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Analysis Of Calcitonin Receptor Binding And Function
Funder
National Health and Medical Research Council
Funding Amount
$382,821.00
Summary
Receptors form a basic intermediary as the acceptor site for signals that are transmitted between the cells that make up our body. Modulation of receptors, therefore, forms a key target in our ability to treat disease. The largest class of receptors is the superfamily of G protein-coupled receptors (GPCRs), which transmit signals within a cell via proteins called G proteins. GPCRs form between 1 and 5% of the entire repertoire of human genes. One group of GPCRs provide the target for small prote ....Receptors form a basic intermediary as the acceptor site for signals that are transmitted between the cells that make up our body. Modulation of receptors, therefore, forms a key target in our ability to treat disease. The largest class of receptors is the superfamily of G protein-coupled receptors (GPCRs), which transmit signals within a cell via proteins called G proteins. GPCRs form between 1 and 5% of the entire repertoire of human genes. One group of GPCRs provide the target for small protein molecules that cirulate through the body. One such circulating molecule is calcitonin, a peptide that plays an important role in maintaining circulating calcium levels in the body, which is essential for proper maintenance of the skeleton. As a consequence of this action, calcitonin is an important clinically used tool in the treatment of bone disease such as osteoporosis and Paget's disease. Due to the molecular nature of calcitonin and its receptors (and other related receptors) that have a broad, complex mechanism of interaction, we have very little definitive information on how calcitonin interfaces with its receptor to signal to target cells. The current project utilises a novel method of permanently linking calcitonin to its receptor, allowing identification of how the two components come together. Furthermore, the project will explore the functional consequence of naturally occuring genetic variation (genotype) and also examine whether the occurence of specific calcitonin receptor genotype is correlated with disease markers for osteoporosis and obesity. This information provides important fundamentals for understanding how this and related receptors work and the potential for rational design of improved theraupeutic tools.Read moreRead less
The Physiological Role Of Calcitonin And Its Receptor In Bone Cell Metabolism.
Funder
National Health and Medical Research Council
Funding Amount
$496,446.00
Summary
Throughout adult life, bone tissue is continuously remodelled. The two main processes involved in bone remodelling, are bone formation and bone breakdown. Bone formation is controlled by cells known as osteoblasts and bone breakdown is controlled by cells known as osteoclasts. Under normal circumstances these two processes are tightly coupled. Excessive breakdown of bone, causes these two processes to become unbalanced and results in bone loss. This is the basis of many bone diseases such as ost ....Throughout adult life, bone tissue is continuously remodelled. The two main processes involved in bone remodelling, are bone formation and bone breakdown. Bone formation is controlled by cells known as osteoblasts and bone breakdown is controlled by cells known as osteoclasts. Under normal circumstances these two processes are tightly coupled. Excessive breakdown of bone, causes these two processes to become unbalanced and results in bone loss. This is the basis of many bone diseases such as osteoporosis, a condition in which the bones become fragile and therefore more susceptible to fracture. 1 in 2 women and 1 in 3 men aged 70 years and older suffer from osteoporosis in Australia. Despite this, the mechanisms which control osteoclast breakdown of bone are not well understood. Our laboratory is interested in how hormones affect osteoclast action. We plan to examine the role of the hormone calcitonin, an important inhibitor of osteoclastic bone breakdown. This will be achieved by studying transgenic mice in which the receptor, or target, for calcitonin is specifically removed from osteoclasts. This will allow us to precisely determine the role of calcitonin in osteoclast function. Data generated by our research group indicates that calcitonin is also involved in controlling bone formation, however, the way in which calcitonin acts on osteoblasts remains poorly understood. Therefore, studying our transgenic mice will also help clarify the role calcitonin plays in bone formation. Current treatment for osteoporosis involves the administration of drugs which inhibit bone breakdown. This project will increase our understanding of how calcitonin acts to regulate bone breakdown and bone formation and may assist in the design of new therapies for osteoporosis. We believe that this research is of great importance as osteoporosis is becoming more prevalent as the population ages.Read moreRead less
The Physiological Relevance Of Calcitonin In Osteoclast Function
Funder
