Project description:Objective: Alcoholic hepatitis (AH) is characterized by the expansion of ductular reaction (DR) cells and expression of liver progenitor cell (LPC) markers. The aim of this study was to identify the gene expression profile and associated genes of DR cells and to evaluate its weight in alcoholic disease progression. Design: KRT7+, KRT7- and total liver fractions were laser microdissected from liver biopsies (n=6) of patients with AH and whole transcriptome was sequenced. Gene signature was assessed in transcriptomic data from 41 patients with alcoholic liver disease. Pro-inflammatory profile was evaluated in tissue and serum samples and in human LPC organoids. Results: Transcriptome analysis of KRT7+ DR cells uncovered intrinsic gene pathways of DR and allowed identifying genes associated with DR expressed in AH. In addition, DR gene signature and associated genes correlated with disease progression and poor outcome in AH patients. Importantly, DR presented a pro-inflammatory profile with expression of CXC and CCL chemokines and was associated with infiltrating neutrophils. Moreover, LPC markers correlated with liver expression and circulating levels of inflammatory mediators. In vitro, human LPC organoids mimicked ductular reaction gene expression profile and produced chemokines. Moreover, LPC promoted neutrophil migration and enhanced their inflammatory profile. Conclusions: Here we report for the first time the gene expression signature of DR in AH and its association with disease progression. Functional and experimental analysis demonstrates that DR cells have a pro-inflammatory profile, and suggest their involvement in neutrophil recruitment and liver inflammatory response.

Project description:Background & aims: The role of microRNAs (miRNAs) in Alcoholic Hepatitis (AH) and their potential as therapeutic targets in liver disease has not been explored yet. This study aims at profiling miRNA in AH and identifying dysregulated miRNAs involved in AH pathophysiology. Methods: miRNA expression arrays were performed in 13 AH, 5 alcohol liver disease-induced cirrhosis (ALD-CH), 5 nonalcoholic steatohepatitis induced cirrhosis (NASH-CH), 4 HCV-induced cirrhosis (HCV-CH) and 6 non-injured liver control samples. Genome wide expression profile was retrieved for 12 paired AH and control samples. MiRNA and mRNA expression data was integrated and identified miRNAs were validated in AH samples and in animal models of liver injury. Results: The miRNA array showed 111 upregulated and 66 downregulated miRNAs in AH versus healthy subjects. The comparison of miRNA profile in liver samples from AH among ALD-CH, HCV-CH and NASH-CH identified 18 miRNAs specifically dysregulated in AH. Integrative miRNA and mRNA analysis in AH identified dysregulated miRNAs for which their target genes were also dysregulated. A functional analysis of identified miRNAs and their targets revealed their involvement in the regulation of canonical pathways related to apoptosis, fatty acid metabolism and cell cycle among others. miRNAs expression (miR-182, miR-21, miR-155, miR-214, miR-432, miR-422a) was validated in an independent cohort of AH. MiR-182 expression correlated with cholestasis, disease severity and short-term mortality. Moreover, miR-182 expression is associated to cholestasis with ductular reaction but not to fibrosis and inflammation in animal models of liver injury. Conclusions: AH is characterized by an important dysregulation of miRNA expression with a unique miRNA profile. MiRNAs specifically expressed in AH are associated to cholestasis… Uncovered miRNAs are involved in important pathophysiological features in AH suggesting ta regulation of he role of miRNAs in the regulation of AH, and highlight miR-182 as a potential regulator of its pathophysiology. miRNA expression arrays were performed in 13 AH(Alcoholic hepatitis), 5 alcohol liver disease-induced cirrhosis (ALD-CH), 5 nonalcoholic steatohepatitis induced cirrhosis (NASH-CH), 4 HCV-induced cirrhosis (HCV-CH) and 6 non-injured liver control samples(CTRL).

