Project description:Purpose: Human Embryonic Stem Cell (hESC)-derived insulin-producing beta cells offer a promising cell-based therapy for diabetes. However, efficient hESC to beta cell differentiation has proven difficult, possibly due to the lack of cross-talk with the appropriate mesenchymal niche. To define organ-specific niche signals, we isolated pancreatic and gastrointestinal stromal cells and analyzed their transcriptomes during development. Methods: mRNA profiles from E13.5 mice were generated from mesenchymal cells dissected from wild-type (WT) intestine, stomach, pancreas and mutant Sufu-/- Spop -/- pancreatic mesenchyme, in duplicate, by illumina HiSeq 2500. Reads were aligned to the mm10 assembly and unambiguously mapping reads were analyzed at the gene level for differential expression between tissue types alignment using STAR and differential analysis using DESeq2. Results: Using our workflow, we mapped about 30 million reads per sample to mm10. Differential expression (DE) analysis identified over 900 significantly differentially expressed genes between WT pancreatic mesenchyme and gastrointestinal mesenchymes, and over 1100 genes differentially expressed between WT and mutant pancreatic mesenchyme. Our findings reveal the importance of tightly-regulated Hh signaling in the pancreatic mesenchyme. In vivo inactivation of mesenchymal Hh signaling leads to annular pancreas, and stroma-specific activation of Hh signaling via loss of Hh regulators, Sufu and Spop, impairs pancreatic growth and beta cell genesis. Genetic rescue and transcriptome analyses show that these Sufu and Spop knockout defects occur through GLI2-mediated activation of gastrointestinal stromal signals such as Wnt ligands. Importantly, inhibition of Wnt signaling in organoid and hESC cultures significantly promotes insulin-producing cell generation, revealing the requirement for organ-specific regulation of stromal niche signals.

Project description:SUFU and SPOP mediated downregulation of Hh signaling promotes pancreatic beta-cell differentiation through the regulation of organ-specific stromal niche signals

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Project description:This SuperSeries is composed of the SubSeries listed below.

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Project description:A single-cell transcriptional analysis was performed on GLI2+ stromal cells from the adult murine lung. Whole adult murine lung tissue was dissociated to single cells and subjected to fluorescence activated cell sorting (FACS) to select all live GLI2+ cells. The single cell RNA-sequencing library was then subsequently generated. Cells were sequenced at a depth of ~60,000 reads/cell. We captured approximately 4,600 cells with a median of 2,246 genes detected per cell utilizing a droplet-based barcoding approach to capture single cells for RNA sequencing. The results demonstrate that the GLI2+ population is segregated into distinct stromal subtypes along the proximal-distal axis of the lung with distinct functional contribution to matrix production and paracrine signaling within their distinctive niche.

Project description:We disrupted the spatial Hh activation gradient in murine lung by inducing the constitutively active form of the Hh effector, Smo (SmoM2), throughout the entire GLI2+ stroma and performed RNA-seq on the bulk GLI2+ population. Whole adult murine lung tissue was dissociated to single cells and subjected to fluorescence activated cell sorting (FACS) to select all live GLi2+ cells. The bulk RNA-sequencing library was then subsequently generated. Cells were sequenced at a depth of average of 45 million reads/sample. The results reveal that expansion of Hh activation in the GLI2+ domain in the murine lung resulted in upregulation of genes that are expressed in the proximal stroma fibroblasts. Conversely, Hh activation downregulated genes enriched in the distal stroma as well as mesothelial cells.