National Health and Medical Research Council
Funding Amount
$437,640.00
Summary
Throughout adult life, bone tissue is continuously remodelled. The two main processes involved in bone remodelling, are bone formation and bone breakdown. Bone formation is controlled by cells known as osteoblasts and bone breakdown is controlled by cells known as osteoclasts. Under normal circumstances these two processes are tightly coupled. Excessive breakdown of bone, causes these two processes to become unbalanced and results in bone loss. This is the basis of many bone diseases such as ost ....Throughout adult life, bone tissue is continuously remodelled. The two main processes involved in bone remodelling, are bone formation and bone breakdown. Bone formation is controlled by cells known as osteoblasts and bone breakdown is controlled by cells known as osteoclasts. Under normal circumstances these two processes are tightly coupled. Excessive breakdown of bone, causes these two processes to become unbalanced and results in bone loss. This is the basis of many bone diseases such as osteoporosis, a condition in which the bones become fragile and therefore more susceptible to fracture. 1 in 2 women and 1 in 5 men aged 70 years and older suffer from osteoporosis in Australia. Despite this, the mechanisms which control osteoclast breakdown of bone are not well understood. Our laboratory is interested in how hormones affect osteoclast action. We plan to examine the role of the hormone calcitonin, thought to be important inhibitor of osteoclastic bone breakdown. This will be achieved by studying transgenic mice in which the receptor for calcitonin is specifically removed from osteoclasts. This will allow us to precisely determine the role of calcitonin in osteoclast function. Current treatment for osteoporosis involves the administration of drugs which inhibit bone breakdown. This project will increase our understanding of how calcitonin acts to regulate the function of osteoclasts. We believe that this research is of great importance as osteoporosis is becoming more prevalent as the population ages.Read moreRead less
Identifying The Physiological Actions Of Calcitonin
Funder
National Health and Medical Research Council
Funding Amount
$683,040.00
Summary
Calcitonin is a hormone whose main action has long been regarded as the slowing down of bone breakdown, however, its importance in human physiology is unknown. The aim of this study is to understand the role of calcitonin in regulating bone formation and protecting the skeleton in times of calcium stress, such as lactation. These results will greatly advance our understanding of the control of bone and calcium homeostasis, which will have implications for the treatment of bone disorders.
Breast cancer remains the major form of cancer diagnosed in women, and is still the leading cause of cancer death. There remains a pressing need to find better ways to treat this disease. Increasingly, cancer treatments will make use of a growing knowledge of the factors that normally regulate cell growth, and will apply this knowledge to make cancer cells more sensitive to existing anticancer treatments. We are proposing here to study the hormone calcitonin as a novel regulator of cancer cell g ....Breast cancer remains the major form of cancer diagnosed in women, and is still the leading cause of cancer death. There remains a pressing need to find better ways to treat this disease. Increasingly, cancer treatments will make use of a growing knowledge of the factors that normally regulate cell growth, and will apply this knowledge to make cancer cells more sensitive to existing anticancer treatments. We are proposing here to study the hormone calcitonin as a novel regulator of cancer cell growth. Calcitonin is better known as a hormone that inhibits bone loss, by acting on bone resorbing cells called osteoclasts. However, our present proposal is based on our recent finding that the receptor for calcitonin is for some reason also found in many breast cancers. Moreover, we have shown that calcitonin can potently inhibit the growth of cells that have the calcitonin receptor on their surface. We plan to extend these findings in 4 ways: 1 We will make use of a large bank of breast cancer samples at the Royal Adelaide Hospital to determine whether the presence of the calcitonin receptor in breast cancers is related to other features of the tumours, such as their propensity to spread to other organs. 2 We will investigate the mechanisms by which calcitonin slows the growth of cells. 3 We have unique access to new calcitonin-like molecules, called calcitonin mimetics, which we will investigate for the ability to inhibit cell growth. These molecules are much cheaper and probably easier to administer than calcitonin itself. 4 We will investigate whether treatment of cells with calcitonin makes them more sensitive to other anticancer treatments. We hope that success in this project will lead to a more detailed understanding of the way that molecules like calcitonin can regulate cell growth and to new treatment options for cancer.Read moreRead less