The hydrophobic lock-and-key intersubunit motif of glutathione transferase A1-1: implications for catalysis, ligandin function and stability (original) (raw)
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Biochemical Journal, 2006
The dimeric structure of certain cytosolic GSTs (glutathione Stransferases) is stabilized by a hydrophobic lock-and-key motif at their subunit interface. In hGSTA1-1 (human class Alpha GST with two type-1 subunits), the key consists of two residues, Met 51 and Phe 52 , that fit into a hydrophobic cavity (lock) in the adjacent subunit. SEC (size-exclusion chromatography)-HPLC, far-UV CD and tryptophan fluorescence of the M51A and M51A/ F52S mutants indicated the non-disruptive nature of these mutations on the global structure. While the M51A mutant retained 80 % of wild-type activity, the activity of the M51A/F52S was markedly diminished, indicating the importance of Phe 52 in maintaining the correct conformation at the active site. The M51A and M51A/F52S mutations altered the binding of ANS (8-anilinonaphthalene-l-sulphonic acid) at the H-site by destabilizing helix 9 in the C-terminal region. Data from urea unfolding studies show that the dimer is destabilized by both mutations and that the dimer dissociates to aggregation-prone monomers at low urea concentrations before global unfolding. Although not essential for the assembly of the dimeric structure of hGSTA1-1, both Met 51 and Phe 52 in the intersubunit lock-and-key motif play important structural roles in maintaining the catalytic and ligandin functions and stability of the GST dimer.
Journal of Biological Chemistry, 2001
An N-capping box and a hydrophobic staple motif are strictly conserved in the core of all known glutathione S-transferases (GST). In the present work, mutations of hGSTA1-1 enzyme residues forming these motifs have been generated. The analysis of S154A, D157A, and S154A/D157A capping mutants indicate that the removal of this local signal destabilizes the protein. The fact that the third helical residue D157A mutation (N-3) was much more destabilizing than the first helical residue S154A mutation (N-cap) suggests that the appropriate conformation of the conserved substructure formed by the ␣6-helix and preceding loop (GST motif II) is crucial for the overall protein stability. The refolding study of GSTA1-1 variants supports the prediction that this subdomain could represent a nucleation site of refolding. The analysis of L153A, I158A, L153G, and L153A/I158A hydrophobic staple mutants indicate that the removal of this motif destabilizes the GSTA1-1 structure as well as its refolding transition state. The hydrophobic staple interaction favors essential inter-domain contacts and, thereby, in contrast to capping interactions, accelerates the enzyme reactivation. Its strict conservation in the GST system supports the suggestion that this local signal could represent an evolutionarily conserved determinant for rapid folding.
Functional role of the lock and key motif at the subunit interface of glutathione transferase p1-1
Journal of Biological Chemistry, 2004
The glutathione transferases (GSTs) represent a superfamily of dimeric proteins. Each subunit has an active site, but there is no evidence for the existence of catalytically active monomers. The lock and key motif is responsible for a highly conserved hydrophobic interaction in the subunit interface of pi, mu, and alpha class glutathione transferases. The key residue, which is either Phe or Tyr (Tyr 50 in human GSTP1-1) in one subunit, is wedged into a hydrophobic pocket of the other subunit. To study how an essentially inactive subunit influences the activity of the neighboring subunit, we have generated the heterodimer composed of subunits from the fully active human wild-type GSTP1-1 and the nearly inactive mutant Y50A obtained by mutation of the key residue Tyr 50 to Ala. Although the key residue is located far from the catalytic center, the k cat value of mutant Y50A decreased about 1300-fold in comparison with the wild-type enzyme. The decrease of the k cat value of the heterodimer by about 27-fold rather than the expected 2-fold in comparison with the wild-type enzyme indicates that the two active sites of the dimeric enzyme work synergistically. Further evidence for cooperativity was found in the nonhyperbolic GSH saturation curves. A network of hydrogen-bonded water molecules, found in crystal structures of GSTP1-1, connects the two active sites and the main chain carbonyl group of Tyr 50 , thereby offering a mechanism for communication between the two active sites. It is concluded that a subunit becomes catalytically competent by positioning the key residue of one subunit into the lock pocket of the other subunit, thereby stabilizing the loop following the helix ␣2, which interacts directly with GSH.
