Expression and function of P2 receptors in bone

ATP (adenosine 5'-triphosphate) is one of the most important extracellular regulatory molecules in the skeleton. Extracellular ATP and other nucleotides signal through P2 receptors, a diverse group of receptors that are widely expressed by bone cells. P2 receptors are divided into two subclasses; P2Y G-protein coupled receptors, and P2X ligand-gated ion channels, and there is functional and molecular evidence for the expression of these receptors on both osteoblasts and osteoclasts. In order to activate P2 receptors, nucleotides must be released into the bone microenvironment. ATP is present in mmol concentrations in cells and can be released by cell lysis, cell trauma or physiological mechanisms, possibly through ABC transporters. Following co-activation of P2Y and PTH1 receptors on osteoblasts, there are multiple levels of interaction in downstream signalling that eventually lead to synergistic expression of osteoblastic genes, providing a mechanism for integrating local and systemic regulatory signals in bone particularly with regard to the activation of bone remodelling. Activation of P2Y1 receptors on osteoblasts enhances expression of RANKL leading indirectly to an increase in osteoclast formation and resorption. Expression of P2X7 inducible pores on osteoclast precursor cell membranes allows fusion to form multinucleated osteoclasts and blockade of this receptor inhibits resorption. The capacity of extracellular nucleotides to provide a highly localized and transient signal coupled with the profound effects of P2 receptor activation on osteoblastic and osteoclastic cells and the synergistic interactions with systemic hormones, indicate that nucleotides have a strong influence over bone tissue growth and regeneration.     

Direct transcriptional targets of sex steroid hormones in bone

The sex steroid hormones, androgens and estrogens, via their respective nuclear receptors, regulate bone mineral density in humans and mice. Very little is known about the direct targets of the androgen and estrogen receptors in bone cells. First, models of hormone and receptor deficiency in mouse and human bone are discussed. This review then focuses on the direct targets of the receptors in osteoblasts and osteoclasts. A direct target of a NR is defined here as a gene that is regulated by NR binding to the DNA (either through DNA binding or association with a DNA binding protein) at an enhancer or promoter of that gene. The experimental evidence that illustrates androgen and estrogen gene regulation in osteoblasts and osteoclasts will be summarized and compared with the phenotype of the hormones in vivo.     

Tumor necrosis factors alpha and beta induce osteoblastic cells to stimulate osteoclastic bone resorption

Antigen- or mitogen-stimulated leukocytes release bone-resorbing activity into culture supernatants in vitro. Among the agents likely to be present in such supernatants are monocyte-derived tumor necrosis factor (TNF-alpha) and lymphocyte-derived tumor necrosis factor (TNF-beta) (lymphotoxin), both of which have recently been shown to stimulate bone resorption in organ culture. To identify the mechanism of action of these agents, we compared bone resorption by isolated osteoclasts with bone resorption by osteoclasts cocultured with osteoblastic cells, and with bone resorption by osteoclasts incubated with supernatants from osteoblastic cells, in the presence and absence of recombinant TNF-alpha and TNF-beta. We found that neither TNF-alpha nor TNF-beta had any significant effect on bone resorption by isolated osteoclasts, but in the presence of osteoblasts the agents caused a twofold to threefold stimulation of bone resorption. A similar degree of stimulation was achieved by supernatants from osteoblasts incubated with TNF before addition to osteoclasts, compared with supernatants to which TNF were added after osteoblast incubation. These experiments suggest that TNF-alpha and TNF-beta stimulate bone resorption through a primary effect on osteoblastic cells, which are induced by TNF to produce a factor that stimulates osteoclastic resorption. Half-maximal stimulation of resorption occurred at 1.5 X 10(-10) M and 2.5 X 10(-10) M for TNF-alpha and TNF-beta, respectively. This degree of potency is comparable to that of parathyroid hormone, the major physiologic systemic regulator of bone resorption, and suggests that the TNF may exert a significant influence on osteoclastic bone resorption in vivo.     

