Curcumin-glutathione interactions and the role of human glutathione S-transferase P1-1

Curcumin (diferuloylmethane), a yellow pigment of turmeric with antioxidant properties has been shown to be a cancer preventative in animal studies. It contains two electrophilic alpha, beta-unsaturated carbonyl groups, which can react with nucleophilic compounds such as glutathione (GSH), but formation of the GSH-curcumin conjugates has not previously been demonstrated. In the present studies, we investigated the reactions of curcumin with GSH and the effect of recombinant human glutathione S-transferase(GST)P1-1 on reaction kinetics. Glutathionylated products of curcumin identified by FAB-MS and MALDI-MS included mono- and di-glutathionyl-adducts of curcumin as well as cyclic rearrangement products of GSH adducts of feruloylmethylketone (FMK) and feruloylaldehyde (FAL). The presence of GSTP1-1 significantly accelerated the initial rate of GSH-mediated consumption of curcumin in 10 mM potassium phosphate, pH 7.0, and 1 mM GSH. GSTP1-1 kinetics determined using HPLC indicated substrate inhibition (apparent K(m) for curcumin of 25+/-11 microM, and apparent K(i) for curcumin of 8+/-3 microM). GSTP1-1 was also shown to catalyze the reverse reaction leading to the formation of curcumin from GSH adducts of FMK and FAL.     

Inactivation of glutathione peroxidase by superoxide radical

The selenium-containing glutathione peroxidase, when in its active reduced form, was inactivated during exposure to the xanthine oxidase reaction. Superoxide dismutase completely prevented this inactivation, whereas catalase, hydroxyl radical scavengers, or chelators did not, indicating that O2 was the responsible agent. Conversion of GSH peroxidase to its oxidized form, by exposure to hydroperoxides, rendered it insensitive toward O2. The oxidized enzyme regained susceptibility toward inactivation by O2 when reduced with GSH. The inactivation by O2 could be reversed by GSH; however, sequential exposure to O2 and then hydroperoxides caused irreversible inactivation. Reactivity toward CN- has been used as a measure of the oxidized form of GSH peroxidase, whereas reactivity toward iodoacetate has been taken as an indicator of the reduced form. By these criteria both O2 and hydroperoxides convert the reduced form to oxidized forms. A mechanism involving oxidation of the selenocysteine residue at the active site has been proposed to account for these observations.     

Identification of a thioselenurane intermediate in the reaction between phenylaminoalkyl selenoxides and glutathione

Selenium has a long history of association with human health and disease, and a low concentration of selenium in plasma has been identified in epidemiological studies as a risk factor for several disorders associated with oxidative stress. This association suggests that organoselenium compounds capable of propagating a selenium redox cycle might supplement natural cellular defenses against oxidants, such as peroxynitrite and hydrogen peroxide. While several such organoselenium compounds are under active investigation as potential therapeutic agents, chemical characterization of reaction intermediates involved in their redox cycling has been problematical. We now report evidence that the reaction between phenylaminoalkyl selenoxides and glutathione (GSH) proceeds through the intermediacy of a thioselenurane species. The results of stopped-flow kinetic experiments were consistent with a rapid and stoichiometric initial reaction of GSH with selenoxide to generate a kinetically-detectable intermediate, followed by a slower reaction of this intermediate with a second molecule of GSH to produce the final selenide and GSSG products. Flow injection ESI-MS and ESI-MS/MS experiments confirmed that the reaction intermediate is indeed a thioselenurane. Final structural characterization of the thioselenurane intermediate was obtained from analysis of the daughter ions produced in flow injection ESI-MS/MS experiments. These results help to elucidate the chemical nature of the redox cycling of phenylaminoalkyl selenides, and represent, to our knowledge, the first evidence for the intermediacy of a thioselenurane species in the reaction of thiols with selenoxides.     

Determination of glutathione in biological material by flow-injection analysis using an enzymatic recycling reaction

A sensitive and specific assay for glutathione using a recycling reaction followed by spectrophotometric detection in a flow-injection analysis system is presented. The proposed method provides specific amplification of the response to glutathione by combined use of the enzyme GSSG reductase and the chromogenic reagent 5,5'-dithiobis(2-nitrobenzoic acid). Both oxidized (GSSG) and reduced (GSH) glutathione are detected, so that GSSG must be determined separately after alkylation of the GSH with N-ethylmaleimide. The sensitivity is controlled by the number of times the cycle occurs and therefore by the residence time of the sample in the reactor. This time depends on the reactor length and the flow rate. The influence of residence time, temperature, and enzyme concentration on the response has been studied and the optimum reaction conditions have been selected. The sample throughput is as high as 30 h(-1) and the detection limit is 1 pmol GSH at a signal-to-noise ratio of 3. The method has been evaluated by the quantification of GSH and GSSG in isolated hepatocytes. A high correlation between the new flow-injection analysis method and the original spectrophotometric batch assay has been found (slope = 1.039, intercept = 0.6, n = 216, r = 0.977). The main advantages of the proposed method are high sample throughout, high sensitivity, and good reproducibility.     

