Divalent cations mimic the inhibitory effect of extracellular ionised calcium on bone resorption by isolated rat osteoclasts: further evidence for a "calcium receptor".

Osteoclast activity is thought to be regulated by calcitonin, as well as by the level of ionised calcium generated locally as a result of bone resorption. The exposure of isolated osteoclasts to elevated ambient calcium levels has been shown to lower resorptive activity and to reduce rates of enzyme release. We have attempted to determine whether these effects are mediated by a divalent cation-sensitive "calcium receptor," as has been reported for the parathyroid chief cells. Thus, we compared the effect of alkaline earth metal cations on osteoclast function using a morphometric measure of bone resorption and a spectrophotometric method for measuring the activity of the released enzyme, acid phosphatase. The exposure of resorbing osteoclasts to between 5 and 20 mM extracellular ionised calcium ([Ca2+]e) inhibited bone resorption and enzyme release to an extent similar to that seen with 0.1 to 10 microM ionomycin. The effect of combining submaximal concentrations of [Ca2+]e (15 mM) and ionomycin (0.1 microM) resulted in additivity, suggesting that the influence of [Ca2+]e on bone resorption was mediated by elevated intracellular calcium levels ([Ca2+]i). The other cations studied (Mg2+, Ba2+) were effective and elicited similar effects, although some required higher concentrations. Thus, whilst Ca2+ and Mg2+ were effective at 10 to 15 mM levels, Ba2+ was effective only at high (20 mM) concentrations. These findings are consistent with an influence of [Ca2+]e on osteoclast activity through an action on a surface membrane "calcium receptor" that can also bind other divalent cations, rather than by passive changes of [Ca2+]i with [Ca2+]e elevation.     

Cytosolic free calcium dependent regulation of osteoclast bone resorbing activity

Osteoclasts are sensitive to KCl-induced depolarization and to increased extracellular calcium concentration, and respond to these treatments with cytosolic calcium increase. In this study we evaluated the possibility that these experimental conditions could affect osteoclast bone resorption. We found that, incubating osteoclasts with 3H-proline previously labeled bone particles the resorbing activity was inhibited by both depolarization and extracellular calcium concentration increase. The released radioactivity was, in fact, 48% and 52% respectively compared to the untreated cultures. These data demonstrated that cytosolic calcium increase is one of the messengers of the pathway that inhibits, in this condition, bone resorption. Furthermore, as in parathyroid cells, extracellular calcium acts with a negative direct feedback mechanism that controls osteoclast activity.     

Osteoclast and its roles in calcium metabolism and bone development and remodeling

Osteoclasts are multinucleated cells responsible for bone resorption and play important roles in normal skeletal development, in the maintenance of its integrity throughout life, and in calcium metabolism. During bone resorption, the cytoskeleton of osteoclasts undergoes extensive reorganization, with polarization and formation of ruffled borders to secrete acid and formation of sealing zone to prevent leakage. The differentiation and function of osteoclasts are in turn regulated by osteoblasts, stromal cells, and bone. They are also subjected to negative feedback regulation by extracellular and intracellular calcium concentrations.     

Involvement of capacitive calcium entry and calcium store refilling in osteoclastic survival and bone resorption process

Bone resorption is closely dependent on osteoclastic survival and osteoclast apoptotic cell death could represent a key step at the end of this process. In order to precise the possible role of calcium movement in osteoclastic cell death, we investigated whether intracellular calcium store replenishment and capacitive calcium entry (CCE) are involved in osteoclastic survival and bone resorption. We demonstrate that (i). thapsigargin, a sarco-endoplasmic reticulum calcium ATPase pump (SERCA) blocker, decreases both osteoclastic survival and bone resorption process, (ii). 2-aminoethoxydiphenyl borate (2-APB) and SKF-96365, two store-operated channel (SOC) blockers, dramatically decrease osteoclastic survival and bone resorption and (iii). culture in calcium-free medium and thapsigargin exposure synergically inhibit osteoclastic survival which falls dramatically to a value close to 0% (P<0.001). Inversely, osteoclastic survival increases significantly when thapsigargin-treated cells are cultured in the presence of 20mM calcium, suggesting that increasing extracellular calcium concentration stimulates osteoclasts survival when the filling of intracellular stores is prevented. Taken together, our data strongly suggest that in osteoclasts, calcium movements between cellular compartments involved in the regulation of calcium signalling, such as calcium stores refilling and CCE, are closely associated to the regulation of osteoclast survival and bone resorption.     

