Project description:Background and aims: Lethal liver failure is an important clinical issue. To overcome liver failure, we focused on liver regeneration mechanisms by activation of HSCs and KCs. It is known that the HSC-secreted Mac-2 binding protein glycan isomer (M2BPGi) has a function to activate Kupffer cells (KCs) in fibrotic liver. However, the importance and functional mechanism of liver regeneration by HSCs/M2BPGi/KCs axis in remnant liver after hepatectomy are still unknown. The aim of this study is to clarify whether the HSCs-derived M2BPGi can activate KCs in damaged-liver by not only fibrosis but also after hepatectomy and to elucidate the new molecular mechanism of liver regeneration by HSCs and KCs. Methods: We examined the effect of M2BPGi on human hepatocytes and KCs, and explored secretory factors from M2BPGi-activated KCs by proteomics approach. Further, the effect of Glucose-regulated protein 78 (GRP78) as one of the M2BPGi-related secreted proteins on liver regeneration was examined in in vitro analysis and mouse hepatectomy model. Results: Although M2BPGi had no hepatocyte promoting effect, M2BPGi promoted the production of GRP78 in KCs. The KCs-drived GRP78 promoted hepatocyte proliferation. GRP78 administration facilitated liver regeneration in 70% hepatectomy mice and increased the survival rate in lethal 90% hepatectomy mice with liver failure. Conclusion: The M2BPGi activated-KCs extract the GRP78 which facilitates liver regeneration via activation of the proliferation potency of hepatocytes. Moreover, GRP78 administration could improve the survival in the lethal mice model. Our data suggested that the new hepatotrophic factor GRP78 may be a promising therapeutic tool for lethal liver failure in the clinic.

Project description:Autoimmune hepatitis is an interface hepatitis characterized by the progressive destruction of the liver parenchyma, the cause of which is still obscure. Interleukin (IL)-17A is a major driver of autoimmunity, which can be produced by innate immune cells against several intracellular pathogens. Here, we investigated the involvement of IL-17A in a mice model of immune-mediated hepatitis with the intestine exposed to Salmonella typhimurium. Our results showed more severe Concanavalin (Con) A-induced liver injury and gut microbiome dysbiosis when the mice were treated with a gavage of S. typhimurium. Then the Natural Killer (NK) T cells were over-activated by the accumulated IL-17A in the liver in the Con A and S. typhimurium administration group. IL-17A could activate NKT cells by inducing CD178 expression via IL-4/STAT6 signaling. Furthermore, via the portal tract, the laminae propria mucosal-associated invariant T (MAIT) cell-derived IL-17A could be the original driver of NKT cells’ over-activation in intragastric administration of S. typhimurium and Con A injection. In IL-17A deficient mice, Con A-induced liver injury and NKT cells activation was alleviated. However, when AAV-sh-mIL-17a was used to specifically knock down IL-17A in liver, it seemed that hepatic IL-17a knock down did not significantly influence the liver injury. Our results suggested that, under Con A-induction, laminae propria MAIT-derived IL-17A activated hepatic NKT, and this axis could be a therapeutic target in autoimmune liver disease.

Project description:To characterise liver cells from wt, untreated adult male mice. In particular we are interested on hepatocytes (HCs), hepatic stellate cells (HSCs), liver sinuisoidal endothelial cells (LSECs), Kupffer cells (KCs) and cholangiocytes (CHs).

Project description:Cannabinoid 1 receptor (CB1R) expression is upregulated in hepatocytes during viral hepatitis, cirrhosis, and both alcoholic and non-alcoholic fatty liver disease (FLD), whereas its expression is muted under usual physiological conditions. Inhibiting CB1R has been shown to be beneficial in preserving hepatic function in FLD but it is unclear if inhibiting CB1R during an inflammatory response to an acute hepatic injury, such as toxin - induced injury, would also be beneficial. We tested if nullification of hepatocyte-specific CB1R (hCNR1-/-) in mice protects against concanavalin A (Con A) - induced liver injury. We looked for evidence of liver damage and markers of inflammation in response to Con A by measuring liver enzyme levels and proinflammatory cytokines (e.g., TNF-α, IL-1β, IL-6, IL-17) in serum collected from hCNR1-/- and control mice. We observed a shift to the right in the dose-response curve for liver injury and inflammation in hCNR1-/- mice. We also found less inflammatory cell infiltration and focal necrosis in livers of hCNR1-/- mice compared to controls, resulting from downregulated apoptotic markers. This anti-apoptotic mechanism results from increased activation of nuclear factor kappa B (NF-κB), especially membrane-bound TNF-α, via downregulated TNF-α receptor 2 (TNFR2) transcription levels. We also found that CB1R in hepatocytes regulated liver inflammation - related gene transcription. Collectively, these findings provide insight into involvement of CB1R in the pathogenesis of acute liver injury.

Project description:Hepatitis B virus (HBV) is known for its ability to interact with the host cell DNA methylation machinery. In HBV-infected hepatocytes, this interaction leads to chronic liver diseases, including hepatocellular carcinoma (HCC). We studied the extent of genomic changes induced by natural HBV infection in human primary hepatocytes. Transcriptome and methylome profiles were obtained at different time points post-infection to identify HBV-specific alterations. Although gene expression and DNA methylation do not directly correlate, they both seem to reflect the effect of cell culture and viral infection at different levels.These changes in the hepatocyte cellular program shed light on the initial events leading to HBV-associated liver diseases.

