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 V1Vo-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.
Citation: Hildenbrand ZL, Molugu SK, Stock D, Bernal RA (2010) The C-H Peripheral Stalk Base: A Novel Component in V1-ATPase Assembly. PLoS ONE 5(9): e12588. doi:10.1371/journal.pone.0012588
Editor: Maxim Antopolsky, University of Helsinki, Finland
Received: July 1, 2010; Accepted: August 10, 2010; Published: September 3, 2010
Copyright: © 2010 Hildenbrand et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: Only University startup funds were used to support the work presented here. The University of Texas at El Paso had no role in study, design, data collection and analysis, decision to publish or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Vacuolar ATPases (V-ATPases) are biological rotary motors that harness the energy derived from ATP hydrolysis to drive the translocation of protons across a membrane. These proton pumps generate electrochemical gradients across organelle and plasma membranes to facilitate a number of secondary transport systems that are involved in a wide variety of biological processes . V-ATPases are found in particularly high concentrations in many intracellular compartments such as vacuoles, endosomes, lysosomes, clathrin-coated vesicles and synaptic vesicles. Here they assist in receptor-mediated endocytosis, intracellular trafficking, apoptosis, and the uptake and storage of neurotransmitters, respectively –. Defects in the human V-ATPase enzyme play a putative role in number of pathologies including osteopetrosis, osteoporosis, gastritis, diabetes and cancer –.
Structurally the yeast V-ATPase is a large complex that is composed of 14 different subunits arranged into two functional domains; a cytosolic V1 and a membrane-bound VO. The soluble V1-domain has a molecular mass of approximately 640 kDa and is composed of eight subunits denoted A-H that are architecturally arranged into sub-complexes according to their distinct roles in the rotary mechanism. For example, subunits A and B form the A3B3 catalytic complex that is responsible for hydrolyzing ATP and inducing the rotation of the DF central rotor stalk.
The architecture of the yeast V1-ATPase has been previously investigated by X-ray scattering , electrospray ionization-mass spectrometry , and electron microscopy –, revealing the existence of three peripheral stalks. Additionally, recent work has shown subunits C and H to be positioned at the V1VO-interface , , where they interact with the three EG peripheral stalk heterodimers , , . Subunits C and H are believed to undergo a conformation change that plays a major role in the regulatory dissociation process of the V-ATPase , , . Together these studies indicate that subunits C and H function independently of each other however, the extent of their interactions at the V1VO-interface has remained unclear.
In the work presented here, cryo-electron microscopy (cryo-EM) was used to visualize the yeast V1-ATPase, revealing subunits C and H engaged in a unique interaction. Our CE3G3H reconstruction is highlighted by three distinct peripheral stalk densities that are stabilized by a CH subunit peripheral stalk base. Furthermore, these results provide evidence for the possible involvement of subunits C and H in the formation of a novel sub-complex that can assemble as part of the free V1-ATPase.
Purification of Yeast V1-ATPase
Efficient isolation of the highly purified yeast V1-ATPase resulted from the attachment of a FLAG epitope to the carboxy-terminus of the A subunits. Subsequent purification using a FLAG antibody conjugated to an agarose resin and size exclusion chromatography resulted in a highly purified yeast V1-ATPase domain (Figure 1A). Detergent was not used in the purification protocol in order to avoid co-purification of the Vo-domain with the desired V1 component. The fully purified V1-ATPase was found in a series of sub-complexes, giving rise to the discovery of the CE3G3H sub-assembly. Mechanical dissociation of the individual sub-complexes from the complete V1-domain may have occurred during sample purification through the size-exclusion column or may have resulted from the freeze/thaw cycles during storage of the sample prior to data collection. The identity and the molecular mass of each of the subunits A, B, C, D, E, F, G and H were experimentally determined to be 67.7, 57.6, 44.2, 29.2, 26.5, 13.4, 12.7 and 54.4 kDa, respectively using MALDI-TOF mass spectrometry.
Figure 1. V1-ATPase sample homogeneity and sub-complex formation.
(A) The purified yeast V1-ATPase as analyzed by 10% SDS-PAGE. The sample was run in three separate wells to further validate of its homogeneity. (B) The reference-free class averages of the V1-ATPase sub-complexes of raw particles from the cryo-EM data set. The A3B3DF complex (top row) is highlighted by a noticeable protrusion corresponding to the DF central stalk. The DF complex (middle row) assumes a boot-like overall shape and is surrounded by additional peripheral densities. The saddle-shaped CE3G3H sub-assembly (bottom row) contains strong density at the three vertices where the three peripheral stalks are bound to the C and H subunits.doi:10.1371/journal.pone.0012588.g001
Three-Dimensional Reconstructions of the Yeast V1-ATPase
In examining the cryo-EM micrographs and the resulting class averages, it was determined that the particles existed in a number of different shapes that were inconsistent with one another. Visual identification and separation of the different particles was too difficult to accomplish manually due to the poor contrast of the cryo-EM micrographs. However, the MULTIREFINE command within EMAN  was able to split the data set into separate subdirectories according to particle shape (Figure 1B) (Figure S1). This separation resulted in three independent reconstructions of the A3B3DF, DF and CE3G3H sub-complexes refined to 14, 18 and 16 Å resolution respectively (Figure S2). Interestingly, the DF central stalk was captured in two separate reconstructions and in two different conformations. Collectively the three reconstructions presented here are in agreement with the most current stoichiometry of the V1-ATPase  and constitute the entire V1-domain.
