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)

The beta-subunit of the mitochondrial ATP synthase complex comprises the bulk, if not all, of the catalytic nucleotide binding site on the enzyme. A region of homologous sequence rich in glycines (G) and containing a basic lysine (K) and a threonine (T) is found in the beta-subunit as well as many other purine nucleotide binding proteins. The consensus sequence of this region is Gx4GKT, where x represents any amino acid, and is called the A region or glycine-rich loop. The related function of these proteins implies that the glycine-rich loop is directly involved in nucleotide binding. Here we directly test the involvement of the beta-subunit's glycine-rich region in adenine nucleotide binding using two independent approaches. A synthetic fifty amino acid peptide, PP-50, containing the glycine-rich region and the surrounding sequence was assessed for secondary structure and interaction with potential ligands. Circular dichroism spectropolarimetry indicates that PP-50 assumes a predominantly beta-sheet conformation in solution. Significantly, the peptide precipitates from solution when ATP, ADP, GTP, ITP, and pyrophosphate are added, but not when AMP or phosphate are included. Magnesium is not required for the interaction with the purine nucleotides. Complimentary to these studies, the sequence around the Gx4GKT motif was deleted from a recombinant rat liver beta-subunit overexpressed in E. coli. While the wild type beta-subunit showed specificity for the tri- and diphosphonucleotides, the deletion mutant bound tri-, di-, and monophosphate nucleotides with equal affinity.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Mitochondrial F-type ATPases: the glycine-rich loop of the beta-subunit is a pyrophosphate binding domain. 133 55

We have seen that there is no simple answer to the question 'what controls respiration?' The answer varies with (a) the size of the system examined (mitochondria, cell or organ), (b) the conditions (rate of ATP use, level of hormonal stimulation), and (c) the particular organ examined. Of the various theories of control of respiration outlined in the introduction the ideas of Chance & Williams (1955, 1956) give the basic mechanism of how respiration is regulated. Increased ATP usage can cause increased respiration and ATP synthesis by mass action in all the main tissues. Superimposed on this basic mechanism is calcium control of matrix dehydrogenases (at least in heart and liver), and possibly also of the respiratory chain (at least in liver) and ATP synthase (at least in heart). In many tissues calcium also stimulates ATP usage directly; thus calcium may stimulate energy metabolism at (at least) four possible sites, the importance of each regulation varying with tissue. Regulation of multiple sites may occur (from a teleological point of view) because: (a) energy metabolism is branched and thus proportionate regulation of branches is required in order to maintain constant fluxes to branches (e.g. to proton leak or different ATP uses); and/or (b) control over fluxes is shared by a number of reactions, so that large increases in flux requires stimulation at multiple sites because each site has relatively little control. Control may be distributed throughout energy metabolism, possibly due to the necessity of minimizing cell protein levels (see Brown, 1991). The idea that energy metabolism is regulated by energy charge (as proposed by Atkinson, 1968, 1977) is misleading in mammals. Neither mitochondrial ATP synthesis nor cellular ATP usage is a unique function of energy charge as AMP is not a significant regulator (see for example Erecinska et al., 1977). The near-equilibrium hypothesis of Klingenberg (1961) and Erecinska & Wilson (1982) is partially correct in that oxidative phosphorylation is often close to equilibrium (apart from cytochrome oxidase) and as a consequence respiration and ATP synthesis are mainly regulated by (a) the phosphorylation potential, and (b) the NADH/NAD+ ratio. However, oxidative phosphorylation is not always close to equilibrium, at least in isolated mitochondria, and relative proximity to equilibrium does not prevent the respiratory chain, the proton leak, the ATP synthase and ANC having significant control over the fluxes. Thus in some conditions respiration rate correlates better with [ADP] than with phosphorylation potential, and may be relatively insensitive to mitochondrial NADH/NAD+ ratio.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Control of respiration and ATP synthesis in mammalian mitochondria and cells. 159 89

