Life hanging on a thread; disrupting the structure and function of lepidopteran silking behaviour. The production and use of silk by many invertebrates is vital for their survival. We develop a means of visualising and understanding the role of silking behaviour as a survival mechanism for Helicoverpa larvae (a key world-wide pest) with a view to disrupting silking. This novel project allows us to understand not just where larvae go but what they do along the way. The project outcomes will have ....Life hanging on a thread; disrupting the structure and function of lepidopteran silking behaviour. The production and use of silk by many invertebrates is vital for their survival. We develop a means of visualising and understanding the role of silking behaviour as a survival mechanism for Helicoverpa larvae (a key world-wide pest) with a view to disrupting silking. This novel project allows us to understand not just where larvae go but what they do along the way. The project outcomes will have wide application to the study and control of lepidopteran pests in natural and agricultural ecosystems and is of interest to applied and fundamental projects associated with insect pest control, behaviour and ecology.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0561042
Funder
Australian Research Council
Funding Amount
$852,705.00
Summary
Establishing a high-throughput Protein Production Unit. We seek to establish a world class high-throughput (H-T) protein production unit, the first of its kind in Australia. Throughout the unit robotic technology will be used to build and test protein expression systems as well as drive large scale protein production. The product of the unit will be high quality, pure protein, effective expression systems and world class research. The unit will act as a centre for research into H-T protein ex ....Establishing a high-throughput Protein Production Unit. We seek to establish a world class high-throughput (H-T) protein production unit, the first of its kind in Australia. Throughout the unit robotic technology will be used to build and test protein expression systems as well as drive large scale protein production. The product of the unit will be high quality, pure protein, effective expression systems and world class research. The unit will act as a centre for research into H-T protein expression technology, will underpin the finest biological research, provide the basis for large "structural genomic" type approaches to biological problems and provide a wealth of projects for the Australian synchrotron.Read moreRead less
ARC/NHMRC Research Network Fluorescence Applications in Biotechnology and Life Sciences. This Network will concentrate Australian research in new applications of fluorescence to biological systems to solve significant problems in health diagnostics, biotechnology and the environment. The scientific goals identified by the Network such as highly selective fluorescent labelling and purpose-engineered fluorochromes will be accompanied by the development of specialised instrumentation. These resear ....ARC/NHMRC Research Network Fluorescence Applications in Biotechnology and Life Sciences. This Network will concentrate Australian research in new applications of fluorescence to biological systems to solve significant problems in health diagnostics, biotechnology and the environment. The scientific goals identified by the Network such as highly selective fluorescent labelling and purpose-engineered fluorochromes will be accompanied by the development of specialised instrumentation. These research directions pursued by strong multi-disciplinary teams spanning biology, chemistry, physics, bioengineering and medicine will benefit from the support of the Network programs. Through its focus on academic - industry collaboration the Network will also facilitate development of basic scientific discoveries into commercial outcomes.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0775673
Funder
Australian Research Council
Funding Amount
$1,200,000.00
Summary
A high throughput protein crystallization & imaging facility. Protein crystallography is an important field of research that enables us to understand the precise shape of proteins. The precise shape of a protein determines the function of a protein. This information is essential in understanding the physiological role of a protein and may be used for the development of therapeutics, where approrpiate. We aim to develop a high-throughput robotics system that will enable us to determine the sh ....A high throughput protein crystallization & imaging facility. Protein crystallography is an important field of research that enables us to understand the precise shape of proteins. The precise shape of a protein determines the function of a protein. This information is essential in understanding the physiological role of a protein and may be used for the development of therapeutics, where approrpiate. We aim to develop a high-throughput robotics system that will enable us to determine the shape of many proteins more rapidly, thereby greatly accelerating the pace of biomedical research.Read moreRead less