Cloning and function of rabbit peroxisome proliferator-activated receptor delta/beta in mature osteoclasts

Osteoclasts modulate bone resorption under physiological and pathological conditions. Previously, we showed that both estrogens and retinoids regulated osteoclastic bone resorption and postulated that such regulation was directly mediated through their cognate receptors expressed in mature osteoclasts. In this study, we searched for expression of other members of the nuclear hormone receptor superfamily in osteoclasts. Using the low stringency homologous hybridization method, we isolated the peroxisome proliferator-activated receptor delta/beta (PPARdelta/beta) cDNA from mature rabbit osteoclasts. Northern blot analysis showed that PPARdelta/beta mRNA was highly expressed in highly enriched rabbit osteoclasts. Carbaprostacyclin, a prostacyclin analogue known to be a ligand for PPARdelta/beta, significantly induced both bone-resorbing activities of isolated mature rabbit osteoclasts and mRNA expression of the cathepsin K, carbonic anhydrase type II, and tartrate-resistant acid phosphatase genes in these cells. Moreover, the carbaprostacyclin-induced bone resorption was completely blocked by an antisense phosphothiorate oligodeoxynucleotide of PPARdelta/beta but not by the sense phosphothiorate oligodeoxynucleotide of the same DNA sequence. Our results suggest that PPARdelta/beta may be involved in direct modulation of osteoclastic bone resorption.     

Oestrogen action on bone cells

Sex steroids have an important impact on bone physiology. Oestrogen (E) appears to be the most important sex steroid in preventing osteoporosis in women. Despite the overwhelming evidence that oestrogens modulate bone growth and turnover in vivo, oestrogen receptors (ER) were detected only recently. Two forms of ER have been discovered so far, ERalpha and ERbeta. Both have been detected in osteoblasts and osteoclasts as well. A number of growth factors and cytokines appear to modulate bone resorption in vitro and in vivo. Among others, interleukin-1 and -6 and tumor necrosis factor alpha and beta were found to be extremely potent stimulators of bone resorption. Binding of different cytokines to their receptors in osteoblasts result in the release of soluble factors that act directly on osteoclasts to modulate their recruitment or activity. Thus, E, apart from the direct regulation of osteoclasts, which it achieves through its receptors, can inhibit the release of osteoclast stimulatory factors or enhance the release of osteoclast inhibitory factors. In general, E is an inhibitor of bone resorption that decreases both osteoclast numbers and activity. Recently, it has also been shown that it promotes apoptosis. Moreover, it also has anabolic effects on osteoblasts. However, E action on osteoclasts is superior in comparison with that on osteoblasts. Recent data have shown that transforming growth factor beta (TGFbeta) mediates the actions of E in bone. Following the example of raloxifene it may be proved that the role of TGFbeta in the actions of E in bone is central and has not only academic interest. More data are needed to elucidate this issue. Finally, recent data suggest the importance of E for bone maturation and development of peak bone mass in men. It seems likely that both E and androgens are required for the growth and maintenance of the adult male skeleton.     

Lactoferrin and bone; structure-activity relationships.

The maintenance of the mechanical integrity of the skeleton depends on bone remodeling, the well-coordinated balance between bone formation by osteoblasts and bone resorption by osteoclasts. The coupled action of osteoblasts and osteoclasts is regulated by the action of many local and circulating hormones and factors as well as central regulation by a neurological mechanism. We have previously shown that lactoferrin can promote bone growth. At physiological concentrations, lactoferrin potently stimulates the proliferation and differentiation of primary osteoblasts and acts as a survival factor. Lactoferrin also affects osteoclasts, potently inhibiting their formation. In vivo, local injection of lactoferrin results in substantial increases in bone formation and bone area. In a critical bone-defect model in vivo, lactoferrin was also seen to promote bone growth. The mitogenic effect of lactoferrin in osteoblast-like cells is mediated mainly through low-density lipoprotein-receptor protein-1 (LRP1), a member of the low-density lipoprotein-receptor-related proteins that are primarily known as endocytic receptors; however, LRP1 is not necessary for the anti-apoptotic actions of lactoferrin. Lactoferrin also induces the activation of p42/44 mitogen-activated protein kinase (MAPK) signalling and the PI3-kinase-dependent phosphorylation of Akt in osteoblasts. In this study, we examined other properties of lactoferrin and the way they affect osteogenic activity. The degree of glycosylation, iron-binding, and the structure-activity relationships indicate that lactoferrin maintains osteogenic activity in deglycosylated, holo, and apo forms, and in with various small fragments of the molecule. These data suggest that lactoferrin signals through more than 1 membrane-bound receptor to produce its anabolic skeletal effects, and that it signals through diverse pathways. We conclude that lactoferrin might have a physiological role in bone growth and healing and a potential therapeutic role as an anabolic factor in osteoporosis.     

