Discovery Early Career Researcher Award - Grant ID: DE210100908
Funder
Australian Research Council
Funding Amount
$461,815.00
Summary
Maximising the beneficial impacts of mycorrhizal fungi on grain nutrition. This project aims to determine the effects of beneficial soil fungi on wheat and rice grain quality for human nutrition using an innovative combination of physiological, molecular and agronomic techniques. The project expects to generate fundamental knowledge in sustainable agriculture, to improve grain quality and value. Expected outcomes of this project include enhanced understanding of the mechanisms underlying improve ....Maximising the beneficial impacts of mycorrhizal fungi on grain nutrition. This project aims to determine the effects of beneficial soil fungi on wheat and rice grain quality for human nutrition using an innovative combination of physiological, molecular and agronomic techniques. The project expects to generate fundamental knowledge in sustainable agriculture, to improve grain quality and value. Expected outcomes of this project include enhanced understanding of the mechanisms underlying improved grain quality, and the capacity to use soil fungi to increase grain micronutrient concentrations and bioavailability. This should provide significant environmental and societal benefits, such as promotion of the sustainable use of agricultural soils and more nutritious grain products for human consumption.Read moreRead less
Investigating a novel signalling pathway for crop improvement. This project will dissect a newly identified signalling pathway in plants that regulates plant water use and carbon gain. It will deploy multiple techniques, including novel biosensors, to understand the links between the metabolism of plants and their environmental responses. The project will build partnerships with scientists at leading international institutions for enhanced outcomes, including access to specialised equipment and ....Investigating a novel signalling pathway for crop improvement. This project will dissect a newly identified signalling pathway in plants that regulates plant water use and carbon gain. It will deploy multiple techniques, including novel biosensors, to understand the links between the metabolism of plants and their environmental responses. The project will build partnerships with scientists at leading international institutions for enhanced outcomes, including access to specialised equipment and upskilling of our scientists. The generation of barley with the latest gene editing techniques aims to produce a non-GM crop with the potential for enhanced root C sequestration, lower water use and improved yield, three key goals for agricultural sustainability in the face of a drying Australian climate.Read moreRead less
Field and quasi-field phenotyping for the quantitative characterisation of wheat yield under stress. The project aims to develop state-of-the-art monitoring and profiling capabilities for the quantitative assessment of plant growth performance in field and quasi-field environments under the abiotic stress conditions of drought and nutrient deficiency. This project involves the design and use of high resolution but low budget imaging stations to capture the growth of cereal plants in competitive ....Field and quasi-field phenotyping for the quantitative characterisation of wheat yield under stress. The project aims to develop state-of-the-art monitoring and profiling capabilities for the quantitative assessment of plant growth performance in field and quasi-field environments under the abiotic stress conditions of drought and nutrient deficiency. This project involves the design and use of high resolution but low budget imaging stations to capture the growth of cereal plants in competitive environments. Novel computer vision and image processing techniques will be applied to the image data to quantitatively characterise the success of genetic varieties to tolerate abiotic stress environments under actual field conditions.Read moreRead less
Engineering the plant mitochondrial electron transport chain for tolerance of environmental stress. Plants often face hostile environments that place them under stress. Reactive oxygen molecules produced under these conditions act as signals to activate defense mechanisms, but also cause cell damage. Mitochondria are subcellular compartments involved in energy production and are essential for plant growth and development, but they have also been implicated in the response of plants to environmen ....Engineering the plant mitochondrial electron transport chain for tolerance of environmental stress. Plants often face hostile environments that place them under stress. Reactive oxygen molecules produced under these conditions act as signals to activate defense mechanisms, but also cause cell damage. Mitochondria are subcellular compartments involved in energy production and are essential for plant growth and development, but they have also been implicated in the response of plants to environmental stress, and in production of reactive oxygen molecules. This project will investigate special features of plant mitochondria that ameliorate oxidative stress. Potential outcomes include crops better able to cope with environmental stress.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190100806
Funder
Australian Research Council
Funding Amount
$419,854.00
Summary
Towards herbicide cocktails with a new mode of action to avert resistance. This project aims to target herbicide resistant weeds which represent one of the largest threats to Australian and global food security. Targeting of unexplored pathways in plants to develop a novel herbicide strategy is expected to be achieved, and will include the structural and functional characterisation of key enzymes in these pathways. This project is expected to provide significant benefits for effective weed manag ....Towards herbicide cocktails with a new mode of action to avert resistance. This project aims to target herbicide resistant weeds which represent one of the largest threats to Australian and global food security. Targeting of unexplored pathways in plants to develop a novel herbicide strategy is expected to be achieved, and will include the structural and functional characterisation of key enzymes in these pathways. This project is expected to provide significant benefits for effective weed management to sustain Australia’s agricultural industry through enhanced food production from increased crop yields, whilst ensuring food security. These outcomes, coupled with decades of over-reliance on current herbicides, means there has never been a greater need for new and effective herbicides.Read moreRead less
