Karen E. Callon

In Vitro and in Vivo Effects of Adiponectin on Bone

Fat mass impacts on both bone turnover and bone density and is a critical risk factor for osteoporotic fractures. Adipocyte-derived hormones may contribute to this relationship, and adiponectin is a principal circulating adipokine. However, its effects on bone remain unclear. We have, therefore, investigated the direct effects of adiponectin on primary cultures of osteoblastic and osteoclastic cells in vitro and determined its integrated effects in vivo by characterizing the bone phenotype of adiponectin-deficient mice. Adiponectin was dose-dependently mitogenic to primary rat and human osteoblasts ( approximately 50% increase at 10 microg/ml) and markedly inhibited osteoclastogenesis at concentrations of 1 microg/ml or greater. It had no effect on osteoclastogenesis in RAW-264.7 cells or on bone resorption in isolated mature osteoclasts. In adiponectin knockout (AdKO) male C57BL/6J mice, trabecular bone volume and trabecular number (assessed by microcomputed tomography) were increased at 14 wk of age by 30% (P = 0.02) and 38% (P = 0.0009), respectively. Similar, nonsignificant trends were observed at 8 and 22 wk of age. Biomechanical testing showed lower bone fragility and reduced cortical hardness at 14 wk. We conclude that adiponectin stimulates osteoblast growth but inhibits osteoclastogenesis, probably via an effect on stromal cells. However, the AdKO mouse has increased bone mass, suggesting that adiponectin also has indirect effects on bone, possibly through modulating growth factor action or insulin sensitivity. Because adiponectin does influence bone mass in vivo, it is likely to be a contributor to the fat-bone relationship.

Effects of calcitonin, amylin, and calcitonin gene-related peptide on osteoclast development

Amylin and calcitonin gene-related peptide (CGRP) are homologous 37 amino acid peptides that are found in the circulation. Both peptides belong to the calcitonin family. Similar to calcitonin, amylin and CGRP inhibit osteoclast activity, although they are much less potent than calcitonin. Calcitonin is known to act on the latter stages of osteoclast development, inhibiting the fusion of committed preosteoclasts to form mature multinucleated cells; however, whether or not calcitonin acts earlier in the formation of the precursor osteoclasts is controversial. The question of osteoclast development has never been examined with respect to amylin and CGRP. These issues are addressed in the present study. We studied the effects of calcitonin (salmon and rat), amylin (human and rat), and CGRP (human and rat) in mouse bone marrow cultures stimulated to generate osteoclasts using 1alpha,25-dihydroxyvitamin D3. Calcitonin dose-dependently decreased the numbers of tartrate-resistant acid phosphatase (TRAP)-positive multinucleated cells as well as TRAP-positive mono-/binucleated cells at concentrations >10(-13) mol/L. Amylin and CGRP showed similar effects at concentrations >10(-9) mol/L. In addition, calcitonin substantially reduced the ratio of TRAP-positive multinucleated to mono-binucleated cells, indicating an effect on fusion of osteoclast precursors. The present data establish that this family of peptides not only acts on mature osteoclasts but also inhibits their development in bone marrow cultures. This activity is shared by amylin and CGRP. The much greater potency of calcitonin than amylin and CGRP is consistent with the action of these peptides being mediated by calcitonin receptors.

Cellular characterization of the gouty tophus: A quantitative analysis

OBJECTIVE To characterize the cellular architecture of the tophus and to determine the presence of cytokines implicated in the initiation and resolution of gouty inflammation. METHODS Sixteen fixed, paraffin-embedded, uninfected tophus samples were surgically obtained from 12 patients with microscopically proven gout and were analyzed by quantitative immunohistochemistry. The number of cells present in the corona and fibrovascular zones of the tophus was analyzed by Genmod mixed models analysis. RESULTS Numerous CD68+ mononucleated and multinucleated cells were present within the corona zone. Mast cells were identified in all tophus samples and at similar densities throughout the corona and fibrovascular zones. In contrast, neutrophils were rarely observed. Plasma cells were present in very high numbers within the corona zone. The overall number of CD20+ B cells was much lower. However, in 6 of 12 patients (50%), at least 1 B cell aggregate was present in the fibrovascular zone. Large numbers of cells expressing interleukin-1beta (IL-1beta) were observed in the corona zone. Transforming growth factor beta1 (TGFbeta1)-expressing mononucleated cells were also identified. The number of CD68+ cells correlated with the number of cells expressing IL-1beta (r = 0.691, P = 0.009) and the number expressing TGFbeta1 (r = 0.518, P = 0.04). CONCLUSION The tophus represents a complex and organized chronic inflammatory tissue response to monosodium urate monohydrate crystals involving both innate and adaptive immune cells. The coexpression of IL-1beta and TGFbeta1 suggests that both proinflammatory and antiinflammatory factors present within the tophus contribute to a cycle of chronic inflammation, attempted resolution, and tissue remodeling.

