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prdm1a drives a fate switch between hair cells of different mechanosensory organs

Author

Listed:
  • Jeremy E. Sandler

    (Stowers Institute for Medical Research)

  • Ya-Yin Tsai

    (Stowers Institute for Medical Research)

  • Shiyuan Chen

    (Stowers Institute for Medical Research)

  • Logan Sabin

    (Stowers Institute for Medical Research)

  • Mark E. Lush

    (Stowers Institute for Medical Research)

  • Abhinav Sur

    (Eunice Kennedy Shriver National Institute of Child Health and Human Development)

  • Elizabeth Ellis

    (Stowers Institute for Medical Research)

  • Nhung T. T. Tran

    (Stowers Institute for Medical Research)

  • Malcolm Cook

    (Stowers Institute for Medical Research)

  • Allison R. Scott

    (Stowers Institute for Medical Research)

  • Jonathan S. Kniss

    (Stowers Institute for Medical Research
    Fredonia State University of New York)

  • Jeffrey A. Farrell

    (Eunice Kennedy Shriver National Institute of Child Health and Human Development)

  • Tatjana Piotrowski

    (Stowers Institute for Medical Research)

Abstract

Vertebrate inner ear mechanosensory hair cells detect sound and gravitational forces. Additionally, fishes have homologous lateral line hair cells in the skin that detect water vibrations for orientation and predator avoidance. Hair cells in the lateral line and ear of fishes and other non-mammalian vertebrates regenerate readily after damage, but mammalians lack this ability, causing deafness and vestibular defects. As yet, experimental attempts at hair cell regeneration in mice result in incompletely differentiated and immature hair cells. Despite differences in regeneration capabilities, the gene regulatory networks (GRNs) driving hair cell maturation during development are highly similar across vertebrates. Here, we show that the transcription factor prdm1a plays a key role in the hair cell fate GRN in the zebrafish lateral line. Mutating prdm1a respecifies lateral line hair cells into ear hair cells, altering morphology and transcriptome. Understanding how transcription factors control diverse hair cell fates in zebrafish is crucial for understanding the yet unsolved regeneration of diverse hair cells in mammalian ears to restore hearing and balance.

Suggested Citation

  • Jeremy E. Sandler & Ya-Yin Tsai & Shiyuan Chen & Logan Sabin & Mark E. Lush & Abhinav Sur & Elizabeth Ellis & Nhung T. T. Tran & Malcolm Cook & Allison R. Scott & Jonathan S. Kniss & Jeffrey A. Farrel, 2025. "prdm1a drives a fate switch between hair cells of different mechanosensory organs," Nature Communications, Nature, vol. 16(1), pages 1-15, December.
    • Handle: RePEc:nat:natcom:v:16:y:2025:i:1:d:10.1038_s41467-025-62942-0
    DOI: 10.1038/s41467-025-62942-0
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    References listed on IDEAS

    as
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