Biogenesis inspired total synthesis of natural products. The project will study the chemical synthesis of a number of novel natural products. Most significantly, this project will deliver new methods for organic synthesis of complex molecules. The rewards from the total synthesis of bioactive compounds are enormous for the community and in the education and training of scientists.
Control of immune recognition and response by microbial metabolites. This project aims to study immune recognition of microbial metabolites and develop reagents to control immune responses. Chemical synthesis will be used to develop new antigens for unconventional T cells and the first soluble agonists and antagonists of a glycolipid-sensing immune receptor. Expected outcomes include the discovery of new immune effectors, broadening our knowledge of the repertoire of small molecules that can be ....Control of immune recognition and response by microbial metabolites. This project aims to study immune recognition of microbial metabolites and develop reagents to control immune responses. Chemical synthesis will be used to develop new antigens for unconventional T cells and the first soluble agonists and antagonists of a glycolipid-sensing immune receptor. Expected outcomes include the discovery of new immune effectors, broadening our knowledge of the repertoire of small molecules that can be sensed by the immune system, and developing chemical approaches to promote or dampen immune responses. Major benefits include research training in chemical biology, strengthened international linkages and fundamental insights into the chemical basis of immune recognition and response.Read moreRead less
Using chemistry to illuminate sulfoglycolysis, a major organosulfur pathway. This project aims to develop a detailed molecular description of the sulfoglycolysis pathway, a major pathway involved in cycling an abundant sulfolipid. The project will use an integrated chemical, biochemical and structural approach to illuminate how sulfoglycolysis degrades sulfolipid to access its elemental and energy constituents. Expected outcomes include an advanced understanding of the biosulfur cycle, the devel ....Using chemistry to illuminate sulfoglycolysis, a major organosulfur pathway. This project aims to develop a detailed molecular description of the sulfoglycolysis pathway, a major pathway involved in cycling an abundant sulfolipid. The project will use an integrated chemical, biochemical and structural approach to illuminate how sulfoglycolysis degrades sulfolipid to access its elemental and energy constituents. Expected outcomes include an advanced understanding of the biosulfur cycle, the development of new chemical approaches to manipulate sulfur cycling for agricultural and biotechnology applications, and deepened ties to leading international researchers. Potential benefits include new strategies to reduce dependence on agricultural fertilisers, promote gut wellbeing, and control insect pests.Read moreRead less
Total Synthesis of Myxobacteria Metabolites and Analogues. This project will investigate the total chemical synthesis of complex myxobacteria metabolites. In addition, the synthesis of new analogues of some of these natural products will also be investigated. The project endeavours to develop new methods for chemical synthesis and also to produce new therapeutic products which may possess greater efficacy and superior biological activities than the natural compounds. Most significantly, this pro ....Total Synthesis of Myxobacteria Metabolites and Analogues. This project will investigate the total chemical synthesis of complex myxobacteria metabolites. In addition, the synthesis of new analogues of some of these natural products will also be investigated. The project endeavours to develop new methods for chemical synthesis and also to produce new therapeutic products which may possess greater efficacy and superior biological activities than the natural compounds. Most significantly, this project will deliver natural and new compounds for analysis of anti-cancer activity. The rewards of the development of new synthetic methods are enormous for the community and in the education of our scientists.Read moreRead less
Chemical probes for the study of a unique enzyme from Mycobacterium tuberculosis. The design and chemical synthesis of molecules that selectively inhibit pathogen-specific enzymes is a validated approach toward new therapeutic agents. Mycobacterium tuberculosis contains a unique cytochrome P450 enzyme that catalyses an unusual chemical transformation to generate the product mycocyclosin. This research project will synthesise chemical probes to study the mechanism of this enzyme and the biologica ....Chemical probes for the study of a unique enzyme from Mycobacterium tuberculosis. The design and chemical synthesis of molecules that selectively inhibit pathogen-specific enzymes is a validated approach toward new therapeutic agents. Mycobacterium tuberculosis contains a unique cytochrome P450 enzyme that catalyses an unusual chemical transformation to generate the product mycocyclosin. This research project will synthesise chemical probes to study the mechanism of this enzyme and the biological role of mycocyclosin. Selective inhibitors of the enzyme will be developed, which will provide a foundation for the exploitation of these molecules in cellular research and medicine.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130101673
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Access to biomimetic carbohydrate receptors using dynamic combinatorial chemistry. This project aims to utilise novel synthetic technology for the development of cyclic peptide libraries as novel drug leads for the treatment of Dengue virus, HIV and cancer.