The A3B3DF reconstruction was refined to 14 Å resolution and reveals a unique central stalk interaction that has previously only been seen in prokaryotic models (Figure 2A). At the current resolution, the six individual subunits can be discerned each having an approximate width of 35 Å. The identity of the A and B subunit locations was revealed by an automated rigid body fitting of available X-ray coordinates for the A3B3DF sub-assembly (PDB 3A5D) (Figure 2B). The three A subunits appear to have regions of their density protruding away from the center of the A3B3 complex forming knob-like densities that are thought to be representative of an amino acid insertion near the amino-termini . Additionally, the three B subunits appear consistent in their shape and relative size, collectively forming a triangular cap at the point furthest away from the membrane.
Figure 2. The V1-ATPase A3B3DF and DF sub-complexes.
(A) The 14 Å resolution cryo-EM reconstruction of the catalytic A3B3DF complex. (B) X-ray coordinates for the T. thermophilus A3B3DF sub-assembly (PDB 3A5D) were fit into the EM density to characterize the A (orange) and B (yellow) trimers as well as the central stalk (subunit D-cyan). (C) A close up view of the central stalk interactions in which subunit F (magenta) is in the retracted conformation (PDB 3A5D). (D) The extended conformation of subunit F (magenta) from T. thermophilus (PDB 2D00) was fit into the central stalk density to occupy the narrow bridging interaction that tethers the central stalk to a contralateral A subunit. (E) The DF reconstruction highlighted by a boot-like structure with additional peripheral densities. (F) Subunits D and F fit into the DF reconstruction to characterize the respective subunit domains. The retracted conformation of F was fit to compliment the boundaries of the EM density.doi:10.1371/journal.pone.0012588.g002
The central stalk density has an approximate width of 30 Å and projects roughly 70 Å from the base of the A3B3 catalytic complex. At its insertion point into the A3B3 complex, the central stalk interacts with a single catalytic A subunit, consistent with the well-established mechanism that describes the coupling of proton-translocation and central stalk rotation to ATP synthesis in the F-ATP synthase . The spatial occupancy of this density was validated with the X-ray coordinates for subunit D (PDB 3A5D) in which the long slender α-helical domain of subunit D was fit asymmetrically nearest one of the catalytic AB interfaces (Figure 2C). The central stalk also contains an additional density at its distal end corresponding to an extended conformation of subunit F. When fit with available X-ray coordinates (PDB 2D00) it was confirmed that subunit F extends contralaterally to interact with a single A subunit thus bridging the distal end of the central stalk to the base of the A3B3 complex (Figure 2D). This DFA rotor-stator interaction is also the likely cause of the central stalk bending to a 45°angle.
An 18 Å reconstruction of the isolated DF rotary subunits resulted from a particle alignment centered on the central stalk and not the catalytic subunits as seen in the A3B3DF reconstruction. As a result, most of the A and B trimer densities were averaged away due to their misalignment in relation to the now anchored central stalk. Four globular densities are seen above noise level surrounding the central stalk nearest its likely insertion point into the A3B3 complex (Figure 2E). The centers of three of these satellite densities are spaced roughly 70 Å apart, corresponding to the relative distance between the centers of the A or B subunits in the A3B3DF reconstruction. These densities are approximately 25 Å wide along the short axis of the V1-ATPase and are representative of the A or B subunits that were mostly averaged away.
The DF reconstruction features a strong tubular-shaped density that spans approximately 80 Å about the long axis of the V1-ATPase and is representative of subunit D as indicated by the fitting of the T. thermophilus coordinates (PDB 3A5D) (Figure 2F). Near its projected insertion point into the A3B3 complex this density has an approximate width of 30 Å, corresponding to the girth of the central stalk in the A3B3DF reconstruction. At the distal end, the central stalk contains a protuberance roughly 25 Å long and perpendicular to the orientation of subunit D. This feature adds to the asymmetry of the complex, giving it a “foot-like” appearance that is occupied by of the retracted conformation of subunit F. The extended conformation was unable to fit into the DF reconstruction due to a lack of density available for the carboxy-terminus to extend from the amino-terminus. These results further indicate that subunit F is in the retracted conformation in the isolated DF reconstruction.
