GST Substrates Research Articles

Prostaglandin synthase activity of sigma- and mu-class glutathione transferases in a parasitic trematode, Clonorchis sinensis.

Sigma-class glutathione transferase (GST) proteins with dual GST and prostaglandin synthase (PGS) activities play a crucial role in the establishment of Clonorchis sinensis infection. Herein, we analyzed the structural and enzymatic properties of sigma-class GST (CsGST-σ) proteins to obtain insight into their antioxidant and immunomodulatory functions in comparison with mu-class GST (CsGST-μ) proteins. CsGST-σ proteins conserved characteristic structures, which had been described in mammalian hematopoietic prostaglandin D2 synthases. Recombinant forms of these CsGST-σ and CsGST-μ proteins expressed in Escherichia coli exhibited considerable degrees of GST and PGS activities with substantially different specific activities. All recombinant proteins displayed higher affinities toward prostaglandin H2 (PGS substrate; average Km of 30.7 and 3.0 μm for prostaglandin D2 [PGDS] and E2 synthase [PGES], respectively) than those toward CDNB (GST substrate; average Km of 1,205.1 μm). Furthermore, the catalytic efficiency (Kcat/Km) of the PGDS/PGES activity was higher than that of GST activity (average Kcat/Km of 3.1, 0.7, and 7.0×10-3 s-1μm-1 for PGDS, PGES, and GST, respectively). Our data strongly suggest that the C. sinensis sigma- and mu-class GST proteins are deeply involved in regulating host immune responses by generating PGD2 and PGE2 in addition to their roles in general detoxification.

Human mitochondrial glutathione transferases: Kinetic parameters and accommodation of a mitochondria-targeting group in substrates

Glutathione-S-transferases are key to the cellular detoxification of xenobiotics and products of oxidative damage. GSTs catalyse the reaction of glutathione (GSH) with electrophiles to form stable thioether adducts. GSTK1-1 is the main GST isoform in the mitochondrial matrix, but the GSTA1-1 and GSTA4-4 isoforms are also thought to be in the mitochondria with their distribution altering in transformed cells, thus potentially providing a cancer specific target. A mitochondria-targeted version of the GST substrate 1-chloro-2,4-dinitrobenzene (CDNB), MitoCDNB, has been used to manipulate the mitochondrial GSH pool. To finesse this approach to target particular GST isoforms in the context of cancer, here we have determined the kcat/Km for the human isoforms of GSTK1-1, GSTA1-1 and GSTA4-4 with respect to GSH and CDNB. We show how the rate of the GST-catalysed reaction between GSH and CDNB analogues can be modified by both the electron withdrawing substituents, and by the position of the mitochondria-targeting triphenylphosphonium on the chlorobenzene ring to tune the activity of mitochondria-targeted substrates. These findings can now be exploited to selectively disrupt the mitochondrial GSH pools of cancer cells expressing particular GST isoforms.

Structure-activity analysis suggests an olfactory function for the unique antennal delta glutathione transferase of Apis mellifera.

Glutathione transferases (GST) are detoxification enzymes that conjugate glutathione to a wide array of molecules. In the honey bee Apis mellifera, AmGSTD1 is the sole member of the delta class of GSTs, with expression in antennae. Here, we structurally and biochemically characterized AmGSTD1 to elucidate its function. We showed that AmGSTD1 can efficiently catalyse the glutathione conjugation of classical GST substrates. Additionally, AmGSTD1 exhibits binding properties with a range of odorant compounds. AmGSTD1 has a peculiar interface with a structural motif we propose to call 'sulfur sandwich'. This motif consists of a cysteine disulfide bridge sandwiched between the sulfur atoms of two methionine residues and is stabilized by CH…S hydrogen bonds and S…S sigma-hole interactions. Thermal stability studies confirmed that this motif is important for AmGSTD1 stability and, thus, could facilitate its functions in olfaction.

