Project description:The diethylnitrosamine HCC rat model (DEN-HCC) is a useful preclinical model mirroring human hepatocellular carcinoma. To overcome tumor heterogeneity of human HCCs linked to different etiologies and clonal selection, rat HCC samples were compared with matched non-tumor livers in order to identify HCC-related genes involved in the carcinogenetic process. Specifically, male Wistar rats received DEN (Sigma-Aldrich) in the drinking water (100 mg/L) for 8 weeks. Two weeks later the end of DEN treatment, animals were monitored by ultrasound imaging. Animals were euthanized 1 or 2 months after the end of DEN treatment, when the major diameter of at least one HCC nodule reached a dimension of 10 mm. Samples were collected for molecular biology and total RNA for microarray analysis was extracted by using Trizol. Two rat livers from untreated mice were included in the analysis.

Project description:Through the analysis of mouse liver tumours promoted by distinct routes (DEN exposure alone, DEN exposure plus non-genotoxic insult with phenobarbital and non-alcoholic fatty liver disease); we report that the cancer associated hyper-methylated CGI events in mice are also predicated by silent promoters that are enriched for both the DNA modification 5-hydroxymethylcytosine (5hmC) and the histone modification H3K27me3 in normal liver. During cancer progression these CGIs undergo hypo-hydroxymethylation, prior to subsequent hyper-methylation; whilst retaining H3K27me3. A similar loss of promoter-core 5hmC is observed in Tet1 deficient mouse livers indicating that reduced Tet1 binding at CGIs may be responsible for the epigenetic dysregulation observed during hepatocarcinogenesis. Consistent with this reduced Tet1 protein levels are observed in mouse liver tumour lesions. As in human, DNA methylation changes at CGIs do not appear to be direct drivers of hepatocellular carcinoma progression in mice. Instead dynamic changes in H3K27me3 promoter deposition are strongly associated with tumour-specific activation and repression of transcription. Our data suggests that loss of promoter associated 5hmC in diverse liver tumours licences DNA methylation reprogramming at silent CGIs during cancer progression. 5-mc is a well establisehd epigenetic mark typically related to gene silencing events. Phenobarbital (PB) is a well studied non-genotoxic carcinogen with roles in epigenetic perturbation. We profile 5mC in both control mouse livers as well as in the livers of 12 week PB treated mice. We also profile 5mC in liver tumours arising in the presence of long term PB exposure (35 week: resulting in Ctnnb1 mutated tumours) to a Ha-Ras liver tumour which arose without PB. Samples: 2 control and 2 PB exposed mouse livers, 3 liver tumours resulting from long term PB exposrue and 1 liver tumour arising without PB

Project description:Through the analysis of mouse liver tumours promoted by distinct routes (DEN exposure alone, DEN exposure plus non-genotoxic insult with phenobarbital and non-alcoholic fatty liver disease); we report that the cancer associated hyper-methylated CGI events in mice are also predicated by silent promoters that are enriched for both the DNA modification 5-hydroxymethylcytosine (5hmC) and the histone modification H3K27me3 in normal liver. During cancer progression these CGIs undergo hypo-hydroxymethylation, prior to subsequent hyper-methylation; whilst retaining H3K27me3. A similar loss of promoter-core 5hmC is observed in Tet1 deficient mouse livers indicating that reduced Tet1 binding at CGIs may be responsible for the epigenetic dysregulation observed during hepatocarcinogenesis. Consistent with this reduced Tet1 protein levels are observed in mouse liver tumour lesions. As in human, DNA methylation changes at CGIs do not appear to be direct drivers of hepatocellular carcinoma progression in mice. Instead dynamic changes in H3K27me3 promoter deposition are strongly associated with tumour-specific activation and repression of transcription. Our data suggests that loss of promoter associated 5hmC in diverse liver tumours licences DNA methylation reprogramming at silent CGIs during cancer progression. 5-hmC is a novel epigenetic mark derived from oxidation of methylcytosine. Phenobarbital (PB) is a well studied non-genotoxic carcinogen with roles in epigenetic perturbation. We profile 5hmC in both control mouse livers as well as in the livers of 12 week PB treated mice. We also profile 5hmC in liver tumours arising in the presence of long term PB exposure (35 week: resulting in Ctnnb1 mutated tumours) to a Ha-Ras liver tumour which arose without PB. Samples: 5hmC profiles in 2 control and 2 PB exposed mouse livers, 3 liver tumours resulting from long term PB exposrue and 1 liver tumour arising without PB

