WNT signaling drives cholangiocarcinoma growth and can be pharmacologically inhibited
Luke Boulter, … , Owen J. Sansom, Stuart J. Forbes
Luke Boulter, … , Owen J. Sansom, Stuart J. Forbes
Published February 17, 2015
Citation Information: J Clin Invest. 2015;125(3):1269-1285. https://doi.org/10.1172/JCI76452.
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WNT signaling drives cholangiocarcinoma growth and can be pharmacologically inhibited

Abstract

Cholangiocarcinoma (CC) is typically diagnosed at an advanced stage and is refractory to surgical intervention and chemotherapy. Despite a global increase in the incidence of CC, little progress has been made toward the development of treatments for this cancer. Here we utilized human tissue; CC cell xenografts; a p53-deficient transgenic mouse model; and a non-transgenic, chemically induced rat model of CC that accurately reflects both the inflammatory and regenerative background associated with human CC pathology. Using these systems, we determined that the WNT pathway is highly activated in CCs and that inflammatory macrophages are required to establish this WNT-high state in vivo. Moreover, depletion of macrophages or inhibition of WNT signaling with one of two small molecule WNT inhibitors in mouse and rat CC models markedly reduced CC proliferation and increased apoptosis, resulting in tumor regression. Together, these results demonstrate that enhanced WNT signaling is a characteristic of CC and suggest that targeting WNT signaling pathways has potential as a therapeutic strategy for CC.

Authors

Luke Boulter, Rachel V. Guest, Timothy J. Kendall, David H. Wilson, Davina Wojtacha, Andrew J. Robson, Rachel A. Ridgway, Kay Samuel, Nico Van Rooijen, Simon T. Barry, Stephen J. Wigmore, Owen J. Sansom, Stuart J. Forbes

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Figure 3

The WNT pathway is activated in a rat model of CC.

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The WNT pathway is activated in a rat model of CC. (A) Immunohistochemis...
(A) Immunohistochemistry for CTNNB1 (red) and KRT19 (green) in precancerous TAA rats. (B) Immunohistochemistry for CTNNB1 and KRT19 in cancerous TAA rats. White arrows in insets, nuclear positivity of CTNNB1; dotted line, tumor interface. (C) mRNA expression of WNT pathway targets in 26-week TAA versus matched non-treated controls (n = 6 per group). (D) mRNA expression of WNT ligands Wnt10a and Wnt7b; WNT pathway effectors Rspo1, Bcl9, Birc5, Axin2, Rnf43, and Lgr4; and cell cycle targets Aurka, Aurkb, and Aurkc. (E) Immunohisto­chemistry in rat CC for CTNNB1 (red), BIRC5 (green), and LEF1 and CCND2 (brown). Graph: Quantification of epithelial nuclear staining in 26-week TAA rat (n = 10). (F) Immunohistochemistry for WNT7B (red) and RSPO-1 (green) in TAA-induced CC. Data are presented as mean ± SEM. Kruskal-Wallis test; ***P < 0.001. Photomicrograph scale bars: 50 μm; insets, 10 μm.