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Single Molecule Studies of Replisomal Function. It has recently become possible to watch the copying of DNA molecules with a specialized microscope in real time. This process requires assembly of a complex molecular machine on the DNA, followed by triggering of its function, and yields exquisitely detailed information about how the machine works. In this new collaboration between scientists in Australia and the U.S.A., we will assemble these machines on single DNA molecules, watch how they work ....Single Molecule Studies of Replisomal Function. It has recently become possible to watch the copying of DNA molecules with a specialized microscope in real time. This process requires assembly of a complex molecular machine on the DNA, followed by triggering of its function, and yields exquisitely detailed information about how the machine works. In this new collaboration between scientists in Australia and the U.S.A., we will assemble these machines on single DNA molecules, watch how they work and simultaneously measure the very small forces that the machines generate. This will give Australian scientists access to a new technology for studying molecular machines.Read moreRead less
Synthesis and Functionalisation of Advanced Polymer Films and Particles. Scientific and technological advances at the frontiers of nano- and biotechnology are poised to revolutionise the scope of treatment and healthcare options. This project will involve the synthesis of engineered polymer building blocks with the capability for multifunctional and intelligent response. These smart polymers will then be assembled into responsive nanostructured materials for drug delivery and biosensing applica ....Synthesis and Functionalisation of Advanced Polymer Films and Particles. Scientific and technological advances at the frontiers of nano- and biotechnology are poised to revolutionise the scope of treatment and healthcare options. This project will involve the synthesis of engineered polymer building blocks with the capability for multifunctional and intelligent response. These smart polymers will then be assembled into responsive nanostructured materials for drug delivery and biosensing applications. These materials are expected to have health benefits for Australian citizens and will contribute to a world-leading nanobiotechnology industry. The project will also provide development opportunities for young scientists and will also foster multidisciplinary collaborations within both Australia and abroad.Read moreRead less
Polymer Globules: Beyond the Homopolymer Model. Polymers are long chainlike molecules which play a crucial role in many aspects of our lives. As plastics they represent the most versatile and ubiquitous of man-made materials. Moreover, all living things depend on polymers for the structure of their cells and for the inheritance and function through DNA and proteins. Despite their importance our understanding of polymers is rather limited. The research funded by this proposal will enable us to ....Polymer Globules: Beyond the Homopolymer Model. Polymers are long chainlike molecules which play a crucial role in many aspects of our lives. As plastics they represent the most versatile and ubiquitous of man-made materials. Moreover, all living things depend on polymers for the structure of their cells and for the inheritance and function through DNA and proteins. Despite their importance our understanding of polymers is rather limited. The research funded by this proposal will enable us to understand more complicated kinds of polymers. This will help uncover some fascinating physics and in the long term develop new materials and promote new advances in biology. Read moreRead less
Molecular Mechanisms of Biochemical Regulation: Neutron and X-ray Scattering Studies. This project will develop and use novel neutron and x-ray scattering methods to study the molecular mechanisms by which nature regulates biochemical processes. Healthy function requires cells to tightly control and coordinate a myriad of molecular activities. My research focuses on a set of interdependent molecular networks inside cells whose behavior is controlled by the so-called 'second messengers' that tr ....Molecular Mechanisms of Biochemical Regulation: Neutron and X-ray Scattering Studies. This project will develop and use novel neutron and x-ray scattering methods to study the molecular mechanisms by which nature regulates biochemical processes. Healthy function requires cells to tightly control and coordinate a myriad of molecular activities. My research focuses on a set of interdependent molecular networks inside cells whose behavior is controlled by the so-called 'second messengers' that translate external signals into the right cellular responses. The proposed experiments will provide a unique structural framework by which we can understand how these signals are transmitted. Such knowledge is an important foundation for advances in biomedical research and biotechnology applications.Read moreRead less
Molecular mechanisms of two-component signal transduction in bacteria. The focus of this research is on the protein complexes that transmit signals in bacteria to elicit the desired responses to environmental stimuli. Like many dynamic processes in cells, signaling requires proteins that are flexible and hence resistant to high-resolution structural analysis using crystallography. We will make use of new research infrastructure at the Australian synchrotron and OPAL research reactor to overcom ....Molecular mechanisms of two-component signal transduction in bacteria. The focus of this research is on the protein complexes that transmit signals in bacteria to elicit the desired responses to environmental stimuli. Like many dynamic processes in cells, signaling requires proteins that are flexible and hence resistant to high-resolution structural analysis using crystallography. We will make use of new research infrastructure at the Australian synchrotron and OPAL research reactor to overcome the challenges of flexibility in these systems. The proteins we will study are not found in humans, and hence our research will provide important structural data on potential targets for the design of novel antibiotics to fight bacterial infection.Read moreRead less
