Abstract
One of the major events in animal morphogenesis is the emergence of a polar body axis. Here, we combine classic grafting techniques with live imaging to study the emergence of body axis polarity during whole body regeneration in Hydra. Composite tissues are made by fusing two rings, excised from separate animals, in different configurations that vary in the polarity and original positions of the rings along the body axes of the parent animals. Under frustrating initial configurations, body axis polarity that is otherwise stably inherited from the parent animal, can become labile and even be reversed. Importantly, the site of head regeneration exhibits a strong bias toward the edges of the tissue, even when this involves polarity reversal. In particular, we observe head formation at an originally aboral tissue edge, which is not compatible with models of Hydra regeneration based only on preexisting morphogen gradients or an injury response. Rather, we suggest that the structural bias toward head formation at the doublets’ edge is reinforced by the presence of a defect in the organization of the supra-cellular actin fibers, which invariably forms at the edge as the tissue heals. In this scenario, the defect supports head formation at the edge, even though a defect is neither required nor sufficient for head formation. Altogether, our results suggest that body axis determination is an integrated process that arises from the dynamic interplay between mechanical feedback and signaling processes.
Competing Interest Statement
The authors have declared no competing interest.