Abstract
In this study, we investigated the effect of CCN2 (cellular communication network factor 2), previously termed connective tissue growth factor, deposited in bone matrix on osteoclastogenesis and osteoblast differentiation. To mimic the bone matrix environment, osteocytic MLO-Y4 cells had been embedded in collagen-gel with recombinant CCN2 (rCCN2), and mouse macrophage-like RAW264.7 cells were inoculated on the gel and treated with receptor activator of NF-κB ligand (RANKL). NFATc1 and cathepsin K (CTSK) productions were more increased in the combination of RAW264.7 and MLO-Y4 cells treated with rCCN2 than the combination without rCCN2. Next, we isolated an osteocyte-enriched population of cells and osteoclast progenitor cells from wild type and tamoxifen-inducible Ccn2-deficient (KO) mice and performed similar analysis. NFATc1 and CTSK productions were decreased in the KO osteocyte-enriched population at 6 months after the tamoxifen injection, regardless of the origin of the osteoclast progenitor cells. Interestingly, CTSK production was rather increased in KO osteocytes at 1 year after the injection. Finally, the combination of osteoblastic MC3T3-E1 and MLO-Y4 cells in rCCN2-containing bone matrix revealed the up-regulation of osteoblastic marker genes. These findings suggest that CCN2 supplied by osteocytes regulates both osteoclastogenesis and osteoblast differentiation.
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Introduction
Bone is continuously rebuilt by the cooperative action of bone-resorbing osteoclasts and bone-forming osteoblasts1. This process, termed “bone remodeling,” is thought to be important to maintain both the architecture and strength of bone tissues1,2. Recently, an in vitro culture system for osteocytes was established; and, as a result, these cells were found to have multiple functions, such as mechanosensing in response to mechanical loadings and regulation of bone remodeling3. Osteocytes are terminally differentiated osteoblasts and are the most abundant cells in bone tissues3. It is also well-known fact that osteocytes have many cell processes extending through canaliculi to form numerous connected communication networks between themselves and cells on the bone surface3,4. Therefore, it is believed that many extracellular communications with neighboring osteocytes, osteoblasts, and osteoclasts play an important role for osteocytes by acting as mechanosensory and regulatory cells of bone remodeling3,4,5. Osteocytes are not necessarily all in the same stage of differentiation3,6. Osteocytes localized around the bone surface extend many cell processes, are young, and capable of bone-forming activity3,6. In fact, it was reported that receptor activator of NF-κB ligand (RANKL), which has a critical role in osteoclastogenesis, is expressed in young osteocytes7, as observed in osteoblasts and chondrocytes8,9. On the other hand, older osteocytes, which are embedded deep in the bone matrix, are characterized by few cytoplasmic organelles and thin cell bodies, and do not express RANKL and bone formation markers6,7. These findings suggest that the morphology and functions of osteocytes change in a time-dependent manner.
Osteocytes function as mechanosensors within bone3. Mechanical stress loaded onto bone is sensed by osteocytes via their cell projections that are spread throughout the entire bone tissues, and physical stimulation is translated into biochemical signals3,4. These signals are believed to regulate the actions of osteoblasts and osteoclasts, thereby providing a mechanism to regulate bone formation and resorption according to the local microenvironment of the bone3. However, the biochemical signals coming from osteocytes are still unknown. We hypothesized that one of these biochemical signaling molecules could be CCN2 (cellular communication network factor 2), which was previously named connective tissue growth factor, because we earlier clarified that CCN2 was induced by mechanical stress and promotes the differentiation of osteoblasts as well as osteoclast formation10,11,12,13.
CCN2 is known as an extracellular matrix-associated (matricellular) protein. It is characterized by the presence of 4 distinct modules, i.e., insulin-like growth factor-binding protein (IGFBP), von Willebrand factor type C (VWC), thrombospondin type 1 repeat (TSP1), and a carboxyl terminal cystine knot (CT), which modules follow an N-terminal secretory signal14,15,16. It was reported that each module of CCN2 interacts with membrane proteins such as integrins as well as with many growth factors involved in bone remodeling14,15,16, thus suggesting that CCN2 may control a network of growth factors and membrane proteins during bone remodeling. We also reported that CCN2 promotes osteoblast differentiation12 and osteoclast formation13 in vitro. In addition, the gene expression and protein production of CCN2 were observed in osteocytes of alveolar bone during experimental tooth movement in mice17. Taken together, these findings suggest that, when mechanical stress is applied to osteocytes in bone tissues, CCN2 produced by osteocytes may promote the differentiation of neighboring osteoblasts as well as the formation of osteoclasts, via their cell projection network.
