Project description:Non-alcoholic steatohepatitis (NASH) is a life-threatening liver disease for which no drug has been approved. We have previously shown that human-derived hepatic in vitro models can be used to mimic key cellular mechanisms involved in the progression of NASH. In the present study, we first assess the predictive capacity of different in vitro models and then investigate how the reduction of NASH-specific parameters upon treatment with elafibranor, a PPAR-α/δ agonist, correlates with clinical NASH-resolution obtained through bariatric surgery. Whole genome transcriptomics analyses revealed that in vitro NASH models based on primary human hepatocytes (PHH), HepaRG and human skin stem cell-derived hepatic progenitors (hSKP-HPC) exhibit up to 35% overlap with publicly available datasets of liver biopsies of 4 cohorts of NASH patients. Exposure of the in vitro NASH models to elafibranor partially reverses these human-specific transcriptional NASH signatures, with the hSKP-HPC-derived NASH model showing the most sensitive response. NASH-specific transcriptomic changes observed in patients that underwent bariatric surgery correlated with the changes observed in the in vitro NASH models exposed to the PPAR-α/δ agonist. PPARGC1A, PPARA and SIRT1 are shared upstream regulators in the PHH-, HepaRG- and hSKP-HPC NASH models exposed to elafibranor. Activation of these upstream regulators increases the expression of ANGPTL4, PDK4 and PLIN2, while this does not occur in patients that underwent bariatric surgery, suggesting an adverse effect on lipid metabolism. In conclusion, pathologic and therapeutic (anti-)NASH-specific transcriptional responses can be mimicked in PHH, HepaRG and hSKP-HPC, while the latter most sensitively responds to drug testing. PPAR-α/δ agonism adversely modulates pro-steatogenic genes which deserves attention in further studies.

Project description:A barrier to drug development for non-alcoholic steatohepatitis (NASH) is the absence of translational pre-clinical human-relevant systems. An in vitro liver model was engineered to incorporate hepatic sinusoidal flow, transport, and lipotoxic stress risk factors (glucose, insulin, free fatty acids) with co-cultured primary human hepatocytes, hepatic stellate cells (HSC), and macrophages. Transcriptomic, lipidomic, and functional endpoints were evaluated and compared to clinical data from NASH patient biopsies. The lipotoxic milieu promoted hepatocyte lipid accumulation (4-fold increase, p<0.01) and a lipidomics signature similar to NASH biopsies. Hepatocyte glucose output increased with decreased insulin sensitivity. These changes were accompanied by increased inflammatory analyte secretion (e.g. IL6, IL8, ALT). Fibrogenic activation markers increased with lipotoxic conditions, including secreted TGFβ (>5-fold increase, p<0.05), extracellular matrix gene expression, and HSC activation. Significant pathway correlation existed between this in vitro model and human biopsies. Consistent with clinical trial data, 0.5μM obeticholic acid in this model promoted a healthy lipidomic signature, reduced inflammatory and fibrotic secreted factors, but also increased ApoB secretion, suggesting a potential adverse effect on lipoprotein metabolism. Lipotoxic stress activates similar biological signatures observed in NASH patients in this system, which may be relevant for interrogating novel therapeutic approaches to treat NASH.

Project description:The mechanisms underlying the progression of non-alcoholic steatohepatitis (NASH) are not completely elucidated. In this study we have integrated gene expression profiling of liver biopsies of NASH patients with translational studies in a mouse model of steatohepatitis and with pharmacological interventions in isolated hepatocytes to identify a novel mechanism implicated in the pathogenesis of NASH. By using high-density oligonucleotide microarray analysis we identified a significant enrichment of known genes involved in the multi-step catalysis of long chain polyunsaturated fatty acids, including delta-5 and 6 desaturases. A combined inhibitor of delta-5 and delta-6 desaturases significantly reduced intracellular lipid accumulation and inflammatory gene expression in isolated hepatocytes. Gas chromatography analysis revealed impaired delta-5 desaturase activity toward the omega-3 pathway in livers from mice with high-fat diet (HFD)-induced NASH. Consistently, restoration of omega-3 index in transgenic fat-1 mice expressing an omega-3 desaturase, which allows the endogenous conversion of omega-6 into omega-3 fatty acids, produced a significant reduction in hepatic insulin resistance, hepatic steatosis, macrophage infiltration and necroinflammatory liver injury, accompanied by attenuated expression of genes involved in inflammation, fatty acid uptake and lipogenesis. These results were comparable to those obtained in a group of mice receiving a HFD supplemented with EPA/DHA. Of interest, hepatocytes from fat-1 mice or supplemented with EPA exhibited synergistic anti-steatotic and anti-inflammatory actions with the delta-5/ delta-6 inhibitor. Conclusion: These findings indicate that both endogenous and exogenous restoration of the hepatic balance between omega-6 and omega-3 fatty acids and/or modulation of desaturase activities exert preventive actions in NASH. The complete database comprised the expression measurements of 18185 genes for liver sample groups: 8 non-alcoholic steatohepatitis (NASH ) and 7 control samples. This dataset is part of the TransQST collection.

