Pilot-scale production of therapeutically-active cannabinoids . The Isolation of minor therapeutically-active cannabinoids from cannabis at pilot scale would establish a commercially competitive Australian industry and lead to a superior position in the global marketplace. This project aims to select elite clones from genetically diverse cannabis strains for yield of minor, but therapeutically-active, cannabinoids, and develop a pilot-scale extraction and separation procedure that can be scaled- ....Pilot-scale production of therapeutically-active cannabinoids . The Isolation of minor therapeutically-active cannabinoids from cannabis at pilot scale would establish a commercially competitive Australian industry and lead to a superior position in the global marketplace. This project aims to select elite clones from genetically diverse cannabis strains for yield of minor, but therapeutically-active, cannabinoids, and develop a pilot-scale extraction and separation procedure that can be scaled-up for commercial production. This would contribute to the growth of the agri-biotechnology sector and a skilled multidisciplinary workforce in rural Australia, thus providing significant economic benefit. The novel scale-up procedure has potential for industry adoption to add value to Australian manufacturing.
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Functional characterisation of the necrotrophic effector proteins Tox1 and Tox3 from the wheat pathogen Stagonospora nodorum. Fungal pathogens cost the Australian agricultural industry over one billion dollars per year. This project will build upon recent key advances to provide a fundamental basis on how fungal pathogens cause disease. The results from this study will promote future advances in disease management with the aim of securing Australian wheat supplies.
Interactions between genotype, plant nutrition and fungal disease development in strawberry. Strawberry (Fragaria x ananassa) growers lose more than 30% of their crop annually to disease. This project will elucidate the role of plant nutrition in disease development and investigate the interaction/s between plant genotype, pathogen and the environment. The physiological basis for durable resistance will also be established. Molecular markers for field resistance and nutrient use efficiency will ....Interactions between genotype, plant nutrition and fungal disease development in strawberry. Strawberry (Fragaria x ananassa) growers lose more than 30% of their crop annually to disease. This project will elucidate the role of plant nutrition in disease development and investigate the interaction/s between plant genotype, pathogen and the environment. The physiological basis for durable resistance will also be established. Molecular markers for field resistance and nutrient use efficiency will be developed for use in breeding programs. Furthermore, this project will enhance profitability and sustainability of the Australian strawberry industry.
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Discovery Early Career Researcher Award - Grant ID: DE120101562
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Quantifying the contribution of leaf vein networks to the leaf economics spectrum in native and agricultural species. Using a combination of eco-physiological and geometric measures this project will evaluate the influence of leaf vein networks on leaf economics. It is expected that this work will identify vein investment and network design as major sources of variability underlying species adaptive strategies, and the global leaf economics spectrum as a whole.
The role of plant hormones in legume symbioses. Soil microbes can give plants access to previously unavailable but essential nutrients through symbioses. Legumes are unique as they form symbioses with both nitrogen-fixing bacteria and with mycorrhizal fungi that supply nutrients such as phosphate. This proposal will investigate the role of the plant hormones (small, mobile, potent growth regulators) in the formation of these symbiotic relationships across legume genera. An insight into the commo ....The role of plant hormones in legume symbioses. Soil microbes can give plants access to previously unavailable but essential nutrients through symbioses. Legumes are unique as they form symbioses with both nitrogen-fixing bacteria and with mycorrhizal fungi that supply nutrients such as phosphate. This proposal will investigate the role of the plant hormones (small, mobile, potent growth regulators) in the formation of these symbiotic relationships across legume genera. An insight into the common and divergent roles of hormones in these symbioses is essential to provide researchers and breeders with new tools to maximise nutrient acquisition by legumes, important crops contributing an estimated one billion Australian dollars per year to the Australian economy.Read moreRead less
Understanding the evolution of fungicide resistance for durable control of fungal pathogens in pyrethrum. The pyrethrum plant is grown for the extraction of natural insecticidal pyrethrins used in a variety of pest control products. Australia supplies 60 per cent of the global market for natural pyrethrins. Fungal pathogens of pyrethrum can cause severe losses. This project will investigate fungicide resistance in these pathogens at the molecular level.
Cell wall invertase regulates fruit and seed development through sugar signals, sugar transporters and plasmodesmal gating. This project seeks to understand the molecular and cellular events controlling carbohydrate allocation in fruit and seed by focusing the coupling between sugar metabolism and transport using tomato as a model. The information generated may provide technological opportunities to improve fruit and seed development hence, crop yield.
Mechanisms regulating plant cell expansion: assessing the role of aquaporins and sugar signalling. This project seeks to understand the role of water channel genes in controlling water flow into expanding plant cells by using cotton fibre as a model cell. Water flow plays critical roles in plant growth, hence yield. The information generated may provide technological opportunities for improving water flow and utilization, hence, crop yield.
Does manipulation of carbon and nitrogen metabolism in transgenic rice modify flag leaf senescence and grain filling at elevated CO2? This collaborative project between Australia and Japan aims to develop strategies for genetic manipulation of rice to improve grain yield of crops growing under rising atmospheric carbon dioxide (CO2) concentrations. A promising strategy is to slow aging of leaves that supply sugars and nitrogen to the developing grain for synthesis of starch and protein. High CO2 ....Does manipulation of carbon and nitrogen metabolism in transgenic rice modify flag leaf senescence and grain filling at elevated CO2? This collaborative project between Australia and Japan aims to develop strategies for genetic manipulation of rice to improve grain yield of crops growing under rising atmospheric carbon dioxide (CO2) concentrations. A promising strategy is to slow aging of leaves that supply sugars and nitrogen to the developing grain for synthesis of starch and protein. High CO2 alters the balance between supply and demand processes and consequently the first step in developing a strategy is to understand how these processes are regulated. To achieve this understanding we will use genetically modified plants with single alterations to either supply or demand functions.Read moreRead less
Regulation and expression of disease resistance responses in the Rhynchosporium secalis/barley interaction. The barley leaf scald fungus, Rhynchosporium secalis, causes annual losses of up to 10% in Australia's major export crop, barley. The primary aim of this project is to isolate and understand the interplay of genes specifically involved in the regulation of resistance to scald. Several resistance-specific genes will be functionally analysed to identify regulatory signalling pathways that li ....Regulation and expression of disease resistance responses in the Rhynchosporium secalis/barley interaction. The barley leaf scald fungus, Rhynchosporium secalis, causes annual losses of up to 10% in Australia's major export crop, barley. The primary aim of this project is to isolate and understand the interplay of genes specifically involved in the regulation of resistance to scald. Several resistance-specific genes will be functionally analysed to identify regulatory signalling pathways that link genetic expression with the specific gene-for-gene disease resistance phenotype. Knowledge of the genes controlling signalling processes within the disease-challenged plant will allow for the development of more effective and durable resistances by traditional breeding and transgenic approaches.Read moreRead less