Advancing plant synthetic gene circuit capability, robustness, and use. This project aims to advance our ability to control gene expression in plants using synthetic gene circuits. By expanding the toolkit and optimizing circuit components, we aim to achieve more complex capabilities and robust implementation. Furthermore, we will apply gene circuit technologies to enhance plant frost tolerance. The expected project outcomes include a significant advance in gene circuit capabilities, a better un ....Advancing plant synthetic gene circuit capability, robustness, and use. This project aims to advance our ability to control gene expression in plants using synthetic gene circuits. By expanding the toolkit and optimizing circuit components, we aim to achieve more complex capabilities and robust implementation. Furthermore, we will apply gene circuit technologies to enhance plant frost tolerance. The expected project outcomes include a significant advance in gene circuit capabilities, a better understanding of their behavior in plant cells, and the ability to use them to confer advantageous traits. The benefits of this research include new plant biotechnology tools that will underpin future crop yield improvements, and advances in plant-based pharmaceuticals and materials.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
Synthetic biology tools for just-in-time control of biosynthetic pathways. Synthetic biology enables sustainable synthesis of precious chemicals, ranging from drugs to biomaterials. Using microbes, high production levels are usually attained by overexpressing the genes that make the desired product, but this simple approach often fails for antibiotics and other compounds that are toxic to microbes. Using synthetic biology this project builds genetic circuits enabling smart, just-in-time activati ....Synthetic biology tools for just-in-time control of biosynthetic pathways. Synthetic biology enables sustainable synthesis of precious chemicals, ranging from drugs to biomaterials. Using microbes, high production levels are usually attained by overexpressing the genes that make the desired product, but this simple approach often fails for antibiotics and other compounds that are toxic to microbes. Using synthetic biology this project builds genetic circuits enabling smart, just-in-time activation of target genes, which is pervasive in natural pathways. Using these circuits we will boost 1) the production of a valuable antibiotic and 2) calcite precipitation in self-healing concrete. This approach enables the biosynthesis of many other chemicals, leading to cleaner and greener bio-factories.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
Building a CO2 foundry for sustainable carbon capture and utilisation. This project aims to develop innovative carbon capture and utilisation technology that fuses synthetic biology with inorganic chemistry. The project expects to develop nano-structured electrocatalysts to efficiently convert CO2 from industrial emission into acetate, and genetically-engineered microbes to rapidly transform acetate into platform chemicals and biopolymers. Expected outcomes include an integrated electro-/biocata ....Building a CO2 foundry for sustainable carbon capture and utilisation. This project aims to develop innovative carbon capture and utilisation technology that fuses synthetic biology with inorganic chemistry. The project expects to develop nano-structured electrocatalysts to efficiently convert CO2 from industrial emission into acetate, and genetically-engineered microbes to rapidly transform acetate into platform chemicals and biopolymers. Expected outcomes include an integrated electro-/biocatalytic prototype with unprecedented CO2 conversion efficiency, as well as building a multidisciplinary research capacity in synthetic biology and nanotechnology. This should provide significant benefits, by reducing greenhouse gases and providing the basis for a carbon-negative chemical industry.Read moreRead less
Engineering Fungal Nonribosomal Peptide Synthetases for Novel Alkaloids. This project aims to use protein-domain shuffling aided by structural biology to decode and engineer a class of modular megaenzymes, called nonribosomal peptide synthetases (NRPSs), in fungi. These are responsible for the biosynthesis of peptide-derived bioactive molecules, such as the antibiotic penicillin and the immunosuppressant cyclosporin. Expected outcomes of this project include a fungal NRPS engineering platform fo ....Engineering Fungal Nonribosomal Peptide Synthetases for Novel Alkaloids. This project aims to use protein-domain shuffling aided by structural biology to decode and engineer a class of modular megaenzymes, called nonribosomal peptide synthetases (NRPSs), in fungi. These are responsible for the biosynthesis of peptide-derived bioactive molecules, such as the antibiotic penicillin and the immunosuppressant cyclosporin. Expected outcomes of this project include a fungal NRPS engineering platform for generating new molecules with desirable biological activities that can be readily scaled up for sustainable bioproduction. This will provide significant benefits to Australia through the development of cutting-edge biotechnologies as well as the discovery of new pharmaceuticals, veterinary products and agrichemicals.Read moreRead less