Improving grain legume seeds for future climates. Grain legumes are essential for sustainable agriculture and human dietary protein, but seed quality is predicted to decline under future scenarios of high CO2 and warmer temperatures. This project aims to improve legume seed quality under future climates by comparing metabolites and physiological traits of chickpea and other legumes to establish mechanisms by which legumes maximise seed nutrient allocation. The anticipated outcomes include new me ....Improving grain legume seeds for future climates. Grain legumes are essential for sustainable agriculture and human dietary protein, but seed quality is predicted to decline under future scenarios of high CO2 and warmer temperatures. This project aims to improve legume seed quality under future climates by comparing metabolites and physiological traits of chickpea and other legumes to establish mechanisms by which legumes maximise seed nutrient allocation. The anticipated outcomes include new metabolite-based breeding markers for the improvement of crops with higher seed proteins, micronutrients and bioactive compounds that are adapted to future climates. Seed nutrient improvement will also include increased biological nitrogen fixation to reduce the need for chemical nitrogen fertilisers.Read moreRead less
Regulation of proteolysis by specialised adaptor proteins. Training research scientists of the future forms an integral part of this research program and this collaboration will provide an excellent opportunity for young Australian scientists to be exposed to the very professional and competitive environment of basic research, as it exists in Germany. It will expose early career researchers to new ideas and emerging methodologies arming them with valuable skills, which they will transfer to Aust ....Regulation of proteolysis by specialised adaptor proteins. Training research scientists of the future forms an integral part of this research program and this collaboration will provide an excellent opportunity for young Australian scientists to be exposed to the very professional and competitive environment of basic research, as it exists in Germany. It will expose early career researchers to new ideas and emerging methodologies arming them with valuable skills, which they will transfer to Australia. The involvement of Prof. Turgay in the Deutsche Forschungsgemeinschaft (DFG) Priority Programme: Proteolysis in Prokaryotes also provides a unique opportunity for these young researchers to interact with several of the worlds leading scientists in the area of proteolysis, enhancing Australia's reputation at the forefront of science.Read moreRead less
Differential Expression Proteomics: Identification and Quantitation of Peptides and Proteins by Fixed Charge Derivatization and Tandem Mass Spectrometry. The aim of this proposal is to develop novel strategies for the rapid, sensitive and selective identification and quantitation of proteins present in complex mixtures. Specifically, isotopically labeled fixed charge derivatives of peptides containing selected amino acids will be developed that direct the formation of product ions following tan ....Differential Expression Proteomics: Identification and Quantitation of Peptides and Proteins by Fixed Charge Derivatization and Tandem Mass Spectrometry. The aim of this proposal is to develop novel strategies for the rapid, sensitive and selective identification and quantitation of proteins present in complex mixtures. Specifically, isotopically labeled fixed charge derivatives of peptides containing selected amino acids will be developed that direct the formation of product ions following tandem mass spectrometry toward a single fragmentation channel. This approach will provide enhanced selectivity and sensitivity of up to 2 orders of magnitude over existing approaches, and will allow examination, at the protein level, of the complex cellular changes that occur following transformation of cells from a normal to a diseased state.Read moreRead less
Unravelling transthyretin amyloid, bounding ahead using wallabies. Each protein in our body has a unique shape that enables it to function correctly. For unknown reasons, some proteins can change their shape, aggregate with other proteins and stick to the outside of cells of major organs or nerves. This prevents those cells from working properly and results in disease. Transthyretin is a protein that changes shape and aggregates in the heart of most people over the age of 70. The disease is call ....Unravelling transthyretin amyloid, bounding ahead using wallabies. Each protein in our body has a unique shape that enables it to function correctly. For unknown reasons, some proteins can change their shape, aggregate with other proteins and stick to the outside of cells of major organs or nerves. This prevents those cells from working properly and results in disease. Transthyretin is a protein that changes shape and aggregates in the heart of most people over the age of 70. The disease is called Senile Systemic Amyloidosis (SSA). It is not known how or why this happens. There is no cure or therapy. This project will use transthyretins from human and wallaby to explore a possible cause of SSA. If our hypothesis is correct, we will propose preventative actions to reduce the incidence of SSA in the future.Read moreRead less
Function and modulation of the protein quality control network in mammalian mitochondria. This project has potential technological benefit in the areas of biotechnology and molecular medicine especially in relation to age-related cellular degeneration. As a result of our research outputs, strategies could be developed to either delay the onset or reduce the severity of diseases related to mitochondrial dysfunction. Training research scientists of the future, forms an integral part of our researc ....Function and modulation of the protein quality control network in mammalian mitochondria. This project has potential technological benefit in the areas of biotechnology and molecular medicine especially in relation to age-related cellular degeneration. As a result of our research outputs, strategies could be developed to either delay the onset or reduce the severity of diseases related to mitochondrial dysfunction. Training research scientists of the future, forms an integral part of our research program and our association with world leaders in the field provide excellent opportunity for exchange of personnel, ideas and emerging methodologies. This project will lead the way in this field and consequently will expand Australia's reputation at the forefront of scientific advancement. Read moreRead less
