Tomihisa Takahashi

Inductive Effects of Dexamethasone on the Gene Expression of Cbfa1, Osterix and Bone Matrix Proteins During Differentiation of Cultured Primary Rat Osteoblasts

Runx2/core binding factor alpha 1 (Cbfa1) and Osterix (Osx) are osteoblast-specific transcription factors essential for the development of a mature osteoblast phenotype and are thought to activate osteoblast marker genes in vivo to produce a bone-specific matrix. Dexamethasone (Dex) is known to be a potent stimulator of osteoblastic differentiation in vitro, however, the exact role is still unclear. To investigate the mechanisms of the stimulation of osteoblastic differentiation by Dex, we evaluated the effects of Dex on proliferation and mineralization as well as on mRNA expression of Cbfa1, Osx and osteoblast marker genes, osteocalcin (OC) and bone sialoprotein (BSP) mRNAs in differentiating foetal rat calvarial cells (FRCC), which were cultured for 35 days in the presence or absence of 10−7 M Dex. Treatment of FRCC with Dex resulted in the stimulation of cell proliferation and increased the number of cells, which are able to produce bone-like nodules with a mineralized matrix when compared to untreated controls. Northern blot analysis revealed that, in the absence of Dex, Cbfa1 mRNA expressed at day 8, while Osx mRNA expressed at day 15. Subsequently expression of these mRNAs increased up to day 21, followed by constant expression during the culture period. The expression of OC and BSP mRNAs appeared to be synchronous with that of Osx mRNA and was detectable at day 15 with an increase thereafter. The presence of Dex resulted in an induction in Cbfa1 and Osx mRNA expression. The former appeared at day 5 and the latter appeared at day 11. Subsequently expression of Cbfa1 and Osx mRNAs increased up to day 15 with a decrease thereafter. Expression of OC and BSP mRNAs appeared to be coincident with that of Osx mRNA and was detectable at day 11 and reached a maximum at day 15 followed by constant expression. These observations indicate that induction of Cbfa1 and Osx mRNAs by Dex may be followed by activation of osteoblast marker genes such as OC and BSP mRNAs to produce a bone-specific matrix that subsequently becomes mineralized. Thus, it is likely that Dex may promote osteoblastic differentiation and mineralization of FRCC by inducing the expression of Cbfa1 and Osx genes in vitro.

Overexpression of Runx2 and MKP-1 Stimulates Transdifferentiation of 3T3-L1 Preadipocytes into Bone-Forming Osteoblasts In Vitro

Runx2, a transcription factor, is essential for osteoblastic differentiation, bone formation, and maintenance. We examined the effect of Runx2 on transdifferentiation of 3T3-L1 preadipocytes into functional, mature osteoblasts. Forced expression of exogenous Runx2 using a retroviral gene-delivery system showed increases of alkaline phosphatase (ALP) activity and expression of the osteoblastic marker genes osteocalcin (OC), bone sialoprotein (BSP), and osterix (Osx), accompanied by low-level matrix mineralization. In contrast, adipocytic differentiation was completely blocked with downregulation of adipogenic transcription factors PPARγ2, C/EBPα, and C/EBPδ. Treatment of dexamethasone (Dex), a synthetic glucocorticoid, stimulated the formation of mineralized nodules in Runx2-overexpressing 3T3-L1 cells with increases of ALP, OC, BSP, and Osx expression. Here, we focused on a dual specific phosphatase, mitogen-activated protein kinase (MKP-1), since Dex significantly increased MKP-1 expression in Runx2-overexpressing 3T3-L1 cells. Forced expression of exogenous MKP-1 resulted in accumulation of robust matrix mineralization in parallel with induction of ALP activity and expression of OC, BSP, and Osx in Runx2-overexpressing 3T3-L1 cells. These results suggest that simultaneous overexpression of Runx2 and MKP-1 is effective for transdifferentiation of preadipocytes into fully differentiated bone-forming osteoblasts and provide a novel strategy for cell-based therapeutic applications requiring significant numbers of osteogenic cells to synthesize mineralized constructs for the treatment of large bone defects.

