Project description:Fibrosis, or scarring, can affect many organs including liver, lung, heart, kidney, intestines etc. and contributes to ~40% of mortality in the industrialized world. Unlike other organs, fibrosis in the liver typically resolves when the source of injury is extinguished. Elucidating the molecular mechanisms that underlie spontaneous fibrosis resolution may lead to novel antifibrotic strategies. In this study we established a robust mouse model of fibrosis regression in MASH (Metabolic dysfunction-Associated Steatohepatitis), a highly prevalent chronic liver disease worldwide, and performed single cell and in situ molecular profiling to define the molecular drivers of fibrosis regression. As fibrosis regressed, inflammatory cell numbers decreased and endothelial cell (EC) numbers increased. Prediction of cell-cell communication using the Calligraphy pipeline identified a Wnt9b-Sfrp2 crosstalk that emerged as fibrosis resolved. To investigate the Wnt9b-Sfrp2 crosstalk as a driver of fibrosis resolution we treated mice with recombinant SFRP2, a WNT inhibitor, which attenuated spontaneous fibrosis regression compared to vehicle-treated mice. Using single nucleus RNA sequencing, we identified a subset of liver ECs termed ‘Endo4’, as the source of Wnt9b. Immunostaining of the Endo4 marker VWF using tissue clearing and 3D imaging identified VWF+ vasculature surrounded by activated hepatic stellate cells (HSCs) that penetrated deep into the fibrotic septa, establishing them as de facto scar-associated ECs. Functionally, using a novel in situ protease activity-based probes, prominent serine protease activity was found to be co-localized with both scar-associated Endo4 ECs and HSCs. In summary, WNT-dependent endo-stellate crosstalk within the fibrotic niche represents a novel regulatory node in murine MASH fibrosis regression and a promising therapeutic target.

Project description:Fibrosis, or scarring, can affect many organs including liver, lung, heart, kidney, intestines etc. and contributes to ~40% of mortality in the industrialized world. Unlike other organs, fibrosis in the liver typically resolves when the source of injury is extinguished. Elucidating the molecular mechanisms that underlie spontaneous fibrosis resolution may lead to novel antifibrotic strategies. In this study we established a robust mouse model of fibrosis regression in MASH (Metabolic dysfunction-Associated Steatohepatitis), a highly prevalent chronic liver disease worldwide, and performed single cell and in situ molecular profiling to define the molecular drivers of fibrosis regression. As fibrosis regressed, inflammatory cell numbers decreased and endothelial cell (EC) numbers increased. Prediction of cell-cell communication using the Calligraphy pipeline identified a Wnt9b-Sfrp2 crosstalk that emerged as fibrosis resolved. To investigate the Wnt9b-Sfrp2 crosstalk as a driver of fibrosis resolution we treated mice with recombinant SFRP2, a WNT inhibitor, which attenuated spontaneous fibrosis regression compared to vehicle-treated mice. Using single nucleus RNA sequencing, we identified a subset of liver ECs termed ‘Endo4’, as the source of Wnt9b. Immunostaining of the Endo4 marker VWF using tissue clearing and 3D imaging identified VWF+ vasculature surrounded by activated hepatic stellate cells (HSCs) that penetrated deep into the fibrotic septa, establishing them as de facto scar-associated ECs. Functionally, using a novel in situ protease activity-based probes, prominent serine protease activity was found to be co-localized with both scar-associated Endo4 ECs and HSCs. In summary, WNT-dependent endo-stellate crosstalk within the fibrotic niche represents a novel regulatory node in murine MASH fibrosis regression and a promising therapeutic target.

Project description:The mechanisms of hepatic stellate cell (HSC) activation and the development of liver fibrosis remains largely unknow. Here, we revealed a fibrosis related mechanism of hepatocytes-HSCs crosstalk regulated by hepatocyte LONP1. We demonstrate that hepatocyte LONP1 expression is decreased in HFD-fed mice and MASH patients. Liver-specific LONP1 deficiency increases orotic acid level and aggravates MASH-induced liver fibrosis in mice. We have identified DHODH as a substrate that is selectively degraded by LONP1 in an ATP-dependent manner. Moreover, activation of LONP1 reduces orotic acid levels and alleviates MASH-induced fibrosis in mice. Mechanistically, LONP1 mediates DHODH turnover, maintaining lower orotic acid levels to inhibit ATF3-mediated HSC proliferation and activation, thereby preventing liver fibrosis. Furthermore, plasma orotic acid levels are negatively correlated with liver LONP1 levels in humans. Therefore, targeting LONP1-mediated hepatocyte-HSC communication may represent a promising therapeutic strategy for MASH-induced liver fibrosis.

Project description:While macrophage heterogeneity during Metabolic dysfunction-associated steatohepatitis (MASH) has been described, the fate of these macrophages during MASH regression is poorly understood. Comparing macrophage heterogeneity during MASH progression vs regression, we identified specific macrophage sub- populations that are critical for MASH/fibrosis resolution. We elucidated the restorative pathways and gene signatures that define regression associated macrophages (RAM) and establish the importance of TREM2+ macrophages during MASH regression. Liver resident Kupffer cells are lost during MASH and are replaced by four distinct monocyte derived macrophage sub-populations. Trem2 is expressed in two macrophage sub- populations: (i) monocyte-derived macrophages occupying the Kupffer cell niche (MoKC) and (ii) lipid-associated macrophages (LAM). In regression livers, no new transcriptionally distinct MF sub-population emerged. However, the relative macrophage composition changed during regression compared to MASH. While MoKC was the major macrophage sub-population during MASH, they decreased during regression. LAM was the dominant macrophage sub-type during MASH regression and maintained Trem2 expression. Both MoKC and LAM were enriched in disease resolving pathways. Absence of TREM2 restricted the emergence of LAMs and formation of hepatic crown like structures (hCLS). TREM2+ macrophages are functionally important not only for restricting MASH-fibrosis progression, but also for effective regression of inflammation and fibrosis. TREM2+ MF are superior collagen degraders. Lack of TREM2+ macrophages also prevented elimination of hepatic steatosis and inactivation of HSC during regression, indicating their significance in metabolic co-ordination with other cell- types in the liver. TREM2 imparts this protective effect through multifactorial mechanisms, including improved phagocytosis, lipid-handling and collagen degradation.

