Phosphorus-efficient Australian plants: applications for crop improvement. This project aims to investigate ways to improve the phosphorus (P) efficiency of selected crops (Lupinus) in Australia. The phosphorus impoverished soils in Australia has allowed the evolution of plants that are highly efficient at acquiring and using phosphorus. Increasing understanding of highly-efficient phosphorus use mechanisms at the physiological, biochemical, anatomical and molecular biological levels will provid ....Phosphorus-efficient Australian plants: applications for crop improvement. This project aims to investigate ways to improve the phosphorus (P) efficiency of selected crops (Lupinus) in Australia. The phosphorus impoverished soils in Australia has allowed the evolution of plants that are highly efficient at acquiring and using phosphorus. Increasing understanding of highly-efficient phosphorus use mechanisms at the physiological, biochemical, anatomical and molecular biological levels will provide knowledge of traits to guide breeding efforts to develop more phosphorus efficient crops that can perform well in P-limited environments; an outstanding strategy to balance the phosphorus demand for increasing global food production with gradually decreasing non-renewable phosphorus reserves. An expected outcome of this project is to develop crops better able to use scarce phosphorus.Read moreRead less
Deciphering organelle transport mechanisms in plants. Plant growth, productivity and seed yield all depend on organelle function which requires metabolites and proteins
to be transported across membranes. This mechanism of transport is carried out by specific transporters that have
the ability to transport macromolecules, and regulate organelle function. We have identified new transporters that
are involved in amino acid and protein transport in the mitochondria, chloroplast and peroxisomes. We ....Deciphering organelle transport mechanisms in plants. Plant growth, productivity and seed yield all depend on organelle function which requires metabolites and proteins
to be transported across membranes. This mechanism of transport is carried out by specific transporters that have
the ability to transport macromolecules, and regulate organelle function. We have identified new transporters that
are involved in amino acid and protein transport in the mitochondria, chloroplast and peroxisomes. We will assign
function to each protein and investigate the importance in regulating organelle biogenesis. This will allow us to
modulate plant energy production for optimal growth and to withstand abiotic stress, all of which have
agriculturally beneficial consequences. Read moreRead less
Resolving the steps in the evolution of C4 photosynthesis. This project aims to identify the molecular mechanisms responsible for the evolution of grasses using the C4 biochemical pathway that enables plants to survive in hot, dry, high-light environments. The endemic Australian subtribe Neurachninae is the only known grass group that contains C4 species, species using the ancestral C3 pathway, as well as species using pathways intermediate to C3 and C4. Through a comparative approach employing ....Resolving the steps in the evolution of C4 photosynthesis. This project aims to identify the molecular mechanisms responsible for the evolution of grasses using the C4 biochemical pathway that enables plants to survive in hot, dry, high-light environments. The endemic Australian subtribe Neurachninae is the only known grass group that contains C4 species, species using the ancestral C3 pathway, as well as species using pathways intermediate to C3 and C4. Through a comparative approach employing high-throughput sequencing technologies, it is expected that the molecular changes underlying the transition from C3 to C4 will be identified. These results should define what is required to engineer plant varieties with increased yield and the ability to withstand climate change effects.Read moreRead less
Mitochondrial Biogenesis and Signalling in Plants . This proposal aims to define the mechanisms of how mitochondrial growth and stress signalling interact and are regulated. Mitochondria are central machines in cells that use energy obtained through photosynthesis to drive growth and also play an important role in sensing and responding to non-optimal environmental growth conditions. As mitochondrial growth and stress signalling are antagonistic, growth is retarded when stress signalling is acti ....Mitochondrial Biogenesis and Signalling in Plants . This proposal aims to define the mechanisms of how mitochondrial growth and stress signalling interact and are regulated. Mitochondria are central machines in cells that use energy obtained through photosynthesis to drive growth and also play an important role in sensing and responding to non-optimal environmental growth conditions. As mitochondrial growth and stress signalling are antagonistic, growth is retarded when stress signalling is activated. Thus, the outcomes will be new knowledge and understanding of how plants balance growth and stress responses. This benefit of this knowledge and understanding is that it can be used to pursue novel avenues to optimise crop performance in changing and adverse environments.Read moreRead less
From energy stress to hormones: new signals in bacteria and plants. This project will use molecular tools to detect and identify new chemical signals, known as butenolides, that regulate the growth and development of bacteria and plants. This project will use innovative, interdisciplinary techniques to discover where these butenolide signals come from, and how both bacteria and plants detect them. Expected outcomes of this project include a greater understanding of how plants use butenolides to ....From energy stress to hormones: new signals in bacteria and plants. This project will use molecular tools to detect and identify new chemical signals, known as butenolides, that regulate the growth and development of bacteria and plants. This project will use innovative, interdisciplinary techniques to discover where these butenolide signals come from, and how both bacteria and plants detect them. Expected outcomes of this project include a greater understanding of how plants use butenolides to cope with stress such as drought or salinity, and the design of new technologies for manipulating the growth of both plants and bacteria. The long-term benefits of this work should include fresh approaches for enhancing plant performance under sub-optimal conditions.Read moreRead less