Heterogeneity of cellular glutathione among cells derived from a murine fibrosarcoma or a human renal cell carcinoma detected by flow cytometric analysis

Monochlorobimane (syn-(ClCH2, CH3)-1,5-diazabicyclo-[3.3.0]-octa-3,6-dione-2,8-dione; mBCl) forms a fluorescent adduct with glutathione (GSH), which has been used as a basis for flow cytometric analysis. While mBCl will react nonspecifically with many different thiols, preferential derivatization of GSH can be achieved by using a low concentration of mBCl, since the reaction with GSH is catalyzed by GSH S-transferase, and the nonenzymatic reaction is very slow (k = 3.3 x 10(-1) M-1 s-1 at 37 degrees C, pH 7.5). The rate of derivatization of cellular GSH can be 1000 times greater than predicted from the nonenzymatic reaction rate, although this factor can vary among cell lines. GSH values obtained by flow cytometry (FCM) agree well with those obtained by an enzymatic assay, over a wide range of GSH values, for EMT6/SF cells treated with L-buthionine sulfoximine to vary GSH content. FCM analysis of the GSH content of cells obtained by disaggregation of EMT6/SF tumors, grown in BALB/c mice, revealed a wide variation in single-cell GSH content. The data suggest that there are distinct subpopulations within these tumors, which can be partially characterized by GSH content, but may also have other distinguishing characteristics, such as enhanced sensitivity or resistance to cytotoxic agents. Heterogeneity in single-cell GSH content was also observed by FCM analysis of cells obtained by disaggregation of a biopsy of a human renal cell carcinoma. This result points to the potential value of FCM analysis of GSH in the identification and characterization of human tumor subpopulations which may be of clinical significance in the treatment of cancer by radiation or chemotherapeutic agents.     

Elucidation of the mechanism of selenoprotein glutathione peroxidase (GPx)-catalyzed hydrogen peroxide reduction by two glutathione molecules: a density functional study

The mechanism of the hydrogen peroxide reduction by two molecules of glutathione catalyzed by the selenoprotein glutatione peroxidase (GPx) has been computationally studied. It has been shown that the first elementary reaction of this process, (E-SeH) + H(2)O(2) --> (E-SeOH) + H(2)O (1), proceeds via a stepwise pathway with the overall barrier of 17.1 kcal/mol, which is in good agreement with the experimental barrier of 14.9 kcal/mol. During reaction 1, the Gln83 residue has been found to play a key role as a proton acceptor, which is consistent with experiments. The second elementary reaction, (E-SeOH) + GSH --> (E-Se-SG) + HOH (2), proceeds with the barrier of 17.9 kcal/mol. The last elementary reaction, (E-Se-SG) + GSH --> (E-SeH) + GS-SG (3), is initiated with the coordination of the second glutathione molecule. The calculations clearly suggest that the amide backbone of the Gly50 residue directly participates in this reaction and the presence of two water molecules is absolutely vital for the reaction to occur. This reaction proceeds with the barrier of 21.5 kcal/mol and is suggested to be a rate-determining step of the entire GPx-catalyzed reaction H(2)O(2) + 2GSH --> GS-SG + 2H(2)O. The results discussed in the present study provide intricate details of every step of the catalytic mechanism of the GPx enzyme and are in good general agreement with experimental findings and suggestions.     

