Assessing the physiological roles of ubiquitination in regulating neuronal ion channels, receptors and transporters. Significant alterations in the activity neuronal transporters and receptors occur during tissue injury and regeneration as well as in many neurodegenerative disease states. Modulation of the pathways that control these transporters is an emerging therapeutic target, however, the molecular basis of these control mechanisms remain poorly understood. The outcome of this project will ....Assessing the physiological roles of ubiquitination in regulating neuronal ion channels, receptors and transporters. Significant alterations in the activity neuronal transporters and receptors occur during tissue injury and regeneration as well as in many neurodegenerative disease states. Modulation of the pathways that control these transporters is an emerging therapeutic target, however, the molecular basis of these control mechanisms remain poorly understood. The outcome of this project will be a thorough characterisation of a novel regulatory paradigm in neurons that is likely to be crucial for neuronal development and regeneration, and will potentially provide novel therapeutic targets for various neuronal diseases.Read moreRead less
G-protein coupled receptor-mediated calcium signalling in parasympathetic neurons. External chemical stimuli act on specific cell-surface receptors of neurons resulting in an increase in the intracellular calcium ion concentration which acts as a second messenger to alter neuronal excitability. There are, however, many receptors acting through a number of closely related proteins involving complex intracellular signalling pathways which remain poorly understood. This project uses molecular, elec ....G-protein coupled receptor-mediated calcium signalling in parasympathetic neurons. External chemical stimuli act on specific cell-surface receptors of neurons resulting in an increase in the intracellular calcium ion concentration which acts as a second messenger to alter neuronal excitability. There are, however, many receptors acting through a number of closely related proteins involving complex intracellular signalling pathways which remain poorly understood. This project uses molecular, electrical and fluorescence techniques to elucidate the molecular basis for these interactions by identifying the roles individual proteins play in integrating diverse extracellular stimuli and neuronal excitablility in the peripheral nervous system.Read moreRead less
Functional ubiquitination of neuronal voltage-gated sodium channels. Alterations in the electrical properties of excitable cells occur during tissue injury and regeneration as well as many disease states. Preventing or controlling these changes is a key strategic therapeutic aim. It is, however, only through a comprehensive understanding of the molecular mechanisms that regulate cellular excitability that we can identify these therapeutic targets. The major outcome of this project will be a thor ....Functional ubiquitination of neuronal voltage-gated sodium channels. Alterations in the electrical properties of excitable cells occur during tissue injury and regeneration as well as many disease states. Preventing or controlling these changes is a key strategic therapeutic aim. It is, however, only through a comprehensive understanding of the molecular mechanisms that regulate cellular excitability that we can identify these therapeutic targets. The major outcome of this project will be a thorough characterisation of a novel pathway that is potentially crucial in the development, homeostasis and regeneration of the nervous system. Disruption of normal function of this system may underlie the hyperexcitability observed in mannu neurodegenerative conditions.Read moreRead less
The Shape of Plants; Discovering factors that control morphology by organizing the cytoskeleton. Understanding how plants generate the huge diversity of shapes seen in nature is both a scientific challenge and a biotechnological opportunity. Microtubules dominate cell architecture, providing dynamic, yet rigid, frameworks for defining or changing growth polarity. We recently discovered and cloned MOR1, a gene that is essential for organizing microtubules and controlling morphogenesis. This place ....The Shape of Plants; Discovering factors that control morphology by organizing the cytoskeleton. Understanding how plants generate the huge diversity of shapes seen in nature is both a scientific challenge and a biotechnological opportunity. Microtubules dominate cell architecture, providing dynamic, yet rigid, frameworks for defining or changing growth polarity. We recently discovered and cloned MOR1, a gene that is essential for organizing microtubules and controlling morphogenesis. This places us in a strong position to resolve a long-standing mystery: how are microtubules organized? We intend to define MOR1's structural attributes, identify its interacting proteins and innovate an ambitious screen for additional genes that have related functions. This project should stimulate new ideas and applications.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668413
Funder
Australian Research Council
Funding Amount
$723,000.00
Summary
The Nanoscale Characterisation Centre WA Analytical Biological Transmission Electron Microscope Facility. A new regional analytical biological TEM (BioTEM) will provide critical support to acclaimed medical and biological groups researching nationally significant age-related health, agricultural and environmental questions. The BioTEM, for example, will allow a unique opportunity to detect metal uptake and accumulation in bone-forming cells. This research will provide insight into metal induce ....The Nanoscale Characterisation Centre WA Analytical Biological Transmission Electron Microscope Facility. A new regional analytical biological TEM (BioTEM) will provide critical support to acclaimed medical and biological groups researching nationally significant age-related health, agricultural and environmental questions. The BioTEM, for example, will allow a unique opportunity to detect metal uptake and accumulation in bone-forming cells. This research will provide insight into metal induced afflictions, such as nasal ulcer, lung cancer, contact dermatitis and hypersensitivity reactions like asthma. The BioTEM will also be used to study how plants take up nutrients and how they use these compounds for growth, development and reproduction. Successes in this research will transfer to the important development of salt-tolerant plant species.Read moreRead less
