Project description:When bound to the vitamin D receptor (VDR), the active form of vitamin D, 1,25-dihydroxyvitamin D (1,25D) is a potent regulator of osteoblast transcription. Less clear is the impact of 1,25D on posttranscriptional events in osteoblasts, such as the generation and action of microRNAs (miRNAs). Microarray analysis using replicate (n?=?3) primary cultures of human osteoblasts (HOBs) identified human miRNAs that were differentially regulated by >1.5-fold following treatment with 1,25D (10 nM, 6 hours), which included miRNAs 637 and 1228. Quantitative reverse transcription PCR analyses showed that the host gene for miR-1228, low-density lipoprotein receptor-related protein 1 (LRP1), was coinduced with miR-1228 in a dose-dependent fashion following treatment with 1,25D (0.1-10 nM, 6 hours). By contrast, the endogenous host gene for miR-637, death-associated protein kinase 3 (DAPK3), was transcriptionally repressed by following treatment with 1,25D. Analysis of two potential targets for miR-637 and miR-1228 in HOB, type IV collagen (COL4A1) and bone morphogenic protein 2 kinase (BMP2K), respectively, showed that 1,25D-mediates suppression of these targets via distinct mechanisms. In the case of miR-637, suppression of COL4A1 appears to occur via decreased levels of COL4A1 mRNA. By contrast, suppression of BMP2K by miR-1228 appears to occur by inhibition of protein translation. In mature HOBs, small interfering RNA (siRNA) inactivation of miR-1228 alone was sufficient to abrogate 1,25D-mediated downregulation of BMP2K protein expression. This was associated with suppression of prodifferentiation responses to 1,25D in HOB, as represented by parallel decrease in osteocalcin and alkaline phosphatase expression. These data show for the first time that the effects of 1,25D on human bone cells are not restricted to classical VDR-mediated transcriptional responses but also involve miRNA-directed posttranscriptional mechanisms.

Project description:Identified a series of miRNAs transcriptionally regulated by vitamin D treatment within osteoblasts. Several miRNAs were validated in dose escalation experiments. Furthermore, downstream miRNA targets were appraised and found to regulate target message and protein levels. These findings were assessed in early and late passaged osteoblasts and found an age-dependent regulation of some miRNAs, while others were considered constituitiously expressed. Inhibitor studies of one key bone-related miRNA demonstrated the importance of this miRNA to regulate vitamin D-mediate osteoblastic differentiation during mineralizaition.

Project description:Identified a series of miRNAs transcriptionally regulated by vitamin D treatment within osteoblasts. Several miRNAs were validated in dose escalation experiments. Furthermore, downstream miRNA targets were appraised and found to regulate target message and protein levels. These findings were assessed in early and late passaged osteoblasts and found an age-dependent regulation of some miRNAs, while others were considered constituitiously expressed. Inhibitor studies of one key bone-related miRNA demonstrated the importance of this miRNA to regulate vitamin D-mediate osteoblastic differentiation during mineralizaition. Three independent sets of passage 8 primary human osteoblasts were either treated with vehicle (ethanol) or 1,25D3 (10nM) for 6 hours. Total RNA was collected using the miRNA Vana kit (ABI) and then quality assessed, and sent for miRNA array processesing.

Project description:Vitamin E (VitE) is essential for vertebrate embryogenesis, but the mechanisms involved remain unknown. To study embryonic development, we fed zebrafish adults (>55 days) either VitE sufficient (E+) or deficient (E-) diets for >80 days, then the fish were spawned to generate E+ and E- embryos. To evaluate the transcriptional basis of the metabolic and phenotypic outcomes, E+ and E- embryos at 12, 18 and 24 h post-fertilization (hpf) were subjected to gene expression profiling by RNASeq. Hierarchical clustering, over-representation analyses and gene set enrichment analyses were performed with differentially expressed genes. E- embryos experienced overall disruption to gene expression associated with gene transcription, carbohydrate and energy metabolism, intracellular signaling and the formation of embryonic structures. mTOR was apparently a major controller of these changes. Thus, embryonic VitE deficiency results in genetic and transcriptional dysregulation as early as 12 hpf, leading to metabolic dysfunction and ultimately lethal outcomes.