Role of nuclear factor-κ B in the expression by tumor necrosis factor-α of the human polymeric immunoglobulin receptor (pIgR ) gene

Abstract We analyzed the mechanism of human polymeric immunoglobulin receptor (pIgR) gene upregulation by tumor necrosis factor (TNF)-α. Northern blot analysis showed that the expression of pIgR mRNA was enhanced by TNF-α stimulation. This activation was completely inhibited by RNA polymerase or protein synthesis inhibitors, suggesting that the regulation of pIgR gene expression depends on de novo RNA and protein synthesis. Furthermore, the stimulation of pIgR mRNA by TNF-α was decreased by pyrrolidinedithiocarbamate and l-1-4′-tosylamino-phenylethyl-chloromethyl ketone, which are known nuclear factor (NF)-κB inhibitors. For further analysis of gene regulation, we cloned and sequenced the 1.5-kb 5′-flanking region of the pIgR gene. In the upstream region, we found two NF-κB-binding motifs (named κB1 and κB2 from the 5′ region). An electrophoretic mobility shift assay indicated that two components of the NF-κB/Rel family, p50 and p65, bound with higher affinity to the κB2 element than to the κB1 element. We also analyzed pIgR gene expression using reporter plasmids expressing the firefly luciferase gene. Stimulation by TNF-α significantly activated the pIgR gene promoter, as a 775-bp upstream region of the pIgR gene increased luciferase gene expression in cells treated with TNF-α. The activation of promoter activity by TNF-α was abolished when a mutation was inserted into κB1 or κB2. These data indicated that pIgR gene expression induced by TNF-α is transcriptionally regulated via activation of NF-κB. In addition, there is a possibility that another factor may act in concert with NF-κB.

Cloning and expression of the chicken immunoglobulin joining (J)-chain cDNA.

Abstract The J chain is a component of polymeric immunoglobulin (Ig) molecules and may play an important role in their polymerization and the transport of polymeric Ig across epithelial cells. In this study, the primary structure of the chicken J chain was determined by sequencing cDNA clones. The cDNA had an open reading frame of 476 nucleotides encoding a putative protein of 158 amino acid residues including the signal sequence. The 3′ untranslated region consisted of 1216 nucleotides and a poly(A) tail. The deduced amino acid sequence of the chicken J chain had a high degree of homology to that of human, cow, rabbit, mouse, frog, and earthworm, with eight conserved Cys residues identical to the mammalian J chains. Northern blot hybridization performed with total RNA from various chicken tissues revealed high levels of J-chain mRNA expression in spleen, intestine, Harderian gland, and bursa of Fabricius, and low levels in the thymus. The J chain was expressed in the bursa as early as day 15 of embryogenesis. These data indicated that the chicken J-chain gene displays a high degree of homology with that of other species, and is expressed at an early stage of development of the chicken immune system.

Effects of bone morphogenetic protein-2 and transforming growth factor beta1 on gene expression of transcription factors, AJ18 and Runx2 in cultured osteoblastic cells.

Osteoblast differentiation is controlled by multiple transcription factors, Runx2, AJ18, Osterix, Dlx5 and Msx2. The mechanisms of regulation of AJ18 mRNA expression by the transforming growth factor β (TGF-β) superfamily remain poorly understood. However, it is known that BMP-2 induces differentiation of C26 cells into more mature osteoblastic cells. The present study, using Northern blot and real-time reverse transcription polymerase chain reaction analyses, investigated the effects of bone morphogenetic protein-2 (BMP-2) and TGF-β 1 on mRNA expression of AJ18 and Runx2 in a clonal osteoblast precursor cell line ROB-C26 (C26) cultured for 3, 6 or 9 days in the presence or absence of BMP-2. Although mRNA expression of Osterix and bone sialoprotein (BSP) was undetectable in the C26 culture, BMP-2 induced Osterix expression on days 3–9, but not BSP expression. BMP-2 also stimulated significantly Dlx5 expression on days 3–9, Msx2 and matrix Gla protein expressions on days 3 and 6, Runx2, alkaline phosphatase and osteocalcin expressions on days 6 and 9 in the culture. Furthermore, BMP-2 increased significantly Smad5 mRNA in the culture on day 3, indicating BMP-2 involvement in the regulation of Smad5 mRNA expression. In contrast, the inhibitory effects of BMP-2 on AJ18 mRNA expression were significant on days 3–9, indicating that a decrease in AJ18 mRNA expression is essential for the increased osteoblastic differentiation. Furthermore, TGF-β 1 (0, 0.1, 1.0 and 5.0 ng/ml) treatment of C26 cells cultured for 6 days in the presence or absence of BMP-2 for 24 h stimulated mRNA levels of AJ18 and Runx2, maximal stimulation occurring principally at 1.0 ng/ml. These observations indicate that the expression of AJ18 and Runx2 mRNAs in C26 cells is under the control of BMP-2 and TGF-β 1, which exert different effects on AJ18 mRNA expression, but are potent stimulators of Runx2 mRNA expression during osteoblast differentiation.

