Subunit D (Vma8p) of the yeast vacuolar H+-ATPase plays a role in coupling of proton transport and ATP hydrolysis

Protein Homeostasis Networks and the Use of Yeast to Guide Interventions in Alzheimer's Disease

Alzheimer's Disease (AD) is a progressive multifactorial age-related neurodegenerative disorder that causes the majority of deaths due to dementia in the elderly. Although various risk factors have been found to be associated with AD progression, the cause of the disease is still unresolved. The loss of proteostasis is one of the major causes of AD: it is evident by aggregation of misfolded proteins, lipid homeostasis disruption, accumulation of autophagic vesicles, and oxidative damage during the disease progression. Different models have been developed to study AD, one of which is a yeast model. Yeasts are simple unicellular eukaryotic cells that have provided great insights into human cell biology. Various yeast models, including unmodified and genetically modified yeasts, have been established for studying AD and have provided significant amount of information on AD pathology and potential interventions. The conservation of various human biological processes, including signal transduction, energy metabolism, protein homeostasis, stress responses, oxidative phosphorylation, vesicle trafficking, apoptosis, endocytosis, and ageing, renders yeast a fascinating, powerful model for AD. In addition, the easy manipulation of the yeast genome and availability of methods to evaluate yeast cells rapidly in high throughput technological platforms strengthen the rationale of using yeast as a model. This review focuses on the description of the proteostasis network in yeast and its comparison with the human proteostasis network. It further elaborates on the AD-associated proteostasis failure and applications of the yeast proteostasis network to understand AD pathology and its potential to guide interventions against AD.

Wheat V-H+-ATPase subunit genes significantly affect salt tolerance in Arabidopsis thaliana

Genes for V-H⁺-ATPase subunits were identified and cloned from the salt-tolerant wheat mutant RH8706-49. Sequences of these genes are highly conserved in plants. Overexpression of these genes in Arabidopsis thaliana improved its salt tolerance, and increased the activities of V-H⁺-ATPase and Na⁺/H⁺ exchange, with the largest increase in plants carrying the c subunit of V-H⁺-ATPase. Results from quantitative RT-PCR analysis indicated that the mRNA level of each V-H⁺-ATPase subunit in the Arabidopsis increased under salt stress. Overall, our results suggest that each V-H⁺-ATPase subunit plays a key role in enhancing salt tolerance in plants.

Inhibitors of V-ATPase proton transport reveal uncoupling functions of tether linking cytosolic and membrane domains of V0 subunit a (Vph1p)

Vacuolar ATPases (V-ATPases) are important for many cellular processes, as they regulate pH by pumping cytosolic protons into intracellular organelles. The cytoplasm is acidified when V-ATPase is inhibited; thus we conducted a high-throughput screen of a chemical library to search for compounds that acidify the yeast cytosol in vivo using pHluorin-based flow cytometry. Two inhibitors, alexidine dihydrochloride (EC(50) = 39 μM) and thonzonium bromide (EC(50) = 69 μM), prevented ATP-dependent proton transport in purified vacuolar membranes. They acidified the yeast cytosol and caused pH-sensitive growth defects typical of V-ATPase mutants (vma phenotype). At concentrations greater than 10 μM the inhibitors were cytotoxic, even at the permissive pH (pH 5.0). Membrane fractions treated with alexidine dihydrochloride and thonzonium bromide fully retained concanamycin A-sensitive ATPase activity despite the fact that proton translocation was inhibited by 80-90%, indicating that V-ATPases were uncoupled. Mutant V-ATPase membranes lacking residues 362-407 of the tether of Vph1p subunit a of V(0) were resistant to thonzonium bromide but not to alexidine dihydrochloride, suggesting that this conserved sequence confers uncoupling potential to V(1)V(0) complexes and that alexidine dihydrochloride uncouples the enzyme by a different mechanism. The inhibitors also uncoupled the Candida albicans enzyme and prevented cell growth, showing further specificity for V-ATPases. Thus, a new class of V-ATPase inhibitors (uncouplers), which are not simply ionophores, provided new insights into the enzyme mechanism and original evidence supporting the hypothesis that V-ATPases may not be optimally coupled in vivo. The consequences of uncoupling V-ATPases in vivo as potential drug targets are discussed.

Lansoprazole as a rescue agent in chemoresistant tumors: a phase I/II study in companion animals with spontaneously occurring tumors

BACKGROUND

The treatment of human cancer has been seriously hampered for decades by resistance to chemotherapeutic drugs. Mechanisms underlying this resistance are far from being entirely known. A very efficient mechanism of tumor resistance to drugs is related to the modification of tumour microenvironment through changes in the extracellular and intracellular pH. The acidification of tumor microenvironment depends on proton pumps that actively pump protons outside the cells, mostly to avoid intracellular acidification. In fact, we have shown in pre-clinical settings as pre-treatment with proton-pumps inhibitors (PPI) increase tumor cell and tumor responsiveness to chemotherapeutics. In this study pet with spontaneously occurring cancer proven refractory to conventional chemotherapy have been recruited in a compassionate study.

METHODS

Thirty-four companion animals (27 dogs and 7 cats) were treated adding to their chemotherapy protocols the pump inhibitor lansoprazole at high dose, as suggested by pre-clinical experiments. Their responses have been compared to those of seventeen pets (10 dogs and 7 cats) whose owners did not pursue any other therapy than continuing the currently ongoing chemotherapy protocols.

