MeCP2-induced heterochromatin organization is driven by oligomerization-based liquid-liquid phase separation and restricted by DNA methylation.

Hui Zhang, Hector Romero, Annika Schmidt, Katalina Gagova, Weihua Qin, Bianca Bertulat, Anne Lehmkuhl, Manuela Milden, Malte Eck, Tobias Meckel, Heinrich Leonhardt, M Cristina Cardoso
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引用次数: 10

Abstract

Heterochromatin is the highly compacted form of chromatin with various condensation levels hallmarked by high DNA methylation. MeCP2 is mostly known as a DNA methylation reader but has also been reported as a heterochromatin organizer. Here, we combine liquid-liquid phase separation (LLPS) analysis and single-molecule tracking with quantification of local MeCP2 concentrations in vitro and in vivo to explore the mechanism of MeCP2-driven heterochromatin organization and dynamics. We show that MeCP2 alone forms liquid-like spherical droplets via multivalent electrostatic interactions and with isotropic mobility. Crowded environments and DNA promote MeCP2 LLPS and slow down MeCP2 mobility. DNA methylation, however, restricts the growth of heterochromatin compartments correlating with immobilization of MeCP2. Furthermore, MeCP2 self-interaction is required for LLPS and is disrupted by Rett syndrome mutations. In summary, we are able to model the heterochromatin compartmentalization as well as MeCP2 concentration and heterogeneous motion in the minimal in vitro system.

Abstract Image

Abstract Image

Abstract Image

mecp2诱导的异染色质组织由基于寡聚化的液-液相分离驱动,并受到DNA甲基化的限制。
异染色质是染色质的高度压缩形式,具有不同的浓缩水平,以高DNA甲基化为特征。MeCP2主要被认为是DNA甲基化解读器,但也有报道称它是异染色质组织者。本研究将液-液相分离(LLPS)分析和单分子跟踪与体外和体内局部MeCP2浓度定量相结合,探讨MeCP2驱动异染色质组织和动力学的机制。我们发现MeCP2单独通过多价静电相互作用和各向同性迁移率形成液体状球形液滴。拥挤的环境和DNA促进了MeCP2的LLPS,减缓了MeCP2的移动性。然而,DNA甲基化限制了与MeCP2固定相关的异染色质区室的生长。此外,MeCP2自相互作用是LLPS所必需的,并被Rett综合征突变破坏。总之,我们能够在最小的体外系统中模拟异染色质区隔化以及MeCP2浓度和异质运动。
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