The DinB superfamily includes novel mycothiol, bacillithiol, and glutathione S-transferases

The superfamily of glutathione S-transferases has been the subject of extensive study; however, Actinobacteria produce mycothiol (MSH) in place of glutathione, and no mycothiol S-transferase (MST) has been identified. Using mycothiol and monochlorobimane as substrates, an MST activity was detected in extracts of Mycobacterium smegmatis and purified sufficiently to allow identification of MSMEG_0887, a member the DUF664 family of the DinB superfamily, as the MST. The identity of the M. smegmatis and homologous Mycobacterium tuberculosis (Rv0443) enzymes was confirmed by cloning, and the expressed proteins were found to be active with MSH but not bacillithiol (BSH) or glutathione (GSH). Bacillus subtilis YfiT is another member of the DinB superfamily, but this bacterium produces BSH. The YfiT protein was shown to have S-transferase activity with monochlorobimane when assayed with BSH but not with MSH or GSH. Enterococcus faecalis EF_3021 shares some homology with MSMEG_0887, but En. faecalis produces GSH but not MSH or BSH. Cloned and expressed EF_0321 was active with monochlorobimane and GSH but not with MSH or BSH. MDMPI_2 is another member of the DinB superfamily and has been previously shown to have mycothiol-dependent maleylpyruvate isomerase activity. Three of the eight families of the DinB superfamily include proteins shown to catalyze thiol-dependent metabolic or detoxification activities. Because more than two-thirds of the sequences assigned to the DinB superfamily are members of these families, it seems likely that such activity is dominant in the DinB superfamily.     

Assessment of cellular reduced glutathione content in Pseudokirchneriella subcapitata using monochlorobimane

The green alga Pseudokirchneriella subcapitata has been extensively used for the assessment of adverse impacts of pollutants. Glutathione is involved in antioxidant defence and drug detoxification. Intracellular reduced glutathione (GSH) concentration can be used as an indicator of the health of cells. This work describes a simple and fast fluorescent cell-based assay for the evaluation of intracellular GSH in the alga P. subcapitata, using monochlorobimane (mBCl). Metabolically active algal cells incubated with 50?μmol?L^?1 mBCl form fluorescent bimane–glutathione (B-SG) adducts that can be measured fluorometrically. The distribution of GSH (B-SG adducts) in whole cells can be observed by epifluorescence microscopy, in the form of blue fluorescent spots. Depletion of cellular GSH with iodoacetamide, inhibition of glutathione S-transferase with ethacrynic acid or heat-induced death of the cells inhibited the formation of fluorescent adducts in the presence of mBCl. The fluorometric assay, using the 96-well microplate format, was able to detect GSH depletion in algal cells. This cell-based assay can be used to evaluate decreases in GSH content due to exposure to toxicants. This assay is amenable to automation and may be useful in high-throughput toxicity screening using the alga P. subcapitata.     

Quantitative in vivo measurement of glutathione in Arabidopsis cells

A new, non-destructive assay is described to quantify cytoplasmic glutathione (GSH) levels in vivo in single cells or populations of cells from Arabidopsis suspension cultures. Cytoplasmic GSH was labelled with monochlorobimane (MCB) in situ to give a fluorescent GSH-bimane (GSB) conjugate. At low (10-100 microM) concentrations of MCB, labelling was mediated by a glutathione S-transferase, which confers specificity for GSH. HPLC analysis of MCB-labelled low molecular-weight thiols showed that the assay measures the total GSH pool, including the oxidized glutathione. The progress curve for the labelling could be described using Michaelis-Menten kinetics with an apparent KM of 40 microM and Vmax of 470 micromol lcyt -1 min-1. There was no evidence for de novo synthesis of GSH during the labelling period of 2 h, suggesting that control of GSH synthesis is not mediated by feedback control of gamma-glutamylcysteine synthetase in this system. The total cellular level of GSH was calculated from the plateau value of the progress curve, after appropriate calibration, as 830-942 nmol g-1 FW. The volume fraction of cytoplasm was measured from serial optical sections of bimane-labelled cells collected by confocal laser scanning microscopy (CLSM) with excitation 442 nm, or two-photon laser scanning microscopy (TPLSM) with excitation 770 nm. A value of 42 +/- 3% cytoplasm was determined by manual segmentation, and a value of 37 +/- 2% using stereological techniques. Using these figures, values for cytoplasmic [GSH] were estimated to be between 2.7 +/- 0.3 and 3.2 +/- 0.3 mM for cell populations. In addition, measurement of GSH levels in individual cells using CLSM and TPLSM gave values of 3.0 +/- 0.5 and 3.5 +/- 0.7 mM, respectively.     

