STAT5B SH2 结构域中致癌驱动突变 N642H 的结构影响

Liam Haas-Neill, Deniz Meneksedag-Erol, Ayesha Chaudhry, Masha Novoselova, Qirat F. Ashraf, Elvin D. de Araujo, Derek J. Wilson, Sarah Rauscher
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引用次数: 0

摘要

信号转导和激活转录 5B(STAT5B)蛋白的点突变 N642H 与侵袭性和耐药性白血病有关。这种突变被认为是由于活性平行二聚体状态的稳定性增加导致 STAT5B 的过度激活而诱发癌症。然而,由于目前还没有平行二聚体的结构,导致这种稳定的分子机制还不十分清楚。为了研究该突变的作用机制,我们对 STAT5B 和 STAT5B(N642H)的多种低聚物形式(包括平行二聚体模型)进行了广泛的全原子分子动力学模拟。N642H 突变直接影响了平行二聚体磷酸酪氨酸(PY)结合口袋内的氢键网络,增强了PY结合相互作用。模拟结果表明,apo STAT5B 具有高度灵活性,可以探索多种构象空间。相比之下,apo STAT5B(N642H)可进入两种不同的构象状态,其中一种类似于平行二聚体的构象。对 STAT5B 和 STAT5B(N642H)进行的氢氘交换(HDX)质谱测量结果支持了关于突变对结构和动力学影响的模拟预测,其中使用了磷酸肽来模拟平行二聚化对 SH2 结构域的影响。这项工作揭示的分子水平信息有助于我们了解 STAT5B 因 N642H 突变而过度激活的情况,并有助于为针对这种突变的新型治疗策略铺平道路。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
The structural influence of the oncogenic driver mutation N642H in the STAT5B SH2 domain
The point mutation N642H of the signal transducer and activator of transcription 5B (STAT5B) protein is associated with aggressive and drug-resistant forms of leukemia. This mutation is thought to promote cancer due to hyperactivation of STAT5B caused by increased stability of the active, parallel dimer state. However, the molecular mechanism leading to this stabilization is not well understood as there is currently no structure of the parallel dimer. To investigate the mutation's mechanism of action, we conducted extensive all-atom molecular dynamics simulations of multiple oligomeric forms of both STAT5B and STAT5B(N642H), including a model for the parallel dimer. The N642H mutation directly affects the hydrogen bonding network within the phosphotyrosine (pY)-binding pocket of the parallel dimer, enhancing the pY-binding interaction. The simulations indicate that apo STAT5B is highly flexible, exploring a diverse conformational space. In contrast, apo STAT5B(N642H) accesses two distinct conformational states, one of which resembles the conformation of the parallel dimer. The simulation predictions of the effects of the mutation on structure and dynamics are supported by the results of hydrogen-deuterium exchange (HDX) mass spectrometry measurements carried out on STAT5B and STAT5B(N642H) in which a phosphopeptide was used to mimic the effects of parallel dimerization on the SH2 domain. The molecular-level information uncovered in this work contributes to our understanding of STAT5B hyperactivation by the N642H mutation and could help pave the way for novel therapeutic strategies targeting this mutation.
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