Fyn-STEP-Tau axis: the nanoscale mechanisms of synaptic plasticity. This project investigates how brain cells use their molecular machinery to communicate with one another. At the heart of this process lies the synapses, the contact points that connect brain cells. This project will employ an innovative combination of quantitative microscopy techniques, gene knockout mouse models, and advanced computational and mathematical analyses to generate new knowledge on how a crucial set of proteins orga ....Fyn-STEP-Tau axis: the nanoscale mechanisms of synaptic plasticity. This project investigates how brain cells use their molecular machinery to communicate with one another. At the heart of this process lies the synapses, the contact points that connect brain cells. This project will employ an innovative combination of quantitative microscopy techniques, gene knockout mouse models, and advanced computational and mathematical analyses to generate new knowledge on how a crucial set of proteins organises in space and time to regulate synaptic connectivity. This will provide significant benefits, including molecular-level insight into the inner workings of the brain and interdisciplinary training for students. The expected outcomes include a deeper understanding of brain functions, such as learning and memory.Read moreRead less
Molecular basis of glutamate receptor trafficking in neuronal plasticity . Neurons communicate via synapses, where chemicals (such as glutamate) are released to transmit neuronal signals. This proposal is aimed at understanding the molecular mechanisms of neuronal communication and adaptive plasticity, which are essential for normal brain function. The proposed research will combine biophysical, biochemical, molecular and cell biological assays to elucidate how the trafficking of glutamate recep ....Molecular basis of glutamate receptor trafficking in neuronal plasticity . Neurons communicate via synapses, where chemicals (such as glutamate) are released to transmit neuronal signals. This proposal is aimed at understanding the molecular mechanisms of neuronal communication and adaptive plasticity, which are essential for normal brain function. The proposed research will combine biophysical, biochemical, molecular and cell biological assays to elucidate how the trafficking of glutamate receptors is regulated in neurons during plasticity and learning. The outcomes will enhance our understanding of how neural plasticity is generated and maintained, knowledge that is critical for our understanding of the cellular correlates of information, sensory and motor processing, as well as learning, memory and cognition.Read moreRead less
Mapping the integration of T cell fate control across time and space. This project aims to apply new methods to determine how coordination of signalling complexes impacts upon the fate of cells of the adaptive immune system. It expects to determine how the context of signallng orchestrates cell fates such as differentiation, death and proliferation. The project is expected to yield an experimental and analytical platform for further investigations into a broad range of biological questions, and ....Mapping the integration of T cell fate control across time and space. This project aims to apply new methods to determine how coordination of signalling complexes impacts upon the fate of cells of the adaptive immune system. It expects to determine how the context of signallng orchestrates cell fates such as differentiation, death and proliferation. The project is expected to yield an experimental and analytical platform for further investigations into a broad range of biological questions, and to provide new knowledge of this fundamental problem. This platform should support further work that ultimately provides new models for tissue and immune cell regeneration, and new manufacturing platforms for therapies for humans and livestock, among other benefits.Read moreRead less