Electron transport catalysis in organohalide pollutant respiration. This project aims to understand the link between substrate specificity and gene sequence of dehalogenating enzymes in organohalide respiring bacteria (ORB) and the mechanism by which electrons are transferred to dehalogenating enzymes through protein-protein interactions. Organohalides were present in Earth's early history and now pollute the environment globally. Organohalide respiring bacteria (ORB) can degrade these pollutant ....Electron transport catalysis in organohalide pollutant respiration. This project aims to understand the link between substrate specificity and gene sequence of dehalogenating enzymes in organohalide respiring bacteria (ORB) and the mechanism by which electrons are transferred to dehalogenating enzymes through protein-protein interactions. Organohalides were present in Earth's early history and now pollute the environment globally. Organohalide respiring bacteria (ORB) can degrade these pollutants by using them as terminal electron acceptors in their respiratory metabolism. This represents one of the most ancient respiratory systems on Earth about which little is known. This project will add to our fundamental knowledge of microbial evolution and metabolic systems, and pave the way for next generation organohalide remediation technologies.Read moreRead less
High-throughput single-molecule directed evolution. DNA polymerases are essential enzymes in many biotechnological tools, including DNA sequencing and PCR tests. However, existing DNA polymerases have limitations, resulting in inaccuracies and inefficiencies. Existing methods to improve polymerases lack sensitivity to screen for subtle, yet pivotal traits. This project aims to overcome this limitation by developing a new single-molecule directed-evolution system to evolve better polymerases. Wit ....High-throughput single-molecule directed evolution. DNA polymerases are essential enzymes in many biotechnological tools, including DNA sequencing and PCR tests. However, existing DNA polymerases have limitations, resulting in inaccuracies and inefficiencies. Existing methods to improve polymerases lack sensitivity to screen for subtle, yet pivotal traits. This project aims to overcome this limitation by developing a new single-molecule directed-evolution system to evolve better polymerases. With this new technology we aim to identify DNA polymerases with improved performance that benefit biotechnological applications. Additionally, these single-molecule directed-evolution methods will benefit the wider scientific community and lay the foundation for further advances in directed evolution.Read moreRead less
Re-purposing shelved 'antibiotics' in the search for new herbicides. This project aims to identify target-specific herbicidal compounds that inhibit amino acid biosynthesis pathways to tackle herbicide resistance. This project expects to validate a novel herbicide discovery strategy by exploiting the similarity between bacterial and plant enzymes in these pathways to re-purpose failed 'antibiotics'. Expected outcomes include advances in our knowledge of the structure, function and inhibition of ....Re-purposing shelved 'antibiotics' in the search for new herbicides. This project aims to identify target-specific herbicidal compounds that inhibit amino acid biosynthesis pathways to tackle herbicide resistance. This project expects to validate a novel herbicide discovery strategy by exploiting the similarity between bacterial and plant enzymes in these pathways to re-purpose failed 'antibiotics'. Expected outcomes include advances in our knowledge of the structure, function and inhibition of novel herbicide targets, and the identification of compounds with herbicidal activity. This should lay the foundations for long-term benefits related to improving the quantity and quality of Australia’s crops to ensure our food security.Read moreRead less
Augmenting the activity of glyoxalase-1 to increase dicarbonyl clearance . Reactive intermediates generated during our metabolism contribute to ageing. Glyoxalase-1 is a key defence enzyme against these toxic intermediates and therefore ageing itself. This project aims to investigate novel pathways how the expression and activity of glyoxalase-1 are regulated. This interdisciplinary project expects to generate new understanding by combining relevant cell and animal models, protein chemistry, epi ....Augmenting the activity of glyoxalase-1 to increase dicarbonyl clearance . Reactive intermediates generated during our metabolism contribute to ageing. Glyoxalase-1 is a key defence enzyme against these toxic intermediates and therefore ageing itself. This project aims to investigate novel pathways how the expression and activity of glyoxalase-1 are regulated. This interdisciplinary project expects to generate new understanding by combining relevant cell and animal models, protein chemistry, epigenetics and structural biology. It is expected that this work will improve understanding of this fundamental biological defence. This will allow us to identify the potential means to enhance the capacity of glyoxalase-1 to the future benefit of biological ageing.Read moreRead less
Understanding chaperone function, one molecule at a time. This project aims to determine how molecular chaperones, a class of proteins represented in all phyla of life, work together to keep proteins folded and functional, particularly following cellular stress. This is important as proteins are involved in virtually all biological processes. This project will exploit innovative microscopy techniques to watch these molecular chaperones as they work. Expected outcomes of this project are the firs ....Understanding chaperone function, one molecule at a time. This project aims to determine how molecular chaperones, a class of proteins represented in all phyla of life, work together to keep proteins folded and functional, particularly following cellular stress. This is important as proteins are involved in virtually all biological processes. This project will exploit innovative microscopy techniques to watch these molecular chaperones as they work. Expected outcomes of this project are the first definitive description of how molecular chaperones interact to refold proteins, and the development of novel methods to study dynamic biological processes. This should provide significant benefits including enhanced collaboration and scientific capacity in Australia.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100780
Funder
Australian Research Council
Funding Amount
$455,237.00
