Networks and Islands of Genome Nano-architecture and Their Potential Relevance for Radiation Biology : (A Hypothesis and Experimental Verification Hints).

Q4 Biochemistry, Genetics and Molecular Biology Results and Problems in Cell Differentiation Pub Date : 2022-01-01 DOI:10.1007/978-3-031-06573-6_1
Michael Hausmann, Georg Hildenbrand, Götz Pilarczyk
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引用次数: 3

Abstract

The cell nucleus is a complex biological system in which simultaneous reactions and functions take place to keep the cell as an individualized, specialized system running well. The cell nucleus contains chromatin packed in various degrees of density and separated in volumes of chromosome territories and subchromosomal domains. Between the chromatin, however, there is enough "free" space for floating RNA, proteins, enzymes, ATPs, ions, water molecules, etc. which are trafficking by super- and supra-diffusion to the interaction points where they are required. It seems that this trafficking works somehow automatically and drives the system perfectly. After exposure to ionizing radiation causing DNA damage from single base damage up to chromatin double-strand breaks, the whole system "cell nucleus" responds, and repair processes are starting to recover the fully functional and intact system. In molecular biology, many individual epigenetic pathways of DNA damage response or repair of single and double-strand breaks are described. How these responses are embedded into the response of the system as a whole is often out of the focus of consideration. In this article, we want to follow the hypothesis of chromatin architecture's impact on epigenetic pathways and vice versa. Based on the assumption that chromatin acts like an "aperiodic solid state within a limited volume," functionally determined networks and local topologies ("islands") can be defined that drive the appropriate repair process at a given damage site. Experimental results of investigations of the chromatin nano-architecture and DNA repair clusters obtained by means of single-molecule localization microscopy offer hints and perspectives that may contribute to verifying the hypothesis.

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基因组纳米结构的网络和孤岛及其与辐射生物学的潜在相关性:(一个假设和实验验证提示)。
细胞核是一个复杂的生物系统,同时发生反应和功能,以保持细胞作为一个个性化的,专门的系统运行良好。细胞核中含有密度不同的染色质,并以染色体区域和亚染色体区域的体积分隔。然而,在染色质之间,有足够的“自由”空间供漂浮的RNA、蛋白质、酶、atp、离子、水分子等通过超扩散和超扩散运输到需要它们的相互作用点。似乎这种交易在某种程度上是自动运作的,并完美地驱动着整个系统。暴露在电离辐射下导致DNA损伤,从单碱基损伤到染色质双链断裂,整个系统“细胞核”做出反应,修复过程开始恢复功能完整的系统。在分子生物学中,描述了许多DNA损伤反应或单链和双链断裂修复的个体表观遗传途径。如何将这些响应嵌入到整个系统的响应中,通常不在考虑的重点范围之内。在本文中,我们希望遵循染色质结构影响表观遗传途径的假设,反之亦然。基于染色质像“有限体积内的非周期性固态”的假设,可以定义功能确定的网络和局部拓扑(“岛屿”),它们驱动给定损伤部位的适当修复过程。利用单分子定位显微镜研究染色质纳米结构和DNA修复簇的实验结果为验证这一假设提供了线索和视角。
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来源期刊
Results and Problems in Cell Differentiation
Results and Problems in Cell Differentiation Biochemistry, Genetics and Molecular Biology-Developmental Biology
CiteScore
1.90
自引率
0.00%
发文量
21
期刊介绍: Results and Problems in Cell Differentiation is an up-to-date book series that presents and explores selected questions of cell and developmental biology. Each volume focuses on a single, well-defined topic. Reviews address basic questions and phenomena, but also provide concise information on the most recent advances. Together, the volumes provide a valuable overview of this exciting and dynamically expanding field.
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