Compromised Fetal Brain Development: Neurogenesis And The Potential For Therapeutic Intervention.
Funder
National Health and Medical Research Council
Funding Amount
$497,280.00
Summary
Lack of oxygen to the fetal brain during pregnancy is thought to be the main causes of brain injury in newborns. Some of these infants will suffer developmental and behavioural problems including cerebral palsy, schizophrenia and epilepsy. Currently, there is no effective treatment to redress these changes in brain development and this is one of the major challenges in perinatal medicine today. We have previously shown in a guinea pig model of chronic placental insufficiency (reduced oxygen and ....Lack of oxygen to the fetal brain during pregnancy is thought to be the main causes of brain injury in newborns. Some of these infants will suffer developmental and behavioural problems including cerebral palsy, schizophrenia and epilepsy. Currently, there is no effective treatment to redress these changes in brain development and this is one of the major challenges in perinatal medicine today. We have previously shown in a guinea pig model of chronic placental insufficiency (reduced oxygen and nutrient levels during pregnancy) that there is a reduction in neurons and in the connections between them. This may result from a reduction in number of newly generated neurons (neurogenesis), or an increase in neuronal death (apoptosis), or both. To develop therapeutic strategies to improve brain growth and ultimately functional recovery, we must understand the mechanisms which lead to these brain changes. In this project, we will use our guinea pig model to: 1) determine whether a suboptimal fetal environment decreases neuronal numbers by influencing neurogenesis, apoptosis or both, 2) study changes in the compromised brain environment which are likely to influence apoptosis and neurogenesis, 3) determine whether a suboptimal fetal environment has long-term effects on adult neurogenesis and 4) determine whether treatment with erythropoietin (Epo), a naturally occurring hormone, can resolve deficits in brain development and function. Epo is an exciting candidate as it is, or is in the process of being used to treat stroke and newborn asphyxiation. Epo has also been shown to prevent neuronal death and promote neurogenesis following brain injury. Understanding the mechanisms and finding effective treatments for brain damage is a vital area of endeavour if we are to help infants develop their maximum potential and reduce the enormous social, economic and educational burden which must be borne by the individual and society in general when things go wrong during pregnancy.Read moreRead less
Glutathione is a natural antioxidant, which is known to protect cells in the body from chemical damage. A small part of the glutathione in cells is found in the mitochondria, a structure that is involved in producing the chemical energy needed for normal cell function. The mitochondria are also involved under some circumstances in promoting the death of cells. Although glutathione in general has been well studied, much less attention has been paid to the function of glutathione in mitochondria, ....Glutathione is a natural antioxidant, which is known to protect cells in the body from chemical damage. A small part of the glutathione in cells is found in the mitochondria, a structure that is involved in producing the chemical energy needed for normal cell function. The mitochondria are also involved under some circumstances in promoting the death of cells. Although glutathione in general has been well studied, much less attention has been paid to the function of glutathione in mitochondria, particularly in cells from the brain. Our recent studies indicate that this mitochondrial pool of glutathione is particularly important in limiting the death of cells from the brain when exposed to damaging substances that are increased in some diseases. Thus, the capacity of mitochondrial glutathione to deal with such substances might be a factor in determining the extent of cell loss in the brain, which is an important determinant of symptoms in some of the major neurological diseases. Consistent with this possibility, we have obtained evidence indicating that decreases in glutathione in the mitochondria contribute to the cell death and brain damage that results from a stroke. In our proposed studies, we will investigate the function of mitochondrial glutathione in the two major cell populations from the brain, neurons and astrocytes. We will characterise the protective role of the glutathione and investigate how it enters the mitochondria and what factors influence the amount that is present. This will provide new insights into the function of glutathione in the mitochondria and could also suggest novel approaches for manipulating this antioxidant pool. We will also study models of stroke and some related brain disorders to more directly test the role of this antioxidant in disease and to assess whether manipulating the content of glutathione in the mitochondria has the potential to reduce damage and improve function in these disordersRead moreRead less
Targeting Necroptosis Signalling To Counter Stroke-induced Brain Injury
Funder
National Health and Medical Research Council
Funding Amount
$605,809.00
Summary
The origins of the brain injury that arises from stroke remain a matter of enormous interest. Our work suggests that a poorly understood form of cell death, termed necroptosis, contributes to injury to the brain following stroke. In addition to developing an advanced understanding of this process, we will use drugs developed at the Walter and Eliza Hall Institute to test whether blocking this process might be a plausible therapeutic strategy in stroke patients.