RESULTS

The drug was overall well tolerated, with only four dogs experiencing side effects due to gastric hypochlorhydria consisting with vomiting and or diarrhea. In terms of overall response twenty-three pets out of 34 had partial or complete responses (67.6%) the remaining patients experienced no response or progressive disease however most owners reported improved quality of life in most of the non responders. On the other hand, only three animals in the control group (17%) experienced short lived partial responses (1-3 months duration) while all the others died of progressive disease within two months.

CONCLUSIONS

high dose proton pump inhibitors have been shown to induce reversal of tumor chemoresistance as well as improvement of the quality of life in pets with down staged cancer and in the majority of the treated animals PPI were well tolerated. Further studies are warranted to assess the efficacy of this strategy in patients with advanced cancers in companion animals as well as in humans.

Vma8p-GFP fusions can be functionally incorporated into V-ATPase, suggesting structural flexibility at the top of V1

The vacuolar ATPase (V-ATPase) complex of yeast (Saccharomyces cerevisiae) is comprised of two sectors, V(1) (catalytic) and V(O) (proton transfer). The hexameric (A(3)B(3)) cylinder of V(1) has a central cavity that must accommodate at least part of the rotary stalk of V-ATPase, a key component of which is subunit D (Vma8p). Recent electron microscopy (EM) data for the prokaryote V-ATPase complex (Thermus thermophilus) suggest that subunit D penetrates deeply into the central cavity. The functional counterpart of subunit D in mitochondrial F(1)F(O)-ATP synthase, subunit γ, occupies almost the entire length of the central cavity. To test whether the structure of yeast Vma8p mirrors that of subunit γ, we probed the location of the C-terminus of Vma8p by attachment of a large protein adduct, green fluorescent protein (GFP). We found that truncated Vma8p proteins lacking up to 40 C-terminal residues fused to GFP can be incorporated into functional V-ATPase complexes, and are able to support cell growth under alkaline conditions. We conclude that large protein adducts can be accommodated at the top of the central cavity of V(1) without compromising V-ATPase function, arguing for structural flexibility of the V(1) sector.

Saccharomyces cerevisiae genome-wide mutant screen for sensitivity to 2,4-diacetylphloroglucinol, an antibiotic produced by Pseudomonas fluorescens

2,4-Diacetylphloroglucinol (2,4-DAPG), an antibiotic produced by Pseudomonas fluorescens, has broad-spectrum antibiotic activity, inhibiting organisms ranging from viruses, bacteria, and fungi to higher plants and mammalian cells. The biosynthesis and regulation of 2,4-DAPG in P. fluorescens are well described, but the mode of action against target organisms is poorly understood. As a first step to elucidate the mechanism, we screened a deletion library of Saccharomyces cerevisiae in broth and agar medium supplemented with 2,4-DAPG. We identified 231 mutants that showed increased sensitivity to 2,4-DAPG under both conditions, including 22 multidrug resistance-related mutants. Three major physiological functions correlated with an increase in sensitivity to 2,4-DAPG: membrane function, reactive oxygen regulation, and cell homeostasis. Physiological studies with wild-type yeast validated the results of the mutant screens. The chemical-genetic fitness profile of 2,4-DAPG resembled those of menthol, sodium azide, and hydrogen peroxide determined in previous high-throughput screening studies. Collectively, these findings indicate that 2,4-DAPG acts on multiple basic cellular processes.

Proton pump inhibitors as anti vacuolar-ATPases drugs: a novel anticancer strategy

The vacuolar ATPases are ATP-dependent proton pumps whose functions include the acidification of intracellular compartments and the extrusion of protons through the cell cytoplasmic membrane. These pumps play a pivotal role in the regulation of cell pH in normal cells and, to a much greater extent, in tumor cells. In fact, the glucose metabolism in hypoxic conditions by the neoplasms leads to an intercellular pH drift towards acidity. The acid microenvironment is modulated through the over-expression of H+ transporters that are also involved in tumor progression, invasiveness, distant spread and chemoresistance. Several strategies to block/downmodulate the efficiency of these transporters are currently being investigated. Among them, proton pump inhibitors have shown to successfully block the H+ transporters in vitro and in vivo, leading to apoptotic death. Furthermore, their action seems to synergize with conventional chemotherapy protocols, leading to chemosensitization and reversal of chemoresistance. Aim of this article is to critically revise the current knowledge of this cellular machinery and to summarize the therapeutic strategies developed to counter this mechanism.

Vacuolar H+-ATPase meets glycosylation in patients with cutis laxa

Glycosylation of proteins is one of the most important post-translational modifications. Defects in the glycan biosynthesis result in congenital malformation syndromes, also known as congenital disorders of glycosylation (CDG). Based on the iso-electric focusing patterns of plasma transferrin and apolipoprotein C-III a combined defect in N- and O-glycosylation was identified in patients with autosomal recessive cutis laxa type II (ARCL II). Disease-causing mutations were identified in the ATP6V0A2 gene, encoding the a2 subunit of the vacuolar H(+)-ATPase (V-ATPase). The V-ATPases are multi-subunit, ATP-dependent proton pumps located in membranes of cells and organels. In this article, we describe the structure, function and regulation of the V-ATPase and the phenotypes currently known to result from V-ATPase mutations. A clinical overview of cutis laxa syndromes is presented with a focus on ARCL II. Finally, the relationship between ATP6V0A2 mutations, the glycosylation defect and the ARCLII phenotype is discussed.

