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Control of osteoblast regeneration by a train of Erk activity waves

Author

Listed:
  • Alessandro De Simone

    (Duke University
    Duke University Medical Center)

  • Maya N. Evanitsky

    (Duke University
    Duke University Medical Center)

  • Luke Hayden

    (Duke University
    Duke University Medical Center)

  • Ben D. Cox

    (Duke University
    Duke University Medical Center
    University of California, Davis)

  • Julia Wang

    (Duke University
    Duke University Medical Center)

  • Valerie A. Tornini

    (Duke University
    Duke University Medical Center
    Yale University School of Medicine)

  • Jianhong Ou

    (Duke University)

  • Anna Chao

    (Duke University
    Duke University Medical Center)

  • Kenneth D. Poss

    (Duke University
    Duke University Medical Center
    Duke University
    Duke University Medical Center)

  • Stefano Di Talia

    (Duke University
    Duke University Medical Center
    Duke University Medical Center)

Abstract

Regeneration is a complex chain of events that restores a tissue to its original size and shape. The tissue-wide coordination of cellular dynamics that is needed for proper morphogenesis is challenged by the large dimensions of regenerating body parts. Feedback mechanisms in biochemical pathways can provide effective communication across great distances1–5, but how they might regulate growth during tissue regeneration is unresolved6,7. Here we report that rhythmic travelling waves of Erk activity control the growth of bone in time and space in regenerating zebrafish scales, millimetre-sized discs of protective body armour. We find that waves of Erk activity travel across the osteoblast population as expanding concentric rings that are broadcast from a central source, inducing ring-like patterns of tissue growth. Using a combination of theoretical and experimental analyses, we show that Erk activity propagates as excitable trigger waves that are able to traverse the entire scale in approximately two days and that the frequency of wave generation controls the rate of scale regeneration. Furthermore, the periodic induction of synchronous, tissue-wide activation of Erk in place of travelling waves impairs tissue growth, which indicates that wave-distributed Erk activation is key to regeneration. Our findings reveal trigger waves as a regulatory strategy to coordinate cell behaviour and instruct tissue form during regeneration.

Suggested Citation

  • Alessandro De Simone & Maya N. Evanitsky & Luke Hayden & Ben D. Cox & Julia Wang & Valerie A. Tornini & Jianhong Ou & Anna Chao & Kenneth D. Poss & Stefano Di Talia, 2021. "Control of osteoblast regeneration by a train of Erk activity waves," Nature, Nature, vol. 590(7844), pages 129-133, February.
    • Handle: RePEc:nat:nature:v:590:y:2021:i:7844:d:10.1038_s41586-020-03085-8
    DOI: 10.1038/s41586-020-03085-8
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    Cited by:

    1. Florian J. Bock & Egor Sedov & Elle Koren & Anna L. Koessinger & Catherine Cloix & Désirée Zerbst & Dimitris Athineos & Jayanthi Anand & Kirsteen J. Campbell & Karen Blyth & Yaron Fuchs & Stephen W. G, 2021. "Apoptotic stress-induced FGF signalling promotes non-cell autonomous resistance to cell death," Nature Communications, Nature, vol. 12(1), pages 1-14, December.
    2. Mikaela L. Follmer & Trevor J. Isner & Yunus H. Ozekin & Claire H. Levitt & Carolyn L. Burek & Richard K. P. Benninger & Emily Anne Bates, 2024. "Depolarization induces calcium-dependent BMP4 release from mouse embryonic palate mesenchymal cells," Nature Communications, Nature, vol. 15(1), pages 1-19, December.

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