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中心体蛋白 A (CENP-A) 阵列在低盐离子强度下比典型阵列更为凝聚。

CENP-A arrays are more condensed than canonical arrays at low ionic strength.

机构信息

Buchmann Institute for Molecular Life Sciences, Frankfurt, Germany.

Department of Biochemistry and Biophysics, Perelman School of Medicine, University of Pennsylvania, Philadelphia, Pennsylvania.

出版信息

Biophys J. 2014 Feb 18;106(4):875-82. doi: 10.1016/j.bpj.2014.01.005.

DOI:10.1016/j.bpj.2014.01.005
PMID:24559990
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3944588/
Abstract

The centromeric histone H3 variant centromeric protein A (CENP-A), whose sequence is the least conserved among all histone variants, is responsible for specifying the location of the centromere. Here, we present a comprehensive study of CENP-A nucleosome arrays by cryo-electron tomography. We see that CENP-A arrays have different biophysical properties than canonical ones under low ionic conditions, as they are more condensed with a 20% smaller average nearest-neighbor distance and a 30% higher nucleosome density. We find that CENP-A nucleosomes have a predominantly crossed DNA entry/exit site that is narrowed on average by 8°, and they have a propensity to stack face to face. We therefore propose that CENP-A induces geometric constraints at the nucleosome DNA entry/exit site to bring neighboring nucleosomes into close proximity. This specific property of CENP-A may be responsible for generating a fundamental process that contributes to increased chromatin fiber compaction that is propagated under physiological conditions to form centromeric chromatin.

摘要

着丝粒组蛋白 H3 变体着丝粒蛋白 A(CENP-A)的序列在所有组蛋白变体中是最不保守的,负责指定着丝粒的位置。在这里,我们通过低温电子断层扫描对 CENP-A 核小体阵列进行了全面研究。我们发现,在低离子条件下,CENP-A 阵列具有与经典核小体不同的生物物理特性,因为它们更加凝聚,平均最近邻距离小 20%,核小体密度高 30%。我们发现 CENP-A 核小体具有占主导地位的交叉 DNA 进入/退出位点,该位点平均变窄 8°,并且它们具有面对面堆叠的倾向。因此,我们提出 CENP-A 在核小体 DNA 进入/退出位点诱导几何约束,使相邻核小体紧密接近。CENP-A 的这种特定性质可能负责产生一个基本过程,该过程有助于增加染色质纤维的紧缩,这种紧缩在生理条件下传播,以形成着丝粒染色质。

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