A supra-cellular model for coupling of bone resorption to formation during remodeling: lessons from two bone resorption inhibitors affecting bone formation differently

The bone matrix is maintained functional through the combined action of bone resorbing osteoclasts and bone forming osteoblasts, in so-called bone remodeling units. The coupling of these two activities is critical for securing bone replenishment and involves osteogenic factors released by the osteoclasts. However, the osteoclasts are separated from the mature bone forming osteoblasts in time and space. Therefore the target cell of these osteoclastic factors has remained unknown. Recent explorations of the physical microenvironment of osteoclasts revealed a cell layer lining the bone marrow and forming a canopy over the whole remodeling surface, spanning from the osteoclasts to the bone forming osteoblasts. Several observations show that these canopy cells are a source of osteoblast progenitors, and we hypothesized therefore that they are the likely cells targeted by the osteogenic factors of the osteoclasts. Here we provide evidence supporting this hypothesis, by comparing the osteoclast-canopy interface in response to two types of bone resorption inhibitors in rabbit lumbar vertebrae. The bisphosphonate alendronate, an inhibitor leading to low bone formation levels, reduces the extent of canopy coverage above osteoclasts. This effect is in accordance with its toxic action on periosteoclastic cells. In contrast, odanacatib, an inhibitor preserving bone formation, increases the extent of the osteoclast-canopy interface. Interestingly, these distinct effects correlate with how fast bone formation follows resorption during these respective treatments. Furthermore, canopy cells exhibit uPARAP/Endo180, a receptor able to bind the collagen made available by osteoclasts, and reported to mediate osteoblast recruitment. Overall these observations support a mechanism where the recruitment of bone forming osteoblasts from the canopy is induced by osteoclastic factors, thereby favoring initiation of bone formation. They lead to a model where the osteoclast-canopy interface is the physical site where coupling of bone resorption to bone formation occurs.     

Osteoblastic regulation of osteoclast survival: effect of calcitriol

Throughout life, bone is remodelled in a dynamic process which results in a balance between bone formation by osteoblasts and bone resorption by osteoclasts. It is now clearly established that osteoblasts/stromal cells are crucial for differentiation of osteoclasts, through a mechanism involving cell-to-cell contact. However, the possible involvement of osteoblasts and stromal cells in the survival of osteoclasts has not yet been clearly demonstrated. In this study, we assessed the influence of cellular microenvironment, especially osteoblasts, on the osteoclast survival. Our results have shown significant differences in osteoclastic survival between unfractionated bone cells and pure osteoclasts. Furthermore, we have shown that addition of 1.25(OH)2D3 to unfractionated bone cells resulted in a dose-dependent increase in osteoclast survival. Finally, we have shown that a conditioned medium obtained from rat osteoblastic cells cultured with calcitriol was able to increase significantly survival of pure osteoclasts. Taken together, these results strongly suggest that osteoblastic cells present in the bone microenvironment might play a role in the osteoclastic survival by producing soluble factor which modulate osteoclast apoptosis.     

Extracellular ADP is a powerful osteolytic agent: evidence for signaling through the P2Y(1) receptor on bone cells.

