Yap1 Activation Enables Bypass of Oncogenic Kras Addiction in Pancreatic Cancer

Kapoor, Avnish; Yao, Wantong; Hua, Sujun; Liewen, Alison; Wang, Qiuyun; Zhong, Yi; Wu, Chang Jiun; Sadanandam, Anguraj; Hu, Baoli; Chang, Qing; Chu, Gerald C.; Al-Khalil, Ramsey; Jiang, Shan; Xia, Hongai; Fletcher-Sananikone, Eliot; Lim, Carol S.; Horwitz, Gillian I.; Viale, Andrea; Pettazzoni, Piergiorgio; Sánchez, Nora; Wang, Huamin; Protopopov, Alexei; Zhang, Jianhua; Heffernan, Timothy P.; Johnson, Randy L.; Chin, Lynda; Wang, Y. Alan; Draetta, Giulio; DePinho, Ronald A.

doi:10.1016/j.cell.2014.06.003

Cited by 603 publications

(545 citation statements)

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Section: Oncogenic Kras Escapersmentioning

confidence: 99%

“…In this model, oncogenic Kras extinction permanently eliminates most tumors; however, a subset of tumors can bypass Kras dependency and undergoes spontaneous recurrence (Kapoor et al 2014). Multidimensional genomic, transcriptomic, and proteomic profiling has revealed several distinct mechanisms, including, most prominently, amplification of the Yap1 oncogene of the Hippo pathway (Kapoor et al 2014). Interestingly, YAP1 was also identified in multiple genetic screens as one of the top hits that confer resistance to KRAS suppression or targeted cancer therapy with RAF and MEK inhibitors (Shao et al 2014;Lin et al 2015), further corroborating the role of the YAP1 pathway in driving resistance to targeted therapy.…”

Section: Oncogenic Kras Escapersmentioning

confidence: 99%

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Genetics and biology of pancreatic ductal adenocarcinoma

et al. 2016

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With 5-year survival rates remaining constant at 6% and rising incidences associated with an epidemic in obesity and metabolic syndrome, pancreatic ductal adenocarcinoma (PDAC) is on track to become the second most common cause of cancer-related deaths by 2030. The high mortality rate of PDAC stems primarily from the lack of early diagnosis and ineffective treatment for advanced tumors. During the past decade, the comprehensive atlas of genomic alterations, the prominence of specific pathways, the preclinical validation of such emerging targets, sophisticated preclinical model systems, and the molecular classification of PDAC into specific disease subtypes have all converged to illuminate drug discovery programs with clearer clinical path hypotheses. A deeper understanding of cancer cell biology, particularly altered cancer cell metabolism and impaired DNA repair processes, is providing novel therapeutic strategies that show strong preclinical activity. Elucidation of tumor biology principles, most notably a deeper understanding of the complexity of immune regulation in the tumor microenvironment, has provided an exciting framework to reawaken the immune system to attack PDAC cancer cells. While the long road of translation lies ahead, the path to meaningful clinical progress has never been clearer to improve PDAC patient survival. Pancreatic ductal adenocarcinoma (PDAC) pathogenesisOn gross inspection, PDAC presents as a poorly demarcated, firm white-yellow mass, with the surrounding nonmalignant pancreas typically showing atrophy, fibrosis, and dilated ducts due to the obstructive effects of expanding carcinoma. Microscopically, these neoplasms vary from well-differentiated gland-forming carcinomas to poorly differentiated "sarcomatoid" carcinomas diagnosed only upon immunolabeling due to predominant mesenchymal features (Hruban et al. 2007). PDAC evolves from well-defined precursor lesions that, in the context of their genetic features, define the genetic progression model of pancreatic carcinogenesis (Yachida et al. 2010). Early disease histology manifests as several distinct types of precursor lesions-the most common are microscopic pancreatic intraepithelial neoplasia (PanIN), followed by the macroscopic cysts; namely, the intraductal papillary mucinous neoplasm (IPMN) and mucinous cystic neoplasm (MCN) (Matthaei et al. 2011). Since most PDAC cases become clinically apparent at advanced stages, major opportunities to reduce mortality rest with diagnostics and treatments that would enable the reliable identification and elimination of high-risk precursor lesions. Thus, the identification of these precursor lesions has provided an essential framework to define the genomic features that drive progression to advanced disease and develop effective screening and targeted therapeutics for earlier stage disease (Eser et al. 2011).The noninvasive PanIN lesions were formerly classified into three grades according to the extent of cytological and architectural atypia: PanIN1A (flat lesion) and PanIN1B (micropapillary...

