Parabiosis model does not show presence of circulating osteoprogenitor cells

The goal of this study was to determine the presence of osteoprogenitor cells in the peripheral blood. Experiments were conducted with a parabiosis model in which osteoblast specific transgenic mice (Col2.3GFP or hOC‐GFP) were surgically joined with a transgenic mouse where herpes virus thymidine kinase gene is under the control of the collagen α1 promoter (Col2.3ΔTK). This method permits conditional ablation of osteoblasts by ganciclovir (GCV) treatment. In parabionts treated with GCV for 15 days or 1.5–2 months, GFP (hOC‐GFP or Col2.3GFP) expression was not detected in histological preparations or in marrow stromal cell cultures from the Col2.3ΔTK parabiont. Finally, Col2.3GFP/Col2.3ΔTK pairs were treated with GCV for 15 days and allowed to recover from GCV for 3 months. Again there was a failure to detect Col2.3GFP expressing cells in the Col2.3ΔTK parabiont. These observations, at least within the limits of this model system, allow the conclusion that osteoprogenitor cells do not readily circulate. genesis 48:171–182, 2010. © 2010 wiley‐Liss, Inc.     

Perichondrial expression of Wdr5 regulates chondrocyte proliferation and differentiation

Wdr5 is developmentally expressed in osteoblasts and is required for osteoblast differentiation. Mice overexpressing Wdr5 under the control of the mouse α(1)I collagen promoter (Col I-Wdr5) display accelerated osteoblast differentiation as well as accelerated chondrocyte differentiation, suggesting that overexpression of Wdr5 in osteoblasts affects chondrocyte differentiation. To elucidate the molecular mechanism by which overexpression of Wdr5 in the perichondrium regulates chondrocyte differentiation, studies were undertaken using skeletal elements and cultured metatarsals isolated from wild-type and Col I-Wdr5 embryos. FGF18 mRNA levels were decreased in Col I-Wdr5 humeri. Furthermore, local delivery of FGF18 to the bone collar of ex vivo cultures of metatarsals attenuated the chondrocyte phenotype of the Col I-Wdr5 metatarsals. Impairing local FGF action in wild-type metatarsals resulted in a chondrocyte phenotype analogous to that of Col I-Wdr5 metatarsals implicating impaired FGF action as the cause of the phenotype observed. The expression of Twist-1, which regulates chondrocyte differentiation, was increased in Col I-Wdr5 humeri. Chromatin immunoprecipitation analyses demonstrated that Wdr5 is recruited to the Twist-1 promoter. These findings support a model in which overexpression of Wdr5 in the perichondrium promotes chondrocyte differentiation by modulating the expression of Twist-1 and FGF18.     

Neuropeptide Y is expressed by osteocytes and can inhibit osteoblastic activity

Osteocytes are the most abundant osteoblast lineage cells within the bone matrix. They respond to mechanical stimulation and can participate in the release of regulatory proteins that can modulate the activity of other bone cells. We hypothesize that neuropeptide Y (NPY), a neurotransmitter with regulatory functions in bone formation, is produced by osteocytes and can affect osteoblast activity. To study the expression of NPY by the osteoblast lineage cells, we utilized transgenic mouse models in which we can identify and isolate populations of osteoblasts and osteocytes. The Col2.3GFP transgene is active in osteoblasts and osteocytes, while the DMP1 promoter drives green fluorescent protein (GFP) expression in osteocytes. Real‐time PCR analysis of RNA from the isolated populations of cells derived from neonatal calvaria showed higher NPY mRNA in the preosteocytes/osteocytes fraction compared to osteoblasts. NPY immunostaining confirmed the strong expression of NPY in osteocytes (DMP1GFP⁺), and lower levels in osteoblasts. In addition, the presence of NPY receptor Y1 mRNA was detected in cavaria and long bone, as well as in primary calvarial osteoblast cultures, whereas Y2 mRNA was restricted to the brain. Furthermore, NPY expression was reduced by 30–40% in primary calvarial cultures when subjected to fluid shear stress. In addition, treatment of mouse calvarial osteoblasts with exogenous NPY showed a reduction in the levels of intracellular cAMP and markers of osteoblast differentiation (osteocalcin, BSP, and DMP1). These results highlight the potential regulation of osteoblast lineage differentiation by local NPY signaling. J. Cell. Biochem. 108: 621–630, 2009. © 2009 Wiley‐Liss, Inc.     