Conventional Ccn2-deficient mice die soon after birth due to respiratory distress caused by malformation of the rib cage as a result of severe skeletal abnormalities18. In fact, primary chondrocytes derived from the rib cage and osteoblasts from the calvariae of Ccn2-knockout mice at E18.5 exhibit impaired DNA synthesis and faulty extracellular matrix production19. Tartrate-resistant acid phosphatase (TRAP)-positive giant cells along with the bone trabeculae are also decreased in number in Ccn2 mutants13. In addition, neonatal Ccn2-deficient mice show deformed long bones18. These findings indicate that not only osteoblastogenesis and osteoclastogenesis, but also bone remodeling, which is the balance of bone formation and bone resorption may be impaired in Ccn2-deficient mice. Therefore, it is possible that CCN2 and osteocytes embedded in bone matrix may together regulate bone remodeling. To clarify this point, Ccn2-deficient osteocytes are needed. However, osteocytes cannot be isolated from conventional Ccn2-deficeint mice because of the neonatal death of these mice18. Therefore, we employed tamoxifen-inducible conditional Ccn2-deficent mice20,21. These mice were born at expected Mendelian ratios, displayed no obvious skeletal abnormalities at birth, and grew normally to adulthood, with their weight being the same as that of wild type mice20,21. Here, the aim of our study is to clarify the effect of CCN2 from osteocytes on bone remodeling. We investigated the roles of CCN2 in osteoclastogenesis and osteoblast differentiation by using a 3-D culture system of a murine osteocytic cell line, MLO-Y4 cells22, and an osteocyte-enriched cell population isolated from tamoxifen-inducible conditional Ccn2-deficient mice. Here we found that osteocyte-derived CCN2 modified both osteoblast differentiation and osteoclast formation, indicating CCN2 to be an essential factor of bone remodeling.
Results
Down-regulation of Opg in MLO-Y4 cells embedded into collagen gel containing recombinant CCN2 protein (rCCN2)
CCN2 is known to be present in bone tissues23. In order to mimic the bone microenvironment, we established a three-dimensional (3-D) culture system, in which MLO-Y4 cells are embedded into collagen gel with rCCN2 (300 ng/ml; Fig. 1A). Using this system, we firstly investigated whether or not the morphology of MLO-Y4 cells would be affected by rCCN2 in the collagen gel. After cultivation for 2 days, the cells were fixed and fluorescent-phalloidin staining was performed. As a result, the morphology of MLO-Y4 cells embedded in the collagen gel showed no difference by the treatment with either PBS or rCCN2 (Fig. 1B). Next, we examined the gene expression levels of osteocyte markers, such as Osteocalcin (Ocn), Dentin matrix protein 1 (Dmp1), Connexin 43 (Cx43) and Fibroblast growth factor 23 (Fgf23). As shown in Fig. 1C, although the gene expression of Ccn2 was up-regulated in MLO-Y4 cells embedded in the collagen gel with rCCN2, there was no effect on the gene expression of osteocytic markers (Fig. 1C). However, we showed that the gene expression and protein production of osteoprotegerin (OPG), which is a decoy receptor of RANK, was significantly decreased by rCCN2 embedded in the gel, although RANKL expression showed no difference (Fig. 1C–E). Since we had earlier reported that CCN2 plays an important role in bone formation12 and bone resorption13, this finding suggests that CCN2 affected osteoclastogenesis via osteocytes but that osteocytic marker gene expressions were not involved.
MLO-Y4 cells promoted osteoclast formation from RAW264.7 cells in 3-D culture with rCCN2
Next, to investigate whether or not MLO-Y4 cells with rCCN2 would promote osteoclastogenesis, we constructed a 3-D culture system of MLO-Y4 cells in a collagen gel containing rCCN2 and thereafter inoculated RAW264.7 cells onto the collagen gel. Then, the RAW264.7 cells were treated with Glutathione S-transferase (GST)-fused RANKL (GST-RANKL; Fig. 2A). As shown in Fig. 2B, TRAP-positive giant cells were detected in cultures treated with GST-RANKL, and these cells were further increased in number when rCCN2 was present in the gel. On the other hand, as a control experiment, treatment with GST protein slightly yielded TRAP-positive cells on the gel with rCCN2 and few TRAP-positive cells were found on the gel with PBS (Fig. 2B). To support these results, we investigated the protein level of nuclear factor of activated T cells (NFATc1), which is a critical transcriptional factor in osteoclast differentiation, in RAW264.7 cells cultured on the gel containing MLO-Y4 cells with or without rCCN2. As shown in Fig. 2C,D, the level of NFATc1 was significantly increased in RANKL-stimulated RAW264.7 cells on the gel including MLO-Y4 cells with rCCN2, compared with that on the gel with PBS. Interestingly, NFATc1 was slightly detected in RAW264.7 cells on the gel including MLO-Y4 cells and rCCN2 even by the treatment with GST, although densitometric analysis of the band showed no significant difference (Fig. 2D). This finding indicates that CCN2 in the gel may have stimulated osteoclast formation by RAW264.7 cells directly. Since CCN2 is known to be regulated by Sox9 that plays a critical role in chondrogenesis24, we transfected MLO-Y4 cells with a Sox9 expression vector containing 3 × HA tag by using electroporation and examined whether CCN2 was regulated by Sox9, or not (Fig. S1A). After transfection, total RNA was isolated and real-time PCR analysis was performed. As shown in Fig. S1B, Ccn2 expression showed no change in MLO-Y4 cells by the transfection of the Sox9 expression vector.
