Differentiated skeletal cells contribute to blastema formation during zebrafish fin regeneration

The origin of cells that generate the blastema following appendage amputation has been a long-standing question in epimorphic regeneration studies. The blastema is thought to originate from either stem (or progenitor) cells or differentiated cells of various tissues that undergo dedifferentiation. H...

Full description

Bibliographic Details
Main Author: Sousa, Sara (author)
Other Authors: Afonso, Nuno (author), Bensimon-Brito, Anabela (author), Fonseca, Mariana (author), Simões, Mariana (author), Leon, Joaquin (author), Roehl, Henry (author), Cancela, M. Leonor (author), Jacinto, António (author)
Format: article
Language:eng
Published: 2018
Subjects:
Limb regeneration
Heart regeneration
Gene-rxpression
Sonic-hedgehog
Dedifferentiation
Proliferation
Tail
Teleosts
Occurs
Acid
Fin regeneration
Skeletal regeneration
Blastema formation
Zebrafish
Online Access:http://hdl.handle.net/10400.1/11943
Country:Portugal
Oai:oai:sapientia.ualg.pt:10400.1/11943
Description
Summary:The origin of cells that generate the blastema following appendage amputation has been a long-standing question in epimorphic regeneration studies. The blastema is thought to originate from either stem (or progenitor) cells or differentiated cells of various tissues that undergo dedifferentiation. Here, we investigate the origin of cells that contribute to the regeneration of zebrafish caudal fin skeletal elements. We provide evidence that the process of lepidotrichia (bony rays) regeneration is initiated as early as 24 hours post-amputation and that differentiated scleroblasts acquire a proliferative state, detach from the lepidotrichia surface, migrate distally, integrate into the blastema and dedifferentiate. These findings provide novel insights into the origin of cells in epimorphic appendage regeneration in zebrafish and suggest conservation of regeneration mechanisms between fish and amphibians.

Similar Items