Evolution of the biofabrication of mineralized structures in animals. Shells and skeletons are produced by a wide range of animals. These highly-order crystalline structures are genetically-encoded and produce high-performance composite materials that exceed present capabilities in human engineering. This international collaboration will elucidate the molecular mechanisms controlling the fabrication of these architectures. This knowledge will contribute significantly to the development of materi ....Evolution of the biofabrication of mineralized structures in animals. Shells and skeletons are produced by a wide range of animals. These highly-order crystalline structures are genetically-encoded and produce high-performance composite materials that exceed present capabilities in human engineering. This international collaboration will elucidate the molecular mechanisms controlling the fabrication of these architectures. This knowledge will contribute significantly to the development of materials for advanced electronics and energy transducers, human bone therapeutics and marine-based products such as pearls and cements, through the identification of genes underlying biofabrication networks and the development of in vitro bioproduction systems.Read moreRead less
Control of Wolbachia replication: maintaining a stable symbiosis. This project will use a comparative genomics approach to better understand how Wolbachia infections of insects are able to maintain themselves in insects without causing pathology. The results will allow us to better understand a distinguishing characteristic of an intracellular symbiont, namely replication control. The results also have the potential to lead to new approaches to insect pest control through a better understanding ....Control of Wolbachia replication: maintaining a stable symbiosis. This project will use a comparative genomics approach to better understand how Wolbachia infections of insects are able to maintain themselves in insects without causing pathology. The results will allow us to better understand a distinguishing characteristic of an intracellular symbiont, namely replication control. The results also have the potential to lead to new approaches to insect pest control through a better understanding of how Wolbachia might be used to skew insect population age structure.Read moreRead less
The sponge genome project and the evolution of multicellularity: using comparative genomics and developmental biology to reconstruct the first animals. Recently the entire genome from a living fossil - a sponge from the Great Barrier Reef - was sequenced (jointly supported by the ARC and US Department of Energy). As this genome is assembled and analysed, many of the fundamental biological processes that underlie the construction and evolution of all animals, including humans, will be revealed. ....The sponge genome project and the evolution of multicellularity: using comparative genomics and developmental biology to reconstruct the first animals. Recently the entire genome from a living fossil - a sponge from the Great Barrier Reef - was sequenced (jointly supported by the ARC and US Department of Energy). As this genome is assembled and analysed, many of the fundamental biological processes that underlie the construction and evolution of all animals, including humans, will be revealed. In addition, sponge genomics will fuel innovations in medicine and biotechnology. Specifically, sponges are renowned for their capacity to synthesise bioactive compounds used in drug development, and high-grade silica used for semi-conductor construction. This project will identify the gene networks controlling these biosynthetic processes.Read moreRead less
Early animal evolution: reconstructing the last common metazoan ancestor through the analysis of developmental and structural genes in sponges. All animals, from the simplest invertebrates to humans, arose from a common ancestor. Reconstruction of this ancestor requires the comparison of metazoan developmental genetic architectures. Here we contribute to this pursuit by studying a phylogenetically and biological appropriate metazoan system - marine sponge embryos and larvae. Using high-throughp ....Early animal evolution: reconstructing the last common metazoan ancestor through the analysis of developmental and structural genes in sponges. All animals, from the simplest invertebrates to humans, arose from a common ancestor. Reconstruction of this ancestor requires the comparison of metazoan developmental genetic architectures. Here we contribute to this pursuit by studying a phylogenetically and biological appropriate metazoan system - marine sponge embryos and larvae. Using high-throughput gene profiling techniques, we will analyse the developmental genetics underlying the sponge body plan. Commonalities shared between sponges and more sophisticated animals are likely to have been present in the "genetic toolkit" of the most ancient metazoan ancestor and, as such, is the genetic foundation from which all animal biodiversity arose.Read moreRead less