生物素化
链霉亲和素
四聚体
二聚体
化学
单体
四级结构
生物素
生物物理学
立体化学
生物化学
生物
酶
有机化学
蛋白质亚单位
基因
聚合物
作者
Kok Hong Lim,Heng Huang,Arnd Pralle,Sheldon Park
出处
期刊:Biochemistry
[American Chemical Society]
日期:2011-09-06
卷期号:50 (40): 8682-8691
被引量:62
摘要
Although streptavidin’s high affinity for biotin has made it a widely used and studied binding protein and labeling tool, its tetrameric structure may interfere with some assays. A streptavidin mutant with a simpler quaternary structure would demonstrate a molecular-level understanding of its structural organization and lead to the development of a novel molecular reagent. However, modulating the tetrameric structure without disrupting biotin binding has been extremely difficult. In this study, we describe the design of a stable monomer that binds biotin both in vitro and in vivo. To this end, we constructed and characterized monomers containing rationally designed mutations. The mutations improved the stability of the monomer (increase in Tm from 31 to 47 °C) as well as its affinity (increase in Kd from 123 to 38 nM). We also used the stability-improved monomer to construct a dimer consisting of two streptavidin subunits that interact across the dimer–dimer interface, which we call the A/D dimer. The biotin binding pocket is conserved between the tetramer and the A/D dimer, and therefore, the dimer is expected to have a significantly higher affinity than the monomer. The affinity of the dimer (Kd = 17 nM) is higher than that of the monomer but is still many orders of magnitude lower than that of the wild-type tetramer, which suggests there are other factors important for high-affinity biotin binding. We show that the engineered streptavidin monomer and dimer can selectively bind biotinylated targets in vivo by labeling the cells displaying biotinylated receptors. Therefore, the designed mutants may be useful in novel applications as well as in future studies in elucidating the role of oligomerization in streptavidin function.
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