Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C1260386 (GSH)
 38,102 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The major focus of this work was to investigate how altered protein thiol redox homeostasis affects radiation-induced cell death. We used the cells of wild-type CHO cell line K1, the CHO cell line E89, which is null for G6PD activity, and a radiation-sensitive CHO cell line, XRS5. The protein-thiol redox status of cells was altered with cell-permeable disulfides, hydroxyethyldisulfide (HEDS) or lipoate. HEDS is primarily reduced by thioltransferase (glutaredoxin), with GSH as the electron donor. In contrast, lipoate is reduced by thioredoxin reductase. HEDS was reduced at a greater rate than lipoate by G6PD-containing K1 (wild-type) cells. Reduction of disulfides by G6PD-deficient cells was significantly slower with HEDS as substrate and was nearly absent with lipoate. The rate of reduction of HEDS by E89 cells decelerated to near zero by 30 min, whereas the reduction continued at nearly the same rate during the entire measurement period for K1 cells. HEDS treatment decreased the GSH and protein thiol (PSH) content more in G6PD-deficient cells than in G6PD-containing cells. On the other hand, lipoate did not significantly alter the protein thiol, but it increased the GSH in K1 cells. Acute depletion of GSH by l-buthionine-sulfoximine (l-BSO) in combination with dimethylfumarate significantly decreased the rate of reduction of HEDS by K1 cells close to that of G6PD-deficient cells. Prior GSH depletion by l-BSO alone significantly decreased the PSH in glucose-depleted E89 cells exposed to HEDS, but this did not occur with K1 cells. The radiation response of G6PD-deficient cells was significantly sensitized by HEDS, but HEDS did not have this effect on K1 cells. The DNA repair-deficient XRS5 CHO cells displayed the same capacity as K1 cells for HEDS reduction, and like K1 cells the XRS5 cells were not sensitized to radiation by HEDS treatment. Deprivation of glucose, which provides the substrate for G6PD in the oxidative pentose phosphate cycle, decreased the rate of bioreduction of HEDS and lipoate in G6PD-containing cells to the level in G6PD-deficient cells. In the absence of glucose, HEDS treatment diminished non-protein thiol and protein thiol to the same level as those in G6PD-deficient cells and sensitized the K1 cells to HEDS treatment. However, depletion of glucose did not alter the sensitivity of XRS5 cells in either the presence or absence of HEDS. Overall the results suggest a major role for pentose cycle control of protein redox state coupled to the activities of the thioltransferase and thioredoxin systems. The results also show that protein thiol status is a critical factor in cell survival after irradiation.
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PMID:Radiation response of cells during altered protein thiol redox. 1264 93

In a previous study, we found that treatment of rat heart mitochondria with H(2)O(2) resulted in a decline and subsequent recovery in the rate of state 3 NADH-linked respiration. These effects were shown to be mediated by reversible alterations in NAD(P)H utilization and in the activities of specific Krebs cycle enzymes alpha-ketoglutarate dehydrogenase (KGDH) and succinate dehydrogenase. The purpose of the current study was to examine potential mechanism(s) by which H(2)O(2) reversibly alters KGDH activity. We report here that inactivation is not simply due to direct interaction of H(2)O(2) with KGDH. In addition, incubation of mitochondria with deferroxamine, an iron chelator, or 1,3-dimethyl-2-thiourea, an oxygen radical scavenger, prior to addition of H(2)O(2) did not alter the rate or extent of inactivation. Thus, inactivation does not appear to involve a more potent oxygen radical formed upon metal-catalyzed oxidation. Inactive KGDH from H(2)O(2)-treated mitochondria was reactivated with dithiothreitol, implicating oxidation of a protein sulfhydryl(s). However, the thioredoxin system had no effect, indicating that enzyme inactivation is not due to the formation of intra- or intermolecular disulfide(s) or a sulfenic acid. Upon incubation of mitochondria with H(2)O(2), reduced GSH levels fell rapidly prior to enzyme inactivation but recovered at the same time as enzyme activity. Importantly, treatment of inactive KGDH with glutaredoxin facilitated the GSH-dependent recovery of KGDH activity. Glutaredoxin is characterized as a specific and efficient catalyst of protein deglutathionylation. Thus, the results of the current study indicate that KGDH activity appears to be modulated through enzymatic glutathionylation and deglutathionylation. These studies demonstrate a novel mechanism by which KGDH activity and mitochondrial function can be modulated by redox status.
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PMID:Reversible inactivation of alpha-ketoglutarate dehydrogenase in response to alterations in the mitochondrial glutathione status. 1268 Jul 78