Project description:Purpose: Cholestatic liver injury is associated with intrahepatic biliary fibrosis, which can progress to cirrhosis. Resident hepatic progenitor cells (HPCs) expressing Prominin-1 (Prom1/CD133) become activated and participate in the expansion of cholangiocytes known as the ductular reaction. Previously, we demonstrated that in biliary atresia, Prom1(+) HPCs are present within developing fibrosis and that null mutation of Prom1 significantly abrogates fibrogenesis. Here, we hypothesized that these activated Prom1-expressing HPCs promote fibrogenesis in cholestatic liver injury. Methods: Using Prom1CreERT2-nLacZ/+;Rosa26Lsl-GFP/+ mice, we traced the fate of Prom1-expressing HPCs in the growth of the neonatal and adult livers and in biliary fibrosis induced by bile duct ligation (BDL). Results: Prom1-expressing cell lineage labeling with Green Fluorescent Protein (GFP) on postnatal day 1 exhibited an expanded population as well as bipotent differentiation potential towards both hepatocytes and cholangiocytes at postnatal day 35. However, in the adult liver, they lost hepatocyte differentiation potential. Upon cholestatic liver injury, adult Prom1-expressing HPCs gave rise to both PROM1(+) and PROM1(-) cholangiocytes contributing to ductular reaction without hepatocyte or myofibroblast differentiation. RNA-sequencing analysis of GFP(+) Prom1-expressing HPC lineage revealed a persistent cholangiocyte phenotype and evidence of Transforming Growth Factor-b pathway activation. Conclusion: Our data indicate that Prom1-expressing HPCs promote biliary fibrosis by activation of myofibroblasts in cholestatic liver injury.

Project description:We previously showed that severe liver diseases are characterized by expansion of liver progenitor cells (LPC), which correlates with disease severity. However, the origin and role of LPC in liver physiology and in the hepatic response to injury remains a contentious topic. We have now used genetic lineage tracing of Hnf1β-expressing biliary duct cells to assess their contribution to LPC expansion and hepatocyte generation during normal liver homeostasis, and following different types of liver injury. We found that ductular reaction cells in human cirrhotic livers express HNF1β. However, HNF1β expression was not present in newly generated EpCAM-positive hepatocytes. Using a tamoxifen-inducible Hnf1βCreER/R26RYFP/LacZ mouse, we show that there is no contribution of the biliary epithelium to hepatocyte turnover during liver homeostasis in healthy mice. Moreover, after loss of liver mass, Hnf1β+ LPC did not contribute to hepatocyte regeneration. We also assessed the contribution of Hnf1β+ cells following acute and repeated liver injury. All animal models showed expansion of LPC, as assessed by immunostaining and gene expression profile of sorted YFP-positive cells. A contribution of Hnf1β+ LPC to hepatocyte generation was not detected in animal models of liver injury with preserved hepatocyte regenerative potential such as acute acetaminophen, carbon tetrachloride injury, or chronic diethoxycarbonyl-1,4-dihydro-collidin (DDC)-diet. However, in mice fed with choline-deficient ethionine-supplemented (CDE)-diet, which causes profound hepatocyte damage and arrest, a small number of hepatocytes were derived from Hnf1β+ cells. Conclusion: Hnf1β+ cells do not participate in hepatocyte turnover in the healthy liver or during liver regeneration after partial hepatectomy. After liver injury, LPC arise from the biliary duct epithelium, which gives rise to a limited number of hepatocytes only when hepatocyte regeneration is compromised. Transcriptomic profile using MoGeneST-2.0 chip from 3 samples of YFP+ CDE, 3 samples of YFP+ DDC, 2 samples of YFP+ UTR and 3 samples YFP-

