A calpain-6/YAP axis in sarcoma stem cells that drives the outgrowth of tumors and metastases.

Sarcomas include cancer stem cells, but how these cells contribute to local and metastatic relapse is largely unknown. We previously showed the pro-tumor functions of calpain-6 in sarcoma stem cells. Here, we use an osteosarcoma cell model, osteosarcoma tissues and transcriptomic data from human tumors to study gene patterns associated with calpain-6 expression or suppression. Calpain-6 modulates the expression of Hippo pathway genes and stabilizes the hippo effector YAP. It also modulates the vesicular trafficking of ß-catenin degradation complexes. Calpain-6 expression is associated with genes of the G2M phase of the cell cycle, supports G2M-related YAP activities and up-regulated genes controlling mitosis in sarcoma stem cells and tissues. In mouse models of bone sarcoma, most tumor cells expressed calpain-6 during the early steps of tumor out-growth. YAP inhibition prevented the neoformation of primary tumors and metastases but had no effect on already developed tumors. It could even accelerate lung metastasis associated with large bone tumors by affecting tumor-associated inflammation in the host tissues. Our results highlight a specific mechanism involving YAP transcriptional activity in cancer stem cells that is crucial during the early steps of tumor and metastasis outgrowth and that could be targeted to prevent sarcoma relapse.

Metastatic Progression of Osteosarcomas: A Review of Current Knowledge of Environmental versus Oncogenic Drivers.

Metastases of osteosarcomas are heterogeneous. They may grow simultaneously with the primary tumor, during treatment or shortly after, or a long time after the end of the treatment. They occur mainly in lungs but also in bone and various soft tissues. They can have the same histology as the primary tumor or show a shift towards a different differentiation path. However, the metastatic capacities of osteosarcoma cells can be predicted by gene and microRNA signatures. Despite the identification of numerous metastasis-promoting/predicting factors, there is no efficient therapeutic strategy to reduce the number of patients developing a metastatic disease or to cure these metastatic patients, except surgery. Indeed, these patients are generally resistant to the classical chemo- and to immuno-therapy. Hence, the knowledge of specific mechanisms should be extended to reveal novel therapeutic approaches. Recent studies that used DNA and RNA sequencing technologies highlighted complex relations between primary and secondary tumors. The reported results also supported a hierarchical organization of the tumor cell clones, suggesting that cancer stem cells are involved. Because of their chemoresistance, their plasticity, and their ability to modulate the immune environment, the osteosarcoma stem cells could be important players in the metastatic process.

Calpain-6 controls the fate of sarcoma stem cells by promoting autophagy and preventing senescence.

Sarcomas are still unsolved therapeutic challenges. Cancer stem cells are believed to contribute to sarcoma development, but lack of specific markers prevents their characterization and targeting. Here, we show that calpain-6 expression is associated with cancer stem cell features. In mouse models of bone sarcoma, calpain-6-expressing cells have unique tumor-initiating and metastatic capacities. Calpain-6 levels are especially high in tumors that have been successfully propagated in mouse to establish patient-derived xenografts. We found that calpain-6 levels are increased by hypoxia in vitro and calpain-6 is detected within hypoxic areas in tumors. Furthermore, calpain-6 expression depends on the stem cell transcription network that involves Oct4, Nanog, and Sox2 and is activated by hypoxia. Calpain-6 knockdown blocks tumor development in mouse and induces depletion of the cancer stem cell population. Data from transcriptomic analyses reveal that calpain-6 expression in sarcomas inversely correlates with senescence markers. Calpain-6 knockdown suppresses hypoxia-dependent prevention of senescence entry and also promotion of autophagic flux. Together, our results demonstrate that calpain-6 identifies sarcoma cells with stem-like properties and is a mediator of hypoxia to prevent senescence, promote autophagy, and maintain the tumor-initiating cell population. These findings open what we believe is a novel therapeutic avenue for targeting sarcoma stem cells.

Correction: Osteoblastic heparan sulfate glycosaminoglycans control bone remodeling by regulating Wnt signaling and the crosstalk between bone surface and marrow cells.

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Osteoblastic heparan sulfate glycosaminoglycans control bone remodeling by regulating Wnt signaling and the crosstalk between bone surface and marrow cells.

