EC:2.5.1.18 - FACTA Search

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Query: EC:2.5.1.18 (glutathione S-transferase)
22,582 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Recombinant glutathione S-transferase P (GST-P) was purified in a homogeneous state. Fatty acid analysis by gas-liquid chromatography-mass spectrometry (GC-MS) revealed that GST-P forms 1:1 complex with fatty acids, mostly palmitic acid or stearic acid, which were hardly isolated from the complex even through Lipidex 1,000 column chromatography at 37 degrees C. Temperature dependent analysis of 1H-NMR on the association between GST-P and fatty acids indicated that molecular motion of fatty acids were strongly restrained in a hydrophobic 'pocket' below the temperature of protein denaturation. On the other hand, there existed another hydrophobic ligand binding region, to which fatty acid and bilirubin would bind with relatively lower affinity. The binding region was determined to be at around 142-157 residues from amino terminus by the studies of GST-P binding to fatty acid-linked Sepharose and affinity labelings with either fluorescent fatty acid or bilirubin. The binding to this region noncompetitively inhibited the enzyme activity. Furthermore, circular dichroism (CD) analysis showed that the binding of hydrophobic ligands changed the secondary structure of GST-P, which suggested that the enzyme activity was regulated through conformational changes. As tryptophan 38 was assumed to locate at the active center from the study of site-directed mutagenesis, conformation of the active center was investigated by measuring the intrinsic tryptophan fluorescence. It showed that hydrophobic ligand binding caused the drastic conformational change, of which would be referred to the regulation of the enzyme activity.
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PMID:[Identification and characterization of hydrophobic ligand binding region in glutathione S-transferase P]. 844 4

Recombinant glutathione S-transferase P (GST-P) was purified in a homogeneous state. Fatty acid analysis of the enzyme revealed that the final enzyme preparation endogenously bound fatty acids, mostly palmitic acid or stearic acid, which were difficult to dissociate from the complex. Temperature-dependent analysis by 1H NMR indicated that the molecular motion of fatty acids was strongly restrained under physiological conditions, which was significantly different from that of serum albumin. On the other hand, there existed another hydrophobic ligand-binding region in GST-P, to which 1-amino-8-naphthalenesulfonic acid and bilirubin would bind with relatively lower affinity than the endogenously bound fatty acid. The hydrophobic ligand-binding region was determined to be around 141-156 residues from the N-terminus by procedures including association of the enzyme to fatty acid-linked Sepharose and affinity labeling with fluorescent fatty acid. Furthermore, circular dichroism analysis showed that the binding of hydrophobic ligand to GST-P produced a remarkable conformational change of the enzyme, which led to states devoid of transferase activity. In addition, the hydrophobic ligand binding caused a significant fluorescence quenching of tryptophan 38, which was assumed to be located at the active center of GST-P. It could be the result of a conformational change of the active center of the enzyme.
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PMID:Identification of the hydrophobic ligand-binding region in recombinant glutathione S-transferase P and its binding effect on the conformational state of the enzyme. 847 Aug 90

Subunit IV of Rhodobacter sphaeroides cytochrome b-c1 complex was over-expressed in Escherichia coli JM109 cells as a glutathione S-transferase fusion protein (GST-RSIV) using the expression vector, pGEX/RSIV. Maximum yield of soluble active recombinant fusion protein was obtained from cells harvested 3 h after induction of growth at 37 degrees C in LB medium. Subunit IV was released from the fusion protein by proteolytic cleavage with thrombin. When subjected to SDS-polyacrylamide gel electrophoresis, isolated recombinant subunit IV of R. sphaeroides cytochrome b-c1 complex. Although the isolated recombinant subunit IV is soluble in aqueous solution, it is in a highly aggregated form, with an apparent molecular mass of over 1000 kDa. The addition of detergent deaggregates the isolated protein, suggesting that the recombinant protein exists as a hydrophobic aggregation in aqueous solution. When the three-subunit core cytochrome b-c1 complex, purified from RS delta IV-adapted chromatophores containing a fraction of the wild type cytochrome b-c1 complex activity, was reacted with varying amounts of recombinant subunit IV, the activity increased as the subunit IV concentration increased. Maximum activity restoration was reached when 1 mol of subunit IV/mol of three-subunit core complex was used. The reconstituted cytochrome b-c1 complex is similar to the wild-type complex in molecular size, apparent Km for Q2H2, and inhibitor sensitivity, indicating that recombinant subunit IV is properly assembled into the active cytochrome b-c1 complex. A tryptophan residue in subunit IV was found to be involved in the interaction with the three-subunit core complex.
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PMID:Functional expression of subunit IV of Rhodobacter sphaeroides cytochrome b-c1 complex and reconstitution of recombinant protein with three-subunit core complex. 856 59

