Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: KEGG:D02011 (FAD)
5,530 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Electron-transferring flavoprotein (ETF) isolated from pig kidney is a heterodimer containing one FAD and one AMP [Sato, K. et al. (1993) J. Biochem. 114, 215-222]. This paper presents a method for separation of the alpha and beta subunits on a preparative scale. The subunits were separated by cation-exchange chromatography in the presence of 6 M urea at pH 7.6. The subunits were obtained in unfolded forms with denaturant. The unfolded subunits were restored to the heterodimeric form having FAD and AMP with high yield after incubation with FAD and AMP under non-denaturing conditions. The far-UV CD spectrum, the fluorescence and absorption spectra of the bound FAD, and the enzyme activity of the reconstituted ETF were all identical to those of the ETF isolated from pig kidney. Thus, an experimental system was established for the reconstitution of ETF from the four components, alpha, beta, FAD, and AMP. Analyses of the absorption spectra of the separated subunits suggested that the contents of aromatic residues were one tryptophan and six tyrosines in alpha and one tryptophan and one tyrosine in beta. The possibility that one subunit binds with FAD or AMP in the absence of the other subunit was examined by measuring the flavin and protein fluorescence spectra, but no spectral changes reflecting such binding were detected. This result suggests that the coexistence of both the subunits is necessary for the binding of FAD and AMP with the protein.
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PMID:Preparation of separated alpha and beta subunits of electron-transferring flavoprotein in unfolded forms and their restoration to the native holoprotein form. 779 72

The carboxyl-terminal region of plant ferredoxin-NADP+ reductases is formed by an invariant alpha-helix/loop/beta-strand, culminating in a conserved tyrosine that displays extensive interaction with the prosthetic group FAD. We have investigated the potential role of the terminal region in reductase function, by introducing mutations and deletions on pea ferredoxin-NADP+ reductase overexpressed in Escherichia coli. Replacement of the terminal tyrosine by tryptophan, phenylalanine, serine, and glycine resulted in a 2.2-, 2.0-, 22-, and 302-fold reduction, respectively, in kcat for the diaphorase reaction, whereas elimination of the tyrosine caused a 846-fold decrease in kcat. Km values were largely unaffected by the substitutions. Similar results were obtained when the mutants were assayed for cytochrome c reduction, indicating that aromaticity is the most important factor to the function of the tyrosine in catalysis. The presence of the phenol ring at the carboxyl-terminal position of wild-type reductase is important, but not an absolute requirement for enzyme function or FAD assembly. Deletion of the alpha-helix/beta-strand region prevented reductase proper folding in the bacterial host, while shortening of the terminal region by splicing 3 amino acids at the beginning of the alpha-helix produced a moderately soluble reductase, devoid of FAD and enzymatic activity.
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PMID:Probing the role of the carboxyl-terminal region of ferredoxin-NADP+ reductase by site-directed mutagenesis and deletion analysis. 836 77

Cytochrome P450BM-3 from Bacillus megaterium is a soluble, catalytically self-sufficient fatty acid mono-oxygenase that, in structural organization and amino acid sequence, resembles the Class II (microsomal) P450 systems. Its single polypeptide chain contains both a P450 heme domain and an NADPH:P450 reductase domain, each of which bears significant homology with its microsomal counterparts. We report here the critical nature of three amino acids in the reductase domain of this enzyme with respect to FMN binding and catalytic activity. We used site-directed mutagenesis to change glycine 570 to bulkier amino acids; none of these mutant enzymes contained FMN after purification. We also made substitutions for tryptophan 574 and tyrosine 536, which by sequence analogy (Porter, T. D. (1991) Trends Biochem. Sci. 16, 154-158) were proposed to bind FMN through stacking of the aromatic rings with the isoalloxazine ring of the flavin. Mutants of tryptophan 574 which retained the aromatic side chain contained no less than 0.85 mol of FMN per mol of enzyme, while aspartate and glycine substitutions yielded enzymes which did not incorporate FMN. Substitution of tyrosine 536 with aspartate gave an enzyme which contained 0.44 mol of FMN per mol of enzyme but was inactive as a fatty acid hydroxylase and had only 2% of wild-type cytochrome c reductase activity, while the glycine mutant at this position bound no FMN. Furthermore, although all of the mutant enzymes contained 1 mol of FAD per mol of enzyme, the Y536D mutant and those entirely lacking FMN retained no more than 40% of wild-type ferricyanide reductase activity. By assaying these enzymes in the presence of added FMN, we were able to assess the relative importance of the residues in the wild-type sequence with respect to their contribution to FMN binding. In addition, the aromatic mutants of tryptophan 574, which were nearly as active in cytochrome c reduction as wild-type P450BM-3, were only 20% as active in myristate hydroxylation as the wild-type enzyme, suggesting that this amino acid plays an important role in the flow of electrons between the P450 heme and reductase domains.
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PMID:Critical residues involved in FMN binding and catalytic activity in cytochrome P450BM-3. 846 85

