Trypanothione-dependent glyoxalase I in Trypanosoma cruzi

The glyoxalase system, comprizing glyoxalase I and glyoxalase II, is a ubiquitous pathway that detoxifies highly reactive aldehydes, such as methylglyoxal, using glutathione as a cofactor. Recent studies of Leishmania major glyoxalase I and Trypanosoma brucei glyoxalase II have revealed a unique dependence upon the trypanosomatid thiol trypanothione as a cofactor. This difference suggests that the trypanothione-dependent glyoxalase system may be an attractive target for rational drug design against the trypanosomatid parasites. Here we describe the cloning, expression and kinetic characterization of glyoxalase I from Trypanosoma cruzi. Like L. major glyoxalase I, recombinant T. cruzi glyoxalase I showed a preference for nickel as its metal cofactor. In contrast with the L. major enzyme, T. cruzi glyoxalase I was far less fast-idious in its choice of metal cofactor efficiently utilizing cobalt, manganese and zinc. T. cruzi glyoxalase I isomerized hemithio-acetal adducts of trypanothione more than 2400 times more efficiently than glutathione adducts, with the methylglyoxal adducts 2-3-fold better substrates than the equivalent phenylglyoxal adducts. However, glutathionylspermidine hemithioacetal adducts were most efficiently isomerized and the glutathionylspermidine-based inhibitor S-4-bromobenzylglutathionylspermidine was found to be a potent linear competitive inhibitor of the T. cruzi enzyme with a K(i) of 5.4+/-0.6 microM. Prediction algorithms, combined with subcellular fractionation, suggest that T. cruzi glyoxalase I localizes not only to the cytosol but also the mitochondria of T. cruzi epimastigotes. The contrasting substrate specificities of human and trypanosomatid glyoxalase enzymes, confirmed in the present study, suggest that the glyoxalase system may be an attractive target for anti-trypanosomal chemotherapy.     

Expression of glyoxalase, glutathione peroxidase and glutathione S-transferase isoenzymes in different bovine tissues

(1) The tissue-specific expression of various glutathione-dependent enzymes, including glutathione S-transferase (GST), glutathione peroxidase and glyoxalase I, has been studied in bovine adrenals, brain, heart, kidney, liver, lung and spleen. Of the organs studied, liver was found to possess the greatest GST and glyoxalase I activity, and spleen the greatest glutathione peroxidase activity. The adrenals contained large amounts of these glutathione-dependent enzymes, but significant differences were observed between the cortex and medulla. (2) GST and glyoxalase I activity were isolated by S-hexylglutathione affinity chromatography. Glyoxalase I was found in all the organs examined, but GST exhibited marked tissue-specific expression. (3) The alpha, mu and pi classes of GST (i.e., those that comprise respectively Ya/Yc, Yb/Yn and Yf subunits) were all identified in bovine tissues. However, the Ya and Yc subunits of the alpha class GST were not co-ordinately regulated nor were the Yb and Yn subunits of the mu class GST. (4) Bovine Ya subunits (25.5-25.7 kDa) were detected in the adrenal, liver and kidney, but not in brain, heart, lung or spleen. The Yc subunit (26.4 kDa) was expressed in all those organs which expressed the Ya subunit, but was also found in lung. The mu class Yb (27.0 kDa) and Yn (26.1 kDa) subunits were present in all organs; however, brain, lung and spleen contained significantly more Yn than Yb type subunits. The pi class Yf subunit (24.8 kDa) was detected in large amounts in the adrenals, brain, heart, lung and spleen, but not in kidney or liver. (5) Gradient affinity elution of S-hexylglutathione-Sepharose showed that the bovine proteins that bind to this matrix elute in the order Ya/Yc, Yf, Yb/Yn and glyoxalase I. (6) In conclusion, the present investigation has shown that bovine GST are much more complex than previously supposed; Asaoka (J. Biochem. 95 (1984) 685-696) reported the purification of mu class GST but neither alpha nor pi class GST were isolated.     