The rate of trypsin cleavage of the epsilon subunit of Escherichia coli F1 (ECF1) has been found to be ligand-dependent, as measured indirectly by the activation of the enzyme that occurs on protease digestion, or when followed directly by monitoring the cleavage of this subunit using monoclonal antibodies. The cleavage of the epsilon subunit was fast in the presence of ADP alone, ADP + MG2+, ATP + EDTA, or AMP-PNP, but slow when Pi was added along with ADP + Mg2+ or when ATP + Mg2+ was added to generate ADP + Pi (+Mg2+) in the catalytic site(s). The half-maximal concentration of Pi required in the presence of ADP + Mg2+ to protect the epsilon subunit from cleavage by trypsin was 50 microM, which is in the range measured for the high-affinity binding of Pi to F1. The ligand-dependent conformational changes in the epsilon subunit were also examined in cross-linking experiments using the water-soluble carbodiimide 1-ethyl-3-[3-(dimethylamino)propyl]carbodiimide (EDC). In the presence of ATP + Mg2+ or ADP + Mg2+ + Pi, the epsilon subunit cross-linked to beta in high yield. With ATP + EDTA or ADP + Mg2+ (no Pi), the yield of the beta-epsilon cross-linked product was much reduced. We conclude that the epsilon subunit undergoes a conformational change dependent on the presence of Pi. It has been found previously that binding of the epsilon subunit to ECF1 inhibits ATPase activity by decreasing the off rate of Pi [Dunn, S. D., Zadorozny, V. D., Tozer, R. G., & Orr, L. E. (1987) Biochemistry 26, 4488-4493]. This reciprocal relationship between Pi binding and epsilon-subunit conformation has important implications for energy transduction by the E. coli ATP synthase.
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PMID:Catalytic site nucleotide and inorganic phosphate dependence of the conformation of the epsilon subunit in Escherichia coli adenosinetriphosphatase. 182 19

Nucleotide-depleted mitochondrial F1-ATPase (F1[0,0]) is inhibited by the diadenosine oligophosphate compounds, AP4A, AP5A, and AP6A (where APxA stands for 5',5'-diadenosine oligophosphates having a chain of x phosphoryl groups linking the two adenosine moieties). When F1[0,0] is preincubated with these compounds and then assayed for ATP hydrolysis activity under conditions that normally allow turnover at all three catalytic sites, the maximal level of inhibition observed is 80%. However, when assayed at lower ATP concentrations under conditions that allow simultaneous turnover at only two of the three sites, no inhibition is observed. A decrease in the number of phosphoryl groups that links the adenosine moieties to less than 4 (AP3A, AP2A) converts the compound to an activator of ATP hydrolysis, similar in effect to that obtained when one mol of ADP or 2-azido-ADP binds at a catalytic site on F1[0,0]. Inhibition by the compounds requires the presence of at least one vacant noncatalytic site. Evidence is provided that the probes also interact with a catalytic site. The stoichiometry for maximal inhibition by AP4A is 0.94 mol/mol of F1. The data presented support a model for the structure of nucleotide-binding sites on F1 that places catalytic and noncatalytic sites in close proximity in an orientation analogous to the ATP and AMP binding sites on adenylate kinase. Inhibition of the enzyme by the dinucleotide compounds can be explained by the cross-bridging of one of the catalytic sites to a noncatalytic site in analogy to the inhibition of adenylate kinase by AP5A. The residual capacity for bi-site catalysis indicates that the second and third catalytic sites remain catalytically active.
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PMID:Adenine nucleotide-binding sites on mitochondrial F1-ATPase. Evidence for an adenylate kinase-like orientation of catalytic and noncatalytic sites. 182 4

The beta subunit isolated from the chloroplast ATP synthase F1 (CF1) has a single dissociable nucleotide binding site, consistent with the proposed function of this subunit in nucleotide binding and catalysis. The beta subunit bound the nucleotide analogs trinitrophenyl-ATP (TNP-ATP) or trinitrophenyl-ADP (TNP-ADP) with nearly equal affinities (Kd = 1-2 microM) but did not bind trinitrophenyl-AMP. Both ATP and ADP effectively competed with TNP-ATP for binding. Other nucleoside triphosphates were also able to compete with TNP-ATP for binding to beta; their order of effectiveness (ATP greater than GTP, ITP greater than CTP) mimicked the normal substrate specificity of CF1. The single nucleotide binding site on the isolated beta subunit very closely resembles the low affinity catalytic site (site 3) of CF1 (Bruist, M.F., and Hammes, G. G. (1981) Biochemistry 20, 6298-6305), suggesting that tight nucleotide binding by other sites on the enzyme involves other CF1 subunits in addition to the beta subunit. The results are inconsistent with an earlier report (Frasch, W.D., Green, J., Caguial, J., and Mejia, A. (1989) J. Biol. Chem. 264, 5064-5069), which suggested more than one nucleotide binding site per beta subunit. Binding of nucleotides to the isolated beta subunit was eliminated by a brief heat treatment (40 degrees C for 10 min) of the protein. A small change in the circular dichroism spectrum of beta accompanied the heat treatment indicating that a localized (rather than global) change in the folding of beta, involving at least part of the nucleotide binding domain, had occurred. Also accompanying the loss of nucleotide binding was a loss of the reconstitutive capacity of the beta subunit. ATP protected against the effects of the heat treatment.
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PMID:Nucleotide binding to the isolated beta subunit of the chloroplast ATP synthase. 182 6

