NHEJ途径中的灵活迭代步骤

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC ACS Applied Electronic Materials Pub Date : 2023-07-01 DOI:10.1016/j.pbiomolbio.2023.05.001
Go Watanabe, Michael R. Lieber
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引用次数: 3

摘要

长期以来,对非同源DNA末端连接(NHEJ)的细胞和生化研究已经证实,核酸酶和聚合酶作用对于修复很大一部分自然产生的双链断裂(DSBs)是必要的。这一结论来源于NHEJ的研究,从酵母到人类和所有基因可处理的模式生物。从最近的实时和结构研究中得出的生化模型尚未纳入DNA末端处理的物理空间或时间。在实时单分子FRET(smFRET)研究中,我们分析了确定的生化系统中DNA末端的NHEJ突触。我们描述了一种柔性突触(FS)状态,其中DNA末端仅通过Ku和XRCC4:DNA连接酶4(X4L4)接近,并且在一个或多个微同源核苷酸(MH)之间发生碱基配对之前,其取向还不允许连接,从而允许直列紧密突触(CS)状态。如果不能实现MH,那么XLF对于结扎是至关重要的。FS和CS都不需要DNA-PKcs,除非Artemis激活是必要的,以允许局部切除和随后连接的两个DNA末端之间的碱基配对。在这里,我们推测了这种FS状态可能的3D配置,它将以迭代的方式在空间上适应核酸酶和聚合酶的处理步骤。FS模型允许在每轮核酸酶或聚合酶作用后重复尝试在DSB连接至少一条链。除了激活阿耳忒弥斯,还讨论了DNA PKcs的其他可能作用。
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The flexible and iterative steps within the NHEJ pathway

Cellular and biochemical studies of nonhomologous DNA end joining (NHEJ) have long established that nuclease and polymerase action are necessary for the repair of a very large fraction of naturally-arising double-strand breaks (DSBs). This conclusion is derived from NHEJ studies ranging from yeast to humans and all genetically-tractable model organisms. Biochemical models derived from recent real-time and structural studies have yet to incorporate physical space or timing for DNA end processing. In real-time single molecule FRET (smFRET) studies, we analyzed NHEJ synapsis of DNA ends in a defined biochemical system. We described a Flexible Synapsis (FS) state in which the DNA ends were in proximity via only Ku and XRCC4:DNA ligase 4 (X4L4), and in an orientation that would not yet permit ligation until base pairing between one or more nucleotides of microhomology (MH) occurred, thereby allowing an in-line Close Synapsis (CS) state. If no MH was achievable, then XLF was critical for ligation. Neither FS or CS required DNA-PKcs, unless Artemis activation was necessary to permit local resection and subsequent base pairing between the two DNA ends being joined. Here we conjecture on possible 3D configurations for this FS state, which would spatially accommodate the nuclease and polymerase processing steps in an iterative manner. The FS model permits repeated attempts at ligation of at least one strand at the DSB after each round of nuclease or polymerase action. In addition to activation of Artemis, other possible roles for DNA-PKcs are discussed.

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CiteScore
7.20
自引率
4.30%
发文量
567
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