Movement of mitochondria between cells. This project aims to characterise how mitochondria move between cells into grafted cells with dysfunctional mitochondrial function. How mitochondria reach the acceptor cell and how they move from the donor cell is not known. The project will use a 'bottom-up' approach, starting from a reconstituted system, via in vitro, co-culture stage to a relevant biological model, increasing complexity and biological relevance. It will document that the process of mito ....Movement of mitochondria between cells. This project aims to characterise how mitochondria move between cells into grafted cells with dysfunctional mitochondrial function. How mitochondria reach the acceptor cell and how they move from the donor cell is not known. The project will use a 'bottom-up' approach, starting from a reconstituted system, via in vitro, co-culture stage to a relevant biological model, increasing complexity and biological relevance. It will document that the process of mitochondrial intercellular movement is dependent on intercellular bridges and a specific mobility system. The project is of high relevance for cell biology.Read moreRead less
Mixing the jigsaw pieces of natural products: new molecules-new properties. This project aims to examine the capacity of exploiting the bacterial biosynthetic machinery to fast-track access to analogues of natural products. Due to increased drug resistance, new reservoirs of natural products are needed for evaluation as future drugs. Desferrioxamine B will be used as a model natural product to establish the biosynthesis of new analogues in bacterial culture supplemented with unsaturated, fluorin ....Mixing the jigsaw pieces of natural products: new molecules-new properties. This project aims to examine the capacity of exploiting the bacterial biosynthetic machinery to fast-track access to analogues of natural products. Due to increased drug resistance, new reservoirs of natural products are needed for evaluation as future drugs. Desferrioxamine B will be used as a model natural product to establish the biosynthesis of new analogues in bacterial culture supplemented with unsaturated, fluorinated or deuterated building blocks. The intended outcomes are to deliver advances in methods for generating structurally diverse pools of natural products, new label-free probes, knowledge of natural product biosynthesis, and excellence in training research students in frontier methods in chemical biology and drug discovery.Read moreRead less
New antibiotics: engaging microbial chemical diversity. This project will explore Australian microbial biodiversity, to detect, isolate and identify new natural chemicals with potent and selective antibacterial properties. Knowledge of these molecules will inspire and inform the development of new classes of antibiotic, effective against multi-drug resistant infections.
Developing a multicomponent platform for targeted gene delivery. Gene delivery systems are important tools in biological research and offer many exciting future prospects. Delivering gene material is very difficult in practice: rapid deterioration, poor cell uptake, and reaching the right tissue and cell types are major obstacles. Ways to overcome each barrier individually have been suggested in existing research but these components have not yet been combined in a single solution, which this pr ....Developing a multicomponent platform for targeted gene delivery. Gene delivery systems are important tools in biological research and offer many exciting future prospects. Delivering gene material is very difficult in practice: rapid deterioration, poor cell uptake, and reaching the right tissue and cell types are major obstacles. Ways to overcome each barrier individually have been suggested in existing research but these components have not yet been combined in a single solution, which this project will tackle. This proposal aims to create a technology to stabilise and deliver active gene material to target cells. The gene delivery tool developed in this project will advance biological research greatly with many potential future applications.Read moreRead less
Chemical probes to dissect the cell cycle of globally important parasites . This project aims to develop new reagents, called chemical probes, to visualise key biological events in globally important pathogens. We will use innovative chemistry to modify the building blocks of DNA and provide researchers with essential tools to 'see' DNA synthesis in order to study growth and replication of pathogens in combination with microscopy. This project expects to support a major technical advance that wi ....Chemical probes to dissect the cell cycle of globally important parasites . This project aims to develop new reagents, called chemical probes, to visualise key biological events in globally important pathogens. We will use innovative chemistry to modify the building blocks of DNA and provide researchers with essential tools to 'see' DNA synthesis in order to study growth and replication of pathogens in combination with microscopy. This project expects to support a major technical advance that will address important gaps in our understanding of many pathogens (e.g. those that cause malaria and tuberculosis), at both the cellular and molecular levels. This should provide significant benefits by enabling researchers worldwide to identify new intervention opportunities that target unique aspects of pathogen biology.Read moreRead less
