拓扑相关结构域:一个不变的框架还是一个动态的支架?
Topologically Associating Domains: An invariant framework or a dynamic scaffold?
作者信息
Cubeñas-Potts Caelin, Corces Victor G
机构信息
a Department of Biology ; Emory University ; Atlanta , GA USA.
出版信息
Nucleus. 2015;6(6):430-4. doi: 10.1080/19491034.2015.1096467. Epub 2015 Sep 29.
Abstract
Metazoan genomes are organized into regions of topologically associating domains (TADs). TADs are demarcated by border elements, which are enriched for active genes and high occupancy architectural protein binding sites. We recently demonstrated that 3D chromatin architecture is dynamic in response to heat shock, a physiological stress that downregulates transcription and causes a global redistribution of architectural proteins. We utilized a quantitative measure of border strength after heat shock, transcriptional inhibition, and architectural protein knockdown to demonstrate that changes in both transcription and architectural protein occupancy contribute to heat shock-induced TAD dynamics. Notably, architectural proteins appear to play a more important role in altering 3D chromatin architecture. Here, we discuss the implications of our findings on previous studies evaluating the dynamics of TAD structure during cellular differentiation. We propose that the subset of variable TADs observed after differentiation are representative of cell-type specific gene expression and are biologically significant.
摘要
后生动物基因组被组织成拓扑相关结构域(TADs)区域。TADs由边界元件界定,边界元件富含活性基因和高占有率的结构蛋白结合位点。我们最近证明,三维染色质结构在热休克反应中是动态的,热休克是一种生理应激,它会下调转录并导致结构蛋白的全局重新分布。我们利用热休克、转录抑制和结构蛋白敲低后边界强度的定量测量,来证明转录和结构蛋白占有率的变化都有助于热休克诱导的TAD动态变化。值得注意的是,结构蛋白似乎在改变三维染色质结构中起更重要的作用。在这里,我们讨论了我们的发现对先前评估细胞分化过程中TAD结构动态的研究的影响。我们提出,分化后观察到的可变TAD子集代表了细胞类型特异性基因表达,并且具有生物学意义。
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