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Statistical analyses for spatial organisation in T cell signalling networks. This project aims to reveal how nanoscale spatial organisation encodes plasticity in the T cell signalling network, and how T cells exploit this plasticity to regulate sensitivity to antigens. In adoptive immunity, T cells respond appropriately to any given antigen, but how they make decisions is unclear. This project will define how nanoscale spatial organisation of signalling molecules shapes signalling strength and p ....Statistical analyses for spatial organisation in T cell signalling networks. This project aims to reveal how nanoscale spatial organisation encodes plasticity in the T cell signalling network, and how T cells exploit this plasticity to regulate sensitivity to antigens. In adoptive immunity, T cells respond appropriately to any given antigen, but how they make decisions is unclear. This project will define how nanoscale spatial organisation of signalling molecules shapes signalling strength and plasticity in the T cell antigen receptor (TCR) network; and infer rules linking spatial organisation and signalling activities in intact T cells. Contextualising the TCR signalling network is expected to reveal the origin and use of network plasticity for T cell decision-making. Such information could be invaluable for the design of vaccines and immune-modulating drugs.Read moreRead less
Spatio-temporal modelling of Ras dependent MAP kinase activation. This project is at the heart of the national research priority 'Frontier Technologies for Building and Transforming Australian Industries'. Using cutting edge methods and techniques of systems biology, coupled with innovative experimental molecular cell biology we will construct and simulate mathematical models of the EGF-regulated MAP kinase pathway. The project will yield new insights into the fundamental mechanisms of cell sign ....Spatio-temporal modelling of Ras dependent MAP kinase activation. This project is at the heart of the national research priority 'Frontier Technologies for Building and Transforming Australian Industries'. Using cutting edge methods and techniques of systems biology, coupled with innovative experimental molecular cell biology we will construct and simulate mathematical models of the EGF-regulated MAP kinase pathway. The project will yield new insights into the fundamental mechanisms of cell signal transduction that drive cell division, differentiation and transformation and may enable the design of new anticancer therapies. Importantly, the modelling and simulation methods developed in the project will have a general applicability to other complex systems such as sustainable ecological systems.Read moreRead less
Multiscale stochastic modelling of tumour robustness. This project will develop cutting-edge modelling methodologies of systems biology and innovative experimental techniques to investigate the principles of tumour initiation and progression, which lay at the heart of the national research priority Frontier Technologies for Building and Transforming Australian Industries. The primary outcome will be fundamental new paradigms explaining tumour initiation, cancer disease progression and the evolut ....Multiscale stochastic modelling of tumour robustness. This project will develop cutting-edge modelling methodologies of systems biology and innovative experimental techniques to investigate the principles of tumour initiation and progression, which lay at the heart of the national research priority Frontier Technologies for Building and Transforming Australian Industries. The primary outcome will be fundamental new paradigms explaining tumour initiation, cancer disease progression and the evolution of therapy resistance. The deep insights gained in this research have the potential for the optimal treatment strategies of cancer diseases, which is strongly relevant to promoting and maintaining good health for Australians.Read moreRead less
The biosynthesis and evolution of novel semiochemicals in orchids. This project aims to discover new enzymes and genes, unlocking new tools for producing useful chemicals. Many plants secure pollination by attracting animal pollinators. How these crucial interactions evolved remains a mystery. Australia is a world centre for pollination by sexual deception in which hundreds of orchids use novel semiochemicals to sexually attract specific pollinators. In this study we aim to: characterise the bio ....The biosynthesis and evolution of novel semiochemicals in orchids. This project aims to discover new enzymes and genes, unlocking new tools for producing useful chemicals. Many plants secure pollination by attracting animal pollinators. How these crucial interactions evolved remains a mystery. Australia is a world centre for pollination by sexual deception in which hundreds of orchids use novel semiochemicals to sexually attract specific pollinators. In this study we aim to: characterise the biosynthetic pathway and molecular basis of these unique semiochemicals; investigate speciation processes with robust orchid phylogenies; and reveal new insights into the evolution of animal pollination. This should also lead to better design options for managing endangered orchids and developing resilient populations.Read moreRead less
Active Transport Of Calcium Across Dental Enamel Cells - Testing A New Paradigm
Funder
National Health and Medical Research Council
Funding Amount
$258,000.00
Summary
