Skeletal parasympathetic innervation communicates central IL-1 signals regulating bone mass accrual

Bone mass accrual is a major determinant of skeletal mass, governed by bone remodeling, which consists of bone resorption by osteoclasts and bone formation by osteoblasts. Bone mass accrual is inhibited by sympathetic signaling centrally regulated through activation of receptors for serotonin, leptin, and ACh. However, skeletal activity of the parasympathetic nervous system (PSNS) has not been reported at the bone level. Here we report skeletal immune-positive fibers for the PSNS marker vesicular ACh transporter (VAChT). Pseudorabies virus inoculated into the distal femoral metaphysis is identifiable in the sacral intermediolateral cell column and central autonomic nucleus, demonstrating PSNS femoral innervation originating in the spinal cord. The PSNS neurotransmitter ACh targets nicotinic (nAChRs), but not muscarinic receptors in bone cells, affecting mainly osteoclasts. nAChR agonists up-regulate osteoclast apoptosis and restrain bone resorption. Mice deficient of the α₂nAChR subunit have increased bone resorption and low bone mass. Silencing of the IL-1 receptor signaling in the central nervous system by brain-specific overexpression of the human IL-1 receptor antagonist (hIL1ra_Ast^+/+ mice) leads to very low skeletal VAChT expression and ACh levels. These mice also exhibit increased bone resorption and low bone mass. In WT but not in hIL1ra_Ast^+/+ mice, the cholinergic ACh esterase inhibitor pyridostigmine increases ACh levels and bone mass apparently by inhibiting bone resorption. Taken together, these results identify a previously unexplored key central IL-1–parasympathetic–bone axis that antagonizes the skeletal sympathetic tone, thus potently favoring bone mass accrual.     

Oxytocin is an anabolic bone hormone

We report that oxytocin (OT), a primitive neurohypophyseal hormone, hitherto thought solely to modulate lactation and social bonding, is a direct regulator of bone mass. Deletion of OT or the OT receptor (Oxtr) in male or female mice causes osteoporosis resulting from reduced bone formation. Consistent with low bone formation, OT stimulates the differentiation of osteoblasts to a mineralizing phenotype by causing the up-regulation of BMP-2, which in turn controls Schnurri-2 and 3, Osterix, and ATF-4 expression. In contrast, OT has dual effects on the osteoclast. It stimulates osteoclast formation both directly, by activating NF-κB and MAP kinase signaling, and indirectly through the up-regulation of RANK-L. On the other hand, OT inhibits bone resorption by mature osteoclasts by triggering cytosolic Ca²⁺ release and NO synthesis. Together, the complementary genetic and pharmacologic approaches reveal OT as a novel anabolic regulator of bone mass, with potential implications for osteoporosis therapy.     

Bisphosphonates in bone cement inhibit PMMA particle induced bone resorption

OBJECTIVE—Wear particle induced bone resorption is thought to be one of the mechanisms that contribute to implant loosening. It has previously been shown that macrophages, in response to polymethylmethacrylate (PMMA) particles, differentiate into bone resorbing osteoclasts, and that this process is inhibited by a bisphosphonate, etidronate (EHDP). The aim of this study was to determine whether incorporating EHDP in bone cement could reduce PMMA associated bone resorption.
METHODS—Two concentrations of EHDP were mixed with PMMA monomer before polymerisation. Particles of PMMA (1-10 µm) were generated then added to mouse monocytes cocultured with UMR106 rat osteoblast-like cells and the extent of osteoclast differentiation was determined by assessing the extent of tartrate resistant acid phosphatase (TRAP) staining and measuring the amount of lacunar bone resorption.
RESULTS—The addition of PMMA to monocyte-UMR106 cocultures resulted in a marked increase in the number of TRAP positive osteoclast-like cells and a significant increase in the number of lacunar resorption pits compared with control cultures to which no particles had been added. After the addition of particles of PMMA + 20 mg EHDP, significantly fewer lacunar pits (p=0.00006) and fewer TRAP positive cells were noted compared with cocultures containing PMMA particles alone.
CONCLUSIONS—These results indicate that by mixing a bisphosphonate with bone cement, it is possible to inhibit PMMA particle induced bone resorption. This bisphosphonate inhibition of PMMA biomaterial wear particle containing macrophage-osteoclast differentiation and bone resorption may provide a possible therapeutic strategy to prevent or to control the osteolysis of aseptic loosening.

