Purification and Characterisation of Hepatic Glutathione Transferases from a Herbivorous Marsupial, the Brushtail Possum (Trichosurus vulpecula)

A single glutathione transferase isoenzyme was purified from hepatic cytosol of the brushtail possum and shown to represent 3.6 ± 0.3% of the total cytosolic protein. Characterisation of the enzyme, termed Possum GST 1–1, indicated that it possessed similar catalytic activity and structural homology with isoenzymes belonging to the alpha class of glutathione transferases. This homodimeric GST exhibited a single band with an apparent molecular mass of 25.4 kDa on sodium dodecyl sulphate-polyacrylamide gels and an apparent pI of 9.8. Inhibition studies demonstrated that Possum GST 1–1 displays binding affinity for a range of inhibitors similar to that shown by alpha class GSTs purified from other mammals. Immunoblot analysis demonstrated immuno-cross reactivity between Possum GST 1–1 and antisera raised against human alpha GST, while this GST did not cross-react with antisera raised against human mu and pi GST. N-terminal sequencing of purified Possum GST 1–1 revealed that the N-terminus of the protein is chemically blocked. Sequence analysis of three internal peptide sequences demonstrated homology with mammalian alpha GSTs. Of particular interest is the significant substrate specificity that Possum GST 1–1 displays with both organic and inorganic hydroperoxides. It is proposed that this substrate specificity is an evolutionary adaptation to a diet high in potentially toxic plant allelochemicals.     

Structural determinants of glutathione transferases with azathioprine activity identified by DNA shuffling of alpha class members

A library of alpha class glutathione transferases (GSTs), composed of chimeric enzymes derived from human (A1-1, A2-2 and A3-3), bovine (A1-1) and rat (A2-2 and A3-3) cDNA sequences was constructed by the method of DNA shuffling. The GST variants were screened in bacterial lysates for activity with the immunosuppressive agent azathioprine, a prodrug that is transformed into its active form, 6-mercaptopurine, by reaction with the tripeptide glutathione catalyzed by GSTs. Important structural determinants for activity with azathioprine were recognized by means of primary structure analysis and activities of purified enzymes chosen from the screening. The amino acid sequences could be divided into 23 exchangeable segments on the basis of the primary structures of 45 chosen clones. Segments 2, 20, 21, and 22 were identified as primary determinants of the azathioprine activity representing two of the regions forming the substrate-binding H-site. Segments 21 and 22 are situated in the C-terminal helix characterizing alpha class GSTs, which is instrumental in their catalytic function. The study demonstrates the power of DNA shuffling in identifying segments of primary structure that are important for catalytic activity with a targeted substrate. GSTs in combination with azathioprine have potential as selectable markers for use in gene therapy. Knowledge of activity-determining segments in the structure is valuable in the protein engineering of glutathione transferase for enhanced or suppressed activity.     

Structural Basis for Featuring of Steroid Isomerase Activity in Alpha Class Glutathione Transferases

Glutathione transferases (GSTs) are abundant enzymes catalyzing the conjugation of hydrophobic toxic substrates with glutathione. In addition to detoxication, human GST A3-3 displays prominent steroid double-bond isomerase activity; e.g. transforming Δ⁵-androstene-3-17-dione into Δ⁴-androstene-3-17-dione (AD). This chemical transformation is a crucial step in the biosynthesis of steroids, such as testosterone and progesterone. In contrast to GST A3-3, the homologous GST A2-2 does not show significant steroid isomerase activity. We have solved the 3D structures of human GSTs A2-2 and A3-3 in complex with AD. In the GST A3-3 crystal structure, AD was bound in an orientation suitable for the glutathione (GSH)-mediated catalysis to occur. In GST A2-2, however, AD was bound in a completely different orientation with its reactive double bond distant from the GSH-binding site. The structures illustrate how a few amino acid substitutions in the active site spectacularly alter the binding mode of the steroid substrate in relation to the conserved catalytic groups and an essentially fixed polypeptide chain conformation. Furthermore, AD did not bind to the GST A2-2-GSH complex. Altogether, these results provide a first-time structural insight into the steroid isomerase activity of any GST and explain the 5000-fold difference in catalytic efficiency between GSTs A2-2 and A3-3. More generally, the structures illustrate how dramatic diversification of functional properties can arise via minimal structural alterations. We suggest a novel structure-based mechanism of the steroid isomerization reaction.     