Project description:In rodent liver, a single injection of N-nitrosodiethylamine (DEN) followed by chronic treatment with the antiepileptic drug phenobarbital (PB) promotes the outgrowth of hepatocellular tumors with activating mutations in Ctnnb1, encoding the transcription factor β-catenin. We now studied long-term effects of PB treatment in livers of transgenic mice with hepatocyte-specific knockout (KO) of Apc, a negative regulator of β-catenin signaling. The number of Apc KO hepatocytes present in the liver decreased with age, indicative of a selective disadvantage of Apc KO cells in the absence of PB. Following liver tumor promotion by PB in Apc KO mice for 9 months, tumor burden was quantified and histological appearance, gene expression profiles, and activity of oncogenic signaling pathways of the tumors were analyzed. In Apc KO mice fed with PB, we observed an increased hepatic tumor volume fraction and tumor multiplicity, as compared to non-promoted animals. Tumors in the PB-treated Apc KO group were mostly eosinophilic hepatocellular adenoma with activated β-catenin, due to the deletion of Apc. These tumors exhibited striking phenotypic similarities to DEN-induced Ctnnb1-mutated tumors, regarding histological appearance and expression of marker proteins and mRNAs. A particular sub-population of tumors, Apc KO-driven basophilic hepatocellular carcinomas, exclusively appeared in the non-PB-treated group but was absent from PB-promoted livers. In conclusion, phenobarbital promotes the outgrowth of Apc-deficient, β-catenin-activated hepatocellular adenoma while simultaneously inhibiting the formation of a certain population of Apc-driven hepatocellular carcinoma.

Project description:This model is an expansion of the Regan2022 - Mechanosensitive EMT model (MODEL2208050001); it includes a TGFβ signaling module and autocrine signaling in mesenchymal cells. The expanded 150-node (630 link) modular model undergoes EMT triggered by biomechanical and growth signaling crosstalk, or by TGFβ. As its predecessor, this model also reproduces the ability of the core EMT transcriptional network to maintain distinct epithelial, hybrid E/M and mesenchymal states, as well as EMT driven by mitogens such as EGF on stiff ECM. We also reproduce the observed lack of stepwise MET, in that our model's dynamics does not pass through the hybrid E/M state during MET. We show that in the absence of strong autocrine signals such as TGFβ (not included in this version), cells cannot maintain their mesenchymal state in the absence of mitogens, on softer matrices, or at high cell density. In contrast, potent autocrine signaling can stabilize the mesenchymal state in all but very dense monolayers on soft ECM. This expanded model also reproduces the inhibitory effects of TGFβ on proliferation and anoikis resistance in mesenchymal cells, as well as its ability to trigger apoptosis on soft ECM vs. EMT on stiff matrices. The model offers several experimentally testable predictions related to the effect of neighbors on partial vs. full EMT, the tug of war between mitosis and the maintenance of migratory hybrid E/M states, as well as cell cycle defects in dynamic, heterogeneous populations of epithelial, hybrid E/M and mesenchymal cells.

Project description:Using RNA-seq analysis, we study a DEN-induced HCC rat model during fibrosis progression and HCC development with special focus on liver inflammatory microenvironment. RNA-seq results show that DEN-induced liver tumors in rat model share remarkable molecular characteristics with human HCC, especially with HCC associated with high proliferation. In conclusion, our study provides detailed insight into the hepatocarcinogenesis in a commonly used model of HCC, facilitating the future use of this model for preclinical testing.

