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:Primary human hepatocytes (PHH) are an essential tool for modeling drug metabolism and liver disease. However, variable plating efficiencies, short lifespan in culture and resistance to genetic manipulation have limited their use. Here we show that retrorsine improves human hepatocyte repopulation of chimeric mice to levels where poor donor PHH can be isolated for ex vivo cultures. Mouse-passaged (mp)PHH cultures overcome the marked donor-to-donor variability of cryopreserved PHH and remain functional for months, as demonstrated by metabolic assays and infection with hepatitis B virus and Plasmodium falciparum. mpPHH can be efficiently genetically modified in culture, mobilized and then re-cultured as spheroids or re-transplanted to create highly humanized mice carrying a genetically altered hepatocyte graft. Together, these advances provide flexible tools for studying human liver disease and evaluating hepatocyte-targeted gene therapy approaches

Project description:3D spheroids of primary human hepatocytes (3D PHH) keep a differentiated phenotype with retained metabolic function and proteome fingerprint for weeks in culture. As a result, 3D PHH are gaining ground as a model for mechanistic studies on liver homeostasis and in vitro to in vivo (IVIV)predictions in drug discovery. However, the function of drug-transporting proteins has not yet been studied in the 3D PHH. Here we used the organic cation transporter 1 (OCT1/SLC22A1) as a model to explore both transporter kinetics and long-term regulation of transporter activity via different pathways. The 3D PHH were cultured for one week and then used for short- and long-term studies. The OCT1 transporter kinetics was assessed using the fluorescent model substrate 4-(4-(dimethylamino)styryl)-N-methylpyridinium (ASP+) and known OCT1 inhibitors in individual 3D PHH. For long-term studies, the 3D PHH were exposed to xenobiotics for seven days, after which protein expression and OCT1 function were assessed. Global proteomics analysis was used to track prototypical changes of other regulated proteins. ASP+ kinetics indicated a fully functional OCT1 transporter with a Km value of 14.14±3.97 using three donors. Established OCT1 inhibitors reduced the uptake of ASP+ in the 3D PHH spheroids, resulting in 40-60% of the maximal uptake rate of ASP+. The long-term exposure studies showed that OCT1 is relatively stable to the activation of a broad range of pathways known to regulate ADME proteins. Importantly, while expression levels of other ADME proteins, such as CYP3A4 and MDR1 were regulated as expected, OCT1 levels remained stable. In conclusion, our results show for the first time that 3D PHH spheroids express fully active OCT1 and that transporter kinetics can be studied in 3D PHH. We also confirm that OCT1 remains stable and functional during activation of various pathways that alter the expression and function of other ADME proteins.

