Microbial junk food: developing synthetic platforms for plastic degradation. This project aims to establish the genetic basis of polyethelene biodegradation (PED) by microbes from the gut microbiome of plastic-eating caterpillars. It will transform the active microbial PED genes into carefully designed synthetic microbes for efficient, safe and large-scale PED. The project will combine innovative functional microbial genetic tools and synthetic biology techniques with solid biochemistry and bioi ....Microbial junk food: developing synthetic platforms for plastic degradation. This project aims to establish the genetic basis of polyethelene biodegradation (PED) by microbes from the gut microbiome of plastic-eating caterpillars. It will transform the active microbial PED genes into carefully designed synthetic microbes for efficient, safe and large-scale PED. The project will combine innovative functional microbial genetic tools and synthetic biology techniques with solid biochemistry and bioinformatics to produce translatable synthetic platforms containing key genes optimised for efficient PE waste removal. The outcomes will have the potential to transform the relative ineffective and expensive current methods for PE disposal into flexible, cost-effective and sustainable solutions applicable to multiple sectors.Read moreRead less
Structure-guided optimisation of light-driven microalgae cell factories. Every two hours Earth receives more solar energy than is required to power our entire global economy for a year. This project aims to engineer advanced single cell green algae for high-efficiency solar light capture, to power next-generation light-driven bio-manufacture. The significance is to advance industry-scale production of sustainable products using microalgae. This is economically, socially and environmentally benef ....Structure-guided optimisation of light-driven microalgae cell factories. Every two hours Earth receives more solar energy than is required to power our entire global economy for a year. This project aims to engineer advanced single cell green algae for high-efficiency solar light capture, to power next-generation light-driven bio-manufacture. The significance is to advance industry-scale production of sustainable products using microalgae. This is economically, socially and environmentally beneficial. Project outcomes are designed to advance the technology from high-value bio-manufacture in microalgae, such as pharmaceuticals (e.g. biologicals), to mid-value products (e.g. fine chemicals) through to low-cost products, such as renewable fuels to help deliver key UN Sustainable Development Goals.Read moreRead less
On the Hunt: Boosting Productivity of Cell Factories by Advanced Searches . This project aims to advance our fundamental understanding of molecular mechanisms underlying protein secretion in yeast, an industrial workhorse and a model organism. It will develop a unique multifaceted research platform to identify and analyse superior yeast strains with the desired traits at the single-cell level. Expected outcomes include a new analytical tool for high-throughput strain analysis and advanced knowle ....On the Hunt: Boosting Productivity of Cell Factories by Advanced Searches . This project aims to advance our fundamental understanding of molecular mechanisms underlying protein secretion in yeast, an industrial workhorse and a model organism. It will develop a unique multifaceted research platform to identify and analyse superior yeast strains with the desired traits at the single-cell level. Expected outcomes include a new analytical tool for high-throughput strain analysis and advanced knowledge of yeast molecular biology that can be applied to improve cell factories for the next generation of fuels, food and pharmaceuticals. This will provide significant economic and social benefits by boosting biotech industry growth, facilitating the transition to a sustainable society and improving Australia’s biosecurity.Read moreRead less
Establishing Vibrio natriegens as Ultra-Rapid Host for Synthetic Biology. This project aims to harness Vibrio natriegens, the world’s fastest-growing bacterium, as a microbial cell factory for synthetic biology and biotechnology. The project expects to develop new genetic tools and genetically-engineered microbes that can rapidly transform cheap feedstocks, such as plastic waste, into valuable chemicals and bioplastics. Expected outcomes include new knowledge on the mechanisms driving V. natrieg ....Establishing Vibrio natriegens as Ultra-Rapid Host for Synthetic Biology. This project aims to harness Vibrio natriegens, the world’s fastest-growing bacterium, as a microbial cell factory for synthetic biology and biotechnology. The project expects to develop new genetic tools and genetically-engineered microbes that can rapidly transform cheap feedstocks, such as plastic waste, into valuable chemicals and bioplastics. Expected outcomes include new knowledge on the mechanisms driving V. natriegens’ rapid growth, as well as building Australian multidisciplinary research capacity in synthetic biology that can translate this potential into bio-manufacturing processes. Significant benefits include the means to cut plastic pollution in our environment and to provide the basis for a carbon-negative chemical industry.Read moreRead less
Mid-Career Industry Fellowships - Grant ID: IM230100154
Funder
Australian Research Council
Funding Amount
$1,049,904.00
Summary