The metabolic changes associated with the sudden onset of ischemia caused by occlusion of a major coronary artery include (a) cessation of aerobic metabolism, (b) depletion of creatine phosphate (CP), (c) onset of anaerobic glycolysis, and (d) accumulation of glycolytic products, such as lactate and alpha glycerol phosphate (alpha GP), and catabolites of the nucleotide pools in the tissue. These changes are associated with contractile failure and electrocardiographic alterations. Since the demand of the myocardium for high-energy phosphate (approximately P) exceeds the available supply, the net amount of ATP in tissue decreases. Eighty percent of the supply of approximately P utilized by severely ischemic tissue comes from anaerobic glycolysis using glycogen as the principal substrate. Early in ischemia, contractile activity utilizes ATP, but much of the continuing utilization of ATP by the ischemic tissue is energy wasted via the mitochondrial ATPase. A lesser quantity of ATP is used by ion transport ATPases. Metabolic changes slow as the duration of ischemia increases. Irreversibly injured myocytes exhibit (a) very low levels of ATP (less than 10% of control); (b) cessation of anaerobic glycolysis; (c) high levels of H+, AMP, INO, lactate, and alpha GP; (d) a greatly increased osmolar load; (e) mitochondrial swelling and formation of amorphous matrix densities; and (f) disruption of the sarcolemma. The latter event is generally recognized as lethal, but its pathogenesis remains to be established. Most severely ischemic myocytes are dead in regional ischemia in the anesthetized open-chest dog heart after only 60 minutes of ischemia. Less severely ischemic myocytes in the mid- and subepicardial myocardium survive for as long as six hours. Virtually all myocytes destined to die in a zone of ischemia are irreversibly injured after six hours of ischemia have passed. Certain changes exhibited by myocytes injured by severe ischemia and reperfused late in the reversible phase of injury do not return to the control conditions for a period of days, while others rebound in only seconds to minutes. The adenine nucleotide pool still is not fully restored after four days of reperfusion. Stunning disappears after one to two days of reflow. The preconditioning effect is partially lost after two hours of reperfusion. The timing of its disappearance has not been fully established. Aerobic metabolism is restored after only a few minutes of reperfusion. Thus, reperfusion salvages injured myocardium and restores its structure and function to the control state at a variable rate.
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PMID:The cell biology of acute myocardial ischemia. 203 69

In the present communication, the activity of 24 oxidoreductases, transferases, isomerases and hydrolases was examined histochemically in ragged-red fibres of human skeletal muscle specimens. The biopsy material was obtained from patients with neuromuscular diseases caused by an abnormally metabolic functioning of the muscle mitochondria. The granular accumulations of the ragged-red fibres were characterized by an impressive activity of all mitochondrial and most non-mitochondrial enzymes examined, whether participating in the aerobic or in the anaerobic pathways. With the exception of mitochondrial Mg2(+)-stimulated ATPase, acid phosphatase and AMP-aminohydrolase, there was no activity of the other hydrolytic enzymes studied in these regions. The strong activity of mitochondrial ATPase points to the presence of loosely coupled and/or uncoupled mitochondria. Ragged-red fibres that exhibited a diffuse and corpuscular activity of acid phosphatase, were always undergoing necrotic changes. Adsorption studies with diluted enzyme solutions demonstrated that the granular accumulations display a specific, moderate affinity for glycolytic enzymes.
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PMID:Histochemical features of ragged-red fibres in diseased skeletal muscles. 208 41

