Small heat-shock molecular chaperone proteins and amyloid fibrils. This proposal addresses the fundamental mechanisms of protein aggregation associated with debilitating age-related diseases, e.g. Alzheimer's, Parkinson's and cataract, and the prevention of aggregation via the action of a group of molecular chaperone proteins known as small heat-shock proteins. With the ageing population, the prevalence of these diseases will increase significantly over the next 20 years. Understanding and treat ....Small heat-shock molecular chaperone proteins and amyloid fibrils. This proposal addresses the fundamental mechanisms of protein aggregation associated with debilitating age-related diseases, e.g. Alzheimer's, Parkinson's and cataract, and the prevention of aggregation via the action of a group of molecular chaperone proteins known as small heat-shock proteins. With the ageing population, the prevalence of these diseases will increase significantly over the next 20 years. Understanding and treating these diseases will therefore have significant long-term health benefits. Furthermore, the highly structured protein aggregates that form as hallmarks of many of these diseases have potential wide ranging applications in the emerging field of bionanotechnology, e.g. as nanowires and biofilms.Read moreRead less
The bHLH.PAS transcription factors: Determinants of dimerization specificity and high affinity DNA binding. This program of fundamental research will advance our knowledge of the way essential proteins act to correctly regulate critical biological processes. A detailed understanding of these processes at the molecular level has the potential to contribute to the design of pharmaceutical compounds to assist in the treatment of diseases such as ischaemia, myocardial infarction and tumour progress ....The bHLH.PAS transcription factors: Determinants of dimerization specificity and high affinity DNA binding. This program of fundamental research will advance our knowledge of the way essential proteins act to correctly regulate critical biological processes. A detailed understanding of these processes at the molecular level has the potential to contribute to the design of pharmaceutical compounds to assist in the treatment of diseases such as ischaemia, myocardial infarction and tumour progression. The work will contribute to the training of one or more graduate students in a technologically advancing and internationally competitive field.Read moreRead less
Investigation of the fundamental roles of class Ib MHC (major histocompatibility complex) molecules in immunity. The proposed research program, using laboratory-based and synchrotron-based radiation, will provide insight into the roles of a poorly understood class of immune molecules. This will improve our understanding of the regulation of immunity, and the knowledge gained will increase Australia's international research profile.
Structural studies of the interactions of actinin-4 and intracellular signalling proteins. The intracellular signalling cascade plays important roles in cellular processes such as growth and differentiation by exerting changes in gene expression or remodelling of the intracellular protein framework. The actin-based cytoskeleton is one such network of proteins responsible for a number of processes including cell division, migration and adhesion to other cells and tissues. This proposal aims to un ....Structural studies of the interactions of actinin-4 and intracellular signalling proteins. The intracellular signalling cascade plays important roles in cellular processes such as growth and differentiation by exerting changes in gene expression or remodelling of the intracellular protein framework. The actin-based cytoskeleton is one such network of proteins responsible for a number of processes including cell division, migration and adhesion to other cells and tissues. This proposal aims to understand how actinin-4, a component of the actin cytoskeleton in non-muscle tissues, interacts with and is stimulated by proteins of the intracellular signalling cascade.Read moreRead less
Rejuvenating adult stem cells. This project aims to uncover intimate links between metabolic regulation and longevity in adult stem cells, the source of all cells in the body. Understanding why we age and whether ageing is preventable are research challenges which must be first attacked at a cellular level. This project will try to rejuvenate aged stem cells by interfering with a prospective molecular master switch of aging and also develop an approach to identify and select youthful stem cells. ....Rejuvenating adult stem cells. This project aims to uncover intimate links between metabolic regulation and longevity in adult stem cells, the source of all cells in the body. Understanding why we age and whether ageing is preventable are research challenges which must be first attacked at a cellular level. This project will try to rejuvenate aged stem cells by interfering with a prospective molecular master switch of aging and also develop an approach to identify and select youthful stem cells. The results are expected to be important beyond informing the science of ageing, in the areas of tissue engineering, wound healing, embryology and cancer.Read moreRead less
