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
How organisms coordinate energy supply and demand. The metabolic stress sensing protein kinase called the AMP activated protein kinase controls metabolism of all eukaryotes to meet the needs of energy demand and nutrient supply. It is responsible for accelerating metabolism (glucose transport, glycolysis and fatty acid oxidation) in response to energy demand and with caloric restriction it regulates gene transcription to adapt to energy supply. This project is to provide a comprehensive unders ....How organisms coordinate energy supply and demand. The metabolic stress sensing protein kinase called the AMP activated protein kinase controls metabolism of all eukaryotes to meet the needs of energy demand and nutrient supply. It is responsible for accelerating metabolism (glucose transport, glycolysis and fatty acid oxidation) in response to energy demand and with caloric restriction it regulates gene transcription to adapt to energy supply. This project is to provide a comprehensive understanding of the AMP activated protein kinase (enzyme isoforms, genes, physiological roles and regulation). This knowledge will have major benefits in biopharmaceutical development, the livestock, plant and sport/racing industries.Read moreRead less
Special Research Initiatives - Grant ID: SR0354766
Funder
Australian Research Council
Funding Amount
$10,000.00
Summary
Molecular farming: seizing the opportunity to establish a new technology based, value adding industry in and for Australia. Molecular farming involves the production of novel products in plants and brings together the technology to genetically modify plants to produce these products with efficient production of plant biomass. The range of potential products is very broad and includes therapeutic and industrial proteins, bioplastics, fibres, food additives, glues and dyes. The molecular farming i ....Molecular farming: seizing the opportunity to establish a new technology based, value adding industry in and for Australia. Molecular farming involves the production of novel products in plants and brings together the technology to genetically modify plants to produce these products with efficient production of plant biomass. The range of potential products is very broad and includes therapeutic and industrial proteins, bioplastics, fibres, food additives, glues and dyes. The molecular farming industry is already established in North America with products on the market. Australia has an outstanding opportunity to participate in this new industry as a producer if we can aggregate the critical scientific mass and work together with the current fledgling industry and State and Federal regulators.Read moreRead less
Genetic and molecular analysis of long-distance gene silencing in Arabidopsis. Gene silencing is a surveillance mechanism in plants and animals to ensure that all genes are switched on or off at the right time. It is also a defence mechanism against viruses. Perturbation of gene silencing can be a cause of genetic diseases, and conversely, gene silencing has immense potential as a therapeutic tool for correcting genetic diseases and curing viral diseases. When silencing is triggered against a ge ....Genetic and molecular analysis of long-distance gene silencing in Arabidopsis. Gene silencing is a surveillance mechanism in plants and animals to ensure that all genes are switched on or off at the right time. It is also a defence mechanism against viruses. Perturbation of gene silencing can be a cause of genetic diseases, and conversely, gene silencing has immense potential as a therapeutic tool for correcting genetic diseases and curing viral diseases. When silencing is triggered against a gene or virus in plants, genetic signals are transmitted throughout the organism to systemically switch off the specific gene or virus. Expected long-term national/community benefits from understanding gene silencing are wide-ranging, from improved crops through to drugs and gene therapy.Read moreRead less
Innovative Approaches to Membrane Protein Crystallography & Drug Discovery. Membrane proteins make up around 30% of the predicted products from our human genome, are critical for life, and represent the targets of biological agents like hormones and toxins as well as most drugs. Yet these proteins have persistently defied our best efforts to study them: we know very little about what they do or what they look like. This project is aimed at cracking the problem of membrane proteins, while at the ....Innovative Approaches to Membrane Protein Crystallography & Drug Discovery. Membrane proteins make up around 30% of the predicted products from our human genome, are critical for life, and represent the targets of biological agents like hormones and toxins as well as most drugs. Yet these proteins have persistently defied our best efforts to study them: we know very little about what they do or what they look like. This project is aimed at cracking the problem of membrane proteins, while at the same time developing screening methods that can be used to design drugs against them. The long-term benefits to the community will include fundamental new knowledge and the development of new technologies and pharmaceuticals.Read moreRead less