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
Mechanism Of Action Of A Quinazolinone In Models Of PD
Funder
National Health and Medical Research Council
Funding Amount
$667,548.00
Summary
By the time symptoms of Parkinson's disease (PD) appear, 60-70% of the cells in a crucial part of the brain called the substantia nigra have been destroyed and within a few years of diagnosis, most of the remaining cells have died. This project investigates the causes of this cell loss and a how a new class of compounds could interrupts the process. Success in achieving the aims of this proposal will add to our knowledge of the causes of neuronal death in PD
Enhancing neurogenesis in the adult primate brain. New neurons are robustly generated in the subependymal zone (SEZ) during human development. Thus, the SEZ may represent an endogenous modifiable source of neurons to enhance plasticity and therapeutic potential in the brain. However, despite our preliminary data, SEZ neurogenesis beyond the first months of life is controversial. This project aims to understand changes in the capacity for human SEZ proliferation from birth through to ageing and w ....Enhancing neurogenesis in the adult primate brain. New neurons are robustly generated in the subependymal zone (SEZ) during human development. Thus, the SEZ may represent an endogenous modifiable source of neurons to enhance plasticity and therapeutic potential in the brain. However, despite our preliminary data, SEZ neurogenesis beyond the first months of life is controversial. This project aims to understand changes in the capacity for human SEZ proliferation from birth through to ageing and whether neurogenesis may be induced by inflammation in the adult. Using transcriptomics we will also determine how the neurogenic environment changes with age/inflammation. This project is an important step in proving that the brain's potential to generate new neurons extends beyond infancy.Read moreRead less
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
Cracking the LIM-code: Transcription factor networks in developmental biology. Our current inability to stimulate the regeneration of nervous tissue is frustrated by a lack of detailed knowledge of the complex processes that take place at the molecular and cellular levels during development. We are determining how a group of cellular proteins that have key roles in neural development interact with each other and with DNA. With this information we are developing reagents that can be used to probe ....Cracking the LIM-code: Transcription factor networks in developmental biology. Our current inability to stimulate the regeneration of nervous tissue is frustrated by a lack of detailed knowledge of the complex processes that take place at the molecular and cellular levels during development. We are determining how a group of cellular proteins that have key roles in neural development interact with each other and with DNA. With this information we are developing reagents that can be used to probe the fundamental process of cell differentiation in the central nervous system.Read moreRead less
Cell Death In The Retina: Analysing The Switch That Triggers Dependency On Target-derived Trophic Factors
Funder
National Health and Medical Research Council
Funding Amount
$428,414.00
Summary
Construction of the developing nervous system in the embryo involves the creation of nerve cells and their connections, but also involves loss of a proportion of these cells prior to maturation. We will study this process of cell death and how developing nerve cells switch on their dependency to survival factors. In so doing we will better understand what happens when brain development goes wrong and also devise new ways to protect nerve cells in the injured or degenerate adult nervous system.
Cellular Plasticity in the Brain: discovering molecular mechanisms controlling the production of neurons during brain development, function, ageing and disease. The program aims to understand the mechanisms regulating Brain Plasticity - this recently discovered property of the brain to respond to environmental stimuli, both physiological and pathological, by producing new functional neurons. Specifically, the program will discover how the brain's stem cells are stimulated to produce new neurons. ....Cellular Plasticity in the Brain: discovering molecular mechanisms controlling the production of neurons during brain development, function, ageing and disease. The program aims to understand the mechanisms regulating Brain Plasticity - this recently discovered property of the brain to respond to environmental stimuli, both physiological and pathological, by producing new functional neurons. Specifically, the program will discover how the brain's stem cells are stimulated to produce new neurons. This understanding will significantly expand our knowledge of how the brain develops, and how functions, like memory, are modulated by neuronal replacement. Discoveries will underpin the development of, in association with Australia's biotechnology sector, a new generation of therapeutics, which treat neurological diseases, like Stroke, by stimulating the production of functional neurons.Read moreRead less