The 16 Å reconstruction of the CE3G3H sub-complex contains several unique structural features that support its function and location in the intact V-ATPase (Figure 3A). The X-ray coordinates of the yeast V-ATPase subunits C (PDB 1U7L) and H (PDB 1H08) were fit into the density map to outline the subunit boundaries within the reconstruction (Figure 3B). The EMFIT  and COLORES ,  programs were used to fit the X-ray coordinates of subunit C into the CE3G3H density based on model correlation. The ability of subunit C to bind with two peripheral stalks was also used as a determining factor in accurately docking the respective X-ray coordinates . Alternative computational and manual fittings of subunit C resulted in a lack of reasonable density to accommodate the docking of subunit H. The X-ray structure of subunit H was fit in the remaining density based on recent biochemical findings in Neurospora crassa indicating that the amino-terminus of subunit H accommodates the binding of one of the three peripheral stalks . EMFIT was used to assign quantitative values to the relative accuracy of these X-ray coordinate fitting, yielding sumf values of 52 and 60 respectively . These values correspond to a high average value of density at all of the atomic positions (sumf) as a result of a well placed fit. Additionally, the percentage of atoms in negative density was 0.05 and 0.03 respectively.
Figure 3. The yeast V1-ATPase CE3G3H Reconstruction.
(A) Top and side views of the CE3G3H peripheral stalk complex characterized by the three elongated peripheral stalks. From the top of the complex viewing in the direction of the membrane, the heterodimeric peripheral stalk densities (PS) are outlined in green and lime green to highlight the likely subunit boundaries of subunits E and G. The density was colored on the basis of X-ray fitting results of the E/G complex from T. thermophilus (PDB 3K5B) with a color probing radius of 7 Å. (B) Top and side views of the subunit C (blue) and H (red) interaction highlighted by a precise inter-subunit overlap. Viewing in the direction of the membrane, the carboxy-terminus (CT) of subunit H (PDB 1H08) fits over the neck domain of subunit C (PDB 1U7L) characterizing a contact interface area of approximately 4500 Å2. (C) Top and side views of the CE3G3H sub-assembly with 50% transparent EG heterodimer densities (PDB 3K5B green and lime green) incorporated into the density map to further outline the orientation of the three peripheral stalks relative to subunits C and H.doi:10.1371/journal.pone.0012588.g003
The architecture of the reconstruction can be described as “saddle-shaped”, with a flat central portion and a pronounced ridge. This saddle-like ridge feature contributes to the asymmetry of the model and is likely occupied by the amino terminus of subunit H (Figure 3B). Additionally, the carboxy-terminus (residues 371–421) of subunit H was fit near residues 146–161 and 272–287 of the α-helical “neck” domain in subunit C. This CH interface has a relative contact area of approximately 4,500 Å2, as determined and confirmed by the CCP4 programs AREAIMOL and SURFACE  and the INTERSURF command within the Chimera software suite . Additionally, the CE3G3H complex also contains three distinct vertices, with bulging densities below the equator of the complex protruding some 15 Å in the direction of the membrane. Two of these formations are occupied by the “head” (residues 166–263) and a “foot” (residues 1–48 and 324–373)  domains of subunit C, while the third is populated by the amino-termini of subunit H which also serves as the attachment point for one of the peripheral stalks.
Located in the flat central portion of the reconstruction is a shallow cavity that indents approximately 10 Å from the outer border of the complex and is roughly 20 Å wide. Surrounding this cavity are three strong slender elongated densities seen protruding in the direction of the catalytic complex that clearly represent the peripheral stalks (Figure 3A-right). These extensions are approximately 40 Å long but are likely much longer. However due to their flexibility and subsequent disorder, portions near their distal ends were averaged away. Despite the lack of rigidity, the remainder of these elongated densities could be interpreted by the fitting of the X-ray coordinates of the EG heterodimer (PDB 3K5B) (Figure 3C) . It is worth noting that the presence of these three densities is not the result of particle misalignment due to the pronounced asymmetries within the reconstruction such as the large saddle-like ridge and the central cavity. Misalignment of particles would not result in such strong asymmetric features.
The V-ATPase is a dynamic rotary enzyme that hydrolyzes ATP through a series of differing conformational states, making it difficult to refine a three-dimensional reconstruction of the enzyme to a reasonable resolution. Additionally the fragility of the intact V-ATPase and the difficulties associated with capturing complete V-ATPase particles in a micrograph setting, contribute to the problem of acquiring a high resolution reconstruction. However, in this study the yeast V1-ATPase was visualized to 14 Å resolution, highlighting a novel method for the regulation of catalysis upon detachment from the membrane.