Rat neuronal NO synthase (nNOS) is comprised of a flavin-containing reductase domain and a heme-containing oxygenase domain. Calmodulin binding to nNOS increases the rate of electron transfer from NADPH into its flavins, triggers electron transfer from flavins to the heme, activates NO synthesis, and increases reduction of artificial electron acceptors such as cytochrome c. To investigate what role the reductase domain plays in calmodulin's activation of these functions, we overexpressed a form of the nNOS reductase domain (amino acids 724-1429) in the yeast Pichia pastoris that for the first time exhibits a complete calmodulin response. The reductase domain was purified by 2',5'-ADP affinity chromatography yielding 25 mg of pure protein per liter of culture. It contained 1 FAD and 0.8 FMN per molecule. Most of the protein as isolated contained an air-stable flavin semiquinone radical that was sensitive to FeCN6 oxidation. Anaerobic titration of the FeCN6-oxidized reductase domain with NADPH indicated the flavin semiquinone re-formed after addition of 1-electron equivalent and the flavins could accept up to 3 electrons from NADPH. Calmodulin binding to the recombinant reductase protein increased its rate of NADPH-dependent flavin reduction and its rate of electron transfer to cytochrome c, FeCN6, or dichlorophenolindophenol to fully match the rate increases achieved when calmodulin bound to native full-length nNOS. Calmodulin's activation of the reductase protein was associated with an increase in domain tryptophan and flavin fluorescence. We conclude that many of calmodulin's actions on native nNOS can be fully accounted for through its interaction with the nNOS reductase domain itself.
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PMID:Characterization of the reductase domain of rat neuronal nitric oxide synthase generated in the methylotrophic yeast Pichia pastoris. Calmodulin response is complete within the reductase domain itself. 870 5

Electron-transferring flavoprotein (ETF) from pig kidney is composed of two subunits (alpha and beta, molecular weights of 33,000 and 29,000) and two small molecules, FAD and AMP. In this study, in vitro refolding and unfolding of the subunits of ETF were carried out with urea as the denaturing reagent. The refolding reaction of alpha and beta was revealed to proceed kinetically in two steps: D in equilibrium with I-->N, where D,I, and N denote the denatured, intermediate, and native forms, respectively. The features of the I forms of alpha and beta, described below, are consistent with the concept of the so-called "molten globule state," which is frequently observed in protein refolding. (i) The conversion between D and I was very rapid. (ii) The I form showed as much secondary structure as the N form as judged from the far-UV circular dichroism. (iii) The solvent accessibility of the I form, estimated by the analysis of equilibrium unfolding experiments, was intermediate between those of the D and N forms. (iv) The standard free energy of the I form is almost the same as that of the D form. The refolding reaction progressed more slowly and the environment of the tryptophan chromophore was changed more drastically in beta refolding that in alpha refolding. We previously reported that the reconstitution of holoETF from denatured subunits is speeded up by increasing the AMP concentration. In this study, the effects of AMP, FAD, and the other subunit on the single subunit folding were examined, but no effect was detected. This result suggests that AMP plays a role in a later process, namely, assembly of the four components (refolded alpha and beta, FAD, and AMP).
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PMID:In vitro refolding and unfolding of subunits of electron-transferring flavoprotein: characterization of the folding intermediates and the effects of FAD and AMP on the folding reaction. 888 11