高浓度地塞米松通过下调LMP-1表达抑制大鼠成骨细胞的分化

为探讨地塞米松（dexamethasone,DEX)抑制成骨细胞分化的机制,观察了不同浓度DEX对体外培养大鼠成骨细胞的碱性磷酸酶活性,骨钙素（osteocalcin,OC)合成,I型胶原蛋白表达的影响。并用RT-PCR方法检测了成骨细胞中LIM矿化蛋白1mRNA的表达量,结果显示：低浓度（10^-9mol/L）的DEX能增强碱性磷酸酶的活性、OC的分泌和I型胶原蛋白的表达;而高浓度（10^-7mol/L)的DEX对它们则起抑制作用,并下调成骨细胞正调节因子LMP-1mRNA的表达,上述结果表明,低浓度的DEX促进成骨细胞的分化;高浓度的DEX则抑制成骨细胞的分化,其抑制作用可能是通过下调LMP-1mRNA的表达而实现的。     

Analysis of the odontogenic and osteogenic potentials of dental pulp in vivo using a Col1a1-2.3-GFP transgene

Recently, transgenic mice that carry a Green Fluorescent Protein (GFP) reporter gene fused to 2.3 kb fragment of rat Col1a1 regulatory sequences (pOBCol2.3GFPemd) were generated. In the present study, we have examined the patterns of expression of Col1a1-2.3-GFP during odontoblast differentiation in this transgenic line. We report that Col1a1-2.3-GFP is expressed in newly differentiated odontoblasts secreting predentin and fully differentiated odontoblasts. The pattern of expression of Col1a1-2.3-GFP in odontoblasts is correlated with that of dentin sialophosphoprotein (DSPP). Col1a1-2.3-GFP is also expressed in the osteoblasts and osteocytes of alveolar bone. The pattern of expression of Col1a1-2.3-GFP in osteocytes is correlated with the expression of Dmp1. These observations indicate the 2.3 kb rat Col1a1 promoter fragment has sufficient strength and specificity to monitor the stage-specific changes during both odontoblast and osteoblast differentiation. We also used coronal pulp tissues isolated from postnatal pOBCol2.3GFPemd transgenic animals to follow their differentiation after transplantation under the kidney capsule. Our observations provide direct evidence that the dental pulp contains competent progenitor cells capable of differentiating into new generations of odontoblast-like cells which express high levels of Col1a1-2.3-GFP and DSPP and secrete tubular containing reparative dentin. We also report that the dental pulp is capable of giving rise to atubular bone-like tissue containing osteocytes expressing high levels of Col1a1-2.3-GFP and Dmp1. Our studies indicate that pOBCol2.3GFPemd transgenic animals provide a powerful tool for direct examination of the underlying mechanisms and the signaling pathways involved in dentin regeneration and repair, stem cell properties and heterogeneity of the dental pulp.     

Effect of dexamethasone withdrawal on osteoblastic differentiation of bone marrow stromal cells

Dexamethasone is capable of directing osteoblastic differentiation of bone marrow stromal cells (BMSCs) in vitro, but its effects are not lineage-specific, and sustained exposure has been shown to down-regulate collagen synthesis and induce maturation of an adipocyte subpopulation within BMSC cultures. Such side effects might be reduced if dexamethasone is applied in a regimented manner, but the discrete steps in osteoblastic maturation that are stimulated by dexamethasone are not known. To examine this, dexamethasone was added to medium to initiate differentiation of rat BMSCs cultures and then removed after a varying number of days. Cell layers were analyzed for cell number, rate of collagen synthesis, expression of osteocalcin (OC), bone sialoprotein (BSP) and lipoprotein lipase (LpL), and matrix mineralization. Withdrawal of dexamethasone at 3 and 10 days was found to enhance cell number relative to continuous exposure, but did not affect to decrease collagen synthesis slightly. Late markers of osteoblastic differentiation, BSP expression and matrix mineralization, were also sensitive to dexamethasone and increased systematically with exposure while LpL systematically decreased. These results indicate that dexamethasone acts at both early and late stages to direct proliferative osteoprogenitor cells toward terminal maturation.     

