Ewa Rejnowicz, Matthew Batchelor, Eoin Leen, Mohd Syed Ahangar, Selena G Burgess, Mark W Richards, Arnout P Kalverda, Richard Bayliss
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These regions also have more restricted ps-ns motions than the rest of the TAD, and, along with the phosphodegron, have comparatively high transverse (R2) 15N relaxation rates, indicative of slower timescale dynamics and/or chemical exchange. Collectively these features suggest differential propensities for structure and interaction, either internal or with binding partners, across the TAD. Solution studies on the interaction between N-myc and Aurora-A revealed a previously uncharacterised binding site. The specificity and kinetics of sequential phosphorylation of N-myc by ERK1 and GSK3 were characterised using NMR and resulted in no significant structural changes outside the phosphodegron. When the phosphodegron was doubly phosphorylated, N-myc formed a robust interaction with the Fbxw7-Skp1 complex, but mapping the interaction by NMR suggests a more extensive interface. 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引用次数: 0
摘要
Myc 蛋白是对细胞增殖至关重要的转录因子。它们有一个介导 Max 和 DNA 结合的 C 端结构域,以及一个 N 端无序区,最终形成转录激活结构域(TAD)。TAD 参与了许多蛋白质与蛋白质之间的相互作用,特别是与通过泛素蛋白酶体系统促进稳定性(Aurora-A)或降解(ERK1、GSK3)的激酶的相互作用。我们利用核磁共振(NMR)光谱对 N-myc TAD 的结构、动力学和相互作用进行了探究,并对其骨架进行了完整的分配。化学位移分析表明,N-myc 有两个具有明显螺旋倾向的区域:Trp77-Glu86 和 Ala122-Glu132。与 TAD 的其他部分相比,这些区域的 ps-ns 运动也更受限制,而且与磷酸二聚体一起,具有相对较高的横向 (R2) 15N 松弛率,这表明时间尺度动力学和/或化学交换较慢。总之,这些特征表明整个 TAD 内部或与结合伙伴的结构和相互作用具有不同的倾向性。对 N-myc 和 Aurora-A 之间相互作用的溶液研究发现了一个以前未曾描述过的结合位点。利用核磁共振分析了 ERK1 和 GSK3 对 N-myc 顺序磷酸化的特异性和动力学特征,结果表明磷酸二聚体之外的结构没有发生显著变化。当磷酸化二聚体被双重磷酸化时,N-myc与Fbxw7-Skp1复合物形成了强有力的相互作用,但核磁共振绘制的相互作用图显示了一个更广泛的界面。我们的研究提供了有关 N-myc TAD 动力学和骨架分配的基本见解,这将为今后研究这种关键肿瘤蛋白的结构、动力学、相互作用和翻译后修饰调控提供基础。
Exploring the dynamics and interactions of the N-myc transactivation domain through solution nuclear magnetic resonance spectroscopy.
Myc proteins are transcription factors crucial for cell proliferation. They have a C-terminal domain that mediates Max and DNA binding, and an N-terminal disordered region culminating in the transactivation domain (TAD). The TAD participates in many protein-protein interactions, notably with kinases that promote stability (Aurora-A) or degradation (ERK1, GSK3) via the ubiquitin-proteasome system. We probed the structure, dynamics and interactions of N-myc TAD using nuclear magnetic resonance (NMR) spectroscopy following its complete backbone assignment. Chemical shift analysis revealed that N-myc has two regions with clear helical propensity: Trp77-Glu86 and Ala122-Glu132. These regions also have more restricted ps-ns motions than the rest of the TAD, and, along with the phosphodegron, have comparatively high transverse (R2) 15N relaxation rates, indicative of slower timescale dynamics and/or chemical exchange. Collectively these features suggest differential propensities for structure and interaction, either internal or with binding partners, across the TAD. Solution studies on the interaction between N-myc and Aurora-A revealed a previously uncharacterised binding site. The specificity and kinetics of sequential phosphorylation of N-myc by ERK1 and GSK3 were characterised using NMR and resulted in no significant structural changes outside the phosphodegron. When the phosphodegron was doubly phosphorylated, N-myc formed a robust interaction with the Fbxw7-Skp1 complex, but mapping the interaction by NMR suggests a more extensive interface. Our study provides foundational insights into N-myc TAD dynamics and a backbone assignment that will underpin future work on the structure, dynamics, interactions and regulatory post-translational modifications of this key oncoprotein.
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Exploring the molecular mechanisms that underpin key biological processes, the Biochemical Journal is a leading bioscience journal publishing high-impact scientific research papers and reviews on the latest advances and new mechanistic concepts in the fields of biochemistry, cellular biosciences and molecular biology.
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