The second stalk composed of the b- and delta-subunits connects F0 to F1 via an alpha-subunit in the Escherichia coli ATP synthase

Structure of the vacuolar ATPase by electron microscopy

The structure of the vacuolar ATPase from bovine brain clathrin-coated vesicles has been determined by electron microscopy of negatively stained, detergent-solubilized enzyme molecules. Preparations of both lipid-containing and delipidated enzyme have been analyzed. The complex is organized in two major domains, a V(1) and V(0), with overall dimensions of 28 x 14 x 14 nm. The V(1) is a more or less spherical molecule with a central cavity. The V(0) has the shape of a flattened sphere or doughnut with a radius of about 100 A. The V(1) and V(0) are joined by a 60-A long and 40-A wide central stalk, consisting of several individual protein densities. Two kinds of smaller densities are visible at the top periphery of the V(1), and one of these seems to extend all the way down to the stalk domain in some averages. Images of both the lipid-containing and the delipidated complex show a 30-50-kDa protein density on the lumenal side of the complex, opposite the central stalk, centered in the ring of c subunits. A large trans-membrane mass, probably the C-terminal domain of the 100-kDa subunit a, is seen at the periphery of the c subunit ring in some projections. This large mass has both a lumenal and a cytosolic domain, and it is the cytosolic domain that interacts with the central stalk. Two to three additional protein densities can be seen in the V(1)-V(0) interface, all connected to the central stalk. Overall, the structure of the V-ATPase is similar to the structure of the related F(1)F(0)-ATP synthase, confirming their common origin.

The epsilon subunit of the F(1)F(0) complex of Escherichia coli. cross-linking studies show the same structure in situ as when isolated

Four double mutants in the epsilon subunit were generated, each containing two cysteines, which, based on the NMR structure of this subunit, should form internal disulfide bonds. Two of these were designed to generate interdomain cross-links that lock the C-terminal alpha-helical domain against the beta-sandwich (epsilonM49C/A126C and epsilonF61C/V130C). The second set should give cross-linking between the two C-terminal alpha-helices (epsilonA94C/L128C and epsilonA101C/L121C). All four mutants cross-linked with 90-100% efficiency upon CuCl(2) treatment in isolated Escherichia coli ATP synthase. This shows that the structure obtained for isolated epsilon is essentially the same as in the assembled complex. Functional studies revealed increased ATP hydrolysis after cross-linking between the two domains of the subunit but not after cross-linking between the C-terminal alpha-helices. None of the cross-links had any effect on proton pumping-coupled ATP hydrolysis, on DCCD sensitivity of this activity, or on ATP synthesis rates. Therefore, big conformational changes within epsilon can be ruled out as a part of the enzyme function. Protease digestion studies, however, showed that subtle changes do occur, since the epsilon subunit could be locked in an ADP or 5'-adenylyl-beta,gamma-imidodiphosphate conformation by the cross-linking with resulting differences in cleavage rates.

The dimerization domain of the b subunit of the Escherichia coli F(1)F(0)-ATPase

In this study a series of N- and/or C-terminal truncations of the cytoplasmic domain of the b subunit of the Escherichia coli F(1)F(0) ATP synthase were tested for their ability to form dimers using sedimentation equilibrium ultracentrifugation. The deletion of residues between positions 53 and 122 resulted in a strongly decreased tendency to form dimers, whereas all the polypeptides that included that sequence exhibited high levels of dimer formation. b dimers existed in a reversible monomer-dimer equilibrium and when mixed with other b truncations formed heterodimers efficiently, provided both constructs included the 53-122 sequence. Sedimentation velocity and (15)N NMR relaxation measurements indicated that the dimerization region is highly extended in solution, consistent with an elongated second stalk structure. A cysteine introduced at position 105 was found to readily form intersubunit disulfides, whereas other single cysteines at positions 103-110 failed to form disulfides either with the identical mutant or when mixed with the other 103-110 cysteine mutants. These studies establish that the b subunit dimer depends on interactions that occur between residues in the 53-122 sequence and that the two subunits are oriented in a highly specific manner at the dimer interface.