Osteoclastogenesis from RAW264.7 cells seeded on the gel containing MLO-Y4 cells transfected with a Ccn2 expression vector
To confirm that nascent CCN2 produced by osteocytes promotes osteoclast formation of RAW264.7 cells, we performed transient transfection of MLO-Y4 cells with Ccn2 and green fluorescent protein (Gfp) expression plasmids by using electroporation, and these cells were embedded in a collagen gel. Then, RAW264.7 cells were inoculated onto the gel and treated with GST-RANKL (Fig. 3A). As shown in Fig. 3B, fluorescent signals of GFP were detected in the MLO-Y4 cells, suggesting that Ccn2 expression plasmid together with pmax GFP vector had successfully entered the MLO-Y4 cells. To support these data, we analyzed the CCN2 protein and found that production of CCN2 was further increased in the cells with Ccn2 expression vector than in those with the empty vector. Under these conditions, NFATc1 production was also significantly increased (Fig. 3C,D). In addition, the expression levels of osteoclast differentiation marker genes, Trap and Cathepsin K (Ctsk), were significantly up-regulated in RAW264.7 cells seeded on the gel containing MLO-Y4 cells overexpressing CCN2; but Dendritic cell-specific transmembrane protein (Dc-stamp) expression was unaffected (Fig. 3E). These results suggest that CCN2 produced by MLO-Y4 cells promoted the osteoclast formation from RAW264.7 cells.
Isolation of osteocyte-enriched cell population from the femur of tamoxifen-inducible Ccn2- deficient mice
Next, to investigate the effect of CCN2 loss of function on osteocyte functions, we firstly digested murine femur enzymatically according to a previous report25. Briefly, we isolated osteocyte-enriched fractions from bone marrow-removed long bone by serial digestion with collagenase and decalcification by ethylenediaminetetraacetic acid (EDTA). During fractionation, we collected and pooled the late fractions (Fr5-8). As shown in Fig. 4A, gene expression of osteocyte-markers, such as Dmp1 and Cx43, was up-regulated significantly in the cells from Fr7/8 compared with that for the cells from Fr5/6; and Sost and Fgf23 gene expression levels tended to be increased in Fr7/8 as well. Based on these results, we used the cells from Fr7/8 as the osteocyte-enriched population to carry out all subsequent studies. Of note, expression of Ccn2 in those cells was confirmed for the first time (Fig. 4B). Next, to investigate the effect of Ccn2 deficiency on osteocyte functions, we used osteocytes from tamoxifen-inducible Ccn2-deficient mice. Tamoxifen-inducible Ccn2-deficient mice were generated by crossing Ccn2flox/flox mice with CAG-CreEsr1 mice as described in “Methods”. PCR analysis using genomic DNA showed efficient deletion of Ccn2 in the tail of CAG-CreEsr1;Ccn2flox/flox mice 1 month after injection with tamoxifen (Fig. S2A,B). Efficiency of Ccn2 depletion in the osteocyte-enriched cell population of CAG-CreEsr1;Ccn2flox/flox mice was approximately 80% (Fig. 4B, d) and osteocytic marker genes, such as Dmp1, and Cx43, were significantly repressed (Fig. 4B, a and c). Sost gene expression was unaffected (Fig. 4B, b). Although CAG-CreEsr1;Ccn2flox/flox mice grew normally in appearance20,21 and exhibited no obvious skeletal abnormalities, these results suggest that osteocyte functions may have been impaired in these mice.