Summary
Functional and structural dissection of the human replisome. This project aims to develop technology to visualise the structure and enzymatic activities of the human replisome, the multiprotein assembly that copies DNA before cell division. A combination of novel single-molecule and state-of-the-art cryo-electron microscopy will be used to define how the human replisome coordinates DNA synthesis during times of replication stress. Key outcomes of this project include development of novel molecul ....Functional and structural dissection of the human replisome. This project aims to develop technology to visualise the structure and enzymatic activities of the human replisome, the multiprotein assembly that copies DNA before cell division. A combination of novel single-molecule and state-of-the-art cryo-electron microscopy will be used to define how the human replisome coordinates DNA synthesis during times of replication stress. Key outcomes of this project include development of novel molecular visualisation technologies, leading to the first molecular description of dynamic processes used by the human replisome. Benefits include improved understanding of a fundamental biological process that often malfunctions in cancers, development of novel methodology, and interdisciplinary training.Read moreRead less
Roadblocks in DNA replication. This project aims to develop the technology to visualise and understand the molecular processes responsible for the faithful copying of cellular DNA in the presence of roadblocks caused by chemical pressures and competing intracellular events. Understanding this process is important as DNA replication is responsible for copying the DNA genetic blueprint of cells and is crucial to all life on earth. This project will have as key outcomes the development of novel mol ....Roadblocks in DNA replication. This project aims to develop the technology to visualise and understand the molecular processes responsible for the faithful copying of cellular DNA in the presence of roadblocks caused by chemical pressures and competing intracellular events. Understanding this process is important as DNA replication is responsible for copying the DNA genetic blueprint of cells and is crucial to all life on earth. This project will have as key outcomes the development of novel molecular visualisation technology and the first molecular description of the dynamic processes used by the DNA-replication machinery to navigate roadblocks. These outcomes should provide significant benefits including enhanced collaboration and scientific capacity in Australia.Read moreRead less
Regulation of autophagy dependent cell and tissue deletion. This project aims to elucidate novel mechanisms that regulate autophagy-depdendent cell death during animal development. It will combine the power of Drosophila genetics with multidisciplinary approaches, such as proteomics, bioinformatics and cell biology. Given the conserved nature of autophagy the oucomes will provide highly topical and exciting new knowledge of broad biological significance. The project will help establishing inter ....Regulation of autophagy dependent cell and tissue deletion. This project aims to elucidate novel mechanisms that regulate autophagy-depdendent cell death during animal development. It will combine the power of Drosophila genetics with multidisciplinary approaches, such as proteomics, bioinformatics and cell biology. Given the conserved nature of autophagy the oucomes will provide highly topical and exciting new knowledge of broad biological significance. The project will help establishing international collaborations, enhancing Australia’s competitiveness and reputation in an important area of research, and provide training of HDR students in skills across a range of areas. In the long-term the research findings may translate into improved agriculture, food production and human health outcomes.Read moreRead less
Understanding the mechanisms of peptide cyclisation. This project aims to identify, study, engineer and apply a new class of biocatalysts (called asparaginyl endopeptidase enzymes) as versatile tools for manufacturing of advanced therapeutics and bio-insecticides. The expected outcomes include fundamental new knowledge on the mechanism of action of these catalysts, an expanded toolbox for precision engineering of biomolecules and new strategies for production of high-value pharmaceuticals and cr ....Understanding the mechanisms of peptide cyclisation. This project aims to identify, study, engineer and apply a new class of biocatalysts (called asparaginyl endopeptidase enzymes) as versatile tools for manufacturing of advanced therapeutics and bio-insecticides. The expected outcomes include fundamental new knowledge on the mechanism of action of these catalysts, an expanded toolbox for precision engineering of biomolecules and new strategies for production of high-value pharmaceuticals and crop protecting agents. The project is significant because it will contribute to high value biotechnology and agricultural industries in Australia, with the potential for economic, environmental, training and societal benefits.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190100806
Funder
Australian Research Council
Funding Amount
$419,854.00
Summary
Towards herbicide cocktails with a new mode of action to avert resistance. This project aims to target herbicide resistant weeds which represent one of the largest threats to Australian and global food security. Targeting of unexplored pathways in plants to develop a novel herbicide strategy is expected to be achieved, and will include the structural and functional characterisation of key enzymes in these pathways. This project is expected to provide significant benefits for effective weed manag ....Towards herbicide cocktails with a new mode of action to avert resistance. This project aims to target herbicide resistant weeds which represent one of the largest threats to Australian and global food security. Targeting of unexplored pathways in plants to develop a novel herbicide strategy is expected to be achieved, and will include the structural and functional characterisation of key enzymes in these pathways. This project is expected to provide significant benefits for effective weed management to sustain Australia’s agricultural industry through enhanced food production from increased crop yields, whilst ensuring food security. These outcomes, coupled with decades of over-reliance on current herbicides, means there has never been a greater need for new and effective herbicides.Read moreRead less