DNA磷酸化途径通过腺苷化中间体调节Tdp机制

IF 12.9 1区生物学 Q1 BIOCHEMISTRY & MOLECULAR BIOLOGY

Nature chemical biology Pub Date : 2025-01-16 DOI:10.1038/s41589-024-01832-w

Tianchen An, Qian Tan, Lixu Jiang, Li Liu, Xing Jiang, Liying Liu, Xiaofei Chang, Xihao Tian, Zixin Deng, Shuai Gao, Lianrong Wang, Shi Chen

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引用次数: 0

摘要

在原核生物中，DNA糖-磷酸主链中的非桥接氧可以被硫原子取代，从而导致硫代磷酸酯（PT）修饰。然而，氧到硫取代的机制仍然是个谜。在这项研究中，我们发现了一个超紧凑的DNA磷酸化系统，TdpABC，在极端嗜热菌。这个DNA硫化过程通过两个连续的步骤发生：ATP的初始激活步骤，形成腺苷化的中间体，然后是取代步骤，腺苷基被硫原子取代。与TdpA-TdpB一起，TdpABC系统通过降解无pt噬菌体DNA提供抗噬菌体防御。低温电镜结构分析表明，TdpA六聚体通过螺旋阶梯构象的氢键与一条环状双链DNA结合。然而，TdpAB-DNA相互作用对PT硫的疏水性很敏感。PTs抑制atp驱动的易位和TdpAB在自身dna上的核酸酶活性，从而防止自身免疫。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

A DNA phosphorothioation pathway via adenylated intermediate modulates Tdp machinery

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A DNA phosphorothioation pathway via adenylated intermediate modulates Tdp machinery

In prokaryotes, the non-bridging oxygen in the DNA sugar-phosphate backbone can be enzymatically replaced by a sulfur atom, resulting in phosphorothioate (PT) modification. However, the mechanism underlying the oxygen-to-sulfur substitution remains enigmatic. In this study, we discovered a hypercompact DNA phosphorothioation system, TdpABC, in extreme thermophiles. This DNA sulfuration process occurs through two sequential steps: an initial activation step by ATP to form an adenylated intermediate, followed by a substitution step where the adenyl group is replaced with a sulfur atom. Together with the TdpA–TdpB, the TdpABC system provides anti-phage defense by degrading PT-free phage DNA. Cryogenic electron microscopy structural analysis revealed that the TdpA hexamer binds one strand of encircled duplex DNA via hydrogen bonds arranged in a spiral staircase conformation. Nevertheless, the TdpAB–DNA interaction was sensitive to the hydrophobicity of the PT sulfur. PTs inhibit ATP-driven translocation and nuclease activity of TdpAB on self-DNA, thereby preventing autoimmunity.

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来源期刊

Nature chemical biology 生物-生化与分子生物学

CiteScore

23.90

自引率

1.40%

发文量

238

审稿时长

12 months

期刊介绍： Nature Chemical Biology stands as an esteemed international monthly journal, offering a prominent platform for the chemical biology community to showcase top-tier original research and commentary. Operating at the crossroads of chemistry, biology, and related disciplines, chemical biology utilizes scientific ideas and approaches to comprehend and manipulate biological systems with molecular precision. The journal embraces contributions from the growing community of chemical biologists, encompassing insights from chemists applying principles and tools to biological inquiries and biologists striving to comprehend and control molecular-level biological processes. We prioritize studies unveiling significant conceptual or practical advancements in areas where chemistry and biology intersect, emphasizing basic research, especially those reporting novel chemical or biological tools and offering profound molecular-level insights into underlying biological mechanisms. Nature Chemical Biology also welcomes manuscripts describing applied molecular studies at the chemistry-biology interface due to the broad utility of chemical biology approaches in manipulating or engineering biological systems. Irrespective of scientific focus, we actively seek submissions that creatively blend chemistry and biology, particularly those providing substantial conceptual or methodological breakthroughs with the potential to open innovative research avenues. The journal maintains a robust and impartial review process, emphasizing thorough chemical and biological characterization.