Project description:Recent studies have highlighted the beneficial effect of resolvin D1 (RvD1), a DHA-derived specialized pro-resolving mediator, on metabolic dysfunction-associated steatohepatitis (MASH), but the underlying mechanisms are not well understood. Our study aims to determine the mechanism by which RvD1 protects against MASH progression. RvD1 was administrated to MASH mice, followed by bulk and single-cell RNA sequencing analysis. Primary cells including bone marrow-derived macrophages (BMDMs), Kupffer cells, T cells, and primary hepatocytes were isolated to study the effect of RvD1 on inflammation, cell death, and fibrosis regression genes. RvD1 administration improved MASH features including reducing inflammation, cell death, and liver fibrosis. Mechanistically, RvD1 reduced inflammation by suppressing the stat1-cxcl10 signaling pathway in macrophages and prevented cell death by alleviating ER stress-mediated apoptosis in hepatocytes. Moreover, RvD1 induced Mmp2 and decreased Acta2 expression in hepatic stellate cells (HSCs), and promoted Mmp9 and Mmp12 expression in macrophages, leading to fibrosis regression in MASH. RvD1 reduced stat1-mediated pro-inflammatory response, mitigated ER stress-induced apoptosis, and promotes MMP-mediated fibrosis regression in MASH. Thus, our study highlights the therapeutic potential of RvD1 for MASH.

Project description:Recent studies have highlighted the beneficial effect of resolvin D1 (RvD1), a DHA-derived specialized pro-resolving mediator, on metabolic dysfunction-associated steatohepatitis (MASH), but the underlying mechanisms are not well understood. Our study aims to determine the mechanism by which RvD1 protects against MASH progression. RvD1 was administrated to MASH mice, followed by bulk and single-cell RNA sequencing analysis. Primary cells including bone marrow-derived macrophages (BMDMs), Kupffer cells, T cells, and primary hepatocytes were isolated to study the effect of RvD1 on inflammation, cell death, and fibrosis regression genes. RvD1 administration improved MASH features including reducing inflammation, cell death, and liver fibrosis. Mechanistically, RvD1 reduced inflammation by suppressing the stat1-cxcl10 signaling pathway in macrophages and prevented cell death by alleviating ER stress-mediated apoptosis in hepatocytes. Moreover, RvD1 induced Mmp2 and decreased Acta2 expression in hepatic stellate cells (HSCs), and promoted Mmp9 and Mmp12 expression in macrophages, leading to fibrosis regression in MASH. RvD1 reduced stat1-mediated pro-inflammatory response, mitigated ER stress-induced apoptosis, and promotes MMP-mediated fibrosis regression in MASH. Thus, our study highlights the therapeutic potential of RvD1 for MASH.

Project description:Liver fibrosis is a common pathological process in chronic liver disease, reflecting the advanced stage of the disease. Liver endothelial cells (ECs), especially liver sinusoidal endothelial cells (LSECs), are recognized as critical modulators of liver homeostasis and play essential roles in the recruitment and function of liver immune cells. However, the mechanism of liver EC injury and the occurrence of intercellular crosstalk in liver fibrosis are still unclear. In this study, C57BL/6 male mice were treated with CCl4 for 6 weeks to establish a liver fibrosis model. Masson staining and immunohistochemistry were performed to assess the extent of liver fibrosis. Liver endothelial injury was detected by using scanning electron microscopy (SEM) and PCR technology. Single-cell RNA sequencing (scRNA-seq) was performed to analyze phenotypic changes in nonparenchymal cells and dissect intercellular crosstalk in liver fibrosis. A total of 24,534 cells were analyzed and clustered into 10 main cell subsets. Liver ECs decreased significantly, and macrophage recruitment increased in the CCl4 group. The LSEC fenestrae and surface receptors expression were reduced, and the expression of Cd34 was upregulated. Liver ECs exhibited dense cellular crosstalk with immune cells such as macrophages, T cells, and B cells. The analysis of intercellular signaling pathways revealed that immune cells targeted liver ECs through the Ptprc-Mrc1 and Sell-Podxl signaling pathways to maintain intercellular interactions during liver fibrosis. We described the single-cell landscape of a liver fibrosis mouse model and demonstrated the presence of tight intracellular crosstalk between ECs with macrophages, T, and B cells, revealing cell-cell communications among liver immune cells-ECs during the process of liver fibrosis. The Ptprc-Mrc1 and Sell-Podxl signaling pathways exerted prominent roles in the interaction between immune cells and liver ECs.

Project description:Scar-associated endothelial-stellate cellular crosstalk drives fibrosis resolution in MASH [Spatial Transcriptomics]

Project description:Scar-associated endothelial-stellate cellular crosstalk drives fibrosis resolution in MASH [scRNA-Seq]

Project description:Scar-associated endothelial-stellate cellular crosstalk drives fibrosis resolution in MASH [snRNA-Seq]