Project description:A variety of approaches have been developed for the derivation of hepatocyte-like cells from pluripotent stem cells. Currently, most of these strategies employ step-wise differentiation approaches with recombinant growth-factors or small-molecule analogs to recapitulate developmental signaling pathways. Here, we tested the efficacy of a small-molecule based differentiation protocol for the generation of hepatocyte-like cells from human pluripotent stem cells. Quantitative gene-expression, immunohistochemical, and western blot analyses for SOX17, FOXA2, CXCR4, HNF4A, AFP, indicated the stage-specific differentiation into definitive endoderm, hepatoblast and hepatocyte-like derivatives. Furthermore, hepatocyte-like cells displayed morphological and functional features characteristic of primary hepatocytes, as indicated by the production of ALB (albumin) and ?-1-antitrypsin (A1AT), as well as glycogen storage capacity by periodic acid-Schiff staining. Together, these data support that the small-molecule based hepatic differentiation protocol is a simple, reproducible, and inexpensive method to efficiently drive the differentiation of human pluripotent stem cells towards a hepatocyte-like phenotype, for downstream pharmacogenomic and regenerative medicine applications.

Project description:Endothelial cell (EC) therapy may promote vascular growth or reendothelization in a variety of disease conditions. However, the production of a cell therapy preparation containing differentiated, dividing cells presenting typical EC phenotype, functional properties and chemokine profile is challenging. We focused on comparative analysis of seven small molecule-mediated differentiation protocols of ECs from human induced pluripotent stem cells. Differentiated cells showed a typical surface antigen pattern of ECs as characterized with flow cytometry analysis, functional properties, such as tube formation and ability to uptake acetylated LDL. Gene expression analysis by RNA sequencing revealed an efficient silencing of pluripotency genes and upregulation of genes related to cellular adhesion during differentiation. In addition, distinct patterns of transcription factor expression were identified during cellular reprogramming providing targets for more effective differentiation protocols in the future. Altogether, our results suggest that the most optimal EC differentiation protocol includes early inhibition of Rho-associated coiled-coil kinase and activation of cyclic AMP signaling, and inhibition of transforming growth factor beta signaling after mesodermal stage. These findings provide the first systematic characterization of the most potent signalling factors and small molecules used to generate ECs from human induced pluripotent stem cells and, consequently, this work improves the existing EC differentiation protocols and opens up new avenues for controlling cell fate for regenerative EC therapy.

Project description:Purpose: Corneal endothelial cells (CECs) serve as a barrier and foothold for the corneal stroma to maintain the function and transparency of the cornea. Loss of CECs during aging or disease states leads to blindness, and cell replacement therapy using either donated or artificially differentiated CECs remains the only curative approach. Methods: Human induced pluripotent stem cells (hiPSCs) that were cultured in chemically defined medium were induced with dual-SMAD inhibition to differentiate into neural crest cells (NCCs). A small-molecule library was screened to differentiate the NCCs into corneal endothelial-like cells. The characteristics of these cells were identified with real-time PCR and immunofluorescence. Western blotting was applied to detect the signaling pathways and key factors regulated by the small molecules. Results: We developed an effective protocol to differentiate hiPSCs into CECs with defined small molecules. The hiPSC-CECs were characterized by ZO-1, AQP1, Vimentin and Na+/K+-ATPase. Based on our small-molecule screen, we identified a small-molecule combination, A769662 and AT13148, that enabled the most efficient production of CECs. The combination of A769662 and AT13148 upregulated the PKA/AKT signaling pathway, FOXO1 and PITX2 to promote the conversion of NCCs to CECs. Conclusion: We established an efficient small molecule-based method to differentiate hiPSCs into corneal endothelial-like cells, which might facilitate drug discovery and the development of cell-based therapies for corneal diseases.

Project description:The differentiation of pluripotent stem cells to hepatocytes is well established, yet current methods suffer from several drawbacks. These include a lack of definition and reproducibility, which in part stems from continued reliance on recombinant growth factors. This has remained a stumbling block for the translation of the technology into industry and the clinic for reasons associated with cost and quality. We have devised a growth-factor-free protocol that relies on small molecules to differentiate human pluripotent stem cells toward a hepatic phenotype. The procedure can efficiently direct both human embryonic stem cells and induced pluripotent stem cells to hepatocyte-like cells. The final population of cells demonstrates marker expression at the transcriptional and protein levels, as well as key hepatic functions such as serum protein production, glycogen storage, and cytochrome P450 activity.

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

Project description:Preparing targeted cells for medical applications from human induced pluripotent stem cells (hiPSCs) using growth factors, compounds, or gene transfer has been challenging. Here, we report that human induced hepatic lineage-oriented stem cells (hiHSCs) were generated and expanded as a new type of hiPSC under non-typical coculture with feeder cells in a chemically defined hiPSC medium at a very high density. Self-renewing hiHSCs expressed markers of both human embryonic stem cells (hESCs) and hepatocytes. Those cells were highly expandable, markedly enhancing gene expression of serum hepatic proteins and cytochrome P450 enzymes with the omission of FGF-2 from an undefined hiPSC medium. The hepatic specification of hiHSCs was not attributable to the genetic and epigenetic backgrounds of the starting cells, as they were established from distinct donors and different types of cells. Approximately 90% of hiHSCs autonomously differentiated to hepatocyte-like cells, even in a defined minimum medium without any of the exogenous growth factors necessary for hepatic specification. After 12 days of this culture, the differentiated cells significantly enhanced gene expression of serum hepatic proteins (ALB, SERPINA1, TTR, TF, FABP1, FGG, AGT, RBP4, and AHSG), conjugating enzymes (UGT2B4, UGT2B7, UGT2B10, GSTA2, and GSTA5), transporters (SULT2A1, SLC13A5, and SLCO2B1), and urea cycle-related enzymes (ARG1 and CPS1). In addition, the hepatocyte-like cells performed key functions of urea synthesis, albumin secretion, glycogen storage, indocyanine green uptake, and low-density lipoprotein uptake. The autonomous hepatic specification of hiHSCs was due to their culture conditions (coculture with feeder cells in a defined hiPSC medium at a very high density) in self-renewal rather than in differentiation. These results suggest the feasibility of preparing large quantities of hepatocytes as a convenient and inexpensive hiPSC differentiation. Our study also suggests the necessity of optimizing culture conditions to generate other specific lineage-oriented hiPSCs, allowing for a very simple differentiation.

