胚胎干细胞的转录调控网络。

Yun Shen Chan, Lin Yang, Huck-Hui Ng
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引用次数: 75

摘要

转录调控是生物学中最基本的过程之一,控制着细胞的形态、功能和行为,从而影响着生物体的生存。胚胎干细胞(ESC)为理解脊椎动物系统的转录调控提供了一个很好的模型。最近的努力已经导致鉴定分子事件,赋予这些细胞的多能性和自我更新的独特性质。维持ESC身份的核心监管网络包括三个主要监管机构:Oct4、Sox2和Nanog。询问这些和其他转录因子结合位点的大规模作图研究显示,不同的转录因子组共占用。多转录因子复合物的组装可能是调节esc特异性基因表达的一种机制。这些研究也开始揭示控制ESC身份的转录调控网络。功能缺失RNAi筛选也发现了参与ESC状态稳定传播的新调控分子。这证明了一个ESC转录调控程序,在这个程序中,涉及大量转录因子和表观遗传修饰因子的相互关联的转录调控网络协同作用于ESC和分化特异性基因,以实现细胞状态的稳定。本章追溯了过去十年来在剖析控制ESC身份的转录调控网络方面所做的主要努力,并提供了该领域未来发展方向的观点。
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Transcriptional regulatory networks in embryonic stem cells.

Transcriptional regulation is one of the most fundamental processes in biology, governing the morphology, function, and behavior of cells and thus the survival of organisms. The embryonic stem cell (ESC) provides a good model for the understanding of transcriptional regulation in vertebrate systems. Recent efforts have led to the identification of molecular events, which confer upon these cells the unique properties of pluripotency and self renewal. The core regulatory network maintaining the ESC identity involves three master regulators: Oct4, Sox2, and Nanog. Large-scale mapping studies interrogating the binding sites of these and other transcription factors showed co-occupancy of distinct sets of transcription factors. The assembly of multitranscription factor complexes could serve as a mechanism for providing specificity in regulating ESC-specific gene expression. These studies are also beginning to unravel the transcriptional regulatory networks that govern the ESC identity. Loss-of-function RNAi screens also identified novel regulatory molecules involved in the stable propagation of the ESC state. This argues for an ESC transcriptional regulation program in which interconnected transcriptional regulatory networks involving large numbers of transcription factors and epigenetic modifiers work in concert on ESC- and differentiation-specific genes to achieve cell state stability. This chapter traces the major efforts made over the past decade in dissecting the transcriptional regulatory network governing ESC identity and offers perspectives on the future directions of the field.

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