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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)

Fructose 2,6-bisphosphate (F-2,6-P2) stimulated glycolysis in cell-free extracts of both normal and ras-transfected rat-1 fibroblasts. The extract of the transformed cell glycolyzed more rapidly in both the absence and the presence of F-2,6-P2 than the extract of the parent fibroblast. Addition of mitochondrial ATPase (F1) or inorganic phosphate (Pi) further stimulated lactate production in both cell lines. F-2,6-P2 stimulated the 6-phosphofructo-1-kinase (PFK-1) activity in extracts of normal and transfected cells. The activity in extracts of transformed cells tested with a fructose 6-phosphate regenerating system was considerably higher than in the extract of normal cells. Stimulation of PFK-1 activity by cAMP of both cell lines was not as pronounced as that by F-2,6-P2. In the absence of F-2,6-P2 the PFK-1 activity was strongly inhibited in the transformed cell by ATP concentrations higher than 1 mM, whereas in the normal cell only a marginal inhibition was noted even at 2 or 3 mM ATP. F-2,6-P2 reversed the inhibition of PFK-1 by ATP. Nicotinamide adenine dinucleotide (NAD) at 100 microM (in the presence of 2 mM ATP and 1 microM F-2,6-P2) stimulated PFK-1 activity only in the transformed cell, whereas nicotinamide adenine dinucleotide phosphate (NADP) inhibited PFK-1 activity (in the presence or absence of 1 microM F-2,6-P2) in extracts of both cell lines. No previous observations of stimulation or inhibition by NAD or NADP on PFK-1 activity appear to have been reported. A threefold increase in the intracellular concentration of F-2,6-P2 was observed after transfection of rat-1 fibroblast by the ras oncogene. We conclude from these data that the PFK-1 activity of ras-transfected rat-1 fibroblasts shows a greater response to certain stimulating and inhibitory regulating factors than that of the parent cell.
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PMID:Regulation of 6-phosphofructo-1-kinase activity in ras-transformed rat-1 fibroblasts. 183 35

Beef-heart mitochondrial F1-ATPase contained 5 mol of inorganic phosphate bound per mol of F1, following pretreatment with ATP. A portion of the phosphate, bound most likely at a catalytic site, reacted in dimethylsulfoxide with endogenous adenine nucleotide to form ATP.
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PMID:Beef-heart mitochondrial F1-ATPase can use endogenous bound phosphate to synthesize ATP in dimethyl sulfoxide. 183 82

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

The reaction of mitochondrial F1-ATPase with immobilized substrate was studied by using columns of agarose-hexane-ATP. Mg2+ was required for binding of the enzyme to the column matrix. The column-bound enzyme could be eluted fully by ATP and other nucleoside triphosphates. Nucleoside di- and mono-phosphates were less effective. At a fixed concentration of nucleotide the effectiveness of elution was proportional to the charge on the eluting molecule. The ATP of the column matrix was hydrolysed by the bound F1-ATPase to release phosphate, probably by a uni-site reaction mechanism. Thus the F1-ATPase was bound to the immobilized ATP by a catalytic site. Treatment of the bound F1-ATPase with 4-chloro-7-nitrobenzofurazan prevented complete release of the enzyme by ATP. Only one-third of the bound enzyme was now eluted by the nucleotide. The inhibition of release could be due either to the inhibitor blocking co-operative interactions between sites or to its increasing the tightness of binding of immobilized ADP at the catalytic site.
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PMID:Interaction of ox heart mitochondrial F1-ATPase with immobilized ADP and ATP. 213 26

The membrane topology of subunit alpha from the Escherichia coli F1F0-ATP synthase was studied using a gene fusion technique. Fusion proteins linking different amino-terminal fragments of the alpha subunit with an enzymatically active fragment of alkaline phosphatase were constructed by both random transposition of TnphoA and site-directed mutagenesis. Those proteins with high levels of alkaline phosphatase activity are predicted to define periplasmic domains of alpha, and this was confirmed by testing for cell growth in minimal medium supplemented with polyphosphate (P greater than 75) as the sole source of phosphate. The enzymatic activity of some fusion proteins was shown to be sensitive to glucose present in the growth medium. Results from subcellular fractionation experiments suggest that these fusion proteins may be inactive even though they have a periplasmic alkaline phosphatase. The enzymatic activity appears dependent upon proteolytic release of the alkaline phosphatase moiety from its alpha subunit membrane anchor and suggests the target of glucose repression may be a protease present in the periplasm. For the topological analysis of the alpha subunit, a total of 28 unique fusion proteins were studied and the results were consistent with a model of alpha containing eight transmembrane segments, including periplasmic amino and carboxyl termini. Surprisingly, separate periplasmic domains were identified near amino acids 200, 233, and 270. These results suggest the flanking membrane spans are only 10-15 amino acids in length and not able to span a standard 30 A bilayer in an alpha-helical conformation. These short spans may have interesting mechanistic implications for the function of F0, because they contain several amino acids which appear critical for proton translocation. Finally, a fusion of alkaline phosphatase at amino acid 271, the carboxyl-terminal residue, but not at amino acid 260, was able to complement the strain RH305 (uncB-) for growth on succinate and suggests the last 11 amino acids of the alpha subunit are critical to the function of F1F0-ATP synthase.
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PMID:A topological analysis of subunit alpha from Escherichia coli F1F0-ATP synthase predicts eight transmembrane segments. 216 53

