IDENTIFYING CONTROL ELEMENTS IN CHLOROPLAST GENE EXPRESSION. Energy from sunlight is captured by photosynthesis in plants, providing the basis for the terrestrial food chain. This process takes place in chloroplasts, subcellular structures that derived from photosynthetic bacteria a billion years ago. Chloroplasts have their own DNA, containing genes encoding the most important photosynthetic proteins. This project aims to provide the world’s best resources for the study of chloroplast genes. In ....IDENTIFYING CONTROL ELEMENTS IN CHLOROPLAST GENE EXPRESSION. Energy from sunlight is captured by photosynthesis in plants, providing the basis for the terrestrial food chain. This process takes place in chloroplasts, subcellular structures that derived from photosynthetic bacteria a billion years ago. Chloroplasts have their own DNA, containing genes encoding the most important photosynthetic proteins. This project aims to provide the world’s best resources for the study of chloroplast genes. In the process, we will discover how these important genes are regulated to provide photosynthetic proteins in the right amounts, in the right cells, at the right time. The knowledge and resources gained will facilitate improvement of photosynthetic function in future agricultural crops.Read moreRead less
Mastering pyrimidine editing in RNA. Many plants and animals can alter their genetic information via RNA (ribonucleic acid) editing, a process that is often essential for the growth and development of the organism. This ability provides accurate control over gene expression and has great potential as a biotechnological tool in agriculture and medicine. RNA editing could be used to switch genes on or off in biotechnological production systems with an unprecedented degree of precision, or to corre ....Mastering pyrimidine editing in RNA. Many plants and animals can alter their genetic information via RNA (ribonucleic acid) editing, a process that is often essential for the growth and development of the organism. This ability provides accurate control over gene expression and has great potential as a biotechnological tool in agriculture and medicine. RNA editing could be used to switch genes on or off in biotechnological production systems with an unprecedented degree of precision, or to correct genetic diseases. This project aims to understand two RNA editing pathways in plants, one of which is found nowhere else and likely to involve a novel enzymatic mechanism. We will use the understanding gained to develop novel RNA processing tools usable in any living organism.Read moreRead less
Autocyclases: A new class of self-cyclising proteins. The biotechnology sector is emerging as an important economic strength in Australia. While the improved efficacy and selectivity of biomolecules has seen them emerge as alternatives to existing chemicals in health and agriculture, the stability of biomolecules remains a major limiting factor. A general strategy for improving protein stability is by joining the ends of the peptide chain in a cyclisation reaction. While a wide range of cyclic p ....Autocyclases: A new class of self-cyclising proteins. The biotechnology sector is emerging as an important economic strength in Australia. While the improved efficacy and selectivity of biomolecules has seen them emerge as alternatives to existing chemicals in health and agriculture, the stability of biomolecules remains a major limiting factor. A general strategy for improving protein stability is by joining the ends of the peptide chain in a cyclisation reaction. While a wide range of cyclic peptides and proteins are being developed in Australia and around the world, the cyclisation reaction presents a significant challenge. In this proposal we detail a novel method for protein cyclisation as a general, low-cost and green production method for making a diverse range of biomolecules. Read moreRead less
Engineering self-assembled intracellular biological condensates. Cells depend on proteins linking together to build cellular structure, but how weak interactions build stable structure is a mystery. New evidence suggests proteins come together and then change state, employing liquid-like behaviour that builds vital nanoscale structure, such as nuclear bodies called paraspeckles. This project will unlock the secrets of this mysterious behavior of proteins, using paraspeckles as a model. We will u ....Engineering self-assembled intracellular biological condensates. Cells depend on proteins linking together to build cellular structure, but how weak interactions build stable structure is a mystery. New evidence suggests proteins come together and then change state, employing liquid-like behaviour that builds vital nanoscale structure, such as nuclear bodies called paraspeckles. This project will unlock the secrets of this mysterious behavior of proteins, using paraspeckles as a model. We will use this information for nanotechnology application to build a synthetic paraspeckle inspired structure with bespoke function. Benefits will include new concepts in how vital cell structure is assembled and disassembled, and nanotechnology and synthetic biology tools to manipulate cellular processes.Read moreRead less
Sculpting a masterpiece: synthesis and evolution of minimal yeast genomes. This project aims to better understand genome complexity by engineering minimal yeast genomes that have fewer genes, and are therefore easier to characterise and engineer. Yeast is a model organism and industrial food, fuel, and chemical producer. This project expects to increase our basic understanding of yeast genomes, and develop new tools for engineering whole genomes. Expected outcomes of this project include the eng ....Sculpting a masterpiece: synthesis and evolution of minimal yeast genomes. This project aims to better understand genome complexity by engineering minimal yeast genomes that have fewer genes, and are therefore easier to characterise and engineer. Yeast is a model organism and industrial food, fuel, and chemical producer. This project expects to increase our basic understanding of yeast genomes, and develop new tools for engineering whole genomes. Expected outcomes of this project include the engineering and characterisation of the world's first minimal yeast genome, and the development of novel industrial yeast strains. This will provide significant benefits for both fundamental genetics and biochemistry research, and the industrial use of yeast for bio-manufacturing of sustainable foods, fuels, and chemicals.Read moreRead less
