Three-dimensional structure of glutathione S-transferase from Arabidopsis thaliana at 2.2 A resolution: structural characterization of herbicide-conjugating plant glutathione S-transferases and a novel active site architecture.

Glutathione S-transferases (GST) are a family of multifunctional enzymes involved in the metabolization of a broad variety of xenobiotics and reactive endogenous compounds. The interest in plant glutathione S-transferases may be attributed to their agronomic value, since it has been demonstrated that glutathione conjugation for a variety of herbicides is the major resistance and selectivity factor in plants. The three-dimensional structure of glutathione S-transferase from the plant Arabidopsis thaliana has been solved by multiple isomorphous replacement and multiwavelength anomalous dispersion techniques at 3 A resolution and refined to a final crystallographic R-factor of 17.5% using data from 8 to 2.2 A resolution. The enzyme forms a dimer of two identical subunits each consisting of 211 residues. Each subunit is characterized by the GST-typical modular structure with two spatially distinct domains. Domain I consists of a central four-stranded beta-sheet flanked on one side by two alpha-helices and on the other side by an irregular segment containing three short 3(10)-helices, while domain II is entirely helical. The dimeric molecule is globular with a prominent large cavity formed between the two subunits. The active site is located in a cleft situated between domains I and II and each subunit binds two molecules of a competitive inhibitor S-hexylglutathione. Both hexyl moieties are oriented parallel and fill the H-subsite of the enzyme's active site. The glutathione peptide of one inhibitor, termed productive binding, occupies the G-subsite with multiple interactions similar to those observed for other glutathione S-transferases, while the glutathione backbone of the second inhibitor, termed unproductive binding, exhibits only weak interactions mediated by two polar contacts. A most striking difference from the mammalian glutathione S-transferases, which share a conserved catalytic tyrosine residue, is the lack of this tyrosine in the active site of the plant glutathione S-transferase.

Crystal structure of the catalytic subunit of human protein phosphatase 1 and its complex with tungstate.

Protein phosphatase 1 (PP1) is a serine/threonine protein phosphatase that is essential in regulating diverse cellular processes. Here we report the crystal structure of the catalytic subunit of human PP1 gamma 1 and its complex with tungstate at 2.5 A resolution. The anomalous scattering from tungstate was used in a multiple wavelength anomalous dispersion experiment to derive crystallographic phase information. The protein adopts a single domain with a novel fold, distinct from that of the protein tyrosine phosphatases. A di-nuclear ion centre consisting of Mn2+ and Fe2+ is situated at the catalytic site that binds the phosphate moiety of the substrate. Proton-induced X-ray emission spectroscopy was used to identify the nature of the ions bound to the enzyme. The structural data indicate that dephosphorylation is catalysed in a single step by a metal-activated water molecule. This contrasts with other phosphatases, including protein tyrosine phosphatases, acid and alkaline phosphatases which form phosphoryl-enzyme intermediates. The structure of PP1 provides insight into the molecular mechanism for substrate recognition, enzyme regulation and inhibition of this enzyme by toxins and tumour promoters and a basis for understanding the expanding family of related phosphatases which include PP2A and PP2B (calcineurin).

X-ray structures of human neutrophil collagenase complexed with peptide hydroxamate and peptide thiol inhibitors. Implications for substrate binding and rational drug design.

