Project description:The mammalian liver possesses a remarkable regenerative ability. 1) The 'oval cell' response emanates from the biliary tree when all hepatocytes are affected by chronic liver disease. 2) A massive, proliferative response of mature hepatocytes occurs upon acute liver damage such as partial hepatectomy (PHx). We establish a long-term 3D organoid culture system from mouse and human fetal/pediatric/adult hepatocytes that retain key morphological and functional features of hepatocytes fate. We report the mRNA and single cell sequencing of Hep-Orgs from different donors in different passages. We compared Hep-Orgs with primary hepatocytes, proliferative hepatocytes or Chol-Orgs derived from Epcam+ biliary cells. By analyzing, we determine similar gene expression profile of Hep-Orgs with primary hepatocytes and make genes lists distinguished with undamaged hepatocytes as well. We find the Hep-Orgs resemble proliferative damage-response of hepatocytes after partial hepatectomy while Chol-Orgs express high cholangiocytes markers. The sequencing data constitutes a valuable resource to understand liver organoids especially Hep-Orgs.

Project description:Background & Aims: The increasing requirements for hepatocytes in therapeutics and pharmacy call for an efficient system that enables large-scale production of functional hepatocytes in vitro. Hepatoblast (HB) hold the ability to regenerate liver when damaged, combined with organoid (org) technology, the culture of human pluripotent stem cell (hPSCs) derived HB-orgs was established under 2D culture system, enabling long-term expansion of HB in vitro. However, the expensive cost and the limitation of existing methods impede the further scale up of the production. Methods: Under 3D suspension culture conditions with the support of Matrigel at low concentration in conjunction with employing the developed (defined) medium, we developed a novel system to efficiently and reproducibly generate expandable HB-orgs and functional polarized hepatocyte organoids (P-hep-orgs) derived from hESCs. HB-orgs were further scaled up by dynamic culture in spinner flasks, and the maturity and function of P-hep-orgs was validated by transcriptome analysis and in vitro and in vivo hepatic functional assays. scRNA-seq was used to further profile HB-orgs and P-hep-orgs. Results: Our HB-orgs exhibited biopotency that could differentiate into functional hepatocytes and cholangiocytes. They proliferated actively at least for 15 passages with defined medium through avoiding the excessive autophagy under 3D suspension culture condition. HB-orgs showed higher proliferation rate in dynamic culture conditions and could reach 10^12 cell number at the initiate number of 3 million cells in only 4 weeks. With further differentiation, P-hep-orgs displayed characteristics of hepatocytes in liver, including the polarization state which mediated by integrin-AMPK signalling pathway, molecular features and improved liver functions. Moreover, P-hep-orgs were used for predicting the toxicity of various compounds, and modeling the development of hepatic lipid accumulation, as well as rescuing acute liver failure of mice. Conclusion: Our work provided a cost-efficient method for large-scale generation of 3D HB-orgs and 3D P-hep-orgs that hold considerable potential to be a robust platform for disease research, drug screening/development and toxic study, as well as clinical applications.

Project description:RNA sequencing was performed on liver organoids obtained from biopsies (b-Orgs) and paired tissues collected at different stages of alcohol-associated liver disease (ALD) using biliary (BEC) and hepatocyte (HEP) culture conditions. Different "generations" and passages of b-Orgs cultured with HEP medium were also sequenced. Besides, sequencing was also performed on vehicle and b-Orgs treated with Alcohol-associated hepatitis (AH)-medium. Finally, standard cholangiocyte organoids (Chol-Orgs) generated by dissociation of end-stage liver resections from ALD patients were sequenced.

Project description:The increasing requirements for hepatocytes in therapeutics and pharmacy call for an efficient system that enables large-scale production of functional hepatocytes in vitro. We developed a method to obtain HB-orgs and mature P-hep-orgs from hPSCs under 3D suspension culture system. HB-orgs showed bipotency and proliferate capacity, and P-hep-orgs exhibited hepatic polarization and mature hepatic functions. Single cell RNAseq was used to further profile HB-orgs and P-hep-orgs.

Project description:To investigate the cellular and molecular mechanisms that initiate liver regeneration and liver organoid formation, we performed RNA sequencing in the following cell types: hepatocytes from undamaged livers of mice as well as 6 h, 12 h, 24 h, 48 h, 72 h, 7 d, 14 d, 21 d of liver regeneration after PHx. Hep-Orgs were isolated from adult male mice hepatocytes and cultured for passages.

Project description:Organoids are emerging as a powerful human-based in vitro tool in the biomedical field. However, patient-derived liver organoids fail to recapitulate the liver epithelial heterogeneity and its generation still requires liver surgical resections, thus limiting personalized chronic liver diseases modeling. Here, we report the derivation of organoids from intact liver needle biopsies(b-Orgs) from alcohol-associated liver disease (ALD) patients for precision disease modeling and drug testing. B-Orgs were generated with an efficiency of 80% from patients with early and advanced stages of ALD. b-Orgs show an enriched hepatocyte phenotype as assessed by immunofluorescence, functional studies, and transcriptomics. Single cell RNA-sequencing revealed a heterogeneous epithelial composition comprising hepatocyte, biliary and progenitor hepatobiliary populations, mirroring the epithelial populations found in advanced ALD patients. Moreover, b-Orgs preserve disease-stage features, as b-Orgs from advanced ALD patients showed increased expression of genes related to epithelial-mesenchymal transition, angiogenesis and inflammation. Stimulation of b-Orgs with ethanol and pro-inflammatory mediators,promoted ALD features such asROS production, lipid accumulation, inflammation and decreased proliferation, which were mitigated in response to prednisolone. Overall, we provide a new methodology to obtain b-Orgs showing epithelial complexity and patient specific features, thus expanding organoid-based liver disease modelling for personalized medicine.

