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: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:There are a few markers available to distinguish hepatic stellate cells (HSCs), portal fibroblasts (PFs), and mesothelial cells (MCs) in the adult mouse liver. To identify genes uniquely expressed in these cells, we isolated HSCs having Vitamin A lipids by FACS based on their autofluorescence. We isolated a mixed population containing PFs and MCs as Vitamin A lipid-negative and GFP-positive cells by FACS from Collagen1a1 promoter-driven GFP transgenic mice. MCs were isolated by FACS using anti-GPM6A antibodies from adult mouse livers. PFs were isolated by FACS as Vitamin A lipid-negative, GFP-positive, and GPM6A-negative cells. We also isolated HSCs, MCs, and PFs from Collagen1a1 promoter-driven GFP transgenic mouse livers having biliary fibrosis by FACS. Biliary fibrosis was induced by bile duct ligation for 3 weeks. Sham operation was performed as a control. After separation of these cells, we isolated total RNAs and analyzed mRNA expression by microarray analysis. Total RNA was extracted with RNAqueous Micro (Ambion) and the probes for the microarray were synthesized using the Ovation RNA amplification system V2 and FL-Ovation cDNA Biotin module V2 (Nugen). The labeled probes were hybridized with GeneChip Mouse Genome 430 2.0 arrays (Affymetrix) and signals were analyzed with Genomic Suite software (Partek).

Project description:There are a few markers available to distinguish hepatic stellate cells (HSCs), portal fibroblasts (PFs), and mesothelial cells (MCs) in the adult mouse liver. To identify genes uniquely expressed in these cells, we isolated HSCs having Vitamin A lipids by FACS based on their autofluorescence. We isolated a mixed population containing PFs and MCs as Vitamin A lipid-negative and GFP-positive cells by FACS from Collagen1a1 promoter-driven GFP transgenic mice. MCs were isolated by FACS using anti-GPM6A antibodies from adult mouse livers. PFs were isolated by FACS as Vitamin A lipid-negative, GFP-positive, and GPM6A-negative cells. We also isolated HSCs, MCs, and PFs from Collagen1a1 promoter-driven GFP transgenic mouse livers having biliary fibrosis by FACS. Biliary fibrosis was induced by bile duct ligation for 3 weeks. Sham operation was performed as a control. After separation of these cells, we isolated total RNAs and analyzed mRNA expression by microarray analysis.

Project description:Purpose: to analyze change in gene expression of hPSC derived macrophages upon co-culture with hepatic cells including Huh7 and primary human hepatocytes Methods: SMART-seq2 amplified polyA RNA from sorted iMacs in the co-cultures. Results: the transcriptome of iMacs changed after co-culture with Huh7 cells or pHHs, and changed after the HCV infection of the co-cultured Huh7 cells. Conclusions: the gene expression profiles of co-cultured iMacs indicated that the culture conditions and the microenvironments could reprogrammed iMacs to adopt tissue-specific features and perform specifc functions.

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:Background and aims. Portal hypertension is the main consequence of cirrhosis, responsible for the complications defining clinical decompensation. The only cure for decompensated cirrhosis is liver transplantation, but it is a limited resource and opens the possibility of regenerative therapy. We investigated the potential of human amniotic membrane-derived mesenchymal stromal (hAMSCs) and epithelial (hAECs) stem cells for the treatment of portal hypertension and chronic liver disease. Methods. In vivo: hAMSCs and hAECs were isolated from human amniotic membranes. Cirrhotic rats with ascites (chronic CCl4 inhalation) received 4x10e6 hAMSCs, 4x10e6 hAECs, or vehicle (NaCl 0.9%) (intraperitoneal; n=10 per group). After 2-week we analyzed: a) portal pressure (PP) and liver microcirculatory function; b) liver sinusoidal endothelial (LSECs) and hepatic stellate (HSCs) cells phenotype; c) hepatic fibrosis, inflammation and hepatic function. In vitro: HSCs isolated from CCl4-cirrhotic rats were co-cultured with hAMSCs, hAECs or vehicle for 24h. RNA profile was analyzed by RNAseq. Results. Cirrhotic rats receiving hAMSCs or hAECs had significantly lower PP than vehicle-treated animals, together with improved liver microcirculatory function. This hemodynamic amelioration was associated with improvement in LSECs capillarization and HSCs de-activation, although hepatic collagen/fibrosis was not significantly reduced. Rats that received placenta derived stem cells had markedly reduced hepatic inflammation and oxidative stress. Finally, liver function tests significantly improved in rats receiving hAMSCs. In vitro experiments confirmed HSCs de-activation when co-cultured with stem cells. Conclusion. This pre-clinical study shows that infusion of human amniotic stem cells effectively decreases PP by ameliorating liver microcirculation, suggesting that it may represent a new treatment option for advanced cirrhosis with portal hypertension.

