染色质
X-失活
转录组
生物
基因组
染色体构象捕获
染色体
基因
遗传学
X染色体
细胞生物学
胚胎干细胞
基因沉默
染色质重塑
剂量补偿
动力学(音乐)
分子生物学
西斯特
计算生物学
细胞
人类基因组
基因表达调控
作者
Wenbo Liu,Hao Xie,Zhiyuan Liu,Yujie Chen,Qimin Xia,Heming Xu,Yi Chi,Shuai Gao,Xing Dq
标识
DOI:10.1093/gpbjnl/qzag002
摘要
X chromosome inactivation is a process that compensates X-linked gene dosage in mammalian female cells. The silencing of a randomly selected chromosome is accompanied by dramatic three-dimensional reorganization across the entire chromosome. To investigate the four-dimensional chromatin dynamics during early inactivation stages, we applied the multi-omics sequencing technique HiRES (Hi-C and RNA-seq employed simultaneously), which simultaneously detects the three-dimensional genome and transcriptome in single cells, in a mouse embryonic stem cell line with induced random inactivation. This three-dimensional genome and transcriptome dual-omics data allowed us to identify random inactivation trajectories at single-cell resolution. We characterized multiple layers of X-chromosome reorganization and discovered a transient structural state shared by both X chromosomes, associated with biallelic X-inactive specific transcript (Xist) expression. By constructing single-cell inactivation trajectories, we found that most chromatin remodeling either accompanied or followed gene silencing. Further analysis of interaction decay kinetics revealed that topologically associating domain (TAD) attenuation began from loss of interactions on TAD anchors. This study thus provides a detailed depiction of fine-scale chromatin reorganization during the initiation of random X chromosome inactivation.
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