A Novel Intracellular Roadblock To Cobalamin Utilization In Ageing And Alzheimer�s Disease
Funder
National Health and Medical Research Council
Funding Amount
$11,304.00
Summary
Vitamin B12 is required for red blood cell formation, DNA synthesis and normal neurological function. B12 deficiency contributes to age-related cognitive decline and Alzheimer�s disease. This research will provide important new information regarding the ageing process and the impact that brain changes associated with ageing and Alzheimer's disease have on B12 metabolism. It will provide important information related to the therapeutic potential of B12.
SEZ6 AND NEURONAL CALCIUM SIGNALLING IN SYNAPSE DEVELOPMENT
Funder
National Health and Medical Research Council
Funding Amount
$617,685.00
Summary
Inappropriate development and function of neuronal circuits is a universal feature of neurological disorders of cognition such as Down syndrome, autism spectrum disorders and Fragile X mental retardation, epilepsy, schizophrenia and Alzheimer�s disease. In these diseases, neurons exhibit abnormal neuronal branches (dendrites) and abnormal connections on dendritic spines. This research is aimed at understanding the mechanisms controlling dendrite development that underpin proper neuronal wiring.
Properties Of Dendritic Spines And Their Role In Synaptic Plasticity
Funder
National Health and Medical Research Council
Funding Amount
$336,767.00
Summary
Connections between nerve cells in the brain often occur onto enlarged protrusions called dendritic spines. This proposal will investigate the properties of dendritic spines, and relate differences in spine properties to synaptic plasticity. This information can be used to better understand and treat neurological disorders associated with spine malfunction, as occur in some forms of mental retardation, and may help with understanding the memory loss that occurs during ageing and dementia.
Metabolism And Neurotoxicity Of Hemin And Hemin-derived Iron
Funder
National Health and Medical Research Council
Funding Amount
$346,400.00
Summary
Stroke is a leading cause of death and disability in industrialised countries. Much of the brain damage that follows a hemorrhagic stroke is attributable to the presence of free iron which mediates oxidative stress in brain cells. This iron originates from hemin, which in turn is derived from the hemoglobin in extravasated blood cells. The fact that iron is freed from hemin in the post-stroke period makes it an attractive therapeutic target. However, remarkably little is known about the metaboli ....Stroke is a leading cause of death and disability in industrialised countries. Much of the brain damage that follows a hemorrhagic stroke is attributable to the presence of free iron which mediates oxidative stress in brain cells. This iron originates from hemin, which in turn is derived from the hemoglobin in extravasated blood cells. The fact that iron is freed from hemin in the post-stroke period makes it an attractive therapeutic target. However, remarkably little is known about the metabolism of hemin by the different types of brain cells. The present project investigates the metabolism and neurotoxicity of hemin in brain cells and will examine the capacity of potential therapeutic agents to protect brain cells from hemin toxicity. The data obtained from this project will advance our understanding of the uptake and metabolism of hemin by the four main types of brain cell, and the factors that are likely to be involved in the neurotoxicity of hemin-derived iron following hemorrhagic stroke. The study will also provide data concerning the relative effectiveness of potential therapeutic agents, and information concerning the cell types, time points and aspects of hemin metabolism that are most effectively targeted by these agents. Such advances will guide the development of therapeutic approaches that are directed at minimising the brain damage which results from hemin-derived iron in humans.Read moreRead less
DCC-Robo Interactions Cooperate To Regulate Callosal Axon Guidance
Funder
National Health and Medical Research Council
Funding Amount
$383,422.00
Summary
In order for the brain to function, the correct connections between neurons must be formed during development. These connections, formed by the axonal processes of neurons, are able to find their synaptic targets by sensing molecular cues within the brain that guide them, by attraction or repulsion, to their target. This proposal investigates how attractive and repulsive signals are received and integrated in neurons to enable axons to find their targets in the brain.
Do Changes In HCN Channels Function Cause Epilepsy?
Funder
National Health and Medical Research Council
Funding Amount
$386,172.00
Summary
About 100 000 people suffer from epilepsy in Australia with about one third poorly controlled with current anti-epileptic drugs. It is important to continue to develop novel modes of treatment for this debilitating disease. This project investigates an ion channel, known as HCN that is thought to be involved in making a brain epileptic. Understanding how changes in HCN channels make nerve cells and nerve networks more excitable will help us develop better strategies for designing drugs.