In all V-ATPases the catalytic activity arises from conformational changes resulting from ATP-binding and hydrolysis on the A subunits near the AB interface , , .These changes drive the rotation of the heterodimeric DF central stalk which ultimately results in the translocation of protons across the membrane through the a(cc′)4-5c″d proteolipid ring , , . The dynamic nature of these subunits allows them to assume random orientations, resulting in their density likely being averaged away when computationally analyzed. The only situation in which the DF central stalk and the A3B3 catalytic complex could be captured in a single predominant orientation is when the two entities are held motionless by some coherent interaction as seen in our A3B3DF reconstruction. The importance of such an interaction lies in the maintenance of cell viability. During brief periods of glucose deprivation, the V-ATPase is regulated by the V1-domain disassembly from the membrane-bound VO-domain . However without some form of regulation, the released V1-ATPase can potentially hydrolyze ATP uncontrollably. Kane and Smardon (2003) postulate that potential hydrolysis of ATP by the free V1-ATPase is terminated by subunit H bridging the rotor and stator stalks together . A similar situation has also been explored with the F1-ATPase and an additional portion of the Fob subunit . However in the A3B3DF reconstruction presented here, the abnormal tilting of the central rotor stalk to a 45°angle highlights the extended conformation of subunit F which bridges the rotor and stator entities together. Additionally, subunit F is also seen in its retracted conformation, further supporting the notion that subunit F can adopt two variable conformations depending on ATP availability . The involvement of subunit F in the regulation of the free V1-ATPase was first proposed by Makyio et al, 2005 and later supported by crystallographic data of the A3B3DF sub-assembly from T. thermophilus . This interaction has not been documented in a eukaryotic V-ATPase until now. By obstructing the rotation of the central stalk, the V1-ATPase A3B3 complex can stop cycling between the three nucleotide-binding states thus preventing the unwanted hydrolysis of ATP. A similar event has also been demonstrated in the F-ATP synthase in which the extended conformation of the epsilon subunit restricts the rotational kinetics of the gamma subunit, resulting in the inhibition of ATP hydrolysis .
Additionally, we present the first reconstruction of the complete peripheral stalk architecture of the yeast V-ATPase (subunits CE3G3H). In terms of subunit arrangement at the V1VO-interface, recent EM reconstructions of the complete yeast V-ATPase have proposed that subunit H is in close proximity to subunit C, however the two entities do not actually contact each other , . On the contrary, it is now clear in the free V1-ATPase that the carboxy-terminus of subunit H interacts with the narrow neck domain of subunit C. This arrangement of subunits C and H appears to be extremely stable in which the interface between the two is approximately 4500 Å2. Collectively, the aforementioned variances observed in the subunit orientations at the V1VO-interface are supported by mutagenesis studies which suggest that the carboxy-terminus of subunit H is able to assume varying conformations depending on its involvement in either the free V1- or the complete V-ATPase , .
The three peripheral stalks seen here are much like those considered in the V-ATPase reconstructions from the plant Kalanchoe daigremontiana , bovine , yeast , ,  and the insect Manduca sexta , however in our CE3G3H reconstruction these densities are more clearly defined. Two of the peripheral stalks protrude from subunit C, one from the “head” (residues 166–263) and “foot” domains (residues 1–48 and 324–373), while the third is seen projecting from the amino-terminus of subunit H. This architecture corroborates published findings , , , . Structurally these elongated peripheral densities extend away from the membrane and likely interact with the non-catalytic A/B interfaces , ,  to prevent V1 rotation during catalysis (Figure 4). Further evidence of their stator function lies in the presence of large bulges protruding from the CH base in the direction of the membrane. The arrangement of these unique densities is such that they are likely involved in binding with the membrane-bound a subunit at the V1VO-interface , . As a result, the EG stalks are indirectly attached to the membrane-bound stationary subunit a through their interactions with the CH base.
Figure 4. Stabilization of the catalytic interfaces.
(A) A top view of the CE3G3H complex fit with a 50% transparent representation of the A3B3DF sub-assembly (PDB 3A5D). X-ray coordinates of the EG heterodimer from T. thermophilus (PDB 3K5B) were fit into the density map to discern the extent of the three peripheral stalk boundaries. Based on their orientation, the peripheral stalks (green and lime green) are seen interacting with the non-catalytic interfaces between the A (orange) and B (yellow) subunits , , . This arrangement allows for the nucleotide-binding interfaces (NBI) to be openly accessible for binding to ATP and ADP while also facilitating enough space for rotation of the central stalk (subunit D, cyan).doi:10.1371/journal.pone.0012588.g004
The physiological reasoning for the V-ATPase requiring multiple peripheral stalks lies in the arrangement of the various stator and rotor components. Based on recent X-ray  data, the A3B3DF complex spans an approximate distance of 170 Å down the long axis of the V1-ATPase. This corresponds to the distance from the top of the A3B3 catalytic headpiece to the bottom of the CH base. By comparison, the F-ATP synthase α3β3γ sub-assembly spans an approximate distance of 130 Å along the equivalent components . As a result of the increased distance between the A3B3 complex and the CH peripheral stalk base, the peripheral stalks in the V-ATPase must span a longer distance compared to the F-ATP synthase therefore reducing their stability . By utilizing three peripheral stalks, as opposed to one like in the mitochondrial F-ATP synthase , the V-ATPase is able to accommodate the larger distance and subsequently stabilize the A3B3 complex against the forces induced by the rotor.