Advancing programmable genetic computation to control plant gene activity. Plants can sense diverse internal and external conditions and integrate them to appropriately tune their response and maximize fitness. Plant biotechnology relies heavily on manipulating gene activity to change cell functions and confer advantageous agronomic traits. However, our ability to control plant gene activity remains rudimentary, limiting our biotechnology capabilities. This project aims to develop synthetic gene ....Advancing programmable genetic computation to control plant gene activity. Plants can sense diverse internal and external conditions and integrate them to appropriately tune their response and maximize fitness. Plant biotechnology relies heavily on manipulating gene activity to change cell functions and confer advantageous agronomic traits. However, our ability to control plant gene activity remains rudimentary, limiting our biotechnology capabilities. This project aims to develop synthetic gene logic gates in plants, to enable the construction of programmable genetically-encoded computational functions that can sense and process customizable inputs to drive desired changes in plant function. This advance will underpin useful applications in plant biotechnology such as improved crop stress tolerance and yield.Read moreRead less
A novel platform for the biosynthesis of commercially valuable saxitoxins. Saxitoxins are potent microbial toxins, which pose a significant threat to food and water quality. Highly pure saxitoxins are required for environmental monitoring and studies of cell physiology. Certain analogues have also shown promise as long-lasting and non-addictive pain blockers. However, the procurement of these compounds from natural sources is convoluted and unsustainable. This project aims to use the latest synt ....A novel platform for the biosynthesis of commercially valuable saxitoxins. Saxitoxins are potent microbial toxins, which pose a significant threat to food and water quality. Highly pure saxitoxins are required for environmental monitoring and studies of cell physiology. Certain analogues have also shown promise as long-lasting and non-addictive pain blockers. However, the procurement of these compounds from natural sources is convoluted and unsustainable. This project aims to use the latest synthetic biology techniques to characterise, modify and express saxitoxin biosynthesis pathways, thereby providing a sustainable source of toxin analogues of value to industry and research. This novel 'green technology' will benefit the environment, human health and the Australian economy.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210100323
Funder
Australian Research Council
Funding Amount
$431,000.00
Summary
Synthetic biology to engineer novel disease resistance in cereal crops. This project aims to engineer disease resistance in crops to dangerous fungal pathogens. The strategy is to exploit our knowledge of the plant immune system using structural biology and directed evolution of natural resistance genes, improving their ability to recognise and respond to fungal attack. Fungal pathogens cause some of the most harmful crop diseases in Australia and worldwide. The rapid evolution of fungi overcome ....Synthetic biology to engineer novel disease resistance in cereal crops. This project aims to engineer disease resistance in crops to dangerous fungal pathogens. The strategy is to exploit our knowledge of the plant immune system using structural biology and directed evolution of natural resistance genes, improving their ability to recognise and respond to fungal attack. Fungal pathogens cause some of the most harmful crop diseases in Australia and worldwide. The rapid evolution of fungi overcomes natural plant resistance and management of these diseases is a major challenge to agriculture. Expected outcomes of the project include engineered wheat plants with more effective disease resistance, reducing fungicide usage. This project intends to accelerate crop breeding and contribute to world food security.Read moreRead less
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
A scalable, synthetic retina: signal processing in droplet systems with DNA. This project aims to design DNA-based nanotechnology for processing optical signals in synthetic biological systems. The intended outcome of this project is to develop a system for signal transduction in artificial bilayers using new DNA nanostructures. The anticipated goal of the project is to deliver: 1) light-based control of membrane protein insertion into artificial bilayers; 2) novel DNA-based pores that can trans ....A scalable, synthetic retina: signal processing in droplet systems with DNA. This project aims to design DNA-based nanotechnology for processing optical signals in synthetic biological systems. The intended outcome of this project is to develop a system for signal transduction in artificial bilayers using new DNA nanostructures. The anticipated goal of the project is to deliver: 1) light-based control of membrane protein insertion into artificial bilayers; 2) novel DNA-based pores that can transduce signals across membranes; 3) signal processing using multi-compartment biological components composed. Together, this technology allows us to use light and external signals to control biochemical pathways in synthetic systems.Read moreRead less