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Literature DB >> 28355564

SMARCAD1 Contributes to the Regulation of Naive Pluripotency by Interacting with Histone Citrullination.

Shu Xiao¹, Jia Lu¹, Bharat Sridhar², Xiaoyi Cao¹, Pengfei Yu¹, Tianyi Zhao¹, Chieh-Chun Chen³, Darina McDee¹, Laura Sloofman³, Yang Wang⁴, Marcelo Rivas-Astroza¹, Bhanu Prakash V L Telugu⁵, Dana Levasseur⁶, Kang Zhang⁷, Han Liang⁸, Jing Crystal Zhao⁴, Tetsuya S Tanaka³, Gary Stormo⁹, Sheng Zhong¹⁰.

Abstract

Histone citrullination regulates diverse cellular processes. Here, we report that SMARCAD1 preferentially associates with H3 arginine 26 citrullination (H3R26Cit) peptides present on arrays composed of 384 histone peptides harboring distinct post-transcriptional modifications. Among ten histone modifications assayed by ChIP-seq, H3R26Cit exhibited the most extensive genomewide co-localization with SMARCAD1 binding. Increased Smarcad1 expression correlated with naive pluripotency in pre-implantation embryos. In the presence of LIF, Smarcad1 knockdown (KD) embryonic stem cells lost naive state phenotypes but remained pluripotent, as suggested by morphology, gene expression, histone modifications, alkaline phosphatase activity, energy metabolism, embryoid bodies, teratoma, and chimeras. The majority of H3R26Cit ChIP-seq peaks occupied by SMARCAD1 were associated with increased levels of H3K9me3 in Smarcad1 KD cells. Inhibition of H3Cit induced H3K9me3 at the overlapping regions of H3R26Cit peaks and SMARCAD1 peaks. These data suggest a model in which SMARCAD1 regulates naive pluripotency by interacting with H3R26Cit and suppressing heterochromatin formation.

Entities: CellLine Chemical Disease Gene Species

Keywords: ChIP-seq; SMARCAD1; citrullination; histone modification; naive state; pluripotency; protein array; stem cells

Mesh：

Substances：

Year: 2017 PMID： 28355564 PMCID： PMC5466819 DOI： 10.1016/j.celrep.2017.02.070

Source DB: PubMed Journal: Cell Rep Impact factor: 9.423

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