Project description:Persistent liver injury triggers a fibrogenic program that causes pathologic remodelling of the hepatic microenvironment (i.e., liver fibrosis) and portal hypertension. The dynamics of gene regulation during liver disease progression and regression remain understudied. Here, we generated hepatic transcriptome profiles in two well-established liver disease models at peak fibrosis and during spontaneous regression after the removal of the inducing agents. We linked the dynamics of key liver disease readouts, such as portal pressure, collagen proportionate area, and transaminase serum levels, to most differentially expressed genes, enabling the identification of transcriptomic signatures of progressive vs. regressive liver fibrosis and portal hypertension. These candidate biomarkers (e.g., Scube1, Tcf4, Src, Hmga1, Trem2, Mafk, Mmp7) were also validated in RNA-seq datasets of patients with cirrhosis and portal hypertension. Finally, deconvolution analysis identified major cell types and suggested an association of macrophage and portal hepatocyte signatures with portal hypertension and fibrosis area in both models.

Project description:Global gene expression profiling is useful for elucidating a drug?s mechanism of action (MOA) on the liver; however, such profiling in rats is not very sensitive for predicting human druginduced liver injury, while de-differentiated monolayers of primary human hepatocytes (PHHs) do not permit chronic drug treatment. In contrast, micropatterned co-cultures (MPCCs) containing PHH colonies and 3T3-J2 fibroblasts maintain a stable liver phenotype for 4-6 weeks. Here, we used MPCCs to test the hypothesis that global gene expression patterns in stable PHHs can be used to distinguish clinical hepatotoxic drugs from their non-liver-toxic analogs and understand the MOA prior to the onset of overt hepatotoxicity. We found that MPCCs treated with the clinical hepatotoxic/non-liver-toxic pair, troglitazone/rosiglitazone, at each drug?s reported and non-toxic Cmax (maximum concentration in human plasma) level for 1, 7, and 14 days displayed a total of 12, 269, and 628 differentially expressed genes, respectively, relative to the vehicle-treated control. Troglitazone modulated >75% of transcripts across pathways such as fatty acid and drug metabolism, oxidative stress, inflammatory response, and complement/coagulation cascades. Escalating rosiglitazone?s dose to that of troglitazone?s Cmax increased modulated transcripts relative to the lower dose; however, over half the identified transcripts were still exclusively modulated by troglitazone. Lastly, other hepatotoxins (nefazodone, ibufenac, and tolcapone) also induced a greater number of differentially expressed genes in MPCCs than their non-liver-toxic analogs (buspirone, ibuprofen, and entacapone) following 7 days of treatment. In conclusion, MPCCs allow evaluation of time- and dose-dependent gene expression patterns in PHHs treated chronically with analog drugs.

Project description:Gut-derived microbial metabolites have been shown to play key roles in human physiology and disease. However, establishing mechanistic links between gut microbial metabolites and disease pathogenesis in animal models presents many challenges. The major route of absorption for microbe-derived small molecules is venous drainage via the portal vein to the liver. In the event of extensive liver first pass- or presystemic hepatic metabolism, the route of administration of these metabolites becomes critical. Here we describe a novel portal vein cannulation technique using a subcutaneously implanted osmotic pump to achieve continuous portal vein infusion in mice. First, the microbial metabolite trimethylamine (TMA) was administered over 4 weeks and compared to a vehicle control. Using a liquid chromatography-tandem mass spectrometry (LC-MS/MS), an increase in peripheral plasma levels of TMA and its host liver-derived co-metabolite trimethylamine-N-oxide (TMAO) were observed in a sexually-dimorphic manner. Next, 4-hydroxyphenylacetic acid (4-HPAA), a structurally-distinct microbial metabolite that undergoes extensive hepatic first pass metabolism, was administered portally to examine its effects on hepatic gene expression. Peripheral plasma levels showed no difference in free or total 4-HPAA. However, while liver tissue demonstrated no difference in free 4-HPAA, total levels were increased when compared to the control group. More importantly, significant changes were observed in hepatic gene expression using an unbiased RNA sequencing approach. Collectively, this work describes a novel method for administering gut microbe-derived metabolites via the portal vein, mimicking their physiologic delivery in vivo.