Special Research Initiatives - Grant ID: SR0354474
Funder
Australian Research Council
Funding Amount
$30,000.00
Summary
Metals in Medicine. Metal-based drugs account for several billion dollars of pharmaceutical sales worldwide, but proportionally much less research and development has focussed on this area than organic drugs. Australia has played a pivotal role in the early development of metal-based pharmaceuticals, which remains a research strength. The dual aims of the initiative are to provide a network for a vibrant industry based around metals in medicine and to improve the health of Australians. The ini ....Metals in Medicine. Metal-based drugs account for several billion dollars of pharmaceutical sales worldwide, but proportionally much less research and development has focussed on this area than organic drugs. Australia has played a pivotal role in the early development of metal-based pharmaceuticals, which remains a research strength. The dual aims of the initiative are to provide a network for a vibrant industry based around metals in medicine and to improve the health of Australians. The initiative will foster national and international cross-disciplinary collaborations to address the impediments holding back Australia's potential to take full advantage of our research strength in metals in medicine.Read moreRead less
Pushing the Boundaries of Multi-modal Biospectroscopic Microscopies. In order to understand the fundamentals of life processes, diseases, and their treatments, it is essential to probe fundamental changes in molecular processes in cells, tissues and whole organisms. Much of our understanding of these processes has involved the introduction of chemical probes for biospectroscopy, but these have inherent problems because the probe can often change the biochemistry that is being probed. This projec ....Pushing the Boundaries of Multi-modal Biospectroscopic Microscopies. In order to understand the fundamentals of life processes, diseases, and their treatments, it is essential to probe fundamental changes in molecular processes in cells, tissues and whole organisms. Much of our understanding of these processes has involved the introduction of chemical probes for biospectroscopy, but these have inherent problems because the probe can often change the biochemistry that is being probed. This project will push the boundaries of a variety of micro and nano "probe-free" microscopies to provide fundamental insights into these life processes, which could ultimately lead to improvements in the diagnosis, prevention and treatment of diseases.Read moreRead less
Microprobe and Nanoprobe Studies on Intracellular Disease Processes and Their Treatment. Breakthrough microprobe and nanoprobe technologies, involving X-ray, visible and infrared light can focus into different components of mammalian cells in order to interrogate the biochemistry that is occurring therein. Each of the different wavelengths of light provides complementary biochemical information that enables a deeper understanding of changes in cells that occur as a function of drug treatments an ....Microprobe and Nanoprobe Studies on Intracellular Disease Processes and Their Treatment. Breakthrough microprobe and nanoprobe technologies, involving X-ray, visible and infrared light can focus into different components of mammalian cells in order to interrogate the biochemistry that is occurring therein. Each of the different wavelengths of light provides complementary biochemical information that enables a deeper understanding of changes in cells that occur as a function of drug treatments and disease processes. This will provide unprecedented information as to where drugs go and how they are transformed inside cells that, in turn, may revolutionalise the way in which new drugs are designed that have higher specificity and fewer side effects.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
Discovery Early Career Researcher Award - Grant ID: DE210101176
Funder
Australian Research Council
Funding Amount
$445,000.00
Summary
Fluorescent probes for super-resolution imaging of the amyloid architecture. The goal of this project is to develop chemical tools that enable molecular-level imaging of the amyloid structure. The Nobel Prize-winning super-resolution microscopy provides nanoscale imaging capabilities, but surprisingly there have been no substantive efforts to design fluorescent sensors that are compatible with this cutting-edge technology. In this project, new fluorescent super-resolution sensors will be develop ....Fluorescent probes for super-resolution imaging of the amyloid architecture. The goal of this project is to develop chemical tools that enable molecular-level imaging of the amyloid structure. The Nobel Prize-winning super-resolution microscopy provides nanoscale imaging capabilities, but surprisingly there have been no substantive efforts to design fluorescent sensors that are compatible with this cutting-edge technology. In this project, new fluorescent super-resolution sensors will be developed that enable nanoscale visualisation of amyloid assemblies. These chemical and biochemical studies will establish rational design strategies to develop fluorescent sensors for super-resolution imaging applications and significantly advance our understanding of fundamental differences functional and toxic protein assemblies.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560680
Funder
Australian Research Council
Funding Amount
$901,862.00
Summary
