Tyrosine-7 in human class Pi glutathione S-transferase is important for lowering the pKa of the thiol group of glutathione in the enzyme-glutathione complex.

Previously, we reported the importance of Tyr7 for the catalytic activity of human class Pi glutathione S-transferase [Kong et al. (1992) Biochem. Biophys. Res. Comm., 182, 1122]. As an extension of this study, we investigated the pH dependence of kinetic parameters of the wild-type enzyme and the Y7F mutant. The replacement of Tyr7 with phenylalanine was found to alter the pH dependence of Vmax and Vmax/KmCDNB of the enzyme for conjugation of GSH with 1-chloro-2,4-dinitrobenzene (CDNB). The pKa of the thiol of GSH in the wild-type enzyme-GSH complex was estimated to be about 2.4 pK units lower than that in the Y7F-GSH complex. Tyr7 is thus considered to be important for catalytic activity in lowering the pKa of the thiol of GSH in the enzyme-GSH complex.     

Thermodynamic description of the effect of the mutation Y49F on human glutathione transferase P1-1 in binding with glutathione and the inhibitor S-hexylglutathione

The thermodynamics of binding of both the substrate glutathione (GSH) and the competitive inhibitor S-hexylglutathione to the mutant Y49F of human glutathione S-transferase (hGST P1-1), a key residue at the dimer interface, has been investigated by isothermal titration calorimetry and fluorescence spectroscopy. Calorimetric measurements indicated that the binding of these ligands to both the Y49F mutant and wild-type enzyme is enthalpically favorable and entropically unfavorable over the temperature range studied. The affinity of these ligands for the Y49F mutant is lower than those for the wild-type enzyme due mainly to an entropy change. Therefore, the thermodynamic effect of this mutation is to decrease the entropy loss due to binding. Calorimetric titrations in several buffers with different ionization heat amounts indicate a release of protons when the mutant binds GSH, whereas protons are taken up in binding S-hexylglutathione at pH 6.5. This suggests that the thiol group of GSH releases protons to buffer media during binding and a group with low pKa (such as Asp98) is responsible for the uptake of protons. The temperature dependence of the free energy of binding, DeltaG0, is weak because of the enthalpy-entropy compensation caused by a large heat capacity change. The heat capacity change is -199.5 +/- 26.9 cal K-1 mol-1 for GSH binding and -333.6 +/- 28.8 cal K-1 mol-1 for S-hexylglutathione binding. The thermodynamic parameters are consistent with the mutation Tyr49 --> Phe, producing a slight conformational change in the active site.     

Crystallographic and thermodynamic analysis of the binding of S-octylglutathione to the Tyr 7 to Phe mutant of glutathione S-transferase from Schistosoma japonicum

Glutathione S-transferases are a family of multifunctional enzymes involved in the metabolism of drugs and xenobiotics. Two tyrosine residues, Tyr 7 and Tyr 111, in the active site of the enzyme play an important role in the binding and catalysis of substrate ligands. The crystal structures of Schistosoma japonicum glutathione S-transferase tyrosine 7 to phenylalanine mutant [SjGST(Y7F)] in complex with the substrate glutathione (GSH) and the competitive inhibitor S-octylglutathione (S-octyl-GSH) have been obtained. These new structural data combined with fluorescence spectroscopy and thermodynamic data, obtained by means of isothermal titration calorimetry, allow for detailed characterization of the ligand-binding process. The binding of S-octyl-GSH to SjGST(Y7F) is enthalpically and entropically driven at temperatures below 30 degrees C. The stoichiometry of the binding is one molecule of S-octyl-GSH per mutant dimer, whereas shorter alkyl derivatives bind with a stoichiometry of two molecules per mutant dimer. The SjGST(Y7F).GSH structure showed no major structural differences compared to the wild-type enzyme. In contrast, the structure of SjGST(Y7F).S-octyl-GSH showed asymmetric binding of S-octyl-GSH. This lack of symmetry is reflected in the lower symmetry space group of the SjGST(Y7F).S-octyl-GSH crystals (P6(3)) compared to that of the SjGST(Y7F).GSH crystals (P6(3)22). Moreover, the binding of S-octyl-GSH to the A subunit is accompanied by conformational changes that may be responsible for the lack of binding to the B subunit.     