Potent GST Ketosteroid Isomerase Activity Relevant to Ecdysteroidogenesis in the Malaria Vector Anopheles gambiae

Nobo is a glutathione transferase (GST) crucially contributing to ecdysteroid biosynthesis in insects of the orders Diptera and Lepidoptera. Ecdysone is a vital steroid hormone in insects, which governs larval molting and metamorphosis, and the suppression of its synthesis has potential as a novel approach to insect growth regulation and combatting vectors of disease. In general, GSTs catalyze detoxication, whereas the specific function of Nobo in ecdysteroidogenesis is unknown. We report that Nobo from the malaria-spreading mosquito Anopheles gambiae is a highly efficient ketosteroid isomerase catalyzing double-bond isomerization in the steroids 5-androsten-3,17-dione and 5-pregnen-3,20-dione. These mammalian ketosteroids are unknown in mosquitoes, but the discovered prominent catalytic activity of these compounds suggests that the unknown Nobo substrate in insects has a ketosteroid functionality. Aminoacid residue Asp111 in Nobo is essential for activity with the steroids, but not for conventional GST substrates. Further characterization of Nobo may guide the development of new insecticides to prevent malaria.

Inducible glutathione S-transferase (IrGST1) from the tick Ixodes ricinus is a haem-binding protein

Blood-feeding parasites are inadvertently exposed to high doses of potentially cytotoxic haem liberated upon host blood digestion. Detoxification of free haem is a special challenge for ticks, which digest haemoglobin intracellularly. Ticks lack a haem catabolic mechanism, mediated by haem oxygenase, and need to dispose of vast majority of acquired haem via its accumulation in haemosomes. The knowledge of individual molecules involved in the maintenance of haem homeostasis in ticks is still rather limited. RNA-seq analyses of the Ixodes ricinus midguts from blood- and serum-fed females identified an abundant transcript of glutathione S-transferase (gst) to be substantially up-regulated in the presence of red blood cells in the diet. Here, we have determined the full sequence of this encoding gene, ir-gst1, and found that it is homologous to the delta-/epsilon-class of GSTs. Phylogenetic analyses across related chelicerates revealed that only one clear IrGST1 orthologue could be found in each available transcriptome from hard and soft ticks. These orthologues create a well-supported clade clearly separated from other ticks' or mites’ delta-/epsilon-class GSTs and most likely evolved as an adaptation to tick blood-feeding life style. We have confirmed that IrGST1 expression is induced by dietary haem(oglobin), and not by iron or other components of host blood. Kinetic properties of recombinant IrGST1 were evaluated by model and natural GST substrates. The enzyme was also shown to bind haemin in vitro as evidenced by inhibition assay, VIS spectrophotometry, gel filtration, and affinity chromatography. In the native state, IrGST1 forms a dimer which further polymerises upon binding of excessive amount of haemin molecules. Due to susceptibility of ticks to haem as a signalling molecule, we speculate that the expression of IrGST1 in tick midgut functions as intracellular buffer of labile haem pool to ameliorate its cytotoxic effects upon haemoglobin intracellular hydrolysis.

Olive tree glutathione S -transferase and its response against the herbicides oxyfluorfen and glyphosate

Abstract Glutathione S-transferases (GST, EC 2.5.1.18) are a group of detoxifying enzymes that catalyze the conjugation of glutathione to certain toxins or xenobiotics. These enzymes are very well characterized in mammals and plants in general but not in the olive tree. In this work the GST specific activity, kinetic behavior, substrate specificity, and protein expression levels have been determined in the leaves, fruits, stems, and roots of olive tree cv. Picual. The results reveal the presence of GST in all the organs, the leaves and roots are containing the highest activity levels. Substrate specificity and molecular mass of subunits differ between organs. The use of the herbicides oxyfluorfen and glyphosate caused barely significant changes in the kinetic behavior and GST protein-expression levels, in general. Only in the stems of the olive tree treated with glyphosate were greater GST specific activity and protein expression detected. As conclusions, GST has been located and characterized in leaves, fruits, stems and roots of olive tree and the action of this enzyme, implied in the detoxification processes in this species, is lightly affected by the soil application of oxyfluorfen and glyphosate.

