Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989782
Funder
Australian Research Council
Funding Amount
$524,000.00
Summary
A Core Western Australian Cell Sorting Facility - Ultra-Small Objects and Rare Cell Populations. This new generic capacity to rapidly isolate structures smaller than the cell has extraordinarily wide application in the biological sciences. Making this capacity widely accessible through a core facility to the Western Australian research community will generate research outcomes of national and community benefit. Sorting chromosomes to better understand genetic abnormalities and sorting bacteria t ....A Core Western Australian Cell Sorting Facility - Ultra-Small Objects and Rare Cell Populations. This new generic capacity to rapidly isolate structures smaller than the cell has extraordinarily wide application in the biological sciences. Making this capacity widely accessible through a core facility to the Western Australian research community will generate research outcomes of national and community benefit. Sorting chromosomes to better understand genetic abnormalities and sorting bacteria to better understand and reduce bacterial infection will result in improvements in human health. Sorting parasites, bacteria and immune cells will lead to new animal vaccines for parasites and diseases such as bird flu. Sorting marine plankton will lead to more sustainable marine ecosystems and fisheries.Read moreRead less
Investigation of the metabolism, molecular targets and environmental fate of the seed germination stimulant, butenolide. The potent germination stimulant, known as butenolide, is expected to provide substantial benefits for improving seed germination and seedling vigour of many plant species used in agriculture, land restoration and rehabilitation. Currently, little is known about the stability, persistence and distribution of the butenolide in natural environments and the mechanism of seed dorm ....Investigation of the metabolism, molecular targets and environmental fate of the seed germination stimulant, butenolide. The potent germination stimulant, known as butenolide, is expected to provide substantial benefits for improving seed germination and seedling vigour of many plant species used in agriculture, land restoration and rehabilitation. Currently, little is known about the stability, persistence and distribution of the butenolide in natural environments and the mechanism of seed dormancy breaking. This study now provides a unique opportunity for Australian research to establish a world-leading position in understanding the processes that regulate seed dormancy, particularly in relation to post-mining land rehabilitation. The research findings will also have wider application in plant conservation, weed control and crop production.Read moreRead less
Indian Sandalwood: genetic and oil diversity, and oil biochemistry of the Australian germplasm collection. The main aim is to improve the commerciality of the sandalwood industry in tropical Australia through smarter tree selection and breeding by development of knowledge of oil quality and quantity, oil biochemistry and DNA marker-assisted selection of the germplasm collection available in Australia.
Synthesis and evaluation of labelled germination stimulants for determining the role of butenolide in promoting seed germination. The discovery of the germination promotive agent in smoke (a butenolide) represents a major and internationally significant scientific discovery for Australia and provides exciting opportunities for benefits in agriculture, natural lands management and restoration sciences. The activity demonstrated with a broad range of species shows that the butenolide has general a ....Synthesis and evaluation of labelled germination stimulants for determining the role of butenolide in promoting seed germination. The discovery of the germination promotive agent in smoke (a butenolide) represents a major and internationally significant scientific discovery for Australia and provides exciting opportunities for benefits in agriculture, natural lands management and restoration sciences. The activity demonstrated with a broad range of species shows that the butenolide has general applicability worldwide. This study now provides a unique opportunity for Australian research to establish a world-leading position in understanding the butenolide mode of action within plant seeds which will result in a significant advance in our understanding of the processes that regulate seed dormancy in many plant species. Read moreRead less
Circular Plant Proteins with Pharmaceutical Applications. The proposed research will develop methods for using plants as protein production factories. Initially I will use plants to create engineered cyclotides that incorporate peptides with proven therapeutic activity against cancer and multiple sclerosis. Successful production of therapeutic proteins in plants will benefit Australians by making treatments for these and other diseases more accessible. It also has the potential for a major econo ....Circular Plant Proteins with Pharmaceutical Applications. The proposed research will develop methods for using plants as protein production factories. Initially I will use plants to create engineered cyclotides that incorporate peptides with proven therapeutic activity against cancer and multiple sclerosis. Successful production of therapeutic proteins in plants will benefit Australians by making treatments for these and other diseases more accessible. It also has the potential for a major economic benefit from the sales of Australian-based drugs. This proposal will also provide outstanding research training for graduate students in multidisciplinary methods that constitute state-of the-art structural and plant molecular biology.Read moreRead less
