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
The Mechanisms Of The Anabolic Actions Of Androgens In Bone.
Funder
National Health and Medical Research Council
Funding Amount
$470,960.00
Summary
Androgens (male sex hormones) are one of the few agents that increase bone formation. Androgens act by binding to a specific protein, the androgen receptor (AR). To understand exactly how androgens increase bone formation, we will study mice in which the AR is inactivated only in bone forming cells at specific stages of their development. Understanding the way in which androgens act on bone to increase size and strength will be of great benefit in the design of new treatments for osteoporosis.
The Role Of Androgens In Osteoblast Development And Bone Metabolism.
Funder
National Health and Medical Research Council
Funding Amount
$487,500.00
Summary
Maintenance of the skeleton involves the processes of bone formation by cells known as osteoblasts and bone breakdown by cells known as osteoclasts. When these processes become unbalanced, bone loss results, which is the basis of osteoporosis. The reduced bone mass found in osteoporosis leads to an increased susceptibility to bone fracture. 1 in 2 women and 1 in 3 men over the age of 60 will suffer a fracture due to osteoporosis. The increasing incidence of osteoporotic fractures has lead to ren ....Maintenance of the skeleton involves the processes of bone formation by cells known as osteoblasts and bone breakdown by cells known as osteoclasts. When these processes become unbalanced, bone loss results, which is the basis of osteoporosis. The reduced bone mass found in osteoporosis leads to an increased susceptibility to bone fracture. 1 in 2 women and 1 in 3 men over the age of 60 will suffer a fracture due to osteoporosis. The increasing incidence of osteoporotic fractures has lead to renewed efforts to understand the actions of hormones on bone. Androgens, the male sex hormones, have beneficial effects on skeletal growth and bone maintenance in both males and females by stimulating osteoblasts. It is believed that androgens act by binding to a specific protein known as the androgen receptor (AR), which is only found in androgen-responsive cells. Although it is well documented in human and animal models that androgens stimulate osteoblasts to increase the formation of bone, the way in which they act on osteoblasts remains poorly understood. The aim of this project is to investigate the effects of androgens at different stages of the developing osteoblast. This will be achieved by making transgenic mice in which the androgen receptor has been inactivated only in osteoblasts at specific stages of their development. We hypothesise that the inactivation of the androgen receptor will have dramatic effects on the development and function of osteoblasts. This project will help clarify the role androgens play in bone formation and will give fundamental insights into the basic biology of bone in both normal and disease processes. As androgens are one of the few agents that act to increase bone formation, understanding the way in which they act is important for the treatment of osteoporosis in males and females. We believe that this research is of great importance as osteoporosis becomes more prevalent in our aging population.Read moreRead less
I am a biochemical geneticist working on inherited disorders that affect the musculoskeletal system. My major focus is determining the molecular basis of muscular dystrophies and bone and cartilage disorders.
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
Breast Cancer has a particular preference to form cancer metastases in bone where its presence is associated with bone destruction that frequently results in significant pain and disability. Bone seems to provide a fertile soil for breast cancer cells that have moved into the blood vessels from the original cancer site in the breast. Once tumour cells have invade bone marrow spaces from the blood vessels they are able to grow and induce the normal cells of the bone marrow to destroy the surround ....Breast Cancer has a particular preference to form cancer metastases in bone where its presence is associated with bone destruction that frequently results in significant pain and disability. Bone seems to provide a fertile soil for breast cancer cells that have moved into the blood vessels from the original cancer site in the breast. Once tumour cells have invade bone marrow spaces from the blood vessels they are able to grow and induce the normal cells of the bone marrow to destroy the surrounding hard bone. This allows the tumour to grow faster. Together these processed create a vicious cycle that contributes to the serious consequences of bone metastases. In this project we will be studying mice with breast cancer to understand what makes the bone marrow such a fertile and receptive site for breast cancer metastasis. In particular, we are looking at how the normal processes of bone renewal and repair contribute to the establishment of cancer in bone. We will use the body's own bone protecting protein, called osteoprotegerin, to test how blocking bone destruction will affect the ability of cancer cells to invade and grow in bone. This study has the potential to change the way bone metastases are treated. Treatment of breast cancer could be significantly improved if the fertile soil of bone could be modified to either block the targeting of breast cancer to bone, or to inhibit its growth there.Read moreRead less
Stem Cell Engineering To Establish Tolerance And Reverse Autoimmunity
Funder
National Health and Medical Research Council
Funding Amount
$497,250.00
Summary
The immune system is designed to protect us from harmful invaders such as bacteria, viruses and parasites. It should not attack our own tissues. However, in certain individuals, the immune system does attack our own tissues leading to life threatening conditions such as diabetes, multiple sclerosis and rheumatoid arthritis. To date, there is no cure for autoimmune diseases. Treatment is designed to treat the destructive effects of the disease. A strategy for achieving a cure is to program the im ....The immune system is designed to protect us from harmful invaders such as bacteria, viruses and parasites. It should not attack our own tissues. However, in certain individuals, the immune system does attack our own tissues leading to life threatening conditions such as diabetes, multiple sclerosis and rheumatoid arthritis. To date, there is no cure for autoimmune diseases. Treatment is designed to treat the destructive effects of the disease. A strategy for achieving a cure is to program the immune system to remove the harmful immune cells. Autoimmune gastritis which leads to pernicious anaemia is an autoimmune disease which affects the acid secreting cells of the stomach. To get a better understanding of autoimmune diseases, animal models are often used. We use a number of mouse models of autoimmune gastritis which closely resembles the human disease and thus makes a very good working model. Using these models we are exploring novel techniques aimed at reversing or curing established disease. This relies on removing the disease causing cells from the body and re-programming the immune system so as not to produce these cells.Read moreRead less
Monitoring Bone Loss And Response To Therapy Through Bone Material And Structural Composition
Funder
National Health and Medical Research Council
Funding Amount
$696,111.00
Summary
Millions of scripts are filled for treatment of osteoporosis. However, there is no way of knowing if these drugs are right for these individuals, if it improves bone strength or are actually doing harm. Bone density measurement is of limited value. We have developed a new analysis method that measures changes in bone structure that tell us if the treatment is or is not working so alternative treatment can be used. The aim of this study is to test this new method.
Identification Of Novel PTH Anabolic Targets In Osteoblasts
Funder
National Health and Medical Research Council
Funding Amount
$547,216.00
Summary
Osteoporosis is a major disease affecting Australians. Whilst there are a number of drugs available that will reduce bone loss, there are few drugs available that build new bone, and little is known of the action of these drugs. New targets have been identified that modulate bone formation, and this project aims to validate these in appropriate models and determine their mechanism of action.