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Query: EC:3.6.1.3 (ATPase)
65,361 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

ATPase activity and ATP-induced energization of photosynthetic membranes from Rhodopseudomonas capsulata are stimulated by phosphate; the maximum stimulatory effect occurs at a concentration between 1 and 2 mM. The sensitivity of the ATPase to oligomycin increases in the presence of phosphate since all the Pi-stimulated activity is inhibited by this antibiotic. Aurovertin, which has no effect on ATPase in the absence of phosphate, inhibits completely the activity elicited by this anion. The addition of Pi induces a substantial increase in the V of ATPase activity without changing the affinity of the enzyme for ATP or ADP. Arsenate, at the same concentrations, produces effects very similar to those of phosphate. The stimulation by arsenate of the transfer of energy from ATP to the membrane suggests a non-hydrolytic role of this anion as a modifier of the ATPase activity.
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PMID:Energy transduction in photosynthetic bacteria. VIII. Activation of the energy-transducing ATPase by inorganic phosphate. 12 66

1. Like other energy-transducing membranes, chloroplast membranes bear a coupling ATPase with especially tight binding sites for adenine nucleotides. Membranes washed several times still contain 2.5 nmol ATP and 1.3 nmol ADP bound per mg chlorophyll, which is equivalent to 1.9 ATP and 1.0 ADP per coupling ATPase. 2. In de-energized membranes, these nucleotides exchange to only a limited extent with added nucleotides. In membranes illuminated in the presence of pyocyanine, however, complete exchange of the bound nucleotides occurs rapidly, irrespective of whether ATP or ADP is present in the medium. 3. Pi can exchange into these nucleotided at both the beta and gamma positions when the membranes are energized in the presence of Mg-2+. Equilibrium with the beta and gamma groups of th ebound nucleotides is, however, not complete. 4. The inhibitors and uncouplers Dio-9, S13 and EDTA have different effects on the exchange of nucleotides, the exchange of inorganic phosphate and photophosphorylation. 5. The bound ATP level on the membrane is stable to a wide variety of conditions. The ADP level, however, drops to near zero under conditions of maximal activation of the emmbrane ATPase.
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PMID:Tightly bound nucleotides of the energy-transducing ATPase of chloroplasts and their role in photophosphorylation. 12 85

Recent results suggest consideration of a new concept for oxidative phosphorylation in which a prime function of energy is to bring about release of ATP formed at the catalytic site by reversal of hydrolysis. Data with submitochondrial particles include properties of an uncoupler insensitive Pi=HOH exchange, a rapid reversible formation of bound ATP in presence of uncouplers, and predictable patterns of 32-Pi incorporation into ATP in rapid mixing experiments. ADP is confirmed as the primary Pi acceptor in mitochondrial ATP synthesis, but with chloroplasts ADP is also rapidly labeled. Other findings with pyrophosphatase and with transport ATPase harmonize with the new concept. Measurements of the reversal of ATP cleavage and binding by myosin suggest that oxygen exchanges result from reversible cleavage of ATP to ADP and Pi at the catalytic site and that the principal free energy change in ATP cleavage occurs in ATP binding. Reversal of conformational changes accompanying ATP binding and cleavage is proposed to drive the actin filament in contraction. Thus energy transductions linked to ATP in both mitochondria and muscle may occur primarily through protein conformational change.
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PMID:Coupling of "high-energy" phosphate bonds to energy transductions. 12 70