Project description:An unlimited source of functional human pancreatic β cells are in highly demand. Even with recent advances in pancreatic β-like cell differentiation from human pluripotent stem cells (hPSCs), several hurdles obviously remain and the differentiation protocols need to be further improved. Chemical strategies are particularly useful to address these challenges. Here, through chemical screening, we unexpectedly identified that BET bromodomain inhibitor I-BET151 could robustly promote the expansion of PDX1 and NKX6.1 double-positive human pancreatic progenitors (PPs). These hPSC-derived expandable pancreatic progenitors (ePPs) can proliferate extensively in a chemically defined condition with I-BET151. Even after long-term expansion, these ePPs maintain pancreatic progenitor cell status. In addition, ePPs can efficiently differentiate into pancreatic β-like cells (ePP-β cells). These ePP-β cells are functional and demonstrate glucose-stimulation insulin-secretion (GSIS) capacity. Mechanistically, I-BET151 can activate Notch signaling and promote the expression of key pancreatic progenitor-associated genes and transcriptional network. Conclusively, our studies achieve the long-term goal of robust expansion of human pancreatic progenitors and represent a significant step towards unlimited supplies of functional human pancreatic β cells that are of great interest for biomedical research and regenerative medicine.

Project description:An unlimited source of functional human pancreatic β cells are in highly demand. Even with recent advances in pancreatic β-like cell differentiation from human pluripotent stem cells (hPSCs), several hurdles obviously remain and the differentiation protocols need to be further improved. Chemical strategies are particularly useful to address these challenges. Here, through chemical screening, we unexpectedly identified that BET bromodomain inhibitor I-BET151 could robustly promote the expansion of PDX1 and NKX6.1 double-positive human pancreatic progenitors (PPs). These hPSC-derived expandable pancreatic progenitors (ePPs) can proliferate extensively in a chemically defined condition with I-BET151. Even after long-term expansion, these ePPs maintain pancreatic progenitor cell status. In addition, ePPs can efficiently differentiate into pancreatic β-like cells (ePP-β cells). These ePP-β cells are functional and demonstrate glucose-stimulation insulin-secretion (GSIS) capacity. Mechanistically, I-BET151 can activate Notch signaling and promote the expression of key pancreatic progenitor-associated genes and transcriptional network. Conclusively, our studies achieve the long-term goal of robust expansion of human pancreatic progenitors and represent a significant step towards unlimited supplies of functional human pancreatic β cells that are of great interest for biomedical research and regenerative medicine.

Project description:An unlimited source of functional human pancreatic β cells are in highly demand. Even with recent advances in pancreatic β-like cell differentiation from human pluripotent stem cells (hPSCs), several hurdles obviously remain and the differentiation protocols need to be further improved. Chemical strategies are particularly useful to address these challenges. Here, through chemical screening, we unexpectedly identified that BET bromodomain inhibitor I-BET151 could robustly promote the expansion of PDX1 and NKX6.1 double-positive human pancreatic progenitors (PPs). These hPSC-derived expandable pancreatic progenitors (ePPs) can proliferate extensively in a chemically defined condition with I-BET151. Even after long-term expansion, these ePPs maintain pancreatic progenitor cell status. In addition, ePPs can efficiently differentiate into pancreatic β-like cells (ePP-β cells). These ePP-β cells are functional and demonstrate glucose-stimulation insulin-secretion (GSIS) capacity. Mechanistically, I-BET151 can activate Notch signaling and promote the expression of key pancreatic progenitor-associated genes and transcriptional network. Conclusively, our studies achieve the long-term goal of robust expansion of human pancreatic progenitors and represent a significant step towards unlimited supplies of functional human pancreatic β cells that are of great interest for biomedical research and regenerative medicine.

Project description:An unlimited source of functional human pancreatic β cells are in highly demand. Even with recent advances in pancreatic β-like cell differentiation from human pluripotent stem cells (hPSCs), several hurdles obviously remain and the differentiation protocols need to be further improved. Chemical strategies are particularly useful to address these challenges. Here, through chemical screening, we unexpectedly identified that BET bromodomain inhibitor I-BET151 could robustly promote the expansion of PDX1 and NKX6.1 double-positive human pancreatic progenitors (PPs). These hPSC-derived expandable pancreatic progenitors (ePPs) can proliferate extensively in a chemically defined condition with I-BET151. Even after long-term expansion, these ePPs maintain pancreatic progenitor cell status. In addition, ePPs can efficiently differentiate into pancreatic β-like cells (ePP-β cells). These ePP-β cells are functional and demonstrate glucose-stimulation insulin-secretion (GSIS) capacity. Mechanistically, I-BET151 can activate Notch signaling and promote the expression of key pancreatic progenitor-associated genes and transcriptional network. Conclusively, our studies achieve the long-term goal of robust expansion of human pancreatic progenitors and represent a significant step towards unlimited supplies of functional human pancreatic β cells that are of great interest for biomedical research and regenerative medicine.