Browsing by keyword "*Bone Remodeling"
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Bone remodeling in rheumatic disease: a question of balanceThe past decade has observed an explosion of new information regarding the impact of inflammation on bone. In rheumatic diseases, several factors that act as both immune modulators and regulators of bone homeostasis have been shown to mediate an imbalance in bone resorption and bone formation resulting in joint degeneration. In rheumatoid arthritis (RA), focal bone loss is due to excess bone resorption by osteoclasts. Resorption is mediated in part by increased local expression of the cytokine receptor activator of nuclear factor-kappaB ligand (RANKL) compared with expression of its decoy receptor osteoprotegerin (OPG). Bone formation by osteoblasts is also impaired at erosion sites in RA, and inhibitors of the canonical Wingless (Wnt) signaling pathway, including DKK1, have been implicated in the suppression of normal osteoblast function at these sites. Inhibition of DKK1 in an animal model of RA attenuated bone erosion by increasing OPG expression as well as promoting bone formation. In contrast to RA, inflammation in the spondyloarthropathies often results in excess periosteal bone formation, highlighting that the net impact of inflammation on bone is specific to the site at which inflammation occurs, and the cell types, cytokines, and factors present within the local bone microenvironment. This fertile area of research bears watching for the identification of novel targets for the prevention of abnormal bone remodeling in inflammatory diseases.
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Secreted frizzled related protein 1 is a target to improve fracture healingGenetic studies have identified a high bone mass of phenotype in both human and mouse when canonical Wnt signaling is increased. Secreted frizzled related protein 1 (sFRP1) is one of several Wnt antagonists and among the loss-of-function mouse models in which 32-week-old mice exhibit a high bone mass phenotype. Here we show that impact fracture healing is enhanced in this mouse model of increased Wnt signaling at a physiologic level in young (8 weeks) sFRP1(-/-) mice which do not yet exhibit significant increases in BMD. In vivo deletion of sFRP1 function improves fracture repair by promoting early bone union without adverse effects on the quality of bone tissue reflected by increased mechanical strength. We observe a dramatic reduction of the cartilage callous, increased intramembranous bone formation with bone bridging by 14 days, and early bone remodeling during the 28-day fracture repair process in the sFRP1(-/-) mice. Our molecular analyses of gene markers indicate that the effect of sFRP1 loss-of-function during fracture repair is to accelerate bone healing after formation of the initial hematoma by directing mesenchymal stem cells into the osteoblast lineage via the canonical pathway. Further evidence to support this conclusion is the observation of maximal sFRP1 levels in the cartilaginous callus of a WT mouse. Hence sFRP1(-/-) mouse progenitor cells are shifted directly into the osteoblast lineage. Thus, developing an antagonist to specifically inhibit sFRP1 represents a safe target for stimulating fracture repair and bone formation in metabolic bone disorders, osteoporosis and aging.