Structural modularity of the XIST ribonucleoprotein complex

Zhipeng Lu; Jimmy K Guo; Yuning Wei; Diana R Dou; Brian Zarnegar; Qing Ma; Rui Li; Yang Zhao; Fan Liu; Hani Choudhry; Paul A Khavari; Howard Y Chang

doi:10.1038/s41467-020-20040-3

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Structural modularity of the XIST ribonucleoprotein complex

Journal article

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Structural modularity of the XIST ribonucleoprotein complex

Zhipeng Lu, Jimmy K Guo, Yuning Wei, Diana R Dou, Brian Zarnegar, Qing Ma, Rui Li, Yang Zhao, Fan Liu, Hani Choudhry, …

Nature communications, Vol.11(1), pp.6163-6163

02/12/2020

DOI: https://doi.org/10.1038/s41467-020-20040-3

PMID: 33268787

Abstract

Adenine - analogs & derivatives

Adenine - metabolism

Animals

Base Sequence

Cell Line

Conserved Sequence

CRISPR-Cas Systems

Cross-Linking Reagents

Female

Ficusin - chemistry

Formaldehyde - chemistry

Gene Knock-In Techniques

Humans

K562 Cells

Male

Mice

Mouse Embryonic Stem Cells - cytology

Mouse Embryonic Stem Cells - metabolism

Nucleic Acid Conformation

Pregnancy

Ribonucleoproteins - chemistry

Ribonucleoproteins - genetics

Ribonucleoproteins - metabolism

RNA, Long Noncoding - chemistry

RNA, Long Noncoding - genetics

RNA, Long Noncoding - metabolism

Sequence Analysis, RNA

Long noncoding RNAs are thought to regulate gene expression by organizing protein complexes through unclear mechanisms. XIST controls the inactivation of an entire X chromosome in female placental mammals. Here we develop and integrate several orthogonal structure-interaction methods to demonstrate that XIST RNA-protein complex folds into an evolutionarily conserved modular architecture. Chimeric RNAs and clustered protein binding in fRIP and eCLIP experiments align with long-range RNA secondary structure, revealing discrete XIST domains that interact with distinct sets of effector proteins. CRISPR-Cas9-mediated permutation of the Xist A-repeat location shows that A-repeat serves as a nucleation center for multiple Xist-associated proteins and m A modification. Thus modular architecture plays an essential role, in addition to sequence motifs, in determining the specificity of RBP binding and m A modification. Together, this work builds a comprehensive structure-function model for the XIST RNA-protein complex, and suggests a general strategy for mechanistic studies of large ribonucleoprotein assemblies.

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Title: Structural modularity of the XIST ribonucleoprotein complex
Creators - without role: Zhipeng Lu - Stanford University
Jimmy K Guo - Stanford University
Yuning Wei - Stanford University
Diana R Dou - Stanford University
Brian Zarnegar - Stanford University
Qing Ma - Stanford University
Rui Li - Stanford University
Yang Zhao - Stanford University
Fan Liu - Stanford University
Hani Choudhry - Stanford University
Paul A Khavari - Stanford University
Howard Y Chang - Stanford University
Publication Details: Nature communications, Vol.11(1), pp.6163-6163
Grant note: RM1 HG007735 / NHGRI NIH HHS R01 HG004361 / NHGRI NIH HHS P50 HG007735 / NHGRI NIH HHS R00 HG009662 / NHGRI NIH HHS P30 CA014089 / NCI NIH HHS Howard Hughes Medical Institute
Identifiers: 9939843708331
Academic Unit: King Abdulaziz University
Language: English
Resource Type: Journal article