Purification and characterization of five forms of glutathione transferase from human uterus

Five glutathione transferase (GST) forms were purified from human uterus by glutathione-affinity chromatography followed by chromatofocusing, and their structural, kinetic and immunological properties were investigated. Upon SDS/polyacrylamide slab gel electrophoresis all forms resulted composed of two subunits of identical molecular size. GST V (pI 4.5) is a dimer of 23-kDa subunits. GST I (pI 6.8) and GST IV (pI 4.9) are dimers of 24-kDa subunits whereas GST II (pI 6.1) and GST III (pI 5.5) are dimers of 26.5-kDa subunits. GST V accounts for about 85-90% of the activity whereas the other isoenzymes are present in trace quantities. On the basis of the molecular mass of the subunits, amino acid composition, substrate specificities, sensitivities to inhibitors, CD spectra and immunological studies, GST V appeared very similar to transferase pi. Structural and immunological studies provide evidence that GST IV is closely related to the less 'basic' transferase (GST pI 8.5) of human skin. Extensive similarities have been found between GST II and GST III. The comparison includes amino acid compositions, subunits molecular size and immunological properties. The two enzymes, however, are kinetically distinguishable. The data presented also indicate that GST II and GST III are related to transferase mu and to transferase psi of human liver. Even though GST I has a subunit molecular mass identical to GST IV, several lines of evidence, including catalytic and immunological properties, indicate that they are different from each other. GST I seems not to be related to any of known human transferases, suggesting that it may be specific for the uterus.     

Comparison of glyoxalase I purified from yeast (Saccharomyces cerevisiae) with the enzyme from mammalian sources

Glyoxalase I from yeast (Saccharomyces cerevisiae) purified by affinity chromatography on S-hexylglutathione-Sepharose 6B was characterized and compared with the enzyme from rat liver, pig erythrocytes and human erythrocytes. The molecular weight of glyoxalase I from yeast was, like the enzyme from Rhodospirillum rubrum and Escherichia coli, significantly less (approx. 32000) than that of the enzyme from mammals (approx. 46000). The yeast enzyme is a monomer, whereas the mammalian enzymes are composed of two very similar or identical subunits. The enzymes contain 1Zn atom per subunit. The isoelectric points (at 4 degrees C) for the yeast and mammalian enzymes are at pH7.0 and 4.8 respectively; tryptic-peptide ;maps' display corresponding dissimilarities in structure. These and some additional data indicate that the microbial and the mammalian enzymes may have separate evolutionary origins. The similarities demonstrated in mechanistic and kinetic properties, on the other hand, indicate convergent evolution. The k(cat.) and K(m) values for the yeast enzyme were both higher than those for the enzyme from the mammalian sources with the hemimercaptal adduct of methylglyoxal or phenylglyoxal as the varied substrate and free glutathione at a constant and physiological concentration (2mm). Glyoxalase I from all sources investigated had a k(cat.)/K(m) value near 10(7)s(-1).m(-1), which is close to the theoretical diffusion-controlled rate of enzyme-substrate association. The initial-velocity data show non-Michaelian rate saturation and apparent non-linear inhibition by free glutathione for both yeast and mammalian enzyme. This rate behaviour may have physiological importance, since it counteracts the effects of fluctuations in total glutathione concentrations on the glyoxalase I-dependent metabolism of 2-oxoaldehydes.     

Characterization of the safener-induced glutathione S-transferase isoform II from maize