Two-photon imaging of glutathione levels in intact brain indicates enhanced redox buffering in developing neurons and cells at the cerebrospinal fluid and blood-brain interface

Glutathione is the major cellular thiol present in mammalian cells and is critical for maintenance of redox homeostasis. However, current assay systems for glutathione lack application to intact animal tissues. To map the levels of glutathione in intact brain with cellular resolution (acute tissue slices and live animals), we have used two-photon imaging of monochlorobimane fluorescence, a selective enzyme-mediated marker for reduced glutathione. Previously, in vitro experiments using purified components and cultured glial cells attributed cellular monochlorobimane fluorescence to a glutathione S-transferase-dependent reaction with GSH. Our results indicate that cells at the cerebrospinal fluid or blood-brain interface, such as lateral ventricle ependymal cells (2.73 +/- 0.56 mm; glutathione), meningeal cells (1.45 +/- 0.09 mm), and astroglia (0.91 +/- 0.08 mm), contain high levels of glutathione. In comparison, layer II cortical neurons contained 20% (0.21 +/- 0.02 mm) the glutathione content of nearby astrocytes. Neuronal glutathione labeling increased 250% by the addition of the cell-permeable glutathione precursor N-acetylcysteine indicating that the monochlorobimane level or glutathione S-transferase activity within neurons was not limiting. Regional mapping showed that glutathione was highest in cells lining the lateral ventricles, specifically ependymal cells and the subventricular zone, suggesting a possible function for glutathione in oxidant homeostasis of developing neuronal progenitors. Consistently, developing neurons in the subgranular zone of dentate gyrus contained 3-fold more glutathione than older neurons found in the neighboring granular layer. In conclusion, mapping of glutathione levels in intact brain demonstrates a unique role for enhanced redox potential in developing neurons and cells at the cerebrospinal fluid and blood-brain interface.     

Glutathione in Intact Vacuoles: Comparison of Glutathione Pools in Isolated Vacuoles,Plastids, and Mitochondria from Roots of Red Beet

Proportions between oxidized and reduced glutathione forms were determined in vacuoles isolated from red beet (Beta vulgaris L.) taproots. The pool of vacuolar glutathione was compared with glutathione pools in isolated plastids and mitochondria. The ratio of glutathione forms was assessed by approved methods, such as fluorescence microscopy with the fluorescent probe monochlorobimane (MCB), high-performance liquid chromatography (HPLC), and spectrophotometry with 5,5′-dithiobis-2-nitrobenzoic acid (DTNB). The fluorescence microscopy revealed comparatively low concentrations of reduced glutathione (GSH) in vacuoles. The GSH content was 104 μM on average, which was lower than the GSH levels in mitochondria (448 μM) and plastids (379 μM). The content of reduced (GSH) and oxidized (GSSG) glutathione forms was quantified by means of HPLC and spectrophotometric assays with DTNB. The glutathione concentrations determined by HPLC in the vacuoles were 182 nmol GSH and 25 nmol GSSG per milligram protein. The respective concentrations of GSH and GSSG in the plastids were 112 and 6 nmol/mg protein and they were 228 and 10 nmol/mg protein in the mitochondria. The levels of GSH determined with DTNB were 1.5 times lower, whereas the amounts of GSSG were, by contrast, 1.5–2 times higher than in the HPLC assays. Although the glutathione redox ratios depended to some extent on the method used, the GSH/GSSG ratios were always lower for vacuoles than for plastids and mitochondria. In vacuoles, the pool of oxidized glutathione was higher than in other organelles.     

