Abstract
The potential for regenerating tissues, organs and body parts, even the ability to reconstruct virtually a complete animal from a body fragment, is expressed to a maximum extent in echinoderms which provide fantastic and tractable models for the study of regeneration. Regenerative processes are common in all classes of the phylum, even though specific capabilities differ remarkably between the classes, depending on individual potential of morphogenetic and histogenetic plasticity at tissue and most of all at cellular levels. These phenomena, particularly in adults, imply the existence of stem cells which can be present in the circulating fluids or in the tissues in the form of resident cells, ready to be recruited in the repair and regenerative processes that follow traumatic or self-induced damage. In spite of the impressive effectiveness of their regenerative processes, only a few model systems for the study of regeneration have been developed in echinoderms, each model being unique for its specificity and versatility, and useful for unravelling peculiar aspects of the phenomenon. In addition, larvae of all classes display a unique capacity for rapid regeneration regardless of their developmental stage, showing an unexpected plasticity in terms of processes and mechanisms closely related to events of asexual reproduction and cloning. On the basis of their regenerative potential echinoderms can provide a broad range of valuable new deuterostome models for the study of regeneration genetics, with potential applications in vertebrate regeneration. Since the complexity of the echinoderm genome, as exemplified by the sea urchin genome project, indicates that echinoderms share at least 70% of their proteins with mankind, we shall consider how this provides an important tool kit to aid our understanding of the phenomenon as well as support the development of realistic methods to pursue tissue and organ regeneration in humans.
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Acknowledgements
This work was carried out thanks to the support of a number of specific projects financed through the years by CNR, MURST (COFIN 2003, 2006) and University of Milano (FIRST) programs. VM is grateful for the partial financial support of the Marine Genomics Europe Network of Excellence and MoMa ASI project. The first author is particularly grateful to the following colleagues for their indispensable help and valuable collaboration during the research work: Alice Barbaglio, Anna Biressi, Francesco Bonasoro, Giulio Cossu, Cristiano Di Benedetto, Suzanne Denis Donini, Daniela Mozzi, Lorenzo Parma, Marco Patruno, Michela Sugni.
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Candia-Carnevali, M.D., Thorndyke, M.C., Matranga, V. (2009). Regenerating Echinoderms: A Promise to Understand Stem Cells Potential. In: Rinkevich, B., Matranga, V. (eds) Stem Cells in Marine Organisms. Springer, Dordrecht. https://doi.org/10.1007/978-90-481-2767-2_7
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