ATP synthase: what we know about ATP hydrolysis and what we do not know about ATP synthesis

Normal-mode-based modeling of allosteric couplings that underlie cyclic conformational transition in F(1) ATPase

F(1) ATPase, a rotary motor comprised of a central stalk (gamma subunit) enclosed by three alpha and beta subunits alternately arranged in a hexamer, features highly cooperative binding and hydrolysis of ATP. Despite steady progress in biophysical, biochemical, and computational studies of this fascinating motor, the structural basis for cooperative ATPase involving its three catalytic sites remains not fully understood. To illuminate this key mechanistic puzzle, we have employed a coarse-grained elastic network model to probe the allosteric couplings underlying the cyclic conformational transition in F(1) ATPase at a residue level of detail. We will elucidate how ATP binding and product (ADP and phosphate) release at two catalytic sites are coupled with the rotation of gamma subunit via various domain motions in alpha(3)beta(3) hexamer (including intrasubunit hinge-bending motions in beta subunits and intersubunit rigid-body rotations between adjacent alpha and beta subunits). To this end, we have used a normal-mode-based correlation analysis to quantify the allosteric couplings of these domain motions to local motions at catalytic sites and the rotation of gamma subunit. We have then identified key amino acid residues involved in the above couplings, some of which have been validated against past studies of mutated and gamma-truncated F(1) ATPase. Our finding strongly supports a binding change mechanism where ATP binding to the empty catalytic site triggers a series of intra- and intersubunit domain motions leading to ATP hydrolysis and product release at the other two closed catalytic sites.

ATP synthase with its gamma subunit reduced to the N-terminal helix can still catalyze ATP synthesis

ATP synthase uses a unique rotary mechanism to couple ATP synthesis and hydrolysis to transmembrane proton translocation. As part of the synthesis mechanism, the torque of the rotor has to be converted into conformational rearrangements of the catalytic binding sites on the stator to allow synthesis and release of ATP. The gamma subunit of the rotor, which plays a central role in the energy conversion, consists of two long helices inside the central cavity of the stator cylinder plus a globular portion outside the cylinder. Here, we show that the N-terminal helix alone is able to fulfill the function of full-length gamma in ATP synthesis as long as it connects to the rest of the rotor. This connection can occur via the epsilon subunit. No direct contact between gamma and the c ring seems to be required. In addition, the results indicate that the epsilon subunit of the rotor exists in two different conformations during ATP synthesis and ATP hydrolysis.

Torque generation and elastic power transmission in the rotary F(O)F(1)-ATPase

Adenosine triphosphate (ATP), the universal fuel of the cell, is synthesized from adenosine diphosphate (ADP) and inorganic phosphate (P(i)) by 'ATP synthase' (F(O)F(1)-ATPase). During respiration or photosynthesis, an electrochemical potential difference of protons is set up across the respective membranes. This powers the enzyme's electrical rotary nanomotor (F(O)), which drives the chemical nanomotor (F(1)) by elastic mechanical-power transmission, producing ATP with high kinetic efficiency. Attempts to understand in detail the mechanisms of torque generation in this simple and robust system have been both aided and complicated by a wealth of sometimes conflicting data.

The alpha/beta interfaces of alpha(1)beta(1), alpha(3)beta(3), and F1: domain motions and elastic energy stored during gamma rotation

ATP synthase (F(o)F(1)) consists of F(1) (ATP-driven motor) and F(o) (H(+)-driven motor). F(1) is a complex of alpha(3)beta(3)gammadeltaepsilon subunits, and gamma is the rotating cam in alpha(3)beta(3). Thermophilic F(1) (TF(1)) is exceptional in that it can be crystallized as a beta monomer and an alpha(3)beta(3) oligomer, and it is sufficiently stable to allow alphabeta refolding and reassembly of hybrid complexes containing 1, 2, and 3 modified alpha or beta. The nucleotide-dependent open-close conversion of conformation is an inherent property of an isolated beta and energy and signals are transferred through alpha/beta interfaces. The catalytic and noncatalytic interfaces of both mitochondrial F(1) (MF(1)) and TF(1) were analyzed by an atom search within the limits of 0.40 nm across the alphabeta interfaces. Seven (plus thermophilic loop in TF(1)) contact areas are located at both the catalytic and noncatalytic interfaces on the open beta form. The number of contact areas on closed beta increased to 11 and 9, respectively, in the catalytic and noncatalytic interfaces. The interfaces in the barrel domain are immobile. The torsional elastic strain applied through the mobile areas is concentrated in hinge residues and the P-loop in beta. The notion of elastic energy in F(o)F(1) has been revised. X-ray crystallography of F(1) is a static snap shot of one state and the elastic hypotheses are still inconsistent with the structure, dyamics, and kinetics of F(o)F(1). The domain motion and elastic energy in F(o)F(1) will be elucidated by time-resolved crystallography.

The catalytic transition state in ATP synthase

The catalytic transition state of ATP synthase has been characterized and modeled by combined use of (1) Mg-ADP-fluoroaluminate, Mg-ADP-fluoroscandium, and corresponding Mg-IDP-fluorometals as transition-state analogs; (2) fluorescence signals of beta-Trp331 and beta-Trp148 as optical probes to assess formation of the transition state; (3) mutations of critical catalytic residues to determine side-chain ligands required to stabilize the transition state. Rate acceleration by positive catalytic site cooperativity is explained as due to mobility of alpha-Arg376, acting as an "arginine finger" residue, which interacts with nucleotide specifically at the transition state step of catalysis, not with Mg-ATP- or Mg-ADP-bound ground states. We speculate that formation and collapse of the transition state may engender catalytic site alpha/beta subunit-interface conformational movement, which is linked to gamma-subunit rotation.

