Project description:Human pluripotent stem cell (hPSC)-derived hepatocytes exhibit progressive differentiation toward a phenotype resembling primary human hepatocytes (PHHs). Nevertheless, they still display persistent functional deficiencies in key mature hepatocyte properties, particularly in albumin secretion and ammonia metabolism, remain challenge compared to PHHs. In this study, we elucidated a critical regulatory role of CCAAT/enhancer-binding protein beta (C/EBPβ) in hepatocyte maturation. Forced expression of C/EBPβ significantly enhanced hepatic functionality, as evidenced by increased albumin secretion, upregulation of hepatic-specific genes, and suppression of epithelial-mesenchymal transition (EMT) markers. Mechanistically, we found that C/EBPβ directly binded to the promoter regions of E-cadherin (E-cad) and carbamoyl phosphate synthetase 1 (CPS1), enhancing their transcriptional activation. Furthermore, we identified a functional interaction between C/EBPβ and MAPK signaling, where MAPK1-mediated phosphorylation at Thr-235 potentiated C/EBPβ's transactivation capacity, thereby promoting hepatocyte differentiation and maturation. Our findings establish C/EBPβ as a master regulator of hepatic maturation, orchestrating transcriptional networks and post-translational modification. These insights provide a theoretical framework for optimizing stem cell-derived hepatocyte differentiation, facilitating their applications in various fields.

Project description:Human induced pluripotent stem (iPS) cell-derived hepatocyte-like cells (HLCs) are expected to replace primary human hepatocytes (PHHs) as a new stable source of hepatocytes for pharmaceutical researches. However, HLCs have lower hepatic functions than PHHs, take a long time to be differentiated and cannot be prepared in large quantities due to not proliferating after their terminal differentiation. To overcome these problems, we have established hepatic organoids (iHOs) from HLCs. The iHOs could proliferate approximately 10^20-fold by more than 10 passages and expressed most hepatic genes higher than HLCs. Furthermore, in order to enable the widespread use of iHOs for in vitro drug discovery research, we have developed the two-dimensional culture protcol for them. Two-dimensional cutured iHOs (2D-iHOs) expressed most of major hepatocyte marker genes and proteins much higher than HLC, iHOs, and even PHHs. The 2D-iHOs had glycogen storage capacity, the capacity to uptake and release indocyanine green (ICG), albumin and urea secretion, and the capacity of bile canaliculi formation. Importantly, the 2D-iHOs had the activity of major drug-metabolizing enzymes and responded to hepatotoxic drugs, comparable to PHHs. Thus, 2D-iHOs overcome the limitation of the current models and promise to provide robust and reproducible pharmaceutical assays.

Project description:Hepatocytes hold significant promise for applications in drug screening, disease modeling, and clinical cell transplantation. Generating large amouts of hepatocyte in vitro for those application is still challenging. We have previously established a 5C medium for long-term culture and functional maintanace human primary hepatocytes (PHHs) in vitro. However, 5C condtion could not support hepatocyte expansion, which limited its application. In this study, we established a new hepatocyte expansion medium (NHEM) for efficient hepatocyte expansion, which turned the PHHs into hepatic progenitor-like cells (HPLCs). We also generated an optimized 6C condtion for HPLCs maturation. Overall, this study provide a new strategy to generate large amounts of hepatocytes in vitro.

Project description:Hepatocytes hold significant promise for applications in drug screening, disease modeling, and clinical cell transplantation. Generating large amouts of hepatocyte in vitro for those application is still challenging. We have previously established a 5C medium for long-term culture and functional maintanace human primary hepatocytes (PHHs) in vitro. However, 5C condtion could not support hepatocyte expansion, which limited its application. In this study, we established a new hepatocyte expansion medium (NHEM) for efficient hepatocyte expansion, which turned the PHHs into hepatic progenitor-like cells (HPLCs). We also generated an optimized 6C condtion for HPLCs maturation. Overall, this study provide a new strategy to generate large amounts of hepatocytes in vitro.

