Specific recognition between YTHDF3 and m6A‐modified RNA: An all‐atom molecular dynamics simulation study

Wenxue Zhou, Zhongjie Han, Zhixiang Wu, Weikang Gong, Shuang Yang, Lei Chen, Chunhua Li
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引用次数: 3

Abstract

The YTH domain of YTHDF3 belongs to a class of protein “readers” recognizing the N6‐methyladenosine (m6A) modification in mRNA. Although static crystal structure reveals m6A recognition by a conserved aromatic cage, the dynamic process in recognition and importance of aromatic cage residues are not completely clear. Here, molecular dynamics (MD) simulations are performed to explore the issues and negative selectivity of YTHDF3 toward unmethylated substrate. Our results reveal that there exist conformation selectivity and induced‐fit in YTHDF3 binding with m6A‐modified RNA, where recognition loop and loop6 play important roles in the specific recognition. m6A modification enhances the stability of YTHDF3 in complex with RNA. The methyl group of m6A, like a warhead, enters into the aromatic cage of YTHDF3, where Trp492 anchors the methyl group and constraints m6A, making m6A further stabilized by π–π stacking interactions from Trp438 and Trp497. In addition, the methylation enhances the hydrophobicity of adenosine, facilitating water molecules excluded out of the aromatic cage, which is another reason for the specific recognition and stronger intermolecular interaction. Finally, the comparative analyses of hydrogen bonds and binding free energy between the methylated and unmethylated complexes reveal the physical basis for the preferred recognition of m6A‐modified RNA by YTHDF3. This study sheds light on the mechanism by which YTHDF3 specifically recognizes m6A‐modified RNA and can provide important information for structure‐based drug design.
YTHDF3和m6A修饰RNA的特异性识别:全原子分子动力学模拟研究
YTHDF3的YTH结构域属于一类识别mRNA中N6‐甲基腺苷(m6A)修饰的蛋白质“读者”。虽然静态晶体结构揭示了保守芳香笼对m6A的识别,但芳香笼残基识别的动态过程和重要性尚不完全清楚。本文通过分子动力学(MD)模拟来探讨YTHDF3对未甲基化底物的负选择性。结果表明,YTHDF3与m6A修饰的RNA结合存在构象选择性和诱导拟合,其中识别环和loop6在特异性识别中起重要作用。m6A修饰增强了YTHDF3与RNA复合物的稳定性。m6A的甲基像弹头一样进入YTHDF3的芳香笼中,Trp492锚定甲基并约束m6A,通过Trp438和Trp497的π -π堆叠相互作用使m6A进一步稳定。此外,甲基化增强了腺苷的疏水性,有利于将水分子排除在芳香笼外,这也是腺苷具有特异性识别和更强分子间相互作用的另一个原因。最后,通过对比分析甲基化和未甲基化复合物之间的氢键和结合自由能,揭示了YTHDF3优先识别m6A修饰RNA的物理基础。该研究揭示了YTHDF3特异性识别m6A修饰RNA的机制,并可为基于结构的药物设计提供重要信息。
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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