The safener-induced maize (Zea mays L.) glutathione S-transferase, GST II (EC 2.5.1.18) and another predominant isoform, GST I, were purified from extracts of maize roots treated with the safeners R-25788 (N,N-diallyl-2-dichloroacetamide) or R-29148 (3-dichloroace-tyl-2,2,5-trimethyl-1,3-oxazolidone). The isoforms GST I and GST II are respectively a homodimer of 29-kDa (GST-29) subunits and a heterodimer of 29 and 27-kDa (GST-27) subunits, while GST I is twice as active with 1-chloro-2,4-dinitrobenzene as GST II, GST II is about seven times more active against the herbicide, alachlor. Western blotting using antisera raised against GST-29 and GST-27 showed that GST-29 is present throughout the maize plant prior to safener treatment. In contrast, GST-27 is only present in roots of untreated plants but is induced in all the major aerial organs of maize after root-drenching with safener. The amino-acid sequences of proteolytic fragments of GST-27 show that it is related to GST-29 and identical to the 27-kDa subunit of GST IV.Abbreviations CDNB 1-chloro-2,4-dinitrobenzene - DEAE di-ethylaminoethyl - FPLC fast protein liquid chromatography - GSH reduced glutathione - GST glutathione S-transferase - GST-26 26-kDa subunit of maize GST - GST-27 27-kDa subunit of maize GST - GST-29 29-kDa subunit of maize GST - R-25788 safener N,N-diallyl-2-dichloroacetamide - R-29148 safener 3-dichloroacetyl-2,2,5-trimethyl-1,3-oxazolidone - RPLC reverse phase liquid chromatography We are grateful to M-M. Lay, ZENECA AG Products (formerly ICI Americas), Richmond, Calif., USA for providing [¹⁴C] R-25788. ZENECA Seeds in the UK is part of ZENECA Limited.     

A genomics approach to the comprehensive analysis of the glutathione S-transferase gene family in soybean and maize

By BLAST searching a large expressed sequence tag database for glutathione S-transferase (GST) sequences we have identified 25 soybean (Glycine max) and 42 maize (Zea mays) clones and obtained accurate full-length GST sequences. These clones probably represent the majority of members of the GST multigene family in these species. Plant GSTs are divided according to sequence similarity into three categories: types I, II, and III. Among these GSTs only the active site serine, as well as another serine and arginine in or near the "G-site" are conserved throughout. Type III GSTs have four conserved sequence patches mapping to distinct structural features. Expression analysis reveals the distribution of GSTs in different tissues and treatments: Maize GSTI is overall the most highly expressed in maize, whereas the previously unknown GmGST 8 is most abundant in soybean. Using DNA microarray analysis we observed increased expression among the type III GSTs after inducer treatment of maize shoots, with different genes responding to different treatments. Protein activity for a subset of GSTs varied widely with seven substrates, and any GST exhibiting greater than marginal activity with chloro-2,4 dinitrobenzene activity also exhibited significant activity with all other substrates, suggesting broad individual enzyme substrate specificity.     

Yeast glyoxalase I is a monomeric enzyme with two active sites

The tertiary structure of the monomeric yeast glyoxalase I has been modeled based on the crystal structure of the dimeric human glyoxalase I and a sequence alignment of the two enzymes. The model suggests that yeast glyoxalase I has two active sites contained in a single polypeptide. To investigate this, a recombinant expression clone of yeast glyoxalase I was constructed for overproduction of the enzyme in Escherichia coli. Each putative active site was inactivated by site-directed mutagenesis. According to the alignment, glutamate 163 and glutamate 318 in yeast glyoxalase I correspond to glutamate 172 in human glyoxalase I, a Zn(II) ligand and proposed general base in the catalytic mechanism. The residues were each replaced by glutamine and a double mutant containing both mutations was also constructed. Steady-state kinetics and metal analyses of the recombinant enzymes corroborate that yeast glyoxalase I has two functional active sites. The activities of the catalytic sites seem to be somewhat different. The metal ions bound in the active sites are probably one Fe(II) and one Zn(II), but Mn(II) may replace Zn(II). Yeast glyoxalase I appears to be one of the few enzymes that are present as a single polypeptide with two active sites that catalyze the same reaction.     

Developmental Aspects of Detoxifying Enzymes in Fish (Salmo Iridaeus)

The activities of superoxide dismutase, catalase, glutathione reductase, glutathione peroxidase, glutathione transferase and glyoxalase I have been studied during the embryologic development of rainbow trout (Salmo iridaeus) and in several other trout tissues to investigate the protective development metabolism.

A gradual increase of superoxide dismutase, catalase, glutathione reductase, glyoxalase I and glutathione transferase activities was noted throughout embryo development.

In all trout tissues investigated glutathione peroxidase was found to be extremely low compared to catalase activity. The highest activity of superoxide dismutase, glyoxalase I and glutathione reductase was found in liver followed by kidney.

No change in the number of GST subunits was noted with the transition from the embryonic to the adult stages of life according to the SDS/PAGE and HPLC analyses performed on the GSH-affinity purified fractions.     

