Transport of nucleotide sugars and their roles in cell wall biosynthesis. This project aims to define and manipulate transporters involved in the delivery of activated sugars for cell wall polymer biosynthesis. Cell wall polymers play important structural and functional roles in plants. They also represent an important renewable resource in the form of biomass and contribute to the nutritional value of food. The project will complete the characterisation of cell wall-associated transporters, app ....Transport of nucleotide sugars and their roles in cell wall biosynthesis. This project aims to define and manipulate transporters involved in the delivery of activated sugars for cell wall polymer biosynthesis. Cell wall polymers play important structural and functional roles in plants. They also represent an important renewable resource in the form of biomass and contribute to the nutritional value of food. The project will complete the characterisation of cell wall-associated transporters, apply new technologies to visualise cell wall biosynthesis in growing plants and leverage this knowledge to manipulate biomass in rice. This information will provide fundamental knowledge on a crucial process in plants that can be used the development of functional foods for agriculture and tailored biomass for industry.Read moreRead less
Developing eucalypt plantations for pharmaceutical flavanone production. The project aims to produce the tools and knowledge required to establish plantations of mallee eucalypts for the production of pinocembrin and structurally related flavanones. This is important because these flavanones have been shown to have a range of medicinal applications, including treatment of diseases of the central nervous system. The research plans to focus on producing and establishing trees with improved flavano ....Developing eucalypt plantations for pharmaceutical flavanone production. The project aims to produce the tools and knowledge required to establish plantations of mallee eucalypts for the production of pinocembrin and structurally related flavanones. This is important because these flavanones have been shown to have a range of medicinal applications, including treatment of diseases of the central nervous system. The research plans to focus on producing and establishing trees with improved flavanone content and growth rates, and on understanding the biochemical mechanisms that underlie flavanone production and structural modification. Expected outcomes include supporting the development of profitable plantations in rural Australia and the establishment of plantations more widely in southern Australia, especially on marginal land.Read moreRead less
Adding value to blue mallee plantations. The project aims to develop the tools and knowledge required for establishing and enhancing the profitability of plantations of blue mallee (Eucalyptus polybractea). This is important because mallees have considerable potential for sustainable essential oil and biomass production in low rainfall regions, and they can sequester considerable amounts of carbon in their below-ground parts. The project intends to produce trees with improved oil quality and yie ....Adding value to blue mallee plantations. The project aims to develop the tools and knowledge required for establishing and enhancing the profitability of plantations of blue mallee (Eucalyptus polybractea). This is important because mallees have considerable potential for sustainable essential oil and biomass production in low rainfall regions, and they can sequester considerable amounts of carbon in their below-ground parts. The project intends to produce trees with improved oil quality and yields through chromosome doubling and breeding, and to dissect the mechanisms that underpin essential oil production through the production of mutants and studies of the main monoterpene producing enzyme.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100133
Funder
Australian Research Council
Funding Amount
$230,000.00
Summary
Expansion and Upgrade of the Newcastle Plant Growth Facility. Expansion and upgrade of the Newcastle plant growth facility: The project will upgrade and expand the Newcastle plant growth facility to ensure a continuous supply of high quality plant material required for competitively-funded research programs. This outcome will be achieved by replacing plant growth cabinets that have passed their built-in 15 year redundancy by many years, and the addition of specialist cabinets for Arabidopsis res ....Expansion and Upgrade of the Newcastle Plant Growth Facility. Expansion and upgrade of the Newcastle plant growth facility: The project will upgrade and expand the Newcastle plant growth facility to ensure a continuous supply of high quality plant material required for competitively-funded research programs. This outcome will be achieved by replacing plant growth cabinets that have passed their built-in 15 year redundancy by many years, and the addition of specialist cabinets for Arabidopsis research housed in a renovated PC2 space. Together, the infrastructure additions will enhance the productivity and excellence of core areas of plant biology research in plant development and nutrient transport, which are both areas of research that will be critical to address issues of food security in the future.Read moreRead less
Can we engineer plants to grow on salty soils? This project aims to answer questions about how plants can sustain their growth on salty soils. Plant-derived products constitute a pillar for our society. However, crop yields may be severely penalised due to unfavourable growth conditions, including soil salinity. This is particularly relevant for Australia as a large fraction of its arable land is affected by salt. This project aims to use molecular and cell biology techniques to resolve mechanis ....Can we engineer plants to grow on salty soils? This project aims to answer questions about how plants can sustain their growth on salty soils. Plant-derived products constitute a pillar for our society. However, crop yields may be severely penalised due to unfavourable growth conditions, including soil salinity. This is particularly relevant for Australia as a large fraction of its arable land is affected by salt. This project aims to use molecular and cell biology techniques to resolve mechanisms of how the synthesis of cellulose, which constitutes the bulk of a plant's biomass, is maintained in plants during salt stress. This project has potential for climate change mitigation, enhanced plant biomass production and improved fuel security.Read moreRead less
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
Enhanced algal biofuel production: optimising photosynthesis in Australian strains of marine algae. Algal biofuel produces a sustainable liquid fuel to help meet our future energy needs. This project will pioneer a multifaceted approach in molecular biology and photophysiology to engineer the best biofuel producers from Australian marine algae and will advance innovation in Australia's biofuel biotechnology development.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100001
Funder
Australian Research Council
Funding Amount
$345,475.00
Summary
Pushing the limits of fluorescence microscopy with adaptive optics. This project aims to establish an adaptive optics, super-resolution optical microscopy facility to image cellular events with the highest possible spatial resolution, in a whole cell or tissue context. Sophisticated computer-controlled deformable mirrors will be used to correct the way light is distorted as it passes through specimens, thereby overcoming aberrations found in thick and complex samples. This adaptive optics system ....Pushing the limits of fluorescence microscopy with adaptive optics. This project aims to establish an adaptive optics, super-resolution optical microscopy facility to image cellular events with the highest possible spatial resolution, in a whole cell or tissue context. Sophisticated computer-controlled deformable mirrors will be used to correct the way light is distorted as it passes through specimens, thereby overcoming aberrations found in thick and complex samples. This adaptive optics system will enable researchers to study complex behaviour of biological specimens, at the optical resolution limit in plant and animal tissues, leading to basic biology and biotechnology outcomes in biofuels, biomaterials and biomedicines.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.