Cloning and functional analysis of wheat V-H+-ATPase subunit genes

The root microsomal proteomes of salt-tolerant and salt-sensitive wheat lines under salt stress were analyzed by two-dimensional electrophoresis and mass spectrum. A wheat V-H(+)-ATPase E subunit protein was obtained whose expression was enhanced by salt stress. In silicon cloning identified the full-length cDNA sequences of nine subunits and partial cDNA sequences of two subunits of wheat V-H(+)-ATPase. The expression profiles of these V-H(+)-ATPase subunits in roots and leaves of both salt-tolerant and salt-sensitive wheat lines under salt and abscisic acid (ABA) stress were analyzed. The results indicate that the coordinated enhancement of the expression of V-H(+)-ATPase subunits under salt and ABA stress is an important factor determining improved salt tolerance in wheat. The expression of these subunits was tissue-specific. Overexpression of the E subunit by transgenic Arabidopsis thaliana was able to enhance seed germination, root growth and adult seedling growth under salt stress.

Structure and regulation of the vacuolar ATPases

The vacuolar (H(+))-ATPases (V-ATPases) are ATP-dependent proton pumps responsible for both acidification of intracellular compartments and, for certain cell types, proton transport across the plasma membrane. Intracellular V-ATPases function in both endocytic and intracellular membrane traffic, processing and degradation of macromolecules in secretory and digestive compartments, coupled transport of small molecules such as neurotransmitters and ATP and in the entry of pathogenic agents, including envelope viruses and bacterial toxins. V-ATPases are present in the plasma membrane of renal cells, osteoclasts, macrophages, epididymal cells and certain tumor cells where they are important for urinary acidification, bone resorption, pH homeostasis, sperm maturation and tumor cell invasion, respectively. The V-ATPases are composed of a peripheral domain (V(1)) that carries out ATP hydrolysis and an integral domain (V(0)) responsible for proton transport. V(1) contains eight subunits (A-H) while V(0) contains six subunits (a, c, c', c'', d and e). V-ATPases operate by a rotary mechanism in which ATP hydrolysis within V(1) drives rotation of a central rotary domain, that includes a ring of proteolipid subunits (c, c' and c''), relative to the remainder of the complex. Rotation of the proteolipid ring relative to subunit a within V(0) drives active transport of protons across the membrane. Two important mechanisms of regulating V-ATPase activity in vivo are reversible dissociation of the V(1) and V(0) domains and changes in coupling efficiency of proton transport and ATP hydrolysis. This review focuses on recent advances in our lab in understanding the structure and regulation of the V-ATPases.

Influence of ATP and ADP on dissociation of the V-ATPase into its V(1) and V(O) complexes

Although the reversible dissociation of the V(1)V(O) holoenzyme into its V(1) and V(O) complexes is a general mechanism for the regulation of V-ATPases, important aspects are still not understood. By analyzing the endogenous nucleotide content of the V(1)V(O) holoenzyme and of the V(1) complex, both purified from Manduca sexta larval midgut, we found that the V(1) complex contained 1.7 molec. of ADP, whereas only 0.3 molec. of ADP were bound to the V(1)V(O) holoenzyme. By contrast, both proteins contained only negligible amounts of ATP. Incubation of the V(1)V(O) holoenzyme with various adenine nucleotides revealed that ATP hydrolysis, leading to a state containing tightly bound ADP is necessary for its dissociation.

Characterization of vacuolar-ATPase and selective inhibition of vacuolar-H(+)-ATPase in osteoclasts

V-ATPase plays important roles in controlling the extra- and intra-cellular pH in eukaryotic cell, which is most crucial for cellular processes. V-ATPases are composed of a peripheral V(1) domain responsible for ATP hydrolysis and integral V(0) domain responsible for proton translocation. Osteoclasts are multinucleated cells responsible for bone resorption and relate to many common lytic bone disorders such as osteoporosis, bone aseptic loosening, and tumor-induced bone loss. This review summarizes the structure and function of V-ATPase and its subunit, the role of V-ATPase subunits in osteoclast function, V-ATPase inhibitors for osteoclast function, and highlights the importance of V-ATPase as a potential prime target for anti-resorptive agents.

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.

New insights into the regulation of V-ATPase-dependent proton secretion

The vacuolar H(+)-ATPase (V-ATPase) is a key player in several aspects of cellular function, including acidification of intracellular organelles and regulation of extracellular pH. In specialized cells of the kidney, male reproductive tract and osteoclasts, proton secretion via the V-ATPase represents a major process for the regulation of systemic acid/base status, sperm maturation and bone resorption, respectively. These processes are regulated via modulation of the plasma membrane expression and activity of the V-ATPase. The present review describes selected aspects of V-ATPase regulation, including recycling of V-ATPase-containing vesicles to and from the plasma membrane, assembly/disassembly of the two domains (V(0) and V(1)) of the holoenzyme, and the coupling ratio between ATP hydrolysis and proton pumping. Modulation of the V-ATPase-rich cell phenotype and the pathophysiology of the V-ATPase in humans and experimental animals are also discussed.

