Project description:Hepatocellular carcinoma (HCC) is a leading cause of cancer-related death, often diagnosed at advanced stages and characterized by high recurrence rates. While chronic liver inflammation and metabolic dysfunction are recognized contributors to tumorigenesis, the molecular mechanisms linking early microenvironmental stress to malignant transformation remain poorly understood. MYCN, a proto-oncogenic transcription factor, has emerged as a potential biomarker of cancer stemness, yet its functional role in hepatocarcinogenesis is unclear. Here, we elucidate the oncogenic role of MYCN and its dynamic regulation during metabolic liver tumorigenesis.Using a transposon system in mice and the human hepatocyte cell line Hc, we demonstrate that MYCN overexpression functionally promotes liver tumorigenesis and hepatocyte transformation. Transcriptomic profiling of MYCN-driven tumors revealed molecular features resembling human HCC subtypes enriched in stress-adaptive gene programs, highlighting MYCN's role in shaping tumor-promoting transcriptional landscapes.

Project description:Hepatocellular carcinoma (HCC) is a leading cause of cancer-related death, often diagnosed at advanced stages and characterized by high recurrence rates. While chronic liver inflammation and metabolic dysfunction are recognized contributors to tumorigenesis, the molecular mechanisms linking early microenvironmental stress to malignant transformation remain poorly understood. MYCN, a proto-oncogenic transcription factor, has emerged as a potential biomarker of cancer stemness, yet its functional role in hepatocarcinogenesis is unclear. Here, we applied CUT&RUN-seq analysis and integrated the data with RNA-seq to investigate the direct transcriptional impact of MYCN in liver tumorigenesis. Transcriptomic profiling revealed that MYCN-driven tumors exhibit features of human HCC subtypes enriched in stress-adaptive gene programs. We found genes with upstream MYCN binding showed significantly greater expression changes between tumor and non-tumor samples, suggesting that MYCN binding in promoter-proximal regions has a stronger influence on transcriptional regulation. Pathway analysis revealed significant enrichment in pathways related to cytoskeletal organization, cell motility, and membrane dynamics, all of which are central to intercellular interactions and tumor microenvironment remodeling, indicating that MYCN regulates pathways contributing to tumor microenvironment remodeling and cellular interactions.

Project description:Transgenic mice (n= 40) overexpressing FEAT in the thymus, spleen, liver, and lung developed malignant lymphoma (47.5%, 19/40) and liver cancer (hepatocellular carcinoma, HCC) (35%, 14/40). Notably, HCC arose in half (13/26) of the male transgenic mice, indicating a strong male predilection similar to human HCC. Microarray-based comparative genomic hybridization (array-CGH) suggested that HCC in FEAT transgenic mice recapitulates human hepatocarcinogenesis.

Project description:Hepatocellular carcinoma (HCC) develops almost exclusively in patients with chronic liver disease (CLD) and advanced fibrosis. Here we interrogated functions of hepatic stellate cells (HSC), the main source of fibroblasts in the injured liver, during hepatocarcinogenesis. Genetic depletion, activation, or inhibition established HSC as tumour-promoting in different HCC models. HSC were enriched in the non-tumour environment, where they closely interacted with hepatocytes and modulated hepatocarcinogenesis by regulating hepatocyte proliferation and death. Surprisingly, further analysis of mouse and human HSC subpopulations by single cell and single nucleus RNA-sequencing and their associated mediators revealed dual functions of HSC in hepatocarcinogenesis. Hepatocyte growth factor, enriched in quiescent and cytokine-producing HSC (cyHSC), protected from hepatocyte death and HCC development. In contrast, type I collagen, enriched in highly activated myofibroblastic HSC (myHSC), increased stiffness, TAZ activation, and subsequent hepatocyte proliferation, thereby promoting HCC development. An increasing HSC imbalance with decreased protective cyHSC and increased myHSC during liver disease progression was associated with elevated HCC risk in patients. In summary, our data suggest that the dynamic shift of HSC subpopulations during CLD and their mediators is associated with a switch from HCC protection to HCC promotion.

