PIM-1L Kinase Binds to and Inactivates SRPK1: A Biochemical and Molecular Dynamics Study.

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC ACS Applied Electronic Materials Pub Date : 2024-10-27 DOI:10.1002/prot.26757
Nastazia Lesgidou, Anastasia Koukiali, Eleni Nikolakaki, Thomas Giannakouros, Metaxia Vlassi
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Abstract

SR/RS dipeptide repeats vary in both length and position, and are phosphorylated by SR protein kinases (SRPKs). PIM-1L, the long isoform of PIM-1 kinase, the splicing of which has been implicated in acute myeloid leukemia, contains a domain that consists largely of repeating SR/RS and SH/HS dipeptides (SR/SH-rich). In order to extend our knowledge on the specificity and cellular functions of SRPK1, here we investigate whether PIM-1L could act as substrate of SRPK1 by a combination of biochemical and computational approaches. Our biochemical data showed that the SR/SH-rich domain of PIM-1L was able to associate with SRPK1, yet it could not act as a substrate but, instead, inactivated the kinase. In line with our biochemical data, molecular modeling followed by a microsecond-scale all-atom molecular dynamics (MD) simulation suggests that the SR/SH-rich domain acts as a pseudo-docking peptide that binds to the same acidic docking-groove used in other SRPK1 interactions and induces inactive SRPK1 conformations. Comparative community network analysis of the MD trajectories, unraveled the dynamic architecture of apo SRPK1 and notable alterations of allosteric communications upon PIM-1L peptide binding. This analysis also allowed us to identify key SRPK1 residues, including unique ones, with a pivotal role in mediating allosteric signal propagation within the kinase core. Interestingly, most of the identified amino acids correspond to cancer-associated amino acid changes, validating our results. In total, this work provides insights not only on the details of SRPK1 inhibition by the PIM-1L SR/SH-domain, but also contributes to an in-depth understanding of SRPK1 regulation.

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PIM-1L 激酶与 SRPK1 结合并使其失活:一项生物化学和分子动力学研究。
SR/RS 二肽重复序列的长度和位置各不相同,并被 SR 蛋白激酶(SRPKs)磷酸化。PIM-1L是PIM-1激酶的长异构体,其剪接与急性髓性白血病有关,它含有一个主要由重复的SR/RS和SH/HS二肽(富含SR/SH)组成的结构域。为了扩展我们对 SRPK1 特异性和细胞功能的认识,我们在此通过生化和计算相结合的方法研究 PIM-1L 能否作为 SRPK1 的底物。我们的生化数据显示,PIM-1L的富含SR/SH的结构域能够与SRPK1结合,但它不能作为底物,反而会使激酶失活。与我们的生化数据相一致,分子建模后的微秒级全原子分子动力学(MD)模拟表明,富含 SR/SH 的结构域是一种伪对接肽,它与其他 SRPK1 相互作用中使用的酸性对接沟槽结合,并诱导 SRPK1 的非活性构象。对 MD 轨迹的群落网络比较分析揭示了 apo SRPK1 的动态结构,以及 PIM-1L 肽结合后异构通讯的显著变化。这项分析还让我们确定了关键的 SRPK1 残基,包括在激酶核心内介导异构信号传播中起关键作用的独特残基。有趣的是,大多数被鉴定的氨基酸都与癌症相关的氨基酸变化相对应,这验证了我们的研究结果。总之,这项工作不仅深入揭示了 PIM-1L SR/SH 域抑制 SRPK1 的细节,而且有助于深入理解 SRPK1 的调控。
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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CiteScore
7.20
自引率
4.30%
发文量
567
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