Acidic fibroblast growth factor inhibits osteoblast differentiation in vitro: Altered expression of collagenase,cell growth-related,and mineralization-associated genes

Fibroblast growth factors (FGF) are osteoblast mitogens, but their effects on bone formation are not clearly understood. Most in vitro studies examining the effects of FGFs on osteoblasts have been performed only during the initial proliferative stage of osteoblast culture. In these studies, we examined the consequential effect of acidic FGF in cultures of rat fetal diploid osteoblasts that undergo a developmental differentiation program producing a mineralized bone-like matrix. During the initial growth period (days 1–10), addition of acidic FGF (100 μg/ml) to actively proliferating cells increased (P < 0.05) ³H-thymidine uptake (2,515 ± 137, mean ± SEM vs. 5,884 ± 818 cpm/10⁴ cells). During the second stage of maturation (days 10–15), osteoblasts form multilayered nodules of cells and accumulate matrix, followed by mineralization (stage 3, days 16–29). Addition of acidic FGF to the osteoblast cultures from days 7 to 15 completely blocked nodule formation. Furthermore, addition of acidic FGF after nodule formation (days 14–29) inhibited matrix mineralization, which was associated with a marked increase in collagenase gene expression, and resulted in a progressive change in the morphology of the nodules, with only a few remnants of nonmineralized nodules present by day 29. Histochemical and biochemical analyses revealed a decrease in alkaline phosphatase and mineral content, confirming the acidic FGF-induced inhibition of nodule and matrix formation. To identify mechanisms contributing to these changes, we examined expression of cell growth and bone phenotypic markers. Addition of acidic FGF during the proliferative phase (days 7–8) enhanced histone H4, osteopontin, type 1 collagen, and TGF-β mRNA levels, which are coupled to proliferating osteoblasts, and blocked the normal developmental increase in alkaline phosphatase and osteocalcin gene expression and calcium accumulation. Addition of acidic FGF to the cultures during matrix maturation (days 14–15) reactivated H4, osteopontin, type I collagen, and TGF-β gene expression, and decreased alkaline phosphatase and osteocalcin gene expression. In an in vivo experiment, rats were treated with up to 60 μg/kg/day acidic FGF intravenously for 30 days. Proliferation of osteoblasts and deposition of bone occurred in the marrow space of the diaphysis of the femur in a dose-related fashion. The metaphyseal areas were unaffected by treatment. In conclusion, our data suggest that acidic FGF is a potent mitogen for early stage osteoblasts which leads to modifications in the formation of the extracellular matrix; increases in TGF-β and collagenase are functionally implicated in abrogating competency for nodule formation. Persistence of proliferation prevented expression of alkaline phosphatase and osteocalcin, also contributing to the block in the progression of the osteoblast developmental sequence. © 1996 Wiley-Liss, Inc.     

Evidence of specific characteristics and osteogenic potentiality in bone cells from tibia

Human bone cells used for in vitro studies are mainly derived from bone marrow (BM) or trabecular bone (TB). There are no specific markers or procedures for isolation and growth of these cells. To validate the potentiality of these cells, we isolated human mesenchymal stromal cells (MSCs) and osteoblasts (OBs) from the tibial plateau of the same subject, grown in two different media (α-MEM and DMEM/F12) and analyzed for cell growth, proliferation, phenotype and osteogenic potential. We found that OBs grew well in both media tested, but MSCs were able to grow only in α-MEM medium. OBs in DMEM/F12 showed reduced proliferation capability and expressed a low level of alkaline phosphatase (AP), RUNX-2, osteocalcin (OC), bone sialoprotein (BSP), collagen type I (Col.I) compared with OBs in α-MEM but high level of collagen type XV (Col.XV). Compared with MSCs in α-MEM, OBs have an increased ability to proliferate and express more OC and BSP at molecular level but less AP, RUNX-2 and Col.I than MSCs. Time-course experiments to analyze the osteogenic potential of these cells showed that OBs were more efficient than MSCs. However, these cells obtained from tibial plateau showed a different trend of AP, OC and Col.I osteogenic markers compared to control MSCs from the iliac crest. This study shows that bone-adherent OBs grown in α-MEM medium are more efficient for osteogenic differentiation than BM MSCs and contribute to defining their phenotypic and functional characteristics, so providing a rationale for their use in bone tissue engineering or therapeutic purposes.     

