EC:1.8.1.4 - FACTA Search

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)

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

A series of straight chain N-alkymaleimides was shown to simultaneously inactivate the reductase, transhydrogenase and diaphorase activities of yeast glutathione reductase (NAD(P)H: oxidized-glutathione oxidoreductase, EC 1.6.4.2.) at pH 7.5 and 25 degrees C. Apparent second-order rate constants for the inactivation of all enzyme activities exhibited parallel increases with increasing chainlength from C-2 through C-7 of the alkyl substituent of the enhanced binding of maleimides through nonpolar interactions with the enzyme. Reduction of the active site disulfide with NADPH was required prior to addition of maleimide for inactivation to occur. NADP, AcPyADP, SNADP, AADP, and oxidized glutathione all protected the enzyme from inactivation. 2'AMP, 3' AMP, 2'-phospho-5' AMP, 2'-phospho5'-ADP and 2'-phospho-ADP-ribose although all coenzyme-competitive inhibitors failed to protect the enzyme from N-ethylmaleimide inactivation. N-Phenyl and N-alkylmaleimides covalently modified two, of six available sulfhydryl groups per subunit. No other amino acid residues were modified. The reactivity of these sulfhydryl groups was at least two orders of magnitude higher than any reported for the N-ethylmaleimide reaction with many other 'essential sulfhydryl' enzymes. No change in the charge transfer band of the reduced enzyme was observed upon complete inactivation by N-ethyl, N-heptyl or N-phenylmaleimide. The retention of the charge transfer band after selective modification of two sulfhydryl groups suggests the involvement of a third reactive sulfhydryl group in the functioning of the yeast enzyme. No inactivation was observed when coenzymatically reduced enzyme was incubated with the site-specific sulfhydryl reagent, diazotized AADP.
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PMID:Simultaneous inactivation of the catalytic activities of yeast glutathione reductase by N-alkylmaleimides. 701 85

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

Three flavin derivatives modified at the 2'-position of the flavin N-10 ribityl side chain were synthesized: arabinoflavin, 2'-F-2'-deoxyarabinoflavin, and 2'-deoxyriboflavin. These were converted to the FAD level with FAD synthetase. Apoproteins of lipoamide dehydrogenase, glutathione reductase, and mercuric reductase, a family of flavoprotein oxidoreductases, were reconstituted with these flavins. Significant reduction of the catalytic activities was observed with the modified enzymes. During anaerobic reduction of the modified enzymes with substrate or dithiothreitol, decreased thermodynamic stability of the two-electron reduced enzyme forms (EH2) and the accumulation of the four-electron reduced forms (EH4) noted. This effect was more pronounced in case of arabino-FAD-reconstituted enzymes than with the other two. It was found that NAD+ binding influences the interaction between the flavin and the reduced disulfide in the 2'-F-arabino-FAD-lipoamide dehydrogenase, presumably by altering the relative oxidation-reduction potentials. 19F NMR data were obtained for different forms of the 2'-F-arabino-FAD-lipoamide dehydrogenase, which suggest marked conformational changes from one form to the other. The 19F NMR data for the oxidized forms of all three 2'-F-arabino-FAD proteins suggest that the fluorine experiences very similar chemical environments at the active sites.
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PMID:Chemical modification of the N-10 ribityl side chain of flavins. Effects on properties of flavoprotein disulfide oxidoreductases. 749 74

The flavoprotein thioredoxin reductase catalyzes the reduction of the small redox protein thioredoxin by NADPH. Thioredoxin reductase contains a redox active disulfide and is a member of the pyridine nucleotide-disulfide oxidoreductase family of flavoenzymes that includes lipoamide dehydrogenase, glutathione reductase, trypanothione reductase, mercuric reductase, and NADH peroxidase. The structure of thioredoxin reductase has recently been determined from X-ray crystallographic data. In this paper, we attempt to correlate the structure with a considerable body of mechanistic data and to arrive at a mechanism consistent with both. The path of reducing equivalents in catalysis by glutathione reductase and lipoamide dehydrogenase is clear. To envisage the path of reducing equivalents in catalysis by thioredoxin reductase, a conformational change is required in which the NADPH domain rotates relative to the FAD domain. The rotation moves the nascent dithiol from its observed position adjacent to the re surface of the flavin ring system toward the protein surface for dithiol-disulfide interchange with the protein substrate thioredoxin and moves the nicotinamide ring of NADPH adjacent to the flavin ring for efficient hydride transfer. Reverse rotation allows reduction of the redox active disulfide by the reduced flavin. This requires that the enzyme pass through a ternary complex; the kinetic evidence for such a complex is discussed.
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PMID:Mechanism and structure of thioredoxin reductase from Escherichia coli. 755 16