Functional halt positions of rotary FOF1-ATPase correlated with crystal structures

The F(O)F(1)-ATPase is a rotary molecular motor. Driven by ATP-hydrolysis, its central shaft rotates in 80 degrees and 40 degrees steps, interrupted by catalytic and ATP-waiting dwells. We recorded rotations and halts by means of microvideography in laboratory coordinates. A correlation with molecular coordinates was established by using an engineered pair of cysteines that, under oxidizing conditions, formed zero-length cross-links between the rotor and the stator in an orientation as found in crystals. The fixed orientation coincided with that of the catalytic dwell, whereas the ATP waiting dwell was displaced from it by +40 degrees . In crystals, the convex side of the cranked central shaft faces an empty nucleotide binding site, as if holding it open for arriving ATP. Functional studies suggest that three sites are occupied during a catalytic dwell. Our data imply that the convex side faces a nucleotide-occupied rather than an empty site. The enzyme conformation in crystals seems to differ from the conformation during either dwell of the active enzyme. A revision of current schemes of the mechanism is proposed.

Role of alphaPhe-291 residue in the phosphate-binding subdomain of catalytic sites of Escherichia coli ATP synthase

The role of alphaPhe-291 residue in phosphate binding by Escherichia coli F1F0-ATP synthase was examined. X-ray structures of bovine mitochondrial enzyme suggest that this residue resides in close proximity to the conserved betaR246 residue. Herein, we show that mutations alphaF291D and alphaF291E in E. coli reduce the ATPase activity of F1F0 membranes by 350-fold. Yet, significant oxidative phosphorylation activity is retained. In contrast to wild-type, ATPase activities of mutants were not inhibited by MgADP-azide, MgADP-fluoroaluminate, or MgADP-fluoroscandium. Whereas, 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole (NBD-Cl) inhibited wild-type ATPase essentially completely, ATPase in mutants was inhibited maximally by approximately 75%, although reaction still occurred at residue betaTyr-297, proximal to alphaPhe-291 in the phosphate-binding pocket. Inhibition characteristics supported the conclusion that NBD-Cl reacts in betaE (empty) catalytic sites, as shown previously by X-ray structure analysis. Phosphate protected against NBD-Cl inhibition in wild-type but not in mutants. In addition, our data suggest that the interaction of alphaPhe-291 with phosphate during ATP hydrolysis or synthesis may be distinct.

The structure and function of mitochondrial F1F0-ATP synthases

We review recent advances in understanding of the structure of the F(1)F(0)-ATP synthase of the mitochondrial inner membrane (mtATPase). A significant achievement has been the determination of the structure of the principal peripheral or stator stalk components bringing us closer to achieving the Holy Grail of a complete 3D structure for the complex. A major focus of the field in recent years has been to understand the physiological significance of dimers or other oligomer forms of mtATPase recoverable from membranes and their relationship to the structure of the cristae of the inner mitochondrial membrane. In addition, the association of mtATPase with other membrane proteins has been described and suggests that further levels of functional organization need to be considered. Many reports in recent years have concerned the location and function of ATP synthase complexes or its component subunits on the external surface of the plasma membrane. We consider whether the evidence supports complete complexes being located on the cell surface, the biogenesis of such complexes, and aspects of function especially related to the structure of mtATPase.

ATP synthase: motoring to the finish line

Protonmotive force produced by the electron transport chain is harnessed by the rotary molecular nanomotor ATP synthase to generate ATP. In this issue of Cell, Adachi et al. (2007), in a dazzling display of technical sophistication, now disentangle the coupling between the mechanical force generated by rotation of the ATP synthase subunits and the chemical reactions that occur simultaneously at the enzyme's three catalytic sites.

Coupling of rotation and catalysis in F(1)-ATPase revealed by single-molecule imaging and manipulation

F(1)-ATPase is a rotary molecular motor that proceeds in 120 degrees steps, each driven by ATP hydrolysis. How the chemical reactions that occur in three catalytic sites are coupled to mechanical rotation is the central question. Here, we show by high-speed imaging of rotation in single molecules of F(1) that phosphate release drives the last 40 degrees of the 120 degrees step, and that the 40 degrees rotation accompanies reduction of the affinity for phosphate. We also show, by single-molecule imaging of a fluorescent ATP analog Cy3-ATP while F(1) is forced to rotate slowly, that release of Cy3-ADP occurs at approximately 240 degrees after it is bound as Cy3-ATP at 0 degrees . This and other results suggest that the affinity for ADP also decreases with rotation, and thus ADP release contributes part of energy for rotation. Together with previous results, the coupling scheme is now basically complete.

The Structural Coupling between ATPase Activation and Recovery Stroke in the Myosin II Motor

Before the myosin motor head can perform the next power stroke, it undergoes a large conformational transition in which the converter domain, bearing the lever arm, rotates approximately 65 degrees . Simultaneous with this "recovery stroke," myosin activates its ATPase function by closing the Switch-2 loop over the bound ATP. This coupling between the motions of the converter domain and of the 40 A-distant Switch-2 loop is essential to avoid unproductive ATP hydrolysis. The coupling mechanism is determined here by finding a series of optimized intermediates between crystallographic end structures of the recovery stroke (Dictyostelium discoideum), yielding movies of the transition at atomic detail. The successive formation of two hydrogen bonds by the Switch-2 loop is correlated with the successive see-saw motions of the relay and SH1 helices that hold the converter domain. SH1 helix and Switch-2 loop communicate via a highly conserved loop that wedges against the SH1-helix upon Switch-2 closing.

