Conformational diversity and enantioconvergence in potato epoxide hydrolase 1.

Potato epoxide hydrolase 1 (StEH1) is a biocatalytically important enzyme that exhibits rich enantio- and regioselectivity in the hydrolysis of chiral epoxide substrates. In particular, StEH1 has been demonstrated to enantioconvergently hydrolyze racemic mixes of styrene oxide (SO) to yield (R)-1-phenylethanediol. This work combines computational, crystallographic and biochemical analyses to understand both the origins of the enantioconvergent behavior of the wild-type enzyme, as well as shifts in activities and substrate binding preferences in an engineered StEH1 variant, R-C1B1, which contains four active site substitutions (W106L, L109Y, V141K and I155V). Our calculations are able to reproduce both the enantio- and regioselectivities of StEH1, and demonstrate a clear link between different substrate binding modes and the corresponding selectivity, with the preferred binding modes being shifted between the wild-type enzyme and the R-C1B1 variant. Additionally, we demonstrate that the observed changes in selectivity and the corresponding enantioconvergent behavior are due to a combination of steric and electrostatic effects that modulate both the accessibility of the different carbon atoms to the nucleophilic side chain of D105, as well as the interactions between the substrate and protein amino acid side chains and active site water molecules. Being able to computationally predict such subtle effects for different substrate enantiomers, as well as to understand their origin and how they are affected by mutations, is an important advance towards the computational design of improved biocatalysts for enantioselective synthesis.

Proposed reductive metabolism of artemisinin by glutathione transferases in vitro.

Artemisinin is a sesquiterpene lactone containing an endoperoxide bridge. It is a promising new antimalarial and is particularly useful against the drug resistant strains of Plasmodium falciparum. It has unique antimalarial properties since it acts through the generation of free radicals that alkylate parasite proteins. Since the antimalarial action of the drug is antagonised by glutathione and ascorbate and has unusual pharmacokinetic properties in humans, we have investigated if the drug is broken down by a typical reductive reaction in the presence of glutathione transferases. Cytosolic glutathione transferases (GSTs) detoxify electrophilic xenobiotics by catalysing the formation of glutathione (GSH) conjugates and exhibit glutathione peroxidase activity towards hydroperoxides. Artemisinin was incubated with glutathione, NADPH and glutathione reductase and GSTs in a coupled assay system analogous to the standard assay scheme with cumene hydroperoxide as a substrate of GSTs. Artemisinin was shown to stimulate NADPH oxidation in cytosols from rat liver, kidney, intestines and in affinity purified preparations of GSTs from rat liver. Using human recombinant GSTs hetelorogously expressed in Escherichia coli, artemisinin was similarly shown to stimulate NADPH oxidation with the highest activity observed with GST M1-1. Using recombinant GSTs the activity of GSTs with artemisinin was at least two fold higher than the reaction with CDNB. Considering these results, it is possible that GSTs may contribute to the metabolism of artemisinin in the presence of NADPH and GSSG-reductase. We propose a model, based on the known reactions of GSTs and sesquiterpenes, in which (1) artemisinin reacts with GSH resulting in oxidised glutathione; (2) the oxidised glutathione is then converted to reduced glutathione via glutathione reductase; and (3) the latter reaction may then result in the depletion of NADPH via GSSG-reductase. The ability of artemisinin to react with GSH in the presence of GST may be responsible for the NADPH utilisation observed in vitro and suggests that cytosolic GSTs are likely to be contributing to metabolism of artemisinin and related drugs in vivo.

Chlorine kinetic isotope effects on the haloalkane dehalogenase reaction.

We have found chlorine kinetic isotope effects on the dehalogenation catalyzed by haloalkane dehalogenase from Xanthobacter autotrophicus GJ10 to be 1.0045 +/- 0.0004 for 1,2-dichloroethane and 1.0066 +/- 0.0004 for 1-chlorobutane. The latter isotope effect approaches the intrinsic chlorine kinetic isotope effect for the dehalogenation step. The intrinsic isotope effect has been modeled using semiempirical and DFT theory levels using the ONIOM QM/QM scheme. Our results indicate that the dehalogenation step is reversible; the overall irreversibility of the enzyme-catalyzed reaction is brought about by a step following the dehalogenation.