Characterization of equine GST A3-3 as a steroid isomerase

Glutathione transferases (GSTs) comprise a superfamily of enzymes prominently involved in detoxication by making toxic electrophiles more polar and therefore more easily excretable. However some GSTs have developed alternative functions. Thus, a member of the Alpha class GSTs in pig and human tissues is involved in steroid hormone biosynthesis, catalyzing the obligatory double-bond isomerization of Δ5-androstene-3,17-dione to Δ4-androstene-3,17-dione and of Δ5-pregnene-3,20-dione to Δ4-pregnene-3,20-dione on the biosynthetic pathways to testosterone and progesterone. The human GST A3-3 is the most efficient steroid double-bond isomerase known so far in mammals. The current work extends discoveries of GST enzymes that act in the steroidogenic pathways in large mammals. The mRNA encoding the steroid isomerase GST A3-3 was cloned from testis of the horse (Equus ferus caballus). The concentrations of GSTA3 mRNA were highest in hormone-producing organs such as ovary, testis and adrenal gland. EcaGST A3-3 produced in E. coli has been characterized and shown to have highly efficient steroid double-bond isomerase activity, exceeding its activities with conventional GST substrates. The enzyme now ranks as one of the most efficient steroid isomerases known in mammals and approaches the activity of the bacterial ketosteroid isomerase, one of the most efficient enzymes of all categories known today. The high efficiency and the tissue distribution of EcaGST A3-3 support the view that the enzyme plays a physiologically significant role in the biosynthesis of steroid hormones.

Molecular cloning, biochemical characterization, and expression analysis of two glutathione S-transferase paralogs from the big-belly seahorse (Hippocampus abdominalis).

Glutathione S-transferases (GSTs, EC 2.5.1.18) are important Phase II detoxifying enzymes that catalyze hydrophobic, electrophilic xenobiotic substance with the conjugation of reduced glutathione (GSH). In this study, GSTμ and GSTρ paralogs of GST in the big belly seahorse (Hippocampus abdominalis; HaGSTρ, HaGSTμ) were biochemically, molecularly, functionally characterized to determine their detoxification range and protective capacities upon different pathogenic stresses. HaGSTρ and HaGSTμ are composed of coding sequences of 681bp and 654bp, which encode proteins 225 and 217 amino acids, with predicted molecular masses of 26.06kDa and 25.74kDa respectively. Sequence analysis revealed that both HaGSTs comprise the characteristic GSH-binding site in the thioredoxin-like N-terminal domain and substrate binding site in the C-terminal domain. The recombinant HaGSTρ and HaGSTμ proteins catalyzed the model GST substrate 1-chloro-2, 4-dinitrobenzene (CDNB). Enzyme kinetic analysis revealed different Km and Vmax values for each rHaGST, suggesting that they have different conjugation rates. The optimum conditions (pH, temperature) and inhibitory assays of each protein demonstrated different optimal ranges. However, HaGSTμ was highly expressed in the ovary and gill, whereas HaGSTρ was highly expressed in the gill and pouch. mRNA expression of HaGSTρ and HaGSTμ was significantly elevated upon lipopolysaccharide, Poly (I:C), and Edwardsiella tarda challenges in liver and in blood cells as well as with Streptococcus iniae challenge in blood cells. From these collective experimental results, we propose that HaGSTρ and HaGSTμ are effective in detoxifying xenobiotic toxic agents, and importantly, their mRNA expression could be stimulated by immunological stress signals in the aquatic environment.

Microsomal glutathione transferase 1 attenuated ROS-induced lipid peroxidation in Apostichopus japonicus

Microsomal glutathione transferase (mGST) is a membrane bound glutathione transferase in multifunctional detoxification isoenzymes family and also plays crucial roles in innate immunity. In the present study, a novel microsomal GST homology was identified from Apostichopus japonicus (designated as AjmGST1) by RACE approaches. The full-length cDNA of AjmGST1 was of 1296 bp encoded a protein of 169 amino acids residues. Multiple sequence alignment and phylogenetic analysis together supported that AjmGST1 belonged to a new member in invertebrates mGST family. Spatial expression analysis revealed that AjmGST1was ubiquitously expressed in all examined tissues with the larger magnitude in tentacle. Time-course expression of AjmGST1 mRNA in coelomocytes was up-regulated after Vibrio splendidus challenge from 6 h until 72 h with the peak expression in 24 h, compared with that in the control group. Similarly, the induced expression of AjmGST1 expression was also detected in lipopolysaccharide (LPS) exposed primary coelomocytes. The purified recombinant protein of AjmGST1 showed high activity with GST substrate at pH of 7.0 and temperature of 35 °C. Meantime, the recombinant AjmGST1 depressed H2O2-induced MDA production both in vivo and in vitro. All of these results indicated that AjmGST1 was an important regulator in elimination of lipid peroxidation under immune response.