Effect of Ca2+ on cardiac mitochondrial energy production is modulated by Na+ and H+ dynamics

The energy production of mitochondria in heart increases during exercise. Several works have suggested that calcium acts at multiple control points to activate net ATP production in what is termed "parallel activation". To study this, a computational model of mitochondrial energy metabolism in the heart has been developed that integrates the Dudycha-Jafri model for the tricarboxylic acid cycle with the Magnus-Keizer model for mitochondrial energy metabolism and calcium dynamics. The model improves upon the previous formulation by including an updated formulation for calcium dynamics, and new descriptions of sodium, hydrogen, phosphate, and ATP balance. To this end, it incorporates new formulations for the calcium uniporter, sodium-calcium exchange, sodium-hydrogen exchange, the F(1)F(0)-ATPase, and potassium-hydrogen exchange. The model simulates a wide range of experimental data, including steady-state and simulated pacing protocols. The model suggests that calcium is a potent activator of net ATP production and that as pacing increases energy production due to calcium goes up almost linearly. Furthermore, it suggests that during an extramitochondrial calcium transient, calcium entry and extrusion cause a transient depolarization that serve to increase NADH production by the tricarboxylic acid cycle and NADH consumption by the respiration driven proton pumps. The model suggests that activation of the F(1)F(0)-ATPase by calcium is essential to increase ATP production. In mitochondria very close to the release sites, the depolarization is more severe causing a temporary loss of ATP production. However, due to the short duration of the depolarization the net ATP production is also increased.

Does F1-ATPase have a catalytic site that preferentially binds MgADP?

During ATP synthesis, ATP synthase has to bind MgADP in the presence of an excess of MgATP. Thus, for efficient ATP synthesis it would be desirable if incoming substrate could be bound to a catalytic site with a preference for MgADP over MgATP. We tested three hypotheses predicting the existence of such a site. However, our results showed that, at least in absence of an electrochemical proton gradient, none of the three catalytic sites has a higher affinity for MgADP than for MgATP.

Mechanistic basis for therapeutic targeting of the mitochondrial F1F0-ATPase

Altered cellular bioenergetics are implicated in many disease processes, and modulating the F 1 F o -ATPase, the enzyme responsible for producing the majority of ATP in eukaryotic cells, has been proposed to have therapeutic utility. Bz-423 is a 1,4-benzodiazepine that binds to the oligomycin sensitivity-conferring protein subunit of the mitochondrial F 1 F o -ATPase and inhibits the enzyme. In response to Bz-423, cells moderately decrease ATP synthesis and significantly increase superoxide, resulting in redox-regulated apoptosis. Administering Bz-423 to autoimmune mice leads to apoptosis of pathogenic cells and potent attenuation of disease progression. To determine if a mechanism of action distinguishes Bz-423 from toxic F 1 F o -ATPase inhibitors like oligomycin, we studied how both compounds inhibit the enzyme. Oligomycin is a high-affinity mixed inhibitor, displaying time-dependent inhibition, resulting in severe depletion of ATP. In contrast, Bz-423 is an allosteric inhibitor with lower affinity that rapidly dissociates from the enzyme. Our data support a model in which the interplay of these features underlies the favorable properties of Bz-423. They also represent key criteria for the development of therapeutic F 1 F o -ATPase inhibitors, which should have utility across a range of areas.

VHA-8, the E subunit of V-ATPase, is essential for pH homeostasis and larval development in C. elegans

Vacuolar H+-ATPase (V-ATPase) is an ATP-dependent proton pump, which transports protons across the membrane. It is a multi-protein complex which is composed of at least 13 subunits. The Caenorhabditis elegans vha-8 encodes the E subunit of V-ATPase which is expressed in the hypodermis, intestine and H-shaped excretory cells. VHA-8 is necessary for proper intestinal function likely through its role in cellular acidification of intestinal cells. The null mutants of vha-8 show a larval lethal phenotype indicating that vha-8 is an essential gene for larval development in C. elegans. Interestingly, characteristics of necrotic cell death were observed in the hypodermis and intestine of the arrested larvae suggesting that pH homeostasis via the E subunit of V-ATPase is required for the cell survival in C. elegans.

Requirement of medium ADP for the steady-state hydrolysis of ATP by the proton-translocating Paracoccus denitrificans Fo.F1-ATP synthase

Fo.F1-ATP synthase in inside-out coupled vesicles derived from Paracoccus denitrificans catalyzes Pi-dependent proton-translocating ATPase reaction if exposed to prior energization that relieves ADP.Mg2+ -induced inhibition (Zharova, T.V. and Vinogradov, A.D. (2004) J. Biol. Chem.,279, 12319-12324). Here we present evidence that the presence of medium ADP is required for the steady-state energetically self-sustained coupled ATP hydrolysis. The initial rapid ATPase activity is declined to a certain level if the reaction proceeds in the presence of the ADP-consuming, ATP-regenerating system (pyruvate kinase/phosphoenol pyruvate). The rate and extent of the enzyme de-activation are inversely proportional to the steady-state ADP concentration, which is altered by various amounts of pyruvate kinase at constant ATPase level. The half-maximal rate of stationary ATP hydrolysis is reached at an ADP concentration of 8 x 10(-6) M. The kinetic scheme is proposed explaining the requirement of the reaction products (ADP and Pi), the substrates of ATP synthesis, in the medium for proton-translocating ATP hydrolysis by P. denitrificans Fo.F1-ATP synthase.

