Nano-reactors: Protein cages as reusable scaffolds for designer enzymes. This project aims to develop robust protein cages derived from the coats of viruses to contain heat-stable P450 enzymes, for use as specialised protein bio-catalysts in chemical industries. A valuable chemical precursor of renewable bio-plastics will be produced from seed oils by enzymes, reducing the use of fossil fuels. This synthetic biology approach combines biotechnology, nanotechnology and protein engineering to estab ....Nano-reactors: Protein cages as reusable scaffolds for designer enzymes. This project aims to develop robust protein cages derived from the coats of viruses to contain heat-stable P450 enzymes, for use as specialised protein bio-catalysts in chemical industries. A valuable chemical precursor of renewable bio-plastics will be produced from seed oils by enzymes, reducing the use of fossil fuels. This synthetic biology approach combines biotechnology, nanotechnology and protein engineering to establish a plant-based platform biotechnology for using enzymes as catalysts to make high-value molecules. The project aims to show how to engineer clean, sustainable chemistry in designer nano-environments. This should make synthetic processes more sustainable and enhance advanced chemical manufacturing in Australia.Read moreRead less
Using photosynthesis to power fine chemical production. This project aims to develop robust, solar driven, enzyme-based biocatalysts to synthesise complex metabolites and biopharmaceutical molecules in single-cell micro-algae. The significance of this project is that solar energy is used to drive challenging chemical reactions inexpensively via photosynthesis. Expected outcomes include sustainable, solar driven production of high-value molecules that are difficult or impossible to synthesise che ....Using photosynthesis to power fine chemical production. This project aims to develop robust, solar driven, enzyme-based biocatalysts to synthesise complex metabolites and biopharmaceutical molecules in single-cell micro-algae. The significance of this project is that solar energy is used to drive challenging chemical reactions inexpensively via photosynthesis. Expected outcomes include sustainable, solar driven production of high-value molecules that are difficult or impossible to synthesise chemically. Benefits include proof-of-principle demonstration of new, light-driven green-chemistry processes for the production of biochemicals, biopharmaceuticals, agricultural and industrial chemicals, extending the diversity of molecules we can make while reducing cost and environmental impact of their production.Read moreRead less