Molecular interactions in cell membranes. Cell membranes are a complex composite of proteins and lipids and we have only a rough idea about how they perform their many functions. Together with Leica Microsystems, this project will develop a new microscope that can map the molecular interactions within the membrane revealing details that have never been seen before.
Nutritional and bacterial influences on gut and peripheral homeostasis. Nutritional and bacterial influences on gut and peripheral homeostasis. This project aims to understand the role of macronutrients on gut homeostasis. While the understanding of what factors affect gut homeostasis is still in its infancy, scientists know that its disruption contributes to a broad range of inflammatory diseases, including type 1 diabetes and asthma. This project will determine the role of specific macronutrie ....Nutritional and bacterial influences on gut and peripheral homeostasis. Nutritional and bacterial influences on gut and peripheral homeostasis. This project aims to understand the role of macronutrients on gut homeostasis. While the understanding of what factors affect gut homeostasis is still in its infancy, scientists know that its disruption contributes to a broad range of inflammatory diseases, including type 1 diabetes and asthma. This project will determine the role of specific macronutrients on gut microbiota, gut epithelium, and immunity in mice, and the receptors involved. This research could ultimately lead to significant decreases in the cost of healthcare.Read moreRead less
Life at the nanometre scale: imaging immunological synapses with a novel super-resolution fluorescence microscope. This project aims to image individual proteins in activated white blood cells in order to understand how lymphocytes participate in an immune response. The problem is that current imaging modalities either lack resolution or are unsuitable for live cell and three-dimensional (3D) imaging. With the project’s industry partner, Carl Zeiss MicroImaging, the project will build and apply ....Life at the nanometre scale: imaging immunological synapses with a novel super-resolution fluorescence microscope. This project aims to image individual proteins in activated white blood cells in order to understand how lymphocytes participate in an immune response. The problem is that current imaging modalities either lack resolution or are unsuitable for live cell and three-dimensional (3D) imaging. With the project’s industry partner, Carl Zeiss MicroImaging, the project will build and apply a novel microscope that is capable of visualising single proteins in 3D and live cells. This technology will provide insights into signalling and lymphocyte function on a true molecular scale.Read moreRead less
Investigating the structure of a T cell immune checkpoint molecule. This project aims to investigate the basic structure and function of a key co-receptor expressed on T cells, known as lymphocyte activation gene-3. T cells play a role in the immune system but must be managed to prevent autoimmunity. Insight into the function of the lymphocyte activation gene-3 function can be used to tailor immunotherapeutics to treat a variety of diseases, including cancer. Functionality of the T cell recept ....Investigating the structure of a T cell immune checkpoint molecule. This project aims to investigate the basic structure and function of a key co-receptor expressed on T cells, known as lymphocyte activation gene-3. T cells play a role in the immune system but must be managed to prevent autoimmunity. Insight into the function of the lymphocyte activation gene-3 function can be used to tailor immunotherapeutics to treat a variety of diseases, including cancer. Functionality of the T cell receptor is determined by utilising structural biology and cellular immunology techniques. The impact of this project effects the development of innovative T cell immunomodulatory agents, improving the health and quality of life of the Australian population.Read moreRead less
Pharmacological probes to facilitate preclinical development of modulators of a6 subunit containing nicotinic acetylcholine receptors. Allosteric modulators of alpha7 nicotinic acetylcholine receptors have a promising future as drugs targeting attention deficits in Alzheimer’s disease and schizophrenia but the mechanisms underlying modulation are poorly understood. This project aims to determine its binding site and develop a radioactive labelled compound that competes with its binding. The radi ....Pharmacological probes to facilitate preclinical development of modulators of a6 subunit containing nicotinic acetylcholine receptors. Allosteric modulators of alpha7 nicotinic acetylcholine receptors have a promising future as drugs targeting attention deficits in Alzheimer’s disease and schizophrenia but the mechanisms underlying modulation are poorly understood. This project aims to determine its binding site and develop a radioactive labelled compound that competes with its binding. The radiolabelled compound and a deeper insight into the mode of action will enable development of ligands for positron emission tomography (PET) which will aid in the development of BNC375 as well as other alpha7 modulators.Read moreRead less
Modulating T cell responses with novel Lck activating compounds. Modulating T cell responses with novel Lck activating compounds. This project aims to research T cell receptor (TCR) signal initiation and network plasticity and identify uses for drugs that affect the kinase Lck. The TCR signalling network has considerable plasticity so that modulation of one molecule (here the drug target is Lck) can have non-linear effects on T cell function. This project intends to use novel drugs to understand ....Modulating T cell responses with novel Lck activating compounds. Modulating T cell responses with novel Lck activating compounds. This project aims to research T cell receptor (TCR) signal initiation and network plasticity and identify uses for drugs that affect the kinase Lck. The TCR signalling network has considerable plasticity so that modulation of one molecule (here the drug target is Lck) can have non-linear effects on T cell function. This project intends to use novel drugs to understand how the T cell network can be exploited to control both the magnitude and quality of the T cell responses. This research is expected to aid the design of immune-modulating drugs.Read moreRead less
An Open Source Approach to Understanding an Important Parasite Ion Pump. This project plans to synthesise new compounds that bind the protein ATP4, an essential ion pump in the malaria parasite. It plans to generate a three-dimensional map to understand how these compounds stop ATP4 from working. Several promising new medicines for malaria target ATP4, yet we do not understand properly how they do so. The project’s intended aims will be achieved using new methods in synthetic chemistry and membr ....An Open Source Approach to Understanding an Important Parasite Ion Pump. This project plans to synthesise new compounds that bind the protein ATP4, an essential ion pump in the malaria parasite. It plans to generate a three-dimensional map to understand how these compounds stop ATP4 from working. Several promising new medicines for malaria target ATP4, yet we do not understand properly how they do so. The project’s intended aims will be achieved using new methods in synthetic chemistry and membrane biology, and by leveraging global scientific inputs through online research methods allowing anyone to participate.Read moreRead less
Connecting the dots: Image analysis for single molecule localisation microscopy. It is now possible to record the positions of single fluorescent molecules in intact cells to build up an image literally molecule by molecule. But how to ‘connect the dots’ and extract structural information from molecular coordinates is yet to be worked out. The project aims to do exactly that, and write and implement novel analysis routines to quantify a diverse range of biological structures such as protein comp ....Connecting the dots: Image analysis for single molecule localisation microscopy. It is now possible to record the positions of single fluorescent molecules in intact cells to build up an image literally molecule by molecule. But how to ‘connect the dots’ and extract structural information from molecular coordinates is yet to be worked out. The project aims to do exactly that, and write and implement novel analysis routines to quantify a diverse range of biological structures such as protein complexes, membrane morphologies, filamentous cytoskeletal networks, vesicles and viruses. The project is a collaboration between a cell biologist (Professor Gaus) who is a leader in single molecule localisation microscopy, an expert in fluorescence image analysis (Dr Nicovich) and an industry partner (Dr Lucas) who has a sophisticated software platform.Read moreRead less