Crystallographic and Functional Characterization of the Fluorodifen-inducible Glutathione Transferase from Glycine max Reveals an Active Site Topography Suited for Diphenylether Herbicides and a Novel L-site

Glutathione transferases (GSTs) from the tau class (GSTU) are unique to plants and have important roles in stress tolerance and the detoxification of herbicides in crops and weeds. A fluorodifen-induced GST isoezyme (GmGSTU4-4) belonging to the tau class was purified from Glycine max by affinity chromatography. This isoenzyme was cloned and expressed in Escherichia coli, and its structural and catalytic properties were investigated. The structure of GmGSTU4-4 was determined at 1.75 Å resolution in complex with S-(p-nitrobenzyl)-glutathione (Nb-GSH). The enzyme adopts the canonical GST fold but with a number of functionally important differences. Compared with other plant GSTs, the three-dimensional structure of GmGSTU4-4 primarily shows structural differences in the hydrphobic substrate binding site, the linker segment and the C-terminal region. The X-ray structure identifies key amino acid residues in the hydrophobic binding site (H-site) and provides insights into the substrate specificity and catalytic mechanism of the enzyme. The isoenzyme was highly active in conjugating the diphenylether herbicide fluorodifen. A possible reaction pathway involving the conjugation of glutathione with fluorodifen is described based on site-directed mutagenesis and molecular modeling studies. A serine residue (Ser13) is present in the active site, at a position that would allow it to stabilise the thiolate anion of glutathione and enhance its nucleophilicity. Tyr107 and Arg111 present in the active site are important structural moieties that modulate the catalytic efficiency and specificity of the enzyme, and participate in k_cat regulation by affecting the rate-limiting step of the catalytic reaction. A hitherto undescribed ligand-binding site (L-site) located in a surface pocket of the enzyme was also found. This site is formed by conserved residues, suggesting it may have an important functional role in the transfer and delivery of bound ligands, presumably to specific protein receptors.     

An Inducible Glutathione S-Transferase in Soybean Hypocotyl Is Localized in the Apoplast

Glutathione S-transferases (GSTs) with additional activities as fatty acid hydroperoxidases were investigated in soybean (Glycine max L.) hypocotyls. Aside from the GSTs present in total soluble tissue extracts, enzyme activities and distinct immunoreactive GST polypeptides were also detected in the intercellular washing fluid. Whereas the intracellular isoenzymes were both constitutive and inducible, apoplastic GST and glutathione peroxidase was detectable only in tissues treated with the known GST inducer 2,3,5-triiodobenzoic acid. Monensin inhibited the induced accumulation of apoplastic GST but did not affect the intracellular isoforms. The discovery of apoplastic inducible GST will be discussed in light of the putative function of these enzymes in plants.     

Kinetic analysis of maize glutathione <Emphasis Type="Italic">S</Emphasis>-transferase I catalysing the detoxification from chloroacetanilide herbicides

Glutathione S-transferases (GSTs, EC 2.5.1.18) are a family of multi-functional enzymes involved in biodegradation of several herbicide classes. The ability of the maize isoenzyme GST I to detoxify from the acetanilide herbicide alachlor was investigated by steady-state kinetics and site-directed mutagenesis studies. Steady-state kinetics fit well to a rapid equilibrium random sequential bi-bi mechanism with intrasubunit modulation between GSH binding site (G-site) and electrophile binding site (H-site). The rate-limiting step of the reaction is viscosity-dependent and thermodynamic data suggest that product release is rate-limiting. Three residues of GST I (Trp12, Phe35 and Ile118), which build up the xenobiotic binding site, were mutated and their functional and structural roles during alachlor conjugation were investigated. These residues are not conserved, hence may affect substrate specificity and/or product dissociation. The work showed that the key amino acid residue Phe35 modulates xenobiotic substrate binding and specificity, and participates in k_cat regulation by affecting the rate-limiting step of the catalytic reaction. Trp12 and Ile118 do not seem to carry out such functions but instead, regulate the K_m for alachlor by contributing to its productive orientation in the H-site. The results of the present work have practical significance since this may provide the basis for the rational design of new engineered GSTs with altered substrate specificity towards herbicides and may facilitate the design of new, more selective herbicides.     