Matrix metalloproteinases (MMPs) are a family of zinc endopeptidases involved in tissue remodeling. They have also been implicated in various disease processes including tumour invasion and joint destruction and are therefore attractive targets for inhibitor design. For rational drug design, information of inhibitor binding at the atomic level is essential. Recently, we have published the refined high-resolution crystal structure of the catalytic domain of human neutrophil collagenase (HNC) complexed with the inhibitor Pro-Leu-Gly-NHOH, which is a mimic for the unprimed (P3-P1) residues of a bound peptide substrate. We have now determined two additional HNC complexes formed with the thiol inhibitor HSCH2CH(CH2Ph)CO-L-Ala-Gly-NH2 and another hydroxamate inhibitor, HONHCOCH(iBu)CO-L-Ala-Gly-NH2, which were both refined to R-values of 0.183/0.198 at 0.240/0.225-nm resolution. The inhibitor thiol and hydroxamate groups ligand the catalytic zinc, giving rise to a slightly distorted tetrahedral and trigonal-bipyramidal coordination sphere, respectively. The thiol inhibitor diastereomer with S-configuration at the P1' residue (corresponding to an L-amino acid analog) binds to HNC. Its peptidyl moiety mimics binding of primed (P1'-P3') residues of the substrate. In combination with our first structure a continuous hexapeptide corresponding to a peptide substrate productively bound to HNC was constructed and energy-minimized. Proteolytic cleavage of this Michaelis complex is probably general base-catalyzed as proposed for thermolysin, i.e. a glutamate assists nucleophilic attack of a water molecule. Although there are many structural and mechanistic similarities to thermolysin, substrate binding to MMPs differs due to the interactions beyond S1'-P1'. While thermolysin binds substrates with a kink at P1', substrates are bound in an extended conformation in the collagenases. This property explains the tolerance of thermolysin for D-amino acid residues at the P1' position, in contrast to the collagenases. The third inhibitor, HONHCOCH(iBu)CO-L-Ala-Gly-NH2, unexpectedly binds in a different manner than anticipated from its design and binding mode in thermolysin. Its hydroxamate group obviously interacts with the catalytic zinc in a favourable bidentate manner, but in contrast its isobutyl (iBu) side chain remains outside of the S1' pocket, presumably due to severe constraints imposed by the adjacent planar hydroxamate group. Instead, the C-terminal Ala-Gly-NH2 tail adopts a bent conformation and inserts into this S1' pocket, presumably in a non-optimized manner. Both the isobutyl side chain and the C-terminal peptide tail could be replaced by other, better fitting groups.(ABSTRACT TRUNCATED AT 250 WORDS)

Refined crystal structure of porcine class Pi glutathione S-transferase (pGST P1-1) at 2.1 A resolution.

The crystal structure of class Pi glutathione S-transferase from porcine lung (pGST P1-1) in complex with glutathione sulphonate has been refined at 2.11 A resolution, to a crystallographic R-factor of 16.5% for 21, 165 unique reflections. The refined structure includes 3314 protein atoms, 46 inhibitor (glutathione sulphonate) atoms and 254 water molecules. The model shows good stereochemistry, with root-mean-square deviations from ideal bond lengths and bond angles of 0.011 A and 2.8 degrees, respectively. The estimated root-mean-square co-ordinate error is 0.2 A. The protein is a dimer assembled from identical subunits of 207 amino acid residues. The tertiary structure of the pGST P1 subunit is organized as two domains, the N-terminal domain (domain I, residues 1 to 74) and the larger C-terminal domain (domain II, residues 81 to 207). Glutathione sulphonate, a competitive inhibitor, binds to the G-site region (i.e. the glutathione-binding region) of the active site located on each subunit. Each G-site is, however, structurally dependent of the neighbouring subunit as structural elements forming a fully functional G-site are provided by both subunits, with domain I as the major supporting framework. A number of direct and water-mediated polar interactions are involved in sequestering the glutathione analogue at the G-site. The extended conformation assumed by the enzyme-bound inhibitor as well as the strategic interactions between inhibitor and protein, closely resemble those observed for the physiological substrate, reduced glutathione bound at the active site of class Mu glutathione S-transferase 3-3. Hydrogen bonding between the sulphonyl moiety of the inhibitor and the hydroxyl group of an evolutionary conserved tyrosine residue, Tyr7, provides the first direct structural evidence for a catalytic protein group in glutathione S-transferases that is involved in the activation of the substrate glutathione. The catalytic role for Tyr7 has subsequently been confirmed by mutagenesis and kinetic studies. Comparison of the known crystal structures for class Pi, class Mu and class Alpha isoenzymes, indicates that the cytosolic glutathione S-transferases share a common fold and that the structural features for catalysis are similar.