Project description:Primary human hepatocytes (PHH) are a main instrument in drug metabolism research and in the prediction of drug-induced phase I/II enzyme induction in humans. The HepG2 liver-derived cell line is commonly used as a surrogate for human hepatocytes, but their use in ADME and toxicity studies can be limited because of lowered basal levels of metabolizing enzymes. Despite their widespread use, the transcriptome of HepG2 cells compared to PHH is not well characterized. In this study, microarray analysis was conducted to ascertain the differences and similarities in mRNA expression between HepG2 cells and human hepatocytes before and after exposure to a panel of fluoroquinolone compounds. Comparison of the naïve HepG2 cell and PHH transcriptomes revealed a substantial number of basal gene expression differences. When HepG2 cells were dosed with a series of fluoroquinolones, trovafloxacin, which has been associated with human idiosyncratic hepatotoxicity, induced substantially more gene expression changes than the other quinolones, similar to previous observations with PHH. While TVX-treatment resulted in many gene expression differences between HepG2 cells and PHH, there were also a number of TVX-induced commonalities, including genes involved in RNA processing and mitochondrial function. Taken together, these results provide insight for interpretation of results from drug metabolism and toxicity studies conducted with HepG2 cells in lieu of PHH, and could provide further insight into the mechanistic evaluation of TVX-induced hepatotoxicity. Experiment Overall Design: HepG2 cells were obtained from the American Type Culture Collection (Rockville, MD). The cells were cultured in Minimum Essential Medium (Invitrogen Life Technologies, Carlsbad,CA) with 10% Fetal Bovine Serum under a humidified 5% CO2 atmosphere using T-162 plastic culture flasks. The cells were split when they reached approximately 70-85% confluence after washing with sterile phosphate buffered saline and detachment of the cells with trypsin (Invitrogen Life Technologies, Carlsbad, CA). The HepG2 cells were cultured in 6-well plastic plates upon exposure to quinolone compounds. Primary human hepatocytes, obtained from In Vitro Technologies (IVT, Baltimore, MD) in 6-well type I collagen coated plates, were cultured with 2 mL of Hepatocyte Incubation Media (IVT) at 37°C with 5% CO2 for 24 hours after receipt. Experiment Overall Design: For the genomic experiments, quinolone compounds, dissolved in 0.1 N KOH (Sigma Chemical Co., St. Louis, MO), were added to the wells with fresh media at levels of 100 µM (HepG2) or 400 µM (primary human hepatocytes) for 24 hours using at least two technical replicates. Trovafloxacin was dosed using two separate preparations of HepG2 cells and two separate donors of human hepatocytes. Vehicle control cells were dosed with an equivalent volume of 0.1N KOH as the experimental samples. For intracellular comparison (HepG2 cells vs PHH), naïve cells were harvested using TRIzol� reagent (Invitrogen Life Technologies, Carlsbad, CA). Experiment Overall Design: Total RNA was isolated from the TRIzol� extracts using the standard procedure from the manufacturer. O.D. at 260 nm determined RNA concentrations. RNA quality was accessed using an Agilent Technologies bioanalyzer before proceeding to microarray sample preparation. Microarray analysis was performed using the standard protocol provided by Affymetrix Inc. (Santa Clara, CA) and as previously described, starting with 5 µg of total RNA (Richert et al., 2006). Experiment Overall Design: Fragmented, labeled cRNA was hybridized to an Affymetrix human genome U133A array, which contains sequences corresponding to roughly 22,200 transcripts at 45°C overnight. The arrays were washed, developed, and scanned.

Project description:In drug development, a system for predicting drug metabolism and drug-induced toxicity is necessary to ensure drug safety. Cytochrome P450 family 3 subfamily A member 4 (CYP3A4) is an important drug-metabolizing enzyme expressed in the liver and small intestine, and predicting CYP3A4-mediated drug metabolism and drug-induced toxicity is essential. We previously developed procedures to differentiate human induced pluripotent stem (iPS) cells into hepatocyte-like cells (HLCs) or intestinal epithelial-like cells (IECs) with a fetal phenotype as well as a highly efficient genome editing technology that could enhance the homologous recombination efficiency at any locus, including CYP3A4. By using human iPS cells and our genome editing technology, we generated CYP3A4-knockout (KO) iPS cell-derived HLCs and IECs for the evaluation of CYP3A4-mediated drug metabolism and drug-induced toxicity. CYP3A4 deficiency did not affect pluripotency and hepatic and intestinal differentiation capacities, and CYP3A4 activity was entirely eradicated by CYP3A4 KO. Off-target effects (e.g., inhibition of bile acid excretion) were hardly observed in CYP3A4-KO cells but were observed in CYP3A4 inhibitor-treated (e.g., ketoconazole) cells. To evaluate whether drug-induced hepatotoxicity and enterotoxicity could be predicted using our model, we exposed CYP3A4-KO HLCs and IECs to acetaminophen, amiodarone, desipramine, leflunomide, tacrine, and tolcapone and confirmed that these cells could predict CYP3A4-mediated toxicity. Finally, we examined whether the therapeutic effects of an anti-hepatitis C virus (HCV) drug metabolized by CYP3A4 would be predicted using our model. CYP3A4-KO HLCs were treated with asunaprevir (antiviral drug metabolized by CYP3A4) after HCV infection, and the anti-viral effect was indeed strengthened by CYP3A4 KO. Conclusion: We succeeded in generating a novel evaluation system for prediction of CYP3A4-mediated drug metabolism and drug-induced toxicity.

