College of Veterinary Medicine, Department of Microbiology Genetics & Immunology, Department of Pathobiology & Diagnostic Investigation, Michigan State University, East Lansing, MI 48824, USA.
Department of Biochemistry and Molecular Biology, Michigan State University, East Lansing, MI, USA; Institute for Quantitative Health Sciences and Engineering, Michigan State University, East Lansing, MI, USA.
DNA Repair (Amst). 2024 Sep;141:103716. doi: 10.1016/j.dnarep.2024.103716. Epub 2024 Jul 8.
Given its central role in life, DNA is remarkably easy to damage. Double strand breaks (DSBs) are the most toxic form of DNA damage, and DSBs pose the greatest danger to genomic integrity. In higher vertebrates, the non-homologous end joining pathway (NHEJ) is the predominate pathway that repairs DSBs. NHEJ has three steps: 1) DNA end recognition by the DNA dependent protein kinase [DNA-PK], 2) DNA end-processing by numerous NHEJ accessory factors, and 3) DNA end ligation by the DNA ligase IV complex (LX4). Although this would appear to be a relatively simple mechanism, it has become increasingly apparent that it is not. Recently, much insight has been derived regarding the mechanism of non-homologous end joining through a proliferation of cryo-EM studies, structure-function mutational experiments informed by these new structural data, and novel single-molecule imaging approaches. An emerging consensus in the field is that NHEJ progresses from initial DSB end recognition by DNA-PK to synapsis of the two DNA ends in a long-range synaptic complex where ends are held too far apart (115 Å) for ligation, and then progress to a short-range synaptic complex where ends are positioned close enough for ligation. What was surprising from these structural studies was the observation of two distinct types of DNA-PK dimers that represent NHEJ long-range complexes. In this review, we summarize current knowledge about the function of the distinct NHEJ synaptic complexes and align this new information with emerging cellular single-molecule microscopy studies as well as with previous studies of DNA-PK's function in repair.
鉴于其在生命中的核心作用,DNA 极易受到损伤。双链断裂(DSB)是最具毒性的 DNA 损伤形式,而 DSB 对基因组完整性构成最大威胁。在高等脊椎动物中,非同源末端连接途径(NHEJ)是修复 DSB 的主要途径。NHEJ 有三个步骤:1)DNA 依赖性蛋白激酶 [DNA-PK] 对 DNA 末端的识别,2)许多 NHEJ 辅助因子对 DNA 末端的处理,3)DNA 连接酶 IV 复合物(LX4)对 DNA 末端的连接。尽管这似乎是一个相对简单的机制,但事实并非如此。最近,通过大量冷冻电镜研究、这些新结构数据指导的结构-功能突变实验,以及新的单分子成像方法,人们对非同源末端连接的机制有了更深入的了解。该领域的一个新兴共识是,NHEJ 从 DNA-PK 对初始 DSB 末端的识别开始,然后在长程突触复合物中连接两个 DNA 末端,在长程突触复合物中,末端之间的距离太远(115Å)无法连接,然后进入短程突触复合物,在短程突触复合物中,末端之间的距离足够近,可以进行连接。这些结构研究令人惊讶的是观察到两种不同类型的 DNA-PK 二聚体,它们代表了 NHEJ 的长程复合物。在这篇综述中,我们总结了关于不同 NHEJ 突触复合物功能的现有知识,并将这些新信息与新兴的细胞单分子显微镜研究以及 DNA-PK 在修复中的功能的先前研究进行了对齐。
