scholarly journals The structural roles of a conserved small hydrophobic core in the active site and an ionic bridge in domain I of Delta class glutathione S-transferase

2005 ◽  
Vol 393 (1) ◽  
pp. 89-95 ◽  
Author(s):  
Ardcharaporn Vararattanavech ◽  
Peerada Prommeenate ◽  
Albert J. Ketterman
Keyword(s):  
Active Site ◽  
Electrostatic Interactions ◽  
Hydrophobic Core ◽  
Structural Effects ◽  
Glutathione S Transferase ◽  
Anopheles Dirus ◽  
Structural Stabilization ◽  
Α Helix ◽  
Domain I ◽  
Small Hydrophobic

GSTs (glutathione S-transferases; E.C.2.5.1.18) are a supergene family of dimeric multifunctional enzymes that have a major role in detoxification pathways. Using a GST from the mosquito Anopheles dirus (adGSTD4-4), we have characterized the enzymatic and physical properties of Leu-6, Thr-31, Leu-33, Ala-35, Glu-37, Lys-40 and Glu-42. These residues generate two motifs located in the N-terminal domain (domain I) that are functionally conserved across GST classes. The aim of this study was to understand the function of these two motifs. The first motif is a small hydrophobic core in the G-site (glutathione-binding site) wall, and the second motif contains an ionic bridge at the N-terminus of the α2 helix and is also part of the G-site. The mutations in the small hydrophobic core appear to have structural effects, as shown by the thermal stability, refolding rate and intrinsic fluorescence differences. In the Delta class GST, interactions form an ionic bridge motif located at the beginning of the α2 helix. The data suggest that electrostatic interactions in the α2 helix are involved in α-helix stabilization, and disruption of this ionic bridge interaction changes the movement of the α2-helix region, thereby modulating the interaction of the enzyme with substrates. These results show that the small hydrophobic core and ionic bridge have a major impact on structural stabilization, as well as being required to maintain structural conformation of the enzyme. These structural effects are also transmitted to the active site to influence substrate binding and specificity. Therefore changes in the conformation of the G-site wall in the active site appear to be capable of exerting influences on the tertiary structural organization of the whole GST protein.

scholarly journals Electrostatic interactions affecting the active site of class Sigma glutathione S-transferase

2000 ◽  
Vol 347 (1) ◽  
pp. 193-197 ◽  
Author(s):  
Julie M. STEVENS ◽  
Richard N. ARMSTRONG ◽  
Heini W. DIRR
Keyword(s):  
Ionic Strength ◽  
Conformational Changes ◽  
Active Site ◽  
Electrostatic Interactions ◽  
Size Exclusion ◽  
Tryptophan Residue ◽  
Glutathione S Transferase ◽  
Protein Fluorescence ◽  
Subunit Interface ◽  
Α Helix

We have shown previously that the solvent-induced equilibrium unfolding mechanism of class Sigma glutathione S-transferase (GST) is strongly affected by ionic strength [Stevens, Hornby, Armstrong and Dirr (1998) Biochemistry 37, 15534-15541]. The protein is dimeric and has a hydrophilic subunit interface. Here we show that ionic strength alone has significant effects on the conformation of the protein, in particular at the active site. With the use of NaCl at up to 2 M under equilibrium conditions, the protein lost 60% of its catalytic activity and the single tryptophan residue per subunit became partly exposed. The effect was independent of protein concentration, eliminating the dissociation of the dimer as a possibility for the conformational changes. This was confirmed by size-exclusion HPLC. There was no significant change in the secondary structure of the protein according to far-UV CD data. Manual-mixing and stopped-flow kinetics experiments showed a slow single-exponential salt-induced change in protein fluorescence. For equilibrium and kinetics experiments, the addition of an active-site ligand (S-hexylglutathione) completely protected the protein from the ionic-strength-induced conformational changes. This suggests that the change occurs at or near the active site. Possible structural reasons for these novel effects are proposed, such as the flexibility of the α-helix 2 region as well as the hydrophilic subunit interface, highlighting the importance of electrostatic interactions in maintaining the structure of the active site of this GST.

scholarly journals A sensitive core region in the structure of glutathione S-transferases

