Characterization of the mitochondrial ATP synthase from yeast Saccharomyces cerevisae

The mitochondrial ATP synthase from yeast S. cerevisiae has been genetically modified, purified in a functional form, and characterized with regard to lipid requirement, compatibility with a variety of detergents, and the steric limit with rotation of the central stalk has been assessed. The ATP synthase has been modified on the N-terminus of the β-subunit to include a His(6) tag for Ni-chelate affinity purification. The enzyme is purified by a two-step procedure from submitochondrial particles and the resulting enzyme demonstrates lipid dependent oligomycin sensitive ATPase activity of 50 units/mg. The yeast ATP synthase shows a strong lipid selectivity, with cardiolipin (CL) being the most effective activating lipid and there are 30 moles CL bound per mole enzyme at saturation. Green Fluorescent Protein (GFP) has also been fused to the C-terminus of the ε-subunit to create a steric block for rotation of the central stalk. The ε-GFP fusion peptide is imported into the mitochondrion, assembled with the ATP synthase, and inhibits ATP synthetic and hydrolytic activity of the enzyme. F(1)F(o) ATP synthase with ε-GFP was purified to homogeneity and serves as an excellent enzyme for two- and three-dimensional crystallization studies.     

Structure and subunit arrangement of the A-type ATP synthase complex from the archaeon Methanococcus jannaschii visualized by electron microscopy

In Archaea, bacteria, and eukarya, ATP provides metabolic energy for energy-dependent processes. It is synthesized by enzymes known as A-type or F-type ATP synthase, which are the smallest rotatory engines in nature (Yoshida, M., Muneyuki, E., and Hisabori, T. (2001) Nat. Rev. Mol. Cell. Biol. 2, 669-677; Imamura, H., Nakano, M., Noji, H., Muneyuki, E., Ohkuma, S., Yoshida, M., and Yokoyama, K. (2003) Proc. Natl. Acad. Sci. U. S. A. 100, 2312-2315). Here, we report the first projected structure of an intact A(1)A(0) ATP synthase from Methanococcus jannaschii as determined by electron microscopy and single particle analysis at a resolution of 1.8 nm. The enzyme with an overall length of 25.9 nm is organized in an A(1) headpiece (9.4 x 11.5 nm) and a membrane domain, A(0) (6.4 x 10.6 nm), which are linked by a central stalk with a length of approximately 8 nm. A part of the central stalk is surrounded by a horizontal-situated rodlike structure ("collar"), which interacts with a peripheral stalk extending from the A(0) domain up to the top of the A(1) portion, and a second structure connecting the collar structure with A(1). Superposition of the three-dimensional reconstruction and the solution structure of the A(1) complex from Methanosarcina mazei G?1 have allowed the projections to be interpreted as the A(1) headpiece, a central and the peripheral stalk, and the integral A(0) domain. Finally, the structural organization of the A(1)A(0) complex is discussed in terms of the structural relationship to the related motors, F(1)F(0) ATP synthase and V(1)V(0) ATPases.     

Genetic complementation between mutant b subunits in F1F0 ATP synthase

In Escherichia coli, a parallel homodimer of identical b subunits constitutes the peripheral stalk of F(1)F(0) ATP synthase. Although the two b subunits have long been viewed as a single functional unit, the asymmetric nature of the enzyme complex suggested that the functional roles of each b subunit should not necessarily be considered equivalent. Previous mutagenesis studies of the peripheral stalk suffered from the fact that mutations in the uncF(b) gene affected both of the b subunits. We developed a system to express and study F(1)F(0) ATP synthase complexes containing two different b subunits. Two mutations already known to inactivate the F(1)F(0) ATP synthase complex have been studied using this experimental system. An evolutionarily conserved arginine, b(Arg-36), was known to be crucial for F(1)F(0) ATP synthase function, and the last four C-terminal amino acids had been shown to be important for enzyme assembly. Experiments expressing one of the mutants with a wild type b subunit demonstrated the presence of heterodimers in F(1)F(0) ATP synthase complexes. Activity assays suggested that the heterodimeric F(1)F(0) complexes were functional. When the two defective b subunits were expressed together and in the absence of any wild type b subunit, an active F(1)F(0) ATP synthase complex was assembled. This mutual complementation between fully defective b subunits indicated that each of the two b subunits makes a unique contribution to the functions of the peripheral stalk, such that one mutant b subunit is making up for what the other is lacking.     

