Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100010
Funder
Australian Research Council
Funding Amount
$720,000.00
Summary
A 5-D Correlative Imaging Platform: Combining the strengths of light and electron microscopy. This will be Australia's first dedicated five-dimensional multiphoton-microscopy platform, allowing observation of dynamic structures across different length and time scales under controlled temperatures, followed by high-resolution electron microscopy studies on the same samples. This platform will provide a unique characterisation tool to Australia's top-flight investigators, and so contribute to the ....A 5-D Correlative Imaging Platform: Combining the strengths of light and electron microscopy. This will be Australia's first dedicated five-dimensional multiphoton-microscopy platform, allowing observation of dynamic structures across different length and time scales under controlled temperatures, followed by high-resolution electron microscopy studies on the same samples. This platform will provide a unique characterisation tool to Australia's top-flight investigators, and so contribute to the nation's research priorities. It will enable: fundamental studies of cancer, neural diseases and immune disorders; the development of frontier technologies, such as smart nanomaterials, biosensors and targeted drug delivery; and applied research to help plants and soils adapt to climate variability, and to increase sustainable use of water.Read moreRead less
Structure and activity of host-defence peptides from Australian anurans: anticancer agents, neuropeptides and nNOS inhibitors. We have discovered peptides that may have clinical applications. This is significant as these molecules may have one or more of the following properties. They may have anti-cancer effects; they may increase the effectiveness of the immune system by enhancing lymphocyte formation; and, they may act to reduce inflammation, stroke or cardiac conditions by controlling nitri ....Structure and activity of host-defence peptides from Australian anurans: anticancer agents, neuropeptides and nNOS inhibitors. We have discovered peptides that may have clinical applications. This is significant as these molecules may have one or more of the following properties. They may have anti-cancer effects; they may increase the effectiveness of the immune system by enhancing lymphocyte formation; and, they may act to reduce inflammation, stroke or cardiac conditions by controlling nitric oxide formation. Another national benefit is that personnel involved in this project are trained to the highest international standards in peptide chemistry/mass spectrometry/nuclear magnetic resonance: currently, there are not enough trained scientists in this area to meet demand.Read moreRead less
Biologically active peptides and proteins from anurans: the relationship between structure and activity. We have identified peptides (from glands of frogs and toads), some of which are amongst the most powerful biologically active compounds in the animal kingdom. The aims of this project are to investigate the relationship between the structure and bioactivity of chosen groups of peptides including pheromones, anticancer and antibiotic peptides, and peptides which inhibit neuronal nitric oxide ....Biologically active peptides and proteins from anurans: the relationship between structure and activity. We have identified peptides (from glands of frogs and toads), some of which are amongst the most powerful biologically active compounds in the animal kingdom. The aims of this project are to investigate the relationship between the structure and bioactivity of chosen groups of peptides including pheromones, anticancer and antibiotic peptides, and peptides which inhibit neuronal nitric oxide synthase. It would be of national benefit if any of these peptides have applied application, e.g. if we can use the sex pheromone of the cane toad to reduce its population, or if we can produce an anticancer active peptide of clinical applicability.Read moreRead less
Nanogels: Next Generation Polymeric Particles. The existing knowledge in the formation of polymeric networks limits the technological development of polymer materials. This project will introduce new polymeric particles, called nanogels to open a new area in new polymeric architecture research. A number of new structures based on the nanogels will be developed. These new macromolecules will not only bring the polymer science into a new field, it will provide a great opportunity to discover the ....Nanogels: Next Generation Polymeric Particles. The existing knowledge in the formation of polymeric networks limits the technological development of polymer materials. This project will introduce new polymeric particles, called nanogels to open a new area in new polymeric architecture research. A number of new structures based on the nanogels will be developed. These new macromolecules will not only bring the polymer science into a new field, it will provide a great opportunity to discover the next generation of the polymeric products, particularly for application in automotive paint, drug delivery and bio-molecular separations.Read moreRead less
The First Chemically Accurate Tools in Theoretical Materials Research. Non-metallic materials are widely used in catalytic, separation and sensing applications. This project will create a new, accurate, general and systematic approach to the computational study of non-metallic materials and will provide an enormous step forward in our ability to design these materials for specific applications. With ever increasing demand, growing world population and shrinking natural resources, the benefits of ....The First Chemically Accurate Tools in Theoretical Materials Research. Non-metallic materials are widely used in catalytic, separation and sensing applications. This project will create a new, accurate, general and systematic approach to the computational study of non-metallic materials and will provide an enormous step forward in our ability to design these materials for specific applications. With ever increasing demand, growing world population and shrinking natural resources, the benefits of such rational materials design impact on the development of new, safer, more efficient, reusable materials in chemical, engineering, electronic and biological applications. Read moreRead less
TOWARDS A COMPLETE DESCRIPTION OF HOW ENZYMES WORK: development of simulation methods and protocols, blind test predictions, and experimental validation. Enzymes catalyze quite fantastic chemistry under mild physiological conditions. Many special chemical concepts (such as "transition-state stabilization" and "entropy-enthalpy compensation") proposed to explain these powers are unnecessary. Uniquely for a catalyst, these powers are integral to the structure, properties and dynamics of the protei ....TOWARDS A COMPLETE DESCRIPTION OF HOW ENZYMES WORK: development of simulation methods and protocols, blind test predictions, and experimental validation. Enzymes catalyze quite fantastic chemistry under mild physiological conditions. Many special chemical concepts (such as "transition-state stabilization" and "entropy-enthalpy compensation") proposed to explain these powers are unnecessary. Uniquely for a catalyst, these powers are integral to the structure, properties and dynamics of the protein, as constrained and selected by evolution. The question is how do they work? Answering this requires energetic and thermodynamic analysis beyond current experimental techniques, but accessible by computer simulation. We aim to develop a robust toolkit of simulation methods and protocols, blind test them by predicting the mechanism of a new enzyme, with followup experimental validation.
