Intravital super-resolution imaging via Stimulated Emission Depletion microscopy (STED)-microendoscopy. We will develop a new technology to enable the imaging of sub-cellular structures within a biological specimen, with super-resolution. This intravital super-resolution imaging technology will build off world leading techniques to image objects with super-resolution and to perform this within a specimen, with minimal invasion. The broad ramifications of this technology apply to biology, medical ....Intravital super-resolution imaging via Stimulated Emission Depletion microscopy (STED)-microendoscopy. We will develop a new technology to enable the imaging of sub-cellular structures within a biological specimen, with super-resolution. This intravital super-resolution imaging technology will build off world leading techniques to image objects with super-resolution and to perform this within a specimen, with minimal invasion. The broad ramifications of this technology apply to biology, medical science, imaging and sensing. Important applications include the early detection of debilitating diseases and the advancement of understanding of cellular biology. This research will raise Australia's profile as a world leader in science and technology, building on our emerging presence in the biophysical sciences.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668534
Funder
Australian Research Council
Funding Amount
$770,000.00
Summary
High resolution bioanalytical Fourier transform mass spectrometer combined with liquid chromatograph. This project extends a network of advanced technology for bioanalysis that enables discoveries in biotechnology, molecular medicine and biochemistry. The proposed equipment includes the most powerful mass spectrometer (MS) currently available for bioanalysis to complement an existing network of instruments at four universities in Sydney. These include 3 of 4 nodes of the Australian Proteome Anal ....High resolution bioanalytical Fourier transform mass spectrometer combined with liquid chromatograph. This project extends a network of advanced technology for bioanalysis that enables discoveries in biotechnology, molecular medicine and biochemistry. The proposed equipment includes the most powerful mass spectrometer (MS) currently available for bioanalysis to complement an existing network of instruments at four universities in Sydney. These include 3 of 4 nodes of the Australian Proteome Analysis Facility (APAF). The new technology is a missing link in bioanalytical capability where other instruments are not sufficiently sensitive. The instrument will be managed by MS specialists at the Bioanalytical Mass Spectrometry Facility at UNSW (www.bmsf.unsw.edu.au) where access by and training of users is well established.Read moreRead less
Novel target of amiloride analogues - picornaviral RNA polymerase. Picornaviruses cause a range of diseases such as poliomyelitis, meningitis, myocarditis, hepatitis A, neonatal sepsis and common cold. No antiviral treatment is available for these infections. Nearly 50% of antiviral drugs used in medicine are viral polymerase inhibitors; however picornaviral RNA polymerase has been largely overlooked as a drug target. We have discovered a group of compounds that inhibit picornaviral RNA polymera ....Novel target of amiloride analogues - picornaviral RNA polymerase. Picornaviruses cause a range of diseases such as poliomyelitis, meningitis, myocarditis, hepatitis A, neonatal sepsis and common cold. No antiviral treatment is available for these infections. Nearly 50% of antiviral drugs used in medicine are viral polymerase inhibitors; however picornaviral RNA polymerase has been largely overlooked as a drug target. We have discovered a group of compounds that inhibit picornaviral RNA polymerase. This project aims to define the inhibition mechanism and to evaluate a potential use of these compounds for antiviral drug development.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0883030
Funder
Australian Research Council
Funding Amount
$450,000.00
Summary
High-Resolution Field Emission Scanning Electron Microscopy (FESEM) Platform for Characterisation at the Nanometre-Level. The Field Emission Scanning Electron Microscope (FESEM) is designed to provide fundamental insights into physical and biological systems though characterisation and analysis of structures on nanometre length scales. This versatile instrument will support a wide range of research projects covering all four national research priorities. These range from the characterisation of ....High-Resolution Field Emission Scanning Electron Microscopy (FESEM) Platform for Characterisation at the Nanometre-Level. The Field Emission Scanning Electron Microscope (FESEM) is designed to provide fundamental insights into physical and biological systems though characterisation and analysis of structures on nanometre length scales. This versatile instrument will support a wide range of research projects covering all four national research priorities. These range from the characterisation of light alloys to boost and intensify Australia's aluminium, magnesium and titanium alloy industries, to tissue engineering for the repair of human elastic tissues in skin, artery, bladder and lung, to the study of microtubules in plant cells for genetic manipulation of plants to withstand environmental stresses such as drought or salinity.Read moreRead less
New analgesics based on µ-conotoxins: structure-based design of helical mimetics. Diseases in which voltage-gated sodium channels are implicated are contributors to morbidity and mortality in the Australian population, and this project promises to provide new leads for the future development of drugs to treat such diseases, in particular analgesics for the treatment of chronic pain. The generation of these leads will entail the development of new approaches to mimicking key regions of peptides a ....New analgesics based on µ-conotoxins: structure-based design of helical mimetics. Diseases in which voltage-gated sodium channels are implicated are contributors to morbidity and mortality in the Australian population, and this project promises to provide new leads for the future development of drugs to treat such diseases, in particular analgesics for the treatment of chronic pain. The generation of these leads will entail the development of new approaches to mimicking key regions of peptides and proteins in drug-like molecules. This is a highly interdisciplinary project, spanning structural biology, molecular design, medicinal chemistry, molecular biology and electrophysiology, and the training of PhD graduates with such broad experience represents another national benefit of the project.Read moreRead less