Structural and functional separation of the N- and C-terminal domains of the yeast V-ATPase subunit H

The H subunit of the yeast V-ATPase is an extended structure with two relatively independent domains, an N-terminal domain consisting of amino acids 1-348 and a C-terminal domain consisting of amino acids 352-478. We have expressed these two domains independently and together in a yeast strain lacking the H subunit (vma13Delta mutant). The N-terminal domain partially complements the growth defects of the mutant and supports approximately 25% of the wild-type Mg(2+)-dependent ATPase activity in isolated vacuolar vesicles, but surprisingly, this activity is both largely concanamycin-insensitive and uncoupled from proton transport. The C-terminal domain does not complement the growth defects, and supports no ATP hydrolysis or proton transport, even though it is recruited to the vacuolar membrane. Expression of both domains in a vma13Delta strain gives better complementation than either fragment alone and results in higher concanamycin-sensitive ATPase activity and ATP-driven proton pumping than the N-terminal domain alone. Thus, the two domains make complementary contributions to structural and functional coupling of the peripheral V(1) and membrane V(o) sectors of the V-ATPase, but this coupling does not require that they be joined covalently. The N-terminal domain alone is sufficient for activation of ATP hydrolysis in V(1), but the C-terminal domain is essential for proper communication between the V(1) and V(o) sectors.

Characterization of genes encoding metal tolerance proteins isolated from Nicotiana glauca and Nicotiana tabacum

We have isolated a metal tolerance protein (MTP) gene, NgMTP1, from Nicotiana glauca (a potential phytoremediator plant) and two MTP genes, NtMTP1a and NtMTP1b, from Nicotiana tabacum. These three genes shared approximately 95% homology at the amino acid level. Heterologous expression of any of these three genes complemented Zn and Co tolerance in yeast mutants to a similar extent. In yeast, these proteins were shown to be located to vacuole membrane. These results suggest that the three MTPs operate by sequestering Zn and Co into vacuoles, thereby reducing the toxicity of these metals.

Involvement of the nonhomologous region of subunit A of the yeast V-ATPase in coupling and in vivo dissociation

The catalytic nucleotide binding subunit (subunit A) of the vacuolar proton-translocating ATPase (or V-ATPase) is homologous to the beta-subunit of the F-ATPase but contains a 90-amino acid insert not present in the beta-subunit, termed the nonhomologous region. We previously demonstrated that mutations in this region lead to changes in coupling of proton transport and ATPase activity and to inhibition of in vivo dissociation of the V-ATPase complex, an important regulatory mechanism (Shao, E., Nishi T., Kawasaki-Nishi, S., and Forgac, M. (2003) J. Biol. Chem. 278, 12985-12991). Measurement of the ATP dependence of coupling for the wild type and mutant proteins demonstrates that the coupling differences are observed at ATP concentrations up to 1 mm. A decrease in coupling efficiency is observed at higher ATP concentrations for the wild type and mutant V-ATPases. Immunoprecipitation of an epitope-tagged nonhomologous region from cell lysates indicates that this region is able to bind to the integral V0 domain in the absence of the remainder of the A subunit, an interaction confirmed by immunoprecipitation of V0. Interaction between the nonhomologous region and V0 is reduced upon incubation of cells in the absence of glucose, suggesting that the nonhomologous region may act as a trigger to activate in vivo dissociation. Immunoprecipitation suggests that the epitope tag on the nonhomologous region becomes less accessible upon glucose withdrawal, possibly due to binding to another cellular target. In vivo dissociation of the V-ATPase in response to glucose removal is also blocked by chloroquine, a weak base that neutralizes the acidic pH of the vacuole. The results suggest that the dependence of in vivo dissociation of the V-ATPase on catalytic activity may be due to neutralization of the yeast vacuole, which in turn blocks glucose-dependent dissociation.

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.

The insect plasma membrane H+ V-ATPase: intra-, inter-, and supramolecular aspects

The plasma membrane H+ V-ATPase from the midgut of larval Manduca sexta, commonly called the tobacco hornworm, is the sole energizer of epithelial ion transport in this tissue, being responsible for the alkalinization of the gut lumen up to a pH of more than 11 and for any active ion movement across the epithelium. This minireview deals with those topics of our recent research on this enzyme that may contribute novel aspects to the biochemistry and physiology of V-ATPases. Our research approaches include intramolecular aspects such as subunit topology and the inhibition by macrolide antibiotics, intermolecular aspects such as the hormonal regulation of V-ATPase biosynthesis and the interaction of the V-ATPase with the actin cytoskeleton, and supramolecular aspects such as the interactions of V-ATPase, K+/H+ antiporter, and ion channels, which all function as an ensemble in the transepithelial movement of potassium ions.

Salicylihalamide A inhibits the V0 sector of the V-ATPase through a mechanism distinct from bafilomycin A1

The newly identified specific V-ATPase inhibitor, salicylihalamide A, is distinct from any previously identified V-ATPase inhibitors in that it inhibits only mammalian V-ATPases, but not those from yeast or other fungi (Boyd, M. R., Farina, C., Belfiore, P., Gagliardi, S., Kim, J. W., Hayakawa, Y., Beutler, J. A., McKee, T. C., Bowman, B. J., and Bowman, E. J. (2001) J. Pharmacol. Exp. Ther. 297, 114-120). In addition, salicylihalamide A does not compete with concanamycin or bafilomycin for binding to V-ATPase, indicating that it has a different binding site from those classic V-ATPase inhibitors (Huss, M., Ingenhorst, G., Konig, S., Gassel, M., Drose, S., Zeeck, A., Altendorf, K., and Wieczorek, H. (2002) J. Biol. Chem. 277, 40544-40548). By using purified bovine brain V-pump and its dissociated V(1) and V(0) sectors, we identified the recognition and binding site for salicylihalamide to be within the V(0) domain. Salicylihalamide does not inhibit the ATP hydrolysis activity of the dissociated V(1)-ATPase but inhibits the ATPase activity of the holoenzyme by inhibiting the V(0) domain. Salicylihalamide causes a dramatic redistribution of cytosolic V(1) from soluble to membrane-associated form, a change not observed in cells treated with either bafilomycin or NH(4)Cl. By synthesizing and characterizing a series of salicylihalamide derivatives, we investigated the structural determinants of salicylihalamide inhibition in terms of potency and reversibility, and used this information to suggest a possible binding mechanism.