Pressure-dependent ionization of Tyr 9 in glutathione S-transferase A1-1: contribution of the C-terminal helix to a "soft" active site.

The glutathione S-transferase (GST) isozyme A1-1 contains at its active site a catalytic tyrosine, Tyr9, which hydrogen bonds to, and stabilizes, the thiolate form of glutathione, GS-. In the substrate-free GST A1-1, the Tyr 9 has an unusually low pKa, approximately 8.2, for which the ionization to tyrosinate is monitored conveniently by UV and fluorescence spectroscopy in the tryptophan-free mutant, W21F. In addition, a short alpha-helix, residues 208-222, provides part of the GSH and hydrophobic ligand binding sites, and the helix becomes "disordered" in the absence of ligands. Here, hydrostatic pressure has been used to probe the conformational dynamics of the C-terminal helix, which are apparently linked to Tyr 9 ionization. The extent of ionization of Tyr 9 at pH 7.6 is increased dramatically at low pressures (p1/2 = 0.52 kbar), based on fluorescence titration of Tyr 9. The mutant protein W21F:Y9F exhibits no changes in tyrosine fluorescence up to 1.2 kbar; pressure specifically ionizes Tyr 9. The volume change, delta V, for the pressure-dependent ionization of Tyr 9 at pH 7.6, 19 degrees C, was -33 +/- 3 mL/mol. In contrast, N-acetyl tyrosine exhibits a delta V for deprotonation of -11 +/- 1 mL/mol, beginning from the same extent of initial ionization, pH 9.5. The pressure-dependent ionization is completely reversible for both Tyr 9 and N-acetyl tyrosine. Addition of S-methyl GSH converted the "soft" active site to a noncompressible site that exhibited negligible pressure-dependent ionization of Tyr 9 below 0.8 kbar. In addition, Phe 220 forms part of an "aromatic cluster" with Tyr 9 and Phe 10, and interactions among these residues were hypothesized to control the order of the C-terminal helix. The amino acid substitutions F220Y, F2201, and F220L afford proteins that undergo pressure-dependent ionization of Tyr 9 with delta V values of 31 +/- 2 mL/mol, 43 +/- 3 mL/mol, and 29 +/- 2 mL/mol, respectively. The p1/2 values for Tyr 9 ionization were 0.61 kbar, 0.41 kbar, and 0.46 kbar for F220Y, F220I, and F220L, respectively. Together, the results suggest that the C-terminal helix is conformationally heterogeneous in the absence of ligands. The conformations differ little in free energy, but they are significantly different in volume, and mutations at Phe 220 control the conformational distribution.     

A monomer form of the glutathione S-transferase Y7F mutant from Schistosoma japonicum at acidic pH

Dissociation and unfolding of homodimeric glutathione S-transferase Y7F mutant from Schistosoma japonicum (SjGST-Y7F) were investigated at equilibrium using urea as denaturant. The conserved residue Tyr7 plays a central role in the catalytic mechanism and the mutation Tyr-Phe yields an inactive enzyme that is able to bind the substrate GSH with a higher binding constant than the wild type enzyme. Mutant SjGST-Y7F is a dimer at pH 6 or higher and a stable monomer at pH 5 that binds GSH (K value of 1.2x10(5)+/-6.4x10(3)M(-1) at pH 6.5 and 6.3x10(4)+/-1.25x10(3)M(-1) at pH 5). The stability of the SjGST-Y7F mutant was studied by urea induced unfolding techniques (DeltaG(W)=13.86+/-0.63kcalmol(-1) at pH 6.5 and DeltaG(W)=11.22+/-0.25kcalmol(-1) at pH 5) and the monomeric form characterized by means of size exclusion chromatography, fluorescence, and electrophoretic techniques.     

Slow structural changes shown by the 3-nitrotyrosine-237 residue in pig heart [Tyr(3NO2)237] lactate dehydrogenase.

