From structures to systems: A hierachical approach to understanding sub-cellular components. This program will dramatically extend the range of biomolecular systems that can be modelled with near atomistic precision. It will provide a better understanding of the structure and function of proteins involved in the regulation of membrane fusion and fission as well as shedding light on the assembly of large-scale protein-protein and protein-membrane complexes in general. The work will help place Au ....From structures to systems: A hierachical approach to understanding sub-cellular components. This program will dramatically extend the range of biomolecular systems that can be modelled with near atomistic precision. It will provide a better understanding of the structure and function of proteins involved in the regulation of membrane fusion and fission as well as shedding light on the assembly of large-scale protein-protein and protein-membrane complexes in general. The work will help place Australia at the forefront of developing simulation techniques in biomolecular systems, which are widely used within the chemical and pharmaceutical industries for modelling processes ranging from protein-drug interactions to the phase behaviour of lipids and surfactants. Read moreRead less
Self organization in (bio)molecular systems: Simulating the folding and aggregation of peptides, proteins and lipids. Molecular self-assembly is a basic property of living systems. Most proteins fold spontaneously and then further self-organize into functional complexes, effectively biological machines. Understanding how this occurs is a fundamental theoretical challenge with widespread application. Work will focus on developing methodology to simulate, computationally, the folding and aggrega ....Self organization in (bio)molecular systems: Simulating the folding and aggregation of peptides, proteins and lipids. Molecular self-assembly is a basic property of living systems. Most proteins fold spontaneously and then further self-organize into functional complexes, effectively biological machines. Understanding how this occurs is a fundamental theoretical challenge with widespread application. Work will focus on developing methodology to simulate, computationally, the folding and aggregation of peptides, proteins, and lipids. The aim is to accurately predict the structures of small peptides in solution and to refine crude models of larger molecules (complexes). This will facilitate the development of peptide based therapeutics and is essential in exploiting the growing volume of genetic information in biology and medicine.Read moreRead less
Dynamic modelling of biomolecular systems: Going beyond classical empirical force fields. The ability to accurately model the structural and functional aspects of biomolecular systems at an atomic level is of fundamental importance in the pharmaceutical and biotechnological industries. By developing new approaches for treating dispersion terms and transition metals we aim to improve our understanding of critical biomolecular systems such as how novel anti-cancer metal complexes interact with DNA ....Dynamic modelling of biomolecular systems: Going beyond classical empirical force fields. The ability to accurately model the structural and functional aspects of biomolecular systems at an atomic level is of fundamental importance in the pharmaceutical and biotechnological industries. By developing new approaches for treating dispersion terms and transition metals we aim to improve our understanding of critical biomolecular systems such as how novel anti-cancer metal complexes interact with DNA and block transcription and the role various transition metals such as Cu(II) and Zn(II) stabilize the conformations of peptides involved in Alzheimer's disease. In addition by greatly expanding the range of systems that can be modeled efficiently the work will have widespread benefits in academic research as well as for industry.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560657
Funder
Australian Research Council
Funding Amount
$740,000.00
Summary
Ultra-High Resolution NMR Imaging System for Nanotechnology including Nanobiotechnology. The ultra-high resolution imaging NMR spectrometer at the centre of this application is a generation ahead of comparable facilities in Australia and will extend the research capacity of numerous research groups comprising in excess of 50 academics and postgraduate students. The aims and significance of this infrastructure lie in it being one of the centrepieces of the partner institutions' aspirations to tak ....Ultra-High Resolution NMR Imaging System for Nanotechnology including Nanobiotechnology. The ultra-high resolution imaging NMR spectrometer at the centre of this application is a generation ahead of comparable facilities in Australia and will extend the research capacity of numerous research groups comprising in excess of 50 academics and postgraduate students. The aims and significance of this infrastructure lie in it being one of the centrepieces of the partner institutions' aspirations to take Australia to the cutting edge of nanotechnology and cognate disciplines many of which are areas of national priority. The expected manifold outcomes include research of the highest rank into fundamental problems of drug development through to applied outcomes such as new nanomaterials and improved horticulture/fruit preservation.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0344441
Funder
Australian Research Council
Funding Amount
$390,000.00
Summary
