The Demosponge Amphimedon queenslandica: Reconstructing the Ancestral Metazoan Genome and Deciphering the Origin of Animal Multicellularity

doi:10.1101/pdb.emo108

Cite as: Cold Spring Harb. Protoc.; 2008; doi:10.1101/pdb.emo108

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emo Emerging Model Organisms

The Demosponge Amphimedon queenslandica: Reconstructing the Ancestral Metazoan Genome and Deciphering the Origin of Animal Multicellularity

Bernard M. Degnan¹^,5, Maja Adamska¹^,2, Alina Craigie¹, Sandie M. Degnan¹, Bryony Fahey¹, Marie Gauthier¹, John N.A. Hooper³, Claire Larroux¹, Sally P. Leys⁴, Erica Lovas¹, and Gemma S. Richards¹

¹ School of Integrative Biology, University of Queensland, Brisbane QLD 4072, Australia
² Sars International Centre for Marine Molecular Biology, N-5008 Bergen, Norway
³ Queensland Museum, Queensland, Australia
⁴ Department of Biological Sciences CW 405, University of Alberta, Edmonton, Alberta T6G 2E9, Canada

⁵Corresponding author (b.degnan{at}uq.edu.au)

INTRODUCTION

Sponges are one of the earliest branching metazoans. In additionto undergoing complex development and differentiation, theycan regenerate via stem cells and can discern self from nonself("allorecognition"), making them a useful comparative modelfor a range of metazoan-specific processes. Molecular analysesof these processes have the potential to reveal ancient homologiesshared among all living animals and critical genomic innovationsthat underpin metazoan multicellularity. Amphimedon queenslandica(Porifera, Demospongiae, Haplosclerida, Niphatidae) is the firstporiferan representative to have its genome sequenced, assembled,and annotated. Amphimedon exemplifies many sessile and sedentarymarine invertebrates (e.g., corals, ascidians, bryozoans): Theydisperse during a planktonic larval phase, settle in the vicinityof conspecifics, ward off potential competitors (including incompatiblegenotypes), and ensure that brooded eggs are fertilized by conspecificsperm. Using genomic and expressed sequence tag (EST) resourcesfrom Amphimedon, functional genomic approaches can be appliedto a wide range of ecological and population genetic processes,including fertilization, dispersal, and colonization dynamics,host-symbiont interactions, and secondary metabolite production.Unlike most other sponges, Amphimedon produce hundreds of asynchronouslydeveloping embryos and larvae year-round in distinct, easilyaccessible brood chambers. Embryogenesis gives rise to larvaewith at least a dozen cell types that are segregated into threelayers and patterned along the body axis. In this article, wedescribe some of the methods currently available for studyingA. queenslandica, focusing on the analysis of embryos, larvae,and post-larvae.

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