Nanosized peptide nucleic acid - metal complex hybrids as catalysts for the cleavage of phosphate ester bonds in biological molecules. The information from Human Genome Project is being used to generate molecules with a variety of therapeutic and diagnostic applications. The capability to design, synthesise and manipulate functional molecules that mimic biological processes will underpin many emerging applications. In this project, macrocyclic metal complexes that catalyse the cleavage of phosph ....Nanosized peptide nucleic acid - metal complex hybrids as catalysts for the cleavage of phosphate ester bonds in biological molecules. The information from Human Genome Project is being used to generate molecules with a variety of therapeutic and diagnostic applications. The capability to design, synthesise and manipulate functional molecules that mimic biological processes will underpin many emerging applications. In this project, macrocyclic metal complexes that catalyse the cleavage of phosphate ester bonds in biological molecules will be developed. Active complexes will be incorporated into nanosized peptide nucleic acid (PNA) - metal complex hybrids and applied as artificial enzymes in the sequence specific cleavage of RNA and DNA. Novel applications of these ?artificial enzymes? in biotechnology are anticipated.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100197
Funder
Australian Research Council
Funding Amount
$200,000.00
Summary
National magnetochemical facility. New magnetic materials of the molecular or biological types are quite different to traditional metal oxide magnets widely used, for example, in recording devices. They are very important from the perspective of understanding fundamental properties at low temperatures, in high magnetic fields, or when irradiated by light, but they are also showing promise in a range of applications, such as memory devices and smart cards and in the new area of spintronics and m ....National magnetochemical facility. New magnetic materials of the molecular or biological types are quite different to traditional metal oxide magnets widely used, for example, in recording devices. They are very important from the perspective of understanding fundamental properties at low temperatures, in high magnetic fields, or when irradiated by light, but they are also showing promise in a range of applications, such as memory devices and smart cards and in the new area of spintronics and molecular computers. The magnetochemical projects described here, that require the new equipment being sought, are fundamental in nature but will provide the underpinning of future nanomagnetic materials.Read moreRead less
Bio-inspired Catalysts for Water Oxidation. Successful completion of the project will result in the development of devices that utilise redox active manganese clusters to catalyse the oxidation of water. This achievement would place us at the forefront of international efforts to develop devices that can split water into hydrogen and oxygen, an endeavour which has the potential to solve pressing energy demands. As an added benefit, these devices can be adapted for the purposes of carrying out th ....Bio-inspired Catalysts for Water Oxidation. Successful completion of the project will result in the development of devices that utilise redox active manganese clusters to catalyse the oxidation of water. This achievement would place us at the forefront of international efforts to develop devices that can split water into hydrogen and oxygen, an endeavour which has the potential to solve pressing energy demands. As an added benefit, these devices can be adapted for the purposes of carrying out the catalytic oxidation of organic substrates, for which a variety of industrial and environmental applications can be envisaged.
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Redox initiated chemistry of hydrogenase H-cluster model compounds: Biologically inspired hydrogen activation catalysts? High efficiency, low temperature, cheap hydrogen activation catalysts suitable for fuel cell applications would provide the basis for the development of environmentally benign technologies suitable for transportation and some power applications. Hydrogenase enzymes are high efficiency, low temperature, hydrogen activation catalysts and the active site of the all-iron version ....Redox initiated chemistry of hydrogenase H-cluster model compounds: Biologically inspired hydrogen activation catalysts? High efficiency, low temperature, cheap hydrogen activation catalysts suitable for fuel cell applications would provide the basis for the development of environmentally benign technologies suitable for transportation and some power applications. Hydrogenase enzymes are high efficiency, low temperature, hydrogen activation catalysts and the active site of the all-iron version of the enzyme has recently been revealed to be a remarkable, weakly protein bound, iron-sulfur-carbonyl-cyanide complex. Research into the reactions of redox activated abiological model compounds will provide insights into the molecular basis of the enzymatic reaction, potentially leading to the discovery of highly efficient, biologically inspired hydrogen activation catalysts.Read moreRead less