Project description:Vitamin C (ascorbic acid, AA) is a well-known regulator of bone and cartilage metabolism. However, the mechanisms of AA's action in these tissues are only partly understood. In this study, we confirmed that AA contributes to bone and cartilage metabolism by showing decreased articular cartilage and trabecular bone in AA-deficient spontaneous fracture (sfx) mutant mice. In vitro, we found that AA exerts differential effects on chondrocyte and osteoblast differentiation. Since AA is known to increase levels of 5-hydroxymethylcytosine (5-hmC) and induce DNA demethylation via the ten-eleven translocases (TETs), and since prolyl hydroxylase domain-containing protein 2 (PHD2), a known mediator of AA's effects in these tissues, is part of the same enzyme family as the TETs, we next investigated whether increases in 5-hmC might mediate some of these effects. All TETs and PHDs are expressed in chondrocytes and osteoblasts, and PHD2 is localized in both the cytoplasm and nucleus of the cell, lending plausibility to the hypothesis of altered 5-hmC content in these cells. We found that AA treatment increased levels of 5-hmC in both cell types globally, notably including promoter regions of osteoblast differentiation genes. Furthermore, inhibition of PHD2 decreased 5-hmC levels in chondrocyte differentiation gene promoters, and knockdown of Phd2 in chondrocytes reduced global 5-hmC levels, suggesting for the first time that PHD2 may itself directly mediate increases in 5-hmC in chondrocyte and osteoblast genes. Further investigation of this mechanism could lead to novel therapeutic approaches to treat debilitating diseases such as osteoarthritis and osteoporosis.

Project description:Background:Fibroblast growth factor receptor 2 (FGFR2) play a vital role in skeletogenesis. However, the molecular mechanisms triggered by FGFR2 in osteoblasts are still not fully understood. In this study, proteomics and bioinformatics analysis were performed to investigate changes in the protein profiles regulated by FGFR2, with the goal of characterizing the molecular mechanisms of FGFR2 function in osteoblasts. Methods:In this study, FGFR2-overexpression cell line was established using the lentivirus-packaging vector in human osteoblasts (hFOB1.19). Next, the isobaric tags for relative and absolute quantitation (iTRAQ) in combination with the liquid chromatography-tandem mass spectrometry (LC-MS/MS) method was used to compare the proteomic changes between control and FGFR2-overexpression cells. Thresholds (fold-change of???1.5 and a P-value of?<?0.05) were selected to determine differentially expressed proteins (DEPs). The bioinformatics analysis including GO and pathway analysis were done to identify the key pathways underlying the molecular mechanism. Results:A Total of 149 DEPs was identified. The DEPs mainly located within organelles and involved in protein binding and extracellular regulation of signal transduction. ColI, TNC, FN1 and CDKN1A were strikingly downregulated while UBE2E3, ADNP2 and HSP70 were significantly upregulated in FGFR2-overexpression cells. KEEG analysis suggested the key pathways included cell death, PI3K-Akt signaling, focal adhesion and cell cycle. Conclusions:To our knowledge, this is the first protomic research to investigate alterations in protein levels and affected pathways in FGFR2-overexpression osteoblasts. Thus, this study not only provides a comprehensive dataset on overall protein changes regulated by FGFR2, but also shed light on its potential molecular mechanism in human osteoblasts.

Project description:Background:Nonsteroidal anti-inflammatory drugs (NSAIDs) are frequently used in clinical practice, which can have adverse effects on the osteoblast. The objective of this study was to determine the effect of NSAIDs on the osteoblast by analyzing the gene expression of different markers related to osteoblast maturation and function when treated in vitro with different NSAIDs. Methods:Three human osteoblast lines from bone samples of three healthy volunteers were treated with 10 µM acetaminophen, indomethacin, ketoprofen, diclofenac, ibuprofen, ketorolac, naproxen, and piroxicam. The gene expression of different markers (run related transcription factor 2 [RUNX-2], type 1 collagen [COL-I], osterix [OSX], osteocalcin [OSC], bone morphogenetic protein 2 [BMP-2] and 7 [BMP-7], transforming growth factor ?1 [TGF-?1], and TGF? receptors [TGF?R1, TGF?R2; TGFBR3]) were analyzed by real-time PCR at 24 h of treatment. Results:Expression of RUNX-2, COL-I, OSX, was reduced by treatment with all studied NSAIDs, OSC expression was reduced by all NSAIDs except for ketoprofen, naproxen, or piroxicam. Expression of BMP-7 was reduced by all NSAIDs; BMP-2 was reduced by all except for naproxen. In general, NSAID treatment increased the expression of TGF-?1, but not of its receptors (TGF?-R1, TGF?-R2, andTFG?-R3), which was either unchanged or reduced by the treatment. Conclusion:These data confirm that NSAIDs can affect osteoblast physiology, suggesting their possible impact on bone.

