YAP1 oncogene is a context-specific driver for pancreatic ductal adenocarcinoma
Bo Tu, Jun Yao, Sammy Ferri-Borgogno, Jun Zhao, Shujuan Chen, Qiuyun Wang, Liang Yan, Xin Zhou, Cihui Zhu, Seungmin Bang, Qing Chang, Christopher A. Bristow, Ya’an Kang, Hongwu Zheng, Huamin Wang, Jason B. Fleming, Michael Kim, Timothy P. Heffernan, Giulio F. Draetta, Duojia Pan, Anirban Maitra, Wantong Yao, Sonal Gupta, Haoqiang Ying
Bo Tu, Jun Yao, Sammy Ferri-Borgogno, Jun Zhao, Shujuan Chen, Qiuyun Wang, Liang Yan, Xin Zhou, Cihui Zhu, Seungmin Bang, Qing Chang, Christopher A. Bristow, Ya’an Kang, Hongwu Zheng, Huamin Wang, Jason B. Fleming, Michael Kim, Timothy P. Heffernan, Giulio F. Draetta, Duojia Pan, Anirban Maitra, Wantong Yao, Sonal Gupta, Haoqiang Ying
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Research Article Genetics Oncology

YAP1 oncogene is a context-specific driver for pancreatic ductal adenocarcinoma

Abstract

Transcriptomic profiling classifies pancreatic ductal adenocarcinoma (PDAC) into several molecular subtypes with distinctive histological and clinical characteristics. However, little is known about the molecular mechanisms that define each subtype and their correlation with clinical outcome. Mutant KRAS is the most prominent driver in PDAC, present in over 90% of tumors, but the dependence of tumors on oncogenic KRAS signaling varies between subtypes. In particular, the squamous subtype is relatively independent of oncogenic KRAS signaling and typically displays much more aggressive clinical behavior versus the progenitor subtype. Here, we identified that yes-associated protein 1 (YAP1) activation is enriched in the squamous subtype and associated with poor prognosis. Activation of YAP1 in progenitor subtype cancer cells profoundly enhanced malignant phenotypes and transformed progenitor subtype cells into squamous subtype. Conversely, depletion of YAP1 specifically suppressed tumorigenicity of squamous subtype PDAC cells. Mechanistically, we uncovered a significant positive correlation between WNT5A expression and YAP1 activity in human PDAC and demonstrated that WNT5A overexpression led to YAP1 activation and recapitulated a YAP1-dependent but Kras-independent phenotype of tumor progression and maintenance. Thus, our study identifies YAP1 oncogene as a major driver of squamous subtype PDAC and uncovers the role of WNT5A in driving PDAC malignancy through activation of the YAP pathway.

Authors

Bo Tu, Jun Yao, Sammy Ferri-Borgogno, Jun Zhao, Shujuan Chen, Qiuyun Wang, Liang Yan, Xin Zhou, Cihui Zhu, Seungmin Bang, Qing Chang, Christopher A. Bristow, Ya’an Kang, Hongwu Zheng, Huamin Wang, Jason B. Fleming, Michael Kim, Timothy P. Heffernan, Giulio F. Draetta, Duojia Pan, Anirban Maitra, Wantong Yao, Sonal Gupta, Haoqiang Ying

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Figure 3

YAP1 activation in PDAC is mediated by WNT5A overexpression.

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YAP1 activation in PDAC is mediated by WNT5A overexpression. (A and B) H...
(A and B) Human pancreatic cancer cell lines of progenitor or squamous subtype (A) or mouse PDAC cells of indicated genotypes (B) were subjected to immunofluorescence staining with anti-YAP1 (red) and DAPI (blue). (C) Noncanonical (NC) WNT pathway enrichment score in iKras mouse PDAC tumors without (Amp–) or with (Amp+) Yap1 amplification. (D) Correlation between NC WNT signature and YAP1 signature in PDAC TCGA data set. (E) Western blots for WNT5A in mouse PDAC cells of indicated genotypes and human PDAC cell lines. (F) WNT5A expression in squamous or progenitor subtype human PDACs in TCGA data set. (G) Correlation between WNT5A expression and YAP1 signature in PDAC TCGA data set. (H) Western blot analysis for WNT5A, YAP1, and phospho-YAP1 (S127) in 2 independent iKras-Yap1Amp– cells with CRISPR-mediated Wnt5a deletion. Two independent Wnt5a-knockout (KO) clones were included, and a clone without Wnt5a deletion was used as a control (Ctr). Vinculin blot for E-4 was run in parallel with the rest of the blots for E-4 contemporaneously. (I) E-4 (iKras-Yap1Amp–) Wnt5a-KO cells and PaTu8988S cells expressing GFP or WNT5A were subjected to immunofluorescence staining with anti-YAP1 (red) and DAPI (blue). (J) Relative mRNA levels of YAP1 downstream targets in E-4 (iKras Yap1Amp–) Wnt5a-KO cells. P value was corrected with Dunnett’s method. (K) Western blot analysis for WNT5A, YAP1, and phospho-YAP1 (S127) in mouse iKras PDAC cells (AK192) or human PaTu8988S cells expressing GFP or WNT5A (top). The quantification of phospho-YAP1/total YAP1 signals is shown. (L) Western blot analysis for WNT5A, LATS1/2, phospho-LATS1/2, YAP1, and phospho-YAP1 (S127) in PaTu8988T cells infected with WNT5A shRNAs or nontargeting shRNA (shCtr). The box plots depict the minimum and maximum values (whiskers), the upper and lower quartiles, and the median. The length of the box represents the interquartile range. Error bars from all panels indicate ± SD. *P < 0.05; **P < 0.01. Scale bar: 20 μm.