Interestingly, the formation of the separate and distinct A3B3DF and CE3G3H sub-assemblies presented here sheds light on a potential assembly mechanism for the complete cytoplasmic domain. Based on the relative arrangement of the V1 components, it is likely that the catalytic complex and central stalk collectively dissociate from the CH peripheral stalk base containing the three peripheral stalks (Figure 5). This nascent schematic is further supported by recent high-resolution structural data revealing an A3B3DF complex free of subunits C, H, E and G . While the exact mechanism for this is unclear, subunit C may play the key role as it is the only subunit that does not co-purify with either the V1 or VO domain after complex disassembly . Additionally, small angle X-ray scattering (SAXS) has revealed that subunit C can adopt two very dynamic conformations depending on its involvement in the holoenzyme . Such a conformational change may be stimulated by the phosphorylation of subunit C ,  which is believed to weaken the surface interactions between an EG-C complex formation . However, the dissociation of subunit C from the EG stator does not appear to be the method by which the V1-ATPase regulates its assembly as three copies of the EG complex remain bound with subunits C and H when the CE3G3H complex is dissociated from the remaining V1- components.
Figure 5. Assembly/Disassembly of the free V1-ATPase.
(Left) Side view of the CE3G3H reconstruction fit with the subunits C (PDB 1U7L), H (PDB 1H08) and three copies of the EG heterodimer from T. thermophilus (PDB 3K5B green and lime green). (Right) The rigid body fit of the A3B3DF complex from T. thermophilus (PDB 3A5D-50% transparency), highlighting the precision by which the A3B3DF and CE3G3H sub-complexes fit together. In this arrangement, the A (orange) and B (yellow) trimers are cradled by the three peripheral stalks while the DF central stalk (cyan and magenta) is in line with the shallow cavity that surrounds the C-H interface.doi:10.1371/journal.pone.0012588.g005
It is clear that the CH peripheral stalk base is unique to the dissociated V1-ATPase and represents a dynamic sub-assembly that may be a primary constituent in the formation of the complete cytoplasmic domain. It is tempting to speculate over the mechanism by which the V1-ATPase is assembled, however further analysis is required to identify the physiological stimuli for such an event.
Materials and Methods
Subunit FLAG tagging
Triple-FLAG epitope tags were inserted at the carboxy-terminus of V-ATPase subunits by PCR based homologous recombination in the protease deficient yeast strain c13-ABYS86  using Geneticin resistance as a selectable marker. Colonies were selected on Geneticin containing YPD agar plates. Single colonies were transferred into liquid YPD medium and subjected to western blot analysis using anti-FLAG antibody (SIGMA). Accessibility of the FLAG tags was assessed by pull down assays using anti-FLAG antibody coupled agarose beads.
Saccharomyces cerevisiae cells containing a carboxy-terminal 3xFLAG insert after the sequence for subunit A were cultured on YPD agar plates containing 20 mg/ml Geneticin. YEP media containing 2% glucose was inoculated with single colonies from the culture plates and incubated at 30°C. The cells were allowed to grow until the cells reached mid-log phase growth corresponding to an OD600 between 1 and 5. The cells were pelleted by centrifugation at 5,018×g then resuspended in Zymolyase buffer containing 50 mM Tris pH 8.0, 10 mM MgCl2, 1 M Sorbital and 30 mM DTT. After a second centrifugation step of 5 minutes at 1,500×g, the cells were resuspended in 3 volumes of Zymolyase buffer. To the suspension, Zymolyase 20T was added and the sample was shaken at 50 rpm at 30°C for 40 minutes until the cells were converted to spheroplasts. The spheroplasts were centrifuged at 1,500×g for 5 minutes at 4°C and the pellet was resuspended in ice-cold Zymolyase buffer. The spheroplasts were washed two more times and then lysed by osmotic shock in lysis buffer containing 50 mM Tris pH 8.0, 10 mM MgSO4, 1 mM EDTA, 10 mM potassium acetate, and 1 mM DTT with a cocktail of protease inhibitors. After a number of freeze/thaw cycles, 5 M NaCl was added to a final concentration of 100 mM. Anti-FLAG agarose slurry was added to the supernatant and placed in a disposable BioRad column. After thoroughly washing to remove unbound protein, the V1 was eluted with 500 µl elution buffer consisting of 10 mM Tris pH 8.0, 2% glucose, 3xFLAG peptide 5 mM ATP and 5 mM EDTA for a total of 4 elutions. The sample was then concentrated using a 100k cutoff concentrator unit and applied onto a Superose 6 size-exclusion column equilibrated with a buffer containing 10 mM Tris pH 8.0, 5 mM EDTA, 0.1% glucose, and 5 mM ATP. Sample purity was confirmed by SDS PAGE.
The initial sample concentration was diluted from 12.2 mg/ml to 0.75 mg/ml and blotted onto holey carbon grids before cryogenic plunge freezing. The images were collected on a F20 transmission electron microscope operating at a voltage of 200,000. Data was collected on film at 50,000× magnification and under low dose data collection conditions.