Stimulating bone formation is an important challenge for bone anabolism in osteoporotic patients or to repair bone defects. The osteogenic properties of matrix glycosaminoglycans (GAGs) have been explored; however, the functions of GAGs at the surface of bone-forming cells are less documented. Syndecan-2 is a membrane heparan sulfate proteoglycan that is associated with osteoblastic differentiation. We used a transgenic mouse model with high syndecan-2 expression in osteoblasts to enrich the bone surface with cellular GAGs. Bone mass was increased in these transgenic mice. Syndecan-2 overexpression reduced the expression of receptor activator of NF-kB ligand (RANKL) in bone marrow cells and strongly inhibited bone resorption. Osteoblast activity was not modified in the transgenic mice, but bone formation was decreased in 4-month-old transgenic mice because of reduced osteoblast number. Increased proteoglycan expression at the bone surface resulted in decreased osteoblastic and osteoclastic precursors in bone marrow. Indeed, syndecan-2 overexpression increased apoptosis of mesenchymal precursors within the bone marrow. However, syndecan-2 specifically promoted the vasculature characterized by high expression of CD31 and Endomucin in 6-week-old transgenic mice, but this was reduced in 12-week-old transgenic mice. Finally, syndecan-2 functions as an inhibitor of Wnt-ß-catenin-T-cell factor signaling pathway, activating glycogen synthase kinase 3 and then decreasing the Wnt-dependent production of Wnt ligands and R-spondin. In conclusion, our results show that GAG supply may improve osteogenesis, but also interfere with the crosstalk between the bone surface and marrow cells, altering the supporting function of osteoblasts.

Interaction of HIF1α and ß-catenin inhibits matrix metalloproteinase 13 expression and prevents cartilage damage in mice.

Low oxygen tension (hypoxia) regulates chondrocyte differentiation and metabolism. Hypoxia-inducible factor 1α (HIF1α) is a crucial hypoxic factor for chondrocyte growth and survival during development. The major metalloproteinase matrix metalloproteinase 13 (MMP13) is also associated with chondrocyte hypertrophy in adult articular cartilage, the lack of which protects from cartilage degradation and osteoarthritis (OA) in mice. MMP13 is up-regulated by the Wnt/ß-catenin signaling, a pathway involved in chondrocyte catabolism and OA. We studied the role of HIF1α in regulating Wnt signaling in cartilage and OA. We used mice with conditional knockout of Hif1α (∆Hif1α(chon)) with joint instability. Specific loss of HIF1α exacerbated MMP13 expression and cartilage destruction. Analysis of Wnt signaling in hypoxic chondrocytes showed that HIF1α lowered transcription factor 4 (TCF4)-ß-catenin transcriptional activity and inhibited MMP13 expression. Indeed, HIF1α interacting with ß-catenin displaced TCF4 from MMP13 regulatory sequences. Finally, ΔHif1α(chon) mice with OA that were injected intraarticularly with PKF118-310, an inhibitor of TCF4-ß-catenin interaction, showed less cartilage degradation and reduced MMP13 expression in cartilage. Therefore, HIF1α-ß-catenin interaction is a negative regulator of Wnt signaling and MMP13 transcription, thus reducing catabolism in OA. Our study contributes to the understanding of the role of HIF1α in OA and highlights the HIF1α-ß-catenin interaction, thus providing new insights into the impact of hypoxia in articular cartilage.

Increased NF-κB Activity and Decreased Wnt/ß-Catenin Signaling Mediate Reduced Osteoblast Differentiation and Function in ΔF508 Cystic Fibrosis Transmembrane Conductance Regulator (CFTR) Mice.

