Elucidating Mechanisms For The Biological Activities Of CD46.
Funder
National Health and Medical Research Council
Funding Amount
$228,000.00
Summary
The CD46 protein enables entry into cells of a number of different pathogens, including the measles virus, Neisseria meningitidis (the major cause of meningococcal disease), Neisseria gonorrhoea, Human Herpes Virus 6, and group A streptococcus. In addition, by binding to a key blood component that is often attached to foreign pathogens, CD46 can facilitate binding and entry of other pathogens. As well as facilitating entry of the pathogen, it has recently become apparent that CD46 binding trigge ....The CD46 protein enables entry into cells of a number of different pathogens, including the measles virus, Neisseria meningitidis (the major cause of meningococcal disease), Neisseria gonorrhoea, Human Herpes Virus 6, and group A streptococcus. In addition, by binding to a key blood component that is often attached to foreign pathogens, CD46 can facilitate binding and entry of other pathogens. As well as facilitating entry of the pathogen, it has recently become apparent that CD46 binding triggers a wide range of responses from the human host. Some of these responses are likely to further facilitate survival and proliferation of the pathogen, but others are more likely to facilitate host defence. For examples, signals triggered by binding to CD46 can both abrogate some aspects of the immune response (and it is though that this immunosuppression contributes to the secondary infections that cause the death of nearly one million children each year) and facilitate other aspects of the immune response. By understanding the mechanisms by which CD46 triggers these complex responses, we firstly be able to dissect how important each of these processes are to the overall pathogenecity of the virus or bacteria. Furthmore, this understanding will allow us to design better vaccines and drugs to combat these diseases.Read moreRead less
Deregulation Of Ribosome Signalling, Synthesis And Function During Malignant Transformation.
Funder
National Health and Medical Research Council
Funding Amount
$522,773.00
Summary
A major feature of tumour progression is accelerated cell growth and protein synthesis. Moreover, increased synthesis of ribosomes (the protein synthetic machinery) is associated with malignancy suggesting that it may play a causal role in cancer formation. In support of this, specific inhibitors of both ribosome biogenesis and function are extremely effective in inhibiting the growth of some tumours. This study will examine the mechanisms of deregulation of ribosome biogenesis and function duri ....A major feature of tumour progression is accelerated cell growth and protein synthesis. Moreover, increased synthesis of ribosomes (the protein synthetic machinery) is associated with malignancy suggesting that it may play a causal role in cancer formation. In support of this, specific inhibitors of both ribosome biogenesis and function are extremely effective in inhibiting the growth of some tumours. This study will examine the mechanisms of deregulation of ribosome biogenesis and function during cancer formation and assess for the first time whether aberrant regulation of ribosome biogenesis and function directly contributes to the initiation and-or progression of cancer.Read moreRead less
Active Transport Of Calcium Across Dental Enamel Cells - Testing A New Paradigm
Funder
National Health and Medical Research Council
Funding Amount
$258,000.00
Summary
Dental enamel defects and tooth loss affect over half our population, resulting in substantial suffering and economic costs. It is likely that many enamel defects could be prevented, and replacement teeth made more lifelike, if more was known about the cells responsible for producing enamel. A particular problem is our lack of understanding about how enamel-forming cells avoid overdosing on calcium, which can lead to cellular toxicity. The overall aim of this research is to use the latest cell b ....Dental enamel defects and tooth loss affect over half our population, resulting in substantial suffering and economic costs. It is likely that many enamel defects could be prevented, and replacement teeth made more lifelike, if more was known about the cells responsible for producing enamel. A particular problem is our lack of understanding about how enamel-forming cells avoid overdosing on calcium, which can lead to cellular toxicity. The overall aim of this research is to use the latest cell biology and biochemical techniques to elucidate the mechanisms of calcium handling in enamel cells, with developing teeth from rat as the experimental model. Our focus is on calcium transport mechanisms, a field where past theories were overturned by our recent findings with gene-knockout animals. We will test a new theory that has arisen from our investigations, using drugs and gene-silencing techniques to interfere with the cellular machinery now thought to be crucial for transporting calcium. By providing strong physiological evidence for this new mechanism, our expected results will define specific proteins that might be targeted by drugs and nutrition, and provide important information about how dietary fluoride and caffeine affect enamel quality. These findings would change thinking about how enamel defects can be prevented and provide a solid foundation to the exciting new field of dental bioengineering, whose goal is to coax stem cells to make natural replacement teeth.Read moreRead less