Reactions of Pseudomonas aeruginosa pyocyanin with reduced glutathione

Pseudomonas aeruginosa is the most common cause of chronic and recurrent lung infections in patients with cystic fibrosis (CF) whose sputa contain copious quantities of P. aeruginosa toxin, pyocyanin. Pyocyanin triggers tissue damage mainly by its redox cycling and induction of reactive oxygen species (ROS). The reactions between reduced glutathione (GSH) and pyocyanin were observed using absorption spectra from spectrophotometry and the reaction products analysed by nuclear magnetic resonance imaging. Pyocyanin reacted with GSH non-enzymatically at 37 degrees C resulting in the production of red-brown products, spectophotometrically visible as a 480 nm maximum absorption peak after 24 h of incubation. The reaction was concentration-dependent on reduced glutathione but not on pyocyanin. Minimizing the accessibility of oxygen to the reaction decreased its rate. The anti-oxidant enzyme catalase circumvented the reaction. Proton-NMR analysis demonstrated the persistence of the original aromatic ring and the methyl-group of pyocyanin in the red-brown products. Anti-oxidant agents having thiol groups produced similar spectophotometrically visible peaks. The presence of a previously unidentified non-enzymatic GSH-dependent metabolic pathway for pyocyanin has thus been identified. The reaction between pyocyanin and GSH is concentration-, time-, and O(2)-dependent. The formation of H(2)O(2) as an intermediate and the thiol group in GSH seem to be important in this reaction.     

Semiquantitative bioluminescent assay of glutathione

A novel technique has been developed for semiquantitative detection of glutathione (GSH) in small volumes of liquid samples. GSH is detected via enzymatic linkage to the NADP/NADPH + H⁺ redox system through glutathione reductase. Accumulated NADPH is measured via the bioluminescent FMN oxidoreductase bacterial luciferase reaction. A linear correlation is obtained between bioluminescence intensity of the luciferase reaction and the GSH content of the liquid sample. Possible applications of this procedure are discussed. © 1998 John Wiley & Sons, Ltd.     

Role of glutathione in affecting the radiosensitivity of molecular and cellular systems

Summary It has previously been shown that radioinduced organic radicals can be repaired by hydrogen donation from glutathione (GSH) and this repair is in competition with oxygen (damage fixation).In this paper the influence of exogenous glutathione on the radiation response of the enzyme alcoholdehydrogenase (YADH), DNA in vitro, andE. coli B/r cells has been investigated.GSH is observed to protect YADH essentially by free radical scavenging mechanisms in both presence or absence of oxygen. The same mechanism seems operate in the radioprotection afforded by GSH to DNA in vitro.E. coli B/r cells are protected at higher extent by GSH than its oxidized form (GSSG); the possibility that GSH penetrate into bacterial cells more easily that GSSG can explain their different behaviour.None of the three systems studied has provided definitive support for the occurrence of the hydrogen donation reaction in the radioprotective mechanisms of GSH versus biomolecules and bacterial cells.     

Glutathione and cinnamic acid: natural dietary components used in preventing the process of browning by inhibition of Polyphenol Oxidase in apple juice

Consumer demands for 'freshness' in processed foods has been given increasing attention by food processing industries by searching for minimally processed products. Polyphenol Oxidase (PPO) mediated browning is a major cause of undesirable flavors and nutritional losses in fruit juices. Here the anti-browning efficiency of glutathione (GSH, reduced form) and cinnamic acid (CA) in apple juice is evaluated. It was observed that the rate of the browning reaction could be efficiently delayed using GSH and CA, which act as inhibitors of PPO. Kinetic studies confirm that GSH and CA are non-competitive and competitive inhibitors of PPO respectively.     

Interaction of glutathione and sodium selenite in vitro investigated by electrospray ionization tandem mass spectrometry

Selenite has been found to be an active catalyst for the oxidation of sulphhydryl compounds, such as glutathione (GSH). Considering the biological importance of GSH oxidation and the implication of sulphhydryl compounds in selenium poisoning and other biological activities, more information on selenite oxidation of GSH in enzyme-free conditions is desirable. Herein, we describe glutathione and sodium selenite simply mixed in aqueous solutions. The interaction products and transient intermediate are identified and characterized using electrospray ionization (ESI) tandem mass spectrometry. In the first step, GSH directly reacts to form diglutathione (GSSG) and unstable selenodiglutathione (GS-Se-SG). Then selenodiglutathione further reacted with remaining GSH to form diglutathione and elemental selenium, Se(0). As the amount of GSSG significantly increased or acidity of the solution increased, the redox potential of glutathione [E(0')(GSSG/2GSH) approximately -250 mV (NHE)] significantly shifted to the positive direction. This makes the GSSG react with elemental selenium formed in the solution, which can be demonstrated by another unstable intermediate ion identified at m/z 418 by mass spectrometry with the elemental composition of [GSS-Se](-). The reaction mechanism between GSH and sodium selenite has been proposed according to the ESI-MS, NMR and UV-vis spectrometric measurements.     

