Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0882289
Funder
Australian Research Council
Funding Amount
$520,000.00
Summary
New generation mass spectrometers for characterisation of molecular shape and size. The ion mobility mass spectrometer (IMMS at UOW) will be the first of its kind in Australia, and together with the ion trap mass spectrometer (ITMS at ANU) will continue the tradition of this partnership in providing researchers with cutting-edge instrumentation for nationally and internationally important projects including: (i) fundamental understanding of the ways in which biomolecules recognize one another, ( ....New generation mass spectrometers for characterisation of molecular shape and size. The ion mobility mass spectrometer (IMMS at UOW) will be the first of its kind in Australia, and together with the ion trap mass spectrometer (ITMS at ANU) will continue the tradition of this partnership in providing researchers with cutting-edge instrumentation for nationally and internationally important projects including: (i) fundamental understanding of the ways in which biomolecules recognize one another, (ii) investigating the structure(s) of lipids (fats) in cardiovascular disease and cataract, (iii) developing anticancer drugs, and (iv) development of new materials.Read moreRead less
Proteomics of the Influenza Virus for In-field Surveillance. The influenza virus continues to pose a serious health risk to Australians and remains a leading cause of death. The molecular characterisation of emerging strains of the virus lies at the heart of current surveillance procedures vital to vaccine preparation and the development of new anti-viral drugs. This research will advance a world-first proteomics surveillance of the virus developed in this laboratory that will enable it to be ch ....Proteomics of the Influenza Virus for In-field Surveillance. The influenza virus continues to pose a serious health risk to Australians and remains a leading cause of death. The molecular characterisation of emerging strains of the virus lies at the heart of current surveillance procedures vital to vaccine preparation and the development of new anti-viral drugs. This research will advance a world-first proteomics surveillance of the virus developed in this laboratory that will enable it to be characterised in-field at the site(s) of infection outbreaks. This rapid response is vital, particularly in the event of a pandemic or a deliberate release of the virus in a bioterrorist attack.Read moreRead less
High Pressure and Fluorous Approaches to Fostriecin Libraries: New Therapeutic Opportunities. The natural product, Fostriecin, displays considerable broad-spectrum anti-cancer activity, acting via a novel mechanism. However, this activity is tempered by its considerable instability, being too unstable to be used as a therapeutic agent. Using state-of-the-art approaches we will, rapidly generate libraries of more stable and biologically active fostriecin analogues and examine their potential to b ....High Pressure and Fluorous Approaches to Fostriecin Libraries: New Therapeutic Opportunities. The natural product, Fostriecin, displays considerable broad-spectrum anti-cancer activity, acting via a novel mechanism. However, this activity is tempered by its considerable instability, being too unstable to be used as a therapeutic agent. Using state-of-the-art approaches we will, rapidly generate libraries of more stable and biologically active fostriecin analogues and examine their potential to be used anti-cancer agents. This project represents an opportunity for Australia to take a significant, innovative lead in the development of hitherto unforseen therapeutic agents.Read moreRead less
Gas Phase Dynamics of a Biological Molecular Machine: Fundamentals, Stoichiometries and Stabilities. Over the last twenty years advanced molecular measurement techniques have enabled the characterization of individual biological molecules (proteins and DNA) within different types of cells and diseased tissues. This project uses a new technique that literally "weighs" groups of proteins and/or DNA to help us understand how such large molecules fit together and function within cells (sometimes ref ....Gas Phase Dynamics of a Biological Molecular Machine: Fundamentals, Stoichiometries and Stabilities. Over the last twenty years advanced molecular measurement techniques have enabled the characterization of individual biological molecules (proteins and DNA) within different types of cells and diseased tissues. This project uses a new technique that literally "weighs" groups of proteins and/or DNA to help us understand how such large molecules fit together and function within cells (sometimes referred to as molecular machinery). More detailed knowledge of processes such as those involved in copying DNA when new cells are produced will, in the long term, improve our understanding and treatment of conditions or diseases that result from errors in molecular machinery. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100125
Funder
Australian Research Council
Funding Amount
$330,000.00
Summary
Oxidative stress bioanalytical facility. The primary national benefit of this application is that it will provide a currently unavailable, state-of-the-art facility for Australian scientists to define precisely how changes in cellular redox state contribute to biological processes relevant to health and diseases. The facility will uniquely complement, and in many cases integrate with existing facilities in this area of research in Australia. It will act as a platform for major national and inter ....Oxidative stress bioanalytical facility. The primary national benefit of this application is that it will provide a currently unavailable, state-of-the-art facility for Australian scientists to define precisely how changes in cellular redox state contribute to biological processes relevant to health and diseases. The facility will uniquely complement, and in many cases integrate with existing facilities in this area of research in Australia. It will act as a platform for major national and international research collaborations, develop cutting-edge technology and unique local skills, and contribute to Australia maintaining a leading position in redox-related research in biology and medicine. In doing so, the facility will increase the likelihood of gaining future, value-adding funding.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100142
