Cell cycle-dependent phosphorylation of nucleophosmin and its potential regulation by peptidyl-prolyl cis/trans isomerase.

Journal of molecular biochemistry Pub Date : 2015-11-25

Xuelian Zhao, Junfang Ji, Li-Rong Yu, Timothy Veenstra, Xin Wei Wang

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Abstract

Nucleophosmin (NPM) is a ubiquitously expressed phosphoprotein involved in many cellular processes. Phosphorylation is considered the major regulatory mechanism of the NPM protein, associated with diverse cellular events. In this study, we characterized the phosphorylation status of several physiological phosphorylation sites of NPM, especially the newly confirmed in vivo site threonine 95 (Thr95). NPM-Thr95 exhibits a transient and cell cycle-dependent phosphorylation state compared to several other in vivo phosphorylation sites examined, including Ser4, Thr199 and Thr234/Thr237. In addition, we characterized a functional interaction between NPM and the peptidyl-prolyl isomerase Pin1, which specifically bind to each other during mitosis. The demonstration of this binding represents a novel post-phosphorylation regulatory mechanism for NPM that has not been investigated before. Mutated Pin1 putative binding sites result in defected cell division and reduced number of mitotic cells, suggesting that post-phosphorylation is important for NPM in regulating cell cycle progression.

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核磷蛋白细胞周期依赖性磷酸化及其可能受到肽基脯氨酸顺/反异构酶的调控。

核磷蛋白(nuclear ophosmin, NPM)是一种普遍表达的磷酸化蛋白，参与许多细胞过程。磷酸化被认为是NPM蛋白的主要调控机制，与多种细胞事件相关。在本研究中，我们表征了NPM的几个生理磷酸化位点的磷酸化状态，特别是新确认的体内位点苏氨酸95 (Thr95)。与其他几个体内磷酸化位点(包括Ser4、Thr199和Thr234/Thr237)相比，NPM-Thr95表现出短暂的和细胞周期依赖的磷酸化状态。此外，我们还描述了NPM与肽基脯氨酸异构酶Pin1之间的功能相互作用，它们在有丝分裂期间特异性地相互结合。这种结合的证明代表了一种新的NPM磷酸化后调节机制，这在以前没有被研究过。Pin1结合位点突变导致细胞分裂缺陷和有丝分裂细胞数量减少，表明后磷酸化在NPM调节细胞周期进程中很重要。

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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Journal of molecular biochemistry

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6 weeks