Crosstalk between the canonical NF-κB and Notch signaling pathways inhibits Pparγ expression and promotes pancreatic cancer progression in mice
Eleni Maniati, … , David A. Tuveson, Thorsten Hagemann
Eleni Maniati, … , David A. Tuveson, Thorsten Hagemann
Published November 7, 2011
Citation Information: J Clin Invest. 2011;121(12):4685-4699. https://doi.org/10.1172/JCI45797.
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Research Article Oncology

Crosstalk between the canonical NF-κB and Notch signaling pathways inhibits Pparγ expression and promotes pancreatic cancer progression in mice

Abstract

The majority of human pancreatic cancers have activating mutations in the KRAS proto-oncogene. These mutations result in increased activity of the NF-κB pathway and the subsequent constitutive production of proinflammatory cytokines. Here, we show that inhibitor of κB kinase 2 (Ikk2), a component of the canonical NF-κB signaling pathway, synergizes with basal Notch signaling to upregulate transcription of primary Notch target genes, resulting in suppression of antiinflammatory protein expression and promotion of pancreatic carcinogenesis in mice. We found that in the KrasG12DPdx1-cre mouse model of pancreatic cancer, genetic deletion of Ikk2 in initiated pre-malignant epithelial cells substantially delayed pancreatic oncogenesis and resulted in downregulation of the classical Notch target genes Hes1 and Hey1. Tnf-α stimulated canonical NF-κB signaling and, in collaboration with basal Notch signals, induced optimal expression of Notch targets. Mechanistically, Tnf-α stimulation resulted in phosphorylation of histone H3 at the Hes1 promoter, and this signal was lost with Ikk2 deletion. Hes1 suppresses expression of Pparg, which encodes the antiinflammatory nuclear receptor Pparγ. Thus, crosstalk between Tnf-α/Ikk2 and Notch sustains the intrinsic inflammatory profile of transformed cells. These findings reveal what we believe to be a novel interaction between oncogenic inflammation and a major cell fate pathway and show how these pathways can cooperate to promote cancer progression.

Authors

Eleni Maniati, Maud Bossard, Natalie Cook, Juliana B. Candido, Nia Emami-Shahri, Sergei A. Nedospasov, Frances R. Balkwill, David A. Tuveson, Thorsten Hagemann

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Figure 3

Tnf-α–induced Notch and NF-κB target gene expression in PanIN cell lines.

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Tnf-α–induced Notch and NF-κB target gene expression in PanIN cell lines...
(A) Expression of Hes1 and Hey1 in KrasG12D PanIN cell lines was examined by immunofluorescence staining; cells were left unstimulated or were stimulated with 10 ng/ml rTnf-α for 24 hours. Original magnification, ×40. Blue, DAPI; red, actin; green, Hes1. One representative experiment of 3 performed is shown. (B) Relative mRNA expression of Hes1 and Il1b in PanIN cell lines stimulated with 1 ng/ml rTnf-α for 6 hours. Relative expression was calculated by setting expression of untreated KrasG12D samples as 1. (C) Hes1 luciferase reporter assay in KrasG12DTnfaΔPdx and KrasG12DIkk2ΔPdx PanIN cell lines stimulated with 1 ng/ml rTnf-α for 6 hours. Results were normalized to firefly luciferase activity relative to internal control and are expressed as mean + SD from triplicate transfections. ***P < 0.01. One representative experiment of 3 performed is shown. (D) Kinetic analysis of Hes1 mRNA expression in KrasG12DTnfaΔPdx PanIN cell lines stimulated with 1 ng/ml rTnf-α. (E) KrasG12DTnfaΔPdx PanIN cells were treated with 1 ng/ml rTnf-α in the presence or absence of 15 μg/ml cycloheximide (CHX). Expression of Hes1 was quantified by real-time PCR. Relative expression was calculated by setting expression of untreated KrasG12D samples as 1. (B, D, and E) Data are shown as mean + SD of triplicate determinants, and 1 representative experiment of 3 is shown.