Crystal structure of P22 tailspike protein: interdigitated subunits in a thermostable trimer.

The tailspike protein (TSP) of Salmonella typhimurium phage P22 is a part of the apparatus by which the phage attaches to the bacterial host and hydrolyzes the O antigen. It has served as a model system for genetic and biochemical analysis of protein folding. The x-ray structure of a shortened TSP (residues 109 to 666) was determined to a 2.0 angstrom resolution. Each subunit of the homotrimer contains a large parallel beta helix. The interdigitation of the polypeptide chains at the carboxyl termini is important to protrimer formation in the folding pathway and to thermostability of the mature protein.

The X-ray crystal structure of the catalytic domain of human neutrophil collagenase inhibited by a substrate analogue reveals the essentials for catalysis and specificity.

Matrix metalloproteinases are a family of zinc endopeptidases involved in tissue remodelling. They have been implicated in various disease processes including tumour invasion and joint destruction. These enzymes consist of several domains, which are responsible for latency, catalysis and substrate recognition. Human neutrophil collagenase (PMNL-CL, MMP-8) represents one of the two 'interstitial' collagenases that cleave triple helical collagens types I, II and III. Its 163 residue catalytic domain (Met80 to Gly242) has been expressed in Escherichia coli and crystallized as a non-covalent complex with the inhibitor Pro-Leu-Gly-hydroxylamine. The 2.0 A crystal structure reveals a spherical molecule with a shallow active-site cleft separating a smaller C-terminal subdomain from a bigger N-terminal domain, composed of a five-stranded beta-sheet, two alpha-helices, and bridging loops. The inhibitor mimics the unprimed (P1-P3) residues of a substrate; primed (P1'-P3') peptide substrate residues should bind in an extended conformation, with the bulky P1' side-chain fitting into the deep hydrophobic S1' subsite. Modelling experiments with collagen show that the scissile strand of triple-helical collagen must be freed to fit the subsites. The catalytic zinc ion is situated at the bottom of the active-site cleft and is penta-coordinated by three histidines and by both hydroxamic acid oxygens of the inhibitor. In addition to the catalytic zinc, the catalytic domain harbours a second, non-exchangeable zinc ion and two calcium ions, which are packed against the top of the beta-sheet and presumably function to stabilize the catalytic domain.(ABSTRACT TRUNCATED AT 250 WORDS)

X-ray crystal structures of cytosolic glutathione S-transferases. Implications for protein architecture, substrate recognition and catalytic function.

Crystal structures of cytosolic glutathione S-transferases (EC 2.5.1.18), complexed with glutathione or its analogues, are reviewed. The atomic models define protein architectural relationships between the different gene classes in the superfamily, and reveal the molecular basis for substrate binding at the two adjacent subsites of the active site. Considerable progress has been made in understanding the mechanism whereby the thiol group of glutathione is destabilized (lowering its pKa) at the active site, a rate-enhancement strategy shared by the soluble glutathione S-transferases.

Electrostatic evidence for the activation of the glutathione thiol by Tyr7 in pi-class glutathione transferases.