Acta Crystallographica Section D Biological Crystallography, 2006
Human glutathione transferase A1-1 is a well studied enzyme, but despite a wealth of structural and biochemical data a number of aspects of its catalytic function are still poorly understood. Here, five new crystal structures of this enzyme are described that provide several insights. Firstly, the structure of a complex of the wild-type human enzyme with glutathione was determined for the first time at 2.0 Å resolution. This reveals that glutathione binds in the G site in a very similar fashion as the glutathione portion of substrate analogues in other structures and also that glutathione binding alone is sufficient to stabilize the C-terminal helix of the protein. Secondly, we have studied the complex with a decarboxylated glutathione conjugate that is known to dramatically decrease the activity of the enzyme. The T68E mutant of human glutathione transferase A1-1 recovers some of the activity that is lost with the decarboxylated glutathione, but our structures of this mutant show that none of the earlier explanations of this phenomenon are likely to be correct. Thirdly, and serendipitously, the apo structures also reveal the conformation of the crucial C-terminal region that is disordered in all previous apo structures. The C-terminal region can adopt an ordered helix-like structure even in the apo state, but shows a strong tendency to unwind. Different conformations of the C-terminal regions were observed in the apo states of the two monomers, which suggests that cooperativity could play a role in the activity of the enzyme.
Journal of Molecular Biology, 2005
The C-terminal region in class Alpha glutathione transferase A1-1 (GSTA1-1), which forms an amphipathic a-helix (helix 9), is known to contribute to the catalytic and non-substrate ligand-binding functions of the enzyme. The region in the apo protein is proposed to be disordered which, upon ligand binding at the active-site, becomes structured and localised. Because Ile219 plays a pivotal role in the stability and localisation of the region, the role of tertiary interactions mediated by Ile219 in determining the conformation and dynamics of the C-terminal region were studied. Ligand-binding microcalorimetric and X-ray structural data were obtained to characterise ligand binding at the active-site and the associated localisation of the C-terminal region. In the crystal structure of the I219A hGSTA1-1$ S-hexylglutathione complex, the C-terminal region of one chain is mobile and not observed (unresolved electron density), whereas the corresponding region of the other chain is localised and structured as a result of crystal packing interactions. In solution, the mutant C-terminal region of both chains in the complex is mobile and delocalised resulting in a hydrated, less hydrophobic active-site and a reduction in the affinity of the protein for S-hexylglutathione. Complete dehydration of the active-site, important for maintaining the highly reactive thiolate form of glutathione, requires the binding of ligands and the subsequent localisation of the C-terminal region. Thermodynamic data demonstrate that the mobile C-terminal region in apo hGSTA1-1 is structured and does not undergo ligand-induced folding. Its close proximity to the surface of the wild-type protein is indicated by the concurrence between the observed heat capacity change of complex formation and the type and amount of surface area that becomes buried at the ligand-protein interface when the C-terminal region in the apo protein assumes the same localised structure as that observed in the wild-type complex.