Reduction of exogenous lipoic acid to dihydrolipoate is known to occur in several mammalian cells and tissues. Dihydrolipoate is a potent radical scavenger, and may provide significant antioxidant protection. Because lipoic acid appears in the bloodstream after oral administration, we have examined the reduction of exogenous lipoate by human erythrocytes. Normal human erythrocytes reduced lipoate to dihydrolipoate only in the presence of glucose; deoxyglucose did not substitute for glucose, indicating that the reduction of lipoate requires glucose metabolism. Furthermore, the reduction was shown to be NADPH dependent. Erythrocytes isolated from a human subject with a genetic deficiency of glucose-6-phosphate dehydrogenase (and, therefore, deficient in the formation of NADPH) did not reduce lipoate. Dehydroepiandrosterone, a specific inhibitor of glucose-6-phosphate dehydrogenase, inhibited lipoate reduction. Our findings imply that some of the reduction of exogenous lipoic acid is catalysed by glutathione reductase, a flavoprotein dehydrogenase; mitomycin C, an inhibitor of FAD-dependent reductases, inhibited lipoate reduction by erythrocytes, and glutathione reductase purified from human erythrocytes was observed to reduce lipoic acid in a cell-free system. We further explored these findings with erythrocyte ghosts and liposomes. Our results indicate that a transport system exists for alpha-lipoic acid and dihydrolipoate; resealed erythrocyte ghosts, containing trapped lipoamide dehydrogenase and pyridine nucleotides, reduced externally added lipoate. By contrast, liposomes prepared with enzyme and pyridine nucleotides did not catalyze reduction of lipoate. This work indicates that uptake of exogenous lipoate and reduction to dihydrolipoate by normal human erythrocytes may contribute to oxidant protection in the human bloodstream.
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PMID:Reduction and transport of lipoic acid by human erythrocytes. 763 70

Multiple sequence alignments including the enterococcal NADH peroxidase and NADH oxidase indicate that residues Ser38 and Cys42 align with the two cysteines of the redox-active disulfides found in glutathione reductase (GR), lipoamide dehydrogenase, mercuric reductase, and trypanothione reductase. In order to evaluate those structural determinants involved in the selection of the cysteine-sulfenic acid (Cys-SOH) redox centers found in the two peroxide reductases and the redox-active disulfides present in the GR class of disulfide reductases, NADH peroxidase residues Ser38, Phe39, Leu40, and Ser41 have been individually replaced with Cys. Both the F39C and L40C mutant peroxidases yield active-site disulfides involving the new Cys and the native Cys42; formation of the Cys39-Cys42 disulfide, however, precludes binding of the FAD coenzyme. In contrast, the L40C mutant contains tightly-bound FAD and has been analyzed by both kinetic and spectroscopic approaches. In addition, the L40C and S41C mutant structures have been determined at 2.1 and 2.0 A resolution, respectively, by X-ray crystallography. Formation of the Cys40-Cys42 disulfide bond requires a movement of Cys42-SG to a new position 5.9 A from the flavin-C(4a) position; this is consistent with the inability of the new disulfide to function as a redox center in concert with the flavin. Stereochemical constraints prohibit formation of the Cys41-Cys42 disulfide in the latter mutant.
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PMID:An L40C mutation converts the cysteine-sulfenic acid redox center in enterococcal NADH peroxidase to a disulfide. 771 Oct 38

The reduction of exogenous alpha-lipoic acid to dihydrolipoate by mammalian cells and tissues confers additional antioxidant protection to the cell. Both (R+) and (S-) isomers of alpha-lipoic acid were analyzed as substrates with glutathione reductase from several sources and with mammalian lipoamide dehydrogenase. Mammalian glutathione reductase catalyzed faster reduction of (S)-lipoic acid (1.4-2.4-fold greater activity) than of (R)-lipoic acid, whereas lipoamide dehydrogenase had a very marked preference for (R)-lipoic acid (18-fold greater activity) over (S)-lipoic acid. Mammalian glutathione reductase showed better affinity for (S)-lipoic acid substrate; Km values were 3.5 mM for (S)-lipoic acid and and 7 mM for (R)-lipoic acid. Glutathione reductase from yeast reduced lipoic acid less efficiently than the mammalian enymes, had a Km for both stereoisomers of about 10 mM, and showed little stereospecificity. Although (S)-lipoic acid is not formed in nature, these findings indicate that exogenous (S)-lipoic acid may have a useful role as an antioxidant for mammalian systems.
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PMID:Glutathione reductase and lipoamide dehydrogenase have opposite stereospecificities for alpha-lipoic acid enantiomers. 782 93

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