The prevalent human ΔF508 mutation in the cystic fibrosis transmembrane conductance regulator (CFTR) is associated with reduced bone formation and bone loss in mice. The molecular mechanisms by which the ΔF508-CFTR mutation causes alterations in bone formation are poorly known. In this study, we analyzed the osteoblast phenotype in ΔF508-CFTR mice and characterized the signaling mechanisms underlying this phenotype. Ex vivo studies showed that the ΔF508-CFTR mutation negatively impacted the differentiation of bone marrow stromal cells into osteoblasts and the activity of osteoblasts, demonstrating that the ΔF508-CFTR mutation alters both osteoblast differentiation and function. Treatment with a CFTR corrector rescued the abnormal collagen gene expression in ΔF508-CFTR osteoblasts. Mechanistic analysis revealed that NF-κB signaling and transcriptional activity were increased in mutant osteoblasts. Functional studies showed that the activation of NF-κB transcriptional activity in mutant osteoblasts resulted in increased ß-catenin phosphorylation, reduced osteoblast ß-catenin expression, and altered expression of Wnt/ß-catenin target genes. Pharmacological inhibition of NF-κB activity or activation of canonical Wnt signaling rescued Wnt target gene expression and corrected osteoblast differentiation and function in bone marrow stromal cells and osteoblasts from ΔF508-CFTR mice. Overall, the results show that the ΔF508-CFTR mutation impairs osteoblast differentiation and function as a result of overactive NF-κB and reduced Wnt/ß-catenin signaling. Moreover, the data indicate that pharmacological inhibition of NF-κB or activation of Wnt/ß-catenin signaling can rescue the abnormal osteoblast differentiation and function induced by the prevalent ΔF508-CFTR mutation, suggesting novel therapeutic strategies to correct the osteoblast dysfunctions in cystic fibrosis.

Role of syndecan-2 in osteoblast biology and pathology.

Syndecans 1-4 are a family of transmembrane proteins composed of a core protein and glycosaminoglycan chains. Although the four syndecans have common functions, they appear to be connected to different signaling pathways, and their expression occurs in a cell- and development-specific pattern. In contrast to other syndecans, syndecan-2 expression increases during osteoblast differentiation. Mechanistically, syndecan-2 exerts multiple functions in cells of the osteoblast lineage as it serves as a co-receptor for fibroblast growth factors and Wnt proteins and controls cell adhesion, proliferation, differentiation and apoptosis. Recent studies indicate that syndecan-2 also contributes to osteosarcoma cell response to cytotoxic agents through interactions with Wnt/ß-catenin signaling. Here we summarize our current understanding of the role of syndecan-2 in the control of osteoblast biology and pathology and discuss how syndecan-2 acts as a modulator of the bone cell microenvironment.

Cadherin-mediated cell-cell adhesion and signaling in the skeleton.

Direct cell-to-cell interactions via cell adhesion molecules, in particular cadherins, are critical for morphogenesis, tissue architecture, and cell sorting and differentiation. Partially overlapping, yet distinct roles of N-cadherin (cadherin-2) and cadherin-11 in the skeletal system have emerged from mouse genetics and in vitro studies. Both cadherins are important for precursor commitment to the osteogenic lineage, and genetic ablation of Cdh2 and Cdh11 results in skeletal growth defects and impaired bone formation. While Cdh11 defines the osteogenic lineage, persistence of Cdh2 in osteoblasts in vivo actually inhibits their terminal differentiation and impairs bone formation. The action of cadherins involves both cell-cell adhesion and interference with intracellular signaling, and in particular the Wnt/ß-catenin pathway. Both cadherin-2 and cadherin-11 bind to ß-catenin, thus modulating its cytoplasmic pools and transcriptional activity. Recent data demonstrate that cadherin-2 also interferes with Lrp5/6 signaling by sequestering these receptors in inactive pools via axin binding. These data extend the biologic action of cadherins in bone forming cells, and provide novel mechanisms for development of therapeutic strategies aimed at enhancing bone formation.

ErbB3 silencing reduces osteosarcoma cell proliferation and tumor growth in vivo.

