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 amino acid sequence of an intrinsic inhibitor of mitochondrial ATPase isolated from yeast was completed by using solid-phase sequencing and conventional procedures. The inhibitor was found to be composed of 63 amino acid residues, to lack tryptophan, cysteine, and tyrosine, and to have a molecular weight of about 7,383. The inhibitor was characterized as a basic protein with 16 basic and 13 acidic amino acid residues, and several clusters of basic residues were noted. Some comments are made on the hydrophobic amino acids and the presence of repeated sequences.
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PMID:Amino acid sequence of an intrinsic inhibitor of mitochondrial ATPase from yeast. 645 1

Changes in conformation of the epsilon-subunit of the bovine heart mitochondrial F1-ATPase complex as a result of nucleotide binding have been demonstrated from the phosphorescence emission of tryptophan. The triplet state lifetime shows that whereas nucleoside triphosphate binding to the enzyme in the presence of Mg2+ increases the flexibility of the protein structure surrounding the chromophore, nucleoside diphosphate acts in an opposite manner, enhancing the rigidity of this region of the macromolecule. Such changes in dynamic structure of the epsilon-subunit are evident at high ligand concentration added to both the nucleotide-depleted F1 (Nd-F1) and the F1 preparation containing the three tightly bound nucleotides (F1(2,1)). Since the effects observed are similar in both the F1 forms, the binding to the low affinity sites must be responsible for the conformational changes induced in the epsilon-subunit. This is partially supported by the observation that the Trp lifetime is not significantly affected by adding an equimolar concentration of adenine nucleotide to Nd-F1. The effects on protein structure of nucleotide binding to either catalytic or noncatalytic sites have been distinguished by studying the phosphorescence emission of the F1 complex prepared with the three noncatalytic sites filled and the three catalytic sites vacant (F1(3,0)). Phosphorescence lifetime measurements on this F1 form demonstrate that the binding of Mg-NTP to catalytic sites induces a slight enhancement of the rigidity of the epsilon-subunit. This implies that the binding to the vacant noncatalytic site of F1(2,1) must exert the opposite and larger effect of enhancing the flexibility of the protein structure observed in both Nd-F1 and F1(2,1). The observation that enhanced flexibility of the protein occurs upon addition of adenine nucleotides to F1(2,1) in the absence of Mg2+ provides direct support for this suggestion. The connection between changes in structure and the possible functional role of the epsilon-subunit is discussed.
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PMID:Conformational changes of the mitochondrial F1-ATPase epsilon-subunit induced by nucleotide binding as observed by phosphorescence spectroscopy. 766 7

X-ray structure analysis of the noncatalytic sites of F1-ATPase revealed that residue alpha-Asp261 lies close to the Mg of bound Mg-5'-adenylyl-beta,gamma-imidodiphosphate. Here, the mutation alpha D261N was generated in Escherichia coli and combined with the alpha R365W mutation, allowing nucleotide binding at F1 noncatalytic sites to be specifically monitored by tryptophan fluorescence spectroscopy. Purified alpha D261N/alpha R365W F1-ATPase showed catalytic activity similar to wild-type. An important feature was that, without any resort to nucleotide-depletion procedures, the noncatalytic sites in purified native enzyme were already empty. Binding studies with MgATP, MgADP, and the corresponding free nucleotides led to the following conclusions. Residue alpha-Asp261 interacts with the Mg of Mg-nucleotide in noncatalytic sites and provides a large component of the binding energy (approximately 3 kcal/mol). It is the primary determinant of the preference of noncatalytic sites for Mg-nucleotide. The natural ligands at these sites in wild-type enzyme are the Mg-nucleotides and free nucleotides bind poorly. Under conditions where noncatalytic sites were empty, alpha D261N/alpha R365W F1 showed significant hydrolysis of MgATP. This established unequivocally that occupancy of noncatalytic sites by nucleotide is not required for catalysis.
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PMID:alpha-Aspartate 261 is a key residue in noncatalytic sites of Escherichia coli F1-ATPase. 767 31