Keywords: bisphosphonate; bone resorption; aseptic loosening; macrophages     

Direct measurement of bone resorption and calcium conservation during vitamin D deficiency or hypervitaminosis D

When bone is remodeled during the growth of a given size bone to a larger size, some bone is resorbed and some is deposited. Much of the resorbed bone mineral, calcium, can be reutilized during bone formation. The net and absolute effects of normal growth, vitamin D deficiency, or vitamin D excess were compared on bone resorption, bone formation, and calcium reutilization. Growing chicks were prelabeled extensively with three isotopes: ⁴⁵Ca, [³H]tetracycline, and [³H]proline. Data were obtained weekly during 3 weeks of control growth, vitamin D deficiency, or vitamin D overdosage while on a nonradioactive diet. Bone resorption as measured by increases in the marrow (inner) diameter of the midshaft of the femur and humerus and by the weekly losses of total [³H]tetracycline and [³H]collagen per whole bone was not significantly different among any of the groups studied. The data indicated that the high rate of cortical bone resorption in experimental chicks was not increased above that observed in experimental chicks was not increased above that observed in control chicks. Vitamin D deficiency had little effect on the total ⁴⁵Ca in whole bones, whereas vitamin D-treated chicks lost 40% of their ⁴⁵Ca. Thus, vitamin D overdosage resulted in a decrease of ⁴⁵Ca reutilization, whereas vitamin D deficiency resulted in an apparent increase of ⁴⁵Ca reutilization. Both vitamin D-deficient and vitamin D-treated chicks had a decreased accumulation of dietary calcium per whole bone. The insufficient mineral mass in vitamin D-deficient chicks resulted from the indirect inhibition of bone mineralization due to the low intestinal absorption of calcium rather than from a change in bone resorption. In vitamin D-treated chicks the apparent bone atrophy and net loss of ⁴⁵Ca from bone resulted from inhibiting bone matrix formation and mineralization instead of increasing bone resorption. The constancy of bone resorption under these experimental conditions suggests that bone mineralization is the major regulator of bone mass.     

Monosodium glutamate-sensitive hypothalamic neurons contribute to the control of bone mass

Using chemical lesioning we previously identified hypothalamic neurons that are required for leptin antiosteogenic function. In the course of these studies we observed that destruction of neurons sensitive to monosodium glutamate (MSG) in arcuate nuclei did not affect bone mass. However MSG treatment leads to hypogonadism, a condition inducing bone loss. Therefore the normal bone mass of MSG-treated mice suggested that MSG-sensitive neurons may be implicated in the control of bone mass. To test this hypothesis we assessed bone resorption and bone formation parameters in MSG-treated mice. We show here that MSG-treated mice display the expected increase in bone resorption and that their normal bone mass is due to a concomitant increase in bone formation. Correction of MSG-induced hypogonadism by physiological doses of estradiol corrected the abnormal bone resorptive activity in MSG-treated mice and uncovered their high bone mass phenotype. Because neuropeptide Y (NPY) is highly expressed in MSG-sensitive neurons we tested whether NPY regulates bone formation. Surprisingly, NPY-deficient mice had a normal bone mass. This study reveals that distinct populations of hypothalamic neurons are involved in the control of bone mass and demonstrates that MSG-sensitive neurons control bone formation in a leptin-independent manner. It also indicates that NPY deficiency does not affect bone mass.     

