SUMMARY The hypothalamus has been implicated in skeletal metabolism (Ducy et al., 2000; Sato et al., 2007; Yadav et al., 2009). Whether hunger-promoting neurons of the arcuate nucleus impact the bone is not known. We generated multiple lines of mice to affect AgRP neuronal circuit integrity. We found that mice with Ucp2 gene deletion, in which AgRP neuronal function was impaired, were osteopenic. This phenotype was rescued by cell-selective reactivation of Ucp2 in AgRP neurons. When the AgRP circuitry was impaired by early postnatal deletion of AgRP neurons or by cell autonomous deletion of Sirt1 (AgRP-Sirt1−/−), mice also developed reduced bone mass. No impact of leptin receptor deletion in AgRP neurons was found on bone homeostasis. Suppression of sympathetic tone in AgRP-Sirt1−/− mice reversed osteopenia in transgenic animals. Taken together, these observations establish a significant regulatory role for AgRP neurons in skeletal bone metabolism independent of leptin action.
Colony-stimulating factor-1 (CSF-1) is a hematopoietic growth factor that is released by osteoblasts and is recognized to play a critical role in bone remodeling in vivo and in vitro. CSF-1 is synthesized as a soluble or cellsurface protein. It is unclear, however, whether human osteoblasts express both molecular forms of CSF-1, and whether these isoforms can independently mediate osteoclastogenesis. In the present study, using a combination of quantitative reverse transcriptase polymerase chain reaction, flow cytometry, and Western immunoblot analysis, we have demonstrated that human osteoblast-like cells as well as primary human osteoblasts express the cell-surface form of CSF-1 both constitutively and in response to parathyroid hormone and tumor necrosis factor. Furthermore, using an in vitro coculture system, we have shown that cell-surface CSF-1 alone is sufficient to support osteoclast formation. These findings may be especially significant in view of evidence that direct cell-to-cell contact is critical for osteoclast formation, and suggest that differential regulation of expression of the CSF-1 isoforms may influence osteoclast function modulated by osteotropic hormones.The precise mechanism whereby osteoblasts mediate osteoclastic bone resorption is unclear. One widely held hypothesis is that activated osteoblasts secrete cytokines that directly or indirectly influence osteoclast formation or function (1). Although the exact nature of all of these cytokines is unknown, compelling in vivo and in vitro data have emerged to support a role for colony-stimulating factor-1 (CSF-1) 1 as an osteoblastderived factor involved in osteoclast formation. Thus, in vivo, deficiency of CSF-1 in the op/op osteopetrotic mouse causes a failure of osteoclast formation and bone resorption (2-4), while in vitro studies have demonstrated that CSF-1 is critical for the proliferation and differentiation of osteoclast progenitors (5, 6), that CSF-1 stimulates bone resorption in the fetal mouse metacarpal assay (7), and that CSF-1 receptors are present on osteoclasts (8, 9). Additionally, we have reported that CSF-1 is the principal colony-stimulating activity released from osteoblasts constitutively and in response to PTH and parathyroid hormone-related protein (8). In support of a role for CSF-1 in bone remodeling in humans, Sarma et al. (10) have recently reported that, consistent with studies in mice, recombinant human CSF-1 induces osteoclastogenesis and bone resorption in human marrow cultures.Multiple human CSF-1 mRNA species (4.0, 3.0, 2.3, 1.9, and 1.6 kb) are expressed by the CSF-1 gene (11-15), and molecular cloning of cDNAs derived from these transcripts has demonstrated that the size differences are due to alternative splicing in exon 6 and the alternative use of the 3Ј-end exons 9 or 10 (11-13). A combination of nucleotide sequence analysis and transfection studies indicates that two distinct CSF-1 protein products are encoded by these transcripts. Both primary translation products are membrane-bound glycoproteins t...
Little is known about the modifying effects of age on the skeletal response to intermittent treatment with PTH. We therefore compared the response of 63 aged (18 month old) and 61 young-adult (3 month old) C57BL/6 mice to 4 wk of daily sc injections of either vehicle or h(1-34)PTH at a dose of 95 ng/g body weight. The increase in total body bone mineral density (BMD), compared with vehicle-treated animals, was similar in aged and young-adult mice (+5.6 vs. +6.3%). Aged animals demonstrated a greater increase in spinal BMD than their younger counterparts (+12.0 vs. +5.1%, P = 0.01; absolute increment: 57 x 10(-4) vs. 28 x 10(-4) g/cm(2)). Microcomputed tomography analyses in a subset of the vertebrae showed a trend toward higher L5 trabecular bone volume fraction in the PTH-treated aged animals (+40.2 vs. +19.6%). Vertebral histomorphometry demonstrated a greater PTH-induced increase in osteoblast number in aged vs. young-adult animals (694 vs. 396 cells/mm(2)). In contrast, in the femur the PTH-induced increase in BMD tended to be greater in the young-adult than the aged animals, although this did not reach statistical significance (8.1 vs. 4.2%). The numbers of osteoblast progenitors and mineralizing colonies in cultured marrow were unaffected by PTH treatment in either group. We conclude that aging differentially impacts the regional skeletal response to PTH such that the increase in BMD in the spine is augmented, whereas that in the femur is unaffected. Effects on osteoblast progenitor recruitment do not seem to be the basis for these changes.
Rac1 and Rac2 are thought to have important roles in osteoclasts. Therefore, mice with deletion of both Rac1 and Rac2 in mature osteoclasts (DKO) were generated by crossing Rac1flox/flox mice with mice expressing Cre in the cathepsin K locus and then mating these animals with Rac2−/− mice. DKO mice had markedly impaired tooth eruption. Bone mineral density (BMD) was increased 21% to 33% in 4- to 6-week-old DKO mice at all sites when measured by dual-energy X-ray absorptiometry (DXA) and serum cross-linked C-telopeptide (CTx) was reduced by 52%. The amount of metaphyseal trabecular bone was markedly increased in DKO mice, but the cortices were very thin. Spinal trabecular bone mass was increased. Histomorphometry revealed significant reductions in both osteoclast and osteoblast number and function in 4- to 6-week-old DKO animals. In 14- to 16-week-old animals, osteoclast number was increased, although bone density was further increased. DKO osteoclasts had severely impaired actin ring formation, an impaired ability to generate acid, and reduced resorptive activity in vitro. In addition, their life span ex vivo was reduced. DKO osteoblasts expressed normal differentiation markers except for the expression of osterix, which was reduced. The DKO osteoblasts mineralized normally in vitro, indicating that the in vivo defect in osteoblast function was not cell autonomous. Confocal imaging demonstrated focal disruption of the osteocytic dendritic network in DKO cortical bone. Despite these changes, DKO animals had a normal response to treatment with once-daily parathyroid hormone (PTH). We conclude that Rac1 and Rac2 have critical roles in skeletal metabolism.
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