ATP synthase is responsible for maintaining mitochondrial membrane potential in bloodstream form Trypanosoma brucei

The mitochondrion of Trypanosoma brucei bloodstream form maintains a membrane potential, although it lacks cytochromes and several Krebs cycle enzymes. At this stage, the ATP synthase is present at reduced, although significant, levels. To test whether the ATP synthase at this stage is important for maintaining the mitochondrial membrane potential, we used RNA interference (RNAi) to knock down the levels of the ATP synthase by targeting the F1-ATPase alpha and beta subunits. RNAi-induced cells grew significantly slower than uninduced cells but were not morphologically altered. RNAi of the beta subunit decreased the mRNA and protein levels for the beta subunit, as well as the mRNA and protein levels of the alpha subunit. Similarly, RNAi of alpha subunit decreased the alpha subunit transcript and protein levels, as well as the beta-subunit transcript and protein levels. In contrast, alpha and beta RNAi knockdown resulted in a 60% increase in the F0 complex subunit 9 protein levels without a significant change in the steady-state transcript levels of this subunit. The F0-32-kDa subunit protein expression, however, remained stable throughout induction of RNAi for alpha or beta subunits. Oligomycin-sensitive ATP hydrolytic and synthetic activities were decreased by 43 and 44%, respectively. Significantly, the mitochondrial membrane potential of alpha and beta RNAi cells was decreased compared to wild-type cells, as detected by MitoTracker Red CMXRos fluorescence microscopy and flow cytometry. These results support the role of the ATP synthase in the maintenance of the mitochondrial membrane potential in bloodstream form T. brucei.

Making ATP

We present a mesoscopic model for ATP synthesis by F(1)F(o) ATPase. The model combines the existing experimental knowledge of the F(1) enzyme into a consistent mathematical model that illuminates how the stages in synthesis are related to the protein structure. For example, the model illuminates how specific interactions between the gamma, epsilon, and alpha(3)beta(3) subunits couple the F(o) motor to events at the catalytic sites. The model also elucidates the origin of ADP inhibition of F(1) in its hydrolysis mode. The methodology we develop for constructing the structure-based model should prove useful in modeling other protein motors.

Regulation of the F0F1-ATP synthase: the conformation of subunit epsilon might be determined by directionality of subunit gamma rotation

F(0)F(1)-ATP synthase couples ATP synthesis/hydrolysis with transmembrane proton transport. The catalytic mechanism involves rotation of the gamma epsilon c(approximately 10)-subunits complex relative to the rest of the enzyme. In the absence of protonmotive force the enzyme is inactivated by the tight binding of MgADP. Subunit epsilon also modulates the activity: its conformation can change from a contracted to extended form with C-terminus stretched towards F(1). The latter form inhibits ATP hydrolysis (but not synthesis). We propose that the directionality of the coiled-coil subunit gamma rotation determines whether subunit epsilon is in contracted or extended form. Block of rotation by MgADP presumably induces the extended conformation of subunit epsilon. This conformation might serve as a safety lock, stabilizing the ADP-inhibited state upon de-energization and preventing spontaneous re-activation and wasteful ATP hydrolysis. The hypothesis merges the known regulatory effects of ADP, protonmotive force and conformational changes of subunit epsilon into a consistent picture.

Detecting proton flux across chromatophores driven by F0F1-ATPase using N-(fluorescein-5-thiocarbamoyl)-1,2-dihexadecanoyl-sn-glycero-3-phosphoethanolamine, triethylammonium salt

N-(Fluorescein-5-thiocarbamoyl)-1,2-dihexadecanoyl-sn-glycero-3-phosphoethanolamine, triethylammonium salt (F-DHPE) is a lipid fluorescence dye sensitive to pH changes and is used in this study for detecting proton flux through F0F1-ATPase within chromatophores driven by ATP hydrolysis. F-DHPE is easily labeled to the outer surface of chromatophores. In the range of pH 7.0 to 9.0, fluorescence intensity is sensitive to pH changes. The sensitivity is especially great in the range of pH 8.2 to 9.0, so pH 8.6 was chosen as the appropriate experimental condition. It is shown that added ATP not only acts as a fluorescence quencher but also can be hydrolyzed by F0F1-ATPase to pump protons into chromatophores, resulting in fluorescence restoration. A stimulator (NaSO3) and various types of inhibitors (NaN3, 5'-adenylyl imidodiphosphate [AMP-PNP], and N,N'-dicyclohexylcarbodiimide [DCCD]) of F0F1 confirmed that fluorescence restoration is caused by ATP-driven proton flux. When loaded with one antibody (anti-beta antibody) or two antibodies (anti-beta antibody and sheep to rabbit second antibody), F0F1-ATPase exhibits lower proton pumping activities, as indicated by fluorescence restoration. The possible mechanism of the inhibition of antibodies on proton pumping activity is discussed.

Magnetic isotope effect of magnesium in phosphoglycerate kinase phosphorylation

Phosphoglycerate kinase (PGK) is found to be controlled by a (25)Mg(2+)-related magnetic isotope effect. Mg(2+) nuclear spin selectivity manifests itself in PGK-directed ADP phosphorylation, which has been clearly proven by comparison of ATP synthesis rates estimated in reaction mixtures with different Mg isotopy parameters. Both pure (25)Mg(2+) (nuclear spin 5/2, magnetic moment +0.85) and (24)Mg(2+) (spinless, nonmagnetic nucleus) species as well as their mixtures were used in experiments. In the presence of (25)Mg(2+), ATP production is 2.6 times higher compared with the yield of ATP reached in (24)Mg(2+)-containing PGK-based catalytic systems. The chemical mechanism of this phenomenon is discussed. A key element of the mechanism proposed is a nonradical pair formation in which (25)Mg(+) radical cation and phosphate oxyradical are involved.