Impaired osteoclastogenesis by Ccn2-deficient osteocyte-enriched population
We next used the osteocyte-enriched population of cells from the femur of CAG-CreEsr1;Ccn2flox/flox mice and examined whether or not these cells would modify the osteoclastogenesis of RAW264.7 cells treated with GST-RANKL. As shown in Fig. 5A, the Ccn2-deficient osteocyte-enriched population of cells was embedded into collagen gel, and RAW264.7 cells were then seeded onto the gel. Cell projections showed no difference between control and Ccn2-deficient cells in the gel (Fig. S3A,B). However, both NFATc1 and CTSK production levels were decreased in RANKL-stimulated RAW264.7 cells on the gel containing the Ccn2-deficient osteocytes (Fig. 5B,C). These findings indicate that CCN2 produced by osteocytes modified osteoclastogenesis, but had no effect on the morphology of the cells in osteocyte-enriched population. Because we previously showed that CCN2 produced by osteoclast progenitor cells also plays an important role in osteoclastogenesis13, we next compared the production of NFATc1 and CTSK in the presence of CCN2 produced by the osteoclast progenitor cells or by osteocytes. As shown in Fig. 6A, we isolated bone marrow (BM) cells from the femur of Ccn2flox/flox (wild-type; WT) or CAG-CreEsr1;Ccn2flox/flox (KO) mice 6 months after injection with tamoxifen (7 months old), and inoculated BM cells stimulated by macrophage colony-stimulating factor (M-CSF) onto the collagen gel containing the osteocyte-enriched population of the cells isolated from the same mice. Cell projections in the osteocyte-enriched population from WT and KO cells in the collagen gel showed no difference (Fig. S3C,D). Under these conditions, we performed Western blot analysis using anti-NFATc1 and CTSK antibodies. As shown in Fig. 6B,C, the production levels of NFATc1 and CTSK in the osteocyte-enriched population of cells from WT mice were higher than those for KO mice, regardless of the source of BM cells. These findings suggest that CCN2 derived from osteocytes played a more important role in osteoclastogenesis than CCN2 from osteoclast progenitor cells. Finally, to examine if CCN2 is expressed in osteocytes in vivo, we performed immunofluorescence staining of WT mice at 7-months old by using an anti-CCN2 antibody. As shown in Fig. 6D, CCN2 was produced in osteocytes around bone surface (arrows) and osteoblasts on bone surface (arrowheads). However, CCN2 was not detected in cortical bone from aged mice (Fig. S4). These results confirm that CCN2 is expressed in young and activated osteocytes.
Promotion of CTSK production by Ccn2-deficient osteocyte-enriched population of cells from aged mice
To examine the effect of aging on the observed findings, we isolated osteocyte-enriched population of cells and BM cells from WT or KO mice 1 year after injection with tamoxifen (13 months-old), and constructed 3-D cultures of the osteocyte-enriched population of cells with the BM cells (Fig. 6A). As a result, the morphology was similar between aged WT and KO osteocytes (Fig. S3E,F). The decrease in protein levels of NFATc1 and CTSK in BMCs caused by young Ccn2-deficient osteocytes 6 months after the tamoxifen injection (Fig. 6B,C) was not observed anymore in osteocytes from KO mice 1 year after injection (Fig. 7B,C), suggesting a decrease in CCN2 production by osteocytes in aged mice. Interestingly, CTSK production was rather increased by the combination of the KO osteocyte-enriched population and KO BM cells, although NFATc1 production showed no difference between the two (Fig. 7B,C).
MLO-Y4 cells promoted osteoblast differentiation in 3-D cultures with rCCN2
Finally, we investigated the effect of MLO-Y4 cells embedded into collagen gel with rCCN2 on osteoblast differentiation from a murine osteoblastic cell line MC3T3-E1. As shown in Fig. 8A, we inoculated MC3T3-E1 cells on the gel containing MLO-Y4 cells with rCCN2 at the concentration of 300 ng/ml. In addition, to test the effect of MLO-Y4 cells embedded into the gel with rCCN2, we also inoculated MC3T3-E1 cells on the gel having no MLO-Y4 cells. After 24 h, total RNA was isolated; and real-time PCR analysis was performed by using specific primers for osteoblast differentiation markers, such as Alkaline phosphatase (Alp), runt-related transcription factor 2 (Runx2) and Osterix (Table S1). The gene expressions of Alp (a), Runx2 (b) and Osterix (c) were significantly up-regulated in the combination of MC3T3-E1 cells and MLO-Y4 cells embedded into collagen gel with rCCN2 (Fig. 8B; upper panel, a–c). On the other hand, these levels showed no difference in MC3T3-E1 cells seeded on the gel without MLO-Y4 cells (Fig. 8B; lower panel, d–f). These results indicate that CCN2 modified osteoblast differentiation and that the effect was more pronounced in the presence of osteocytes, suggesting that CCN2-stimulated osteocytes further promoted osteoblast differentiation.
