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
Assessment Of Calcium Signaling In Breast Cancer Cells Associated With Epithelial-mesenchymal Transition
Funder
National Health and Medical Research Council
Funding Amount
$116,762.00
Summary
This research will assess the role of specific proteins that control cell function in a process which is important in the spread of cancer cells throughout the body. The work is aimed at identifying new targets for drugs that may be used to prevent or stop the spread of breast cancer cells to other organs such as the brain and liver.
Calcium acts as a signal to control cell processes important in cancer. The entry of calcium into the cell is regulated by calcium channels and we have found some channels are over-expressed in breast cancer. Altering the expression and activity of these calcium channels is a possible therapeutic approach for cancer. We will determine the reasons and consequences of alterations of calcium channels in breast cancer and whether they are viable anti-cancer therapies and biomarkers.
Regulation Of Nuclear Calcium Concentration In The Life Or Death Of Cells
Funder
National Health and Medical Research Council
Funding Amount
$195,047.00
Summary
The nucleus is the most prominent of all cell organelles and contains the primary genetic material for cellular development and growth. It performs some of the most important functions in the life and death of all living cells. However, little is known about many of the regulatory signals and events that control nuclear function. We will use new genetically-encoded sensor molecules that a living cell can be instructed to produce at various internal locations to explore important features of cell ....The nucleus is the most prominent of all cell organelles and contains the primary genetic material for cellular development and growth. It performs some of the most important functions in the life and death of all living cells. However, little is known about many of the regulatory signals and events that control nuclear function. We will use new genetically-encoded sensor molecules that a living cell can be instructed to produce at various internal locations to explore important features of cell control. This study will look specifically at how changes in the concentration of ionised Ca2+ in the nucleus control the switching on of genes and the initiation of programmed cell death pathways. This information is of significance to our understanding of normal cell growth and development, as well as abnormal growth (e.g. cancer).Read moreRead less
Anthracyclines Disrupt Ca2+ Signalling In Cardiomyocytes: A Contribution To Cardiac Toxicity
Funder
National Health and Medical Research Council
Funding Amount
$525,620.00
Summary
Anthracyclines are one of the most effective drugs used in chemotherapy, but cause side effects resulting in serious heart problems which can be fatal. The link between anthracycline therapy and the problems they cause in the heart is not fully defined. We will investigate mechanisms leading to these side effects and define specific targets of anthracyclines in the heart. It is hoped this will lead to the design of new drugs which counteract the side effects of anthracycline treatment.