Mixing the jigsaw pieces of natural products: new molecules-new properties. This project aims to examine the capacity of exploiting the bacterial biosynthetic machinery to fast-track access to analogues of natural products. Due to increased drug resistance, new reservoirs of natural products are needed for evaluation as future drugs. Desferrioxamine B will be used as a model natural product to establish the biosynthesis of new analogues in bacterial culture supplemented with unsaturated, fluorin ....Mixing the jigsaw pieces of natural products: new molecules-new properties. This project aims to examine the capacity of exploiting the bacterial biosynthetic machinery to fast-track access to analogues of natural products. Due to increased drug resistance, new reservoirs of natural products are needed for evaluation as future drugs. Desferrioxamine B will be used as a model natural product to establish the biosynthesis of new analogues in bacterial culture supplemented with unsaturated, fluorinated or deuterated building blocks. The intended outcomes are to deliver advances in methods for generating structurally diverse pools of natural products, new label-free probes, knowledge of natural product biosynthesis, and excellence in training research students in frontier methods in chemical biology and drug discovery.Read moreRead less
Escaping Bio-Assay Guided Isolation: Nature's Tools for Chemical Biology. The project aims to transform the approach to identify novel biologically active compounds that occur in nature. For decades, natural product chemistry has centred on bio-assay guided isolation, but it has become increasingly difficult to isolate novel compounds. While de-replication strategies detect the presence of known compounds using databases, more impact would be achieved by directly detecting novel compounds. Nucle ....Escaping Bio-Assay Guided Isolation: Nature's Tools for Chemical Biology. The project aims to transform the approach to identify novel biologically active compounds that occur in nature. For decades, natural product chemistry has centred on bio-assay guided isolation, but it has become increasingly difficult to isolate novel compounds. While de-replication strategies detect the presence of known compounds using databases, more impact would be achieved by directly detecting novel compounds. Nuclear magnetic resonance (NMR) spectroscopy detects every molecule that has a proton and is quantitative. This project plans to develop a NMR technique to escape bio-assay guided isolation by analysing a fraction library. Biotechnology innovation is dependent on novel compounds to provide new products. Replacing ‘grind and find’ with a technique that never lies would be transformational.Read moreRead less
Fragment based screening to deliver drugs targeting tuberculosis and the gametocyte and liver stages of Plasmodium. This project will identify natural products that bind to critical proteins in malaria and tuberculosis to discover new ways to treat these diseases.
New antibiotics: engaging microbial chemical diversity. This project will explore Australian microbial biodiversity, to detect, isolate and identify new natural chemicals with potent and selective antibacterial properties. Knowledge of these molecules will inspire and inform the development of new classes of antibiotic, effective against multi-drug resistant infections.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100148
Funder
Australian Research Council
Funding Amount
$1,350,000.00
Summary
Advanced Nuclear Magnetic Resonance Technologies for Southeast Queensland. This project aims to establish an advanced Nuclear Magnetic Resonance capability and capacity at two of Queenslands' leading research intensive universities. The project expects to enhance the scope and productivity of hundreds of research projects spanning natural products, synthetic, medicinal, materials and environmental science. Expected outcomes include smarter science, more productive collaborations and superior res ....Advanced Nuclear Magnetic Resonance Technologies for Southeast Queensland. This project aims to establish an advanced Nuclear Magnetic Resonance capability and capacity at two of Queenslands' leading research intensive universities. The project expects to enhance the scope and productivity of hundreds of research projects spanning natural products, synthetic, medicinal, materials and environmental science. Expected outcomes include smarter science, more productive collaborations and superior research training, leading to innovative solutions to challenging problems that confront science and society. This investment should provide significant benefits in the form of new knowledge across multiple disciplines, informing the design of future medicines, agrochemicals, materials and other products.
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Towards an influenza virus glycan interaction map (Glycointeractome). This project will use nuclear magnetic resonance (NMR) spectroscopy to map carbohydrate interaction used by the virus to cause infection and spread. This information will provide new direction in anti-influenza drug discovery.
Growing a sustainable new molecular resource. This project will provide access to a unique and unexplored Australian molecular resource pre-programmed by evolution for therapeutic potential. These discoveries will enable important biomedical research and advance the development of new improved drugs that treat a diverse array of human diseases and illness.
Sulfoxide Polymers - A New Paradigm in Polymer Design. Low fouling polymers are important for moderating interactions of molecules and particles with cells. In pharmaceutical sciences they are essential tools for extending the pharmacokinetics of dissolved drugs. However, the widely-used low-fouling polymer, poly(ethylene glycol) (PEG) has been recently reported to induce formation of anti-PEG antibodies. Polymeric alternatives to PEG are thus desperately needed. We introduce in this project sup ....Sulfoxide Polymers - A New Paradigm in Polymer Design. Low fouling polymers are important for moderating interactions of molecules and particles with cells. In pharmaceutical sciences they are essential tools for extending the pharmacokinetics of dissolved drugs. However, the widely-used low-fouling polymer, poly(ethylene glycol) (PEG) has been recently reported to induce formation of anti-PEG antibodies. Polymeric alternatives to PEG are thus desperately needed. We introduce in this project super-hydrophilic polymers incorporating sulfoxide groups, mimics of the polar solvent DMSO. The project aims to explore how polymer architecture can enhance biocompatibility and reduce biofouling. The outcome will be a new class of low-fouling polymeric materials with broad application in the biosciences.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100119
Funder
Australian Research Council
Funding Amount
$2,000,000.00
Summary
Regional nuclear magnetic resonance infrastructure network for South East Queensland and Northern New South Wales. Nuclear magnetic resonance infrastructure network: This project will provide support for a nuclear magnetic infrastructure network for use by researchers across five universities. The infrastructure will provide capability for small molecule-based research and will enable cutting-edge scientific collaborative research opportunities.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100170
Funder
Australian Research Council
Funding Amount
$580,000.00
Summary
Bioaffinity mass spectrometry infrastructure to identify small molecules binding to therapeutic targets. The development of anti-infective therapies is challenging because the underlying biology and biochemistry of pathogen virulence is not yet completely understood. This mass spectrometer facility will be used to identify small molecules suited for development into new therapies for malaria, tuberculosis and HIV.