Rotor/Stator interactions of the epsilon subunit in Escherichia coli ATP synthase and implications for enzyme regulation

The H(+)-translocating F(0)F(1)-ATP synthase of Escherichia coli functions as a rotary motor, coupling the transmembrane movement of protons through F(0) to the synthesis of ATP by F(1). Although the epsilon subunit appears to be tightly associated with the gamma subunit in the central stalk region of the rotor assembly, several studies suggest that the C-terminal domain of epsilon can undergo significant conformational change as part of a regulatory process. Here we use disulfide cross-linking of substituted cysteines on functionally coupled ATP synthase to characterize interactions of epsilon with an F(0) component of the rotor (subunit c) and with an F(1) component of the stator (subunit beta). Oxidation of the engineered F(0)F(1) causes formation of two disulfide bonds, betaD380C-S108C epsilon and epsilonE31C-cQ42C, to give a beta-epsilon-c cross-linked product in high yield. The results demonstrate the ability of epsilon to span the central stalk region from the surface of the membrane (epsilon-c) to the bottom of F(1) (beta-epsilon) and suggest that the conformation detected here is distinct from both the "closed" state seen with isolated epsilon (Uhlin, U., Cox, G. B., and Guss, J. M. (1997) Structure 5, 1219-1230) and the "open" state seen in a complex with a truncated form of the gamma subunit (Rodgers, A. J., and Wilce, M. C. (2000) Nat. Struct. Biol. 7, 1051-1054). The kinetics of beta-epsilon and epsilon-c cross-linking were studied separately using F(0)F(1) containing one or the other matched cysteine pair. The rate of cross-linking at the epsilon/c (rotor/rotor) interface is not influenced by the type of nucleotide added. In contrast, the rate of beta-epsilon cross-linking is fastest under ATP hydrolysis conditions, intermediate with MgADP, and slowest with MgAMP-PNP. This is consistent with a regulatory role for a reversible beta/epsilon (stator/rotor) interaction that blocks rotation and inhibits catalysis. Furthermore, the rate of beta-epsilon cross-linking is much faster than that indicated by previous studies, allowing for the possibility of a rapid response to regulatory signals.     

Mitochondrial ATP synthasome. Cristae-enriched membranes and a multiwell detergent screening assay yield dispersed single complexes containing the ATP synthase and carriers for Pi and ADP/ATP

The terminal step of ATP synthesis in intact mitochondria is catalyzed by the ATP synthase (F(0)F(1)) that works in close synchrony with the P(i) and ADP/ATP carriers. Each carrier consists of only a single polypeptide chain in dimeric form, while the ATP synthase is highly complex consisting in animals of 17 known subunit types and more than 30 total subunits. Although structures at high resolution have been obtained for the water-soluble F(1) part of the ATP synthase consisting of only five subunit types, such structures have not been obtained for either the complete ATP synthase or the P(i) and ADP/ATP carriers. Here, we report that all three proteins are localized in highly purified cristae-like vesicles obtained by extensive subfractionation of the mitochondrial inner membrane. Moreover, using a multiwell detergent screening assay, 4 nonionic detergents out of 80 tested were found to disperse these cristae-like vesicles into single soluble complexes or "ATP synthasomes" that contain the ATP synthase in association with the P(i) and ADP/ATP carriers. These studies offer new mechanistic insights into the terminal steps of oxidative phosphorylation in mitochondria and set the stage for future structural efforts designed to visualize in atomic detail the entire complex involved. They also provide evidence that the cristae are a subcompartment of the inner membrane.     

