Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:1.8.1.4 (diaphorase)
 2,754 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The interaction of the pyruvate dehydrogenase multienzyme complex from Escherichia coli with 1,N6-etheno-CoA (epsilonCoA) and coenzyme A (CoA) has been investigated using equilibrium binding, steady-state fluorescence, and fluorescence lifetime measurements. A procedure for the resolution of the pyruvate dehydrogenase multienzyme complex into the pyruvate dehydrogenase enzyme and the transacetylase-flavoprotein subcomplex also is given. Direct binding studies with epsilonCoA indicate that 25 bound epsilonCoA molecules/multienzyme complex can be readily displaced by CoA, while approximately 21 bound epsilonCoA molecules/transacetylase-flavoprotein subcomplex can be displaced by CoA. The dissociation constant for the CoA displaceable epsilonCoA is 57.8 muM for the complex and 126 muM for the subcomplex in 0.02 M potassium phosphate (pH 7.0) at 5 degrees C. The kinetic behavior of epsilonCoA as a substrate was investigated and compared with that of CoA under a variety of conditions; the apparent Michaelis constants for epsilonCoA are considerably larger than those for CoA, while the corresponding maximal velocities are smaller. Fluorescence energy transfer measurements between bound epsilonCoA on the dihydrolipoyl transacetylase enzyme and flavin adenine dinucleotide on the dihydrolipoyl dehydrogenase enzyme either in the complex or subcomplex indicate, assuming the emission and absorption dipoles are randomly oriented, that these two probes must be at least 50 A apart.
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PMID:Fluorescence energy-transfer measurements between coenzyme A and flavin adenine dinucleotide binding sites of the Escherichia coli pyruvate dehydrogenase multienzyme complex. 77 33

The pyruvate dehydrogenase core complex from E. coli K-12, defined as the multienzyme complex which can be obtained with a unique polypeptide chain composition, has been investigated in solution with the X-ray small-angle technique. The molecular mass of the core complex of 3.78-10(6) daltons verifies the ratio of polypeptide chains of 16:16:16 of the three enzyme components, pyruvate dehydrogenase, dihydrolipoamide transacetylase, and dihydrolipoamide dehydrogenase, present in the complex. In connection with the values obtained for the radius of gyration (156.5A), volume (1.07(7) A3) and amount of solvent associated with the complex (1.03 g/g) a loose packing of subunits in the complex has to be assumed. The maximum diameter of the core complex of 433 A, as determined from the correlation function, corroborates the large extension of the complex. The comparison of experimental and theoretical scattering curves reveals a relatively isometric overall shape of the core complex.
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PMID:X-ray small-angle studies of the pyruvate dehydrogenase core complex from Escherichia coli K-12. I. Overall structure of the core complex. 78 4

The interpretation of X-ray small-angle data of the pyruvate dehydrogenase core complex from E. coli K-12 reveals the fine structure of the complex. Specific inner surface (7.07-10(-2 A-1), inner surface (7.60 - 10(5) A2), MEAN TRANSVERSAL LENGTH (56.6 A), coherence length (123.5 A), structural factor (1.1), and coherence area (3.27 - 10(4) A2) have been determined as further structural parameters characterizing the colloidal distribution of matter. Fouier transformations of scattered intensity and of structural amplitude have been carried out and show the existence of slightly disturbed spherical symmetry of the complex built up from subunits. The mean diameter of the three different subunit components of about 78 A was determined from the correlation function or from the distance distribution. The number of subunits in the complex was ascertained to be 40. The radial excess electron density distribution shows the arrangement of the core complex from a "core" (formed by the transacetylase components) with a small hole inside and a "shell" (formed by the pyruvate dehydrogenase and dihydrolipoamide dehydrogenase components). Although not representing a unique solution, a lot of model calculations indicate how the complex is arranged from subunits. At each edge of a cubic centre, the edge formed by two chains of transacetylase, two chains of pyruvate dehydrogenase and two chains of dihydrolipoamide dehydrogenase components are arranged according to the best fit. Far-reaching conformity between experimental results and model was established.
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PMID:X-ray small-angle studies of the pyruvate dehydrogenase core complex from Escherichia coli K-12. II. Subunit structure of the core complex. 78 5