FGF‐2 promotes osteocyte differentiation through increased E11/podoplanin expression

E11/podoplanin is critical in the early stages of osteoblast‐to‐osteocyte transitions (osteocytogenesis), however, the upstream events which regulate E11 expression are unknown. The aim of this study was to examine the effects of FGF‐2 on E11‐mediated osteocytogenesis and to reveal the nature of the underlying signaling pathways regulating this process. Exposure of MC3T3 osteoblast‐like cells and murine primary osteoblasts to FGF‐2 (10 ng/ml) increased E11 mRNA and protein expression (p < 0.05) after 4, 6, and 24 hr. FGF‐2 induced changes in E11 expression were also accompanied by significant (p < 0.01) increases in Phex and Dmp1 (osteocyte markers) expression and decreases in Col1a1, Postn, Bglap, and Alpl (osteoblast markers) expression. Immunofluorescent microscopy revealed that FGF‐2 stimulated E11 expression, facilitated the translocation of E11 toward the cell membrane, and subsequently promoted the formation of osteocyte‐like dendrites in MC3T3 and primary osteoblasts. siRNA knock down of E11 expression achieved >70% reduction of basal E11 mRNA expression (p < 0.05) and effectively abrogated FGF‐2‐related changes in E11 expression and dendrite formation. FGF‐2 strongly activated the ERK signaling pathway in osteoblast‐like cells but inhibition of this pathway did not block the ability of FGF‐2 to enhance E11 expression or to promote acquisition of the osteocyte phenotype. The results of this study highlight a novel mechanism by which FGF‐2 can regulate osteoblast differentiation and osteocyte formation. Specifically, the data suggests that FGF‐2 promotes osteocytogenesis through increased E11 expression and further studies will identify if this regulatory pathway is essential for bone development and maintenance in health and disease.     

GP130/OSMR is the only LIF/IL-6 family receptor complex to promote osteoblast differentiation of calvaria progenitors

Leukemia inhibitory factor (LIF) and its receptor (LIFR) are "twins" of Oncostatin M (OSM) and OSMR, respectively, likely having arisen through gene duplications. We compared their effects in a bone nodule-forming model of in vitro osteogenesis, rat calvaria (RC) cell cultures. Using a dominant-negative LIF mutant (hLIF-05), we showed that in RC cell cultures mouse OSM (mOSM) activates exclusively glycoprotein 130 (gp130)/OSMR. In treatments starting at early nodule formation stage, LIF, mOSM, IL-11, and IL-6 + sIL-6R inhibit bone nodule formation, that is, osteoprogenitor differentiation. Treatment with mOSM, and no other cytokine of the family, in early cultures (day 1-3 or 1-4) increases bone colony numbers. hLIF-05 also dose dependently stimulates bone nodule formation, confirming the inhibitory action of gp130/LIFR on osteogenesis. In pulse treatments at successive stages of bone nodule formation and maturation, LIF blocks osteocalcin (OCN) expression by differentiated osteoblasts, but has no effect on bone sialoprotein (BSP) expression. Mouse OSM inhibits OCN and BSP expression in preconfluent cultures with no or progressively reduced effects at later stages, reflecting the disruption of early nodules, possibly due to the strong apoptotic action of mOSM in RC cell cultures. In summary, LIFR and OSMR display differential effects on differentiation and phenotypic expression of osteogenic cells, most likely through different signal transduction pathways. In particular, gp130/OSMR is the only receptor complex of the family to stimulate osteoprogenitor differentiation in the RC cell culture model.