Kinetics and mechanism of reduction of ferricytochrome c by glutathione and L-cysteine: a comparative study

The kinetics and mechanism of the reduction of ferricytochrome c [Cyt c(III)] by substrates namely glutathione (GSH) and L-cysteine (L-cys) have been investigated spectrophotometrically employing [substrate]T > [Cyt c(III)]T. The reaction exhibits first order dependence in [substrate]T and [Cyt c(III)]T. The pseudo-first order rate constant increases with an increase in pH, indicating that the conjugate base form of the HCyt c(III) is a better oxidant than the parent HCyt c(III). The electron transfer rate constants between the oxidants and GSH for both the k1 and k2 paths are found to be greater than that with L-cysteine. Hence, GSH is a better reductant of Cyt c(III) as compared to L-cysteine. A suitable mechanism has been proposed on the basis of experimental findings. The deprotonation constant for HCyt c(III) and the second order rate constants of k1 and k2 paths for the present reaction at 25 degrees C have been determined.     

Ebselen has dehydroascorbate reductase and thioltransferase-like activities

Ebselen (2-phenyl-1,2-benzisoselenazol-3(2H)-one), a seleno-organic compound, has been reported to mimic glutathione peroxidase (GPX). Since bovine erythrocyte GPX showed dehydroascorbic acid (DHA) reductase and thioltransferase (TTase) activities, ebselen was also examined for DHA reductase and TTase-like activities. Evidence is reported that, in the presence of GSH, ebselen catalyzed the in vitro reduction of DHA to L-ascorbic acid in a dose-dependent manner. Using S-sulfocysteine and GSH as co-substrates, ebselen catalyzed the in vitro formation of glutathione disulfide in a dose-dependent manner, thereby acting as a TTase mimic. 1-Chloro-2,4-dinitrobezene (CDNB), a co-substrate with GSH for glutathione S-transferase, was used to measure rates of adduct formation with ebselen pretreated with GSH and compared with GSH alone. The reaction rate was proportional to ebselen, and ebselen was about 250 times more reactive than GSH on an equimolar basis. The DHA reductase and TTase-like activities, in addition to the powerful nucleophilic reactivity of ebselen selenol, may contribute to ebselen's significant anti-inflammatory and anti-oxidative properties in vivo.     

Unequivocal evidence in support of the nonenzymatic redox coupling between glutathione/glutathione disulfide and ascorbic acid/dehydroascorbic acid.

Experiments were performed to evaluate the nonenzymatic reaction between glutathione (GSH) and dehydroascorbic acid (DHA). Though both ascorbic acid and glutathione disulfide (GSSG) are formed from this reaction, previous work has focused almost exclusively on measurements of ascorbic acid. In contrast, there is very little information about the formation of GSSG under the same conditions as those used to produce ascorbic acid. The emphasis on ascorbic acid stems from the fact that a spectrophotometric technique is available for its measurement, whereas 1H-NMR or an amino acid analyzer has been used to measure GSSG. The present experiments use a simple, rapid method for accurately and precisely measuring the concentrations of GSSG in a solution. The spectrophotometric (340 nm) procedure uses NADPH and glutathione reductase; analysis time is very short, many replicate samples can be tested and as little as 0.05-0.1 mM GSSG can be detected. Using this method, it is shown that there is an equimolar production of GSSG and ascorbic acid from GSH and DHA and that the decrease in GSH is stoichiometrically related to the increase in the concentration of GSSG. The present findings provide additional insight into the interaction between the GSH/GSSG redox couple and the ascorbic acid/DHA redox couple.     

Glutathione and Cinnamic Acid: Natural Dietary Components Used in Preventing the Process of Browning by Inhibition of Polyphenol Oxidase in Apple Juice

Consumer demands for ‘freshness’ in processed foods has been given increasing attention by food processing industries by searching for minimally processed products. Polyphenol Oxidase (PPO) mediated browning is a major cause of undesirable flavors and nutritional losses in fruit juices. Here the anti-browning efficiency of glutathione (GSH, reduced form) and cinnamic acid (CA) in apple juice is evaluated. It was observed that the rate of the browning reaction could be efficiently delayed using GSH and CA, which act as inhibitors of PPO. Kinetic studies confirm that GSH and CA are non-competitive and competitive inhibitors of PPO respectively.     