Fluorescence-lifetime measurements of FAD bound to lipoamide dehydrogenase from Azotobacter vinelandii and Escherichia coli were performed. It is shown from these results that the two FAD groups in the isolated dimeric enzyme, as well as in the enzyme in the intact complex of E. coli, are in non-equivalent surroundings. This contrasts with the near equivalence of the FAD groups of both the enzyme and complex isolated from A. vinelandii. Reduction of the complex with Mg2+, thiamine pyrophosphate and pyruvate or with NADH enables the attachment of a maleimide analogue specifically to the lipoyl moieties of the transacetylase(s). Spin label [N-(1-oxyl-2,2,5,5-tetramethyl-3-pyrrolidinyl)maleimide] introduced in such a way proves the existence of at least two different micro-environments around the lipoyl moieties in complex isolated from A. vinelandii. Electron paramagnetic resonance spectra of the specifically spin-labelled complexes from E. coli and A. vinelandii, when dissolved in tricine [N-tris(hydroxymethyl)-methylglycine] buffer, show interactions of at least two electron spins with each other, which indicate that the lipoyl moieties are rather close together. Fluorescent label [N-(1-anilinonaphthyl-4)maleimide] is specifically attached to the lipoyl moiety of the high-Mr transacetylase of the freshly isolated complex from A. vinelandii. From the large differences in the apparent lifetimes tau p and tau m, as detected by phase fluorimetry, it is shown that this fluorscent label is distributed in different micro-environments. The differences observed in energy transfer between fluorescent label, attached to the lipoyl moiety of the high-Mr transacetylase, indicate different conformations of the complex from A. vinelandii. Upon introduction of the label after reduction with NADH a much larger energy transfer, thus a shorter distance, is observed between the label and FAD than when reduction is performed with Mg2+, thiamine pyrophosphate and pyruvate. A similar conformation dependence upon reduction is found for the pyruvate dehydrogenase complex from E. coli. It is thus proposed that the transacetylase of E. coli and the high-Mr transacetylase of A. vinelandii are both non-symmetrically distributed within the complex.
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PMID:Symmetry and asymmetry of the pyruvate dehydrogenase complexes from Azotobacter vinelandii and Escherichia coli as reflected by fluorescence and spin-label studies. 79 71

An acetate-requiring leaky mutant was induced from Bacillus subtilis 168, and activities of its three alpha-keto acid dehydrogenases were compared with the respectives activities of the parent strain. Both pyruvate and alpha-ketoisovalerate dehydrogenase activities in the mutant were consideralby lower, being only 10-17% of those of the parent, but alpha-ketoglutarate dehydrogenase activity was unchanged. These dehydrogenases are complexed composed of three enzymes: a carboxylase, a lipoic reductase-transacylase, and a dihydrolipoyl dehydrogenase. The carboxylase activity of the affected complexes was no different. Total dihydrolipoyl dehydrogenase activity was only one-third. Thus dihydrolipoyl dehydrogenase is the defective enzyme in the two dehydrogenase complexes; the activity remaining in the mutant is accounted for by the activity of the intact alpha-ketoglutarate dehydrogenase.
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PMID:Activities of alpha-ketoisovalerate, pyruvate, and alpha-ketoglutarate dehydrogenases in a mutant of Bacillus subtilis. 81 42

Microorganisms formed readily ethylenethiourea (ETU) from 5,6-dihydro-3H-imidazo[2,1-c]-1,2,4-dithiazole-3-thione (DIDT), a spontaneous decomposition product of ethylenebisdithiocarbamates. This conversion also takes place after addition of reducing compounds like cysteine, glutathione or ascorbic acid. It consists of two steps: reduction of the S-S bond of DIDT with subsequent release of CS2 to form ETU. DIDT was reduced by NADH in the presence of enzyme extracts from Pseudomonas fluorescens or Asperigillus niger, or by commercial glutathione reductase or lipoamide dehydrogenase. ETU was formed as a result of this enzymatic reduction. The flavin compounds FMN and FAD were also able to promote the reduction of DIDT by NADH.
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PMID:Formation of ethylenethiourea from 5,6-dihydro-3H-imidazo[2,1-c]-1,2,4-dithiazole-3-thione by microorganisms and reducing agents. 81 82

1. The effect of guanidine hydrochloride (GuHCl) on pig heart lipoamide dehydrogenase [NADH: lipoamide oxidoreductase, EC 1.6.4.3.] was investigated by means of enzymatic activity and optical measurements (CD, absorption, and fluorescence spectra). The activity of the enzyme decreased on increasing the concentration of GuHCl and the enzyme was completely inactivated in 2.0 M GuHCl. 2. The contents of alpha-helix, beta, and unordered forms in lipoamide dehydrogenase were estimated to be 34, 14, and 52%, respectively. On increasing the concentration of GuHCl, the content of alpha-helix in lipoamide dehydrogenase decreased, whereas the content of the beta form hardly changed. 3. The native lipoamide dehydrogenase showed absorption, CD, and fluorescence spectra characteristic of bound FAD in the visible region, suggesting hydrophobic interaction between the protein moiety and FAD chromophore. The absorption, CD, and fluorescence spectra of the enzyme in 2.0 M GuHCl were similar to those of free FAD in the buffer, suggesting the release of FAD from the protein moiety. 4. The protein fluorescence spectrum of lipoamide dehydrogenase had a maximum at 350 nm blue-shifted by 8 nm from that of tryptophan in aqueous solution. The maximum of the enzyme in 2.0 M GuHCl was red-shifted to 357 nm. This suggests exposure of tryptophan residues to a polar environment. The maximum, 352nm, of the apoenzyme shifted to 350 nm on addition of FAD. These results show that the conformation in the microenvironment of some tryptophan residues in lipoamide dehydrogenase is affected by the dissociation-association of FAD. 5. The contents of alpha-helix, beta, and unordered forms in the apoenzyme were estimated to be 35, 8, and 57%, respectively. These values are similar to those of the native holoenzyme. The alpha-helical structure in the apoenzyme molecule was more sensitive to GuHCl than that in the holoenzyme. FAD and two hydrophobic probes, 8-anilinonaphthalene-1-sulfonate (ANS) and 4 benzolamido-4'-aminostilbene-2,2'-disulfonate (MBAS), which can bind to the apoenzyme, stabilized the alpha-helical structure in the apoenzyme molecule.
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PMID:Effect of guanidine hydrochloride on the holo- and apo-enzymes of pig heart lipoamide dehydrogenase. 93 80

