Wound healing: Surprising support from distant sources.

The resurfacing of cutaneous wounds in mammals takes up to several weeks, but in zebrafish complete coverage is achieved within hours. New work uncovers that the rapid wound healing on zebrafish body surfaces involves the mobilization of fin-resident epithelial cells.

The fin roundabout: Slit-Robo and S1P signaling coordinate fin morphogenesis.

Development of vertebrate limbs and fins requires that tissue growth is directed outwards, away from the body. How such directed growth is achieved is a fascinating biological problem. For limb/fin formation and outgrowth, signaling between mesenchymal cells and the overlying epithelium is essential.

Zebrafish fin regeneration involves generic and regeneration-specific osteoblast injury responses.

Successful regeneration requires the coordinated execution of multiple cellular responses to injury. In amputated zebrafish fins, mature osteoblasts dedifferentiate, migrate towards the injury, and form proliferative osteogenic blastema cells. We show that osteoblast migration is preceded by cell elongation and alignment along the proximodistal axis, which require actomyosin, but not microtubule (MT) turnover.

Zebrafish Fin: Complex Molecular Interactions and Cellular Mechanisms Guiding Regeneration.

The zebrafish caudal fin has become a popular model to study cellular and molecular mechanisms of regeneration due to its high regenerative capacity, accessibility for experimental manipulations, and relatively simple anatomy. The formation of a regenerative epidermis and blastema are crucial initial events and tightly regulated. Both the regenerative epidermis and the blastema are highly organized structures containing distinct domains, and several signaling pathways regulate the formation and interaction of these domains.

NF-κB Signaling Negatively Regulates Osteoblast Dedifferentiation during Zebrafish Bone Regeneration.

Dedifferentiation of mature cells is an intriguing cellular process associated with regeneration of several organs. During zebrafish fin regeneration, osteoblasts dedifferentiate to osteogenic progenitors that provide source cells for bone restoration. We performed a high-content in vivo chemical screen for regulators of osteoblast dedifferentiation and fin regenerative growth.