Dexamethasone promotes DMP1 mRNA expression by inhibiting negative regulation of Runx2 in multipotential mesenchymal progenitor, ROB-C26.

Dentin matrix protein 1 (DMP1) is an acidic phosphorylated extracellular protein and essential for mineralization of dentin and bone; however, the precise mechanism regulating DMP1 expression is not fully understood. A synthetic glucocorticoid (GC), dexamethasone (Dex), promotes an early osteoblast differentiation of a mesenchymal progenitor, ROB‐C26 (C26), in parallel with inductive expression of an osteoblast‐specific transcription factor, Runx2, and other extracellular matrix proteins such as osteocalcin and bone sialoprotein (BSP). We have examined the effect of Dex on DMP1 expression via induction of Runx2 in C26 cells. Real time RT‐PCR showed that Dex increases DMP1 mRNA expression levels at time‐ and dose‐dependent manners and a GC antagonist, RU486, drastically inhibited DMP1 mRNA expression levels. Furthermore, Dex increased the luciferase activity of six‐repeated osteoblast‐specific cis‐acting element 2 (6 × OSE2), which is the binding sequence of Runx2, suggesting that Dex stimulates DMP1 expression via activation of Runx2. However, unexpected results showed that overexpression of exogenous Runx2 depressed DMP1 mRNA expression level, even after cells had been treated with Dex, while downregulated expression of endogenous Runx2 enhanced Dex‐induced DMP1 mRNA expression level. These results imply that large amounts of exogenous Runx2 inhibit DMP1 expression, whereas small amounts are more effective for Dex‐induced DMP1 expression in C26 cells. Therefore, Dex may activate some factors that inhibit negative action of Runx2 on DMP1 expression. Since mitogen‐activating protein kinase (MAPK) phosphatase‐1 (MKP‐1) has been reported to affect the Dex‐induced osteoblast differentiation via decrease of Runx2‐phosphorylation, we focus on the relationship between MKP‐1 and DMP1 expression. Dex increases MKP‐1 expression, and overexpression of exogenous MKP‐1 showed significant increase of luciferase activity of 6 × OSE up to the level detected in Dex‐treated C26 cells. However, no inductive DMP1 mRNA expression level was found in C26 cells unlike BSP and OPN. These results suggest that although MKP‐1 increases DNA‐binding activity of Runx2, DMP1 expression may require the collaboration of MKP‐1 and additive factors to stimulate Runx2‐mediated DMP1 expression in the post‐transcriptional event of Dex‐treated C26 cells.

Inhibition of Wnt/β-catenin signaling by dexamethasone promotes adipocyte differentiation in mesenchymal progenitor cells, ROB-C26

Dexamethasone (Dex) stimulates the differentiation of mesenchymal progenitor cells into adipocytes and osteoblasts. However, the mechanisms underlying Dex-induced differentiation have not been clearly elucidated. We examined the effect of Dex on the expression and activity of Wnt/β-catenin signal-related molecules in a clonal mesenchymal progenitor cell line, ROB-C26 (C26). Dex induced the mRNA expression of Wnt antagonists, dickkopf-1 (Dkk-1), and Wnt inhibitory factor (WIF)-1. Immunocytochemical analysis showed that the downregulation of β-catenin protein expression by Dex occured concomitantly with the increased expression of the PPARγ protein. Dex decreased phosphorylation of Ser9-GSK3β and expression of active β-catenin protein. To examine the effects of Dex on Wnt/β-catenin activity, we used immunocytochemistry to analyze TCF/LEF-mediated transcription during Dex-induced adipogenesis in Wnt indicator (TOPEGFP) C26 cells. Our results demonstrated that Dex repressed TCF/LEF-mediated transcription, but induced adipocyte differentiation. Treatment with a GSK3β inhibitor attenuated Dex-induced inhibition of TCF/LEF-mediated transcriptional activity, but suppressed Dex-induced adipocyte differentiation, indicating that adipocyte differentiation and inhibition of Wnt/β-catenin activity by Dex are mediated by GSK3β activity. Furthermore, β-catenin knockdown not only suppressed Dex-induced ALP-positive osteoblasts differentiation but also promoted Dex-induced adipocytes differentiation. These results suggest that inhibition of β-catenin expression by Dex promotes the differentiation of mesenchymal progenitor cells into adipocytes.

