Enhancing native seed performance for minesite restoration and biodiversity conservation. The knowledge and practical outcomes generated from this project will facilitate more effective restoration of degraded native ecosystems through the return of a wider range of key understorey plant taxa and more efficient use of seed supplies. Availability of a broader suite of species will increase biodiversity, improve ecosystem resilience to change, and help in the conservation and recovery of nationall ....Enhancing native seed performance for minesite restoration and biodiversity conservation. The knowledge and practical outcomes generated from this project will facilitate more effective restoration of degraded native ecosystems through the return of a wider range of key understorey plant taxa and more efficient use of seed supplies. Availability of a broader suite of species will increase biodiversity, improve ecosystem resilience to change, and help in the conservation and recovery of nationally threatened taxa. By increasing the range of species with horticultural potential available for commercial propagation, it will also reduce the harvest of wild flowers. More efficient production and use of seed stocks will reduce the pressure on limited seed resources from seed harvesting.Read moreRead less
Novel oxygen sensing tools for monitoring the effects of dredging on Australian seagrass communities. Seagrass meadows sustain marine biodiversity and the fishing industries on Australian coasts. Dredging of ports and shipping channels is contributing to their rapid global decline. The project will use state-of-the-art technologies in bio-optics and genomics to create a toolkit for seagrass managers to make informed decisions to safeguard seagrass meadows.
Efficient organelle transformation. Chloroplasts and mitochondria are the powerhouses of plant and animal cells. Ability to express introduced genes in these organelles has enormous biotechnological potential in agriculture and medicine, but practical development has been almost stalled for 15 years by very low transformation efficiency. Plastid transformation is today routine only in tobacco; and mitochondrial transformation has been achieved only in yeasts and algae. We have developed a soluti ....Efficient organelle transformation. Chloroplasts and mitochondria are the powerhouses of plant and animal cells. Ability to express introduced genes in these organelles has enormous biotechnological potential in agriculture and medicine, but practical development has been almost stalled for 15 years by very low transformation efficiency. Plastid transformation is today routine only in tobacco; and mitochondrial transformation has been achieved only in yeasts and algae. We have developed a solution, and achieved the key technical requirements for proof of concept. This collaboration between industry, government and university partners will deliver key Australian-owned IP, for environmentally-friendly plant biofactories, and for treatment of mitochondrial genetic disorders.Read moreRead less
Development of cryopreservation for high value provenance collections of recalcitrant plant species used in post-mining restoration. This project will develop new and innovative ways to store highly valued native plant germplasm at ultra cold temperatures (-196 °C, in liquid nitrogen) as a means to ensure that elite genotypes used in minesite restoration and critically endangered species are not lost forever to extinction. This project will be the first of its type in Australia utilising a multi ....Development of cryopreservation for high value provenance collections of recalcitrant plant species used in post-mining restoration. This project will develop new and innovative ways to store highly valued native plant germplasm at ultra cold temperatures (-196 °C, in liquid nitrogen) as a means to ensure that elite genotypes used in minesite restoration and critically endangered species are not lost forever to extinction. This project will be the first of its type in Australia utilising a multidisciplinary approach to answer key storage questions and will provide significant national benefits to conservation programs and landcare groups, providing these with additional resources to ensure the long-term survival of native plant germplasm collections. Read moreRead less
Potential of Corymbia torelliana hybrids for hardwood forestry and investigation of their seed dispersal by Trigona bees. Cadaghi (Corymbia torelliana) and their hybrids with spotted gums (C. variegata complex) have enormous potential for plantation forestry. These hybrids have many excellent features that make them exciting as hardwood species, such as resistence to disease, tolerance of marginal environments, good wood properties, and fast growth rates. This project will create hybrids between ....Potential of Corymbia torelliana hybrids for hardwood forestry and investigation of their seed dispersal by Trigona bees. Cadaghi (Corymbia torelliana) and their hybrids with spotted gums (C. variegata complex) have enormous potential for plantation forestry. These hybrids have many excellent features that make them exciting as hardwood species, such as resistence to disease, tolerance of marginal environments, good wood properties, and fast growth rates. This project will create hybrids between Corymbia torelliana and spotted gums to identify hybrids which are suitable for sustainable wood production on marginal agricultural lands.