ATP synthase motor components: proposal and animation of two dynamic models for stator function

Recent research indicates that ATP synthases (F(0)F(1)) contain two distinct nanomotors, one an electrochemically driven proton motor contained within F(0) that drives an ATP hydrolysis-driven motor (F(1)) in reverse during ATP synthesis. This is depicted in recent models as involving a series of events in which each of the three alphabeta pairs comprising F(1) is induced via a centrally rotating subunit (gamma) to undergo the sequential binding changes necessary to synthesize ATP (binding change mechanism). Stabilization of this rotary process (i.e., to minimize "wobble" of F(1)) is provided in current models by a peripheral stalk or "stator" that has recently been shown to extend from near the bottom of the ATP synthase molecule to the very top of F(1). Although quite elegant, these models envision the stator as fixed during ATP synthesis, i.e., bound to only a single alphabeta pair. This is despite the fact that the binding change mechanism views each alphabeta pair as going through the same sequential order of conformational changes which demonstrate a chemical equivalency among them. For this reason, we propose here two different dynamic models for stator function during ATP synthesis. Both models have been designed to maintain chemical equivalency among the three alphabeta pairs during ATP synthesis and both have been animated.     

ATP synthase: subunit-subunit interactions in the stator stalk

In ATP synthase, proton translocation through the Fo subcomplex and ATP synthesis/hydrolysis in the F1 subcomplex are coupled by subunit rotation. The static, non-rotating portions of F1 and Fo are attached to each other via the peripheral "stator stalk", which has to withstand elastic strain during subunit rotation. In Escherichia coli, the stator stalk consists of subunits b2delta; in other organisms, it has three or four different subunits. Recent advances in this area include affinity measurements between individual components of the stator stalk as well as a detailed analysis of the interaction between subunit delta (or its mitochondrial counterpart, the oligomycin-sensitivity conferring protein, OSCP) and F1. The current status of our knowledge of the structure of the stator stalk and of the interactions between its subunits will be discussed in this review.     

Location of subunit d in the peripheral stalk of the ATP synthase from Saccharomyces cerevisiae

ATP synthase from Saccharomyces cerevisiae is an approximately 600 kDa membrane protein complex. The enzyme couples the proton motive force across the mitochondrial inner membrane to the synthesis of ATP from ADP and inorganic phosphate. The peripheral stalk subcomplex acts as a stator, preventing the rotation of the soluble F 1 region relative to the membrane-bound F O region during ATP synthesis. Component subunits of the peripheral stalk are Atp5p (OSCP), Atp4p (subunit b), Atp7p (subunit d), and Atp14p (subunit h). X-ray crystallography has defined the structure of a large fragment of the bovine peripheral stalk, including 75% of subunit d (residues 3-123). Docking the peripheral stalk structure into a cryo-EM map of intact yeast ATP synthase showed that residue 123 of subunit d lies close to the bottom edge of F 1. The 37 missing C-terminal residues are predicted to either fold back toward the apex of F 1 or extend toward the membrane. To locate the C terminus of subunit d within the peripheral stalk of ATP synthase from S. cerevisiae, a biotinylation signal was fused to the protein. The biotin acceptor domain became biotinylated in vivo and was subsequently labeled with avidin in vitro. Electron microscopy of the avidin-labeled complex showed the label tethered close to the membrane surface. We propose that the C-terminal region of subunit d spans the gap from F 1 to F O, reinforcing this section of the peripheral stalk.     