Osteosarcoma is the most common primary bone tumor in children and adults. Despite improved prognosis, resistance to chemotherapy remains responsible for failure of osteosarcoma treatment. The identification of the molecular signals that contribute to the aberrant osteosarcoma cell growth may provide clues to develop new therapeutic strategies for chemoresistant osteosarcoma. Here we show that the expression of ErbB3 is increased in human osteosarcoma cells in vitro. Tissue microarray analysis of tissue cores from osteosarcoma patients further showed that the ErbB3 protein expression is higher in bone tumors compared to normal bone tissue, and is further increased in patients with recurrent disease or soft tissue metastasis. In murine osteosarcoma cells, silencing ErbB3 using shRNA decreased cell replication, cell migration and invasion, indicating that ErbB3 contributes to tumor cell growth and invasiveness. Furthermore, ErbB3 silencing markedly reduced tumor growth in a murine allograft model in vivo. Immunohistochemal analysis showed that the reduced tumor growth induced by ErbB3 silencing in this model resulted from decreased cell osteosarcoma cell proliferation, supporting a role of ErbB3 in bone tumor growth in vivo. Taken together, the results reveal that ErbB3 expression in human osteosarcoma correlates with tumor grade. Furthermore, silencing ErbB3 in a murine osteosarcoma model results in decreased cell growth and invasiveness in vitro, and reduced tumor growth in vivo, which supports the potential therapeutic interest of targeting ErbB3 in osteosarcoma.

Targeted inhibition of T-cell factor activity promotes syndecan-2 expression and sensitization to doxorubicin in osteosarcoma cells and bone tumors in mice.

Alterations of Wnt signaling appear to be involved in the pathogenesis of osteosarcoma, presenting mutations of adenomatous polyposis coli (APC) and epigenetic downregulation of Wnt inhibitory factor 1. However, the precise role of Wnt effectors in the bone cancer progression remains unclear. We previously showed that Wnt/ß-catenin/T-cell factor (TCF) activation are responsible for the repression of syndecan-2, a key modulator of apoptosis and chemosensitivity in osteosarcoma cells, suggesting a role of Wnt signaling in chemoresistance. In this study, we investigated the functional relationship between syndecan-2, Wnt/ß-catenin/TCF signaling and chemosensitivity in these cells. To this goal, we selected resistant osteosarcoma cells from sensitive human cell lines using repeated exposures to doxorubicin. In doxorubicin-responsive but not in doxorubicin-resistant-derived cells syndecan-2 expression was upregulated by doxorubicin treatment. Moreover, syndecan-2 overexpression restored the sensitivity to doxorubicin in resistant-derived cells. We found that syndecan-2 induction by doxorubicin is forkhead box protein O3A (Foxo3a)-dependent. Foxo3a overexpression resulted in increased syndecan-2 expression in sensitive and resistant-derived cells. Doxorubicin modulated Foxo3a binding on syndecan-2 gene promoter and induced Foxo-dependent inhibition of Wnt/TCF activity. Conversely, ß-catenin/TCF activation impaired syndecan-2 induction by doxorubicin, indicating that Wnt signaling is competing with the action of the cytotoxic drug. However, ß-catenin was also found to be required for Foxo3a activity. Consistently, Dickkopf 1 (DKK1) and secreted frizzled-related protein 1 (sFRP-1) altered doxorubicin action in sensitive cells, whereas inhibition of TCF activity strongly decreased cell viability and increased sensitivity to doxorubicin in sensitive and resistant cells. TCF inhibition also increased the effect of doxorubicin treatment in an orthotopic bone tumor model in mice. Altogether, these data provide evidence that the repression of syndecan-2 by Wnt/ß-catenin/TCF signaling contributes to the resistance of osteosarcoma cells to doxorubicin and suggest that TCF inhibition may represent a novel therapeutic strategy in osteosarcoma.

Targeting the E3 ubiquitin casitas B-lineage lymphoma decreases osteosarcoma cell growth and survival and reduces tumorigenesis.

Targeting receptor tyrosine kinase (RTK) degradation may be an interesting approach to reduce RTK cell signaling in cancer cells. Here we show that increasing E3 ubiquitin ligase casitas B-lineage lymphoma (c-Cbl) expression using lentiviral infection decreased osteosarcoma cell replication and survival and reduced cell migration and invasion in murine and human osteosarcoma cells. Conversely, c-Cbl inhibition using short hairpin RNA (shRNA) increased osteosarcoma cell growth and survival, as well as invasion and migration, indicating that c-Cbl plays a critical role as a bone tumor suppressor. Importantly, the anticancer effect of increasing c-Cbl expression in osteosarcoma cells was related mainly to the downregulation of epidermal growth factor receptor (EGFR) and platelet-derived growth factor receptor alpha (PDGFRα). In a murine bone tumor model, increasing c-Cbl expression also reduced RTK expression, resulting in decreased tumor cell proliferation and survival and reduced tumor growth. Interestingly, increasing c-Cbl also markedly reduced lung metastasis in mice. Tissue microarray analysis revealed that low c-Cbl protein expression is associated with elevated EGFR and PDGFRα protein levels in human osteosarcoma with poor outcome. This study shows that increasing c-Cbl expression reduces osteosarcoma cell growth, survival, and metastasis in part through downregulation of RTKs, which supports the potential therapeutic interest of targeting c-Cbl in malignant bone diseases involving increased RTK.