Accelerating the genetic improvement of grain legumes for Australia by developing doubled haploid technology for field pea and chickpea. Doubled haploid technology is used in many broad acre crop species to accelerate cultivar development and create homozygous populations for genetic mapping. Field pea and chickpea have been unresponsive to this technique but a recent breakthrough by UWA researchers has resulted in haploid pro-embryos from in vitro cultured immature pollen. A barrier to further ....Accelerating the genetic improvement of grain legumes for Australia by developing doubled haploid technology for field pea and chickpea. Doubled haploid technology is used in many broad acre crop species to accelerate cultivar development and create homozygous populations for genetic mapping. Field pea and chickpea have been unresponsive to this technique but a recent breakthrough by UWA researchers has resulted in haploid pro-embryos from in vitro cultured immature pollen. A barrier to further embryo maturation has been identified, which we propose to overcome using powerful microscopy tools to elucidate haploid embryology processes. This information will be applied to develop world-first in vitro doubled haploid protocols for these species, which will facilitate the development and accelerated delivery to industry of better adapted, high yielding cultivars.Read moreRead less
Expanding the gene pool of canola (Brassica napus) by introgressing valuable genes from related species. Canola is a high value export crop from Australia, and an important rotational crop which improves sustainability of agriculture through a disease and weed break for cereal crops. While breeders have improved quality, disease resistance and adaptation of canola to Australian conditions over the past 30 years, this has reduced genetic variation to dangerously low levels. Wide crossing with d ....Expanding the gene pool of canola (Brassica napus) by introgressing valuable genes from related species. Canola is a high value export crop from Australia, and an important rotational crop which improves sustainability of agriculture through a disease and weed break for cereal crops. While breeders have improved quality, disease resistance and adaptation of canola to Australian conditions over the past 30 years, this has reduced genetic variation to dangerously low levels. Wide crossing with drought tolerant Brassica carinata (Ethiopean mustard) will help to alleviate this problem. New uses of biotechnology, combined with molecular genetics, will help to overcome species barriers to introduce useful new genes into canola for Australian canola breeders.Read moreRead less
Why are many fungicide lead compounds active against pathogens in axenic culture but inactive when applied to infected plants? It is much cheaper and easier to screen compounds for fungicidal activity in vivo (that is against the fungus grown in axenic culture) than to test in planta. However, it is commonly observed that compounds active in in vivo screens do not subsequently prove to be active in planta. The aim of this project is to investigate the physiological, biochemical and genetics basi ....Why are many fungicide lead compounds active against pathogens in axenic culture but inactive when applied to infected plants? It is much cheaper and easier to screen compounds for fungicidal activity in vivo (that is against the fungus grown in axenic culture) than to test in planta. However, it is commonly observed that compounds active in in vivo screens do not subsequently prove to be active in planta. The aim of this project is to investigate the physiological, biochemical and genetics basis of this discrepancy and to attempt to provide tools that circumvent the problem. It is expected the project will generate novel information on the environment in the plant experienced by the fungus.Read moreRead less
Fabrication of robust nanoscale optical biosensors using the novel spinning disc reactor technology. Spinning Disc Reactor (SDR) technology is new to Australia and will have wide ranging applications in nano-technology, and is destined to attract significant industrial interest beyond the proposed application in nano-scale biosensors. SDR is based on continuous flow and is more benign (less chemical waste) than traditional batch technology with a smaller footprint and significantly reduced capit ....Fabrication of robust nanoscale optical biosensors using the novel spinning disc reactor technology. Spinning Disc Reactor (SDR) technology is new to Australia and will have wide ranging applications in nano-technology, and is destined to attract significant industrial interest beyond the proposed application in nano-scale biosensors. SDR is based on continuous flow and is more benign (less chemical waste) than traditional batch technology with a smaller footprint and significantly reduced capital outlay. The emergence of SDR technology will revolutionize the practice of nano-engineering leading to miniaturization of devices, advances in information technologies and intelligent systems, and the revolution in medical science. The exciting research will enhance public opinion towards science.Read moreRead less