Venom-derived blood-brain-barrier shuttles. This project aims to discover new venom peptides capable of crossing the blood-brain barrier and to develop non-toxic peptide-based brain delivery systems. It addresses long-standing challenges and knowledge gaps in the delivery of macromolecules across biological barriers. Expected outcomes include an improved understanding of the strategies nature exploits to reach targets in the brain, mechanistic pathways to cross biological membranes, and innovati ....Venom-derived blood-brain-barrier shuttles. This project aims to discover new venom peptides capable of crossing the blood-brain barrier and to develop non-toxic peptide-based brain delivery systems. It addresses long-standing challenges and knowledge gaps in the delivery of macromolecules across biological barriers. Expected outcomes include an improved understanding of the strategies nature exploits to reach targets in the brain, mechanistic pathways to cross biological membranes, and innovative discovery and chemistry strategies to advance fundamental research across the chemical and biological sciences. Anticipated benefits include technological innovations relevant to Australia’s biotechnology sector and enhanced capacity for cross-disciplinary collaboration.Read moreRead less
Liposaccharide based peptide and vaccine delivery systems: improving the bioavailability and immunogenicity of Luteinizing Hormone-Releasing Hormone. This project aims to develop new lipid- and sugar-based drug delivery systems for Luteinizing-hormone-releasing hormone (LHRH), a hormone which regulates the level of enzymes involved in fertility conditions and prostate cancers. This technology could be extended to significantly increase the number of drugs available on the market, such as peptide ....Liposaccharide based peptide and vaccine delivery systems: improving the bioavailability and immunogenicity of Luteinizing Hormone-Releasing Hormone. This project aims to develop new lipid- and sugar-based drug delivery systems for Luteinizing-hormone-releasing hormone (LHRH), a hormone which regulates the level of enzymes involved in fertility conditions and prostate cancers. This technology could be extended to significantly increase the number of drugs available on the market, such as peptide drugs and vaccines.Read moreRead less
Expanding access to modified proteins via a novel semi-synthetic platform. This project aims to address a critical knowledge gap in understanding how post-translational modifications modulate the structure and activity of proteins. By developing an innovative semi-synthetic platform to produce pure proteins inaccessible by existing methods, the project will reveal how natural protein modifications influence structure and function. Expected outcomes include the delivery of breakthrough technologi ....Expanding access to modified proteins via a novel semi-synthetic platform. This project aims to address a critical knowledge gap in understanding how post-translational modifications modulate the structure and activity of proteins. By developing an innovative semi-synthetic platform to produce pure proteins inaccessible by existing methods, the project will reveal how natural protein modifications influence structure and function. Expected outcomes include the delivery of breakthrough technologies for accessing modified proteins for a range of applications in academia and industry, as well as the generation of new knowledge in the fields of chemistry and biology. The project will lead to the training of interdisciplinary early career researchers and has the potential to benefit Australia’s biotechnology sector.Read moreRead less
Towards an influenza virus glycan interaction map (Glycointeractome). This project will use nuclear magnetic resonance (NMR) spectroscopy to map carbohydrate interaction used by the virus to cause infection and spread. This information will provide new direction in anti-influenza drug discovery.
Escaping Bio-Assay Guided Isolation: Nature's Tools for Chemical Biology. The project aims to transform the approach to identify novel biologically active compounds that occur in nature. For decades, natural product chemistry has centred on bio-assay guided isolation, but it has become increasingly difficult to isolate novel compounds. While de-replication strategies detect the presence of known compounds using databases, more impact would be achieved by directly detecting novel compounds. Nucle ....Escaping Bio-Assay Guided Isolation: Nature's Tools for Chemical Biology. The project aims to transform the approach to identify novel biologically active compounds that occur in nature. For decades, natural product chemistry has centred on bio-assay guided isolation, but it has become increasingly difficult to isolate novel compounds. While de-replication strategies detect the presence of known compounds using databases, more impact would be achieved by directly detecting novel compounds. Nuclear magnetic resonance (NMR) spectroscopy detects every molecule that has a proton and is quantitative. This project plans to develop a NMR technique to escape bio-assay guided isolation by analysing a fraction library. Biotechnology innovation is dependent on novel compounds to provide new products. Replacing ‘grind and find’ with a technique that never lies would be transformational.Read moreRead less