Project description:Liver fibrosis is characterized by the excessive formation and accumulation of matrix proteins as a result of wound healing in the liver. A main event during fibrogenesis is the activation of the liver resident quiescent hepatic stellate cell (qHSC). Recent studies suggest that reversion of the activated HSC (aHSC) phenotype into a quiescent-like phenotype could be a major cellular mechanism underlying fibrosis regression in the liver, thereby offering new therapeutic perspectives for the treatment of liver fibrosis. The goal of the present study is to identify experimental conditions that can revert the activated status of human HSCs and to map the molecular events associated with this phenotype reversion by gene expression profiling Transcriptomic profiling of primary human quiescent HSCs (qHSCs), in vitro activated HSCs (aHSCs) and in vitro reverted HSCs (rHSCs). The cell types come from different donors (This is detailed in the original manuscript.).

Project description:Hepatic stellate cells (HSCs) experience phenotypic transformation, from the quiescent phenotype to the activated one, after different etiologies of liver injury. Liver fibrosis is then occurred upon the activation of HSCs. miR-16 deficiency is identified to be an important characteristic of HSCs activation. We used Affymetrix rat 230 2.0 arrays (Affymetrix, Santa Clara, U.S.A.) to uncover the global alternations of transcriptome under miR-16 restoration. We isolated quiescent hepatic stellate cells (HSCs) from adult male SD rats (normal control group) by in situ perfusion and density-gradient centrifugation. Activated HSCs were separated from rats of fibrosis model group, which were treated by 40% carbon tetrachloride (CCl4) for 8 weeks, by means of liver section, digestion and sequential centrifugation. Quiescent and activated HSCs were then divided into 4 groups at random, namely quiescent HSCs, activated HSCs, pLV-miR-16-treated HSCs and pLV-GFP-treated HSCs. The pLV-miR-16-treated group, pLV-GFP-treated group were infected with pLV-miR-16 and pLV-GFP, respectively.

Project description:Liver fibrosis is an urgent clinical problem without effective treatment. Herein, we conducted a high-content screening on a natural “privileged” diterpenoid library to identify a potent anti-liver fibrosis lead DP. Leveraging photoaffinity labeling approach, apolipoprotein L2 (APOL2), an ER-rich protein, was identified as the direct target of DP. APOL2 is mainly expressed in activated hepatic stellate cells (HSCs) and could activate HSCs to synthesize ECM proteins. It can be induced by TGF-β1 and be antagonized by DP. Mechanistically, upon TGF-β1stimulation, APOL2 binds ER Ca2+ pump SERCA2 to trigger ER stress, elevating its downstream PERK-HES1 axis to promote liver fibrosis, mildly dependent on the canonical TGF-β/Smad signaling. As a result, ablation of APOL2 significantly alleviated TGF-β1-stimulated HSCs activation, and abolished anti-fibrosis effect of DP. Our findings not only define APOL2 as a novel therapeutic target for liver fibrosis, but also highlight DP as a promising lead for treatment of this symptom.

Project description:Unveiling the regulatory pathways maintaining hepatic stellate cells (HSC) in a quiescent (q) phenotype is essential to develop new therapeutic strategies to treat fibrogenic diseases. To uncover the miRNA-mRNAs regulatory interactions in qHSCs, HSCs were FACS-sorted from healthy livers and activated HSCs were generated in vitro. MiRNA Taqman array analysis showed HSCs expressed a low number of miRNA, from which 46 were down-regulated and 212 up-regulated upon activation. Computational integration of miRNA and gene expression profiles revealed that 66% of qHSCs miRNAs correlated with more than 6 altered targeted mRNAs (17,28±10,7 targets/miRNA), whereas aHSC-associated miRNAs had an average of 1,49 targeted genes. Interestingly, interaction networks generated by miRNA-targeted genes in qHSCs were associated with key HSCs activation processes. Next, selected miRNAs were validated in healthy and cirrhotic human livers and miR-192 was chosen for functional analysis. Down-regulation of miR-192 in HSC was found to be an early event during fibrosis progression in mouse models of liver injury. Moreover, mimic assays for miR-192 in HSCs revealed its role in HSC activation, proliferation and migration. Together, these results uncover the importance of miRNAs in the maintenance of qHSC phenotype and form the basis for understanding the regulatory networks in HSCs. Transcriptomic profile derived from four quiescent hepatic stellate (QHSC), four activated hepatic stellate (AHSC), three liver sinusoidal endothelial (LSEC) and two hepatocytes cells (HEP).