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
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 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 Role Of A Protease Activated Receptor System In Prostate Cancer Bone Metastasis.
Funder
National Health and Medical Research Council
Funding Amount
$582,204.00
Summary
Prostate cancer is one of the most significant health issues for men. This disease occurs because certain proteins start to function abnormally. Our focus is on a protein called PAR2, present on the surface of prostate cancer cells and bone cells, which we propose helps cancer cells to spread to bone. In our project, we aim to understand how this happens so that we can develop ways to block prostate cancer metastasis to bone.
Pathophysiology And Prevention Of Methotrexate Chemotherapy-induced Bone Growth Defects
Funder
National Health and Medical Research Council
Funding Amount
$622,598.00
Summary
Childhood chemotherapy often causes growth arrest, osteoporosis, and fractures in cancer patients and survivors. Using a rat model, this project will study how the most commonly used chemotherapy drug methotrexate causes bone growth defects and examine any protective effects of two natural-derived substances. This work will increase our knowledge on chemotherapy-induced bone growth defects, and will be useful for developing a preventative treatment.
Genetic And Metabolic Determinants Of Spontaneous Physical Activity
Funder
National Health and Medical Research Council
Funding Amount
$67,828.00
Summary
It could be argued that obesity is the most significant public health problem facing Australians today. Almost one in five adult Australians are obese, making them highly susceptible to diabetes, coronary heart disease, high blood pressure, high blood lipid levels, and some cancers, as well as reduced psychosocial health. There is therefore an urgent need to reduce the prevalence of obesity in our society. Unfortunately, attempts to sustain significant weight loss by dieting and exercise are nea ....It could be argued that obesity is the most significant public health problem facing Australians today. Almost one in five adult Australians are obese, making them highly susceptible to diabetes, coronary heart disease, high blood pressure, high blood lipid levels, and some cancers, as well as reduced psychosocial health. There is therefore an urgent need to reduce the prevalence of obesity in our society. Unfortunately, attempts to sustain significant weight loss by dieting and exercise are nearly always unsuccessful and none of the anti-obesity drugs currently on the market are safe to use long-term. Effective treatments for obesity are only likely to be developed once we understand more about what controls body weight regulation. An inactive lifestyle is clearly a risk factor for obesity. Spontaneous physical activity (or activity associated with daily life, as opposed to formal exercise) can play a major role in determining body weight. Recent work suggests that spontaneous physical activity is influenced not only by our environment but by our biological makeup as well (i.e. genetic and metabolic factors). The aim of this study is to investigate what some of these factors are, and whether they are responsible for altering body weight regulation in animal models of obesity. Specifically we will be looking at whether spontaneous physical activity is influenced by circulating hormones (such as leptin, oestrogen, and pancreatic polypeptide) and a messenger molecule (nitric oxide), and we will also identify genes which influence physical activity in a mouse model of obesity. By examining the genetic and metabolic basis of inactivity in obese rodent models, this project will further our understanding of how energy balance is disturbed in obesity in the hope of developing better therapies to treat obesity in the future.Read moreRead less