Involvement of ATP synthase residues alphaArg-376, betaArg-182, and betaLys-155 in Pi binding

alphaArg-376, betaLys-155, and betaArg-182 are catalytically important ATP synthase residues that were proposed to be involved in substrate Pi binding and subsequent steps of ATP synthesis [Senior, A.E., Nadanaciva, S. and Weber, J. (2002) Biochim. Biophys. Acta 1553, 188-211]. Here, it was shown using purified Escherichia coli F(1)-ATPase that whereas Pi protected wild-type from reaction with 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole, mutations betaK155Q, betaR182Q, betaR182K, and alphaR376Q abolished protection. Therefore, in ATP synthesis initial binding of substrate Pi in open catalytic site betaE is supported by each of these three residues.

Effects of site-directed mutation on the function of the chloroplast ATP synthase epsilon subunit

The previous work in our lab showed that the spinach chloroplast ATP synthase epsilon mutant with 3 amino acid residues deleted from the N-terminus had much lower ability to inhibit ATP hydrolysis and block proton leakage in comparison to a mutant with 1 or 2 residues deleted from the N-terminus. The present study aimed at determining whether there is special importance in the structure and function of the N-terminal third residue of the chloroplast epsilon subunit. The leucine residue at the N-terminal third site (Leu3) of the spinach chloroplast epsilon subunit was replaced with Ile, Phe, Thr, Arg, Glu or Pro by site-directed mutagenesis, forming mutants epsilonL3I, epsilonL3F, epsilonL3T, epsilonL3R, epsilonL3E and epsilonL3P, respectively. These epsilon variants all showed lower abilities to inhibit ATP hydrolysis and to block proton leakage, as compared to the wild type epsilon subunit (epsilonWT). The abilities of mutants epsilonL3I and epsilonL3F to restore the ATP synthesis activity of reconstituted membranes were higher than those of epsilonWT, but the abilities of the other epsilon variants were lower than that of epsilonWT. These results indicate that the hydrophobic and neutral characteristics of Leu3 of the chloroplast epsilon subunit are very important for its ability to inhibit ATP hydrolysis and block proton leakage, and for the ATP synthesis ability of ATP synthase.

High hydrostatic pressure perturbs the interactions between CF(0)F(1) subunits and induces a dual effect on activity

Chloroplast ATP-synthase is an H(+)/ATP-driven rotary motor in which a hydrophobic multi-subunit assemblage rotates within a hydrophilic stator, and subunit interactions dictate alternate-site catalysis. To explore the relevance of these interactions for catalysis we use hydrostatic pressure to induce conformational changes and/or subunit dissociation, and the resulting changes in the ATPase activity and oligomer structure are evaluated. Under moderate hydrostatic pressure (up to 60-80 MPa), ATPase activity is increased by 1.5-fold. This is not related to an increase in the affinity for ATP, but seems to correlate with an enhanced turnover induced by pressure, and an activation volume for the ATPase reaction of -23.7 ml/mol. Higher pressure (up to 200 MPa) leads to dissociation of the enzyme, as shown by enzyme inactivation, increased binding of 8-anilinonaphthalene-1-sulfonate (ANS) to hydrophobic regions, and labeling of specific Cys residues on the beta and alpha subunits by N-iodoacetyl-N'-(5-sulfo-1-naphthyl)ethylene-4-diamine (IAEDANS). Compression-decompression cycles (between 0.1 and 200 MPa) inactivate CF(0)F(1) in a concentration-dependent manner, although after decompression no enzyme subunit is retained on a Sephadex-G-50 centrifuge column or is further labeled by IAEDANS. It is proposed that moderate hydrostatic pressures induce elastic compression of CF(0)F(1), leading to enhanced turnover. High pressure dissociation impairs the contacts needed for rotational catalysis.

Observation of calcium-dependent unidirectional rotational motion in recombinant photosynthetic F1-ATPase molecules

ATP hydrolysis and synthesis by the F(0)F(1)-ATP synthase are coupled to proton translocation across the membrane in the presence of magnesium. Calcium is known, however, to disrupt this coupling in the photosynthetic enzyme in a unique way: it does not support ATP synthesis, and CaATP hydrolysis is decoupled from any proton translocation, but the membrane does not become leaky to protons. Understanding the molecular basis of these calcium-dependent effects can shed light on the as yet unclear mechanism of coupling between proton transport and rotational catalysis. We show here, using an actin filament gamma-rotation assay, that CaATP is capable of sustaining rotational motion in a highly active hybrid photosynthetic F(1)-ATPase consisting of alpha and beta subunits from Rhodospirillum rubrum and gamma subunit from spinach chloroplasts (alpha(R)(3)beta(R)(3)gamma(C)). The rotation was found to be similar to that induced by MgATP in Escherichia coli F(1)-ATPase molecules. Our results suggest a possible long range pathway that enables the bound CaATP to induce full rotational motion of gamma but might block transmission of this rotational motion into proton translocation by the F(0) part of the ATP synthase.

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.

