Visualising neuron-glia interactions in the injured central nervous system. The adult brain and spinal cord recovery poorly from injury. Attempts to overcome this problem include methods to promote the intrinsic regenerative capacity of injured neurons, and modulating the inhibitory extracellular environment to become permissive to regeneration. The goal of this project is to investigate an endogenous regenerative mechanism in the injured brain. This project will use the latest, cutting-edge mic ....Visualising neuron-glia interactions in the injured central nervous system. The adult brain and spinal cord recovery poorly from injury. Attempts to overcome this problem include methods to promote the intrinsic regenerative capacity of injured neurons, and modulating the inhibitory extracellular environment to become permissive to regeneration. The goal of this project is to investigate an endogenous regenerative mechanism in the injured brain. This project will use the latest, cutting-edge microscopy techniques to visualise whether the endogenous astrocyte protein metallothionein can promote regeneration in the injured nervous system of living zebrafish. The successful outcomes of this project will provide significant insight into understanding how the brain responds to injury.Read moreRead less
Unravelling the mechanism of vesicular docking in neurosecretory cells. The fusion of secretory vesicles (SVs) by exocytosis underpins neuronal and hormonal communication. The aim of this project is to unravel all the steps bringing these vesicles to the plasma membrane where they dock. Specifically, we aim to unravel the role for the cytoskeleton in creating an interface where SV confinement leads to the appropriate pairing of molecules mediating the fusion between the vesicles and the plasma m ....Unravelling the mechanism of vesicular docking in neurosecretory cells. The fusion of secretory vesicles (SVs) by exocytosis underpins neuronal and hormonal communication. The aim of this project is to unravel all the steps bringing these vesicles to the plasma membrane where they dock. Specifically, we aim to unravel the role for the cytoskeleton in creating an interface where SV confinement leads to the appropriate pairing of molecules mediating the fusion between the vesicles and the plasma membrane. Unravelling these novel molecular mechanisms is essential for our understanding of neuronal function in the healthy nervous and hormonal systems.Read moreRead less
Role of Tau and Synapsin in clustering distinct synaptic vesicle pools. Neurotransmitter-containing synaptic vesicles (SVs) are highly enriched in specific locations of brain cells, called nerve terminals via an unknown mechanism. The clustering of SVs depend on the phosphorylation of an unknown set of proteins. Two key proteins have been identified for their phosphorylation pattern and their potential to form membraneless compartments: tau and synapsin. Using highly innovative single-molecule s ....Role of Tau and Synapsin in clustering distinct synaptic vesicle pools. Neurotransmitter-containing synaptic vesicles (SVs) are highly enriched in specific locations of brain cells, called nerve terminals via an unknown mechanism. The clustering of SVs depend on the phosphorylation of an unknown set of proteins. Two key proteins have been identified for their phosphorylation pattern and their potential to form membraneless compartments: tau and synapsin. Using highly innovative single-molecule super-resolution microscopy, this grant will uncover how tau and synapsin phosphorylation controls the clustering of SVs thereby regulating neurotransmitter release. This project uses improved nanoscopic technologies and international
collaborations to unveil novel avenues in our understanding of brain communication.Read moreRead less
Super-resolving neurotransmitter release machinery during priming. Understanding how neurons communicate in the brain is one of the most challenging feats in neuroscience. The assembly of the molecular machinery involved in communication is unknown. This grant aims to understand how priming molecules Munc18 and Munc13, undergo a series of molecular steps leading to the release of neurotransmitter. Using innovative single-molecule super-resolution imaging we will uncover how Munc18 and Munc13 are ....Super-resolving neurotransmitter release machinery during priming. Understanding how neurons communicate in the brain is one of the most challenging feats in neuroscience. The assembly of the molecular machinery involved in communication is unknown. This grant aims to understand how priming molecules Munc18 and Munc13, undergo a series of molecular steps leading to the release of neurotransmitter. Using innovative single-molecule super-resolution imaging we will uncover how Munc18 and Munc13 are spatially and temporally organised to mediate communication. By elucidating how nanoclustering of these essential proteins enables key steps, this grant will reveal how brain cells communicate. This may then provide new opportunities to optimise underlying functions such as cognition, sensory and motor processing.Read moreRead less
Novel role of RNA methylation in neuronal homeostasis. This proposal is aimed at understanding the RNA signalling that takes place in neuronal homeostatic response. The crucial role of neuronal homeostasis for normal brain function is evidenced throughout the nervous system; however, the precise underlying mechanisms are still not well understood. The proposed research will utilise high-throughput sequencing approaches coupled with biochemical, molecular and cell biological assays to provide mec ....Novel role of RNA methylation in neuronal homeostasis. This proposal is aimed at understanding the RNA signalling that takes place in neuronal homeostatic response. The crucial role of neuronal homeostasis for normal brain function is evidenced throughout the nervous system; however, the precise underlying mechanisms are still not well understood. The proposed research will utilise high-throughput sequencing approaches coupled with biochemical, molecular and cell biological assays to provide mechanistic insights into the molecular processes that control neuronal homeostatic responses. This will elucidate how neural plasticity and network stability are maintained, a process that is critical for our understanding of sensory processing, learning and memory throughout life.Read moreRead less