Calpain-6 is an endothelin-1 signaling dependent protective factor in chemoresistant osteosarcoma.

Bone tumors strongly influence normal tissues and stimulate bone cells for the production of cytokines supporting proliferation and abnormal survival in cancer cells. We previously reported that the proteoglycan syndecan-2 controls the activity of various cytokines and growth factors and also modulates apoptosis and response to cytotoxic agents in osteosarcoma cell lines. Here, we show that syndecan-2 has a stronger tumor suppressor activity in vivo. We identify calpain-6 as a target gene downregulated by syndecan-2 in cells and in vivo. We demonstrate that calpain-6 expression in osteosarcoma cells depends on endothelin-1, a mediator of the tumor progression in bone. Syndecan-2 overexpression alters ERK1/2, PI3K/AKT and NFκB pathways that are calpain-6-promoting signals downstream of endothelin-1. Immunohistochemical analysis shows that calpain-6 is expressed in human bone tumors and metastases. A high expression of calpain-6 was specially found in recurrent osteosarcoma. Moreover, calpain-6 levels in primary tumors were inversely related to the response to chemotherapy. Consistently, calpain-6 was increased by doxorubicin and was found to be expressed at higher levels in doxorubicin-resistant U2OS osteosarcoma-derived cells as compared to responsive cells. Inhibition of calpain-6 with shRNA resulted in decreased proliferation, increased spontaneous apoptosis and increased sensitivity to doxorubicin and also methotrexate in responsive and resistant osteosarcoma cells. Taken together, our data show that syndecan-2 exerts its pro-apoptotic function through modulation of the endothelin-1/NFκB signaling and through downregulation of calpain-6, a protective factor that contributes to abnormal cell survival. Thus, this study identifies calpain-6 as a new possible therapeutic target in chemoresistant osteosarcoma.

High Wnt signaling represses the proapoptotic proteoglycan syndecan-2 in osteosarcoma cells.

Osteosarcoma is characterized by frequent relapse and metastatic disease associated with resistance to chemotherapy. We previously showed that syndecan-2 is a mediator of the antioncogenic effect of chemotherapeutic drugs. The purpose of this work was to elucidate molecular mechanisms responsible for the low expression of syndecan-2 in osteosarcoma. We compared the regulatory activity of cis-acting DNA sequences of the syndecan-2 gene in osteosarcoma and osteoblastic cell lines. We identified a DNA region that negatively regulates syndecan-2 transcription in the osteosarcoma cells. T-cell factors (TCF) bind to this sequence in vivo. Wnt3a stimulation, beta-catenin activation, and TCF overexpression resulted in syndecan-2 repression, whereas Wnt inhibition using sFRP-1 increased syndecan-2 expression in U2OS cells. RhoA activation blunted the stimulatory effect of sFRP-1 on syndecan-2 transcription, whereas RhoA inhibition enhanced syndecan-2 expression. These results indicate that Wnt/beta-catenin and Wnt/RhoA signaling contribute to syndecan-2 repression. The alteration of syndecan-2 expression in osteosarcoma cell lines also seemed to be related to a higher shedding, controlled by Wnt/RhoA. Conversely, syndecan-2 was found to activate its own expression in U2OS cells through RhoA inhibition. These data identify a molecular network that may contribute to the low expression of the proapoptotic proteoglycan syndecan-2 in osteosarcoma cells. The high activity of the canonical Wnt pathway in the different osteosarcoma cells induces a constitutive repression of syndecan-2 transcription, whereas Wnt/RhoA signaling blocks the amplification loop of syndecan-2 expression. Our results identify syndecan-2 as a Wnt target and bring new insights into a possible pathologic role of Wnt signaling in osteosarcoma.