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.

Examination of the transcription factor NtcA-binding motif by in vitro selection of DNA sequences from a random library.

A recursive in vitro selection among random DNA sequences was used for analysis of the cyanobacterial transcription factor NtcA-binding motifs. An eight-base palindromic sequence, TGTA-(N(8))-TACA, was found to be the optimal NtcA-binding sequence. The more divergent the binding sequences, compared to this consensus sequence, the lower the NtcA affinity. The second and third bases in each four-nucleotide half of the consensus sequence were crucial for NtcA binding, and they were in general highly conserved. The most frequently occurring sequence in the middle weakly conserved region was similar to that of the NtcA-binding motif of the Anabaena sp. strain PCC 7120 glnA gene, previously known to have high affinity for NtcA. This indicates that the middle sequences were selected for high NtcA affinity. Analysis of natural NtcA-binding motifs showed that these could be classified into two groups based on differences in recognition consensus sequences. It is suggested that NtcA naturally recognizes different DNA-binding motifs, or has differential affinities to these sequences under different physiological conditions.

Functional expression and affinity selection of single-chain cro by phage display: isolation of novel DNA-binding proteins.

A robust selection system affording phage display of the DNA-binding helix-turn-helix protein Cro is presented. The aim of the work was to construct an experimental system allowing for the construction and isolation of Cro-derived protein with new DNA-binding properties. A derivative of the phage lambda Cro repressor, scCro8, in which the protein subunits had been covalently connected via a peptide linker was expressed in fusion with the gene 3 protein of Escherichia coli filamentous phage. The phage-displayed single-chain Cro was shown to retain the DNA binding properties of its wild-type Cro counterpart regarding DNA sequence specificity and binding affinity. A kinetic analysis revealed the rate constant of dissociation of the single-chain Cro-phage/DNA complex to be indistinguishable from that of the free single-chain Cro. Affinity selection using a biotinylated DNA with a target consensus operator sequence allowed for a 3000-fold enrichment of phages displaying single-chain Cro over control phages. The selection was based on entrapment of phage/DNA complexes formed in solution on streptavidin-coated paramagnetic beads. The expression system was subsequently used to isolate variant scCro8 proteins, mutated in their DNA-binding residues, that specifically recognized new, unnatural target DNA ligands.

An approach to optimizing the active site in a glutathione transferase by evolution in vitro.

A glutathione transferase (GST) mutant with four active-site substitutions (Phe(10)-->Pro/Ala(12)-->Trp/Leu(107)-->Phe/Leu(108)-->Arg) (C36) was isolated from a library of active-site mutants of human GST A1-1 by the combination of phage display and mechanism-based affinity adsorption [Hansson, Widersten and Mannervik (1997) Biochemistry 36, 11252-11260]. C36 was selected on the basis of its affinity for the transition-state analogue 1-(S-glutathionyl)-2,4, 6-trinitrocyclohexadienate. C36 affords a 10(5)-fold rate enhancement over the uncatalysed reaction between reduced glutathione and 1-chloro-2,4-dinitrobenzene (CDNB), as evidenced by the ratio between k(cat)/K(m) and the second-order rate constant k(2). The present study shows that C36 can evolve to an even higher catalytic efficiency by an additional site-specific mutation. Random mutations of the fifth active-site residue 208 allowed the identification of 18 variants, of which the mutant C36 Met(208)-->Cys proved to be the most active form. The altered activity was substrate selective such that the catalytic efficiency with CDNB and with 1-chloro-6-trifluoromethyl-2,4-dinitrobenzene were increased 2-3-fold, whereas the activity with ethacrynic acid was decreased by a factor of 8. The results show that a single-point mutation in the active site of an enzyme may modulate the catalytic activity without being directly involved as a functional group in the enzymic mechanism. Such limited modifications are relevant both to the natural evolution and the in vitro redesign of proteins for novel functions.

Hydrophobic sequences can substitute for the wild-type N-terminal sequence of cystatin A (stefin A) in tight binding to cysteine proteinases selection of high-affinity N-terminal region variants by phage display.

