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Linkage Infrastructure, Equipment And Facilities - Grant ID: LE200100140
Funder
Australian Research Council
Funding Amount
$945,000.00
Summary
An integrated, multi-nodal bio-layer interferometry facility. Biomolecular interaction research in Australia is currently constrained by low-throughput, labor intensive techniques that impede research progress and often forces it overseas. This project aims to develop a world-class, integrated, multi-node bio-layer interferometry facility. This project expects to generate new knowledge in diverse areas of research ranging from biodiscovery to agricultural vaccine technology. Using biolayer inte ....An integrated, multi-nodal bio-layer interferometry facility. Biomolecular interaction research in Australia is currently constrained by low-throughput, labor intensive techniques that impede research progress and often forces it overseas. This project aims to develop a world-class, integrated, multi-node bio-layer interferometry facility. This project expects to generate new knowledge in diverse areas of research ranging from biodiscovery to agricultural vaccine technology. Using biolayer interferometry, the leading-edge biomolecular interaction technique will provide significant benefits by developing high-throughput assay techniques, thus enabling diverse streams of national benefit research and propelling Australia to the forefront of biomolecular interaction research.Read moreRead less
Retromer directs membrane protein trafficking within the endosome. The exposure of proteins to the extracellular environment is dependent on how the travel through the various regions of the cell. The work will lead to a richer understanding of how this process is regulated by protein complexes. These complexes act within cells to drive the formation of membrane transport tubules containing cargo molecules.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100150
Funder
Australian Research Council
Funding Amount
$500,000.00
Summary
Beyond Proteomics: structure and function of protein modifications. The world's leading cancer therapeutics have come from the protein phosphorylation field, and glycomics has led to drugs that combat the flu and that stimulate red blood cell production in cancer patients. Thus there is a bright future for discovery of new medicines based on new knowledge in this area. Protein modifications are key to the understanding of disease mechanisms and for searching for new disease markers and new the ....Beyond Proteomics: structure and function of protein modifications. The world's leading cancer therapeutics have come from the protein phosphorylation field, and glycomics has led to drugs that combat the flu and that stimulate red blood cell production in cancer patients. Thus there is a bright future for discovery of new medicines based on new knowledge in this area. Protein modifications are key to the understanding of disease mechanisms and for searching for new disease markers and new therapeutics. In the hands of local experts the instruments will enable identification of these modifications and provide improved understanding of biology, increase the national competitiveness of Australia's scientists, and provide advanced technology training to the next generation of scientists.Read moreRead less
Making muscle: molecular dissection of membrane domain formation. For a muscle to contract efficiently in response to an electrical signal it requires the formation of an extensive system of hollow membranous tubules through which the signal can be propagated. This proposal addresses the molecular mechanisms involved in the formation of this tubule system in skeletal muscle. This project will develop cell biology in a whole organism rather than a cell culture system and provide a new framework f ....Making muscle: molecular dissection of membrane domain formation. For a muscle to contract efficiently in response to an electrical signal it requires the formation of an extensive system of hollow membranous tubules through which the signal can be propagated. This proposal addresses the molecular mechanisms involved in the formation of this tubule system in skeletal muscle. This project will develop cell biology in a whole organism rather than a cell culture system and provide a new framework for Australian and international cell biologists. It will generate new knowledge, train young Australian scientists, help build international collaborative networks and engage the public outside the research community.Read moreRead less
The core inflammasome as a model for caspase activation. This project aims to change the paradigm for the structure of the active inflammasome. Inflammasomes activate caspases, enzymes central to cell death and inflammatory processes. The current concept of inflammasomes is that caspases are recruited into a single massive protein complex seen as a “speck” in the cell. This project proposes the speck is a terminal stage, after the major enzymatic activity is over. This project aims to purify sma ....The core inflammasome as a model for caspase activation. This project aims to change the paradigm for the structure of the active inflammasome. Inflammasomes activate caspases, enzymes central to cell death and inflammatory processes. The current concept of inflammasomes is that caspases are recruited into a single massive protein complex seen as a “speck” in the cell. This project proposes the speck is a terminal stage, after the major enzymatic activity is over. This project aims to purify smaller early stage inflammasome complexes, for structural analysis. The outcome will be a clearer understanding of processes of caspase activation and inflammasome formation. This will provide significant benefits, such as improve our understanding of processes of cell death and innate immunity, and train students.Read moreRead less