There is increasing evidence that extracellular nucleotides act on bone cells via P2 receptors. This study investigated the action of ADP and 2-methylthioADP, a potent ADP analog with selectivity for the P2Y(1) receptor, on osteoclasts, the bone-resorbing multinuclear cells. Using three different assays, we show that ADP and 2-methylthioADP at nanomolar to submicromolar levels caused up to fourfold to sixfold increases in osteoclastic bone resorption. On mature rat osteoclasts, cultured for 1 day on polished dentine disks, peak effects on resorption pit formation were observed between 20 nM and 2 microM of ADP. The same concentrations of ADP also stimulated osteoclast and resorption pit formation in 10-day mouse marrow cultures on dentine disks. In 3-day explant cultures of mouse calvarial bones, the stimulatory effect of ADP on osteoclast-mediated Ca(2+) release was greatest at 5-50 microM and equivalent to the maximal effects of prostaglandin E(2). The ADP effects were blocked in a nontoxic manner by MRS 2179, a P2Y(1) receptor antagonist. Using in situ hybridization and immunocytochemistry, we found evidence for P2Y(1) receptor expression on both osteoclasts and osteoblasts; thus, ADP could exert its actions both directly on osteoclasts and indirectly via P2Y(1) receptors on osteoblasts. As a major ATP degradation product, ADP is a novel stimulator of bone resorption that could help mediate inflammatory bone loss in vivo.     

Regulation of osteoclast activity.

Osteoclasts are the primary cell type responsible for bone resorption. This paper reviews many of the known regulators of osteoclast activity, including hormones, cytokines, ions, and arachidonic acid metabolites. Most of the hormones and cytokines that inhibit osteoclast activity act directly on the osteoclasts. In contrast, most of the hormones and cytokines that stimulate osteoclast activity act indirectly through osteoblasts. Particularly interesting in this regard are agents that directly inhibit activity of highly purified osteoclasts yet stimulate activity of osteoclasts that are co-cultured with osteoblasts. Recent studies have demonstrated that the primary mechanism by which bone resorptive agents stimulate osteoclast activity indirectly is likely to be up-regulation of production of osteoclast differentiation factor/osteoprotegerin ligand (ODF/OPGL) by the osteoblasts. In addition to discussing regulators of osteoclast activity per se, this paper also reviews the role of osteoclast apoptosis to limit the extent of bone resorption.     

Normal human osteoclasts formed from peripheral blood monocytes express PTH type 1 receptors and are stimulated by PTH in the absence of osteoblasts

The prevailing view for many years has been that osteoclasts do not express parathyroid hormone (PTH) receptors and that PTH's effects on osteoclasts are mediated indirectly via osteoblasts. However, several recent reports suggest that osteoclasts express PTH receptors. In this study, we tested the hypothesis that human osteoclasts formed in vitro express functional PTH type 1 receptors (PTH1R). Peripheral blood monocytes (PBMC) were cultured on bone slices or plastic culture dishes with human recombinant RANK ligand (RANKL) and recombinant human macrophage colony-stimulating factor (M-CSF) for 16-21 days. This resulted in a mixed population of mono- and multi-nucleated cells, all of which stained positively for the human calcitonin receptor. The cells actively resorbed bone, as assessed by release of C-terminal telopeptide of type I collagen and the formation of abundant resorption pits. We obtained evidence for the presence of PTH1R in these cells by four independent techniques. First, using immunocytochemistry, positive staining for PTH1R was observed in both mono- and multi-nucleated cells intimately associated with resorption cavities. Second, PTH1R protein expression was demonstrated by Western blot analysis. Third, the cells expressed PTH1R mRNA at 21 days and treatment with 10(-7) M hPTH (1-34) reduced PTH1R mRNA expression by 35%. Finally, bone resorption was reproducibly increased by two to threefold when PTH (1-34) was added to the cultures. These findings provide strong support for a direct stimulatory action of PTH on human osteoclasts mediated by PTH1R. This suggests a dual regulatory mechanism, whereby PTH acts both directly on osteoclasts and also, indirectly, via osteoblasts.     

Characterization of interferon gamma receptors on osteoclasts: effect of interferon gamma on osteoclastic superoxide generation

Osteoclasts are the primary cells responsible for bone resorption. Osteoclast formation and bone resorption activities involve processes tightly controlled by a network of cytokines. The presence of interferon gamma (IFN-gamma) receptors on osteoclasts is a necessary prerequisite for IFN-gamma to directly affect osteoclastic activity. To date, the presence of the IFN-gamma receptor on osteoclasts has not been established. This study provides evidence that osteoclasts express the IFN-gamma receptor. Specific binding of IFN-gamma to the osteoclastic receptor stimulates osteoclastic superoxide generation. The p91 and p47 components of the NADPH oxidase increase after IFN-gamma stimulation and may account for the enhanced superoxide generation. Antisense experiments targeting p91 and p47 subunits abrogate the increased osteoclastic superoxide production stimulated by IFN-gamma. Thus, superoxide generation by osteoclasts is stimulated by activation of a functional IFN-gamma receptor on the osteoclast.     