The p75 neurotrophin receptor regulates MC3T3-E1 osteoblastic differentiation

While the role of p75(NTR) signaling in the regulation of nerve-related cell growth and survival has been well documented, its actions in osteoblasts are poorly understood. In this study, we examined the effects of p75(NTR) on osteoblast proliferation and differentiation using the MC3T3-E1 pre-osteoblast cell line. Proliferation and osteogenic differentiation were significantly enhanced in p75(NTR)-overexpressing MC3T3-E1 cells (p75GFP-E1). In addition, expression of osteoblast-specific osteocalcin (OCN), bone sialoprotein (BSP), and osterix mRNA, ALP activity, and mineralization capacity were dramatically enhanced in p75GFP-E1 cells, compared to wild MC3T3-E1 cells (GFP-E1). To determine the binding partner of p75(NTR) in p75GFP-E1 cells during osteogenic differentiation, we examined the expression of trkA, trkB, and trkC that are known binding partners of p75(NTR), as well as NgR. Pharmacological inhibition of trk tyrosine kinase with the K252a inhibitor resulted in marked reduction in the level of ALPase under osteogenic conditions. The deletion of the GDI binding domain in the p75(NTR)-GFP construct had no effect on mineralization. Taken together, our studies demonstrated that p75(NTR) signaling through the trk tyrosine kinase pathway affects osteoblast functions by targeting osteoblast proliferation and differentiation.

Suppression of lamin A/C by short hairpin RNAs promotes adipocyte lineage commitment in mesenchymal progenitor cell line, ROB-C26

Lamin A/C gene encodes a nuclear membrane protein, and mutations in this gene are associated with diverse degenerative diseases that are linked to premature aging. While lamin A/C is involved in the regulation of tissue homeostasis, the distinct expression patterns are poorly understood in the mesenchymal cells differentiating into adipocytes. Here, we examined the expression of lamin A/C in a rat mesenchymal progenitor cell-line, ROB-C26 (C26). Immunocytochemical analysis showed that lamin A/C was transiently down-regulated in immature adipocytes, but its expression increased with terminal differentiation. To elucidate the role of lamin A/C expression on mesenchymal cell differentiation, lamin A/C expression was suppressed using short hairpin RNA (shRNA) molecules in C26 cells. In the absence of adipogenic stimuli, lamin A/C shRNA decreased alkaline phosphatase (ALP) activity, but induced preadipocyte factor -1 (Pref-1) mRNA expression. In the presence of adipogenic stimuli, lamin A/C knockdown promotes adipocytes differentiation, as assessed by the detection of an increase in Oil Red O staining. RT-PCR analysis showed that lamin A/C shRNA resulted in increased mRNA expression of PPARγ2 and aP2 during adipocyte differentiation. These results suggest that decreased lamin A/C expression levels not only suppress osteoblast phenotypes but also promote adipocyte differentiation in C26 cells.

Ontogeny of the Secretory IgA System in Humans

Secretory immunoglobulins consist of IgA or IgM, secretory component (SC) and joining (J) chain. J chain is a 15 kilodalton polypeptide that participates in the intracellular polymerization of IgA and IgM and is found in plasma cells1. J chain was also found at earlier stages of B cell differentiation before the onset of immunoglobulin synthesise2. IgA or IgM is produced by plasma cells, polymerized intracellularly and secreted into the lamina propria of glandular tissues. SC, which is localized in the basolateral membrane of glandular tissues, functions as a receptor for J chain-containing polymeric immunoglobulins3. Ontogenically, it has been reported that SC and IgM are expressed at an early gestational age while IgA usually appears later4,5. However, the exact development of the secretory immune system in the human fetus has not been examined extensively.