Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0561169
Funder
Australian Research Council
Funding Amount
$188,000.00
Summary
Facility for multidimensional fractionation of complex biological mixtures. Acquisition of multidimensional fractionation equipment will allow researchers to separate proteins from complex mixtures, and to compare whole protein profiles of multiple samples. This will permit correlation of specific protein changes associated with infection or disease, a major focus of post-genomic programs of research. The equipment will also provide identification of the key differentiating proteins using mini ....Facility for multidimensional fractionation of complex biological mixtures. Acquisition of multidimensional fractionation equipment will allow researchers to separate proteins from complex mixtures, and to compare whole protein profiles of multiple samples. This will permit correlation of specific protein changes associated with infection or disease, a major focus of post-genomic programs of research. The equipment will also provide identification of the key differentiating proteins using minimal material. Numerous world-class projects and researchers will be able to move more rapidly and reliably from crude cell extracts to identifiable markers, and maintain their competitive positions the recognition of key targets in drug design, disease diagnosis and vaccine development.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989336
Funder
Australian Research Council
Funding Amount
$560,000.00
Summary
The South Australian Facility for Small and Large Molecule X-Ray Diffraction Structure Determination. The precise three dimensional arrangement of atoms within molecular and macromolecular structures defines their function. Thus, the discovery, development and application of biological compounds, catalysts, nanodevices and pharmaceuticals require X-ray diffraction structure determination. These endeavours underpin the conversion of academic research into real benefits for the community and are ....The South Australian Facility for Small and Large Molecule X-Ray Diffraction Structure Determination. The precise three dimensional arrangement of atoms within molecular and macromolecular structures defines their function. Thus, the discovery, development and application of biological compounds, catalysts, nanodevices and pharmaceuticals require X-ray diffraction structure determination. These endeavours underpin the conversion of academic research into real benefits for the community and are critical for the competitiveness of Australian industry, national productivity and economic growth. This application seeks to provide a facility for multidisciplinary scientific development that will enhance academic-industrial collaboration. This will position SA research community for scientific breakthroughs that benefit the Australian community.Read moreRead less
Carbohydrate language changes in vertebrate-pathogen co-evolution. This project aims to understand protein glycosylation’s role in host-pathogen relationships and cross-species transmission. Species specific sugars extensively modify cell surface and body fluid proteins. These glycans build a universal language that cells use and pathogens abuse. This project will use glycomics and glycoproteomics to uncover how pathogens learned to speak and interpret glyco-languages between different species. ....Carbohydrate language changes in vertebrate-pathogen co-evolution. This project aims to understand protein glycosylation’s role in host-pathogen relationships and cross-species transmission. Species specific sugars extensively modify cell surface and body fluid proteins. These glycans build a universal language that cells use and pathogens abuse. This project will use glycomics and glycoproteomics to uncover how pathogens learned to speak and interpret glyco-languages between different species. This project is expected to develop a glycan dictionary which could reveal host-pathogen co-evolution and glycosylation evolution in the Chordata phylum and counteract zoonoses threats.Read moreRead less
Understanding chaperone function, one molecule at a time. This project aims to determine how molecular chaperones, a class of proteins represented in all phyla of life, work together to keep proteins folded and functional, particularly following cellular stress. This is important as proteins are involved in virtually all biological processes. This project will exploit innovative microscopy techniques to watch these molecular chaperones as they work. Expected outcomes of this project are the firs ....Understanding chaperone function, one molecule at a time. This project aims to determine how molecular chaperones, a class of proteins represented in all phyla of life, work together to keep proteins folded and functional, particularly following cellular stress. This is important as proteins are involved in virtually all biological processes. This project will exploit innovative microscopy techniques to watch these molecular chaperones as they work. Expected outcomes of this project are the first definitive description of how molecular chaperones interact to refold proteins, and the development of novel methods to study dynamic biological processes. This should provide significant benefits including enhanced collaboration and scientific capacity in Australia.Read moreRead less
