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Transcription factor-driven coordination of cell cycle exit and lineage-specification in vivo during granulocytic differentiation

Author

Listed:
  • Kim Theilgaard-Mönch

    (University of Copenhagen
    University of Copenhagen
    University of Copenhagen
    Rigshospitalet)

  • Sachin Pundhir

    (University of Copenhagen
    University of Copenhagen
    University of Copenhagen
    University of Copenhagen)

  • Kristian Reckzeh

    (University of Copenhagen
    University of Copenhagen
    University of Copenhagen)

  • Jinyu Su

    (University of Copenhagen
    University of Copenhagen
    University of Copenhagen)

  • Marta Tapia

    (University of Copenhagen
    University of Copenhagen
    University of Copenhagen)

  • Benjamin Furtwängler

    (University of Copenhagen
    University of Copenhagen
    University of Copenhagen)

  • Johan Jendholm

    (University of Copenhagen
    University of Copenhagen
    University of Copenhagen)

  • Janus Schou Jakobsen

    (University of Copenhagen
    University of Copenhagen
    University of Copenhagen)

  • Marie Sigurd Hasemann

    (University of Copenhagen
    University of Copenhagen
    University of Copenhagen)

  • Kasper Jermiin Knudsen

    (University of Copenhagen
    University of Copenhagen
    University of Copenhagen)

  • Jack Bernard Cowland

    (Rigshospitalet
    Rigshospitalet)

  • Anna Fossum

    (University of Copenhagen)

  • Erwin Schoof

    (University of Copenhagen
    University of Copenhagen
    University of Copenhagen
    Technical University of Denmark)

  • Mikkel Bruhn Schuster

    (University of Copenhagen
    University of Copenhagen
    University of Copenhagen)

  • Bo T. Porse

    (University of Copenhagen
    University of Copenhagen
    University of Copenhagen)

Abstract

Differentiation of multipotent stem cells into mature cells is fundamental for development and homeostasis of mammalian tissues, and requires the coordinated induction of lineage-specific transcriptional programs and cell cycle withdrawal. To understand the underlying regulatory mechanisms of this fundamental process, we investigated how the tissue-specific transcription factors, CEBPA and CEBPE, coordinate cell cycle exit and lineage-specification in vivo during granulocytic differentiation. We demonstrate that CEBPA promotes lineage-specification by launching an enhancer-primed differentiation program and direct activation of CEBPE expression. Subsequently, CEBPE confers promoter-driven cell cycle exit by sequential repression of MYC target gene expression at the G1/S transition and E2F-meditated G2/M gene expression, as well as by the up-regulation of Cdk1/2/4 inhibitors. Following cell cycle exit, CEBPE unleashes the CEBPA-primed differentiation program to generate mature granulocytes. These findings highlight how tissue-specific transcription factors coordinate cell cycle exit with differentiation through the use of distinct gene regulatory elements.

Suggested Citation

  • Kim Theilgaard-Mönch & Sachin Pundhir & Kristian Reckzeh & Jinyu Su & Marta Tapia & Benjamin Furtwängler & Johan Jendholm & Janus Schou Jakobsen & Marie Sigurd Hasemann & Kasper Jermiin Knudsen & Jack, 2022. "Transcription factor-driven coordination of cell cycle exit and lineage-specification in vivo during granulocytic differentiation," Nature Communications, Nature, vol. 13(1), pages 1-17, December.
    • Handle: RePEc:nat:natcom:v:13:y:2022:i:1:d:10.1038_s41467-022-31332-1
    DOI: 10.1038/s41467-022-31332-1
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    References listed on IDEAS

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    1. Darren A. Cusanovich & James P. Reddington & David A. Garfield & Riza M. Daza & Delasa Aghamirzaie & Raquel Marco-Ferreres & Hannah A. Pliner & Lena Christiansen & Xiaojie Qiu & Frank J. Steemers & Co, 2018. "The cis-regulatory dynamics of embryonic development at single-cell resolution," Nature, Nature, vol. 555(7697), pages 538-542, March.
    2. Erwin M. Schoof & Benjamin Furtwängler & Nil Üresin & Nicolas Rapin & Simonas Savickas & Coline Gentil & Eric Lechman & Ulrich auf dem Keller & John E. Dick & Bo T. Porse, 2021. "Quantitative single-cell proteomics as a tool to characterize cellular hierarchies," Nature Communications, Nature, vol. 12(1), pages 1-15, December.
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