1. The pKa of the phenolic hydroxy group of the Tyr(3NO2)-237 residue in pig heart [Tyr(3NO2)237]lactate dehydrogenase is 7.2 in the apoenzyme, 7.4 in the enzyme-NADH complex and 7.8 in the enzyme-NADH-oxamate complex. The alkaline shift from apoenzyme to ternary complex is ascribed to the approach of the Glu-107 residue during the movement of the polypeptide loop residues 98-110. 2. The affinities of the nitrated enzyme for NADH and for oxamate (in the presence of NADH) are slightly less than those of the native enzyme. The turnover number for the nitrated enzyme in the pyruvate-to-lactate direction is about 0.75 of the value for the native enzyme. 3. Temperature-jump relaxation experiments of the enzyme saturated with NADH but fractionally saturated with oxamate are interpreted to show that the pKa of the nitrotyrosine residue responds to a protein rearrangement after oxamate binds to the binary enzyme-NADH complex. 4. Transient-kinetic experiments show the environment of the Tyr(3NO2)-237 residue in the enzyme-NADH-pyruvate complex of the steady state to be similar to that in the enzyme-NADH-oxamate inhibitor complex.     

Spectroscopic and kinetic evidence for the thiolate anion of glutathione at the active site of glutathione S-transferase

Ultraviolet difference spectroscopy of the binary complex of isozyme 4-4 of rat liver glutathione S-transferase with glutathione (GSH) and the enzyme alone or as the binary complex with the oxygen analogue, gamma-L-glutamyl-L-serylglycine (GOH), at neutral pH reveals an absorption band at 239 nm (epsilon = 5200 M-1 cm-1) that is assigned to the thiolate anion (GS-) of the bound tripeptide. Titration of this difference absorption band over the pH range 5-8 indicates that the thiol of enzyme-bound GSH has a pKa = 6.6, which is about 2.4 pK units less than that in aqueous solution and consistent with the kinetically determined pKa previously reported [Chen et al. (1988) Biochemistry 27, 647]. The observed shift in the pKa between enzyme-bound and free GSH suggests that about 3.3 kcal/mol of the intrinsic binding energy of the peptide is utilized to lower the pKa into the physiological pH range. Apparent dissociation constants for both GSH and GOH are comparable and vary by a factor of less than 2 over the same pH range. Site occupancy data and spectral band intensity reveal large extinction coefficients at 239 nm (epsilon = 5200 M-1 cm-1) and 250 nm (epsilon = 1100 M-1 cm-1) that are consistent with the existence of either a glutathione thiolate (E.GS-) or ion-paired thiolate (EH+.GS-) in the active site. The observation that GS- is likely the predominant tripeptide species bound at the active site suggested that the carboxylate analogue of GSH, gamma-L-glutamyl-(D,L-2-aminomalonyl)glycine, should bind more tightly than GSH.(ABSTRACT TRUNCATED AT 250 WORDS)     

Local protein dynamics and catalysis: detection of segmental motion associated with rate-limiting product release by a glutathione transferase

Glutathione transferase rGSTM1-1 catalyzes the addition of glutathione (GSH) to 1-chloro-2,4-dinitrobenzene, a reaction in which the chemical step is 60-fold faster than the physical step of product release. The hydroxyl group of Y115, located in the active site access channel, controls the egress of product from the active site. The Y115F mutant enzyme has a k(cat) (72 s(-)(1)) that is 3.6-fold larger than that of the native enzyme (20 s(-)(1)). Crystallographic observations and evidence from amide proton exchange kinetics are consistent with localized increases in the degree of segmental motion of the Y115F mutant that are coupled to the enhanced rate of product release. The loss of hydrogen bonding interactions involving the hydroxyl group of Y115 is reflected in subtle alterations in the backbone position, an increase in B-factors for structural elements that comprise the channel to the active site, and, most dramatically, a loss of well-defined electron density near the site of mutation. The kinetics of amide proton exchange are also enhanced by a factor between 3 and 12 in these regions, providing direct, quantitative evidence for changes in local protein dynamics affecting product release. The enhanced product release rate is proposed to derive from a small shift in the equilibrium population of protein conformers that permit egress of the product from the active site.     

