EC:3.6.3.14 - FACTA Search

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Query: EC:3.6.3.14 (ATP synthase)
7,042 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

ATP synthase is found in bacteria, chloroplasts and mitochondria. The simplest known example of such an enzyme is that in the eubacterium Escherichia coli; it is a membrane-bound assembly of eight different polypeptides assembled with a stoichiometry of alpha 3 beta 3 gamma 1 delta 1 epsilon 1 a1b2c10-12. The first five of these constitute a globular structure, F1-ATPase, which is bound to an intrinsic membrane domain, F0, an assembly of the three remaining subunits. ATP synthases driven by photosynthesis are slightly more complex. In chloroplasts, and probably in photosynthetic bacteria, they have nine subunits, all homologues of the components of the E. coli enzyme; the additional subunit is a duplicated and diverged relation of subunit b. The mammalian mitochondrial enzyme is more complex. It contains 14 different polypeptides, of which 13 have been characterized. Two membrane components, a (or ATPase-6) and A6L, are encoded in the mitochondrial genome in overlapping genes and the remaining subunits are nuclear gene products that are translated on cytoplasmic ribosomes and then imported into the organelle. The sequence of the proteins of ATP-synthase have provided information about amino acids that are important for its function. For example, amino acids contributing to nucleotide binding sites have been identified. Also, they provide the basis of models of secondary structure of membrane components that constitute the transmembrane proton channel. An understanding of the coupling of the transmembrane potential gradient for protons, delta mu H+, to ATP synthesis will probably require the determination of the structure of the entire membrane bound complex. Crystals have been obtained of the globular domain, F1-ATPase. They diffract to a resolution of 3-4 A and data collection is in progress. As a preliminary step towards crystallization of the entire complex, we have purified it from bovine mitochondria and reconstituted it into phospholipid vesicles.
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PMID:Structural aspects of proton-pumping ATPases. 197 Jun 43

The three beta subunits of the isolated Escherichia coli F1-ATPase react independently with chemical reagents (Stan-Lotter, H. and Bragg, P.D. (1986) Arch. Biochem. Biophys. 284, 116-120). Thus, one beta subunit is readily cross-linked to the epsilon subunit, Another reacts with N,N'-dicyclohexylcarbodiimide (DCCD), and the third one is modified on a lysine residue by 4-chloro-7-nitrobenzofurazan (NbfCl). The binding site for the ATP analog, 2-azido-ATP, was not associated with a specific type of beta subunit (Bragg, P.D. and Hou, C. (1989) Biochim. Biophys. Acta 974, 24-29). We now show that this binding site is a catalytic site as opposed to a noncatalytic nucleotide-binding site. NbfCl reacted with a tyrosine residue on the DCCD-reacting beta subunit in contrast to the different subunit location of the lysine residue labeled by the reagent. Thus, O to N transfer of the Nbf group in the free F1-ATPase involves transfer between subunits. The chemical labelling pattern of membrane-bound F1-ATPase differed from that of free F1. The strict asymmetry of labeling of the free F1-ATPase was not observed. Thus, double labeling of beta subunits by several reagents was found. This suggests that the asymmetry was not induced by chemical modification, but is inherent in the structure of the ATPase.
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PMID:Reaction of membrane-bound F1-adenosine triphosphatase of Escherichia coli with chemical ligands and the asymmetry of beta subunits. 213 13

The mechanism whereby tertiary amine local anesthetics affect the activity of membrane proteins was investigated by studying the interaction of phenothiazines with mitochondrial ATP synthase. These drugs caused inhibition of the activity of the membrane-bound enzyme at concentrations that do not perturb the phospholipid bilayer. The inhibitory effect appeared consequent to interaction with multiple sites located on both the F1 and the F0 components of the enzyme complex, since: (a) Dixon plots were parabolic; (b) the membrane-bound enzyme was more sensitive to the drug effect than the isolated F1 component; (c) conditions that decreased oligomycin sensitivity also decreased the sensitivity to phenothiazines; (d) irreversible binding of photochemically activated phenothiazines to the ATP synthase complex, followed by detachment of the F1 moiety and reconstitution with purified F1 resulted in an inhibited enzyme complex. These data are interpreted as indicating that tertiary amine local anesthetics affect the activity of membrane proteins by interacting with hydrophobic sites located on both their integral and peripheral domains.
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PMID:Mechanism of local anesthetic effect. Involvement of F0 in the inhibition of mitochondrial ATP synthase by phenothiazines. 213 14