Image Processing and Analysis
Electron micrographs were scanned and digitized on a Nikon Super CoolScan 9000 ED scanner and binned to an effective pixel size of 2.4 Å. Particles were boxed using the automated algorithm in the program SIGNATURE . Determination of defocus was accomplished with the program CTFFIND and Contrast Transform Function (CTF) correction was performed using CTFIT . An Initial model of the A3B3DF reconstruction was created using the STARTCSYM function in the EMAN software suite assuming 3-fold symmetry (C3) to account for the pseudo-3-fold symmetry of the A3B3 complex . Initial models of the DF and CE3G3H sub-complexes were derived from early MULTIREFINE experiments in which the particles were sorted into distinct subdirectories using multivariate statistical analysis (MSA). This was done assuming no symmetry (C1). Iterative refinement of the final three reconstructions was performed in subsequent MULTIREFINE experiments assuming C1 symmetry for each. The final A3B3DF, DF and CE3G3H reconstructions used 21,682, 14,873 and 20,128 particles respectively. The resolution of the final reconstructions was estimated based on a Fourier shell correlation (FSC) criterion of 0.5 using the EOTEST command within EMAN, which measured the degree of correlation when the data was split in half.
X-ray coordinates for the T. thermophilus A3B3DF sub-assembly (PDB 3A5D), subunit F (PDB 2D00), and yeast subunits C (PDB 1U7L) and H (PDB 1HO8) were fit into the EM density maps using the programs COOT , CHIMERA , EMFIT  and COLORES , . X-ray coordinates of the peripheral stalks from T. thermophilus (PDB 3K5B) were placed into the location they likely occupy in the V1 ATPase to put the reconstruction into context. The program EMFIT  was utilized to assign quantitative values proportional to the relative precision of the X-ray coordinate fittings. Outputs included an average value of density at all atomic positions between -100 and 100 (sumf) and a percentage of atoms in negative density (outside of density). All visualization was done with the programs VMD  and Chimera .
Raw Particle Images of the A3B3DF, DF, and CE3G3H Reconstructions.
(5.05 MB TIF)
Fourier Shell Correlations of the A3B3DF, DF, and CE3G3H Reconstructions. The final resolution values for the A3B3DF, DF, and CE3G3H reconstructions were determined to be 14, 18, and 16 Å respectively.
(1.56 MB TIF)
We would like to thank James Whyte and Sean Munro from the Medical Research Council Laboratory of Molecular Biology, Cambridge, UK who gave us the vector for PCR based homologous recombination in yeast and also Seema Khan for assistance with FLAG tagging of the yeast subunits.
Conceived and designed the experiments: RAB. Performed the experiments: ZLH. Analyzed the data: SM. Contributed reagents/materials/analysis tools: DS. Wrote the paper: ZLH.
- 1. Forgac M (2007) Vacuolar ATPases: rotary proton pumps in physiology and pathophysiology. Nature Reviews Molecular Cell Biology 8: 917–929.
- 2. Crider BP, Xie XS (2003) Characterization of the functional coupling of bovine brain vacuolar-type H(+)-translocating ATPase. Effect of divalent cations, phospholipids, and subunit H (SFD). Journal of Biological Chemistry 278: 44281–44288.
- 3. Gregorini M, Wang J, Xie XS, Milligan RA, Engel A (2007) Three-dimensional reconstruction of bovine brain V-ATPase by cryo-electron microscopy and single particle analysis. J Struct Biol 158: 445–454.
- 4. Inoue T, Wilkens S, Forgac M (2003) Subunit structure, function, and arrangement in the yeast and coated vesicle V-ATPases. J Bioenerg Biomembr 35: 291–299.
- 5. Jefferies KC, Cipriano DJ, Forgac M (2008) Function, structure and regulation of the vacuolar (H+)-ATPases. Arch Biochem Biophys 476: 33–42.
- 6. Gruenberg J, van der Goot FG (2006) Mechanisms of pathogen entry through the endosomal compartments. Nat Rev Mol Cell Biol 7: 495–504.
- 7. Kornak U, Schulz A, Friedrich W, Uhlhaas S, Kremens B, et al. (2000) Mutations in the a3 subunit of the vacuolar H(+)-ATPase cause infantile malignant osteopetrosis. Hum Mol Genet 9: 2059–2063.
- 8. Visentin L, Dodds RA, Valente M, Misiano P, Bradbeer JN, et al. (2000) A selective inhibitor of the osteoclastic V-H(+)-ATPase prevents bone loss in both thyroparathyroidectomized and ovariectomized rats. J Clin Invest 106: 309–318.
- 9. Sun-Wada GH, Toyomura T, Murata Y, Yamamoto A, Futai M, et al. (2006) The a3 isoform of V-ATPase regulates insulin secretion from pancreatic beta-cells. J Cell Sci 119: 4531–4540.