Discussion
We previously reported that CCN2 was strongly expressed in pre-hypertrophic chondrocytes of growth plate and that it promoted chondrocyte proliferation and differentiation15,26, osteoblast differentiation12,15,23, and osteoclast formation13,15. In addition, an in vivo study revealed that conventional Ccn2-deficient mice suffered neonatal death due to respiratory failure as a result of abnormal rib cage development during embryonic stages18. These findings suggest that CCN2 is a critical growth factor that dynamically regulates skeletogenic processes, such as endochondral ossification, during development15. On the other hand, the expression level of CCN2 is very low during the adult stage27; and its physiological roles at that time remained unknown. To clarify the roles of CCN2 during the adult stage, in this study we used CAG-CreEsr1;Ccn2flox/flox mice, in which the Ccn2 gene in the whole body could be knocked down by injection with tamoxifen after birth20,21. The mice that received tamoxifen injection starting at 1 month of age displayed no obvious skeletal abnormalities by 6 months or 1 year after the injection with tamoxifen, although their weight was reduced compared with that of the control mice 1 year after the injection with tamoxifen (Fig. S2C). However, a preliminary histological analysis has shown that bone mass tended to be decreased in secondary ossification centers of CAG-CreEsr1;Ccn2flox/flox mice tibiae (Fig. S2D), suggesting that CCN2 is somehow involved in bone remodeling, although further investigation needs to be carried out to confirm these findings. Apart from such preliminary data, we suspect that CCN2 locally induced during tissue regeneration, such as during bone or cartilage wound healing, plays major roles in such tissue regeneration, based on previous results28,29. Furthermore, it is reported that the CCN2 gene expression level is increased in the trabecular bone of the human lumbar spine, which is always exposed to mechanical loadings, compared with that in trabecular bone of the human iliac crest, where no mechanical loading occurs30. Because there are common biological processes between bone remodeling and bone regeneration, these findings together suggest that CCN2 induced by mechanical loading has an important role in bone remodeling, even in adult tissues.
Because it is well-known fact that osteocytes sense mechanical stresses loaded onto bone tissues3,4, we considered that investigating the roles of CCN2 in bone tissue might lead to elucidation of the molecular mechanism of bone remodeling regulated by osteocytes. Since adequate bone remodeling is performed under the balance of bone formation and bone resorption1,2, we firstly investigated how CCN2 present with osteocytes affected osteoclast formation. We believe that our 3-D culture system of MLO-Y4 cells and osteocyte-enriched cell population in collagen gel is biologically similar to the environment of bone tissues in vivo, because these cells extend cell projections that connect the neighboring cells therein (Figs 1B and 3B)5. Therefore, 3-D cultures of MLO-Y4 cells in collagen gel containing rCCN2 were prepared; and RAW264.7 cells were inoculated onto it. As a result, MLO-Y4 cells embedded in the rCCN2 containing gel promoted osteoclastogenesis of RAW264.7 cells on the gel (Fig. 2C,D). It is reported that integrin αvβ3 attaches between cell processes and the extracellular matrix (ECM)31. Since it is well-known that CCN2 interacts with integrin αvβ314, CCN2 may act through its binding to integrin αvβ3 on MLO-Y4 cells embedded in collagen gel. Additionally, we showed that Ccn2 gene was significantly up-regulated in MLO-Y4 cells by rCCN2 in the collagen gel (Fig. 1C; a). This result indicates that Ccn2 in MLO-Y4 cells is regulated in an autocrine manner by the rCCN2 in the gel, probably through the integrin signaling. Moreover, to clarify the roles of CCN2 in osteocyte functions more directly, we isolated the osteocyte-enriched population of cells from tamoxifen-inducible Ccn2-deficient mice 6 months after injection with tamoxifen and prepared 3-D cultures in the collagen gel. BM cells, which were isolated from the bone marrow of the same mice, were treated with M-CSF. Then, M-CSF-treated BM cells were inoculated onto the gel and treated with RANKL. As shown in Fig. 6B,C, osteoclastogenesis was impaired in cultures of cells in the Ccn2-deficient osteocyte-enriched population, even if BMCs were from either WT or KO mice. These results suggest that CCN2 from osteocytes promoted osteoclastogenesis. It was reported that osteocytes regulate bone resorption via RANKL and OPG production32,33. As shown in Fig. 1C–E, when MLO-Y4 cells were stimulated by rCCN2, the gene expression and protein production of OPG were significantly decreased. Therefore, we suspected that OPG expression was increased by the deletion of CCN2 in osteocytes. However, when we investigated the gene expression levels of RANKL and OPG in the osteocyte-enriched population derived from WT and KO mice, these gene expression levels showed no difference between the 2 sources (Fig. S5). Taken together, these results suggest that the effect of osteocyte-produced CCN2 on osteoclast formation was not mediated via RANKL and OPG productions, but was directly conferred by CCN2.
The reductions in protein levels of NFATc1 and CTSK in BM cells caused by osteocytes derived from KO mice 6 months after injection with tamoxifen (Fig. 6B,C) were observed like in the case of osteocytes derived from KO mice 1 month after the injection (Fig. 5B,C), but the reduction was not observed in osteocytes from KO mice 1 year after the injection (Fig. 7B,C). In other words, the stimulatory effects of osteocyte-derived CCN2 on NFATc1 and CTSK protein levels in BM cells were observed in 2- and 7-month-old mice (Figs 5B,C and 6B,C), but the effect was not observed in 13 months-old mice (Fig. 7B,C). In general, transmission electron micrographs of osteocytes show that young osteocytes, which are located around the bone surface, have a large Golgi apparatus, prominent rough endoplasmic reticulum, and numerous cytoplasmic processes projecting into the surrounding matrix, whereas mature osteocytes, which are located in the deep of bone matrix, are characterized by increased lacunar volume, an electron-dense lacunar surface, condensed nuclei, and numerous cytoplasmic vacuoles6. These morphological characteristics suggest that mature osteocytes undergo a decrease in their protein production and release, compared with young osteocytes. Furthermore, it is noteworthy that expression and production of CCN2 are higher in younger cells/tissues than in older cells/tissues14,15,16. Our data of immunofluorescence was also similar to these findings (Figs 6D and S4). Therefore, it is feasible that the release of CCN2 from osteocytes in aged mice would be decreased, resulting in decreased osteoclastogenesis regulated by osteocytes.