A phage-display library of the cysteine-proteinase inhibitor, cystatin A, was constructed in which variants with the four N-terminal amino acids randomly mutated were expressed on the surface of filamenteous phage. Screening of this library for binding to papain gave predominantly variants with a glycine residue in position 4. This finding is in agreement with previous conclusions that glycine in this position is essential for tight binding of cystatin A to cysteine proteinases by allowing optimal interaction of the N-terminal region of the inhibitor with the enzyme. In contrast, the first three residues of the variants obtained by the screening were more variable. Two variants were identified with similar affinities for papain as the wild-type inhibitor, but with these residues, Val-Phe-Thr- or Ile-Leu-Leu, differing appreciably from those of the wild-type, Met-Ile-Pro. Other sequences of the N-terminal region, presumably mainly hydrophobic, can thus substitute for the wild-type sequence and contribute similar energy to the inhibitor-proteinase interaction. The two variants binding tightly to papain differed in their affinity for cathepsin B, demonstrating that cystatin variants with increased selectivity for a particular target cysteine proteinase can be obtained by phage-display technology.

Structural determinants in domain II of human glutathione transferase M2-2 govern the characteristic activities with aminochrome, 2-cyano-1,3-dimethyl-1-nitrosoguanidine, and 1,2-dichloro-4-nitrobenzene.

Two human Mu class glutathione transferases, hGST M1-1 and hGST M2-2, with high sequence identity (84%) exhibit a 100-fold difference in activities with the substrates aminochrome, 2-cyano-1,3-dimethyl-1-nitrosoguanidine (cyanoDMNG), and 1,2-dichloro-4-nitrobenzene (DCNB), hGST M2-2 being more efficient. A sequence alignment with the rat Mu class GST M3-3, an enzyme also showing high activities with aminochrome and DCNB, demonstrated an identical structural cluster of residues 164-168 in the alpha6-helices of rGST M3-3 and hGST M2-2, a motif unique among known sequences of human, rat, and mouse Mu class GSTs. A putative electrostatic network Arg107-Asp161-Arg165-Glu164(-Gln167) was identified based on the published three-dimensional structure of hGST M2-2. Corresponding variant residues of hGSTM1-1 (Leu165, Asp164, and Arg167) as well as the active site residue Ser209 were targeted for point mutations, introducing hGST M2-2 residues to the framework of hGST M1-1, to improve the activities with substrates characteristic of hGST M2-2. In addition, chimeric enzymes composed of hGST M1-1 and hGST M2-2 sequences were analyzed. The activity with 1-chloro-2,4-dinitrobenzene (CDNB) was retained in all mutant enzymes, proving that they were catalytically competent, but none of the point mutations improved the activities with hGST M2-2 characteristic substrates. The chimeric enzymes showed that the structural determinants of these activities reside in domain II and that residue Arg165 in hGST M2-2 appears to be important for the reactions with cyanoDMNG and DCNB. A mutant, which contained all the hGST M2-2 residues of the putative electrostatic network, was still lacking one order of magnitude of the activities with the characteristic substrates of wild-type hGST M2-2. It was concluded that a limited set of point mutations is not sufficient, but that indirect secondary structural affects also contribute to the hGST M2-2 characteristic activities with aminochrome, cyanoDMNG, and DCNB.

Heterologous expression in Escherichia coli of soluble active-site random mutants of haloalkane dehalogenase from Xanthobacter autotrophicus GJ10 by coexpression of molecular chaperonins GroEL/ES.

A system for heterologous expression in Escherichia coli of dehaloalkane dehalogenase Dh1A from Xanthobacter autotrophicus strain GJ10 is presented. The strategy involved overexpression of E. coli chaperonins GroEL/ES which facilitated the production of soluble Dh1A. When active-site mutant forms were constructed they could not to any detectable degree be expressed in a soluble state in the absence of overproduced GroEL/ES. However, with the described expression system, wild-type Dh1A as well as variant forms randomly mutated in the active-site residues Phe172 and Trp175 were reliably produced. An introduced C-terminal (His)5-tag provided an immunological handle as well as a site for metal ion coordination utilized in affinity chromatography for the purification of recombinant Dh1A. The purified His-tagged enzyme, Dh1A-5His, was confirmed to be catalytically fully active when measuring the dehalogenase activity with dichloroethane as substrate.

