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ATP 结合通过促进 DNA 上的一维扩散来促进 SWR1 染色质重塑酶的靶标搜索。

ATP binding facilitates target search of SWR1 chromatin remodeler by promoting one-dimensional diffusion on DNA.

机构信息

Department of Biophysics and Biophysical Chemistry, Johns Hopkins University, Baltimore, United States.

Department of Biology, Johns Hopkins University, Baltimore, United States.

出版信息

Elife. 2022 Jul 25;11:e77352. doi: 10.7554/eLife.77352.

DOI:10.7554/eLife.77352
PMID:35876491
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9365391/
Abstract

One-dimensional (1D) target search is a well-characterized phenomenon for many DNA-binding proteins but is poorly understood for chromatin remodelers. Herein, we characterize the 1D scanning properties of SWR1, a conserved yeast chromatin remodeler that performs histone exchange on +1 nucleosomes adjacent to a nucleosome-depleted region (NDR) at gene promoters. We demonstrate that SWR1 has a kinetic binding preference for DNA of NDR length as opposed to gene-body linker length DNA. Using single and dual color single-particle tracking on DNA stretched with optical tweezers, we directly observe SWR1 diffusion on DNA. We found that various factors impact SWR1 scanning, including ATP which promotes diffusion through nucleotide binding rather than ATP hydrolysis. A DNA-binding subunit, Swc2, plays an important role in the overall diffusive behavior of the complex, as the subunit in isolation retains similar, although faster, scanning properties as the whole remodeler. ATP-bound SWR1 slides until it encounters a protein roadblock, of which we tested dCas9 and nucleosomes. The median diffusion coefficient, 0.024 μm/s, in the regime of helical sliding, would mediate rapid encounter of NDR-flanking nucleosomes at length scales found in cellular chromatin.

摘要

一维(1D)目标搜索是许多 DNA 结合蛋白的一个特征现象,但对于染色质重塑剂来说,这种现象还了解甚少。在此,我们对 SWR1 的 1D 扫描特性进行了描述,SWR1 是一种保守的酵母染色质重塑酶,它在基因启动子处的核小体缺失区域(NDR)旁边的+1 核小体上进行组蛋白交换。我们证明,SWR1 对 NDR 长度的 DNA 具有动力学结合偏好,而不是对基因体连接子长度的 DNA。我们使用单分子和双分子单粒子跟踪技术,在 DNA 被光学镊子拉伸的情况下,直接观察 SWR1 在 DNA 上的扩散。我们发现,各种因素会影响 SWR1 的扫描,包括促进通过核苷酸结合而扩散的 ATP,而不是通过 ATP 水解促进扩散。一个 DNA 结合亚基 Swc2 在复合物的整体扩散行为中起着重要作用,因为分离的亚基保留了类似于整个重塑酶的扫描特性,尽管速度更快。与 ATP 结合的 SWR1 会滑动,直到遇到蛋白质障碍,我们在此测试了 dCas9 和核小体。在螺旋滑动的范围内,平均扩散系数为 0.024 μm/s,这将介导在细胞染色质中发现的长度尺度上与 NDR 相邻核小体的快速相遇。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/6e9d/9365391/639993dd07b8/elife-77352-sa2-fig1.jpg
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