Central Muscarinic Receptors as Novel Drug Targets for Parkinson's Disease and Schizophrenia. Psychiatric and neurodegenerative disorders such as schizophrenia and Parkinson's disease are linked to alterations in the activity of neurons in the brain containing the chemical dopamine. Other types of brain neurons containing the chemical acetylcholine regulate dopamine neuron activity by acting on acetylcholine receptors located on dopamine neurons. We aim to determine how these important recepto ....Central Muscarinic Receptors as Novel Drug Targets for Parkinson's Disease and Schizophrenia. Psychiatric and neurodegenerative disorders such as schizophrenia and Parkinson's disease are linked to alterations in the activity of neurons in the brain containing the chemical dopamine. Other types of brain neurons containing the chemical acetylcholine regulate dopamine neuron activity by acting on acetylcholine receptors located on dopamine neurons. We aim to determine how these important receptors regulate dopamine neuron activity using genetically modified mice deficient in acetylcholine receptors, together with newly developed physiological methods and new acetylcholine receptor drugs. These studies will foster the design of novel acetylcholine receptor drugs as effective pharmaceutical treatments of neurological and psychiatric disorders related to brain dopamine dysfunction.Read moreRead less
Molecular mechanisms determining the lipid composition of synapses. Synapses between neurons play a key role in all functions of the nervous system including learning and memory. They are mostly composed of the unique combination of proteins and lipids, which function together to enable neurotransmission. While the molecular mechanisms determining the protein composition of synapses are well characterised, the mechanisms defining the lipid composition of synapses remain unknown. The project will ....Molecular mechanisms determining the lipid composition of synapses. Synapses between neurons play a key role in all functions of the nervous system including learning and memory. They are mostly composed of the unique combination of proteins and lipids, which function together to enable neurotransmission. While the molecular mechanisms determining the protein composition of synapses are well characterised, the mechanisms defining the lipid composition of synapses remain unknown. The project will use advanced techniques of neuroscience and lipid research to determine the mechanisms of lipid transport and retention at synapses. The project is expected to generate new knowledge about the fundamental mechanisms of brain function, which will be useful for developing new therapeutics enhancing the brain power.Read moreRead less
Functional analysis of long noncoding RNAs expressed in the brain. For many years, the mammalian genome has been thought to be mainly junk. Recently, however, it has become evident that most of the genome specifies RNAs that do not encode proteins ('long noncoding' RNAs, lncRNAs), many of which are brain-specific. This project aims to determine the functions of lncRNAs that are expressed in the hippocampus (involved in learning) and the cerebellum (involved in movement coordination) by deleting ....Functional analysis of long noncoding RNAs expressed in the brain. For many years, the mammalian genome has been thought to be mainly junk. Recently, however, it has become evident that most of the genome specifies RNAs that do not encode proteins ('long noncoding' RNAs, lncRNAs), many of which are brain-specific. This project aims to determine the functions of lncRNAs that are expressed in the hippocampus (involved in learning) and the cerebellum (involved in movement coordination) by deleting them in mice, testing for developmental, cognitive and motor effects, and characterising the structures with which they are associated. The results of the project are expected to open new vistas in neuroscience, contributing to understanding the molecular basis of brain function and the 'dark matter' of the genome.Read moreRead less
Regulation of Stress Hormone Receptors in the Brain. Our research will provide information on how the brain controls our response to stress and will allow the development of targeted strategies to reduce the possibility during chronic stress of the development of conditions such as anxiety and depression. This will improve mental health outcomes in Australia and add to Australia's economic and social stability.
The evolution of dim light vision in vertebrates. High sensitivity (rod-based) vision has been extremely important for the survival and adaptive radiation of many vertebrates, including humans over evolutionary time. This multidisciplinary project will reveal the evolutionary and physiological constraints on early photoreception and the difficulties in operating over an enormous range of lighting conditions. Not only will the findings be crucial for our understanding of basic mechanisms of dim l ....The evolution of dim light vision in vertebrates. High sensitivity (rod-based) vision has been extremely important for the survival and adaptive radiation of many vertebrates, including humans over evolutionary time. This multidisciplinary project will reveal the evolutionary and physiological constraints on early photoreception and the difficulties in operating over an enormous range of lighting conditions. Not only will the findings be crucial for our understanding of basic mechanisms of dim light vision, but also provide potential insights into the physiological bases of various rod dystrophies affecting humans and the improved design of more sensitive cameras and safe light environments for rearing animals in captivity e.g. for aquaculture.Read moreRead less