Characterization of domain interfaces in monomeric and dimeric ATP synthase

We disassembled monomeric and dimeric yeast ATP synthase under mild conditions to identify labile proteins and transiently stable subcomplexes that had not been observed before. Specific removal of subunits alpha, beta, oligomycin sensitivity conferring protein (OSCP), and h disrupted the ATP synthase at the gamma-alpha(3)beta(3) rotor-stator interface. Loss of two F(1)-parts from dimeric ATP synthase led to the isolation of a dimeric subcomplex containing membrane and peripheral stalk proteins thus identifying the membrane/peripheral stalk sectors immediately as the dimerizing parts of ATP synthase. Almost all subunit a was found associated with a ring of 10 c-subunits in two-dimensional blue native/SDS gels. We therefore postulate that c10a1-complex is a stable structure in resting ATP synthase until the entry of protons induces a breaking of interactions and stepwise rotation of the c-ring relative to the a-subunit in the catalytic mechanism. Dimeric subunit a was identified in SDS gels in association with two c10-rings suggesting that a c10a2c10-complex may constitute an important part of the monomer-monomer interface in dimeric ATP synthase that seems to be further tightened by subunits b, i, e, g, and h. In contrast to the monomer-monomer interface, the interface between dimers in higher oligomeric structures remains largely unknown. However, we could show that the natural inhibitor protein Inh1 is not required for oligomerization.     

Solution structure of subunit F(6) from the peripheral stalk region of ATP synthase from bovine heart mitochondria

The ATP synthase enzyme structure includes two stalk assemblies, the central stalk and the peripheral stalk. Catalysis involves rotation of the central stalk assembly together with the membrane-embedded ring of c-subunits driven by the trans-membrane proton-motive force, while the alpha and beta-subunits of F(1) are prevented from co-rotating by their attachment to the peripheral stalk. In the absence of structures of either the intact peripheral stalk or larger complexes containing it, we are studying its individual components and their interactions to build up an overall picture of its structure. Here, we describe an NMR structural characterisation of F(6), which is a 76-residue protein located in the peripheral stalk of the bovine ATP synthase and is essential for coupling between the proton-motive force and catalysis. Isolated F(6) has a highly flexible structure comprising two helices packed together through a loose hydrophobic core and connected by an unstructured linker. Analysis of chemical shifts, (15)N relaxation and RDC measurements confirm that the F(6) structure is flexible on a wide range of timescales ranging from nanoseconds to seconds. The relationship between this structure for isolated F(6) and its role in the intact peripheral stalk is discussed.     

Structure of dimeric ATP synthase from mitochondria: an angular association of monomers induces the strong curvature of the inner membrane

Respiration in all cells depends upon synthesis of ATP by the ATP synthase complex, a rotary motor enzyme. The structure of the catalytic moiety of ATP synthase, the so-called F(1) headpiece, is well established. F(1) is connected to the membrane-bound and ion translocating F(0) subcomplex by a central stalk. A peripheral stalk, or stator, prevents futile rotation of the headpiece during catalysis. Although the enzyme functions as a monomer, several lines of evidence have recently suggested that monomeric ATP synthase complexes might interact to form a dimeric supercomplex in mitochondria. However, due to its fragility, the structure of ATP synthase dimers has so far not been precisely defined for any organism. Here we report the purification of a stable dimeric ATP synthase supercomplex, using mitochondria of the alga Polytomella. Structural analysis by electron microscopy and single particle analysis revealed that dimer formation is based on specific interaction of the F(0) parts, not the F(1) headpieces which are not at all in close proximity. Remarkably, the angle between the two F(0) part is about 70 degrees, which induces a strong local bending of the membrane. Hence, the function of ATP synthase dimerisation is to control the unique architecture of the mitochondrial inner membrane.     

Mitochondrial genome integrity mutations uncouple the yeast Saccharomyces cerevisiae ATP synthase

The mitochondrial ATP synthase is a molecular motor, which couples the flow of protons with phosphorylation of ADP. Rotation of the central stalk within the core of ATP synthase effects conformational changes in the active sites driving the synthesis of ATP. Mitochondrial genome integrity (mgi) mutations have been previously identified in the alpha-, beta-, and gamma-subunits of ATP synthase in yeast Kluyveromyces lactis and trypanosome Trypanosoma brucei. These mutations reverse the lethality of the loss of mitochondrial DNA in petite negative strains. Introduction of the homologous mutations in Saccharomyces cerevisiae results in yeast strains that lose mitochondrial DNA at a high rate and accompanied decreases in the coupling of the ATP synthase. The structure of yeast F1-ATPase reveals that the mgi residues cluster around the gamma-subunit and selectively around the collar region of F1. These results indicate that residues within the mgi complementation group are necessary for efficient coupling of ATP synthase, possibly acting as a support to fix the axis of rotation of the central stalk.     

