Dual origins for neural cells during development of the Clytia planula larva

Adult hydrozoan cnidarians undergo extensive tissue turnover, generating neural cell types including nematocytes (stinging cells) and gland cells from interstitial stem cells (i-cells) expressing stemness proteins such as Piwi and Nanos. The contribution of i-cells during embryogenesis, however, has been unclear. Here we address the origin of neural cells during development of the Clytia hemisphaerica planula larva. Marker gene in situ hybridisation revealed that Piwi/Nanos1-expressing cells within the early gastrula presumptive endoderm generate a substantial pool of nematoblasts, a few of which migrate and differentiate in the planula ectoderm. Some neurogenic and neuronal markers, however, showed a markedly distinct expression profile, developing within a basal layer of the aboral/lateral ectoderm during gastrulation. Embryo bisection and lineage tracing experiments confirmed that sensory neurons and secretory cell types derive from gastrula ectoderm, while nematocytes and at least some ganglionic neurons derive from i-cells. Knockdown and inhibitor treatments revealed steps in neuron and nematocyte development regulated by Wnt-{beta}-catenin. We conclude that two distinct neurogenesis pathways operate during Clytia embryogenesis, one involving aboral ectoderm delamination, and one generating mainly nematocytes from i-cell-like precursors. Summary statementDuring embryogenesis in the hydrozoan Clytia neural cell types derive both from Piwi/Nanos expressing "i-cells" and from ectodermal delamination during gastrulation.