Developing biotechnology solutions for improving phosphate acquisition in plants using functional genomics in rice. Global supplies of the most currently used phosphate fertilisers are predicted to be exhausted in less than a century. These fertilisers are non-renewable resources based on phosphate rock deposits and their use are key drivers of both plant production costs and environmental damage in Australia and internationally. Using the power of genetic and functional genomics analyses in ric ....Developing biotechnology solutions for improving phosphate acquisition in plants using functional genomics in rice. Global supplies of the most currently used phosphate fertilisers are predicted to be exhausted in less than a century. These fertilisers are non-renewable resources based on phosphate rock deposits and their use are key drivers of both plant production costs and environmental damage in Australia and internationally. Using the power of genetic and functional genomics analyses in rice, this project will reveal key controllers of phosphate acquisition in plants. Hence, novel biotechnology based solutions can be implemented in a variety of cereal crops to aid reduced use of phosphate fertiliser in agriculture and unlock the large phosphate pool not used by plants in soil.Read moreRead less
Root aquaporins as sensors and regulators of plant water transport. The knowledge we will gain will benefit Australia by allowing better management of plant water use. Because such large quantities of water move through aquaporins in membranes, our understanding of the pores could enable us to manipulate plants to conserve or use water depending on predicted climatic conditions. Molecular aspects of the project will reveal potential novel ways of controlling root water uptake by shoot and root m ....Root aquaporins as sensors and regulators of plant water transport. The knowledge we will gain will benefit Australia by allowing better management of plant water use. Because such large quantities of water move through aquaporins in membranes, our understanding of the pores could enable us to manipulate plants to conserve or use water depending on predicted climatic conditions. Molecular aspects of the project will reveal potential novel ways of controlling root water uptake by shoot and root manipulation. High calibre PhD and Honours students will also be educated to maintain the momentum of international excellence within Australia in the field of plant water relations.Read moreRead less
Development and regulation of thermogenesis in thermoregulating flowers. Flowers of certain primitive plants produce enough heat to raise their temperatures up to 40 C above the air, and regulate it at a nearly constant level. Like warm-blooded mammals, the flowers increase heat production as environmental temperature falls. However, they thermoregulate on a cellular level, unlike mammals with their complex nervous system. We aim to elucidate the mechanisms involved in regulation of heat-prod ....Development and regulation of thermogenesis in thermoregulating flowers. Flowers of certain primitive plants produce enough heat to raise their temperatures up to 40 C above the air, and regulate it at a nearly constant level. Like warm-blooded mammals, the flowers increase heat production as environmental temperature falls. However, they thermoregulate on a cellular level, unlike mammals with their complex nervous system. We aim to elucidate the mechanisms involved in regulation of heat-production, with molecular, biochemical and stable isotope techniques. We will investigate spatial and temporal patterns of gene expression and activity of putative regulatory enzymes. The results will have implications for human physiology and agriculture.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0347746
Funder
Australian Research Council
Funding Amount
$199,000.00
Summary
Circular-dichroism stopped-flow spectrometer for rapid molecular interactions and membrane transport. A stopped-flow spectroscope is requested that can capture the rapid kinetics of changes in conformation of biopolymers, macromolecules and chiral catalysts as they interact with other molecules. This includes measurement of rapid transport of solutes through membrane proteins in lipid membranes. The versatile instrument can also determine circular dichroism spectra of peptides, proteins, tannins ....Circular-dichroism stopped-flow spectrometer for rapid molecular interactions and membrane transport. A stopped-flow spectroscope is requested that can capture the rapid kinetics of changes in conformation of biopolymers, macromolecules and chiral catalysts as they interact with other molecules. This includes measurement of rapid transport of solutes through membrane proteins in lipid membranes. The versatile instrument can also determine circular dichroism spectra of peptides, proteins, tannins, pigment complexes and chiral catalysts that is required within several existing collaborations to understand the tertiary structures, stability and interactions between the complex molecules. The instrument will significantly strengthen research on macromolecules and polymers that have applications in the wine industry, nanotechnology, and biotechnology.Read moreRead less
Calcium compartmentation in leaves: testing an integrated model of water and calcium transport with cell specific functional genomics. Calcium is a vital nutrient to animals and humans and its storage in vegetation is important for its accessibility. We believe this storage is linked to water flow in the leaf by a novel mechanism. This project will provide fundamental understanding of the cell type-specific processes involved in calcium storage and water flow in plants. High calibre PhD and Hono ....Calcium compartmentation in leaves: testing an integrated model of water and calcium transport with cell specific functional genomics. Calcium is a vital nutrient to animals and humans and its storage in vegetation is important for its accessibility. We believe this storage is linked to water flow in the leaf by a novel mechanism. This project will provide fundamental understanding of the cell type-specific processes involved in calcium storage and water flow in plants. High calibre PhD and Honours students will be educated to maintain the momentum of international excellence within Australia in the field of plant nutrient relations. The increase in understanding will allow future work to improve calcium availability and water use by plants to the benefit of agricultural productivity and quality of life.Read moreRead less