FGFR2 signaling underlies p63 oncogenic function in squamous cell carcinoma
Matthew R. Ramsey, … , Alea A. Mills, Leif W. Ellisen
Matthew R. Ramsey, … , Alea A. Mills, Leif W. Ellisen
Published July 8, 2013
Citation Information: J Clin Invest. 2013;123(8):3525-3538. https://doi.org/10.1172/JCI68899.
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Research Article Oncology

FGFR2 signaling underlies p63 oncogenic function in squamous cell carcinoma

Abstract

Oncogenic transcription factors drive many human cancers, yet identifying and therapeutically targeting the resulting deregulated pathways has proven difficult. Squamous cell carcinoma (SCC) is a common and lethal human cancer, and relatively little progress has been made in improving outcomes for SCC due to a poor understanding of its underlying molecular pathogenesis. While SCCs typically lack somatic oncogene-activating mutations, they exhibit frequent overexpression of the p53-related transcription factor p63. We developed an in vivo murine tumor model to investigate the function and key transcriptional programs of p63 in SCC. Here, we show that established SCCs are exquisitely dependent on p63, as acute genetic ablation of p63 in advanced, invasive SCC induced rapid and dramatic apoptosis and tumor regression. In vivo genome-wide gene expression analysis identified a tumor-survival program involving p63-regulated FGFR2 signaling that was activated by ligand emanating from abundant tumor-associated stroma. Correspondingly, we demonstrate the therapeutic efficacy of extinguishing this signaling axis in endogenous SCCs using the clinical FGFR2 inhibitor AZD4547. Collectively, these results reveal an unanticipated role for p63-driven paracrine FGFR2 signaling as an addicting pathway in human cancer and suggest a new approach for the treatment of SCC.

Authors

Matthew R. Ramsey, Catherine Wilson, Benjamin Ory, S. Michael Rothenberg, William Faquin, Alea A. Mills, Leif W. Ellisen

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Figure 4

Direct regulation and requirement for p63-induced Fgfr2 in SCC.

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Direct regulation and requirement for p63-induced Fgfr2 in SCC. (A) QR...
(A) QRT-PCR assessment of mRNA levels of indicated genes in p63-intact (n = 3–5) or p63-excised (n = 3–4) orthotopic tumor samples normalized to β-actin. (B) Western blot of indicated proteins in SCC tumors of indicated genotype. Ribosomal S6 serves as a loading control. T, tamoxifen. (C) ChIP of endogenous p63 at the Col17α1, Pld1, and Fgfr2 loci in murine B9 SCC cells using indicated antibodies. Control designates highly conserved region –2.4 kb upstream of Fgfr2 promoter. (D) ChIP of exogenously expressed, FLAG-epitope tagged WT ΔNp63α or DNA-binding–deficient ΔNp63α (R304W) in B9 cells. GFP-expressing cells serve as a negative control. (E) Relative Fgfr mRNA levels in autochthonous murine tumors, normalized to β-actin. (F) Correlation between ΔNp63 and FGFR2 mRNA levels in human primary HNSCC tumors as assessed by TaqMan QRT-PCR. P value was calculated using Pearson product-moment correlation coefficient. (G) Human FaDU HNSCC cells plated in soft agar 72 hours after infection with p63 or FGFR2-directed shRNAs. (H) Western blot analysis of FaDU HNSCC cells stably expressing indicated proteins 72 hours following infection with p63-directed shRNA or control shRNA. Exogenous ΔNp63α (WT) and ΔNp63α (R304W) contain a FLAG epitope tag and are resistant to p63 shRNA (47). GAPDH serves as a loading control. (I) Colony forming assay of samples in H 10 days after infection with p63-directed or control shRNA. *P < 0.05; **P < 0.01; ***P < 0.001 as assessed by Student’s unpaired t test for all experiments except where indicated. Error bars represent SEM.