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Intermolecular interactions revisited-Flaws in the fabric and applications to lower-dimensional structures. This project aims to capitalise on recent developments, that have shown that previously accepted theories are deeply flawed, in various applications in fundamental physics and in unsolved problems in biology that involve electromagnetic fields. Interactions driven
by electromagnetic fluctuation forces, and real photon exchange, between molecules will be investigated. The project will inv ....Intermolecular interactions revisited-Flaws in the fabric and applications to lower-dimensional structures. This project aims to capitalise on recent developments, that have shown that previously accepted theories are deeply flawed, in various applications in fundamental physics and in unsolved problems in biology that involve electromagnetic fields. Interactions driven
by electromagnetic fluctuation forces, and real photon exchange, between molecules will be investigated. The project will investigate how dispersion interactions change in mesoscopic pores, in electrolytes, and at finite temperatures. Applications involve
catalysis, molecular formation, and quantum logic. The project also aims to develop a unified theory for energy and charge transfer, relevant for photosynthesis and the way biological molecules transfer information.Read moreRead less
Quantum Mechanics and Planetary Atmospheres. The project will increase the visibility and status of Australian research, by the participation of researchers and students in a wide international collaboration, covering experiments, theory, and computation, which will solve a fundamental research problem that has previously defied understanding. The resulting nitrogen model will be relevant to the important fields of global and planetary atmospheric change, and will find immediate application in t ....Quantum Mechanics and Planetary Atmospheres. The project will increase the visibility and status of Australian research, by the participation of researchers and students in a wide international collaboration, covering experiments, theory, and computation, which will solve a fundamental research problem that has previously defied understanding. The resulting nitrogen model will be relevant to the important fields of global and planetary atmospheric change, and will find immediate application in the analysis of results from the NASA missions, Voyager, Cassini, and (later) New Horizons. In the experimental part of the project, an Australian-first extreme-ultraviolet laser facility will be developed which will provide research opportunities complementary to the Australian Synchrotron.Read moreRead less
Response of Proteins to External Non-Ionising Radiation: an Experimental and Computer Modelling Investigation. The expanding use of digital technologies such as mobile phones has led to major health concerns about the effects of non-ionising pulsed radiation exposure which has been shown to produce instantaneous temperature rises undetectable by normal thermometry. The health implications of exposure are not understandable without establishing molecular mechanisms by which pulsed microwaves can ....Response of Proteins to External Non-Ionising Radiation: an Experimental and Computer Modelling Investigation. The expanding use of digital technologies such as mobile phones has led to major health concerns about the effects of non-ionising pulsed radiation exposure which has been shown to produce instantaneous temperature rises undetectable by normal thermometry. The health implications of exposure are not understandable without establishing molecular mechanisms by which pulsed microwaves can cause biological effects. We aim to establish methods for studying the molecular mechanisms of protein structural and energetic changes occurring due to non-ionising radiation. The results will help our industry partner to design specific drugs as well as formulate a scientifically based standard for microwave utilisation.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0775708
Funder
Australian Research Council
Funding Amount
$289,680.00
Summary
X-ray Diffraction Microscope. The results of the research will substantially expand Australia's knowledge base in the area of diffraction, imaging and structural biology. It will build up our expertise in x-ray optics and synchrotron technology, and will open up a new approach to x-ray imaging and structure determination.
This will revolutionize our understanding of cellular and sub-cellular organisation with implications for the treatment of disease while the ability to determine structures ....X-ray Diffraction Microscope. The results of the research will substantially expand Australia's knowledge base in the area of diffraction, imaging and structural biology. It will build up our expertise in x-ray optics and synchrotron technology, and will open up a new approach to x-ray imaging and structure determination.