Project description:Currently, there are no established treatments for NAFLD/NASH. Treatment recommendations include weight reduction through both diet and physical exercise, and weight-loss surgery for extreme obesity. Most medical regimens target components of the metabolic syndrome or oxidative stress associated with the pathogenesis of NASH. These include anti-obesity regimens, insulin sensitizers, anti-hyperlipidemics, and antioxidants. Thus, a need exists to validate approaches that might help the development and progression of hepatic steatosis, oxidative stress, and inflammation in association with NAFLD.

Project description:Hepatocellular carcinoma (HCC) has dismal treatment responses to systemic therapies and is caused by both, viral and non-viral etiologies, including non-alcoholic steatohepatitis (NASH) 1–5. NASH - triggered by high caloric intake and sedentary lifestyle - has become an important driver for HCC development. Immunotherapy has been recently approved for HCC but stratification of responders versus non-responders has remained an unmet need 5–8. Here, we found a progressive accumulation of non-classical activated CD8+PD-1+ T-cells in livers of NASH-affected patients and mice. PD-L1/PD-1-targeted immunotherapy of NASH-induced HCC administered either at cancer-initiation or after cancer-establishment lacked beneficial effects in mice. On the contrary, PD-1-targeted immunotherapy drove hepatic necro-inflammation and increased liver cancer incidence, tumor number, and nodule size. Anti-CD8 or anti-CD8/anti-NK1.1 treatment suppressed liver cancer development, implicating CD8+ T-cells as liver cancer drivers in the context of NASH. In line, PD-1-/- mice challenged with a NASH-inducing diet displayed early-onset of liver cancer. Mechanistically, PD-1-targeted immunotherapy triggered necro-inflammation and a pro-tumorigenic environment in the context of NASH, increasing the abundance of hepatic TOX+CXCR6+ expressing CD8+PD-1+ TNF+ T-cells. Anti-CD8/anti-PD-1 or anti-TNF/anti-PD-1, but not anti-CD4/anti-PD-1 treatment reverted anti-PD1 treatment-related increase of liver inflammation, NASH severity and tumorigenesis. Gene expression profile and increased abundance of murine hepatic CD8+PD-1+ T-cells were corroborated in human CD8+PD-1+ T cells derived from NASH patients. In a meta-analysis of clinical trials testing PD-1-targeting immune checkpoint inhibitors alone (i.e. pembrolizumab) or in combination in 1656 patients with advanced HCC, immunotherapy was not favorable over to control treatment in non-viral- when compared to viral-related HCC. Similarly, in two clinical cohorts tested, patients with NASH-driven HCC had a significantly worse overall survival with PD-1-targeted immunotherapy than HCC patients with other etiologies. Our data identify non-viral etiologies, particularly NASH, as potentially non-responsive in the context of HCC immunotherapy, providing a strong rational basis for patient stratification.

Project description:Non-alcoholic fatty liver disease/steatohepatitis (NAFLD/NASH) is a significant risk factor for hepatocellular carcinoma (HCC). However, a preclinical model of progressive NAFLD/NASH is largely lacking. Here, we report that mice with hepatocyte-specific deletion of Tid1, encoding a mitochondrial cochaperone, tended to develop NASH-dependent HCC. Mice with hepatic Tid1 deficiency showed impairing mitochondrial function and causing fatty acid metabolic dysregulation; meanwhile, sequentially developed fatty liver, NASH, and cirrhosis/HCC in a diethylnitrosamine (DEN) induced oxidative environment. The pathological signatures of human NASH, including cholesterol accumulation and activation of inflammatory and apoptotic signaling pathways, are also present in these mice. Clinically, low Tid1 expression was associated with unfavorable prognosis in patients with HCC. Empirically, hepatic Tid1 deficiency directly disrupts entire mitochondria that play a key role in the NASH-dependent HCC development. Overall, we established a new mouse model that develops NASH-dependent HCC and provides a promising approach to improve the treatment.

