A crystallographic study of the glutathione binding site of glutathione reductase at 0.3-nm resolution

The binding of glutathione, some related molecules and two redox compounds to crystals of glutathione reductase has been investigated by X-ray crystallography at 0.3-nm resolution. Models for several bound ligands have been built and subjected to crystallographic refinement. The results clearly show the residues involved in glutathione binding as well as the geometry of the disulfide exchange. Glutathione-I is bound in a V-shaped conformation, while glutathione-II is extended. The zwitterionic glutamyl end of glutathione-II appears to be the most tightly bound part of the substrate. All glutathione conjugates and derivatives studied show binding dominated by the interactions at this site. In the reduced enzyme, glutathione-I forms a mixed disulfide intermediate with Cys58. Other structural changes are observed on reduction of the enzyme, and it is demonstrated that the carboxamidomethylated enzyme is a good model for the reduced species. Lipoate, a weak substrate of the enzyme, assumes a defined binding site where its disulfide is available for being attacked by Cys58-S gamma. A second region with affinity for a number of compounds has been found in a large cavity at the dimer interface of the enzyme. No functional role of this site is known.     

Studies on the activity and activation of rat liver microsomal glutathione transferase with a series of glutathione analogues

The substrate specificity of rat liver microsomal glutathione transferase toward glutathione has been examined in a systematic manner. Out of a glycyl-modified and eight gamma-glutamyl-modified glutathione analogues, it was found that four (glutaryl-L-Cys-Gly, alpha-L-Glu-L-Cys-Gly, alpha-D-Glu-L-Cys-Gly, and gamma-L-Glu-L-Cys-beta-Ala) function as substrates. The kinetic parameters for three of these substrates (the alpha-D-Glu-L-Cys-Gly analogue gave very low activity) were compared with those of GSH with both unactivated and the N-ethylmaleimide-activated microsomal glutathione transferase. The alpha-L-Glu-L-Cys-Gly analogue is similar to GSH in that it has a higher kcat (6.9 versus 0.6 s-1) value with the activated enzyme compared with the unactivated enzyme but displays a high Km (6 versus 11 mM) with both forms. Glutaryl-L-Cys-Gly, in contrast, exhibited a similar kcat (8.9 versus 6.7 s-1) with the N-ethylmaleimide-treated enzyme but retains a higher Km value (50 versus 15 mM). Thus, the alpha-amino group of the glutamyl residue in GSH is important for the activity of the activated microsomal glutathione transferase. These observations were quantitated by analyzing the changes in the Gibbs free energy of binding calculated from the changes in kcat/Km values, comparing the analogues to GSH and each other. It is estimated that the binding energy of the alpha-amino group of the glutamyl residue in GSH contributes 9.7 kJ/mol to catalysis by the activated enzyme, whereas the corresponding value for the unactivated enzyme is 3.2 kJ/mol. The importance of the acidic functions in glutathione is also evident as shown by the lack of activity with 4-aminobutyric acid-L-Cys-Gly and the low kcat/Km values with gamma-L-Glu-L-Cys-beta-Ala (0.03 and 0.01 mM-1s-1 for unactivated and activated enzyme, respectively). Utilization of binding energy from a correctly positioned carboxyl group in the glycine residue (10 and 17 kJ/mol for unactivated and activated enzyme, respectively) therefore also appears to be required for optimal activity and activation. A conformational change in the microsomal glutathione transferase upon treatment with N-ethylmaleimide or trypsin, which allows utilization of binding energy from the alpha-amino group of GSH as well as the glycine carboxyl in catalysis, is suggested to account for at least part of the activation of the enzyme.     

Interaction of a glutathione S-conjugate with glutathione reductase. Kinetic and X-ray crystallographic studies

S-Conjugates of glutathione influence the glutathione/glutathione disulfide (GSH/GSSG) status of hepatocytes in at least two ways, namely by inhibition of GSSG transport into the bile [Akerboom et al. (1982) FEBS Lett. 140, 73-76] and by inhibition of the enzyme GSSG reductase (EC 1.6.4.2). The interaction of GSSG reductase with a well-studied conjugate, namely S-(2,4-dinitrophenyl)-glutathione and its electrophilic precursor 1-chloro-2,4-dinitrobenzene are described. For short exposures both compounds are reversible inhibitors of the enzyme, the Ki values being 30 microM and 22 microM respectively. After prolonged incubation, 1-chloro-2,4-dinitrobenzene blocks GSSG reductase irreversibly, which emphasizes the need for rapid conjugate formation in situ. As shown by X-ray crystallography the major binding site of S-(2,4-dinitrophenyl)-glutathione in GSSG reductase overlaps the binding site of the substrate, glutathione disulfide. However, the glutathione moiety of the conjugate does not bind in the same manner as either of the glutathiones in the disulfide.     