Fibroblast growth factor (FGF)-2 directly stimulates mature osteoclast function through activation of FGF receptor 1 and p42/p44 MAP kinase

We previously reported that fibroblast growth factor-2 (FGF-2) acts not only on osteoblasts to stimulate osteoclastic bone resorption indirectly but also on mature osteoclasts directly. In this study, we investigated the mechanism of this direct action of FGF-2 on mature osteoclasts using mouse and rabbit osteoclast culture systems. FGF-2 stimulated pit formation resorbed by isolated rabbit osteoclasts moderately from low concentrations (>/=10(-12) m), whereas at high concentrations (>/=10(-9) m) it showed stimulation on pit formation resorbed by unfractionated bone cells very potently. FGF-2 (>/=10(-12) m) also increased cathepsin K and MMP-9 mRNA levels in mouse and rabbit osteoclasts. Among FGF receptors (FGFR1 to 4) only FGFR1 was detected on isolated mouse osteoclasts, whereas all FGFRs were identified on mouse osteoblasts. FGF-2 (>/=10(-12) m) up-regulated the phosphorylation of cellular proteins, including p42/p44 mitogen-activated protein (MAP) kinase, and increased the kinase activity of immunoprecipitated FGFR1 in mouse osteoclasts. The stimulation of FGF-2 on mouse and rabbit osteoclast functions was abrogated by PD-98059, a specific inhibitor of p42/p44 MAP kinase. These results strongly suggest that FGF-2 acts directly on mature osteoclasts through activation of FGFR1 and p42/p44 MAP kinase, causing the stimulation of bone resorption at physiological or pathological concentrations.     

Short-range intercellular calcium signaling in bone

The regulation of bone turnover is a complex and finely tuned process. Many factors regulate bone remodeling, including hormones, growth factors, cytokines etc. However, little is known about the signals coupling bone formation to bone resorption, and how mechanical forces are translated into biological effects in bone. Intercellular calcium waves are increases in intracellular calcium concentration in single cells, subsequently propagating to adjacent cells, and can be a possible mechanism for the coupling of bone formation to bone resorption. The aim of the present studies was to investigate whether bone cells are capable of communicating via intercellular calcium signals, and determine by which mechanisms the cells propagate the signals. First, we found that osteoblastic cells can propagate intercellular calcium transients upon mechanical stimulation, and that there are two principally different mechanisms for this propagation. One mechanism involves the secretion of a nucleotide, possibly ATP, acting in an autocrine action to purinergic P2Y2 receptors on the neighboring cells, leading to intracellular IP3 generation and subsequent release of calcium from intracellular stores. The other mechanism involves the passage of a small messenger through gap junctions to the cytoplasm of the neighboring cells, inducing depolarization of the plasma membrane with subsequent opening of membrane bound voltage-operated calcium channels. Next, we found that osteoblasts can propagate these signals to osteoclasts as well. We demonstrated that paracrine action of ATP was responsible for the wave propagation, but now the purinergic P2X7 receptor was involved. Thus, the studies demonstrate that calcium signals can be propagated not only among osteoblasts, but also between osteoblasts and osteoclasts in response to mechanical stimulation. Thus, intercellular calcium signaling can be a mechanism by which mechanical stimuli on bone are translated into biological signals in bone cells, and propagated through the network of cells in bone. Further, the observations offer new pharmacological targets for the modulation of bone turnover, and perhaps even for the treatment of bone metabolic disorders.     