Purification,regulation and cloning of a glutathione transferase (GST) from maize resembling the auxin-inducible type-III GSTs

The glutathione transferases (GSTs) from maize (Zea mays L.) with activities toward the chloroacetanilide herbicide metolachlor and the diphenyl ether herbicide fluorodifen were fractionated into two pools based on binding to affinity columns. Pool 1 GSTs were retained on Orange A agarose and were identified as isoenzymes Zea mays (Zm) GST I-I, Zm GST I-II and Zm GST I-III, which have been described previously. Pool 2 GSTs selectively bound to S-hexyl-glutathione-Sepharose and were distinct from the pool 1 GSTs, being composed of a homodimer of 28.5 kDa subunits, termed Zm GST V-V, and a heterodimer of the 28.5 kDa polypeptide and a 27.5 kDa subunit, termed Zm GST V-VI. Using an antibody raised to Zm GST V-VI, a cDNA expression library was screened and a Zm GST V clone identified showing sequence similarity to the type-III auxin-inducible GSTs previously identified in tobacco and other dicotyledenous species. Recombinant Zm GST V-V showed high GST activity towards the diphenyl ether herbicide fluorodifen, detoxified toxic alkenal derivatives and reduced organic hydroperoxides. Antibodies raised to Zm GST I-II and Zm GST V-VI were used to monitor the expression of GST subunits in maize seedlings. Over a 24 h period the Zm GST I subunit was unresponsive to chemical treatment, while expression of Zm GST II was enhanced by auxins, herbicides, the herbicide safener dichlormid and glutathione. The Zm GST V subunit was more selective in its induction, only accumulating significantly in response to dichlormid treatment. During development Zm GST I and Zm GST V were expressed more in roots than in shoots, with Zm GST II expression limited to the roots.     

A Novel Quasi-Species of Glutathione Transferase with High Activity towards Naturally Occurring Isothiocyanates Evolves from Promiscuous Low-Activity Variants

Glutathione transferases (GSTs) are known as promiscuous enzymes capable of catalyzing the conjugation of glutathione with a broad range of electrophilic substrates. A previous study based on recombinant chimeras derived from human GST M1-1 and GST M2-2 demonstrated the formation of a subset of F1 generation GSTs, which had lost high activity with substrates distinguishing parental enzymes. In the present study, the members of this subset were recombined by DNA shuffling to produce an F2 generation of GSTs. Screening of 930 bacterial clones demonstrated that 83% of recombinant enzyme variants were active with at least one of three alternative substrates: phenethyl isothiocyanate (PEITC), 1-chloro-2,4-dinitrobenzene, or p-nitrophenyl acetate. The majority had similar low activity as the parental GSTs in the F1 generation. However, 17 novel enzymes displayed high activity with PEITC. Half of these enzymes were similar to GST M1-1, which also has high activity with the same substrate, and all of these GSTs featured Tyr116/Ser210 in the active site. This group of F2 variants apparently had reverted to the GST M1-1 type. A second group of F2 variants with high PEITC activity was characterized by His116 in the active site. This category represented a new variety of GSTs, which demonstrated higher selectivity for isothiocyanate substrates than the GST M1-1 type. The different groups of GSTs can be considered as distinct molecular quasi-species, each of which comprises variant amino acid sequences. The quasi-species are structurally distinguished by active-site residues that govern their substrate selectivities. Clearly, minimal alterations of the active site can generate enzymes with highly distinctive functional properties.     