The AROM protein is a pentadomain protein catalysing steps two to six in the prechorismate section of the shikimate pathway in microbial eukaryotes. On the basis of amino acid sequence alignments and the properties of mutants unable to utilize quinic acid as a carbon source, the AROM protein has been proposed to be homologous throughout its length with the proteins regulating transcription of the genes necessary for quinate catabolism. The QUTR transcription repressor protein has been proposed to be homologous with the three C-terminal domains of the AROM protein and one-fifth of the penultimate N-terminal domain. We report here the results of experiments designed to overproduce the QUTR and AROM proteins and their constituent domains in Escherichia coli, the purpose being to facilitate domain purification and (in the case of AROM), complementation of E. coli aro- mutations in order to probe the degree to which individual domains are stable and functional. The 3-dehydroquinate dehydratase domain of the AROM protein and the 3-dehydroquinate dehydratase-like domain of the QUTR spectroscopy and fluorescence emission spectroscopy. The CD spectra were found to be virtually superimposable. The fluorescence emission spectra of both domains had the signal from the tryptophan residues almost completely quenched, giving a tyrosine-dominated spectrum for both the AROM- and QUTR-derived domains. This unexpected observation was demonstrated to be due to a highly unusual environment provided by the tertiary structure, as addition of the denaturant guanidine hydrochloride gave a typical tryptophan-dominated spectrum for both domains. The spectroscopy experiments had the potential to refute the biologically-based proposal for a common origin for the AROM and QUTR proteins; however, the combined biophysical data are consistent with the hypothesis. We have previously reported that the AROM dehydroquinate synthase and 3-dehydroquinate dehydratase are stable and functional as individual domains, but that the 5-enol-pyruvylshikimate-3-phosphate synthase is only active as part of the complete AROM protein or as a bi-domain fragment with dehydroquinate synthase. Here we report that the aromA gene (encoding the AROM protein) of Aspergillus nidulans contains a 53 nt intron in the extreme C-terminus of the shikimate dehydrogenase domain. This finding accounts for the previously reported observation that the AROM protein was unable to complement aroE- (lacking shikimate dehydrogenase) mutations in E. coli. When the intron is removed the correctly translated AROM protein is able to complement the E. coli aroE- mutation. An AROM-derived shikimate dehydrogenase domain is, however, non-functional, but function is restored in a bi-domain protein with e-dehydroquinate dehydratase. This interaction is not entirely specific, as substitution of the 3-dehydroquinate dehydratase domain with the glutathione S-transferase protein partially restores enzyme activity. Similarly an AROM-derived shikimate kinase domain is non-functional, but is functional as part of the complete AROM protein, or as a bi-domain protein with 3-dehydroquinate dehydratase.
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PMID:Comparative analysis of the QUTR transcription repressor protein and the three C-terminal domains of the pentafunctional AROM enzyme. 861 Nov 79

A conserved tyrosine plays a critical role in catalysis by mammalian glutathione S-transferases (GSTs) of the alpha-, mu-, and pi-classes, by forming a hydrogen bond to and stabilizing the thiolate form of glutathione. The hydrogen bonding properties of this tyrosine in the rat A1-1 GST (Tyr-9), in the absence and presence of ligands, have been studied by steady state and time-resolved fluorescence spectroscopy. In order to achieve this, the single tryptophan (Trp 21) found in the rat A1-1 GST has been replaced with the fluorometrically silent phenylalanine (W21F). Additionally, a double mutant lacking this tryptophan and the catalytic tyrosine (W21F:Y9F) has been constructed, and these mutants have been used as probes of ligand effects at Tyr-9. A comparison of the correlated excitation--emission spectra of the W21F mutant and the W21F-Y9F indicates that a red-shifted emission component is contributed by Tyr-9 with excitation bands at 255 and 300 nm, in the ligand-free enzyme. The pH-dependence of the intensity of these spectral cross-peaks is consistent with an active site tyrosine with a pKa of 8.1-8.3. Upon addition of GSH, the red-shifted component is quenched. Multifrequency phase/modulation fluorescence experiments qualitatively demonstrate that GSH causes a decrease in the average excited state lifetime on the red-edge of the spectrum of W21F but not of the W21F:Y9F spectrum. Steady state correlated difference spectra (W21F-W21F:Y9F) have been used to obtain a model for the excitation-emission correlated spectrum of Tyr-9, which indicates that Tyr-9 is heterogeneous at pH 7.5, with properties of both tyrosinate and "normal tyrosine". The tyrosinate fraction is eliminated, and the blue-shifted component becomes more intense upon addition of GSH conjugates, indicating that the weak hydrogen bond between Tyr-9 and thioethers has little charge-transfer character. The S-methyl GSH yields an "anomalous" spectrum at pH 7.5, which retains cross-peaks consistent with ionized tyrosinate. These results indicate that, in the absence of ligand, Tyr-9 forms a strongly polarized hydrogen bond or a fraction of the phenolic hydroxyl group is partially deprotonated. However, when a GSH conjugate with a sufficiently large hydrophobic group occupies the H-site, Tyr-9 is fully protonated, with little charge-transfer character.
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PMID:Ligand effects on the fluorescence properties of tyrosine-9 in alpha 1-1 glutathione S-transferase. 863 25