The F1 moiety of the rat liver mitochondrial ATP synthase/ATPase complex contains as isolated 2 mol Mg2+/mol F1, 1 mol of which is nonexchangeable and the other which is exchangeable (N. Williams, J. Hullihen, and P.L. Pedersen, (1987) Biochemistry 26, 162-169). In addition, the enzyme binds 1 mol ADP/mol F1 and 3 mol AMP.PNP, the latter of which can bind in complex formation with divalent cation and displace the Mg2+ at the exchangeable site. Thus, in terms of ligand binding sites the fully loaded rat liver F1 complex contains 3 mol MgAMP.PNP, 1 mol ADP, and 1 mol Mg2+. In this study we have used several metal ATP complexes or analogs thereof to gain further insight into the ligand binding domains of rat liver F1 and the mechanism by which it catalyzes ATP hydrolysis in soluble and membrane bound form. Studies with LaATP confirmed that MgATP is the most likely substrate for rat liver F1, and provided evidence that the enzyme may contain additional Mg2+ binding sites, undetected in previous studies of F1-ATPases, that are required for catalytic activity. Thus, F1 containing the thermodynamically stable LaATP complex in place of MgATP requires added Mg2+ to induce ATP hydrolysis. As Mg2+ cannot readily displace La2+ under these conditions there appears to be a catalytically important class of Mg2+ binding sites on rat liver F1, distinct from the nonexchangeable Mg2+ site and the sites involved in binding MgATP. Additional studies carried out with exchange inert metal-nucleotide complexes involving rhodium and the Mg2+ and Cd2+ complexes of ATP beta S and ATP alpha S imply that the rate-limiting step in the ATPase reaction pathway occurs subsequent to the P gamma-O-P beta bond cleavage steps, perhaps at the level of Mg(ADP)(Pi) hydrolysis or MgADP release. Evidence is presented that Mg2+ remains coordinated to the leaving group of the reaction, i.e., the beta phosphoryl group. Finally, in contrast to soluble F1, F1 bound to F0 in the inner mitochondrial membrane failed to discriminate between the Mg2+ complexes of the ATP beta S isomers. This indicates that a fundamental difference may exist between the catalytic or kinetic mechanism of F1 and the more physiologically intact F0F1 complex.
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PMID:Investigation of the substrate structure and metal cofactor requirements of the rat liver mitochondrial ATP synthase/ATPase complex. 252 40

4-Azido-2-nitrophenyl pyrophosphate (azido-PPi) labeled with 32P in the alpha position was prepared and used to photolabel beef heart mitochondrial F1. Azido-PPi was hydrolyzed by yeast inorganic pyrophosphatase, but not by mitochondrial F1-ATPase. Incubation of F1 with [alpha-32P]azido-PPi in the dark under conditions of saturation resulted in the binding of the photoprobe to three sites, two of which exhibited a high affinity (Kd = 2 microM), the third one having a lower affinity (Kd = 300 microM). Mg2+ was required for binding. As with PPi [Issartel et al. (1987) J. Biol. Chem. 262, 13538-13544], the binding of 3 mol of azido-PPi/mol of F1 resulted in the release of one tightly bound nucleotide. ADP, AMP-PNP, and PPi competed with azido-PPi for binding to F1, but Pi and the phosphate analogue azidonitrophenyl phosphate did not. The binding of [32P]Pi to F1 was enhanced at low concentrations of azido-PPi, as it was in the presence of low concentrations of PPi. Sulfite, which is thought to bind to an anion-binding site on F1, inhibited competitively the binding of both ADP and azido-PPi, suggesting that the postulated anion-binding site of F1 is related to the exchangeable nucleotide-binding sites. Upon photoirradiation of F1 in the presence of [alpha-32P]azido-PPi, the photoprobe became covalently bound with concomitant inactivation of F1. The plots relating the inactivation of F1 to the covalent binding of the probe were rectilinear up to 50% inactivation.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Synthesis and properties of azidonitrophenyl pyrophosphate, a photoaffinity probe of the nucleotide binding sites of mitochondrial F1-ATPase. 255 70

A mathematical procedure is presented which permits to calculate the steady-state concentrations of AMP, ADP and ATP in an ATP-regenerating assay containing pyruvate kinase and lactate dehydrogenase as auxiliary enzymes. The accuracy of this procedure is demonstrated by the agreement of the calculated concentrations with the experimental data obtained in measurements of mitochondrial ATPase activities. The computer-assisted procedure can be employed (a) to determine extremely low adenine nucleotide concentrations which are difficult to obtain by direct measurements and (b) to adjust and to optimize the assay conditions according to the specific requirements of the experiment, including high concentrations of ATP and prescribed ATP/ADP ratios.
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PMID:A computer assisted method to control the steady state of an ATP-regenerating assay. 275 34

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