TY - JOUR
T1 - T Cells Expressing a Modified FcgRI Exert Antibody-Dependent Cytotoxicity and Overcome the Limitations of CAR T-cell Therapy against Solid Tumors
AU - Rasoulouniriana, Diana
AU - Santana-Magal, Nadine
AU - Gutwillig, Amit
AU - Farhat-Younis, Leen
AU - Tal, Lior
AU - Amar, Sarah
AU - Milyavsky, Michael
AU - Muddineni, Siva Sai Naga Anurag
AU - Solomon, Neta
AU - Shpilt, Hana
AU - Dotan, Shahar
AU - Pilpel, Noam
AU - Waskow, Claudia
AU - Feinmesser, Meora
AU - Rider, Peleg
AU - Carmi, Yaron
N1 - Publisher Copyright:
©2023 The Authors; Published by the American Association for Cancer Research.
PY - 2023/6/1
Y1 - 2023/6/1
N2 - The pioneering design of chimeric antigen receptor (CAR) T-cell therapy demonstrated the potential of reprogramming the immune system. Nonetheless, T-cell exhaustion, toxicity, and suppressive microenvironments limit their efficacy in solid tumors. We previously characterized a subset of tumor-infiltrating CD4þ T cells expressing the FcgRI receptor. Herein, we detail engineering of a receptor, based on the FcgRI structure, allowing T cells to target tumor cells using antibody intermediates. These T cells showed effective and specific cytotoxicity only when an appropriate antibody was added. Only target-bound antibodies activated these cells, while free antibodies were internalized without activation. Their cytotoxic activity was correlated to target protein density, therefore targeting tumor cells with high antigen density while sparing normal cells with low or no expression. This activation mechanism prevented premature exhaustion. Furthermore, during antibody-dependent cytotoxicity these cells secreted attenuated cytokine levels compared with CAR T cells, thereby enhancing their safety profile. These cells eradicated established melanomas, infiltrated the tumor microenvironment, and facilitated host immune cell recruitment in immunocompetent mice. In NOD/SCID gamma mice the cells infiltrate, persist, and eradicate tumors. As opposed to CAR T-cell therapies, which require changing the receptor across different types of cancer, our engineered T cells remain the same across tumor types, while only the injected antibody changes. Overall, we generated a highly flexible T-cell therapy capable of binding a wide range of tumor cells with high affinity, while preserving the cytotoxic specificity only to cells expressing high density of tumor-associated antigens and using a single manufacturing process.
AB - The pioneering design of chimeric antigen receptor (CAR) T-cell therapy demonstrated the potential of reprogramming the immune system. Nonetheless, T-cell exhaustion, toxicity, and suppressive microenvironments limit their efficacy in solid tumors. We previously characterized a subset of tumor-infiltrating CD4þ T cells expressing the FcgRI receptor. Herein, we detail engineering of a receptor, based on the FcgRI structure, allowing T cells to target tumor cells using antibody intermediates. These T cells showed effective and specific cytotoxicity only when an appropriate antibody was added. Only target-bound antibodies activated these cells, while free antibodies were internalized without activation. Their cytotoxic activity was correlated to target protein density, therefore targeting tumor cells with high antigen density while sparing normal cells with low or no expression. This activation mechanism prevented premature exhaustion. Furthermore, during antibody-dependent cytotoxicity these cells secreted attenuated cytokine levels compared with CAR T cells, thereby enhancing their safety profile. These cells eradicated established melanomas, infiltrated the tumor microenvironment, and facilitated host immune cell recruitment in immunocompetent mice. In NOD/SCID gamma mice the cells infiltrate, persist, and eradicate tumors. As opposed to CAR T-cell therapies, which require changing the receptor across different types of cancer, our engineered T cells remain the same across tumor types, while only the injected antibody changes. Overall, we generated a highly flexible T-cell therapy capable of binding a wide range of tumor cells with high affinity, while preserving the cytotoxic specificity only to cells expressing high density of tumor-associated antigens and using a single manufacturing process.
UR - http://www.scopus.com/inward/record.url?scp=85160967908&partnerID=8YFLogxK
U2 - 10.1158/2326-6066.CIR-22-0423
DO - 10.1158/2326-6066.CIR-22-0423
M3 - Article
C2 - 37070661
AN - SCOPUS:85160967908
SN - 2326-6066
VL - 11
SP - 792
EP - 809
JO - Cancer Immunology Research
JF - Cancer Immunology Research
IS - 6
ER -