Project description:Background & aims: The role of microRNAs (miRNAs) in Alcoholic Hepatitis (AH) and their potential as therapeutic targets in liver disease has not been explored yet. This study aims at profiling miRNA in AH and identifying dysregulated miRNAs involved in AH pathophysiology. Methods: miRNA expression arrays were performed in 13 AH, 5 alcohol liver disease-induced cirrhosis (ALD-CH), 5 nonalcoholic steatohepatitis induced cirrhosis (NASH-CH), 4 HCV-induced cirrhosis (HCV-CH) and 6 non-injured liver control samples. Genome wide expression profile was retrieved for 12 paired AH and control samples. MiRNA and mRNA expression data was integrated and identified miRNAs were validated in AH samples and in animal models of liver injury. Results: The miRNA array showed 111 upregulated and 66 downregulated miRNAs in AH versus healthy subjects. The comparison of miRNA profile in liver samples from AH among ALD-CH, HCV-CH and NASH-CH identified 18 miRNAs specifically dysregulated in AH. Integrative miRNA and mRNA analysis in AH identified dysregulated miRNAs for which their target genes were also dysregulated. A functional analysis of identified miRNAs and their targets revealed their involvement in the regulation of canonical pathways related to apoptosis, fatty acid metabolism and cell cycle among others. miRNAs expression (miR-182, miR-21, miR-155, miR-214, miR-432, miR-422a) was validated in an independent cohort of AH. MiR-182 expression correlated with cholestasis, disease severity and short-term mortality. Moreover, miR-182 expression is associated to cholestasis with ductular reaction but not to fibrosis and inflammation in animal models of liver injury. Conclusions: AH is characterized by an important dysregulation of miRNA expression with a unique miRNA profile. MiRNAs specifically expressed in AH are associated to cholestasis… Uncovered miRNAs are involved in important pathophysiological features in AH suggesting ta regulation of he role of miRNAs in the regulation of AH, and highlight miR-182 as a potential regulator of its pathophysiology.

Project description:During chronic liver injury, the ductular reaction generates hepatocytes. The aim of the analysis is to compare the phenotype of the DR-derived hepatocytes with that of native hepaotcytes in the same injured liver and control healthy hepatocytes.

Project description:Recent studies suggested that embryonic stem cells (ESCs) and induced pluripotent stem cells (iPSCs) may represent different pluripotent states as defined by gene expression profiles and differentiation potential. Here we addressed a contribution of a lineage stage-specific donor cell memory in modulating the functional properties of iPSCs. iPSCs were generated from hepatic lineage cells at an early (hepatoblast-derived, HB-iPSCs) and end stage (adult hepatocyte, AH-iPSCs) of hepatocyte differentiation as well as from mouse fetal fibroblasts (MEF-iPSCs) using a lentiviral vector encoding four pluripotency-inducing factors Oct4, Sox2, Klf4, and c-Myc. All resulting iPS cell lines acquired iPSCs phenotype as judged by the accepted criteria including morphology, expression of pluripotency markers, silencing of transducing factors, capacity of multilineage differentiation in teratoma assay and normal diploid karyotype. However, hepatoblasts were more susceptible to reprogramming than either AH or MEF, and HB-iPSCs were more efficient in directed differentiation towards hepatocytic lineage as compared to AH-iPSCs, MEF-iPSCs or mESCs. Extensive comparative transcriptome analyses of the early passage iPSCs, donor cells and mESCs revealed that despite global similarities in gene expression patterns between generated iPSCs and mESCs, HB-iPSCs retained a transcriptional memory (7 up- and 20 down-regulated genes) typical of the original cells. Continuous passaging of HB-iPSCs abolished most of these differences including a superior capacity of hepatic re-differentiation. These results suggest that retention of lineage stage-specific donor memory in iPSCs may facilitate differentiation into donor cell type. The identified gene set may be helpful to improve hepatic differentiation for therapeutic application in liver disease modeling.