Purification and subunit-structural and immunological characterization of five glutathione S-transferases in human liver, and the acidic form as a hepatic tumor marker

Five glutathione S-transferase (GST, EC 2.5.1.18) forms were purified from human liver by S-hexylglutathione affinity chromatography followed by chromatofocusing, and their subunit structures and immunological relationships to rat liver glutathione S-transferase forms were investigated. They were tentatively named GSTs I, II, III, IV and V in order of decreasing apparent isoelectric points (pI) on chromatofocusing. Their subunit molecular weights assessed on SDS-polyacrylamide gel electrophoresis were 27 (Mr X 10(-3)), 27, 27.7,27 and 26, respectively, (26, 26, 27, 26, and 24.5 on the assumption of rat GST subunit Ya, Yb and Yc as 25, 26.5 and 28, respectively), indicating that all forms are composed of two subunits identical in size. However, it was suggested by gel-isoelectric focusing in the presence of urea that GSTs I and IV are different homodimers, consisting of Y1 and Y4 subunits, respectively, which are of identical Mr but different pI, while GST II is a heterodimer composed of Y1 and Y4 subunits. This was confirmed by subunit recombination after guanidine hydrochloride treatment. GST III seemed to be identical with GST-mu with regard to Mr and pI. GST V was immunologically identical with the placental GST-pi. On double immunodiffusion or Western blotting using specific antibodies to rat glutathione S-transferases, GST I, II and IV were related to rat GST 1-1 (ligandin), GST III(mu) to rat GST 4-4 (D), and GST V (pi) to rat GST 7-7 (P), respectively. GST V (pi) was increased in hepatic tumors.     

Activation of glyoxalase I during the cell division cycle and its homology with auxin regulated genes

In several plant systems increase in glyoxalase I activity has been correlated with cell proliferation. Cell cycle studies of tobacco protoplasts indicate a rise in glyoxalase I activity prior to G₂/M phase. Further, synthetic auxin, NAA, induced glyoxalase I activity and cell division significantly. This induction was specific in response to auxin only. Cytokinins alone do not induce cell division or increase enzyme activity. Analysis of glyoxalase I cDNA sequence from soybean shows significant homology with auxin inducible genes particularly Nt107 and limited but strong similarity with identified plant mitotic cyclins, implicating glyoxalase I in possible relationship with certain cell division regulating factors.     

Characterization of Glyoxalase I (E. coli)—Inhibitor Interactions by Electrospray Time-of-Flight Mass Spectrometry and Enzyme Kinetic Analysis

Potential inhibitors of the enzyme glyoxalase I from Escherichia coli have been evaluated using a combination of electrospray mass spectrometry and conventional kinetic analysis. An 11-membered library of potential inhibitors included a glutathione analogue resembling the transition-state intermediate in the glyoxalase I catalysis, several alkyl-glutathione, and one flavonoid. The E. coli glyoxalase I quaternary structure was found to be predominantly dimeric, as is the homologous human glyoxalase I. Binding studies by electrospray revealed that inhibitors bind exclusively to the dimeric form of glyoxalase I. Two specific binding sites were observed per dimer. The transition-state analogue was found to have the highest binding affinity, followed by a newly identified inhibitor; S-{2-[3-hexyloxybenzoyl]-vinyl}glutathione. Kinetic analysis confirmed that the order of affinity established by mass spectrometry could be correlated to inhibitory effects on the enzymatic reaction. This study shows that selective inhibitors may exist for the E. coli homologue of the glyoxalase I enzyme.     

