KEGG:D02011 - FACTA Search

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

We studied the FAD-induced in vitro stimulation of lenticular glutathione reductase in riboflavin-deficient rats. The stimulatory effect of FAD on lenticular glutathione reductase in rats fed a B2-deficient diet for 4 weeks was remarkably higher than in paired control rats fed a B2-supplemented basal diet and control rats had ad libitum access to a B2-supplemented basal diet. The in vitro FAD stimulation effect on rat lenticular glutathione reductase represents a sensitive indicator of the B2 deficient status.
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PMID:FAD-induced in vitro activation of glutathione reductase in the lens of B2 deficient rats. 671 61

The mode of binding of NADPH and oxidized glutathione to the flavoenzyme glutathione reductase has been determined by x-ray crystallography. Furthermore, two intermediates of the reaction have been produced in the crystal and have been structurally elucidated. All these analyses were done at 0.3 nm resolution. The results allow the stereochemical description of the mechanism of the enzyme. The dinucleotide NADPH is bound in an extended conformation with the nicotinamide ring stacking onto the re-face of the flavin part of FAD, and adenine located at the protein surface. The binding of NADPH results in the 2-electron reduced form of the enzyme, EH2. This form has also been analyzed without any ligand bound. In EH2 the redoxactive disulfide bridge of the protein, which lies at the si-face of the flavin ring, is opened and the sulfur of Cys-58 moves by about 0.1 nm into a position where it can attack one of the sulfurs of the substrate oxidized glutathione. This interchange leads to a mixed glutathione-protein disulfide, which can be stabilized in crystals and has been analyzed. By selectively reacting Cys-58 with iodoacetamide the crystalline enzyme can be blocked in its EH2 state. The imidazole of His-467' is near to all sulfurs taking part in the disulfide bridge exchange and is therefore certainly crucial for catalysis. The crystallographic results establish that electrons flow from NADPH to the substrate GSSG via flavin and the redoxactive protein disulfide bridge. This is consistent with the scheme that has been postulated from biochemical, spectroscopic, and model studies.
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PMID:The catalytic mechanism of glutathione reductase as derived from x-ray diffraction analyses of reaction intermediates. 682 32

ETF Dehydrogenase is an iron sulfur flavoprotein responsible for the transfer of electrons between electron transfer flavoprotein (ETF) and CoQ of the electron transport chain. We have determined the resonance Raman spectrum of this enzyme observing in the process at least seven of thirteen flavin bands in the 1100cm-1-1600 cm-1 region of the Raman spectrum. The positions of three of these bands, II, IX, and X (see Figure I and Table I for band numbering system) in ETF dehydrogenase is very similar to their positions in aqueous solution of flavins in which water is hydrogen bonded to N-1, N-5, C=0(2), C=0(4), and N-H(3) of flavin. Conversely the positions of the flavin Raman bands are considerably shifted from those of flavin in nonhydrogen bonding solvent. The positions of bands II, IX, and X are nearly identical to those in the flavoprotein glutathione reductase; x-ray structural investigations on this enzyme indicate that there is extensive hydrogen bonding between FAD and protein in this molecule. A previous study in our laboratory has demonstrated that metal complexation at N-5 and C=0(4) with either Ru or Ag produces large shifts in the positions of Raman bands II, VI, IX, and X. None of these shifts are observed in ETF dehydrogenase indicating that there is no direct inner sphere coordination of Fe to flavin. In addition to the Raman bands of flavin observed in our spectrum, we also observe one band that is in the Fe-S stretching region observed for a variety of Fe-S proteins. This band is located at 331 cm-1. The frequency of the band corresponds to the 335 cm-1 band associated with the strongest Fe-S stretching mode in the 4Fe-4S protein ferrodoxin from C. pasterianum. The observed frequency is quite different from that of the 3Fe-3S proteins such as ferrodoxin(II) from D. gigas. Finally, ETF dehydrogenase shows no loss of activity or visual evidence of photodegradation in the laser beam as most other FeS proteins do.
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PMID:Resonance Raman studies of ETE dehydrogenase (an iron sulfur flavoprotein). 687 Aug 91