Although excess amounts of oxidative stress damage proteins and nucleotides, small amounts of oxidative stress transduce intracellular signals for cellular activation, differentiation and proliferation. Reduction/oxidation(redox) regulation is defined as a biological response to maintain homeostasis against oxidative stress. Thioredoxin, a 12 kD small protein with a redox-active dithiol/disulfide in the conserved active site: -Cys-Gly-Pro-Cys-, is a key molecule for redox regulation as well as glutathione(GSH). Thioredoxin is induced by a variety of oxidative stresses and secreted from cells. Thioredoxin plays crucial roles as a redox-regulator of intracellular signal transduction and as a radical scavenger. Plasma levels of thioredoxin are good biomarkers for oxidative stress. Thioredoxin-transgenic mice are more resistant to cerebral infarction, infection or inflammation and survive longer than control mice. Administration of thioredoxin may have a good potential for anti-aging and anti-stress effects. Redox regulation mechanisms by thioredoxin and other thioredoxin family members will clarify the pathophysiology of oxidative stress-associated disorders.
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PMID:[Experimental and clinical aspects of oxidative stress and redox regulation]. 1269 Jun 27

Apoptosis can be regulated at multiple levels. A number of proteins with regulatory function in cell death are sensitive to cellular redox environment. The antioxidant glutathione (GSH) and redox-sensitive proteins, thioredoxin and glutathione S-transferase, thus regulate cell death pathways by modulating the redox state of specific thiol residues of target proteins including stress kinases, transcription factors, and caspases. GSH in mitochondria plays an important role in the integrity of mitochondrial proteins and lipids known to play a vital role in the permeabilization of mitochondrial membranes and release of proapoptotic factors. The regulation of mitochondrial GSH (mGSH) is determined by its uptake from the cytosol which is dependent on appropriate membrane dynamics. The deposition of cholesterol in mitochondria induced by alcohol intake impairs this translocation, resulting in severe depletion of mGSH and in sensitization to apoptosis stimuli. Although the interaction of proapoptotic proteins with mitochondria initiates apoptotic pathways, recent data indicate that the mitochondrial trafficking of glycosphingolipids, e.g., ganglioside GD3, induced by apoptotic stimuli is a key event that sets off mitochondrial-dependent apoptotic cascades.
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PMID:Redox regulation and signaling lipids in mitochondrial apoptosis. 1272 81

Accumulating evidence strongly suggests that oxidative stress underlies aging processes and that calorie restriction (CR) retards aging processes, leading to an extended lifespan for various organisms. Recent studies revealed that the anti-aging action of CR depends on its anti-oxidative mechanism. However, at present, the status of glutathione (GSH) and thioredoxin (Trx) system, two major thiol redox systems in animal cells during aging and its modulation by CR has not fully been explored. The purpose of this study is two-fold: one, to determine whether these two systems in rat kidney are altered as a consequence of aging; two, to determine whether these systems can be modulated by anti-oxidative CR. The results of our study showed that GSH and GSH-related enzyme activities decreased with age in ad libitum (AL)-fed rats, while CR rats consistently showed resistance to decreases in these activities. Data from the present data further showed that while Trx and Trx reductase (TrxR) in cytoplasm decrease with age in AL-fed rats, CR prevents these decreases. In contrast, we also found that the nuclear translocation of the redox regulators, Trx and Ref-1, increase with age, which was suppressed in CR rats. Therefore, increases in nuclear Trx and Ref-1 during aging may result in the up-regulation of redox-sensitive transcription factors, such as NF-kappaB or AP-1, via the interaction of Ref-1 and Trx in a redox-dependent manner. Our conclusion is that a redox imbalance occurs during aging and that redox changes are minimized through the anti-oxidative action of CR.
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PMID:Modulation of glutathione and thioredoxin systems by calorie restriction during the aging process. 1274 31