The interaction of hydrophobic probes, 8-anilinonaphthalene-1-sulfonate (ANS) and 4-benzoylamido-4'-aminostilbene-2, 2'-disulfonate (MBAS), with pig heart lipoamide dehydrogenase [NADH: lipoamide oxidoreductase, EC 1.6.4.3] was investigated. When ANS or MBAS was mixed with the apoenzyme of lipoamide dehydrogenase, the fluorescence quantum yield, of each dye was enhancedd markedly and the emission maxima concurrently shifted to the blue. The quantum yield, 0.038, of ANS bound to the apoenzyme, calculated from the corrected emission spectrum, was eight times higher than that in buffer solution, and the value, 0.0090, for bound MBAS was eighteen times higher than that in buffer solution. Moreover, the absortion bands of both ANS and MBAS shifted to the red upon binding with the apoenzyme. A general feature of the absorption spectra of these dyes observed on changing the solvent from polar to apolar was a red shift of the absorption bands. These results indicate that ANS or MBAS bound to the apoenzyme of lipoamide dehydrogenase is situated in a hydrophobic region of the apoenzyme molecule. It was found that 2 moles of each dye was bound per mole of the apoenzyme, which contains two polypeptide chains. The dissociation constants for the ANS- and MBAS-apoenzyme complexes were estimated to be 1.03X10(-5) and 1.54X10(-5) M, respectively. The enhanced fluorescence of both dyes bound to the apoenzyme decreased linearly upon adding FAD and disappeared at about 2 moles of FAD per mole of the apoenzyme. This suggests that both ANS and MBAS were displaced from their binding sites on the apoenzyme by FAD. The protein fluorescence spectrum of the apoenzyme had a maximum at 352 nm, which was blue-shifted by 6 nm from that of tryptophan in the buffer. Upon binding ANS or MBAS, the maximum of the protein fluorescence of the apoenzyme returned to 350 nm for the holoenzyme, and the fluorescence intensity decreased. Thus, the conformation around some tryptophan residues was affected by the binding of the dyes. When guanidine hydrochloride (GuHCl) was added to the ANS-apoenzyme complex solution, the enhanced fluorescence due to the bound ANS decreased and the emission maximum concurrently shifted to the red. Further, the maximum of the protein fluorescence of the apoenzyme shifted to the red, indicating the exposure of some tryptophan residues buried in an apolar region of the apoenzyme. Thus the binding of ANS to the apoenzyme was inhibited by protein denaturation due to GuHCL. In contrast, the holoenzyme of lipoamide dehydrogenase did not bind ANS or MBAS at all.
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PMID:Interaction of hydrophobic probes with the apoenzyme of pig heart lipoamide dehydrogenase. 95 45

Friedreich's ataxia patients show evidence of an abnormally elevated and prolonged response of pyruvate and lactate to a glucose load, with normal fasting levels. However, ther is a bimodal distribution of this response with high and low pyruvate responders. This trait appears to be determined genetically, However, although in vivo tests suggest low oxidation of pyruvate, we were unable to confirm any in vitro impairment of each of the components of the pyruvate dehydrogenase (PDH) complex. We conclude that the defect is in the metabolic regulation of PDH, probably at the E3 (lipoamide dehydrogenase) step.
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PMID:Pyruvate metabolism in Friedreich's ataxia. 100 Apr 25

The mammalian pyruvate dehydrogenase complex contains a core, consisting of dihydrolipoyl transacetylase, to which pyruvate dehydrogenase and dihydrolipoyl dehydrogenase are joined. This report describes studies on the kinetic mechanism of the transacetylase-catalyzed reaction between [1-14C]acetyl-CoA and dihydrolipoamide. This reaction appears to be a model of the physiological reaction, in which the acetyl group is transferred from the S-acetyldihydrolipoyl moiety, bound covalently to the transacetylase, to CoA. The model reaction is not affected by pyruvate dehydrogenase or dihydrolipoyl dehydrogenase, their substrates and products, or by removal of the covalently bound lipoyl moiety. These findings, together with the results of initial velocity, product inhibition, and dead-end inhibition studies, indicate that the model reaction and, apparently, the physiological reaction as well, proceeds via the Random Bi Bi (rapid equilibrium) mechanism. It appears that at the catalytic center of the transacetylase there are two adjacent sites, one that binds CoA and acetyl-CoA and another that binds dihydrolipoamide and S-acetyldihydrolipoamide (or the corresponding forms of the covalently bound lipoyl moiety.
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PMID:A kinetic study of dihydrolipoyl transacetylase from bovine kidney. 108 67


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