After studying the effects of almitrine, a new kind of ATPase/ATP synthase inhibitor, on two kinds of isolated mammalian mitochondrion, we have observed that: (1) Almitrine inhibits oligomycin-sensitive ATPase; it decreases the ATP/O value of oxidative phosphorylations without any change in the magnitude of delta mu H+. (2) Almitrine increases the mechanistic H+/ATP stoichiometry of ATPase as shown by measuring either (i) the extent of potassium acetate and of potassium phosphate accumulation sustained by ATP utilisation, or (ii) the electrical charge/ATP (K+/ATP) ratio at steady-state of ATPase activity. (3) Rat liver mitochondria are at least 10-times more sensitive to almitrine than beef heart mitochondria. (4) The change in H+/ATP stoichiometry induced by almitrine depends on the magnitude of the flux through ATPase. The inhibitory effect of almitrine on ATPase/ATP synthase complex, as a consequence of such an H+/ATP stoichiometry change, is discussed.
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PMID:Flux-dependent increase in the stoichiometry of charge translocation by mitochondrial ATPase/ATP synthase induced by almitrine. 216 21

The process of ATP or GTP synthesis by bovine heart submitochondrial particles involves the binding of ADP or GDP to 3 exchangeable sites I, II, and III, and only upon substrate occupation of site III does rapid ATP or GTP synthesis take place. The dissociation constants determined for ADP were KADPI less than or equal to 10(-8) M, KADPII approximately 10(-7) M, and KADPIII (equivalent to apparent KADPm), approximately 3 x 10(-6) M in the low Km mode and KADPIII approximately 150 x 10(-6) M in the high Km mode. For GDP, these constants were KGDPI approximately 10(-6)-10(-5) M, KGDPII approximately 10(-4) M, and KGDPIII approximately 10(-3) M when NADH was the respiratory substrate (Matsuno-Yagi, A., and Hatefi, Y. (1990) J. Biol. Chem. 265, 82-88). Because of its low affinity for the above binding sites, GDP at micromolar concentrations does not lead to GTP synthesis. However, as shown in this paper, micromolar [GDP] undergoes phosphorylation in the presence of micromolar concentrations of ADP. Under these conditions, both ATP and GTP are synthesized. GDP inhibits ATP synthesis with KGDPi congruent to 7 microM, while ADP promotes GTP synthesis in a reaction that requires inorganic phosphate (apparent KPim = 2-3 mM) and is inhibited by uncouplers and inhibitors of the ATP synthase complex. The ADP-promoted GTP synthesis exhibited an "apparent" KGDPm = 4 microM and an "apparent" Vmax = 11 nmol of GTP (min.mg of protein)-1. These results were interpreted to mean that (a) micromolar [ADP] occupies sites I and II, allowing site III to bind and phosphorylate GDP, and (b) the KGDPm and Vmax calculated under these conditions represent values for the low Km-low Vmax mode of GTP synthesis, which in the absence of ADP is not detectable because of the positive cooperativity phase of GTP synthesis with the high KGDPII approximately 10(-4) M.
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PMID:Studies on the mechanism of oxidative phosphorylation. ADP promotion of GDP phosphorylation. 224 94

Oxidative phosphorylation can be treated as two groups of reactions; those that generate protonmotive force (dicarboxylate carrier, succinate dehydrogenase and the respiratory chain) and those that consume protonmotive force (adenine nucleotide and phosphate carriers. ATP synthase and proton leak). Mitochondria from hypothyroid rats have lower rates of respiration in the presence of ADP (state 3) than euthyroid controls. We show that the kinetics of the protonmotive-force generators are unchanged in mitochondria from hypothyroid animals, but the kinetics of the protonmotive-force consumers are altered, supporting proposals that the important effects of thyroid hormone on state 3 are on the ATP synthase or the adenine nucleotide translocator.
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PMID:Thyroid-hormone control of state-3 respiration in isolated rat liver mitochondria. 230 10

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

Palmitic acid and gramicidin D at low concentrations uncouple photophosphorylation in a mechanism that is inconsistent with classical uncoupling in the following properties: (1) delta pH, H+ uptake, or the transmembrane electric potential is not inhibited. (2) O2 evolution is stimulated under nonphosphorylating conditions but slightly inhibited in the presence of adenosine 5'-diphosphate + inorganic phosphate (Pi). (3) Light-triggered adenosine 5'-triphosphate (ATP)-Pi exchange is hardly affected, and ATPase activity is only slightly stimulated. (4) ATP-induced delta pH formation is selectively inhibited. This characteristic uncoupling is observed only when the native coupling sites of the electron transport system are used for energization such as for methylviologen-coupled phosphorylation. With pyocyanine, which creates an artificial coupling site, 1000-fold higher gramicidin D and higher palmitic acid concentrations are required for inhibition, and the inhibition is accompanied by a decrease in delta pH. Moreover, comparison between photosystem 1 and photosystem 2 electron transport and the effects of membrane unstacking suggest that low gramicidin D preferentially inhibits photosystem 2, while palmitic acid inhibits more effectively photosystem 1 coupling sites. The inhibitory capacity of fatty acids significantly drops when the chain length is reduced below 16 hydrocarbons or upon introduction of a single double bond in the hydrocarbon chain. It is suggested that palmitic acid and gramicidin D interfere with a direct H+ transfer between specific electron transport and the ATP synthase complexes, which provides an alternative coupling mechanism in parallel with bulk to bulk delta microH+. The sites of inhibition seem to be located in chloroplast ATP synthase, photosystem 2, and the cytochrome b6f complexes.
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PMID:Anomalous uncoupling of photophosphorylation by palmitic acid and by gramicidin D. 245 May 61


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