Molecular Characterization Of V-ATPase V0 Domain Subunits E1 And E2 In Osteoclast
Funder
National Health and Medical Research Council
Funding Amount
$558,909.00
Summary
Osteoporotic fractures in the elderly are often linked to increased mortality rates. Excess bone resorption is a major contributor to the onset of the disease. The proposed project focuses on the investigation of the molecular mechanisms of acid secretion that is required for the bone degradation in body. The project will examine the role of the proton pump in bone resorption and seek potential targets for the treatment of osteoporosis.
The Role Of Perlecan In Tensional Connective Tissues
Funder
National Health and Medical Research Council
Funding Amount
$605,037.00
Summary
Musculoskeletal diseases affect tension and weight bearing connective tissues which have notoriously poor repair capabilities. These conditions are difficult to treat clinically and surgical repair in many cases does not provide a return to optimal joint function impinging on the quality of life of afflicted individuals and their carers. Our project aims to better understand the structure and function of these tissues in health and disease with a view to improving repair strategies.
Manipulating The Anabolic And Catabolic Responses For Bone Tissue Engineering
Funder
National Health and Medical Research Council
Funding Amount
$58,202.00
Summary
The repair of large bone defects represents a significant clinical problem. Evolving tissue engineering technologies may lead to significant improvements in orthopaedic treatments for these problems. We plan to compare novel biological approaches designed to maximise new bone formation while preventing bone resorption with existing synthetic graft materials. Our research data will be readily translated from the laboratory to a clinical setting.
V-ATPases Subunit D2 Is Critical For Acdification And Bone Resorption.
Funder
National Health and Medical Research Council
Funding Amount
$531,264.00
Summary
Overproduction and excessive activity of osteoclasts underlines many lytic bone disorders such as osteoporosis, Paget's disease and tumor-induced bone loss. The vacuolar proton pump (V-ATPase) located on the plasma membrane of the osteoclast is critical for osteoclastic bone resorption and, therefore represents a potential molecular target for the discovery of novel bone anti-resorptive agents. The proposed project addresses the fundamental role of the V-ATPase in osteoclast differentiation, aci ....Overproduction and excessive activity of osteoclasts underlines many lytic bone disorders such as osteoporosis, Paget's disease and tumor-induced bone loss. The vacuolar proton pump (V-ATPase) located on the plasma membrane of the osteoclast is critical for osteoclastic bone resorption and, therefore represents a potential molecular target for the discovery of novel bone anti-resorptive agents. The proposed project addresses the fundamental role of the V-ATPase in osteoclast differentiation, acidification and bone resorption. Understanding the molecular and cellular mechanisms by which V-ATPases regulate osteoclast function and bone resorption will facilitate the development of novel and selective inhibitors for the treatment of lytic bone disordersRead moreRead less
Osteal Macrophages As Therapeutic Targets For Fracture Repair
Funder
National Health and Medical Research Council
Funding Amount
$618,015.00
Summary
Fragility fracture associated with osteoporosis is a substantial health problem costing $1.62 billion to treat in 2012 in Australia. There is no approved therapy to improve and accelerate fracture healing to help reduce this increasing health burden. This research will advance understanding of fracture repair in healthy and osteoporotic bone and progress development of a fracture therapy to improve bone repair by promoting specialised immune cells.
Failure of bone healing leads to significant pain and disability, such that augmentation of fracture repair is a dynamic and important field of study. A full understanding of bone repair is necessary before we can hope to introduce novel successful therapies. We believe that a improved understanding of the origins of the cells involved with bone healing may lead to new surgical, drug and cell-based therapies for the treatment of recalcitrant bone repair. Stem cells originating from the bone marr ....Failure of bone healing leads to significant pain and disability, such that augmentation of fracture repair is a dynamic and important field of study. A full understanding of bone repair is necessary before we can hope to introduce novel successful therapies. We believe that a improved understanding of the origins of the cells involved with bone healing may lead to new surgical, drug and cell-based therapies for the treatment of recalcitrant bone repair. Stem cells originating from the bone marrow and periosteum are known to differentiate into mature bone cells and produce bone. However, these tissues are damaged or have poor access to the site of bone injury in many severe open fractures. In these cases, bone repair often initiates in a region adjacent to an opposing muscle. This has led us to speculate that cells from the muscle may directly contribute to bone repair. Published studies, which have be confirmed by our group, have demonstrated the strong potential for muscle-derived progenitor cells (satellite cells) to become bone-like in response to stimuli such as bone morphogenic proteins. To put bone-forming potential of muscle cells in perspective, we plan to expand on these studies and compare mouse satellite cells with mouse bone marrow stem cells. In addition, we plan to use a transgenic mouse whose muscle cells become permanently genetically transformed to stain blue. This mouse will allow us to assess the fate of muscle cells and their contribution to bone formation in ectopic bone formation and fracture repair models. This study will explore on the most basic level the cellular contribution of muscle to bone repair. The results of this research project will significantly influence our therapeutic directions for improving fracture repair in the future.Read moreRead less