Kinetic analysis of the slow ionization of glutathione by microsomal glutathione transferase MGST1

An important aspect of the catalytic mechanism of microsomal glutathione transferase (MGST1) is the activation of the thiol of bound glutathione (GSH). GSH binding to MGST1 as measured by thiolate anion formation, proton release, and Meisenheimer complex formation is a slow process that can be described by a rapid binding step (K(GSH)d = 47 +/- 7 mM) of the peptide followed by slow deprotonation (k2 = 0.42 +/- 0.03 s(-1). Release of the GSH thiolate anion is very slow (apparent first-order rate k(-2) = 0.0006 +/- 0.00002 s(-)(1)) and thus explains the overall tight binding of GSH. It has been known for some time that the turnover (kcat) of MGST1 does not correlate well with the chemical reactivity of the electrophilic substrate. The steady-state kinetic parameters determined for GSH and 1-chloro-2,4-dinitrobenzene (CDNB) are consistent with thiolate anion formation (k2) being largely rate-determining in enzyme turnover (kcat = 0.26 +/- 0.07 s(-1). Thus, the chemical step of thiolate addition is not rate-limiting and can be studied as a burst of product formation on reaction of halo-nitroarene electrophiles with the E.GS- complex. The saturation behavior of the concentration dependence of the product burst with CDNB indicates that the reaction occurs in a two-step process that is characterized by rapid equilibrium binding ( = 0.53 +/- 0.08 mM) to the E.GS- complex and a relatively fast chemical reaction with the thiolate (k3 = 500 +/- 40 s(-1). In a series of substrate analogues, it is observed that log k3 is linearly related (rho value 3.5 +/- 0.3) to second substrate reactivity as described by Hammett sigma- values demonstrating a strong dependence on chemical reactivity that is similar to the nonenzymatic reaction (rho = 3.4). Microsomal glutathione transferase 1 displays the unusual property of being activated by sulfhydryl reagents. When the enzyme is activated by N-ethylmaleimide, the rate of thiolate anion formation is greatly enhanced, demonstrating for the first time the specific step that is activated. This result explains earlier observations that the enzyme is activated only with more reactive substrates. Taken together, the observations show that the kinetic mechanism of MGST1 can be described by slow GSH binding/thiolate formation followed by a chemical step that depends on the reactivity of the electrophilic substrate. As the chemical reactivity of the electrophile becomes lower the rate-determining step shifts from thiolate formation to the chemical reaction.     

Residue 219 impacts on the dynamics of the C-terminal region in glutathione transferase A1-1: implications for stability and catalytic and ligandin functions

The C-terminal region in class alpha glutathione transferases (GSTs) modulates the catalytic and nonsubstrate ligand binding functions of these enzymes. Except for mouse GST A1-1 (mGST A1-1), the structures of class alpha GSTs have a bulky aliphatic side chain topologically equivalent to Ile219 in human GST A1-1 (hGST A1-1). In mGST A1-1, the corresponding residue is an alanine. To investigate the role of Ile219 in determining the conformational dynamics of the C-terminal region in hGST A1-1, the residue was replaced by alanine. The substitution had no effect on the global structure of hGST A1-1 but did reduce the conformational stability of the C-terminal region of the protein. This region could be stabilized by ligands bound at the active site. The catalytic behavior of hGST A1-1 was significantly compromised by the I219A mutation as demonstrated by reduced enzyme activity, increased K(m) for the substrates glutathione (GSH) and 1-chloro-2,4-dinitrobenzene (CDNB), and reduced catalytic efficiencies. Inhibition studies also indicated that the binding affinities for product and substrate analogues were dramatically decreased. The affinity of the mutant for GSH was, however, only slightly increased, indicating that the G-site was unaltered by the mutation. The binding affinity and stoichiometry for the anionic dye 8-anilino-1-naphthalene sulfonate (ANS) was also not significantly affected by the I219A mutation. However, the lower DeltaC(p) for ANS binding to the mutant (-0.34 kJ/mol per K compared with -0.84 kJ/mol per K for the wild-type protein) suggests that ANS binding to the mutant results in the burial of less hydrophobic surface area. Fluorescence data also indicates that ANS bound to the mutant is more prone to quenching by water. Overall, the data from this study, together with the structural details of the C-terminal region in mGST A1-1, show that Ile219 is an important structural determinant of the stability and dynamics of the C-terminal region of hGST A1-1.     

