Junyan Tao1,2, Rong Zhang1,2, Sucha Singh1,2, Minakshi Poddar1,2, Emily Xu3, Michael Oertel1,2, Xin Chen4,5, Shanthi Ganesh6, Marc Abrams6, Satdarshan P Monga1,2,7. 1. Department of Pathology, University of Pittsburgh, School of Medicine and University of Pittsburgh Medical Center, Pittsburgh, PA. 2. Pittsburgh Liver Research Center, University of Pittsburgh, School of Medicine and University of Pittsburgh Medical Center, Pittsburgh, PA. 3. Raleigh Charter High School, Raleigh, NC. 4. Department of Bioengineering and Therapeutic Sciences, University California, San Francisco, CA. 5. Liver Center, University California, San Francisco, CA. 6. Dicerna Pharmaceuticals, Inc, Cambridge, MA. 7. Department of Medicine, University of Pittsburgh, School of Medicine and University of Pittsburgh Medical Center, Pittsburgh, PA.
Abstract
Recently, we have shown that coexpression of hMet and mutant-β-catenin using sleeping beauty transposon/transposase leads to hepatocellular carcinoma (HCC) in mice that corresponds to around 10% of human HCC. In the current study, we investigate whether Ras activation, which can occur downstream of Met signaling, is sufficient to cause HCC in association with mutant-β-catenin. We also tested therapeutic efficacy of targeting β-catenin in an HCC model. We show that mutant-K-Ras (G12D), which leads to Ras activation, cooperates with β-catenin mutants (S33Y, S45Y) to yield HCC in mice. Affymetrix microarray showed > 90% similarity in gene expression in mutant-K-Ras-β-catenin and Met-β-catenin HCC. K-Ras-β-catenin tumors showed up-regulation of β-catenin targets like glutamine synthetase (GS), leukocyte cell-derived chemotaxin 2, Regucalcin, and Cyclin-D1 and of K-Ras effectors, including phosphorylated extracellular signal-regulated kinase, phosphorylated protein kinase B, phosphorylated mammalian target of rapamycin, phosphorylated eukaryotic translation initiation factor 4E, phosphorylated 4E-binding protein 1, and p-S6 ribosomal protein. Inclusion of dominant-negative transcription factor 4 at the time of K-Ras-β-catenin injection prevented HCC and downstream β-catenin and Ras signaling. To address whether targeting β-catenin has any benefit postestablishment of HCC, we administered K-Ras-β-catenin mice with EnCore lipid nanoparticles (LNP) loaded with a Dicer substrate small interfering RNA targeting catenin beta 1 (CTNNB1; CTNNB1-LNP), scrambled sequence (Scr-LNP), or phosphate-buffered saline for multiple cycles. A significant decrease in tumor burden was evident in the CTNNB1-LNP group versus all controls, which was associated with dramatic decreases in β-catenin targets and some K-Ras effectors, leading to reduced tumor cell proliferation and viability. Intriguingly, in relatively few mice, non-GS-positive tumors, which were evident as a small subset of overall tumor burden, were not affected by β-catenin suppression. CONCLUSION: Ras activation downstream of c-Met is sufficient to induce clinically relevant HCC in cooperation with mutant β-catenin. β-catenin suppression by a clinically relevant modality is effective in treatment of β-catenin-positive, GS-positive HCCs. (Hepatology 2017;65:1581-1599).