The demonstrated role of proton translocation and resulting electrochemical activity gradients (protonmotive force) in ATP synthesis by chloroplasts is noted. Evidence for the participation of conformational changes in the terminal ATPase (coupling factor, or CF1) is reviewed. Hydrogen exchange into ordinarily cyptic groups of the molecule occurs only when the subtending membranes are put under the stress of a protonmotive force. Since up to 100 hydrogen atoms per mole are involved in the energy-dependent exchange the conformational change permitting tham access to the medium must be a major one. Chemical reagents are beginning to be used to attack groups on CF1 that are exposed only when the membranes are energized. N-ethylmaleimide binds covalently, sulfate causes as yet unspecified damage, and permanganate leads to oxidative damage to CF1 under energized conditions. The last two reagents are analogues of phosphate, and ADP must be added for them to inhibit. On the basis of this and other differences between the conditions needed for inhibition by permanganate or sulfate, and that by N-ethylmaleimide or the hydrogen exchange, a somewhat complex scheme involving several successive or alternative conformations of CF1 can be postulated. Questions are raised as to the way in which a conformational change in a bound protein could be caused by a proton activity gradient across its supporting membrane, and as to whether the altered conformations might constitute a part of the energy transformations leading to ATP synthesis.
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PMID:Chloroplast membranes and coupling factor conformations. 12 71

The classical E2-P intermediate of (Na+ + K+)-ATPase dephosphorylates readily in the presence of K+ and is not affected by the addition of ADP. To determine the significance in the reaction cycle of (Na+ + K+)-ATPase of kinetically atypical phosphorylations of rat brain (Na+ + K+)-ATPase we compared these phosphorylated components with the classical E2-P intermediate of this enzyme by gel electrophoresis. When rat brain (Na+ + K+)-ATPase was phosphorylated in the presence of high concentrations of Na+ a proportion of the phosphorylated material formed was sensitive to ADP but resistant to K+. Similarly, if phosphorylation was carried out in the presence of Na+ and Ca-2+ up to 300 pmol/mg protein of a K+ -resistant, ADP-sensitive material were formed. If phosphorylation was from [gamma-32-P]CTP up to 800 pmol-32-P/mg protein of an ADP-resistant, K+ -sensitive phosphorylated material were formed. On gel electrophoresis these phosphorylated materials co-migrated with authentic Na+ -stimulated, K+ -sensitive, E2-P-phosphorylated intermediate of (Na+ + K+)-ATPase, supporting suggestions that they represent phosphorylated intermediates in the reaction sequence of this enzyme.
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PMID:Gel electrophoretic identity of the (Na+ + Mg-2+)- and (Na+ + Ca-2+)-stimulated phosphorylations of rat brain ATPase. 12 86

Membrane-bound ATPase (EC 3.6.1.3) of Escherichia coli K 12 is released in a soluble form by the mechanical treatments applied to the cells in order to break them. The purification of the soluble enzyme is described. The purified protein gives a single band in 7.5% polyacrylamide gel electrophoresis. The molecular weight is estimated to be 350 000. The enzyme is cold-labile, Mg-2+ dependent, insensitive to inhibition by N, N'-dicyclohexylcarbodiimide and specific for ATP and ADP. Membranes depleted of their ATPase activity by dilution in a buffer of low ionic strength and without Mg-2+ are able to incorporate the purified ATPase only in the presence of 2-6 mM Mg-2+. ATPase binds to particles formed by complementation between supernatant extracts of chl A and chl B mutants. There are three kinds of particles of different buoyant densities (1.10, 1.18 and 1.23); ATPase binds only to the 1.10 and 1.18 particles. The kinetics of incorporation have been studied. ATPase begins to be incorporated into the 1.10 particles after 10 min of incubation up to a maximum at 20 min: from 30 min, ATPase is incorporated only into 1.18 particles and the amount of incorporated ATPase increased in proportion with the peak of 1.18 particles. These kinetics have a hyperbolic pattern. In order to explain the mechanism of assembly involved in complementation, two hypotheses are proposed.
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PMID:Membrane reconstitution in chl-r mutants of Escherichia coli K 12. VII. Purification of the soluble ATPase of supernatant extracts and kinetics of incorporation into reconstituted particles. 12 90