The chain fold of the FAD-binding domain of p-hydroxybenzoate hydroxylase resembles the chain folds of the two nucleotide-binding domains of glutathione reductase. This fold consists of a four-stranded parallel beta-sheet sandwiched between a three-stranded antiparallel beta-sheet and alpha-helices. The nucleotides bind in similar positions relative to this chain fold. The best superposition of the folds has been established and geometrically quantified, giving rise to an equivalencing scheme for 110 residue positions, of which only four residues are identical in all three domains. It is discussed whether this chain fold is also present in a number of other FAD-binding proteins with known sequence. After the second strand of the parallel beta-sheet both FAD-binding domains contain long chain excursions, which make intimate contacts to rather distant parts of the respective molecules. In the environment of the isoalloxazine rings we observe interesting similarities. In both enzymes the si-face of this ring is covered by polypeptide, and only the re-face is accessible for the cofactor NADPH. Furthermore, there is a long alpha-helix in each enzyme, which points with its N-terminal start to the O-2 alpha region of isoalloxazine. These helices are spatially in the same position with respect to the isoalloxazine ring but are at quite different positions along the polypeptide chain. Since they can stabilize a negative charge around O-2 alpha, they may be important for the catalytic processes.
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PMID:Comparison of the three-dimensional protein and nucleotide structure of the FAD-binding domain of p-hydroxybenzoate hydroxylase with the FAD- as well as NADPH-binding domains of glutathione reductase. 687 63

Riboflavin status was studied in 156 older healthy people living at home in The Netherlands by assaying erythrocyte glutathione reductase (with and without FAD). The average activation coefficient of glutathione reductase was found to be 1.42 +/- 0.19. 7% of the population studied showed cataract (based on the eye examination). It seems that no correlation exists between cataract and riboflavin deficiency.
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PMID:Correlation between cataract and glutathione metabolism. 688 4

The magnetic circular dichroic (MCD) spectra of oxidized and reduced flavins are recorded in various solvents. They are shown to be sensitive to flavin environment. The MCD spectra of oxidized and reduced lipoamide dehydrogenase are reported. In the oxidized enzyme the sign of the B term associated with the 27 000-cm-1 band is reversed from free flavins. This is attributed to interaction of the disulfide with the short-axis dipole of FAD. The sign reversal is also present in a closely related disulfide enzyme, glutathione reductase, but absent in glucose oxidase. In the half-reduced enzyme, the appearance of an A term at 18 180 cm-1 is attributable to a charge-transfer complex with a thiolate anion as donor. Insensitivity of the term's energy and intensity to the redox state of flavin suggests that a protein residue may accept or stabilize the thiolate charge transfer.
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PMID:Magnetic circular dichroism studies on the active-site flavin of lipoamide dehydrogenase. 689 75

Extensive amino acid sequence homology has been found between nine tryptic peptides of pig heart lipoamide dehydrogenase (NADH:lipoamide oxidoreductase, EC 1.6.4.3] and the sequence of human erythrocyte glutathione reductase [NAD(P)H:glutathione oxidoreductase, EC 1.6.4.2]. The average homology is 40%. Six lipoamide dehydrogenase peptides are homologous with segments of the two parts of the FAD domain of glutathione reductase, one with the NADPH domain, and two with the interface domain. Thus, the homology extends throughout the molecule.
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PMID:Amino acid sequence homology between pig heart lipoamide dehydrogenase and human erythrocyte glutathione reductase. 695 34

Two-electron reduced glutathione reductase from yeast reacted with iodoacetamide is alkylated almost exclusively in the nascent thiol nearer the amino terminus of the protein. The charge-transfer absorbance, maximal at 530 nm, characteristic of the two-electron reduced enzyme is not lost as the alkylation proceeds, and the product has a spectrum virtually identical with that of the two-electron reduced enzyme. This observation demonstrates that the thiol alkylated is not the charge-transfer-donor thiolate which interacts with the FAD. The spectrum of the monoalkylated derivative is stable in the presence of oxidized glutathione, indicating that the charge-transfer-donor thiol is not involved in interchange with the substrate in the native enzyme. Thus, the nascent thiols produced upon two-electron reduction of glutathione reductase have distinct functions, interchange with the substrate and interaction with the FAD. Treatment of the monoalkylated derivative with the apolar phenylmercuric acetate eliminates the charge-transfer interaction. The spectrum of the resulting species is similar to that of the oxidized enzyme but less resolved and blue shifted by 10 nm. The dependence on pH of the absorbance associated with the thiolate to FAD charge-transfer interaction in native two-electron reduced glutathione reductase is biphasic, with pK values at approximately 4.8 and 7.4. By analogy with glyceraldehyde-3-phosphate dehydrogenase and papain, these data indicate that the thiolate is stabilized by an adjacent basic residue. The pK 7.4 is associated with the titration of the base to give the ion pair, and the pK of 4.8 is associated with the titration of the thiolate. Unlike lipoamide dehydrogenase, glutathione reductase is sufficiently stable to allow titration with dithionite at pH 3.7. The spectrum at this pH is essentially the same as that of the monoalkylated derivative treated with phenylmercuric acetate. The changes with pH are completely reversible.
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PMID:Glutathione reductase from yeast. Differential reactivity of the nascent thiols in two-electron reduced enzyme and properties of a monoalkylated derivative. 701 96