A glutathione transferase from Agrobacterium tumefaciens reveals a novel class of bacterial GST superfamily

In the present work, we report a novel class of glutathione transferases (GSTs) originated from the pathogenic soil bacterium Agrobacterium tumefaciens C58, with structural and catalytic properties not observed previously in prokaryotic and eukaryotic GST isoenzymes. A GST-like sequence from A. tumefaciens C58 (Atu3701) with low similarity to other characterized GST family of enzymes was identified. Phylogenetic analysis showed that it belongs to a distinct GST class not previously described and restricted only in soil bacteria, called the Eta class (H). This enzyme (designated as AtuGSTH1-1) was cloned and expressed in E. coli and its structural and catalytic properties were investigated. Functional analysis showed that AtuGSTH1-1 exhibits significant transferase activity against the common substrates aryl halides, as well as very high peroxidase activity towards organic hydroperoxides. The crystal structure of AtuGSTH1-1 was determined at 1.4 Å resolution in complex with S-(p-nitrobenzyl)-glutathione (Nb-GSH). Although AtuGSTH1-1 adopts the canonical GST fold, sequence and structural characteristics distinct from previously characterized GSTs were identified. The absence of the classic catalytic essential residues (Tyr, Ser, Cys) distinguishes AtuGSTH1-1 from all other cytosolic GSTs of known structure and function. Site-directed mutagenesis showed that instead of the classic catalytic residues, an Arg residue (Arg34), an electron-sharing network, and a bridge of a network of water molecules may form the basis of the catalytic mechanism. Comparative sequence analysis, structural information, and site-directed mutagenesis in combination with kinetic analysis showed that Phe22, Ser25, and Arg187 are additional important residues for the enzyme''s catalytic efficiency and specificity.     

Novel class of glutathione transferases from cyanobacteria exhibit high catalytic activities towards naturally occurring isothiocyanates

In the present paper, we report a novel class of GSTs (glutathione transferases), called the Chi class, originating from cyanobacteria and with properties not observed previously in prokaryotic enzymes. GSTs constitute a widespread multifunctional group of proteins, of which mammalian enzymes are the best characterized. Although GSTs have their origin in prokaryotes, few bacterial representatives have been characterized in detail, and the catalytic activities and substrate specificities observed have generally been very modest. The few well-studied bacterial GSTs have largely unknown physiological functions. Genome databases reveal that cyanobacteria have an extensive arsenal of glutathione-associated proteins. We have studied two cyanobacterial GSTs which are the first examples of bacterial enzymes that are as catalytically efficient as the best mammalian enzymes. GSTs from the thermophile Thermosynechococcus elongatus BP-1 and from Synechococcus elongatus PCC 6301 were found to catalyse the conjugation of naturally occurring plant-derived isothiocyanates to glutathione at high rates. The cyanobacterial GSTs studied are smaller than previously described members of this enzyme family, but display many of the typical structural features that are characteristics of GSTs. They are also active towards several classical substrates, but at the same moderate rates that have been observed for other GSTs derived from prokaryotes. The cloning, expression and characterization of two cyanobacterial GSTs are described. The possible significance of the observed catalytic properties is discussed in the context of physiological relevance and GST evolution.     

Structure-guided activity restoration of the silkworm glutathione transferase Omega GSTO3-3

Glutathione transferases (GSTs) are ubiquitous detoxification enzymes that conjugate hydrophobic xenobiotics with reduced glutathione. The silkworm Bombyx mori encodes four isoforms of GST Omega (GSTO), featured with a catalytic cysteine, except that bmGSTO3-3 has an asparagine substitution of this catalytic residue. Here, we determined the 2.20-Å crystal structure of bmGSTO3-3, which shares a typical GST overall structure. However, the extended C-terminal segment that exists in all the four bmGSTOs occupies the G-site of bmGSTO3-3 and makes it unworkable, as shown by the activity assays. Upon mutation of Asn29 to Cys and truncation of the C-terminal segment, the in vitro GST activity of bmGSTO3-3 could be restored. These findings provided structural insights into the activity regulation of GSTOs.     

