Ribosome profiling reveals the rhythmic liver translatome and circadian clock regulation by upstream open reading frames

Mammalian gene expression displays widespread circadian oscillations. Rhythmic transcription underlies the core clock mechanism, but it cannot explain numerous observations made at the level of protein rhythmicity. We have used ribosome profiling in mouse liver to measure the translation of mRNAs in...

Full description

Saved in:
Bibliographic Details
Published in:Genome research 2015-12, Vol.25 (12), p.1848-1859
Main Authors: Janich, Peggy, Arpat, Alaaddin Bulak, Castelo-Szekely, Violeta, Lopes, Maykel, Gatfield, David
Format: Article
Language:English
Subjects:
5' Untranslated Regions
Animals
Biomarkers
Circadian Clocks - genetics
Circadian Rhythm - genetics
Computational Biology - methods
Gene Expression Profiling
Gene Expression Regulation
Gene Ontology
High-Throughput Nucleotide Sequencing
Liver - metabolism
Male
Mice
Open Reading Frames
Protein Biosynthesis
Response Elements
Ribosomes - genetics
Ribosomes - metabolism
RNA, Messenger - genetics
RNA, Messenger - metabolism
Transcriptome
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Mammalian gene expression displays widespread circadian oscillations. Rhythmic transcription underlies the core clock mechanism, but it cannot explain numerous observations made at the level of protein rhythmicity. We have used ribosome profiling in mouse liver to measure the translation of mRNAs into protein around the clock and at high temporal and nucleotide resolution. We discovered, transcriptome-wide, extensive rhythms in ribosome occupancy and identified a core set of approximately 150 mRNAs subject to particularly robust daily changes in translation efficiency. Cycling proteins produced from nonoscillating transcripts revealed thus-far-unknown rhythmic regulation associated with specific pathways (notably in iron metabolism, through the rhythmic translation of transcripts containing iron responsive elements), and indicated feedback to the rhythmic transcriptome through novel rhythmic transcription factors. Moreover, estimates of relative levels of core clock protein biosynthesis that we deduced from the data explained known features of the circadian clock better than did mRNA expression alone. Finally, we identified uORF translation as a novel regulatory mechanism within the clock circuitry. Consistent with the occurrence of translated uORFs in several core clock transcripts, loss-of-function of Denr, a known regulator of reinitiation after uORF usage and of ribosome recycling, led to circadian period shortening in cells. In summary, our data offer a framework for understanding the dynamics of translational regulation, circadian gene expression, and metabolic control in a solid mammalian organ.
ISSN:1088-9051
1549-5469
DOI:10.1101/gr.195404.115