An evolutionary approach to the design of glutathione-linked enzymes.

Studies of protein structure provide information about principles of protein design that have come into play in natural evolution. This information can be exploited in the redesign of enzymes for novel functions. The glutathione-binding domain of glutathione transferases has similarities with structures in other glutathione-linked proteins, such as glutathione peroxidases and thioredoxin (glutaredoxin), suggesting divergent evolution from a common ancestral protein fold. In contrast, the binding site for glutathione in human glyoxalase I is located at the interface between the two identical subunits of the protein. Comparison with the homologous, but monomeric, yeast glyoxalase I suggests that new domains have originated through gene duplications, and that the oligomeric structure of the mammalian glyoxalase I has arisen by 'domain swapping'. Recombinant DNA techniques are being used for the redesign of glutathione-linked proteins in attempts to create binding proteins with novel functions and catalysts with tailored specificities. Enzymes with desired properties are selected from libraries of variant structures by use of phage display and functional assays.

Structure-activity relationships and thermal stability of human glutathione transferase P1-1 governed by the H-site residue 105.

Human glutathione transferase P1-1 (GSTP1-1) is polymorphic in amino acid residue 105, positioned in the substrate binding H-site. To elucidate the role of this residue an extensive characterization of GSTP1-1/Ile105 and GSTP1-1/Val105 was performed. Mutant enzymes with altered volume and hydrophobicity of residue 105, GSTP1-1/Ala105 and GSTP1-1/Trp105, were constructed and included in the study. Steady-state kinetic parameters and specific activities were determined using a panel of electrophilic substrates, with the aim of covering different types of reaction mechanisms. Analysis of the steady-state kinetic parameters indicates that the effect of the substitution of the amino acid in position 105 is highly dependent on substrate used. When 1-chloro-2,4-dinitrobenzene was used as substrate a change in the side-chain of residue 105 seemed primarily to cause changes in the KM value, while the kcat value was not distinctively affected. With other substrates, such as 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole and ethacrynic acid both kcat and KM values were altered by the substitution of amino acid 105. The constant for formation of the sigma-complex between 1,3, 5-trinitrobenzene and glutathione was shown to be dependent upon the volume of the amino acid in position 105. The nature of the amino acid in position 105 was also shown to affect the thermal stability of the enzyme at 50 degrees C, indicating an important role for this residue in the stabilization of the enzyme. The GSTP1-1/Ile105 variant was approximately two to three times more stable than the Val105 variant as judged by their half-lives. The presence of glutathione in the incubation buffer afforded a threefold increase in the half-lives of the enzymes. Thus, the thermal stability of the enzyme and depending on substrate, both KM values and turnover numbers are influenced by substitutions in position 105 of GSTP1-1.

Differences in the catalytic efficiencies of allelic variants of glutathione transferase P1-1 towards carcinogenic diol epoxides of polycyclic aromatic hydrocarbons.

