Publication date: Available online 19 January 2017
Source:Cell Stem Cell
Author(s): Huanhuan Li, Ping Lai, Jinping Jia, Yawei Song, Qing Xia, Kaimeng Huang, Na He, Wangfang Ping, Jiayu Chen, Zhongzhou Yang, Jiao Li, Mingze Yao, Xiaotao Dong, Jicheng Zhao, Chunhui Hou, Miguel A. Esteban, Shaorong Gao, Duanqing Pei, Andrew P. Hutchins, Hongjie Yao
RNA-binding proteins (RBPs), in addition to their functions in cellular homeostasis, play important roles in lineage specification and maintaining cellular identity. Despite their diverse and essential functions, which touch on nearly all aspects of RNA metabolism, the roles of RBPs in somatic cell reprogramming are poorly understood. Here we show that the DEAD-box RBP DDX5 inhibits reprogramming by repressing the expression and function of the non-canonical polycomb complex 1 (PRC1) subunit RYBP. Disrupting Ddx5 expression improves the efficiency of iPSC generation and impedes processing of miR-125b, leading to Rybp upregulation and suppression of lineage-specific genes via RYBP-dependent ubiquitination of H2AK119. Furthermore, RYBP is required for PRC1-independent recruitment of OCT4 to the promoter of Kdm2b, a histone demethylase gene that promotes reprogramming by reactivating endogenous pluripotency genes. Together, these results reveal important functions of DDX5 in regulating reprogramming and highlight the importance of a Ddx5-miR125b-Rybp axis in controlling cell fate.
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Teaser
RNA-binding proteins have poorly defined roles in somatic cell reprogramming. Li et al. show that the RNA-binding protein DDX5 erects an epigenetic barrier to reprogramming. DDX5 controls RYBP through microRNA-125b to suppress specific somatic genes through deposition of H2AK119ub1 while activating an OCT4-KDM2B pluripotent gene program.http://ift.tt/2jUh0Hh
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