The role of glutathione in the isomerization of delta 5-androstene-3,17-dione catalyzed by human glutathione transferase A1-1

Human glutathione transferase (GST) A1-1 efficiently catalyzes the isomerization of Delta(5)-androstene-3,17-dione (AD) into Delta(4)-androstene-3,17-dione. High activity requires glutathione, but enzymatic catalysis occurs also in the absence of this cofactor. Glutathione alone shows a limited catalytic effect. S-Alkylglutathione derivatives do not promote the reaction, and the pH dependence of the isomerization indicates that the glutathione thiolate serves as a base in the catalytic mechanism. Mutation of the active-site Tyr(9) into Phe significantly decreases the steady-state kinetic parameters, alters their pH dependence, and increases the pK(a) value of the enzyme-bound glutathione thiol. Thus, Tyr(9) promotes the reaction via its phenolic hydroxyl group in protonated form. GST A2-2 has a catalytic efficiency with AD 100-fold lower than the homologous GST A1-1. Another Alpha class enzyme, GST A4-4, is 1000-fold less active than GST A1-1. The Y9F mutant of GST A1-1 is more efficient than GST A2-2 and GST A4-4, both having a glutathione cofactor and an active-site Tyr(9) residue. The active sites of GST A2-2 and GST A1-1 differ by only four amino acid residues, suggesting that proper orientation of AD in relation to the thiolate of glutathione is crucial for high catalytic efficiency in the isomerization reaction. The GST A1-1-catalyzed steroid isomerization provides a complement to the previously described isomerase activity of 3beta-hydroxysteroid dehydrogenase.     

Contribution of aromatic-aromatic interactions to the anomalous pK(a) of tyrosine-9 and the C-terminal dynamics of glutathione S-transferase A1-1

Most cytosolic glutathione S-transferases (GSTs) exploit a hydrogen bond between an active site Tyr and the bound glutathione (GSH) cofactor to lower the pK(a) of the GSH and generate the nucleophilic thiolate anion, GS(-). In human (hGSTA1-1) and rat (rGSTA1-1) homologues, the active site Tyr-9 has a low pK(a) of 8.1-8.3, for which the functional significance is unknown. Crystal structures of GSTA1-1 suggest that weakly polar interactions between the electropositive ring edge of Phe-10 and the pi-cloud of Tyr-9, in the apoenzyme, could stabilize the tyrosinate anion and also modulate the pK(a) of GSH. Upon binding a product GSH conjugate, Phe-10 moves away from Tyr-9, allowing the highly dynamic C-terminus to "close" over the active site. To explore the role of Phe-10 in modulating the Tyr-9 pK(a) and in ligand binding, rGSTA1-1 mutants F10Y, F10L, and F10A were characterized. The pK(a)s of Tyr-9 in the apoenzymes were 8.2 +/- 0.2, 8.7 +/- 0.2, and 9.3 +/- 0.1, respectively, for F10Y, F10L, and F10A, compared to 8.3 +/- 0.2 for the "wild type". The experimentally determined pK(a)s qualitatively paralleled the energies required to remove a proton predicted by ab initio calculations using model compounds constrained to the coordinates of rGSTA1-1. The pK(a) of GSH in the binary complex was significantly less affected by these substitutions. In contrast, F220I and F220Y C-terminal mutations caused the pK(a) of Tyr-9 to decrease modestly. For the binary complex with S-hexyl-GSH, which induces the "closed" conformation, Tyr-9 retains a low pK(a) and the Phe-10 substitutions have significant effects. Presumably, Phe-10 plays a critical structural role in stabilizing the closed conformation. The mutations F10L and F10A also slowed the rate of GSH conjugate binding by 10-20-fold, as measured by stopped-flow fluorescence. The effects of Phe-10 substitution were large for both steps of the biphasic binding reaction, suggesting the importance of aromatic interactions throughout the reaction coordinate. A unified view of the C-terminal dynamics of GSTA1-1 is discussed, which emphasizes the coupling between Tyr-9 ionization, active site solvation, and C-terminal dynamics.     

The anomalous pKa of Tyr-9 in glutathione S-transferase A1-1 catalyzes product release