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.     

Conjugation of the linoleic acid oxidation product, 13-oxooctadeca-9,11-dienoic acid,a bioactive endogenous substrate for mammalian glutathione transferase

The oxidation of linoleic acid leads to the generation of several products with biological activity, including 13-oxooctadeca-9,11-dienoic acid (13-OXO), a bioactive 2,4-dienone that has been linked to cell differentiation. In the current work, the conjugation of 13-OXO by human glutathione transferases (GSTs) of the alpha (A1-1, A4-4), mu (M1-1, M2-2) and pi (the allelic variants P1-1/ile, and P1-1/val) classes, and a rat theta (rT2-2) class enzyme has been evaluated. The kinetics and stereoselectivity of the production of the 13-OXO-glutathione conjugate (13-OXO-SG) have been examined. In contrast to many xenobiotic substrates, the endogenous substrate 13-OXO does not exhibit an appreciable non-enzymatic rate of conjugation under physiological conditions. Therefore, the GST-catalyzed conjugation takes on greater significance as it provides the only realistic means for formation of 13-OXO-SG in most biological systems. Alpha class enzymes are most efficient at catalyzing the formation of 13-OXO-SG with kcat/Km values of 8.9 mM(-1) s(-1) for GST A1-1 and 2.14 mM(-1) s(-1) for GST A4-4. In comparison, enzymes from the mu and pi classes exhibit specificity constants from 0.4 to 0.8 mM(-1) s(-1). Conjugation of 13-OXO with glutathione at C-9 of the substrate can yield a pair of diastereomers that can be resolved by chiral HPLC. GSTs from the mu and pi classes are the most stereoselective enzymes and there is no apparent relationship between catalytic efficiency and stereoselectivity. The role of GST in the metabolic disposition of the bioactive oxidation products of linoleic acid has implications for the regulation of normal cellular functions by these versatile enzymes.     

Differences in the subunit interface residues of alternatively spliced glutathione transferases affects catalytic and structural functions

GSTs (glutathione transferases) are multifunctional widespread enzymes. Currently there are 13 identified classes within this family. Previously most structural characterization has been reported for mammalian Alpha, Mu and Pi class GSTs. In the present study we characterize two enzymes from the insect-specific Delta class, adGSTD3-3 and adGSTD4-4. These two proteins are alternatively spliced products from the same gene and have very similar tertiary structures. Several major contributions to the dimer interface area can be separated into three regions: conserved electrostatic interactions in region 1, hydrophobic interactions in region 2 and an ionic network in region 3. The four amino acid side chains studied in region 1 interact with each other as a planar rectangle. These interactions are highly conserved among the GST classes, Delta, Sigma and Theta. The hydrophobic residues in region 2 are not only subunit interface residues but also active site residues. Overall these three regions provide important contributions to stabilization and folding of the protein. In addition, decreases in yield as well as catalytic activity changes, suggest that the mutations in these regions can disrupt the active site conformation which decreases binding affinity, alters kinetic constants and alters substrate specificity. Several of these residues have only a slight effect on the initial folding of each subunit but have more influence on the dimerization process as well as impacting upon appropriate active site conformation. The results also suggest that even splicing products from the same gene may have specific features in the subunit interface area that would preclude heterodimerization.     

Structure of a tau class glutathione S-transferase from wheat active in herbicide detoxification

Glutathione S-transferases (GSTs) from the phi (GSTF) and tau (GSTU) classes are unique to plants and play important roles in stress tolerance and secondary metabolism as well as catalyzing the detoxification of herbicides in crops and weeds. We have cloned and functionally characterized a group of GSTUs from wheat treated with fenchlorazole-ethyl, a herbicide safener. One of these enzymes, TaGSTU4-4, was highly active in conjugating the chemically distinct wheat herbicides fenoxaprop and dimethenamid. The structure of TaGSTU4-4 has been determined at 2.2 A resolution in complex with S-hexylglutathione. This enzyme is the first tau class GST structure to be determined and most closely resembles the omega class GSTs, but without the unique N-terminal extension or active site cysteine. The X-ray structure identifies key amino acid residues in the hydrophobic binding site and provides insights into the substrate specificity of these enzymes.     