Funder
Australian Research Council
Funding Amount
$500,000.00
Summary
An integrated liquid chromatography mass spectrometry nuclear magnetic resonance (LC-MS-NMR) facility for applications in proteomics and organic chemistry. This application completes the requested liquid chromatography mass spectrometry nuclear magnetic resonance (LCMS-NMR) facility and will allow the training of over 150 researchers, significantly enhancing their research productivity and translation of outcomes in areas of national importance. New breakthroughs in drug development, smart mate ....An integrated liquid chromatography mass spectrometry nuclear magnetic resonance (LC-MS-NMR) facility for applications in proteomics and organic chemistry. This application completes the requested liquid chromatography mass spectrometry nuclear magnetic resonance (LCMS-NMR) facility and will allow the training of over 150 researchers, significantly enhancing their research productivity and translation of outcomes in areas of national importance. New breakthroughs in drug development, smart materials, organic electronic materials and biomedical research require routine access to cutting edge technology. The LCMS-NMR augments the capabilities of our research teams at the forefront of these efforts. These include understanding the impact of the environment on plant and animal development, pest animal control, development of new biotechnology tools, new drugs and new methods for the detection of narcotics and explosives.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100081
Funder
Australian Research Council
Funding Amount
$600,000.00
Summary
Combined scanning tunnelling microscope system for materials characterisation and manipulation at nano scale. The proposed facility is unique in Australia and will substantially enhance national research capabilities in nano-materials, nanotechnology and biotechnology. The proposed infrastructure project will bring more than 20 leading Australian research groups from 10 institutions together to create an outstanding platform to underpin close collaborations among members in a broad field. The pr ....Combined scanning tunnelling microscope system for materials characterisation and manipulation at nano scale. The proposed facility is unique in Australia and will substantially enhance national research capabilities in nano-materials, nanotechnology and biotechnology. The proposed infrastructure project will bring more than 20 leading Australian research groups from 10 institutions together to create an outstanding platform to underpin close collaborations among members in a broad field. The proposed facility will provide significant benefits to Australian researchers in drug design and delivery, nano-material design and characterisation at nano scale for advanced materials, and promotion of renewable energy. This represents a great opportunity to make discoveries and breakthroughs in frontier science and technology in Australia.Read moreRead less
Nanoprobe and Microprobe Structural and Spectroscopic Studies in Biomedical Research. 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 multi-layered information on changes in cells that occur as a function of drug treatments a ....Nanoprobe and Microprobe Structural and Spectroscopic Studies in Biomedical Research. 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 multi-layered information on 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 lower side effects.Read moreRead less
Understanding aerobic respiration: Models for the catalytic centre in proton-pumping heme-copper oxidases. This project tackles ?head on? a key challenge in contemporary biological inorganic chemistry, understanding how at the atomic level aerobic life uses oxygen. All life we see is aerobic, and thus the conceptual advances from this research will progress understanding of our world and ourselves? an important cultural goal. Advancing knowledge of such fundamental processes sits firmly in the a ....Understanding aerobic respiration: Models for the catalytic centre in proton-pumping heme-copper oxidases. This project tackles ?head on? a key challenge in contemporary biological inorganic chemistry, understanding how at the atomic level aerobic life uses oxygen. All life we see is aerobic, and thus the conceptual advances from this research will progress understanding of our world and ourselves? an important cultural goal. Advancing knowledge of such fundamental processes sits firmly in the area of the Research Priority Goal: Breakthrough Science. Postgraduate research students will be trained in sophisticated state-of-the-art theoretical and synthetic chemical methodologies. The project will enhance Australia's research capability in biological (inorganic) chemistry and promote Australia's standing in the International research community.Read moreRead less
Mechanistic Studies of Dimethylsulfide Dehydrogenase: A Novel Bacterial Molybdoenzyme. The aim of this proposal is to use electrochemical, spectroscopic and molecular biological techniques to understand the mechanism of action of the enzyme dimethylsulfide dehydrogenase. This enzyme is representative of an major group of molybdenum-containing enzymes that have importance in microbial biotransformations. The project will provide fundamental information about a multi-redox centre protein that has ....Mechanistic Studies of Dimethylsulfide Dehydrogenase: A Novel Bacterial Molybdoenzyme. The aim of this proposal is to use electrochemical, spectroscopic and molecular biological techniques to understand the mechanism of action of the enzyme dimethylsulfide dehydrogenase. This enzyme is representative of an major group of molybdenum-containing enzymes that have importance in microbial biotransformations. The project will provide fundamental information about a multi-redox centre protein that has potential application in biosensors and biocatalysis.Read moreRead less