Identifying genes controlling the regulatory and metabolic interactions between the energy organelles of the leaf. Plant energy metabolism underlies the synthesis of many important products in crops, and subtle changes in metabolism can enhance key plant traits, such as germination rates, early seedling vigour, biomass/yield, and tolerance to harsh environments. Furthering our understanding on the complex interplay of genes controlling energy metabolism and its impact on leaf function has potent ....Identifying genes controlling the regulatory and metabolic interactions between the energy organelles of the leaf. Plant energy metabolism underlies the synthesis of many important products in crops, and subtle changes in metabolism can enhance key plant traits, such as germination rates, early seedling vigour, biomass/yield, and tolerance to harsh environments. Furthering our understanding on the complex interplay of genes controlling energy metabolism and its impact on leaf function has potential outcomes for smart genetic manipulation either by classical breeding or genetic transformation. There are more than 10,000 genes of unknown function in plant genomes and this represents a tremendous untapped resource for future Australian R&D outcomes and insights from this research proposal will have application to all plant-based agriculture.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989084
Funder
Australian Research Council
Funding Amount
$275,000.00
Summary
Confocal Laser Scanning Microscopy for Live Cell Imaging. The University of Newcastle has invested heavily in its biological and life sciences to create a research nexus focusing on national research priorities in biotechnology and environmental protection. The Live Cell Imaging platform will be utilized by scientists researching such strategically important areas including developmental biology, intracellular signalling cascades, cell cycle dynamics, plant development and microbiology. Moreover ....Confocal Laser Scanning Microscopy for Live Cell Imaging. The University of Newcastle has invested heavily in its biological and life sciences to create a research nexus focusing on national research priorities in biotechnology and environmental protection. The Live Cell Imaging platform will be utilized by scientists researching such strategically important areas including developmental biology, intracellular signalling cascades, cell cycle dynamics, plant development and microbiology. Moreover, this component of the University's research portfolio plays a major role in the postgraduate training of young Australian scientists who will, in turn, fuel future developments in both the life sciences and biotechnology industries.Read moreRead less
Revealing the mechanobiology of neural tube formation. This project aims to understand the formation of the neural tube; a fundamental tissue structure that generates the brain and the spinal cord. Using interdisciplinary approaches and exploiting recent advances in transgenic and imaging technologies, we expect to reveal the complex interplay between cells and their environment that generates mechanical forces to direct neural tissue formation. Outcomes include knowledge of previously intractab ....Revealing the mechanobiology of neural tube formation. This project aims to understand the formation of the neural tube; a fundamental tissue structure that generates the brain and the spinal cord. Using interdisciplinary approaches and exploiting recent advances in transgenic and imaging technologies, we expect to reveal the complex interplay between cells and their environment that generates mechanical forces to direct neural tissue formation. Outcomes include knowledge of previously intractable developmental processes, training of future scientists and development of international collaborations. This should provide enhanced imaging capacity, a higher quality scientific workforce and position Australia at the forefront of cell and developmental biology.Read moreRead less
Determining how the soluble dietary fibre beta-glucan is made in cereals. This Project aims to define the molecular mechanisms that control the processes involved in the biosynthesis and regulation of mixed linkage glucan, a major soluble dietary fibre in the cell walls of cereal grains. Plant cell walls determine the quality of most plant-based products used in modern human societies, yet the regulatory mechanisms responsible for their modulation are not well understood. Key distinguishing feat ....Determining how the soluble dietary fibre beta-glucan is made in cereals. This Project aims to define the molecular mechanisms that control the processes involved in the biosynthesis and regulation of mixed linkage glucan, a major soluble dietary fibre in the cell walls of cereal grains. Plant cell walls determine the quality of most plant-based products used in modern human societies, yet the regulatory mechanisms responsible for their modulation are not well understood. Key distinguishing features of the Project will be the international, integrative, and multidisciplinary approach towards addressing this major challenge in plant biology and the potential of the fundamental scientific discoveries to benefit end-users in the food, feed and beverage industries.Read moreRead less
Monotremes provide a key to understanding the molecular biology of mammalian gamete evolution. As the platypus and echidna (monotremes) are our most distant relatives among living mammals, interpreting their genome is important to determine the molecular sequences in human genes that are essential for fertility, and possibly responsible for infertility. As the only country with monotremes accessible for research, Australia has a responsibility to promote the work. The research can be applied to ....Monotremes provide a key to understanding the molecular biology of mammalian gamete evolution. As the platypus and echidna (monotremes) are our most distant relatives among living mammals, interpreting their genome is important to determine the molecular sequences in human genes that are essential for fertility, and possibly responsible for infertility. As the only country with monotremes accessible for research, Australia has a responsibility to promote the work. The research can be applied to improve the poor breeding record in zoos of these unique, iconic Australian fauna which generate considerable tourist interest. Publication of monotreme research attracts considerable publicity internationally. Publication of the platypus genome sequence in 2008 attracted headlines all over the world.Read moreRead less