An ensemble of theta class glutathione transferases with novel catalytic properties generated by stochastic recombination of fragments of two mammalian enzymes

The correlation between sequence diversity and enzymatic function was studied in a library of Theta class glutathione transferases (GSTs) obtained by stochastic recombination of fragments of cDNA encoding human GST T1-1 and rat GST T2-2. In all, 94 randomly picked clones were characterized with respect to sequence, expression level, and catalytic activity in the conjugation reactions between glutathione and six alternative electrophilic substrates. Out of these six different compounds, dichloromethane is a selective substrate for human GST T1-1, whereas 1-menaphthyl sulfate and 1-chloro-2,4-dinitrobenzene are substrates for rat GST T2-2. The other three substances serve as substrates for both enzymes. Through this broad characterization, we have identified enzyme variants that have acquired novel activity profiles that differ substantially from those of the original GSTs. In addition, the expression levels of many clones were improved in comparison to the parental enzyme. A library of mutants can thus display a distribution of properties from which highly divergent evolutionary pathways may emerge, resembling natural evolutionary processes. From the GST library, a clone was identified that, by the point mutation N49D in the rat GST T2-2 sequence, has a 1700% increased activity with 1-menaphthyl sulfate and a 60% decreased activity with 4-nitrophenethyl bromide. Through the N49D mutation, the ratio of these activities has thus been altered 40-fold. An extensive characterization of a population of stochastically mutated enzymes can accordingly be used to find variants with novel substrate-activity profiles and altered catalytic properties. Recursive recombination of selected sequences displaying optimized properties is a strategy for the engineering of proteins for medical and biochemical applications. Such sequential design is combinatorial protein chemistry based on remodeling of existing structural scaffolds and has similarities to evolutionary processes in nature.     

Minor Modifications of the C-terminal Helix Reschedule the Favored Chemical Reactions Catalyzed by Theta Class Glutathione Transferase T1-1

Adaptive responses to novel toxic challenges provide selective advantages to organisms in evolution. Glutathione transferases (GSTs) play a pivotal role in the cellular defense because they are main contributors to the inactivation of genotoxic compounds of exogenous as well as of endogenous origins. GSTs are promiscuous enzymes catalyzing a variety of chemical reactions with numerous alternative substrates. Despite broad substrate acceptance, individual GSTs display pronounced selectivities such that only a limited number of substrates are transformed with high catalytic efficiency. The present study shows that minor structural changes in the C-terminal helix of mouse GST T1-1 induce major changes in the substrate-activity profile of the enzyme to favor novel chemical reactions and to suppress other reactions catalyzed by the parental enzyme.     

Structures of yeast glutathione‐S‐transferase Gtt2 reveal a new catalytic type of GST family

Glutathione‐S‐transferases (GSTs) are ubiquitous detoxification enzymes that catalyse the conjugation of electrophilic substrates to glutathione. Here, we present the crystal structures of Gtt2, a GST of Saccharomyces cerevisiae, in apo and two ligand‐bound forms, at 2.23 Å, 2.20 Å and 2.10 Å, respectively. Although Gtt2 has the overall structure of a GST, the absence of the classic catalytic essential residues—tyrosine, serine and cysteine—distinguishes it from all other cytosolic GSTs of known structure. Site‐directed mutagenesis in combination with activity assays showed that instead of the classic catalytic residues, a water molecule stabilized by Ser129 and His123 acts as the deprotonator of the glutathione sulphur atom. Furthermore, only glycine and alanine are allowed at the amino‐terminus of helix‐α1 because of stereo‐hindrance. Taken together, these results show that yeast Gtt2 is a novel atypical type of cytosolic GST.