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Australian Laureate Fellowships - Grant ID: FL170100019
Funder
Australian Research Council
Funding Amount
$2,606,250.00
Summary
Proteins in motion - new tools for biotechnology. This project aims to assess the function of proteins by monitoring their motions using new nuclear magnetic resonance (NMR) spectroscopy techniques. As snapshots of 3D protein structures have been determined by crystallography, the new tools are designed to analyse functionally important motions in solution. A facility for ultrafast (> 100 kHz) magic angle spinning NMR spectroscopy of proteins in the semi-solid state will bring cutting-edge know- ....Proteins in motion - new tools for biotechnology. This project aims to assess the function of proteins by monitoring their motions using new nuclear magnetic resonance (NMR) spectroscopy techniques. As snapshots of 3D protein structures have been determined by crystallography, the new tools are designed to analyse functionally important motions in solution. A facility for ultrafast (> 100 kHz) magic angle spinning NMR spectroscopy of proteins in the semi-solid state will bring cutting-edge know-how to Australia and allow the interrogation of 3D structure and dynamics in selected protein regions. The expected outcomes of the project will have immediate benefits for the rational engineering of biocatalysts and in the design of lead compounds in drug development.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100026
Funder
Australian Research Council
Funding Amount
$178,839.00
Summary
Ultrafast magic angle spinning solid-state nuclear magnetic resonance capability. This project aims to extend an existing nuclear magnetic resonance (NMR) spectrometer for structural investigations of proteins in the solid state. Many proteins, such as amyloids and flexible proteins, cannot be studied by X-ray crystallography, solution NMR spectroscopy or cryoelectron microscopy, because they cannot be crystallised or are not sufficiently soluble, or are structurally too heterogeneous. This proj ....Ultrafast magic angle spinning solid-state nuclear magnetic resonance capability. This project aims to extend an existing nuclear magnetic resonance (NMR) spectrometer for structural investigations of proteins in the solid state. Many proteins, such as amyloids and flexible proteins, cannot be studied by X-ray crystallography, solution NMR spectroscopy or cryoelectron microscopy, because they cannot be crystallised or are not sufficiently soluble, or are structurally too heterogeneous. This project will extend the capability of an existing 800 MHz NMR spectrometer to solid-state NMR. By offering ultrafast magic angle spinning speeds, the system aims to afford greatly enhanced sensitivity and multidimensional NMR spectra of protein systems not previously amenable to structural analysis by NMR spectroscopy or other techniques. This will have important applications in biotechnology and biomedicine.Read moreRead less
A genomic and phenomic investigation of a mitochondrial glutathione transferase. The aim of this study is to understand of the genomics, structure and function of glutathione transferase Kappa (GSTK), a novel GST found in mitochondria. The investigations will achieve several outcomes. (1)an understanding of the organisation of GSTK gene(s) in humans and mice; (2) determination of the role of GSTK in mitochondria, by investigating the phenotype of knockout mice; (3) determination of the crysta ....A genomic and phenomic investigation of a mitochondrial glutathione transferase. The aim of this study is to understand of the genomics, structure and function of glutathione transferase Kappa (GSTK), a novel GST found in mitochondria. The investigations will achieve several outcomes. (1)an understanding of the organisation of GSTK gene(s) in humans and mice; (2) determination of the role of GSTK in mitochondria, by investigating the phenotype of knockout mice; (3) determination of the crystal structure of human GSTK; (4) An understanding of GSTK's substrate specificity, reaction kinetics and structure/function relationships. Since GSTK is confined to mitochondria, and may not be related to other GSTs, we may also identify novel functionsRead moreRead less
The hidden secondary metabolite biosynthetic potential of fungi. This proposal aims to develop synthetic biology tools to allow rapid access to the hidden metabolites encoded in fungal genomes and discover how they interact with plant and animal hosts. Genome sequencing reveals that fungi harbour vast hidden potential for biosynthesis of bioactive small molecules. The lack of tools to efficiently access this hidden potential has hindered the ability to develop this uncharted chemical diversity f ....The hidden secondary metabolite biosynthetic potential of fungi. This proposal aims to develop synthetic biology tools to allow rapid access to the hidden metabolites encoded in fungal genomes and discover how they interact with plant and animal hosts. Genome sequencing reveals that fungi harbour vast hidden potential for biosynthesis of bioactive small molecules. The lack of tools to efficiently access this hidden potential has hindered the ability to develop this uncharted chemical diversity for pharmaceutics and agriculture, and understand their biological roles in pathogens. Expected outcomes include sources of bioactive molecules and better management of fungal diseases in crops and humans.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
Tags and algorithms for studies of protein structures and interactions. This project aims to develop a new set of tools to structurally characterise protein-protein and protein-ligand interactions that are difficult or impossible to analyse by other means, facilitate tracking of proteins in biological material and identify interaction partners. The project seeks to focus on the synthesis of new unnatural amino acids and tags for site-specific protein labelling, and a range of techniques for 3D s ....Tags and algorithms for studies of protein structures and interactions. This project aims to develop a new set of tools to structurally characterise protein-protein and protein-ligand interactions that are difficult or impossible to analyse by other means, facilitate tracking of proteins in biological material and identify interaction partners. The project seeks to focus on the synthesis of new unnatural amino acids and tags for site-specific protein labelling, and a range of techniques for 3D structure analysis in solution, in particular NMR spectroscopy. New algorithms are expected to be developed for optimizing NMR spectroscopy and structure calculations from sparse data. The integrated set of tools is expected to deliver better and faster structure analysis and target characterisation to accelerate early stages of drug discovery.Read moreRead less
New methods for drug discovery by NMR spectroscopy. This project aims to advance nuclear magnetic resonance (NMR) spectroscopy methods in the field of drug discovery. It addresses a long-standing bottleneck for medicinal chemists in drug development: the rapid determination of how ligand molecules bind to proteins, where they bind and their orientation in the binding site. The methods include techniques for the attachment of NMR tags to ligands and target proteins, installation of new unnatural ....New methods for drug discovery by NMR spectroscopy. This project aims to advance nuclear magnetic resonance (NMR) spectroscopy methods in the field of drug discovery. It addresses a long-standing bottleneck for medicinal chemists in drug development: the rapid determination of how ligand molecules bind to proteins, where they bind and their orientation in the binding site. The methods include techniques for the attachment of NMR tags to ligands and target proteins, installation of new unnatural amino acids in proteins, and software for automated assignment of NMR spectra and 3D structure modelling of proteins using sparse distance restraints measured by electron paramagnetic resonance (EPR) spectroscopy. The outcome is to benefit the early stages of drug discovery in the biotech industries.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100085
Funder
Australian Research Council
Funding Amount
$450,000.00
Summary
Regional facility for macromolecular x-ray crystallography. This facility in the southern NSW/ACT region will allow research into structures of biological molecules. Research at the facility will contribute to advances in understanding of processes in living organisms, new drugs and new biotechnology with national and international significance.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100027
Funder
Australian Research Council
Funding Amount
$320,000.00
Summary
Sensitive and multinuclear: a dedicated facility for high-throughput characterisation of small molecules. This project will provide new cutting edge nuclear magnetic resonance equipment will enhance an existing shared analysis facility based at University of New South Wales. The new equipment will underpin research in polymers, neuropharmacology, the biological basis of inherited disease, nanomedicine, bioactive compounds and toxins.