It was previously reported that CCN2 is up-regulated by excess mechanical stress in osteocytes and that mechanical stress-produced CCN2 induces osteocyte apoptosis34. Based on this finding, we consider that, when mechanical force is applied to mature osteocytes derived from aged mice, CCN2 is up-regulated in the cells, but CCN2 is not secreted due to decreased number of cell processes that contact osteoblasts and osteoclasts on the bone surface. As a result, CCN2 is accumulated into the mature osteocyte, and apoptosis pathways may thereby be activated. In fact, our preliminary data showed that the number of terminal deoxynucleotidyl transferase dUTP nick end labeling (TUNEL)-positive osteocytes was increased in cortical bone tissues of WT mice, compared with that of KO mice 1 year after injection with tamoxifen (Fig. S6). Moreover, it has been discussed that osteocyte apoptosis plays an important role in the maintenance of bone homeostasis3,34,35. However, since we used only lively osteocytes in this study, it is unknown whether apoptotic osteocytes have no/less osteoclastogenic activity. It is also unknown why the CTSK protein level in BM cells stimulated by Ccn2-deficient osteocytes derived from aged mice was higher than that produced by WT-osteocytes, but some other factors stimulating CTSK production might be released from Ccn2-deficient osteocytes in aged mice. So further investigations are needed to reveal the mechanism underlying these phenomena.
Finally, we investigated the effect of CCN2 from osteocytes on osteoblast differentiation. We cultured MLO-Y4 cells embedded into collagen gel including rCCN2 and inoculated MC3T3-E1 cells onto the gel (Fig. 8A). The gene expression levels of osteoblastic differentiation markers in MC3T3-E1 cells were up-regulated by MLO-Y4 cells embedded into collagen gel with rCCN2 (Fig. 8B). These findings suggest that osteocytes stimulated by CCN2 in the gel promoted not only osteoclastogenesis, but also osteoblast differentiation, leading to the total enhancement of bone remodeling (Fig. S7)36,37.
In summary, when young osteocytes, which are localized around the bone surface, are subjected to mechanical stresses, they produce and secrete CCN2 via numerous cell projections and promote both neighboring osteoclast formation and osteoblast differentiation; hence bone remodeling is promoted by CCN2 from osteocytes. On the other hand, CCN2 from mature osteocytes, which are located deep in the bone matrix, is also up-regulated by mechanical stresses; and this CCN2 accumulates in the cells due to decreased cell projections, resulting in osteocyte death, probably by apoptosis. As a result, bone remodeling turnover may be controlled (Fig. S7). However, to firmly confirm this hypothesis, further investigation is still needed.
Methods
Materials
Alpha-modification of Eagle’s medium (αMEM), fetal bovine serum (FBS), and calf serum (CF) were purchased from MP Biomedicals, LLC (Solon, OH); and fetal bovine serum (FBS) and calf serum (CS) were obtained from Equitech-Bio, Inc. (Kierrville, TX). Plastic dishes and multi-well plates were obtained from Greiner Bio-One (Frickenhausen, Germany). Type I collagen solution (Cellmatrix type I-C and I-A) was purchased from Nitta Gelatin Co. Ltd. (Osaka, Japan). Mirimostim, also known as human macrophage-colony stimulating factor (M-CSF), was obtained from Kyowa Hakko Kirin Co., Ltd. (Tokyo, Japan). Anti-NFATc1 and anti-cathepsin K antibodies were purchased from Santa Cruz Biotechnology (Santa Cruz, CA); anti-CCN2 and anti-glyceraldehyde-3-phosphate dehydrogenase (GAPDH), from Abcam (Cambridge, UK); and anti-β-actin from Sigma (St. Louis, MO). Anti-OPG antibody was from R & D Systems Inc. (Minneapolis, MN). GST-RANKL13 and rCCN238 were prepared as previously described. Ccn2 expression vector was generated as previously described39, and Sox9 expression vector containing 3 × HA tag was kindly provided by Dr. T. Hattori40,41.
