Patskovsky Y V, Patskovska L N, Listowsky I
Department of Biochemistry, Albert Einstein College of Medicine, Bronx, New York 10461, USA.
J Biol Chem. 2000 Feb 4;275(5):3296-304. doi: 10.1074/jbc.275.5.3296.
A series of chimeric human Mu class glutathione S-transferases were designed to determine mechanisms by which they activate enzyme-bound glutathione (GSH) for reaction with electrophilic substrates. In view of evidence that the His(107) residue of hGSTM1a-1a is important for catalysis (Patskovsky, Y. V., Patskovska, L. N., and Listowsky, I. (1999) Biochemistry 38, 1193-1202), the cognate Arg(107) residue of the hGSTM2 subunit was replaced (R107N or R107H) and arginine residues were also incorporated into position 107 of hGSTM1 (H107R) and hGSTM4 (S107R) subunits. The major distinguishing kinetic properties invariably associated with enzymes containing an Arg(107) residue include an inverse dependence of k(cat) on viscosity and lower K(m(GSH values relative to enzymes with other residues at that position. Moreover, affinities for GSH thiolate anion binding are greater for enzymes containing Arg(107))), with K(d) values of 20-50 microM that are consistent with the K(m(GSH values (10-25 microM) obtained by steady-state kinetic analyses. Both thermodynamic and kinetic and data indicate that the Arg(107))) residue is specifically involved in enhancing the binding affinity of GSH thiolate anion relative to that of the protonated form. These enzymes therefore, can be more effective at lower GSH concentrations. Combined mutations indicate that both Arg(107) and Tyr(6) residues are required for thiolate anion formation and stabilization. The three-dimensional structure of ligand-free hGSTM2-2 determined by x-ray crystallography suggests that Arg(107) maintains an electrostatic interaction with the Asp(161) side chain (3 A apart), but is distant from the GSH-binding site. However, an alternative energetically favorable model places the guanidino group 4 A from the sulfur atom of bound GSH. It is suggested therefore, that in solution, motion of the positively charged arginine into the catalytic pocket could provide a counter ion to promote ionization of the sulfhydryl group of GSH, thereby accounting for the observed greater affinity of enzymes containing Arg(107) for binding of thiolate anion.
设计了一系列嵌合人μ类谷胱甘肽S-转移酶,以确定它们激活酶结合的谷胱甘肽(GSH)与亲电底物反应的机制。鉴于有证据表明hGSTM1a-1a的His(107)残基对催化很重要(Patskovsky, Y. V., Patskovska, L. N., and Listowsky, I. (1999) Biochemistry 38, 1193-1202),将hGSTM2亚基的同源Arg(107)残基替换(R107N或R107H),并将精氨酸残基也引入hGSTM1(H107R)和hGSTM4(S107R)亚基的第107位。与含有Arg(107)残基的酶始终相关的主要区别动力学性质包括k(cat)对粘度的反比依赖性以及相对于该位置具有其他残基的酶更低的K(m(GSH)值。此外,含有Arg(107))的酶对GSH硫醇盐阴离子结合的亲和力更高,K(d)值为20 - 50 microM,与通过稳态动力学分析获得的K(m(GSH)值(10 - 25 microM)一致。热力学和动力学数据均表明,Arg(107))残基特别参与增强GSH硫醇盐阴离子相对于质子化形式的结合亲和力。因此,这些酶在较低GSH浓度下可能更有效。组合突变表明,Arg(107)和Tyr(6)残基对于硫醇盐阴离子的形成和稳定都是必需的。通过X射线晶体学确定的无配体hGSTM2-2的三维结构表明,Arg(107)与Asp(161)侧链保持静电相互作用(相距3 Å),但远离GSH结合位点。然而,另一个能量有利的模型将胍基置于距结合的GSH硫原子4 Å处。因此,有人提出,在溶液中,带正电的精氨酸向催化口袋的移动可以提供一个抗衡离子,以促进GSH巯基的电离,从而解释了观察到的含有Arg(107)的酶对硫醇盐阴离子结合的更高亲和力。
