Chemical staples and chemical probes to dissect dynamins cellular roles. Modulation of protein structure drives cellular function. Dynamin GTPase forms at least two macromolecular structures with different cellular functions. The drivers behind these different structures is unknown. In this project we will leverage our discoveries, and planned enhancements, of chemical biology probes that will modulate dynamin activity by inhibiting at three distinct sites, and one site that stimulates dynamin a ....Chemical staples and chemical probes to dissect dynamins cellular roles. Modulation of protein structure drives cellular function. Dynamin GTPase forms at least two macromolecular structures with different cellular functions. The drivers behind these different structures is unknown. In this project we will leverage our discoveries, and planned enhancements, of chemical biology probes that will modulate dynamin activity by inhibiting at three distinct sites, and one site that stimulates dynamin activity. It is known that Dynamin helices and rings are believed responsible for at least three in cell biological functions: in hormone, neutral and receptor internalisation; cellular mitosis and in actin dynamics. Prior to this work we have lacked the tools to understand the role of shape modulation of protein function.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE240100134
Funder
Australian Research Council
Funding Amount
$796,206.00
Summary
Super-resolution platform to accelerate biological and molecular research. This application aims to establish a new molecular analysis platform integrating a microfluid capillary electrophoresis interface directly to a mass spectrometer with advanced data scanning technology. This enables label-free detection, quantitation and characterisation of intact proteins, lipids and metabolites with unprecedented sensitivity, resolution and throughput. It will enhance ARC projects spanning natural produc ....Super-resolution platform to accelerate biological and molecular research. This application aims to establish a new molecular analysis platform integrating a microfluid capillary electrophoresis interface directly to a mass spectrometer with advanced data scanning technology. This enables label-free detection, quantitation and characterisation of intact proteins, lipids and metabolites with unprecedented sensitivity, resolution and throughput. It will enhance ARC projects spanning natural product discovery, biotechnology, agriculture, and animal, plant and marine biology, as well as single-cell proteomics, lipidomics and metabolomics. It will ensure Australia remains at the forefront of molecular and biological research and create new training and collaborative opportunities both nationally and internationally.Read moreRead less
Industrial Transformation Training Centres - Grant ID: IC230100046
Funder
Australian Research Council
Funding Amount
$5,000,000.00
Summary
ARC Training Centre for Radiochemical Technologies and Precision Radiopharmaceuticals. This project aims to train the next generation of radiochemists and discover new molecular approaches to harness radioactivity. Novel chemistry exploiting molecular incorporation of radioactive elements, stable chelation of metal radionuclides, bioconjugation methodologies, radioactivity capture via nanomaterials and cages, and the design of new peptidomimetic targeting molecules will deliver technological adv ....ARC Training Centre for Radiochemical Technologies and Precision Radiopharmaceuticals. This project aims to train the next generation of radiochemists and discover new molecular approaches to harness radioactivity. Novel chemistry exploiting molecular incorporation of radioactive elements, stable chelation of metal radionuclides, bioconjugation methodologies, radioactivity capture via nanomaterials and cages, and the design of new peptidomimetic targeting molecules will deliver technological advances to radiopharmaceutical science. Outcomes will include a highly-skilled workforce and enhanced commercial capacity to meet a rapidly escalating global radiopharmaceutical market. This project will provide significant benefits by securing an internal supply chain and know-how for cutting-edge radiochemical technologies.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230101236
Funder
Australian Research Council
Funding Amount
$444,154.00
Summary
Chimeric molecules for precision protein modification. This project aims to address fundamental questions on how natural modifications of proteins cause functional changes inside cells. The project expects to generate new knowledge in the areas of organic chemistry and chemical biology through the development of a synthetic platform for the discovery of a novel class of chimeric molecules that can trigger precise modifications of proteins. Expected outcomes include a detailed understanding of ho ....Chimeric molecules for precision protein modification. This project aims to address fundamental questions on how natural modifications of proteins cause functional changes inside cells. The project expects to generate new knowledge in the areas of organic chemistry and chemical biology through the development of a synthetic platform for the discovery of a novel class of chimeric molecules that can trigger precise modifications of proteins. Expected outcomes include a detailed understanding of how specific modifications modulate protein and cellular function. Significant benefits of this interdisciplinary project include access to a new class of molecules for basic research that may also find use for cell engineering applications within the growing biotechnology sector in Australia.Read moreRead less
Oxytocin receptor PET ligands: imaging the love receptor’s engagement. This project aims to develop a positron emission tomography (PET) ligand for the oxytocin receptor. This novel platform is significant as it will allow the scientific community to answer questions about the role of the oxytocin receptor in the important process of social behaviour which underlies quality of life. This knowledge gap has remained unanswered for decades due to the lack of specific techniques to measure oxytocin ....Oxytocin receptor PET ligands: imaging the love receptor’s engagement. This project aims to develop a positron emission tomography (PET) ligand for the oxytocin receptor. This novel platform is significant as it will allow the scientific community to answer questions about the role of the oxytocin receptor in the important process of social behaviour which underlies quality of life. This knowledge gap has remained unanswered for decades due to the lack of specific techniques to measure oxytocin receptor engagement. It is also significant as it will equip Australian startup Kinoxis Therapeutics to progress their molecules to market, a process enabled by measuring oxytocin receptor engagement. Our dual expertise on the oxytocin receptor and PET ligand development uniquely situate us to generate this technology.Read moreRead less