Lengthening the second stalk of F(1)F(0) ATP synthase in Escherichia coli

In Escherichia coli F(1)F(0) ATP synthase, the two b subunits dimerize forming the peripheral second stalk linking the membrane F(0) sector to F(1). Previously, we have demonstrated that the enzyme could accommodate relatively large deletions in the b subunits while retaining function (Sorgen, P. L., Caviston, T. L., Perry, R. C., and Cain, B. D. (1998) J. Biol. Chem. 273, 27873-27878). The manipulations of b subunit length have been extended by construction of insertion mutations into the uncF(b) gene adding amino acids to the second stalk. Mutants with insertions of seven amino acids were essentially identical to wild type strains, and mutants with insertions of up to 14 amino acids retained biologically significant levels of activity. Membranes prepared from these strains had readily detectable levels of F(1)F(0)-ATPase activity and proton pumping activity. However, the larger insertions resulted in decreasing levels of activity, and immunoblot analysis indicated that these reductions in activity correlated with reduced levels of b subunit in the membranes. Addition of 18 amino acids was sufficient to result in the loss of F(1)F(0) ATP synthase function. Assuming the predicted alpha-helical structure for this area of the b subunit, the 14-amino acid insertion would result in the addition of enough material to lengthen the b subunit by as much as 20 A. The results of both insertion and deletion experiments support a model in which the second stalk is a flexible feature of the enzyme rather than a rigid rod-like structure.     

Structure of the mitochondrial ATP synthase by electron cryomicroscopy

We have determined the structure of intact ATP synthase from bovine heart mitochondria by electron cryomicroscopy of single particles. Docking of an atomic model of the F1-c10 subcomplex into a major segment of the map has allowed the 32 A resolution density to be interpreted as the F1-ATPase, a central and a peripheral stalk and an FO membrane region that is composed of two domains. One domain of FO corresponds to the ring of c-subunits, and the other probably contains the a-subunit, the transmembrane portion of the b-subunit and the remaining integral membrane proteins of FO. The peripheral stalk wraps around the molecule and connects the apex of F1 to the second domain of FO. The interaction of the peripheral stalk with F1-c10 implies that it binds to a non-catalytic alpha-beta interface in F1 and its inclination where it is not attached to F1 suggests that it has a flexible region that can serve as a stator during both ATP synthesis and ATP hydrolysis.     

ATP synthase--the structure of the stator stalk

ATP synthase synthesizes ATP from ADP and inorganic phosphate using a unique rotary mechanism whereby two subcomplexes move relative to each other, powered by a proton or sodium gradient. The non-rotating parts of the machinery are held together by the "stator stalk". The recent resolution of the structure of a major portion of the stator stalk of mitochondrial ATP synthase represents an important step towards a structural model for the ATP synthase holoenzyme.     

Binding of subunit E into the A-B interface of the A(1)A(O) ATP synthase

Two of the distinct diversities of the engines A(1)A(O) ATP synthase and F(1)F(O) ATP synthase are the existence of two peripheral stalks and the 24kDa stalk subunit E inside the A(1)A(O) ATP synthase. Crystallographic structures of subunit E have been determined recently, but the epitope(s) and the strength to which this subunit does bind in the enzyme complex are still a puzzle. Using the recombinant A(3)B(3)D complex and the major subunits A and B of the methanogenic A(1)A(O) ATP synthase in combination with fluorescence correlation spectroscopy (FCS) we demonstrate, that the stalk subunit E does bind to the catalytic headpiece formed by the A(3)B(3) hexamer with an affinity (K(d)) of 6.1±0.2μM. FCS experiments with single A and B, respectively, demonstrated unequivocally that subunit E binds stronger to subunit B (K(d)=18.9±3.7μM) than to the catalytic A subunit (K(d)=53.1±4.4). Based on the crystallographic structures of the three subunits A, B and E available, the arrangement of the peripheral stalk subunit E in the A-B interface has been modeled, shining light into the A-B-E assembly of this enzyme.     