Characterization of glyoxalase I (E. coli)-inhibitor interactions by electrospray time-of-flight mass spectrometry and enzyme kinetic analysis

Potential inhibitors of the enzyme glyoxalase I from Escherichia coli have been evaluated using a combination of electrospray mass spectrometry and conventional kinetic analysis. An 11-membered library of potential inhibitors included a glutathione analogue resembling the transition-state intermediate in the glyoxalase I catalysis, several alkyl-glutathione, and one flavonoid. The E. coli glyoxalase I quaternary structure was found to be predominantly dimeric, as is the homologous human glyoxalase I. Binding studies by electrospray revealed that inhibitors bind exclusively to the dimeric form of glyoxalase I. Two specific binding sites were observed per dimer. The transition-state analogue was found to have the highest binding affinity, followed by a newly identified inhibitor; S-{2-[3-hexyloxybenzoyl]-vinyl}glutathione. Kinetic analysis confirmed that the order of affinity established by mass spectrometry could be correlated to inhibitory effects on the enzymatic reaction. This study shows that selective inhibitors may exist for the E. coli homologue of the glyoxalase I enzyme.     

Salt- and glyphosate-induced increase in glyoxalase I activity in cell lines of groundnut (Arachis hypogaea)

Glyoxalase I (EC 4.4.1.5) activity has long been associated with rapid cell proliferation, but experimental evidence is forthcoming, linking its role to stress tolerance as well. Proliferative callus cultures of groundnut ( Arachis hypogaea L. cv. JL24) showed a 3.3-fold increase in glyoxalase I activity during the logarithmic growth phase, correlating well with the data on FW gain and mitotic index. Inhibition of cell division decreased glyoxalase I activity and vice versa, thus further corroborating its role as a cell division marker enzyme. Cell lines of A. hypogaea selected in the presence of high salt (NaCl) and herbicide (glyphosate) concentrations, yielded 4.2- to 4.5-fold and 3.9- to 4.6-fold elevated glyoxalase I activity, respectively, in a dose dependent manner reflective of the level of stress tolerance. The stress-induced increase in enzyme activity was also accompanied by an increase in the glutathione content. Exogenous supplementation of glutathione could partially alleviate the growth inhibition of callus cultures induced by methylglyoxal and d -isoascorbic acid, but failed to recover the loss in glyoxalase I activity due to d -isoascorbic acid. The adaptive significance of elevated glyoxalase I activity in maintaining glutathione homeostasis has been discussed in view of our understanding on the role of glutathione in the integration of cellular processes with plant growth and development under stress conditions.     

Structural Basis for Evolution of Product Diversity in Soybean Glutathione Biosynthesis

The redox active peptide glutathione is ubiquitous in nature, but some plants also synthesize glutathione analogs in response to environmental stresses. To understand the evolution of chemical diversity in the closely related enzymes homoglutathione synthetase (hGS) and glutathione synthetase (GS), we determined the structures of soybean (Glycine max) hGS in three states: apoenzyme, bound to γ-glutamylcysteine (γEC), and with hGSH, ADP, and a sulfate ion bound in the active site. Domain movements and rearrangement of active site loops change the structure from an open active site form (apoenzyme and γEC complex) to a closed active site form (hGSH•ADP•SO₄²⁻ complex). The structure of hGS shows that two amino acid differences in an active site loop provide extra space to accommodate the longer β-Ala moiety of hGSH in comparison to the glycinyl group of glutathione. Mutation of either Leu-487 or Pro-488 to an Ala improves catalytic efficiency using Gly, but a double mutation (L487A/P488A) is required to convert the substrate preference of hGS from β-Ala to Gly. These structures, combined with site-directed mutagenesis, reveal the molecular changes that define the substrate preference of hGS, explain the product diversity within evolutionarily related GS-like enzymes, and reinforce the critical role of active site loops in the adaptation and diversification of enzyme function.     

A 2,4-D-inducible glutathione S-transferase from soybean (Glycine max). Purification, characterisation and induction