The F subunit of Thermus thermophilus V1-ATPase promotes ATPase activity but is not necessary for rotation

V(1)-ATPase from the thermophilic bacterium Thermus thermophilus is a molecular rotary motor with a subunit composition of A(3)B(3)DF, and its central rotor is composed of the D and F subunits. To determine the role of the F subunit, we generated an A(3)B(3)D subcomplex and compared it with A(3)B(3)DF. The ATP hydrolyzing activity of A(3)B(3)D (V(max) = 20 s(-1)) was lower than that of A(3)B(3)DF (V(max) = 31 s(-1)) and was more susceptible to MgADP inhibition during ATP hydrolysis. A(3)B(3)D was able to bind the F subunit to form A(3)B(3)DF. The C-terminally truncated F((Delta85-106)) subunit was also bound to A(3)B(3)D, but the F((Delta69-106)) subunit was not, indicating the importance of residues 69-84 of the F subunit for association with A(3)B(3)D. The ATPase activity of A(3)B(3)DF((Delta85-106)) (V(max) = 24 s(-1)) was intermediate between that of A(3)B(3)D and A(3)B(3)DF. A single molecule experiment showed the rotation of the D subunit in A(3)B(3)D, implying that the F subunit is a dispensable component for rotation itself. Thus, the F subunit binds peripherally to the D subunit, but promotes V(1)-ATPase catalysis.

Yeast V1-ATPase: affinity purification and structural features by electron microscopy

V1-ATPase from the yeast Saccharomyces cerevisiae was purified via a FLAG affinity tag introduced into the N terminus of the G subunit. The preparation migrated as a single band in native gel electrophoresis and contained subunits ABCDEFGH (with subunit C present at substoichiometric amounts) as determined by matrix-assisted laser desorption ionization time-of-flight mass spectrometry. The initial specific Ca-ATPase activity was approximately 6 micromol/min/mg. The structure of the yeast V1-ATPase was studied by electron microscopy of negatively stained and frozen hydrated samples. A 25-A resolution three-dimensional model of the complex was calculated from two-dimensional projections by the angular reconstitution technique. The model shows six elongated densities arranged in pseudo-3-fold symmetry around a large central cavity. At the top of the molecule, various protrusions can be seen. At the bottom of the complex, two large masses are visible that are connected to the main body of the molecule. Comparison of the yeast V1 structure with the structure of the intact V1V0-ATPase from bovine brain clathrin-coated vesicles (Wilkens, S., Vasilyeva, E., and Forgac, M. (1999) J. Biol. Chem. 274, 31804-31810) indicates that the structure of the isolated V1 from yeast is very similar to the structure of the V1 domain in the intact V-ATPase complex.

Expression and function of the mouse V-ATPase d subunit isoforms

We have identified a cDNA encoding a novel isoform of the mouse V-ATPase d subunit (d2). The protein encoded is 350 amino acids in length and shows 42 and 67% identity to the yeast d subunit (Vma6p) and the mouse d1 isoform, respectively. Reverse transcriptase-PCR analysis using isoform-specific primers demonstrate that d2 is expressed mainly in kidney and at lower levels in heart, spleen, skeletal muscle, and testis. Although d1 and d2 show similar levels of sequence homology to Vma6p, only the d1 isoform can complement the phenotype of a yeast strain in which VMA6 has been disrupted when cells are grown at 30 degrees C. The d2 isoform, however, can complement the vma6Delta phenotype when cells are grown at 25 degrees C. Moreover, partial assembly of the V-ATPase complex on the vacuolar membrane can be detected under these conditions, although assembly is significantly lower than that observed for the strain expressing Vma6p. This reduced assembly is also reflected in a reduced level of concanamycin-sensitive ATPase activity and proton transport in isolated vacuoles. Comparison of the kinetic properties of V-ATPase complexes containing Vma6p and d1 demonstrate that although the Km for ATP hydrolysis is similar (0.26 and 0.31 mm, respectively), the coupling ratio (proton transport/ATP hydrolysis) is approximately 3-6-fold higher for d1-containing complexes than for Vma6p-containing complexes. These results suggest that subunit d may play a role in coupling of proton transport and ATP hydrolysis.

