基因组拓扑结构的功能意义。
Functional implications of genome topology.
机构信息
Institut de Génétique Humaine, UPR 1142, Centre National de la Recherche Scientifique, Montpellier, France.
出版信息
Nat Struct Mol Biol. 2013 Mar;20(3):290-9. doi: 10.1038/nsmb.2474.
Abstract
Although genomes are defined by their sequence, the linear arrangement of nucleotides is only their most basic feature. A fundamental property of genomes is their topological organization in three-dimensional space in the intact cell nucleus. The application of imaging methods and genome-wide biochemical approaches, combined with functional data, is revealing the precise nature of genome topology and its regulatory functions in gene expression and genome maintenance. The emerging picture is one of extensive self-enforcing feedback between activity and spatial organization of the genome, suggestive of a self-organizing and self-perpetuating system that uses epigenetic dynamics to regulate genome function in response to regulatory cues and to propagate cell-fate memory.
摘要
尽管基因组是由其序列定义的,但核苷酸的线性排列只是其最基本的特征。基因组的一个基本特性是它们在完整细胞核内的三维空间中的拓扑组织。成像方法和全基因组生化方法的应用,结合功能数据,正在揭示基因组拓扑结构的精确性质及其在基因表达和基因组维持中的调节功能。新兴的图景是基因组活性和空间组织之间广泛的自我强化反馈,暗示着一个自我组织和自我维持的系统,利用表观遗传动力学来调节基因组功能以响应调节信号,并传播细胞命运记忆。
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