PLoS Biology (Apr 2017)

Transcriptional regulatory logic of the diurnal cycle in the mouse liver.

  • Jonathan Aryeh Sobel,
  • Irina Krier,
  • Teemu Andersin,
  • Sunil Raghav,
  • Donatella Canella,
  • Federica Gilardi,
  • Alexandra Styliani Kalantzi,
  • Guillaume Rey,
  • Benjamin Weger,
  • Frédéric Gachon,
  • Matteo Dal Peraro,
  • Nouria Hernandez,
  • Ueli Schibler,
  • Bart Deplancke,
  • Felix Naef,
  • CycliX consortium

DOI
https://doi.org/10.1371/journal.pbio.2001069
Journal volume & issue
Vol. 15, no. 4
p. e2001069

Abstract

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Many organisms exhibit temporal rhythms in gene expression that propel diurnal cycles in physiology. In the liver of mammals, these rhythms are controlled by transcription-translation feedback loops of the core circadian clock and by feeding-fasting cycles. To better understand the regulatory interplay between the circadian clock and feeding rhythms, we mapped DNase I hypersensitive sites (DHSs) in the mouse liver during a diurnal cycle. The intensity of DNase I cleavages cycled at a substantial fraction of all DHSs, suggesting that DHSs harbor regulatory elements that control rhythmic transcription. Using chromatin immunoprecipitation followed by DNA sequencing (ChIP-seq), we found that hypersensitivity cycled in phase with RNA polymerase II (Pol II) loading and H3K27ac histone marks. We then combined the DHSs with temporal Pol II profiles in wild-type (WT) and Bmal1-/- livers to computationally identify transcription factors through which the core clock and feeding-fasting cycles control diurnal rhythms in transcription. While a similar number of mRNAs accumulated rhythmically in Bmal1-/- compared to WT livers, the amplitudes in Bmal1-/- were generally lower. The residual rhythms in Bmal1-/- reflected transcriptional regulators mediating feeding-fasting responses as well as responses to rhythmic systemic signals. Finally, the analysis of DNase I cuts at nucleotide resolution showed dynamically changing footprints consistent with dynamic binding of CLOCK:BMAL1 complexes. Structural modeling suggested that these footprints are driven by a transient heterotetramer binding configuration at peak activity. Together, our temporal DNase I mappings allowed us to decipher the global regulation of diurnal transcription rhythms in the mouse liver.