Binding of pyrophosphate (PPi) to the three catalytic ("C") and three noncatalytic ("NC") nucleotide sites of Escherichia coli F1-ATPase was determined by fluorescence spectroscopy using mutant enzymes with tryptophan inserted specifically in either C sites (beta Y331W) or NC sites (alpha R365W). Fluorescence of the tryptophan is quenched on binding of nucleotide; PPi binding parameters were determined by competition with ATP or adenyl-5'-yl imidodiphosphate. It was found that MgPPi binds to each NC site with Kd = 20 microM. In contrast, even at millimolar concentration, neither MgPPi nor free PPi showed significant binding to C sites. We confirmed that free PPi displaces nucleotide from C sites, but this was shown to be due to complexation of Mg2+ ions rather than to occupancy of the sites. MgPPi bound at NC sites was found not to affect ATP hydrolysis rates. From the data we propose a two-phase model for nucleotide binding at NC sites. In phase one, NC sites recognize the pyrophosphate "end" of the nucleotide, which binds initially with Kd similar to MgPPi; in phase two, a slow conformational change occurs which tightly sequesters adenine nucleotide. Phase two does not occur with guanine nucleotide. This model explains the preference of NC sites for adenine nucleotides. Pi (5 mM) did not bind to either C or NC sites.
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PMID:Location and properties of pyrophosphate-binding sites in Escherichia coli F1-ATPase. 775 15

The bovine heart mitochondrial F1-ATPase complex exhibits an intrinsic tryptophan phosphorescence that can be used to monitor structural changes of the epsilon-subunit. The phosphorescence decay rate of F1 containing the tightly bound nucleotides increases upon addition of adenine nucleoside triphosphate in the presence of magnesium. The average phosphorescence lifetime of this enzyme preparation decreases from 10.2 to 7.8 ms upon Mg-ATP addition. Since increasing phosphorescence decay rate is related to increasing flexibility of proteins, Mg-ATP added to the F1-ATPase complex can enhance the flexibility of the protein structure surrounding the chromophore. Experiments carried out on F1 prepared with the three noncatalytic sites filled and the three catalytic sites vacant show a significant increase of the phosphorescence lifetime from 6.4 ms to 7.6 ms upon Mg-ATP addition. These results suggest that the mitochondrial F1-ATPase epsilon-subunit conformation senses differently the nucleoside triphosphate binding to catalytic or noncatalytic sites.
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PMID:A study of the mitochondrial F1-ATPase tryptophan phosphorescence at 273 K. 785 90

We have engineered a mutant form of Escherichia coli F1-ATPase which is tryptophan-free and contains five mutations, namely delta W28L/alpha W513F/gamma W108Y/gamma W206Y/beta W107F. A strain carrying all five mutations grew normally by oxidative phosphorylation. Purified mutant F1-ATPase showed Vmax and Km both 65% higher than wild-type, resulting in kcat/Km the same as wild-type. The pH dependence of ATPase activity in mutant enzyme was very similar to that in wild-type. Catalytic-site nucleotide-binding characteristics were measured using the analog lin-benzo-ADP and sensitivity to inhibitors was tested using dicyclohexylcarbodiimide, azide and aurovertin. The mutant enzyme was very similar to wild-type in each of these characteristics. The fluorescence spectrum of mutant enzyme confirmed the absence of tryptophan. We have therefore established that it is possible to generate a tryptophan-free enzyme which retains normal catalytic function, oligomeric stability and in vivo assembly.
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PMID:Tryptophan-free Escherichia coli F1-ATPase. 813 49

Tryptophan fluorescence was investigated as a tool to study the noncatalytic nucleotide-binding sites of Escherichia coli F1-ATPase. Site-directed mutagenesis, affinity labeling, and lin-benzo-ATP binding studies had shown that residues alpha R365 and beta Y354 are located close to the base moiety of bound nucleotide; here, we mutagenized each to tryptophan. The new tryptophans gave a fluorescence signal indicating an environment of high (alpha W365) or intermediate (beta W354) polarity in unoccupied sites. alpha W365 fluorescence was completely quenched by binding of ATP or ADP, providing a direct, specific probe of noncatalytic site nucleotide occupancy. Using this signal, we measured binding parameters for ATP and ADP, showed that nucleotide binding was magnesium-dependent, and showed that GTP and ITP did bind to some extent, but AMP, GDP, and IDP did not. It was possible to follow initial rates of MgATP hydrolysis and noncatalytic site binding under identical conditions; the results indicated that occupancy of noncatalytic sites was not required for catalysis. Fluorescence from beta W354 was quenched completely by lin-benzo-ATP, but only slightly by ATP or ADP. Probably, residue beta 354 is not as closely juxtaposed to the adenine ring of bound ATP and ADP as is residue alpha 365. With either alpha W365 or beta W354 as donor and catalytic site-bound lin-benzo-ADP as acceptor, no fluorescence resonance energy transfer was detected, indicating that the distance between non-catalytic and catalytic sites is > or = 27 A.
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PMID:Tryptophan fluorescence provides a direct probe of nucleotide binding in the noncatalytic sites of Escherichia coli F1-ATPase. 815 56