Substrate- and inhibitor-induced conformational changes in the yeast V-ATPase provide evidence for communication between the catalytic and proton-translocating sectors

The vacuolar-type H(+)-ATPases (V-ATPases) are composed of two distinct sectors, a catalytic complex (V(1)) involved in ATP hydrolysis and a membrane-associated complex (V(0)) mediating proton translocation across a lipid bilayer. To date, little is known about the mechanism by which these two functions are coupled. We sought to examine the impact of nucleotide and cation binding on the structure of the core components of the catalytic complex and to determine whether conformational changes within the catalytic complex impact subunits of the membrane-associated complex. Nucleotide- and cation- induced changes in the catalytic core of the V-ATPase were investigated by monitoring changes in the rate and pattern of tryptic digests. ATP.Mg-induced changes were detected in both the catalytic (Vma1p or 69 kDa) and the regulatory subunits (Vma2p or 60 kDa) of the V(1) sector. ATP alone increased the rate of trypsinization of the regulatory subunit, but did not have any effect on Vma1p. Surprisingly, ATP also had an impact on the 95-kDa subunit, a component of the V(0) sector of the V-ATPase. Although the presence of divalent cations had no impact on the V(1) sector, the rate of trypsinization of the 95-kDa subunit was greatly enhanced. The effect of divalent cations on the structure of the 95-kDa subunit was abrogated when trypsinization was performed in the absence of the catalytic sector. Addition of bafilomycin A(1), a V-ATPase inhibitor that putatively binds to the 95-kDa subunit, increased the rate of trypsinization of the catalytic subunit. These data suggest that structural alterations within the V(1) sector result in alterations within the V(0) sector and vice versa. Clearly, a structural link must exist to couple the two sectors. The 95-kDa subunit is ideally suited to fulfill this role. Hydropathy analysis suggests a bipartite structure, with the NH(2)-terminal portion predicted to lie in an aqueous environment and the C-terminal portion predicted to contain 6 transmembrane segments. Tryptic digests of sealed vacuolar vesicles and immunofluorescence studies revealed that the large hydrophilic NH(2)-terminal domain of the 95-kDa subunit is localized toward the cytosol. This region therefore is ideally positioned to interact with components of the V(1) complex, potentially functioning as the elusive link between the two sectors of the V-ATPase.

Defining the domain of binding of F1 subunit epsilon with the polar loop of F0 subunit c in the Escherichia coli ATP synthase

We have previously shown that the E31C-substituted epsilon subunit of F1 can be cross-linked by disulfide bond formation to the Q42C-substituted c subunit of F0 in the Escherichia coli F1F0-ATP synthase complex (Zhang, Y., and Fillingame, R. H. (1995) J. Biol. Chem. 270, 24609-24614). The interactions of subunits epsilon and c are thought to be central to the coupling of H+ transport through F0 to ATP synthesis in F1. To further define the domains of interaction, we have introduced additional Cys into subunit epsilon and subunit c and tested for cross-link formation following sulfhydryl oxidation. The results show that Cys, in a continuous stretch of residues 26-33 in subunit epsilon, can be cross-linked to Cys at positions 40, 42, and 44 in the polar loop region of subunit c. The results are interpreted, and the subunit interaction is modeled using the NMR and x-ray diffraction structures of the monomeric subunits together with information on the packing arrangement of subunit c in a ring of 12 subunits. In the model, residues 26-33 form a turn of antiparallel beta-sheet which packs between the polar loop regions of adjacent subunit c at the cytoplasmic surface of the c12 oligomer.