- 10. Sennoune SR, Martinez-Zaguilan R (2007) Plasmalemmal vacuolar H+-ATPases in angiogenesis, diabetes and cancer. J Bioenerg Biomembr 39: 427–433.
- 11. Armbruster A, Svergun DI, Coskun U, Juliano S, Bailer SM, et al. (2004) Structural analysis of the stalk subunit Vma5p of the yeast V-ATPase in solution. FEBS Lett 570: 119–125.
- 12. Kitagawa N, Mazon H, Heck AJ, Wilkens S (2008) Stoichiometry of the peripheral stalk subunits E and G of yeast V1-ATPase determined by mass spectrometry. Journal of Biological Chemistry 283: 3329–3337.
- 13. Zhang Z, Charsky C, Kane PM, Wilkens S (2003) Yeast V1-ATPase: affinity purification and structural features by electron microscopy. Journal of Biological Chemistry 278: 47299–47306.
- 14. Zhang Z, Zheng Y, Mazon H, Milgrom E, Kitagawa N, et al. (2008) Structure of the yeast vacuolar ATPase. Journal of Biological Chemistry 283: 35983–35995.
- 15. Diepholz M, Borsch M, Bottcher B (2008) Structural organization of the V-ATPase and its implications for regulatory assembly and disassembly. Biochem Soc Trans 36: 1027–1031.
- 16. Diepholz M, Venzke D, Prinz S, Batisse C, Florchinger B, et al. (2008) A different conformation for EGC stator subcomplex in solution and in the assembled yeast V-ATPase: possible implications for regulatory disassembly. Structure 16: 1789–1798.
- 17. Wilkens S, Inoue T, Forgac M (2004) Three-dimensional structure of the vacuolar ATPase. Localization of subunit H by difference imaging and chemical cross-linking. Journal of Biological Chemistry 279: 41942–41949.
- 18. Muench SP, Huss M, Song CF, Phillips C, Wieczorek H, et al. (2009) Cryo-electron microscopy of the vacuolar ATPase motor reveals its mechanical and regulatory complexity. J Mol Biol 386: 989–999.
- 19. Liu M, Tarsio M, Charsky CM, Kane PM (2005) Structural and functional separation of the N- and C-terminal domains of the yeast V-ATPase subunit H. Journal of Biological Chemistry 280: 36978–36985.
- 20. Ludtke SJ, Baldwin PR, Chiu W (1999) EMAN: semiautomated software for high-resolution single-particle reconstructions. J Struct Biol 128: 82–97.
- 21. Maegawa Y, Morita H, Iyaguchi D, Yao M, Watanabe N, et al. (2006) Structure of the catalytic nucleotide-binding subunit A of A-type ATP synthase from Pyrococcus horikoshii reveals a novel domain related to the peripheral stalk. Acta Crystallogr D Biol Crystallogr 62: 483–488.
- 22. Boyer PD (1997) The ATP synthase–a splendid molecular machine. Annu Rev Biochem 66: 717–749.
- 23. Rossmann MG, Bernal R, Pletnev SV (2001) Combining electron microscopic with x-ray crystallographic structures. J Struct Biol 136: 190–200.
- 24. Wriggers W (2010) Using Situs for the integration of multi-resolution structures. Biophys Rev 2: 21–27.
- 25. Chacon P, Wriggers W (2002) Multi-resolution contour-based fitting of macromolecular structures. J Mol Biol 317: 375–384.
- 26. Inoue T, Forgac M (2005) Cysteine-mediated cross-linking indicates that subunit C of the V-ATPase is in close proximity to subunits E and G of the V1 domain and subunit a of the V0 domain. Journal of Biological Chemistry 280: 27896–27903.
- 27. Venzke D, Domgall I, Kocher T, Fethiere J, Fischer S, et al. (2005) Elucidation of the stator organization in the V-ATPase of Neurospora crassa. J Mol Biol 349: 659–669.
- 28. Lee B, Richards FM (1971) The interpretation of protein structures: estimation of static accessibility. J Mol Biol 55: 379–400.
- 29. Pettersen EF, Goddard TD, Huang CC, Couch GS, Greenblatt DM, et al. (2004) UCSF Chimera–a visualization system for exploratory research and analysis. J Comput Chem 25: 1605–1612.
- 30. Drory O, Nelson N (2006) Structural and functional features of yeast V-ATPase subunit C. Biochim Biophys Acta 1757: 297–303.
- 31. Lee LK, Stewart AG, Donohoe M, Bernal RA, Stock D (2010) The structure of the peripheral stalk of Thermus thermophilus H+-ATPase/synthase. Nat Struct Mol Biol 17: 373–378.
- 32. Liu Q, Kane PM, Newman PR, Forgac M (1996) Site-directed mutagenesis of the yeast V-ATPase B subunit (Vma2p). Journal of Biological Chemistry 271: 2018–2022.
- 33. Liu Q, Leng XH, Newman PR, Vasilyeva E, Kane PM, et al. (1997) Site-directed mutagenesis of the yeast V-ATPase A subunit. Journal of Biological Chemistry 272: 11750–11756.
