Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0344441
Funder
Australian Research Council
Funding Amount
$390,000.00
Summary
New Generation Metalloenzyme Magnetic Circular Dichroism Spectrometer Systems. Funding is sought to enhance the existing collaborations between UQ, ANU, Sydney and other universities in the study of metal-centred molecules of biological interest through the construction of advanced magnetic circular dichroism (MCD) spectrometers. These facilities will be the best instruments of their kind, and will enable researchers at Australian institutions to enhance the quality of their research and remain ....New Generation Metalloenzyme Magnetic Circular Dichroism Spectrometer Systems. Funding is sought to enhance the existing collaborations between UQ, ANU, Sydney and other universities in the study of metal-centred molecules of biological interest through the construction of advanced magnetic circular dichroism (MCD) spectrometers. These facilities will be the best instruments of their kind, and will enable researchers at Australian institutions to enhance the quality of their research and remain internationally competitive through the application of modern MCD spectroscopic techniques to the study of metal-centred biomolecules. These facilities will drive a number of programs in the area of metalloenzyme and photosystem II research.Read moreRead less
Monolayer crystallization of membrane proteins. Membrane proteins comprise 25-40% of all proteins and conduct a myriad of finely tuned reactions in every cell. Despite their importance and diversity only ~40 membrane protein structures have been solved, due to the difficulty of producing high quality 2D and 3D crystals. We propose to develop and use the new monolayer crystallization technique, which employs a lipid monolayer as a crystallization template for 2D crystal production. A number of ....Monolayer crystallization of membrane proteins. Membrane proteins comprise 25-40% of all proteins and conduct a myriad of finely tuned reactions in every cell. Despite their importance and diversity only ~40 membrane protein structures have been solved, due to the difficulty of producing high quality 2D and 3D crystals. We propose to develop and use the new monolayer crystallization technique, which employs a lipid monolayer as a crystallization template for 2D crystal production. A number of important membrane proteins are available for these structural studies including ABC transporters, Caveolin-3 and the NS1 protein of Dengue virus, all of which are difficult to crystallize using conventional techniques.Read moreRead less
Structural and Mechanistic Studies of the Oxygen Evolving Centre in Photosystem II. Hydrogen fuel production from electricity and water sources, such as sea water, represents the ultimate goal for the research described here. This is part of an overall scheme, called "Artificial Photosynthesis", to generate clean renewable energy. The present project is an important step in this ambitious program and directly addresses a key hurdle which must be overcome to make artificial photosynthesis feasibl ....Structural and Mechanistic Studies of the Oxygen Evolving Centre in Photosystem II. Hydrogen fuel production from electricity and water sources, such as sea water, represents the ultimate goal for the research described here. This is part of an overall scheme, called "Artificial Photosynthesis", to generate clean renewable energy. The present project is an important step in this ambitious program and directly addresses a key hurdle which must be overcome to make artificial photosynthesis feasible. This hurdle is the efficient electrical conversion of water into hydrogen and oxygen, a two part process of which the latter is the most chemically difficult. The project aims to 'steal nature's secrets', by deciphering and then technologically mimicking the highly efficient means by which plants carry out these processes.Read moreRead less
Bio-Physical Studies of the Oxygen Evolving Complex in Photosystem II. Hydrogen fuel production from electricity and water sources, such as sea water, represents the ultimate goal for the research described here. This is part of an overall scheme, called "Artificial Photosynthesis", to generate clean renewable energy. The present project is an important step in this ambitious program and directly addresses a key hurdle which must be overcome to make artificial photosynthesis feasible. This hurdl ....Bio-Physical Studies of the Oxygen Evolving Complex in Photosystem II. Hydrogen fuel production from electricity and water sources, such as sea water, represents the ultimate goal for the research described here. This is part of an overall scheme, called "Artificial Photosynthesis", to generate clean renewable energy. The present project is an important step in this ambitious program and directly addresses a key hurdle which must be overcome to make artificial photosynthesis feasible. This hurdle is the efficient electrical conversion of water into hydrogen and oxygen, a two part process of which the latter is the most chemically difficult. The project aims to 'steal nature's secrets', by deciphering and then technologically mimicking the highly efficient means by which plants carry out these processes.Read moreRead less
Catalytic Electron Transfer in Photosystem II of Plants and Bacteria. Large scale hydrogen production from electricity and abundant water sources, such as sea water, represents the ultimate goal for the research described here. This is part of an overall scheme, called "Artificial Photosynthesis", to generate clean renewable energy. Although the present project is but one step in this ambitious program, it directly addresses a key hurdle which must be overcome to make the project feasible. This ....Catalytic Electron Transfer in Photosystem II of Plants and Bacteria. Large scale hydrogen production from electricity and abundant water sources, such as sea water, represents the ultimate goal for the research described here. This is part of an overall scheme, called "Artificial Photosynthesis", to generate clean renewable energy. Although the present project is but one step in this ambitious program, it directly addresses a key hurdle which must be overcome to make the project feasible. This is the efficient electrical conversion of water into hydrogen and oxygen, a two part process of which the latter is the most chemically difficult. The project aims to 'steal nature's secrets', by deciphering and then technologically mimicking the highly efficient means by which plants carry out these processes.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