Project description:Vasculogenic Precedes Neurogenic Differentiation in DPSC Transplanted into Root Canals

Project description:To further reveal the regulatory mechanism of melatoin-mediated odontoblastic differentiation during tooth development, we have employed whole genome microarray expression profiling as a discovery platform to identify genes with the potential to modulate melatonin-induced odontoblastic differentiation. Rat dental papilla cells were primary cultured from PN1-3 tooth germ tissue, and treated with melatonin at the concentration of 10-8M for 3 days along with odontoblastic differentiation induction medium (OS). Current microarray analysis generally profiled a total of 181 upregulated genes and 580 downregulated genes between two groups.

Project description:To evaluate the miRNA and mRNA expression profiles (miRNOME and transcriptome) we reconstructed networks identifying miRNAs and mRNA during in vitro osteogenic differentiation of human dental pulp stem cells (DPSC). The DPSCs were cultured in the DMEM + beta-glycerol phosphate, ascorbic acid and dexamethasone for 2 to 21 days. The microRNA or mRNA expression profiling during the differentiation process was analyzed through hybridizations with Agilent miRNA-microarray (8x15K format) or whole-human genome Agilent microarray (4x44K format).

Project description:Neoplastic transformation of DPSC cultured under Hypoxia versus normoxia. Molecular characterization of cell markers associated with tumorigenicity. DPSC array CGH profiles of experimental (HX48h and HX72h) and reference (NX48 and NX72h) genomic DNA samples

Project description:Stem cell-based therapy is an alternative strategy for brain repair. Various cell types have been investigated and dental pulp stem cells (DPSC) have been identified as promising candidates. These multipotent stem cells are found in the dental pulp tissue of molar teeth. They are clinically easily obtained, have a high proliferative rate, and possess neurogenic potential due to their mesoectodermal origin. Here, overexpression of octamer-binding transcription factor 4 (OCT4) in combination with neural conditions was used to reprogram human DPSC along the neural lineage. Transcriptomic analysis of differentially-expressed genes highlighted the expression of genes associated with neural and neuronal functions in the OCT4-overexpressing DPSC following neural induction.

Project description:This study focuses on the impact of ECM (extra-cellular matrix) over cell processes such as proliferation, differentiation or mineralization which is more specifically related to our dental pulp cells. We cultured these dental pulp stem cells (DPSC) in mineralization growth or normal growth conditions. After 21 days, cells were incubated in decellularized solution until no intact cells are seen. After ECM was washed, we studied the mineralization associated to these two different ECM. Matrisome proteins were identified through proteomics. DPSC matrisome is composed of 225 individual different proteins. We classified them according to different categories, the 3 core matrisome categories: glycoproteins, collagens, proteoglycans and the 3 matrisome associated proteins categories: the regulators, affiliated and secreted. When comparing the proteins in the N-ECM and OM-ECM, most of the core matrisome proteins are downregulated in OM conditions, except 3 glycoproteins, as well as regulators and secreted factors. However, annexins were found to be upregulated in OM condition. Cell adhesion, tensile strength and growth factor binding are over-represented in NM ECM. The collagen group and glycoproteins were higher in N-ECM than OM-ECM Thereafter, gingival stem cells (GSC), the less inherit osteogenic potency cells, were seeded on these N-ECM and OM-ECM. When GSCs were seeded on DPSC-derived ECM, the OM-ECM dramatically promoted mineral deposition compared with N-ECM. We hypothesize that annexins could participate in the osteogenic inductive properties. ECM plays a pivotal role in many physiological processes, it regulates cells behavior and can orient cell differentiation. Dental pulp and oral mucosa share embryological origins but differ in their reactions to insults. Dental pulp can mineralize while oral mucosa heals ad integrum. We hypothesize that ECM participate in these characteristics.

Project description:A major challenge to the study and treatment of neurogenetic syndromes is the difficulty in gaining access to live neurons from individuals with these disorders. Although other sources of stem cells are currently available for differentiation into neurons, these can involve invasive procedures and be difficult or expensive to generate limiting their use on a broad scale, especially for rare syndromes which may not be well represented in the local population. Dental pulp stem cells (DPSC) are neural crest derived multipotent stem cells that reside deep the pulp of shed (baby) teeth and have the potential for broad use in the study of neurogenetic disease. In order to investigate the characteristics of DPSC which make them a valuable resource for the study of neurogenetic syndromes we performed a set of viability, senescence and immortalization studies on control DPSC and DPSC derived neurons. We investigated the basic transport conditions and determined the maximum passage number for primary DPSCs. We then immortalized control DPSC using human telomerase reverse trancriptase (hTERT) and evaluated both neuronal differentiation potential and gene expression changes using RNAseq. Here we show that immortalized DPSC share morphological and electrophysiological properties with non-immortalized DPSC. We also show that differentiation of DPSC into neurons changes gene expression for 1305 transcripts, while immortalized neurons differ significantly in gene expression for 183 transcripts of which 94 also changed during differentiation. Taken together, these studies indicate that immortalized dental pulp derived neruons may be a new and powerful resource for the study of rare neurological disorders where patient samples are rare or difficult to obtain. RNA-seq Analysis of 3 neurotypical control DPSC, 3 DPSC derived neurons and 3 each immortalized versions of DPSC and DPSC neurons (~3 weeks post maturation)

Project description:Neoplastic transformation of DPSC cultured under Hypoxia versus normoxia. Molecular characterization of cell markers associated with tumorigenicity.

Project description:Deep proteomics to analyze protein changes during hiPSC differentiation into neurons (iN) 18 days after Ngn2 induction. hiPSC in triplicatas (21 fractions each) iN in triplicates (21 fractions each) Total of 126 raw data files.

Project description:The use of pluripotent stem cells in regenerative medicine and disease modeling is complicated by the variation in differentiation properties between lines. In this study, we characterized 13 human embryonic stem cell. (hESC) and 26 human induced pluripotent stem cell (hiPSC) lines to identify markers that predict neural differentiation behavior. At a general level, markers previously known to distinguish mouse ESCs from epiblast stem cells (EpiSCs) correlated with neural differentiation behavior. More specifically, quantitative analysis of miR-371-3 expression prospectively identified hESC and hiPSC lines with differential neurogenic differentiation propensity and in vivo dopamine neuron engraftment potential. Transient KLF4 transduction increased miR-371-3 expression and altered neurogenic behavior and pluripotency marker expression. Conversely, suppression of miR- 371-3 expression in KLF4-transduced cells rescued neural differentiation propensity. miR-371-3 expression level therefore appears to have both a predictive and a functional role in determining human pluripotent stem cell neurogenic differentiation behavior. [mRNA profiling (Illumina)]: Four human ESC lines (H9, I4, I6, HUES6) at undifferentiation stages were purified with stem cell surface marker SSEA4 and subjected to RNA extraction and hybridization on Illumina microarrays. Each sample has 3 biological repeats, one of which has two technical repeats. [miRNA profiling (Agilent)]: Four human ESC lines (H9, I4, I6, HUES6) at undifferentiation stages were purified with stem cell surface marker SSEA4 and subjected to RNA extraction and hybridization on Agilent microarrays. Each sample has 3 biological repeats, one of which has two technical repeats.