Functional and structural characterisation of Defective embryo and meristems (Dem) proteins involved in plant development. The proposed research will lead to advances in understanding the regulation of plant development, a process impacting on agriculture, environmental management and human health, areas designated as national research priorities. This understanding is required for modifying plant growth and architecture to fit particular environments, for example generating plants with more ext ....Functional and structural characterisation of Defective embryo and meristems (Dem) proteins involved in plant development. The proposed research will lead to advances in understanding the regulation of plant development, a process impacting on agriculture, environmental management and human health, areas designated as national research priorities. This understanding is required for modifying plant growth and architecture to fit particular environments, for example generating plants with more extensive and deeper roots to mine the soil moisture and nutrients to enhance crop productivity in Australia, and maintaining the competitive advantage of Australian agriculture in view of the range of environmental conditions encountered in this country. The project will also contribute to the health of the Australian population through consumable plants in the diet.Read moreRead less
Biochemistry of tropoelastin and elastin: the molecular architecture of elastic fibre assembly. Elastin destruction drives the progression of emphysema, a major component of chronic obstructive pulmonary disease which is a major cause of death. Loss of elastin leads to profound blockage of arteries. If we are to treat these problems we need to know how to make and repair elastin. This research will enable us to discover how elastin is constructed and define its interacting partners. We will lear ....Biochemistry of tropoelastin and elastin: the molecular architecture of elastic fibre assembly. Elastin destruction drives the progression of emphysema, a major component of chronic obstructive pulmonary disease which is a major cause of death. Loss of elastin leads to profound blockage of arteries. If we are to treat these problems we need to know how to make and repair elastin. This research will enable us to discover how elastin is constructed and define its interacting partners. We will learn how to make tissue components found in parts of the body that expand and contract such as the arteries, lung and skin. We will learn about the molecular mechanisms of elastin assembly and cell interactions, which gives us the core molecular toolkit to repair elastin tissue.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0454209
Funder
Australian Research Council
Funding Amount
$126,326.00
Summary
A Glycobiology Facility for Glycoconjugate Analysis and Oligosaccharide Sequencing. The carbohydrate moiety of glycoconjugates plays an important role in their function and metabolism. Advances in glycan analytical and oligosaccharide sequencing techniques offer tremendous potential for the application of glycobiology to biotechnology, cell biology and medicine. This application aims to establish a Glycobiology Facility dedicated to glycoconjugate analysis and oligosaccharide sequencing. Funds a ....A Glycobiology Facility for Glycoconjugate Analysis and Oligosaccharide Sequencing. The carbohydrate moiety of glycoconjugates plays an important role in their function and metabolism. Advances in glycan analytical and oligosaccharide sequencing techniques offer tremendous potential for the application of glycobiology to biotechnology, cell biology and medicine. This application aims to establish a Glycobiology Facility dedicated to glycoconjugate analysis and oligosaccharide sequencing. Funds are requested for state of the art HPLC equipment, associated equipment and reagents for glycan purification/labelling, and a staff member, that are all essential to establish this technology in Australia. The Facility will support $25 million of existing research; approximately half of which is derived from ARC.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100068
Funder
Australian Research Council
Funding Amount
$280,000.00
Summary
Biomembrane Interactions Facility. Biomembrane interactions facility: Characterisation of membrane interactions is important for further advances in biomedical science and drug design. The biomembrane interactions facility will provide modern infrastructure to study membrane biophysics and membrane protein structure and interactions in mammalian, protozoan and bacterial cells. The facility will include a solid-state nuclear magnetic resonance spectrometer and optical analytical instrumentation a ....Biomembrane Interactions Facility. Biomembrane interactions facility: Characterisation of membrane interactions is important for further advances in biomedical science and drug design. The biomembrane interactions facility will provide modern infrastructure to study membrane biophysics and membrane protein structure and interactions in mammalian, protozoan and bacterial cells. The facility will include a solid-state nuclear magnetic resonance spectrometer and optical analytical instrumentation and biosensor equipment. These will enable determination of molecular structure and dynamics within biomembranes and determination of the rates and mechanisms of cell membrane processes; nanoscale measurement of cell membrane properties; and resolution of the interactions between membrane components in cells.Read moreRead less