Structure-based design of anti-osteoporotic drug leads: an integrated approach. One of the major consequences of Australia's aging population is that age-related diseases, such as osteoporosis, are increasing. Apart from the significant human suffering caused by this disease, there is an immense financial burden on the community, patients and their families. Current treatments for osteoporosis are often ineffective and also have major side-effects. An enzyme has been identified which plays a cru ....Structure-based design of anti-osteoporotic drug leads: an integrated approach. One of the major consequences of Australia's aging population is that age-related diseases, such as osteoporosis, are increasing. Apart from the significant human suffering caused by this disease, there is an immense financial burden on the community, patients and their families. Current treatments for osteoporosis are often ineffective and also have major side-effects. An enzyme has been identified which plays a crucial role in the progression of this disease by increasing the rate of bone-thinning. We will make compounds to slow down this enzyme. This project will provide the basis for the future development of new and improved drugs to treat osteoporosis.Read moreRead less
Molecular mechanisms for copper trafficking across membranes. Copper is a trace metal that is essential for all forms of life, however it is toxic in excess. Tightly controlled protein-based metalloregulatory systems are responsible for copper uptake and homeostasis in all cells. Components of these systems are integral membrane transport proteins, which include the Ctr proteins that are solely responsible for copper uptake into eukaryotic cells. This project aims to define the molecular mechani ....Molecular mechanisms for copper trafficking across membranes. Copper is a trace metal that is essential for all forms of life, however it is toxic in excess. Tightly controlled protein-based metalloregulatory systems are responsible for copper uptake and homeostasis in all cells. Components of these systems are integral membrane transport proteins, which include the Ctr proteins that are solely responsible for copper uptake into eukaryotic cells. This project aims to define the molecular mechanisms by which the Ctr proteins transport copper across eukaryotic cell membranes, by solving their three-dimensional structures by X-ray crystallography.Read moreRead less
Mechanisms maintaining mitochondrial copper homeostasis. This project aims to define the molecular mechanisms by which copper is trafficked and balanced within mitochondria. The project will employ an integrated biological, biochemical, biophysical and structural approach to examine the proteins which underpin the balance between the essentiality for copper and its toxicity, within this organelle. This project will deliver fundamental insights into how mitochondria contribute to and achieve cell ....Mechanisms maintaining mitochondrial copper homeostasis. This project aims to define the molecular mechanisms by which copper is trafficked and balanced within mitochondria. The project will employ an integrated biological, biochemical, biophysical and structural approach to examine the proteins which underpin the balance between the essentiality for copper and its toxicity, within this organelle. This project will deliver fundamental insights into how mitochondria contribute to and achieve cellular metal homeostasis, in addition to molecular explanations for how faults in this process result in mitochondrial defects. Major benefits include research training, strengthened international linkages and fundamental insights into mitochondrial biochemistry.Read moreRead less
Understanding and changing the mechanism of an enzyme: converting a peptidase to a phosphotriesterase. Enzymes have the ability to catalyse biological reactions rapidly as a consequence of their unique three-dimensional structures. We seek to define the structures of a family of metalloenzymes that are required in most living organisms to activate hormones, degrade unwanted proteins or recycle the protein building blocks for further synthesis. We shall use this information to enhance a second ....Understanding and changing the mechanism of an enzyme: converting a peptidase to a phosphotriesterase. Enzymes have the ability to catalyse biological reactions rapidly as a consequence of their unique three-dimensional structures. We seek to define the structures of a family of metalloenzymes that are required in most living organisms to activate hormones, degrade unwanted proteins or recycle the protein building blocks for further synthesis. We shall use this information to enhance a second function of these enzymes, namely their ability to break down organophosphorus-containing insecticides and nerve agents. Ultimately, the structural information resulting from this project may be used in drug design to regulate blood pressure and in engineering proteins for bioremediation.Read moreRead less