The pKa of the catalytic Tyr-9 in glutathione S-transferase (GST) A1-1 is lowered from 10.3 to approximately 8.1 in the apoenzyme and approximately 9.0 with a GSH conjugate bound at the active site. However, a clear functional role for the unusual Tyr-9 pKa has not been elucidated. GSTA1-1 also includes a dynamic C terminus that undergoes a ligand-dependent disorder-to-order transition. Previous studies suggest a functional link between Tyr-9 ionization and C-terminal dynamics. Here we directly probe the role of Tyr-9 ionization in ligand binding and C-terminal conformation. An engineered mutant of rGSTA1-1, W21F/F222W, which contains a single Trp at the C terminus, was used as a fluorescent reporter of pH-dependent C-terminal dynamics. This mutant exhibited a pH-dependent change in Trp-222 emission properties consistent with changes in C-terminal solvation or conformation. The apparent pKa values for the conformational transition were 7.9 +/- 0.1 and 9.3 +/- 0.1 for the apoenzyme and ligand-bound enzyme, respectively, in excellent agreement with the pKa for Tyr-9 in these states. The Y9F/W21F/F222W mutant, however, exhibited no such pH-dependent changes. Time-resolved fluorescence anisotropy studies revealed a ligand-dependent, Tyr-9-dependent, change in the order parameter of Trp-222. However, no pH dependence was observed. In equilibrium and pre-steady-state ligand binding studies, product conjugate had a decreased equilibrium binding affinity (KD), concomitant with increased binding and dissociation rates, at higher pH values. Furthermore, the recovered pKa values for the pH-dependent microscopic rate constants ranged from 7.7 to 8.4, also in agreement with the pKa of Tyr-9. In contrast, the Y9F/W21F/F222W mutant had no pH-dependent transition in KD or rate constants for ligand binding or dissociation. The combined results indicate that the macroscopic populations of "open" and "closed" states of the C terminus are not determined solely by the ionization state of Tyr-9. However, the rates of transition between these states are faster for the ionized Tyr-9. The ionized Tyr-9 states provide a parallel pathway for product dissociation, which is kinetically and thermodynamically favored. In silico kinetic models further support the functional role for the parallel dissociation pathway provided by ionized Tyr-9.     

The tyrosine-225 to phenylalanine mutation of Escherichia coli aspartate aminotransferase results in an alkaline transition in the spectrophotometric and kinetic pKa values and reduced values of both kcat and Km

Tyrosine-225 is hydrogen-bonded to the 3'-hydroxyl group of pyridoxal 5'-phosphate in the active site of aspartate aminotransferase. Replacement of this residue with phenylalanine (Y225F) results in a shift in the acidic limb of the pKa of the kcat/KAsp vs pH profile from 7.1 (wild-type) to 8.4 (mutant). The change in the kinetic pKa is mirrored by a similar shift in the spectrophotometrically determined pKa of the protonated internal aldimine. Thus, a major role of tyrosine-225 is to provide a hydrogen bond that stabilizes the reactive unprotonated form of the internal aldimine in the neutral pH range. The Km value for L-aspartate and the dissociation constant for alpha-methyl-DL-aspartate are respectively 20- and 37-fold lower in the mutant than in the wild-type enzyme, while the dissociation constant for maleate is much less perturbed. These results are interpreted in terms of competition between the Tyr225 hydroxyl group and the substrate or quasi-substrate amino group for the coenzyme. The value of kcat in Y225F is 450-fold less than the corresponding rate constant in wild type. The increased affinity of the mutant enzyme for substrates, combined with the lack of discrimination against deuterium in the C alpha position of L-aspartate in Y225F-catalyzed transamination [Kirsch, J. F., Toney, M. D., & Goldberg, J. M. (1990) in Protein and Pharmaceutical Engineering (Craik, C. S., Fletterick, R., Matthews, C. R., & Wells, J., Eds.) pp 105-118, Wiley-Liss, New York], suggests that the rate-determining step in the mutant is hydrolysis of the ketimine intermediate rather than C alpha-H abstraction which is partially rate-determining in wild type.     

Active-site residues governing high steroid isomerase activity in human glutathione transferase A3-3

