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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Biosynthesis and functions of two phytotoxins in Septoria nodorum blotch. This project aims to investigate how a fungal plant pathogen makes and uses small bioactive molecules to facilitate infection. It will characterise the function of the genes and enzymes involved in the biosynthesis of a light-activated phytotoxic molecule and a potential anti-plant defence molecule found in the pathogenic wheat fungus Parastagonospora nodorum, and investigate their contribution to disease development. Expe ....Biosynthesis and functions of two phytotoxins in Septoria nodorum blotch. This project aims to investigate how a fungal plant pathogen makes and uses small bioactive molecules to facilitate infection. It will characterise the function of the genes and enzymes involved in the biosynthesis of a light-activated phytotoxic molecule and a potential anti-plant defence molecule found in the pathogenic wheat fungus Parastagonospora nodorum, and investigate their contribution to disease development. Expected outcomes include better understanding of plant-microbe interactions, disease management strategies, technologies for identifying biosynthetic pathways in other fungi, and enzyme technology for synthesising molecules. This could lead to new herbicides, biopesticides and drugs.Read moreRead less
Fungal Ribosomally Synthesised and Post-translationally Modified Peptides. Fungi produce an array of molecules called secondary metabolites (SMs) that impact on everyday life (e.g. penicillin). This project aims to investigate a new class of fungal peptide SMs called RiPPs which are structurally unique from existing molecules and offer the exciting prospect of harbouring new and novel biological activities. This project expects to discover the mechanisms of RiPP synthesis and their biological ro ....Fungal Ribosomally Synthesised and Post-translationally Modified Peptides. Fungi produce an array of molecules called secondary metabolites (SMs) that impact on everyday life (e.g. penicillin). This project aims to investigate a new class of fungal peptide SMs called RiPPs which are structurally unique from existing molecules and offer the exciting prospect of harbouring new and novel biological activities. This project expects to discover the mechanisms of RiPP synthesis and their biological roles in plant pathogenic fungi, and uncover and engineer novel RiPPs with desired bioactivities. The expected outcome from this project will be a seminal advance in fungal SM biology which should provide significant benefits through the generation of exciting new lead molecules for the agricultural and medical industries.Read moreRead less
Understanding the Chemical Processes Involved in the Metabolism of Peptide Hormones. Peptide hormones regulate normal physiological activity in humans, and their over-production causes diseases such as cancer. The aims of this project are: to delineate the chemical processes through which these hormones are produced; to develop inhibitors of enzymes involved in hormone production, and agonists and antagonists of receptors through which the hormones act; and to study the ability of the inhibitors ....Understanding the Chemical Processes Involved in the Metabolism of Peptide Hormones. Peptide hormones regulate normal physiological activity in humans, and their over-production causes diseases such as cancer. The aims of this project are: to delineate the chemical processes through which these hormones are produced; to develop inhibitors of enzymes involved in hormone production, and agonists and antagonists of receptors through which the hormones act; and to study the ability of the inhibitors, agonists and antagonists to override and bypass the chemical control mechanisms through which hormone levels are usually maintained at homeostasis. The research is expected to lead to a better fundamental understanding of hormone metabolism, and to underpin the basis for the development of new disease therapies.Read moreRead less
Facilitating drug synthesis, development and detection: the enzymatic synthesis of beta-glucuronides. This project will develop new catalysts to aid the development of pharmaceuticals and help fight the war against drugs.
Harnessing molecular strain for drug discovery and bioconjugation. Peptides and proteins are increasingly important therapies for the treatment of disease. Nevertheless, the synthesis and optimisation of these high-value compounds still relies primarily on technologies developed decades ago. There is a desperate need for modern strategies to unlock the full potential of peptides and proteins for diverse applications in drug discovery. This interdisciplinary research aims to develop new tools for ....Harnessing molecular strain for drug discovery and bioconjugation. Peptides and proteins are increasingly important therapies for the treatment of disease. Nevertheless, the synthesis and optimisation of these high-value compounds still relies primarily on technologies developed decades ago. There is a desperate need for modern strategies to unlock the full potential of peptides and proteins for diverse applications in drug discovery. This interdisciplinary research aims to develop new tools for the construction and modification of peptides and proteins by harnessing the energy in a unique class of strained molecules. A focus on peptide-based inhibitors of the proteasome, a critical target for modern cancer treatments, should provide future health and economic benefits for the Australian community.Read moreRead less
New Protocols for the Chemical Synthesis of Biologically Relevant Systems. Enzyme- and metal-catalysed processes will be developed and exploited for the purpose of establishing concise syntheses of biologically active and otherwise inaccessible natural products and their analogues. The range of structures to be targeted is structurally diverse and these have the potential to act as agrochemicals and/or as therapeutic agents for the treatment of a range of disease states in mammals including bact ....New Protocols for the Chemical Synthesis of Biologically Relevant Systems. Enzyme- and metal-catalysed processes will be developed and exploited for the purpose of establishing concise syntheses of biologically active and otherwise inaccessible natural products and their analogues. The range of structures to be targeted is structurally diverse and these have the potential to act as agrochemicals and/or as therapeutic agents for the treatment of a range of disease states in mammals including bacterial and viral infections, neuro-degenerative conditions and impaired cognitive function. Anti-angiogenic compounds that control otherwise unregulated cellular growth may also arise from these studies. The generation of new, homochiral metabolites for use in chemoenzymatic synthesis should also emerge from this project.Read moreRead less
Harnessing strain for chemical synthesis: The cyclopropane angle. This project aims to develop new reaction pathways of cyclopropanes, the smallest and most strained monocyclic ring systems, but which are also stable and easily prepared. Cyclopropanes have unique capacities to serve as highly effective building blocks in the synthesis of a wide range of otherwise difficult to access and biologically active molecular frameworks. This project will use cyclopropanes to rapidly assemble biologically ....Harnessing strain for chemical synthesis: The cyclopropane angle. This project aims to develop new reaction pathways of cyclopropanes, the smallest and most strained monocyclic ring systems, but which are also stable and easily prepared. Cyclopropanes have unique capacities to serve as highly effective building blocks in the synthesis of a wide range of otherwise difficult to access and biologically active molecular frameworks. This project will use cyclopropanes to rapidly assemble biologically active systems, especially pharmaceutically or agrochemically valuable natural products and relevant analogues.Read moreRead less
Advances in Peptide Synthesis: Exploiting Underutilised Functional Groups. The translation of therapeutically-relevant classes of peptides to the clinic is often limited by chemists' ability to synthesise these complex biomolecules efficiently and sustainably. This project aims to develop new tools for the preparation of designer peptides that are broadly inspired by an underutilised reactive group found in naturally-occurring peptide sequences. Expected outcomes encompass health and economic be ....Advances in Peptide Synthesis: Exploiting Underutilised Functional Groups. The translation of therapeutically-relevant classes of peptides to the clinic is often limited by chemists' ability to synthesise these complex biomolecules efficiently and sustainably. This project aims to develop new tools for the preparation of designer peptides that are broadly inspired by an underutilised reactive group found in naturally-occurring peptide sequences. Expected outcomes encompass health and economic benefits for the Australian community, including: the first approach to a class of promising antibiotic peptide natural product analogues, the development of a mild electrochemical approach to peptide modification, and the production of a library of novel amino acids for incorporation into potential antibiotic leads.Read moreRead less