Manipulation of carbon partitioning to enhance the value of sugarcane. Manipulation of carbon partitioning to enhance the value of sugarcane. This project aims to develop enhanced varieties of sugarcane, a highly efficient crop for capturing carbon in plant biomass. This project will use genomic and metabolomic tools to investigate the biochemical and molecular genetic control of carbon partitioning into the major components of sugarcane biomass; identify key genetic controls of sucrose, cellulo ....Manipulation of carbon partitioning to enhance the value of sugarcane. Manipulation of carbon partitioning to enhance the value of sugarcane. This project aims to develop enhanced varieties of sugarcane, a highly efficient crop for capturing carbon in plant biomass. This project will use genomic and metabolomic tools to investigate the biochemical and molecular genetic control of carbon partitioning into the major components of sugarcane biomass; identify key genetic controls of sucrose, cellulose, hemicellulose and lignin biosynthesis; and establish strategies for genetic selection of sugarcane genotypes with desirable biomass components. Anticipated outcomes are an optimised industrial sugarcane crops with higher sugar content and other biomass components designed for high value end uses such as bio-energy or bio-material production.Read moreRead less
A novel reversible male sterility system for hybrid seed production in canola, cotton and oilseed mustard. Demand for grains, fibre and other agricultural products has recently increased significantly. Hence, the security of food production is emerging as a critical global issue. We have identified a central component (AtMYB103) controlling tapetum and thus pollen development and designed a novel reversible male sterility system using AtMYB103. The efficient hybrid seed production systems develo ....A novel reversible male sterility system for hybrid seed production in canola, cotton and oilseed mustard. Demand for grains, fibre and other agricultural products has recently increased significantly. Hence, the security of food production is emerging as a critical global issue. We have identified a central component (AtMYB103) controlling tapetum and thus pollen development and designed a novel reversible male sterility system using AtMYB103. The efficient hybrid seed production systems developed in this project for canola, cotton and mustard will increase the productivity of the Australian oilseed and fibre industries. AtMYB103 gene is conserved among many crop plants. Hence, the new technologies and knowledge gained will be applicable to a wide range of crop plants and have important implications for the agricultural and food industries.Read moreRead less
Improved Indian Mustard for sustainable biodiesel production. There is an urgent need to reduce Australia's dependency on fossil fuels and to improve the sustainability of the Australian farming sector. The on-farm production of biodiesel will reduce farm input costs, reduce farmer dependency on fluctuations in fossil fuel costs and reduce greenhouse gas emissions. Indian mustard is drought tolerant and produces inedible oil suitable for biodiesel production. The genetic improvement of Indian mu ....Improved Indian Mustard for sustainable biodiesel production. There is an urgent need to reduce Australia's dependency on fossil fuels and to improve the sustainability of the Australian farming sector. The on-farm production of biodiesel will reduce farm input costs, reduce farmer dependency on fluctuations in fossil fuel costs and reduce greenhouse gas emissions. Indian mustard is drought tolerant and produces inedible oil suitable for biodiesel production. The genetic improvement of Indian mustard will provide farmers with a viable crop for biodiesel production and its bio-fumigation properties make it an effective addition to the crop rotation. Useful by-products include a natural insecticide and, once the glucosinolates are removed, meal suitable for animal feed. Read moreRead less
Characterisation of a major quantitative trait locus on wheat chromosome 3BL responsible for Fusarium crown rot resistance. Fusarium crown rot (FCR) is a serious wheat disease in Australia and worldwide. Our team has identified a major chromosome region controlling this disease. This project is proposing to develop DNA markers for marker assisted breeding, to understand the genetic mechanism of resistance and to identify genes responsible for resistance to the disease.
