Discovery Early Career Researcher Award - Grant ID: DE200101064
Funder
Australian Research Council
Funding Amount
$416,000.00
Summary
Exploring eco-evolutionary dynamics to predict the future of coral reefs. This project aims to predict the future of coral reefs in the rapidly changing climate of the Anthropocene by integrating state-of-the-art population genomics with evolutionary and ecological modelling. The project expects to describe pathways of genetic and non-genetic adaptation; and the strength and direction of connectivity of warm vs cold adapted coral populations - united in an eco-evolutionary framework. Expected ou ....Exploring eco-evolutionary dynamics to predict the future of coral reefs. This project aims to predict the future of coral reefs in the rapidly changing climate of the Anthropocene by integrating state-of-the-art population genomics with evolutionary and ecological modelling. The project expects to describe pathways of genetic and non-genetic adaptation; and the strength and direction of connectivity of warm vs cold adapted coral populations - united in an eco-evolutionary framework. Expected outcomes address critical gaps in data and methodology that currently hinder our ability to reliably model the evolutionary and ecological dynamics of one of the most biologically diverse, socially and economically valuable and climatically vulnerable ecosystems of our planet, contributing to their science-based management. 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
Variation in larval gene expression in a marine invertebrate: implications for population divergence via differential settlement response. Evolutionary and ecological functional genomics is an emerging field that integrates gene profiling technologies with experimental and field approaches of ecology and evolution. I take this approach to address a key problem in marine invertebrate biology: how do larvae respond to their environment and how does variation in this response influence the distribu ....Variation in larval gene expression in a marine invertebrate: implications for population divergence via differential settlement response. Evolutionary and ecological functional genomics is an emerging field that integrates gene profiling technologies with experimental and field approaches of ecology and evolution. I take this approach to address a key problem in marine invertebrate biology: how do larvae respond to their environment and how does variation in this response influence the distribution and evolution of a species? I will use a marine gastropod (abalone) model, for which there exists substantial development and population genetic data, and established aquaculture methodologies. Outcomes of this study will enhance knowledge of the stock structure of this and other commercial fisheries, as well as aquaculture efficiency.Read moreRead less
The transcriptome, genome and metagenome of Acropora millepora: a model system for studying coral health and disease. Corals have an iconic significance for Australia, which has the best-preserved reef system in the world. The Great Barrier Reef is worth more than $6 billion per year to the Australian economy, and provides employment for 68000 people. The research will provide insights into the molecular bases of stress and disease in corals and the internal mechanisms by which corals attempt to ....The transcriptome, genome and metagenome of Acropora millepora: a model system for studying coral health and disease. Corals have an iconic significance for Australia, which has the best-preserved reef system in the world. The Great Barrier Reef is worth more than $6 billion per year to the Australian economy, and provides employment for 68000 people. The research will provide insights into the molecular bases of stress and disease in corals and the internal mechanisms by which corals attempt to combat them. The results will allow the design of strategies for better reef management, resulting in economic, environmental and social benefits for Australia.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0347875
Funder
Australian Research Council
Funding Amount
$280,000.00
Summary
Enhanced genetic analysis facilities at James Cook University. The acquisition of molecular data, DNA sequences or allele frequencies, is the major requirement of almost all laboratory research in the life sciences, and is the rate-limiting step for many research projects locally. The current application underpins novel research initiatives at James Cook University, and is intended to provide centralized state-of-the-art high throughput DNA sequencing and genotyping facility for the north Queens ....Enhanced genetic analysis facilities at James Cook University. The acquisition of molecular data, DNA sequences or allele frequencies, is the major requirement of almost all laboratory research in the life sciences, and is the rate-limiting step for many research projects locally. The current application underpins novel research initiatives at James Cook University, and is intended to provide centralized state-of-the-art high throughput DNA sequencing and genotyping facility for the north Queensland life sciences community.Read moreRead less
Fisheries genomics of snapper in Australia and New Zealand Waters. This industry-driven project aims to assemble a strategic research alliance to generate and apply knowledge to a highly significant fisheries resource. It involves collaboration between the five major state government fisheries agencies in Australia, the New Zealand’s Crown Research Institute for seafood and two Australian labs with leadership in fish genetics and genomics. It expects to generate and integrate genomic, environmen ....Fisheries genomics of snapper in Australia and New Zealand Waters. This industry-driven project aims to assemble a strategic research alliance to generate and apply knowledge to a highly significant fisheries resource. It involves collaboration between the five major state government fisheries agencies in Australia, the New Zealand’s Crown Research Institute for seafood and two Australian labs with leadership in fish genetics and genomics. It expects to generate and integrate genomic, environmental and phenotypic datasets for snapper populations from across vast coastal regions of the two countries. The outcomes should substantially enhance intra- and inter-jurisdictional fisheries management and aquaculture initiatives, providing commercial, social and environmental benefits for many stakeholders.Read moreRead less
The Epigenetics of Sex in the Dragon. Genetic codes do not directly translate to phenotypes -- environment acts through epigenetics to modify development. We use advanced molecular techniques to examine how epigenetics responds to temperature to reverse sex in our novel animal model, the dragon lizard. How does the cell sense temperature? Once the extrinsic signal is captured, how does it influence chromatin modification to release or suppress key genes in the sex differentiation pathway? Which ....The Epigenetics of Sex in the Dragon. Genetic codes do not directly translate to phenotypes -- environment acts through epigenetics to modify development. We use advanced molecular techniques to examine how epigenetics responds to temperature to reverse sex in our novel animal model, the dragon lizard. How does the cell sense temperature? Once the extrinsic signal is captured, how does it influence chromatin modification to release or suppress key genes in the sex differentiation pathway? Which sex genes are targets? Epigenetic enzymes are astonishingly conserved, providing exciting opportunities to draw from human systems to unravel novel signatures of temperature-induced sex switching in reptiles. This project will advance knowledge of developmental programming generally.Read moreRead less