Comprehensive characterization of three glutathione S-transferase family proteins from black rockfish (Sebastes schlegelii)

Glutathione S-transferases (GSTs, EC 2.5.1.18) are categorized as phase II enzymes, which form an important multifunctional family associated with a wide variety of catalytic activities. GSTω, GSTρ, and GSTθ are cytosolic GSTs which have been extensively studied in a variety of organisms; however, few studies have focused on teleosts. Those paralogs from black rockfish (Sebastes schlegelii; RfGSTω, RfGSTρ, and RfGSTθ, respectively) were molecularly, biochemically, and functionally characterized to determine their antioxidant extent and protective aptitudes upon pathogenic stress. RfGSTω, RfGSTρ, and RfGSTθ, contained open reading frames of 717bp, 678bp, and 720bp respectively, which encoded respective proteins of 239, 226, and 240 amino acids in length. In silico analysis revealed that all RfGSTs possessed characteristic N-terminal domains bearing glutathione (GSH)-binding sites, and C-terminal domains containing substrate-binding sites. Recombinant RfGSTω (rRfGSTω) catalyzed the conjugation of GSH to dehydroascorbate (DHA), while rRfGSTθ and rRfGSTρ catalyzed to the model GST substrate 1-Chloro-2,4-dinitrobenzene (CDNB). Kinetic analysis revealed variation in Km and Vmax values for each rRfGST, indicating their different conjugation rates. The optimum conditions (pH and temperature) and inhibition assays of each protein demonstrated different optimal ranges showing their wide range of activity as an assembly. RfGSTω and RfGSTθ paralogs demonstrated their antioxidant potential towards H2O2 and heavy metals (Cd, Zn, and Cu) in vitro, while RfGSTρ had an antioxidant potential only towards heavy metals (Zn and Cu). Though all the paralogs were ubiquitously expressed in different magnitudes, RfGSTω was highly expressed in blood, whereas RfGSTρ and RfGSTθ were highly expressed in liver. The mRNA expression of RfGSTω and RfGSTθ, upon Streptococcus iniae and poly I:C stimulation, revealed a significantly up-regulated expression, whereas RfGSTρ mRNA expression was significantly down-regulated. Collectively, our findings suggest that RfGSTω, RfGSTρ, and RfGSTθ paralogs are potent in detoxifying xenobiotic toxics, capable of protecting cells from oxidative stress generated by both H2O2 and heavy metals, and finally, yet importantly, stimulated under pathogenic stress signals.

Substrate specificities of two tau class glutathione transferases inducible by 2,4,6-trinitrotoluene in poplar

BackgroundThe genome of poplar (Populus trichocarpa) encodes 81 glutathione transferases (GSTs) annotated in eight distinct classes. The tau class is considered the most versatile in the biotransformation of xenobiotics and is composed of 58 GSTs. Two of the enzymes, GSTU16 and GSTU45, have particular interest since their expression is induced by exposure of poplar tissues to 2,4,6-trinitrotoluene (TNT) and could potentially be involved in the metabolism of this toxic environmental contaminant. ResultsDNA encoding these GSTs was synthesized and the proteins were heterologously expressed in Escherichia coli and the purified enzymes were characterized. Major conclusionsGSTU16 assayed with a number of conventional GST substrates showed the highest specific activity (60μmolmin−1mg−1) with phenethyl isothiocyanate, 150-fold higher than that with CDNB. By contrast, GSTU45 showed CDNB as the most active substrate (3.3μmolmin−1mg−1) whereas all of the 16 alternative substrates tested yielded significantly lower activities. Homology modeling suggested that the aromatic residues Phe10 and Tyr107 in the active site of GSTU16 are promoting the high activity with PEITC and other substrates with aromatic side-chains. Nonetheless, TNT was a poor substrate for GSTU16 as well as for GSTU45 with a specific activity of 0.05nmolmin−1mg−1 for both enzymes. General significanceGSTU16 and GSTU45 do not play a major role in the degradation of TNT in poplar.

