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Molecular Mechanisms of Biochemical Regulation: Neutron and X-ray Scattering Studies. This project will develop and use novel neutron and x-ray scattering methods to study the molecular mechanisms by which nature regulates biochemical processes. Healthy function requires cells to tightly control and coordinate a myriad of molecular activities. My research focuses on a set of interdependent molecular networks inside cells whose behavior is controlled by the so-called 'second messengers' that tr ....Molecular Mechanisms of Biochemical Regulation: Neutron and X-ray Scattering Studies. This project will develop and use novel neutron and x-ray scattering methods to study the molecular mechanisms by which nature regulates biochemical processes. Healthy function requires cells to tightly control and coordinate a myriad of molecular activities. My research focuses on a set of interdependent molecular networks inside cells whose behavior is controlled by the so-called 'second messengers' that translate external signals into the right cellular responses. The proposed experiments will provide a unique structural framework by which we can understand how these signals are transmitted. Such knowledge is an important foundation for advances in biomedical research and biotechnology applications.Read moreRead less
Molecular mechanisms of two-component signal transduction in bacteria. The focus of this research is on the protein complexes that transmit signals in bacteria to elicit the desired responses to environmental stimuli. Like many dynamic processes in cells, signaling requires proteins that are flexible and hence resistant to high-resolution structural analysis using crystallography. We will make use of new research infrastructure at the Australian synchrotron and OPAL research reactor to overcom ....Molecular mechanisms of two-component signal transduction in bacteria. The focus of this research is on the protein complexes that transmit signals in bacteria to elicit the desired responses to environmental stimuli. Like many dynamic processes in cells, signaling requires proteins that are flexible and hence resistant to high-resolution structural analysis using crystallography. We will make use of new research infrastructure at the Australian synchrotron and OPAL research reactor to overcome the challenges of flexibility in these systems. The proteins we will study are not found in humans, and hence our research will provide important structural data on potential targets for the design of novel antibiotics to fight bacterial infection.Read moreRead less
New approaches to functional and structural genomics. Genome sequencing has revealed complete sets of macromolecules that make up our cells. We now need to learn how these macromolecules work together in a coordinated fashion. The proposed research will lead to the discovery of new biological molecules, interactions and processes essential for the function of cells, identify new therapeutic targets and strategies to combat disease, identify new concepts in bio- and nanotechnology, and train new ....New approaches to functional and structural genomics. Genome sequencing has revealed complete sets of macromolecules that make up our cells. We now need to learn how these macromolecules work together in a coordinated fashion. The proposed research will lead to the discovery of new biological molecules, interactions and processes essential for the function of cells, identify new therapeutic targets and strategies to combat disease, identify new concepts in bio- and nanotechnology, and train new interdisciplinary researchers. It will underpin the National Research Priorities (Frontier Technologies for Building and Transforming Australian Industries, and Promoting and Maintaining Good Health) and help Australia capitalise on a plethora of opportunities for future economic and health benefits.Read moreRead less
Contributions to the foundations upon which true crystal engineering of functional solids will be based. The emerging area of crystal engineering promises to provide access to sophisticated materials tailored for specific applications. A major thrust of the proposed work is concerned with controlling the interactions and thus the arrangement of small molecular building blocks used to construct such materials. Through a variety of novel approaches that are proposed, we expect that our research wo ....Contributions to the foundations upon which true crystal engineering of functional solids will be based. The emerging area of crystal engineering promises to provide access to sophisticated materials tailored for specific applications. A major thrust of the proposed work is concerned with controlling the interactions and thus the arrangement of small molecular building blocks used to construct such materials. Through a variety of novel approaches that are proposed, we expect that our research work will provide a valuable scientific contribution to the development of crystal engineering, whilst affording an excellent training ground for the sorts of scientists upon whom Australia's future prosperity will depend.Read moreRead less
Coordination Polymers and Oligomers and Labyrinthine Molecular Solids as Materials for the Sorption of Gases/Vapours, with Emphasis on Hydrogen. The work will afford new types of gas sorbing solids, which may find practical uses in the separation and storage of gases and in catalysis. Hydrogen is almost the perfect, pollution-free fuel; Australia's abundant sunlight potentially makes it cheap and readily available here. The lack of a safe and economic means of storing hydrogen at easily achiev ....Coordination Polymers and Oligomers and Labyrinthine Molecular Solids as Materials for the Sorption of Gases/Vapours, with Emphasis on Hydrogen. The work will afford new types of gas sorbing solids, which may find practical uses in the separation and storage of gases and in catalysis. Hydrogen is almost the perfect, pollution-free fuel; Australia's abundant sunlight potentially makes it cheap and readily available here. The lack of a safe and economic means of storing hydrogen at easily achieved and maintained pressures remains the chief obstacle to the viability of numerous hydrogen-powered devices of the future such as cell phones, laptop computers, cordless tools and vehicles. The work proposed will contribute to the development of safe, efficient, and portable hydrogen storage systems.Read moreRead less
Control of the Enantiomeric Self-Resolution Process. The availability of enantiopure molecules is crucial in chemistry and medicine. Enantiomeric self-resolution on crystallisation provides pure left- and right-handed molecules from 1:1 mixtures of the two. It is the simplest and cheapest means of obtaining enantiopure molecules, but its occurrence in any given case cannot normally be
predicted. The understanding and control of the self-resolution process gained through this project will repre ....Control of the Enantiomeric Self-Resolution Process. The availability of enantiopure molecules is crucial in chemistry and medicine. Enantiomeric self-resolution on crystallisation provides pure left- and right-handed molecules from 1:1 mixtures of the two. It is the simplest and cheapest means of obtaining enantiopure molecules, but its occurrence in any given case cannot normally be
predicted. The understanding and control of the self-resolution process gained through this project will represent a major breakthrough in organic and pharmaceutical chemistry. This technological advance will make pure handed molecules available readily and cheaply, thereby allowing chemical, pharmaceutical and biological developments to be made by Australian industry.