Discovery of novel circular proteins in bacteria, plants and animals: applications in drug design and crop protection. The overall goal is to use innovative methods in chemistry, biochemistry and molecular biology to determine the structures and functions of several families of circular proteins that have exciting pharmaceutical and agricultural applications. These molecules differ from conventional proteins in that they have no ends: their termini are seamlessly joined, thereby making them exce ....Discovery of novel circular proteins in bacteria, plants and animals: applications in drug design and crop protection. The overall goal is to use innovative methods in chemistry, biochemistry and molecular biology to determine the structures and functions of several families of circular proteins that have exciting pharmaceutical and agricultural applications. These molecules differ from conventional proteins in that they have no ends: their termini are seamlessly joined, thereby making them exceptionally stable and resistant to enzyme digestion. The big question is ?How and why does Nature produce circular proteins?" Increasing our knowledge of why circular proteins have evolved will facilitate their applications in drug design and in the development of novel insecticides.Read moreRead less
Membrane transporters in oxidative stress signalling and tolerance in plants. Oxidative stress imposed by salinity and drought severely limits agricultural crop production, resulting in multibillion dollar losses to farmers. Australia is one of the driest continents, with a significant proportion of arable land affected by salinity. Thus, developing salt- and drought tolerant species is critical to minimise the impact of these stresses on crop production. This project will reveal specific ionic ....Membrane transporters in oxidative stress signalling and tolerance in plants. Oxidative stress imposed by salinity and drought severely limits agricultural crop production, resulting in multibillion dollar losses to farmers. Australia is one of the driest continents, with a significant proportion of arable land affected by salinity. Thus, developing salt- and drought tolerant species is critical to minimise the impact of these stresses on crop production. This project will reveal specific ionic mechanisms mediating reactive oxygen species signalling and tolerance in plants. This will help achieve the above goal by providing plant breeders with vital information on key genes controlling oxidative stress tolerance in plants. Read moreRead less
Coping with flooding: nutrient transport in oxygen-deprived roots. Flooding damages plants by reducing oxygen supply to roots. The project will study effects of low oxygen on nutrient transport by roots. Understanding root functioning during low oxygen will enhance knowledge of plant acclimation to soil water logging. The project will contribute to the National Goal of 'Responding to Climate Change and Variability'.
Diversity of pollination biology in heat-producing flowers. This research is an entirely new approach to understanding pollination biology. It will highlight the value of ecological diversity in tropical ecosystems and will work toward conservation of these threatened habitats. The project is very strong in developing international links, involving Australia, Germany, France, Turkey, Brazil, Guyana, India and Malaysia. By supporting research involving the International Canopy Crane Network, A ....Diversity of pollination biology in heat-producing flowers. This research is an entirely new approach to understanding pollination biology. It will highlight the value of ecological diversity in tropical ecosystems and will work toward conservation of these threatened habitats. The project is very strong in developing international links, involving Australia, Germany, France, Turkey, Brazil, Guyana, India and Malaysia. By supporting research involving the International Canopy Crane Network, Australia will be recognised as a major contributor to the multinational effort. The project deals with energetics of scarab beetles, with work on reproductive energetics of natural and pest species. Research maintains and develops critical thought, essential for effective university teaching and training.Read moreRead less
More than defence: primary roles for cyanogenic glucosides. The tropical crop, sorghum, produces toxic cyanide to avoid being eaten by herbivores, but this diverts resources away from growth and reproduction. Using non-toxic sorghum mutants, this project seeks to explain how cyanide production is regulated and enhance agricultural efficiency in the face of climate change.