The Journal of biological chemistry, 1996
Presteady-state and steady-state kinetics of human glutathione transferase P1-1 (EC 2.5.1.18) have been studied at pH 5.0 by using 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole, a poor co-substrate for this isoenzyme. Steady-state kinetics fits well with the simplest rapid equilibrium random sequential bi-bi mechanism and reveals a strong intrasubunit synergistic modulation between the GSH-binding site (G-site) and the hydrophobic binding site for the co-substrate (H-site); the affinity of the G-site for GSH increases about 30 times at saturating co-substrate and vice versa. Presteady-state experiments and thermodynamic data indicate that the rate-limiting step is a physical event and, probably, a structural transition of the ternary complex. Similar to that observed with 1-chloro-2,4-dinitrobenzene (may be related to the frequency of enzyme motions. The observed low, viscosity-independent k cat value suggests that these motions are slow and diffusion-independent for an increased internal viscosity. In fact, molecular modeling suggests that the hydroxyl group of Tyr-108, which resides in helix 4, may be in hydrogen bonding distance of the oxygen atom of this new substrate, thus yielding a less flexible H-site. This effect might be transmitted to the G-site via helix 4
Biochemical Journal, 1998
A topologically conserved residue in α-helix 6 of domain II of human glutathione transferase (hGST) A1-1 was mutated to investigate its contribution to protein stability and the unfolding pathway. The replacement of Leu-164 with alanine (L164A) did not impact on the functional and gross structural properties of native hGST A1-1. The wild-type protein unfolds via a three-state pathway in which only folded dimer and unfolded monomer were highly populated at equilibrium; a native-like dimeric intermediate with partially dissociated domains I and II was detected using stopped-flow fluorescence studies [Wallace, Sluis-Cremer and Dirr (1998) Biochemistry 37, 5320–5328]. In the present study, urea-induced equilibrium unfolding of L164A hGST A1-1 indicated a destabilization of the native state and suggested the presence of a stable dimeric intermediate. The unfolding kinetic pathway for L164A hGST A1-1, like that for the wild type, is biphasic, with a fast and a slow unfolding event; the ca...
Conventional steady-state kinetic studies of the dimeric human glutathione transferase (GST) P1-1 do not reveal obvious deviations from Michaelis-Menten behavior. By contrast, engineering of the key residue Y50 of the lock-and-key motif in the subunit interface reveals allosteric properties of the enzyme. The low-activity mutant Y50C, characterized by 150-fold decreased k cat and 300-fold increased K M GSH values, displays an apparent Hill coefficient of 0.82 ± 0.22. Chemical alkylation of the sulfhydryl group of Y50C by unnatural n-butyl or n-pentyl substitutions enhances the catalytic efficiency k cat /K M GSH to near the wild-type value but still yields Hill coefficients of 0.61 ± 0.08 and 0.86 ± 0.1, respectively. Thus, allosteric kinetic behavior is not dependent on low activity of the enzyme. On the other hand, S-cyclobutylmethyl-substituted Y50C, which also displays high catalytic efficiency, has a Hill coefficient of 0.99 ± 0.11, showing that subtle differences in structure at the subunit interface influence the complex kinetic behavior. Furthermore, inhibition studies of native GST P1-1 using ethacrynic acid demonstrate that a ligand bound noncovalently to the wild-type enzyme also can elicit allosteric kinetic behavior. Thus, we conclude that the GST P1-1 structure has intrinsic allostery that becomes overt under some, but not all, ambient conditions.
Journal of Molecular Biology, 1998
Previous kinetic studies on human glutathione transferase P1-1 have indicated that the motions of an irregular alpha-helix (helix 2) lining the glutathione (GSH) binding site are viscosity dependent and may modulate the af®nity of GSH binding. The effect of single amino acid residue substitutions (Gly to Ala) in this region is investigated here by sitedirected mutagenesis. Three mutants (Gly41Ala, Gly50Ala and Gly41Ala/Gly50Ala) were overexpressed in Escherichia coli, puri®ed, and characterized by kinetic, structural, and spectroscopic studies. All these mutant enzymes show k cat values similar to that of the wild-type enzyme, while the [S] 0.5 for GSH increases about eight-fold in the Gly41Ala mutant and more than 100-fold in the Gly41Ala/Gly50Ala double mutant. This change in af®nity towards GSH is accompanied by an induced positive cooperativity as re¯ected by Hill coef®cients of 1.4 (Gly41Ala) and 1.7 (Gly41Ala/Gly50Ala) upon substrate binding. Taken together, these data suggest that the region around helix 2 is markedly altered leading to the observed intersubunit communication. Molecular modeling of the Gly41Ala/Gly50Ala mutant and of the inactive oxidized form of the native enzyme provides a structural explanation of our results.