Project description:Transcriptional profiling by bulk RNA sequencing of murine livers or sorted immune cells, from DEN ALIOS NASH-HCC mouse model. Mice treated with CXCR2i (AZD5069) monotherapy, anti-PD1 monotherapy, or combination CXCR2i, anti-PD1 treatment. Published in doi: 10.1136/gutjnl-2021-326259

Project description:As the central hub metabolic organ bodily, the liver is paramount to keep whole-body energy homeostasis. Further, mitochondria are the central metabolic hub within cells to connect the main catabolized, energy production, and hormonal signaling pathways. It is evident that mitochondrial dysfunction may play a critical role in the development of NASH. Accordingly, understanding the underlying mechanisms of mitochondrial dysfunction is of importance to develop therapies for NASH. Here, we report that mice with hepatocyte-specific deletion of Tid1, encoding a mitochondrial cochaperone, tended to develop NASH-dependent HCC. The hepatocellular nodules were developed in 3-month DEN-treated Tid1-/- mice. At the age of 6 months, the DEN-treated Tid1-/- mice showed a higher number of tumors and greater tumor size than the DEN-treated Tid1+/- mice, followed by the DEN-treated WT mice. To gain insights into the mRNA changes during NASH-HCC progress, we performed an RNA-seq analysis with livers collected from 6-month DEN-treated mice.

Project description:c-Fos, a member of the stress-activated Activator Protein 1 (AP-1) transcription factor family, is expressed in human hepatocellular cancer (HCC). Using genetically engineered mouse models (GEMMs) we show that hepatocyte-specific expression of c-Fos leads to a proliferative, de-differentiated phenotype, whereas hepatocyte-specific deletion of c-Fos protects against diethylnitrosamine (DEN)-induced liver cancer. Furthermore, c-Fos-expressing livers resemble human HCCs based on expression profiles. In the present RNA seq, we intend to analyze the transcriptomic profile of livers at 2 and 4 mo hepatocyte-specific c-Fos expression compared to the corresponding age-matched control mice. Moreover, we analyzed livers of mice with hepatocyte-specific deletion c-Fos at 48h after DEN treatment compared to identically treated control mice.

Project description:Through the analysis of mouse liver tumours promoted by distinct routes (DEN exposure alone, DEN exposure plus non-genotoxic insult with phenobarbital and non-alcoholic fatty liver disease); we report that the cancer associated hyper-methylated CGI events in mice are also predicated by silent promoters that are enriched for both the DNA modification 5-hydroxymethylcytosine (5hmC) and the histone modification H3K27me3 in normal liver. During cancer progression these CGIs undergo hypo-hydroxymethylation, prior to subsequent hyper-methylation; whilst retaining H3K27me3. A similar loss of promoter-core 5hmC is observed in Tet1 deficient mouse livers indicating that reduced Tet1 binding at CGIs may be responsible for the epigenetic dysregulation observed during hepatocarcinogenesis. Consistent with this reduced Tet1 protein levels are observed in mouse liver tumour lesions. As in human, DNA methylation changes at CGIs do not appear to be direct drivers of hepatocellular carcinoma progression in mice. Instead dynamic changes in H3K27me3 promoter deposition are strongly associated with tumour-specific activation and repression of transcription. Our data suggests that loss of promoter associated 5hmC in diverse liver tumours licences DNA methylation reprogramming at silent CGIs during cancer progression. 5-mc is a well establisehd epigenetic mark typically related to gene silencing events. Phenobarbital (PB) is a well studied non-genotoxic carcinogen with roles in epigenetic perturbation. We profile 5mC in both control mouse livers as well as in liver tumours of high fat diet exposed mice who have progressed through NASH. Samples: 5mC profiles in livers of 2 control and 2 NASH driven HCC samples