Osteoclast lineage and function

Osteoclasts are members of the monocyte/macrophage lineage and are formed by cellular fusions from their mononuclear precursors. Their differentiation is regulated by a number of other cells and their products, especially by RANKL and M-CSF. The resorbing osteoclasts are polarized and show specific plasma membrane domains. Polarization and bone resorption need a continuous membrane trafficking and modulation of the cytoskeleton. The most characteristic feature of osteoclasts is their unique capacity to dissolve crystalline hydroxyapatite by targeted secretion of HCl into the extracellular resorption lacuna. Organic matrix is degraded by enzymes like cathepsin K and the degradation products are transcytosed through the cell for secretion. Dissolution of hydroxyapatite releases large amounts of soluble calcium, phosphate and bicarbonate. Removal of these ions apparently involves the vesicular pathways and direct ion transport via different ion exchangers, channels and pumps. Detailed molecular knowledge of osteoclast differentiation and function has helped us to identify several target molecules and develop specific treatments to inhibit pathological bone resorption in various skeletal diseases.     

Antithetic effects of ryanodine and ruthenium red on osteclast-mediated bone resorption and intracellular calcium concentrations

In the process of bone remodeling, osteoclasts are responsible for resorption of bone. High levels of intracellular calcium decrease the bone resorbing activity of osteoclasts and increase detachment of osteoclasts from the bone surface. The regulatory role of intracellular calcium in bone resorption is not clearly understood. To understand this phenomenon, we studied the effects of the intracellular calcium modulators ryanodine and ruthenium red on bone resorption using the disaggregated osteoclast pit assay. Changes in intracellular calcium concentrations after treatment with these compounds were detected with the fluoroprobe fura2. With ryanodine, a significant, dose-dependent decrease in bone resorption was detected. This inhibition of bone resorption was reversible upon the removal of ryanodine. Ryanodine increased intracellular calcium concentrations, suggesting that the mechanism of inhibition by ryanodine was via alterations in intracellular stores of calcium. After treatment with ruthenium red, osteoclasts resorbed significantly more bone compared to vehicle-treated cells. This increase in bone resorption correlated with a decrease in intracellular calcium concentrations. The addition of parathyroid hormone or ruthenium red to osteoclast cultures containing ryanodine did not attenuate the decrease in bone resorption caused by ryanodine, suggesting that the mechanism of ryanodine inhibition of bone resorption may involve the “locking” of a calcium channel in an open position. © 1995 Wiley-Liss, Inc.     

钙敏感受体在骨代谢中的研究进展

钙敏感受体感受细胞外的钙离子水平,调控一系列激素的释放以维持机体的钙稳态。钙稳态的调节过程与骨代谢相偶联,钙敏感受体通过直接或间接对破骨和成骨细胞的调控,动员或者抑制骨钙入血。虽然钙敏感受体已被证实调控骨代谢,但是详尽的调控机制仍在不断探究中。目前认为细胞外的高钙水平会激活钙敏感受体,抑制甲状旁腺激素分泌并促进降钙素释放,进而破骨细胞被抑制,成骨细胞动员,增加了骨质合成。本文就近年来关于钙敏感受体调控骨代谢的研究进展作一综述,为促进钙敏感受体及相关作用因子治疗骨代谢疾病的研究提供参考。     

Regulation of bone resorption and osteoclast survival by nitric oxide: possible involvement of NMDA-receptor