Thermodynamic properties of 12 different F1-ATPase enzymes were analyzed in order to gain insights into the catalytic mechanism and the nature of energy coupling to delta mu H+. The enzymes were normal soluble Escherichia coli F1, a group of nine beta-subunit mutant soluble E. coli F1 enzymes (G142S, K155Q, K155E, E181Q, E192Q, M209I, D242N, D242V, R246C), and both soluble and membrane-bound bovine heart mitochondrial F1. Unisite activity was studied by use of Gibbs free energy diagrams, difference energy diagrams, and derivation of linear free energy relationships. This allowed construction of binding energy diagrams for both the unisite ATP hydrolysis and ATP synthesis reaction pathways, which were in agreement. The binding energy diagrams showed that the step of Pi binding is a major energy-requiring step in ATP synthesis, as is the step of ATP release. It is suggested that there are two major catalytic enzyme conformations, and ATP- and an ADP-binding conformation. The effects of the mutations on the rate-limiting steps of multisite as compared to unisite activity were correlated, suggesting a direct link between the rate-limiting steps of the two types of activity. Multisite activity was analyzed by Arrhenius plots and by study of relative promotion from unisite to multisite rate. Changes in binding energy due to mutation were seen to have direct effects on multisite catalysis. From all the data, a model is derived to describe the mechanism of ATP synthesis. ATP hydrolysis, and energy coupling to delta mu H+ in F1F0-ATPases.
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PMID:Thermodynamic analyses of the catalytic pathway of F1-ATPase from Escherichia coli. Implications regarding the nature of energy coupling by F1-ATPases. 213 23

An ATPase from anaerobic Lactobacillus casei has been isolated and 100-times purified. The 400 kDa enzyme molecule was found to have a hexagonal structure 10 nm in diameter composed of at least six protein masses. SDS-electrophoresis reveals four or, under certain conditions, five types of subunit, of apparent molecular masses 57 (alpha), 55 (beta), 40 (gamma), 22 (delta) and 14 (epsilon) kDa with stoichiometry of 3 alpha, 3 beta, gamma, delta, epsilon. The following features resembling F1-ATPases from other sources were found to be inherent in the solubilized L. casei ATPase. (i) Detachment from the membrane desensitizes ATPase to low DCCD concentrations and sensitizes it to water-soluble carbodiimide. (ii) Soluble ATPase is inhibited by Nbf chloride and azide, is resistant to SH-modifiers and is activated by sulfite and octyl glucoside, the activating effect being much stronger than in the case of the membrane-bound ATPase. Substrate specificity of the enzyme is also similar to that of other factors F1. Divalent cations strongly activate the soluble enzyme when added at a concentration equal to that of ATP. An excess of Mn2+, Mg2+ or Co2+ inhibits ATPase activity of F1, whereas that of Ca2+ induces its further activation. No other F1-like ATPases are found in L. casei. It is concluded that this anaerobic bacterium possesses a typical F1-ATPase similar to those in mitochondria, chloroplasts, aerobic and photosynthetic eubacteria.
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PMID:The F1-type ATPase in anaerobic Lactobacillus casei. 213 82

1. The kinetic characteristics of the ATP hydrolysis by membrane-bound and Triton X-100 solubilized mitochondrial ATPase, during the isoproterenol-induced cardiomyopathy, were investigated. 2. An increase in the inhibitory action of the oligomycin, a decrease in the affinity of the ATP binding sites and an increase of both activation energy and rate of thermal inactivation were observed for mitochondrial ATPase. 3. The possibility that the changes described are related to the modifications of the active configuration of mitochondrial ATPase, during the isoproterenol-induced cardiomyopathy, is discussed.
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PMID:Kinetic properties of mitochondrial ATPase during isoproterenol-induced cardiomyopathy. 214 51

Oligomycin sensitivity-conferring protein (OSCP) is a water-soluble subunit of bovine heart mitochondrial H(+)-ATPase (F1-F0). In order to investigate the requirement of OSCP for passive proton conductance through mitochondrial F0, OSCP-depleted membrane preparations were obtained by extracting purified F1-F0 complexes with 4.0 M urea. The residual complexes, referred to as UF0, were found to be deficient with respect to OSCP, as well as alpha, beta, and gamma subunits of F1-ATPase, but had a full complement of coupling factor 6 as judged by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and Western blotting techniques. These UF0 complexes had no intrinsic ATPase activity and were able to bind nearly the same amount of F1-ATPase in the presence of either OSCP or NH4+ ions alone, or a combination of the two. However, the preparations exhibited an absolute dependency on OSCP for conferral of oligomycin sensitivity to membrane-bound ATPase. The passive proton conductance in UF0 proteoliposomes was measured by time-resolved quenching of 9-amino-6-chloro-2-methoxyacridine or 9-aminoacridine fluorescence following a valinomycin-induced K(+)-diffusion potential. The data clearly establish that OSCP is not a necessary component of the F0 proton channel nor is its presence required for conductance blockage by the inhibitors oligomycin or dicyclohexylcarbodiimide. Furthermore, OSCP does not prevent or block passive H+ leakage. Comparisons of OSCP with the F1-F0 subunits from Escherichia coli and chloroplast lead us to suggest that mitochondrial OSCP is, both structurally and functionally, a hybrid between the beta and delta subunits of the prokaryotic systems.
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PMID:ATP synthase complex from bovine heart mitochondria. Passive H+ conduction through F0 does not require oligomycin sensitivity-conferring protein. 215 6

