Charge block-driven liquid-liquid phase separation: A mechanism of how phosphorylation regulates phase behavior of disordered proteins.

IF 1.6 Q4 BIOPHYSICS Biophysics and physicobiology Pub Date : 2024-03-28 eCollection Date: 2024-01-01 DOI:10.2142/biophysico.bppb-v21.0012
Hisashi Shimamura, Hiroya Yamazaki, Shige H Yoshimura
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Abstract

Phosphorylation regulates protein function by modulating stereospecific interactions between protein-protein or enzyme-ligand. On the other hand, many bioinformatics studies have demonstrated that phosphorylation preferably occurs in intrinsically disordered regions (IDRs), which do not have any secondary and tertiary structures. Although studies have demonstrated that phosphorylation changes the phase behavior of IDRs, the mechanism, which is distinct from the "stereospecific" effect, had not been elucidated. Here, we describe how phosphorylation in IDRs regulates the protein function by modulating phase behavior. Mitotic phosphorylation in the IDRs of Ki-67 and NPM1 promotes or suppresses liquid-liquid phase separation, respectively, by altering the "charge blockiness" along the polypeptide chain. The phosphorylation-mediated regulation of liquid-liquid phase separation by enhancing or suppressing "charge blockiness," rather than by modulating stereospecific interactions, may provide one of the general mechanisms of protein regulation by posttranslational modifications and the role of multiple phosphorylations.

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电荷块驱动的液-液相分离:磷酸化如何调节无序蛋白质相行为的机制
磷酸化通过调节蛋白质-蛋白质或酶-配体之间的立体特异性相互作用来调节蛋白质的功能。另一方面,许多生物信息学研究表明,磷酸化最好发生在没有任何二级和三级结构的内在无序区(IDRs)。尽管研究表明磷酸化会改变 IDR 的相行为,但其机制与 "立体特异性 "效应不同,尚未得到阐明。在这里,我们描述了 IDRs 中的磷酸化是如何通过调节相位行为来调节蛋白质功能的。Ki-67 和 NPM1 的 IDR 中的有丝分裂磷酸化通过改变多肽链上的 "电荷阻塞性",分别促进或抑制液-液相分离。磷酸化介导的通过增强或抑制 "电荷阻滞性 "而不是通过调节立体特异性相互作用来调节液-液相分离的过程,可能提供了通过翻译后修饰和多重磷酸化作用来调节蛋白质的一般机制之一。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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