Glutathione transferase (GST) A3-3 is the most efficient human steroid double-bond isomerase known. The activity with Delta(5)-androstene-3,17-dione is highly dependent on the phenolic hydroxyl group of Tyr-9 and the thiolate of glutathione. Removal of these groups caused an 1.1 x 10(5)-fold decrease in k(cat); the Y9F mutant displayed a 150-fold lower isomerase activity in the presence of glutathione and a further 740-fold lower activity in the absence of glutathione. The Y9F mutation in GST A3-3 did not markedly decrease the activity with the alternative substrate 1-chloro-2,4-dinitrobenzene. Residues Phe-10, Leu-111, and Ala-216 selectively govern the activity with the steroid substrate. Mutating residue 111 into phenylalanine caused a 25-fold decrease in k(cat)/K(m) for the steroid isomerization. The mutations A216S and F10S, separate or combined, affected the isomerase activity only marginally, but with the additional L111F mutation k(cat)/K(m) was reduced to 0.8% of that of the wild-type value. In contrast, the activities with 1-chloro-2,4-dinitrobenzene and phenethylisothiocyanate were not largely affected by the combined mutations F10S/L111F/A216S. K(i) values for Delta(5)-androstene-3,17-dione and Delta(4)-androstene-3,17-dione were increased by the triple mutation F10S/L111F/A216S. The pK(a) of the thiol group of active-site-bound glutathione, 6.1, increased to 6.5 in GST A3-3/Y9F. The pK(a) of the active-site Tyr-9 was 7.9 for the wild-type enzyme. The pH dependence of k(cat)/K(m) of wild-type GST A3-3 for the isomerase reaction displays two kinetic pK(a) values, 6.2 and 8.1. The basic limb of the pH dependence of k(cat) and k(cat)/K(m) disappears in the Y9F mutant. Therefore, the higher kinetic pK(a) reflects ionization of Tyr-9, and the lower one reflects ionization of glutathione. We propose a reaction mechanism for the double-bond isomerization involving abstraction of a proton from C4 in the steroid accompanied by protonation of C6, the thiolate of glutathione serving as a base and Tyr-9 assisting by polarizing the 3-oxo group of the substrate.     

A model for glutathione binding and activation in the fosfomycin resistance protein, FosA

The genomically encoded fosfomycin resistance protein from Pseudomonas aeruginosa (FosA(PA)) utilizes Mn(II) and K(+) to catalyze the addition of glutathione (GSH) to C1 of the antibiotic rendering it inactive. Although this protein has been structurally and kinetically characterized with respect to the substrate, fosfomycin, questions remain regarding how the enzyme binds the thiol substrate, GSH. Computational studies have revealed a potential GSH binding site in FosA(PA) that involves six electrostatic or hydrogen-bonding interactions with protein side-chains as well as six additional residues that contribute van der Waals interactions. A strategically placed tyrosine residue, Y39, appears to be involved in the ionization of GSH during catalysis. The Y39F mutant exhibits a 13-fold reduction of catalytic activity (k(cat)=14+/-2s(-1)), suggesting a role in the ionization of GSH. Mutation of five other residues (W34, Q36, S50, K90, and R93) implicated in ionic of hydrogen-bonding interactions resulted in enzymes with reduced catalytic efficiency, affinity for GSH, or both. The mutant enzymes were also found to be less effective resistant proteins in the biological context of Escherichia coli. The more conservative W34H mutant has native-like catalytic efficiency suggesting that the imidazole NH group can replace the indole group of W34 that is important for GSH binding. In the absence of co-crystal structural data with the thiol substrate, these results provide important insights into the role of GSH in catalysis.     

A highly acidic tyrosine 9 and a normally titrating tyrosine 212 contribute to the catalytic mechanism of human glutathione transferase A4-4

Human glutathione transferase A4-4 is an enzyme catalyzing the detoxication of intracellularly produced electrophiles such as 4-hydroxynonenal and other alkenal products of lipid peroxidation. Two tyrosines in the active site of the enzyme have been studied with help of UV difference spectroscopy and site-directed mutagenesis. The titration curve of GST A4-4 shows a pK(a) of 6.7 attributable to tyrosine 9, which in the Y212F mutant was shifted to pK(a) 7.1. In both cases the pK(a) was independent of the absence or presence of GSH. Thus, the active-site tyrosine 9 of this isoenzyme is more than one unit more acidic than the corresponding tyrosine of other Alpha class glutathione transferases. The tyrosines remaining in the Y9F mutant titrate like free tyrosine with pK(a) values > or = 10. A mechanism involving a tyrosine-9-bound water molecule acting as a proton shuttle is proposed for the Michael additions catalyzed by GST A4-4.     

Tyrosine 8 contributes to catalysis but is not required for activity of rat liver glutathione S-transferase, 1-1.