Osteoclast-osteoblast communication

Cells in osteoclast and osteoblast lineages communicate with each other through cell-cell contact, diffusible paracrine factors and cell-bone matrix interaction. Osteoclast-osteoblast communication occurs in a basic multicellular unit (BMU) at the initiation, transition and termination phases of bone remodeling. At the initiation phase, hematopoietic precursors are recruited to the BMU. These precursors express cell surface receptors including c-Fms, RANK and costimulatory molecules, such as osteoclast-associated receptor (OSCAR), and differentiate into osteoclasts following cell-cell contact with osteoblasts, which express ligands. Subsequently, the transition from bone resorption to formation is mediated by osteoclast-derived ‘coupling factors’, which direct the differentiation and activation of osteoblasts in resorbed lacunae to refill it with new bone. Bidirectional signaling generated by interaction between ephrinB2 on osteoclasts and EphB4 on osteoblast precursors facilitates the transition. Such interaction is likely to occur between osteoclasts and lining cells in the bone remodeling compartment (BRC). At the termination phase, bone remodeling is completed by osteoblastic bone formation and mineralization of bone matrix. Here, we describe molecular communication between osteoclasts and osteoblasts at distinct phases of bone remodeling.     

Dexamethasone inhibits bone resorption by indirectly inducing apoptosis of the bone-resorbing osteoclasts via the action of osteoblastic cells

Although glucocorticoids (GCs) are physiologically essentialfor bone metabolism, it is generally accepted that high dosesof GCs cause bone loss through a combination of decreased boneformation and increased bone resorption. However, the actionof GCs on mature osteoclasts remains contradictory. In thisstudy, we have examined the effect of GCs on osteoclasticbone-resorbing activity and osteoclast apoptosis, by using twodifferent cell types, rabbit unfractionated bone cells andhighly enriched mature osteoclasts (>95% of purity).Dexamethasone (Dex, 10^-10–10^-7 M) inhibited resorption pit formation on a dentine slice by the unfractionated bone cells in a dose- and time-dependent manner.However, Dex had no effect on the bone-resorbing activity of the isolated mature osteoclasts. When the isolated osteoclastswere co-cultured with rabbit osteoblastic cells, the osteoclastic bone resorption decreased in response to Dex,dependent on the number of osteoblastic cells. Like the effecton the bone resorption, Dex induced osteoclast apoptosis in cultures of the unfractionated bone cells, whereas it did not promote the apoptosis of the isolated osteoclasts. An inhibitorof caspases, Z-Asp-CH2-DCB attenuated both the inhibitory effecton osteoclastic bone resorption and the stimulatory effect onthe osteoclast apoptosis. In addition, the osteoblastic cellswere required for the osteoclast apoptosis induced by Dex. These findings indicate that the main target cells of GCs arenon-osteoclastic cells such as osteoblasts and that GCsindirectly inhibit bone resorption by inducing apoptosis ofthe mature osteoclasts through the action of non-osteoclasticcells. This study expands our knowledge about the multifunctional roles of GCs in bone metabolism.     

Non-enzymatic glycation of bone collagen modifies osteoclastic activity and differentiation

Type I collagen, the major organic component of bone matrix, undergoes a series of post-translational modifications that occur with aging, such as the non-enzymatic glycation. This spontaneous reaction leads to the formation of advanced glycation end products (AGEs), which accumulate in bone tissue and affect its structural and mechanical properties. We have investigated the role of matrix AGEs on bone resorption mediated by mature osteoclasts and the effects of exogenous AGEs on osteoclastogenesis. Using in vitro resorption assays performed on control- and AGE-modified bone and ivory slices, we showed that the resorption process was markedly inhibited when mature osteoclasts were seeded on slices containing matrix pentosidine, a well characterized AGE. More specifically, the total area resorbed per slice, and the area degraded per resorption lacuna created by osteoclasts, were significantly decreased in AGE-containing slices. This inhibition of bone resorption was confirmed by a marked reduction of the release of type I collagen fragments generated by the collagenolytic enzymes secreted by osteoclasts in the culture medium of AGE-modified mineralized matrices. This effect is likely to result from decreased solubility of collagen molecules in the presence of AGEs, as documented by the reduction of pepsin-mediated digestion of AGE-containing collagen. We found that AGE-modified BSA totally inhibited osteoclastogenesis in vitro, most likely by impairing the commitment of osteoclast progenitors into pre-osteoclastic cells. Although the mechanisms remain unknown, AGEs might interfere with osteoclastic differentiation and activity through their interaction with specific cell-surface receptors, because we showed that both osteoclast progenitors and mature osteoclasts expressed different AGEs receptors, including receptor for AGEs (RAGEs). These results suggest that AGEs decreased osteoclast-induced bone resorption, by altering not only the structural integrity of bone matrix proteins but also the osteoclastic differentiation process. We suggest that AGEs may play a role in the alterations of bone remodeling associated with aging and diabetes.     