Fungi Power: Designer Fungal Cell Factories for Advanced Biomanufacturing. This project aims to build an advanced biomanufacturing platform based on filamentous fungi in collaboration with industry. Using synthetic biology, the project expects to engineer superior fungal host strains customisable to the needs of the industry and to address their technological gaps. The expected outcomes include the development of cost-efficient and sustainable fungal-based bioprocesses for the companies to produ ....Fungi Power: Designer Fungal Cell Factories for Advanced Biomanufacturing. This project aims to build an advanced biomanufacturing platform based on filamentous fungi in collaboration with industry. Using synthetic biology, the project expects to engineer superior fungal host strains customisable to the needs of the industry and to address their technological gaps. The expected outcomes include the development of cost-efficient and sustainable fungal-based bioprocesses for the companies to produce products, such as fine chemicals, pharmaceutical actives and food ingredients. The project would provide significant benefits by enabling existing and emerging companies' commercial successes and competitiveness in global markets, creating new jobs and resulting in the growth of the bio-economy in Australia.Read moreRead less
Biosynthetic Hooks for an Enigmatic Marine Toxin. This project aims to characterise the genetic basis for the production of tetrodotoxin; a potent neurotoxin of ecological and biomedical significance. We hypothesise that tetrodotoxin is produced by microorganisms and transferred via the food web to fish, molluscs and other marine animals. Our integrated genomic and synthetic biology approach, targeting key biosynthesis genes, will reveal pathways for the production of tetrodotoxin and other pote ....Biosynthetic Hooks for an Enigmatic Marine Toxin. This project aims to characterise the genetic basis for the production of tetrodotoxin; a potent neurotoxin of ecological and biomedical significance. We hypothesise that tetrodotoxin is produced by microorganisms and transferred via the food web to fish, molluscs and other marine animals. Our integrated genomic and synthetic biology approach, targeting key biosynthesis genes, will reveal pathways for the production of tetrodotoxin and other potentially valuable compounds. In addition to providing unprecedented insight into the ecology and biosynthesis of this enigmatic toxin, the data generated will enable improved management of seafood safety and provide a foundation for the future development of novel neuroactive compounds.Read moreRead less
Discovery and directed evolution of small molecule biosensors. This project aims to address the need for novel small molecule biosensing capability in diverse fields including food and wine production, environmental monitoring, biocatalysis, and diagnostics using a synthetic biology approach. The significance of this work is the development of new biosensors by a strong interdisciplinary team contributing bioinformatics to identify new biosensors, innovative protein engineering approaches, and c ....Discovery and directed evolution of small molecule biosensors. This project aims to address the need for novel small molecule biosensing capability in diverse fields including food and wine production, environmental monitoring, biocatalysis, and diagnostics using a synthetic biology approach. The significance of this work is the development of new biosensors by a strong interdisciplinary team contributing bioinformatics to identify new biosensors, innovative protein engineering approaches, and cutting-edge directed evolution methodologies. Intended outcomes include enhanced institutional capacity for interdisciplinary collaboration; discovery of fundamentally important bacterial sensors; and development of synthetic regulatory circuits enabling outgrowth of non-biological biocatalysis industries.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230101081
Funder
Australian Research Council
Funding Amount
$458,238.00
Summary
Developing CRISPR Prime Editing for highly efficient precise gene editing. This project will further develop a recent breakthrough in gene editing technology named CRISPR prime editing to improve its performance in generating specific genome modifications in cells and organisms. This project expects to generate new knowledge regarding optimal strategies for its deployment as well as create novel enhanced versions of the technology. This would significantly enhance our ability to perform precise ....Developing CRISPR Prime Editing for highly efficient precise gene editing. This project will further develop a recent breakthrough in gene editing technology named CRISPR prime editing to improve its performance in generating specific genome modifications in cells and organisms. This project expects to generate new knowledge regarding optimal strategies for its deployment as well as create novel enhanced versions of the technology. This would significantly enhance our ability to perform precise genome modification of organisms and lead to substantial benefits for a vast array of applications in fundamental and applied biology. Future applications will include generating mutations in cells and model organisms for basic research and creating genetically enhanced agricultural animals or plants.Read moreRead less
Flipping the mattress: infinite polyurethane recycling by synthetic biology. Australia is covered in billions of tonnes of plastic and yet <10% is recycled today. Polyurethane (PU) is ubiquitous in our everyday lives, from lacquer coatings to elastane clothing to durable foam padding in car seats, cushions and mattresses. Currently, there are few avenues for PU recycling and much ends up in landfill e.g., a single mattress produces 15-20kg of PU foam waste. Luckily, biodegradation of PU can occu ....Flipping the mattress: infinite polyurethane recycling by synthetic biology. Australia is covered in billions of tonnes of plastic and yet <10% is recycled today. Polyurethane (PU) is ubiquitous in our everyday lives, from lacquer coatings to elastane clothing to durable foam padding in car seats, cushions and mattresses. Currently, there are few avenues for PU recycling and much ends up in landfill e.g., a single mattress produces 15-20kg of PU foam waste. Luckily, biodegradation of PU can occur naturally via various microbial means and from insects, like Galleria mellonella larvae. The overall aim of this research project is to understand plastic biodegradation and translate nature’s solutions into flexible and efficient synthetic enzyme technologies that can sustainably recycle commonly used PU foams. Read moreRead less