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
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 Interactions of Chemical Agents with Ion-Channel Proteins. With a minimal number of functional units (proteins) viruses are able to replicate. All of these proteins are possible antiviral targets. In this project we wil1 focus on a short protein called Vpu found in membranes of the HIV-1 virus and aim to analyse the interaction of potential pore blocking compounds. It is essential to know exactly where they sit and how the overall structure of Vpu is affected. For this enterprise we wi ....Molecular Interactions of Chemical Agents with Ion-Channel Proteins. With a minimal number of functional units (proteins) viruses are able to replicate. All of these proteins are possible antiviral targets. In this project we wil1 focus on a short protein called Vpu found in membranes of the HIV-1 virus and aim to analyse the interaction of potential pore blocking compounds. It is essential to know exactly where they sit and how the overall structure of Vpu is affected. For this enterprise we will use nuclear magnetic resonance (NMR) spectroscopy. This information will serve as a springboard for future investigations of virus membrane proteins.
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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
Manipulating the self-assembly properties of fungal hydrophobin proteins for the design of novel biological polymers. Hydrophobin-based products will be novel biocompatible and biodegradable products with applications in the fields of medical implants, biosensors, detergents, coatings and pharmaceutical and industrial emulsions. They have the potential to directly improve the lives of all Australians and to be of benefit to the Australian economy and environment. This collaborative research pro ....Manipulating the self-assembly properties of fungal hydrophobin proteins for the design of novel biological polymers. Hydrophobin-based products will be novel biocompatible and biodegradable products with applications in the fields of medical implants, biosensors, detergents, coatings and pharmaceutical and industrial emulsions. They have the potential to directly improve the lives of all Australians and to be of benefit to the Australian economy and environment. This collaborative research project will enable Australian scientists to gain from working with a multinational company and to acquire skills in the rapidly expanding fields of structural and molecular biology. The University of Sydney will own any intellectual property arising from this work and will benefit from the commercialisation of hydrophobin-based products.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