Project description:Induced pluripotent stem cell-derived human hepatocyte-like cells (iHeps) could provide a powerful tool for studying the mechanisms underlying human liver development and disease, testing the efficacy and safety of pharmaceuticals across different patients (i.e. personalized medicine), and enabling cell-based therapies in the clinic. However, current in vitro protocols that rely upon growth factors and extracellular matrices (ECM) alone yield iHeps with low levels of liver functions relative to adult primary human hepatocytes (PHHs). Moreover, these low hepatic functions in iHeps are difficult to maintain for prolonged times (weeks to months) in culture. Here, we engineered a micropatterned co-culture (iMPCC) platform in a multi-well format that, in contrast to conventional confluent cultures, significantly enhanced the functional maturation and longevity of iHeps in culture for 4 weeks in vitro when benchmarked against multiple donors of PHHs. In particular, iHeps were micropatterned onto collagen-coated domains of empirically optimized dimensions, surrounded by 3T3-J2 murine embryonic fibroblasts, and then sandwiched with a thin layer of ECM gel (Matrigel™). We assessed iHep maturity via global gene expression profiles, hepatic polarity, secretion of albumin and urea, basal CYP450 activities, phase-II conjugation, drug-mediated CYP450 induction, and drug-induced hepatotoxicity. Conclusion: Controlling both homotypic interactions between iHeps and heterotypic interactions with stromal fibroblasts significantly matures iHep functions and maintains them for several weeks in culture. In the future, iMPCCs could prove useful for drug screening, studying molecular mechanisms underlying iHep differentiation, modeling liver diseases, and integration into human-on-a-chip systems being designed to assess multi-organ responses to compounds. We used Affymetrix microarrays to profile the global gene expression of co-culture stabilized iHeps (iMPCCs) relative to freshly isolated and co-culture stabilized primary human hepatocytes (2 donors). To assess the transcriptomic stability of iHeps in iMPCCs, RNA was extracted following 9 and 21 days of culture for hybridization to Affymetrix microarrays. The hepatic maturation state of iHeps was assessed by comparing gene expression against microarrays containing data from two primary human hepatocyte donors, both following hepatocyte isolation (day 0) and after stabilization in the micropatterened co-culture platform (day 6 and day 42 MPCCs), as previously described.

Project description:Background: Induced pluripotent stem cells (iPSCs) induced hepatocytes (iHeps) are widely used in modeling human liver diseases and as a potential source for cell replacement therapy. However, most iHeps are relatively immature and hard to maintain for long-term in-vitro. Results: The hepatic differentiation improved when EMT was inhibited at late stage of iHeps differentiation, and iHeps EMTi demonstrated the ability to be maintained in- vitro for an extended period up to Day 60. In-vitro analysis showed that iHeps EMTi exhibited significantly higher expression levels of hepatic functional markers, and enhanced hepatocyte functions, including lipid accumulation, glycogen storage, albumin secretion and urea acid metabolism. Moreover, the molecular profiles of iHeps EMTi are closer to those of primary human hepatocytes (PHHs). In addition, the in-vivo engraftment efficiency of iHeps EMTi was also improved as compared to iHeps alone. Conclusion: We established a robust protocol via EMT suppression to generate iHeps from human iPSCs with improved function, long-term in-vitro maintenance capacity, and enhanced repopulation efficiency.

Project description:Human liver organoids are expected to be a hepatocyte source for preclinical in vitro studies. Although these organoids show long-term proliferation, their hepatic functions remain low. Here, we propose a novel method for two dimensional (2D)-cultured hepatic differentiation from human liver organoids. When cultured under a 2D condition, the single cells from human liver organoids were seeded on collagen type I-coated plates. Then, optimal conditions for hepatic differentiation were screened using several reagents. We determined the 2D-cultured hepatocyte differentiation method from human liver organoids. Hepatic gene expressions in human liver organoids-derived hepatocytes (Org-HEPs) were greatly increased, compared to those in human liver organoids. The metabolic activities of cytochrome P450 (CYP) 1A2, CYP2C8, CYP2E1 and CYP3A4 were at levels comparable to those in primary human hepatocytes (PHHs). These results suggested that human liver organoids could be differentiated into highly functional hepatocytes in 2D culture. We also treated Org-HEPs and PHHs with hepatotoxic drugs. The cell viability of Org-HEPs was almost the same as that of PHHs, suggesting that Org-HEPs could be used for hepatotoxicity tests. Thus, Org-HEPs will be useful for pharmaceutical research.

