Brain Plasticity Following Changes In Sensory Input
Funder
National Health and Medical Research Council
Funding Amount
$312,576.00
Summary
The research proposed here will investigate the mechanisms our brains use to adapt to changes in sensory input, as occurs following blindness, deafness, nerve damage or loss of a limb. The information gathered will help develop treatments for diseases associated with sensory loss, as well as those associated with deficits in our ability to learn and remember, such as Alzheimer's disease.
The amygdala is an area of the brain that is involved in assigning emotional content to sensory information. Disorders of the amygdala lead to a variety of anxiety-related mental disorders such as panic attacks and post-traumatic stress. This grant will study how the NMDA receptor, which plays a central role in memory formation, works in the amygdala. We will determine the functional role of this receptor in the amygdala and how it may be modified by experience.
Mechanisms Underlying Short- And Long-term Plasticity At The Mossy Fibre -> CA3 Synapse In The Hippocampus
Funder
National Health and Medical Research Council
Funding Amount
$272,750.00
Summary
Synapses, the contacts between brain cells, are extremely plastic. They can become stronger and weaker depending on the activity they experience. The hippocampus, a structure in the brain, is known to be critical to the formation of conscious memories. The plastic nature of the synapse in this structure is thought to underlie learning and memory. Understanding the mechanisms that are responsible for the changes in synaptic strength in the hippocampus are therefore important to our understanding ....Synapses, the contacts between brain cells, are extremely plastic. They can become stronger and weaker depending on the activity they experience. The hippocampus, a structure in the brain, is known to be critical to the formation of conscious memories. The plastic nature of the synapse in this structure is thought to underlie learning and memory. Understanding the mechanisms that are responsible for the changes in synaptic strength in the hippocampus are therefore important to our understanding of learning and memory. This proposal describes a series of experiments that are designed to determine the mechanisms of plastic changes . We hope, that by understanding these mechanisms, we can start to understand how we learn and remember.Read moreRead less
The research described in this Project Grant application should help to us understand how our brains make memories. Our brains contain billions of interconnected nerve cells forming unimaginable numbers of possible networks. Previous research indicates that repetitive activation of individual networks can lead to changes in the strength of connections between nerve cells. These changes in connection strength are thought to underlie learning and memory. The experiments described in this proposal ....The research described in this Project Grant application should help to us understand how our brains make memories. Our brains contain billions of interconnected nerve cells forming unimaginable numbers of possible networks. Previous research indicates that repetitive activation of individual networks can lead to changes in the strength of connections between nerve cells. These changes in connection strength are thought to underlie learning and memory. The experiments described in this proposal will address the mechanisms underlying changes in the strength of connections between nerve cells. As most of the inputs nerve cells receive from other nerve cells are made onto their dendrites (small branching processes that extend from the cell body), the main objective is to investigate the interactions at the dendritic level responsible for changes in connection strength. The results of this work will raise our understanding of how memories are formed, which will be essential if we are to understand the cellular processes disrupted during memory dysfunction in neurological disorders such as dementia.Read moreRead less
Protein Partners Of Rapsyn That Regulate Acetylcholine Receptor Clustering
Funder
National Health and Medical Research Council
Funding Amount
$411,000.00
Summary
Spinal nerves control our limb muscles by releasing chemical signals directly onto the surface of muscle fibres that they contact. These chemical signalling contacts are called synapses. They are like the synapses between nerve cells in our brains but easier to study, meaning that we can make more rapid progress in understanding how synapses work. The sensor receptors for chemical signals at the nerve-to-muscle synapse are held in place on the muscle fibre surface by a protein called rapsyn. In ....Spinal nerves control our limb muscles by releasing chemical signals directly onto the surface of muscle fibres that they contact. These chemical signalling contacts are called synapses. They are like the synapses between nerve cells in our brains but easier to study, meaning that we can make more rapid progress in understanding how synapses work. The sensor receptors for chemical signals at the nerve-to-muscle synapse are held in place on the muscle fibre surface by a protein called rapsyn. In turn, rapsyn must be organized by other chemical signals from the nerve, but we don't know exactly how this happens. When the receptors become disorganized at the synapse, in diseases such as Myasthenia Gravis, we lose control of our muscles. This project will employ newly developing techniques of proteomics and genomics to identify new proteins that bind to rapsyn and to test how they work to organize receptors at the synapse. By identifying the proteins that control rapsyn we may be able to develop new treatments for Myasthenia Gravis that restore the function of the synapse with less side effects than current therapies.Read moreRead less
Development And Refinement Of Neural Connections In The Adult Brain In Health And Disease
Funder
National Health and Medical Research Council
Funding Amount
$8,061,596.00
Summary
Our group will use innovative approaches such as advanced imaging and cell-sorting and development of animal models to determine how new neurons are generated, how they travel to different parts of the brain and how they integrate into the existing brain circuitry. These discoveries will point to new ways in which to treat brain damage both during ageing and during pathology. Since team members have previously been involved in progressing molecular discovery to clinical trials, we are also in a ....Our group will use innovative approaches such as advanced imaging and cell-sorting and development of animal models to determine how new neurons are generated, how they travel to different parts of the brain and how they integrate into the existing brain circuitry. These discoveries will point to new ways in which to treat brain damage both during ageing and during pathology. Since team members have previously been involved in progressing molecular discovery to clinical trials, we are also in a good position to exploit these discoveries in partnership with the biopharmaceutical industry.Read moreRead less