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人源 ISWI 染色质重塑因子与 DNA 修复位点的结合动力学阐明了它们的靶定位机制。

Binding kinetics of human ISWI chromatin-remodelers to DNA repair sites elucidate their target location mechanism.

机构信息

Research Group Genome Organization & Function, Deutsches Krebsforschungszentrum & BioQuant, Heidelberg, Germany.

出版信息

Nucleus. 2011 Mar-Apr;2(2):105-12. doi: 10.4161/nucl.2.2.15209.

DOI:10.4161/nucl.2.2.15209
PMID:21738833
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3127092/
Abstract

Chromatin remodelers translocate nucleosomes along the DNA chain in an ATP-dependent manner. This catalytic activity is particularly important for DNA replication and repair since both processes require a significant amount of nucleosome translocations and assembly during DNA synthesis. Recently, we have studied the mobility and interactions of the human ISWI family chromatin remodelers Snf2H and Snf2L as well as Acf1, one of the non-catalytic subunits present in the ACF and CHRAC complexes of Snf2H. We proposed that these protein complexes identify their nucleosomal substrates via a continuous sampling mechanism. It rationalizes the relatively high nuclear mobility and abundance observed for all ISWI proteins in terms of fast target location. According to our model a certain type of ISWI complex visits a given nucleosome in the human genome on the timescale of several seconds to a few minutes. Here, we show that the ISWI proteins Snf2H, Snf2L as well as Acf1 accumulate at UV-induced DNA damage sites within tens of seconds and reach a plateau after a few minutes. These findings corroborate the predictions of the continuous sampling mechanism as an efficient way for targeting chromatin remodelers to sites in the genome that require their activity. In comparison to the mobility of PCNA (proliferating cell nuclear antigen) that also accumulates at DNA repair sites the specifics of substrate location by chromatin remodelers are further characterized.

摘要

染色质重塑酶以 ATP 依赖的方式沿 DNA 链迁移核小体。这种催化活性对于 DNA 复制和修复尤为重要,因为这两个过程都需要在 DNA 合成过程中进行大量的核小体迁移和组装。最近,我们研究了人类 ISWI 家族染色质重塑酶 Snf2H 和 Snf2L 以及 Acf1 的迁移性和相互作用,Acf1 是 Snf2H 的 ACF 和 CHRAC 复合物中存在的非催化亚基之一。我们提出这些蛋白复合物通过连续采样机制来识别它们的核小体底物。它根据快速的靶定位点合理化了所有 ISWI 蛋白在核内的相对高迁移率和丰度。根据我们的模型,某种类型的 ISWI 复合物在人类基因组中以几秒钟到几分钟的时间尺度访问给定的核小体。在这里,我们表明 ISWI 蛋白 Snf2H、Snf2L 和 Acf1 在数十秒内聚集在 UV 诱导的 DNA 损伤部位,并在几分钟后达到稳定状态。这些发现证实了连续采样机制作为将染色质重塑酶靶向基因组中需要其活性的部位的有效方式的预测。与也在 DNA 修复部位积累的增殖细胞核抗原 (PCNA) 的迁移性相比,染色质重塑酶的底物定位的具体情况进一步得到了表征。

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