Role of betaAsn-243 in the phosphate-binding subdomain of catalytic sites of Escherichia coli F(1)-ATPase

In the catalytic mechanism of ATP synthase, phosphate (P(i)) binding and release steps are believed to be correlated to gamma-subunit rotation, and P(i) binding is proposed to be prerequisite for binding ADP in the face of high cellular [ATP]/[ADP] ratios. In x-ray structures, residue betaAsn-243 appears centrally located in the P(i)-binding subdomain of catalytic sites. Here we studied the role of betaAsn-243 in Escherichia coli ATP synthase by mutagenesis to Ala and Asp. Mutation betaN243A caused 30-fold impairment of F(1)-ATPase activity; 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole inhibited this activity less potently than in wild type and P(i) protected from inhibition. ADP-fluoroaluminate was more inhibitory than in wild-type, but ADP-fluoroscandium was less inhibitory. betaN243D F(1)-ATPase activity was impaired by 1300-fold and was not inhibited by ADP-fluoroaluminate or ADP-fluoroscandium. 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole activated betaN243D F(1)-ATPase, and P(i) did not affect activation. We conclude that residue betaAsn-243 is not involved in P(i) binding directly but is necessary for correct organization of the transition state complex through extensive involvement in hydrogen bonding to neighboring residues. It is also probably involved in orientation of the "attacking water" and of an associated second water.

A normal mode analysis of structural plasticity in the biomolecular motor F(1)-ATPase

Normal modes have been used to explore the inherent flexibility of the alpha, beta and gamma subunits of F(1)-ATPase in isolation and as part of the alpha(3)beta(3)gamma complex. It was found that the structural plasticity of the gamma and beta subunits, in particular, correlates with their functions. The N and C-terminal helices forming the coiled-coil domain of the gamma subunit are highly flexible in the isolated subunit, but more rigid in the alpha(3)beta(3)gamma complex due to interactions with other subunits. The globular domain of the gamma subunit is structurally relatively rigid when isolated and in the alpha(3)beta(3)gamma complex; this is important for its functional role in coupling the F(0) and F(1) complex of ATP synthase and in inducing the conformational changes of the beta subunits in synthesis. Most important, the character of the lowest-frequency modes of the beta(E) subunit is highly correlated with the large beta(E) --> beta(TP) transition. This holds for the C-terminal domain and the nucleotide-binding domain, which undergo significant conformational transitions in the functional cycle of F(1)-ATPase. This is most evident in the ligand-free beta(E) subunit; the flexibility in the nucleotide-binding domain is reduced somewhat in the beta(TP) subunit in the presence of Mg(2+).ATP. The low-frequency modes of the alpha(3)beta(3)gamma complex show that the motions of the globular domain of the gamma subunit and of the C-terminal and nucleotide binding domains of the beta(E) subunits are coupled, in accord with their function. Overall, the normal mode analysis reveals that F(1)-ATPase, like other macromolecular assemblies, has the intrinsic structural flexibility required for its function encoded in its sequence and three-dimensional structure. This inherent plasticity is an essential aspect of assuring a small free energy cost for the large-scale conformational transition that occurs in molecular motors.

The structure of bovine F1-ATPase inhibited by ADP and beryllium fluoride

The structure of bovine F1-ATPase inhibited with ADP and beryllium fluoride at 2.0 angstroms resolution contains two ADP.BeF3- complexes mimicking ATP, bound in the catalytic sites of the beta(TP) and beta(DP) subunits. Except for a 1 angstrom shift in the guanidinium of alphaArg373, the conformations of catalytic side chains are very similar in both sites. However, the ordered water molecule that carries out nucleophilic attack on the gamma-phosphate of ATP during hydrolysis is 2.6 angstroms from the beryllium in the beta(DP) subunit and 3.8 angstroms away in the beta(TP) subunit, strongly indicating that the beta(DP) subunit is the catalytically active conformation. In the structure of F1-ATPase with five bound ADP molecules (three in alpha-subunits, one each in the beta(TP) and beta(DP) subunits), which has also been determined, the conformation of alphaArg373 suggests that it senses the presence (or absence) of the gamma-phosphate of ATP. Two catalytic schemes are discussed concerning the various structures of bovine F1-ATPase.

Mutagenesis of residue betaArg-246 in the phosphate-binding subdomain of catalytic sites of Escherichia coli F1-ATPase

Residues responsible for phosphate binding in F(1)F(0)-ATP synthase catalytic sites are of significant interest because phosphate binding is believed linked to proton gradient-driven subunit rotation. From x-ray structures, a phosphate-binding subdomain is evident in catalytic sites, with conserved betaArg-246 in a suitable position to bind phosphate. Mutations betaR246Q, betaR246K, and betaR246A in Escherichia coli were found to impair oxidative phosphorylation and to reduce ATPase activity of purified F(1) by 100-fold. In contrast to wild type, ATPase of mutants was not inhibited by MgADP-fluoroaluminate or MgADP-fluoroscandium, showing the Arg side chain is required for wild-type transition state formation. Whereas 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole (NBD-Cl) inhibited wild-type ATPase essentially completely, ATPase in mutants was inhibited maximally by approximately 50%, although reaction still occurred at residue betaTyr-297, proximal to betaArg-246 in the phosphate-binding pocket. Inhibition characteristics supported the conclusion that NBD-Cl reacts in betaE (empty) catalytic sites, as shown previously by x-ray structure analysis. Phosphate protected against NBD-Cl inhibition in wild type but not in mutants. The results show that phosphate can bind in the betaE catalytic site of E. coli F(1) and that betaArg-246 is an important phosphate-binding residue.

