation. The V-ATPases have been involved in multidrug resistance. Recently, plasma membrane V-ATPases have been involved in regulation of extracellular acidity, essential for cellular invasiveness and proliferation in tumor metastasis. The current knowledge regarding the structure and function of V-ATPase and its role in cancer biology is discussed. F in F₀F₁ ATPase is the coupling energy factor.     

Electron-microscopic structure of the V-ATPase from mung bean

The vacuolar H⁺-ATPase from mung bean (Vigna radiata L. cv. Wilczek) was purified to homogeneity. The purified complex contained all the reported subunits from mung bean, but also included a 40-kDa subunit, corresponding to the membrane-associated subunit d, which has not previously been observed. The structure of the V-ATPase from mung bean was studied by electron microscopy of negatively stained samples. An analysis of over 6,000 single-particle images obtained by electron microscopy of the purified complex revealed that the complex, similar to other V-ATPases, is organized into two major domains V₁ and V_o with overall dimensions of 25 nm×13.7 nm and a stalk region connecting the V₁ and V_o domains. Several individual areas of protein density were observed in the stalk region, indicating its complexity. The projections clearly showed that the complex contained one central stalk and at least two peripheral stalks. Subcomplexes containing subunits A, B and E, dissociated from the tonoplast membrane by KI, were purified. The structure of the subcomplex was also studied by electron microscopy followed by single-molecule analysis of 13,000 projections. Our preliminary results reveal an area of high protein density at the bottom of the subcomplex immediately below the cavity formed by the A and B subunits, indicating the position of subunit E.Abbreviations MSA Multivariate statistical analysis - 2D, 3D Two-, three-dimensional - V-ATPase Vacuolar H⁺-ATPase     

Regulation of Vacuolar Proton-translocating ATPase Activity and Assembly by Extracellular pH

Vacuolar proton-translocating ATPases (V-ATPases) are responsible for organelle acidification in all eukaryotic cells. The yeast V-ATPase, known to be regulated by reversible disassembly in response to glucose deprivation, was recently reported to be regulated by extracellular pH as well (Padilla-López, S., and Pearce, D. A. (2006) J. Biol. Chem. 281, 10273–10280). Consistent with those results, we find 57% higher V-ATPase activity in vacuoles isolated after cell growth at extracellular pH of 7 than after growth at pH 5 in minimal medium. Remarkably, under these conditions, the V-ATPase also becomes largely insensitive to reversible disassembly, maintaining a low vacuolar pH and high levels of V₁ subunit assembly, ATPase activity, and proton pumping during glucose deprivation. Cytosolic pH is constant under these conditions, indicating that the lack of reversible disassembly is not a response to altered cytosolic pH. We propose that when alternative mechanisms of vacuolar acidification are not available, maintaining V-ATPase activity becomes a priority, and the pump is not down-regulated in response to energy limitation. These results also suggest that integrated pH and metabolic inputs determine the final assembly state and activity of the V-ATPase.     

Structural Analysis of the N-terminal Domain of Subunit a of the Yeast Vacuolar ATPase (V-ATPase) Using Accessibility of Single Cysteine Substitutions to Chemical Modification

The vacuolar ATPase (V-ATPase) is a multisubunit complex that carries out ATP-driven proton transport. It is composed of a peripheral V₁ domain that hydrolyzes ATP and an integral V₀ domain that translocates protons. Subunit a is a 100-kDa integral membrane protein (part of V₀) that possesses an N-terminal cytoplasmic domain and a C-terminal hydrophobic domain. Although the C-terminal domain functions in proton transport, the N-terminal domain is critical for intracellular targeting and regulation of V-ATPase assembly. Despite its importance, there is currently no high resolution structure for subunit a of the V-ATPase. Recently, the crystal structure of the N-terminal domain of the related subunit I from the archaebacterium Meiothermus ruber was reported. We have used homology modeling to construct a model of the N-terminal domain of Vph1p, one of two isoforms of subunit a expressed in yeast. To test this model, unique cysteine residues were introduced into a Cys-less form of Vph1p and their accessibility to modification by the sulfhydryl reagent 3-(N-maleimido-propionyl) biocytin (MPB) was determined. In addition, accessibility of introduced cysteine residues to MPB modification was compared in the V₁V₀ complex and the free V₀ domain to identify residues protected from modification by the presence of V₁. The results provide an experimental test of the proposed model and have identified regions of the N-terminal domain of subunit a that likely serve as interfacial contact sites with the peripheral V₁ domain. The possible significance of these results for in vivo regulation of V-ATPase assembly is discussed.     

The C-H Peripheral Stalk Base: A Novel Component in V1-ATPase Assembly

Vacuolar ATPases (V-ATPases) are molecular machines responsible for creating electrochemical gradients and preserving pH-dependent cellular compartments by way of proton translocation across the membrane. V-ATPases employ a dynamic rotary mechanism that is driven by ATP hydrolysis and the central rotor stalk. Regulation of this rotational catalysis is the result of a reversible V₁V_o-domain dissociation that is required to preserve ATP during instances of cellular starvation. Recently the method by which the free V₁-ATPase abrogates the hydrolytic breakdown of ATP upon dissociating from the membrane has become increasingly clear. In this instance the central stalk subunit F adopts an extended conformation to engage in a bridging interaction tethering the rotor and stator components together. However, the architecture by which this mechanism is stabilized has remained ambiguous despite previous work. In an effort to elucidate the method by which the rotational catalysis is maintained, the architecture of the peripheral stalks and their respective binding interactions was investigated using cryo-electron microscopy. In addition to confirming the bridging interaction exuded by subunit F for the first time in a eukaryotic V-ATPase, subunits C and H are seen interacting with one another in a tight interaction that provides a base for the three EG peripheral stalks. The formation of a CE₃G₃H sub-assembly appears to be unique to the dissociated V-ATPase and highlights the stator architecture in addition to revealing a possible intermediate in the assembly mechanism of the free V₁-ATPase.     

Subunit Structure, Function, and Arrangement in the Yeast and Coated Vesicle V-ATPases

The vacuolar (H⁺)-ATPases (or V-ATPases) are ATP-dependent proton pumps that function both to acidify intracellular compartments and to transport protons across the plasma membrane. Acidification of intracellular compartments is important for such processes as receptor-mediated endocytosis, intracellular trafficking, protein processing, and coupled transport. Plasma membrane V-ATPases function in renal acidification, bone resorption, pH homeostasis, and, possibly, tumor metastasis. This review will focus on work from our laboratories on the V-ATPases from mammalian clathrin-coated vesicles and from yeast. The V-ATPases are composed of two domains. The peripheral V₁ domain has a molecular mass of 640 kDa and is composed of eight different subunits (subunits A–H) of molecular mass 70–13 kDa. The integral V₀ domain, which has a molecular mass of 260 kDa, is composed of five different subunits (subunits a, d, c, c', and c) of molecular mass 100–17 kDa. The V₁ domain is responsible for ATP hydrolysis whereas the V₀ domain is responsible for proton transport. Using a variety of techniques, including cysteine-mediated crosslinking and electron microscopy, we have defined both the overall shape of the V-ATPase and the V₀ domain as well as the location of various subunits within the complex. We have employed site-directed and random mutagenesis to identify subunits and residues involved in nucleotide binding and hydrolysis, proton translocation, and the coupling of these two processes. We have also investigated the mechanism of regulation of the V-ATPase by reversible dissociation and the role of different subunits in this process.