Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0272170 (SDS)
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Octopus glutathione transferase (GST) was enzymically active in aerosol-OT [sodium bis-(2-ethylhexyl)sulphosuccinate]/iso-octane reverse micelles albeit with lowered catalytic constant (kcat). The enzyme reaction rate was found to be dependent on the [H2O]/[surfactant] ratio (omega(o)) of the system with maximum rate observed at omega(o) 13.88, which corresponded to vesicles with a core volume of 64 nm3. According to the physical examinations, a vesicle of this size is barely large enough to accommodate a monomeric enzyme subunit. Dissociation of the enzyme in reverse micelles was confirmed by cross-linking of the associated subunits with glutaraldehyde and separation of the monomers and dimers with electrophoresis in the presence of SDS. The kinetic properties of the enzyme were investigated by steady-state kinetic analysis. Both GSH and 1-chloro-2,4-dinitrobenzene (CDNB) showed substrate inhibition and the Michaelis constant for CDNB was increased by 36-fold to 11.05 mM in reverse micelles. Results on the initial-velocity and product-inhibition studies indicate that the octopus GST conforms to a steady-state sequential random Bi Bi mechanism. The results from a log kcat versus pH plot suggest that amino acid residues with pKa values of 6.56 0.07 and 8.81 0.17 should be deprotonated to give optimum catalytic function. In contrast, the amino acid residue with a pKa value of 9.69 0.16 in aqueous solution had to be protonated for the reaction to proceed. We propose that the pKa1 (6.56) is that for the enzyme-bound GSH, which has a pKa value lowered by 1.40-1.54 pH units compared with that of free GSH in reverse micelles. The most probable candidate for the observed pKa2 (8.81) is Tyr7 of GST. The pKa of Tyr7 is 0.88 pH unit lower than that in aqueous solution and is about 2 pH units below the normal tyrosine. This tyrosyl residue may act as a base catalyst facilitating the dissociation of enzyme-bound GSH. The possible interaction of GST with plasma membrane in vivo is discussed.
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PMID:Kinetic mechanism of octopus hepatopancreatic glutathione transferase in reverse micelles. 861 35

In the present work, we have studied glutathione transferase (GST) activity and GST subunits distribution in the liver of young and aged rats kept under hypoxic or hyperoxic normobaric conditions as model of oxidative stress. A significant decrease of GST activity was detected in young hypoxic rat liver, whereas a significant increase occurred in aged hypoxic liver. No significant alteration of activity was obtained in both young and aged rat livers subjected to hyperoxic treatment. Substrate specificity measurements, SDS/PAGE analysis and reverse-phase HPLC, of GSH-affinity purified fractions were used to study the changes in the GST subunits pattern occurring in the liver of rat as a consequence of hypoxic and hyperoxic treatment. The results demonstrate that young and aged rat liver has a different constitutive GST subunit pattern which are markedly and differentially altered in hypoxia or hyperoxia. The hyperoxic treatment caused an increase of GST subunit 3 in aged, but not in young liver. In aged liver, both the hypoxic and hyperoxic treatment produced a decrease of GST subunit 4. After hypoxic treatment GST subunit 3 significantly increased in both young and aged liver. GST subunit 1a increased in both young and adult liver after hyperoxia. Following hypoxia a decrease of subunit 1a was seen in both young and aged liver. After hypoxic treatment, subunit 6 doubled in young, but not in aged, livers. It was concluded that the alterations in GST subunit expression occurring in the liver as a consequence of hypoxic or hyperoxic treatment respond to the necessity of a better protection of liver against the products of oxidative metabolism.
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PMID:Alteration of glutathione transferase subunits composition in the liver of young and aged rats submitted to hypoxic and hyperoxic conditions. 867 34