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Section: Oncogenic Kras Escapersmentioning

confidence: 99%

Section: Oncogenic Kras Escapersmentioning

confidence: 99%

Genetics and biology of pancreatic ductal adenocarcinoma

et al. 2016

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“…YAP1 is a transcriptional coactivator in the Hippo signaling pathway (15). Increased YAP1 expression or activity can promote the growth of tumor cells, including human HCC (14,16).…”

Section: Discussionmentioning

confidence: 99%

“…It was reported that β-catenin-driven cancers require a YAP1 transcriptional complex for survival and tumorigenesis (14). Enforced YAP1 expression can enable tumor maintenance upon Kras G12D extinction in a human pancreatic ductal adenocarcinoma model (15). Moreover, YAP1 amplification has been described as an essential oncogene in various types of human cancers, including human HCC (16).…”

Section: Introductionmentioning

confidence: 99%

FGF8 promotes cell proliferation and resistance to EGFR inhibitors via upregulation of EGFR in human hepatocellular carcinoma cells

et al. 2017

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Abstract. Fibroblast growth factor 8 (FGF8), a member of the fibroblast growth factor (FGF) family, is upregulated in several human cancers, including HCC (HCC). Previous studies have demonstrated that FGF8 increased cell growth and invasion of tumor cells. In the present study we investigated whether FGF8 is involved in the cell proliferation and resistance to several drugs in human HCC cells. We stably overexpressed FGF8 by lentiviral transfection. In addition, we also added recombinant FGF8 instead of stably overexpressing FGF8 in human HCC cells. Stable overexpression of FGF8 or exogenous recombinant FGF8 resulted in significantly enhanced cell proliferation in human HCC cells. With the use of CellTiter-Glo assay for the determination of cell viability, we found that FGF8 increased the resistance to epidermal growth factor receptor (EGFR) inhibitors in human HCC cells. Additionally, the expression of EGFR was also upregulated by stably overexpressing FGF8 or exogenous recombinant FGF8. Yes-associated protein 1 (YAP1) was reported to upregulate the expression of EGFR. Moreover, we also found that FGF8 increased the expression of YAP1 and knockdown of YAP1 eliminated the upregulation of EGFR and the resistance to EGFR inhibition induced by FGF8. Our study provides evidence that FGF8 plays an important role in the resistance to EGFR inhibition of human HCC cells.

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“…Other areas where there is obvious potential for engineering input include: novel biosensors and pointof-care diagnostics for early detection of disease via the capture and detection of circulating biomarkers (liquid biopsies) [24][25][26][27]; the use of smart wearable or implantable electrochemical sensors to characterise tumour response to chemotherapy in situ or to monitor disease progression and/or signs of relapse [28,29]; artificial intelligence (AI), such as machine learning to help physicians make better diagnoses and guide treatment decisions while minimising costs [30]; metabolic and proteomic profiling of body fluids for the identification of tumoural areas in situ [31][32][33]; and disease-detecting or disease-fighting nanotechnologies (e.g. DNA nanobots [34], quantum dots [35]) for reporting disease status and selectively delivering drugs to tumour cells whilst minimising systemic side effects [36].…”

mentioning

confidence: 99%