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Importance of conformational and electrostatic contributions in simulations of enzyme reaction mechanisms. The research will contribute to the development of biomolecular simulation in Australia by demonstrating its potential to complement experiment, and also promote the effective use of APAC (Australian national supercomputer facilities) resources by providing advanced programs and computational protocols for other researchers. It will assist the diffusion of computational biology technology i ....Importance of conformational and electrostatic contributions in simulations of enzyme reaction mechanisms. The research will contribute to the development of biomolecular simulation in Australia by demonstrating its potential to complement experiment, and also promote the effective use of APAC (Australian national supercomputer facilities) resources by providing advanced programs and computational protocols for other researchers. It will assist the diffusion of computational biology technology into industrial applications such as rational drug design and protein engineering, as, for example, in our associated Linkage project grant, and provide novel insights into protein engineering and other sorts of design, which transcend concepts currently used in biomimetic chemistry.Read moreRead less
Helium droplets: a nanoscale laboratory for studying intermolecular bonding and chemical reactivity. This type of research requires a rather complicated apparatus capable of creating a stream of helium droplets, embedding molecules and interrogating their properties using laser spectroscopy. The apparatus built in Sydney is the only one capable of this in Australia and using this new apparatus we will create many novel, bizarre and intriguing aggregates of molecules and atoms. The project involv ....Helium droplets: a nanoscale laboratory for studying intermolecular bonding and chemical reactivity. This type of research requires a rather complicated apparatus capable of creating a stream of helium droplets, embedding molecules and interrogating their properties using laser spectroscopy. The apparatus built in Sydney is the only one capable of this in Australia and using this new apparatus we will create many novel, bizarre and intriguing aggregates of molecules and atoms. The project involves cutting-edge scientific methods and will shift the boundaries of can-do science in the laser laboratory at the University of Sydney and in Australia in general.Read moreRead less
Nanomagnetic Molecular Materials. This research project involves the preparation of new molecular magnets using metals such as manganese and vanadium and a study of their physical properties. Metal compounds of the cluster type are significant since they are nanoscale in size and offer new quantum features, with an improved understanding of the magnetic properties as a primary outcome and long term possible use in future quantum computers. This fundamental study provides excellent training to p ....Nanomagnetic Molecular Materials. This research project involves the preparation of new molecular magnets using metals such as manganese and vanadium and a study of their physical properties. Metal compounds of the cluster type are significant since they are nanoscale in size and offer new quantum features, with an improved understanding of the magnetic properties as a primary outcome and long term possible use in future quantum computers. This fundamental study provides excellent training to post-graduate students and makes them ideally suited to take jobs in advanced materials, an area being emphasised in Australia's nanotechnological future.Read moreRead less
Nanomagnetic Materials from Molecular Clusters and Coordination Polymers. Magnetic materials are important through their use in recording tapes and other electronic devices. Traditional magnetic materials are metals, alloys or metal oxides made by high temperature methods. Our aims are to synthesize new chemical and molecule based solid materials which possess the properties of traditional magnets but which are made by careful chemical design at ambient temperatures. We will make materials which ....Nanomagnetic Materials from Molecular Clusters and Coordination Polymers. Magnetic materials are important through their use in recording tapes and other electronic devices. Traditional magnetic materials are metals, alloys or metal oxides made by high temperature methods. Our aims are to synthesize new chemical and molecule based solid materials which possess the properties of traditional magnets but which are made by careful chemical design at ambient temperatures. We will make materials which have three-dimensional network structures or large clusters of ions such as manganese bridged by organic molecules. Their magnetic properties will be studied in detail. The cluster compounds are significant since they are nanoscale in size and offer new features, with long term possible use in future quantum computers.Read moreRead less