Project description:The capacity to generate functional hepatocytes from renewable human pluripotent stem cells (hPSCs) could address limited supplies of primary human hepatocytes. However, hepatocytes differentiated from hPSCs in vitro are functionally immature. To understand mechanisms regulating maturation of in vitro derived hepatocytes, we developed a 3D spheroid differentiation system and compared gene regulatory elements in uncultured human primary hepatocytes with those in hepatocytes that were differentiated in 2D or 3D conditions from human PSCs by RNA-seq, ATAC-seq, and H3K27Ac ChIP-seq. Three-dimensional differentiation improved enhancer activity and expression of transcription factor ONECUT1, but was insufficient to upregulate human-specific mature hepatocytes marker gene CYP3A4 or super-enhancer regulated transcription factor gene NFIC. Regulome comparisons showed reduced enrichment of thyroid receptor THRB motifs in accessible chromatin and in active enhancers without reduced transcription of THRB, suggesting the regulation at the level of THRB ligands in PSC-differentiated hepatocytes. Addition of thyroid hormone T3 to the PSC-differentiated hepatocytes increased CYP3A4 expression. T3 increased binding of THRB to the CYP3A4 proximal enhancer and restored the super-enhancer status and gene expression of NFIC and reduced expression of AFP. The resultant hPSC-hepatocytes showed gene expression, epigenetic status and super-enhancer landscape closer to primary hepatocytes and activated regulatory regions including non-coding SNPs associated with liver-related diseases. Transplanting the 3D PSC-hepatocytes into immunocompromised mice resulted in engraftment of human hepatocytes in the mouse liver parenchyma without disrupting normal liver histology at 6 months after transplantation. This work provides insights into the functions of nuclear receptor THRB and highlights the importance of the environmental factors-nuclear receptors axis in regulating maturation of human PSC-differentiated cell types.

Project description:The capacity to generate functional hepatocytes from renewable human pluripotent stem cells (hPSCs) could address limited supplies of primary human hepatocytes. However, hepatocytes differentiated from hPSCs in vitro are functionally immature. To understand mechanisms regulating maturation of in vitro derived hepatocytes, we developed a 3D spheroid differentiation system and compared gene regulatory elements in uncultured human primary hepatocytes with those in hepatocytes that were differentiated in 2D or 3D conditions from human PSCs by RNA-seq, ATAC-seq, and H3K27Ac ChIP-seq. Three-dimensional differentiation improved enhancer activity and expression of transcription factor ONECUT1, but was insufficient to upregulate human-specific mature hepatocytes marker gene CYP3A4 or super-enhancer regulated transcription factor gene NFIC. Regulome comparisons showed reduced enrichment of thyroid receptor THRB motifs in accessible chromatin and in active enhancers without reduced transcription of THRB, suggesting the regulation at the level of THRB ligands in PSC-differentiated hepatocytes. Addition of thyroid hormone T3 to the PSC-differentiated hepatocytes increased CYP3A4 expression. T3 increased binding of THRB to the CYP3A4 proximal enhancer and restored the super-enhancer status and gene expression of NFIC and reduced expression of AFP. The resultant hPSC-hepatocytes showed gene expression, epigenetic status and super-enhancer landscape closer to primary hepatocytes and activated regulatory regions including non-coding SNPs associated with liver-related diseases. Transplanting the 3D PSC-hepatocytes into immunocompromised mice resulted in engraftment of human hepatocytes in the mouse liver parenchyma without disrupting normal liver histology at 6 months after transplantation. This work provides insights into the functions of nuclear receptor THRB and highlights the importance of the environmental factors-nuclear receptors axis in regulating maturation of human PSC-differentiated cell types.

Project description:Hepatic organoids are a recent innovation in in vitro modelling. Initial studies suggest organoids better recapitulate the liver phenotype in vitro compared to pre-existing proliferative cell models. However, their propensity for drug metabolism and detoxification remains poorly characterised. A global proteomic profiling of undifferentiated and differentiated hepatic murine organoids and donor-matched livers was therefore performed to assess both their similarity to liver tissue and DMET expression. iTRAQ analysis revealed 4,405 proteins commonly detected across all sample types. Differentiation of organoids significantly increased the expression of multiple CYP450s, phase II enzymes, liver biomarkers and hepatic transporters. While the final phenotype of differentiated organoids is distinct from liver tissue, they contain multiple DMET proteins necessary for liver function and drug metabolism, such as CYP450 3A, GSTA and MDR1A. Hepatic organoids may therefore represent an attractive novel model for hepatotoxicity testing, although further experimentation, optimisation and characterisation is needed relative to pre-existing models to fully contextualise their use as a putative in vitro model of DILI.

Project description:Defining molecular controls that orchestrate human brain development is essential for uncovering the complexity behind neurodevelopment and the pathogenesis of neurological disorders. Due to the difficulties in accessing embryonic and fetal brain tissues, the differentiation of human pluripotent stem cell (hPSC)-derived three-dimensional neural organoids has made it possible to recapitulate this developmental process in vitro and provide a unique opportunity to investigate human brain development and disease. To elucidate the molecular programs that drive this highly dynamic process, here, we generate a comprehensive trans-omic map of the phosphoproteome, proteome, and transcriptome of the initial stages of pluripotency and neural differentiation towards the formation of cerebral organoids. Our integrative analysis uncovers key phospho-signalling events underlying neural lineage differentiation, and their convergence on transcriptional (co-)factors and chromatin remodellers that govern downstream gene regulatory networks (GRNs). Comparative analysis with developing human and mouse embryos using these GRNs demonstrates the fidelity of our early cerebral organoids in modelling embryonic brain development. Finally, we demonstrate biochemical modulation of the AKT signalling as a key molecular switch for controlling human cerebral organoid formation. Our data provides a comprehensive resource to gain insight into the molecular controls in human embryonic brain development and also provide a guide for future development of protocols for human cerebral organoid differentiation.

