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
Room-temperature quantum microscopy for advanced nanoscale imaging. Original, inspired and most often cross-disciplinary efforts are the only way to solve some of nature's most obscure mysteries. Successful development of high-resolution quantum microscopy will lead to a range of benefits for the community and the nation; from graduate student training in cutting edge technology, building links between academic, industry and government groups to providing new insights and approaches into diseas ....Room-temperature quantum microscopy for advanced nanoscale imaging. Original, inspired and most often cross-disciplinary efforts are the only way to solve some of nature's most obscure mysteries. Successful development of high-resolution quantum microscopy will lead to a range of benefits for the community and the nation; from graduate student training in cutting edge technology, building links between academic, industry and government groups to providing new insights and approaches into disease identification and therapy. This project aims to demonstrate a world-first in imaging sensitivity, and success will directly enhance Australia's global reputation as a leader in innovation and collaboration. 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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Nuclear magnetic resonance (NMR) studies of complex cellular responses: isotopomer sub-spaces, 'lost' ATP and 'tunable' anisotropy. Red blood cells (RBCs) transport oxygen around the body but they have other roles that are mediated by complex interconnecting metabolic pathways that generate myriad metabolites including ATP. A longstanding conundrum is the inability to account for ~60% of ATP turnover in human RBCs. Processes that may consume this 'lost' ATP, include autonomous motion of the cel ....Nuclear magnetic resonance (NMR) studies of complex cellular responses: isotopomer sub-spaces, 'lost' ATP and 'tunable' anisotropy. Red blood cells (RBCs) transport oxygen around the body but they have other roles that are mediated by complex interconnecting metabolic pathways that generate myriad metabolites including ATP. A longstanding conundrum is the inability to account for ~60% of ATP turnover in human RBCs. Processes that may consume this 'lost' ATP, include autonomous motion of the cell membrane called 'flickering', and maintenance of the biconcave-disc shape. NMR spectroscopy of quadrupolar nuclei in chiral aligned media, and isotopomer analysis will be used to define the kinetics of metabolism and membrane processes and thus help define the molecular basis of major blood disorders. Read moreRead less
NMR Spectroscopy of Complex Cellular Processes. The Theme is the cell viewed as a complex regulated molecular assembly. The Aim is to establish an integrated mathematical model of red cell metabolism, membrane transport, shape, and mechanical properties, principally by using NMR spectroscopy. The Significance will be discovery of new aspects of cellular structure and function, and new NMR theory for molecular bioscience. Outcomes will include new NMR measurements of kinetics of metabolic reactio ....NMR Spectroscopy of Complex Cellular Processes. The Theme is the cell viewed as a complex regulated molecular assembly. The Aim is to establish an integrated mathematical model of red cell metabolism, membrane transport, shape, and mechanical properties, principally by using NMR spectroscopy. The Significance will be discovery of new aspects of cellular structure and function, and new NMR theory for molecular bioscience. Outcomes will include new NMR measurements of kinetics of metabolic reactions, rates of membrane transport, solute diffusion, and functions of key membrane- and cytoskeletal proteins. Practical applications will include strategies for modelling complex biochemical systems, and circumventing metabolic defects arising from inheritance, the environment, and therapies.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0219038
Funder
Australian Research Council
Funding Amount
$320,000.00
Summary
Focused Ion Beam System for multidisciplinary applications. A Focused Ion Beam (FIB)system to be housed in a central facility and configured for maximum flexibility and utility over a very wide range of disciplines and applications. It will be used for micromachining and nanoscale fabrication, as an imaging device sensitive to crystal orientation and as a preparation device for scanning and transmission electron microscopy. It will support research including electronic and opto-electronic mater ....Focused Ion Beam System for multidisciplinary applications. A Focused Ion Beam (FIB)system to be housed in a central facility and configured for maximum flexibility and utility over a very wide range of disciplines and applications. It will be used for micromachining and nanoscale fabrication, as an imaging device sensitive to crystal orientation and as a preparation device for scanning and transmission electron microscopy. It will support research including electronic and opto-electronic materials, nanotechnology, complex mesoscale structures, earth sciences, small system optics, fracture behaviour of polymers and biocomposites.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989648
Funder
Australian Research Council
Funding Amount
$350,000.00
Summary
Optical test-bed facility for mid infrared components for sensing, imaging and astrophotonics. This test facility will enable Australian researchers to validate optical components and technologies at wavelengths from 2.5 to 20 microns, that are crucial for a wide range of applications including biophotonics, sensing, imaging, defense, and astro-photonics. Technologies related to the Mid IR are
expected to have a significant impact on quality of life and global economy. It will enable Australi ....Optical test-bed facility for mid infrared components for sensing, imaging and astrophotonics. This test facility will enable Australian researchers to validate optical components and technologies at wavelengths from 2.5 to 20 microns, that are crucial for a wide range of applications including biophotonics, sensing, imaging, defense, and astro-photonics. Technologies related to the Mid IR are
expected to have a significant impact on quality of life and global economy. It will enable Australian researchers to achieve a major impact in many areas of Mid IR fundamental and applied science as well as industry sectors such as sensing, biophotonics, defence, health, bio-security and imaging. Read moreRead less
Liquid light: aqueous bio-sensing in microstructured polymer optical fibres. This project builds on Australia's world-leading position in the development of microstructured polymer optical fibres, and applies the unique benefits they provide to for ultra- sensitive bio-sensing. By using the microstructure to simultaneously confine light and liquid, microstructured optical fibres provide a unique platform for ultra-sensitive spectroscopy and structural studies of biomolecules in solution. The wor ....Liquid light: aqueous bio-sensing in microstructured polymer optical fibres. This project builds on Australia's world-leading position in the development of microstructured polymer optical fibres, and applies the unique benefits they provide to for ultra- sensitive bio-sensing. By using the microstructure to simultaneously confine light and liquid, microstructured optical fibres provide a unique platform for ultra-sensitive spectroscopy and structural studies of biomolecules in solution. The work has profound implications both for fundamental science and applications, particularly in medical diagnostics.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560818
Funder
Australian Research Council
Funding Amount
$154,000.00
Summary
A Pico-Newton Scale Force Measurement Apparatus for Polymer Physics and Non-equilibrium Statistical Mechanics. We propose to build a state-of-the-art Optical Tweezers apparatus that measures small forces and torques on micron-sized objects located in 'optical traps'. Using a single laser beam and computer-generated holograms, we will create arrays of optical traps that move or 'dance', and alter the force/torque-imposing properties of each trap. This proposed research equipment will be used (1 ....A Pico-Newton Scale Force Measurement Apparatus for Polymer Physics and Non-equilibrium Statistical Mechanics. We propose to build a state-of-the-art Optical Tweezers apparatus that measures small forces and torques on micron-sized objects located in 'optical traps'. Using a single laser beam and computer-generated holograms, we will create arrays of optical traps that move or 'dance', and alter the force/torque-imposing properties of each trap. This proposed research equipment will be used (1) to study the physics of single synthetic polymer and naturally occuring biopolymer chains, (2) to quantify experimentally, and for the first time, newly predicted molecular-scale forces, and (3) to demonstrate new theories in non-equilibrium statistical mechanics that quantitatively describe the operation of nanomachines. Read moreRead less