Microsomal glutathione transferase (GSTm) is activated up to fivefold by incubation with glutathione disulfide (GSSG). The process is reversed by the addition of an NADPH-regenerating system consisting of glutathione reductase and glucose 6-phosphate/glucose-6-phosphate dehydrogenase. By treating the microsomes at different GSH/GSSG ratios a Kox value of 0.047 is found, i.e., 21 times more GSSG than GSH is necessary to produce half-maximal activation. The Kox is independent of the total glutathione concentration, indicating that S-thiolation by GSH rather than interchain or intrachain disulfide bridge formation is responsible for activation. Further evidence for S-thiolation of GSTm comes from SDS-PAGE under nonreducing conditions and Western blotting. Treating microsomes with GSSG or with GSH and t-butyl hydroperoxide or cumene hydroperoxide results in the appearance of a second GSTm band at approximately 17.7 kDa in addition to the native band at 17.3 kDa, the size difference approximately corresponding to the molecular mass of glutathione. The 17.7-kDa band is not seen in the presence of mercaptoethanol. Microsomal preparations from rat livers perfused with t-butyl hydroperoxide or cumene hydroperoxide also contain both GSTm forms. We suggest that under oxidative stress the microsomal GST in the cell can be activated through direct hydroperoxide-mediated S-thiolation of the enzyme with GSH, its reversal occurring via a thiol exchange-mediated dethiolation imposed by the intracellular glutathione redox state.
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PMID:Protein S-thiolation and regulation of microsomal glutathione transferase activity by the glutathione redox couple. 880 37

Thioltransferase (TTase) activity was identified and partially purified from the ocular tissue for the first time. The enzyme activity depended on the presence of reduced glutathione (GSH), glutathione reductase (GR) and NADPH to reduce the disulfide bond in a synthetic substrate, hydroxyl ethyl disulfide (HEDS). Maximum activity was obtained in a pH 7.4 phosphate buffer at 30 degrees C. This enzyme distinguishes from other reducing enzymes such as thioredoxin that do not require GSH and GR for their catalytic activity. It also differs from the 52 kDa enzyme, protein disulfide isomerase by its smaller molecular size and its stability against heat treatment. TTase activity was higher in the epithelial layer but distributed evenly in the rest of the lens also, TTase showed similar activity in the lenses obtained from rats, pigs, bovine, guinea pigs, chick embryos and humans. The molecular weight of this enzyme was estimated to be 11.5 kDa on a SDS-PAGE system. Western blot analysis showed the protein reacted positively to the antibody raised by the purified pig liver TTase. Similarly the antibody raised by the partially purified lens enzyme reacted positively with the purified pig lever TTase. The presence of TTase in the lens was confirmed further with the slot blot analysis where it demonstrated a 32P-labeled cDNA from pig liver TTase hybridizing with the RNA in the pig lens or rabbit lens epithelium cells. Based on the above information it was concluded that the lens TTase is comparable to TTase from other tissues in its functional and structural properties. It is hypothesized that the lens TTase has a significant physiological role in sulfhydryl homeostasis in the lens by protecting the SH groups of the proteins from S-thiolation. It is speculated that, lens TTase may be primary antioxidant in the lens along with GSH and GR by protecting the vulnerable lens proteins against oxidative damage.
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PMID:Evidence for the presence of thioltransferase in the lens. 894 50

A mouse embryo culture model was used to determine whether embryonic prostaglandin H synthase (PHS)-catalyzed bioactivation and resultant oxidative damage to embryonic protein and DNA may constitute a molecular mechanism mediating phenytoin and benzo[a]pyrene teratogenesis. Embryos were explanted from CD-1 mouse dams on gestational day 9.5 (vaginal plug = day 1) and incubated for either 4 h (biochemistry) or 24 h (embryotoxicity) at 37 degrees C in medium containing either phenytoin (20 micrograms/ml, 80 microM), benzo[a]pyrene (10 microM), or their respective vehicles. As previously observed with phenytoin (Mol. Pharmacol.48: 112-120, 1995), embryos incubated with benzo[a]pyrene showed decreases in anterior neuropore closure, turning, yolk sac diameter, and somite development (p < .05). Addition of the antioxidative enzyme superoxide dismutase (SOD) substantially enhanced embryonic SOD activity (p < .05) and completely inhibited benzo[a]pyrene embryotoxicity (p < .05). Substantial PHS was detected in day 9.5 embryos using SDS/PAGE, anti-PHS antibody, and alkaline phosphatase-conjugated donkey anti-goat IgG. Embryonic protein oxidation was detected by the reaction of 0.5 mM 2,4-dinitrophenylhydrazine with protein carbonyl groups. This method was first validated by using a known hydroxyl radical-generating system consisting of vanadyl sulfate and H2O2, with bovine serum albumin or embryonic protein as the target. Embryonic proteins were characterized by SDS/PAGE, anti-dinitrophenyl antisera, and peroxidase-labeled goat anti-donkey IgG. Using enhanced chemiluminescence, the number and content of oxidized protein bands detected between 25 and 200 kDa were substantially increased by both phenytoin and benzo[a]pyrene. Addition of the reducing agent dithiothreitol, or SOD or catalase, decreased protein oxidation in phenytoin-exposed embryos. Both phenytoin (Mol. Pharmacol.48: 112-120, 1995) and benzo[a]pyrene enhanced embryonic DNA oxidation, determined by the formation of 8-hydroxy-2'-deoxyguanosine, as measured by high-performance liquid chromatography (HPLC) (p < .05). Phenytoin also enhanced the oxidation of embryonic glutathione (GSH) to its GSSG disulfide, as measured by HPLC (p < .05). These results provide direct evidence that, in the absence of maternal or placental processes, embryonic PHS-catalyzed bioactivation and reactive oxygen species-mediated oxidation of embryonic protein, thiols, and DNA may constitute a molecular mechanism mediating phenytoin and benzo[a]pyrene teratogenesis.
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PMID:Evidence for embryonic prostaglandin H synthase-catalyzed bioactivation and reactive oxygen species-mediated oxidation of cellular macromolecules in phenytoin and benzo[a]pyrene teratogenesis. 901 24