Drug targets in malaria parasites. Malaria is rampant throughout our Region and hinders the economies of our neighbours reducing regional prosperity and stability. Australian security and aid personnel deployed in the Region contract malaria infections and global warming could bring malaria-carrying mosquitoes south to Sydney. Australia is pre-eminent in malaria research, making lead discoveries in vaccine and drug development. However, we lack crucial resources to study the parasite in the mo ....Drug targets in malaria parasites. Malaria is rampant throughout our Region and hinders the economies of our neighbours reducing regional prosperity and stability. Australian security and aid personnel deployed in the Region contract malaria infections and global warming could bring malaria-carrying mosquitoes south to Sydney. Australia is pre-eminent in malaria research, making lead discoveries in vaccine and drug development. However, we lack crucial resources to study the parasite in the mosquito phase of its life cycle. The Federation Fellowship will create a malaria mosquito facility to redress this crucial gap in our capability. The Fellowship will double as foreign aid investment by enhancing our capacity to protect ourselves as well as supporting our neighbours.Read moreRead less
The role of intracellular calcium stores in cardiac pacemaking. The spontaneous firing of pacemaker cells is central to regulation of the cardiovascular system particularly during exercise. The discovery that pacemaker cell function is modulated in part by calcium ions will change our understanding of the changes in heart rate during exercise and in diseases which affect the pacemaker cells. Better understanding of the way in which spontaneous activity of these cells is regulated is the key to ....The role of intracellular calcium stores in cardiac pacemaking. The spontaneous firing of pacemaker cells is central to regulation of the cardiovascular system particularly during exercise. The discovery that pacemaker cell function is modulated in part by calcium ions will change our understanding of the changes in heart rate during exercise and in diseases which affect the pacemaker cells. Better understanding of the way in which spontaneous activity of these cells is regulated is the key to controlling or modifying their function.Read moreRead less
Electro-active and migratory peptides in lipid bilayers: NMR and biophysical studies. All living things are characterized by the separation of inner space from the surrounding medium by a self-assembling membrane. Selective entry and exit of water, ions and solutes is a defining feature of each type of cell. Some proteins sense the voltage difference across the cell membrane and open or close in response to voltage changes. Others, like bacterial toxins assemble in the membrane as pores, while o ....Electro-active and migratory peptides in lipid bilayers: NMR and biophysical studies. All living things are characterized by the separation of inner space from the surrounding medium by a self-assembling membrane. Selective entry and exit of water, ions and solutes is a defining feature of each type of cell. Some proteins sense the voltage difference across the cell membrane and open or close in response to voltage changes. Others, like bacterial toxins assemble in the membrane as pores, while other peptides migrate across the membrane piggy-backing their peptide cargo. The aim is to understand the molecular mechanisms in examples of these membrane-active peptides and proteins with a view to enabling rational intervention into their operation in situ in normal and disease states.Read moreRead less
NMR studies of membrane proteins and peptides in novel amphiphilic mesophases. Membrane proteins are the next frontier in structural biology. Our goal is the structural and mechanistic characterization of the proteins and peptides from platypus venom and a cardiac potassium ion channel, HERG, that has a particular role in the suppression of cardiac arrhythmias. To do this we will refine and develop methods using amphiphilic mesophases and micelles and state-of-the-art NMR spectroscopy. Electrop ....NMR studies of membrane proteins and peptides in novel amphiphilic mesophases. Membrane proteins are the next frontier in structural biology. Our goal is the structural and mechanistic characterization of the proteins and peptides from platypus venom and a cardiac potassium ion channel, HERG, that has a particular role in the suppression of cardiac arrhythmias. To do this we will refine and develop methods using amphiphilic mesophases and micelles and state-of-the-art NMR spectroscopy. Electrophysiological analysis of ion channels and interactions with toxins will relate NMR structures to function. The NMR methodologies we develop will have broad applicability to membrane proteins in general.
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Protein chips for the high-throughput study of immune complexes by mass spectrometry. Mass spectrometry is a core enabling technology for proteomics with proteins identified by molecular weight, mass maps and sequencing within the confines of a mass spectrometer. We have found conditions under which it is possible to preserve and detect protein complexes by matrix-assisted laser desorption ionization (MALDI) mass spectrometry that has promising implications for the high-throughput screening of p ....Protein chips for the high-throughput study of immune complexes by mass spectrometry. Mass spectrometry is a core enabling technology for proteomics with proteins identified by molecular weight, mass maps and sequencing within the confines of a mass spectrometer. We have found conditions under which it is possible to preserve and detect protein complexes by matrix-assisted laser desorption ionization (MALDI) mass spectrometry that has promising implications for the high-throughput screening of protein-protein interactions. Technologies pioneered by the applicant will be advanced to achieve the high-throughput analysis of antibody complexes with native gel recovered protein antigens across emerging strains of the influenza virus by means of miniature protein chips.Read moreRead less