Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0882295
Funder
Australian Research Council
Funding Amount
$225,000.00
Summary
X-ray crystallography resource for membrane proteins and large macromolecular complexes. Structural biology is the underpinning of biotechnology, biopharmaceuticals and rational therapeutic design. The most successful technique for determining the structures of proteins and large macromolecular complexes is x-ray crystallography. This proposal will set up a network of state of the art resources in the Sydney region to capitalise on expertise in these areas. The facilities will foster basic re ....X-ray crystallography resource for membrane proteins and large macromolecular complexes. Structural biology is the underpinning of biotechnology, biopharmaceuticals and rational therapeutic design. The most successful technique for determining the structures of proteins and large macromolecular complexes is x-ray crystallography. This proposal will set up a network of state of the art resources in the Sydney region to capitalise on expertise in these areas. The facilities will foster basic research and collaborations with industry, which will enhance Australia's profile and commercialisation of research. The facility will enhance the usage of the Australian synchrotron, producing flagship projects on the edge of technical possibilities.Read moreRead less
Function and regulation of the Na+,K+-ATPase. The Na+,K+-ATPase is the major energy-consuming enzyme of animal cells. Its ion pumping is essential for numerous physiological functions (e.g. heart, kidney, brain). Molecular detail of its pumping mechanism is, however, lacking and its regulation is still unclear. We will use rapid reaction methods on purified enzyme in vitro to locate the rate-determining step of the enzyme cycle, determine its mechanism, investigate its regulation by sodium conce ....Function and regulation of the Na+,K+-ATPase. The Na+,K+-ATPase is the major energy-consuming enzyme of animal cells. Its ion pumping is essential for numerous physiological functions (e.g. heart, kidney, brain). Molecular detail of its pumping mechanism is, however, lacking and its regulation is still unclear. We will use rapid reaction methods on purified enzyme in vitro to locate the rate-determining step of the enzyme cycle, determine its mechanism, investigate its regulation by sodium concentration, phosphorylation and membrane composition, and isolate its charge-transporting steps. The results will have immediate impact on the understanding of the enzyme's mechanism, its metabolic control and its role in disease.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100149
Funder
Australian Research Council
Funding Amount
$590,000.00
Summary
Reaching new heights in high-resolution electron microscopy . High-resolution electron microscopy (EM): Direct electron detection cameras are a recent technological breakthrough delivering one of the greatest single advancements to the field of molecular cryo-EM. The aim of this project is to enable a 'first of a kind' cryo-EM platform in Australia enabling high-throughput atomic resolution protein structure determination. This will be achieved by integrating a state-of-the-art Gatan K2 Summit D ....Reaching new heights in high-resolution electron microscopy . High-resolution electron microscopy (EM): Direct electron detection cameras are a recent technological breakthrough delivering one of the greatest single advancements to the field of molecular cryo-EM. The aim of this project is to enable a 'first of a kind' cryo-EM platform in Australia enabling high-throughput atomic resolution protein structure determination. This will be achieved by integrating a state-of-the-art Gatan K2 Summit Direct Electron Detection camera system into the established cryo-EM facility managed by the University of Queensland node of the Australian Microscopy and Microanalysis Facility. This will offer unique and significantly improved capabilities for atomic resolution protein structure analysis, and will support a broad range of projects across the biological sciences.Read moreRead less
How cholesterol optimises ion pump function in animal membranes. This project aims to determine how cholesterol optimises ion pump function in animal membranes and to identify the major effects of cholesterol and its derivatives on membranes’ physical properties. All animal cells need high levels of cholesterol in the plasma membrane for survival. Insufficient cholesterol biosynthesis leads to severe birth defects. The need for cholesterol is likely linked to its acceleration of sodium pump acti ....How cholesterol optimises ion pump function in animal membranes. This project aims to determine how cholesterol optimises ion pump function in animal membranes and to identify the major effects of cholesterol and its derivatives on membranes’ physical properties. All animal cells need high levels of cholesterol in the plasma membrane for survival. Insufficient cholesterol biosynthesis leads to severe birth defects. The need for cholesterol is likely linked to its acceleration of sodium pump activity, essential to physiological processes including cell division, nerve, muscle and kidney activity. An expected benefit of the project is knowledge on the molecular origin of diseases associated with inhibition of cholesterol production, and a more complete understanding of the crucial role played by cholesterol via its effect on ion pumping towards the healthy functioning of vital organs, particularly in heart muscle and nerves.Read moreRead less
Lipid-protein interplay in the mechanism of the sodium pump. The sodium pump is the major energy-consuming enzyme of animal cells. Its ion pumping is essential to numerous physiological processes (e.g. nerve, muscle and kidney activity and the maintenance of cell volume). Because of its importance in so many cell functions, the enzyme must be able to respond to cellular conditions. Using measurements of the enzyme's activity in isolated membrane fragments and comparison with its behaviour in liv ....Lipid-protein interplay in the mechanism of the sodium pump. The sodium pump is the major energy-consuming enzyme of animal cells. Its ion pumping is essential to numerous physiological processes (e.g. nerve, muscle and kidney activity and the maintenance of cell volume). Because of its importance in so many cell functions, the enzyme must be able to respond to cellular conditions. Using measurements of the enzyme's activity in isolated membrane fragments and comparison with its behaviour in living cells, this project aims to determine how sodium pump activity is modulated by transmembrane electric potential and intramembrane electric field strength. Our project could provide fundamental new knowledge on how membrane protein function in general can be controlled by electrical properties of their lipid surroundings.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100224
Funder
Australian Research Council
Funding Amount
$250,000.00
Summary
Multi-mode fluorescence microscope for visualising the dynamics of cellular processes at the single-molecule level. Fluorescence is the emission of light by a substance that has absorbed light of a different wavelength. This fluorescence microscopy facility will allow the visualisation of the dynamic processes that define life at the molecular level. This insight will help us understand cellular function and how it is impaired in various diseases including cancer and neurodegenerative disorders ....Multi-mode fluorescence microscope for visualising the dynamics of cellular processes at the single-molecule level. Fluorescence is the emission of light by a substance that has absorbed light of a different wavelength. This fluorescence microscopy facility will allow the visualisation of the dynamic processes that define life at the molecular level. This insight will help us understand cellular function and how it is impaired in various diseases including cancer and neurodegenerative disorders such as Parkinson’s and Alzheimer’s disease.Read moreRead less