Macromolecular Condensates: From Globules to Toroids and Beyond. Polymers are long-chain molecules which are vital for all living things. Examples include proteins and DNA which carries all of the information needed for life. In the cell and in the laboratory these polymers are often found in a compact folded state. Current polymer science is good at describing very flexible polymers, but fails to describe most biological polymers which have backbones that are difficult to bend. Our aim is to ....Macromolecular Condensates: From Globules to Toroids and Beyond. Polymers are long-chain molecules which are vital for all living things. Examples include proteins and DNA which carries all of the information needed for life. In the cell and in the laboratory these polymers are often found in a compact folded state. Current polymer science is good at describing very flexible polymers, but fails to describe most biological polymers which have backbones that are difficult to bend. Our aim is to describe the folded or globular state for many kinds of biological polymers and thus improve our understanding of the role of polymers in living things.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE130100141
Funder
Australian Research Council
Funding Amount
$310,000.00
Summary
High resolution nuclear magnetic resonance spectroscopy for glycomics, metabonomics and soft materials applications. This project will enhance the nuclear magnetic resonance spectroscopy capabilities and the world class research being undertaken at the Institute for Glycomics, Griffith University and Queensland University of Technology. This powerful technique can contribute information in diverse research areas such as glycomics, metabonomics and soft materials research.
Studies of the Dynamic Language of Bio-Molecular Communication and Signalling. For normal biological function, a multitude of external signals must be interpreted and responded to by cells. The responses must be carefully regulated and coordinated, or else pathological conditions will develop and, if not corrected, lead to uncontrolled proliferation or cell death. This project studies the mechanisms by which cells transmit signals. Proteins accomplish this communication by modifying the inter ....Studies of the Dynamic Language of Bio-Molecular Communication and Signalling. For normal biological function, a multitude of external signals must be interpreted and responded to by cells. The responses must be carefully regulated and coordinated, or else pathological conditions will develop and, if not corrected, lead to uncontrolled proliferation or cell death. This project studies the mechanisms by which cells transmit signals. Proteins accomplish this communication by modifying the interactions among their functional domains, effectively creating a conformational language. Knowledge of this language will impact biomedicine through its contributions to understanding the molecular pathology of diseased states, and biotechnology by enhancing our ability to use biological processes for applications.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0346892
Funder
Australian Research Council
Funding Amount
$689,000.00
Summary
Protein Over-Expression/Purification and Macromolecular Structure Determination by X-Ray Diffraction. This proposal seeks funds for state-of-the-art facilities for protein over-expression and macromolecular X-ray diffraction. This will build upon recent initiatives within the collaborating institutions in the field of Structural Biology. It will enable research groups in Perth to pursue the large-scale production of important proteins and to conduct high-resolution structural studies using X-ray ....Protein Over-Expression/Purification and Macromolecular Structure Determination by X-Ray Diffraction. This proposal seeks funds for state-of-the-art facilities for protein over-expression and macromolecular X-ray diffraction. This will build upon recent initiatives within the collaborating institutions in the field of Structural Biology. It will enable research groups in Perth to pursue the large-scale production of important proteins and to conduct high-resolution structural studies using X-ray crystallographic techniques. This technology, which is one of the most important tools in modern biology, provides unique insights into the chemical mechanisms of biological macromolecules and will significantly enhance a great breadth of biological research in Western Australia.Read moreRead less
Structure and dynamics of a multiprotein-mRNA complex involved in the regulation of gene expression. RNA/protein interactions are now recognised as a major control point in the regulation of gene-expression. Proteins such as HuR and the poly(C)-binding proteins (PCBPs) act to stabilise and transport specific messenger (m)RNAs, and thus determine their translation levels. In contrast to such an important function, very little is known about these protein/mRNA interactions at an atomic level. The ....Structure and dynamics of a multiprotein-mRNA complex involved in the regulation of gene expression. RNA/protein interactions are now recognised as a major control point in the regulation of gene-expression. Proteins such as HuR and the poly(C)-binding proteins (PCBPs) act to stabilise and transport specific messenger (m)RNAs, and thus determine their translation levels. In contrast to such an important function, very little is known about these protein/mRNA interactions at an atomic level. The current study will investigate the structural and biophysical properties of a recently discovered HuR/PCBP/mRNA complex implicated in the regulation of androgen receptor expression. This information has the potential to assist in the development of drugs to reduce AR expression in prostate cancer.Read moreRead less