Ccn2-conditonal knockout mice and isolation of osteocyte-rich fractions
Tamoxifen-inducible Ccn2 conditional knockout mice (CAG-CreEsr1;Ccn2flox/flox) were generated by mating Ccn2flox/flox mice20,21, and CAG-CreEsr1 transgenic mice. The structure of targeting vector for the generation of Ccn2flox/flox mice is shown in Fig. S2A. B6. Cg-Tg(CAG-cre/Esr1)5Amc/J mice (CAG-CreEsr1 transgenic mice) were purchased from the Jackson Laboratory (Bar Harbor, ME)42. These transgenic mice express Cre recombinase gene under the control of CAG promoter and the recombination occurs in all over the body42. In these transgenic mice, the mutant mouse estrogen receptor fused to Cre recombinase does not bind to estrogen at physiological concentrations, but binds to the synthetic ligand, tamoxifen (Sigma), leading to its nuclear translocation. Therefore, to systemically delete Ccn2 gene from CAG-CreEsr1;Ccn2flox/flox mice, we injected these mice (1-month-old; females) intraperitoneally with tamoxifen dissolved in sunflower oil (30 mg/ml) given at a dose of 0.15 mg/g body weight at a frequency of once a day for 3 days. Ccn2flox/flox littermates were used as controls. These mice were housed in cages with paper-chip bedding under specific pathogen-free conditions with an inverted 12-h light/12-h dark cycle in a humidity-temperature controlled environment, and were provided standard diet and water ad libitum. The animals were maintained in accordance with Fundamental Guidelines for Proper Conduct of Animal Experiment and Related Activities in Academic Research Institutions. An osteocyte-enriched cell population was isolated according to a previous report25. Briefly, to isolate the osteocyte-enriched population, 1 month, 6 months or 1 year after the injection with tamoxifen, the mice were euthanized and femurs were isolated from the tamoxifen-treated and control mice. Then, the muscles and periosteum were mechanically removed by using a scalpel. After the bone marrow had been flushed out with serum-free αMEM, the bones were cut into small pieces and treated for 20 min with 0.2% collagenase. The supernatant was aspirated as fraction 1 (Fr1) and the bone pieces were then treated for 20 min with 5 mM EDTA and the solution was aspirated (fraction 2; Fr2). This was repeated and cells released into fraction 5 (Fr5) to 8 (Fr8) were collected; and cells in Fr5 and Fr6 were combined into a single sample, as were those in Fr7 and Fr8, and then these cells were cultured on collagen-coated plates in αMEM supplemented with both 5% FBS and 5% CS for several days. All animal experiment protocols (OKU-2017360, OKU-2017157) were approved by the Animal Care and Use Committee, Okayama University.
Cell cultures
Mouse osteocytic cell line MLO-Y4 was kindly donated by Dr. Lynda F. Bonewald (Indiana University)22, and these cells were inoculated at a density of 1 × 104/cm2 and cultured on dishes or multi-well plates coated with Cellmatrix type I-C (Nitta Gelatin; Osaka, Japan) in αMEM supplemented with 5% FBS and 5% CS. The murine macrophage-like cell line RAW264.7 (which can be induced to form osteoclast-like cells) and osteoblastic cell line MC3T3-E1 were routinely cultured in αMEM supplemented with 10% FBS in an incubator at 37 °C with an atmosphere of 5% CO2 in humidified air.
Three-dimensional culture system
A 3-D culture system was constructed by mixing equal volumes of type I collagen solution (Cellmatrix type I-A; Nitta Gelatin) and 2 × αMEM with 5% FBS and 5% CS, adding the desired numbers of MLO-Y4 cells or cells of a mouse osteocyte-rich cell population with or without CCN2, and pouring the mixture into each well of multi-well plates5. Then, the solution was allowed to gel at 37 °C for 20 min; and the gel cultures were placed in an incubator with humidified air at 37 °C, 5% CO2 in αMEM supplemented with 10% FBS. After incubation for 1–2 days, RAW264.7 or MC3T3-E1 cells were inoculated onto the gel to investigate osteoclastogenesis or osteoblast differentiation, respectively. In some experiments, 3-D cultures were prepared without the RAW264.7 or MC3T3-E1 cells to detect osteocyte functions.
Western blot analysis
After 3-D cultivation of osteocytes, culture medium was removed and the collagen gels were digested by 1% collagenase at 37 °C for 30 min. Then, the cells pelleted by centrifugation were lysed by cell lysis buffer (20 mM Tris-HCl pH 7.7, 150 mM NaCl, 1 mM EDTA, 1% Triton X-100); and thereafter Western blot analysis was performed as described previously43.
Phalloidin staining
After cultivation, the cells embedded into collagen gel were fixed with 3.7% paraformaldehyde for 1 h at room temperature and made permeable with 0.1% NP-40 in PBS. The cells were then incubated with fluorescein phalloidin (Cytoskeleton, Inc., Denver, Co.), which was prepared according to the manufacturer’s directions11. Phalloidin labeling was performed for 1 h at room temperature. After having been washed with PBS 3 times, the cells were observed under a fluorescence microscope.