Project description:Primary human hepatocytes (PHH) are a main instrument in drug metabolism research and in the prediction of drug-induced phase I/II enzyme induction in humans. The HepG2 liver-derived cell line is commonly used as a surrogate for human hepatocytes, but their use in ADME and toxicity studies can be limited because of lowered basal levels of metabolizing enzymes. Despite their widespread use, the transcriptome of HepG2 cells compared to PHH is not well characterized. In this study, microarray analysis was conducted to ascertain the differences and similarities in mRNA expression between HepG2 cells and human hepatocytes before and after exposure to a panel of fluoroquinolone compounds. Comparison of the naïve HepG2 cell and PHH transcriptomes revealed a substantial number of basal gene expression differences. When HepG2 cells were dosed with a series of fluoroquinolones, trovafloxacin, which has been associated with human idiosyncratic hepatotoxicity, induced substantially more gene expression changes than the other quinolones, similar to previous observations with PHH. While TVX-treatment resulted in many gene expression differences between HepG2 cells and PHH, there were also a number of TVX-induced commonalities, including genes involved in RNA processing and mitochondrial function. Taken together, these results provide insight for interpretation of results from drug metabolism and toxicity studies conducted with HepG2 cells in lieu of PHH, and could provide further insight into the mechanistic evaluation of TVX-induced hepatotoxicity. Keywords: Cell Type Comparison

Project description:In vitro models of human liver functions are used across a diverse range of applications in preclinical drug development and disease modeling, with particular increasing interest in models that capture facets of liver inflammatory status. This study investigates how the interplay between biophysical and biochemical microenvironment cues influence phenotypic responses, including inflammation signatures, of primary human hepatocytes (PHH) cultured in a commercially available perfused bioreactor. A 3D printing-based alginate microwell system was designed to form thousands of hepatic spheroids in a scalable manner as a comparator 3D culture modality to the bioreactor. Soft, synthetic extracellular matrix (ECM) hydrogel scaffolds with biophysical properties mimicking features of liver were engineered to replace polystyrene scaffolds, and the biochemical microenvironment was modulated with a defined set of growth factors and signaling modulators. The supplemented media significantly increased tissue density, albumin secretion, and CYP3A4 activity but also upregulated inflammatory markers. Basal inflammatory markers were lower for cells maintained in ECM hydrogel scaffolds or spheroid formats than polystyrene scaffolds, while hydrogel scaffolds exhibited the most sensitive response to inflammation as assessed by multiplexed cytokine and RNA-seq analyses. Together, these engineered 3D liver microenvironments provide insights for probing human liver functions and inflammatory response in vitro.

Project description:End-stage liver diseases are an increasing health burden and liver transplantations are currently the only curative treatment option. Due to a lack of donor livers, alternative treatments are urgently needed. Human liver organoids are very promising for regenerative medicine, however, organoids are currently cultured in Matrigel, which is extracted from the extracellular matrix of the Engelbreth-Holm-Swarm mouse sarcoma. Matrigel is poorly defined, suffers from high batch-to-batch variability and is of murine origin, which limits clinical application of organoids. Here, a novel hydrogel based on polyisocyanopeptides (PIC) and laminin-111 is described for human liver organoid culture. PIC is a synthetic hydrogel with thermodynamic properties, making it easy to handle and very attractive for clinical applications. Organoids in an optimized PIC hydrogel proliferate at rates comparable to Matrigel; proliferation rates are stiffness-dependent, with lower stiffnesses being optimal for organoid proliferation. Moreover, organoids can be efficiently differentiated towards hepatocyte-like cells with key liver functions. This proliferation and differentiation potential can be maintained over at least 16 passages. Our results indicate that PIC is a promising material for human liver organoid culture and has the potential to be used in a variety of clinical applications including cell therapy and tissue engineering.

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: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.