Abstract
PD-1 immune checkpoint inhibitors have produced encouraging results in patients with hepatocellular carcinoma (HCC). However, what determines resistance to anti– PD-1 therapies is unclear. We created a novel genetically engineered mouse model of HCC that enables interrogation of how different genetic alterations affect immune surveillance and response to immunotherapies. Expression of exogenous antigens in MYC;Trp53 HCCs led to T cell–mediated immune −/− surveillance, which was accompanied by decreased tumor formation and increased survival. Some −/− antigen-expressing MYC;Trp53 HCCs escaped the immune system by upregulating the β-catenin (CTNNB1) pathway. Accordingly, expression of exogenous antigens in MYC;CTNNB1 HCCs had no effect, demonstrating that β-catenin promoted immune escape, which involved defective recruitment of dendritic cells and consequently impaired T-cell activity. Expression of chemokine CCL5 in antigen-expressing MYC;CTNNB1 HCCs restored immune surveillance. Finally, β-catenin–driven tumors were resistant to anti–PD-1. In summary, β-catenin activation promotes immune escape and resistance to anti–PD-1 and could represent a novel biomarker for HCC patient exclusion. SIGNIFICANCE: Determinants of response to anti–PD-1 immunotherapies in HCC are poorly understood. Using a novel mouse model of HCC, we show that β-catenin activation promotes immune evasion and resistance to anti–PD-1 therapy and could potentially represent a novel biomarker for HCC patient exclusion.
| Original language | English |
|---|---|
| Pages (from-to) | 1124-1141 |
| Number of pages | 18 |
| Journal | Cancer Discovery |
| Volume | 9 |
| Issue number | 8 |
| DOIs | |
| State | Published - Aug 2019 |
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In: Cancer Discovery, Vol. 9, No. 8, 08.2019, p. 1124-1141.
Research output: Contribution to journal › Article › peer-review
TY - JOUR
T1 - β-catenin activation promotes immune escape and resistance to anti–PD-1 therapy in hepatocellular carcinoma
AU - de Galarreta, Marina Ruiz
AU - Bresnahan, Erin
AU - Molina-Sánchez, Pedro
AU - Lindblad, Katherine E.
AU - Maier, Barbara
AU - Sia, Daniela
AU - Puigvehi, Marc
AU - Miguela, Verónica
AU - Casanova-Acebes, María
AU - Dhainaut, Maxime
AU - Villacorta-Martin, Carlos
AU - Singhi, Aatur D.
AU - Moghe, Akshata
AU - von Felden, Johann
AU - Grinspan, Lauren Tal
AU - Wang, Shuang
AU - Kamphorst, Alice O.
AU - Monga, Satdarshan P.
AU - Brown, Brian D.
AU - Villanueva, Augusto
AU - Llovet, Josep M.
AU - Merad, Miriam
AU - Lujambio, Amaia
N1 - Funding Information: We wish to thank the patients who generously provided tissues and participated in our studies. We thank Drs. Scott Lowe, Xin Chen, Tyler Jacks, and Feng Zhang for access to plasmids. We thank the Center for Comparative Medicine and Surgery (CCMS), the Tisch Cancer Institute Flow Cytometry Shared Resource Facility, the ISMMS Oncological Sciences Histology Shared Resource Facility, ISMMS Genomics Core Facility, the Translational and Molecular Imaging Institute (TMII) Imaging Core, and the ISMMS Biorepository and Pathology Core. We thank Drs. Scott L. Friedman, Joshua Brody, and Andriana Kotini for insightful comments. M. Ruiz de Galarreta was supported by the Fundación Alfonso Martín Escudero Fellowship and the Damon Runyon-Rachleff Innovation Award (DR52-18). E. Bresnahan was supported by the Damon Runyon-Rachleff Innovation Award (DR52-18). P. Molina-Sánchez was supported by a Pfizer Research Grant and the NIH/NCI R37 Merit Award (R37CA230636). K.E. Lindblad was supported by the NIH/NCI R37 Merit Award (R37CA230636) and the Graduate School of Biomedical Sciences at ISMMS. B. Maier was supported by the NIH/NIAID R56AI137244 grant. D. Sia was supported by the Gilead Science Research Scholar in Liver Diseases. M. Puigvehi received a scholarship grant from the Asociación Española para el Estudio del Hígado (AEEH). V. Miguela was supported by Department of Defense (DoD) Career Development Award (CA150178) and DoD Translational Team Science Award (CA150272P2). M. Casanova-Acebes was supported by the Long-Term Human Frontiers Science Program (LT00110/2015-L/1). M. Dhainaut was supported by the Belgian American Educational Foundation. C. Villacorta-Martin was supported by the DoD