Analysis of Arabidopsis glutathione-transferases in yeast

The genome of Arabidopsis thaliana encodes 54 functional glutathione transferases (GSTs), classified in seven clades. Although plant GSTs have been implicated in the detoxification of xenobiotics, such as herbicides, extensive redundancy within this large gene family impedes a functional analysis in planta. In this study, a GST-deficient yeast strain was established as a system for analyzing plant GSTs that allows screening for GST substrates and identifying substrate preferences within the plant GST family. To this end, five yeast genes encoding GSTs and GST-related proteins were simultaneously disrupted. The resulting yeast quintuple mutant showed a strongly reduced conjugation of the GST substrates 1-chloro-2,4-dinitrobenzene (CDNB) and 4-chloro-7-nitro-2,1,3-benzoxadiazole (NBD-Cl). Consistently, the quintuple mutant was hypersensitive to CDNB, and this phenotype was complemented by the inducible expression of Arabidopsis GSTs. The conjugating activity of the plant GSTs was assessed by in vitro enzymatic assays and via analysis of exposed yeast cells. The formation of glutathione adducts with dinitrobenzene was unequivocally verified by stable isotope labeling and subsequent accurate ultrahigh-resolution mass spectrometry (ICR-FTMS). Analysis of Arabidopsis GSTs encompassing six clades and 42 members demonstrated functional expression in yeast by using CDNB and NBD-Cl as model substrates. Subsequently, the established yeast system was explored for its potential to screen the Arabidopsis GST family for conjugation of the fungicide anilazine. Thirty Arabidopsis GSTs were identified that conferred increased levels of glutathionylated anilazine. Efficient anilazine conjugation was observed in the presence of the phi, tau, and theta clade GSTs including AtGSTF2, AtGSTF4, AtGSTF6, AtGSTF8, AtGSTF10, and AtGSTT2, none of which had previously been known to contribute to fungicide detoxification. ICR-FTMS analysis of yeast extracts allowed the simultaneous detection and semiquantification of anilazine conjugates as well as catabolites.

Occupation of the electrophilic substrate‐binding site of glutathione S‐transferase M1‐1 enhances its function as an activator of 1‐cysteine peroxiredoxin

Glutathione S‐transferase mu (GST‐mu) can form an in vitro heterodimer with 1‐cysteine peroxiredoxin, peroxiredoxin 6 (Prdx6), in the presence of glutathione (GSH), but the peroxidase specific activity of this complex is only 1.0 μmol/min/mg Prdx6, which is ~20% of that of the complex between the pi isozyme of GST and Prdx6 under the same conditions [L.A. Ralat, Y. Manevich, A.B. Fisher, R.F. Colman, Biochemistry 45 (2006) 360–372]. These results suggested that the interactions are different between Prdx6 and GST isozymes, which share an identity of less than 30%. Here, we show that Prdx6 can reduce hydrogen peroxide at 4.7 ± 0.3 μmol/min/mg Prdx6, as assayed using the GSH reductase/GSH/NADPH‐coupled GSH‐peroxidase method, after a 1‐hour incubation with a 1:1 molar ratio of GST‐mu at pH 8, containing saturating amounts of GSH and an electrophilic GST substrate analog, 2,4‐dinitrophenol. Interestingly, after this same incubation, GST‐mu lost all of its activity with respect to monobromobimane, a substrate that occupies a distinguishable site from 2,4‐dinitrophenol. These results suggest that occupation of the electrophilic site of GST‐mu may render a conformational change which optimizes its interaction with Prdx6, allowing the transfer of GSH to the inactive Cys‐47−sulfenic acid form of Prdx6, regenerating an active Prdx6, while inhibiting GST‐mu activity. Supported by NIH/NHLBI R01554495.

Effect of Glucagon-Like Peptide 2 on Hepatic, Renal, and Intestinal Disposition of 1-Chloro-2,4-dinitrobenzene