A number of spectrophotometric studies [Graminski, G.F., Kubo, Y. & Armstrong, R.N. (1989) Biochemistry 28, 3562-3568; Liu, S., Zhang, P., Ji, X., Johnson, W.W., Gilliland, G.L. & Armstrong, R.N. (1992) J. Biol. Chem. 267, 4296-4299] have recently shown that the glutathione (GSH) thiol is deprotonated when it is in complex with glutathione S-transferase. Different models have been proposed for the activation of the glutathione S gamma, all pointing out the key role of active-site residue Tyr7. It remains unclear, however, how Tyr7 is actually involved in this process. In this paper we present an analysis of the electrostatic potential in the region of the active site of a pi-class GSH transferase. This analysis provides evidence that the titration behaviour of the absorption band of the E.GSH complex with a pK between 6 and 7 [Liu, S., Zhang, P., Ji, X., Johnson, W.W., Gilliland, G.L. & Armstrong, R.N. (1992) J. Biol. Chem. 267, 4296-4299] should rather be explained by the protonation/deprotonation equilibrium of Tyr7 than by the protonation/deprotonation equilibrium of the GSH thiol group itself. On the basis of this conclusion, a mechanism for activation of GSH is proposed: the Tyr7 OH group is deprotonated by the influence of the protein charge constellation and the peptide dipoles. Thus it acts as a general base, promotes proton abstraction from the GSH thiol and creates a thiolate anion with high nucleophilic reactivity.

Structure determination and refinement of human alpha class glutathione transferase A1-1, and a comparison with the Mu and Pi class enzymes.

The crystal structure of human alpha class glutathione transferase A1-1 has been determined and refined to a resolution of 2.6 A. There are two copies of the dimeric enzyme in the asymmetric unit. Each monomer is built from two domains. A bound inhibitor, S-benzyl-glutathione, is primarily associated with one of these domains via a network of hydrogen bonds and salt-links. In particular, the sulphur atom of the inhibitor forms a hydrogen bond to the hydroxyl group of Tyr9 and the guanido group of Arg15. The benzyl group of the inhibitor is completely buried in a hydrophobic pocket. The structure shows an overall similarity to the mu and pi class enzymes particularly in the glutathione-binding domain". The main difference concerns the extended C terminus of the alpha class enzyme which forms an extra alpha-helix that blocks one entrance to the active site and makes up part of the substrate binding site.

Chemical modification of GSH transferase P1-1 confirms the presence of Arg-13, Lys-44 and one carboxylate group in the GSH-binding domain of the active site.

GSH transferase P1-1 (GSTP1-1) was modified with group-specific reagents. Kinetic experiments demonstrated that inactivation of GSTP1-1 occurred upon reaction of one arginine residue per subunit with diacetyl, one lysine residue per subunit with 2,4,6-trinitrobenzene sulphonate, or one carboxylate group per subunit with 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide. All three inactivation reactions were inhibited by compounds known to bind at the GSH site of the enzyme but were unaffected by the electrophile 1-chloro-2,4-dinitrobenzene. N-terminal sequence analysis showed that Arg-13 was modified by diacetyl and that this modification was inhibited by GSH. Arg-11 was not modified. The lysine residue modified by 2,4,6-trinitrobenzene sulphonate and protected by S-octylglutathione was identified as Lys-44 by sequencing of tryptic peptides. The findings are in agreement with the involvement of Arg-13 and Lys-44 in binding of GSH, as determined from the crystal structure [Reinemer, Dirr, Ladenstein, Huber, Lo Bello, Frederici and Parker (1992) J. Mol. Biol. 227, 214-226]. The present data also implicate a single carboxylate in GSH binding, consistent with the involvement of Asp-98 of subunit B determined from the crystallographic study. The GSH-binding determinants of GSTP1-1 are compared using sequence similarity with those of GSTs of Alpha, Mu and Theta classes.

Three-dimensional structure of class pi glutathione S-transferase from human placenta in complex with S-hexylglutathione at 2.8 A resolution.

The three-dimensional structure of human class pi glutathione S-transferase from placenta (hGSTP1-1), a homodimeric enzyme, has been solved by Patterson search methods and refined at 2.8 A resolution to a final crystallographic R-factor of 19.6% (8.0 to 2.8 A resolution). Subunit folding topology, subunit overall structure and subunit association closely resembles the structure of porcine class pi glutathione S-transferase. The binding site of a competitive inhibitor, S-hexylglutathione, is analyzed and the locations of the binding regions for glutathione (G-site) and electrophilic substrates (H-site) are determined. The specific interactions between protein and the inhibitor's glutathione peptide are the same as those observed between glutathione sulfonate and the porcine isozyme. The H-site is located adjacent to the G-site, with the hexyl moiety lying above a segment (residues 8 to 10) connecting strand beta 1 and helix alpha A where it is in hydrophobic contact with Tyr7, Phe8, Val10, Val35 and Tyr106. Catalytic models are discussed on the basis of the molecular structure.