Project description:The most common primary malignancy of the liver, hepatocellular carcinoma (HCC), is a heterogeneous tumor entity with high metastatic potential and complex pathophysiology. Increasing evidence suggests that tissue mechanics plays a critical role in tumor onset and progression. Here we show that plectin, a major cytoskeletal crosslinker protein, plays a crucial role in mechanical homeostasis and mechanosensitive oncogenic signaling that drives hepatocarcinogenesis. Our expression analyses revealed elevated plectin levels in liver tumors, which correlated with poor prognosis for HCC patients. Using autochthonous and orthotopic mouse models we demonstrated that genetic and pharmacological inactivation of plectin potently suppressed the initiation and growth of HCC. Moreover, plectin targeting potently inhibited the invasion potential of human HCC cells and reduced their metastatic outgrowth in the lung. Proteomic and phosphoproteomic profiling linked plectin-dependent disruption of cytoskeletal networks to attenuation of oncogenic FAK, MAPK/Erk, and PI3K/AKT signatures. Importantly, by combining cell line-based and murine HCC models, we show that plectin inhibitor plecstatin-1 (PST) is well-tolerated and potently inhibits HCC progression. In conclusion, our study demonstrates that plectin-controlled cytoarchitecture is a key determinant of HCC development and suggests that pharmacologically induced disruption of mechanical homeostasis may represent a new therapeutic strategy for HCC treatment.

Project description:The most common primary malignancy of the liver, hepatocellular carcinoma (HCC), is a heterogeneous tumor entity with high metastatic potential and complex pathophysiology. Increasing evidence suggests that tissue mechanics plays a critical role in tumor onset and progression. Here we show that plectin, a major cytoskeletal crosslinker protein, plays a crucial role in mechanical homeostasis and mechanosensitive oncogenic signaling that drives hepatocarcinogenesis. Our expression analyses revealed elevated plectin levels in liver tumors, which correlated with poor prognosis for HCC patients. Using autochthonous and orthotopic mouse models we demonstrated that genetic and pharmacological inactivation of plectin potently suppressed the initiation and growth of HCC. Moreover, plectin targeting potently inhibited the invasion potential of human HCC cells and reduced their metastatic outgrowth in the lung. Proteomic and phosphoproteomic profiling linked plectin-dependent disruption of cytoskeletal networks to attenuation of oncogenic FAK, MAPK/Erk, and PI3K/AKT signatures. Importantly, by combining cell line-based and murine HCC models, we show that plectin inhibitor plecstatin-1 (PST) is well-tolerated and potently inhibits HCC progression. In conclusion, our study demonstrates that plectin-controlled cytoarchitecture is a key determinant of HCC development and suggests that pharmacologically induced disruption of mechanical homeostasis may represent a new therapeutic strategy for HCC treatment.

Project description:The most common primary malignancy of the liver, hepatocellular carcinoma (HCC), is a heterogeneous tumor entity with high metastatic potential and complex pathophysiology. Increasing evidence suggests that tissue mechanics plays a critical role in tumor onset and progression. Here we show that plectin, a major cytoskeletal crosslinker protein, plays a crucial role in mechanical homeostasis and mechanosensitive oncogenic signaling that drives hepatocarcinogenesis. Our expression analyses revealed elevated plectin levels in liver tumors, which correlated with poor prognosis for HCC patients. Using autochthonous and orthotopic mouse models we demonstrated that genetic and pharmacological inactivation of plectin potently suppressed the initiation and growth of HCC. Moreover, plectin targeting potently inhibited the invasion potential of human HCC cells and reduced their metastatic outgrowth in the lung. Proteomic and phosphoproteomic profiling linked plectin-dependent disruption of cytoskeletal networks to attenuation of oncogenic FAK, MAPK/Erk, and PI3K/AKT signatures. Importantly, by combining cell line-based and murine HCC models, we show that plectin inhibitor plecstatin-1 (PST) is well-tolerated and potently inhibits HCC progression. In conclusion, our study demonstrates that plectin-controlled cytoarchitecture is a key determinant of HCC development and suggests that pharmacologically induced disruption of mechanical homeostasis may represent a new therapeutic strategy for HCC treatment.