Tryparedoxin peroxidases (TXNPx) are peroxiredoxin-type enzymes that detoxify hydroperoxides in trypanosomatids. Reduction equivalents are provided by trypanothione [T(SH)2] via tryparedoxin (TXN). The T(SH)2-dependent peroxidase system was reconstituted from TXNPx and TXN of T. brucei brucei (TbTXN-Px and TbTXN). TbTXNPx efficiently reduces organic hydroperoxides and is specifically reduced by TbTXN, less efficiently by thioredoxin, but not by glutathione (GSH) or T(SH)2. The kinetic pattern does not comply with a simple rate equation but suggests negative co-operativity of reaction centers. Gel permeation of oxidized TbTXNPx yields peaks corresponding to a decamer and higher aggregates. Electron microscopy shows regular ring structures in the decamer peak. Upon reduction, the rings tend to depolymerise forming open-chain oligomers. Co-oxidation of TbTXNPx with TbTXNC43S yields a dead-end intermediate mimicking the catalytic intermediate. Its size complies with a stoichiometry of one TXN per subunit of TXNPx. Electron microscopy of the intermediate displays pentangular structures that are compatible with a model of a decameric TbTXNPx ring with ten bound TbTXN molecules. The redox-dependent changes in shape and aggregation state, the kinetic pattern and molecular models support the view that, upon oxidation of a reaction center, other subunits adopt a conformation that has lower reactivity with the hydroperoxide.
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PMID:Kinetics and redox-sensitive oligomerisation reveal negative subunit cooperativity in tryparedoxin peroxidase of Trypanosoma brucei brucei. 1275 91

The high content of glutathione (GSH) in the lens is believed to protect thiols in structural proteins and enzymes for proper biological functions. The lens has both biosynthetic and regenerating systems for GSH to maintain its large pool size. However, ageing lenses or lenses under oxidative stress show an extensively diminished size of GSH pool with some protein thiols being S-thiolated by oxidized non-protein thiols to form protein-thiol mixed disulfides, either as protein-S-S-glutathione (PSSG) or protein-S-S-cysteine (PSSC) or protein-S-S-gamma-glutamylcysteine. It was shown in an H(2)O(2)-induced cataract model that PSSG formation precedes a cascade of events before cataract formation, starting with protein disulfide crosslinks, protein solubility loss and high molecular weight aggregation. Furthermore, this early oxidative damage in protein thiols can be spontaneously reversed in H(2)O(2) pretreated lenses if the oxidant is removed in time. This dethiolation process appears to have mediated through a redox-regulating enzyme, thioltransferase (TTase), which is ubiquitously present in microbial, plant and animal tissues, including the lens. The GSH-dependent, low molecular weight (11.8 kDa) cytosolic enzyme plays an important role in oxidative defense and can modulate key metabolic enzymes in the glycolytic pathway. The enzyme repairs oxidatively damaged proteins/enzymes through its unique catalytic site with a vicinal cysteine moiety, which can specifically dethiolate protein-S-S-glutathione and restore protein free SH groups for proper enzymatic or protein functions. Most importantly, it has been demonstrated that thioltransferase has a remarkable resistance to oxidation (H(2)O(2)) in cultured human and rabbit lens epithelial cells under oxidative stress conditions when other oxidation defense systems of GSH peroxidase and GSH reductase are severely inactivated. A second repair enzyme, thioredoxin (TRx), which is NADPH-dependent, is widely found in many lower and higher life forms of life. It can dethiolate protein disulfides and thus is an extremely important regulator for redox homeostasis in the cells. Thioredoxin has been recently found in the lens and has been shown to participate in the repair process of oxidatively damaged lens proteins/enzymes. These two enzymes may work synergistically to regulate and repair thiols in lens proteins and enzymes, keeping a balanced redox potential to maintain the function of the lens.
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PMID:Redox regulation in the lens. 1289 45