Glutathione S-transferases (GSTs; EC 2.5.1.18) have recently been proposed to form one large group among the auxin-induced proteins. However. the properties and regulation of such auxin-responsive GSTs in the plant still await detailed investigation. In this study, a 2,4-dichloro-phenoxyacetic acid (2,4-D)-inducible GST isozyme from soybean ( Glycine max [L.] Merr. cv. Williams) was purified to near homogeneity by anion-exchange and affinity chromatography on S-hexylglutathione agarose. The native enzyme had a molecular mass of 49 kDa, as determined by gel filtration, and consisted of 26-kDa subunits. The purified GST conjugated glutathione to 1-chloro-2,4-dinitrobenzene and to the herbicide metolachlor, but not to the other GST substrates atrazine. fluorodifen or trans-cinnamic acid. The N-termmal amino acid sequence shared significant homology with the deduced polypeptide sequences of two 2,4-D-inducible genes from tobacco, par A and CNT107 . The levels of the 26-kDa GST subunit protein in soybean hypocotyls were analysed by immunoblotting. At micromolar concentrations, 2,4-D induced a transient increase in net accumulation of GST, whereas indole-3-acetic acid or I-naphthaleneacetic acid did not increase the GST levels. Known inhibitors of polar auxin transport, including 2.3.5-tri-iodobenzoic acid. N-I-naphthylphthalamic acid and analogues thereof, differed widely in their ability to elicit GST protein accumulation. It is concluded that the induction of soybean GST by 2,4-D and by some of the auxin transport inhibitors is not related to auxin activity or to changes in the endogenous auxin levels.     

Escherichia coli glyoxalase II is a binuclear zinc-dependent metalloenzyme

Cytotoxic methylglyoxal is detoxified by the two-enzyme glyoxalase system. Glyoxalase I (GlxI) catalyzes conversion of non-enzymatically produced methylglyoxal-glutathione hemithioacetal into its corresponding thioester. Glyoxalase II (Glx II) hydrolyzes the thioester into d-lactate and free glutathione. Glyoxalase I and II are metalloenzymes, which possess mononuclear and binuclear active sites, respectively. There are two distinct classes of GlxI; the first class is Zn2+-dependent and is composed of GlxI from mainly eukaryotic organisms and the second class is composed of non-Zn2+-dependent (but Ni2+ or Co2+-dependent) GlxI enzymes (mainly prokaryotic and leishmanial species). GlxII is typically Zn2+-activated, containing Zn2+ and either Fe3+/Fe2+ or Mn2+ at the active site depending upon the biological source. To address whether two classes of GlxII might exist, glyoxalase II from Escherichia coli was cloned and overexpressed and characterized. Unlike E. coli GlxI, which is non-Zn2+-dependent, Zn2+ activates the E. coli GlxII enzyme, with no evidence for Ni2+ metal utilization.     

Nonstereospecific substrate usage by glyoxalase I

Glyoxalase I operates on a mixture of rapidly interconverting diasteriomeric thiohemiacetals, formed in a preequilibrium step between glutathione and alpha-ketoaldehyde. That both diasteriomers are directly used as substrates by the enzyme from yeast and from porcine erythrocytes is an outcome of a series of isotope-trapping experiments in which pulse solutions composed of the two diasteriomeric thiohemiacetals, due to [3H]glutathione and phenylglyoxal, are rapidly mixed with chase solutions containing excess unlabeled glutathione and successively increasing concentrations of glyoxalase I. As the enzyme approaches infinite concentration in the chase solution, the radioactivity incorporated into the S-mandeloylglutathione product approaches 100% of the total radioactivity due to both diasteriomers from the pulse solution. The special properties of the active site that allow the enzyme to accommodate both diasteriomeric substrate forms may also account for the fact that the cis and the trans isomers of various para-substituted S-(phenylethenyl)glutathione derivatives are both strong competitive inhibitors of the enzyme. A catalytic mechanism is proposed for glyoxalase I involving catalyzed interconversion of the bound diasteriomeric thiohemiacetals before transformation to final product.     

Characterisation of glutathione transferases and glutathione peroxidases in pea (Pisum sativum)