1. The F1-ATPase from bovine heart mitochondria was shown to chemically react and to absorb 2-hydroxy-5-nitrobenzyl bromide (HNB) with changes in catalytic properties. 2. The treatment of the enzyme with HNB at concentrations below 0.5 mM resulted in an increase of Vm and in an unchanged Km. Above 0.5 mM HNB elicited a concentration-dependent inhibition of F1. 3. HNB was found tightly bound to the enzyme epsilon-subunit whose tryptophan residue resulted modified. 4. The F1 activation appears the consequence of the covalent binding of the reagent to the enzyme, whilst inhibition results from non-covalent, reversible binding. 5. The possibility that the epsilon-subunit of mitochondrial F1-ATPase may influence the functional or regulating domain of the enzyme is discussed.
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PMID:Interactions and effects of 2-hydroxy-5-nitrobenzyl bromide on the bovine heart mitochondrial F1-ATPase. 822 73

We report the detection of tryptophan phosphorescence emission from the sole residue in the epsilon-subunit of the bovine heart mitochondrial F1-ATPase complex. The phosphorescence spectrum, intensity and decay kinetics have been measured over the temperature range 160-273 K. The fine structure in the phosphorescence spectrum at low temperature, with the 0-0 vibrational band centered at 411 nm, reveals the hydrophobic nature of the chromophore's environment. Both the large width of the 0-0 vibrational band and the heterogeneous decay kinetics in fluid solution emphasize the existence of multiple conformations of the epsilon-subunit, structures which are rather stable as they do not interconvert in the millisecond time scale. Further, from the relatively long triplet lifetime at 273 K, it is possible to infer the existence of a tight, rigid core in the structure of the epsilon-subunit. Under subunit-dissociating conditions (6 M urea), the spectrum at 160 K undergoes a slight blue shift but since the phosphorescence lifetime, at all temperatures, is similar or longer than in the absence of dissociant, we conclude that dissociation does not lead to solvent exposure of the tryptophanyl side-chain. This conclusion is supported by the results obtained at 273 K by dissociating F1 in the presence of 0.3 M guanidine hydrochloride. Phosphorescence lifetimes indicate that 6 M urea leads to a more compact structure of the epsilon-subunit, whereas the opposite occurs when Mg-ATP is added to nucleotide-depleted F1. These spectroscopic changes establish unequivocally that the binding of the adenine nucleotide to the enzyme is accompanied by conformational changes involving the epsilon-subunit.
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PMID:Tryptophan phosphorescence as a structural probe of mitochondrial F1-ATPase epsilon-subunit. 831 82

Residue beta Y331 of Escherichia coli F1-ATPase is known from previous affinity labeling, mutagenesis, and lin-benzo-ADP binding experiments to interact directly with the adenine moiety of substrates bound in catalytic sites. Here we mutagenized beta Y331 to tryptophan. Mutant cells grew well on succinate or limiting glucose; purified mutant F1 had kappa cat/Km and lin-benzo-ADP binding characteristics similar to wild type. Fluorescence from beta W331 residues exhibited a maximum at 349 nm, indicating a polar environment in unoccupied sites. ATP, ADP, or AMPPNP caused virtually complete quenching of beta W331 fluorescence, so that the fluorescence of mutant F1 with occupied catalytic sites resembled that of wild-type enzyme. Therefore the beta W331 fluorescence provided a direct probe of nucleotide binding to catalytic sites under true equilibrium conditions. We measured ATP binding and hydrolysis in parallel experiments and found that occupancy of one or two catalytic sites per F1 molecule did not yield significant rates of hydrolysis while occupancy of all three sites yielded Vmax rates. Km(ATP) was similar to Kd3, the Kd for ATP binding to the third catalytic site. We also measured AMPPNP and ADP binding parameters. For ADP, the "on" rate at the first catalytic site was much faster (> or = 5 x 10(5) M-1 s-1) than seen previously by centrifuge column procedures, although the Kd was not much changed. For AMPPNP, the "on" rate at the first site was 2 orders of magnitude less than for ADP or ATP, and the Kd was similar to that for ADP.
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PMID:Specific placement of tryptophan in the catalytic sites of Escherichia coli F1-ATPase provides a direct probe of nucleotide binding: maximal ATP hydrolysis occurs with three sites occupied. 837 71

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