2003 ◽  
Vol 373 (3) ◽  
pp. 759-765 ◽  
Author(s):  
Jantana WONGSANTICHON ◽  
Thasaneeya HARNNOI ◽  
Albert J. KETTERMAN
Keyword(s):  
Active Site ◽  
Site Directed Mutagenesis ◽  
Size Exclusion ◽  
Single Amino Acid ◽  
Variant Form ◽  
Active Site Residues ◽  
Glutathione S Transferase ◽  
Anopheles Dirus ◽  
Single Amino Acid Change ◽  
Exclusion Chromatography

A variant form of an Anopheles dirus glutathione S-transferase (GST), designated AdGSTD4-4, possesses a single amino acid change of leucine to arginine (Leu-103-Arg). Although residue 103 is outside of the active site, it has major effects on enzymic properties. To investigate these structural effects, site-directed mutagenesis was used to generate mutants by changing the non-polar leucine to alanine, glutamate, isoleucine, methionine, asparagine, or tyrosine. All of the recombinant GSTs showed approximately the same expression level at 25° C. Several of the mutants lacked glutathione (GSH)-binding affinity but were purified by S-hexyl-GSH-based affinity chromatography. However the protein yields (70-fold lower), as well as the GST activity (100-fold lower), of Leu-103-Tyr and Leu-103-Arg purifications were surprisingly low and precluded the performance of kinetic experiments. Size-exclusion chromatography showed that both GSTs Leu-103-Tyr and Leu-103-Arg formed dimers. Using 1-chloro-2,4-dinitrobenzene (CDNB) and GSH substrates to determine kinetic constants it was demonstrated that the other Leu-103 mutants possessed a greater Km towards GSH and a differing Km towards CDNB. The Vmax ranged from 44.7 to 87.0 μmol/min per mg (wild-type, 44.7 μmol/min per mg). Substrate-specificity studies showed different selectivity properties for each mutant. The structural residue Leu-103 affects the active site through H-bond and van-der-Waal contacts with six active-site residues in the GSH binding site. Changes in this interior core residue appear to disrupt internal packing, which affects active-site residues as well as residues at the subunit–subunit interface. Finally, the data suggest that Leu-103 is noteworthy as a sensitive residue in the GST structure that modulates enzyme activity as well as stability.

scholarly journals Electrostatic interactions affecting the active site of class Sigma glutathione S-transferase

2000 ◽  
Vol 347 (1) ◽  
pp. 193 ◽  
Author(s):  
Julie M. STEVENS ◽  
Richard N. ARMSTRONG ◽  
Heini W. DIRR
Keyword(s):  
Active Site ◽  
Electrostatic Interactions ◽  
Glutathione S Transferase

Crystal structure of enoyl-CoA hydratase from Thermus thermophilus HB8

2021 ◽  
Vol 77 (5) ◽  
pp. 148-155
Author(s):  
Sivaraman Padavattan ◽  
Sneha Jos ◽  
Hemanga Gogoi ◽  
Bagautdin Bagautdinov
Keyword(s):  
Crystal Structure ◽  
Active Site ◽  
Thermus Thermophilus ◽  
Tca Cycle ◽  
Significant Shift ◽  
Oxidation Pathway ◽  
Ligand Binding Sites ◽  
Chain Acyl ◽  
Α Helix ◽  
Enoyl Coa Hydratase

Fatty-acid degradation is an oxidative process that involves four enzymatic steps and is referred to as the β-oxidation pathway. During this process, long-chain acyl-CoAs are broken down into acetyl-CoA, which enters the mitochondrial tricarboxylic acid (TCA) cycle, resulting in the production of energy in the form of ATP. Enoyl-CoA hydratase (ECH) catalyzes the second step of the β-oxidation pathway by the syn addition of water to the double bond between C2 and C3 of a 2-trans-enoyl-CoA, resulting in the formation of a 3-hydroxyacyl CoA. Here, the crystal structure of ECH from Thermus thermophilus HB8 (TtECH) is reported at 2.85 Å resolution. TtECH forms a hexamer as a dimer of trimers, and wide clefts are uniquely formed between the two trimers. Although the overall structure of TtECH is similar to that of a hexameric ECH from Rattus norvegicus (RnECH), there is a significant shift in the positions of the helices and loops around the active-site region, which includes the replacement of a longer α3 helix with a shorter α-helix and 310-helix in RnECH. Additionally, one of the catalytic residues of RnECH, Glu144 (numbering based on the RnECH enzyme), is replaced by a glycine in TtECH, while the other catalytic residue Glu164, as well as Ala98 and Gly141 that stabilize the enolate intermediate, is conserved. Their putative ligand-binding sites and active-site residue compositions are dissimilar.