The inhibition of Saccharomyces cerevisiae aldehyde dehydrogenase (AlDH) by gaseous nitric oxide (NO) in solution and by NO generated from diethylamine nonoate was time and concentration dependent. The presence of oxygen significantly reduced the extent of inhibition by NO, indicating that NO itself rather than an oxidation product of NO such as N2O3 is the inhibitory species under physiological conditions. A cysteine residue at the active site of the enzyme was implicated in this inhibition based on the following observations: a) NAD+ and NADP+, but not reduced cofactors, significantly enhanced inhibition of AlDH by NO; b) the aldehyde substrate, benzaldehyde, blocked inhibition; and c) inhibition was accompanied by loss of free sulfhydryl groups on the enzyme. Activity of the NO-inactivated enzyme was readily restored by treatment with dithiothreitol (DTT), but not with GSH. This difference was attributed, in part, to a redox process leading to the formation of a cyclic DTT disulfide. Based on the chemistry deduced from model systems, the reaction of NO with AlDH sulfhydryls was shown to produce intramolecular disulfides and N2O. These disulfides were shown to be intrasubunit disulfides by nonreducing SDS-PAGE analysis of the NO- inhibited enzyme. Following complete inhibition of AlDH by NO, four of the eight titratable (Ellman's reagent) sulfhydryl groups of AlDH were found to be oxidized to disulfides. These results suggest that a) the sulfhydryl group of active site Cys-302 and a proximal cysteine are oxidized to form an intrasubunit disulfide by NO; b) only two of the four subunits of AlDH are catalytically active; and c) NO preferentially oxidizes sulfhydryl groups of the catalytically active subunits. A detailed mechanism for the inhibition of AlDH by NO is presented.
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PMID:Mechanism for the inhibition of aldehyde dehydrogenase by nitric oxide. 908 20

Trypanothione, the essential metabolite in the oxidant defense system of trypanosomatids, is synthesized by two distinct proteins, glutathionylspermidine synthetase and trypanothione synthetase. Glutathionylspermidine synthetase was purified to homogeneity from the trypanosomatid Crithidia fasciculata by aqueous two-phase systems and chromatography. The enzyme showed a specific activity of 38 micromol of glutathionylspermidine formed per min per mg of protein. Its molecular mass was 78 kDa in SDS-polyacrylamide gel electrophoresis, and it appeared predominantly monomeric in native polyacrylamide gel electrophoresis and gel filtration. The isoelectric point was at pH 4.6, and the pH optimum was near 7.6. Partial amino acid sequencing revealed homology with, but low similarity to, the glutathionylspermidine synthetase/amidase of Escherichia coli, and amidase activity was not detected in glutathionylspermidine synthetase of C. fasciculata. The kinetics of trypanosomatid glutathionylspermidine synthetase revealed a rapid equilibrium random mechanism with limiting Km values for Mg2+-ATP, GSH, and spermidine of 0.25 +/- 0.02, 2.51 +/- 0.33, and 0.47 +/- 0. 09 mM, respectively, and a kcat of 415 +/- 78 min-1. Partial reactions at restricted cosubstrate supply were not detected by 31P NMR, supporting the necessity of a quarternary complex formation for catalysis. ADP inhibited competitively with respect to ATP (Ki = 0. 08 mM) and trypanothione exerted a feedback inhibition competitive with GSH (Ki = 0.48 mM).
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PMID:Convenient isolation and kinetic mechanism of glutathionylspermidine synthetase from Crithidia fasciculata. 911 52