Skeletal remodelling and bone related hormones in two adults with increased bone mass

This study of two cases documents increased bone mass in a 30-yr-old man and osteopetrosis in a 38-yr-old woman and examines the patients in terms of radiologic features, bone photon absorptiometry and bone biopsy analyses which include tetracycline kinetics. Both patients had elevated bone mass based on quantitative bone histology of iliac crest biopsies normal, or low PTH, and normal calcitonin values. However, they differed markedly from each other in other respects: One patient possessed significantly increased rates of bone formation and mineralization, had elevated serum alkaline phosphatase, increased total hydroxyproline over a 24 hour urine collection but displayed a normal amount of bone surface involved in resorption. The other subject had normal bone formation parameters, but had elevated serum acid phosphatase and a significantly elevated resorbing (crenated) surface. Although most theories ascribe the cause of osteopetrosis to decreased resorption, our study shows that increased bone formation, even when accompanied by normal resorption, can lead to the abnormal accumulation of bone mass. In this respect, the resorptive response of this patient was abnormal; the normal coupled relationship between bone formation and bone resorption, which ensures proper control of endosteal bone volume, had been lost.     

Oleoyl serine,an endogenous N-acyl amide,modulates bone remodeling and mass

Bone mass is determined by a continuous remodeling process, whereby the mineralized matrix is being removed by osteoclasts and subsequently replaced with newly formed bone tissue produced by osteoblasts. Here we report the presence of endogenous amides of long-chain fatty acids with amino acids or with ethanolamine (N-acyl amides) in mouse bone. Of these compounds, N-oleoyl-l-serine (OS) had the highest activity in an osteoblast proliferation assay. In these cells, OS triggers a Gi-protein-coupled receptor and Erk1/2. It also mitigates osteoclast number by promoting osteoclast apoptosis through the inhibition of Erk1/2 phosphorylation and receptor activator of nuclear-κB ligand (RANKL) expression in bone marrow stromal cells and osteoblasts. In intact mice, OS moderately increases bone volume density mainly by inhibiting bone resorption. However, in a mouse ovariectomy (OVX) model for osteoporosis, OS effectively rescues bone loss by increasing bone formation and markedly restraining bone resorption. The differential effect of exogenous OS in the OVX vs. intact animals is apparently a result of an OVX-induced decrease in skeletal OS levels. These data show that OS is a previously unexplored lipid regulator of bone remodeling. It represents a lead to antiosteoporotic drug discovery, advantageous to currently available therapies, which are essentially either proformative or antiresorptive.     

Regulation of bone remodeling by vasopressin explains the bone loss in hyponatremia