Vibrational Spectroscopy Microprobe/FESEM/AFM Imaging of Cells, Tissues and Materials. State-of-the-art vibrational mapping and imaging equipment (integrated with a field-emission scanning electron microscope (FESEM) and an atomic force microscope (AFM)) will provide enabling technologies for cutting-edge research in disease diagnosis, identification of pathogens, mapping of the entry and distribution of pharmaceutics into cells, and materials research. An InVia Renishaw Raman spectrometer (sub ....Vibrational Spectroscopy Microprobe/FESEM/AFM Imaging of Cells, Tissues and Materials. State-of-the-art vibrational mapping and imaging equipment (integrated with a field-emission scanning electron microscope (FESEM) and an atomic force microscope (AFM)) will provide enabling technologies for cutting-edge research in disease diagnosis, identification of pathogens, mapping of the entry and distribution of pharmaceutics into cells, and materials research. An InVia Renishaw Raman spectrometer (sub-micron spatial positioning and micron spatial resolution) will be interfaced to an FEI Quanta FESEM for combined Raman (spectroscopic), EDS and SEM (morphological) imaging/mapping at the sub-cellular level. Complementary new-generation Raman and IR spectrometer upgrades will provide an integrated world-class equipment platform.Read moreRead less
Molecular study of copper-promoted ubiquitination. This project aims to study copper-promoted ubiquitination, a novel discovery that a conserved copper binding site in conjugating enzyme UBE2D2 promotes ubiquitination of a range of proteins including tumor suppressor p53. It predicts a correlation between copper homeostasis and cellular proteostasis and may rationalise an inverse relationship between Alzheimer's disease and cancer. This project will employ a range of integrated approaches to ill ....Molecular study of copper-promoted ubiquitination. This project aims to study copper-promoted ubiquitination, a novel discovery that a conserved copper binding site in conjugating enzyme UBE2D2 promotes ubiquitination of a range of proteins including tumor suppressor p53. It predicts a correlation between copper homeostasis and cellular proteostasis and may rationalise an inverse relationship between Alzheimer's disease and cancer. This project will employ a range of integrated approaches to illuminate the molecular nature of this copper action. Expected outcomes include an understanding of the molecular mechanisms of this process, and enhanced interdisciplinary collaboration. Potential benefits include new strategies to intervene in copper-related disorders.Read moreRead less
The role of copper in the early ubiquitination pathway. This project aims to explore the role of copper in ageing and protein turnover. The removal of damaged or excess proteins is achieved by ubiquitin-tagging in all kingdoms of life. It has recently been observed that one of the earliest steps of this process appears to be driven by copper. This project aims to elaborate the precise biochemical mechanisms by which copper regulates this important tagging and protein turnover system. It proposes ....The role of copper in the early ubiquitination pathway. This project aims to explore the role of copper in ageing and protein turnover. The removal of damaged or excess proteins is achieved by ubiquitin-tagging in all kingdoms of life. It has recently been observed that one of the earliest steps of this process appears to be driven by copper. This project aims to elaborate the precise biochemical mechanisms by which copper regulates this important tagging and protein turnover system. It proposes to characterise the structure and function of a newly identified copper-dependent form of cell enzyme which could be involved in amplifying ubiquitin-tagged protein breakdown. Copper is essential for life in all domains. Identifying copper as a major regulator in protein clearance is important in understanding this fundamental biological machinery.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100174
Funder
Australian Research Council
Funding Amount
$800,000.00
Summary
Innovative synchrotron science - program for access to the Australian National Beamline Facility and cutting-edge beamlines at international synchrotrons. Synchrotron science dramatically affects the community through the innovative scientific, engineering and medical research outcomes it produces. This program for access to synchrotron beamlines is aimed at enhancing Australia's high international standing in synchrotron science and will have many flow-on effects in areas such as health and ind ....Innovative synchrotron science - program for access to the Australian National Beamline Facility and cutting-edge beamlines at international synchrotrons. Synchrotron science dramatically affects the community through the innovative scientific, engineering and medical research outcomes it produces. This program for access to synchrotron beamlines is aimed at enhancing Australia's high international standing in synchrotron science and will have many flow-on effects in areas such as health and industry.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130100424
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Strike while the iron is hot - structure and reactivity of iron-oxo complexes that mimic carbon-hydrogen bond activating enzymes. To meet the demands of a burgeoning global population, new and more sustainable methods for producing chemicals that are ubiquitous to modern life are required. This project will provide valuable information on how to improve the way chemicals are made by using nature as a blueprint for designing the next generation of catalysts that contain iron.