The C-terminal region of human glutathione transferase A1-1 affects the rate of glutathione binding and the ionization of the active-site Tyr9

In human glutathione transferase (GST) A1-1, the C-terminal region covers the active site and contributes to substrate binding. This region is flexible, but upon binding of an active-site ligand, it is stabilized as an amphipatic alpha-helix. The stabilization has implications for the catalytic activity of the enzyme. In the present study, residue M208 in GST A1-1 has been mutated to Lys and Glu, and residue F220 to Ala and Thr. These mutations are likely to destabilize the C-terminal region due to loss of hydrophobic interactions with the rest of the hydrophobic binding site. The rate constant for binding of glutathione to wild-type GST A1-1 is 450 mM(-)(1) s(-)(1) at 5 degrees C and pH 7.0, which is less than for an association limited by diffusion. However, the M208 and the F220 mutations increase the apparent on-rate constant for glutathione binding to 640-1170 mM(-)(1) s(-)(1). The binding data can be explained by a rapid reversible transition between different enzyme conformations occurring prior to glutathione binding, and restriction of the access to the active site by the C-terminal region. The effect of the mutations appears to be promotion of a less closed conformation, thereby facilitating the association of glutathione and enzyme. Both the M208 and F220 mutants display a lowered pK(a) value ( approximately 0.3 log unit) of the catalytically important Tyr9. Residue 208 does not interact directly with Tyr9 in the active site, and the shift in pK(a) value is therefore ascribed to the proposed dislocation of the C-terminal region caused by the mutation.     

Conversion of glutathione to glutathione disulfide, a catalytic function of gamma-glutamyl transpeptidase.

A purification procedure, based on that previously used for rat kidney gamma-glutamyl transpeptidase, was used for the purification of glutathione oxidase (which converts glutathione to gluthathione disulfide). The two activities co-purified, the ratio of the activities remaining constant through all steps of the isolation procedure. The purified enzyme was separable into 12 isozymic species by isoelectric focusing. All 12 isozymes exhibited a constant ratio of transpeptidase to glutathione oxidase activities, strongly supporting the conclusion that conversion of glutathione to glutathione disulfide is a catalytic function of gamma-glutamyl transpeptidase. Modulation of oxidase activity by inhibitors and acceptor substrates of transpeptidase is discussed in relation to the possible glutathione binding sites involved in gamma-glutamyl transfer and oxidase activities of the enzyme.     

Irreversible inhibition of the human placental NADP-linked 15-hydroxyprostaglandin dehydrogenase/9-ketoprostaglandin reductase by glutathione thiosulfonate

Oxidation of glutathione disulfide by a mixture of performic and hydrochloric acids leads to the formation of several compounds that are stronger inhibitors than glutathione disulfide of the placental enzyme that possess both NADP-linked 15-hydroxyprostaglandin dehydrogenase and 9-ketoprostaglandin reductase activities. The only one of these inhibitors that has been identified is glutathione thiosulfonate. The others are unstable and may include glutathione sulfinyl sulfone and glutathione disulfone. Since the enzyme appears to have a glutathione binding site in close proximity to its active site and glutathione thiosulfonate reacts with free sulfhydryl groups, the effects of this thiosulfonate on the enzyme were examined in more detail. Glutathione thiosulfonate and methyl methanethiosulfonate cause a time-dependent irreversible inhibition of both the hydroxyprostaglandin dehydrogenase and the ketoprostaglandin reductase activities, presumably by reacting with a free sulfhydryl at the prostaglandin binding site. Experiments with PGA1-glutathione show that this sulfhydryl is not necessary for the catalytic activity of the enzyme as long as the substrate can bind at the glutathione site.     