Targeting mitochondrial dysfunction in disease. Defects in mitochondria, the energy producing compartments within cells, lead to severe neurodegenerative diseases and contribute to the development of cancer. Treatment for such diseases caused by mutations in mitochondrial DNA remains unsatisfactory and mostly confined to supportive measures. The identification of proteins that regulate gene expression within mitochondria provides an unexplored resource of potential disease modulators and drug ta ....Targeting mitochondrial dysfunction in disease. Defects in mitochondria, the energy producing compartments within cells, lead to severe neurodegenerative diseases and contribute to the development of cancer. Treatment for such diseases caused by mutations in mitochondrial DNA remains unsatisfactory and mostly confined to supportive measures. The identification of proteins that regulate gene expression within mitochondria provides an unexplored resource of potential disease modulators and drug targets. This research will lead to new strategies in the design of improved anticancer drugs, which is an important Australian research priority that will promote and maintain good health, and provide potential commercial outcomes.Read moreRead less
Metals in biocatalysis. Metals and enzymes are essential for the chemistry of life. This project will aim to garner the potential of metal-dependent enzymes to develop new drugs against osteoporosis, combat the spread of antibiotics resistance and optimise some of these enzymes to detoxify pesticide-polluted environments, thus contributing to global health and food security.
Understanding and Inhibiting the P450 CYP24 enzyme, a target for cancer chemotherapeutics. This project falls within the National Research Priority of Promoting and Maintaining Good Health in the category of ageing well and productively. CYP24 inhibition provides a particular target for breast and prostate cancer which are the second leading cause of death in women and men, respectively. The proposed research will result in the production of CYP24 inhibitors that will be assessed in vivo at th ....Understanding and Inhibiting the P450 CYP24 enzyme, a target for cancer chemotherapeutics. This project falls within the National Research Priority of Promoting and Maintaining Good Health in the category of ageing well and productively. CYP24 inhibition provides a particular target for breast and prostate cancer which are the second leading cause of death in women and men, respectively. The proposed research will result in the production of CYP24 inhibitors that will be assessed in vivo at the Hanson Institute in Adelaide as potential anti-cancer drugs. Finally, there is a significant benefit in technology transfer to Australia from our collaborators in the USA in the field of computer aided inhibitor design.Read moreRead less
Biologically inert probes to unravel nutrient directed cellular processing . In this project we will develop novel compounds that can act as probes of the pathways present in cells for the uptake of nutrients and other essential molecules and show how to generate new agents for identifying and targeting specific populations of cells. The project will generate new tools for understanding biological processes including cell transport and processing. The insights gained from this work are expected ....Biologically inert probes to unravel nutrient directed cellular processing . In this project we will develop novel compounds that can act as probes of the pathways present in cells for the uptake of nutrients and other essential molecules and show how to generate new agents for identifying and targeting specific populations of cells. The project will generate new tools for understanding biological processes including cell transport and processing. The insights gained from this work are expected to help guide the development of new agents for selectively delivering imaging and biologically active agents to cells.Read moreRead less
Detecting stress-induced changes to subcellular copper pools in brain cells. Copper (Cu) plays essential roles in the functioning of brain cells, but the regulation and activity of this metal is poorly understood. This project aims to map sub-cellular Cu pools in brain cells, with particular emphasis on the effects of cellular stresses on these pools. These studies are expected to contribute important new methods for the study of Cu biology, and could provide valuable information about how Cu ho ....Detecting stress-induced changes to subcellular copper pools in brain cells. Copper (Cu) plays essential roles in the functioning of brain cells, but the regulation and activity of this metal is poorly understood. This project aims to map sub-cellular Cu pools in brain cells, with particular emphasis on the effects of cellular stresses on these pools. These studies are expected to contribute important new methods for the study of Cu biology, and could provide valuable information about how Cu homeostasis is maintained or perturbed under various stresses. In the future, this work is expected to form the basis of studies of brain Cu pools in neurodegenerative diseases.Read moreRead less