This will revolutionize our understanding of cellular and sub-cellular organisation with implications for the treatment of disease while the ability to determine structures of membrane proteins will open the door to fresh opportunities in rational drug design and biotechnology that will promote innovation in this industry, and the likely foundation of new start-up companies.Read moreRead less
Streamlining the dynamin epilepsy drug pipeline. Epilepsy affects up to one percent of Australia's population, yet one in three fail to respond to current medications. Our results will greatly impact on development of future epilepsy therapy. Identification of a new target for epileptic will allow better drug design to improve the potency of our lead drugs. This holds hope that new generation drugs will be more effective. The drugs are predicted to have fewer complications and side-effects. Th ....Streamlining the dynamin epilepsy drug pipeline. Epilepsy affects up to one percent of Australia's population, yet one in three fail to respond to current medications. Our results will greatly impact on development of future epilepsy therapy. Identification of a new target for epileptic will allow better drug design to improve the potency of our lead drugs. This holds hope that new generation drugs will be more effective. The drugs are predicted to have fewer complications and side-effects. The outcome has the potential to vastly improve prospects for up to 200,000 Australians. Intellectual property (IP) retained in Australia will generate future biotechnology industry. The novel chemical biological approaches will facilitate training of future generations of Australian scientists.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
Protein-mRNA interactions and their role in post-transcriptional regulation. The research outcomes will be of fundamental importance in the field of gene regulation, and as such will result in publications in high-profile international journals and continue to contribute to Australia's outstanding international reputation in biological research. Students and research associates that have the opportunity to work on this project will be trained in the use of state-of-the art technologies in bioche ....Protein-mRNA interactions and their role in post-transcriptional regulation. The research outcomes will be of fundamental importance in the field of gene regulation, and as such will result in publications in high-profile international journals and continue to contribute to Australia's outstanding international reputation in biological research. Students and research associates that have the opportunity to work on this project will be trained in the use of state-of-the art technologies in biochemistry, scientific rigour and presentation skills and thus contribute to the quality of our national workforce. Furthermore, applications that arise from this work will contribute to Australia's intellectual property and future development of biotechnological industry.Read moreRead less
Molecular machines: regulation of the catalysis and rotation of the enzyme ATP synthase. This project aims to elucidate the regulation of the molecular machine ATP synthase. ATP synthase is an enzyme that performs a critical role in all cells - the synthesis of ATP, the universal biological energy currency. It is known that the enzyme operates via rotation of a central stalk which is driven by a hydrogen ion gradient across a membrane. Constructs of this molecule have been envisaged in the desig ....Molecular machines: regulation of the catalysis and rotation of the enzyme ATP synthase. This project aims to elucidate the regulation of the molecular machine ATP synthase. ATP synthase is an enzyme that performs a critical role in all cells - the synthesis of ATP, the universal biological energy currency. It is known that the enzyme operates via rotation of a central stalk which is driven by a hydrogen ion gradient across a membrane. Constructs of this molecule have been envisaged in the design of future biological nano-motors. Our work will provide an understanding of the regulation of this enzyme with potential application in the control of nano-motors.Read moreRead less
Functional Dissection of the Bacterial Replisome. We now have the complete sequences of genes in humans and many other organisms, but we know much less about how the protein products of the genes communicate with each other to create and grow cells. Australia has recently invested heavily in state-of-the-art instruments that can be used to tackle these problems. This project will involve close interaction of four laboratories to use new instruments to determine how a large assembly of proteins i ....Functional Dissection of the Bacterial Replisome. We now have the complete sequences of genes in humans and many other organisms, but we know much less about how the protein products of the genes communicate with each other to create and grow cells. Australia has recently invested heavily in state-of-the-art instruments that can be used to tackle these problems. This project will involve close interaction of four laboratories to use new instruments to determine how a large assembly of proteins interact in a biological machine that makes DNA. This process occurs in similar ways in all organisms, and is essential for life. Understanding how DNA is made will help scientists to develop new antibacterial drugs, and learn how to make practical use of molecular machines that imitate biology.Read moreRead less
Mapping Protein Contacts and Conformational Changes in Macromolecular Assemblies. We now have a great deal of information about the structures of proteins that interact to do much of the chemistry that governs the lives of cells and organisms, but are just beginning to understand how proteins communicate with each other in the large, dynamic molecular machines that carry out many cellular functions. Australia has invested in expensive instrumentation that can be used in conjunction with new labo ....Mapping Protein Contacts and Conformational Changes in Macromolecular Assemblies. We now have a great deal of information about the structures of proteins that interact to do much of the chemistry that governs the lives of cells and organisms, but are just beginning to understand how proteins communicate with each other in the large, dynamic molecular machines that carry out many cellular functions. Australia has invested in expensive instrumentation that can be used in conjunction with new laboratory methods to develop better understanding of how these machines work, and how they malfunction in disease. This project will bring together four scientists with a unique combination of expertise and novel technologies to develop understanding of changes in structure of a large protein complex in different functional states.Read moreRead less