Central (hypothalamic) control of bone mass is proposed to be mediated through beta2-adrenergic receptors (beta2-ARs). While investigations in mouse bone cells suggest that epinephrine enhances both RANKL and OPG mRNA via both beta-ARs and alpha-ARs, whether alpha-ARs are expressed in human bone cells is controversial. The current study investigated the expression of alpha1-AR and beta2-AR mRNA and protein and the functional role of adrenergic stimulation in human osteoblasts (HOBs). Expression of alpha1B- and beta2-ARs was examined by RT-PCR, immunofluorescence microscopy and Western blot (for alpha1B-ARs). Proliferation in HOBs was assessed by (3)H-thymidine incorporation and expression of RANKL and OPG was determined by quantitative RT-PCR. RNA message for alpha1B- and beta2-ARs was expressed in HOBs and MG63 human osteosarcoma cells. alpha1B- and beta2-AR immunofluorescent localization in HOBs was shown for the first time by deconvolution microscopy. alpha1B-AR protein was identified in HOBs by Western blot. Both alpha1-agonists and propranolol (beta-blocker) increased HOB replication but fenoterol, a beta2-agonist, inhibited it. Fenoterol nearly doubled RANKL mRNA and this was inhibited by propranolol. The alpha1-agonist cirazoline increased OPG mRNA and this increase was abolished by siRNA knockdown of alpha1B-ARs in HOBs. These data indicate that both alpha1-ARs and beta2-ARs are present and functional in HOBs. In addition to beta2-ARs, alpha1-ARs in human bone cells may play a role in modulation of bone turnover by the sympathetic nervous system.
Using human peripheral blood mononuclear cells as osteoclast precursors, we showed that dexamethasone stimulated osteoclast generation at a pharmacological concentration but did not affect the life span of human osteoclasts. Dexamethasone also dose-dependently increased signals for osteoclastogenesis.Introduction: Glucocorticoid-induced osteoporosis is a common and serious disease. Glucocorticoids predominantly affect osteoblast proliferation and life span. Much of the bone loss is caused by reduced bone formation, but there is also an element of increased bone resorption. Materials and Methods: Human peripheral blood mononuclear cells were cultured on whale dentine and induced to differentiate to osteoclasts by RANKL and human macrophage-colony stimulating factor (M-CSF). Osteoclast activity was quantified by pit area. RANKL and osteoprotegerin (OPG) expression in osteoblasts were measured by real-time RT-PCR. Results: In the early phase of osteoclast generation (0-16 days), cultures from two different donors showed that dexamethasone at 10 −8 M increased pit area by 2.5-fold, whereas lower concentrations had no effect. At the highest dexamethasone concentration (10 −7 M), pit area was reduced. In 21-day cultures from three other donors, a similar increase was seen with dexamethasone at 10 −8 M. There was, however, no evidence of increased life span of osteoclasts with dexamethasone. In human primary osteoblasts, dexamethasone dosedependently reduced OPG and increased RANKL expression as measured by quantitative real time RT-PCR. Conclusion: These data provide some explanation at a cellular and molecular level for the observed increase in bone resorption seen in patients treated with glucocorticoids and indicate that there are clear direct effects of glucocorticoids on bone resorption in human cell systems that may differ from other species.
Bone strength, a determinant of resistance to fracture, depends on BMD, geometry, microarchitecture, bone turnover rates, and properties of the bone at the material level. Despite comparable antifracture efficacy, anti-catabolics and bone anabolic agents are likely to modify the various determinants of bone strength in very different ways. Eight weeks after ovariectomy (OVX), 8-mo-old osteoporotic rats received pamidronate (APD; 0.6 mg/kg, 5 days/mo, SC), raloxifene (3 mg/kg, 5/7 days, tube feeding), PTH(1-34) (10 mg/kg, 5/7 days, SC), or vehicle for 16 wk, and we measured vertebral BMD, maximal load, stiffness and energy, microarchitecture, and material properties by nanoindentation, which allows the calculation of the elastic modulus, tissue hardness, and working energy. Markers of bone turnover, plasma osteocalcin, and urinary deoxypyridinoline (Dpd) were also determined. PTH induced greater maximal load than APD or raloxifene, as well as greater absorbed energy, BMD, and increased bone turnover markers. PTH markedly increased trabecular bone volume and connectivity to values higher than sham. Animals treated with APD had BV/TV values significantly higher than OVX but lower than sham, whereas raloxifene had no effect. Tissue hardness was identical in PTH-treated and OVX untreated controls. In contrast, APD reversed the decline in strength to levels not significantly different to sham, reduced bone turnover, and increased hardness. Raloxifene markedly increased material level cortical hardness and elastic modulus. These results show the different mechanisms by which anti-catabolics and bone anabolics reduce fracture risk. PTH influences microarchitecture, whereas bisphosphonates alter material-level bone properties, with probable opposite effects on remodeling space. Raloxifene primarily improved the material stiffness at the cortical level.
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