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The Functional Interplay Between Alpha Synuclein And Synaptophysin In Synaptic Vesicle Recycling
Funder
National Health and Medical Research Council
Funding Amount
$405,461.00
Summary
Parkinson’s Disease (PD) is the second most common neurodegenerative disorder, affecting 7 million people worldwide. ?-synuclein is a protein in that brain that is likely to contribute to the death of brain cells in PD, but the normal role of the protein remains unknown. This study will investigate the function of ?-synuclein in maintaining normal healthy brain activity. In addition, this work will help us understand the processes that go awry in neurodegenerative disease states such as PD.
Macrophages are white blood cells that provide front line defence against infection by initiating inflammatory responses by ingesting or phagocytosing microbes and by releasing soluble messengers (cytokines) to recruit other immune cells. These defensive functions require extensive trafficking of proteins within the macrophages. Protein trafficking is orchestrated in part by a family of membrane fusion proteins called SNAREs. By defining the relevant SNAREs, we have recently discovered a much ac ....Macrophages are white blood cells that provide front line defence against infection by initiating inflammatory responses by ingesting or phagocytosing microbes and by releasing soluble messengers (cytokines) to recruit other immune cells. These defensive functions require extensive trafficking of proteins within the macrophages. Protein trafficking is orchestrated in part by a family of membrane fusion proteins called SNAREs. By defining the relevant SNAREs, we have recently discovered a much acclaimed and novel pathway that allows efficient, combined cytokine secretion and phagocytosis in macrophages. Our studies proposed here will now expand on this discovery by comparing the phagocytic process, in terms of SNARE-mediated membrane and cytokine trafficking, for a wide range of microbes, highlighting differences that could provide new avenues for drug development. Moreover, since our strategy of using SNAREs to investigate and map trafficking pathways has proven so successful, we will now launch a major large-scale initiative to study ALL SNARE-mediated trafficking pathways in macrophages using a discovery pipeline of assays, including live cell imaging, we have developed. This will provide valuable information on many SNAREs including those associated with disease, and will elucidate trafficking pathways governing all macrophage actions in immunity, including cytokine secretion and antigen presentation. All of these pathways are highly relevant to current drug targets being used clinically or studied in inflammatory disease and for the development of vaccines.Read moreRead less
PROBABILITY OF QUANTAL SECRETION AT NEUROMUSCULAR SYNAPSES
Funder
National Health and Medical Research Council
Funding Amount
$334,232.00
Summary
The classical preparation for the study of synaptic transmission is the amphibian neuromuscular junction, for which there is the largest body of experimental data. This synapse was instrumental in the discovery that transmitters are released in packets or quanta, that this occurs at specialized release sites in the nerve terminal, and that receptor molecules on the muscles cells are strategically placed to receive the transmitter. Our work on this synapse has shown that each of these release sit ....The classical preparation for the study of synaptic transmission is the amphibian neuromuscular junction, for which there is the largest body of experimental data. This synapse was instrumental in the discovery that transmitters are released in packets or quanta, that this occurs at specialized release sites in the nerve terminal, and that receptor molecules on the muscles cells are strategically placed to receive the transmitter. Our work on this synapse has shown that each of these release sites have different probabilities for the secretion of a quantum and that this probability is correlated with the width of the release site. More recently we have shown that, whilst the size of a quantum does not vary between adjacent release sites, the area over which the quantum is released does vary between sites. The probability of quantal secretion is proportional to this area, as is the number of vesicles present at the release site. In this project we intend to relate this probability of secretion to the proteins that regulate the release of a quantum and in particular how these proteins interact to determine the time course of increase in probability at a release site after the passage of an impulse. The affects of trains of impulses on this probability are also to be delineated, in particular how the calcium which enters the terminal during these trains determines a long-term enhancement in probability after the train has ceased. This research will provide a molecular description of secretion from motor-nerve terminals.Read moreRead less