Unravelling the immunology of complex glycolipids by chemical synthesis. This project seeks to develop new approaches to chemically synthesise bacterial and fungal glycolipids and develop a molecular-level understanding of their effect on the immune system. Bacterial and fungal glycolipids are exotic chemical species that act as danger signals to prime and modulate our innate immune responses. These complex glycolipids possess powerful immunological activities that continue to shape our understa ....Unravelling the immunology of complex glycolipids by chemical synthesis. This project seeks to develop new approaches to chemically synthesise bacterial and fungal glycolipids and develop a molecular-level understanding of their effect on the immune system. Bacterial and fungal glycolipids are exotic chemical species that act as danger signals to prime and modulate our innate immune responses. These complex glycolipids possess powerful immunological activities that continue to shape our understanding of innate immunity, yet cannot be acquired from natural sources in the quantities and purity needed. The approaches expected to be developed in the project will be used to illuminate molecular details of immune signalling through pattern recognition receptors and presentation on specialised glycolipid antigen-presenting molecules. Outcomes may include new ways to fight disease and promote health by marshalling the resources of the immune system.Read moreRead less
Dissecting a major sulfur cycling pathway: sulfoglycolysis. This project will elucidate the molecular details of sulfoglycolysis, a group of metabolic pathways through which the sulfur-containing sugar sulfoquinovose is catabolized. The project will employ an integrated metabolomic, chemical, biochemical and structural approach to dissect how various sulfoglycolytic organisms degrade sulfoquinovose. This project will deliver a deeper understanding of this major biochemical pathway and develop ne ....Dissecting a major sulfur cycling pathway: sulfoglycolysis. This project will elucidate the molecular details of sulfoglycolysis, a group of metabolic pathways through which the sulfur-containing sugar sulfoquinovose is catabolized. The project will employ an integrated metabolomic, chemical, biochemical and structural approach to dissect how various sulfoglycolytic organisms degrade sulfoquinovose. This project will deliver a deeper understanding of this major biochemical pathway and develop new chemical and metabolic approaches to manipulate sulfur cycling in the environment. Benefits will include biotechnology applications of newly discovered proteins, and sustainable approaches to reduce our dependence on agricultural fertilisers.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE160100120
Funder
Australian Research Council
Funding Amount
$800,000.00
Summary
Dynamic Nuclear Polarisation system for molecular structure determination. Dynamic nuclear polarisation system for molecular structure determination:
This project aims to establish the first dynamic nuclear polarisation (DNP) spectrometer in Australia. DNP is designed to enhance the sensitivity of nuclear magnetic resonance techniques for molecular structure determination. The instrumentation would enable advancements in the biological and material sciences by providing enhanced sensitivity to ....Dynamic Nuclear Polarisation system for molecular structure determination. Dynamic nuclear polarisation system for molecular structure determination:
This project aims to establish the first dynamic nuclear polarisation (DNP) spectrometer in Australia. DNP is designed to enhance the sensitivity of nuclear magnetic resonance techniques for molecular structure determination. The instrumentation would enable advancements in the biological and material sciences by providing enhanced sensitivity to allow biomolecular and in-cell structure determination and the characterisation of new advanced materials. The facility is expected to drive interdisciplinary research and bring together scientific expertise that will accelerate advances in biomedical science, biochemistry, forensic science and security, polymers and nano-electronics.Read moreRead less
New methodology for the manufacture of opioid pharmaceuticals and the discovery of novel opiate receptor ligands. Semi-synthetic opiates are important analgesic agents and are used in the treatment of alcohol and opiate dependence. This project will focus on the application of new, greener and more efficient methods for the preparation of these medicinal agents.