Nitric oxide has been shown to play an important role in regulation of bone resorption. However, the role of endogenous nitric oxide on osteoclast activity remains still controversial. In this work, using RT-PCR amplification, we demonstrated that rabbit mature osteoclasts express mRNA encoding for neuronal nitric oxide synthase suggesting that this enzyme could be involved in basal nitric oxide production in these cells. Then we assessed the effect of carboxy-PTIO, a nitric oxide scavenger, on in vitro bone resorption and osteoclast survival. Carboxy-PTIO (10-100 microM) inhibited osteoclastic bone resorption in a dose dependent manner and induced osteoclast apoptosis by a mechanism involving caspase 3 activation. These results suggest that basal concentration of endogenous nitric oxide may be essential for normal bone resorption by supporting osteoclast survival. Because osteoclasts express N-methyl-d-aspartate-receptor (NMDA-R), we hypothesized that in osteoclasts NMDA-R may be involved in nitric oxide production as in neuronal cells. We confirmed that blockade of NMDA-R with specific non-competitive antagonists, MK801 and DEP, strongly inhibited bone resorption. As for carboxy-PTIO, we showed that blockade of NMDA-R by both antagonists induced osteoclast apoptosis in a dose dependent manner by a mechanism dependent on caspase 3 activation. Intracellular calcium concentration in osteoclasts decreased within minutes in the presence of both antagonists. Finally, MK801-induced osteoclast apoptosis was partially reversed in the presence of small amount of SNAP (100 nM), a nitric oxide donor, suggesting that the effect of NMDA-R on osteoclast apoptotic cell death could be due to a decrease in nitric oxide production. Taken together, our results are consistent with the hypothesis that NMDA-R on osteoclasts could have a similar function as those in neuronal cells, i.e., to allow a calcium influx, which in turn activates a constitutive neuronal nitric oxide synthase. Nitric oxide generated by this pathway may be essential for osteoclast survival and hence for normal bone resorption.     

Optimized transfection of diced siRNA into mature primary human osteoclasts: inhibition of cathepsin K mediated bone resorption by siRNA

Osteoclasts are large multinucleated cells responsible for bone resorption. Bone resorption is dependent on the liberation of calcium by acid and protease destruction of the bone matrix by proteinases. The key proteinase produced by the osteoclast is cathepsin K. Targeted knock-down of cathepsin K was performed using small inhibitory RNA (siRNA). siRNA is a method that introduces short double-stranded RNA molecules that instruct the RNA-induced silencing complex (RISC) to degrade mRNA species complementary to the siRNA. Transfection of siRNA by lipid cations allows for short-term inhibition of expression of the targeted gene. We show that transfection of primary human osteoclasts with siRNA to cathepsin K reduces expression by > or = 60% and significantly inhibits bone resorption with a reduction of both resorption pit numbers (P = 0.018) and resorbed area (P = 0.013). We also show that FuGENE 6 is an effective lipid transfection reagent with which to transfect primary human osteoclasts, that does not produce off-target effects.     

Degradation of hydroxyapatite in vivo and in vitro requires osteoclastic sodium-bicarbonate co-transporter NBCn1

Dissolution of the inorganic bone matrix releases not only calcium and phosphate ions, but also bicarbonate. Electroneutral sodium-bicarbonate co-transporter (NBCn1) is expressed in inactive osteoclasts, but its physiological role in bone resorption has remained unknown. We show here that NBCn1, encoded by the SLC4A7 gene, is directly involved in bone resorption. NBCn1 protein was specifically found at the bone-facing ruffled border areas, and metabolic acidosis increased NBCn1 expression in rats in vivo. In human hematopoietic stem cell cultures, NBCn1 mRNA expression was observed only after formation of resorbing osteoclasts. To further confirm the critical role of NBCn1 during bone resorption, human hematopoietic stem cells were transduced with SLC4A7 shRNA lentiviral particles. Downregulation of NBCn1 both on mRNA and protein level by lentiviral shRNAs significantly inhibited bone resorption and increased intracellular acidification in osteoclasts. The lentiviral particles did not impair osteoclast survival, or differentiation of the hematopoietic or mesenchymal precursor cells into osteoclasts or osteoblasts in vitro. Inhibition of NBCn1 activity may thus provide a new way to regulate osteoclast activity during pathological bone resorption.     