MMP-9 antisense oligodeoxynucleotide exerts an inhibitory effect on osteoclastic bone resorption by suppressing cell migration

We have previously shown that matrix metalloproteinases (MMPs) play a role in osteoclastic bone resorption by facilitating migration of osteoclastic cells toward bone surface through matrices. Of MMPs identified so far, MMP-9 is likely the most important proteinase for the action, since osteoclasts express this enzyme at a tremendously high level. However, no direct evidence has been provided to demonstrate its contribution to bone resorption. In this study, to address this point, we used an MMP-9 antisense phosphothiorate oligodeoxynucleotide (S-ODN), which was shown to inhibit the protein synthesis of MMP-9 efficiently. We demonstrated that the antisense S-ODN inhibited osteoclastic pit formation on matrigel-coated dentine slices in a concentration-dependent manner with a maximum reduction of total pit volume by 53% at 10 microM. These results, taken together, suggest that MMP-9 is involved in osteoclastic bone resorption process possibly by facilitating migration of osteoclasts through proteoglican-rich matrices.     

A two-receptor model for the action of parathyroid hormone on osteoblasts: a role for intracellular free calcium and cAMP

It has been suggested that intracellular Ca2+, in addition to cAMP, plays an important role in PTH-stimulated bone resorption. There is now strong evidence indicating that the osteoblast is the main target cell for PTH action, regulating indirectly, via cell-cell communication, osteoclastic bone resorption. In order to investigate the possible role of free cytosolic calcium in stimulated bone resorption, we studied the effects of the intact hormone (bPTH 1-84) and some of its fragments (bPTH (1-34), bPTH(3-34,) (Nle-8, Nle-18,Tyr-34) bPTH (3-34) amide) on their capacity to modify the cytosolic Ca2+ concentration in rat osteoblast-like cells. The experiments were performed using Quin-2, a fluorescent indicator of free calcium. We found an excellent correlation between the ability of PTH and PTH fragments to transiently increase cytosolic Ca2+ concentration in rat osteoblast-like cells and their ability to stimulate bone resorption in embryonic rat calvaria in vitro. On the other hand, no direct correlation was found for the cAMP and bone-resorbing responses. On the ground of these data we propose a two-receptor model for PTH action in osteoblasts, in which one receptor is coupled to the production of cAMP, whereas the other is involved in the increase of cytosolic Ca2+. Activation of both receptors by PTH (1-84) or PTH (1-34) leads to the full physiological response in osteoblasts, most probably the release of one or more factors which stimulate the activity of existing osteoclasts and others which stimulate the recruitment of additional osteoclasts.     

Human osteoclast ontogeny and pathological bone resorption

Monocytes and macrophages are capable of degrading both the mineral and organic components of bone and are known to secrete local factors which stimulate host osteoclastic bone resorption. Recent studies have shown that monocytes and macrophages, including those isolated from neoplastic and inflammatory lesions, can also be induced to differentiate into cells that show all the cytochemical and functional characteristics of mature osteoclasts, including lacunar bone resorption. Monocyte/macrophage-osteoclast differentiation occurs in the presence of osteoblasts/bone stromal cells (which express osteoclast differentiation factor) and macrophage-colony stimulating factor and is inhibited by osteoprotegerin. Various systemic hormones and local factors (e.g. cytokines, growth factors, prostaglandins) modulate osteoclast formation by controlling these cellular and humoral elements. Various pathological lesions of bone and joint (e.g. carcinomatous metastases, arthritis, aseptic loosening) are associated with osteolysis. These lesions generally contain a chronic inflammatory infiltrate in which macrophages form a significant fraction. One cellular mechanism whereby pathological bone resorption may be effected is through generation of increased numbers of bone-resorbing osteoclasts from macrophages. Production of humoral factors which stimulate mononuclear phagocyte-osteoclast differentiation and osteoclast activity is also likely to influence the extent of pathological bone resorption.