Although hyponatremia is known to be associated with osteoporosis and a high fracture risk, the mechanism through which bone loss ensues has remained unclear. As hyponatremic patients have elevated circulating arginine-vasopressin (AVP) levels, we examined whether AVP can affect the skeleton directly as yet another component of the pituitary-bone axis. Here, we report that the two Avp receptors, Avpr1α and Avpr2, coupled to Erk activation, are expressed in osteoblasts and osteoclasts. AVP injected into wild-type mice enhanced and reduced, respectively, the formation of bone-resorbing osteoclasts and bone-forming osteoblasts. Conversely, the exposure of osteoblast precursors to Avpr1α or Avpr2 antagonists, namely SR49059 or ADAM, increased osteoblastogenesis, as did the genetic deletion of Avpr1α. In contrast, osteoclast formation and bone resorption were both reduced in Avpr1α^−/− cultures. This process increased bone formation and reduced resorption resulted in a profound enhancement of bone mass in Avpr1α^−/− mice and in wild-type mice injected with SR49059. Collectively, the data not only establish a primary role for Avp signaling in bone mass regulation, but also call for further studies on the skeletal actions of Avpr inhibitors used commonly in hyponatremic patients.Over the past decade, studies by others and us have documented direct effects of pituitary hormones on the skeleton. We have identified functional receptors for thyroid stimulating hormone (TSH), follicle stimulating hormone (FSH), adrenocorticotropic hormone (ACTH), and oxytocin (OT) on murine and human bone cells, namely bone-forming osteoblasts and bone-resorbing osteoclasts (1–4). The genetic deletion of either the receptor or the ligand itself, as in the case of FSH and OT, results in overt skeletal abnormalities. Specifically, deleting OT or its receptor, the Oxtr, causes profound osteopenia, which primarily arises from a dramatic reduction in bone formation by the osteoblast (4). Such studies have helped establish a pituitary-bone axis, in which pituitary hormones bypass their known targets, such as the thyroid, ovaries, adrenal, and breast, to regulate bone directly (5).This growing body of data not only informs us of novel functions of pituitary hormones, but also explains the hitherto poorly understood mechanisms of certain forms of osteoporosis, which have traditionally been attributed solely to changes in distal hormones. For example, we find that low TSH signaling contributes to the bone loss in hyperthyroidism, which was thought solely to be a result of elevated thyroid hormones (6). We have also speculated that the rapid bone loss that occurs during late perimenopause, at a time when estradiol levels are relatively normal, could—at least in part—be caused by elevated serum FSH levels. Thus, an antibody to FSH reduces bone loss in ovariectomized mice by stimulating bone formation and inhibiting bone resorption (7). Similarly, through its skeletal anabolic actions, elevated OT levels during pregnancy and lactation could play a major role in enabling fetal skeletal mineralization and allowing the mother to recover from the osteoporosis caused by the intergenerational transfer of calcium (8).Here, we report studies on arginine-vasopressin (AVP), another posterior pituitary hormone, which differs from OT only by two amino acids (9). The direct skeletal actions of AVP have never been explored, despite multiple and recurring observations that hyponatremia, which is invariably accompanied by elevated plasma AVP levels, is associated with bone loss and a high fracture risk (10–16). It has been thought that, as bone is a large reservoir for sodium ions, hyponatremia will trigger sodium release from the skeleton by increasing bone resorption (17, 18). However, the molecular basis of any such effect remains unknown. Interestingly, a recent study has described a male patient with syndrome of inappropriate secretion of antidiuretic hormone- (SIADH) induced hyponatremia, who had severe osteoporosis, despite having no identifiable risk factors (19). Plasma AVP was elevated by ∼30-fold, raising the possibility that high circulating AVP levels may cause the profound bone loss.We show that AVP is a key regulator of bone resorption and formation, the two principal components of bone remodeling. Both Avp receptors, Avpr1α and Avpr2, are expressed on osteoclasts and osteoblasts, and their stimulation triggers extracellular signal regulated kinase (Erk) activation, which in turn suppresses bone formation and stimulates bone resorption. This decoupling would favor bone loss, as noted in hyponatremic states. However, we also find that the genetic deletion of Avpr1 or the pharmacologic inhibition of Avpr1 or Avpr2 increases bone mass not only by stimulating osteoblastogenesis and new bone synthesis, but also by simultaneously inhibiting osteoclast formation and bone resorption. We speculate, therefore, that the targeted therapy of hyponatremia with aquaretics (or AVPR inhibitors) could result in overall bone gain. Purposefully designed clinical studies in populations in whom hyponatremia is a significant clinical problem (20), and whom are otherwise also at a high risk for fracture (21), should shed further light on the proposed osteoprotective action of AVPR antagonists in people.     

Mechanisms of in Vivo Degradation and Resorption of Calcium Phosphate Based Biomaterials

Calcium phosphate ceramic materials are extensively used for bone replacement and regeneration in orthopedic, dental, and maxillofacial surgical applications. In order for these biomaterials to work effectively it is imperative that they undergo the process of degradation and resorption in vivo. This allows for the space to be created for the new bone tissue to form and infiltrate within the implanted graft material. Several factors affect the biodegradation and resorption of calcium phosphate materials after implantation. Various cell types are involved in the degradation process by phagocytic mechanisms (monocytes/macrophages, fibroblasts, osteoblasts) or via an acidic mechanism to reduce the micro-environmental pH which results in demineralization of the cement matrix and resorption via osteoclasts. These cells exert their degradation effects directly or indirectly through the cytokine growth factor secretion and their sensitivity and response to these biomolecules. This article discusses the mechanisms of calcium phosphate material degradation in vivo.     