Synaptotagmin VII regulates bone remodeling by modulating osteoclast and osteoblast secretion

Maintenance of bone mass and integrity requires a tight balance between resorption by osteoclasts and formation by osteoblasts. Exocytosis of functional proteins is a prerequisite for the activity of both cells. In the present study, we show that synaptotagmin VII, a calcium sensor protein that regulates exocytosis, is associated with lysosomes in osteoclasts and bone matrix protein-containing vesicles in osteoblasts. Absence of synaptotagmin VII inhibits cathepsin K secretion and formation of the ruffled border in osteoclasts and bone matrix protein deposition in osteoblasts, without affecting the differentiation of either cell. Reflecting these in vitro findings, synaptotagmin VII-deficient mice are osteopenic due to impaired bone resorption and formation. Therefore, synaptotagmin VII plays an important role in bone remodeling and homeostasis by modulating secretory pathways functionally important in osteoclasts and osteoblasts.     

Stimulation of bone resorption and osteoclast clear zone formation by low pH: A time-course study

The significance of low pH-induced stimulation of osteoclastic bone resorption has recently been questioned following the finding that embryonic chick osteoclasts were only weakly stimulated by extremely low pH (6.5) and that the effect was transient, apparently due to cytotoxicity. Although low pH in the range 6.8–7.2 is known to stimulate rat osteoclasts over 24 h, the long-term effects of low pH on mammalian osteoclasts are not known. We have therefore conducted time-course studies over 72 h on the effect of pH in the range 6.3–7.3 on bone resorption and cytotoxicity in both rat and chick osteoclasts. In neonatal rat osteoclasts, lowering extracellular pH produced a powerful and significant stimulation of resorption over 24 h. Detailed analysis of the resorption focus revealed that this was due mainly to a higher proportion of active osteoclasts at lower pH. In addition, osteoclasts excavated slightly larger pits at low pH. Stimulation was no longer significant at 72 h, however, due to a pH-dependent slowing of resorption at acid pH associated 1) with cytotoxicity primarily of nonosteoclastic cells and 2) with an acceleration of bone resorption after 24 h at more alkaline pH. Resorption stimulated by low pH was associated with the formation of actin-rich “clear zones” within the osteoclast. Chick osteoclasts were less sensitive to low pH than rat osteoclasts but nonetheless showed a consistently higher level of resorption at low pH over 24–72 h. These results suggest that protons play an important regulatory role in neonatal rat osteoclasts, and stimulate the formation of clear zones. The lower sensitivity of the chick osteoclast to acid pH may be due to a species difference or the chick osteoclast's higher basal level of resorption. © 1993 Wiley-Liss, Inc.     

Podosome organization drives osteoclast-mediated bone resorption

Osteoclasts are the cells responsible for physiological bone resorption. A specific organization of their most prominent cytoskeletal structures, podosomes, is crucial for the degradation of mineralized bone matrix. Each podosome is constituted of an F-actin-enriched central core surrounded by a loose F-actin network, called the podosome cloud. In addition to intrinsic actin dynamics, podosomes are defined by their adhesion to the extracellular matrix, mainly via core-linking CD44 and cloud-linking integrins. These properties allow podosomes to collectively evolve into different patterns implicated in migration and bone resorption. Indeed, to resorb bone, osteoclasts polarize, actively secrete protons, and proteases into the resorption pit where these molecules are confined by a podosome-containing sealing zone. Here, we review recent advancements on podosome structure and regulatory pathways in osteoclasts. We also discuss the distinct functions of different podosome patterns during the lifespan of a single osteoclast.     

Hypoxia is a major stimulator of osteoclast formation and bone resorption

Hypoxia is known to act as a general stimulator of cells derived from marrow precursors. We investigated the effect of oxygen tension on the formation and function of osteoclasts, the cells responsible for bore resorption, which are of promonocytic origin. Using 7- and 13-day cultures of mouse marrow cells on ivory discs, we found that reducing oxygen tension from the ambient atmospheric level of 20% by increasing the proportion of nitrogen caused progressive increases in the formation of multinucleated osteoclasts and resorption pits. Peak effects occurred in 2% oxygen, where stimulations of resorption up to 21-fold were measured. Significant stimulations of osteoclast formation and resorption were observed even in severely hypoxic cultures gassed with 0.2% oxygen. Short-term cultures of cells disaggregated from rat bones indicated that hypoxia did not alter the resorptive activity of mature osteoclasts, but reduced their survival or adherence. In 3-day organ cultures of mouse calvarial bones, exposure to 2% oxygen resulted in maximal, fivefold stimulation of osteoclast-mediated calcium release, an effect equivalent to that of prostaglandin E(2) (PGE(2)), a reference osteolytic agent. Hypoxia also caused a moderate acidosis in calvarial cultures, presumably as a result of increased anaerobic metabolism; this observation is significant because osteoclast activation is dependent on extracellular acidification. Our experiments reveal a previously-overlooked mechanism of considerable potential importance for the regulation of bone destruction. These findings may help explain the bone loss associated with a wide range of pathological states involving local or systemic hypoxia, and emphasize the importance of the vasculature in bone.     

