Tree-mediated methane fluxes: A new frontier in the global carbon cycle. Methane is an extremely potent greenhouse gas. Recent evidence suggests that tree-mediated fluxes may be a significant, but overlooked source of methane to the atmosphere. This project aims to quantify the magnitude and drivers of tree-mediated methane fluxes from Australia’s dominant forest types. Innovatively, we will be using a novel combination of empirical field based measurements, gas tracer experiments, microbial ana ....Tree-mediated methane fluxes: A new frontier in the global carbon cycle. Methane is an extremely potent greenhouse gas. Recent evidence suggests that tree-mediated fluxes may be a significant, but overlooked source of methane to the atmosphere. This project aims to quantify the magnitude and drivers of tree-mediated methane fluxes from Australia’s dominant forest types. Innovatively, we will be using a novel combination of empirical field based measurements, gas tracer experiments, microbial analysis and modelling methods. Expected outcomes are a mechanistic understanding of tree-mediated methane fluxes, helping to constrain regional, national and global methane budgets. The results of this study will help inform publicly funded greenhouse gas abatement strategies, ensuring a maximal return on investment.Read moreRead less
Going beyond genetics: the shape of marsupial evolution and conservation. This project aims to explain the past and protect the present biodiversity of endangered marsupial mammals such as bilbies and koalas. It will generate new knowledge using an interdisciplinary combination of 3D analysis of skull shape, reflecting a mammal’s ability to feed and sense its surrounds, with the fast-moving fields of marsupial conservation and evolutionary genetics. This will help to anticipate if, and how, chan ....Going beyond genetics: the shape of marsupial evolution and conservation. This project aims to explain the past and protect the present biodiversity of endangered marsupial mammals such as bilbies and koalas. It will generate new knowledge using an interdisciplinary combination of 3D analysis of skull shape, reflecting a mammal’s ability to feed and sense its surrounds, with the fast-moving fields of marsupial conservation and evolutionary genetics. This will help to anticipate if, and how, changing environments and declining numbers reduce these species’ ability to adapt. Benefits include better information to support improved conservation decisions and identification of genes underlying the evolution of marsupial skull diversity.Read moreRead less
Structural and molecular studies of endocrine disruption in Australia fauna. Contamination of waterways with compounds that disrupt hormone (endocrine) function is a major environmental problem and threat to the health and fertility of animals. Specifically, we lack an understanding of how these potent endocrine disrupting compounds function in native species. Using an innovative combination of structural and molecular biology approaches we will elucidate the mechanisms of action of environmenta ....Structural and molecular studies of endocrine disruption in Australia fauna. Contamination of waterways with compounds that disrupt hormone (endocrine) function is a major environmental problem and threat to the health and fertility of animals. Specifically, we lack an understanding of how these potent endocrine disrupting compounds function in native species. Using an innovative combination of structural and molecular biology approaches we will elucidate the mechanisms of action of environmental endocrine disrupting compounds in native aquatic species - model fish and the platypus; and develop novel technologies for their detection. This work will provide an understanding of the environmental threat of these pollutants to our unique wildlife and will guide future waterway management. Read moreRead less
Plastic brains: Neural adaptations to changing environments in reptiles. The project aims to quantify brain anatomy on an unprecedented scale in comparative neurobiology. Focusing on Australia’s diverse and extensive collection of reptiles, including goannas, dragons and venomous snakes, the project expects to generate new knowledge on the evolution of brains as these animals adapted to new habitats and climates. Data will be collected by cutting-edge micro-CT technology and advanced phylogeneti ....Plastic brains: Neural adaptations to changing environments in reptiles. The project aims to quantify brain anatomy on an unprecedented scale in comparative neurobiology. Focusing on Australia’s diverse and extensive collection of reptiles, including goannas, dragons and venomous snakes, the project expects to generate new knowledge on the evolution of brains as these animals adapted to new habitats and climates. Data will be collected by cutting-edge micro-CT technology and advanced phylogenetic techniques, which will be complemented by detailed neuroanatomy. Expected outcomes include enhanced understanding of the effects of temperature on brains, and a large database of 3D digital anatomical models. A major benefit includes a greater ability to mitigate the effects of environmental change.Read moreRead less
Saving seagrass from climate change. This research aims to test whether seagrass ecosystems can be safeguarded from climate change impacts by enhancing genetic connectivity in range edge populations using novel genetic rescue approaches. We will use the range edge seagrass meadows of the UNESCO World Heritage Site of Shark Bay as our model, which was significantly impacted by a marine heat wave in 2010/2011. The project will generate new knowledge on how seagrasses can adapt and survive in situ. ....Saving seagrass from climate change. This research aims to test whether seagrass ecosystems can be safeguarded from climate change impacts by enhancing genetic connectivity in range edge populations using novel genetic rescue approaches. We will use the range edge seagrass meadows of the UNESCO World Heritage Site of Shark Bay as our model, which was significantly impacted by a marine heat wave in 2010/2011. The project will generate new knowledge on how seagrasses can adapt and survive in situ. Expected outcomes are improved conservation, management and restoration practices for seagrass meadows. This should provide significant benefits for long-term resilience of this economically and culturally significant ecosystem.Read moreRead less