Probenicid inhibition of fluorescence extrusion after MCB-staining of rat-1 fibroblasts

The intracellular fluorescence level of cells stained continuously with monochlorobimane was monitored by flow cytometry in order to assess the initial rate of glutatione to monochlorobimane conjugation as a measure of glutathione S-transferase activity. In addition to a rapid initial increase and a plateau level, a decline in fluorescence intensity was found upon prolonged flow cytometric monitoring. Exposure to probenicid, an inhibitor of an ATP-dependent organic anion pump, prevented this decrease. Incubation with vanadate and verapamil was without effect. Thus, extrusion of fluorescentglutathione-conjugate perturbs the proportionality between initial glutathione level and monochlorobimane-dependent fluorescence intensity. Monitoring by flow cytometry the decrease in monochlorobimane-dependent fluorescence may be useful to detect multidrug resistant cells.     

Direct evidence of intercellular sharing of glutathione via metabolic cooperation

Intracellular glutathione (GSH) content and cell density are known to be two important determinants of cell sensitivity to free radicals and radiation. We have investigated intercellular sharing of GSH via metabolic cooperation (MC) by measuring the GSH content of Chinese hamster V79 cells under conditions that varied MC among cells. GSH was measured by flow cytometry with monochlorobimane, which becomes fluorescent after conjugation to GSH by GSH-S-transferase. High-performance liquid chromatography was used to confirm the accuracy of GSH measurements by flow cytometry. Several lines of evidence indicate sharing of GSH or its precursor gamma-glutamylcysteine via MC. These include a cell density-dependent heterogeneity in GSH content, reconstitution of GSH in GSH-depleted cells by coculture with nondepleted cells (except when the depleted cells were MC deficient), and decreased equilibration of GSH among GSH-depleted cells and nondepleted cells when an inhibitor of MC (phorbol myristate acetate) was present. The equilibration of GSH among GSH-depleted cells and nondepleted cells in coculture was not inhibitable by acivicin, suggesting that this form of intercellular sharing of GSH does not rely on gamma-glutamyltransferase-mediated extracellular transport of GSH.     

Glutathione in the olfactory mucosa of rainbow trout (Oncorhyncus mykiss)

We have correlated biochemical analysis with histochemistryand light microscopy of semi-thin sections to study the distributionof glutathione (GSH) in the olfactory mucosa of rainbow trout.GSH was derivatized with the thiol-specific fluorescent probe,monobromobimane, then either quantified by HPLC or localizedby fluorescence microscopy. The concentration of GSH in theolfactory rosette was 0.51 ± 0.06 µmol/g of tissue.GSH was present in the cytoplasm of olfactory epithelial cells,with the olfactory knobs and dendrites of a subpopulation ofolfactory receptor cells labeling intensely. Melanophores inthe lamina propria also labeled strongly. The fluorescent stainingwas absent following depletion of GSH by formation of conjugateswith 1-chloro-2,4-dinitrobenzene.     

An LTC4 binding site in gastric mucosa is shared with glutathione

Recent results from our laboratory and others have suggested a possible physiological functional role(s) for leukotrienes in gastric mucosa. In the present study 3H-LTC4 binds to washed rabbit gastric mucosal membranes at 4 degrees C with a Kd of 5 nM and a Bmax of 31.3 pmol/mg protein. Leukotrienes D4, E4, B4, oxidized glutathione (GSSG), cysteine, and mercaptoethanol were unable to displace 3H-LTC4 at 1 microM concentrations, while GSH inhibited binding with a Ki of 47 nM. Differential centrifugation of the membrane preparation to remove mitochondria resulted in Ki values for LTC4 and GSH of 14 and 23 nM, respectively. The similar binding affinities and competitive receptor binding kinetics for GSH and LTC4, the low affinity for other leukotrienes, and a Ki of 7 microM for hematin, a substrate for glutathione S-transferase, suggest that 3H-LTC4 binds to a GSH site which does not discriminate between LTC4 and GSH. Membranes fractionated to remove mitochondria were assayed for glutathione peroxidase, gamma-glutamyltranspeptidase, and glutathione S-transferase as possible binding sites for LTC4. We were unable to detect enzyme activity for any of the three enzymes. The binding of LTC4 in gastric mucosa differs from other tissues with respect to the high affinity for GSH, and thus becomes an appropriate tissue in which to investigate the relationships between LTC4 and GSH.     