Recently, we have shown that coexpression of hMet and mutant-β-catenin using sleeping beauty transposon/transposase leads to hepatocellular carcinoma (HCC) in mice that corresponds to around 10% of human HCC. In the current study, we investigate whether Ras activation, which can occur downstream of Met signaling, is sufficient to cause HCC in association with mutant-β-catenin. We also tested therapeutic efficacy of targeting β-catenin in an HCC model. We show that mutant-K-Ras (G12D), which leads to Ras activation, cooperates with β-catenin mutants (S33Y, S45Y) to yield HCC in mice. Affymetrix microarray showed > 90% similarity in gene expression in mutant-K-Ras-β-catenin and Met-β-catenin HCC. K-Ras-β-catenin tumors showed up-regulation of β-catenin targets like glutamine synthetase (GS), leukocyte cell-derived chemotaxin 2, Regucalcin, and Cyclin-D1 and of K-Ras effectors, including phosphorylated extracellular signal-regulated kinase, phosphorylated protein kinase B, phosphorylated mammalian target of rapamycin, phosphorylated eukaryotic translation initiation factor 4E, phosphorylated 4E-binding protein 1, and p-S6 ribosomal protein. Inclusion of dominant-negative transcription factor 4 at the time of K-Ras-β-catenin injection prevented HCC and downstream β-catenin and Ras signaling. To address whether targeting β-catenin has any benefit postestablishment of HCC, we administered K-Ras-β-catenin mice with EnCore lipid nanoparticles (LNP) loaded with a Dicer substrate small interfering RNA targeting catenin beta 1 (CTNNB1; CTNNB1-LNP), scrambled sequence (Scr-LNP), or phosphate-buffered saline for multiple cycles. A significant decrease in tumor burden was evident in the CTNNB1-LNP group versus all controls, which was associated with dramatic decreases in β-catenin targets and some K-Ras effectors, leading to reduced tumor cell proliferation and viability. Intriguingly, in relatively few mice, non-GS-positive tumors, which were evident as a small subset of overall tumor burden, were not affected by β-catenin suppression. CONCLUSION: Ras activation downstream of c-Met is sufficient to induce clinically relevant HCC in cooperation with mutant β-catenin. β-catenin suppression by a clinically relevant modality is effective in treatment of β-catenin-positive, GS-positive HCCs. (Hepatology 2017;65:1581-1599).
Authors: S Tardito; M Chiu; J Uggeri; A Zerbini; F Da Ros; V Dall'Asta; G Missale; O Bussolati Journal: Curr Cancer Drug Targets Date: 2011-10 Impact factor: 3.428
Authors: Pippa Newell; Sara Toffanin; Augusto Villanueva; Derek Y Chiang; Beatriz Minguez; Laia Cabellos; Radoslav Savic; Yujin Hoshida; Kiat Hon Lim; Pedro Melgar-Lesmes; Steven Yea; Judit Peix; Kemal Deniz; M Isabel Fiel; Swan Thung; Clara Alsinet; Victoria Tovar; Vincenzo Mazzaferro; Jordi Bruix; Sasan Roayaie; Myron Schwartz; Scott L Friedman; Josep M Llovet Journal: J Hepatol Date: 2009-06-12 Impact factor: 25.083
Authors: Simon A Forbes; David Beare; Prasad Gunasekaran; Kenric Leung; Nidhi Bindal; Harry Boutselakis; Minjie Ding; Sally Bamford; Charlotte Cole; Sari Ward; Chai Yin Kok; Mingming Jia; Tisham De; Jon W Teague; Michael R Stratton; Ultan McDermott; Peter J Campbell Journal: Nucleic Acids Res Date: 2014-10-29 Impact factor: 16.971
Authors: Saverio Tardito; Anaïs Oudin; Shafiq U Ahmed; Fred Fack; Olivier Keunen; Liang Zheng; Hrvoje Miletic; Per Øystein Sakariassen; Adam Weinstock; Allon Wagner; Susan L Lindsay; Andreas K Hock; Susan C Barnett; Eytan Ruppin; Svein Harald Mørkve; Morten Lund-Johansen; Anthony J Chalmers; Rolf Bjerkvig; Simone P Niclou; Eyal Gottlieb Journal: Nat Cell Biol Date: 2015-11-23 Impact factor: 28.824
Authors: Shanthi Ganesh; Xue Shui; Kevin P Craig; Martin L Koser; Girish R Chopda; Wendy A Cyr; Chengjung Lai; Henryk Dudek; Weimin Wang; Bob D Brown; Marc T Abrams Journal: Mol Cancer Ther Date: 2017-12-27 Impact factor: 6.261