Human targets of Pseudomonas aeruginosa pyocyanin

Pseudomonas aeruginosa produces copious amounts of the redoxactive tricyclic compound pyocyanin that kills competing microbes and mammalian cells, especially during cystic fibrosis lung infection. Cross-phylum susceptibility to pyocyanin suggests the existence of evolutionarily conserved physiological targets. We screened a Saccharomyces cerevisiae deletion library to identify presumptive pyocyanin targets with the expectation that similar targets would be conserved in humans. Fifty S. cerevisiae targets were provisionally identified, of which 60% have orthologous human counterparts. These targets encompassed major cellular pathways involved in the cell cycle, electron transport and respiration, epidermal cell growth, protein sorting, vesicle transport, and the vacuolar ATPase. Using cultured human lung epithelial cells, we showed that pyocyanin-mediated reactive oxygen intermediates inactivate human vacuolar ATPase, supporting the validity of the yeast screen. We discuss how the inactivation of V-ATPase may negatively impact the lung function of cystic fibrosis patients.

Catalysis, evolution and life

Living organisms are unique in their ability to generate and replicate ordered systems from disordered components. Generation of order, replication of the individual, and evolution of the species all depend on the successful utilization of external energy derived from chemicals and light. The information for reproduction is encoded in nucleic acids, but evolution depends on a limited variability in replication, and proceeds through the selection of individuals with altered biochemistry. Essentially all biochemistry is catalyzed; therefore, altered biochemistry implies altered or new catalysts. In that sense catalysis is the medium of evolution. We propose that a basic property of enzymes, at least as fundamental as reaction rate enhancement, is to adjust the reaction path by altering and eventually optimizing the reversible interchange of chemical, electrical and mechanical energy among themselves and their reactants.

Proton translocation driven by ATP hydrolysis in V-ATPases

The vacuolar H(+)-ATPases (or V-ATPases) are a family of ATP-dependent proton pumps responsible for acidification of intracellular compartments and, in certain cases, proton transport across the plasma membrane of eukaryotic cells. They are multisubunit complexes composed of a peripheral domain (V(1)) responsible for ATP hydrolysis and an integral domain (V(0)) responsible for proton translocation. Based upon their structural similarity to the F(1)F(0) ATP synthases, the V-ATPases are thought to operate by a rotary mechanism in which ATP hydrolysis in V(1) drives rotation of a ring of proteolipid subunits in V(0). This review is focused on the current structural knowledge of the V-ATPases as it relates to the mechanism of ATP-driven proton translocation.

Mutational analysis of the non-homologous region of subunit A of the yeast V-ATPase

Subunit A is the catalytic nucleotide binding subunit of the vacuolar proton-translocating ATPase (or V-ATPase) and is homologous to subunit beta of the F(1)F(0) ATP synthase (or F-ATPase). Amino acid sequence alignment of these subunits reveals a 90-amino acid insert in subunit A (termed the non-homologous region) that is absent from subunit beta. To investigate the functional role of this region, site-directed mutagenesis has been performed on the VMA1 gene that encodes subunit A in yeast. Substitutions were performed on 13 amino acid residues within this region that are conserved in all available A subunit sequences. Most of the 18 mutations introduced showed normal assembly of the V-ATPase. Of these, one (R219K) greatly reduced both proton transport and ATPase activity. By contrast, the P217V mutant showed significantly reduced ATPase activity but higher than normal levels of proton transport, suggesting an increase in coupling efficiency. Two other mutations in the same region (P223V and P233V) showed decreased coupling efficiency, suggesting that changes in the non-homologous region can alter coupling of proton transport and ATP hydrolysis. It was previously shown that the V-ATPase must possess at least 5-10% activity relative to wild type to undergo in vivo dissociation in response to glucose withdrawal. However, four of the mutations studied (G150A, D157E, P177V, and P223V) were partially or completely blocked in dissociation despite having greater than 30% of wild type levels of activity. These results suggest that changes in the non-homologous region can also alter in vivo dissociation of the V-ATPase independent of effects on activity.

Resolution of the V1 ATPase from Manduca sexta into subcomplexes and visualization of an ATPase-active A3B3EG complex by electron microscopy

The effect of the ATPase activity of Manduca sexta V(1) ATPase by the amphipathic detergent lauryldimethylamine oxide (LDAO) and the relationship of these activities to the subunit composition of V(1) were studied. The V(1) was highly activated in the presence of 0.04-0.06% LDAO combined with release of the subunits H, C, and F from the enzyme. Increase of LDAO concentration to 0.1-0.2% caused the characterized subcomplexes A(3)B(3)HEGF and A(3)B(3)EG with a remaining ATPase activity of 52 and 65%, respectively. The hydrolytic-active A(3)B(3)EG subcomplex has been visualized by electron microscopy showing six major masses of density in a pseudo-hexagonal arrangement surrounding a seventh mass. The compositions of the various subcomplexes and fragments of V(1) provide an organization of the subunits in the enzyme in the framework of the known three-dimensional reconstruction of the V(1) ATPase from M. sexta (Radermacher, M., Ruiz, T., Wieczorek, H., and Grüber, G. (2001) J. Struct. Biol. 135, 26-37).

Structure, subunit function and regulation of the coated vesicle and yeast vacuolar (H(+))-ATPases

The vacuolar (H(+))-ATPases (or V-ATPases) are ATP-dependent proton pumps that function to acidify intracellular compartments in eukaryotic cells. This acidification is essential for such processes as receptor-mediated endocytosis, intracellular targeting of lysosomal enzymes, protein processing and degradation and the coupled transport of small molecules. V-ATPases in the plasma membrane of specialized cells also function in such processes as renal acidification, bone resorption and pH homeostasis. Work from our laboratory has focused on the V-ATPases from clathrin-coated vesicles and yeast vacuoles.Structurally, the V-ATPases are composed of two domains: a peripheral complex (V(1)) composed of eight different subunits (A-H) that is responsible for ATP hydrolysis and an integral complex (V(0)) composed of five different subunits (a, d, c, c' and c") that is responsible for proton translocation. Electron microscopy has revealed the presence of multiple stalks connecting the V(1) and V(0) domains, and crosslinking has been used to address the arrangement of subunits in the complex. Site-directed mutagenesis has been employed to identify residues involved in ATP hydrolysis and proton translocation and to study the topology of the 100 kDa a subunit. This subunit has been shown to control intracellular targeting of the V-ATPase and to influence reversible dissociation and coupling of proton transport and ATP hydrolysis.