To investigate the effects of UV-B exposure on the protein solutions of different lens parts, rabbit lenses were separated into the equator (Eq), anterior cortex (Ac), nucleus (Nu) and posterior cortex (Pc). After homogenization, the water-soluble protein from each part was irradiated with UV-B at 0 to 0.225 J/cm2. Alterations in the content of protein SH, carbonyl groups, light scattering intensity and SDS-PAGE pattern were measured to compare the effect of UV-B on the protein solutions of various lens parts with or without additional GSH to test its preventive effect. The results showed that after UV-B irradiation, the protein sulfhydryl groups are gradually reduced. The nonprotein thiol (GSH added to the protein solution) was lost more rapidly than the protein sulfhydryl. The high molecular bands on the SDS-PAGE pattern mainly aggregated with disulfide. UV-B damage also increased the content of carbonyl groups and light scattering, irrespective of the lens parts. Lens proteins from the equator suffered the least damage while those of the nucleus were most strongly affected by UV-B exposure. This study suggests that the lens proteins from various lens parts have different responses to UV-B exposure; the sensitivity was in the following order: Eq < Ac < or = Pc < Nu.
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PMID:In vitro UV-B effect on lens protein solutions. 915 33

In order to study the role played by known and novel genes in growth control and neoplasia, we here compare the pEX and pGEX bacterial expression systems for recombinant oncoprotein production and for generation of specific antisera. The results of five pEX (MS2-c-Fos, MS2-Fra-1, MS2-JunD, bgal-c-Jun and bgal-JunB) and two pGEX [glutathione S-transferase (GSH)-JE/MCP-1 and GST-JunD] fusion-protein productions are presented. Higher (15-43-fold) yields are obtained with the pEX system, but only the pGEX system allows separation of the protein of interest from the fusion moiety by digestion with specific proteases. The degree of fusion-protein purification, as assessed by SDS/PAGE, is similar for both systems. Proteins produced by both systems were successfully used in the generation of specific antisera. The choice between the pEX and pGEX systems is dependent upon the specific recombinant protein produced.
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PMID:Use of pEX and pGEX bacterial heterologous protein expression systems for recombinant oncoprotein production and antisera generation. 919 74

Oxidative stress causes modification of cellular macromolecules and leads to cell damage. The objective of this study was to identify protein modifications that relate to thiol groups in human red blood cells under oxidative stress. With t-butyl hydroperoxide (t-BH) treatment, results of isoelectric focusing (IEF) analysis showed that two dithiothreitol-reversible modifications are observed, one toward the cathode and the other to the anode. Protein change toward the cathode was demonstrated to be hemoglobin oxidation, which gains a net positive charge, based on the same focus on IEF gels as hemoglobin and methemoglobin and molecular weight analysis by SDS-polyacrylamide gel electrophoresis (SDS-PAGE). Otherwise, the change toward the anode was the result of mixed disulfide formation between GSH and protein thiols. Based on the results of molecular weight analysis and its reversion from methemoglobin, protein formed mixed disulfides with GSH were also regarded as hemoglobin. As red blood samples were treated with diamide or GSSG, in addition to the mixed disulfides observed in t-BH-treated cells, additional hemoglobin-GSH mixed disulfide appeared. But the disappearance of this diamide-induced additional mixed disulfide by treating cells with t-BH after diamide treatment suggests that the increase of negative charges from GSH are offset by ferrohemoglobin oxidation to ferrihemoglobin. Additionally, other dithiothreitol-reversible modifications of one cell membrane protein, spectrin, were also observed from the formation of high molecular weight molecules as detected by SDS-PAGE. Results indicate that protein thiols in human red blood cells are susceptible to modification under oxidative stress. IEF analysis provides a useful tool to measure methemoglobin and hemoglobin GSH mixed disulfide formation.
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PMID:Protein thiol modifications of human red blood cells treated with t-butyl hydroperoxide. 930 84


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