Topological and functional study of subunit h of the F1Fo ATP synthase complex in yeast Saccharomyces cerevisiae

Subunit h, a 92-residue-long, hydrophilic, acidic protein, is a component of the yeast mitochondrial F1Fo ATP synthase. This subunit, homologous to the mammalian factor F6, is essential for the correct assembly and/or functioning of this enzyme since yeast cells lacking it are not able to grow on nonfermentable carbon sources. Chemical cross-links between subunit h and subunit 4 have previously been shown, suggesting that subunit h is a component of the peripheral stalk of the F1Fo ATP synthase. The construction of cysteine-containing subunit h mutants and the use of bismaleimide reagents provided insights into its environment. Cross-links were obtained between subunit h and subunits alpha, f, d, and 4. These results and secondary structure predictions allowed us to build a structural model and to propose that this subunit occupies a central place in the peripheral stalk between the F1 sector and the membrane. In addition, subunit h was found to have a stoichiometry of one in the F1Fo ATP synthase complex and to be in close proximity to another subunit h belonging to another F1Fo ATP synthase in the inner mitochondrial membrane. Finally, functional characterization of mitochondria from mutants expressing different C-terminal shortened subunit h suggested that its C-terminal part is not essential for the assembly of a functional F1Fo ATP synthase.     

Yeast cells depleted in Atp14p fail to assemble Atp6p within the ATP synthase and exhibit altered mitochondrial cristae morphology

Within the yeast mitochondrial ATP synthase, subunit h is a small nuclear encoded protein belonging to the so-called "peripheral stalk" that connects the enzyme catalytic F(1) component to the mitochondrial inner membrane. This study examines the role of subunit h in ATP synthase function and assembly using a regulatable, doxycycline-repressible subunit h gene to overcome the strong instability of the mtDNA previously observed in strains lacking the native subunit h gene. Yeast cells expressing less than 3% of subunit h, but still containing intact mitochondrial genomes, grew poorly on respiratory substrates because of a major impairment of ATP synthesis originating from the ATP synthase, whereas the respiratory chain complexes were not affected. The lack of ATP synthesis in the subunit h-depleted (deltah) mitochondria was attributed to defects in the assembly/stability of the ATP synthase. A main feature of deltah-mitochondria was a very low content (<6%) in the mitochondrially encoded Atp6p subunit, an essential component of the enzyme proton channel, which was in large part because of a slowing down in translation. Interestingly, depletion of subunit h resulted in dramatic changes in mitochondrial cristae morphology, which further supports the existence of a link between the ATP synthase and the folding/biogenesis of the inner mitochondrial membrane.     

The second stalk of Escherichia coli ATP synthase

Two stalks link the F(1) and F(0) sectors of ATP synthase. The central stalk contains the gamma and epsilon subunits and is thought to function in rotational catalysis as a rotor driving conformational changes in the catalytic alpha(3)beta(3) complex. The two b subunits and the delta subunit associate to form b(2)delta, a second, peripheral stalk extending from the membrane up the side of alpha(3)beta(3) and binding to the N-terminal regions of the alpha subunits, which are approx. 125 A from the membrane. This second stalk is essential for binding F(1) to F(0) and is believed to function as a stator during rotational catalysis. In vitro, b(2)delta is a highly extended complex held together by weak interactions. Recent work has identified the domains of b which are essential for dimerization and for interaction with delta. Disulphide cross-linking studies imply that the second stalk is a permanent structure which remains associated with one alpha subunit or alphabeta pair. However, the weak interactions between the polypeptides in b(2)delta pose a challenge for the proposed stator function.