人工金属蛋白的晶体结构：通过将脱辅基肌红蛋白中的丙氨酸71突变为甘氨酸实现FeIII（席夫碱）的紧密结合。

Crystal structures of artificial metalloproteins: tight binding of FeIII(Schiff-Base) by mutation of Ala71 to Gly in apo-myoglobin.

作者信息

Ueno Takafumi, Ohashi Masataka, Kono Masaharu, Kondo Kazuyoshi, Suzuki Atsuo, Yamane Takashi, Watanabe Yoshihito

机构信息

Research Center for Materials Science, Nagoya University, Nagoya 464-8602, Japan.

出版信息

Inorg Chem. 2004 May 3;43(9):2852-8. doi: 10.1021/ic0498539.

DOI:10.1021/ic0498539

PMID:15106972

Abstract

Apo-myoglobin (apo-Mb) and apo-A71GMb were successfully reconstituted with FeIII(salophen) (1) (salophen = N,N'-bis(salicylidene)-1,2-phenilenediamine), Fe(III)(3,3'-Me2-salophen) (2), and FeIII(5,5'-t-Bu2-salophen) (3). The crystal structure of 2.apo-A71GMb shows the tight binding of the complex in the Mb cavity, while in wild-type apo-Mb it is highly disordered due to the steric repulsion with Ala71. Furthermore, the structure of 2.apo-A71GMb suggests a possible accommodation of a small substrate in the cavity. In fact, the cyanide association rate constant of 2.apo-A71GMb is 216-fold larger compared to that of 2.apo-Mb. These results provide us principles for the noncovalent fixation of synthetic metal cofactors at the desired positions in protein matrixes.

摘要

脱辅基肌红蛋白（apo-Mb）和脱辅基A71G肌红蛋白（apo-A71GMb）已成功地与FeIII（邻苯二酚）（1）（邻苯二酚=N，N'-双（水杨醛）-1,2-苯二胺）、Fe(III)(3,3'-二甲基邻苯二酚)（2）和FeIII(5,5'-二叔丁基邻苯二酚)（3）进行了重组。2.apo-A71GMb的晶体结构表明该配合物在肌红蛋白腔内紧密结合，而在野生型脱辅基肌红蛋白中，由于与Ala71的空间排斥作用，它高度无序。此外，2.apo-A71GMb的结构表明腔内可能容纳一个小的底物。事实上，2.apo-A71GMb的氰化物缔合速率常数比2.apo-Mb的大216倍。这些结果为我们在蛋白质基质中所需位置非共价固定合成金属辅因子提供了原理。

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人工金属蛋白的晶体结构：通过将脱辅基肌红蛋白中的丙氨酸71突变为甘氨酸实现FeIII（席夫碱）的紧密结合。

Crystal structures of artificial metalloproteins: tight binding of FeIII(Schiff-Base) by mutation of Ala71 to Gly in apo-myoglobin.

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