Branching scleractinian corals are niche-constructing organisms, providing continuouslygrowing,
structural foundation for spectacularly biodiverse coral reef ecosystems.
More...Branching scleractinian corals are niche-constructing organisms, providing continuouslygrowing,
structural foundation for spectacularly biodiverse coral reef ecosystems. A large
part of their success lies in the ability to quickly regenerate following mechanical damage.
Even now, when the corals undergo great decline due to anthropogenic weather and storm
extremes, it is surprising how little is known about molecular mechanisms governing
regeneration in these iconic organisms. In this study, we used RNA-seq to identify genes
involved in the regeneration of Acropora millepora, starting with the initial wound closure
up to complete rebuilding of lost structures. Many of the differentially expressed genes we
found in the wound healing steps are homologues of genes known to be involved in wound
healing and regeneration of bilaterian and other cnidarian species, prominently including
multiple components of FGF and Wnt signalling pathways. Comparison between genes
involved in wound healing and continuous growth of the colony demonstrates both
similarity and distinctiveness of the genetic programs controlling these processes. A striking
example is specific expression of c-Fos, a transcription factor with conserved role in early
injury response, during the earliest stages of wound healing of A. millepora.
By comparing results obtained in diverse experimental conditions including a closed-loop,
recirculating aquarium and a flow-through system of marine station, we have demonstrated
feasibility of using zooxanthellate scleractinian corals as experimental models in
fundamental biology research, including studies of regeneration
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