PHC1 Maintains Pluripotency by Organizing Genome-wide Chromatin Interactions of the Nanog Locus

Overview

Journal Nat Commun

Specialty Biology

Date 2021 May 15

PMID 33990559

Citations 12

Authors

Li Chen

Qiaoqiao Tong

Xiaowen Chen

Penglei Jiang

Hua Yu

Qianbing Zhao

Lingang Sun

Chao Liu

Bin Gu

Yuping Zheng

Lijiang Fei

Xiao Jiang

Wenjuan Li

Giacomo Volpe

Mazid Md Abdul

Guoji Guo

Jin Zhang

Pengxu Qian

Qiming Sun

Dante Neculai

Miguel A Esteban

Chen Li

Feiqiu Wen

Junfeng Ji

Affiliations

Soon will be listed here.

Abstract

Polycomb group (PcG) proteins maintain cell identity by repressing gene expression during development. Surprisingly, emerging studies have recently reported that a number of PcG proteins directly activate gene expression during cell fate determination process. However, the mechanisms by which they direct gene activation in pluripotency remain poorly understood. Here, we show that Phc1, a subunit of canonical polycomb repressive complex 1 (cPRC1), can exert its function in pluripotency maintenance via a PRC1-independent activation of Nanog. Ablation of Phc1 reduces the expression of Nanog and overexpression of Nanog partially rescues impaired pluripotency caused by Phc1 depletion. We find that Phc1 interacts with Nanog and activates Nanog transcription by stabilizing the genome-wide chromatin interactions of the Nanog locus. This adds to the already known canonical function of PRC1 in pluripotency maintenance via a PRC1-dependent repression of differentiation genes. Overall, our study reveals a function of Phc1 to activate Nanog transcription through regulating chromatin architecture and proposes a paradigm for PcG proteins to maintain pluripotency.

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