Understanding The Mechanisms Of PTEN Transfer Into Glial Cells Using Exosomes
Funder
National Health and Medical Research Council
Funding Amount
$567,253.00
Summary
This application will develop a new way of treating brain cancer which currently affects 1500 adults in Australia per year with no lasting cures. The average patient with a malignant brain tumour do not survive for more than 12 months. We have discovered a method of restoring a cancer suppressor substance that is lost from brain tumours. If successful, this treatment has the potential to limit or reverse the progression of brain tumours.
Delayed Radial Glial Maturation Linked To NFI Deficiency As An Underlying Cause Of Cortical Defects In Humans And Mice
Funder
National Health and Medical Research Council
Funding Amount
$801,979.00
Summary
The timely generation of neurons and glia is important for brain development and consequently brain function throughout life. Nuclear factor I (NFI) genes are important for regulating the production of neurons and glia, and people with disrupted NFI genes have severe cognitive and motor deficits. Using human genetic data and mouse models, we will analyse how disrupting these genes affects brain development, and changes the overall structure and wiring of the cerebral cortex as well as behaviour.
Vascular And Neuro-glial Dysfunction In Diabetic Retinopathy
Funder
National Health and Medical Research Council
Funding Amount
$481,500.00
Summary
The retina is responsible for sight. Vision occurs by interactions between blood vessels, neurons (cells that transmit electrical signals for vision) and glia (cells that support the retina). In diabetes, high amounts of glucose in blood increases certain factors within retinal cells. These factors slowly cause damage, such that after 15 years of diabetes all patients will have some retinal disease and many will loose sight. Indeed, diabetes is the leading cause of blindness in working people. T ....The retina is responsible for sight. Vision occurs by interactions between blood vessels, neurons (cells that transmit electrical signals for vision) and glia (cells that support the retina). In diabetes, high amounts of glucose in blood increases certain factors within retinal cells. These factors slowly cause damage, such that after 15 years of diabetes all patients will have some retinal disease and many will loose sight. Indeed, diabetes is the leading cause of blindness in working people. The main treatment for diabetic retinal disease is to burn away damaged blood vessels, however, this treatment has problems. Firstly, the burns destroy healthy retina and the disease continues, secondly, the treatment is performed late in the disease and therefore does not prevent the early changes in retinal cells, and thirdly, changes in neurons and glia are often not considered. Therefore, there is an urgent need to understand how blood vessels, neurons and glia interact with each other to threaten vision in diabetes, with the intention of developing safer and more effective treatments. This will be the focus of the current project. Currently, there are no studies that have examined the sequential changes in retinal blood vessels, neurons and glia in diabetes. This is mainly due to the lack of an experimental rodent model that progresses from mild to severe diabetic retinal disease. In 2003, we established such a model in the diabetic Ren-2 rat. In this project the diabetic Ren-2 rat will be used to study retinal cell changes and also to identify the factors that damage these cells. We suggest that angiotensin, bradykinin and VEGF are involved. These factors are present in the normal retina and are increased in diabetes. We will block these factors with specific drugs with the intention of understanding how these factors affect retinal cells in diabetes, and also to develop new drug therapies for the treatment of both early and late diabetic retinal disease.Read moreRead less
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