INSULIN INCREASES HISTOMORPHOMETRIC INDICES OF BONE FORMATION IN VIVO

Recent clinical studies have established that bone density is related to both fat mass and circulating insulin levels. A direct action of insulin on the osteoblast may contribute to these relationships. Osteoblast-like cells have insulin receptors, and insulin has been shown to stimulate proliferation of these cells in vitro. However, it has not been possible to study the effects of insulin administration on bone in vivo because of the metabolic effects of insulin, particularly hypoglycemia. A model involving the local injection of insulin over one hemicalvaria of an adult mouse overcomes these difficulties and permits the histomorphometric study of insulins action on bone. Insulin or vehicle was injected daily for 5 days over the right hemicalvariae of adult mice, and the animals were sacrificed 1 week later. All indices of bone formation were significantly increased in imsulin-treated hemicalvariae compared with the noninjected hemicalvariae. There was a 2.73±0.50-fold increase in osteoid area (P=0.0005), a 2.20±0.37-fold increase in osteoblast surface (P=0.021) and a 2.04±0.29-fold increase in osteoblast number (P=0.021). Indices of bone resorption tended to decline and mineralized bone area tended to increase in insulin-treated animals. The direct action of insulin on bone may contribute to the increased bone density seen in obesity and to the osteopenia of type I diabets, conditions associated with insulin excess and deficiency, respectively.

Imatinib promotes osteoblast differentiation by inhibiting PDGFR signaling and inhibits osteoclastogenesis by both direct and stromal cell-dependent mechanisms.

Several lines of evidence suggest that imatinib may affect skeletal tissue. We show that inhibition by imatinib of PDGFR signaling in osteoblasts activates osteoblast differentiation and inhibits osteoblast proliferation and that imatinib inhibits osteoclastogenesis by both stromal cell‐dependent and direct effects on osteoclast precursors.

Comparison of the Effects of Calcitonin Gene‐Related Peptide and Amylin on Osteoblasts

Calcitonin gene‐related peptide (CGRP) and amylin are homologous 37‐amino‐acid peptides which have been demonstrated to have anabolic effects on bone. It is not clear whether these effects are mediated by a common receptor, nor is it known which ligand is the more potent. These questions are addressed in the present study using cultures of fetal rat osteoblasts. CGRP increased cell number when present in a concentration ≥10−9 M, but 10−8 M CGRP was required to stimulate thymidine and phenylalanine incorporation. Amylin was effective on these indices at 100‐fold lower concentrations, and its maximal effects were about twice as great as those of CGRP. ED50s for the effects of amylin and CGRP on cell number were 10−12 M and 10−10 M, respectively. There was no additivity between maximal doses of the peptides on these indices. The effects of specific receptor blockers on the maximal stimulation of cell number by these peptides were also studied. The CGRP receptor‐blocker, CGRP‐(8–37), completely blocked the effect of CGRP at blocker concentrations ≥10−9 M. In contrast, the amylin receptor blocker, amylin‐(8–37), completely blocked the effects of CGRP when the blocker was present in concentrations as low as 10−11 M. The KI of CGRP‐(8–37) was 2 × 10−10 M and that of amylin‐(8–37) was 7 × 10−12 M. In converse experiments studying the blockade of maximal doses of amylin, amylin‐(8–37) 10−10 M was effective (KI 1 × 10−10 M), whereas a 100‐fold greater concentration of CGRP‐(8–37) was necessary to achieve the same effect (KI 6 × 10−9 M). It is concluded that amylin and CGRP probably act through a common receptor to stimulate osteoblast growth, and that this receptor has a higher affinity for amylin than for CGRP.

Systemic administration of amylin increases bone mass, linear growth, and adiposity in adult male mice

Amylin is a peptide hormone cosecreted with insulin from the pancreatic β-cells that can act as an osteoblast mitogen and as an inhibitor of bone resorption. The effects on bone of its systemic administration are uncertain. The present study addresses this question in adult male mice that were given daily subcutaneous injections of amylin (10.5 μg) or vehicle ( n = 20 in each group) for 4 wk. Histomorphometric indices of bone formation increased 30-100% in the amylin-treated group, whereas resorption indices were reduced by ∼70% ( P < 0.005 for all indices). Total bone volume in the proximal tibia was 13.5 ± 1.4% in control animals and 23.0 ± 2.0% in those receiving amylin ( P = 0.0005). Cortical width, tibial growth plate width, tibial length, body weight, and fat mass were all increased in the amylin-treated group. It is concluded that systemic administration of amylin increases skeletal mass and linear bone growth. This peptide has potential as a therapy for osteoporosis if its bone effects can be dissociated from those on soft tissue mass.