Project description:We previously showed that severe liver diseases are characterized by expansion of liver progenitor cells (LPC), which correlates with disease severity. However, the origin and role of LPC in liver physiology and in the hepatic response to injury remains a contentious topic. We have now used genetic lineage tracing of Hnf1β-expressing biliary duct cells to assess their contribution to LPC expansion and hepatocyte generation during normal liver homeostasis, and following different types of liver injury. We found that ductular reaction cells in human cirrhotic livers express HNF1β. However, HNF1β expression was not present in newly generated EpCAM-positive hepatocytes. Using a tamoxifen-inducible Hnf1βCreER/R26RYFP/LacZ mouse, we show that there is no contribution of the biliary epithelium to hepatocyte turnover during liver homeostasis in healthy mice. Moreover, after loss of liver mass, Hnf1β+ LPC did not contribute to hepatocyte regeneration. We also assessed the contribution of Hnf1β+ cells following acute and repeated liver injury. All animal models showed expansion of LPC, as assessed by immunostaining and gene expression profile of sorted YFP-positive cells. A contribution of Hnf1β+ LPC to hepatocyte generation was not detected in animal models of liver injury with preserved hepatocyte regenerative potential such as acute acetaminophen, carbon tetrachloride injury, or chronic diethoxycarbonyl-1,4-dihydro-collidin (DDC)-diet. However, in mice fed with choline-deficient ethionine-supplemented (CDE)-diet, which causes profound hepatocyte damage and arrest, a small number of hepatocytes were derived from Hnf1β+ cells. Conclusion: Hnf1β+ cells do not participate in hepatocyte turnover in the healthy liver or during liver regeneration after partial hepatectomy. After liver injury, LPC arise from the biliary duct epithelium, which gives rise to a limited number of hepatocytes only when hepatocyte regeneration is compromised.

Project description:In other to assess functional involvement of Klf5 in DR regulation, we made liver-specific Klf5 knockout mice. Ductular reaction upon cholestatic liver injury is severely suppressed in these mice. We conducted RNA-seq analysis on the BECs from control mice and Klf5 LKO mice upon DDC injury to further elucidate the Klf5 functions.

Project description:Recent studies suggested that embryonic stem cells (ESCs) and induced pluripotent stem cells (iPSCs) may represent different pluripotent states as defined by gene expression profiles and differentiation potential. Here we addressed a contribution of a lineage stage-specific donor cell memory in modulating the functional properties of iPSCs. iPSCs were generated from hepatic lineage cells at an early (hepatoblast-derived, HB-iPSCs) and end stage (adult hepatocyte, AH-iPSCs) of hepatocyte differentiation as well as from mouse fetal fibroblasts (MEF-iPSCs) using a lentiviral vector encoding four pluripotency-inducing factors Oct4, Sox2, Klf4, and c-Myc. All resulting iPS cell lines acquired iPSCs phenotype as judged by the accepted criteria including morphology, expression of pluripotency markers, silencing of transducing factors, capacity of multilineage differentiation in teratoma assay and normal diploid karyotype. However, hepatoblasts were more susceptible to reprogramming than either AH or MEF, and HB-iPSCs were more efficient in directed differentiation towards hepatocytic lineage as compared to AH-iPSCs, MEF-iPSCs or mESCs. Extensive comparative transcriptome analyses of the early passage iPSCs, donor cells and mESCs revealed that despite global similarities in gene expression patterns between generated iPSCs and mESCs, HB-iPSCs retained a transcriptional memory (7 up- and 20 down-regulated genes) typical of the original cells. Continuous passaging of HB-iPSCs abolished most of these differences including a superior capacity of hepatic re-differentiation. These results suggest that retention of lineage stage-specific donor memory in iPSCs may facilitate differentiation into donor cell type. The identified gene set may be helpful to improve hepatic differentiation for therapeutic application in liver disease modeling. A total of 200 ng RNA from four independent biological replicates of MACS-sorted mESC and iPSC were linearly amplified according to manufactures’ specification (Ambion, Austin, Tx,). For in vitro transcription (IVT), reactions were incubated for 16 h at 37ºC. The efficiency of the single round amplification was measured by NanoDrop (ND1000, Thermo Scientific). Hybridization, washing, detection (Cy3-streptavidin, Amersham Biosciences, GE Healthcare), and scanning were performed on an illumina iScan system (Illumina) using reagents and following protocols supplied by the manufacturer. The biotinylated cRNA (750 ng/sample) was hybridized on Sentrix beadchips human Ref-8v3 for 18 h at 58ºC while rocking (5 rpm).