Three-dimensional map of a plant V-ATPase based on electron microscopy

V-ATPases pump protons into the interior of various subcellular compartments at the expense of ATP. Previous studies have shown that these pumps comprise a membrane-integrated, proton-translocating (V(0)), and a soluble catalytic (V(1)) subcomplex connected to one another by a thin stalk region. We present two three-dimensional maps derived from electron microscopic images of the complete V-ATPase complex from the plant Kalanchoë daigremontiana at a resolution of 2.2 nm. In the presence of a non-hydrolyzable ATP analogue, the details of the stalk region between V(0) and V(1) were revealed for the first time in their three-dimensional organization. A central stalk was surrounded by three peripheral stalks of different sizes and shapes. In the absence of the ATP analogue, the tilt of V(0) changed with respect to V(1), and the stalk region was less clearly defined, perhaps due to increased flexibility and partial detachment of some of the peripheral stalks. These structural changes corresponded to decreased stability of the complex and might be the initial step in a controlled disassembly.

A simple nomenclature for a complex proton pump: VHA genes encode the vacuolar H(+)-ATPase

The vacuolar-type H(+)-ATPase acidifies intracellular compartments and is essential for many processes, including cotransport, guard cell movement, development, and tolerance to environmental stress. We have identified at least 26 genes encoding subunits of the vacuolar-type H(+)-ATPase in the Arabidopsis thaliana genome, although inconsistent nomenclature of these genes is confusing. The pump consists of subunits A through H of the peripheral V(1) complex, and subunits a, c, c" and d of the V(o) membrane sector. Most V(1) subunits are encoded by a single gene, whereas V(o) subunits are encoded by multiple genes found in duplicated segments of the genome. We propose to name these genes VHA-x, where x represents the letter code for each subunit. Applying a consistent nomenclature will help us to understand how the expression, assembly and activity of this pump are integrated with plant growth, signaling, development and adaptation.

Mutational analysis of the subunit C (Vma5p) of the yeast vacuolar H+-ATPase

Subunit C is a V(1) sector subunit found in all vacuolar H(+)-ATPases (V-ATPases) that may be part of the peripheral stalk connecting the peripheral V(1) sector with the membrane-bound V(0) sector of the enzyme (Wilkens, S., Vasilyeva, E., and Forgac, M. (1999) J. Biol. Chem. 274, 31804--31810). To elucidate subunit C function, we performed random and site-directed mutagenesis of the yeast VMA5 gene. Site-directed mutations in the most highly conserved region of Vma5p, residues 305--325, decreased catalytic activity of the V-ATPase by up to 48% without affecting assembly. A truncation mutant (K360stop) identified by random mutagenesis suggested a small region near the C terminus of the protein (amino acids 382--388) might be important for subunit stability. Site-directed mutagenesis revealed that three aromatic amino acids in this region (Tyr-382, Phe-385, and Tyr-388) in addition to four other conserved aromatic amino acids (Phe-260, Tyr-262, Phe-296, Phe-300) are essential for stable assembly of V(1) with V(0), although alanine substitutions at these positions support some activity in vivo. Surprisingly, three mutations (F260A, Y262A, and F385A) greatly decrease the stability of the V-ATPase in vitro but increase its k(cat) for ATP hydrolysis and proton transport by at least 3-fold. The peripheral stalk of V-ATPases must balance the stability essential for productive catalysis with the dynamic instability involved in regulation; these three mutations may perturb that balance.

Cysteine-directed cross-linking to subunit B suggests that subunit E forms part of the peripheral stalk of the vacuolar H+-ATPase

We have employed a combination of site-directed mutagenesis and covalent cross-linking to identify subunits in close proximity to subunit B in the vacuolar H(+)-ATPase (V-ATPase) complex. Unique cysteine residues were introduced into a Cys-less form of subunit B, and the V-ATPase complex in isolated vacuolar membranes from each mutant strain was reacted with the bifunctional, photoactivable maleimide reagent 4-(N-maleimido)benzophenone. Photoactivation resulted in cross-linking of the unique sulfhydryl groups on subunit B with other subunits in the complex. Four of the eight mutants constructed containing a unique cysteine residue at Ala(15), Lys(45), Glu(494), or Thr(501) resulted in the formation of cross-linked products, which were recognized by Western blot analysis using antibodies against both subunits B and E. These products had a molecular mass of 84 kDa, consistent with a cross-linked product of subunits B and E. Molecular modeling of subunit B places Ala(15) and Lys(45) near the top of the V(1) structure (i.e. farthest from the membrane), whereas Glu(494) and Thr(501) are predicted to reside near the bottom of V(1), with all four residues predicted to be oriented toward the external surface of the complex. A model incorporating these and previous data is presented in which subunit E exists in an extended conformation on the outer surface of the A(3)B(3) hexamer that forms the core of the V(1) domain. This location for subunit E suggests that this subunit forms part of the peripheral stalk of the V-ATPase that links the V(1) and V(0) domains.