The basis of recognition and disposal of dysfunctional proteins by clusterin. When proteins become damaged they can precipitate. A blood protein called clusterin prevents precipitation of damaged proteins. Clusterin does this by forming complexes with the damaged proteins. Clusterin is the first blood protein known to do this. We will discover which parts of clusterin are responsible for this activity. We will also discover whether cells can take up and dispose of the complexes of clusterin and ....The basis of recognition and disposal of dysfunctional proteins by clusterin. When proteins become damaged they can precipitate. A blood protein called clusterin prevents precipitation of damaged proteins. Clusterin does this by forming complexes with the damaged proteins. Clusterin is the first blood protein known to do this. We will discover which parts of clusterin are responsible for this activity. We will also discover whether cells can take up and dispose of the complexes of clusterin and damaged proteins. This work is important because some diseases (eg, Alzheimers disease) involve the toxic effects of abnormal protein precipitation. Understanding how clusterin works may help in developing better treatments for these diseases.Read moreRead less
Innovative Approaches for Defining the Interaction of Insulin like Growth Factor I (IGF I) with the Type 1 IGF Receptor. This study will improve our understanding of the interactions of Insulin-like Growth Factors (IGFs) with their principal receptor, the IGF-1R. A sound understanding of these interactions is essential for the development of non-peptide IGF antagonists designed for therapeutic applications. Such molecules could lead to new therapeutic approaches for diseases in which dysregul ....Innovative Approaches for Defining the Interaction of Insulin like Growth Factor I (IGF I) with the Type 1 IGF Receptor. This study will improve our understanding of the interactions of Insulin-like Growth Factors (IGFs) with their principal receptor, the IGF-1R. A sound understanding of these interactions is essential for the development of non-peptide IGF antagonists designed for therapeutic applications. Such molecules could lead to new therapeutic approaches for diseases in which dysregulation of the IGF system has been implicated including cancer, diabetes and atherosclerosis.
Since IGFs are major determinants of growth, the outcomes of this project could also lead to improvements in animal production with major benefit to primary industry. New IGF analogues developed could assist biotechnology exports.
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The rational design and construction of new genetic circuits for applications in synthetic biology. By designing, building and testing new gene control modules, this project will gain an understanding of the design principles required for the construction of biological circuits with predictable and controllable behaviour. The ability to build such circuits will have significant economic benefit in areas such as metabolic engineering and biomedicine.
Aquaporins in roots: resolving observations linking them to diverse processes in water relations and plant productivity. The knowledge we gain will benefit Australia by allowing better management of plant water use and productivity. This is critical for adaptation to a drier climate where water is a critical resource. Large quantities of water move through aquaporin proteins in plants, therefore our understanding of these and the way they influence other processes in plant growth could enable us ....Aquaporins in roots: resolving observations linking them to diverse processes in water relations and plant productivity. The knowledge we gain will benefit Australia by allowing better management of plant water use and productivity. This is critical for adaptation to a drier climate where water is a critical resource. Large quantities of water move through aquaporin proteins in plants, therefore our understanding of these and the way they influence other processes in plant growth could enable us to manipulate plants to conserve water or to extract it more efficiently from the soil. Molecular aspects of the project could reveal new unexploited links between water and plant productivity. High calibre PhD and Honours students will also be educated to maintain the momentum of international excellence within Australia in the field of plant water relations.Read moreRead less
Use of mitochondrial electron transport chain mutants to evaluate how non-phosphorylating respiration influences plant metabolite profiles and stress tolerance. This project uses transgenic plant technology to elucidate how mitochondrial function impacts on the profile of metabolites in plant cell and tissues and whether altering these profiles influences a plant's ability tog row in harsh conditions. It will contribute to our fundamental knowledge of plant metabolism using a metabolomic anaylsi ....Use of mitochondrial electron transport chain mutants to evaluate how non-phosphorylating respiration influences plant metabolite profiles and stress tolerance. This project uses transgenic plant technology to elucidate how mitochondrial function impacts on the profile of metabolites in plant cell and tissues and whether altering these profiles influences a plant's ability tog row in harsh conditions. It will contribute to our fundamental knowledge of plant metabolism using a metabolomic anaylsis of plant stress response. This will be achieved using new high-throughput technologies, allowing reliable qualitative and quantitative analysis of large numbers of samples. This approach will compliment existing genomic and proteomic analyses of plants exposed to abiotic stress.Read moreRead less