Understanding how the multiple roles of olfactory ensheathing cells guide the growth and regeneration of olfactory axons. The outcomes of this project will increase the understanding of how nerve cells develop and regenerate after injury. The research outcomes and the development of new innovative methodologies as part of the project will be of high significance for the neuroscience research community both within Australia and overseas. The findings will also pave the way for the development of ....Understanding how the multiple roles of olfactory ensheathing cells guide the growth and regeneration of olfactory axons. The outcomes of this project will increase the understanding of how nerve cells develop and regenerate after injury. The research outcomes and the development of new innovative methodologies as part of the project will be of high significance for the neuroscience research community both within Australia and overseas. The findings will also pave the way for the development of novel therapies that promote neuronal regeneration relevant for disorders such as spinal cord injury and Alzheimer's disease, which constitute a large socio-economic burden in Australia. Currently, 400 people contract spinal cord injury every year, corresponding to an annual cost of $1 billion, and more than 500 000 aging people suffer from Alzheimer's disease.Read moreRead less
Understanding how cells in the olfactory nerve prevent brain infection. The project hypothesis is that the phagocytic activity of olfactory ensheathing cells (OECs) is the key factor that prevents bacteria from accessing the brain via the olfactory nerve, and allows continuous regeneration of the olfactory nervous system. This project aims to investigate how OECs phagocytose bacteria and debris from degenerating axons in vivo, and determine key molecular mechanisms in the process. Thus, we will ....Understanding how cells in the olfactory nerve prevent brain infection. The project hypothesis is that the phagocytic activity of olfactory ensheathing cells (OECs) is the key factor that prevents bacteria from accessing the brain via the olfactory nerve, and allows continuous regeneration of the olfactory nervous system. This project aims to investigate how OECs phagocytose bacteria and debris from degenerating axons in vivo, and determine key molecular mechanisms in the process. Thus, we will characterise an unknown aspect of OEC biology that is neglected in the field. Intended outcomes include a paradigm shift that glial cells, and not circulatory immune cells, are the main defense against microbial invasion of the olfactory nerve. This is relevant for new therapies targeting neural infection/injury and antibiotic usage.Read moreRead less
Mechanisms of memory function involving site-specific tau phosphorylation. This project aims to understand the molecular principles that facilitate encoding, maintenance and retrieval of memories in the brain. To store memories in brain circuits, electrical and chemical signals are crucial. Brain cells can integrate signals into biochemical modifications of intracellular proteins. The nature of the protein modifications that represent memory within brain cells is unknown. This project uses innov ....Mechanisms of memory function involving site-specific tau phosphorylation. This project aims to understand the molecular principles that facilitate encoding, maintenance and retrieval of memories in the brain. To store memories in brain circuits, electrical and chemical signals are crucial. Brain cells can integrate signals into biochemical modifications of intracellular proteins. The nature of the protein modifications that represent memory within brain cells is unknown. This project uses innovative genome editing, mathematical modelling and proteomic approaches, to study how biochemical modifications of a key protein called tau help encode and retrieve memories. These molecular insights will make a significant advance in the current understanding of a brain function that is essential to all human activities.Read moreRead less
Molecular control of memory traces. This project aims to understand how particular molecules help encode memories in the brain for future retrieval. Individual memories are encoded in brain cells through an unknown physical process. This project uses innovative approaches to manipulate memory-containing cells and will provide a new detailed explanation of memory. Outcomes of this work will significantly advance the current understanding of how memories are physically generated and maintained, wh ....Molecular control of memory traces. This project aims to understand how particular molecules help encode memories in the brain for future retrieval. Individual memories are encoded in brain cells through an unknown physical process. This project uses innovative approaches to manipulate memory-containing cells and will provide a new detailed explanation of memory. Outcomes of this work will significantly advance the current understanding of how memories are physically generated and maintained, which is an essential component of human and animal life. This research provides significant benefits in understanding the biology behind memory and in maintaining memory capacity in ageing.