Translational Team Science Award (CA150272P3). J. von Felden is supported by the German Research Foundation (FE 1746/1-1). S.P. Monga was supported by NIH grant R01CA204586 and the Endowed Chair for Experimental Pathology. A. Villanueva was supported by the DoD Translational Team Science Award (CA150272P3). B.D. Brown was supported by R33CA223947. J.M. Llovet was supported by the NCI (P30-CA196521), the DoD Translational Team Science Award (CA150272P1), the European Commission (EC)/Horizon 2020 Program (HEPCAR, Ref. 667273-2), EIT Health (CRISH2, Ref. 18053), the Accelerator Award (CRUCK, AEEC, AIRC; HUNTER, Ref. C9380/A26813), the Samuel Waxman Cancer Research Foundation, Spanish National Health Institute (SAF2016-76390), and the Gener-alitat de Catalunya/AGAUR (SGR-1358). M. Merad was supported by NIH/NIAID (U19AI128949). A. Lujambio was supported by a Damon Runyon-Rachleff Innovation Award (DR52-18), R37 Merit Award (R37CA230636), DoD Career Development Award (CA150178), DoD Translational Team Science Award (CA150272P2), and the Icahn School of Medicine at Mount Sinai. The Tisch Cancer Institute and related research facilities are supported by P30 CA196521. Funding Information: We wish to thank the patients who generously provided tissues and participated in our studies. We thank Drs. Scott Lowe, Xin Chen, Tyler Jacks, and Feng Zhang for access to plasmids. We thank the Center for Comparative Medicine and Surgery (CCMS), the Tisch Cancer Institute Flow Cytometry Shared Resource Facility, the ISMMS Oncological Sciences Histology Shared Resource Facility, ISMMS Genomics Core Facility, the Translational and Molecular Imaging Institute (TMII) Imaging Core, and the ISMMS Biorepository and Pathology Core. We thank Drs. Scott L. Friedman, Joshua Brody, and Andriana Kotini for insightful comments. M. Ruiz de Galarreta was supported by the Fundaci?n Alfonso Mart?n Escudero Fellowship and the Damon Runyon-Rachleff Innovation Award (DR52-18). E. Bresnahan was supported by the Damon Runyon-Rachleff Innovation Award (DR52-18). P. Molina-S?nchez was supported by a Pfizer Research Grant and the NIH/NCI R37 Merit Award (R37CA230636). K.E. Lindblad was supported by the NIH/NCI R37 Merit Award (R37CA230636) and the Graduate School of Biomedical Sciences at ISMMS. B. Maier was supported by the NIH/NIAID R56AI137244 grant. D. Sia was supported by the Gilead Science Research Scholar in Liver Diseases. M. Puigvehi received a scholarship grant from the Asociaci?n Espa?ola para el Estudio del H?gado (AEEH). V. Miguela was supported by Department of Defense (DoD) Career Development Award (CA150178) and DoD Translational Team Science Award (CA150272P2). M. Casanova-Acebes was supported by the Long-Term Human Frontiers Science Program (LT00110/2015-L/1). M. Dhainaut was supported by the Belgian American Educational Foundation. C. Villacorta-Martin was supported by the DoD Translational Team Science Award (CA150272P3). J. von Felden is supported by the German Research Foundation (FE 1746/1-1). S.P. Monga was supported by NIH grant R01CA204586 and the Endowed Chair for Experimental Pathology. A. Villanueva was supported by the DoD Translational Team Science Award (CA150272P3). B.D. Brown was supported by R33CA223947. J.M. Llovet was supported by the NCI (P30-CA196521), the DoD Translational Team Science Award (CA150272P1), the European Commission (EC)/Horizon 2020 Program (HEPCAR, Ref. 667273-2), EIT Health (CRISH2, Ref. 18053), the Accelerator Award (CRUCK, AEEC, AIRC; HUNTER, Ref. C9380/A26813), the Samuel Waxman Cancer Research Foundation, Spanish National Health Institute (SAF2016-76390), and the Gener-alitat de Catalunya/AGAUR (SGR-1358). M. Merad was supported by NIH/NIAID (U19AI128949). A. Lujambio was supported by a Damon Runyon-Rachleff Innovation Award (DR52-18), R37 Merit Award (R37CA230636), DoD Career Development Award (CA150178), DoD Translational Team Science Award (CA150272P2), and the Icahn School of Medicine at Mount Sinai. The Tisch Cancer Institute and related research facilities are supported by P30 CA196521. The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked advertisement in accordance with 18 U.S.C. Section 1734 solely to indicate this fact. Publisher Copyright: © 2019 American Association for Cancer Research.