Threonine 244 in the alpha subunit of Paracoccus denitrificans transfer flavoprotein (ETF) lies seven residues to the amino terminus of a proposed dinucleotide binding motif for the ADP moiety of the FAD prosthetic group. This residue is highly conserved in the alpha subunits of all known ETFs, and the most frequent pathogenic mutation in human ETF encodes a methionine substitution at the corresponding position, alphaT266. The X-ray crystal structures of human and P. denitrificans ETFs are very similar. The hydroxyl hydrogen and a backbone amide hydrogen of alphaT266 are hydrogen bonded to N(5) and C(4)O of the flavin, respectively, and the corresponding alphaT244 has the same structural role in P. denitrificans ETF. We substituted a methionine for T244 in the alpha subunit of P. denitrificans ETF and expressed the mutant ETF in Escherichia coli. The mutant protein was purified, characterized, and compared with wild type P. denitrificans ETF. The mutation has no significant effect on the global structure of the protein as inferred from visible and near-ultraviolet absorption and circular dichroism spectra, far-ultraviolet circular dichroism spectra, and infrared spectra in 1H2O and 2H2O. Intrinsic fluorescence due to tryptophan of the mutant protein is 60% greater than that of the wild type ETF. This increased tryptophan fluorescence is probably due to a change in the environment of the nearby W239. Tyrosine fluorescence is unchanged in the mutant protein, although two tyrosine residues are close to the site of the mutation. These results indicate that a change in structure is minor and localized. Kinetic constants of the reductive half-reaction of ETF with porcine medium chain acyl-CoA dehydrogenase are unaltered when alphaT244M ETF serves as the substrate; however, the mutant ETF fails to exhibit saturation kinetics when the semiquinone form of the protein is used as the substrate in the disproportionation reaction catalyzed by P. denitrificans electron transfer flavoprotein-ubiquinone oxidoreductase (ETF-QO). The redox behavior of the mutant ETF was also altered as determined from the equilibrium constant of the disproportionation reaction. The separation of flavin redox potentials between the oxidized/semiquinone couple and semiquinone/hydroquinone couple are -6 mV in the wild type ETF and -27 mV in the mutant ETF. The mutation does not alter the AMP content of the protein, although the extent and fidelity of AMP-dependent, in vitro renaturation of the mutant AMP-free apoETF is reduced by 57% compared to renaturation of wild type apoETF, likely due to the absence of the potential hydrogen bond donor T244.
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PMID:alphaT244M mutation affects the redox, kinetic, and in vitro folding properties of Paracoccus denitrificans electron transfer flavoprotein. 910 14

Flavodoxin reductase from Escherichia coli is an FAD-containing oxidoreductase that transports electrons between flavodoxin or ferredoxin and NADPH. Together with flavodoxin, the enzyme is involved in the reductive activation of three E. coli enzymes: cobalamin-dependent methionine synthase, pyruvate formate lyase and anaerobic ribonucleotide reductase. An additional function for the oxidoreductase appears to be to protect the bacteria against oxygen radicals. The three-dimensional structure of flavodoxin reductase has been solved by multiple isomorphous replacement, and has been refined at 1.7 A to an R-value of 18.4% and Rfree 24.8%. The monomeric molecule contains one beta-sandwich FAD domain and an alpha/beta NADP domain. The overall structure is similar to other reductases of the NADP-ferredoxin reductase family in spite of the low sequence similarities within the family. Flavodoxin reductase lacks the loop which is involved in the binding of the adenosine moiety of FAD in other FAD binding enzymes of the superfamily but is missing in the FMN binding phthalate dioxygenase reductase. Instead of this loop, the adenine interacts with an extra tryptophan at the C terminus. The FAD in flavodoxin reductase has an unusual bent conformation with a hydrogen bond between the adenine and the isoalloxazine. This is probably the cause of the unusual spectrum of the enzyme. There is a pronounced cleft close to the isoalloxazine that appears to be well suited for binding of flavodoxin/ferredoxin. Two extra short strands of the NADP-binding domain probably act as an anchor point for the binding of flavodoxin.
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PMID:The three-dimensional structure of flavodoxin reductase from Escherichia coli at 1.7 A resolution. 914 48

