Porphyrin-Based Supramolecular Assemblies and Arrays - Model Systems for the Construction of Photosynthetic Mimics. Crown ether-based multichromophoric systems will be used to mimic the steps through which plants convert light into chemical energy. The crown bridging units allow a variety of metal and organic cations, which provide electronic and structural roles, to be non-covalently bound within their cavities. These systems are advantageous over other photosynthetic models in that a variety ....Porphyrin-Based Supramolecular Assemblies and Arrays - Model Systems for the Construction of Photosynthetic Mimics. Crown ether-based multichromophoric systems will be used to mimic the steps through which plants convert light into chemical energy. The crown bridging units allow a variety of metal and organic cations, which provide electronic and structural roles, to be non-covalently bound within their cavities. These systems are advantageous over other photosynthetic models in that a variety of electron transfer mediators can be examined in a readily controlled and systematic way simply through the choice of cation. In this way, the role played by molecular recognition in the modulation of long-range electron transfer can be evaluated. This work will lead to designing better artificial solar energy converters and molecular electronic devices.Read moreRead less
Exploring new roles for phosphorus radicals in health, environment, and technology. Several practical outcomes will arise from this project. Information on processes that contribute to genetic disease and cancer will be derived through studies of the role of phosphorus radicals in DNA damage. Processes that lead to the degradation of natural and synthetic materials in the environment will be explored. Clean reactions will be developed for the fabrication of advanced materials (e.g. pharmaceutica ....Exploring new roles for phosphorus radicals in health, environment, and technology. Several practical outcomes will arise from this project. Information on processes that contribute to genetic disease and cancer will be derived through studies of the role of phosphorus radicals in DNA damage. Processes that lead to the degradation of natural and synthetic materials in the environment will be explored. Clean reactions will be developed for the fabrication of advanced materials (e.g. pharmaceuticals). These innovations will expand Australia's international profile in a growing research area. The project will also address three of Australia's National Research Priorities, contribute to the training of researchers in Free Radical Chemistry, and initiate research collaborations with institutions in France and the USA.Read moreRead less
Exploring Aspects of Supramolecular Chemistry as a Paradigm for Advanced Functional Materials. This research proposal aims to provide an intellectual grounding in the use of molecular recognition for the assembly of complex arrays for new materials research. The development of molecular systems and supramolecular arrays that are capable of solar energy conversion (e.g. photovoltaics and artificial photosynthesis) or that have potential applications in catalysis will provide advances in the deve ....Exploring Aspects of Supramolecular Chemistry as a Paradigm for Advanced Functional Materials. This research proposal aims to provide an intellectual grounding in the use of molecular recognition for the assembly of complex arrays for new materials research. The development of molecular systems and supramolecular arrays that are capable of solar energy conversion (e.g. photovoltaics and artificial photosynthesis) or that have potential applications in catalysis will provide advances in the development of these industries within Australia. Such developments may also lead to breakthroughs in areas such as optoelectronics and cleaner energy production. Read moreRead less
Tail-anchored membrane proteins: prediction, targeting, assembly and function. Using computer-based searches of genome sequence data, we now have a complete list of tail-anchored membrane proteins in the yeast Saccharomyces cerevisiae. These include a number of essential proteins, such as SNAREs and TOM proteins responsible for building cellular membranes in all organisms, including man. Of the additional protein sequences discovered in the search, 8 represent proteins of known function while 19 ....Tail-anchored membrane proteins: prediction, targeting, assembly and function. Using computer-based searches of genome sequence data, we now have a complete list of tail-anchored membrane proteins in the yeast Saccharomyces cerevisiae. These include a number of essential proteins, such as SNAREs and TOM proteins responsible for building cellular membranes in all organisms, including man. Of the additional protein sequences discovered in the search, 8 represent proteins of known function while 19 are novel. We propose to study the subcellular location of these 19 novel proteins, and solve how they are targeted to and inserted in membranes. We will also investigate the function of the newly-discovered proteins.Read moreRead less
Structure and function of the protein translocation channels in the mitochondrial outer membrane. Biological membranes are the basis of life and understanding how proteins are inserted into membranes is a major goal in the Biological Sciences. The TOM complex is a molecular machine mediating protein insertion into a biological membrane. Recent successes with X-ray diffraction of protein crystals, and solution and solid-state NMR spectroscopy have heralded leaps-and-bound advances for our knowled ....Structure and function of the protein translocation channels in the mitochondrial outer membrane. Biological membranes are the basis of life and understanding how proteins are inserted into membranes is a major goal in the Biological Sciences. The TOM complex is a molecular machine mediating protein insertion into a biological membrane. Recent successes with X-ray diffraction of protein crystals, and solution and solid-state NMR spectroscopy have heralded leaps-and-bound advances for our knowledge of how membranes work at the molecular level. Using a combination of phylogenetic analysis, yeast genetics and these new techniques from structural biology, we will characterize the structure and function of the core from the TOM complex.Read moreRead less