Absence epilepsy is the commonest form of idiopathic generalized epilepsy. It can lead to hundreds of seizures per day, and mainly affects children between the ages of four and eight. Its cause is in most cases unknown. In this study we will use a rat model of absence epilepsy to investigate the cellular basis of this disease. Preliminary work indicates that a particular protein - HCN1 - is reduced in the cortex of rats with absence epilepsy. This protein codes for a pore in the membrane of nerv ....Absence epilepsy is the commonest form of idiopathic generalized epilepsy. It can lead to hundreds of seizures per day, and mainly affects children between the ages of four and eight. Its cause is in most cases unknown. In this study we will use a rat model of absence epilepsy to investigate the cellular basis of this disease. Preliminary work indicates that a particular protein - HCN1 - is reduced in the cortex of rats with absence epilepsy. This protein codes for a pore in the membrane of nerve cells, which acts like a switch. We have preliminary evidence that in rats with absence epilepsy this switch does not work properly. We wish to investigate how this influences the activity of nerve cells in rats with absence epilepsy. Furthermore, as absence epilepsy is an inherited disease, we wish to track down the genetic basis of this disease. This will give us clues as to the cause of the disease in this rat model. This research will shed light on the potentially important role of the HCN1 protein in absence epilepsy, which may represent an potentially new therapeutic target for the development of drugs for the treatment of absence epilepsy.Read moreRead less
A Novel Mechanism For The Maintenance Of Catecholamine Synthesis
Funder
National Health and Medical Research Council
Funding Amount
$356,250.00
Summary
Stress causes an acute response that prepares us for flight or a fight and an adaptive response that requires days to establish. The catecholamines, including adrenaline, noradrenaline and dopamine are critical to both the acute and adaptive stress responses. They are secreted from cells at the level of the nervous system and the adrenal gland. We all respond differently to stress and if we do not cope we can become hypertensive or depressed. These pathologies require drug management and the dru ....Stress causes an acute response that prepares us for flight or a fight and an adaptive response that requires days to establish. The catecholamines, including adrenaline, noradrenaline and dopamine are critical to both the acute and adaptive stress responses. They are secreted from cells at the level of the nervous system and the adrenal gland. We all respond differently to stress and if we do not cope we can become hypertensive or depressed. These pathologies require drug management and the drugs all affect the catecholamine systems. Tyrosine hydroxylase controls catecholamine synthesis and it is activated in both the acute and adaptive phases of the stress response in order to replace catecholamines that have been secreted. Tyrosine hydroxylase is activated by protein phosphorylation in the acute phase and by the synthesis of new tyrosine hydroxylase in the adaptive phase. We have now discovered an additional and novel phase that we refer to as sustained tyrosine hydroxylase activation. This phase spans at least the period between the acute (mins) and adaptive phases (days). It involves the sustained phosphorylation of tyrosine hydroxylase and its mechanism appears to differ from the other two phases. In this project we will answer three questions. Does sustained tyrosine hydroxylase activation: 1 Occur in response to many stimuli and in many catecholamine cell types? 2 Occur by a single mechanism, different to the other phases, in all circumstances? 3 Play a role in the control of blood pressure and depression? This project will provide fundamental data about the mechanisms and consequences of sustained tyrosine hydroxylase activation, which is a part of the stress response not previously discovered. The data may impact on the way we design drugs to control stress responses, including antidepressants and antihypertensives.Read moreRead less
Cyclic-nucleotide-dependent Regulation Of Axon Guidance Sensitivity
Funder
National Health and Medical Research Council
Funding Amount
$527,338.00
Summary
Problems in wiring up the brain underlie several nervous system disorders. The goal of this project is to understand better how this wiring normally forms. This will ultimately lead to a better understanding of what can go wrong with brain wiring, and how to fix such problems. It will also lead to a better understanding of how to make axons regenerate after injury.
Mechanisms Guiding Pathfinding And Positioning Of Cortical Interneurons
Funder
National Health and Medical Research Council
Funding Amount
$621,606.00
Summary
Brain disorders place an economic and social burden on Australia and the personal costs of these illnesses are immeasurable. Several brain abnormalities are caused from the failure of neurons to position themselves in the correct location when the brain develops. Our study aims to discover how neurons move and what factors influence this process. It provides an understanding of normal brain development, as well as providing insight into what may go wrong in the formation of brain diseases.