Molecular structure and function of the glycine receptor. This proposal will employ a cutting edge approach to reveal fundamental new insights into the ways that ligand-gated ion channels, and proteins in general, work. The new knowledge and technology developed here will broaden and strengthen Australia's research expertise across a number of basic scientific disciplines. The results will also have relevance to human health. Glycine receptors have an essential role in brain function and are ....Molecular structure and function of the glycine receptor. This proposal will employ a cutting edge approach to reveal fundamental new insights into the ways that ligand-gated ion channels, and proteins in general, work. The new knowledge and technology developed here will broaden and strengthen Australia's research expertise across a number of basic scientific disciplines. The results will also have relevance to human health. Glycine receptors have an essential role in brain function and are targets for anaesthetics and drugs of abuse. GlyRs are also important in modulating pain sensation by the brain. New insights into how natural agonists and drugs affect ion channel structure and function may lead to novel therapeutic opportunities and improved drug structure predictions.Read moreRead less
Ion transport in the malaria parasite and parasitised erythrocyte. This work will contribute to the national research effort in parasitology (an area in which the ARC has established a Research Network), as well as laying the groundwork for subsequent efforts (not part of this grant) to develop new antimalarial strategies. Although not yet endemic in Australia, malaria is a serious problem in the local region and, as the major developed nation in the region Australia has an obligation to make ....Ion transport in the malaria parasite and parasitised erythrocyte. This work will contribute to the national research effort in parasitology (an area in which the ARC has established a Research Network), as well as laying the groundwork for subsequent efforts (not part of this grant) to develop new antimalarial strategies. Although not yet endemic in Australia, malaria is a serious problem in the local region and, as the major developed nation in the region Australia has an obligation to make a significant contribution to research in this area. The work proposed here will contribute to Australia's meeting this obligation.Read moreRead less
Second messenger-activated calcium channels in liver cells. This project concerns second messenger-activated calcium channels, part of the family of hormone-activated calcium channels which are essential to the functions of all animal cells. The aims are to elucidate the properties of a novel "large conductance" Ca2+ channel (using maitotoxin as an artificial activator), an inositol 1,4,5-trisphosphate-activated calcium channel, and the calcium channel formed by the transient receptor potential ....Second messenger-activated calcium channels in liver cells. This project concerns second messenger-activated calcium channels, part of the family of hormone-activated calcium channels which are essential to the functions of all animal cells. The aims are to elucidate the properties of a novel "large conductance" Ca2+ channel (using maitotoxin as an artificial activator), an inositol 1,4,5-trisphosphate-activated calcium channel, and the calcium channel formed by the transient receptor potential-1 (TRP-1) protein in hepatocytes. The electrophysiological properties, mechanisms of activation and intracellular trafficking of the channels will be investigated. It is anticipated the results will provide basic information on the physiological functions of second messenger-activated calcium channels. This will benefit the understanding of liver function, hepatotoxicity in animals, animal production and the development of pharmaceuticals in animal husbandary.Read moreRead less
Amino acid transporters and the chloroquine resistance transporter of the intracellular malaria parasite. This work entails an ongoing collaboration between three independent research groups with highly complementary expertise and experience. It will make a significant contribution to the maintenance of Australia's scientific capabilities and training opportunities. The project will yield important insights into the biology of the causative agent of a major human disease, and the mechanism by ....Amino acid transporters and the chloroquine resistance transporter of the intracellular malaria parasite. This work entails an ongoing collaboration between three independent research groups with highly complementary expertise and experience. It will make a significant contribution to the maintenance of Australia's scientific capabilities and training opportunities. The project will yield important insights into the biology of the causative agent of a major human disease, and the mechanism by which the malaria parasite has developed resistance to antimalarial drugs. Although not yet endemic in Australia, malaria is a serious problem in the local region and this work will help Australia meet its obligations to carry out high-quality research that advances our knowledge in this area.
Read moreRead less