New Generation Metalloenzyme Magnetic Circular Dichroism Spectrometer Systems. Funding is sought to enhance the existing collaborations between UQ, ANU, Sydney and other universities in the study of metal-centred molecules of biological interest through the construction of advanced magnetic circular dichroism (MCD) spectrometers. These facilities will be the best instruments of their kind, and will enable researchers at Australian institutions to enhance the quality of their research and remain ....New Generation Metalloenzyme Magnetic Circular Dichroism Spectrometer Systems. Funding is sought to enhance the existing collaborations between UQ, ANU, Sydney and other universities in the study of metal-centred molecules of biological interest through the construction of advanced magnetic circular dichroism (MCD) spectrometers. These facilities will be the best instruments of their kind, and will enable researchers at Australian institutions to enhance the quality of their research and remain internationally competitive through the application of modern MCD spectroscopic techniques to the study of metal-centred biomolecules. These facilities will drive a number of programs in the area of metalloenzyme and photosystem II research.Read moreRead less
High throughput engineering of genetically encodable fluorescent sensors of intracellular signalling networks. Understanding of biochemical processes in living organisms is central to biological research and drug discovery. At present, the field suffers from a chronic paucity of adequate observation methods. The proposed project represents an interdisciplinary effort to create approaches for real-time monitoring of complex cellular chemistries. This work will deliver novel technologies for use i ....High throughput engineering of genetically encodable fluorescent sensors of intracellular signalling networks. Understanding of biochemical processes in living organisms is central to biological research and drug discovery. At present, the field suffers from a chronic paucity of adequate observation methods. The proposed project represents an interdisciplinary effort to create approaches for real-time monitoring of complex cellular chemistries. This work will deliver novel technologies for use in diagnostics and drug development. It will provide vital information on the changes in cellular processes induced by malignant transformation, viral infection and aging. This work will generate both health and economic benefits for the community and have a positive impact on the international visibility of Australian biomedical research.Read moreRead less
Quantum coherence of electronic transport in layered magnetoresistive materials. The continued rapid expansion of information technology requires new materials and devices for information storage. State of the art computer memories are based on new materials which consist of layers of complex arrays of atoms. These materials have metallic properties quite unlike those of simple metals such as copper and steel. This research will lead to a greater understanding of and ability to design better ma ....Quantum coherence of electronic transport in layered magnetoresistive materials. The continued rapid expansion of information technology requires new materials and devices for information storage. State of the art computer memories are based on new materials which consist of layers of complex arrays of atoms. These materials have metallic properties quite unlike those of simple metals such as copper and steel. This research will lead to a greater understanding of and ability to design better materials. Australia's capacity for research and development in this scientifically challenging and technologically important field will be enhanced by this project. Read moreRead less
Biomolecular optoelectronic materials and devices. The melanins are the molecules in our skin, eyes and hair that provide colour and protection from the sun. In addition to being important bio-molecules, they have properties which make them useful for high tech applications especially in electronics and optoelectronics. Unfortunately, our current understanding of these fascinating materials is poor. In our project we aim to solve this limiting problem. We will develop new science to explain thei ....Biomolecular optoelectronic materials and devices. The melanins are the molecules in our skin, eyes and hair that provide colour and protection from the sun. In addition to being important bio-molecules, they have properties which make them useful for high tech applications especially in electronics and optoelectronics. Unfortunately, our current understanding of these fascinating materials is poor. In our project we aim to solve this limiting problem. We will develop new science to explain their behaviour, and use this knowledge to create bio-compatible hi-tech materials and devices. We anticipate significant benefits from the perspectives of basic science and utilisation of biomaterials for new green technologies.Read moreRead less
Increasing the Efficiency of Biomolecular Simulations. This program will extend the range of biomolecular systems that can be modelled with near atomistic precision. It will provide a better understanding of the structure and function of proteins involved in the regulation of membrane fusion and fission as well as shedding light on the assembly of large-scale protein-protein and protein-membrane complexes in general. The work will help place Australia at the forefront of developing simulation t ....Increasing the Efficiency of Biomolecular Simulations. This program will extend the range of biomolecular systems that can be modelled with near atomistic precision. It will provide a better understanding of the structure and function of proteins involved in the regulation of membrane fusion and fission as well as shedding light on the assembly of large-scale protein-protein and protein-membrane complexes in general. The work will help place Australia at the forefront of developing simulation techniques in biomolecular systems, which are widely used within the chemical and pharmaceutical industries. It will also provide opportunities for the training and development of young Australian researchers with top European laboratories. Read moreRead less