Reaction of rat liver glutathione S-transferase, isozyme 1-1, with 4-(fluorosulfonyl)benzoic acid (4-FSB), a xenobiotic substrate analogue, results in a time-dependent inactivation of the enzyme to a final value of 35% of its original activity when assayed at pH 6.5 with 1-chloro-2,4-dinitrobenzene (CDNB) as substrate. The rate of inactivation exhibits a nonlinear dependence on the concentration of 4-FSB from 0.25 mM to 9 mM, characterized by a KI of 0.78 mM and kmax of 0.011 min-1. S-Hexylglutathione or the xenobiotic substrate analogue, 2,4-dinitrophenol, protects against inactivation of the enzyme by 4-FSB, whereas S-methylglutathione has little effect on the reaction. These experiments indicate that reaction occurs within the active site of the enzyme, probably in the binding site of the xenobiotic substrate, close to the glutathione binding site. Incorporation of [3,5-3H]-4-FSB into the enzyme in the absence and presence of S-hexylglutathione suggests that modification of one residue is responsible for the partial loss of enzyme activity. Tyr 8 and Cys 17 are shown to be the reaction targets of 4-FSB, but only Tyr 8 is protected against 4-FSB by S-hexylglutathione. DTT regenerates cysteine from the reaction product of cysteine and 4-FSB, but does not reactivate the enzyme. These results show that modification of Tyr 8 by 4-FSB causes the partial inactivation of the enzyme. The Michaelis constants for various substrates are not changed by the modification of the enzyme. The pH dependence of the enzyme-catalyzed reaction of glutathione with CDNB for the modified enzyme, as compared with the native enzyme, reveals an increase of about 0.9 in the apparent pKa, which has been interpreted as representing the ionization of enzyme-bound glutathione; however, this pKa of about 7.4 for modified enzyme remains far below the pK of 9.1 for the -SH of free glutathione. Previously, it was considered that Tyr 8 was essential for GST catalysis. In contrast, we conclude that Tyr 8 facilitates the ionization of the thiol group of glutathione bound to glutathione S-transferase, but is not required for enzyme activity.     

Site-directed mutagenesis of glutathione S-transferase YaYa. Important roles of tyrosine 9 and aspartic acid 101 in catalysis.

The roles of tyrosine 9 and aspartic acid 101 in the catalytic mechanism of rat glutathione S-transferase YaYa were studied by site-directed mutagenesis. Replacement of tyrosine 9 with phenylalanine (Y9F), threonine (Y9T), histidine (Y9H), or valine (Y9V) resulted in mutant enzymes with less than 5% catalytic activity of the wild type enzymes. Kinetic studies with purified Y9F and Y9T mutants demonstrated poor catalytic efficiencies which were largely due to a drastic decrease in kcat. The estimated pK alpha values of the sulfhydryl group of glutathione bound to Y9F and Y9T mutant enzymes were 8.5 to 8.7, similar to the chemical reaction, in contrast to the estimated pK alpha value of 6.7 to 6.8 for the glutathione enzyme complex of wild type glutathione S-transferase. These results indicate that tyrosine 9 is directly responsible for the lowering of the pKa of the sulfhydryl group of glutathione, presumably due to the stabilization of the thiolate anion through hydrogen bonding with the hydroxyl group of tyrosine. To examine the role of aspartic acid in the binding of glutathione to YaYa, 4 conserved aspartic acid residues at positions 61, 93, 101, and 157 were changed to glutamic acid and asparagine. All mutant enzymes retained either full or partial activity except D157N, which was virtually inactive. Kinetic studies with four mutant enzymes (D93E, D93N, D101E, and D101N) indicate that only D101N exhibited a 5-fold increase in Km toward glutathione. Also, the binding of this mutant to the affinity column was greatly reduced. These results demonstrate that aspartic acid 101 plays an important role in glutathione interaction to YaYa. The role of aspartic acid 157 in catalysis remains to be determined.     

The catalytic Tyr-9 of glutathione S-transferase A1-1 controls the dynamics of the C terminus

