Inexhaustible hair-cell regeneration in young and aged zebrafish

Inexhaustible hair-cell regeneration in young and aged zebrafish

Animals have evolved two general strategies to counter injury and maintain physiological function. The most prevalent is protection by isolating vital organs into body cavities. However, protection is not optimal for sensory systems because their external components need to be exposed to the environ...

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Bibliographic Details
Published in:Biology open Vol. 4; no. 7; pp. 903 - 909
Main Authors: Pinto-Teixeira, Filipe, Viader-Llargués, Oriol, Torres-Mejía, Elen, Turan, Melissa, González-Gualda, Estela, Pola-Morell, Laura, López-Schier, Hernán
Format: Journal Article
Language:English
Published: England The Company of Biologists Ltd 15-07-2015
Royal Society
The Company of Biologists
Subjects:
Adult
Danio rerio
Epithelium
Hair
Hair cells
Injuries
Lateral line
Life Sciences
Neuromasts
Notch
Organs
Regeneration
Self organization
Sense organs
Sensory systems
Zebrafish
Regeneration
Adult
Lateral line
Self organization
Hair cells
Notch
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Summary:Animals have evolved two general strategies to counter injury and maintain physiological function. The most prevalent is protection by isolating vital organs into body cavities. However, protection is not optimal for sensory systems because their external components need to be exposed to the environment to fulfill their receptive function. Thus, a common strategy to maintain sensory abilities against persistent environmental insult involves repair and regeneration. However, whether age or frequent injuries affect the regenerative capacity of sensory organs remains unknown. We have found that neuromasts of the zebrafish lateral line regenerate mechanosensory hair cells after recurrent severe injuries and in adulthood. Moreover, neuromasts can reverse transient imbalances of Notch signaling that result in defective organ proportions during repair. Our results reveal inextinguishable hair-cell regeneration in the lateral line, and suggest that the neuromast epithelium is formed by plastic territories that are maintained by continuous intercellular communication.
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These authors contributed equally to this work
Present address: New York University, 70 Washington Square South, New York, NY 10012, USA.
Present address: Helmholtz Zentrum München, German Research Center for Environmental Health, Ingolstaedter Landstraße 1, D-85764 Neuherberg, Munich, Germany.
ISSN:2046-6390
2046-6390
DOI:10.1242/bio.012112