Dental stem cells from human exfoliated deciduous teeth (SHED) and dental follicle cells (DFCs) are neural crest-derived stem cells from human dental tissues. Interestingly, SHED and DFCs can successfully differentiate into neuron-like cells. We hypothesized that SHED and DFCs have the same neural cell differentiation potentials. To evaluate neural cell differentiation, we cultivated SHED and DFCs in four different serum-replacement media (SRMs) and analyzed cell morphology, cell proliferation, and gene expression patterns before and after differentiation. In a standard cell culture medium, SHED and DFCs have not only similar cell morphologies, but they also have similar gene expression patterns for known stem cell markers. However, only SHED expressed the neural stem cell marker Pax6. After cultivation in SRMs, cell proliferations of DFCs and SHED were reduced and the cell morphology was spindle-like with long processes. However, differentiated DFCs and SHED had different neural cell marker expression patterns. For example, gene expression of the late neural cell marker microtubule-associated protein 2 was upregulated in DFCs and downregulated in SHED in SRM with the B27 supplement. In contrast, SHED formed neurosphere-like cell clusters in SRM with the B27 supplement, epidermal growth factor, and fibroblast growth factor-2. Moreover, SHED differentially expressed the glial cell marker glial fibrillary acidic protein, which in contrast was weakly or not expressed in DFCs. In conclusion, SHED and DFCs have different neural differentiation potentials under the same cell culture conditions.
Recently, osteogenic precursor cells were isolated from human dental follicles, which differentiate into cementoblast- or osteoblast-like cells under in vitro conditions after the induction with dexamethasone or insulin. However, mechanisms for osteogenic differentiation are not understood in detail. In a previous study, real-time RT-PCR results demonstrated molecular mechanisms in dental follicle cells (DFCs) during osteogenic differentiation that are different from those in bone-marrow-derived mesenchymal stem cells. We analysed gene expression profiles in DFCs before and after osteogenic differentiation with the Affymetrix GeneChip(R) Human Gene 1.0 ST Array. Transcripts of 98 genes were up-regulated after differentiation. These genes could be clustered into subcategories such as cell differentiation, cell morphogenesis, and skeletal development. Osteoblast-specific transcription factors like osterix and runx2 were constitutively expressed in differentiated DFCs. In contrast, the transcription factor ZBTB16, which promotes the osteoblastic differentiation of mesenchymal stem cells as an up-stream regulator of runx2, was differentially expressed after differentiation. Transcription factors NR4A3, KLF9 and TSC22D3, involved in the regulation of cellular development, were up-regulated as well. In conclusion, we present the first transcriptome of human DFCs before and after osteogenic differentiation. This study sheds new light on the complex mechanism of osteogenic differentiation in DFCs.
Irinotecan induces hepatic steatosis via autophagy impairment and inflammation via ERK activation. Sorafenib appears as a novel therapeutic option for the prevention and treatment of irinotecan-induced inflammation.
Human dental follicle cells (DFCs) are progenitor cells. Recent studies supposed that osteogenic differentiation of DFCs is controlled by growth factors such as BMP2 and IGF2, but their influence on the differentiation of DFCs has not been investigated in detail. We examined DFCs after the induction of osteogenic differentiation with BMP2, IGF2 and a standard osteogenic differentiation medium (ODM) with dexamethasone. The alkaline phosphatase (ALP) activity and the calcium accumulation demonstrated osteogenic differentiation after all treatments, but with the most effective differentiation by ODM. Interestingly, markers of the process of osteoblast differentiation were much higher up-regulated in BMP2- or IGF2-treated cells than in ODM-treated cells. To evaluate the reason of these differences, we compared genome-wide expression profiles at an early stage of differentiation. Chondroblast markers in BMP2-differentiated cells and general markers for cell differentiation/proliferation in IGF2-treated cells were significantly regulated. However, ODM-treated DFCs expressed late markers of osteogenic-differentiated DFCs such as the transcription factor ZBTB16 that is not expressed in BMP2- or IGF2-differentiated cells. Importantly, although the BMP-antagonist noggin (NOG) diminishes the phosphorylation of SMAD1 in DFCs, it did not inhibit osteogenic differentiation by ODM and the expression of ZBTB16. In conclusion, this study demonstrates that osteogenic differentiation of DFCs can be stimulated with all tested inducers but also independently of BMP signaling. To evaluate this mechanism, the transcription factor ZBTB16 is a target for further investigations.
Human dental follicle cells (DFCs) are progenitor cells. Recent studies supposed that osteogenic differentiation of DFCs is controlled by growth factors such as BMP2 and IGF2, but their influence on the differentiation of DFCs has not been investigated in detail. We examined DFCs after the induction of osteogenic differentiation with BMP2, IGF2 and a standard osteogenic differentiation medium (ODM) with dexamethasone. The alkaline phosphatase (ALP) activity and the calcium accumulation demonstrated osteogenic differentiation after all treatments, but with the most effective differentiation by ODM. Interestingly, markers of the process of osteoblast differentiation were much higher up-regulated in BMP2- or IGF2-treated cells than in ODM-treated cells. To evaluate the reason of these differences, we compared genome-wide expression profiles at an early stage of differentiation. Chondroblast markers in BMP2-differentiated cells and general markers for cell differentiation/proliferation in IGF2-treated cells were significantly regulated. However, ODM-treated DFCs expressed late markers of osteogenic-differentiated DFCs such as the transcription factor ZBTB16 that is not expressed in BMP2- or IGF2-differentiated cells. Importantly, although the BMP-antagonist noggin (NOG) diminishes the phosphorylation of SMAD1 in DFCs, it did not inhibit osteogenic differentiation by ODM and the expression of ZBTB16. In conclusion, this study demonstrates that osteogenic differentiation of DFCs can be stimulated with all tested inducers but also independently of BMP signaling. To evaluate this mechanism, the transcription factor ZBTB16 is a target for further investigations.
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