Previous studies have identified allelic variants of the human glutathione transferase (GST) Pi gene and showed that the two different encoded proteins with isoleucine (GSTP1-1/I-105) or valine (GSTP1-1/V-105) at position 105, respectively, differ significantly in their catalytic activities with model substrates. Moreover, recent epidemiological studies have demonstrated that individuals differing in the expression of these allelic variants also differ in susceptibility to tumour formation in certain organs, including such in which polycyclic aromatic hydrocarbons (PAH) may be etiological factors. In the present study the catalytic efficiencies (kcat/Km) of these GSTP1-1 variants were determined with a number of stereoisomeric bay-region diol epoxides, known as the ultimate mutagenic and carcinogenic metabolites of PAH, including those from chrysene, benzo[a]pyrene and dibenz[a,h]anthracene. In addition, GSTP1-1 mutants in which amino residue 105 is alanine (GSTP1-1/A-105) or tryptophan (GSTP1-1/W-105) have been constructed and characterized. GSTP1-1/V-105 was found to be more active than GSTP1-1/I-105 in conjugation reactions with the bulky diol epoxides of PAH, being up to 3-fold as active towards the anti- and syn-diol epoxide enantiomers with R-absolute configuration at the benzylic oxiranyl carbon. Comparing the four enzyme variants, GSTP1-1/A-105 generally demonstrated the highest kcat/Km value and GSTP1-1/W-105 the lowest with the anti-diol epoxides. A close correlation was observed between the volume occupied by the amino acid residue at position 105 and the value of kcat/Km. With the syn-diol epoxides, such a correlation was observed with alanine, valine and isoleucine, whereas tryptophan was associated with increased kcat/Km values. The mutational replacement of isoleucine with alanine or tryptophan at position 105 did not alter the enantio selectivity of the GSTP1-1 variants compared with the naturally occurring allelic variants GSTP1-1/I-105 and GSTP1-1/V-105. Since the amino acid at position 105 forms part of the substrate binding site (H-site) the effect of increasing bulkiness is expected to cause restricted access of the diol epoxide and proper alignment of the two reactants for efficient glutathionylation. In conclusion, the present study indicates that individuals who are homozygous for the allele GSTP1* B (coding for GSTP1-1/V-105) display a higher susceptibility to malignancy because of other factors than a decreased catalytic efficiency of GSTP1-1/V-105 in the detoxication of carcinogenic diol epoxides of benzo[a]pyrene or structurally related PAH.

Glutathione conjugation of bay- and fjord-region diol epoxides of polycyclic aromatic hydrocarbons by glutathione transferases M1-1 and P1-1.

Metabolism of polycyclic aromatic hydrocarbons in mammalian cells results in the formation of vicinal diol epoxides considered as ultimate carcinogens if the oxirane ring is located in a bay- or fjord-region of the parent compound. In the present study, individual stereoisomers of the bay-region diol epoxides of chrysene, dibenz[a,h]anthracene, and benzo[a]pyrene as well as of the fjord-region diol epoxides of benzo[c]phenanthrene, benzo[c]chrysene, and benzo[g]-chrysene have been incubated with GSH in the presence of human glutathione transferases GSTM1-1 (a mu-class enzyme) and GSTP1-1 (a pi-class enzyme). As previously shown with GSTA1-1 (an alpha-class enzyme) both M1-1 and P1-1 demonstrate considerable activity toward a number of the diol epoxides studied, although a great variation in catalytic efficiency and enantioselectivity was observed. With GSTM1-1, the bay-region diol epoxides, in particular the syn-diastereomers were in most cases more efficiently conjugated with GSH than the fjord-region analogues. GSTM1-1 demonstrated an enantioselectivity ranging from no preference (50%) to high preference (> or = 90%) for conjugation of the enantiomers with R-configuration at the benzylic position of the oxirane ring. With GSTP1-1, the enzyme demonstrated appreciable activity toward both bay- and fjord-region diol epoxides and, in most cases, a preference for the anti-diastereomers. In contrast to GSTM1-1 and as previously shown for GSTA1-1, GSTP1-1 showed an exclusive preference for conjugation of the enantiomers with R-configuration at the benzylic oxirane carbon. With both GSTM1-1 and GSTP1-1, the chemically most reactive diol epoxide, the (+)-syn-enantiomer of trans-7,8-dihydroxy-9,10-epoxy-7,8,9,-10-tetrahydrobenzo[a]pyrene (BPDE), was the best substrate. As for GSTA1-1, no obvious correlation between chemical reactivity or lipophilicity of the compounds and catalytic efficiencies was observed. Molecular modeling of diol epoxides in the active sites of GSTP1-1 and -A1-1 is in agreement with the assumption, based on functional studies, that the H-site of GSTA1-1 [Jernström et al. (1996) Carcinogenesis 17, 1491-1498] can accommodate stereoisomers of different sizes. Further, modeling of the enantiomers of anti- and syn-BPDE in the active site of GSTP1-1 provides an explanation for the exclusive preference for the enantiomers with R-configuration at the benzylic oxirane carbon. These isomers could be snuggly fitted in the H-site close to the GSH sulfur, whereas those with opposite stereochemistry could not.

Mechanism-based phage display selection of active-site mutants of human glutathione transferase A1-1 catalyzing SNAr reactions.

