From trash to treasure: engineering waste carbon utilisation in yeast. This project aims to engineer yeast to convert carbon dioxide- and methane-derived methanol into sustainable chemicals, foods, and pharmaceuticals. This project expects to generate new design principles for methanol metabolism by using the innovative approach of laboratory evolution along with state-of-the-art bio-engineering capabilities at Macquarie University and The University of Queensland. Expected outcomes of this proj ....From trash to treasure: engineering waste carbon utilisation in yeast. This project aims to engineer yeast to convert carbon dioxide- and methane-derived methanol into sustainable chemicals, foods, and pharmaceuticals. This project expects to generate new design principles for methanol metabolism by using the innovative approach of laboratory evolution along with state-of-the-art bio-engineering capabilities at Macquarie University and The University of Queensland. Expected outcomes of this project include new manufacturing processes for chemicals and foods, discovery of novel metabolism in yeast, and enhanced collaboration between Australia, Denmark, and the United States. This Project will provide benefits through sustainable bio-manufacturing, new economic activity, and reduced greenhouse gas emissions.Read moreRead less
EnzOnomy - an enzyme-based production pipeline for the bioeconomy. The sustainable production of high value chemicals (e.g. fuels, foods) from renewable materials is a cornerstone for the emerging global bioeconomy. We aim to harness the potential of protein engineering to develop a technology (EnzOnomy) to convert renewable raw material (e.g. sugar) into platform chemicals (e.g. isobutanol, a building block for jet fuels, fibers, plastics and antioxidants). Our multi-disciplinary and well estab ....EnzOnomy - an enzyme-based production pipeline for the bioeconomy. The sustainable production of high value chemicals (e.g. fuels, foods) from renewable materials is a cornerstone for the emerging global bioeconomy. We aim to harness the potential of protein engineering to develop a technology (EnzOnomy) to convert renewable raw material (e.g. sugar) into platform chemicals (e.g. isobutanol, a building block for jet fuels, fibers, plastics and antioxidants). Our multi-disciplinary and well established international team will link scientific progress to markets to enhance potential commercial impact in the bioeconomy. The project thus provides great benefit for our nation as it embeds Australia in technologies and global networks that will cement its leading position to safe-guard the future of our planet.
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Regulation of DNA replication initiation during Drosophila development. This proposal addresses the fundamental issue of the regulation of DNA
replication during development, using the animal model system, Drosophila melanogaster. This research uses a whole animal genetic and cell biological approach to explore DNA replication regulatory mechanisms that are present in multicellular organisms but not in yeast. The work undertaken here will make a significant contribution to our understanding of ....Regulation of DNA replication initiation during Drosophila development. This proposal addresses the fundamental issue of the regulation of DNA
replication during development, using the animal model system, Drosophila melanogaster. This research uses a whole animal genetic and cell biological approach to explore DNA replication regulatory mechanisms that are present in multicellular organisms but not in yeast. The work undertaken here will make a significant contribution to our understanding of DNA replication regulation within a developing organism that will be relevant to all animals.Read moreRead less
Unveiling and characterisation of a fundamental pathway important in cell division. This work will have a major impact by producing top quality research that addresses a fundamental biological question of relevance to all organisms. The research will advance understanding of genetic factors important in foetal and early childhood development and proliferative disorders that occur during ageing. This work will provide intellectual and practical training to Honours and PhD students and postdoctora ....Unveiling and characterisation of a fundamental pathway important in cell division. This work will have a major impact by producing top quality research that addresses a fundamental biological question of relevance to all organisms. The research will advance understanding of genetic factors important in foetal and early childhood development and proliferative disorders that occur during ageing. This work will provide intellectual and practical training to Honours and PhD students and postdoctoral researchers in the disciplines of Molecular Genetics, Molecular & Cellular Biology, Developmental Cell Biology, Mass Spectrometry and Proteomics, which will be of immense benefit to their scientific careers and the Australian scientific community.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100010
Funder
Australian Research Council
Funding Amount
$720,000.00
Summary
A 5-D Correlative Imaging Platform: Combining the strengths of light and electron microscopy. This will be Australia's first dedicated five-dimensional multiphoton-microscopy platform, allowing observation of dynamic structures across different length and time scales under controlled temperatures, followed by high-resolution electron microscopy studies on the same samples. This platform will provide a unique characterisation tool to Australia's top-flight investigators, and so contribute to the ....A 5-D Correlative Imaging Platform: Combining the strengths of light and electron microscopy. This will be Australia's first dedicated five-dimensional multiphoton-microscopy platform, allowing observation of dynamic structures across different length and time scales under controlled temperatures, followed by high-resolution electron microscopy studies on the same samples. This platform will provide a unique characterisation tool to Australia's top-flight investigators, and so contribute to the nation's research priorities. It will enable: fundamental studies of cancer, neural diseases and immune disorders; the development of frontier technologies, such as smart nanomaterials, biosensors and targeted drug delivery; and applied research to help plants and soils adapt to climate variability, and to increase sustainable use of water.Read moreRead less
Understanding the structural basis for catalysis and substrate specificity in non-heme diiron medium-chain alkane hydroxylases. This work will determine the molecular basis for catalysis and specificity of non-heme diiron medium-chain alkane hydroxylases by obtaining the first structure of such an enzyme. This pivotal knowledge will drive enzyme engineering for applications in biodegradation of spilt oils and biosynthesis of pharmaceuticals and high-cost chemicals.
Novel ultraviolet radiation filters from extreme environments. This project aims to exploit uncultured microorganisms to produce and characterise novel ultraviolet radiation-filter biosynthesis pathways. Current ultraviolet radiation-filtering compounds are toxic and persistent. There is a need for biodegradable, ultraviolet radiation filters that are safe for use across a variety of health and industrial applications. Over millions of years, the damaging effect of ultraviolet radiation has exer ....Novel ultraviolet radiation filters from extreme environments. This project aims to exploit uncultured microorganisms to produce and characterise novel ultraviolet radiation-filter biosynthesis pathways. Current ultraviolet radiation-filtering compounds are toxic and persistent. There is a need for biodegradable, ultraviolet radiation filters that are safe for use across a variety of health and industrial applications. Over millions of years, the damaging effect of ultraviolet radiation has exerted selective pressure on organisms that has driven the evolutionary diversity of natural radiation-filtering compounds. This project expects to characterise and harness the microbial diversity of unique high ultraviolet radiation ecosystems via synthetic biology to produce industrially and pharmacologically useful ultraviolet radiation filters.Read moreRead less