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Towards high efficiency biofuel systems: a molecular resolution three-dimensional atlas of the photosynthetic machinery of a high-efficiency green algae cell. Solar-powered single-cell green-algae systems represent a powerful and environmentally friendly biotechnology used to produce clean fuels, food and high value products. This project is focused on solving the three-dimensional structure of key components of the photosynthetic machinery to improve the efficiency and profitability of advance ....Towards high efficiency biofuel systems: a molecular resolution three-dimensional atlas of the photosynthetic machinery of a high-efficiency green algae cell. Solar-powered single-cell green-algae systems represent a powerful and environmentally friendly biotechnology used to produce clean fuels, food and high value products. This project is focused on solving the three-dimensional structure of key components of the photosynthetic machinery to improve the efficiency and profitability of advance microalgae production systems.Read moreRead less
Bioengineering High Efficiency Solar Driven H2 Production. The project aims to bio-engineer high-efficiency microalgae cell-lines that can drive solar powered H2 production from water. It plans to do so by increasing proton and electron supply to the H2-producing hydrogenase. It builds on patented cell lines that have enhanced light capture efficiency and H2 production capabilities. The aim of this project is to increase the efficiency of the last stage of the process (three fold) in a major ste ....Bioengineering High Efficiency Solar Driven H2 Production. The project aims to bio-engineer high-efficiency microalgae cell-lines that can drive solar powered H2 production from water. It plans to do so by increasing proton and electron supply to the H2-producing hydrogenase. It builds on patented cell lines that have enhanced light capture efficiency and H2 production capabilities. The aim of this project is to increase the efficiency of the last stage of the process (three fold) in a major step in developing economic solar-fuel systems. National benefits include the development of advanced microalgae fuels systems to increase future fuel security, reduce CO2 emissions and assist with regional development.Read moreRead less
Advanced solar powered hydrogen production systems based on green algal cells. This project aims to enhance the efficiency of solar powered hydrogen production from water and will facilitate the co-production of H2 and oil through microalgal biofuel systems. This frontier science project will therefore deliver a process with high solar conversion efficiency and will deliver multiple product streams increasing profitability.
Integrons in Xanthomonas pathovars: Do they have a role in plant pathogenicity? Bacteria in the genus Xanthomonas cause serious diseases of plants, identification being based on the plant species from which they were originally recovered. Xanthomonads contain integrons, genetic elements capable of acquiring and expressing diverse genes. In other bacterial groups, the gene content of integrons varies significantly between strains of the same species, and in many cases these genes code for cell su ....Integrons in Xanthomonas pathovars: Do they have a role in plant pathogenicity? Bacteria in the genus Xanthomonas cause serious diseases of plants, identification being based on the plant species from which they were originally recovered. Xanthomonads contain integrons, genetic elements capable of acquiring and expressing diverse genes. In other bacterial groups, the gene content of integrons varies significantly between strains of the same species, and in many cases these genes code for cell surface proteins. These characteristics are precisely those we might expect to be responsible for interactions between plants and bacteria. This project aims to examine a large collection of xanthomonads for integrons, and determine whether particular integron gene contents are associated with host-pathogen specificity.
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Spatio-temporal analysis of molecular changes during leaf senescence in arabidopsis and wheat and their response to the environment. Innovative agricultural solutions in Australia can be gained by changing the abundance of proteins and metabolites to influence plant performance and provide more robust plants and plant products. The aging and dying of leaves (leaf senescence) is a key factor in our understanding of plant development and the recovery of nutrients from dying tissues. Leaf senescenc ....Spatio-temporal analysis of molecular changes during leaf senescence in arabidopsis and wheat and their response to the environment. Innovative agricultural solutions in Australia can be gained by changing the abundance of proteins and metabolites to influence plant performance and provide more robust plants and plant products. The aging and dying of leaves (leaf senescence) is a key factor in our understanding of plant development and the recovery of nutrients from dying tissues. Leaf senescence is also important for pre-harvest impacts on seed and grain quality as leaves represent the major nitrogen store remobilised to feed these plant products. This work will support the generation of intellectual property to be applied within Australia's plant-based industries and at the same time provides a strong environment for the training of students and researchers.Read moreRead less
Mineral content of leaves and the ratio of water loss to carbon gain: environmental and genetic controls and comparison with stable isotopic measures. The ash content of leaves has promise as a cheap screen of water-use efficiency or of 'vigour' in crop plants, but the underlying mechanisms are not understood. The underlying science is at the intersection of plant growth, water use and nutrition. This project will aid breeders in understanding the conditions under which the screen may work.