Project description:Germline cell-derived pluripotent stem cells (GPSCs) are similar to embryonic stem (ES) cells in that they can proliferate intensively and differentiate into a variety of cell types, including cardiomyocytes and neurons. In this report, mouse GPSCs were induced to differentiate into hepatocytes with very high efficiency, and demonstrated, for the first time, to be functional. These hepatocytes were characterised at cellular and molecular levels. The GPSC-derived hepatocytes not only expressed hepatic markers, but were also metabolically active as shown by albumin and haptoglobin secretion, urea synthesis, glycogen storage and indocyanine green uptake. Previous studies have revealed some inherent differences in gene expression between undifferentiated mouse ES cells and GPSCs. We wanted to investigate whether this difference may impact on the hepatocyte differentiation capacity of the GPSCs. Large-scale gene expression profiling revealed a strong similarity between GPSC and ES cells at different stages of induced hepatic differentiation. Moreover, Pearson correlation analysis of the microarray datasets revealed that, at late hepatic differentiation stages, the in vitro-derived cells were closer to fetal mouse primary hepatocytes. Thus, adult GPSCs offer great potential for cell ment therapy for a wide variety of liver diseases. Mouse ES cells and GPSCs at various times of hepatocyte differentiation, compared to embryonal (E16) and postnatal (PN1) mouse primary hepatocytes. The supplementary file 'GSE19044_non-normalized.txt' contains non-normalized data for Samples GSM471318-GSM471359.

Project description:Induced pluripotent stem cell-derived human hepatocyte-like cells (iHeps) could provide a powerful tool for studying the mechanisms underlying human liver development and disease, testing the efficacy and safety of pharmaceuticals across different patients (i.e. personalized medicine), and enabling cell-based therapies in the clinic. However, current in vitro protocols that rely upon growth factors and extracellular matrices (ECM) alone yield iHeps with low levels of liver functions relative to adult primary human hepatocytes (PHHs). Moreover, these low hepatic functions in iHeps are difficult to maintain for prolonged times (weeks to months) in culture. Here, we engineered a micropatterned co-culture (iMPCC) platform in a multi-well format that, in contrast to conventional confluent cultures, significantly enhanced the functional maturation and longevity of iHeps in culture for 4 weeks in vitro when benchmarked against multiple donors of PHHs. In particular, iHeps were micropatterned onto collagen-coated domains of empirically optimized dimensions, surrounded by 3T3-J2 murine embryonic fibroblasts, and then sandwiched with a thin layer of ECM gel (Matrigel™). We assessed iHep maturity via global gene expression profiles, hepatic polarity, secretion of albumin and urea, basal CYP450 activities, phase-II conjugation, drug-mediated CYP450 induction, and drug-induced hepatotoxicity. Conclusion: Controlling both homotypic interactions between iHeps and heterotypic interactions with stromal fibroblasts significantly matures iHep functions and maintains them for several weeks in culture. In the future, iMPCCs could prove useful for drug screening, studying molecular mechanisms underlying iHep differentiation, modeling liver diseases, and integration into human-on-a-chip systems being designed to assess multi-organ responses to compounds. We used Affymetrix microarrays to profile the global gene expression of co-culture stabilized iHeps (iMPCCs) relative to freshly isolated and co-culture stabilized primary human hepatocytes (2 donors).

Project description:Hepatocyte-like cells derived from human pluripotent stem cells (hPSC-HLCs) offer an alternative to primary hepatocytes commonly used for drug screenings and toxicological tests. However, these cells do not have hepatic functions comparable to those of hepatocytes in vivo due to insufficient hepatic differentiation. Here we showed that the hepatic functions of hPSC-HLCs were facilitated by applying physiological liver temperatures during hepatic differentiation. We identified the optimal temperature by treating HLCs derived from H9 human embryonic stem cells (hESC-HLCs) at 39 °C; the 42 °C treatment caused significantly greater cell death than the 39 °C treatment. We confirmed the improvement of hepatic functions, such as albumin secretion, cytochrome P450 3A activity, and collagen production, without severe cell damage. In combination with existing hepatic differentiation protocols, the method proposed here may further improve hepatic functions for hPSCs and lead to the realization of drug discovery efforts and drug toxicological tests.