Proline-glutamate chimeras in isopeptides. Synthesis and biological evaluation of conformationally restricted glutathione analogues

The two novel diastereoisomeric glutathione analogues 1 and 2 have been designed and synthesized by replacing the native gamma-glutamylic moiety with the conformational rigid skeleton of cis- or trans-4-carboxy-L-proline residue. Both analogues have been obtained by following the solution phase peptide chemistry methodologies and final reduction of the corresponding disulfide forms 13 and 14. The two analogues 1 and 2 have been tested towards gamma-glutamyltranspeptidase (gamma-GT) and human glutathione S-transferase (hGST P1-1). Both analogues 1 and 2 are completely resistant to enzymatic degradation by gamma-GT. The S-transferase utilizes the analogue 2 as a good substrate while is unable to bind the analogue 1.     

The binding of the retro-analogue of glutathione disulfide to glutathione reductase

The retro-analogue of glutathione disulfide was bound to the GSSG binding site of crystalline glutathione reductase. The binding mode revealed why the analogue is a very poor substrate in enzyme catalysis. The observed binding mode difference between natural substrate and retro-analogue is explained.     

Expression, purification, and characterization of Mycobacterium tuberculosis mycothione reductase.

Mycothione reductase from the human pathogen Mycobacterium tuberculosis has been cloned, expressed in Mycobacterium smegmatis, and purified 145-fold to homogeneity in 43% yield. Amino acid sequence alignment of mycothione reductase with the functionally homologous glutathione and trypanothione reductase indicates conservation of the catalytically important redox-active disulfide, histidine-glutamate ion pair, and regions involved in binding both the FAD cofactor and the substrate NADPH. The homogeneous 50 kDa subunit enzyme exists as a homodimer and is NADPH-dependent and highly specific for the structurally unique low-molecular mass disulfide, mycothione, exhibiting Michaelis constants of 8 and 73 microM for NADPH and mycothione, respectively. HPLC analysis indicated the presence of 1 mol of bound FAD per monomer as the cofactor exhibiting an absorption spectrum with a lambda(max) at 462 nm with an extinction coefficient of 11 300 M(-)(1) cm(-)(1). The reductive titration of the enzyme with NADH indicates the presence of a charge-transfer complex of one of the presumptive catalytic thiolates and FAD absorbing at ca. 530 nm. Reaction with serially truncated mycothione and other disulfides and pyridine nucleotide analogues indicates a strict minimal disulfide substrate requirement for the glucosamine moiety of mycothione. The enzyme exhibits bi-bi ping-pong kinetics with both disulfide and quinone substrates. Transhydrogenase activity is observed using NADH and thio-NADP(+), confirming the kinetic mechanism. We suggest mycothione reductase as the newest member of the class I flavoprotein disulfide reductase family of oxidoreductases.     

Irreversible inhibition of the human placental NADP-linked 15-hydroxyrpostaglandin dehydrogenase/9-ketoprostaglandin reductase by glutathione thiosulfonate

Oxidation of glutathione disulfide by a mixture of performic and hydrochloric acids leads to the formation of several compounds that are stronger inhibitors than glutathione disulfide of the placental enzyme that posses both NADP-linked 15-hydroxypyrostaglandin dehydrogenase and 9-ketoprostaglandin reductase activities. The only one of these inhibitors that has been identified is glutathione thiosulfonate. The others are unstble and may include glutathione sulfinyl sulfone and glutathione disulfone. Since the enzyme appears to have a glutathione binding site in close proximity to its active site and glutathione thiosulfonate reacts with free sulfhydryl groups, the effects of this thiosulfonate on the enzyme were examined in more detail. Glutahione thiosulfonate and methyl methanethiosulfonate cause a time-dependent irreversible inhibition of both the hydroxyprostaglandin dehydrogenase and the ketoprostaglandin reductase activities, presumably by reacting with a free sulfhydryl at the prostaglandin binding site. Experiments with PGA-glutathione show that this sulfhydryl is not necessary for the catalytic activity of the enzyme as long as the substrate can bind at the glutahione site.     

Crystal structure of the antioxidant enzyme glutathione reductase inactivated by peroxynitrite.

As part of our studies on the nitric oxide-related pathology of cerebral malaria, we show that the antioxidative enzyme glutathione reductase (GR) is inactivated by peroxynitrite, with GR from the malarial parasite Plasmodium falciparum being more sensitive than human GR. The crystal structure of modified human GR at 1.9-A resolution provides the first picture of protein inactivation by peroxynitrite and reveals that this is due to the exclusive nitration of 2 Tyr residues (residues 106 and 114) at the glutathione disulfide-binding site. The selective nitration explains the impairment of binding the peptide substrate and thus the nearly 1000-fold decrease in catalytic efficiency (k(cat)/K(m)) of glutathione reductase observed at physiologic pH. By oxidizing the catalytic dithiol to a disulfide, peroxynitrite itself can act as a substrate of unmodified and bisnitrated P. falciparum glutathione reductase.     

