Taurog Rebecca E, Jakubowski Hieronim, Matthews Rowena G
Department of Biological Chemistry, The University of Michigan, Ann Arbor, Michigan 48109-1055, USA.
Biochemistry. 2006 Apr 25;45(16):5083-91. doi: 10.1021/bi060051u.
Cobalamin-independent methionine synthase (MetE) catalyzes the transfer of the N5-methyl group of methyltetrahydrofolate (CH(3)-H(4)folate) to the sulfur of homocysteine (Hcy) to form methionine and tetrahydrofolate (H(4)folate) as products. This reaction is thought to involve a direct methyl transfer from one substrate to the other, requiring the two substrates to interact in a ternary complex. The crystal structure of a MetE.CH(3)-H(4)folate binary complex shows that the methyl group is pointing away from the Hcy binding site and is quite distant from the position where the sulfur of Hcy would be, raising the possibility that this binary complex is nonproductive. The CH(3)-H(4)folate must either rearrange or dissociate before methyl transfer can occur. Therefore, determining the order of substrate binding is of interest. We have used kinetic and equilibrium measurements in addition to isotope trapping experiments to elucidate the kinetic pathway of substrate binding in MetE. These studies demonstrate that both substrate binary complexes are chemically and kinetically competent for methyl transfer and suggest that the conformation observed in the crystal structure is indeed on-pathway. Additionally, the substrates are shown to bind synergistically, with each substrate binding 30-fold more tightly in the presence of the other. Methyl transfer has been determined to be slow compared to ternary complex formation and dissociation. Simulations indicate that nearly all of the enzyme is present as the ternary complex under physiological conditions.
不依赖钴胺素的蛋氨酸合酶(MetE)催化甲基四氢叶酸(CH(3)-H(4)叶酸)的N5-甲基基团转移至同型半胱氨酸(Hcy)的硫原子上,生成蛋氨酸和四氢叶酸(H(4)叶酸)作为产物。该反应被认为涉及从一种底物到另一种底物的直接甲基转移,这要求两种底物在三元复合物中相互作用。MetE.CH(3)-H(4)叶酸二元复合物的晶体结构表明,甲基基团远离Hcy结合位点,且与Hcy硫原子所在位置相距甚远,这增加了该二元复合物无活性的可能性。在甲基转移发生之前,CH(3)-H(4)叶酸必须重新排列或解离。因此,确定底物结合的顺序很有意义。我们除了进行同位素捕获实验外,还使用了动力学和平衡测量来阐明MetE中底物结合的动力学途径。这些研究表明,两种底物二元复合物在化学和动力学上都能够进行甲基转移,并表明晶体结构中观察到的构象确实处于反应途径上。此外,底物表现出协同结合,在另一种底物存在的情况下,每种底物的结合亲和力提高30倍。与三元复合物的形成和解离相比,甲基转移已被确定为较慢。模拟表明,在生理条件下,几乎所有的酶都以三元复合物的形式存在。