Real-time RT-PCR analysis
Total RNA was isolated from MLO-Y4 and osteocyte-rich cell population by using ISOGEN reagent (Nippon Gene, Tokyo, Japan). First-strand cDNA was synthesized with a primerScriptTM reverse transcriptase (RT) reagent kit (Takara Shuzo, Tokyo, Japan), and amplification reactions were performed by using a SYBR® Green Real-time PCR Master Mix (Toyobo, Tokyo, Japan) or Luna, universal qPCR master mix (New England Biolabs Inc., Ipswich, MA) and StepOne plus real-time PCR system (Applied Biosystems, Carlsbad, CA), as described previously11,43. The nucleotide sequences of the primers and expected sizes of the amplicons are shown in Table S1.
Osteoclastogenesis
Osteoclastogenesis of RAW264.7 cells or bone marrow (BM) cells on the collagen gel was evaluated based on the production of NFATc1 and cathepsin K, as well as TRAP staining. Briefly, RAW264.7 cells were inoculated at a density of 1 × 104/cm2 onto the collagen gel in wells of 12-well plates and incubated in the presence or absence of GST-RANKL at the concentration of 100 ng/ml for 2 days11. BMCs were obtained as described previously13,44 and cultured in a 5% CO2 air at 37 °C in αMEM supplemented with 10% FBS and 50 ng/ml mirimostim (M-CSF) for 3 days13,44. Then, the attached cells were collected and inoculated at a density of 7.5 × 104/cm2 onto the collagen gel in wells of 24-well plate. Until typical multinucleate cells appeared, the cells were treated with GST-RANKL at the concentration of 100 ng/ml.
Overexpression of CCN2 or Sox9 by electroporation in MLO-Y4 cells
After MLO-Y4 cells had reached confluence, they were collected with 0.05% trypsin-EDTA. The cells were then re-suspended in Nucleofector solution containing both 2 μg CCN2 expression vector39 or Sox9 expression vector containing 3 × HA tag40,41 and pmax GFP vector or both negative control vector (empty vector; EV) and pmax GFP vector. Electroporation was performed by using an AmaxaTM mouse dendritic cell NucleofectorTM kit and Amaxa NucleofectorTM II device (Lonza Cologne GmbH, Cologne, Germany) according to the manufacturer’s instructions11.
Indirect immunofluorescence analysis
Femurs of wild-type mice at 7-months and 13-months old were dissected and fixed in 10% formalin overnight at 4 °C. Next, the tissues were decalcified with 10% EDTA for 3 weeks and subsequently embedded in paraffin. Cortical bone sections were prepared and deparaffinized, and treated with hyaluronidase (25 mg/ml) for 30 min at room temperature for epitope retrieval. Then, these sections were made permeable with 0.1% NP-40 in PBS. Indirect immunofluorescence analysis was performed by using an anti-CCN2 antibody as described previously45. Finally, the sections were stained with 4’6-diamidino-2-phenylindole (DAPI) to detect the nucleus. Sections stained without primary antibody were used as negative controls, which showed no detectable signals.
Statistical analysis
Unless otherwise specified, all experiments were repeated at least twice, and similar results were obtained. Statistical analysis for 2 group-comparison was performed by using Student′s t-test, and statistical analysis for multi-group comparisons was performed by performing Bonferroni’s test. All data were presented as the mean and standard deviation. All methods were performed in accordance with the guidelines and regulations of Scientific Reports.
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Acknowledgements
We thank Dr. Lynda F. Bonewald provided MLO-Y4 cells with valuable instruction. Drs Takako Hattori and Kazumi Kawata for their technical assistance and helpful suggestions. Miss Yoshiko Miyake is also gratefully acknowledged for her secretarial assistance. This work was supported in part by KAKENHI grants from the programs Grants-in-Aid for Scientific Research (C) to T.N. (#JP26462810, #JP17K11641) and (B) to M.T. (#JP24390415, #JP15H05014, #JP19H03817), and for Challenging Exploratory Research to SK (#JP17K19756) and MT (#JP17K19757) from Japan Society for the Promotion of Sciences, Japan.
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T.N. participated in the study design, performed all of the experiments, and drafted the manuscript and all figures. S.K. designed and coordinated the study and helped to draft the manuscript. H.Y. generated Ccn2flox/flox mice. M.M. generated Ccn2flox/flox mice. M.T. participated in the study design and helped to draft the manuscript.
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Nishida, T., Kubota, S., Yokoi, H. et al. Roles of matricellular CCN2 deposited by osteocytes in osteoclastogenesis and osteoblast differentiation. Sci Rep 9, 10913 (2019). https://doi.org/10.1038/s41598-019-47285-3
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DOI: https://doi.org/10.1038/s41598-019-47285-3
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