Dephosphorylation of [32P]phosphoenzyme of bovine brain Na+,K+-stimulated ATP phosphohydrolase (EC 3.6.1.3), labelled by [gamma-32P]ATP, was investigated at 21 degrees C by means of a rapid-mixing technique. On addition of a high concentration of KCl (10 mM) to [32P]phosphoenzyme at steady state in the presence of Mg2+ and Na+, very rapid dephosphorylation was obtained. Simultaneously, the amount of [32P]orthophosphate increased at about the same rate. It was concluded that this K+-stimulated dephosphorylation and liberation of [32P]orthophosphate from the [32P]phosphoenzyme was rapid enough to participate in the Na+,K+-stimulated hydrolysis of ATP. In order to study the dephosphorylation in absence of continuing 32P-labelling, excess unlabelled ATP or a chelator of Mg2+ was added. Simultaneous addition of a high concentration of KCl to the [32P]phosphoenzyme formed in the presence of Mg2+ and Na+ but in the absence of K+, resulted in an initial very rapid phase and a subsequent slower phase of dephosphorylation. With KCl also initially present in the incubation medium, only the slow phase was observed. The slow phase of dephosphorylation also seemed to be sufficiently rapid to participate in the Na+, K+-stimulated ATPase reaction. On addition of a high concentration of ADP (5 mM) to [32P]phosphoenzyme formed in the presence of Mg2+ and Na+, an initial comparatively rapid, and later slow phase of dephosphorylation were detected. This gave further support for different forms of phosphoenzyme. Approximate concentrations of these forms, in the absence and presence of KCl, were estimated by extrapolation and the turnover of these forms was calculated. The nature of the kinetically different components of phosphoenzyme and their role in the Na+, K+-stimulated ATPase reaction is discussed.
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PMID:Bovine brain Na+,K+-stimulated ATP phosphohydrolase studied by a rapid-mixing technique. K+-stimulated liberation of [32P] orthophosphate from [32P] phosphoenzyme and resolution of the dephosphorylation into two phases. 12 3

1. Conditions for binding of [gamma-32P]ATP to bovine brain Na+,K+-stimulated ATPase were investigated by the indirect technique of measuring the initial rate of 32P-labelling of the active site of the enzyme. 2. At 100 muM [gamma-32P]ATP in the presence of 3 mM MgCl2, approximately the same very high rate of formation of [32P]phosphoenzyme was obtained irrespective of whether [gamma-32P]ATP was added to the enzyme simultaneously with, or 70 ms in advance of the addition of NaCl. A comparatively slow rate of phosphorylation was obtained at 5 muM[gamma-32P]ATP without preincubation. However, on preincubation of the enzyme with 5 muM[gamma-32P]ATP a rate of formation of [32P]phosphoenzyme almost as rapid as at 100 muM[gamma-32P]ATP was observed. 3. A transient [32P]phosphoenzyme was discovered. It appeared in the presence of K+, under conditions which allowed extensive binding of [gamma-32P]-ATP. The amount of [gamma-32P]ATP that could be bound to the enzyme seemed to equal the amount of [32P] phosphorylatable sites. 4. The formation of the transient [32P] phosphoenzyme was inhibited by ADP. The transient [32P] phosphoenzyme was concluded mainly to represent the K+-insensitive and ADP-sensitive E1-32P. 5. When KCl was present in the enzyme solution before the addition of NaCl only a comparatively slow rate of phosphorylation was observed. On preincubation of the enzyme with [gamma-32]ATP an increase in the rate of formation of [32P] phosphoenzyme was obtained, but there was no transient [32P]-phosphoenzyme. The transient [32P]phosphoenzyme was, however, detected when the enzyme solution contained NaCl in addition to KCl and the phosphorylation was started by the addition of [gamma-32P]ATP.
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PMID:Bovine brain Na+, K+-stimulated ATP phosphohydrolase studied by a rapid-mixing technique. Detection of a transient [32P]phosphoenzyme formed in the presence of potassium ions. 12 4

