Oncogenic β-catenin triggers an inflammatory response that determines the aggressiveness of hepatocellular carcinoma in mice
Marie Anson, Anne-Marie Crain-Denoyelle, Véronique Baud, Fanny Chereau, Angélique Gougelet, Benoit Terris, Satoshi Yamagoe, Sabine Colnot, Mireille Viguier, Christine Perret, Jean-Pierre Couty
Marie Anson, Anne-Marie Crain-Denoyelle, Véronique Baud, Fanny Chereau, Angélique Gougelet, Benoit Terris, Satoshi Yamagoe, Sabine Colnot, Mireille Viguier, Christine Perret, Jean-Pierre Couty
View: Text | PDF
Research Article Oncology

Oncogenic β-catenin triggers an inflammatory response that determines the aggressiveness of hepatocellular carcinoma in mice

Abstract

Hepatocellular carcinoma (HCC) is the third leading cause of cancer-related death worldwide. Its pathogenesis is frequently linked to liver inflammation. Gain-of-function mutations in the gene encoding β-catenin are frequent genetic modifications found in human HCCs. Thus, we investigated whether inflammation was a component of β-catenin–induced tumorigenesis using genetically modified mouse models that recapitulated the stages of initiation and progression of this tumoral process. Oncogenic β-catenin signaling was found to induce an inflammatory program in hepatocytes that involved direct transcriptional control by β-catenin and activation of the NF-κB pathway. This led to a specific inflammatory response, the intensity of which determined the degree of tumor aggressiveness. The chemokine-like chemotactic factor leukocyte cell–derived chemotaxin 2 (LECT2) and invariant NKT (iNKT) cells were identified as key interconnected effectors of liver β-catenin–induced inflammation. In genetic deletion models lacking the gene encoding LECT2 or iNKT cells, hepatic β-catenin signaling triggered the formation of highly malignant HCCs with lung metastasis. Thus, our results identify inflammation as a key player in β-catenin–induced liver tumorigenesis. We provide strong evidence that, by activating pro- and antiinflammatory mediators, β-catenin signaling produces an inflammatory microenvironment that has an impact on tumoral development. Our data are consistent with the fact that most β-catenin–activated HCCs are of better prognosis.

Authors

Marie Anson, Anne-Marie Crain-Denoyelle, Véronique Baud, Fanny Chereau, Angélique Gougelet, Benoit Terris, Satoshi Yamagoe, Sabine Colnot, Mireille Viguier, Christine Perret, Jean-Pierre Couty

×

Figure 8

iNKTs and LECT2 are critical cellular and molecular players controlling tumoral progression of β-catenin–dependent liver tumorigenesis.

Options: View larger image (or click on image) Download as PowerPoint
iNKTs and LECT2 are critical cellular and molecular players controlling ...
(A) 12-month-old Lpk-myc+ (n = 12) and Lpk-myc+LECT2–/– (n = 11) or Lpk-myc+Jα18–/– (n = 7) mice were sacrificed, and the number of tumor nodules was evaluated (arrows). (B) The graph represents the mean number of tumors for each group of mice. (CH) Paraffin-embedded sections obtained from Lpk-myc+, Lpk-myc+LECT2–/–, and Lpk-myc+Jα18–/– livers were stained with H&E, and the grade of differentiation for each tumor nodule was assessed. Scale bars: 1 mm (CE); 120 μm (F); 60 μm (G and H). (I) The graph shows the mean number of tumors for each group of mice, according to their degree of differentiation. (J) Immunohistochemistry of Ki67 expression was performed on paraffin-embedded sections obtained from Lpk-myc+ and Lpk-myc+LECT2–/– or Lpk-myc+Jα18–/– livers to evaluate the proliferation rate of the tumor nodules. Scale bars: 50 μm. (K) The graph represents the mean number of Ki67+ cells for each group of mice. (L) Paraffin-embedded sections obtained from Lpk-myc+, Lpk-myc+LECT2–/–, and Lpk-myc+Jα18–/– lungs were stained with H&E. Scale bars: 4 mm (left); 200 μm (middle, right).