Cellular Responses To Thrombin In Skeletal Pathology
Funder
National Health and Medical Research Council
Funding Amount
$120,775.00
Summary
Many diseases of bones, such as osteoporosis and delayed fracture repair, result from the abnormal function of bone cells. Factors regulating bone cell function are, therefore, important in maintaining a healthy skeleton, as well as in the skeleton's response to disease. The enzyme thrombin is involved in blood coagulation but also causes bone cells to alter their behaviour. Thrombin stimulates proliferation of bone-forming cells and protects them from premature death. Thrombin also stimulates t ....Many diseases of bones, such as osteoporosis and delayed fracture repair, result from the abnormal function of bone cells. Factors regulating bone cell function are, therefore, important in maintaining a healthy skeleton, as well as in the skeleton's response to disease. The enzyme thrombin is involved in blood coagulation but also causes bone cells to alter their behaviour. Thrombin stimulates proliferation of bone-forming cells and protects them from premature death. Thrombin also stimulates the breakdown of bone. We will investigate how thrombin's effects on bone cell behaviour influence the course of bone healing. We will also determine how thrombin stimulates bone breakdown and increases survival of bone-forming cells. This study will contribute to the understanding of how bone cells function in health and disease.Read moreRead less
We have found that leptin, a new hormone produced by fat cells which regulates appetite and metabolism, is a powerful inhibitor of osteoclast formation. Osteoclasts are large cells present in bone which are responsible for bone resorption and therefore these cells contribute to common bone conditions such as osteoporosis, Paget's disease and bone cancer. Osteoporosis causes a great deal of pain and disability and it alone costs the Australian taxpayers more than $400 million per year. Persons wh ....We have found that leptin, a new hormone produced by fat cells which regulates appetite and metabolism, is a powerful inhibitor of osteoclast formation. Osteoclasts are large cells present in bone which are responsible for bone resorption and therefore these cells contribute to common bone conditions such as osteoporosis, Paget's disease and bone cancer. Osteoporosis causes a great deal of pain and disability and it alone costs the Australian taxpayers more than $400 million per year. Persons who are overweight tend to have higher circulating blood levels of leptin and also tend to have denser bones, which suggests that there might be a relationship between blood leptin and bone density or strength. Furthermore, leptin is produced in the bone marrow which is where osteoclasts are produced. Osteoclasts are formed from white blood cells which are present in the bone marrow and the blood. Very recent discoveries have identified a family of new factors which play a key role in the formation of osteoclasts. One of these factors has been called osteoprotegerin and is an inhibitor of osteoclast formation. Mutant mice lacking osteoprotegerin have greatly increased numbers of osteoclasts and severe osteoporosis whereas mutants with too much osteoprotegerin have bones which are much denser than normal. The availability of these factors now allows the generation of human osteoclasts in the laboratory which enables the further study of how the process is regulated. We have found that leptin increases the amount of osteoprotegerin produced by white blood cells and we believe that this is the major way that leptin inhibits osteoclast generation. In this project, we intend to further investigate how and why leptin is able to influence the generation and function of osteoclasts as leptin may be a suitable treatment for osteoporosis and other bone diseases.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 Role Of Protease-activated Receptor-2 In Regulation Of Bone Metabolism
Funder
National Health and Medical Research Council
Funding Amount
$216,100.00
Summary
Many diseases of bones, such as osteoporosis and delayed fracture repair, result from the abnormal function of bone cells. Factors regulating bone cell function are, therefore, important in maintaining a healthy skeleton, as well as in the skeleton's response to disease. We have recently demonstrated the presence of a receptor called PAR-2 on bone-forming cells. We have also shown that activation of PAR-2 inhibits the development of bone-resorbing cells (osteoclasts) in response to hormones. We ....Many diseases of bones, such as osteoporosis and delayed fracture repair, result from the abnormal function of bone cells. Factors regulating bone cell function are, therefore, important in maintaining a healthy skeleton, as well as in the skeleton's response to disease. We have recently demonstrated the presence of a receptor called PAR-2 on bone-forming cells. We have also shown that activation of PAR-2 inhibits the development of bone-resorbing cells (osteoclasts) in response to hormones. We plan to investigate the mechanism of this effect, as well as to identify how PAR-2 activation modulates other responses of bone cells to hormones. Molecules that activate PAR-2 are present in bone in certain disease situations, but it is not known what activates PAR-2 in bone under normal conditions. We will identify physiological activators of PAR-2 within bone.Read moreRead less
Role Of The Growth Hormone Binding Protein As A Transcriptional Activator
Funder
National Health and Medical Research Council
Funding Amount
$387,226.00
Summary
Growth hormone is an important hormone therapeutic for treating dwarfism. Recently, many new therapeutic applications for growth hormone have been discovered, particularly in relation to its role as an anabolic agent. These include post surgery recovery, enhanced bone fracture healing, Crohns disease, dilated cardiomyopathy, infertility and of course, ageing. This proposal examines a novel way that GH could work, that is by sending the extracellular part of its receptor (GHBP) to the nucleus, wh ....Growth hormone is an important hormone therapeutic for treating dwarfism. Recently, many new therapeutic applications for growth hormone have been discovered, particularly in relation to its role as an anabolic agent. These include post surgery recovery, enhanced bone fracture healing, Crohns disease, dilated cardiomyopathy, infertility and of course, ageing. This proposal examines a novel way that GH could work, that is by sending the extracellular part of its receptor (GHBP) to the nucleus, where it can directly activate gene readout. This would have the effect of augmenting the normal action of GH to regulate gene readout. We have exciting preliminary data which makes us think this may be a new mechanism for hormone activation of genes. The level of GHBP in the nucleus is regulated, and if a defect in export of the GHBP occurred, this would lead to accumulation of nuclear GHBP and stimulate cell proliferation. This may be important in cancer cell proliferation, since we find nuclear GHBP in cancers.Read moreRead less
Investigation Of COX-2 Regulation Of Bone Turnover And Mechanically Induced Bone Formation By Genetic Overexpression.
