Australia, the centre of diversity and the centre of origin of rice? Wild relatives of rice are found across northern Australia. The project aims to apply emerging technologies for efficient whole genome sequencing to determination of the genetic diversity of these populations in relation to cultivated rice and wild rice from other parts of the world. The role of the Australian populations in the evolution of rice and the potential of these populations to contribute valuable diversity to rice cr ....Australia, the centre of diversity and the centre of origin of rice? Wild relatives of rice are found across northern Australia. The project aims to apply emerging technologies for efficient whole genome sequencing to determination of the genetic diversity of these populations in relation to cultivated rice and wild rice from other parts of the world. The role of the Australian populations in the evolution of rice and the potential of these populations to contribute valuable diversity to rice crops worldwide are intended to be analysed. The impact of domestication on rice in Asia is expected to be established by the characterisation of the related Australian populations that were isolated from the impacts of agriculture for around 7000 years. Whole genome associations with environment may provide clues to adapting agriculture to climate.Read moreRead less
Breaking the nexus: more biomass in cereal grain. Grain yield is controlled by complex, regulated genetic networks or quantitative trait loci (QTLs) derived from natural variations in many crop plants. Yield is a product of the three major parameters: panicle number, grain number and grain size, trade-offs are commonly observed between grain number and size. There is evidence to suggest it is possible to improve grain size without altering overall biomass. With the genomic and genetic resource t ....Breaking the nexus: more biomass in cereal grain. Grain yield is controlled by complex, regulated genetic networks or quantitative trait loci (QTLs) derived from natural variations in many crop plants. Yield is a product of the three major parameters: panicle number, grain number and grain size, trade-offs are commonly observed between grain number and size. There is evidence to suggest it is possible to improve grain size without altering overall biomass. With the genomic and genetic resource tools at hand. This project will elucidate the genetic architecture of grain size, and manipulate the key loci to generate more biomass in the grain, minimising or eliminating the adverse impact on seed number. This will maximise harvestable yield without imposing increased demand for water and nutrients.Read moreRead less
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
Cereal blueprints for a water-limited world. This project aims to demonstrate that key developmental genes in cereals can be manipulated to design plant architecture for specific resource-limited environments. Producing more food with less water is one of the greatest challenges facing humanity today. This project expects to increase understanding of how shoot and root systems can be uncoupled to enhance crop adaptation in water-limited environments using an accelerated genome editing approach. ....Cereal blueprints for a water-limited world. This project aims to demonstrate that key developmental genes in cereals can be manipulated to design plant architecture for specific resource-limited environments. Producing more food with less water is one of the greatest challenges facing humanity today. This project expects to increase understanding of how shoot and root systems can be uncoupled to enhance crop adaptation in water-limited environments using an accelerated genome editing approach. An expected outcome of the project is enhanced drought adaptation for cereals in a dry world. This should provide significant benefits to farmers and consumers in Australia and worldwide.Read moreRead less
Plant heterotrimeric G proteins: new roles in defence, stomatal control and ABA perception. Agriculture is an important economic activity in Australia that results in considerable export revenues. Two of the major problems facing agriculture around the globe are the incidence of diseases and the scarcity of water. Agricultural losses caused by plant pathogens and low water availability account for billions of dollars every year and have profound economic and social implications. Water is an extr ....Plant heterotrimeric G proteins: new roles in defence, stomatal control and ABA perception. Agriculture is an important economic activity in Australia that results in considerable export revenues. Two of the major problems facing agriculture around the globe are the incidence of diseases and the scarcity of water. Agricultural losses caused by plant pathogens and low water availability account for billions of dollars every year and have profound economic and social implications. Water is an extremely scarce resource in Australia and periodic droughts inflict immense losses to the Australian agricultural sector. Our research will explore new and cleaner strategies to provide crop protection as well as to increase water use efficiency.Read moreRead less
Extreme expression: building a platform for industrial plant biotechnology. Plants have remarkable potential as bioreactors for the production of usually non-plant compounds such as medical proteins, industrial proteins including enzymes and polymers. However, to realise this potential, there needs to be very significant advances in the amount of target compounds produced in the bioreactor plants and to develop other plant species as bioreactors. The aim of this project is to develop technologie ....Extreme expression: building a platform for industrial plant biotechnology. Plants have remarkable potential as bioreactors for the production of usually non-plant compounds such as medical proteins, industrial proteins including enzymes and polymers. However, to realise this potential, there needs to be very significant advances in the amount of target compounds produced in the bioreactor plants and to develop other plant species as bioreactors. The aim of this project is to develop technologies that provide the platform to produce large quantities of target novel compounds in plants and extend the range of plant species that can be used as bioreactors. These technologies will provide the basis of a dynamic biofarming industry in Australia.Read moreRead less
To move or not to move: are insect movement strategies driven by plant-induced defences? Plants change chemically when damaged by insects. By showing how movement and feeding is related to these induced defences we can manipulate plant defences to resist insect attack in a more focused way. Our target insects are major pests against which we use large amounts of insecticide. Our research will decrease insect damage to crops using existing genetic machinery of plants as opposed to inserting 'nove ....To move or not to move: are insect movement strategies driven by plant-induced defences? Plants change chemically when damaged by insects. By showing how movement and feeding is related to these induced defences we can manipulate plant defences to resist insect attack in a more focused way. Our target insects are major pests against which we use large amounts of insecticide. Our research will decrease insect damage to crops using existing genetic machinery of plants as opposed to inserting 'novel' toxin-expressing genes. This project builds on Australia's strong record of achievement in agricultural and natural resource research by increasing understanding of the interplay between plant traits and insects. We will build cross-disciplinary research capacity training a new generation of biologists in an exciting area of science.Read moreRead less
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
Development of novel pest management tools for major insect pests. The project will provide new options for environmentally sustainable control of some of the world's worst pests. Cost effective systems will be developed that prevent crop damage, using chemicals identical to naturally occurring plant compounds, combined with tiny quantities of insecticides, to lure and kill adult moths before they lay eggs.
NextGen Sorghum: Genomic approaches to novel renewable bioproducts. Next Gen Sorghums will have enhanced nutritional and processing qualities for humans and animals, and be ideal feedstocks for the bio-economy for the delivery of novel products. Our approaches in reverse genetics to identify gene networks which control sorghum seed development, cell size, cell wall thickness and the way in which starch and protein are packaged within the grain will generate knowledge to underpin the future utili ....NextGen Sorghum: Genomic approaches to novel renewable bioproducts. Next Gen Sorghums will have enhanced nutritional and processing qualities for humans and animals, and be ideal feedstocks for the bio-economy for the delivery of novel products. Our approaches in reverse genetics to identify gene networks which control sorghum seed development, cell size, cell wall thickness and the way in which starch and protein are packaged within the grain will generate knowledge to underpin the future utilisation of this important grain. This will help to drive the future of Australian cereals industries, with health benefits to consumers, the enhanced delivery of specialised feedstocks for novel and renewable bio-products, and financial benefits to farmers.Read moreRead less