Syndecan-2 affects the basal and chemotherapy-induced apoptosis in osteosarcoma.

Syndecans are transmembrane heparan sulfate proteoglycans controlling cell adhesion, migration, and proliferation. We previously showed that syndecan-2 is involved in the control of apoptosis in cultured osteosarcoma cells. These data led us to the hypothesis that syndecan-2 may play a role in the apoptotic signaling in bone tumors. We immunohistochemically analyzed tissue sections from biopsies from 21 patients with well-characterized osteosarcoma. These tissues expressed low levels of syndecan-2 compared with osteoblasts and osteocytes in normal bone. Cultured human osteosarcoma cells also produced lower mRNA levels of syndecan-2 than normal osteoblastic cells. Moreover, the presence of syndecan-2 correlated with spontaneous apoptosis in osteosarcoma tissues as assessed by detection of DNA fragmentation in situ. Overexpression of syndecan-2 resulted in decreased number of migrating and invading U2OS osteosarcoma cells in Matrigel. In addition, overexpression of syndecan-2 sensitized human osteosarcoma cells to chemotherapy-induced apoptosis, increasing the response to methotrexate, doxorubicin, and cisplatin. Consistently, knockdown of the proteoglycan using stable transfection with a plasmid coding small interfering RNA resulted in inhibition of chemotherapy-induced apoptosis. Analysis of syndecan-2 expression both in biopsies and in corresponding postchemotherapy-resected tumors, as well as in cells treated with methotrexate or doxorubicin, showed that the cytotoxic action of chemotherapy can be associated with an increase in syndecan-2. These results provide support for a tumor-suppressor function for syndecan-2 and suggest that dysregulation of apoptosis may be related to abnormal syndecan-2 expression or induction in osteosarcoma. Moreover, our data identify syndecan-2 as a new factor mediating the antioncogenic effect of chemotherapeutic drugs.

Dual involvement of protein kinase C delta in apoptosis induced by syndecan-2 in osteoblasts.

Syndecans are proteoglycans that act as signaling molecules. Previously, we showed that syndecan-2 (SYND2) is involved in the control of osteoblastic (OB) cell apoptosis. Here, we show a novel functional interaction between SYND2 and protein kinase C delta (PKCdelta). Overexpression of SYND2 in MG63 OB cells resulted in increased PKCdelta protein level without change in PKCdelta mRNA production. In SYND2-transfected cells, the increase in PKCdelta was restricted to the cytosolic compartment, threonine 505-PKCdelta was underphosphorylated and immunoprecipitated PKCdelta showed decreased capacity to phosphorylate histone, indicating that SYND2 decreased PKCdelta activity. Inhibition of PKCdelta by Rottlerin or a dead-kinase dominant negative (DN) construct activated effector caspases and increased the number of apoptotic cells. In addition, rescue of kinase activity with a construct coding, the PKCdelta catalytic domain (CAT) reduced SYND2-induced apoptosis. This indicates that PKCdelta acts as a pro-survival kinase and that SYND2 inhibits the anti-apoptotic action of PKCdelta in OB cells. We also showed that overexpression of PKCdelta wild type (WT) induced osteoblast apoptosis. Moreover, inhibition of PKCdelta by siRNA resulted in increased apoptosis in control cells but reduced apoptosis in SYND2-overexpressing osteoblasts, indicating that SYND2 requires PKCdelta accumulation to induce apoptosis. These results show that SYND2 modulates PKCdelta actions by inhibition of the canonical allosterical activation pathway that plays an anti-apoptotic role in OB cells, and promotion of a pro-apoptotic role that may depend on PKCdelta protein level and that participates to the induction of cell death by SYND2. This establishes a functional interaction between SYND2 and PKCdelta in osteoblasts.

Syndecan-2 overexpression induces osteosarcoma cell apoptosis: Implication of syndecan-2 cytoplasmic domain and JNK signaling.