The frameshift protein p6* encoded directly upstream of the protease in the human immunodeficiency virus type 1 (HIV-1) pol reading frame is thought to be a natural inhibitor of protease activation and to play a role in the polyprotein processing of Gag and Gag-Pol precursors. To allow structural characterization of the p6* transframe protein, the p6* coding region was cloned into the vector pGEX-KG and expressed in Escherichia coli as a fusion protein with glutathione S-transferase (GST) under the control of the tac promoter. Thrombin cleavage of the construct resulted in a 70-amino-acid polypeptide which is extended by two additional residues at the N-terminus compared to the natural p6* sequence. The native purification procedure including an affinity and a size-exclusion chromatography step yielded sufficient amounts of highly pure protein suitable for NMR spectroscopy. Fluorescence, circular dichroism and 1H-NMR spectroscopy were applied to characterize the structure of protein. Two-dimensional NMR spectra provided essentially complete sequence-specific resonance assignments at pH 5.9. Although there is evidence for a helix-forming tendency in the N-terminus of the protein, the experiments indicate that p6* has no overall stable secondary or tertiary structure with the single tryptophan exposed in aqueous solution. However, the results reported herein open the way to characterize further the interaction of p6* with the HIV-1 protease in structural and functional in vitro studies.
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PMID:Sequence-specific resonance assignments of the 1H-NMR spectra and structural characterization in solution of the HIV-1 transframe protein p6. 864 76

Lipoprotein lipase (LPL), the major enzyme responsible for the hydrolysis of plasma triglycerides, promotes binding and catabolism of triglyceride-rich lipoproteins by various cultured cells. Recent studies demonstrate that LPL binds to three members of the low density lipoprotein (LDL) receptor family, including the LDL receptor-related protein (LRP), GP330/LRP-2, and very low density lipoprotein (VLDL) receptors and induces receptor-mediated lipoprotein catabolism. We show here that LDL receptors also bind LPL and mediate LPL-dependent catabolism of large VLDL with Sf 100-400. Up-regulation of LDL receptors by lovastatin treatment of normal human foreskin fibroblasts (FSF cells) resulted in an increase in LPL-induced VLDL binding and catabolism to a level that was 10-15-fold greater than in LDL receptor-negative fibroblasts, despite similar LRP activity in both cell lines. This indicates that the contribution of LRP to LPL-dependent degradation of VLDL is small when LDL receptors are maximally up-regulated. Furthermore studies in LRP-deficient murine embryonic fibroblasts showed that the level of LPL-dependent degradation of VLDL was similar to that in normal murine embryonic fibroblasts. LPL also promoted the internalization of protein-free triglyceride emulsions; lovastatin-treatment resulted in 2-fold higher uptake in FSF cells, indicating that LPL itself could bind to LDL receptors. However, the lower induction of emulsion catabolism as compared with native VLDL suggests that LPL-induced catabolism via LDL receptors is only partially dependent on receptor binding by LPL and instead is primarily due to activation of apolipoproteins such as apoE. A fusion protein between glutathione S-transferase and the catalytically inactive carboxyl-terminal domain of LPL (GST-LPLC) also induced binding and catabolism of VLDL. However GST-LPLC was not as active as native LPL, indicating that lipolysis is required for a maximal LPL effect. Mutations of critical tryptophan residues in GST-LPLC that abolished binding to VLDL converted the protein to an inhibitor of lipoprotein binding to LDL receptors. In solid-phase assays using immobilized receptors, LDL receptors bound to LPL in a dose-dependent manner. Both LPL and GST-LPLC promoted binding of VLDL to LDL receptor-coated wells. These results indicate that LPL binds to LDL receptors and suggest that the carboxyl-terminal domain of LPL contributes to this interaction.
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PMID:Lipoprotein lipase binds to low density lipoprotein receptors and induces receptor-mediated catabolism of very low density lipoproteins in vitro. 866 92

