超分辨率 GSDIM 显微镜揭示了不同基因毒性胁迫下 DNA 修复灶的独特纳米级特征

IF 3 3区生物学 Q2 GENETICS & HEREDITY

DNA Repair Pub Date : 2024-01-16 DOI:10.1016/j.dnarep.2024.103626

Haibin Qian , Audrey Margaretha Plat , Ard Jonker , Ron A. Hoebe , Przemek Krawczyk

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引用次数: 0

摘要

DNA 双链断裂启动了 DNA 损伤反应（DDR），导致修复蛋白在断裂位点聚集并形成所谓的病灶。各种显微镜方法，如宽视场、共焦、电子和超分辨率显微镜，已被用于研究这些结构。然而，不同的DNA损伤剂对它们的（纳米）结构的影响仍不清楚。利用 GSDIM 超分辨率显微镜，我们研究了荧光标记的 DDR 蛋白（53BP1、RNF168、MDC1）和γH2AX 在接受γ-辐照、依托泊苷、顺铂或羟基脲处理的 U2OS 细胞中的分布情况。我们的研究结果表明，不同的诱导剂，甚至是机制相似的诱导剂，都会显著改变病灶结构及其纳米级超微结构，包括病灶大小、纳米簇特征、荧光团密度和定位。此外，在相同的治疗条件下，DDR 蛋白也会出现不同的行为。这些发现对涉及这些药剂的癌症治疗策略具有重要意义，并为 DDR 的纳米级组织提供了见解。

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Super-resolution GSDIM microscopy unveils distinct nanoscale characteristics of DNA repair foci under diverse genotoxic stress

DNA double-strand breaks initiate the DNA damage response (DDR), leading to the accumulation of repair proteins at break sites and the formation of the-so-called foci. Various microscopy methods, such as wide-field, confocal, electron, and super-resolution microscopy, have been used to study these structures. However, the impact of different DNA-damaging agents on their (nano)structure remains unclear. Utilising GSDIM super-resolution microscopy, here we investigated the distribution of fluorescently tagged DDR proteins (53BP1, RNF168, MDC1) and γH2AX in U2OS cells treated with γ-irradiation, etoposide, cisplatin, or hydroxyurea. Our results revealed that both foci structure and their nanoscale ultrastructure, including foci size, nanocluster characteristics, fluorophore density and localisation, can be significantly altered by different inducing agents, even ones with similar mechanisms. Furthermore, distinct behaviours of DDR proteins were observed under the same treatment. These findings have implications for cancer treatment strategies involving these agents and provide insights into the nanoscale organisation of the DDR.

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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.