- 34. Vasilyeva E, Liu Q, MacLeod KJ, Baleja JD, Forgac M (2000) Cysteine scanning mutagenesis of the noncatalytic nucleotide binding site of the yeast V-ATPase. Journal of Biological Chemistry 275: 255–260.
- 35. Tomashek JJ, Garrison BS, Klionsky DJ (1997) Reconstitution in vitro of the V1 complex from the yeast vacuolar proton-translocating ATPase. Assembly recapitulates mechanism. Journal of Biological Chemistry 272: 16618–16623.
- 36. Tomashek JJ, Graham LA, Hutchins MU, Stevens TH, Klionsky DJ (1997) V1-situated stalk subunits of the yeast vacuolar proton-translocating ATPase. Journal of Biological Chemistry 272: 26787–26793.
- 37. Wilkens S, Vasilyeva E, Forgac M (1999) Structure of the vacuolar ATPase by electron microscopy. Journal of Biological Chemistry 274: 31804–31810.
- 38. Kane PM (1995) Disassembly and reassembly of the yeast vacuolar H(+)-ATPase in vivo. Journal of Biological Chemistry 270: 17025–17032.
- 39. Kane PM, Smardon AM (2003) Assembly and regulation of the yeast vacuolar H+-ATPase. J Bioenerg Biomembr 35: 313–321.
- 40. Suzuki T, Suzuki J, Mitome N, Ueno H, Yoshida M (2000) Second stalk of ATP synthase. Cross-linking of gamma subunit in F1 to truncated Fob subunit prevents ATP hydrolysis. Journal of Biological Chemistry 275: 37902–37906.
- 41. Makyio H, Iino R, Ikeda C, Imamura H, Tamakoshi M, et al. (2005) Structure of a central stalk subunit F of prokaryotic V-type ATPase/synthase from Thermus thermophilus. EMBO J 24: 3974–3983.
- 42. Numoto N, Hasegawa Y, Takeda K, Miki K (2009) Inter-subunit interaction and quaternary rearrangement defined by the central stalk of prokaryotic V1-ATPase. EMBO Rep 10: 1228–1234.
- 43. Iino R, Hasegawa R, Tabata KV, Noji H (2009) Mechanism of inhibition by C-terminal alpha-helices of the epsilon subunit of Escherichia coli FoF1-ATP synthase. Journal of Biological Chemistry 284: 17457–17464.
- 44. Flannery AR, Stevens TH (2008) Functional characterization of the N-terminal domain of subunit H (Vma13p) of the yeast vacuolar ATPase. Journal of Biological Chemistry 283: 29099–29108.
- 45. Domgall I, Venzke D, Luttge U, Ratajczak R, Bottcher B (2002) Three-dimensional map of a plant V-ATPase based on electron microscopy. Journal of Biological Chemistry 277: 13115–13121.
- 46. Bernal RA, Stock D (2004) Three-dimensional structure of the intact Thermus thermophilus H+-ATPase/synthase by electron microscopy. Structure 12: 1789–1798.
- 47. Gibbons C, Montgomery MG, Leslie AG, Walker JE (2000) The structure of the central stalk in bovine F(1)-ATPase at 2.4 A resolution. Nat Struct Biol 7: 1055–1061.
- 48. Dickson VK, Silvester JA, Fearnley IM, Leslie AG, Walker JE (2006) On the structure of the stator of the mitochondrial ATP synthase. EMBO J 25: 2911–2918.
- 49. Voss M, Vitavska O, Walz B, Wieczorek H, Baumann O (2007) Stimulus-induced phosphorylation of vacuolar H(+)-ATPase by protein kinase A. Journal of Biological Chemistry 282: 33735–33742.
- 50. Hong-Hermesdorf A, Brux A, Gruber A, Gruber G, Schumacher K (2006) A WNK kinase binds and phosphorylates V-ATPase subunit C. FEBS Lett 580: 932–939.
- 51. Heinemeyer W, Kleinschmidt JA, Saidowsky J, Escher C, Wolf DH (1991) Proteinase yscE, the yeast proteasome/multicatalytic-multifunctionalproteinase: mutants unravel its function in stress induced proteolysis and uncover its necessity for cell survival. EMBO J 10: 555–562.
- 52. Chen JZ, Grigorieff N (2007) SIGNATURE: a single-particle selection system for molecular electron microscopy. J Struct Biol 157: 168–173.
- 53. Mindell JA, Grigorieff N (2003) Accurate determination of local defocus and specimen tilt in electron microscopy. J Struct Biol 142: 334–347.
- 54. Emsley P, Cowtan K (2004) Coot: model-building tools for molecular graphics. Acta Crystallogr D Biol Crystallogr 60: 2126–2132.
- 55. Humphrey W, Dalke A, Schulten K (1996) VMD: visual molecular dynamics. J Mol Graph 14: 33–38, 27-38.