The NORAD lncRNA assembles a topoisomerase complex critical for genome stability

Creators: Munschauer, Mathias; Nguyen, Celina T.; Sirokman, Klara; Hartigan, Christina R.; Hogstrom, Larson; Engreitz, Jesse M.; Ulirsch, Jacob C.; Fulco, Charles P.; Subramanian, Vidya; Chen, Jenny; Schenone, Monica; Guttman, Mitchell; Carr, Steven A.; Lander, Eric S.

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Abstract

The human genome contains thousands of long non-coding RNAs, but specific biological functions and biochemical mechanisms have been discovered for only about a dozen. A specific long non-coding RNA—non-coding RNA activated by DNA damage (NORAD)—has recently been shown to be required for maintaining genomic stability, but its molecular mechanism is unknown. Here we combine RNA antisense purification and quantitative mass spectrometry to identify proteins that directly interact with NORAD in living cells. We show that NORAD interacts with proteins involved in DNA replication and repair in steady-state cells and localizes to the nucleus upon stimulation with replication stress or DNA damage. In particular, NORAD interacts with RBMX, a component of the DNA-damage response, and contains the strongest RBMX-binding site in the transcriptome. We demonstrate that NORAD controls the ability of RBMX to assemble a ribonucleoprotein complex—which we term NORAD-activated ribonucleoprotein complex 1 (NARC1)—that contains the known suppressors of genomic instability topoisomerase I (TOP1), ALYREF and the PRPF19–CDC5L complex. Cells depleted for NORAD or RBMX display an increased frequency of chromosome segregation defects, reduced replication-fork velocity and altered cell-cycle progression—which represent phenotypes that are mechanistically linked to TOP1 and PRPF19–CDC5L function. Expression of NORAD in trans can rescue defects caused by NORAD depletion, but rescue is significantly impaired when the RBMX-binding site in NORAD is deleted. Our results demonstrate that the interaction between NORAD and RBMX is important for NORAD function, and that NORAD is required for the assembly of the previously unknown topoisomerase complex NARC1, which contributes to maintaining genomic stability. In addition, we uncover a previously unknown function for long non-coding RNAs in modulating the ability of an RNA-binding protein to assemble a higher-order ribonucleoprotein complex.

Additional Information

© 2018 Springer Nature Limited. Received: 10 January 2018; Accepted: 17 July 2018; Published online 27 August 2018. We thank C. A. McHugh for help setting up RAP MS; K. A. Knouse for help imaging mitotic cells; C. W. Garvie for help with size-exclusion chromatography; L. Ludwig for help with cell-cycle data visualization; L. Gaffney for artwork; T. Wang, B. Cleary, S. R. Grossman, M. Yassour, C. M. Vockley, B. Cimini, K. W. Karhohs, M. Doan, S. A. Myers, D. R. Mani and V. G. Sankaran for discussions. M.M. is supported by a Deutsche Forschungsgemeinschaft (DFG) Research Fellowship. J.M.E. is supported by the Harvard Society of Fellows. M.G. is supported by an NIH Director's Early Independence Award (DP5OD012190), the NIH 4DN program Nucleome Project (U01 DA040612 and U01 HL130007), the New York Stem Cell Foundation, the Edward Mallinckrodt Foundation, Sontag Foundation, Searle Scholars Program, Pew-Steward Scholars program and funds from the California Institute of Technology. M.G. is a NYSCF-Robertson Investigator. Work in the Lander Laboratory is supported by the Broad Institute. Reviewer information: Nature thanks R. Bonasio, S. Diedrichs and the other anonymous reviewer(s) for their contribution to the peer review of this work. Author Contributions: M.M. and E.S.L. conceived and designed the study. M.M. performed and analysed all experiments; C.T.N. and K.S. assisted with several experiments, including CLIP. V.S. helped with RNA FISH experiments. C.T.N. analysed RNA FISH and PLA images. C.R.H. collected mass spectrometry data under supervision of M.S. and S.A.C. and helped with design of mass spectrometry experiments. M.G. helped setting up RAP MS, L.H. and J.M.E. developed computational tools and analysed CLIP data. J.M.E. and C.P.F. helped with CRISPR interference and contributed analytical ideas. J.C. performed evolutionary analysis. J.C.U. performed differential gene expression and alternative splicing analysis. M.M. and E.S.L. wrote the manuscript with input from all authors. E.S.L. supervised the work and obtained funding. Competing interests: The Broad Institute holds patents and has filed patent applications on technologies related to other aspects of CRISPR. Reporting summary: Further information on research design is available in the Nature Research Reporting Summary linked to this paper. Code availability: Code for the analyses described in this paper is available from the corresponding authors upon request. Data availability: Sequencing data for this study are available at the Gene Expression Omnibus under the accession number GSE114953. The original mass spectra may be downloaded from MassIVE (http://massive.ucsd.edu) using the identifier: MSV000082561. The data are directly accessible via ftp://massive.ucsd.edu/MSV000082561. All other data are available from the corresponding authors upon reasonable request.

Errata

In the 'Reviewer information' section of this Letter, 'S. Diederichs' was incorrectly listed as 'S. Diedrichs'; this has been corrected online.

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Resource type: Journal Article
Publisher: Nature Publishing Group
Published in: Nature, 561(7721), 132-136, ISSN: 0028-0836.