Project description:Directional flow-mediated mesenchymal force drives epithelial tube constriction and splitting

Project description:The signaling crosstalk between the tracheal mesenchyme and epithelium has not been researched extensively leaving a substantial gap of knowledge in the mechanisms dictating embryonic development of the proximal airways by the adjacent mesenchyme. Recently, we have reported that embryos lacking mesenchymal expression of Sox9 did not develop tracheal cartilage rings and showed aberrant differentiation of the tracheal epithelium. Herein, we propose that tracheal cartilage provides local inductive signals responsible for the proper differentiation, metabolism, and inflammatory status regulation of the tracheal epithelium. The tracheal epithelium of mesenchyme-specific Sox9D/D mutants showed altered mRNA expression of various epithelial markers such as Pb1fa1, Sftpb, Scgb1a1, and Tff-1. In vitro tracheal epithelial cell cultures confirmed that tracheal chondrocytes secrete factors that inhibit club cell differentiation. Whole gene expression profiling and ingenuity pathway analysis showed that the TNF-a, IFN-g and TGF-b signaling pathways were significantly altered in the Sox9 mutant trachea. Tnf-a and Ifn-g interfered with the differentiation of tracheal epithelial progenitor cells into mature epithelial cell types in vitro. Meanwhile, mesenchymal knockout of Tgf-b1 in vivo resulted in altered differentiation of the tracheal epithelium. Finally, mitochondrial enzymes involved in fat and glycogen metabolism Cox8b and Cox7a1 were strongly up-regulated in the Sox9 mutant trachea, with consequently increased number and size of glycogen storage vacuoles. Our results support an a role for tracheal cartilage in the modulation of the differentiation and metabolism, and the expression of inflammatory related genes in the tracheal epithelium by feeding into the TNF-a, IFN-g and TGF-b signaling pathways.

Project description:Mechanical force has been shown to regulate periodontal ligament cells (PDLs) behaviors. However, different force types lead to distinct PDLs’ responses. Here, the differential gene expression profiling of PDLs subjected to static and intermittent compressive forces was examined using RNA sequencing technique. Results demonstrated that the static and intermittent compressive force treated PDLs exhibited the differential regulation genes. KEGG pathway enrichment analysis revealed that focal adhesion and transforming growth factor beta signaling pathway were commonly upregulated while calcium signaling pathway was downregulated in both static and intermittent compressive force-treated PDLs. Interestingly, Wnt signaling pathway was upregulated only in the PDLs that subjected to the intermittent compressive force.

Project description:To explore the lncRNA landscape of periodontal ligament stem cells (PDLSCs) subjected to compressive force.

Project description:This file contains a 136-node modular Boolean network model of EMT triggered by biomechanical and growth signaling crosstalk, linked to a published network of epithelial contact inhibition, proliferation, and apoptosis (MODEL2006170001). This model reproduces the ability of the core EMT transcriptional network to maintain distinct epithelial, hybrid E/M and mesenchymal states, as well as EMT driven by mitogens such as EGF on stiff ECM. We also reproduce the observed lack of stepwise MET, in that our model's dynamics does not pass through the hybrid E/M state during MET. We show that in the absence of strong autocrine signals such as TGFβ (not included in this version), cells cannot maintain their mesenchymal state in the absence of mitogens, on softer matrices, or at high cell density.

Project description:The conducting airway epithelium of the rodent and human lung is underlaid by mesenchymal cells that include vasculature, smooth muscle, fibroblasts and cartilage. The goal of this project is to identify cellular and molecular changes in the mesenchyme after injury to the epithelium by exposure to SO2 and which may participate in repair of the epithelium We used Affymetrix microarray analysis to compare transcripts in tracheal mesenchyme before and after SO2 injury. Mice tracheal epithelium and mesenchyme were separate for RNA extraction before and 48hrs after SO2 injury. Sample from 4 mice were pooled for each biological experiment. The experiments were repeated three times for triplicate samples.