Nck influences preosteoblastic/osteoblastic migration and bone mass

Migration of the cells in osteoblastic lineage, including preosteoblasts and osteoblasts, has been postulated to influence bone formation. However, the molecular bases that link preosteoblastic/osteoblastic cell migration and bone formation are incompletely understood. Nck (noncatalytic region of tyrosine kinase; collectively referred to Nck1 and Nck2) is a member of the signaling adaptors that regulate cell migration and cytoskeletal structures, but its function in cells in the osteoblastic lineage is not known. Therefore, we examined the role of Nck in migration of these cells. Nck is expressed in preosteoblasts/osteoblasts, and its knockdown suppresses migration as well as cell spreading and attachment to substrates. In contrast, Nck1 overexpression enhances spreading and increases migration and attachment. As for signaling, Nck double knockdown suppresses migration toward IGF1 (insulin-like growth factor 1). In these cells, Nck1 binds to IRS-1 (insulin receptor substrate 1) based on immunoprecipitation experiments using anti-Nck and anti–IRS-1 antibodies. In vivo, Nck knockdown suppresses enlargement of the pellet of DiI-labeled preosteoblasts/osteoblasts placed in the calvarial defects. Genetic experiments indicate that conditional double deletion of both Nck1 and Nck2 specifically in osteoblasts causes osteopenia. In these mice, Nck double deficiency suppresses the levels of bone-formation parameters such as bone formation rate in vivo. Interestingly, bone-resorption parameters are not affected. Finally, Nck deficiency suppresses repair of bone injury after bone marrow ablation. These results reveal that Nck regulates preosteoblastic/osteoblastic migration and bone mass.Bone is a metabolically dynamic tissue, as it is continuously remodeled based on repetition of bone resorption and bone formation (1). Under normal conditions, bone formation and bone resorption are coupled and balanced by the activities of osteoblasts and osteoclasts, respectively (2). Bone remodeling occurs first by osteoclastic bone resorption. Then, preosteoblasts or their precursors migrate into the resorption cavities and attach to the bottom of the cavities, followed by osteoblastic bone formation to start to fill the bone cavity through producing bone matrix (3). Therefore, preosteoblastic migration and attachment during bone remodeling are critical events to maintain bone mass (4–6). Regarding cell migration, most of the important motility and migration in remodeling is undergone by precursors of osteoblasts that are shown to be recruited by TGF-beta1, and these cells differentiate under the control of IGF1 (insulin-like growth factor 1) at the sites of remodeling (7, 8). Migration and attachment of the cells in the lineage of osteoblastic cells are also important in the case of repair after bone injury, as these cells migrate into the bone injury site and start to proliferate and to produce bone. These cellular events are considered to be critical in understanding the pathological state in bone, such as osteoporosis. However, the molecular bases of preosteoblastic/osteoblastic migration with respect to cytoskeletal regulation and its relevance to bone mass determination are still incompletely understood.The key steps in the migration and attachment of the cells include extension of the cell membrane, remodeling of actin cytoskeleton, formation of adhesion complex, and organization of stress fibers. Remodeling of actin cytoskeleton is a process of dynamic assembly and disassembly of filamentous actin. Such reorganization of actin cytoskeleton governs essential aspects of cell motility and attachment that are required for the formation of cellular structures such as lamellipodia, filopodia, stress fibers, and focal adhesions (9, 10). Preosteoblasts and osteoblasts are known to be capable of migrating toward chemo-attractants such as anabolic cytokines (7, 8). However, the key molecules involved in control of cytoskeleton that regulates osteoblastic cell migration and their relevance to bone mass regulation have yet to be elucidated.Nck (noncatalytic region of tyrosine kinase) adaptor proteins are cytosolic effectors that regulate remodeling of the actin cytoskeleton (11, 12). Mammals carry two closely related Nck genes, Nck1 and Nck2 (collectively termed Nck), that contain three N-terminal Src homology 3 (SH3) domains and a single C-terminal SH2 domain. Although actin cytoskeleton plays a critical role in cells and Nck is one of the possible factors affecting polymeric actin dynamics, the function of Nck in osteoblastic cells and in regulation of bone mass is incompletely understood. Therefore, we examined the role of Nck in the migration of bone cells and its relevance to the regulation of bone mass.     

