Project description:We found that hepatocytes isolated from adult mouse livers can dedifferentiate into progenitor-like cells and exhibit a hybrid epithelial/mesenchymal phenotype in monolayer culture. dediHeps can re-differentiate into mature hepatocytes by forming aggregates and fetal intestinal progenitor cells (FIPCs) by forming organoids in three-dimensional culture. We conducted RNA-seq analyses to investigate the characteristincs of hepatocytes, dediHeps, dediHep aggregates, dediHep derived spherical organoids, dediHep derived budding organoids, FIPC derived spherical organoids, intestinal stem cell (ISC) derived budding organoids, and CLiP cells (Katsuda, 2016).

Project description:The purpose of this study was to characterise iPSC-derived human intestinal epithelial organoids (iPSCo) by comparing these cultures with primary purified intestinal epithelial cells (IEC). Intestinal epithelial organoid (IEO) cultures were derived from at least three different lines of iPSCs, RNA was extracted and gene expression was profiled using RNA-sequencing. We compared these profiles with datasets we have previously derived from purified IEC from mature terminal ileum (TI) and sigmoid colon (SC) as well as human fetal proximal gut (FPG) and fetal distal gut (FDG).

Project description:Immortal spheroids were generated from fetal mouse intestine using the culture system developed to culture organoids from adult intestinal epithelium. Spheroids are made of a monostratified polarized epithelium displaying a poorly differentiated intestinal phenotype. The proportion of spheroids generated from intestinal explants progressively decreases from fetal to postnatal period, with a corresponding increase in production of organoids. Spheroid cells show indefinite self-renewing properties but exhibit a transcriptome strikingly different from that of adult intestinal stem cells reminiscent of incompletely caudalized progenitors. The receptor Lgr4, but not Lgr5, is essential for their growth. Trop2/Tacstd2 and Cnx43/Gja1, two markers highly enriched in spheroids, are expressed throughout the E14 intestinal epithelium. Comparison of in utero and neonatal lineage tracing using Cnx43-CreER and Lgr5-CreERT2 mice identified spheroid-generating cells as developmental progenitors involved in generation of the prenatal intestinal epithelium. Ex vivo, spheroid cells have the potential to differentiate into organoids, thus qualifying them as a new type of intestinal stem-like cells. Two-channel microarray experiments were performed from spheroid/organoid pairs isolated each from a given embryo. Following initial seeding of small intestine from a given embryo/mouse (at E16, E18 or P0), spheroids and organoids were selectively picked up for each animal and replated for 3 passages to reach sample homogeneity. Hybridization was performed on the 4 independent pairs with dye-swap.

Project description:The purpose of this study was to characterise iPSC-derived human intestinal epithelial organoids (iPSCo) by comparing these cultures with primary purified intestinal epithelial cells (IEC). Intestinal epithelial organoid (IEO) cultures were derived from at least three different lines of iPSCs, DNA was extracted and gene expression was profiled using Illumina Infinium HumanMethylation450Beadarray. We compared these profiles with datasets we have previously derived from purified IEC from mature terminal ileum (TI) and sigmoid colon (SC) as well as human fetal proximal gut (FPG) and fetal distal gut (FDG).

Project description:Here we profiled fetal intestinal epithlelium derived organoids at day 3 (group1) and 30 (group2) of culture, adult orgnanoids at day 3 (group3) and 30 (group4) of culture and whole intestinal tissues at P0(group5) and adult (group6).

Project description:Development of intestinal organoids from single intestinal stem cells is driven by the regenerative capacity of the intestinal epithelium. To unravel molecular mechanisms orchestrating organoid formation and self-organization, we developed a high-content image-based screening assay for an annotated compound library. We generated multivariate feature profiles for hundreds of thousands of individual organoids to quantitatively describe the phenotypic landscape of organoid development. Generated phenotypic fingerprints were then used to infer regulatory genetic interactions from a single screen, establishing a novel paradigm in genetic interaction screening applied to an emergent system. This allowed the identification of novel modules of genes that regulate cell identity transitions and maintain the balance between regeneration and homeostasis. We then characterized a crucial role of retinoic acid nuclear receptors in controlling the exit from the regenerative state and in driving enterocyte differentiation. By combining quantitative imaging with RNA sequencing we confirmed the role of endogenous retinoic acid signaling and metabolism in initiating transcriptional programs guiding intestinal epithelium cell fate transitions and identified a small molecule inhibitor of retinoid x receptor, RXR, that improved intestinal regeneration in vivo. We use RNA sequencing to describe transcriptional changes induced in intestinal organoids cultured in presence of retinoic signaling modulators.