Project description:Non-alcoholic fatty liver disease (NAFLD) has increased over the last decades and may evolve into hepatocellular carcinoma (HCC). As HCC is challenging to treat, knowledge on the modifia-ble risk factors for NAFLD/HCC, (e.g. hypercaloric diets rich in fructose) is essential. We used a model of diethyl nitrosamine-induced hepatocarcinogenesis to investigate the liver cancer-promoting effects of a diet supplemented with 10% liquid fructose, administered to male and female rats for 11 months. A subset of the fructose-supplemented rats received resveratrol in the last 4 months of treatment. We observed metabolic abnormalities mainly in the female fructose-supplemented rats (increases in weight, adiposity, and plasma glucose and triglycerides, as well as liver triglycerides and a reduced insulin sensitivity index), which were partially reversed by resveratrol. The livers of fructose-supplemented rats showed no de visu or histological evi-dence of liver tumorigenesis. Targeted analysis of 84 cancer-related genes in the female liver samples revealed expression changes associated with cancer-related pathways, but individual genes indicated that some changes increased the risk of hepatocarcinogenesis (Sfrp2, Ccl5, Socs3, and Gstp1), while others exerted a protective/preventive effect (Bcl2 and Cdh1). In conclusion, our data do not clearly demonstrate that chronic fructose supplementation promotes HCC development in rats.

Project description:Disruption of the epigenome is a hallmark of human disease including liver cirrhosis and hepatocellular carcinoma (HCC). While genetic heterogeneity is an established effector of pathologic phenotypes, epigenetic heterogeneity is less well understood. Environmental exposures including hepatitis C viral (HCV) infection and metabolic syndrome alter the liver-specific DNA methylation landscape and influence the onset of liver cancer. Given that currently available treatments are unable to target the most frequently mutated genes in HCC, there is an unmet need for novel therapeutic strategies to prevent or reverse hepatic tumorigenesis, which the epigenome may provide. We performed genome-wide profiling of DNA methylation, copy number, and gene expression landscapes from multiple liver regions from 31 patients with liver disease to examine their crosstalk and define the individual and combinatorial contribution of these processes to liver disease progression. We identify epigenetic heterogeneity hotspots that are conserved across patients. Elevated epigenetic heterogeneity associates with increases in gene expression heterogeneity. Cirrhotic regions comprise two distinct cohorts, one exclusively epigenetic, and a second where epigenetic and copy number variations collaborate. Epigenetic heterogeneity hotspots are enriched for genes central to liver function (e.g., HNF1A) and known tumor suppressors (e.g., RASSF1A). These hotspots encompass genes including ACSL1, ACSL5, MAT1A, and ELFN1, which have phenotypic effects in cell line functional screens, supporting their relevance to hepatocarcinogenesis. Substantial epigenetic heterogeneity arises early in liver disease development, targeting key pathways in the progression and initiation of both cirrhosis and HCC. Integration of epigenetic and transcriptional heterogeneity unveils putative epigenetic regulators of hepatocarcinogenesis.

Project description:Disruption of the epigenome is a hallmark of human disease including liver cirrhosis and hepatocellular carcinoma (HCC). While genetic heterogeneity is an established effector of pathologic phenotypes, epigenetic heterogeneity is less well understood. Environmental exposures including hepatitis C viral (HCV) infection and metabolic syndrome alter the liver-specific DNA methylation landscape and influence the onset of liver cancer. Given that currently available treatments are unable to target the most frequently mutated genes in HCC, there is an unmet need for novel therapeutic strategies to prevent or reverse hepatic tumorigenesis, which the epigenome may provide. We performed genome-wide profiling of DNA methylation, copy number, and gene expression landscapes from multiple liver regions from 31 patients with liver disease to examine their crosstalk and define the individual and combinatorial contribution of these processes to liver disease progression. We identify epigenetic heterogeneity hotspots that are conserved across patients. Elevated epigenetic heterogeneity associates with increases in gene expression heterogeneity. Cirrhotic regions comprise two distinct cohorts, one exclusively epigenetic, and a second where epigenetic and copy number variations collaborate. Epigenetic heterogeneity hotspots are enriched for genes central to liver function (e.g., HNF1A) and known tumor suppressors (e.g., RASSF1A). These hotspots encompass genes including ACSL1, ACSL5, MAT1A, and ELFN1, which have phenotypic effects in cell line functional screens, supporting their relevance to hepatocarcinogenesis. Substantial epigenetic heterogeneity arises early in liver disease development, targeting key pathways in the progression and initiation of both cirrhosis and HCC. Integration of epigenetic and transcriptional heterogeneity unveils putative epigenetic regulators of hepatocarcinogenesis.