Development of Australian model systems for speciation research. Our project will contribute to an understanding of the process of speciation, a fundamental biological problem, for which there are few well-developed model systems in the world. We will further our understanding of how Australia's extraordinary diversity of animal species have evolved, knowledge which is valuable for understanding the future impact of climatic and environmental changes on species. Our research will generate furthe ....Development of Australian model systems for speciation research. Our project will contribute to an understanding of the process of speciation, a fundamental biological problem, for which there are few well-developed model systems in the world. We will further our understanding of how Australia's extraordinary diversity of animal species have evolved, knowledge which is valuable for understanding the future impact of climatic and environmental changes on species. Our research will generate further knowledge of the diversity and biological significance of subterranean fauna in the arid zone of Australia, providing important background data for assessing the impacts of mining activities on groundwater-dependent-ecosystems and improved strategies for their sustainable management. Read moreRead less
Male germ line transgenesis and siRNA technology for manipulating genes in domestic species. Professor Shemesh has successfully developed male germ line transgenesis in species such as bovine and chicken. This technology allows genes to be manipulated via sperm in a wide range of animals besides mice, avoiding the need for a female in vitro fertilization regimen. He is curently applying interference RNA (siRNA) transgenically to manipulate genes in vivo. Together these two technologies offer imm ....Male germ line transgenesis and siRNA technology for manipulating genes in domestic species. Professor Shemesh has successfully developed male germ line transgenesis in species such as bovine and chicken. This technology allows genes to be manipulated via sperm in a wide range of animals besides mice, avoiding the need for a female in vitro fertilization regimen. He is curently applying interference RNA (siRNA) transgenically to manipulate genes in vivo. Together these two technologies offer immense possibilities to manipulate a wide range of species for economic, biotechnological or medical research purposes. Professor Shemesh wishes to come to Adelaide to establish these technologies there as parts of ongoing research projects, related to the physiology of the ovarian hormone relaxin in aging research.Read moreRead less
Combining the soft with the hard: The assembly of artificial cell membranes on porous semiconductors. The platform technologies developed in this project will have a wide range of applications. They will reveal new insights into drug-membrane and drug-protein interactions underpinning development of a new generation of drugs acting on transmembrane proteins that are linked to a wide range of diseases. The development of membrane-based biosensing devices targeting ion channels, membrane active pe ....Combining the soft with the hard: The assembly of artificial cell membranes on porous semiconductors. The platform technologies developed in this project will have a wide range of applications. They will reveal new insights into drug-membrane and drug-protein interactions underpinning development of a new generation of drugs acting on transmembrane proteins that are linked to a wide range of diseases. The development of membrane-based biosensing devices targeting ion channels, membrane active peptides or toxins which can be applied to biomedical diagnostics, biotoxin detection, environmental and food control will be readily achievable. This international interdisciplinary nanobiotechnology programme and its outcomes will enhance Australia's abilities in frontier technologies and build research strength in nanobiotechnology.Read moreRead less
Conformationally constrained and immobilized beta-peptides. The research builds on world-class expertise in Australia (particularly Adelaide) in proteomics to provide a basis for fundamental advances in chemistry that will underpin the development of new pharmaceuticals and smart materials, and future technologies and industries. We create a mix of research at the interface of disciplines within academia and industry, with linkages to the very best international researchers and centres. A new cr ....Conformationally constrained and immobilized beta-peptides. The research builds on world-class expertise in Australia (particularly Adelaide) in proteomics to provide a basis for fundamental advances in chemistry that will underpin the development of new pharmaceuticals and smart materials, and future technologies and industries. We create a mix of research at the interface of disciplines within academia and industry, with linkages to the very best international researchers and centres. A new critical mass of expertise in a number of advancing areas of chemistry, biology, and materials science will be introduced to Australia. This will enhance existing strengths and opportunities in proteomics and biomedical research for the treatment of disease.Read moreRead less
Cumulenes and Heterocumulenes - Stellar Molecules and New Materials. This project involves the formation and characterisation of transient neutrals (formed in the mass spectrometer by neutralisation of charged precursor ions) which are either found in stellar dust clouds, or related molecules which may be either potential stellar molecules or have importance in the development of new materials. This work may lead to a better understanding of how biomolecules are formed in interstellar environs. ....Cumulenes and Heterocumulenes - Stellar Molecules and New Materials. This project involves the formation and characterisation of transient neutrals (formed in the mass spectrometer by neutralisation of charged precursor ions) which are either found in stellar dust clouds, or related molecules which may be either potential stellar molecules or have importance in the development of new materials. This work may lead to a better understanding of how biomolecules are formed in interstellar environs. The Adelaide and Berlin groups are internationally known, already with ongoing collaboration. This application seeks to extend the scope of this world-class research, and to train the premier graduate students in astrochemistry.Read moreRead less
New clean and green aqueous metathesis. The technique of olefin metathesis has already yielded new pharmaceuticals and materials for use in consumer products and ballistic protection. This project will help move metathesis into the realms of natures aqueous environment, a key advance if metathesis is to reveal its full potential in biological, polymeric, and pharmaceutical applications. We specifically aim to target treatments for cataract (and other conditions associated with an aging populatio ....New clean and green aqueous metathesis. The technique of olefin metathesis has already yielded new pharmaceuticals and materials for use in consumer products and ballistic protection. This project will help move metathesis into the realms of natures aqueous environment, a key advance if metathesis is to reveal its full potential in biological, polymeric, and pharmaceutical applications. We specifically aim to target treatments for cataract (and other conditions associated with an aging population) and also important new biopolymers for use in health technologies of the future.Read moreRead less
Evolution of host relationships among the parasitic wasps inferred from morphology, DNA sequences and mitochondrial genome organisation. The parasitic Hymenoptera (wasps) are extensively used as biological control agents of agricultural and horticultural pests worldwide, but detailed information on their evolutionary relationships, how they have coevolved with major host groups, and the patterns of host relationships across various wasp families are lacking. This project will employ DNA sequence ....Evolution of host relationships among the parasitic wasps inferred from morphology, DNA sequences and mitochondrial genome organisation. The parasitic Hymenoptera (wasps) are extensively used as biological control agents of agricultural and horticultural pests worldwide, but detailed information on their evolutionary relationships, how they have coevolved with major host groups, and the patterns of host relationships across various wasp families are lacking. This project will employ DNA sequence data from 'new' genes, information on mitochondrial genome organisation, as well as morphology, to generate robust phylogenies for braconid and scelionid wasps that can be used to determine patterns of host utilisation and predict hosts for wasp groups where this information is currently unknown.Read moreRead less