The ability of the liver, small intestine, and kidney to synthesize and subsequently eliminate dinitrophenyl-S-glutathione (DNP-SG), a substrate for multidrug resistance-associated protein 2 (Mrp2), was assessed in rats treated with glucagon-like peptide 2 (GLP-2, 12 μg/100 g b.wt. s.c. every 12 h for 5 consecutive days). An in vivo perfused jejunum model with simultaneous bile and urine collection was used. A single intravenous dose of 30 μmol/kg b.wt. 1-chloro-2,4-dinitrobenzene (CDNB) was administered, and its conjugate, DNP-SG, and dinitrophenyl cysteinyl glycine (DNP-CG), resulting from the action of γ-glutamyltransferase on DNP-SG, were determined in bile, intestinal perfusate, and urine by high-performance liquid chromatography. Tissue content of DNP-SG was also assessed in liver, intestine, and kidneys. Biliary excretion of DNP-SG+DNP-CG was decreased in GLP-2 rats with respect to controls. In contrast, their intestinal excretion was substantially increased, whereas urinary elimination was not affected. Western blot and real-time polymerase chain reaction studies revealed preserved levels of Mrp2 protein and mRNA in liver and renal cortex and a significant increase in intestine in response to GLP-2 treatment. Tissue content of DNP-SG detected 5 min after CDNB administration was decreased in liver, increased in intestine, and unchanged in kidney in GLP-2 versus control group, consistent with GLP-2-induced down-regulation of expression of glutathione transferase (GST) Mu in liver and up-regulation of GST-Alpha in intestine at both protein and mRNA levels. In conclusion, GLP-2 induced selective changes in hepatic and intestinal disposition of a common GST and Mrp2 substrate administered systemically that could be of pharmacological or toxicological relevance under therapeutic treatment conditions.

Five Decades with Glutathione and the GSTome

Uncle Folke inspired me to become a biochemist by demonstrating electrophoresis experiments on butterfly hemolymph in his kitchen. Glutathione became the subject for my undergraduate project in 1964 and has remained a focal point in my research owing to its multifarious roles in the cell. Since the 1960s, the multiple forms of glutathione transferase (GST), the GSTome, were isolated and characterized, some of which were discovered in our laboratory. Products of oxidative processes were found to be natural GST substrates. Examples of toxic compounds against which particular GSTs provide protection include 4-hydroxynonenal and ortho-quinones, with possible links to the etiology of Alzheimer and Parkinson diseases and other degenerative conditions. The role of thioltransferase and glutathione reductase in the cellular reduction of disulfides and other oxidized forms of thiols was clarified. Glyoxalase I catalyzes still another glutathione-dependent detoxication reaction. The unusual steady-state kinetics of this zinc-containing enzyme initiated model discrimination by regression analysis. Functional properties of the enzymes have been altered by stochastic mutations based on DNA shuffling and rationally tailored by structure-based redesign. We found it useful to represent promiscuous enzymes by vectors or points in multidimensional substrate-activity space and visualize them by multivariate analysis. Adopting the concept “molecular quasi-species,” we describe clusters of functionally related enzyme variants that may emerge in natural as well as directed evolution.

Synthesis and Characterization of a Series of Highly Fluorogenic Substrates for Glutathione Transferases, a General Strategy

Glutathione transferases (GSTs) are used in biotechnology applications as fusion partners for facile purification and are also overexpressed in certain tumors. Consequently, there is a need for sensitive detection of the enzymes. Here we describe a general strategy for the synthesis and characterization of novel fluorogenic substrates for GSTs. The substrates were synthesized by introducing an electrophilic sulfonamide linkage to fluorescent molecules containing an amino group [e.g., 2,4-dinitrobenzenesulfonamide (DNs) derivatives of coumarin, cresyl violet, and rhodamine]. The derivatives were essentially nonfluorescent, and upon GST catalyzed cleavage of the dinitrobenzenesulfonamide, free fluorophore is released (and 1-glutathionyl-2,4-dinitrobenzene + SO(2)). All the coumarin-, cresyl violet- and rhodamine-based fluorogenic probes turned out to be good substrates for most GSTs, especially for GSTA(1-1), in terms of strong fluorescence increases (71-1200-fold), high k(cat)/K(m) values (10(4)-10(7) M(-1) s(-1)) and significant rate enhancements (10(6)-10(9)-fold). The substrates were successfully applied to quantitate very low levels of GST activity in cell extracts and DNs-cresyl violet was also successfully applied to the imaging of microsomal MGST(1) activity in living cells. The cresyl violet stained cells retained their fluorescence after fixation, which is a very useful property. In summary, we describe a general and versatile strategy to generate fluorogenic GST substrates, some of them providing the most sensitive assays so far described for GSTs.