嗜酸氧化亚铁硫杆菌的谷胱甘肽还原酶的结构模建和底物分子对接

极端环境微生物嗜酸氧化亚铁硫杆菌的谷胱甘肽还原酶(GR)可能在它的抵抗极端酸性,有毒和氧化性的生物浸出环境中发挥至关重要的作用.通过同源模建技术和分子动力学模拟,它的一个三维结构被构建,优化和检验了.获得的结构被进一步用于搜索绑定位点,跟辅因子黄素腺嘌呤二核苷酸(FAD)和底物谷胱甘肽(GSSG)进行分子柔性对接,并以此识别关健残基.对接结果显示,位于活性残基Cys42和Cys47之间的二硫键夹在FAD的活性位点和底物GSSG的二硫键之间.它们之间的距离非常靠近,这跟底物反应机理的初始步骤的情况十分一致.相互作用能表明8个酶中残基Cys42,Cys47,GIu443B,Glu444B,His438B,Ser14,Thr447B和Lys51是固定或激活GSSG的关键残基,这跟以前的实验事实相吻合.此外,根据相互作用能我们还新发现7个重要残基(Arg449B,Pro439B,Thr440B,Thr310,Va143,Gly46 and Va148).所有这些残基在其它物种中的相应物中也都是保守的.这些结果有助于进一步的实验研究和理解其催化机理,进而揭示这种细菌的抗毒机理,服务于工业应用.     

Construction of the active site of glutathione peroxidase on polymer-based nanoparticles

A new nanoenzyme model with glutathione peroxidase-like active site was constructed on polystyrene nanoparticle (PN1) via microemulsion polymerization. In this model system, two functional monomers were designed: one is a tellurium-containing compound that was introduced on the surface of the nanoparticle and acts as a catalytic center, and the other one is an arginine-containing compound designed as a binding site for the complexation of the carboxyl group of substrate 3-carboxy-4-nitrobenzenethiol (ArSH, 1). As a new glutathione peroxidase (GPx) mimic, it demonstrated excellent catalytic activity and substrate specificity. In ArSH assay system, it was at least 316,000-fold more efficient than PhSeSePh for the reduction of cumene hydroperoxide (CUOOH) by ArSH. In contrast to model PN2, which lacks of substrate binding site, PN1 exhibits an obvious enhancement in catalytic activity. To further promote the catalytic efficiency, a substrate ArSH surface-imprinted nanoenzyme model (I-PN) was developed. By correctly incorporating and positioning the catalytic center tellurium and functional binding factor guanidinium, a continuative activity enhancement of 596,000-fold for the reduction of CUOOH by catalyst I-PN compared with diphenyl diselenide (PhSeSePh) was observed. The results clearly show that polymeric nanoparticle can be developed as an excellent model for combining most of catalytic factors of enzyme into one scaffold.     

Truncated mutants of human thioredoxin reductase 1 do not exhibit glutathione reductase activity

The substrate spectrum of human thioredoxin reductase (hTrxR) is attributed to its C-terminal extension of 16 amino acids carrying a selenocysteine residue. The concept of an evolutionary link between thioredoxin reductase and glutathione reductase (GR) is presently discussed and supported by the fact that almost all residues at catalytic and substrate recognition sites are identical. Here, we addressed the question if a deletion of the C-terminal part of TrxR leads to recognition of glutathione disulfide (GSSG), the substrate of GR. We introduced mutations at the putative substrate binding site to enhance GSSG binding and turnover. However, none of these enzyme species accepted GSSG as substrate better than the full length cysteine mutant of TrxR, excluding a role of the C-terminal extension in preventing GSSG binding. Furthermore, we show that GSSG binding at the N-terminal active site of TrxR is electrostatically disfavoured.     

Role of the glutamyl alpha-carboxylate of the substrate glutathione in the catalytic mechanism of human glutathione transferase A1-1.

