DHX36 特异性基序 (DSM) 通过加速募集 DNA G-四链体结构来提高特异性。

The DHX36-specific-motif (DSM) enhances specificity by accelerating recruitment of DNA G-quadruplex structures.

机构信息

Department of Molecular Biosciences, The University of Texas at Austin, Austin, TX78712, USA.

Department of Biology, Stanford University, Stanford, CA94305, USA.

出版信息

Biol Chem. 2020 Dec 16;402(5):593-604. doi: 10.1515/hsz-2020-0302. Print 2021 Apr 27.

DOI:10.1515/hsz-2020-0302

PMID:33857359

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8054968/

Abstract

DHX36 is a eukaryotic DEAH/RHA family helicase that disrupts G-quadruplex structures (G4s) with high specificity, contributing to regulatory roles of G4s. Here we used a DHX36 truncation to examine the roles of the 13-amino acid DHX36-specific motif (DSM) in DNA G4 recognition and disruption. We found that the DSM promotes G4 recognition and specificity by increasing the G4 binding rate of DHX36 without affecting the dissociation rate. Further, for most of the G4s measured, the DSM has little or no effect on the G4 disruption step by DHX36, implying that contacts with the G4 are maintained through the transition state for G4 disruption. This result suggests that partial disruption of the G4 from the 3' end is sufficient to reach the overall transition state for G4 disruption, while the DSM remains unperturbed at the 5' end. Interestingly, the DSM does not contribute to G4 binding kinetics or thermodynamics at low temperature, indicating a highly modular function. Together, our results animate recent DHX36 crystal structures, suggesting a model in which the DSM recruits G4s in a modular and flexible manner by contacting the 5' face early in binding, prior to rate-limiting capture and disruption of the G4 by the helicase core.

摘要

DHX36 是一种真核 DEAH/RHA 家族解旋酶，能高度特异性地破坏 G-四链体结构 (G4s)，从而发挥 G4s 的调控作用。在此，我们利用 DHX36 的截断体来研究 13 个氨基酸的 DHX36 特异性基序 (DSM) 在 DNA G4 识别和破坏中的作用。我们发现，DSM 通过提高 DHX36 与 G4 的结合速率而促进 G4 的识别和特异性，而不影响其解离速率。此外，对于大多数所测的 G4，DSM 对 DHX36 的 G4 破坏步骤几乎没有影响或没有影响，这表明在 G4 破坏的过渡态中保持了与 G4 的接触。这一结果表明，从 3' 端部分破坏 G4 足以达到 G4 破坏的总过渡态，而 DSM 在 5' 端仍保持稳定。有趣的是，DSM 并未对低温下的 G4 结合动力学或热力学产生影响，表明其具有高度模块化的功能。总的来说，我们的研究结果为最近的 DHX36 晶体结构提供了依据，表明 DSM 通过在结合早期接触 5' 面，以模块化和灵活的方式募集 G4，从而招募 G4，这一过程先于由解旋酶核心进行限速捕获和 G4 破坏。

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