The structural relationship of the catalytic portion (ECF1) of the Escherichia coli F1F0 ATP synthase (ECF1F0) to the intact, membrane-bound complex has been determined by cryoelectron microscopy and image analysis of single, unordered particles. ECF1F0, reconstituted into membrane structures, has been preserved and examined in its native state in a layer of amorphous ice. Side views of the ECF1F0 show the same elongated bilobed and trilobed projection of the ECF1 views shown previously to be normal to the hexagonal projection. The elongated aqueous cavity of the ECF1 is perpendicular to the membrane bilayer profile in the bilobed view. ECF1 is separated from the membrane-embedded F0 by a narrow stalk approximately 40 A long and approximately 25-30 A thick. The F0 part extends from the lipid bilayer by approximately 10 A on the side facing the ECF1. There is no clear extension of the protein on the opposite side of the membrane.
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PMID:Structure of the ATP synthase complex (ECF1F0) of Escherichia coli from cryoelectron microscopy. 220 May 6

Twenty-one hybridoma cell lines which secret antibodies to the subunits of the Escherichia coli F1-ATPase were produced. Included within the set are four antibodies which are specific for alpha, six for beta, three for gamma, four for delta and four for epsilon. The antibodies were divided into binding competition subgroups. Two such competition subgroups are represented for the alpha, beta, and epsilon subunits, one for delta and three for gamma. The ability to bind intact F1-ATPase was demonstrated for some of the antibodies to alpha and beta, and for all of those to delta, while the antibodies to gamma and epsilon gave unclear results. All of the antibodies to alpha and beta which bound ATPase were found to have effects on the ATPase activity of purified E. coli F1-ATPase. One of those to alpha inhibited activity by about 30%. Another anti-alpha was mildly stimulatory. The four antibodies to beta which bound ATPase inhibited activity by 90%. In contrast, membrane-bound ATPase was hardly affected by the antibodies to alpha, but was inhibited by 40-60% by the antibodies to beta. The other antibodies to alpha and beta bound only free subunits, or partially dissociated ATPase, suggesting that their epitopes are buried between subunits in ATPase. These antibodies had no effects on activity. The ability of the antibodies to recognize ATPase subunits present in crude extracts from mitochondria, chloroplasts, and a variety of bacteria was tested using nitrocellulose blots of sodium dodecyl sulfate-polyacrylamide gels. One anti-beta specifically recognized proteins in the range of 50,000-60,000 daltons in each of the extracts, although the reaction with mitochondrial beta was weak. Some of the other antibodies had limited cross-reaction, but most were specific for the E. coli protein. In some species, those proteins which were recognized by the anti-beta ran with a higher apparent molecular weight than proteins which were recognized by an anti-alpha. All antibodies which exhibited cross-reactivity were found to recognize sites which were not exposed in intact ATPase, implying that the surfaces which lie between subunits are most highly conserved.
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PMID:Monoclonal antibodies to Escherichia coli F1-ATPase. Correlation of binding site location with interspecies cross-reactivity and effects on enzyme activity. 241 24

After the proposal of the chemiosmotic theory by Mitchell (1966, 1979) it has been recognized that different membrane-bound enzymes are able to use the energy derived from ionic gradients for the synthesis of ATP. These include the F1-ATPases of mitochondria and chloroplasts, the Ca2+-dependent ATPase of sarcoplasmic reticulum and the (Na+,K+)-ATPase of plasma membrane. In these systems the process of energy transduction is fully reversible. The enzyme can use the energy derived from the hydrolysis of ATP to build up a concentration gradient of ions across the membrane and, in the reverse process, use the energy derived from the gradient to synthesize ATP. Another interesting system in which these forms of energy are interconverted is found in photosynthetic bacteria. In chromatophores of Rhodospirillum rubrum there is a membrane-bound pyrophosphatase that, like the transport ATPases, catalyses the synthesis of pyrophosphate from Pi when a light-dependent proton gradient is formed across the chromatophore membrane. Like F1-ATPase, this enzyme is also able to generate an electrochemical potential gradient of protons at the expense of pyrophosphate hydrolysis. The mechanism by which the energy derived from a gradient is used by membrane-bound enzymes to catalyse the synthesis of high-energy phosphate compounds is still far from understood. Among the different enzymes studied, Ca2+-dependent ATPase is probably the system in which most is known about the mechanism of energy transduction. We now know of experimental conditions which allow us to move the different intermediary steps of the catalytic cycle of the enzyme in the direction of ATP synthesis. Thus, ATP synthesis can be attained after a single catalytic cycle in the absence of a transmembrane Ca2+ gradient. The net synthesis of ATP can be promoted by a variety of perturbations, including Ca2+, pH and water activity. These experiments indicate that during the catalytic cycle different forms of energy are interconverted by the Ca2+-dependent ATPase. The ultimate step of the cycle seems to be a change of water activity within the catalytic site of the ATPase. A common feature of all membrane-bound enzymes mentioned above is that during the catalytic cycle there are steps in which the hydrolysis of a phosphate compound (ATP, pyrophosphate or an acyl phosphate residue) is accompanied by only a small change in free energy. In conditions similar to those found in the cytosol, the hydrolysis of these phosphate compounds is accompanied by a much larger change in free energy.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Role of water in processes of energy transduction: Ca2+-transport ATPase and inorganic pyrophosphatase. 242 74

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