Department of Chemistry and Open Laboratory of Chemical Biology, University of Hong Kong, Pokfulam Road, Hong Kong, China.
Proc Natl Acad Sci U S A. 2010 Mar 16;107(11):4943-8. doi: 10.1073/pnas.0913970107. Epub 2010 Mar 1.
GroES is an indispensable chaperonin virtually found throughout all life forms. Consequently, mutations of this protein must be critically scrutinized by natural selection. Nevertheless, the homolog from a potentially virulent gastric pathogen, Helicobacter pylori, strikingly features a histidine/cysteine-rich C terminus that shares no significant homology with other family members. Additionally, three more (H45, C51, and C53) are uniquely present in its apical domain. The statistical analyses show that these residues may have originated from negative selection, presumably driven by either dependent or independent amino acid mutations. In the absence of the C-terminal metal-binding domain, the mutant protein still exhibits a substantial capacity for zinc binding in vivo. The biochemical properties of site-directed mutants indicate that H45, C51, and C53 make up an oxidation-sensitive zinc-binding site that may donate the bound metal to a zinc acceptor. Of interest, bismuth antiulcer drugs strongly bind at this site (K(d) of approximately 7 x 10(-26) M), replacing the bound zinc and consequently inducing the disruption of the quaternary structure. Because biological features by negative selection are usually inert to change during evolution, this study sheds light on a promising field whereby medicines can be designed or improved to specifically target the residues that uniquely evolved in pathogenic proteins so as to retard the emergence of drug resistance.
GroES 是一种不可或缺的伴侣蛋白,几乎存在于所有生命形式中。因此,这种蛋白质的突变必须受到自然选择的严格审查。然而,来自潜在毒性胃病原体幽门螺杆菌的同源物具有一个显著的富含组氨酸/半胱氨酸的 C 末端,与其他家族成员没有显著的同源性。此外,还有另外三个(H45、C51 和 C53)仅存在于其顶端结构域中。统计分析表明,这些残基可能来自负选择,可能是由依赖或独立的氨基酸突变驱动的。在缺乏 C 末端金属结合结构域的情况下,突变蛋白在体内仍然表现出对锌的大量结合能力。定点突变体的生化特性表明,H45、C51 和 C53 构成了一个氧化敏感的锌结合位点,可能将结合的金属捐赠给锌受体。有趣的是,铋抗溃疡药物强烈结合在这个位点(K(d)约为 7 x 10(-26) M),取代了结合的锌,从而导致四级结构的破坏。由于负选择的生物学特征在进化过程中通常不会发生变化,因此这项研究为一个有前途的领域提供了启示,即可以设计或改进药物,以专门针对在致病蛋白中独特进化的残基,从而延缓耐药性的出现。