Investigating insect neuronal plasticity under genetic and chemical stress. This project aims to study receptors that translate chemical signals into electrical signals in animal brains. These receptors are targeted by insecticides used to control the major pests that afflict agriculture and domestic pets. The project aims to establish the functions of nicotinic acetylcholine receptors in several behaviours and in insecticide responsiveness in the model insect, Drosophila melanogaster, using mut ....Investigating insect neuronal plasticity under genetic and chemical stress. This project aims to study receptors that translate chemical signals into electrical signals in animal brains. These receptors are targeted by insecticides used to control the major pests that afflict agriculture and domestic pets. The project aims to establish the functions of nicotinic acetylcholine receptors in several behaviours and in insecticide responsiveness in the model insect, Drosophila melanogaster, using mutations that knock out the function of receptor subunits. Prior research has pointed to plasticity in the expression and transport of these receptors in response to genetic and environmental change. This project aims to identify the underlying mechanisms that provide the insect with resilience, to provide better options for pest control.Read moreRead less
Characterisation of Genes involved in Secondary Metabolism in the Blackleg Pathogen of Canola. Blackleg caused by the fungus Leptosphaeria maculans is the major disease of canola. In spite of the economic importance of this fungus, little is known about its metabolic pathways, its genes and how they are organised. We have sequenced a large piece of L. maculans DNA comprising eight genes, including a regulatory gene and one that may be may be involved in producing secondary metabolites such as ....Characterisation of Genes involved in Secondary Metabolism in the Blackleg Pathogen of Canola. Blackleg caused by the fungus Leptosphaeria maculans is the major disease of canola. In spite of the economic importance of this fungus, little is known about its metabolic pathways, its genes and how they are organised. We have sequenced a large piece of L. maculans DNA comprising eight genes, including a regulatory gene and one that may be may be involved in producing secondary metabolites such as phytotoxins. We will determine the role of these genes in metabolism and the disease process, thus providing insights into secondary metabolism and gene regulation in this important plant pathogen.Read moreRead less
Global genetic regulation of carbon metabolism in filamentous fungi. Fungi are of great importance in medicine, agriculture and industry. They are used extensively for food, antibiotic and chemical production and, increasingly, for generating cheap substrates for bioethanol. However many are serious pathogens of plants and humans. Understanding how fungi control their metabolism is of fundamental importance for their more effective use or control. This project takes advantage of a fungus that is ....Global genetic regulation of carbon metabolism in filamentous fungi. Fungi are of great importance in medicine, agriculture and industry. They are used extensively for food, antibiotic and chemical production and, increasingly, for generating cheap substrates for bioethanol. However many are serious pathogens of plants and humans. Understanding how fungi control their metabolism is of fundamental importance for their more effective use or control. This project takes advantage of a fungus that is easily studied in the laboratory by advanced genetic techniques to identify the ways in which genes are turned on and off in response to changes in the nutrients available. By comparing DNA sequences the results are readily applied to fungi of economic importance.Read moreRead less
Special Research Initiatives - Grant ID: SR0354908
Funder
Australian Research Council
Funding Amount
$10,000.00
Summary
The Insect-Plant Chemical Ecology Network (IPCEN). We bring together plant molecular biology, entomology and analytical chemistry to transform three leading fields of Australian research into an advanced science with far reaching capabilities in innovative research and applied outcomes. Expertise studying the biochemical pathways that produce specific plant compounds and expertise in insect recognition and response to these chemicals will be brought together. This will lead to new research outco ....The Insect-Plant Chemical Ecology Network (IPCEN). We bring together plant molecular biology, entomology and analytical chemistry to transform three leading fields of Australian research into an advanced science with far reaching capabilities in innovative research and applied outcomes. Expertise studying the biochemical pathways that produce specific plant compounds and expertise in insect recognition and response to these chemicals will be brought together. This will lead to new research outcomes and solutions to problems in agriculture, horticulture, forestry and protection of Australia's native flora. Researchers are struggling to create these links, constrained by disciplinary boundaries and geographical isolation. Key industries and researchers already support this proposal.Read moreRead less
Australian plague locust population genetics and migratory behaviour. The project will allow improved monitoring and forecasting of locusts in Australia and thereby help prevent locust outbreaks. Benefits will arise directly through greater effectiveness in reducing locust damage to crops, and indirectly to Australian rural industry generally through the economic benefits of reduced losses and locust control costs. Environmental and social benefits will also arise from reduced, better targeted u ....Australian plague locust population genetics and migratory behaviour. The project will allow improved monitoring and forecasting of locusts in Australia and thereby help prevent locust outbreaks. Benefits will arise directly through greater effectiveness in reducing locust damage to crops, and indirectly to Australian rural industry generally through the economic benefits of reduced losses and locust control costs. Environmental and social benefits will also arise from reduced, better targeted use of chemical insecticides. This in turn can produce secondary economic benefits, e.g. through enhanced growth and profitability of the organic beef industry within the main locust-outbreak area. Read moreRead less
Using comparative genomics to identify genes responsible for adaptation to environmental toxins. The US National Human Genome Research Institute has committed to sequencing the genomes of ten different Drosophila (fly) species. We will search these genomes, and two others that are already available, for genes that allow flies to cope with environmental toxins found in the plants upon which they feed and breed. These same genes have the potential to degrade many of the insecticides used to con ....Using comparative genomics to identify genes responsible for adaptation to environmental toxins. The US National Human Genome Research Institute has committed to sequencing the genomes of ten different Drosophila (fly) species. We will search these genomes, and two others that are already available, for genes that allow flies to cope with environmental toxins found in the plants upon which they feed and breed. These same genes have the potential to degrade many of the insecticides used to control insect pests. Hence, this research will contribute to ongoing efforts to minimize the threat to agriculture posed by the insecticide resistance that frequently evolves in pest species. Read moreRead less
Improved insect pest control through understanding mechanisms of insecticide action. Receptors in the nervous system relay signals required for nerve function. Insecticides targeting these receptors provide insect pest control. Better insecticides could be designed if the proteins involved in receptor assembly function were known. In identifying these proteins this project will improve options for safe and effective pest control.