Funder
National Health and Medical Research Council
Funding Amount
$440,750.00
Summary
This project is important because it uses novel experimental models to advance our knowledge of prostaglandin biology in normal and pathological bone remodelling, and the response of the skeleton to increased physical activity. We expect that a genetic modification in mice to increase the normal production of key prostaglandin enzymes, cyclooxygenase-2 (COX-2), in bone cells will increase the number of cells that remove bone (osteoclasts), and increase bone loss and the rate of bone turnover whe ....This project is important because it uses novel experimental models to advance our knowledge of prostaglandin biology in normal and pathological bone remodelling, and the response of the skeleton to increased physical activity. We expect that a genetic modification in mice to increase the normal production of key prostaglandin enzymes, cyclooxygenase-2 (COX-2), in bone cells will increase the number of cells that remove bone (osteoclasts), and increase bone loss and the rate of bone turnover when compared to normal mice. We believe this will occur via the effect of prostaglandins on expression of genes that control osteoclast formation. This will be tested by examining the structure of the skeleton, and the expression of certain genes, in transgenic mice at different ages from 2-8 months. These effects may be exacerbated in conditions of increased bone turnover, such as postmenopausal bone loss. This will be tested by examining the bone structure and gene expression in adult mice following removal of their ovaries. Due to the role of COX-2 in adaptation of bone to mechanical loading, we also expect the load-bearing skeleton to be more sensitive to increased weight-bearing activity. We will investigate this hypothesis by applying mechanical loads to the tibiae of mice in a controlled manner and then analysing the bone structure. Knowledge of specific pathways by which bone formation can be stimulated is important for developing novel approaches to induction and augmentation of osteogenesis in skeletal diseases associated with ageing or disability, or for maintenance of new bone around implants. The discovery that COX-2 is a key enzyme in mechanotransduction and osteoclastogenesis in bone, and a pharmacological target for modulating inflammation, has considerable clinical significance. Exploiting this knowledge requires precise knowledge of the role of this enzyme in bone remodelling and adaptation and our experiments will contribute significantly to that knowledgeRead moreRead less
Osteoclasts (OC) are large multinucleated cells present in bone that are responsible for bone resorption. The renewal of bone and bone growth are regulated by the opposing actions of OCs and osteoblasts, cells that form new bone. Together, with other accessory cells in the bone marrow, these constitute 'bone-forming units' (BFU). Excess production or over-activation of OCs in the BFU leads to common bone conditions such as osteoporosis, Paget's disease and the bone lysis caused by bone cancers. ....Osteoclasts (OC) are large multinucleated cells present in bone that are responsible for bone resorption. The renewal of bone and bone growth are regulated by the opposing actions of OCs and osteoblasts, cells that form new bone. Together, with other accessory cells in the bone marrow, these constitute 'bone-forming units' (BFU). Excess production or over-activation of OCs in the BFU leads to common bone conditions such as osteoporosis, Paget's disease and the bone lysis caused by bone cancers. Osteoporosis causes a great deal of pain and disability and it alone costs the Australian taxpayers more than $400 million per year. OCs are formed from white blood cells that are present in the bone marrow and the blood. The recent discovery of a family of new factors that control the formation of OCs has enabled the generation of human OCs in the laboratory so now we can investigate the genes that control the process of conversion of white blood cells to OCs. An important advance in this project involves the use of cord blood that contains stem cells. These very na ve cells will enable us to study the very earliest genes that control differentiation of precursors to OC. We have found a number of genes that are regulated by these new bone-forming factors. In white blood cells the activation of particular genes can regulate OC formation. One example is vitamin D-upregulated gene, VDUP. This gene is of particular interest as it causes inhibition of the mechanism that leads to OC formation in the bone. Obviously, the ability to control a 'switch' that regulates OC formation may enable us to control the progress of bone loss in diseases such as osteoporosis. In this project, we intend to investigate how and why the genes that lead to OC formation are regulated and what influence the various bone cell factors have on the formation of bone-resorbing OCs. These studies will lead to the development of treatments for osteoporosis and other bone diseases.Read moreRead less