Project description:Purpose : This study was performed to investigate the changes in gene expression in periodontal ligament (PDL) cells between normal occlusal function and hypofunction through RNA sequencing and elucidate the related role in maintaining the PDL homeostasis. Method : Premolars extracted for orthodontic treatment were used. The teeth with occlusal contact for control group (n=17), teeth without occlusal contact for experienment group (n=17). After the PDL cells were isolated from the extracted teeth, differentially expressed gene (DEG) analysis, and real-time PCR were performed to compare the two groups. The effect of Bardet-Biedl syndrome 7 (BBS7) knockdown was evaluated by RT-qPCR, Wound healing assay, and Tubule formation assay. Result : We detected that the expression of BBS7 was downregulated in occlusal hypofunctional PDL through RNA-sequencing. Sonic Hedgehog signaling (Shh) activity was closely associated with BBS7 expression in periodontal ligament cells. In addition, the cell migration and angiogenesis were also suppressed by BBS7 knockdown in vitro. Conclusion : We suggest that BBS7 plays an essential role in maintaining Shh signaling activity for PDL homeostasis.

Project description:There are histological and functional differences between human deciduous and permanent pediodontal ligament (PDL) tissues. The purpose of this study was to determine the differences between these two types of tissue at the molecular level by comparative gene expression analysis. PDL samples were obtained from permanent premolars (n=38) and anterior deciduous teeth (n=31) extracted from 40 healthy persons. Comparative cDNA microarrary analysis revealed several differences in gene expression between the deciduous and permanent PDL tissues.

Project description:Exploring the transcriptome heterogeneity of macrophages during orthodontic force-induced alveolar bone remodeling

Project description:The aim of this study was to evaluate and compare the gene expression profiles of dental follicle and periodontal ligament in humans, which can possibly explain their functions of dental follicle and PDL such as eruption coordination and stress resorption. That may apply this information to clinical problem like eruption disturbance and to periodontal tissue engineering. PDL samples were obtained from permanent premolars (n=11) and dental follicle samples were obtained during extraction of supernumerary teeth (n=4). Comparative cDNA microarray analysis revealed several differences in gene expression between permanent PDL and dental follicles.

Project description:The bulk RNA-seq dataset was generated for the cell lines below and used for two major purposes: 1. DEG analysis and GSEA analysis comparing IBN-R and IBN-S cells 2. DEG analysis and GSEA analysis comparing MCL cells with/without MI-2 treatment.

Project description:Human periodontal ligament (HPDL) is continuously exposed to mechanical stress in vivo. In this study, in utilizing DNA chips, we analyzed the influences of mechanical stress on the gene expression profile of HPDL cells in vitro. HPDL cells were obtained from extracted first premolars of individuals undergoing tooth extraction for orthodontic treatment. Then, HPDL cells were applied to a stretch apparatus. They were constantly stretched and relaxed at 0.5 Hz for 48hr with 110ï¼ force elongation. After the application of the cyclic tension force, total RNA was extracted. Then, in utilizing the DNA chips (Human Oligo 30K DNA Chip containing almost all human genes in the genome). We analyzed the differences of gene expression between the stretched and the non-stretched control HPDL cells The DNA chip analysis identified 17 up-regulated genes that showed at least 2-fold difference in their relative intensities between the stretched and the control. This result included the genes for the glutamate receptor binding protein: HOMER1, for the growth factor receptor: CNTFR, for the ECM remodeling protein: MMP15, for the protein interacting with calcineurin A: DSCR1, for the cytoskeletal protein: LRRFIP1, for the glutamate receptor: GRIN3A and some novel genes. On the basis of these data, we suggest that mechanical stress, in other words in vivo occlusal force, may affect the functions of HPDL cells Gene expression profiles were constructed using Human Oligo DNA Chip 30K (Hitachi software engineering) in human periodontal ligament cells (The 48-h stretched and the 48-h non-stretched, control).

Project description:Human periodontal ligament (HPDL) is continuously exposed to mechanical stress in vivo. In this study, in utilizing DNA chips, we analyzed the influences of mechanical stress on the gene expression profile of HPDL cells in vitro. HPDL cells were obtained from extracted first premolars of individuals undergoing tooth extraction for orthodontic treatment. Then, HPDL cells were applied to a stretch apparatus. They were constantly stretched and relaxed at 0.5 Hz for 48hr with 110％ force elongation. After the application of the cyclic tension force, total RNA was extracted. Then, in utilizing the DNA chips (Human Oligo 30K DNA Chip containing almost all human genes in the genome). We analyzed the differences of gene expression between the stretched and the non-stretched control HPDL cells The DNA chip analysis identified 17 up-regulated genes that showed at least 2-fold difference in their relative intensities between the stretched and the control. This result included the genes for the glutamate receptor binding protein: HOMER1, for the growth factor receptor: CNTFR, for the ECM remodeling protein: MMP15, for the protein interacting with calcineurin A: DSCR1, for the cytoskeletal protein: LRRFIP1, for the glutamate receptor: GRIN3A and some novel genes. On the basis of these data, we suggest that mechanical stress, in other words in vivo occlusal force, may affect the functions of HPDL cells

Project description:The periodontal ligament (PDL), which connects the teeth to the alveolar bone, is essential for periodontal tissue homeostasis. Although the significance of the PDL is recognized, molecular mechanisms underlying PDL function are not well-known. We report that Mohawk homeobox (Mkx), a tendon-specific transcription factor, regulates PDL homeostasis by preventing its degeneration. Mkx is expressed in the mouse PDL at the age of 10 weeks and 12 months. In Mkx-/- mice, age-dependent expansion of the PDL at the maxillary 1st molar (M1) furcation area was observed. Transmission electron microscopy (TEM) revealed that Mkx-/- mice presented collagen fibril degeneration in PDL with age, while the collagen fibril diameter gradually increased in Mkx+/+ mice. PDL cells lost their shape in Mkx-/- mice, suggesting changes in PDL properties. Microarray and quantitative polymerase chain reaction (qPCR) analyses of Mkx-/- PDL revealed an increase in osteogenic gene expression and no change in PDL- and inflammatory-related gene expression. Additionally, COL1A1 and COL1A2 were upregulated in Mkx-overexpressing human PDL fibroblasts, whereas osteogenic genes were downregulated. Our results indicate that Mkx prevents PDL degeneration by regulating osteogenesis. Mohawk transcription factor is essential for homeostasis of the periodontal ligament by regulating osteogenic changes with age.

Project description:The epigenetic regulation on gene transcription affected by Electronic-cigarette (E-cig) to human gingival mesenchymal (GMSC) is not fully understood. Here, we collected GMSCs from systemically healthy patients due to the premolars and extracted for orthodontic reasons, and treated with E-cig smoke with original flavor (G2), E-cig smoke with menthol flavor (G3), E-cig liquid with original flavor (G4), and E-cig liquid with menthol flavor (G5) by the optimal conditions of LC50, and conducted H3K27me3 ChIP-seq to compare with untreated control (G0).

Project description:Physiological functions of periodontal ligament (PDL) include anchorage, force absorption,and proprioceptive information. Despite the knowledge about biology of PDL cells, there is a lack of information regarding the molecular signature of permanent (PermPDL) and deciduous (DecPDL) PDL tissues. The present study was designed to characterize the membrane proteome of DecPDL and PermPDL primary cells (n=6) by a label-free quantitative proteome.