Structure/function of the beta-barrel domain of F1-ATPase in the yeast Saccharomyces cerevisiae

The first 90 amino acids of the alpha- and beta-subunits of mitochondrial F1-ATPase are folded into beta-barrel domains and were postulated to be important for stabilizing the enzyme (Abrahams, J. P., Leslie, A. G., Lutter, R., and Walker, J. E. (1994) Nature 370, 621-628). The role of the domains was studied by making chimeric enzymes, replacing the domains from the yeast Saccharomyces cerevisiae enzyme with the corresponding domains from the enzyme of the thermophilic bacterium Bacillus PS3. The enzymes containing the chimeric alpha-, beta-, or alpha- and beta-subunits were not functional. However, gain-of-function mutations were obtained from the strain containing the enzyme with the chimeric PS3/yeast beta-subunit. The gain-of-function mutations were all in codons encoding the beta-barrel domain of the beta-subunit, and the residues appear to map out a region of subunit-subunit interactions. Gain-of-function mutations were also obtained that provided functional expression of the chimeric PS3/yeast alpha- and beta-subunits together. Biochemical analysis of this active chimeric enzyme indicated that it was not significantly more thermostable or labile than the wild type. The results of this study indicate that the beta-barrel domains form critical contacts (distinct from those between the alpha- and beta-subunits) that are important for the assembly of the ATP synthase.

Structure of the membrane domain of subunit b of the Escherichia coli F0F1 ATP synthase

The structure of the N-terminal transmembrane domain (residues 1-34) of subunit b of the Escherichia coli F0F1-ATP synthase has been solved by two-dimensional 1H NMR in a membrane mimetic solvent mixture of chloroform/methanol/H2O (4:4:1). Residues 4-22 form an alpha-helix, which is likely to span the hydrophobic domain of the lipid bilayer to anchor the largely hydrophilic subunit b in the membrane. The helical structure is interrupted by a rigid bend in the region of residues 23-26 with alpha-helical structure resuming at Pro-27 at an angle offset by 20 degrees from the transmembrane helix. In native subunit b, the hinge region and C-terminal alpha-helical segment would connect the transmembrane helix to the cytoplasmic domain. The transmembrane domains of the two subunit b in F0 were shown to be close to each other by cross-linking experiments in which single Cys were substituted for residues 2-21 of the native subunit and b-b dimer formation tested after oxidation with Cu(II)(phenanthroline)2. Cys residues that formed disulfide cross-links were found with a periodicity indicative of one face of an alpha-helix, over the span of residues 2-18, where Cys at positions 2, 6, and 10 formed dimers in highest yield. A model for the dimer is presented based upon the NMR structure and distance constraints from the cross-linking data. The transmembrane alpha-helices are positioned at a 23 degrees angle to each other with the side chains of Thr-6, Gln-10, Phe-14, and Phe-17 at the interface between subunits. The change in direction of helical packing at the hinge region may be important in the functional interaction of the cytoplasmic domains.

Single copies of subunits d, oligomycin-sensitivity conferring protein, and b are present in the Saccharomyces cerevisiae mitochondrial ATP synthase

In the mitochondrial ATP synthase (mtATPase) of the yeast Saccharomyces cerevisiae, the stoichiometry of subunits d, oligomycin-sensitivity conferring protein (OSCP), and b is poorly defined. We have investigated the stoichiometry of these subunits by the application of hexahistidine affinity purification technology. We have previously demonstrated that intact mtATPase complexes incorporating a Hex6-tagged subunit can be isolated via Ni2+-nitrilotriacetic acid affinity chromatography (Bateson, M., Devenish, R. J., Nagley, P., and Prescott, M. (1996) Anal. Biochem. 238, 14-18). Strains were constructed in which Hex6-tagged versions of subunits d, OSCP, and b were coexpressed with the corresponding wild-type subunit. This coexpression resulted in a mixed population of mtATPase complexes containing untagged wild-type and Hex6-tagged subunits. The stoichiometry of each subunit was then assessed by determining whether or not the untagged wild-type subunit could be recovered from Ni2+-nitrilotriacetic acid purifications as an integral component of those complexes absorbed by virtue of the Hex6-tagged subunit. As only the Hex6-tagged subunit was recovered from such purifications, we demonstrate that the stoichiometry of subunits d, OSCP, and b in yeast is 1 in each case.