Why the ROS matters: One-electron oxidants focus DNA damage and repair on G-quadruplexes for gene regulation

IF 3 3区生物学 Q2 GENETICS & HEREDITY DNA Repair Pub Date : 2024-11-16 DOI:10.1016/j.dnarep.2024.103789

Aaron M. Fleming, Cynthia J. Burrows

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Abstract

Hydrogen peroxide is a precursor to reactive oxygen species (ROS) in cells because of its high reactivity with iron(II) carbonate complexes formed in the labile iron pool due to a high concentration of intracellular bicarbonate (25–100 mM). This chemistry leads to the formation of carbonate radical anion rather than hydroxyl radical, and unlike the latter ROS, CO₃^•- is a milder one-electron oxidant with high specificity for guanine oxidation in DNA and RNA. In addition to metabolism, another major source of DNA oxidation is inflammation which generates peroxynitrite, another precursor to CO₃^•- via reaction with dissolved CO₂. The identity of the ROS is important because not all radicals react with DNA in the same way. Whereas hydroxyl radical forms adducts at all four bases and reacts with multiple positions on ribose leading to base loss and strand breaks, carbonate radical anion is focused on guanosine oxidation to yield 8-oxo-7,8-dihydroguanosine in nucleic acids and the nucleotide pool, a modification that can function epigenetically in the context of a G-quadruplex. DNA sequences of multiple adjacent guanines, as found in G-quadruplex-forming sequences of gene promoters, are particularly susceptible to oxidative damage, and the focusing of CO₃^•- chemistry on these sites can lead to a transcriptional response during base excision repair. In this pathway, AP-endonuclease 1 plays a key role in accelerating G-quadruplex folding as well as recruiting activating transcription factors to impact gene expression.

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ROS 为何重要？单电子氧化剂使 DNA 损伤和修复集中于 G 型四联体，从而实现基因调控

过氧化氢是细胞中活性氧（ROS）的前体，因为它与细胞内高浓度碳酸氢盐（25-100 毫摩尔）在易失铁池中形成的碳酸铁（II）络合物具有高度反应性。这种化学反应会形成碳酸根阴离子而不是羟基自由基，与羟基自由基不同，CO3--是一种较温和的单电子氧化剂，对 DNA 和 RNA 中的鸟嘌呤氧化具有高度特异性。除新陈代谢外，DNA 氧化的另一个主要来源是炎症，炎症通过与溶解的 CO2 反应产生过亚硝酸盐，这是 CO3--的另一种前体。ROS 的特性非常重要，因为并非所有自由基都以相同的方式与 DNA 发生反应。羟基自由基会在所有四个碱基上形成加合物，并与核糖上的多个位置发生反应，导致碱基缺失和链断裂，而碳酸自由基阴离子则主要作用于鸟苷氧化，在核酸和核苷酸池中生成 8-氧代-7,8-二氢鸟苷，这种修饰可在 G 型四联体中发挥表观遗传作用。在基因启动子的 G-四叠体形成序列中发现的多个相邻鸟嘌呤的 DNA 序列特别容易受到氧化损伤，在碱基切除修复过程中，CO3-化学作用集中在这些位点上会导致转录反应。在这一途径中，AP-内切酶 1 在加速 G-四叠体折叠以及招募激活转录因子以影响基因表达方面起着关键作用。

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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来源期刊

DNA Repair 生物-毒理学

CiteScore

7.60

自引率

5.30%

发文量

审稿时长

59 days

期刊介绍： DNA Repair provides a forum for the comprehensive coverage of DNA repair and cellular responses to DNA damage. The journal publishes original observations on genetic, cellular, biochemical, structural and molecular aspects of DNA repair, mutagenesis, cell cycle regulation, apoptosis and other biological responses in cells exposed to genomic insult, as well as their relationship to human disease. DNA Repair publishes full-length research articles, brief reports on research, and reviews. The journal welcomes articles describing databases, methods and new technologies supporting research on DNA repair and responses to DNA damage. Letters to the Editor, hot topics and classics in DNA repair, historical reflections, book reviews and meeting reports also will be considered for publication.