Mutational substitution of residues implicated by crystal structure in binding the substrate glutathione to human glutathione S-transferase pi.

Site-directed substitution mutations were introduced into a cDNA expression vector (pUC120 pi) that encoded a human glutathione S-transferase pi isozyme to non-conservatively replace four residues (Tyr7, Arg13, Gln62 and Asp96). Our earlier X-ray crystallographic analysis implicated these residues in binding and/or chemically activating the substrate glutathione. Each substitution mutation decreased the specific activity of the enzyme to less than 2% of the wild-type. Glutathione-binding was also reduced; however, the Tyr7----Phe mutant still retained 27% of the wild-type capacity to bind glutathione, underlining the primary role that this residue is likely to play in chemically activating the glutathione molecule during catalysis.

The three-dimensional structure of class pi glutathione S-transferase in complex with glutathione sulfonate at 2.3 A resolution.

The three-dimensional structure of class pi glutathione S-transferase from pig lung, a homodimeric enzyme, has been solved by multiple isomorphous replacement at 3 A resolution and preliminarily refined at 2.3 A resolution (R = 0.24). Each subunit (207 residues) is folded into two domains of different structure. Domain I (residues 1-74) consists of a central four-stranded beta-sheet flanked on one side by two alpha-helices and on the other side, facing the solvent, by a bent, irregular helix structure. The topological pattern resembles the bacteriophage T4 thioredoxin fold, in spite of their dissimilar sequences. Domain II (residues 81-207) contains five alpha-helices. The dimeric molecule is globular with dimensions of about 55 A x 52 A x 45 A. Between the subunits and along the local diad, is a large cavity which could possibly be involved in the transport of nonsubstrate ligands. The binding site of the competitive inhibitor, glutathione sulfonate, is located on domain I, and is part of a cleft formed between intrasubunit domains. Glutathione sulfonate is bound in an extended conformation through multiple interactions. Only three contact residues, namely Tyr7, Gln62 and Asp96 are conserved within the family of cytosolic glutathione S-transferases. The exact location of the binding site(s) of the electrophilic substrate is not clear. Catalytic models are discussed on the basis of the molecular structure.

Class pi glutathione S-transferase from pig lung. Purification, biochemical characterization, primary structure and crystallization.

A cytosolic glutathione S-transferase from pig lung was purified 210-fold to apparent homogeneity. The enzyme was classified as a class pi isoenzyme on the basis of its physical and chemical properties. It is homodimeric with a subunit Mr of 23,500, has a pI of 7.2, and shows a high specific activity towards ethacrynic acid. The glutathione analogues, S-hexylglutathione and glutathione sulfonate, were strong reversible inhibitors. The enzyme's primary structure, established entirely by protein chemical methods, consists of 203 amino acids and is highly similar (82-84% residue identity) to the rat and human class pi isoenzymes. Furthermore, there was no evidence of microheterogeneity or post-translational modifications. Each subunit contains a highly reactive cysteine residue, the modification of which leads to enzyme inactivation. None of the cysteine residues in the pig enzyme appear to form intramolecular disulfide bonds. Singel crystals of the glutathione-S-transferase-glutathione-sulfonate complex were obtained by the hanging-drop method of vapour diffusion from poly(ethylene glycol) 4000 solutions. The crystals belong to the orthorhombic space group P212121 with unit cell dimensions of a = 10.125 nm, b = 8.253 nm and c = 5.428 nm and diffract to better than 0.22 nm.