Modulation of Osteoclastogenesis by Fatty Acids

Clinical studies have shown that total body fat mass is related to both bone density and fracture risk and that fat ingestion reduces bone turnover. These effects are at least partially mediated by endocrine mechanisms, but it is possible that lipids might act directly on bone. We assessed the effects of broad fractions of milk lipids in osteoblasts, bone marrow, and neonatal mouse calvariae. Several milk fractions and their hydrolysates inhibited osteoclastogenesis in bone marrow cultures, so we assessed the effects of free fatty acids in this model. Saturated fatty acids (0.1-10 microg/ml) inhibited osteoclastogenesis in bone marrow cultures and RAW264.7 cells. This effect was maximal for C14:0 to C18:0 fatty acids. The introduction of greater than 1 double bond abrogated this effect; omega3 and omega6 fatty acids had comparable low activity. Osteoblast proliferation was modestly increased by the antiosteoclastogenic compounds, ruling out a nonspecific toxic effect. Active fatty acids did not consistently change expression of receptor activator of nuclear factor-kappaB ligand or osteoprotegerin in osteoblastic cells nor did they affect the activity of key enzymes in the mevalonate pathway. However, receptors known to bind fatty acids were found to be expressed in osteoblastic (GPR120) and osteoclastic (GPR40, 41, 43, 120) cells. A synthetic GPR 40/120 agonist mimicked the inhibitory effects of fatty acids on osteoclastogenesis. These findings provide a novel link between lipid and bone metabolism, which might contribute to the positive relationship between adiposity and bone density as well as provide novel targets for pharmaceutical and nutriceutical development.

Enhanced osteoclastogenesis in patients with tophaceous gout: Urate crystals promote osteoclast development through interactions with stromal cells

OBJECTIVE To analyze cellular mechanisms of bone erosion in gout. METHODS Peripheral blood mononuclear cells (PBMCs) and synovial fluid mononuclear cells (SFMCs) from patients with gout were analyzed for the presence of osteoclast precursors. Fixed tophus and bone samples were analyzed by immunohistochemistry. Mechanisms of osteoclastogenesis were studied by culturing murine preosteoclast RAW 264.7 cells, bone marrow stromal ST2 cells, and human synovial fibroblasts with monosodium urate monohydrate (MSU) crystals. RESULTS PBMCs from patients with severe erosive gout had the preferential ability to form osteoclast-like cells in culture with RANKL and monocyte colony-stimulating factor (M-CSF). The number of PBMC-derived tartrate-resistant acid phosphatase (TRAP)-positive multinucleated cells strongly correlated with the number of tophi (r = 0.6296, P = 0.630). Patients with severe erosive and tophaceous gout also had higher circulating concentrations of RANKL and M-CSF. Furthermore, greater numbers of TRAP-positive multinucleated cells were cultured from SFMCs derived from gouty knee effusions than from paired PBMCs (P = 0.004). Immunohistochemical analysis demonstrated numerous multinucleated cells expressing osteoclast markers within tophi and at the interface between soft tissue and bone. MSU crystals did not directly promote osteoclast formation from RAW 264.7 cells in vitro. However, MSU crystals inhibited osteoprotegerin gene and protein expression in ST2 cells and human synovial fibroblasts, without significantly altering RANKL gene expression. Conditioned medium from ST2 cells cultured with MSU crystals promoted osteoclast formation from RAW 264.7 cells in the presence of RANKL. CONCLUSION Chronic tophaceous and erosive gout is characterized by enhanced osteoclast development. These data provide a rationale for the study of osteoclast-targeted therapies for the prevention of bone damage in chronic gout.

Adrenomedullin is a potent stimulator of osteoblastic activity in vitro and in vivo

Adrenomedullin is a 52-amino acid vasodilator peptide produced in many tissues, including bone. It has 20% sequence identity with amylin, a regulator of osteoblast growth, and circulates in picomolar concentrations. The present study assesses whether adrenomedullin also acts on osteoblasts. At concentrations of 10-12 M and greater, adrenomedullin produced a dose-dependent increase in cell number and [3H]thymidine incorporation in cultures of fetal rat osteoblasts. This effect was also seen with adrenomedullin-(15-52), -(22-52), and -(27-52), but adrenomedullin-(40-52) was inactive. These effects were lost in the presence of amylin blockers, suggesting they were mediated by the amylin receptor. Adrenomedullin also increased [3H]thymidine incorporation into cultured neonatal mouse calvaria but, unlike amylin, did not reduce bone resorption in this model. Adrenomedullin stimulated phenylalanine incorporation into both isolated osteoblasts and calvaria. When injected daily for 5 days over the calvariae of adult mice, it increased indexes of bone formation two- to threefold ( P < 0.0001) and increased mineralized bone area by 14% ( P = 0.004). It is concluded that adrenomedullin regulates osteoblast function and that it increases bone mass in vivo. The potential of this family of peptides in the therapy of osteoporosis should be further evaluated.