Project description:Kupffer cells (KCs) are highly abundant, intravascular, liver-resident macrophages long known for their scavenger and phagocytic functions. KCs are also able to present antigen to CD8+ T cells and promote either T cell tolerance or full effector differentiation, but the mechanisms underlying these discrepant outcomes are poorly understood. Here, we used a mouse model of hepatitis B virus (HBV) infection – where HBV-specific naïve CD8+ T cells recognizing hepatocellular antigens are driven into a state of immune dysfunction – to identify a subset of KCs (referred to as KC2) that improves the antiviral function of T cells upon exogenous administration of IL-2. Mechanistically, KC2 were found to be both enriched in the IL-2 sensing machinery and poised to productively cross-present hepatocellular antigens in response to this cytokine. Removing MHC-I from all KCs – including KC2 – as well as selectively depleting KC2 impaired the capacity of IL-2 to revert the T cell dysfunction induced by intrahepatic priming. Together, these findings indicate that, by sensing IL-2 and cross-presenting hepatocellular antigens, KC2 overcome the tolerogenic potential of the hepatic microenvironment and suggest new strategies for boosting T cell immunity in the liver.

Project description:Kupffer cells (KCs) are tissue-resident macrophages which colonize the developing liver early during embryogenesis1. Throughout development and adulthood, KCs have distinct core functions that are essential for liver and organismal homeostasis, such as supporting fetal erythropoiesis as well as postnatal erythrocyte recycling and liver metabolism2. KCs acquire their tissue-specific transcriptional signature immediately after colonizing the liver, mature together with the tissue, and adapt to the tissue’s function1,3,4. However, whether perturbation of macrophage core functions during development may contribute to or cause disease at postnatal stages is poorly understood. Here, we utilize a maternal obesity model to disturb KC functions during gestation. We show that offspring born to obese mothers develop fatty liver disease that is accompanied by a local pro-inflammatory response, a phenotype that is augmented if the offspring is kept on control diet after birth. Further, transcriptional analyses reveal that KCs undergo developmental programming through the maternal high-fat diet, which lasts until adulthood. The offspring’s KC developmental programming is irreversible despite the switch to control diet and leads to increased lipid uptake in hepatocytes mediated via paracrine factors stemming from KCs. The transcriptional programming of KCs and the fatty liver disease phenotype are rescued by genetic depletion of hypoxia-inducible factor alpha (Hif1a) in macrophages during gestation. These results demonstrate that macrophages rely on an undisturbed development to fulfil their core functions and support organ homeostasis during adulthood, and establish developmental programming of KCs as a therapeutic strategy for metabolic disorders, such as fatty liver disease.

Project description:Kupffer cells (KCs) are tissue-resident macrophages which colonize the developing liver early during embryogenesis1. Throughout development and adulthood, KCs have distinct core functions that are essential for liver and organismal homeostasis, such as supporting fetal erythropoiesis as well as postnatal erythrocyte recycling and liver metabolism2. KCs acquire their tissue-specific transcriptional signature immediately after colonizing the liver, mature together with the tissue, and adapt to the tissue’s function1,3,4. However, whether perturbation of macrophage core functions during development may contribute to or cause disease at postnatal stages is poorly understood. Here, we utilize a maternal obesity model to disturb KC functions during gestation. We show that offspring born to obese mothers develop fatty liver disease that is accompanied by a local pro-inflammatory response, a phenotype that is augmented if the offspring is kept on control diet after birth. Further, transcriptional analyses reveal that KCs undergo developmental programming through the maternal high-fat diet, which lasts until adulthood. The offspring’s KC developmental programming is irreversible despite the switch to control diet and leads to increased lipid uptake in hepatocytes mediated via paracrine factors stemming from KCs. The transcriptional programming of KCs and the fatty liver disease phenotype are rescued by genetic depletion of hypoxia-inducible factor alpha (Hif1a) in macrophages during gestation. These results demonstrate that macrophages rely on an undisturbed development to fulfil their core functions and support organ homeostasis during adulthood, and establish developmental programming of KCs as a therapeutic strategy for metabolic disorders, such as fatty liver disease.

Project description:To explore the effect of Bicd2 in Con A-induced acute autoimmune hepatitis, we conducted single cell RNA sequencing of AAV-scramble or AAV-shBicd2 infected mice livers in response to Con A injection.

Project description:Hepatitis B Virus constitutes a major threat to global public health by infecting hepatocytes, initiating and driving the progress to end-stage liver disease and liver cancer. Curing treatment for HBV infection is yet unavailable, mainly due to unmet gaps in current understanding of HBV-host interaction. Here, multi-omics interrogations were conducted to generate the first landscape of HBV-induced global changes in host transcriptome, translatome and proteome, which identified multiple translatomic events that HBV orchestrated to remodel host proteostasis networks and afford micro-environments essential for HBV proliferation and persistence.