scholarly journals Residual Helicity at the Active Site of the Histidine Phosphocarrier, HPr, Modulates Binding Affinity to Its Natural Partners

2021 ◽  
Vol 22 (19) ◽  
pp. 10805
Author(s):  
José L. Neira ◽  
David Ortega-Alarcón ◽  
Bruno Rizzuti ◽  
Martina Palomino-Schätzlein ◽  
Adrián Velázquez-Campoy ◽  
...  
Keyword(s):  
Staphylococcus Aureus ◽  
Active Site ◽  
Antibacterial Properties ◽  
Helical Structure ◽  
Titration Calorimetry ◽  
Its Sequence ◽  
Wild Type ◽  
Phosphotransferase System ◽  
Residual Structure ◽  
Α Helix

The phosphoenolpyruvate-dependent phosphotransferase system (PTS) modulates the preferential use of sugars in bacteria. The first proteins in the cascade are common to all organisms (EI and HPr). The active site of HPr involves a histidine (His15) located immediately before the beginning of the first α-helix. The regulator of sigma D (Rsd) protein also binds to HPr. The region of HPr comprising residues Gly9-Ala30 (HPr9–30), involving the first α-helix (Ala16-Thr27) and the preceding active site loop, binds to both the N-terminal region of EI and intact Rsd. HPr9–30 is mainly disordered. We attempted to improve the affinity of HPr9–30 to both proteins by mutating its sequence to increase its helicity. We designed peptides that led to a marginally larger population in solution of the helical structure of HPr9–30. Molecular simulations also suggested a modest increment in the helical population of mutants, when compared to the wild-type. The mutants, however, were bound with a less favorable affinity than the wild-type to both the N-terminal of EI (EIN) or Rsd, as tested by isothermal titration calorimetry and fluorescence. Furthermore, mutants showed lower antibacterial properties against Staphylococcus aureus than the wild-type peptide. Therefore, we concluded that in HPr, a compromise between binding to its partners and residual structure at the active site must exist to carry out its function.

scholarly journals Catalytic and structural contributions for glutathione-binding residues in a Delta class glutathione S-transferase

2004 ◽  
Vol 382 (2) ◽  
pp. 751-757 ◽  
Author(s):  
Pakorn WINAYANUWATTIKUN ◽  
Albert J. KETTERMAN
Keyword(s):  
Binding Site ◽  
Active Site ◽  
Structural Integrity ◽  
Catalytic Mechanism ◽  
Tertiary Structure ◽  
Site Directed Mutagenesis ◽  
Active Site Residues ◽  
Anopheles Dirus ◽  
Steady State Kinetics ◽  
Cellular Detoxification

Glutathione S-transferases (GSTs) are dimeric proteins that play a major role in cellular detoxification. The GSTs in mosquito Anopheles dirus species B, an important malaria vector in South East Asia, are of interest because they can play an important role in insecticide resistance. In the present study, we characterized the Anopheles dirus (Ad)GST D3-3 which is an alternatively spliced product of the adgst1AS1 gene. The data from the crystal structure of GST D3-3 shows that Ile-52, Glu-64, Ser-65, Arg-66 and Met-101 interact directly with glutathione. To study the active-site function of these residues, alanine substitution site-directed mutagenesis was performed resulting in five mutants: I52A (Ile-52→Ala), E64A, S65A, R66A and M101A. Interestingly, the E64A mutant was expressed in Escherichia coli in inclusion bodies, suggesting that this residue is involved with the tertiary structure or folding property of this enzyme. However, the I52A, S65A, R66A and M101A mutants were purified by glutathione affinity chromatography and the enzyme activity characterized. On the basis of steady-state kinetics, difference spectroscopy, unfolding and refolding studies, it was concluded that these residues: (1) contribute to the affinity of the GSH-binding site (‘G-site’) for GSH, (2) influence GSH thiol ionization, (3) participate in kcat regulation by affecting the rate-limiting step of the reaction, and in the case of Ile-52 and Arg-66, influenced structural integrity and/or folding of the enzyme. The structural perturbations from these mutants are probably transmitted to the hydrophobic-substrate-binding site (‘H-site’) through changes in active site topology or through effects on GSH orientation. Therefore these active site residues appear to contribute to various steps in the catalytic mechanism, as well as having an influence on the packing of the protein.