Glutathione reductase (Mr 2 x 52 500), a flavoenzyme of known three-dimensional structure, catalyses the reduction of glutathione disulfide by NADPH. This paper describes the primary structure of the FAD-binding domain which ranges from AcAla-1 to Gly-157. The three CNBr-produced fragments (69, 10 and 80 residues) of the domain were fractionated further by enzymatic and chemical methods; isolated peptides were sequenced mainly by automatic solid-phase Edman degradation. The tryptic peptides were overlapped by chymotryptic peptides. A fragment which results from cleavage at the acid-labile bond between Asp-135 and Pro-136 supplied peptides for overlapping the CNBr-produced fragments. In addition, many peptides were ordered and overlapped by computerized comparison with a complete sequence guessed from the electron density map. With one exception the computer method and the chemical alignment gave the same results. The sequence data are discussed in the light of the secondary and tertiary structure (Schulz et al. (1978) Nature (Lond.) 273, 120--124]. The 17 N-terminal residues are not visible in the electron density map. Consequently our numbering scheme differs from that of Schulz et al. by approximately 20 residues. Acetylation of the N terminus and an unusual composition of the following residues may serve to protect the loose N-terminal section of the protein against proteolysis in situ. The four cysteinyl residues of the FAD domain are of special interest. Cys-2 at the tip of the N-terminal extension is likely to be involved in the aggregation behaviour of glutathione reductase. Cys-58 and Cys-63 (formerly Cys-41 and Cys-46) represent the enzyme's redox-active dithiol. Cys-90 with its location at the twofold axis forms a disulfide bridge with Cys-90 of the other peptide chain of the enzyme. This might be related to the fact that both peptide chains contribute to each of the two active centers. In view of the interchain disulfide bridge glutathione reductase should be regarded as a monomeric protein. The sequence of the FAD-binding domain was compared with the sequence of the NADPH-binding domain of glutathione reductase using a computer program. As discussed, the scarcity of sequence similarities does not argue against the assumption that the two nucleotide-binding domains of glutathione reductase originated by gene duplication. The pyrophosphate moiety of FAD binds to a part of the polypeptide chain which in geometric structure, in topology and in sequence resembles the phosphate loops of other nucleotide-binding proteins and of flavodoxin. Using the phosphate loop as a reference, the N-terminal sequence of five flavoproteins can be aligned. The results of Williams et al. on the sequence of lipoamide dehydrogenase (EC 1.6.4.3) and our data on glutathione reductase (EC 1.6.4.2) show clearly that these two mechanistically similar enzymes possess homologous structures.
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PMID:Glutathione reductase from human erythrocytes: amino-acid sequence of the structurally known FAD-binding domain. 703 15

1. Sequence analysis of the NADPH domain (residues 158--293) and of the interface domain (365--478) was based on 12 CNBr fragments, which were isolated using ion-exchange chromatography and paper methods. Fragments with more than 15 residues were digested further with trypsin and chymotrypsin. The isolated peptides were sequenced by automated solid-phase Edman degradation. All sequenced peptides were ordered and overlapped by computerized comparisons with a complete sequence guessed from the electron density map of the protein. In the case of short CNBr fragments, this alignment was confirmed by the sequence analysis of protein fragments resulting from incomplete CNBr cleavage. 2. In the NADPH domain, residue 197, which is involved in an induced-fit mechanism, was identified as a tyrosine. The structure of the NADPH domain is probably homologous with the NAD domain of lipoamide dehydrogenase and with the FAD domain of several proteins, but not with NADPH domains of known chain-fold in other proteins. 3. The paper completes the sequence analysis of glutathione reductase so that the enzyme is now known in atomic detail. The numbering scheme of the chemically determined sequence will be used henceforth in crystallographic studies also. As inferred from the sequence data each of the two identical chains contains 478 amino acid residues, the composition being Cys10, Asp21, Asn17, Thr31, Ser31, Glu29, Gln11, Pro24, Gly43, Ala42, Val44, Met15, Ile29, Leu34, Tyr13, Phe14, Lys34, His16. Arg17, and Trp3. From these data an Mr of 2 x 51 600 was calculated for the FAD-free apoenzyme and an Mr of 2 x 42 400 for the holoenzyme.
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PMID:Glutathione reductase from human erythrocytes. The sequences of the NADPH domain and of the interface domain. 706 May 51

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