VIB Department of Structural Biology, Vrije Universiteit Brussel, Brussels, Belgium.
IUBMB Life. 2012 Jun;64(6):513-20. doi: 10.1002/iub.1034. Epub 2012 Apr 25.
Proteins containing intrinsically disordered (ID) regions are widespread in eukaryotic organisms and are mostly utilized in regulatory processes. ID regions can mediate binary interactions of proteins or promote organization of large assemblies. Post-translational modifications of ID regions often serve as decision points in signaling pathways. Why Nature distinguished ID proteins in molecular recognition functions? In a simple view, binding of ID regions is accompanied by a large entropic penalty as compared to folded proteins. Even in complexes however, ID regions can preserve their conformational freedom, thereby recruit further partners and perform various functions. What sort of benefits ID regions offer for molecular interactions and which properties are exploited in the corresponding complexes? Here, we review models explaining the recognition mechanisms of ID proteins. Motif-based interactions are central to all proposed scenarios, including prestructured elements, anchoring sites and linear motifs. We aim to extract consensus features of the models, which could be used to predict ID-binding sites for a variety of partners.
富含无规则(ID)区域的蛋白质在真核生物中广泛存在,主要用于调控过程。ID 区域可以介导蛋白质的二元相互作用或促进大型组装体的组织。ID 区域的翻译后修饰通常作为信号通路中的决策点。大自然为什么要在分子识别功能中区分 ID 蛋白?从简单的角度来看,与折叠蛋白相比,ID 区域的结合伴随着较大的熵罚。然而,即使在复合物中,ID 区域也可以保持其构象自由度,从而招募更多的伴侣并发挥各种功能。ID 区域为分子相互作用提供了哪些好处,以及相应的复合物利用了哪些特性?在这里,我们综述了解释 ID 蛋白识别机制的模型。基于模体的相互作用是所有提出的方案的核心,包括预结构化元件、锚定位点和线性模体。我们旨在提取模型的共识特征,这些特征可用于预测各种伴侣的 ID 结合位点。
