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Nature DOI:10.1038/nature12894

Genome-wide probing of RNA structure reveals active unfolding of mRNA structures in vivo.

Publication TypeJournal Article
Year of Publication2014
AuthorsRouskin, S, Zubradt, M, Washietl, S, Kellis, M, Weissman, JS
Date Published2014 Jan 30
KeywordsFibroblasts, Genome, Fungal, High-Throughput Nucleotide Sequencing, Humans, K562 Cells, Nucleic Acid Conformation, Nucleic Acid Denaturation, RNA Folding, RNA Stability, RNA, Fungal, RNA, Messenger, Saccharomyces cerevisiae, Sulfuric Acid Esters, Thermodynamics

RNA has a dual role as an informational molecule and a direct effector of biological tasks. The latter function is enabled by RNA's ability to adopt complex secondary and tertiary folds and thus has motivated extensive computational and experimental efforts for determining RNA structures. Existing approaches for evaluating RNA structure have been largely limited to in vitro systems, yet the thermodynamic forces which drive RNA folding in vitro may not be sufficient to predict stable RNA structures in vivo. Indeed, the presence of RNA-binding proteins and ATP-dependent helicases can influence which structures are present inside cells. Here we present an approach for globally monitoring RNA structure in native conditions in vivo with single-nucleotide precision. This method is based on in vivo modification with dimethyl sulphate (DMS), which reacts with unpaired adenine and cytosine residues, followed by deep sequencing to monitor modifications. Our data from yeast and mammalian cells are in excellent agreement with known messenger RNA structures and with the high-resolution crystal structure of the Saccharomyces cerevisiae ribosome. Comparison between in vivo and in vitro data reveals that in rapidly dividing cells there are vastly fewer structured mRNA regions in vivo than in vitro. Even thermostable RNA structures are often denatured in cells, highlighting the importance of cellular processes in regulating RNA structure. Indeed, analysis of mRNA structure under ATP-depleted conditions in yeast shows that energy-dependent processes strongly contribute to the predominantly unfolded state of mRNAs inside cells. Our studies broadly enable the functional analysis of physiological RNA structures and reveal that, in contrast to the Anfinsen view of protein folding whereby the structure formed is the most thermodynamically favourable, thermodynamics have an incomplete role in determining mRNA structure in vivo.


Alternate JournalNature
PubMed ID24336214
PubMed Central IDPMC3966492
Grant ListP50 GM102706 / GM / NIGMS NIH HHS / United States
R01 HG004037 / HG / NHGRI NIH HHS / United States
/ / Howard Hughes Medical Institute / United States