Project description:Non-alcoholic steatohepatitis (NASH), which is increasing in incidence due to the obesity epidemic, is a T-cell mediated, auto-aggressive condition that can result in progressive liver disease and hepatocellular carcinoma (HCC). The gut-liver axis contributes to NASH, yet mechanisms underlying metabolic T-cell activation and NASH-related fibrosis have largely remained elusive. We found that gastrointestinal B-cells are activated and increased in number in mouse/human NASH, allowing metabolic T-cell activation to induce NASH antigen- and microbiota-independently. Genetic/therapeutic depletion of B-cells systemically or of gastrointestinal B-cells specifically, prevented or reverted NASH and fibrosis. Secretion of immunoglobulins was essential for NASH and fibrosis development. IgA secretion was necessary for fibrosis-induction by activating CD11b+CCR2+F4/80+CD11c-FCGR1+ hepatic myeloid cells through an IgA-FcRγ signaling-axis. Furthermore, clinical/molecular analyses from NASH-patients demonstrated IgA and activated FcRγ+ hepatic myeloid cells to correlate with the degree of liver-fibrosis. Thus, gastrointestinal B-cells and the IgA-FcRγ signaling-axis on hepatic myeloid cells represent potential therapeutic targets to treat NASH.

Project description:Necroptosis contributes to hepatocyte death (HC) in non-alcoholic steatohepatitis (NASH), but the fate and roles of necroptotic hepatocytes (necHCs) in NASH remain unknown. We show here that the accumulation of necHCs is associated with worsening NASH in humans and in mice with diet-induced NASH and that NASH liver showed evidence of impaired necHC clearance by liver macrophages. Further, the "don't-eat-me" ligand CD47 on HCs and its receptor, SIRPα, on liver macrophages, were markedly upregulated in human and mouse NASH. In vitro, anti-CD47 or anti-SIRPα promoted necHC engulfment by primary liver macrophages. In a proof-of-concept mouse model of inducible HC necroptosis, anti-CD47 increased necHC uptake by liver macrophages and inhibited hepatic stellate cell (HSC) activation, which is responsible for liver fibrogenesis. Most importantly, treatment of two mouse models of diet-induced NASH with anti-CD47 or anti-SIRPα increased the uptake of necHC by liver macrophages and decreased HSC activation and liver fibrosis. These findings provide evidence that impaired clearance of necHCs by liver macrophages due to CD47-SIRPα upregulation contributes to fibrotic NASH and suggest therapeutic blockade of the CD47-SIRPα axis as a strategy to decrease the accumulation of necHCs in NASH liver and dampen the progression of hepatic fibrosis.

Project description:Background and Aims: Nonalcoholic steatohepatitis (NASH) will soon become the leading cause of liver transplantation in the US and is also associated with increased COVID-19 mortality. Currently, there are no FDA approved drugs available that slow NASH progression or address NASH liver involvement in COVID-19. Since animal models cannot fully recapitulate human NASH, we hypothesized that stem cells isolated directly from end-stage NASH patient liver may address current knowledge gaps in human NASH pathology. Approach and Results: We devised methods allowing derivation, proliferation, hepatic differentiation and extensive characterization of bipotent ductal organoids from irreversibly damaged NASH patient liver. The transcriptomes of organoids derived from NASH liver, but not healthy liver show significant upregulation of pro-inflammatory and cytochrome p450-related pathways, as well as of known liver fibrosis and tumor markers, with the degree of upregulation being NASH patient-specific.

Project description:Non-alcoholic fatty liver (NAFL) has the potential to progress to non-alcoholic steatohepatitis (NASH) or to promote type 2 diabetes mellitus (T2DM). However, NASH and T2DM do not always develop coordinately. We established rat models of NAFL, NASH, and NAFL + T2DM to recapitulate different phenotypes associated with NAFLD and its progression. Microarrays were used to identify hepatic gene expression changes in each of these models. The goal is to identify a predictor of different NAFLD progressions. Non-alcoholic fatty liver disease (NAFLD) is recognized as a low-grade systemic inflammatory state with both hepatic and extra-hepatic manifestations. We aimed to identify common key regulators and adaptive pathways in different NAFLD phenotypes. NAFL, NASH and NAFL+T2DM rat models were used to represent simple fatty liver, fatty liver with severe hepatic manifestations, and fatty liver with severe metabolic manifestations, respectively. We applied microarray analysis to characterize the key regulators and adaptive pathways in different NAFLD phenotypes. There are 12 samples in our study which belonged to 4 groups, and each group contains 3 different samples.