Chromatin condensation is driven by the energetically favourable interaction between nucleosome core particles (NCPs). The close NCP-NCP contact, stacking, is a primary structural element of all condensed states of chromatin in vitro and in vivo. However, the molecular structure of stacked nucleosomes as well as the nature of the interactions involved in its formation have not yet been systematically studied. Here we undertake an investigation of both the structural and physico-chemical features of NCP structure and the NCP-NCP stacking. We introduce an “NCP-centred” set of parameters (NCP-NCP distance, shift, rise, tilt, and others) that allows numerical characterisation of the mutual positions of the NCPs in the stacking and in any other structures formed by the NCP. NCP stacking in more than 140 published NCP crystal structures were analysed. In addition, coarse grained (CG) MD simulations modelling NCP condensation was carried out. The CG model takes into account details of the nucleosome structure and adequately describes the long range electrostatic forces as well as excluded volume effects acting in chromatin. The CG simulations showed good agreement with experimental data and revealed the importance of the H2A and H4 N-terminal tail bridging and screening as well as tail-tail correlations in the stacked nucleosomes.
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机译:染色质缩合由核小体核心颗粒(NCPS)之间的能量良好的相互作用驱动。 Close NCP-NCP接触,堆叠是在体外和体内染色质的所有浓缩状态的主要结构元素。然而,尚未系统地研究了堆积的核瘤的分子结构以及其形成中涉及的相互作用的性质。在这里,我们对NCP结构的结构和物理化学特征和NCP-NCP堆叠进行了调查。我们介绍了一个“NCP-NCP距离”参数(NCP-NCP距离,换档,倾斜等),允许在堆叠中的NCP和NCP形成的任何其他结构中的NCP的相互位置的数值表征。分析了140多个公布的NCP晶体结构中的NCP堆叠。此外,进行了建模NCP凝结的粗粒(CG)MD模拟。 CG模型考虑了核小体结构的细节,并充分描述了长距离的静态力以及在染色质中作用的排除体积效应。 CG模拟显示了与实验数据的良好一致性,并揭示了H2A和H4 N末端尾桥和筛选以及堆叠的核心中的尾部相关性的重要性。
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