Stimulation of bone formation and prevention of bone loss by prostaglandin E EP4 receptor activation

Bone remodeling, comprising resorption of existing bone and de novo bone formation, is required for the maintenance of a constant bone mass. Prostaglandin (PG)E2 promotes both bone resorption and bone formation. By infusing PGE2 to mice lacking each of four PGE receptor (EP) subtypes, we have identified EP4 as the receptor that mediates bone formation in response to this agent. Consistently, bone formation was induced in wild-type mice by infusion of an EP4-selective agonist and not agonists specific for other EP subtypes. In culture of bone marrow cells from wild-type mice, PGE2 induced expression of core-binding factor alpha1 (Runx2/Cbfa1) and enhanced formation of mineralized nodules, both of which were absent in the culture of cells from EP4-deficient mice. Furthermore, administration of the EP4 agonist restored bone mass and strength normally lost in rats subjected to ovariectomy or immobilization. Histomorphometric analysis revealed that the EP4 agonist induced significant increases in the volume of cancellous bone, osteoid formation, and the number of osteoblasts in the affected bone of immobilized rats, indicating that activation of EP4 induces de novo bone formation. In addition, osteoclasts were found on the increased bone surface at a density comparable to that found in the bone of control animals. These results suggest that activation of EP4 induces bone remodeling in vivo and that EP4-selective drugs may be beneficial in humans with osteoporosis.     

Strontium ranelate: a dual mode of action rebalancing bone turnover in favour of bone formation

The increased bone remodeling in women after menopause induces an imbalance between bone resorption and formation, leading to decreased bone mass, altered bone microarchitecture, and increased fracture risk. Current antiosteoporotic drugs decrease bone remodeling or increase bone formation. Strontium ranelate (Protelos) is a newly developed antiosteoporotic drug that acts by reducing bone resorption and promoting bone formation, thereby inducing a positive bone balance. In rat and mouse culture models, strontium ranelate enhances preosteoblastic cell replication and bone formation markers. In contrast, it decreases rodent osteoclastic cell resorbing activity and human osteoclast differentiation, and increases rabbit osteoclast apoptosis. In vivo, strontium ranelate increases bone formation and reduces bone resorption in mice, resulting in increased vertebral bone mass. In rats, strontium ranelate increases bone mass and improves microarchitecture and bone geometry, resulting in increased bone resistance. In ovariectomized rats, strontium ranelate decreases bone resorption but maintains high bone formation, resulting in improved bone microarchitecture and increased bone mass and strength. In clinical trials, serum alkaline phosphatase levels increased whereas serum CTX levels simultaneously decreased in patients treated with Protelos versus placebo at all time-points. In these trials, histomorphometric analysis of bone biopsies showed that the osteoblast surface and mineral apposition rate increased whereas bone resorption parameters tended to decrease in treated patients compared to the placebo group. These preclinical and clinical data indicate that strontium ranelate acts by increasing bone formation and decreasing bone resorption, thus rebalancing bone turnover in favour of bone formation, an effect that results in increased bone mass and strength.     