Dental enamel defects and tooth loss affect over half our population, resulting in substantial suffering and economic costs. It is likely that many enamel defects could be prevented, and replacement teeth made more lifelike, if more was known about the cells responsible for producing enamel. A particular problem is our lack of understanding about how enamel-forming cells avoid overdosing on calcium, which can lead to cellular toxicity. The overall aim of this research is to use the latest cell b ....Dental enamel defects and tooth loss affect over half our population, resulting in substantial suffering and economic costs. It is likely that many enamel defects could be prevented, and replacement teeth made more lifelike, if more was known about the cells responsible for producing enamel. A particular problem is our lack of understanding about how enamel-forming cells avoid overdosing on calcium, which can lead to cellular toxicity. The overall aim of this research is to use the latest cell biology and biochemical techniques to elucidate the mechanisms of calcium handling in enamel cells, with developing teeth from rat as the experimental model. Our focus is on calcium transport mechanisms, a field where past theories were overturned by our recent findings with gene-knockout animals. We will test a new theory that has arisen from our investigations, using drugs and gene-silencing techniques to interfere with the cellular machinery now thought to be crucial for transporting calcium. By providing strong physiological evidence for this new mechanism, our expected results will define specific proteins that might be targeted by drugs and nutrition, and provide important information about how dietary fluoride and caffeine affect enamel quality. These findings would change thinking about how enamel defects can be prevented and provide a solid foundation to the exciting new field of dental bioengineering, whose goal is to coax stem cells to make natural replacement teeth.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0454170
Funder
Australian Research Council
Funding Amount
$187,341.00
Summary
Biacore3000-Expansion of Proteomics Facility. The sequencing of the human genome has led to redirection of effort towards the rapid characterisation of the products of genes, proteins. This project will establish state of the art facilities for protein identification and characterisation in the Hunter Region. The investigators are representative of several major research programs and are unified by their specific expertise in the fundamental molecular mechanisms underlying the control of cellula ....Biacore3000-Expansion of Proteomics Facility. The sequencing of the human genome has led to redirection of effort towards the rapid characterisation of the products of genes, proteins. This project will establish state of the art facilities for protein identification and characterisation in the Hunter Region. The investigators are representative of several major research programs and are unified by their specific expertise in the fundamental molecular mechanisms underlying the control of cellular processes in plants, animals and humans. Understanding these mechanisms will provide the basis for improved management of the environment and pathological conditions through identifying molecular targets for diagnosis, genetic manipulation or drug design.Read moreRead less
Molecular mechanisms of cyclic Adenosine Monophosphate (AMP) induced apoptosis. Cyclic Adenosine Monophosphate (cAMP) is an important cellular chemical necessary for cell growth. However, de-regulated cAMP production in response to altered physiology can result in cellular death or apoptosis. This is attributed to the development of certain human diseases and this project aims to understand the molecular mechanism behind this process.
Elucidating the regulation of cell death by random mutagenesis of key apoptotic proteins. All organisms need to remove damaged or excessive cells. This cell death process is called apoptosis. Defects in apoptosis result in numerous diseases including cancer, and neurodegenerative and immune disorders. Determining how this process is regulated is of crucial importance for therapeutic intervention. We will utilise a powerful strategy to mutate proteins required for apoptosis so that they no longer ....Elucidating the regulation of cell death by random mutagenesis of key apoptotic proteins. All organisms need to remove damaged or excessive cells. This cell death process is called apoptosis. Defects in apoptosis result in numerous diseases including cancer, and neurodegenerative and immune disorders. Determining how this process is regulated is of crucial importance for therapeutic intervention. We will utilise a powerful strategy to mutate proteins required for apoptosis so that they no longer work, which will allow the identification of protein regions essential for cell death activity . This will lead to identification of potential drug targets to control apoptosis. Elucidating the mechanism of cell death will lead to the development of novel and improved therapies for diseases such as cancer and neurodegenerative disease.Read moreRead less
Determining the molecular regulation of blood vessel development and angiogenesis. Abnormal blood vessel growth is associated with diseases including cancer, macular degeneration, diabetic retinopathy and chronic inflammation. This project focuses on understanding normal blood vessel growth in order to gather clues to help discover ways of preventing abnormal blood vessel growth during disease.
Investigation of the biology of insulin-like growth factor 1 and its derivatives for the development of new therapeutics. This project will investigate the biology of insulin-like growth factor 1, a key molecule in growth, development and, in particular, the wound healing process. Its success will lead to improved treatments for non-healing (chronic) wounds and, potentially, new anti-cancer treatments.