Dissecting The Molecular Mechanisms Behind Actin Filament Disassembly - An Essential Process In Malaria Parasite Cell Movement
Funder
National Health and Medical Research Council
Funding Amount
$311,860.00
Summary
The malaria parasite’s survival is reliant on efficient cell movement - a process that depends on the remodeling of the parasite actin cytoskeleton. The aim of this project is to understand how the actin cytoskeleton is disassembled when the parasite moves and to dissect the role of a key parasite protein, PfADF1, in the process. This project will elucidate fundamental insights into a key aspect of malaria parasite biology and, significantly, will shed light on how parasite movement can be inhib ....The malaria parasite’s survival is reliant on efficient cell movement - a process that depends on the remodeling of the parasite actin cytoskeleton. The aim of this project is to understand how the actin cytoskeleton is disassembled when the parasite moves and to dissect the role of a key parasite protein, PfADF1, in the process. This project will elucidate fundamental insights into a key aspect of malaria parasite biology and, significantly, will shed light on how parasite movement can be inhibited.Read moreRead less
Biological Role of Contraction-Induced Heat Shock Protein Expression. It is well known that mammalian skeletal muscle increases its expression of a group of highly conserved proteins, the heat shock proteins (HSP) in response to repeated contraction. However, the biological role of this expression is unclear. The aim of this project is to determine the biological role of contraction-induced HSP expression. We expect to show that HSP synthesis in response to exercise has three major roles; 1) to ....Biological Role of Contraction-Induced Heat Shock Protein Expression. It is well known that mammalian skeletal muscle increases its expression of a group of highly conserved proteins, the heat shock proteins (HSP) in response to repeated contraction. However, the biological role of this expression is unclear. The aim of this project is to determine the biological role of contraction-induced HSP expression. We expect to show that HSP synthesis in response to exercise has three major roles; 1) to act to repair damaged proteins in recovery from muscle injury 2) to act as a "molecular motor" to translocate proteins from one region of a muscle cell to another and 3) to be released into the circulation in order to act as a central signal to activate immune cells. Such a project will be significant because it will allow for a fundamental understanding as to why these proteins are produced in response to exercise. We expect to enhance our understanding of fundamental cell biology.Read moreRead less
NaviGAIT: New Software To Simplify Interpretation Of Gait Analysis Data
Funder
National Health and Medical Research Council
Funding Amount
$179,905.00
Summary
NaviGAIT is a new software package to support interpretation of gait analysis data. It is based upon Gait Profiling, a new technique to reduce the complexity of such data. At present data intepretation is restricted to a few expert clinicians. The new software will allow non-expert clinicians to interpret data and hence make gait analysis more accessible, cheaper and more clincally useful. A module of NaviGAIT specifically for children with cerebral palsy will be the first to be developed.
Biomathematical Analysis Of Cell Invasion: Migration Of Neural Crest Cells To Form The Enteric Nervous System
Funder
National Health and Medical Research Council
Funding Amount
$449,484.00
Summary
Extending scientific studies to a mathematical level is the way to produce deep understanding and control. Mathematics has been applied less to biology, particularly the biology of development, than to other branches of science, no doubt due to the innate complexity and technical difficulties of seeing and measuring what is actually going on. Labelling, imaging and computational tools to visualise biological processes are only now becoming available. To build our bodies during embryonic developm ....Extending scientific studies to a mathematical level is the way to produce deep understanding and control. Mathematics has been applied less to biology, particularly the biology of development, than to other branches of science, no doubt due to the innate complexity and technical difficulties of seeing and measuring what is actually going on. Labelling, imaging and computational tools to visualise biological processes are only now becoming available. To build our bodies during embryonic development, cells must move; this is called cell migration. The same process occurs throughout life in wound repair. Uncontrolled migration is the hallmark of malignant cancers, where it is called invasion. The molecular mechanisms in cells that allow them to move are just beginning to be understood. However, the big questions determining the general rules of migration are more difficult to approach. Here are some examples of such questions. When to migrate? Where to migrate to? Which pathways? How many cells to migrate? How far? How fast? How to stop? Such simple questions are still unanswered. We are pioneering a novel and unique approach combining imaging of real cells migrating in real tissues (digital time-lapse movies) with mathematical modelling to understand the driving forces of cell migration-invasion. This technology is here applied to a particular example of cell migration where precursor nerve cells migrate all the way along the length of the gastro-intestinal tract in early development. This process gives rise to fatal birth defects associated with migration failure. The development of the nervous system in the gut has features in common with all other migrations and invasions, normal and pathological. A much more profound knowledge of the big picture of the developmentally and clinically crucial process of cell migration-invasion will emerge from this marriage of biological experimentation and mathematical modelling.Read moreRead less
