How a single signaling pathway patterns the morphologically distinct body forms within one organism remains an open question in developmental biology. Colonial hydrozoans, which transition through metamorphosis from a free-living planula to an architecturally complex branching colony, provide a compelling system to address this problem. Wnt signaling is well established as a key regulator of cnidarian axis patterning, yet the expression patterns and roles of Wnt components across the successive morphological transitions of the life cycle, particularly during colony growth, remain largely unknown. Here we provide a comprehensive expression map of Wnt ligands, Frizzled receptors, downstream components, and endogenous inhibitors throughout the entire life cycle of the thecate hydrozoan Dynamena pumila, from larval axis patterning through metamorphosis to colony growth. We show that in the larva, multiple Wnt genes are expressed in spatially distinct, partially overlapping domains spanning the entire oral-aboral axis, suggesting that combinatorial Wnt signaling underlies primary axis patterning in D. pumila. Rather than being directly inherited by the colony, this larval patterning system is extensively reorganized during metamorphosis, with individual ligands disappearing, newly activated, or redeployed in new spatial contexts. In the growing colony, combinatorial expression of Wnt genes marks distinct parts of the colony, while an activator-inhibitor logic involving canonical Wnt components and likely the antagonist sFRP3/4 drives the cyclic subdivision of the shoot growth tip into hydranth primordia and a self-renewing central primordium. Together, our results reveal a dynamic, flexible Wnt patterning system that is redeployed in new developmental contexts to generate the architectural complexity of the hydrozoan colony.
Vetrova et al. (Mon,) studied this question.