The Role Of Intersectin-1 In Endocytic Anomalies: Implications For Down Syndrome And Alzheimer's Disease
Funder
National Health and Medical Research Council
Funding Amount
$510,500.00
Summary
Individuals with Down syndrome have three copies of human chromosome 21, rather than the normal two. We have discovered a gene called Intersectin-1, located on human chromosome 21, that is expressed at higher levels than normal in individuals with Down syndrome. Intersectin-1 has a role in endocytosis, a process whereby cells take up molecules from the outside. Endocytosis occurs in all cells but is highly specialised in the brain where chemical transmitters are released and then rapidly recover ....Individuals with Down syndrome have three copies of human chromosome 21, rather than the normal two. We have discovered a gene called Intersectin-1, located on human chromosome 21, that is expressed at higher levels than normal in individuals with Down syndrome. Intersectin-1 has a role in endocytosis, a process whereby cells take up molecules from the outside. Endocytosis occurs in all cells but is highly specialised in the brain where chemical transmitters are released and then rapidly recovered by endocytosis in a process enabling neurones to pass signals to one another. A disturbance in endocytosis has been reported as the earliest hallmark of Alzheimer's disease in both non-Down syndrome and Down syndrome individuals. This disturbance is characterised by the presence of enlarged endosomes (small packages in neuronal cells containing chemical neurotransmitters formed during endocytosis). These enlarged endosomes are present long before the characteristic plaques of Alzheimer's disease appear. Since all individuals with Down syndrome develop Alzheimer's-like neuropathology, there must be a common disease mechanism that can be traced to the extra gene dosage from chromosome 21. We propose that a malfunctioning of Intersectin-1 is this common mechanism and we aim to test our hypothesis by the generation and analysis of mouse models of disrupted endocytosis.Read moreRead less
Astrocyte-Neuron Communication: Unravelling The Role Of Astrocytes In The Modulation Of Neuronal Circuits
Funder
National Health and Medical Research Council
Funding Amount
$403,064.00
Summary
Astrocytes, a type of glial cell, are the most numerous cell type in the brain. They outnumber their neuronal counterparts by ten times and make up almost 90% of adult brain weight. They were originally thought to have only a supportive role in brain metabolism and the regulation of brain blood flow. It is now known that they also modulate neurons and their synapses through release of vesicles containing specific substances and have key roles in some neuropathic (e.g. pain and epilepsy) and neur ....Astrocytes, a type of glial cell, are the most numerous cell type in the brain. They outnumber their neuronal counterparts by ten times and make up almost 90% of adult brain weight. They were originally thought to have only a supportive role in brain metabolism and the regulation of brain blood flow. It is now known that they also modulate neurons and their synapses through release of vesicles containing specific substances and have key roles in some neuropathic (e.g. pain and epilepsy) and neurodegenerative states (e.g. Alzheimer's disease, Parkinson's disease, and multiple sclerosis). Many of these diseases are associated with a pathological astrocyte process known as 'reactivity'. This process remains enigmatic, resulting in so-called reactive gliosis, a reaction characterized by changes in gene expression, cell enlargement and changes in cell shape, and, in some cases, cell division. Most of the research on astrocyte reactivity has focused on the impairment of astrocyte metabolic activities. Comparatively little is known about the effect of reactive gliosis on so called 'newer' astrocyte roles such as their ability to interact with each other and nearby neurons using exocytosis of gliotransmitters (GTs: glutamate and ATP) and neurotrophic factors (NTFs: glial and brain derived neurotrophic factors). This project will both further investigate the normal mechanisms of astrocyte-neuron communication, and examine the effects of astrocyte reactivity on these mechanisms. The aim is to identify possible therapeutic targets to ameliorate the detrimental affects of neurodegeneration.Read moreRead less
Insulin-regulated Aminopeptidase, Glucose And Memory
Funder
National Health and Medical Research Council
Funding Amount
$555,693.00
Summary
We have previously shown that inhibitors of IRAP improve performance in memory tasks in normal and memory impaired animals and are currently developing new treatments for memory loss using IRAP as a target. In this study, we will investigate the physiological roles of IRAP and its association with intracellular proteins. The knowledge obtained will provide insights of how the brain process memory and confirm the suitability of IRAP inhibitors as drugs for treating memory deficits.