To determine whether the acute inhibition of bone formation and deficit in bone mineral induced by skeletal unloading can be prevented, we studied the effects of intermittent parathyroid hormone (PTH) administration (8 g/100 g/day) on growing rats submitted to 8 days of skeletal unloading. Loss of weight bearing decreased periosteal bone formation by 34 and 51% at the tibiofibular junction and tibial midshaft, respectively, and reduced the normal gain in tibial mass by 35%. Treatment with PTH of normally loaded and unloaded animals increased mRNA for osteocalcin (؉58 and ؉148%, respectively), cancellous bone volume in the proximal tibia (؉41 and ؉42%, respectively), and bone formation at the tibiofibular junction (؉27 and ؉27%, respectively). Formation was also stimulated at the midshaft in unloaded (؉47%, p < 0.05), but not loaded animals (؊3%, NS). Although cancellous bone volume was preserved in PTH-treated, unloaded animals, PTH did not restore periosteal bone formation to normal nor prevent the deficit in overall tibial mass induced by unloading. We conclude that the effects of PTH on bone formation are region specific and load dependent. PTH can prevent the decrease in cancellous bone volume and reduce the decrement in cortical bone formation induced by loss of weight bearing.
ABSTRACT:Introduction: The metalloproteinase, pregnancy-associated plasma protein-A (PAPP-A) functions to enhance local insulin-like growth factor (IGF)-I bioavailability through cleavage of inhibitory IGF binding proteins. Because IGF-I is an important regulator of skeletal growth and remodeling and PAPP-A is highly expressed by osteoblastic cells, we hypothesized that, in the absence of PAPP-A, bone physiology would be compromised because of a blunting of local IGF-I action even in the presence of normal circulating IGF-I levels. Materials and Methods: pQCT, CT, histomorphometry, and mechanical strength testing were performed on bones from PAPP-A knockout (KO) mice and wildtype (WT) littermates at 2-12 mo of age. IGF-I levels and bone formation and resorption markers were determined in sera from these animals. Results: Volumetric BMD in PAPP-A KO mice measured by pQCT at the femoral midshaft, which is primarily cortical bone, was 10% less than WT at 2 mo. This difference was maintained at 4, 6, and 12 mo. Cortical thickness at this site was similarly decreased. On the other hand, trabecular bone at the distal femur (pQCT) and in the tibia (CT) showed age-progressive decreases in bone volume fraction in PAPP-A KO compared with WT mice. Tibial CT indicated a 46% relative decrease in trabecular bone volume/total volume (BV/TV) and a 28% relative decrease in trabecular thickness in PAPP-A KO compared with WT mice at 6 mo. These trabecular deficiencies in PAPP-A KO mice corresponded to a weakening of the bone. Serum markers and bone histomorphometry indicated that the primary impact of PAPP-A is on skeletal remodeling resulting in a state of low-turnover osteopenia in adult PAPP-A KO mice. Circulating IGF-I levels were not altered in PAPP-A KO mice. Conclusions: PAPP-A is a bone growth regulatory factor in vivo and, in its absence, mice show skeletal insufficiency in mass, density, architecture, and strength. The data suggest a primary role for PAPP-A in modulating local IGF bioavailability for trabecular bone remodeling.
Loss of bone mass during periods of skeletal unloading remains an important clinical problem. To determine the extent to which resorption contributes to the relative loss of bone during skeletal unloading of the growing rat and to explore potential means of preventing such bone loss, 0.1 mg P/kg alendronate was administered to rats before unloading of the hindquarters. Skeletal unloading markedly reduced the normal increase in tibial mass and calcium content during the 9 day period of observation, primarily by decreasing bone formation, although bone resorption was also modestly stimulated. Alendronate not only prevented the relative loss of skeletal mass during unloading but led to a dramatic increase in calcified tissue in the proximal tibia compared with the vehicle-treated unloaded or normally loaded controls. Bone formation, however, assessed both by tetracycline labeling and by [3H]proline and 45Ca incorporation, was suppressed by alendronate treatment and further decreased by skeletal unloading. Total osteoclast number increased in alendronate-treated animals, but values were similar to those in controls when corrected for the increased bone area. However, the osteoclasts had poorly developed brush borders and appeared not to engage the bone surface when examined at the ultrastructural level. We conclude that alendronate prevents the relative loss of mineralized tissue in growing rats subjected to skeletal unloading, but it does so primarily by inhibiting the resorption of the primary and secondary spongiosa, leading to altered bone modeling in the metaphysis.
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