Project description:In the small intestine (SI), regionalisation enables sequential processing of food and nutrient absorption. To characterise the basis for region-specific mesenchymal-epithelial crosstalks during late small intestinal morphogenesis, we combined transcriptional profiling of epithelial and mesenchymal cell populations isolated from different intestinal regions with ChIP-seq, 3D imaging and functional ex vivo and organoid studies. We find that a mesenchymal PDGFRA-high population located in close proximity to the developing epithelium is enriched for genes involved in signalling and support the epithelium in a region-specific manner via the establishment of a proximal to distal gradient of epithelial Wnt activity. Furthermore, we provide evidence that Wnt signalling in the distal SI directly regulates epithelial expression of Sonic Hedgehog (SHH), which in turn acts on mesenchymal cells driving villi formation. Our results therefore uncover a mechanistic link between Wnt and Hedgehog signalling across different cellular compartments central for anterior-posterior regionalisation and correct organ formation.

Project description:Mechanical force regulates various biological responses in many cell types. Here, the retinoic acid treated mouse gingival fibroblast derived induced pluripotent stem cells were treated with intermittent compressive for 24 h and gene expression profiling was evaluated using RNA sequencing technique. Results indicated that intermittent compressive stress regulated various pathways in these cells including p53 signaling and other metabolic pathways.

Project description:This model is an expansion of the Regan2022 - Mechanosensitive EMT model (MODEL2208050001); it includes a TGFβ signaling module and autocrine signaling in mesenchymal cells. The expanded 150-node (630 link) modular model undergoes EMT triggered by biomechanical and growth signaling crosstalk, or by TGFβ. As its predecessor, this model also reproduces the ability of the core EMT transcriptional network to maintain distinct epithelial, hybrid E/M and mesenchymal states, as well as EMT driven by mitogens such as EGF on stiff ECM. We also reproduce the observed lack of stepwise MET, in that our model's dynamics does not pass through the hybrid E/M state during MET. We show that in the absence of strong autocrine signals such as TGFβ (not included in this version), cells cannot maintain their mesenchymal state in the absence of mitogens, on softer matrices, or at high cell density. In contrast, potent autocrine signaling can stabilize the mesenchymal state in all but very dense monolayers on soft ECM. This expanded model also reproduces the inhibitory effects of TGFβ on proliferation and anoikis resistance in mesenchymal cells, as well as its ability to trigger apoptosis on soft ECM vs. EMT on stiff matrices. The model offers several experimentally testable predictions related to the effect of neighbors on partial vs. full EMT, the tug of war between mitosis and the maintenance of migratory hybrid E/M states, as well as cell cycle defects in dynamic, heterogeneous populations of epithelial, hybrid E/M and mesenchymal cells.

Project description:Yin Yang 1 (YY1) is a multifunctional zinc-finger-containing transcription factor that plays crucial roles in numerous biological processes by selectively activating or repressing transcription, depending upon promoter contextual differences and specific protein interactions. In mice, Yy1 null mutants die early in gestation while Yy1 hypomorphs die at birth from lung defects. We studied how the epithelial-specific inactivation of Yy1 impacts on lung development. The Yy1 mutation in lung epithelium resulted in neonatal death due to respiratory failure. It impaired tracheal cartilage formation, altered cell differentiation, abrogated lung branching, and caused airway dilation similar to those seen in human congenital cystic lung diseases. The cystic lung phenotype in Yy1 mutants can be explained by the reduced expression of Shh in lung endoderm, a transcriptional target of YY1, and the subsequent derepression of mesenchymal Fgf10 expression. Accordingly, SHH supplementation partially rescued the lung phenotype in vitro. Analysis of human lung tissues revealed decreased YY1 expression in children with pleuropulmonary blastoma (PPB), a rare pediatric lung tumor arising during fetal development and associated with DICER1 mutations. No evidence for a potential genetic interplay between murine Dicer and Yy1 genes during lung morphogenesis was observed. However, the cystic lung phenotype resulting from the epithelial inactivation of Dicer function mimics the Yy1 lung malformations with similar changes in Shh and Fgf10 expression. Together, our data demonstrate the critical requirement for YY1 in lung morphogenesis and identify Yy1 mutant mice as a potential model for studying the genetic basis of PPB.