Development of technologies to monitor multimolecular complexes. Development of technologies to monitor multimolecular complexes. This project aims to develop technologies to monitor how proteins and their interacting molecules (such as hormones) form multi-component complexes, and how these complexes function in the cell, including movement from the cell surface, into different cellular compartments and back up to the surface. These technologies are expected to enable monitoring in live cells i ....Development of technologies to monitor multimolecular complexes. Development of technologies to monitor multimolecular complexes. This project aims to develop technologies to monitor how proteins and their interacting molecules (such as hormones) form multi-component complexes, and how these complexes function in the cell, including movement from the cell surface, into different cellular compartments and back up to the surface. These technologies are expected to enable monitoring in live cells in real-time with high sensitivity. This project could have broad benefits for and affect study of all aspects of the life sciences at the cellular and molecular levels. How these protein complexes function in cells underpins much of our understanding of biology, and technological tools.Read moreRead less
An integrated nano-bioengineered chip for enhanced molecular evolution. This project aims to develop a novel molecular evolution platform technology for the rapid selection of high value target binding molecules from diverse molecular libraries using an electrically activated nanofluidic chip coated with target. Significant outcomes from the project is the controlled selection of target binding molecules that is not possible with current methods and improved understanding of nanoforce driven mol ....An integrated nano-bioengineered chip for enhanced molecular evolution. This project aims to develop a novel molecular evolution platform technology for the rapid selection of high value target binding molecules from diverse molecular libraries using an electrically activated nanofluidic chip coated with target. Significant outcomes from the project is the controlled selection of target binding molecules that is not possible with current methods and improved understanding of nanoforce driven molecular collisions on nano-bioengineered surfaces. This provides significant benefits, creating new knowledge in nanomaterials and advanced manufacturing of nanofabricated devices, creating commercial interest and positioning Australia at the forefront of molecular discovery technology, a highly valuable global market.
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Imaging the world of miniature venomous arthropods. Venomous arthropods produce a myriad of biologically active peptides, with many having potential as pharmacological tools, bioinsecticides and pharmaceuticals. Most studies to date have focussed on large arthropods; smaller species remain neglected due to the difficulties of venom collection. This project seeks to further advance the pioneering imaging mass spectrometry approaches the project team developed for imaging toxins in the venom gland ....Imaging the world of miniature venomous arthropods. Venomous arthropods produce a myriad of biologically active peptides, with many having potential as pharmacological tools, bioinsecticides and pharmaceuticals. Most studies to date have focussed on large arthropods; smaller species remain neglected due to the difficulties of venom collection. This project seeks to further advance the pioneering imaging mass spectrometry approaches the project team developed for imaging toxins in the venom glands of spiders and centipedes. By combining high-resolution matrix-assisted laser desorption ionisation imaging data with histological and transcriptomic information the project aims to provide the first detailed insights into the neglected world of miniature arthropod venoms. The approaches developed by this project aim to have wide application in the field of biology.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120102857
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Innovative chemical tools for the isolation, biochemical and structural analysis of biological macromolecular assemblies. This project will develop a new approach for determining the three dimensional structures of protein complexes. This project will demonstrate this approach by determining the structure of a protein complex involved in gene regulation and disease.
Moonlighting from sugar to metal. This project intends to use integrated genetics, biochemistry and omics to decipher the roles of the highly conserved OST3 proteins, which have been implicated in the disparate functions of regulating protein glycosylation and transporting magnesium. The project plans to detail the role of OST3 proteins in regulating mammalian glycosylation and reconstruct the vertebrate co-evolutionary trajectory of OST3 protein–substrate interactions. It also aims to identify ....Moonlighting from sugar to metal. This project intends to use integrated genetics, biochemistry and omics to decipher the roles of the highly conserved OST3 proteins, which have been implicated in the disparate functions of regulating protein glycosylation and transporting magnesium. The project plans to detail the role of OST3 proteins in regulating mammalian glycosylation and reconstruct the vertebrate co-evolutionary trajectory of OST3 protein–substrate interactions. It also aims to identify and characterise the regulation, mechanisms and metabolic consequences of OST3 protein-mediated magnesium transport. These outcomes may provide insights into eukaryotic biology, and allow advances in engineered systems for glycoprotein production and modulating cellular metabolism with potential research and therapeutic utility.Read moreRead less