The glutathione S-transferase enzymes (GSTs) have a tyrosine or serine residue at their active site that hydrogen bonds to and stabilizes the thiolate anion of glutathione, GS(-). The importance of this hydrogen bond is obvious, in light of the enhanced nucleophilicity of GS(-) versus the protonated thiol. Several A-class GSTs contain a C-terminal segment that undergoes a ligand-dependent local folding reaction. Here, we demonstrate the effects of the Y9F substitution on binding affinity for glutathione conjugates and on rates of the order-disorder transition of the C terminus in rat GST A1-1. The equilibrium binding affinity of the glutathione conjugate, GS-NBD (NBD-Cl, 7-chloro-4-nitrobenzo-2-oxa-1, 3-diazole), was decreased from 4.09 microm to 0.641 microm upon substitution of Tyr-9 with Phe. This result was supported by isothermal titration calorimetry, with K(d) values of 1.51 microm and 0.391 microm for wild type and Y9F, respectively. The increase in binding affinity for the mutant is associated with dramatic decreases in rates for the C-terminal order-disorder transition, based on a stopped-flow kinetic analysis. The same effects were observed, qualitatively, for a second GSH conjugate, GS-ethacrynic acid. Apparently, the phenolic hydroxyl group of Tyr-9 is critical for orchestrating C-terminal dynamics and efficient product release, in addition to its role in lowering the pK(a) of GSH.     

Role of tyrosine 65 in the mechanism of serine hydroxymethyltransferase

Crystal structures of human and rabbit cytosolic serine hydroxymethyltransferase have shown that Tyr65 is likely to be a key residue in the mechanism of the enzyme. In the ternary complex of Escherichia coli serine hydroxymethyltransferase with glycine and 5-formyltetrahydrofolate, the hydroxyl of Tyr65 is one of four enzyme side chains within hydrogen-bonding distance of the carboxylate group of the substrate glycine. To probe the role of Tyr65 it was changed by site-directed mutagenesis to Phe65. The three-dimensional structure of the Y65F site mutant was determined and shown to be isomorphous with the wild-type enzyme except for the missing Tyr hydroxyl group. The kinetic properties of this mutant enzyme in catalyzing reactions with serine, glycine, allothreonine, D- and L-alanine, and 5,10-methenyltetrahydrofolate substrates were determined. The properties of the enzyme with D- and L-alanine, glycine in the absence of tetrahydrofolate, and 5, 10-methenyltetrahydrofolate were not significantly changed. However, catalytic activity was greatly decreased for serine and allothreonine cleavage and for the solvent alpha-proton exchange of glycine in the presence of tetrahydrofolate. The decreased catalytic activity for these reactions could be explained by a greater than 2 orders of magnitude increase in affinity of Y65F mutant serine hydroxymethyltransferase for these amino acids bound as the external aldimine. These data are consistent with a role for the Tyr65 hydroxyl group in the conversion of a closed active site to an open structure.     

Mannitol-1-phosphate dehydrogenase of Escherichia coli. Chemical properties and binding of substrates.

Mannitol-1-phosphate dehydrogenase was purified to homogeneity, and some chemical and physical properties were examined. The isoelectric point is 4.19. Amino acid analysis and polyacrylamide-gel electrophoresis in presence of SDS indicate a subunit Mr of about 22,000, whereas gel filtration and electrophoresis of the native enzyme indicate an Mr of 45,000. Thus the enzyme is a dimer. Amino acid analysis showed cysteine, tyrosine, histidine and tryptophan to be present in low quantities, one, three, four and four residues per subunit respectively. The zinc content is not significant to activity. The enzyme is inactivated (greater than 99%) by reaction of 5,5'-dithiobis-(2-nitrobenzoate) with the single thiol group; the inactivation rate depends hyperbolically on reagent concentration, indicating non-covalent binding of the reagent before covalent modification. The pH-dependence indicated a pKa greater than 10.5 for the thiol group. Coenzymes (NAD+ and NADH) at saturating concentrations protect completely against reaction with 5,5'-dithiobis-(2-nitrobenzoate), and substrates (mannitol 1-phosphate, fructose 6-phosphate) protect strongly but not completely. These results suggest that the thiol group is near the catalytic site, and indicate that substrates as well as coenzymes bind to free enzyme. Dissociation constants were determined from these protective effects: 0.6 +/- 0.1 microM for NADH, 0.2 +/- 0.03 mM for NAD+, 9 +/- 3 microM for mannitol 1-phosphate, 0.06 +/- 0.03 mM for fructose 6-phosphate. The binding order for reaction thus may be random for mannitol 1-phosphate oxidation, though ordered for fructose 6-phosphate reduction. Coenzyme and substrate binding in the E X NADH-mannitol 1-phosphate complex is weaker than in the binary complexes, though in the E X NADH+-fructose 6-phosphate complex binding is stronger.