The vacuolar (H+)-ATPases--nature's most versatile proton pumps

The pH of intracellular compartments in eukaryotic cells is a carefully controlled parameter that affects many cellular processes, including intracellular membrane transport, prohormone processing and transport of neurotransmitters, as well as the entry of many viruses into cells. The transporters responsible for controlling this crucial parameter in many intracellular compartments are the vacuolar (H+)-ATPases (V-ATPases). Recent advances in our understanding of the structure and regulation of the V-ATPases, together with the mapping of human genetic defects to genes that encode V-ATPase subunits, have led to tremendous excitement in this field.

Novel vacuolar H+-ATPase complexes resulting from overproduction of Vma5p and Vma13p

The vacuolar H(+)-ATPase (V-ATPase) is a multisubunit complex composed of two sectors: V(1), a peripheral membrane sector responsible for ATP hydrolysis, and V(0), an integral membrane sector that forms a proton pore. Vma5p and Vma13p are V(1) sector subunits that have been implicated in the structural and functional coupling of the V-ATPase. Cells overexpressing Vma5p and Vma13p demonstrate a classic Vma(-) growth phenotype. Closer biochemical examination of Vma13p-overproducing strains revealed a functionally uncoupled V-ATPase in vacuolar vesicles. The ATP hydrolysis rate was 72% of the wild-type rate; but there was no proton translocation, and two V(1) subunits (Vma4p and Vma8p) were present at lower levels. Vma5p overproduction moderately affected both V-ATPase activity and proton translocation without affecting enzyme assembly. High level overexpression of Vma5p and Vma13p was lethal even in wild-type cells. In the absence of an intact V(0) sector, overproduction of Vma5p and Vma13p had a more detrimental effect on growth than their deletion. Overproduced Vma5p associated with cytosolic V(1) complexes; this association may cause the lethality.

Arg-735 of the 100-kDa subunit a of the yeast V-ATPase is essential for proton translocation

The vacuolar (H(+))-ATPases (V-ATPases) are ATP-dependent proton pumps that acidify intracellular compartments and pump protons across specialized plasma membranes. Proton translocation occurs through the integral V(0) domain, which contains five different subunits (a, d, c, c', and c"). Proton transport is critically dependent on buried acidic residues present in three different proteolipid subunits (c, c', and c"). Mutations in the 100-kDa subunit a have also influenced activity, but none of these residues has proven to be required absolutely for proton transport. On the basis of previous observations on the F-ATPases, we have investigated the role of two highly conserved arginine residues present in the last two putative transmembrane segments of the yeast V-ATPase a subunit (Vph1p). Substitution of Asn, Glu, or Gln for Arg-735 in TM8 gives a V-ATPase that is fully assembled but is totally devoid of proton transport and ATPase activity. Replacement of Arg-735 by Lys gives a V-ATPase that, although completely inactive for proton transport, retains 24% of wild-type ATPase activity, suggesting a partial uncoupling of proton transport and ATP hydrolysis in this mutant. By contrast, nonconservative mutations of Arg-799 in TM9 lead to both defective assembly of the V-ATPase complex and decreases in activity of the assembled V-ATPase. These results suggest that Arg-735 is absolutely required for proton transport by the V-ATPases and is discussed in the context of a revised model of the topology of the 100-kDa subunit a.

Structure–function relationships of A-, F- and V-ATPases

Ion-translocating ATPases, such as the F1Fo-, V1Vo- and archaeal A1Ao enzymes, are essential cellular energy converters which transduce the chemical energy of ATP hydrolysis into transmembrane ionic electrochemical potential differences. Based on subunit composition and primary structures of the subunits, these types of ATPases are related through evolution; however, they differ with respect to function. Recent work has focused on the three-dimensional structural relationships of the major, nucleotide-binding subunits A and B of the A1/V1-ATPases and the corresponding β and α subunits of the F1-ATPase, and the location of the coupling subunits within the stalk that provide the physical linkage between the regions of ATP hydrolysis and ion transduction. This review focuses on the structural homologies and diversities of A1-, F1- and V1-ATPases, in particular on significant differences between the stalk regions of these families of enzymes.

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.

Structure of the VPATPD gene encoding subunit D of the human vacuolar proton ATPase

The HSD11B2 and VPATPD genes encoding the human kidney isozyme of 11beta-hydroxysteroid dehydrogenase (11-HSD2) and subunit D of the vacuolar proton ATPase, respectively, are located on chromosome 16q22. They are transcribed from complementary DNA strands and their 3' ends are only 0.5 kilobase apart. Because polymorphisms in HSD11B2 have been associated with hypertension and salt sensitivity, we characterized the human VPATPD gene. It spans 19 kb and consists of 8 exons. The encoded protein is 99.5% identical to mouse subunit D at the amino acid level. An alternating purine-pyrimidine tract is located in the 3'-untranslated region of VPATPD. On genotyping 17 hypertensive subjects, no length polymorphism was found. Although VPATPD and HSD11B2 are both expressed in kidney and placenta, they are regulated differently; forskolin upregulates HSD11B2 but not VPATPD in human choriocarcinoma JEG3 cells. The functional significance of the proximity of these two genes remains to be established.