Cys-X Scanning for Expansion of Active-site Residues and Modulation of Catalytic Functions in a Glutathione Transferase

We propose Cys-X scanning as a semisynthetic approach to engineer the functional properties of recombinant proteins. As in the case of Ala scanning, key residues in the primary structure are identified, and one of them is replaced by Cys via site-directed mutagenesis. The thiol of the residue introduced is subsequently modified by alternative chemical reagents to yield diverse Cys-X mutants of the protein. This chemical approach is orthogonal to Ala or Cys scanning and allows the expansion of the repertoire of amino acid side chains far beyond those present in natural proteins. In its present application, we have introduced Cys-X residues in human glutathione transferase (GST) M2-2, replacing Met-212 in the substrate-binding site. To achieve selectivity of the modifications, the Cys residues in the wild-type enzyme were replaced by Ala. A suite of simple substitutions resulted in a set of homologous Met derivatives ranging from normethionine to S-heptyl-cysteine. The chemical modifications were validated by HPLC and mass spectrometry. The derivatized mutant enzymes were assayed with alternative GST substrates representing diverse chemical reactions: aromatic substitution, epoxide opening, transnitrosylation, and addition to an ortho-quinone. The Cys substitutions had different effects on the alternative substrates and differentially enhanced or suppressed catalytic activities depending on both the Cys-X substitution and the substrate assayed. As a consequence, the enzyme specificity profile could be changed among the alternative substrates. The procedure lends itself to large-scale production of Cys-X modified protein variants.

Abstract 1345: Bioactivation of luteolin as a prodrug by tyrosinase inhibits human glutathione S-transferase and induces toxicity in SK-MEL-28 melanoma cells

Abstract Glutathione S-transferase (GST) play significant role in the metabolism and detoxification of drugs used in treatment of melanoma, resulting in a decrease in their efficacy against melanoma. In the present study, we investigated: i) the selective inhibition of GST by luteolin in the presence of tyrosinase, an abundant enzyme found in melanoma, and ii) the induction of apoptosis, change in mitochondrial permeability, cell viability, cell migration and GSH depletion by luteolin in human melanoma SK-MEL-28 cell culture. The inhibition of GST was investigated using CDNB method. DTNB method was used to measure GSH depletion. MTT assay, Annexin V apoptosis assay and TMRM fluorescence were used in the investigation of biochemical mechanism of luteolin toxicity in melanoma cells. Luteolin (40 µM) induced toxicity and death in 50% of cells after 48 h incubation. Cell treatment with luteolin (40 µM) resulted in apoptotic cell death in 70% of cells and caused 45% decrease in TMRM fluorescence indicating change in mitochondrial membrane permeability. At 1 h incubation, luteolin was bioactivated by tyrosinase to luteoline-quinone for 71% as measured by GSH depletion. The luteolin is effective in preventing metastasis of cancerous cells as evident by cell migration assay. At 48 h incubation, luteolin as low as 5 µM effectively prevented the cell migration. In the presence of tyrosinase, luteolin (10 µM) showed about 87% GST inhibition; whereas in the absence of tyrosinase, luteolin led to negligible GST inhibition. Both luteolin-SG conjugate and luteolin-quinone (10 µM) inhibited ≥90% of GST activity via reversible and irreversible competitive mechanisms with Ki of 0.9 and 6.4 µM with respect to GSH, respectively. The luteolin-SG conjugate inhibited GST activity reversibly and non-competitively with Ki of 1.8, whereas luteolin-quinone showed irreversible competitive inhibition of GST activity with Ki of 1.0 µM with respect to CDNB. While luteolin is not a substrate for GST, Luteolin (25 µM) non-competitively inhibited GST with Ki of 39 µM with respect to GSH and competitively with Ki of 61 µM with respect to CDNB. Luteolin, at the concentration range of 5-80 µM, exhibited 78-99% GST inhibition in human SK-MEL-28 cell homogenate. In summary, our results suggest that luteolin was bioactivated by tyrosinase to form a quinone and luteolin-glutathione conjugate, which played major role in the inhibition of GST. For the first time, we demonstrate that luteolin acts as a selective inhibitor of GST in the presence of tyrosinase. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 102nd Annual Meeting of the American Association for Cancer Research; 2011 Apr 2-6; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2011;71(8 Suppl):Abstract nr 1345. doi:10.1158/1538-7445.AM2011-1345

Abstract 746: Bioactivation of caffeic acid phenethyl ester prodrug by tyrosinase inhibits human glutathione S-transferase and cause selective toxicity to melanoma cells

