Independence of centromeric and pericentromeric chromatin stability on CCAN components.

IF 3.1 3区生物学 Q3 CELL BIOLOGY

Molecular Biology of the Cell Pub Date : 2025-04-01 Epub Date: 2025-02-12 DOI:10.1091/mbc.E24-02-0066

Ronald J Biggs, Mingxuan Sun, Kousik Sundararajan, Eline Hendrix, Aaron F Straight, John F Marko

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Abstract

The chromatin of the centromere provides the assembly site for the mitotic kinetochore that couples microtubule attachment and force production to chromosome movement in mitosis. The chromatin of the centromere is specified by nucleosomes containing the histone H3 variant, CENP-A. The constitutive centromeric-associated network (CCAN) and kinetochore are assembled on CENP-A chromatin to enable chromosome separation. CENP-A chromatin is surrounded by pericentromeric heterochromatin, which itself is bound by the sequence specific binding protein, CENP-B. We performed mechanical experiments on mitotic chromosomes while tracking CENP-A and CENP-B to observe the centromere's stiffness and the role of the CCAN. We degraded CENP-C and CENP-N containing auxin-inducible degrons, which we verified compromises the CCAN via observation of CENP-T loss. Chromosome stretching revealed that the CENP-A domain does not visibly stretch, even in the absence of CENP-C and/or CENP-N. Pericentromeric chromatin deforms upon force application, stretching ∼3-fold less than the entire chromosome. CENP-C and/or CENP-N loss has no impact on pericentromere stretching. Chromosome-disconnecting nuclease treatments showed no structural effects on CENP-A. Our experiments show that the core-centromeric chromatin is more resilient and likely mechanically disconnected from the underlying pericentromeric chromatin, while the pericentric chromatin is deformable yet stiffer than the chromosome arms.

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中心染色质和周边染色质的稳定性与 CCAN 成分无关

着丝粒的染色质为有丝分裂中的着丝点提供了装配位点，使微管附着和有丝分裂中染色体运动产生作用力。着丝粒的染色质由含有组蛋白H3变体CENP-A的核小体指定。着丝粒相关网络（CCAN）和着丝粒在CENP-A染色质上组装，使染色体分离成为可能。CENP-A染色质被中心周围异染色质包围，并被序列特异性结合蛋白CENP-B结合。我们在有丝分裂染色体上进行机械实验，同时跟踪CENP-A和CENP-B，观察着丝粒的硬度和CCAN的作用。我们使用生长素诱导的降解物降解了CENP-C和CENP-N，通过观察CENP-T的损失，我们证实了这损害了CCAN。染色体拉伸显示，即使在没有CENP-C和/或CENP-N的情况下，CENP-A结构域也没有明显的拉伸。在施加力时，中心点周围的染色质会变形，比整个染色体的拉伸约少3倍。CENP-C和/或CENP-N的丢失对中心周围拉伸没有影响。染色体分离核酸酶处理对CENP-A无结构影响。我们的实验表明，核心-着丝粒染色质具有更强的弹性，并且可能与底层的周着丝粒染色质机械分离，而周着丝粒染色质可变形，但比染色体臂更硬。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Molecular Biology of the Cell 生物-细胞生物学

CiteScore

6.00

自引率

6.10%

发文量

402

审稿时长

2 months

期刊介绍： MBoC publishes research articles that present conceptual advances of broad interest and significance within all areas of cell, molecular, and developmental biology. We welcome manuscripts that describe advances with applications across topics including but not limited to: cell growth and division; nuclear and cytoskeletal processes; membrane trafficking and autophagy; organelle biology; quantitative cell biology; physical cell biology and mechanobiology; cell signaling; stem cell biology and development; cancer biology; cellular immunology and microbial pathogenesis; cellular neurobiology; prokaryotic cell biology; and cell biology of disease.