Metals in biocatalysis. Metals and enzymes are essential for the chemistry of life. This project will aim to garner the potential of metal-dependent enzymes to develop new drugs against osteoporosis, combat the spread of antibiotics resistance and optimise some of these enzymes to detoxify pesticide-polluted environments, thus contributing to global health and food security.
Venomics: Molecular and functional analysis of Australian snake venoms for development of human therapeutics. Australian snake venoms are lethal cocktails with potent effects on mammalian physiological processes, designed to immobilize and kill prey animals. Major targets of venom components are the nervous and blood coagulation systems but there is reason to believe that venoms have many other as yet unrecognized effects on mammalian systems. The project will combine techniques of modern mole ....Venomics: Molecular and functional analysis of Australian snake venoms for development of human therapeutics. Australian snake venoms are lethal cocktails with potent effects on mammalian physiological processes, designed to immobilize and kill prey animals. Major targets of venom components are the nervous and blood coagulation systems but there is reason to believe that venoms have many other as yet unrecognized effects on mammalian systems. The project will combine techniques of modern molecular biology (particularly transcriptomics and proteomics) with functional and structural analysis of purified venom components. Venoms from approximately 20 Australian snakes will be studied to reveal lead compounds for improved human pharmaceuticals against common disorders such as high blood pressure, bleeding and stroke.Read moreRead less
Novel tools and nanotechnology to navigate intracellular trafficking. This project aims to investigate how material accesses different compartments inside cells, also known as trafficking. Using immunology, cell biology and nanotechnology, the project will manipulate intracellular trafficking to achieve specific cellular functions. Outcomes will also form the basis of intellectual property development for new products by Australian biotechnology companies. These products will improve veterinary ....Novel tools and nanotechnology to navigate intracellular trafficking. This project aims to investigate how material accesses different compartments inside cells, also known as trafficking. Using immunology, cell biology and nanotechnology, the project will manipulate intracellular trafficking to achieve specific cellular functions. Outcomes will also form the basis of intellectual property development for new products by Australian biotechnology companies. These products will improve veterinary and human health services, leading to increased productivity.Read moreRead less
In vitro expression of macrocyclic peptides. This project aims to develop a novel strategy for the production of polypeptides with unnatural chemical groups using a sense codon reassignment approach. Novel peptides could be used in a range of pharmaceutical applications. Peptides made of 20 natural amino acids cover only a very small fraction of the available chemical and functional space. While a peptide’s functionality can be extended with unnatural amino acids, the methods for their site-sele ....In vitro expression of macrocyclic peptides. This project aims to develop a novel strategy for the production of polypeptides with unnatural chemical groups using a sense codon reassignment approach. Novel peptides could be used in a range of pharmaceutical applications. Peptides made of 20 natural amino acids cover only a very small fraction of the available chemical and functional space. While a peptide’s functionality can be extended with unnatural amino acids, the methods for their site-selective incorporation are inefficient. The project’s strategy relies on the depletion of selected tRNAs from an in vitro protein translation system and their replacement with synthetic tRNAs, charged with unnatural amino acids. It is expected that the developed technology could be used to rapidly generate and screen highly diversified macrocyclic peptide libraries.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560862
Funder
Australian Research Council
Funding Amount
$546,700.00
Summary
South Australian Facility for Advanced Molecular Imaging. The aim of this project is to establish the South Australian Facility for Advanced Molecular Imaging. The Facility builds on existing expertise and cooperation between the collaborating institutions to expand our capability in advanced analytical confocal microscopy of a wide range of materials from living cells to artificial surfaces. New state-of-the-art microscopes will allow the direct quantitative analysis of molecular interactions w ....South Australian Facility for Advanced Molecular Imaging. The aim of this project is to establish the South Australian Facility for Advanced Molecular Imaging. The Facility builds on existing expertise and cooperation between the collaborating institutions to expand our capability in advanced analytical confocal microscopy of a wide range of materials from living cells to artificial surfaces. New state-of-the-art microscopes will allow the direct quantitative analysis of molecular interactions with high temporal and spatial resolutions. This will advance: understanding the regulation of cellular signalling, gene expression and growth in normal and pathological conditions; development of biosensor technology; and the application of new biomaterials in medicine and industry.Read moreRead less
How filopodia connect macrophages to the outside world. Fundamental to life is the ability of cells to sense their surroundings and respond accordingly. This project aims to generate a biological understanding of how certain immune cells carry out such processes, thus enabling them to combat infections.
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
MOLECULAR BREEDING OF CYTOCHROME P450 ENZYMES. Cytochrome P450s are enzymes that catalyse an impressive array of oxidative transformations. However, there is little available data on how to modify their substrate specificity and generate tailored biocatalysts. We plan to use an emerging technology known as DNA shuffling to create libraries of P450s with varying activities. These will then be screened for enzymes that can catalyse the formation of indigo (a blue dye) and indirubin (a chemother ....MOLECULAR BREEDING OF CYTOCHROME P450 ENZYMES. Cytochrome P450s are enzymes that catalyse an impressive array of oxidative transformations. However, there is little available data on how to modify their substrate specificity and generate tailored biocatalysts. We plan to use an emerging technology known as DNA shuffling to create libraries of P450s with varying activities. These will then be screened for enzymes that can catalyse the formation of indigo (a blue dye) and indirubin (a chemotherapeutic agent). The enzymes that catalyse indigo formation will be useful in the production of coloured transgenic plants and those that produce indirubin will have a role in gene therapy.Read moreRead less
Development and use of novel technologies to improve drugs targeting G protein-coupled receptor complexes involved in disease. The purpose of this project is to develop and use new and innovative technologies to improve many of the drugs taken for a wide range of medical conditions. The expected outcomes are the discovery of better drugs and a greater understanding of the drugs currently on the market, particularly enabling improved management of side-effects.