Glutathione peroxidases (GPOXs) and glutathione transferases, also termed glutathione S-transferases (GST, EC 2.5.1.18), with activities toward a range of xenobiotic substrates including herbicides, have been characterized in etiolated pea (Pisum sativum L. cv. Feltham's First) seedlings. Crude extracts showed high activity toward a range of GST substrates including 1-chloro-2,4-dinitrobenzene (GSTC activity) and the herbicide fluorodifen (GSTF) but low activities toward chloroacetanilides and atrazine. Treatment of the pea seedlings with the herbicide safener dichlormid selectively increased the activity of GSTC and the GST which detoxified atrazine. This induction was restricted to the roots and was not observed with any of the other GST or GPOX activities. In contrast, treatment with CuCl₂ increased GPOX activity in the root but had no effect on any GST activity, while treatment of epicotyls with elicitors of the phytoalexin response increased GST activity toward ethacrynic acid, but had no effect on other GST or GPOX activities. The major enzymes with GSTC, GSTF and GPOX activities were purified from pea epicotyls 3609-fold, 1431-fold and 1554-fold, respectively. During purification by hydrophobic interaction chromatography and affinity chromatography using S-hexyl-glutathione as ligand all three activities co-eluted but could be partially resolved by anion exchange chromatography and gel filtration chromatography. Both GSTC and GPOX had a molecular mass of 48 kDa and their activities were associated with a similar 27.5-kDa subunit but distinct 29-kDa subunits. GSTF could be resolved into two isoenzymes with molecular masses of 49.5 and 54 kDa. GSTF activity was associated with a unique 30-kDa subunit in addition to 27.5- and 29-kDa peptides, suggesting that the two isoenzymes were composed of differing subunits. These results demonstrate that peas contain multiple GST isoenzymes some of which have GPOX activity and that the various activities are differentially responsive to biotic and abiotic stress.     

Inhibition of mammalian glyoxalase I (lactoylglutathione lyase) by N-acylated S-blocked glutathione derivatives as a probe for the role of the N-site of glutathione in glyoxalase I mechanism

A series of twelve S-blocked and N,S-blocked glutathione derivatives has been studied as inhibitors of glyoxalase I [R)-S-lactoylglutathione methylglyoxal-lyase (isomerising), EC 4.4.1.5) from human erythrocytes. A number of new N,S-blocked glutathiones have been synthesised. Inhibition at pH 7.0, 25 degrees C was linear-competitive in all cases and the Ki values were interpreted in terms of the absence of a specific binding interaction for the N-site of the inhibitor and the absence of coupling between binding processes at N- and S-sites (the regions around the NH2 and HS groups, respectively, of GSH analogues bound to enzyme). These observations are in strong contrast to previous results with the yeast enzyme. Some Ki values were measured for yeast glyoxalase I. A special binding interaction of the phenyl groups with enzyme from both species was found for glutathione derivatives with N-acyl groups of structure -NH X CO X X X Y X Ph but not for -NH X COPh, where X and Y were variously -CH2-, -NH- and -O-. Studies were made of the range of stability of human erythrocyte glyoxalase I to pH. The pH profiles for the Ki values of S-p-bromobenzyl)glutathione and N-acetyl-S-(p-bromobenzyl)glutathione indicated no pH dependence for the latter and little, if any, for the former inhibitor. The mean Ki over the pH range 5-8.5 for S-(p-bromobenzyl)glutathione was 1.21 +/- 0.37 microM and for N-acetyl-S-(p-bromobenzyl)glutathione in the same pH range, Ki decreased from 1.45 +/- 0.26 microM to 0.88 +/- 0.11 M.     

Perfluorodecanoic acid decreases the enzyme activity and the amount of glutathione S-transferases proteins and mRNAs in vivo

The effects of the anti-wetting agent perfluoro-n-decanoic acid (PFDA) on various glutathione S-transferase (GST) enzyme activities were studied in vitro and in vivo. In addition the effects of PFDA treatment on the amount of some glutathione S-transferase subunits and their corresponding translatable mRNA were studied in vivo. PFDA like some other peroxisome proliferators was a non-competitive inhibitor of several GST enzyme activities in vitro. In vivo PFDA reduced the enzyme activity towards substrates which are indicative for the Ya, Yb1 and Yb2 subunits of GSTs to a larger extent than the enzyme activity towards the substrate indicative for the Yc subunit. Whereas the reduction of GST enzyme activities by other peroxisome proliferators was shown to be caused by an inhibition of the relevant enzymes in vivo, PFDA was found to decrease the GST enzyme activities at least in part by lowering the amount of the various GST subunits in vivo due to a lowered concentration of translatable mRNA coding for these enzymes. In addition PFDA abolished the inducibility of GST mRNAs by phenobarbital. Thus PFDA might be an interesting tool for mechanistic studies of the control of GST expression in the liver.