The Australian Parkinson's Project - Uncovering Genetic Risk Factors For Sporadic PD
Funder
National Health and Medical Research Council
Funding Amount
$768,546.00
Summary
Parkinson s disease (PD) is a progressively disabling movement disorder afflicting many elderly Australians. It is caused by the degeneration of specific nerve cells in the brain that produce certain chemicals and patients suffer from an inability to move fluently (or ultimately at all). At present we do not know what triggers this neurodegeneration, but it is believed that complex interactions between inherited (genetic) and environmental factors contribute significantly to the phenomenon. This ....Parkinson s disease (PD) is a progressively disabling movement disorder afflicting many elderly Australians. It is caused by the degeneration of specific nerve cells in the brain that produce certain chemicals and patients suffer from an inability to move fluently (or ultimately at all). At present we do not know what triggers this neurodegeneration, but it is believed that complex interactions between inherited (genetic) and environmental factors contribute significantly to the phenomenon. This project aims to learn more about these complex interactions and their association with PD. People with PD and unaffected individuals will be recruited from throughout Australia and we will look for specific combinations of genetic, environmental and lifestyle factors that either increase or decrease an individual's risk for PD. This research will identify the most common dominant genetic and environmental influences for PD in Australia, enabling scientists to focus on the most relevant biological pathways to target therapeutically.Read moreRead less
Dissecting The Molecular Mechanisms Driving Cell Migration During Neurulation Triggered By The Netrin Receptor, Neogenin
Funder
National Health and Medical Research Council
Funding Amount
$432,750.00
Summary
In humans, abnormalities in brain and spinal cord formation during early embryogenesis result in congenital syndromes such as spina bifida and anencephaly. These defects occur at a rate of 1-1000 pregnancies and are therefore a major contributor to pre- and perinatal deaths. In the early embryo, the brain and spinal cord begin as a hollow tube of cells (the neural tube) that subsequently expands into the complex structures seen at birth. It is known that the neural tube is formed by a complex pr ....In humans, abnormalities in brain and spinal cord formation during early embryogenesis result in congenital syndromes such as spina bifida and anencephaly. These defects occur at a rate of 1-1000 pregnancies and are therefore a major contributor to pre- and perinatal deaths. In the early embryo, the brain and spinal cord begin as a hollow tube of cells (the neural tube) that subsequently expands into the complex structures seen at birth. It is known that the neural tube is formed by a complex process in which early neural cells migrate toward the midline of the embryo and subsequently coalesce. This project seeks to determine the function of one molecular signaling pathway (the neogenin pathway) that has been implicated in driving these cell migration events. We will initially use the frog, Xenopus laevis, as our embryonic model since the developmental processes that form the Xenopus neural tube closely parallel those ocurring in the human embryo. This model will allow us to identify the molecules in the neogenin signaling pathway. We will also create mice that carry a mutation in the neogenin gene so that we can study neogenin function in the mammal. We anticipate that these studies will provide important insights into the development of the central nervous system and also into the aberrant molecular processes underlying neural tube defects in man.Read moreRead less
Advances In The Understanding Of Autoimmune Encephalitides And Associated Movement Disorders In Children
Funder
National Health and Medical Research Council
Funding Amount
$68,832.00
Summary
Encephalitis in childhood can be devastating with long lasting effects and mortality. This research focuses on children who suffer from encephalitis due to an autoimmune process. In such cases many children present with involuntary abnormal body movements. This project will explore whether differences in the nature of these movements or in electroencephalography or brain imaging with MRI, can help early differentiation of different types of autoimmune encephalitis.