Simulation of Different Three-Dimensional Models of Whole Interphase Nuclei Compared to Experiments - A Consistent Scale-Bridging Simulation Framework for Genome Organization.

Q4 Biochemistry, Genetics and Molecular Biology Results and Problems in Cell Differentiation Pub Date : 2022-01-01 DOI:10.1007/978-3-031-06573-6_18
Tobias A Knoch
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Abstract

The three-dimensional architecture of chromosomes, their arrangement, and dynamics within cell nuclei are still subject of debate. Obviously, the function of genomes-the storage, replication, and transcription of genetic information-has closely coevolved with this architecture and its dynamics, and hence are closely connected. In this work a scale-bridging framework investigates how of the 30 nm chromatin fibre organizes into chromosomes including their arrangement and morphology in the simulation of whole nuclei. Therefore, mainly two different topologies were simulated with corresponding parameter variations and comparing them to experiments: The Multi-Loop-Subcompartment (MLS) model, in which (stable) small loops form (stable) rosettes, connected by chromatin linkers, and the Random-Walk/Giant-Loop (RW/GL) model, in which large loops are attached to a flexible non-protein backbone, were simulated for various loop and linker sizes. The 30 nm chromatin fibre was modelled as a polymer chain with stretching, bending and excluded volume interactions. A spherical boundary potential simulated the confinement to nuclei with different radii. Simulated annealing and Brownian Dynamics methods were applied in a four-step decondensation procedure to generate from metaphase decondensated interphase configurations at thermodynamical equilibrium. Both the MLS and the RW/GL models form chromosome territories, with different morphologies: The MLS rosettes result in distinct subchromosomal domains visible in electron and confocal laser scanning microscopic images. In contrast, the big RW/GL loops lead to a mostly homogeneous chromatin distribution. Even small changes of the model parameters induced significant rearrangements of the chromatin morphology. The low overlap of chromosomes, arms, and subchromosomal domains observed in experiments agrees only with the MLS model. The chromatin density distribution in CLSM image stacks reveals a bimodal behaviour in agreement with recent experiments. Combination of these results with a variety of (spatial distance) measurements favour an MLS like model with loops and linkers of 63 to 126 kbp. The predicted large spaces between the chromatin fibres allow typically sized biological molecules to reach nearly every location in the nucleus by moderately obstructed diffusion and is in disagreement with the much simplified assumption that defined channels between territories for molecular transport as in the Interchromosomal Domain (ICD) hypothesis exist and are necessary for transport. All this is also in agreement with recent selective high-resolution chromosome interaction capture (T2C) experiments, the scaling behaviour of the DNA sequence, the dynamics of the chromatin fibre, the diffusion of molecules, and other measurements. Also all other chromosome topologies can in principle be excluded. In summary, polymer simulations of whole nuclei compared to experimental data not only clearly favour only a stable loop aggregate/rosette like genome architecture whose local topology is tightly connected to the global morphology and dynamics of the cell nucleus and hence can be used for understanding genome organization also in respect to diagnosis and treatment. This is in agreement with and also leads to a general novel framework of genome emergence, function, and evolution.

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整个间期细胞核不同三维模型的模拟与实验比较——基因组组织的一致尺度桥接模拟框架。
染色体的三维结构,它们的排列和细胞核内的动力学仍然是争论的主题。显然,基因组的功能——遗传信息的存储、复制和转录——与这种结构及其动态紧密地共同进化,因此紧密地联系在一起。在这项工作中,一个尺度桥接框架研究了30纳米染色质纤维如何组织成染色体,包括它们在模拟整个细胞核中的排列和形态。因此,主要模拟了两种不同的拓扑结构及其相应的参数变化,并将其与实验进行比较:多环-亚室(MLS)模型,其中(稳定的)小环形成(稳定的)花环,由染色质连接体连接;随机行走/巨环(RW/GL)模型,其中大环附着在灵活的非蛋白骨架上,模拟了不同的环和连接体大小。30纳米的染色质纤维被建模为具有拉伸、弯曲和排除体积相互作用的聚合物链。用球面边界势模拟了对不同半径核的约束。模拟退火和布朗动力学方法应用于四步脱密过程,从热力学平衡的中期脱密间相构型生成。MLS和RW/GL模型都形成染色体区域,具有不同的形态:MLS玫瑰结导致在电子和共聚焦激光扫描显微镜图像中可见不同的亚染色体区域。相反,大的RW/GL环导致染色质分布基本均匀。即使模型参数的微小变化也会引起染色质形态的显著重排。实验中观察到的染色体、臂和亚染色体结构域的低重叠只与MLS模型一致。与最近的实验结果一致,CLSM图像堆中的染色质密度分布显示出双峰行为。将这些结果与各种(空间距离)测量相结合,支持具有63至126 kbp环路和连接器的MLS模型。预测的染色质纤维之间的大空间允许典型大小的生物分子通过适度阻碍的扩散到达细胞核中的几乎每个位置,这与染色体间结构域(ICD)假设中分子运输区域之间的定义通道存在并且是运输所必需的简化假设不一致。所有这些也与最近的选择性高分辨率染色体相互作用捕获(T2C)实验、DNA序列的缩放行为、染色质纤维的动力学、分子扩散和其他测量结果一致。此外,所有其他的染色体拓扑结构原则上都可以被排除在外。总之,与实验数据相比,全细胞核的聚合物模拟不仅明显倾向于稳定的环聚集体/玫瑰花状基因组结构,其局部拓扑结构与细胞核的整体形态和动力学紧密相连,因此可用于理解基因组组织,也可用于诊断和治疗。这与基因组出现、功能和进化的一般新框架是一致的,也导致了这一框架。
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来源期刊
Results and Problems in Cell Differentiation
Results and Problems in Cell Differentiation Biochemistry, Genetics and Molecular Biology-Developmental Biology
CiteScore
1.90
自引率
0.00%
发文量
21
期刊介绍: Results and Problems in Cell Differentiation is an up-to-date book series that presents and explores selected questions of cell and developmental biology. Each volume focuses on a single, well-defined topic. Reviews address basic questions and phenomena, but also provide concise information on the most recent advances. Together, the volumes provide a valuable overview of this exciting and dynamically expanding field.
期刊最新文献
Early Syncytialization of the Ovine Placenta Revisited. HIV-1 Induced Cell-to-Cell Fusion or Syncytium Formation. Mathematical Modeling of Virus-Mediated Syncytia Formation: Past Successes and Future Directions. Muscle Progenitor Cell Fusion in the Maintenance of Skeletal Muscle. Osteoclasts at Bone Remodeling: Order from Order.
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