A feather star is born: embryonic development and nervous system organization in the crinoidAntedon mediterranea

Abstract

AbstractBackgroundCrinoids belong to the phylum Echinodermata, marine invertebrates with a highly derived pentaradial body plan. As the only living members of the Pelmatozoa, the sister group to other extant echinoderms, crinoids are in a key phylogenetic position to reconstruct the evolutionary history of this phylum. However, the development of crinoids has been scarcely investigated, limiting their potential for comparative studies. Many crinoids are difficult to collect in the wild and embryo manipulation is challenging. Conversely, the Mediterranean feather starAntedon mediterraneacan be found in shallow waters and has been used for experimental studies, most notably to investigate regeneration.ResultsThe aim here was to establishA. mediterraneaas an experimental system for developmental biology. To accomplish this, we set up a method for culturing embryosin vitrofrom zygote to hatching larva stage that allowed us to define a developmental timeline and a standardized staging system for this species. We then optimized protocols to characterize the development of the main structures of the feather star body plan, using a combination of microscopy techniques and whole mount immunohistochemistry andin situhybridization chain reaction. Focusing on the nervous system, we show that the larval apical organ includes a combination of serotonergic, GABAergic and glutamatergic neurons that form under the influence of a conserved anterior molecular signature. The larval neural plexus is instead composed of glutamatergic neurons and develops during the formation of the ciliary bands. Larval neurons disappear at metamorphosis, and the ectoneural and entoneural components of the adult nervous system develop early in post-metamorphic stages. Furthermore, the oral ectoderm that contains the ectoneural system acquires an “anterior” signature expressingSix3/6andLhx2/9orthologs.ConclusionsOur results deepen our knowledge on crinoid development and provide new techniques to investigate feather star embryogenesis, promoting the use ofA. mediterraneain developmental and evolutionary biology. This in turn will pave the way for the inclusion of crinoids in comparative studies to understand the origin of the echinoderm body plan and clarify many unanswered questions on deuterostome evolution.