Abstract Glutathione S-transferase (GST) plays a major role in detoxification of anti-cancer drugs and hence diminishing their toxicity towards cancer cells. In the current study, we investigated Caffeic Acid Phenethyl Ester (CAPE) as selective cytotoxic agent and GST inhibitor in melanoma cells. Tyrosinase is found abundantly in melanoma cells, was used as a primary molecular target to bioactivate CAPE to an o-quinone, which could react with glutathione to form CAPE glutathione conjugate. The inhibition of GST was investigated using CDNB method. LC/MS/MS was used to determine the formation of CAPE glutathione conjugate by tyrosinase. MTT assay and Annexin V apoptosis assay were used in the investigation of biochemical mechanism of CAPE toxicity. A number of modulators were used to investigate the role of GST and glutathione synthesis in melanoma cell lines. At 30 min incubation, CAPE was metabolized 65% by tyrosinase as measured by glutathione depletion. LC/MS/MS studies revealed that the major product formed as the result of CAPE bioactivation by tyrosinase in the presence of the glutathione was a CAPE-glutathione conjugate. In the presence of tyrosinase, CAPE 10 and 25µM showed 47% and 90% of GST inhibition whereas in the absence of tyrosinase CAPE did not show significant GST inhibition. Both pre-formed CAPE-glutathione conjugate and CAPE-quinone demonstrated 95% GST inhibition, whereas CAPE alone did not show any GST inhibition. It was also found that CAPE was not a substrate for GST. Our results showed that CAPE 15µM was selectively toxic towards five melanoma cell lines in comparison to four non-melanoma cells lines. For instance, CAPE 15µM showed 90% apoptotic cell death in melanoma cells. Furthermore, the role of intracellular glutathione was investigated. BSO, a GSH biosynthesis inhibitor, increased the CAPE toxicity by 26%, whereas GSH and N-acetyl cysteine marginally prevented CAPE toxicity towards melanoma cells for 10%. It was also shown that CAPE lead to significant intracellular glutathione depletion, intracellular GST inhibition and ROS formation in melanoma cells. On the other hand, although 4-hydroxyanisole, L-tyrosine and caffeic acid, were found to be metabolized by tyrosinase to form quinones and glutathione conjugates none of these compounds inhibited GST in the presence and absence of tyrosinase indicating that CAPE was the only compound from this series that selectively inhibited GST in the presence of tyrosinase. In summary, our results suggests CAPE was metabolized by tyrosinase to form a quinone and CAPE glutathione conjugate, which played a major role in inhibition of GST. In addition, the biochemical mechanisms of CAPE toxicity revealed that quinone formation, intracellular glutathione depletion and ROS formation played a role in CAPE selective toxicity towards melanoma cells. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 101st Annual Meeting of the American Association for Cancer Research; 2010 Apr 17-21; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2010;70(8 Suppl):Abstract nr 746.

Expression of Candida albicans glutathione transferases is induced inside phagocytes and upon diverse environmental stresses

Candida albicans has four ORFs for glutathione transferases (GSTs) of the GTT classes, and another one coding for an Omega class member. Under laboratory conditions, only GTT11 (GTT1/2 class) and GTO1 (Omega class) are expressed significantly in exponentially growing cells, particularly when these are subjected to diverse environmental stresses, including oxidative stress. They also become transitorily upregulated at the early stationary phase. Accordingly, the levels of the CaGto1 and CaGtt11 proteins increase after treatment with oxidants and upon osmotic stress, in addition to the early stationary phase. GTT11 and GTO1 transcription shows a complex dependence on the Hog1 and Cap1 factors upon different stresses. Purified CaGtt11 and CaGto1 proteins display enzyme activities similar to the Saccharomyces cerevisiae homologues. Thus, CaGtt11 has activity against standard GST substrates and is also active as peroxidase, while CaGto1 displays thiol oxidoreductase and dehydroascorbate reductase activities. Fluorescence microscopy and subfractionation studies indicate that CaGto1 is cytosolic, while CaGtt11 is associated with a particulate fraction. Under ex vivo conditions, CaGto1 and CaGtt11 become transitorily upregulated inside macrophages and neutrophils. Under these conditions, the promoter of GTT14 (GTT1/2 class) also becomes activated. These observations point to the importance of C. albicans GSTs in the defence against phagocytes.