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Light-activated Bioconjugates for Applications in Synthesis and Biosensing. This project will allow the Australian biotechnology industry to develop better diagnostic biosensors that are controlled using light, making them cheaper and faster than the current generation of electronically controlled biosensors. Improvements in the response time of biosensors can be a matter of life and death, for instance, during a surgical operation. The project will benefit the pharmaceutical industry as it will ....Light-activated Bioconjugates for Applications in Synthesis and Biosensing. This project will allow the Australian biotechnology industry to develop better diagnostic biosensors that are controlled using light, making them cheaper and faster than the current generation of electronically controlled biosensors. Improvements in the response time of biosensors can be a matter of life and death, for instance, during a surgical operation. The project will benefit the pharmaceutical industry as it will allow the making of so-called chiral drugs cheaper and safer but problems with the purity of chiral drugs have in the past caused serious side-effects such as in the tragic case of thalidomide.Read moreRead less
Crowns, cages and cavities: Insights into host-guest chemistry from experimental charge density analysis of supramolecular crystals. Supramolecular systems - molecular aggregates - underpin the design and development of materials for a vast number of potential applications, in areas as diverse as catalysis, targeted drug delivery, gas storage, chemical separation, electro-optics and nonlinear optics. They also serve as models for complex phenomena such as self-assembly and ligand-receptor bindin ....Crowns, cages and cavities: Insights into host-guest chemistry from experimental charge density analysis of supramolecular crystals. Supramolecular systems - molecular aggregates - underpin the design and development of materials for a vast number of potential applications, in areas as diverse as catalysis, targeted drug delivery, gas storage, chemical separation, electro-optics and nonlinear optics. They also serve as models for complex phenomena such as self-assembly and ligand-receptor binding. Outcomes will impact on several of the nation's articulated research priorities and, through involvement of postdoctoral fellows and postgraduate students in an international collaboration of this nature, the project contributes directly to producing graduates and researchers familiar with state-of-the-art experimental facilities, both within Australia and overseas.Read moreRead less
Self-Assembly of Nanoscale Molecular Capsules. Nature uses the self-assembly of molecules for the construction of highly complex and functional structures. An understanding of this process will enable the design of new molecular systems, capable of application in areas that include medicine, electronics and communications. Such self-assembly will play a key role in the development of nanotechnology, a rapidly expanding field that is likely to become a major technology in the foreseeable future. ....Self-Assembly of Nanoscale Molecular Capsules. Nature uses the self-assembly of molecules for the construction of highly complex and functional structures. An understanding of this process will enable the design of new molecular systems, capable of application in areas that include medicine, electronics and communications. Such self-assembly will play a key role in the development of nanotechnology, a rapidly expanding field that is likely to become a major technology in the foreseeable future. It is of crucial importance for Australia to maintain cutting-edge research (and research training) in this area if the nation and its industries are to be active contributors to the coming revolution.Read moreRead less
New Membrane Methods to Extract Lactose From Waste Dairy Streams. Dairy processors throughout the world produce about 145,000,000 t of liquid whey per year. Lactose, the principle component in cheese whey, contributes a significant pollution problem for dairy processors. The aim of this Linkage Award application is to develop membranes that selectively extract the lactose. This requires the preparation of membrane carriers that transport the lactose through the membrane. The development of new a ....New Membrane Methods to Extract Lactose From Waste Dairy Streams. Dairy processors throughout the world produce about 145,000,000 t of liquid whey per year. Lactose, the principle component in cheese whey, contributes a significant pollution problem for dairy processors. The aim of this Linkage Award application is to develop membranes that selectively extract the lactose. This requires the preparation of membrane carriers that transport the lactose through the membrane. The development of new approaches and technologies for the isolation and purification of lactose from feed streams may lead to improved processes for manufacture of purified lactose or new lactose products.Read moreRead less