SUMMARYWe studied the role of Wnt signaling in axis formation during metamorphosis and regeneration in the cnidarian Hydractinia. Activation of Wnt downstream events during metamorphosis resulted in a complete oralization of the animals and repression of aboral structures (i.e. stolons). The expression of Wnt3, Tcf and Brachyury was upregulated and became ubiquitous. Rescue experiments using Tcf RNAi resulted in normal metamorphosis and quantitatively normal Wnt3 and Brachyury expression. Isolated, decapitated polyps regenerated only heads but no stolons. Activation of Wnt downstream targets in regenerating animals resulted in oralization of the polyps. Knocking down Tcf or Wnt3 by RNAi inhibited head regeneration and resulted in complex phenotypes that included ectopic aboral structures. Multiple heads then grew when the RNAi effect had dissipated. Our results provide functional evidence that Wnt promotes head formation but represses the formation of stolons, whereas downregulation of Wnt promotes stolons and represses head formation.
We have studied the role the canonical Wnt pathway plays in hydroid pattern formation during embryonic development and metamorphosis. Transcripts of Wnt and Tcf were asymmetrically deposited in the oocyte and subsequent developmental stages, marking the sites of first cleavage, posterior larval pole and the upcoming head of the metamorphosed polyp. To address the function of these genes, we activated downstream events of the Wnt pathway by pharmacologically blocking GSK-3beta. These treatments rendered the polar expression of Tcf ubiquitous and induced development of ectopic axes that contained head structures. These results allow concluding that Wnt signaling controls axis formation and regional tissue fates along it, determining one single axis terminus from which later the mouth and hypostome develop. Our data also indicate Wnt functions in axis formation and axial patterning as in higher metazoans, and thus point to an ancestral role of Wnt signaling in these processes in animal evolution.
Metamorphosin A (MMA) isolated from the anthozoan Anthopleura elegantissima has recently been shown to interfere with developmental control in the colonial hydroid Hydractinia echinata. In order to identify the functional homologue in this species we have cloned cDNAs of the precursor protein from Hydractinia and, for comparison, precursor sequences from two further anthozoans. The deduced preproproteins contain multiple copies of propeptides to be processed into a great variety of novel neuropeptides most of which are N-terminally different from MMA. Original MMA is only contained in the anthozoan precursors. Most of the novel neuropeptides will have the carboxyl terminus LWamide. Therefore, we term this novel neuropeptide family the LWamides. Peptides synthesized according to the precursor sequence of H. echinata and added to planulae trigger metamorphosis. In contrast, none of 11 other known biologically active peptides including carboxamidated neuropeptides were effective. Expression analysis by in situ hybridization and by antibodies against the H. echinata peptide reveals the presence of the gene product in planulae at the proper time and at the due spatial location expected for a natural role in metamorphosis. LWamide transcripts are also observed in nerve cells of primary and adult polyps, suggesting LWamides to be a multifunctional family of neuropeptides.
With the rapid increase of the quantity of molecular data, many animals joined the ranks of the so-called 'emerging models' of Evo-Devo. One of the necessary steps in converting an emerging model into an established one is gaining comprehensive knowledge of its normal embryonic development. The marine colonial hydrozoan Hydractinia echinata - an excellent model for research on stem cells, metamorphosis, and allorecognition - has been studied for decades. Yet knowledge of its embryonic development remains fragmentary and incomplete. Here we provide a detailed account of H. echinata embryonic development using in vivo observations, histology, immunohistochemistry, and electron microscopy. Furthermore, we propose a model describing the cellular basis of the morphogenetic movements occurring during development and also reveal a functional link between canonical Wnt signaling and regional differences in the morphology of the embryo. Hydractinia embryogenesis is an example of the diversity and plasticity of hydrozoan development where multiple routes lead to the same result - the formation of a normal planula larva.
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