Syndecans are cell surface heparan sulfate proteoglycans that serve as co-receptors and modulate the actions of a number of extracellular ligands. Syndecans thereby regulate cell adhesion, proliferation, and differentiation. Studies in cancer cells suggest that syndecans may also modulate cell viability. We previously showed that syndecan-2 controls the growth of normal human osteoblastic cells. In this study, we examined the role of syndecan-2 in osteosarcoma cell proliferation and apoptosis. To this goal, MG63 osteosarcoma cells which express low syndecan-2 levels were transfected to overexpress full-length syndecan-2 or truncated syndecan-2 lacking its cytoplasmic domain. Determination of cell growth by cell counting and 3H-thymidine incorporation showed that truncated syndecan-2 inhibited MG63 cell proliferation. Flow cytometry analysis of DNA content and colony forming test revealed that syndecan-2, but not truncated syndecan-2, induced MG63 cell death. We show that characteristic features of apoptosis such as caspase activation, PARP cleavage, cytochrome c release, increased Bax expression, and DNA fragmentation were associated with syndecan-2-induced cell death. We further show that expression of full-length or truncated syndecan-2 induced differential activation of MAPK phosphorylation in MG63 cells. Notably, syndecan-2 but not truncated syndecan-2 overexpression increased JNK phosphorylation. Moreover, SP600125, a specific inhibitor of JNK, suppressed Bax expression induced by syndecan-2 overexpression, indicating that JNK activation mediates syndecan-2-induced apoptosis. The results show that syndecan-2 induces osteoblastic cell apoptosis through the JNK/Bax apoptotic pathway and that the cytoplasmic domain of syndecan-2 is required for this action. This supports a role for syndecan-2 in the regulation of osteosarcoma cell fate and identifies one signaling pathway by which syndecan-2 induces apoptosis in osteosarcoma cells.

Apoptosis in membranous bone formation: role of fibroblast growth factor and bone morphogenetic protein signaling.

Membranous ossification occurs by the condensation of mesenchymal cells followed by their progressive differentiation into osteoblasts that form a mineralized matrix in ossification centers. The balance between proliferating and differentiated osteogenic cells at the suture areas between calvarial bones is essential for the control of suture maintenance and membranous bone formation. The mechanisms of regulation of na apoptosis in suture areas begin to be understood. Fibroblast growth factor (FGF) and bone morphogenetic protein (BMP) are important regulators of mesenchymal, preosteoblast, and osteoblast apoptosis in suture areas. Perturbations in FGF or BMP signaling lead to alter the number of apoptotic osteogenic cells, resulting in premature or delayed suture closure. Recent data indicate that FGF signaling downregulates preosteoblast apoptosis, thereby preventing premature fusion of adjacent mineralizing extremities. In contrast, continuous FGF signaling or constitutive FGF receptor activation, as well as BMP signaling, upregulate osteoblast apoptosis. Additionally, multiple signaling mechanisms, including PI3K and PKC, appear to be involved in the control of calvarial osteoblast apoptosis by FGF and BMP. These mechanisms allow a fine control of the number of functional bone-forming cells and, thereby, the normal progression of membranous bone formation.

Growth factors and bone formation in osteoporosis: roles for fibroblast growth factor and transforming growth factor beta.

Osteoporosis is characterised by excess bone fragility resulting from bone loss and altered bone microarchitecture. Bone loss occurring during aging and after menopause in women is known to result from an imbalance between bone formation and resorption. Bone formation is dependent on the commitment of osteoprogenitor cells, the proliferation of pre-osteoblasts, their differentiation into mature osteoblasts synthesising bone matrix and the life-span of mature osteoblasts. Transforming Growth Factor beta (TGFbeta) and Fibroblast Growth Factors (FGFs) are important factors that promote osteoprogenitor cell proliferation and osteogenesis. Reduced expression of TGFbeta in bone was found in several animal models of osteopenia. In addition, both FGF and TGFbeta were found to exert anabolic effects on bone formation in intact animals and to reduce bone loss in experimental models of osteoporosis. Both genetic manipulation of FGF and TGFbeta or their receptors in mice and bone phenotype associated with FGF receptors and TGFbeta mutations or polymorphism suggest that TGFbeta and FGF signalling may contribute to the control of osteogenesis and bone mass in vivo. The determination of molecular mechanisms involved in the anabolic actions of FGF and TGFbeta in cells of the osteoblastic lineage may lead in the future to the development of new therapeutic strategies aimed at improving bone formation in osteoporotic patients.