The glutathione S-transferases (GST) are a supergene family of phase II detoxification enzymes which catalyse the S-conjugation between glutathione and an electrophilic substrate. The active site can be divided into two adjacent functional regions, a highly specific G-site for binding the physiological substrate glutathione and a nonspecific H-site for binding nonpolar electrophilic substrates. Equilibrium and kinetic unfolding experiments employing tryptophan fluorescence and enzyme activity measurements were preformed to study the effect of ligand binding to the G-site on the unfolding and stability of the porcine class pi glutathione S-transferase against urea. The presence of glutathione caused a shift in the equilibrium-unfolding curves towards lower urea concentrations and enhanced the first-order rate constant for unfolding suggesting a destabilisation of the pGSTP1-1 structure against urea. The presence of either glutathione sulphonate or S-hexylglutathione, however, produced the opposite effect in that their binding to the G-site appeared to exet a stablising effect against urea. The binding of these glutathione analogues also reduced significantly the degree of cooperativity of unfolding indicating a possible change in the protein's unfolding pathway.
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PMID:Effect of glutathione, glutathione sulphonate and S-hexylglutathione on the conformational stability of class pi glutathione S-transferase. 876 97

Anthranilate synthase (AS, EC 4.1.3.27) catalyzes the conversion of chorismate into anthranilate, the biosynthetic precursor of both tryptophan and numerous secondary metabolites, including inducible plant defense compounds. The higher plant Ruta graveolens produces tryptophan and elicitor-inducible, anthranilate-derived alkaloids by means of two differentially expressed nuclear genes for chloroplast-localized AS alpha subunits, AS alpha 1 and AS alpha 2. Mechanisms that partition chorismate between tryptophan and inducible alkaloids thus do not entail chloroplast/cytosol separation of AS isoenzymes and yet might involve differential feedback regulation of pathway-specific AS alpha subunits. The two AS alpha isoenzymes of R. graveolens were expressed as glutathione S-transferase fusion proteins in Escherichia coli deletion mutants defective in AS activity and were purified to homogeneity. Differential sensitivity of the transformed E. coli strains toward 5-methyltryptophan, a false-feedback inhibitor of AS, was demonstrated. Characterization of affinity-purified AS alpha isoenzymes revealed that the noninducible AS alpha 2 of R. graveolens is strongly feedback inhibited by 10 microns tryptophan. In contrast, the elicitor-inducible AS alpha 1 isoenzyme is only slightly affected even by tryptophan concentrations 10-fold higher than those observed in planta. These results are consistent with the hypothesis that chorismate flux into biosynthesis of tryptophan and defense-related alkaloid biosynthesis in R. graveolens is regulated at the site of AS alpha isoenzymes at both genetic and enzymatic levels.
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PMID:Anthranilate synthase from Ruta graveolens. Duplicated AS alpha genes encode tryptophan-sensitive and tryptophan-insensitive isoenzymes specific to amino acid and alkaloid biosynthesis. 878 26

To determine the location of the non-substrate-ligand-binding region in mammalian glutathione S-transferases, fluorescence-resonance energy transfer was used to calculate distances between tryptophan residues and protein-bound 8-anilinonaphthalene 1-sulphonate (an anionic ligand) in the human class-alpha glutathione S-transferase, and in a human Trp28-->Phe mutant class-pi glutathione S-transferase. Distance values of 2.21 nm and 1.82 nm were calculated for the class-alpha and class-pi enzymes, respectively. Since glutathione S-transferases bind one non-substrate ligand/protein dimer, the ligand-binding region, according to the calculated distances, is found to be located in the dimer interface near the twofold axis. This region is the same as that in which the parasitic helminth Schistosoma japonicum glutathione S-transferase binds praziquantel, a non-substrate drug used to treat schistosomiasis [McTigue, M. A., Williams, D. R. & Tainer, J. A. (1995) J. Mol. Biol. 246, 21-27]. Since the overall folding topology is conserved and certain features at the dimer interface are similar throughout the superfamily, it is reasonable to expect that all cytosolic glutathione S-transferases bind non-substrate ligands in the amphipathic groove at the dimer interface.
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PMID:Determination of a binding site for a non-substrate ligand in mammalian cytosolic glutathione S-transferases by means of fluorescence-resonance energy transfer. 891 46

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