5-(Pentafluorobenzoylamino)fluorescein: A selective substrate for the determination of glutathione concentration and glutathione S-transferase activity

5-(Pentafluorobenzoylamino)fluorescein (PFB-F), a new thiol-reactive molecule was synthesized to improve the detection limits and specificity of the assays for glutathione S-transferase (GST) activity and glutathione (GSH). A rapid assay method to measure GSH concentration or GST activity and the simultaneous analysis of multiple samples is possible because the glutathione adduct, GS-TFB-F, is separated from PFB-F by thin-layer chromatography (TLC) and can be quantitated by a fluorescence scanner. The detection limits for GSH and for GST activity using TLC were found to be as low as 10 pmol/microl and 1 ng/microl using equine liver GST, respectively. Determination of GSH concentration or GST activity in bovine pulmonary artery endothelial (BPAE) cell lysates gave a linear response for samples corresponding to 500-2500 cells. PFB-F could also measure GST activities of GST fusion proteins and prove to be a suitable substrate for determining the activities of human GST isozymes and other sources of mammalian GST. The selectivity of PFB-F with GSH was proven by comparing trace amount of the adducts that formed with cysteine and beta-galactosidase to that formed with GSH. The HPLC profile of a reaction mixture where cell lysate was used in place of purified GST, also shows only two main peaks, corresponding to GS-TFB-F and unreacted PFB-F. The selectivity of PFB-F for GSH was further confirmed by exposing BPAE cells to dl-buthionine-[S,R]-sulfoximine (BSO). Our results of GS-TFB-F determination indicate that 12-, 24-, or 36-h incubations with BSO caused 2-, 6-, or 7.6-fold reductions in GSH levels, respectively.     

A Comparison Between Different Methods for the Determination of Reduced and Oxidized Glutathione in Mammalian Tissues

In this study, three rapid assay techniques for the determination of glutathione, one enzymatic, one flu-orometric and one newly patented colorimetric method, were compared by measuring reduced (GSH) and oxidized (GSSG) glutathione in guinea-pig heart and liver. The HPLC technique was used as a standard, since it is considered the most reliable assay method. In heart, all methods measured the same levels of GSH (about 1 µmole/g wet tissue), whereas in liver the fluorometric assay gave GSH levels about half as high as those measured by the other methods (about 3 vs. 7 µmoles/g wet tissue). Conversely, the fluorometric assay grossly overestimated GSSG concentration (by 5 to 8 times) in both heart and liver. These results confirm previous doubts about the use of the fluorometric technique for GSSC determination in mammalian tissues and also raise some questions about its use for the measurement of GSH in liver. In this tissue, the GSH concentration determined by the fluorometric method was shown to be inversely correlated with the size of the sample, suggesting the presence of some quenching material.     

A study on the in vitro interaction between tyrosinase and glutathione S-transferase

The actions of glutathione S-transferase and tyrosinase on the in vitro production of glutathionyl-3,4-dihydroxyphenylalanine and the dopachrome level in the presence of GSH and L-3,4-dihydroxyphenylalanine were studied. No clear evidence of complementarity between tyrosinase and glutathione S-transferase was observed; on the contrary, in the presence of glutathione S-transferase the glutathionyl-3,4-dihydroxyphenylalanine yield was lower than with tyrosinase only, as measured by HPLC. It is concluded that the spontaneous conjugation of GSH with dopaquinone should probably be high enough to scavenge the toxic quinone and to produce precursors for phaeomelanogenesis.     

Differential effects of H2S on cytoplasmic and nuclear thiol concentrations in different tissues of Brassica roots

H₂S-fumigation experiments with the sulphur-demanding plant Brassica oleracea L. (hybrid curly kale) were carried out to modulate glutathione levels in root tip cells. Plants were exposed in small fumigation cabinets to 0.4 μl l^–1 H₂S for 96 h. The data obtained by HPLC analysis of bimane-labeled thiols showed a slight increase of glutathione contents of about 20% in the roots of H₂S fumigated plants. The histochemical non-destructive assay for the determination of glutathione in single cells of whole plant organs was carried out for the first time by the use of monochlorobimane (BmCl) in situ to give a fluorescent GSH–bimane conjugate, followed by a fixation procedure. A significant increase of the fluorescence signal after the H₂S treatment was localized in the cytoplasm as well as in the nucleoplasm of root meristem cells.     

