Biosynthesis and functions of two phytotoxins in Septoria nodorum blotch. This project aims to investigate how a fungal plant pathogen makes and uses small bioactive molecules to facilitate infection. It will characterise the function of the genes and enzymes involved in the biosynthesis of a light-activated phytotoxic molecule and a potential anti-plant defence molecule found in the pathogenic wheat fungus Parastagonospora nodorum, and investigate their contribution to disease development. Expe ....Biosynthesis and functions of two phytotoxins in Septoria nodorum blotch. This project aims to investigate how a fungal plant pathogen makes and uses small bioactive molecules to facilitate infection. It will characterise the function of the genes and enzymes involved in the biosynthesis of a light-activated phytotoxic molecule and a potential anti-plant defence molecule found in the pathogenic wheat fungus Parastagonospora nodorum, and investigate their contribution to disease development. Expected outcomes include better understanding of plant-microbe interactions, disease management strategies, technologies for identifying biosynthetic pathways in other fungi, and enzyme technology for synthesising molecules. This could lead to new herbicides, biopesticides and drugs.Read moreRead less
ARC Centre of Excellence in Synthetic Biology. The ARC Centre of Excellence in Synthetic Biology (CoESB) will provide the technical innovation critical for Australia to develop a vibrant bioeconomy building on the nation’s strengths in agriculture. For thousands of years we have used microbes to create bread, wine, cheese. Now, our Centre will pioneer new approaches to the design of synthetic microbes, enabling the development of custom-designed microbial communities, synthetic organelles and ne ....ARC Centre of Excellence in Synthetic Biology. The ARC Centre of Excellence in Synthetic Biology (CoESB) will provide the technical innovation critical for Australia to develop a vibrant bioeconomy building on the nation’s strengths in agriculture. For thousands of years we have used microbes to create bread, wine, cheese. Now, our Centre will pioneer new approaches to the design of synthetic microbes, enabling the development of custom-designed microbial communities, synthetic organelles and new to nature biological pathways and enzymes. CoESB will combine engineering with molecular biology to design and construct novel biological systems that can convert biomass from agriculture or waste streams to biofuel, bioplastics and other high-value chemicals.Read moreRead less
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
Genetic selection of artificial polyketides. This project aims to harness the potential of synthetic biology to build cells that can make valuable new derivatives of polyketides. Polyketides are natural products that have proven to be highly effective for use in industry, medicine and agriculture. The technologies developed in this project will provide resources to discover new chemicals, accessible to almost any scientific laboratory. Expected outcomes include the opportunity to put the future ....Genetic selection of artificial polyketides. This project aims to harness the potential of synthetic biology to build cells that can make valuable new derivatives of polyketides. Polyketides are natural products that have proven to be highly effective for use in industry, medicine and agriculture. The technologies developed in this project will provide resources to discover new chemicals, accessible to almost any scientific laboratory. Expected outcomes include the opportunity to put the future of natural product discovery and optimisation in the hands of the wider scientific community, which will provide significant benefits, such as providing new tools for Australian industries.Read moreRead less
Synthetic regulators of gene expression. RNA plays many essential roles in cells, from information transfer and regulation of gene expression to scaffolding macromolecular structures and catalysis. Despite these realisations the current approaches to manipulate RNA are limited in many respects. This project will use synthetic biology approaches to engineer synthetic regulators of RNAs in living cells. These studies will provide new tools for use in biological research and provide insights into h ....Synthetic regulators of gene expression. RNA plays many essential roles in cells, from information transfer and regulation of gene expression to scaffolding macromolecular structures and catalysis. Despite these realisations the current approaches to manipulate RNA are limited in many respects. This project will use synthetic biology approaches to engineer synthetic regulators of RNAs in living cells. These studies will provide new tools for use in biological research and provide insights into how natural proteins control gene expression. Furthermore, this project will use these tools to understand the mechanisms of how proteins are synthesised in mammalian mitochondria.Read moreRead less
Universal transcriptome editing technologies. Ribonucleic acid (RNA) is life’s most essential molecule – as no living cell or virus can function without it. Although RNA plays many critical roles in cells, from information transfer and regulation of gene expression to scaffolding macromolecular structures and catalysis, the current approaches to manipulate RNA for technological purposes are limited in many respects. This project brings together the scientists who were the first to discover a uni ....Universal transcriptome editing technologies. Ribonucleic acid (RNA) is life’s most essential molecule – as no living cell or virus can function without it. Although RNA plays many critical roles in cells, from information transfer and regulation of gene expression to scaffolding macromolecular structures and catalysis, the current approaches to manipulate RNA for technological purposes are limited in many respects. This project brings together the scientists who were the first to discover a universal code for recognition of RNA by proteins and one of the world’s leading RNA-focused biotechnology companies, Locana Biosciences, with the goal of providing robust and versatile tools to target RNA in diverse organisms.Read moreRead less
Complexities of the mitochondrial transcriptome. This project aims to understand mitochondrial gene expression and energy production. Energy production is important for living things to grow and develop. In mammals, the mitochondria, the energy producing “powerhouses of the cell”, contain their own genetic assembly instructions. This project aims to understand these genetic instructions, revealing how genes control energy production. This project will characterise the genetic instructions, the m ....Complexities of the mitochondrial transcriptome. This project aims to understand mitochondrial gene expression and energy production. Energy production is important for living things to grow and develop. In mammals, the mitochondria, the energy producing “powerhouses of the cell”, contain their own genetic assembly instructions. This project aims to understand these genetic instructions, revealing how genes control energy production. This project will characterise the genetic instructions, the mitochondrial transcriptome and the proteins that control them. These advances are expected to provide a mechanistic understanding of how gene expression responds to changes in cellular energy demands. This knowledge will generate new biotechnological tools for Australian science and will have important long-term implications for improving agriculture and medicineRead 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
From energy stress to hormones: new signals in bacteria and plants. This project will use molecular tools to detect and identify new chemical signals, known as butenolides, that regulate the growth and development of bacteria and plants. This project will use innovative, interdisciplinary techniques to discover where these butenolide signals come from, and how both bacteria and plants detect them. Expected outcomes of this project include a greater understanding of how plants use butenolides to ....From energy stress to hormones: new signals in bacteria and plants. This project will use molecular tools to detect and identify new chemical signals, known as butenolides, that regulate the growth and development of bacteria and plants. This project will use innovative, interdisciplinary techniques to discover where these butenolide signals come from, and how both bacteria and plants detect them. Expected outcomes of this project include a greater understanding of how plants use butenolides to cope with stress such as drought or salinity, and the design of new technologies for manipulating the growth of both plants and bacteria. The long-term benefits of this work should include fresh approaches for enhancing plant performance under sub-optimal conditions.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