Project description:Immortal spheroids were generated from fetal mouse intestine using the culture system developed to culture organoids from adult intestinal epithelium. Spheroids are made of a monostratified polarized epithelium displaying a poorly differentiated intestinal phenotype. The proportion of spheroids generated from intestinal explants progressively decreases from fetal to postnatal period, with a corresponding increase in production of organoids. Spheroid cells show indefinite self-renewing properties but exhibit a transcriptome strikingly different from that of adult intestinal stem cells reminiscent of incompletely caudalized progenitors. The receptor Lgr4, but not Lgr5, is essential for their growth. Trop2/Tacstd2 and Cnx43/Gja1, two markers highly enriched in spheroids, are expressed throughout the E14 intestinal epithelium. Comparison of in utero and neonatal lineage tracing using Cnx43-CreER and Lgr5-CreERT2 mice identified spheroid-generating cells as developmental progenitors involved in generation of the prenatal intestinal epithelium. Ex vivo, spheroid cells have the potential to differentiate into organoids, thus qualifying them as a new type of intestinal stem-like cells.

Project description:Mechanisms underlying human hepatocyte growth in development and regeneration are incompletely understood. In vitro, human fetal hepatocytes (FH) can be robustly grown as organoids, while adult primary human hepatocyte (PHH) organoids remain difficult to expand, suggesting different growth requirements between fetal and adult hepatocytes. Here, we characterize hepatocyte organoid outgrowth using temporal transcriptomic and phenotypic approaches. FHs initiate reciprocal transcriptional programs involving increased proliferation and repressed lipid metabolism upon initiation of organoid growth. We exploited these insights to design maturation conditions for FH organoids, resulting in acquisition of mature hepatocyte morphological traits and increased expression of functional markers. During PHH organoid outgrowth in the same culture condition, the adult transcriptomes initially mimic the fetal transcriptomic signatures, but PHHs rapidly acquire disbalanced proliferation-lipid metabolism dynamics, resulting in steatosis and halted organoid growth. IL6 supplementation, as emerged from the fetal dataset, and simultaneous activation of the metabolic regulator FXR, prevents steatosis and promotes PHH proliferation, resulting in improved expansion of the derived organoids. Single-cell RNA sequencing analyses reveal preservation of their fetal and adult hepatocyte identities in the respective organoid cultures. Our findings uncover mitogen requirements and metabolic differences determining proliferation of hepatocytes changing from development to adulthood.

Project description:Mechanisms underlying human hepatocyte growth in development and regeneration are incompletely understood. In vitro, human fetal hepatocytes (FH) can be robustly grown as organoids, while adult primary human hepatocyte (PHH) organoids remain difficult to expand, suggesting different growth requirements between fetal and adult hepatocytes. Here, we characterize hepatocyte organoid outgrowth using temporal transcriptomic and phenotypic approaches. FHs initiate reciprocal transcriptional programs involving increased proliferation and repressed lipid metabolism upon initiation of organoid growth. We exploited these insights to design maturation conditions for FH organoids, resulting in acquisition of mature hepatocyte morphological traits and increased expression of functional markers. During PHH organoid outgrowth in the same culture condition, the adult transcriptomes initially mimic the fetal transcriptomic signatures, but PHHs rapidly acquire disbalanced proliferation-lipid metabolism dynamics, resulting in steatosis and halted organoid growth. IL6 supplementation, as emerged from the fetal dataset, and simultaneous activation of the metabolic regulator FXR, prevents steatosis and promotes PHH proliferation, resulting in improved expansion of the derived organoids. Single-cell RNA sequencing analyses reveal preservation of their fetal and adult hepatocyte identities in the respective organoid cultures. Our findings uncover mitogen requirements and metabolic differences determining proliferation of hepatocytes changing from development to adulthood.

Project description:This experiment is designed to test if differentiation is altered upon depletion of either Smarcc1 or Smarca4