The effects of Na+ and K+ ions on the elementary steps in the reaction of Na+-K+-dependent ATPase (EC 3.6.1.3) were investigated in 0.5-600mM NaCL and 0-10mM KCL, at a fixed concentration (1mM) OF MgCL2, AT PH 8.5 and at 15 degrees. The data were analyzed on the basis of the reaction mechanism in which a phosphorylated intermediate, E ADP P (abbreviated as EP), is formed via two kinds of enzyme-substrate comples, E1ATP and E2ATP, and EP is in equilibrium with E2ATP, and is hydrolyzed to produce P1 and ADP. The following results were obtained: 1. The rate od E2ATP-formation, vf, increased with increase in the Na+ concentration, reached a maximum level, and then decreased with further increase in the Na+ concentration at various K+ concentrations. The value of vf was given as (see article). 2. The reciprocal of the equilibrium constants, K2, of the step E1ATPEQUILIBRIUM E ADP P in the presence of low concentrations of Na+ was larger than that in the presence of high concrntrations of Na+, indicating that the equilibrium shifted markedly toward E2ATP at low concentrations of Na+. The relation of K3 with Na concentration was rather complicated on varying the concentration of K+. However, generally speaking, it increased with increase in the K+ concentration. 3. The decomposition of EP was markedly activated by even low concentrations of K+, and inhibited by high concentrations of Na+. The inhibition by Na+ was partially suppressed by K+. The rate constant of EP-decomposition, vo/(EP), was given by (see article) where (vo/(EP) K+EQUALS0 was the value of vo/[EP] in the absence of K+.
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PMID:Effects of sodium and potassium ions on the elementary steps in the reaction of Na+-K+-dependent ATPase1. 12 71

Previously, we proposed the following reaction machanism for the transport ATPase (EC 3.6.1.3) reaction in the presence of high concentrations of Mg2+ and Na+:(see article). Some kinetic and thermodynamic properties of steps 3 and 4 were investigated, and the following results were obtained. 1. When the reaction was started by adding ATP to the enzyme in the presence of 50 mM Na+ and 0.5 mM K+ or in the presence of 50mM Na+ and 0.5mM Rb+, the amount of E ADP P increased with time and maintained a constant level after reaching a maximum. We could not observe the initial burst of EP formation, which was observed by Post er al. in the presence of 8 mM Na+ and 0.01 mM Rb+. 2. The existence of quasi-equilibrium between E2ATP and E ADP P in the presence of low concentrations of Na+ was suggested by the fact that the values of the reciprocal of the equilibrium constant, K3 of step 3 obtained by the following three methods were almost the same. a) The value of 1+K3 was estimated from the ratio of vo/[EP] to kd, where vo is the rate of ATP hydrolysis in the steady state, [EP] the concentration of EP, and kd the first-order rate constant of EP disappearance after stopping EP formation. b) This value was also calculated from the ratio of the amount of P1 liberated to that of decrease in EP after stopping EP formation. c) The value of K3 was also calculated from the initial rapid decrease in EP on adding K+ and EDTA, assuming that the rapid decrease was due to a shift of the equilibrium toward E2ATP on adding K+. For example, the value of K3 with 10mM NaCL and 0.5mM KCL was 7--11. Although ATP formation due to a shift of the equilibrium toward E2ATP by a K+ jump in the presence of a low concentration of Na+ was observed at 0 degrees, the amount of ATP formed by a K+ jump at 15 degrees was less than the value expected from the shift of the equilibrium. 3. The values of delta H degrees and delta S degrees of step 3 were estimated in the presence of a sufficient amount of Na+ and in the absence of K+. They were +4--+5 kcal mole minus 1 and +15--+16 entropy units mole minus1, respectively. On the basis of kinetic studies of the elementary steps and the overall reaction of Na+-K+-dependent ATPase [EC 3.6.1.3], we (1--4) showed that a phosphorylated intermediate, EP, is formed via two kinds of enzyme-substrate complex, E1ATP and E2ATP, that the EP is in K+-dependent quasi-equilibrium with E2ATP, and that in the presence of high concentration of Mg2+, EP is in a high-energy state and contains bound ADP, E ADP P.(see article).
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PMID:Properties of the conversion of an enzyme-ATP complex to a phosphorylated intermediate in the reaction of Na+-K+-dependent ATPase1. 12 72

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