A library of active-site mutants has been constructed by targeting selected amino acid residues in human glutathione transferase (GST) A1-1 for random mutagenesis. The mutated residues are suitably positioned for interaction with the second, electrophilic substrate, in particular chloronitrobenzene derivatives undergoing SNAr reactions. DNA representing the GST A1-1 mutant library was fused with DNA encoding gene III protein, a component of the coat of filamentous phage. Phage display was used for affinity selection of GST A1-1 mutants with altered catalytic properties. The affinity ligand used was the sigma-complex of 1,3,5-trinitrobenzene and glutathione immobilized to Sepharose. The complex was designed to mimic the transition state of SNAr reactions catalyzed by GSTs. The selection system is based on the combination of affinity for the sigma-complex as well as the ability to promote its formation, thus mimicking two salient features of the assumed catalytic mechanism for the SNAr reactions. Many of the GST A1-1 mutants selected and analyzed contained an aromatic amino acid residue in one of the mutated positions, suggesting favorable interactions with the trinitrocyclohexadienate moiety of the affinity ligand. A mutant C36 was selected for more detailed studies. Its catalytic efficiency with several chloronitrobenzene substrates was 20-90-fold lower than that of wild-type GST A1-1, but fully comparable to naturally evolved GSTs of different classes, providing a 10(5)-fold rate enhancement over the uncatalyzed reaction. In the conjugation of ethacrynic acid, a Michael addition reaction, mutant C36 was 13-fold more efficient than the wild-type enzyme. Within experimental error, the quotient between the KF values for wild-type GST A1-1 and mutant C36 is the same as that between the kcat/KM values determined with 1-chloro-2,4-dinitrobenzene for the two enzyme forms. This result indicates that sigma-complex formation is rate-limiting for the catalyzed reaction. Thus, the principle of transition-state stabilization as a component of catalysis has been successfully exploited in affinity selection of catalytically competent GST A1-1 mutants. This mechanism-based procedure also selects for the ability to promote sigma-complex formation, and serves as a probe of the catalytic mechanism.

Glutathione transferases catalyse the detoxication of oxidized metabolites (o-quinones) of catecholamines and may serve as an antioxidant system preventing degenerative cellular processes.

o-Quinones are physiological oxidation products of catecholamines that contribute to redox cycling, toxicity and apoptosis, i.e. the neurodegenerative processes underlying Parkinson's disease and schizophrenia. The present study shows that the cyclized o-quinones aminochrome, dopachrome, adrenochrome and noradrenochrome, derived from dopamine, dopa, adrenaline and noradrenaline respectively, are efficiently conjugated with glutathione in the presence of human glutathione transferase (GST) M2-2. The oxidation product of adrenaline, adrenochrome, is less active as a substrate for GST M2-2, and more efficiently conjugated by GST M1-1. Evidence for expression of GST M2-2 in substantia nigra of human brain was obtained by identification of the corresponding PCR product in a cDNA library. Glutathione conjugation of these quinones is a detoxication reaction that prevents redox cycling, thus indicating that GSTs have a cytoprotective role involving elimination of reactive chemical species originating from the oxidative metabolism of catecholamines. In particular, GST M2-2 has the capacity to provide protection relevant to the prevention of neurodegenerative diseases.

Conjugation of highly reactive aflatoxin B1 exo-8,9-epoxide catalyzed by rat and human glutathione transferases: estimation of kinetic parameters.

Aflatoxin B1 (AFB1) exo-8,9-epoxide, the reactive product of the hepatocarcinogen AFB1, is stable in aprotic solvents but hydrolyzes rapidly in H2O at 25 degrees C and pH 7 (t1/2 = 1 s). However, it is also known that some glutathione (GSH) transferases can conjugate the epoxide with GSH to give the adduct in high yield. We developed an approach to estimating kinetic parameters for reactions involving this epoxide or other substrates that are unstable to H2O. Varying concentrations of the (anhydrous) epoxide and GSH transferase were mixed and the GSH conjugates were measured. The final concentrations of product were known for each set of the starting epoxide and enzyme concentrations in a modeling approach, where the competition with the hydrolysis reaction is considered with two variables, a K for binding of the enzyme and epoxide and a rate k2, which includes microscopic steps following complex formation and resulting in conjugate formation. The ratio k2/K, a measure of enzyme efficiency, varied among individual recombinant GSH transferases in the the order (rat) 10-10 >> 3-3 > (human) M1-1 > T1-1 > A1-1 > P1-1 > A2-2, from 3 x 10(6) to 10 M(-1) s(-1). The high ratio of M1-1 among the human GSH transferase enzymes tested is consistent with other work in which GSH-AFB1 conjugates were not detected in hepatocytes with an M1 null polymorphism. This general kinetic approach should be applicable to estimation of kinetic parameters involved in the interaction of other unstable substrates with enzymes.