An unusual feature of Cadaghi is that native Trigona bees disperse their seeds. This project will investigate this unique seed dispersal mechanism and identify features of hybrids that are not attractive to bees. This will prevent environmental problems by preventing hybrids from dispersing seeds, becoming weedy and harming the Trigona bees.
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Enabling Molecular Plant Breeding for Drought Adaptation Using Genome-to-Phenome Modelling Technologies. Effective molecular plant breeding for improved water productivity of sorghum would generate significant economic and social benefits for rural communities in NE Australia. There is a significant opportunity to expand the sorghum industry in the region. Despite the global financial crisis, global demand for meat continues to increase, generating strong demand from intensive livestock industri ....Enabling Molecular Plant Breeding for Drought Adaptation Using Genome-to-Phenome Modelling Technologies. Effective molecular plant breeding for improved water productivity of sorghum would generate significant economic and social benefits for rural communities in NE Australia. There is a significant opportunity to expand the sorghum industry in the region. Despite the global financial crisis, global demand for meat continues to increase, generating strong demand from intensive livestock industries for feed grain. Price is projected to return to high levels given continuing use of major feed grains for biofuel. A 10% increase in sorghum production would add net value of $48M annually, much via employment. The scientific content of this project positions Australia at the leading edge globally in this emerging research field. Read moreRead less
Living in a high carbon dioxide world: impacts on freshwater phytoplankton populations from elevated atmospheric carbon dioxide. This project will investigate likely changes in phytoplankton populations in reservoirs that will be caused by increases in atmospheric carbon dioxide over the next century. The project will provide water supply managers with the necessary information to plan future strategies for water treatment and operating procedures.
Eco-Turf: Water and nutrient use efficient turfgrasses from Australian biodiversity. Domestic water consumption in Australia is approximately 30% higher than the OECD average. Approximately one third of domestic water consumption is applied to the garden, including turfgrass lawns. Turfgrasses are significant users of fertilisers, which can lead to problems with runoff and infiltration into the water table. We will use the unique diversity of Australian couch grasses to identify new turfs for ....Eco-Turf: Water and nutrient use efficient turfgrasses from Australian biodiversity. Domestic water consumption in Australia is approximately 30% higher than the OECD average. Approximately one third of domestic water consumption is applied to the garden, including turfgrass lawns. Turfgrasses are significant users of fertilisers, which can lead to problems with runoff and infiltration into the water table. We will use the unique diversity of Australian couch grasses to identify new turfs for domestic, sportsground and amenity lawns. This project will develop tools to select turfgrasses that maintain quality with reduced inputs of water and nutrients, leading to an overall reduction in resource use and downstream ecological effects. Benefits of this project extend to urban and rural communities Australia-wide.Read moreRead less
Polymetallic phytoextraction applied to mine waste. Phytoextraction involves the use of hyperaccumulator plants to grow and concentrate a metal. Subsequently, the crop is harvested and the metal extracted. The aim of this research is to investigate the uptake and chemically induced uptake of heavy metals (Ni, Co, Au, Ag, Cu, Pb, Zn, Pt, Pd, Cr) by plants grown on mine tailings and mine waste materials. Outcomes will include practical methods of metal extraction that are cheap to employ where met ....Polymetallic phytoextraction applied to mine waste. Phytoextraction involves the use of hyperaccumulator plants to grow and concentrate a metal. Subsequently, the crop is harvested and the metal extracted. The aim of this research is to investigate the uptake and chemically induced uptake of heavy metals (Ni, Co, Au, Ag, Cu, Pb, Zn, Pt, Pd, Cr) by plants grown on mine tailings and mine waste materials. Outcomes will include practical methods of metal extraction that are cheap to employ where metal concentrations are subeconomic and of potential environmental impact during mining and after mine closure.Read moreRead less