PY - 2019/8
Y1 - 2019/8
N2 - PD-1 immune checkpoint inhibitors have produced encouraging results in patients with hepatocellular carcinoma (HCC). However, what determines resistance to anti– PD-1 therapies is unclear. We created a novel genetically engineered mouse model of HCC that enables interrogation of how different genetic alterations affect immune surveillance and response to immunotherapies. Expression of exogenous antigens in MYC;Trp53 HCCs led to T cell–mediated immune −/− surveillance, which was accompanied by decreased tumor formation and increased survival. Some −/− antigen-expressing MYC;Trp53 HCCs escaped the immune system by upregulating the β-catenin (CTNNB1) pathway. Accordingly, expression of exogenous antigens in MYC;CTNNB1 HCCs had no effect, demonstrating that β-catenin promoted immune escape, which involved defective recruitment of dendritic cells and consequently impaired T-cell activity. Expression of chemokine CCL5 in antigen-expressing MYC;CTNNB1 HCCs restored immune surveillance. Finally, β-catenin–driven tumors were resistant to anti–PD-1. In summary, β-catenin activation promotes immune escape and resistance to anti–PD-1 and could represent a novel biomarker for HCC patient exclusion. SIGNIFICANCE: Determinants of response to anti–PD-1 immunotherapies in HCC are poorly understood. Using a novel mouse model of HCC, we show that β-catenin activation promotes immune evasion and resistance to anti–PD-1 therapy and could potentially represent a novel biomarker for HCC patient exclusion.
AB - PD-1 immune checkpoint inhibitors have produced encouraging results in patients with hepatocellular carcinoma (HCC). However, what determines resistance to anti– PD-1 therapies is unclear. We created a novel genetically engineered mouse model of HCC that enables interrogation of how different genetic alterations affect immune surveillance and response to immunotherapies. Expression of exogenous antigens in MYC;Trp53 HCCs led to T cell–mediated immune −/− surveillance, which was accompanied by decreased tumor formation and increased survival. Some −/− antigen-expressing MYC;Trp53 HCCs escaped the immune system by upregulating the β-catenin (CTNNB1) pathway. Accordingly, expression of exogenous antigens in MYC;CTNNB1 HCCs had no effect, demonstrating that β-catenin promoted immune escape, which involved defective recruitment of dendritic cells and consequently impaired T-cell activity. Expression of chemokine CCL5 in antigen-expressing MYC;CTNNB1 HCCs restored immune surveillance. Finally, β-catenin–driven tumors were resistant to anti–PD-1. In summary, β-catenin activation promotes immune escape and resistance to anti–PD-1 and could represent a novel biomarker for HCC patient exclusion. SIGNIFICANCE: Determinants of response to anti–PD-1 immunotherapies in HCC are poorly understood. Using a novel mouse model of HCC, we show that β-catenin activation promotes immune evasion and resistance to anti–PD-1 therapy and could potentially represent a novel biomarker for HCC patient exclusion.
UR - http://www.scopus.com/inward/record.url?scp=85070801211&partnerID=8YFLogxK
U2 - 10.1158/2159-8290.CD-19-0074
DO - 10.1158/2159-8290.CD-19-0074
M3 - Article
C2 - 31186238
AN - SCOPUS:85070801211
SN - 2159-8274
VL - 9
SP - 1124
EP - 1141
JO - Cancer Discovery
JF - Cancer Discovery
IS - 8
ER -