The recognition and catalytic hydrolysis of ATP by protonated phenanthroline-bridged polyamine and (or) Ca(II), Mg(II), Zn(II), and La(III) ions

The supramolecular interactions of 2,9-di(((2′-phenylamino)ethyleneamino)methyl)-1,10-phenanthroline (L) and (or) metal ions (M = Ca2+, Mg2+, Zn2+, or La3+) with nucleotides were investigated. Furthermore, the hydrolysis of ATP catalyzed by a protonated ligand and (or) a metal ion (M = Ca2+, Mg2+, Zn2+, or La3+) was studied at pH 7.6 using 31P NMR spectra. Kinetics studies show that at pH 7.6 the protonated ligand, with a rate constant of 2.9 × 10–4 min–1, does not significantly promote ATP hydrolysis. However, in the presence of Ca2+, Mg2+, Zn2+, or La3+ ions, L can accelerate the hydrolysis of ATP, with corresponding rate constants of 5.73, 1.48, 6.76, and 31.7 × 10–3 min–1, respectively, which are about 29-, 7.5-, 34-, and 159-fold faster than the hydrolysis rate of free ATP. By comparison with M–ATP (M = Ca2+, Mg2+, and La3+) systems, the rates of M–L–ATP were also promoted. This has been achieved through the effective recognition of ATP and the availability of a good intramolecular nucleophile, i.e., a free amino nitrogen atom of L. Compared with the Zn2+–ATP system, the decrease in the rate of the Zn2+–L–ATP system at pH 7.6 may be attributed to the competition between the mixed ligands in binding Zn2+. Similar to L–ATP, the hydrolysis reactions in the Zn2+–L–ATP or M–L–ATP (M = Ca2+, Mg2+, and La3+) systems occur through an addition–elimination type mechanism, in which phosphoramidate intermediates were observed at 2.88 and 4.06 parts per million (ppm) in the L–ATP and Mg2+–L–ATP systems, respectively. Here, metal ions add control or regulation to the hydrolysis reaction. Key words: recognition, ATP hydrolysis, metal ions, phenanthroline-bridged polyamine.

Chemomechanical coupling in F1-ATPase revealed by simultaneous observation of nucleotide kinetics and rotation

F(1)-ATPase is a rotary molecular motor in which unidirectional rotation of the central gamma subunit is powered by ATP hydrolysis in three catalytic sites arranged 120 degrees apart around gamma. To study how hydrolysis reactions produce mechanical rotation, we observed rotation under an optical microscope to see which of the three sites bound and released a fluorescent ATP analog. Assuming that the analog mimics authentic ATP, the following scheme emerges: (i) in the ATP-waiting state, one site, dictated by the orientation of gamma, is empty, whereas the other two bind a nucleotide; (ii) ATP binding to the empty site drives an approximately 80 degrees rotation of gamma; (iii) this triggers a reaction(s), hydrolysis and/or phosphate release, but not ADP release in the site that bound ATP one step earlier; (iv) completion of this reaction induces further approximately 40 degrees rotation.

The Escherichia coli F1F0 ATP synthase displays biphasic synthesis kinetics

The F1F0 proton-translocating ATPase/synthase is the primary generator of ATP in most organisms growing aerobically. Kinetic assays of ATP synthesis have been conducted using enzymes from mitochondria and chloroplasts. However, limited data on ATP synthesis by the model Escherichia coli enzyme are available, mostly because of the lack of an efficient and reproducible assay. We have developed an optimized assay and have collected synthase kinetic data over a substrate concentration range of 2 orders of magnitude for both ADP and Pi from the synthase enzyme of E. coli. Negative and positive cooperativity of substrate binding and positive catalytic cooperativity were all observed. ATP synthesis displayed biphasic kinetics for ADP indicating that 1) the enzyme is capable of catalyzing efficient ATP synthesis when only two of three catalytic sites are occupied by ADP; and 2) occupation of the third site further activates the rate of catalysis.

Interacting helical surfaces of the transmembrane segments of subunits a and c' of the yeast V-ATPase defined by disulfide-mediated cross-linking

Proton translocation by the vacuolar (H+)-ATPase (or V-ATPase) has been shown by mutagenesis to be dependent upon charged residues present within transmembrane segments of subunit a as well as the three proteolipid subunits (c, c', and c"). Interaction between R735 in TM7 of subunit a and the glutamic acid residue in the middle of TM4 of subunits c and c' or TM2 of subunit c" has been proposed to be essential for proton release to the luminal compartment. In order to determine whether the helical face of TM7 of subunit a containing R735 is capable of interacting with the helical face of TM4 of subunit c' containing the essential glutamic acid residue (Glu-145), cysteine-mediated cross-linking between these subunits in yeast has been performed. Cys-less forms of subunits a and c' as well as forms containing unique cysteine residues were constructed, introduced together into a strain disrupted in both endogenous subunits, and tested for growth at neutral pH, for assembly competence and for cross-linking in the presence of cupric-phenanthroline by SDS-PAGE and Western blot analysis. Four different cysteine mutants of subunit a were each tested pairwise with ten different unique cysteine mutants of subunit c'. Strong cross-linking was observed for the pairs aS728C/c'I142C, aA731C/c'E145C, aA738C/c'F143C, aA738C/c'L147C, and aL739C/c'L147C. Partial cross-linking was observed for an additional 13 of 40 pairs analyzed. When arrayed on a helical wheel diagram, the results suggest that the helical face of TM7 of subunit a containing Arg-735 interacts with the helical face of TM4 of subunit c' centered on Val-146 and bounded by Glu-145 and Leu-147. The results are consistent with a possible rotational flexibility of one or both of these transmembrane segments as well as some flexibility of movement perpendicular to the membrane.