Engineering plants via modified microtubule dynamics. The plant microtubule cytoskeleton is involved in many economically important functions such as controlling growth and development, cellulose deposition, and responses to pathogens and salinity. This project will increase our understanding of how the regulation of the microtubule cytoskeleton affects these processes and move us nearer to achieving economically important goals, such as the development of crop plants with improved traits. Thi ....Engineering plants via modified microtubule dynamics. The plant microtubule cytoskeleton is involved in many economically important functions such as controlling growth and development, cellulose deposition, and responses to pathogens and salinity. This project will increase our understanding of how the regulation of the microtubule cytoskeleton affects these processes and move us nearer to achieving economically important goals, such as the development of crop plants with improved traits. This project will also help maintain Australia's position at the forefront of plant cell and molecular biology.Read moreRead less
Comparative Biophysical Studies on Photosystem II of Higher Plants and Cyanobacteria. Photosystem II (PS-II) is one of two light trapping protein assemblies involved in the conversion of light into metabolic energy in all plants and algae. The manganese containing active site of PS-II is responsible for oxygen formation from water. The organisation and functioning of this centre and the detailed mechanism of photochemical energy conversion are not understood. This project will employ a combinati ....Comparative Biophysical Studies on Photosystem II of Higher Plants and Cyanobacteria. Photosystem II (PS-II) is one of two light trapping protein assemblies involved in the conversion of light into metabolic energy in all plants and algae. The manganese containing active site of PS-II is responsible for oxygen formation from water. The organisation and functioning of this centre and the detailed mechanism of photochemical energy conversion are not understood. This project will employ a combination of powerful biophysical techniques to probe the structure and mechanism of PS-II as a knowledge base for eventual genetic manipulation of plants and stategies for artificial photosynthesis.Read moreRead less
A novel DNA motif involved in plant mitochondrial stress responses. The future of Australia's agriculture is threatened by limited water resources, temperature extremes and soil salinity. This project aims to unravel how plants are able to adapt to this continuously changing environment, by focusing on the role of mitochondria - cellular compartments essential for energy metabolism and plant stress responses.
Discovery Early Career Researcher Award - Grant ID: DE170100054
Funder
Australian Research Council
Funding Amount
$372,000.00
Summary
How plants respond to cell wall signals. This project aims to discover mechanisms of plant cell wall signalling and modify plant cell walls for improved food, textiles, building materials and renewable biofuels without inadvertently activating cell wall signalling. However, attempts to improve cell walls have been ineffective because it is not known how plants use cell wall signalling to sense and compensate for cell wall changes. This project expects to develop both a genetic screen to find mut ....How plants respond to cell wall signals. This project aims to discover mechanisms of plant cell wall signalling and modify plant cell walls for improved food, textiles, building materials and renewable biofuels without inadvertently activating cell wall signalling. However, attempts to improve cell walls have been ineffective because it is not known how plants use cell wall signalling to sense and compensate for cell wall changes. This project expects to develop both a genetic screen to find mutants defective in cell wall signal transduction and a bioinformatic tool to compare genomes across species and discover cell wall signalling components. Potential benefits include addressing Australian research priorities: Food, Environmental Change, and Energy.Read moreRead less