University of Szeged, Department of Optics and Quantum Electronics, Hungary.
Nanoscale. 2019 Aug 1;11(30):14226-14236. doi: 10.1039/c9nr03696b.
In eukaryotic cells, each process, in which DNA is involved, should take place in the context of a chromatin structure. DNA double-strand breaks (DSBs) are one of the most deleterious lesions often leading to chromosomal rearrangement. In response to environmental stresses, cells have developed repair mechanisms to eliminate the DSBs. Upon DSB induction, several factors play roles in chromatin relaxation by catalysing the appropriate histone posttranslational modification (PTM) steps, therefore promoting the access of the repair factors to the DSBs. Among these PTMs, the phosphorylation of the histone variant H2AX at its Ser139 residue (also known as γH2AX) could be observed at the break sites. The structure of a DNA double-strand break induced repair focus has to be organized during the repair as it contributes to the accessibility of specific repair proteins to the damaged site. Our aim was to develop a quantitative approach to analyse the morphology of single repair foci by super-resolution dSTORM microscopy to gain insight into chromatin organization in DNA repair. We have established a specific dSTORM measurement process by developing a new analytical algorithm for gaining quantitative information about chromatin morphology and repair foci topology at an individual γH2AX enriched repair focus. Using this method we quantified single repair foci to show the distribution of γH2AX. The image of individual γH2AX referred to as the Single target Molecule response scatter Plot (SMPlot) was obtained by using high lateral resolution dSTORM images. Determination of the average localization numbers in an SMPlot was one of the key steps of quantitative dSTORM. A repair focus is made up of nanofoci. Such a substructure of repair foci can only be resolved and detected with super-resolution microscopy. Determination of the number of γH2AXs in the nanofoci was another key step of quantitative dSTORM. Additionally, based on our new analysis method, we were able to show the number of nucleosomes in each nanofocus that could allow us to define the possible chromatin structure and the nucleosome density around the break sites. This method is one of the first demonstrations of a single-cell based quantitative measurement of a discrete repair focus, which could provide new opportunities to categorize the spatial organization of nanofoci by parametric determination of topological similarity.
在真核细胞中,涉及 DNA 的每个过程都应在染色质结构的背景下进行。DNA 双链断裂(DSB)是最具危害性的损伤之一,通常导致染色体重排。为了应对环境压力,细胞已经开发出修复机制来消除 DSB。在 DSB 诱导后,几种因素通过催化适当的组蛋白翻译后修饰(PTM)步骤在染色质松弛中发挥作用,从而促进修复因子接近 DSB。在这些 PTM 中,组蛋白变体 H2AX 的丝氨酸 139 残基(也称为 γH2AX)的磷酸化可以在断裂部位观察到。在修复过程中,必须组织 DNA 双链断裂诱导的修复焦点的结构,因为它有助于特定修复蛋白到达受损部位。我们的目的是开发一种定量方法来通过超分辨率 dSTORM 显微镜分析单个修复焦点的形态,以深入了解 DNA 修复中的染色质组织。我们通过开发一种新的分析算法来建立特定的 dSTORM 测量过程,该算法用于获取关于单个 γH2AX 富集修复焦点的染色质形态和修复焦点拓扑结构的定量信息。使用该方法,我们对单个修复焦点进行了量化,以显示 γH2AX 的分布。通过使用高横向分辨率 dSTORM 图像获得单个 γH2AX 的图像,称为单个靶分子响应散点图(SMPlot)。在 SMPlot 中确定平均定位数是定量 dSTORM 的关键步骤之一。修复焦点由纳米焦点组成。只有超分辨率显微镜才能解析和检测这种修复焦点的亚结构。确定纳米焦点中的 γH2AX 数量是定量 dSTORM 的另一个关键步骤。此外,基于我们的新分析方法,我们能够显示每个纳米焦点中的核小体数量,这可以使我们定义断裂部位周围可能的染色质结构和核小体密度。该方法是第一个基于单细胞的离散修复焦点定量测量之一,它可以通过拓扑相似性的参数确定来提供对纳米焦点空间组织进行分类的新机会。