Dissociation of the neuronal regulation of bone mass and energy metabolism by leptin in vivo

The leptin regulation of bone remodeling, which has been documented through studies of loss-of-function mutations of this hormone or of its receptor in mice and humans, still raised several unanswered questions. For instance, it has been assumed but not formally demonstrated that this regulation occurs through neuronal means. Likewise, it has not been possible until now to dissociate the influence leptin exerts on appetite and energy expenditure from this function. We show here through mouse genetic studies that a deletion of the leptin receptor in neurons results in an increase in bone formation and bone resorption, resulting in a high bone mass as seen in leptin-deficient mice. In contrast, the same deletion in osteoblasts only does not influence bone remodeling. Furthermore, through the use of l/l mice, a model of gain of function in leptin signaling harboring a Y985L substitution in the leptin receptor, we show that leptin signaling inhibits bone mass accrual by up-regulating sympathetic activity independently of any change in appetite or energy expenditure. This work establishes that in vivo leptin regulates bone mass accrual by acting through neuronal means and provides a direct demonstration that this function of leptin can occur independently of its regulation of energy metabolism.     

Androgens regulate bone resorption activity of isolated osteoclasts in vitro

For many years it has been recognized that sex steroids have profound effects on bone metabolism. The current perception is that estrogen decreases bone resorption and androgen increases bone deposition. To investigate the potential for androgens to directly modulate bone resorption, we have examined avian osteoclast and human and mouse osteoclast-like cells for androgen responsiveness. There was a dose-dependent decrease in resorption activity in response to α-dihydrotestosterone (α-DHT), β-DHT, testosterone, or the synthetic androgen RU1881. This decrease was blocked by cotreatment with the specific androgen antagonist hydroxyflutamide. Further examination of avian osteoclasts revealed that the cells exhibited specific and saturable nuclear binding of tritiated RU1881 and that α-DHT stimulated the activity of the androgen response element as measured by using a chloramphenicol acetyltransferase reporter plasmid. In addition, avian osteoclasts responded to androgen treatment with elevated production and secretion of transforming growth factor β, a well documented response to androgen exposure in other cell systems. Treatment with either α-DHT or β-DHT for 24 hours resulted in a significant dose-dependent decrease in secretion of cathepsin B and tartrate-resistant acid phosphatase. This response to β-DHT, a stereoisomer of α-DHT that is inactive in other androgen receptor-dependent systems, supports the hypothesis that the osteoclast androgen receptor has unusual ligand-binding properties. Taken together, these results confirm the presence of functional androgen receptors in these cells and support the conclusion that osteoclasts are able to respond directly to androgens in vitro and thus are potential androgen target cells in vivo.     

Galectin-3 is essential for proper bone cell differentiation and activity,bone remodeling and biomechanical competence in mice

ObjectiveGalectin-3 is constitutively expressed in bone cells and was recently shown to modulate osteogenic transdifferentiation of vascular smooth muscle cells and atherosclerotic calcification. However, the role of galectin-3 in bone physiology is largely undefined. To address this issue, we analyzed (1) the skeletal features of 1-, 3- and 6-month-old galectin-3 null (Lgals3^−/−) and wild type (WT) mice and (2) the differentiation and function of osteoblasts and osteoclasts derived from these animals.MethodsLong bone phenotype, gene expression profile, and remodeling were investigated by micro-computed tomography, real time-PCR, static and dynamic histomorphometry, and assessment of biochemical markers of bone resorption and formation. Bone competence was also evaluated by biomechanical testing at 3 months. In vitro, the effects of galectin-3 deficiency on bone cell differentiation and function were investigated by assessing (a) gene expression of osteoblast markers, alkaline phosphatase activity, mineralization assay, and WNT/β-catenin signaling (of which galectin-3 is a known regulator) in osteoblasts; and (b) tartrate-resistant acid phosphatase activity and bone resorption activity in osteoclasts.ResultsLgals3^−/− mice revealed a wide range of age-dependent alterations including lower bone formation and higher bone resorption, accelerated age-dependent trabecular bone loss (p < 0.01 vs. WT at 3 months) and reduced bone strength (p < 0.01 vs. WT at 3 months). These abnormalities were accompanied by a steady inflammatory state, as revealed by higher bone expression of the pro-inflammatory cytokines interleukin (IL)-1β and IL-6 (p < 0.001 vs. WT at 3 months), increased content of osteal macrophages (p < 0.01 vs. WT at 3 months), and reduced expression of markers of alternative (M2) macrophage activation. Lgals3^−/− osteoblasts and osteoclasts showed impaired terminal differentiation, reduced mineralization capacity (p < 0.01 vs. WT cells) and resorption activity (p < 0.01 vs. WT cells). Mechanistically, impaired differentiation and function of Lgals3^−/− osteoblasts was associated with altered WNT/β-catenin signaling (p < 0.01 vs. WT cells).ConclusionsThese data provide evidence for a contribution of galectin-3 to bone cell maturation and function, bone remodeling, and biomechanical competence, thus identifying galectin-3 as a promising therapeutic target for age-related disorders of bone remodeling.     

