[PhD Thesis Presentation_Zoom] - Po-Shun Chuang - "From Polyps to Colonies: Applying polyp bail-out to study coral coloniality"
Presenter: Po-Shun Chuang
Supervisor: Satoshi Mitarai
Unit: Marine Biophysics
Zoom URL: to be available 48 hours prior to the examination
Title: From Polyps to Colonies: Applying polyp bail-out to study coral coloniality
Colonial lifestyles have been adopted by the majority of shallow-water stony corals (Cnidaria; Scleractinia), as they facilitate coral responses to environmental changes. Polyp bail-out, a coral stress response featuring colony dissociation and polyp detachment, offers a platform to study coloniality in stony corals. However, employing bailed-out polyps in coral research requires greater understanding of the biology of this stress response.
This thesis investigates the molecular basis of polyp bail-out in Pocillopora acuta, a branching coral that is common in the oceans around Okinawa, Japan, and examines bailed-out polyps to study the biological foundation of coral coloniality. First, I probe molecular mechanisms involved in hyperosmosis-induced polyp bail-out, based upon a P. acuta transcriptome assembly. Then, I monitor morphological and genetic changes of solitary P. acuta polyps after the induced bail-out response. Finally, I explore transcriptional profiles of bailed-out polyps and those of intact colonies in order to identify differences between corals at different levels of structural and social complexity.
Based on transcriptomic data, activation of TNF and FGF signaling pathways was identified during initiation of polyp bail-out, possibly linking them to the colony-dissociation and polyp-detachment processes in bail-out, respectively. Under ambient conditions, about half of bailed-out polyps displayed morphological recovery and genetic resumption of fundamental cellular processes within five days. When compared to recovered solitary polyps, healthy colonies showed activation of genes for neurological and circulatory system development and those with potential molecular transport regulatory functions. Furthermore, in response to environmental stresses, few genetic changes were shared by polyps and colonies, suggesting that coloniality promotes distinctively different stress responses, probably enhancing fitness in stony corals. Interestingly, transcriptomic data also revealed possible participation of the activin signaling system in development of coloniality.
This thesis presents a robust polyp bail-out induction protocol and develops a foundation for its application to coral research. Using this new research model, this thesis presents the first molecular-level study of coral coloniality and identifies genes potentially participating in functional integration of coral colonies, which are expected to be fruitful topics for future studies.