Ca2+ as an extracellular signal in bone

Bone is the major sink and store for calcium and it fulfils essential roles in the maintenance of extracellular free ionised calcium concentration ([Ca2+]e) within its homeostatic range (1.1-1.3 mM). In response to acute hypercalcaemia or hypocalcaemia, Ca2+ is rapidly transported into or out of bone. Bone turnover (and therefore bone Ca2+ turnover) achieves the long-term correction of the [Ca2+]e by the metabolic actions of osteoblasts and osteoclasts, as they respectively incorporate or release Ca2+ from bone. These processes are regulated by the actions of hormones, such as parathyroid hormone (PTH), the release of which is a function of the [Ca2+]e, and is regulated by the action of the Ca2+-sensing receptor (CaR) in the parathyroid gland. Tissue culture studies indicate that bone cells also directly respond to increasing and decreasing [Ca2+]e in their vicinity, independently of the systemic factors. Nevertheless, further studies are necessary to identify how the acute and long-term local changes in [Ca2+]e affect bone cells and the physiological processes they are involved in. Also, the molecular mechanisms which enable the bone cells to sense and respond to [Ca2+]e are not clear. Like the parathyroid cells, bone cells also express the CaR, and accumulating evidence indicates the involvement of this receptor in their responses to the changing extracellular ionic environment.     

Podosomes are dispensable for osteoclast differentiation and migration

Podosomes are adhesion structures characteristic of the myeloid cell lineage, encompassing osteoclasts, dendritic cells and macrophages. Podosomes are actin-based structures that are dynamic and capable of self-organization. In particular in the osteoclast, podosomes densely pack into a thick ring called the sealing zone. This adhesion structure is typical of osteoclasts and necessary for the resorption of the bone matrix. We thought to explore in more details the role of podosomes during osteoclast differentiation and migration. To this end, we made from soft to stiff substrates that had not been functionalized with extracellular matrix proteins. Such substrates did not support podosome formation in osteoclasts. With such devices, we could show that integrin activation was sufficient to drive podosome assembly, in a substrate stiffness independent fashion. We additionally report here that osteoclast differentiation is a podosome-independent process. Finally, we show that osteoclasts devoid of podosomes can migrate efficiently. Our study further illustrates the great capacity of myeloid cells to adapt to the different environments they encounter during their life cycle.     

High extracellular calcium concentrations directly stimulate osteoclast apoptosis

Although the inhibitory effects of high extracellular calcium concentrations ([Ca](e)) on osteoclastic bone resorption have been known for several years, the exact mechanism remains poorly understood. The present study was performed to investigate the possible effect of [Ca](e) on osteoclast apoptosis. Using highly purified rabbit osteoclasts, we have shown that calcium directly promotes apoptosis in a dose-dependent manner which correlates with the dose range of calcium for the inhibition of bone resorption. A time-course experiment of apoptotic changes of osteoclasts cultured in presence of 1.8 or 20 mM calcium showed a significant difference after as early as 8 h of culture. After 72 h of culture, we observed that 80% of the cells cultured in the presence of 20 mM calcium displayed the typical features of apoptosis compared to only 20% in the medium containing 1.8 mM calcium. Calcium channel blockers and ryanodine abrogated the effects of [Ca](e) on apoptosis while neomycin, a calcium-sensing receptor agonist, did not alter cell viability. Taken together, these results suggest that calcium influx is involved in calcium-induced osteoclast apoptosis. Our results are consistent with the concept that in the presence of high [Ca](e) generated during bone demineralization, osteoclasts are subjected to negative-feedback regulation due, at least in part, to the induction of apoptosis.     

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.