Human class Mu glutathione transferases, in particular isoenzyme M2-2, catalyze detoxication of the dopamine metabolite aminochrome.

Human glutathione transferases (GSTs) were shown to catalyze the reductive glutathione conjugation of aminochrome (2, 3-dihydroindole-5,6-dione). The class Mu enzyme GST M2-2 displayed the highest specific activity (148 micromol/min/mg), whereas GSTs A1-1, A2-2, M1-1, M3-3, and P1-1 had markedly lower activities (<1 micromol/min/mg). The product of the conjugation, with a UV spectrum exhibiting absorption peaks at 277 and 295 nm, was 4-S-glutathionyl-5,6-dihydroxyindoline as determined by NMR spectroscopy. In contrast to reduced forms of aminochrome (leucoaminochrome and o-semiquinone), 4-S-glutathionyl-5, 6-dihydroxyindoline was stable in the presence of molecular oxygen, superoxide radicals, and hydrogen peroxide. However, the strongly oxidizing complex of Mn3+ and pyrophosphate oxidizes 4-S-glutathionyl-5,6-dihydroxyindoline to 4-S-glutathionylaminochrome, a new quinone derivative with an absorption peak at 620 nm. GST M2-2 (and to a lower degree, GST M1-1) prevents the formation of reactive oxygen species linked to one-electron reduction of aminochrome catalyzed by NADPH-cytochrome P450 reductase. The results suggest that the reductive conjugation of aminochrome catalyzed by GSTs, in particular GST M2-2, is an important cellular antioxidant activity preventing the formation of o-semiquinone and thereby the generation of reactive oxygen species.

Involvement of the carboxyl groups of glutathione in the catalytic mechanism of human glutathione transferase A1-1.

The present study proposes the participation of both carboxylate groups of the glutathione molecule as functional entities in the catalytic apparatus of human glutathione transferase (GST) A1-1. Functional studies in combination with structural data provide evidence for the alpha-carboxylate of the Glu residue of glutathione acting as a proton acceptor in the catalytic mechanism. The Glu carboxylate is hydrogen-bonded to a protein hydroxyl group and a main-chain NH, as well as to a water molecule of low mobility in the active site region. The Glu alpha-carboxylate of glutathione is bound in a similar manner to the active sites of mammalian glutathione transferases of classes Alpha, Mu, and Pi, for which three-dimensional structures are known. Mutation of the hydroxyl group that is hydrogen-bonded to the alpha-carboxylate of the Glu residue of glutathione (Thr68->Val) caused a shift of the pH dependence of the enzyme-catalyzed reaction, suggesting that the acidic limb of the pH-activity profile reflects the ionization of the carboxylate of the Glu residue of glutathione. The second carboxylate group of glutathione, which is part of its Gly residue, interacts with two Arg side chains in GST A1-1. One of these residues (Arg45) may influence an ionic interaction (Arg221/Asp42), which appears to contribute to binding of the second substrate by fixing the C-terminal alpha-helix as a lid over the active site. Removal of the Gly residue from the glutathione molecule caused a 13-fold increase in the KM value for the electrophilic substrate. Thus, the Gly carboxylate of glutathione, by way of influencing the topology of the active site, contributes to the binding of the second substrate of the enzyme. Consequently, the glutathione molecule has several functions in the glutathione transferase catalyzed reactions, not only as a substrate providing the thiol group for different types of chemical reactions but also as a substrate contributing a carboxylate that acts as a proton acceptor in the catalytic mechanism and a carboxylate that modulates binding of the second substrate to the enzyme.