The evolutionary potential of fragmented and declining populations. This project aims to integrate adaptive genomic and epigenomic information from wild, captive and reintroduced populations to identify evolutionary potential across different life-histories and levels of habitat fragmentation. The project will capitalise on knowledge and genomic resources for Australian freshwater fishes, including a natural experiment of evolution. It is expected that the project will address fundamental and ap ....The evolutionary potential of fragmented and declining populations. This project aims to integrate adaptive genomic and epigenomic information from wild, captive and reintroduced populations to identify evolutionary potential across different life-histories and levels of habitat fragmentation. The project will capitalise on knowledge and genomic resources for Australian freshwater fishes, including a natural experiment of evolution. It is expected that the project will address fundamental and applied questions about the adaptive capacity of populations in their natural environment. The outcomes of the project will help evaluate and improve local and ecosystem-level initiatives towards the sustainable management of aquatic biodiversity impacted by human activities. The project will also inform on management of water resources in the Murray-Darling Basin.Read moreRead less
Carbon costs of plant nutrient and water uptake. This project aims to investigate how much carbon plants need to invest belowground in return for water and nutrients. By using economic principles of supply and demand the project will quantify carbon expenditure for water and nutrients in grasslands and crops under different climate and land management scenarios. This project will use triple and quadruple isotope labelling techniques and explore the dependency of carbon investment on plant-microb ....Carbon costs of plant nutrient and water uptake. This project aims to investigate how much carbon plants need to invest belowground in return for water and nutrients. By using economic principles of supply and demand the project will quantify carbon expenditure for water and nutrients in grasslands and crops under different climate and land management scenarios. This project will use triple and quadruple isotope labelling techniques and explore the dependency of carbon investment on plant-microbial interactions and availability of belowground resources. Expected outcomes include new knowledge to build a universal framework about plant carbon-water-nutrient economics. This will benefit global carbon cycling models and efforts to increase nutrient and water use efficiencies in agricultural crops.Read moreRead less
Hidden complexity in microRNA function. This project aims to determine the extent to which microRNAs function through “non-canonical” mechanisms within cell nuclei, how their roles are expanded by naturally occurring sequence variation and how their activity is controlled by little known families of genes that sequester and inhibit their availability. The knowledge generated is significant as microRNAs regulate the expression of virtually all genes and biological processes, yet these mechanisms ....Hidden complexity in microRNA function. This project aims to determine the extent to which microRNAs function through “non-canonical” mechanisms within cell nuclei, how their roles are expanded by naturally occurring sequence variation and how their activity is controlled by little known families of genes that sequester and inhibit their availability. The knowledge generated is significant as microRNAs regulate the expression of virtually all genes and biological processes, yet these mechanisms of function remain poorly characterised and seldom considered. The expected outcome of better understanding mechanisms through which microRNAs work should provide significant benefit to safe and effective development of microRNAs for future agricultural or therapeutic application.Read moreRead less
Snake fangs: insights into evolution, palaeoclimate and biodesign . This project aims to generate unprecedented insights into the fangs of venomous snakes, focusing on elapids (taipans, tiger snakes etc). We will examine fang shape diversity, correlation with behavior and ecology, evolutionary history, and biomechanical properties. Data will be collected using cutting-edge micro-CT technology and analysed using 3D geometric morphometrics, computer simulations, and advanced phylogenetic techniqu ....Snake fangs: insights into evolution, palaeoclimate and biodesign . This project aims to generate unprecedented insights into the fangs of venomous snakes, focusing on elapids (taipans, tiger snakes etc). We will examine fang shape diversity, correlation with behavior and ecology, evolutionary history, and biomechanical properties. Data will be collected using cutting-edge micro-CT technology and analysed using 3D geometric morphometrics, computer simulations, and advanced phylogenetic techniques. This should greatly improve understanding of the evolution of venom fangs in all snakes. Other benefits include a large 3D reference database allowing identification of fossil fangs, with applications for studies of past climates, and a characterisation of fang biomechanics, relevant to biodesign and biomimicry.Read moreRead less
Spatio-temporal activation of genes in cells and mice. This project aims to develop novel genetic methods and instrumentation for the local, rapid and reversible activation of genes in cells and mice. This project expects to generate highly innovative light- and sound-based technologies that will permit to study living systems on the gene-level with unprecedented precision. Expected outcomes include new research and technology capacity to broadly address fundamental biological questions and to c ....Spatio-temporal activation of genes in cells and mice. This project aims to develop novel genetic methods and instrumentation for the local, rapid and reversible activation of genes in cells and mice. This project expects to generate highly innovative light- and sound-based technologies that will permit to study living systems on the gene-level with unprecedented precision. Expected outcomes include new research and technology capacity to broadly address fundamental biological questions and to create new applied processes. This project intends to provide significant benefits, such as enhanced knowledge generation, multidisciplinary training opportunities and patentable technologies.Read moreRead less