The Glu alpha-carboxylate of glutathione contributes to the catalytic function of the glutathione transferases. The catalytic efficiency of human glutathione transferase A1-1 (GST A1-1) in the conjugation reaction with 1-chloro-2,4-dinitrobenzene is reduced 15 000-fold if the decarboxylated analogue of glutathione, dGSH (GABA-Cys-Gly), is used as an alternative thiol substrate. The decrease is partially due to an inability of the enzyme to promote ionization of dGSH. The pK(a) value of the thiol group of the natural substrate glutathione decreases from 9.2 to 6.7 upon binding to GST A1-1. However, the lack of the Glu alpha-carboxylate in dGSH raised the pK(a) value of the thiol in the enzymatic reaction to that of the nonenzymatic reaction. Furthermore, K(M)(dGSH) was 100-fold higher than K(M)(GSH). The active-site residue Thr68 forms a hydrogen bond to the Glu alpha-carboxylate of glutathione. Introduction of a carboxylate into GST A1-1 by a T68E mutation increased the catalytic efficiency with dGSH 10-fold and reduced the pK(a) value of the active site bound dGSH by approximately 1 pH unit. The altered pK(a) value is consistent with a catalytic mechanism where the carboxylate contributes to ionization of the glutathione thiol group. With Delta(5)-androstene-3,17-dione as substrate the efficiency of the enzyme is decreased 24 000-fold while with 4-nitrocinnamaldehyde (NCA) the decrease is less than 150-fold. In the latter reaction NCA accepts a proton and, unlike the other reactions studied, may not be dependent on the Glu alpha-carboxylate for deprotonation of the thiol group. An additional function of the Glu alpha-carboxylate may be productive orientation of glutathione within the active site.     

Incorporation of glutathione peroxidase active site into polymer based on imprinting strategy

Glutathione peroxidase (GPx, EC 1.11.1.9) is a key enzyme involved in scavenging of reactive oxygen species in biological system. For developing an efficient GPx-like antioxidant, catalytically necessary amino acid derivatives which located near the GPx active center were prepared as functional monomers. Via predetermined imprinting with substrate glutathione (GSH), a polymer-based GPx mimic with a similar structure of catalytic center of natural GPx was developed, and it demonstrated high-catalytic efficiency and substrate specificity. The imprinting polymer (I-PEM) exhibits GPx-like activity about three times higher than that of 2-SeCD, a cyclodextrin-based GPx mimic. The detailed studies on kinetics revealed that not only the substrate binding but also positional arrangement of reacting groups contribute significantly to the catalytic efficiency of the peroxidase model.     

Substrate specificity of rat liver glutathione S-transferase isoenzymes for a series of glutathione analogues, modified at the gamma-glutamyl moiety.

The substrate specificity of purified rat liver glutathione S-transferases (GSTs) for a series of gamma-glutamyl-modified GSH analogues was investigated. GST isoenzyme 3-3 catalysed the conjugation of 1-chloro-2,4-dinitrobenzene with six out of the nine analogues. alpha-L-Glu-L-Cys-Gly and alpha-D-Glu-L-Cys-Gly showed catalytic efficiencies of 40% and 130% that of GSH respectively. The GSH analogue with an alpha-D-glutamyl moiety appeared to be a highly isoenzyme-3-3-specific co-substrate: kcat./Km with GST isoenzyme 4-4 was only about 5% that with GST isoenzyme 3-3, and no enzymic activity was detectable with GST isoenzymes 1-1 and 2-2. GST isoenzyme 4-4 showed some resemblance to GST 3-3: five out of nine co-substrate analogues were accepted by this second isoenzyme of the Mu multigene family. Isoenzymes 1-1 and 2-2, of the Alpha multigene family, accepted only two alternative co-substrates, which indicates that their GSH-binding site is much more specific.     

Cysteine residues are not essential for the catalytic activity of human class Mu glutathione transferase M1a-1a

To investigate the possible involvement of a Cys thiol in the catalysis of the human glutathione transferase M1a-1a, we constructed mutants of this enzyme wherein the four Cys residues present in the native enzyme were replaced by Ala residues. Three mutants, one where all four Cys residues had been replaced and two mutants where three out of four Cys residues were changed into Ala, were characterized regarding their catalytic activities with three different substrates as well as by their binding of three different inhibitors. All three Cys-deficient mutant forms of glutathione transferase M1a-1a were catalytically active with the tested substrates and their binding of inhibitors, measured by I50, were not significantly different from the values previously obtained for the wild-type enzyme. We therefore conclude that none of the Cys residues in this class Mu glutathione transferase are directly involved in the catalysis performed by this enzyme.