Project description:Vitamin E (VitE) is essential for vertebrate embryogenesis, but the mechanisms involved remain unknown. To study embryonic development, we fed zebrafish adults (>45 days) either VitE sufficient (E+) or deficient (E–) diets for >80 days, then the fish were spawned to generate E+ and E– embryos. To evaluate the transcriptional basis of the metabolic and phenotypic outcomes, E+ and E– embryos at 12-, 18- and 24 hours post-fertilization (hpf) were subjected to gene expression profiling by RNASeq. Hierarchical clustering, over representation analyses and gene set enrichment analyses were performed with differentially expressed genes. E– embryos experienced overall disruption to gene expression associated with gene transcription, metabolism, intracellular signaling and the formation of embryonic structures. Thus, the apparently moderate changes in lipid peroxidation and metabolic alterations due to VitE deficiency result in major genetic and transcriptional dysregulation as early as 12 hpf, leading to metabolic dysfunction and ultimately lethal outcomes.

Project description:INTRODUCTION: Bone remodelling and increased subchondral densification are important in osteoarthritis (OA). Modifications of bone vascularisation parameters, which lead to ischemic episodes associated with hypoxic conditions, have been suspected in OA. Among several factors potentially involved, leptin and dickkopf-related protein 2 (DKK2) are good candidates since they are up-regulated in OA osteoblasts (Obs). Therefore, in the present study, we investigated the hypothesis that hypoxia may drive the expression of leptin and DKK2 in OA Obs. METHODS: Obs from the sclerotic portion of OA tibial plateaus were cultured either under 20% or 2% oxygen tension in the presence or not of 50 nM of 1,25-dihydroxyvitamin D3 (VitD3). The expression of leptin, osteocalcin, DKK2, hypoxia-inducible factors (Hif)-1? and -2? was measured by real-time polymerase chain reaction and leptin production by enzyme-linked immunosorbent assay (ELISA). The expression of Hif-1?, Hif-2?, leptin and DKK2 was reduced using silencing (si) RNA technique. Signalling pathway of hypoxia-induced leptin was investigated by western blotting and mitogen-activated protein kinase (MAPK) inhibitors. RESULTS: As expected, hypoxia stimulated the expression of Hif-1 and Hif-2. The expression of leptin and DKK2 in Obs was also stimulated 7-fold and 1.8-fold respectively (p<0.05) under hypoxia. Interestingly, whereas VitD3 stimulated leptin and DKK2 expression 2- and 4.2-fold under normoxia, it further stimulated it to 28- and 6.2-fold under hypoxia (p<0.05). The hypoxia-induced leptin production was confirmed by ELISA, particularly in presence of VitD3 (p<0.02). Compared to Obs incubated in the presence of siScramble RNAs, siHif-2? inhibited VitD3-stimulated leptin mRNA and protein levels by 70% (p=0.004) and 60% (p<0.02), respectively while it failed to significantly alter the expression of DKK2. SiHif-1? has no effect on these genes. Immunoblotting showed that VitD3 greatly stabilized Hif-2? under hypoxic condition. The increase in leptin expression under hypoxia was also regulated, in addition to the role of Hif-2?, by p38 MAPK (p<0.03) and PI 3-kinase (p<0.05). Finally, we demonstrated that the expression of leptin and DKK2 were not related to each other under hypoxia. CONCLUSIONS: Hypoxic conditions via Hif-2 regulation trigger Obs to produce leptin particularly under VitD3 stimulation whereas DKK2 is mainly regulated by VitD3 rather than hypoxia.

Project description:Genomic actions induced by 1alpha25-dihydroxyvitamin D(3) [1,25(OH)(2)D(3)] are crucial for normal bone metabolism, mainly because they regulate active intestinal calcium transport. To evaluate whether the vitamin D receptor (VDR) has a specific role in growth-plate development and endochondral bone formation, we investigated mice with conditional inactivation of VDR in chondrocytes. Growth-plate chondrocyte development was not affected by the lack of VDR. Yet vascular invasion was impaired, and osteoclast number was reduced in juvenile mice, resulting in increased trabecular bone mass. In vitro experiments confirmed that VDR signaling in chondrocytes directly regulated osteoclastogenesis by inducing receptor activator of NF-kappaB ligand (RANKL) expression. Remarkably, mineral homeostasis was also affected in chondrocyte-specific VDR-null mice, as serum phosphate and 1,25(OH)(2)D levels were increased in young mice, in whom growth-plate activity is important. Both in vivo and in vitro analysis indicated that VDR inactivation in chondrocytes reduced the expression of FGF23 by osteoblasts and consequently led to increased renal expression of 1alpha-hydroxylase and of sodium phosphate cotransporter type IIa. Taken together, our findings provide evidence that VDR signaling in chondrocytes is required for timely osteoclast formation during bone development and for the endocrine action of bone in phosphate homeostasis.