Oxidative stress evokes various cellular events, including activation of transcription factors, apoptosis, and cell cycle arrest. Accumulating evidence shows that reduction/oxidation (redox) plays an important role in the regulation of apoptosis and cell cycle arrest elicited by oxidative stress. Cellular redox is controlled by the thioredoxin (TRX) and glutathione (GSH) systems. TRX and GSH systems regulate cell growth and cell death by the activation of transcription factors, the sensitivity of cells to cytokines and growth factors, and the components of the apoptosis pathways. This brief review describes the current knowledge on the redox regulation of cell growth and apoptosis.
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PMID:Redox regulation of cell growth and cell death. 1295 15

Multiple sequence alignments of the eight glutathione (GSH) transferase homologues encoded in the genome of Escherichia coli were used to define a consensus sequence for the proteins. The consensus sequence was analyzed in the context of the three-dimensional structure of the gst gene product (EGST) obtained from two different crystal forms of the enzyme. The enzyme consists of two domains. The N-terminal region (domain I) has a thioredoxin-like alpha/beta-fold, while the C-terminal domain (domain II) is all alpha-helical. The majority of the consensus residues (12/17) reside in the N-terminal domain. Fifteen of the 17 residues are involved in hydrophobic core interactions, turns, or electrostatic interactions between the two domains. The results suggest that all of the homologues retain a well-defined group of structural elements both in and between the N-terminal alpha/beta domain and the C-terminal domain. The conservation of two key residues for the recognition motif for the gamma-glutamyl-portion of GSH indicates that the homologues may interact with GSH or GSH analogues such as glutathionylspermidine or alpha-amino acids. The genome context of two of the homologues forms the basis for a hypothesis that the b2989 and yibF gene products are involved in glutathionylspermidine and selenium biochemistry, respectively.
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PMID:Conserved structural elements in glutathione transferase homologues encoded in the genome of Escherichia coli. 1463 20

The multifunctional enzyme thioredoxin-glutathione reductase (TGR) was purified to homogeneity from the soluble fraction of Taenia crassiceps metacestode (cysticerci). Specific activities of 17.5 and 4.7 U mg(-1) were obtained with Plasmodium falciparum thioredoxin and GSSG, respectively, at pH 7.75. Under the same conditions, Km values of 17, 15, and 3 microM were respectively calculated for thioredoxin, GSSG and NADPH. The kcat/Km ratio of T. crassiceps TGR for both thioredoxin and GSSG falls in the range observed for typical thioredoxin reductases and glutathione reductases. Purified enzyme also showed glutaredoxin activity, with a specific activity of 19.2 U mg(-1) with hydroxyethyl disulfide as substrate. Both thioredoxin and GSSG disulfide reductase activities were fully inhibited by nanomolar concentrations of the gold compound auranofin, supporting the existence of an essential selenocysteine residue. Relative molecular mass of native enzyme was 136,000 +/- 3000, while the corresponding value per subunit, obtained under denaturing conditions, was 66,000 +/- 1000. These results suggest TGR exists as a dimeric protein. Isoelectric point of the enzyme was at pH 5.2. Moderate or high concentrations of GSSG, but neither thioredoxin nor NADPH, resulted in a markedly hysteretic kinetic, characterized by a lag time before the steady state velocity was reached. The magnitude of the lag time was dependent on GSSG and enzyme concentration. Preincubation of the enzyme with micromolar concentrations of GSH or DTT abolished the hysteresis, suggesting that a thiol-disulfide exchange mechanism is involved.
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PMID:Purification, characterization and kinetic properties of the multifunctional thioredoxin-glutathione reductase from Taenia crassiceps metacestode (cysticerci). 1466 13


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