Nicotinamide adenine dinucleotide phosphate-regenerating system coupled to a glutathione-reductase microtiter method for determination of total glutathione concentrations in adherent growing cancer cell lines

Improvements in the traditional glutathione (GSH)-reductase recycling method for determining total glutathione levels in adherent growing cells have been achieved by eliminating the direct use of expensive nicotinamide adenine dinucleotide phosphate (NADPH) and normalizing the levels of GSH to moles/liter instead of the more usual but more error-prone method of normalizing with cellular protein. A glucose-6-phosphate-dehydrogenase auxiliary reaction has been added to the microtiter-adapted enzyme method of Tietze; thus NADP(+) and glucose-6-phosphate replace NADPH in the method. This modification lowers the possibility for substrate inhibition of the reductase by high levels of NADPH during the initial phase of the reaction while at the same time reducing the assay costs by 75-85%. To calculate the cellular concentration of GSH, the number of cells used for the GSH determination, estimated by counting cell nuclei of benzalkonium chloride-lysed cells with a Coulter Counter Z2, and the average cell volume, also determined with the Coulter Counter, are multiplied to give the total sample volume. The quotient of the amount of GSH found in the cells and the total sample volume yields the GSH concentration in moles/liter. The assay has been validated with respect to precision (+/-2.6%), relative accuracy (-4.2 %), linearity (r(2)=0.98), linear range (0.5-10 microM), and limit of detection (80 pmol). Recovery was cell line dependent and ranged between 70 and 103% in the six cell lines. As an application of this method, the GSH concentrations in six human cancer cell lines were determined, without and with a 24-h preincubation with 200 microM D,L-buthionine-S,R-sulfoximine (BSO), an inhibitor of GSH biosynthesis. As expected, BSO lowered GSH levels on the average 85%.     

Glutathione peroxidase in lens and a source of hydrogen peroxide in aqueous humour

1. Glutathione peroxidase has been demonstrated in cattle, rabbit and guineapig lenses. 2. The enzyme will oxidize GSH either with hydrogen peroxide added at the start of the reaction or with hydrogen peroxide generated enzymically with glucose oxidase. 3. No product other than GSSG was detected. 4. Oxidation of GSH can be coupled with oxidation of malate through the intermediate reaction of glutathione reductase and NADPH₂. 5. Traces of hydrogen peroxide are present in aqueous humour: it is formed when the ascorbic acid of aqueous humour is oxidized. 6. Hydrogen peroxide will diffuse into the explanted intact lens and oxidize the contained GSH. The addition of glucose to the medium together with hydrogen peroxide maintains the concentration of lens GSH. 7. Glutathione peroxidase in lens extracts will couple with the oxidation of ascorbic acid. 8. It is suggested that, as there is only weak catalase activity in lens, glutathione peroxidase may act as one link between the oxygen of the aqueous humour and NADPH₂.     

Covalent coupling of reduced glutathione with ribose: loss of cosubstrate ability to glutathione peroxidase

Glycation (nonenzymatic glycosylation of proteins) is known to be increased as a result of hyperglycaemia in diabetes. Moreover, cell glutathione concentration has been found to be lower in diabetics and such depletion may impair the cell defence against toxic radical species. Ribose being a potent reducing sugar expected to be increased in cells of diabetics where the pentose phosphate pathway is enhanced, its putative condensation with glutathione was investigated. Reduced glutathione (GSH) was incubated with ribose and the structure of the resultant product was assessed by mass spectrometry, as well as the measurement of its remaining thiol group. A covalent reaction clearly occurred between the reducing sugar and GSH, to give an adduct named N-ribosyl-1-glutathione. This adduct appears to be the Amadori product resulting from the condensation of the primary amine group of GSH with the aldehyde group of ribose. Interestingly, the adduct could not be used as a proper substrate by glutathione peroxidase although it keeps its thiol group. We conclude that the coupling of GSH with a monosaccharide such as ribose might contribute to the decreased cell GSH and glutathione peroxidase activity observed in diabetics.     

晶状体生化的研究:正常和亚硒酸钠诱发白内障大鼠晶状体中与谷胱甘肽代谢有关的三种酶活性的测定

测定了用亚硒酸钠诱发的大鼠白内障晶状体中谷胱甘肽过氧化物酶(GSH-Px)、谷胱甘肽还原酶(GSSG-R)和谷胱甘肽硫转移酶(GSH-S)的活性,并与正常晶休中这三种酶的活性作了比较。结果表明,核浊浑期晶状体中GSH-Px的活性比正常晶状体的高一倍,但在整个晶状体浑浊时降低,GSSG-R的活性变化与GSH-PX相似,这两种酶在代谢上是相关的。GSH-S的活性在核浑浊期不改变,但在完全浑浊后降低。