Effect of hypoxic cell radiosensitizers on glutathione level and related enzyme activities in isolated rat hepatocytes

A comparative study of the effect of misonidazole and novel radiosensitizers on glutathione (GSH) levels and related enzyme activities in isolated rat hepatocytes was performed. Incubation of hepatocytes with 5 mM radiosensitizers led to a decrease in the intracellular GSH level. The most pronounced decrease in cellular GSH was evoked by 2,4-dinitroimidazole-1-ethanol (DNIE); after incubation for only 15 min, GSH was hardly detected. DNIE-mediated GSH loss was dependent upon its concentration. DNIE reacted with GSH nonenzymatically as well as with diethylmaleate, while misonidazole and 1-methyl-2-methyl-sulfinyl-5-methoxycarbonylimidazole (KIH-3) did not. Addition of partially purified glutathione S-transferase (GST) did not enhance DNIE-mediated GSH loss in a cell-free system. DNIE inhibited glutathione peroxidase (GSH-Px), GST, and glutathione reductase (GSSG-R) activities in hepatocytes, while misonidazole and KIH-3 did not. GSH-Px activity assayed with H2O2 as substrate was the most inhibited. Inhibition of GSH-Px activity assayed with cumene hydroperoxide as substrate and GST was less than that of GSH-Px assayed with H2O2 as substrate. GSSG-R activity was decreased by DNIE, but not significantly. Incubation of purified GSH-Px with DNIE resulted in a little change in the activity when assayed with H2O2 as substrate.     

Immunocytochemical localization of the major glutathione S-transferases in adult Schistosoma mansoni

Indirect immunofluorescence was used to investigate the tissue distribution of the major isoenzymes of Schistosoma mansoni glutathione S-transferase (GSH S-transferase). When polyclonal rabbit antisera against GSH S-transferase isoenzymes SmGST-1, -02, and -3 were applied to cryostat or plastic-embedded sections of fixed adult worms, a punctate pattern of enzyme distribution was observed that was restricted to the parenchyma. Labeling was much more pronounced in males than females, consistent with the biochemically determined distribution of these enzymes between the sexes. Intense immunolabeling was noted within the subectocytoplasmic core tissue of the tubercles of the male that appeared to be connected to deep parenchymal cells by immunoreactive cell processes. Immunofluorescence could be blocked completely by prior incubation of antisera with affinity-purified enzyme. Although schistosome GSH S-transferases have been reported to be protective antigens, no immunoreactivity was detected within or on the tegument, including the dorsal spines of the male. The lack of tegumental immunoreactivity was confirmed by immunoblotting of tegumental membrane preparations following SDS-PAGE. Muscle fibers, vitelline cells, and cecal epithelium also failed to react. The fact that the GSH S-transferases were not uniformly distributed among all parenchymal cells suggests the existence of subpopulations of parenchymal cells that are preferentially involved in the conjugation of electrophiles with glutathione.     

Use of Monochlorobimane to Determine the In Vivo Effect of Cadmium,Copper and Lead on Glutathione Status in Mercenaria mercenaria Brown Cells

This study was undertaken to demonstrate the synthesis of glutathione (GSH) in Mercenaria mercenaria brown cells to test the hypothesis that failure to achieve 100% mortality with metal treatment is the result of high concentrations of GSH heterogeneously distributed in the brown cell population and to determine the effect of Cd²⁺, Cu²⁺, and Pb²⁺ on the GSH status in brown cells. The monochlorobimane (MCB) assay appeared to be selective for GSH in brown cells and a close relationship between the levels of GSH measured by MCB and a standard enzymatic method was found. The fluorescent GSH-bimane adduct, once formed within the cell, was not released from the cell. The technique was used to establish that GSH was synthesized in brown cells and was heterogeneously distributed in the brown cell population. Metal concentrations as high as 40 mM cadmium, 6.0 μM copper, or 20 mM lead did not deplete but caused decreases in brown cell GSH concentration that differed significantly (P < 0.05) from controls. The decrease caused by cadmium, copper, and lead was not in a dose dependent manner, whereas, the decrease caused by N-ethylmaleimide (NEM) was. It appears that the partial kill phenomenon associated with metal toxicity may be due to the heterogeneous distribution of GSH in the brown cell population.     