Sweetened kallikrein-related peptidases (KLKs): glycan trees as potential regulators of activation and activity

2014 ◽  
Vol 395 (9) ◽  
pp. 959-976 ◽  
Author(s):  
Shihui Guo ◽  
Wolfgang Skala ◽  
Viktor Magdolen ◽  
Hans Brandstetter ◽  
Peter Goettig
Keyword(s):  
Prostate Cancer ◽  
Endoplasmic Reticulum ◽  
Protein Synthesis ◽  
Benign Prostatic Hyperplasia ◽  
Active Site ◽  
Prostatic Hyperplasia ◽  
Healthy Individuals ◽  
Glycosylation Pattern ◽  
Structural Stabilization ◽  
Respective Function

Abstract Most kallikrein-related peptidases (KLKs) are N-glycosylated with N-acetylglucosamine2-mannose9 units at Asn-Xaa-Ser/Thr sequons during protein synthesis and translocation into the endoplasmic reticulum. These N-glycans are modified in the Golgi machinery, where additional O-glycosylation at Ser and Thr takes place, before exocytotic release of the KLKs into the extracellular space. Sequons are present in all 15 members of the KLKs and comparative studies for KLKs from natural and recombinant sources elucidated some aspects of glycosylation. Although glycosylation of mammalian KLKs 1, 3, 4, 6, and 8 has been analyzed in great detail, e.g., by crystal structures, the respective function remains largely unclear. In some cases, altered enzymatic activity was observed for KLKs upon glycosylation. Remarkably, for KLK3/PSA, changes in the glycosylation pattern were observed in samples of benign prostatic hyperplasia and prostate cancer with respect to healthy individuals. Potential functions of KLK glycosylation in structural stabilization, protection against degradation, and activity modulation of substrate specificity can be deduced from a comparison with other glycosylated proteins and their regulation. According to the new concept of protein sectors, glycosylation distant from the active site might significantly influence the activity of proteases. Novel pharmacological approaches can exploit engineered glycans in the therapeutical context.

scholarly journals The three-dimensional structure of a class-Pi glutathione S-transferase complexed with glutathione: the active-site hydration provides insights into the reaction mechanism

1998 ◽  
Vol 333 (3) ◽  
pp. 811-816 ◽  
Author(s):  
Antonio PÁRRAGA ◽  
Isabel GARCÍA-SÁEZ ◽  
Sinead B. WALSH ◽  
Timothy J. MANTLE ◽  
Miquel COLL
Keyword(s):  
Conformational Changes ◽  
Active Site ◽  
Three Dimensional ◽  
Dimensional Structure ◽  
Water Molecules ◽  
X Ray Diffraction ◽  
Glutathione S Transferase ◽  
X Ray ◽  
The Right

The structure of mouse liver glutathione S-transferase P1-1 complexed with its substrate glutathione (GSH) has been determined by X-ray diffraction analysis. No conformational changes in the glutathione moiety or in the protein, other than small adjustments of some side chains, are observed when compared with glutathione adduct complexes. Our structure confirms that the role of Tyr-7 is to stabilize the thiolate by hydrogen bonding and to position it in the right orientation. A comparison of the enzyme–GSH structure reported here with previously described structures reveals rearrangements in a well-defined network of water molecules in the active site. One of these water molecules (W0), identified in the unliganded enzyme (carboxymethylated at Cys-47), is displaced by the binding of GSH, and a further water molecule (W4) is displaced following the binding of the electrophilic substrate and the formation of the glutathione conjugate. The possibility that one of these water molecules participates in the proton abstraction from the glutathione thiol is discussed.

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