Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0346903
Funder
Australian Research Council
Funding Amount
$250,000.00
Summary
LC-MS system for Faculty of Sciences, U.N.E. LC-MS is a technique for investigating the composition of complex mixtures and identifying its components. This instrumentation will be utilised at UNE in a diverse range of analytical investigations to further the research aims of scientists in chemistry, biological sciences, archaeology, physics, environmental sciences, marine science as well as biological researchers in specialised units based at UNE. The extraordinarily versatile capacity of this ....LC-MS system for Faculty of Sciences, U.N.E. LC-MS is a technique for investigating the composition of complex mixtures and identifying its components. This instrumentation will be utilised at UNE in a diverse range of analytical investigations to further the research aims of scientists in chemistry, biological sciences, archaeology, physics, environmental sciences, marine science as well as biological researchers in specialised units based at UNE. The extraordinarily versatile capacity of this technique for analysis and identification of organic substances, from small molecules through to large proteins and complex plant and animal metabolites, will provide impetus for existing research and stimulus for new research directions.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0882289
Funder
Australian Research Council
Funding Amount
$520,000.00
Summary
New generation mass spectrometers for characterisation of molecular shape and size. The ion mobility mass spectrometer (IMMS at UOW) will be the first of its kind in Australia, and together with the ion trap mass spectrometer (ITMS at ANU) will continue the tradition of this partnership in providing researchers with cutting-edge instrumentation for nationally and internationally important projects including: (i) fundamental understanding of the ways in which biomolecules recognize one another, ( ....New generation mass spectrometers for characterisation of molecular shape and size. The ion mobility mass spectrometer (IMMS at UOW) will be the first of its kind in Australia, and together with the ion trap mass spectrometer (ITMS at ANU) will continue the tradition of this partnership in providing researchers with cutting-edge instrumentation for nationally and internationally important projects including: (i) fundamental understanding of the ways in which biomolecules recognize one another, (ii) investigating the structure(s) of lipids (fats) in cardiovascular disease and cataract, (iii) developing anticancer drugs, and (iv) development of new materials.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0882382
Funder
Australian Research Council
Funding Amount
$245,000.00
Summary
Biophysical Characterisation Facility. The protein analysis facility will have substantial benefits for basic science and biotechnology. It will create capacity for South Australian researchers to study proteins at the biophysical level. The facility will support research projects within the designated national research priority areas of 'Frontier technologies for building and transforming Australian industries' and 'Promoting and maintaining good health
Visualising below the tip of the proteome iceberg. Proteomics attempts to understand human biology by examining the protein components of cells and tissues. Unfortunately, currently available technology only allows approximately 10% of the complexity of these cells and tissues to be concurrently investigated. This project will the physical, chemical and functional properties of protein classes for enrichment, as well as improve technologies for protein visualization, identification and character ....Visualising below the tip of the proteome iceberg. Proteomics attempts to understand human biology by examining the protein components of cells and tissues. Unfortunately, currently available technology only allows approximately 10% of the complexity of these cells and tissues to be concurrently investigated. This project will the physical, chemical and functional properties of protein classes for enrichment, as well as improve technologies for protein visualization, identification and characterization. These approaches will allow the scientific community to further mine beneath the surface of the proteomics 'iceberg'.Read moreRead less
New Methods for Structural Biology in Solution. This project aims to expand the range of applications of nuclear magnetic resonance (NMR) spectroscopy in pharmaceutical research, where NMR spectroscopy is already used routinely for the identification of chemical compounds that bind to protein targets. The techniques developed aim at providing rapid and broadly applicable tools for 3D structure determinations of chemical compounds bound to their protein target, identification of protein-protein i ....New Methods for Structural Biology in Solution. This project aims to expand the range of applications of nuclear magnetic resonance (NMR) spectroscopy in pharmaceutical research, where NMR spectroscopy is already used routinely for the identification of chemical compounds that bind to protein targets. The techniques developed aim at providing rapid and broadly applicable tools for 3D structure determinations of chemical compounds bound to their protein target, identification of protein-protein interaction sites and characterization of protein motions. The limits of NMR spectroscopy will be pushed to analyse systems of significantly increased molecular weights. The project includes applications to drug targets such as the dengue virus NS2B/NS3 protease.Read moreRead less
New Methods for Structural Biology in Solution. New technologies will be developed that are sufficiently rapid and inexpensive to compete with and replace the mutagenesis experiments that biologists usually perform to identify and characterize the functionally important parts of a protein. Nuclear magnetic resonance (NMR) spectroscopy techniques in combination with various selective labelling schemes will be developed with the goal of identification and structural characterization of protein-lig ....New Methods for Structural Biology in Solution. New technologies will be developed that are sufficiently rapid and inexpensive to compete with and replace the mutagenesis experiments that biologists usually perform to identify and characterize the functionally important parts of a protein. Nuclear magnetic resonance (NMR) spectroscopy techniques in combination with various selective labelling schemes will be developed with the goal of identification and structural characterization of protein-ligand interactions at increased rates and enhanced accuracy. In addition, the three-dimensional structures of proteins and protein domains of biologically important functions and unknown fold will be determined by NMR. The project aims at techniques of direct impact in pharmaceutical industry.Read moreRead less
Establishing the role of alpha-2-macroglobulin in quality control of extracellular protein folding. The expected outcomes will provide important advances in understanding the role of alpha-2-macroglobulin (A2M) in maintaining the normal structure/function of extracellular proteins. This information may ultimately aid in the design of agents to be used to clear the body of pathological protein aggregates - potentially providing a direct economic benefit to Australia. The high novelty and broad si ....Establishing the role of alpha-2-macroglobulin in quality control of extracellular protein folding. The expected outcomes will provide important advances in understanding the role of alpha-2-macroglobulin (A2M) in maintaining the normal structure/function of extracellular proteins. This information may ultimately aid in the design of agents to be used to clear the body of pathological protein aggregates - potentially providing a direct economic benefit to Australia. The high novelty and broad significance of this work indicate that it will produce high-impact publications which will tangibly assist Australia being recognized as a major contributor to world research outcomes. This project will also provide a direct social benefit by training research students with the skills necessary to further the development of biological research in Australia.Read moreRead less
Discovering Mechanisms for Quality Control of Extracellular Protein Folding. The expected outcomes will provide important advances in understanding of how the mammalian body maintains the normal structure/function of extracellular proteins. This information may ultimately aid in the design of agents to be used to clear the body of pathological protein aggregates - potentially providing a direct economic benefit to Australia. The high novelty and broad significance of this work indicate that it w ....Discovering Mechanisms for Quality Control of Extracellular Protein Folding. The expected outcomes will provide important advances in understanding of how the mammalian body maintains the normal structure/function of extracellular proteins. This information may ultimately aid in the design of agents to be used to clear the body of pathological protein aggregates - potentially providing a direct economic benefit to Australia. The high novelty and broad significance of this work indicate that it will produce high-impact publications which will tangibly assist Australia being recognized as a major contributor to world research outcomes. This project will also provide a direct social benefit by training research students with the skills necessary to further the development of biological research in Australia. Read moreRead less