AAA+ proteases: substrate binding, translocation and modulation by novel adaptor proteins. Protein quality control is essential for the proper maintenance of the cell. It ensures the correct folding of newly synthesised proteins, the refolding or degradation of misfolded and aggregated proteins, and the controlled degradation of regulatory proteins. These functions are collectively performed by molecular chaperones and proteases. This project will define the molecular basis of substrate selectiv ....AAA+ proteases: substrate binding, translocation and modulation by novel adaptor proteins. Protein quality control is essential for the proper maintenance of the cell. It ensures the correct folding of newly synthesised proteins, the refolding or degradation of misfolded and aggregated proteins, and the controlled degradation of regulatory proteins. These functions are collectively performed by molecular chaperones and proteases. This project will define the molecular basis of substrate selectivity for ATP-dependent proteases and determine the relationship between chaperones and proteases. A major focus will be directed towards the mechanistic analysis of novel AAA+ cofactors such as ClpS, which we recently discovered. A detailed analysis of such proteins is central to understanding how chaperones and protease (a) recognize their substrates and (b) compete for different substrates in vivo.Read moreRead less
Molecular basis of antimicrobial and insecticidal activity of floral defensins from the Solonaceae. The flowers of Solanaceous plants produce high levels of defensins that protect the reproductive tissues against potential damage from microorganisms. The presence of related defensins in mammals, insects and plants indicates that they are part of an ancient defence mechanism. The floral defensins are potent antifungal molecules and surprisingly also have insecticidal activity. The aim of this pro ....Molecular basis of antimicrobial and insecticidal activity of floral defensins from the Solonaceae. The flowers of Solanaceous plants produce high levels of defensins that protect the reproductive tissues against potential damage from microorganisms. The presence of related defensins in mammals, insects and plants indicates that they are part of an ancient defence mechanism. The floral defensins are potent antifungal molecules and surprisingly also have insecticidal activity. The aim of this project is to understand the molecular basis of the antifungal and insecticide activity and to use this knowledge to produce improved molecules for crop protection.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0882913
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
Mass spectrometry facility for the quantitation and analysis of post-translationally modified peptides. This proposal will address a gap in our mass spectrometry capabilities and aid in our understanding of the cellular immune response and investigate the chemical diversity of the targets of immunity. This proposal has broad implications in the basic immunology of antigen presentation, in biomarker discovery as well as in the design of new vaccines in infectious disease and cancer and the develo ....Mass spectrometry facility for the quantitation and analysis of post-translationally modified peptides. This proposal will address a gap in our mass spectrometry capabilities and aid in our understanding of the cellular immune response and investigate the chemical diversity of the targets of immunity. This proposal has broad implications in the basic immunology of antigen presentation, in biomarker discovery as well as in the design of new vaccines in infectious disease and cancer and the development of therapies for autoimmune diseases. In addition to these key scientific outcomes this project will also facilitate the training of several new personnel in a skill area for which there is a critical shortage (mass spectrometry) and promote cross-disciplinary skills (immunology, biochemistry, proteomics).Read moreRead less
Reducing the fat burden: Identification of novel cellular and molecular targets for alleviating skeletal muscle insulin resistance. Insulin resistance and the associated consequences are a major public health problem in Australia and cost the healthcare system >$1.1 billion/year. Exercise training and thiaziolidinedione (TZD) treatment are therapies that partially ameliorate insulin resistance through distinct and independent mechanisms. However, neither intervention represents a viable long-ter ....Reducing the fat burden: Identification of novel cellular and molecular targets for alleviating skeletal muscle insulin resistance. Insulin resistance and the associated consequences are a major public health problem in Australia and cost the healthcare system >$1.1 billion/year. Exercise training and thiaziolidinedione (TZD) treatment are therapies that partially ameliorate insulin resistance through distinct and independent mechanisms. However, neither intervention represents a viable long-term strategy: exercise training has low compliance, while chronic TZD use is associated with several adverse side effects (edema, weight gain etc.). We will investigate the metabolic, cellular and molecular mechanisms by which these therapies each exert their positive effect on insulin action with the aim of identifying novel targets for future drug interventions. Read moreRead less
Searching for novel protein domains: A bioinformatic analysis of whole proteomes. The functional annotation of the set of proteins encoded by a whole genome (the "proteome") is a crucial component of genome research. The aim of this project is to extend the functional and structural annotation of large protein databases by identifying novel protein domain families and building a novel domain library. Our approach is semi-automated and fast, thanks to execution in the fastest parallel supercom ....Searching for novel protein domains: A bioinformatic analysis of whole proteomes. The functional annotation of the set of proteins encoded by a whole genome (the "proteome") is a crucial component of genome research. The aim of this project is to extend the functional and structural annotation of large protein databases by identifying novel protein domain families and building a novel domain library. Our approach is semi-automated and fast, thanks to execution in the fastest parallel supercomputer in Australia available at the Victorian Partnership for Advanced Computing. Our preliminary data demonstrates that our method is feasible.Read moreRead less