Project description:To understand whether the intrinsic capacity of the fetal brain in vitro self-organizes into organoids (FeBOs) to secrete a tissue-like “matrisome” is linked to the maintenance of cell-to-cell organization and integrity, we compared the secretome of intact FeBOs and FeBO-derived neurospheres. We also performed side-by-side comparative proteomic analysis of FeBOs and human fetal brain tissue to investigate if the extracellular matrix (ECM) production in the FeBOs resembled a proper tissue-like ECM niche. Moreover, we also included proteomic analysis of unguided pluripotent stem cell (PSC)-cerebral organoids and PSC-cortical spheroids to understand how the human brain tissue ECM-niche compared not only to the FeBOs but also to PSC-derived 3D brain models.

Project description:The composition of intrahepatic immune cells in primary sclerosing cholangitis (PSC) and their contribution to disease pathogenesis is widely unknown. We here generated a single-cell atlas of intrahepatic T cells in PSC, a type of immune cells that has previously been involved in the pathogenesis of PSC. This atlas provides a valuable data source to the field. Using that atlas, we identified a population of liver-resident naive-like CD4+ T cells which are expanded in livers of patients with PSC compared to healthy and other liver diseases. Trajectory inference suggest that these cells have a propensity to acquire TH17-associated effector functions. Using blood-derived cells naive CD4+ T cells we experimentally prove this propensity. Since TH17-polarized cells are considered to contribute to the development of PSC, our findings point towards a so far underestimated role of naive T cells in PSC.

Project description:Hippo signaling is highly associated with activity in the stem cell compartment of many epithelial tissues. In this study, we examined if Hippo signaling inhibition (by inducing Yap expression) could convert differentiated cells into a progenitor like phenotype. Organoid cells derived from mouse livers under various conditions, wild-type, Yap ON (Plus Dox), and Yap ON then OFF (Minus Dox) was examined. Comparison between freshly isolated hepatocytes; Uninduced_YPF-#.cel against Organoids grown in wild-type conditions (WT), Yap On (in vivo) off (in vitro) - YapOrganoidDoxMinus , and Yap On continuously - YapOrganoidDoxPlus. Organoids grown in culture or YFP+ sorted liver cells after the indicated time of Yap expression were collected. These were amplified using Nugene technology and hybridized to Affymetrix MoGene1.0 st arrays.

Project description:Pioneering studies within the last few years have allowed the in vitro expansion of tissue-specific adult stem cells from a variety of endoderm-derived organs, including the stomach, small intestine and colon. Here we derived organoids from mouse gallbladder tissue (gallbladder organoids), from mouse liver (including the extrahepatic biliary ducts and gallbladder; liver organoids) and from mouse small intestine tissue (intestinal organoids). RNA was prepared from these organoids and used to assay expression of 21,258 genes using Affymetrix gene expression arrays. RNA was also prepared from mouse gallbladder, liver and small intestine tissues and used to assay gene expression in these tissues. Finally, gallbladder organoids were induced to differentiate by removing R-spondin 1 and noggin from the culture media and subjected to gene expression array analysis. RNA was extracted from mouse gallbladder organoids, differentiated gallbladder organoids, liver organoids, small intestine organoids, gallbladder tissue, liver tissue and small intestine tissue and then used for hybridization of Affymetrix gene expression microarrays.

Project description:Based on the identification of a transcriptomic signature, including Slit2, characterizing portal mesenchymal stem cells (PMSC) and derived myofibroblast (MF), we examined the gene expression profile of in liver tissue derived from multiple human liver disorders, including primary sclerosing cholangitis (PSC) (n=12), non-alcoholic steatohepatitis (NASH) (n=7) and other liver diseases (i.e., primary biliary cholangitis, autoimmune hepatitis, alcoholic liver disease and haemochromatosis) (n=8) and compared them to healthy controls (tumor free tissue from livers with metastasis from colorectal cancer) (n=5). We found that SLIT2 was overexpressed in the liver of patients with NASH, PSC and other chronic liver diseases. We also examined the microarray data of the human liver tissue samples for the transcriptomic signatures and found that in the different types of liver diseases the gene signature of PMSCs/PMSC-MFs was increased compared to normal liver, and correlated with the expression of ACTA2, COL1A1 and vWF.

Project description:H9 Pluripotent Stem Cells (PSC) were differentiated to Endometrial Stromal Fibroblasts (PSC-ESF) in monolayer over the course of 12 days. Gene expression was measured at day 0, day 4, day 8, and day 12 of differentiation. At day 12, PSC-ESF were dissociated from monolayer culture for co-culture with endometrial epithelial organoids established from term decidua. Gene expression was also measured after 26 days in co-culture (Cycle 1, vehicle or cAMP/progesterone/estradiol) and after 52 days in co-culture (Cycle 2, vehicle or cAMP/progesterone/estradiol)