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To Understand The Role Of The Plasminogen Activating And Matrix Metalloproteinase Systems In Traumatic Brain Injury
Funder
National Health and Medical Research Council
Funding Amount
$499,321.00
Summary
Tissue-type plasminogen activator (t-PA) is known for its role as a clot dissolving protein. It is present in the brain and following traumatic brain injury (TBI), it can worse brain cell damage. We have established a mouse model of TBI . We will compare brain damage in mice that are deficient in or have high amounts of t-PA. We will also determine whether the recovery rate post-TBI can be improved using specific t-PA blockers. This project may provide new therapies for TBI.
Functional Assessment Of CD40 In The Development Of Multiple Sclerosis
Funder
National Health and Medical Research Council
Funding Amount
$521,910.00
Summary
Many of the genes which affect susceptibility to Multiple Sclerosis (MS) have recently been identified. Two of these genes were first discovered in an Australian study published in Nature Genetics in 2009. One of these is CD40, which controls immune cell activation. In this project we aim to establish how the genetic variant identified affects the function of the CD40 gene in MS. CD40 may prove to be a good therapeutic target, with agents available to modulate CD40 available already.
The Role Of Netrin-DCC In The Development Of The Corpus Callosum
Funder
National Health and Medical Research Council
Funding Amount
$512,065.00
Summary
During embryonic development neurons send out axons that connect to other target neurons within the brain. The proper connectivity of these axons is vital to brain function. The largest axon tract in the brain is called the corpus callosum and connects neurons in the left and right cerebral hemispheres. When the corpus callosum does not form, significant cognitive, motor and sensory deficits occur in patients. This condition, known as agenesis of the corpus callosum (ACC), is associated with ove ....During embryonic development neurons send out axons that connect to other target neurons within the brain. The proper connectivity of these axons is vital to brain function. The largest axon tract in the brain is called the corpus callosum and connects neurons in the left and right cerebral hemispheres. When the corpus callosum does not form, significant cognitive, motor and sensory deficits occur in patients. This condition, known as agenesis of the corpus callosum (ACC), is associated with over 50 different human congenital syndromes. Thus understanding how the genes and molecules involved in the formation of the corpus callosum function in normal development can provide the basis for our understanding of what goes wrong in ACC. In this proposal we will investigate the role of the axon guidance molecule Netrin1, and its receptor DCC, in development of the corpus callosum in both a mouse model and in humans with malformations of the corpus callosum. Although Netrin1-DCC signalling has traditionally been associated with mechanisms of axon guidance, we hypothesize that these molecules may play a different role, specifically in cellular adhesion and ultimately in the fusion of the two cerebral hemispheres, in a manner that allows the corpus callosum to form. A second role for Netrin1-DCC signalling may be in the guidance of these axons once the midline has fused correctly and we investigate this in Aim 2 of the proposal. Finally, we are collaborating with a paediatric neurologist at UCSF, who has identified several mutations in the DCC gene in patients with ACC. In Aim 3 we test whether these mutations disrupt the function of DCC in callosal axon pathfinding. Understanding how these genes function during development of the brain and how their function may be altered in ACC is crucial to providing a proper diagnosis and prognosis for these patients. Ultimately, understanding more about how these genes function could also lead to prevention of these disorders.Read moreRead less
My research focuses on understanding pathobiological mechanisms in acute and chronic neurodegenerative conditions such as stroke and Parkinson’s disease which have large burdens on the community through health care costs and on families because of the lack of effective treatments. An improved understanding of how brain cells die and of how the most abundant brain cell, the astrocyte, can be engineered to be a resource for regenerative medicine offer promise for improved clinical management.
LIM-homeodomain interactions in neuronal development. The loss of central nervous system function, through accident or disease, is devastating for affected individuals and their families. Our current inability to stimulate the regeneration of nervous tissue is a result of the lack of detailed knowledge of the complex processes that must take place, at the molecular and cellular levels, during neuronal development. We are determining how a group of cellular proteins that have key roles in motor n ....LIM-homeodomain interactions in neuronal development. The loss of central nervous system function, through accident or disease, is devastating for affected individuals and their families. Our current inability to stimulate the regeneration of nervous tissue is a result of the lack of detailed knowledge of the complex processes that must take place, at the molecular and cellular levels, during neuronal development. We are determining how a group of cellular proteins that have key roles in motor neuron development interact with each other and with DNA. With this information we are developing reagents that can be used to further probe central nervous system function and may ultimately be used to regenerate damaged nerves.Read moreRead less