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:3D spheroid cultures of primary human hepatocytes (PHH) are used in studies of hepatic drug metabolism and toxicity. However, the 3D spheroids are maintained under different conditions, with possible cofounding results. Here we performed an in-depth analysis of how various culture conditions influence 3D spheroids. Our aim was to find optimal conditions for the maintenance of a normal PHH phenotype.

Project description:Interindividual differences in hepatic metabolism, which are mainly due to genetic polymorphism in its gene, have a large influence on individual drug efficacy and adverse reaction. Hepatocyte-like cells (HLCs) differentiated from human induced pluripotent stem (iPS) cells have the potential to predict interindividual differences in drug metabolism capacity and drug response. However, it remains uncertain whether human iPSC-derived HLCs can reproduce the interindividual difference in hepatic metabolism and drug response. We found that cytochrome P450 (CYP) metabolism capacity and drug responsiveness of the primary human hepatocytes (PHH)-iPSHLCs were highly correlated with those of PHHs, suggesting that the PHH-iPS-HLCs retained donor-specific CYP metabolism capacity and drug responsiveness. We also demonstrated that the interindividual differences, which are due to the diversity of individual SNPs in the CYP gene, could also be reproduced in PHH-iPS-HLCs. We succeeded in establishing, to our knowledge, the first PHH-iPS-HLC panel that reflects the interindividual differences of hepatic drugmetabolizing capacity and drug responsiveness.

Project description:To identify the CAR-, PXR- and PPARα-specific genome-wide expression changes, hepatocyte cultures from six individual donors were treated with the prototypical ligands for CAR (CITCO), PXR (rifampicin) and PPARα (WY14,643) as well as DMSO (vehicle control). Afterwards, the mRNA expression in these samples was determined utilizing Affymetrix® microarrays. Primary human hepatocytes (PHH) from 6 donors were treated for 24 h with 10µM of rifampicin, 50µM of WY14,643, 1µM of CITCO and 0.1% of DMSO (vehicle).

Project description:One of the major challenges of cell therapy is manufacturing of the effective seed cells, which inevitably requires the expansion of cells in vitro. Although considerable progresses have been achieved in expansion of primary human hepatocytes (PHH) in vitro, the transplantation efficiency of proliferating human hepatocytes was decreased with the extended culture. The mechanism of declined transplantation is not clear.Here, we found that long-term cultured proliferating human hepatocytes (lc-ProliHH) significantly upregulated chemokines and proinflammatory cytokines associated with innate immune response. Moreover, lc-ProliHH elicited robust recruitment of macrophages and neutrophils at early stage of transplantation, and being cleared by macrophages caused the engraftment efficiency reduction.Based on these findings, we designed to treat recipient with Dexamethasone (Dex), which decreased the response of innate immune cells and significantly increased the transplantation efficiency to a level approximate to PHH in the liver-injured mice. Furthermore, ProliHH organoid reduced the expression of cytokine genes and behaved close to mature hepatocyte, and as a result, ameliorated their transplantation efficiency as well.

Project description:Human liver organoids, an in vitro 3D culture system to recapitulate biological tissue, are expected to be used for drug discovery. However, Matrigel, the most widely used extracellular matrix for organoid culture, has concerns about safety and reproducibility since it is murine-derived. Morever, low hepatic functions of human liver organoids compared to primary human hepatocytes is considered a challenge. Herein, we attempted to culture human liver organoids, established from primary (cryopreserved) human hepatocytes (PHH), using HYDROX, a chemically defined 3D nanofiber. While proliferative capacity of human liver organoids was lost by HYDROX-culture, the gene expression level of a hepatocyte marker CYP3A4 and the CYP3A4 metabolic activity in HYDROX-cultured liver organoids were significantly improved, comparable to those of PHH. HYDROX-cultured liver organoids when treated with hepatotoxic drugs such as acetaminophen showed similar cell viability to that of PHH, suggesting that HYDROX-cultured liver organoids could be applied to drug-induced hepatotoxicity test. Furthermore, HYDROX-cultured liver organoids maintained its functions for up to 35 days and could be used to estimate chronic drug-induced hepatotoxicity such as those of fialuridine. Our findings demonstrated that human liver organoids obtained high liver functions by HYDROX-culture, meaning that HYDROX could contribute to drug discovery as a novel biomaterial.

Project description:Plasticity of differentiated cells has been proved by nuclear transfer, induced pluripotent cells and transdifferentiation. Here we show that by transduction of 3 factors (FOXA3, HNF1A and HNF4A), human fetal fibroblasts can be converted to hepatocyte-like cells (hiHep cells), expressing hepatic marker genes, and acquiring many mature hepatocyte functions in vitro and in vivo. Human fetal fibroblasts (HFF) were tranfected with 3 liver enriched transcription factors (FOXA3, HNF1A, HNF4A), and converted to hepatocyte-like cells (hiHep cells). HFF and primary human hepatocytes (PHH) serve as control.

Project description:CD14+ human monocytes differentiating into DCs in the presence of IL4 and GM-CSF were treated with agonists for RXR and its partners or vehicle 18 hours after plating (experiment with RXR and permissive partners, donor 1-3) or 14 hours after plating (experiment with nonpermissive partners, donor 4-6). Cells were harvested 12 hours thereafter. Experiments were performed in biological triplicates representing samples from three different donors.  In this study all probable RXR-signaling pathways induced by agonists for RXR, LXRs, PPARs, RAR and VDR were identified in differentiating human monocyte-derived dendritic cells.

Project description:Imaging run on co-culture and isolated cultures of Penicillium sp. #12 with Glutamicibacter arilaitensis. Both strains were isolated from cheese rinds and normalized to OD 0.1 before plating on 2.5% Cheese Curd agar and grown for 7 days at room temperature.