Combining molecular plant physiology and breeding to improve canola (Brassica napus) performance in dry environments. Canola is Australia's most important oilseed crop with 1,400,000 hectares sown annually worth $560m. The major abiotic factor limiting canola production in Australia is water availability. Transpiration efficiency (TE) is a trait with potential to contribute to improved drought tolerance of grain crops. This project seeks to select canola germplasm with improved TE by indirect s ....Combining molecular plant physiology and breeding to improve canola (Brassica napus) performance in dry environments. Canola is Australia's most important oilseed crop with 1,400,000 hectares sown annually worth $560m. The major abiotic factor limiting canola production in Australia is water availability. Transpiration efficiency (TE) is a trait with potential to contribute to improved drought tolerance of grain crops. This project seeks to select canola germplasm with improved TE by indirect selection for carbon-isotope-discrimination. In addition we will use the extensive Brassica-Arabidopsis genome synteny to locate and alter the expression of genes involved in TE using Arabidopsis as a model. The longterm aim is to improve the reliability and overall grain production of canola in Australia. Read moreRead less
Physiological and genetic mechanisms underlying tolerance of bread wheat to ion toxicities. Ion toxicities associated with acidic or alkaline soils and waterlogging cost about $190 million per year in lost yield in Western Australia alone. Soil ameliorants and agricultural measures to deal with these constraints are non-existent (B toxicity in alkaline sodic subsoils), non-effective (liming of acidic subsoils), expensive (drainage for waterlogged soils) or a combination of the above. This projec ....Physiological and genetic mechanisms underlying tolerance of bread wheat to ion toxicities. Ion toxicities associated with acidic or alkaline soils and waterlogging cost about $190 million per year in lost yield in Western Australia alone. Soil ameliorants and agricultural measures to deal with these constraints are non-existent (B toxicity in alkaline sodic subsoils), non-effective (liming of acidic subsoils), expensive (drainage for waterlogged soils) or a combination of the above. This project will characterise wheat genotypes for tolerance to ion toxicities and will lay the groundwork for deliberate breeding effort toward pyramiding tolerance to ion toxicities in elite germplasm.Read moreRead less
Physiological and molecular characterisation of salinity tolerance in chickpea. Chickpea is a grain legume often grown in rotation with cereal crops to enhance profitability and environmental sustainability of broadacre cropping systems in Australia, and elsewhere. Chickpea is sensitive to salinity, and thus can not be grown on soils affected even by mild salinity. Limited grain legume options currently exist for these soils. This project will improve salt tolerance in chickpea and thus allow it ....Physiological and molecular characterisation of salinity tolerance in chickpea. Chickpea is a grain legume often grown in rotation with cereal crops to enhance profitability and environmental sustainability of broadacre cropping systems in Australia, and elsewhere. Chickpea is sensitive to salinity, and thus can not be grown on soils affected even by mild salinity. Limited grain legume options currently exist for these soils. This project will improve salt tolerance in chickpea and thus allow it to be grown in areas too saline for current cultivars. The research contributes to the National Research Priority of 'An Environmentally Sustainable Australia', as new cultivars of chickpea with improved salt tolerance will enhance the profitability and sustainability of rotational cropping systems in Australia.Read moreRead less
Controlling accumulation of elements in the shoots of higher plants by manipulating processes in specific cell types in the roots. This project will provide novel, fundamental understanding of the processes controlling accumulation of elements in the shoots of plants. As such, it will impact on our understanding of processes relevant to stress tolerance, plant nutrition, human nutrition and the removal of toxic metals from soils by plants. These are all areas of great importance to Australian ag ....Controlling accumulation of elements in the shoots of higher plants by manipulating processes in specific cell types in the roots. This project will provide novel, fundamental understanding of the processes controlling accumulation of elements in the shoots of plants. As such, it will impact on our understanding of processes relevant to stress tolerance, plant nutrition, human nutrition and the removal of toxic metals from soils by plants. These are all areas of great importance to Australian agriculture, environmental sustainability and human health. The increased understanding arising from this project will underpin future work to increase agricultural productivity and the quality of life for all in the Australian and international communities.Read moreRead less
Developing molecular and physiological markers for marker-assisted barley breeding for waterlogging tolerance. The overall loss in crop production due to waterlogging is second largest after drought, and more than 5 million hectares in Australia are prone to waterlogging. This project will develop physiological and molecular markers allowing for the development of waterlogging tolerant crops, thus contributing to the National Goal of ‘Responding to Climate Change and Variability’.
Predicting Perfect Partners: climate resilient seed production technology . This project aims to increase productivity and profitability of the Australian sorghum industry in the face of risks imposed by an increasingly variable climate. This project expects to generate new knowledge of processes limiting hybrid seed production and translate this world-class research into tools and services that can be used by seed companies to improve its efficiency and reliability. The intended outcome will in ....Predicting Perfect Partners: climate resilient seed production technology . This project aims to increase productivity and profitability of the Australian sorghum industry in the face of risks imposed by an increasingly variable climate. This project expects to generate new knowledge of processes limiting hybrid seed production and translate this world-class research into tools and services that can be used by seed companies to improve its efficiency and reliability. The intended outcome will increase the security and sustainability of farming by minimising the risk of climate-induced seed shortages, maintaining Australia’s leadership in agricultural technology development. The expected benefits support profitable and productive businesses, providing Australian agriculture with a competitive, sustainable edge.Read moreRead less