Bone mineralization and bone mineral metabolism in children with juvenile rheumatoid arthritis

Objective. To identify mechanisms of the osteopenia associated with juvenile rheumatoid arthritis (JRA) by determining parameters of bone mineralization, and bone mineral content and density (BMC and BMD), in children with JRA. Methods. BMC and BMD were measured by dual x-ray absorptiometry in 41 children with JRA and 62 healthy children. Serum samples were analyzed for concentrations of minerals, vitamin D, parathyroid hormone, osteocalcin, bone-specific alkaline phosphatase (BAP), procollagen I carboxy-terminal propeptide, and tartrate-resistant acid phosphatase (TRAP), and urinary excretion of deoxypyridinoline crosslinks and calcium. Results. BMD was decreased at all sites in JRA patients. BMD, corrected for age, height, weight, and bone area, was decreased at cortical bone sites (1/3 radius, upper and lower extremities, and whole body). Low concentrations of osteocalcin and BAP suggested reduced bone formation, and low TRAP levels suggested decreased resorption. Clinical scales of disease severity were negatively correlated with measures of bone mass. Laboratory markers of disease severity were highly correlated with decreases in markers of bone formation, but not with those of resorption. Although laboratory findings were similar for children with oligoarticular and polyarticular disease, differences in bone mass were greater in children with polyarticular disease. Conclusion. These data suggest an association between decreased bone mineralization in JRA and low bone formation that is related to disease severity. Efforts to stimulate bone formation, therefore, need to be considered clinically in prepubertal children with active JRA.     

Regulation of bone mass through pineal‐derived melatonin‐MT2 receptor pathway

Tryptophan, an essential amino acid through a series of enzymatic reactions gives rise to various metabolites, viz. serotonin and melatonin, that regulate distinct biological functions. We show here that tryptophan metabolism in the pineal gland favors bone mass accrual through production of melatonin, a pineal‐derived neurohormone. Pineal gland‐specific deletion of Tph1, the enzyme that catalyzes the first step in the melatonin biosynthesis lead to a decrease in melatonin levels and a low bone mass due to an isolated decrease in bone formation while bone resorption parameters remained unaffected. Skeletal analysis of the mice deficient in MT1 or MT2 melatonin receptors showed a low bone mass in MT2?/? mice while MT1?/? mice had a normal bone mass compared to the WT mice. This low bone mass in the MT2?/? mice was due to an isolated decrease in osteoblast numbers and bone formation. In vitro assays of the osteoblast cultures derived from the MT1?/? and MT2?/? mice showed a cell intrinsic defect in the proliferation, differentiation and mineralization abilities of MT2?/? osteoblasts compared to WT counterparts, and the mutant cells did not respond to melatonin addition. Finally, we demonstrate that daily oral administration of melatonin can increase bone accrual during growth and can cure ovariectomy‐induced structural and functional degeneration of bone by specifically increasing bone formation. By identifying pineal‐derived melatonin as a regulator of bone mass through MT2 receptors, this study expands the role played by tryptophan derivatives in the regulation of bone mass and underscores its therapeutic relevance in postmenopausal osteoporosis.