Siphonophores are colonial hydrozoans, characterized by complex colony organization and unparalleled zooid functional specialization. Recent genomic studies have offered an evolutionary perspective on how this morphological complexity arose, but a molecular characterization of symmetry breaking in siphonophore embryonic development is still largely missing. Here, bringing together historical data on early development with new immunohistochemical data, we review the diversity of developmental trajectories that lead to the formation of bilaterally symmetric planula larvae in siphonophores. Embryonic development, up to the planula stage, is remarkably similar across siphonophore phylogeny. Then, with the appearance of the lateral endodermal thickening (= ventral endoderm), larval development diverges between taxa, differing in the location and patterning of the primary buds, chronology of budding, establishment of growth zones, and retention of larval zooids. Our work also uncovers a number of open questions in siphonophore development, including homology of different zooids, mechanisms underlying formation and maintenance of spatially restricted growth zone(s), and molecular factors establishing a secondary dorsal-ventral axis in planulae. By discussing siphonophore development and body axes within the broader cnidarian context, we then set the framework for future work on siphonophores, which is finally achievable with the advent of culturing methods.
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Article Synopsis
- The evolutionary origin of Bilateria is unclear, but similarities between cnidarian-like larvae and simple flatworms suggest a connection, linking Xenacoelomorpha as a potential early branch of Bilateria.
- This study focuses on assembling and analyzing the genome of a marine xenacoelomorph, discovering it has a genome size of ~111 Mbp with characteristics similar to other bilaterians.
- The findings indicate that despite its simple body plan, the xenacoelomorph has a complex genome and retains many features typical of bilaterians, challenging previous assumptions about its evolutionary simplicity.
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