On the mechanism of ATP hydrolysis in F1-ATPase

Most of the cellular ATP in living organisms is synthesized by the enzyme F(1)F(o)-ATP synthase. The water soluble F(1) part of the enzyme can also work in reverse and utilize the chemical energy released during ATP hydrolysis to generate mechanical motion. Despite the availability of a large amount of biochemical data and several x-ray crystallographic structures of F(1), there still remains a considerable lack of understanding as to how this protein efficiently converts the chemical energy released during the reaction ATP + H(2)O --> ADP + P(i) into mechanical motion of the stalk. We report here an ab initio QM/MM study of ATP hydrolysis in the beta(TP) catalytic site of F(1). Our simulations provide an atomic level description of the reaction path, its energetics, and the interaction of the nucleotide with the protein environment during catalysis. The simulations suggest that the reaction path with the lowest potential energy barrier proceeds via nucleophilic attack on the gamma-phosphate involving two water molecules. Furthermore, the ATP hydrolysis reaction in beta(TP) is found to be endothermic, demonstrating that the catalytic site is able to support the synthesis of ATP and does not promote ATP hydrolysis in the particular conformation studied.

The unbinding of ATP from F1-ATPase

Using molecular dynamics, we study the unbinding of ATP in F(1)-ATPase from its tight binding state to its weak binding state. The calculations are made feasible through use of interpolated atomic structures from Wang and Oster [Nature 1998, 396: 279-282]. These structures are applied to atoms distant from the catalytic site. The forces from these distant atoms gradually drive a large primary region through a series of sixteen equilibrated steps that trace the hinge bending conformational change in the beta-subunit that drives rotation of gamma-subunit. As the rotation progresses, we find a sequential weakening and breaking of the hydrogen bonds between the ATP molecule and the alpha- and beta-subunits of the ATPase. This finding agrees with the "binding-zipper" model [Oster and Wang, BIOCHIM: Biophys. Acta 2000, 1458: 482-510.] In this model, the progressive formation of the hydrogen bonds is the energy source driving the rotation of the gamma-shaft during hydrolysis. Conversely, the corresponding sequential breaking of these bonds is driven by rotation of the shaft during ATP synthesis. Our results for the energetics during rotation suggest that the nucleotide's coordination with Mg(2+) during binding and release is necessary to account for the observed high efficiency of the motor.

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.

ATP synthesis driven by proton transport in F1F0-ATP synthase

Topical questions in ATP synthase research are: (1) how do protons cause subunit rotation and how does rotation generate ATP synthesis from ADP+Pi? (2) How does hydrolysis of ATP generate subunit rotation and how does rotation bring about uphill transport of protons? The finding that ATP synthase is not just an enzyme but rather a unique nanomotor is attracting a diverse group of researchers keen to find answers. Here we review the most recent work on rapidly developing areas within the field and present proposals for enzymatic and mechanoenzymatic mechanisms.

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.

Reactive oxygen species mediate the down-regulation of mitochondrial transcripts and proteins by tumour necrosis factor-alpha in L929 cells

In this study, we show that reactive oxygen species production induced by tumour necrosis factor alpha (TNF-alpha) in L929 cells was associated with a decrease in the steady-state mRNA levels of the mitochondrial transcript ATPase 6-8. Simultaneously, the transcript levels of two nuclear-encoded glycolytic enzymes, glyceraldehyde-3-phosphate dehydrogenase (GAPDH) and phosphofructokinase, were increased. These changes were associated with decreased protein levels of the ATPase subunit a (encoded by the mitochondrial ATPase 6 gene) and cytochrome c oxidase subunit II, and increased protein levels of phosphofructokinase. Since TNF-alpha had no effect on the amount of mitochondrial DNA, the results suggested that TNF-alpha acted at the transcriptional and/or post-transcriptional level. Reactive oxygen species scavengers, such as butylated hydroxianisole and butylated hydroxytoluene, blocked the production of free radicals, prevented the down-regulation of ATPase 6-8 transcripts, preserved the protein levels of ATPase subunit a and cytochrome c oxidase subunit II, and attenuated the cytotoxic response to TNF-alpha, indicating a direct link between these two phenomena.

The first putative transmembrane segment of subunit c" (Vma16p) of the yeast V-ATPase is not necessary for function

The yeast vacuolar ATPase (V-ATPase) contains three proteolipid subunits: c (Vma3p), c' (Vma11p), and c" (Vma16p). Each subunit contains a buried glutamate residue that is essential for function, and these subunits are not able to substitute for each other in supporting activity. Subunits c and c' each contain four putative transmembrane segments (TM1-4), whereas subunit c" is predicted to contain five. To determine whether TM1 of subunit c" serves an essential function, a deletion mutant of Vma16p was constructed lacking TM1 (Vma16p-Delta TM1). Although this construct does not complement the loss of Vma3p or Vma11p, it does complement the loss of full-length Vma16p. Vacuoles isolated from the strain expressing Vma16p-Delta TM1 showed V-ATPase activity and proton transport greater than 80% relative to wild type and displayed wild type levels of subunits A and a, suggesting normal assembly of the V-ATPase complex. These results suggest that TM1 of Vma16p is dispensable for both activity and assembly of the V-ATPase. To obtain information about the topology of Vma16p, labeling of single cysteine-containing mutants using the membrane-permeable reagent 3-(N-maleimidylpropionyl)biocytin (MPB) and the -impermeable reagent 4-acetamido-4'-maleimidylstilbene-2,2'-disulfonic acid (AMS) was tested. Both the Cys-less form of Vma16p and eight single cysteine-containing mutants retained greater than 80% of wild type levels of activity. Of the eight mutants tested, two (S5C and S178C) were labeled by MPB. MPB-labeling of S5C was blocked by AMS in intact vacuoles, whereas S178C was blocked by AMS only in the presence of permeabilizing concentrations of detergent. In addition, a hemagglutinin epitope tag introduced into the C terminus of Vma16p was recognized by an anti-hemagglutinin antibody in intact vacuolar membranes, suggesting a cytoplasmic orientation for the C terminus. These results suggest that subunit c" contains four rather than five transmembrane segments with both the N and C terminus on the cytoplasmic side of the membrane.