Recombinant glutathione S-transferase (GST) expressing cells purified by flow cytometry on the basis of a GST-catalyzed intracellular conjugation of glutathione to monochlorobimane.

COS cells transiently expressing glutathione S-transferase (GST) pi, Ya, or Yb1 (human Pi, rat Alpha or Mu, cytosolic classes) were purified by flow cytometry and used in colony-forming assays to show that GST confers cellular resistance to the carcinogen benzo[a]pyrene (+/-)-anti-diol epoxide (anti-BPDE). We developed a sorting technique to viably separate recombinant GST+ cells (20%) from the nonexpressing electroporated population (80%) on the basis of a GST-catalyzed intracellular conjugation of glutathione to the fluorescent labeling reagent monochlorobimane (mClB). The concentration of mClB, length of time cells are exposed to mClB, and activity of the expressed GST isozyme determined the degree to which recombinant GST+ cells fluoresced more intensely than controls. On-line reagent addition ensured that all cells were exposed to 25 microM mClB for 30-35 s during transit before being analyzed for fluorescence intensity and sorted. The apparent Km for mClB of the endogenous COS cell GST-catalyzed intracellular reaction was 88 microM. Stained GST Ya+ or Yb1+ cells catalyzed the conjugation 2 or 5 times more effectively than GST pi+ cells. Enzyme activity in cytosolic fractions prepared from sorted recombinant GST+ cells was 1.8 +/- 0.3-fold greater than that of the control (80 +/- 4 nmol/min/mg protein). Upon a 5-fold purification of GST pi+ cells in the electroporated population, resistance to anti-BPDE in colony-forming assays increased 5 times, from 1.1-fold (unsorted) to 1.5-fold (sorted) (P less than 0.001).     

Novel glutathione conjugates formed from epoxyeicosatrienoic acids (EETs)

The catalysis of glutathione (GSH) conjugation to epoxyeicosatrienoic acids (EETs) by various purified isozymes of glutathione S-transferase was studied. A GSH conjugate of 14,15-EET was isolated by HPLC and TLC; this metabolite contained one molecule of EET and one molecule of GSH. Fast atom bombardment mass spectrometry of the isolated metabolite confirmed the structure as a GSH conjugate of 14,15-EET. Studies designed to determine the isozyme specificity of this reaction demonstrated that two isozymes, 3-3, and 5-5, efficiently catalyzed this conjugation reaction. The Km values for 14,15-EET were approximately 10 microM and the Vmax values ranged from 25 to 60 nmol conjugate formed min-1 mg-1 purified transferase 3-3 and 5-5. The 5,6-, 8,9-, and 11,12-EETs were also substrates for the reaction, albeit at lower rates. These results demonstrate that the EETs can serve as substrates for the cytosolic glutathione S-transferases.     

Quantitation of reduced and total glutathione at the femtomole level by high-performance liquid chromatography with fluorescence detection: application to red blood cells and cultured fibroblasts

A new rapid and highly sensitive HPLC method with ortho-phthalaldehyde (OPA) pre-column derivatization has been developed for determination of reduced glutathione (GSH) and total glutathione (GSHt) in human red blood cells and cultured fibroblasts. OPA derivatives are separated on a reversed-phase HPLC column with an acetonitrile–sodium acetate gradient system and detected fluorimetrically. An internal standard (glutathione ethyl ester) is added to facilitate quantitation. Total glutathione is determined after reduction of disulfide groups with dithiothreitol; the oxidized glutathione (GSSG) concentration is calculated by subtraction of the GSH level from the GSHt level. The assay shows high sensitivity (50 fmol per injection, the lowest reported), good precision (C.V. <5.0%), an analytical recovery of GSH and GSSG close to 100%, and linearity (r>0.999). This HPLC technique is very simple and rapid. Its wide applicability and high sensitivity make it a convenient and reliable method for glutathione determination in various biological samples.