D-Amino acid oxidase (DAAO) is the prototype of the flavin-containing oxidases. It catalyzes the oxidative deamination of various D-amino acids, ranging from D-Ala to D-Trp. We have carried out the X-ray analysis of reduced DAAO in complex with the reaction product imino tryptophan (iTrp) and of the covalent adduct generated by the photoinduced reaction of the flavin with 3-methyl-2-oxobutyric acid (kVal). These structures were solved by combination of 8-fold density averaging and least-squares refinement techniques. The FAD redox state of DAAO crystals was assessed by single-crystal polarized absorption microspectrophotometry. iTrp binds to the reduced enzyme with the N, C alpha, C, and C beta atoms positioned 3.8 A from the re side of the flavin. The indole side chain points away from the cofactor and is bound in the active site through a rotation of Tyr224. This residue plays a crucial role in that it adapts its conformation to the size of the active site ligand, providing the enzyme with the plasticity required for binding a broad range of substrates. The iTrp binding mode is fully consistent with the proposal, inferred from the analysis of the native DAAO structure, that substrate oxidation occurs via direct hydride transfer from the C alpha to the flavin N5 atom. In this regard, it is remarkable that, even in the presence of the bulky iTrp ligand, the active center is made solvent inaccessible by loop 216-228. This loop is thought to switch between the "closed" conformation observed in the crystal structures and an "open" state required for substrate binding and product release. Loop closure is likely to have a role in catalysis by increasing the hydrophobicity of the active site, thus making the hydride transfer reaction more effective. Binding of kVal leads to keto acid decarboxylation and formation of a covalent bond between the keto acid C alpha and the flavin N5 atoms. Formation of this acyl adduct results in a nonplanar flavin, characterized by a 22 degrees angle between the pyrimidine and benzene rings. Thus, in addition to an adaptable substrate binding site, DAAO has the ability to bind a highly distorted cofactor. This ability is relevant for the enzyme's function as a highly efficient oxidase.
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PMID:Active site plasticity in D-amino acid oxidase: a crystallographic analysis. 915 26

The catalytic oxidation of beta-D-glucose by the enzyme glucose oxidase involves a redox change of the flavin coenzyme. The structure and the dynamics of the two extreme glucose oxidase forms were studied by using infrared absorption spectroscopy of the amide I'band, tryptophan fluorescence quenching and hydrogen isotopic exchange. The conversion of FAD to FADH2 does not change the amount of alpha-helix present in the protein outer shell, but reorganizes a fraction of random coil to beta-sheet structure. The dynamics of the protein interior vary with the redox states of the flavin without affecting the motions of the structural elements near the protein surface. From the structure of glucose oxidase given by X-ray crystallography, these results suggest that the dynamics of the interface between the two monomers are involved in the catalytic mechanism.
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PMID:Dynamic and structural properties of glucose oxidase enzyme. 946 87

Monomeric sarcosine oxidase (MSOX) and N-methyltryptophan oxidase (MTOX) are homologous enzymes that catalyze the oxidative demethylation of sarcosine (N-methylglycine) and N-methyl-L-tryptophan, respectively. MSOX is induced in various bacteria upon growth on sarcosine. MTOX is an E. coli enzyme of unknown metabolic function. Both enzymes contain covalently bound flavin. The covalent flavin is at the FAD level as judged by electrospray mass spectrometry. The data provide the first evidence that MTOX is a flavoprotein. The following observations indicate that 8alpha-(S-cysteinyl)FAD is the covalent flavin in MSOX from Bacillus sp. B-0618 and MTOX. FMN-containing peptides, prepared by digestion of MSOX or MTOX with trypsin, chymotrypsin, and phosphodiesterase, exhibited absorption and fluorescence properties characteristic of an 8alpha-(S-cysteinyl)flavin and could be bound to apo-flavodoxin. The thioether link in the FMN-containing peptides was converted to the sulfone by performic acid oxidation, as judged by characteristic absorbance changes and an increase in flavin fluorescence. The sulfone underwent a predicted reductive cleavage reaction upon treatment with dithionite, releasing unmodified FMN. Cys315 was identified as the covalent FAD attachment site in MSOX from B. sp. B-0618, as judged by the sequence obtained for a flavin-containing tryptic peptide (GAVCMYT). Cys315 aligns with a conserved cysteine in MSOX from other bacteria, MTOX (Cys308) and pipecolate oxidase, a homologous mammalian enzyme known to contain covalently bound flavin. There is only one conserved cysteine found among these enzymes, suggesting that Cys308 is the covalent flavin attachment site in MTOX.
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PMID:Structure of the flavocoenzyme of two homologous amine oxidases: monomeric sarcosine oxidase and N-methyltryptophan oxidase. 1022 Mar 47


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