TY - JOUR
T1 - T cells genetically engineered to overcome death signaling enhance adoptive cancer immunotherapy
AU - Yamamoto, Tori N.
AU - Lee, Ping Hsien
AU - Vodnala, Suman K.
AU - Gurusamy, Devikala
AU - Kishton, Rigel J.
AU - Yu, Zhiya
AU - Eidizadeh, Arash
AU - Eil, Robert
AU - Fioravanti, Jessica
AU - Gattinoni, Luca
AU - Kochenderfer, James N.
AU - Fry, Terry J.
AU - Aksoy, Bulent Arman
AU - Hammerbacher, Jeffrey E.
AU - Cruz, Anthony C.
AU - Siegel, Richard M.
AU - Restifo, Nicholas P.
AU - Klebanoff, Christopher A.
N1 - Funding Information:
WethankK.HanadaforcontributingtheB16-mhgp100melanoma cell line. We thank S. Patel, S.M. Sukumar, and C. Ouyang for thoughtful discussions; R. Somerville for assistance with patient sample collection; A. Mixon and S. Farid for expertise with cell sorting; B. Karim for histopathology analysis and helpful discussions; and M. Cam and A. Merchant for help with bioinformatics analysis. This work was funded by the National Cancer Institute, Center for Cancer Research (NPR and CAK). Additional funding was provided to CAK by the Parker Institute for Cancer Immunotherapy, Damon Runyon Cancer Research Foundation, William H. Goodwin and Alice Goodwin and the Commonwealth Foundation for Cancer Research, Center for Experimental Therapeutics at MSKCC, and MSKCC Core grant P30 CA008748.
Funding Information:
We thank K. Hanada for contributing the B16-mhgp100 melanoma cell line. We thank S. Patel, S.M. Sukumar, and C. Ouyang for thoughtful discussions; R. Somerville for assistance with patient sample collection; A. Mixon and S. Farid for expertise with cell sorting; B. Karim for histopathology analysis and helpful discussions; and M. Cam and A. Merchant for help with bioinformatics analysis. This work was funded by the National Cancer Institute, Center for Cancer Research (NPR and CAK). Additional funding was provided to CAK by the Parker Institute for Cancer Immunotherapy, Damon Runyon Cancer Research Foundation, William H. Goodwin and Alice Goodwin and the Commonwealth Foundation for Cancer Research, Center for Experimental Therapeutics at MSKCC, and MSKCC Core grant P30 CA008748.
Publisher Copyright:
© 2019 American Society for Clinical Investigation
PY - 2019/4/1
Y1 - 2019/4/1
N2 - Across clinical trials, T cell expansion and persistence following adoptive cell transfer (ACT) have correlated with superior patient outcomes. Herein, we undertook a pan-cancer analysis to identify actionable ligand-receptor pairs capable of compromising T cell durability following ACT. We discovered that FASLG, the gene encoding the apoptosis-inducing ligand FasL, is overexpressed within the majority of human tumor microenvironments (TMEs). Further, we uncovered that Fas, the receptor for FasL, is highly expressed on patient-derived T cells used for clinical ACT. We hypothesized that a cognate Fas-FasL interaction within the TME might limit both T cell persistence and antitumor efficacy. We discovered that genetic engineering of Fas variants impaired in the ability to bind FADD functioned as dominant negative receptors (DNRs), preventing FasL-induced apoptosis in Fas-competent T cells. T cells coengineered with a Fas DNR and either a T cell receptor or chimeric antigen receptor exhibited enhanced persistence following ACT, resulting in superior antitumor efficacy against established solid and hematologic cancers. Despite increased longevity, Fas DNR–engineered T cells did not undergo aberrant expansion or mediate autoimmunity. Thus, T cell–intrinsic disruption of Fas signaling through genetic engineering represents a potentially universal strategy to enhance ACT efficacy across a broad range of human malignancies.
AB - Across clinical trials, T cell expansion and persistence following adoptive cell transfer (ACT) have correlated with superior patient outcomes. Herein, we undertook a pan-cancer analysis to identify actionable ligand-receptor pairs capable of compromising T cell durability following ACT. We discovered that FASLG, the gene encoding the apoptosis-inducing ligand FasL, is overexpressed within the majority of human tumor microenvironments (TMEs). Further, we uncovered that Fas, the receptor for FasL, is highly expressed on patient-derived T cells used for clinical ACT. We hypothesized that a cognate Fas-FasL interaction within the TME might limit both T cell persistence and antitumor efficacy. We discovered that genetic engineering of Fas variants impaired in the ability to bind FADD functioned as dominant negative receptors (DNRs), preventing FasL-induced apoptosis in Fas-competent T cells. T cells coengineered with a Fas DNR and either a T cell receptor or chimeric antigen receptor exhibited enhanced persistence following ACT, resulting in superior antitumor efficacy against established solid and hematologic cancers. Despite increased longevity, Fas DNR–engineered T cells did not undergo aberrant expansion or mediate autoimmunity. Thus, T cell–intrinsic disruption of Fas signaling through genetic engineering represents a potentially universal strategy to enhance ACT efficacy across a broad range of human malignancies.
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U2 - 10.1172/JCI121491
DO - 10.1172/JCI121491
M3 - Article
C2 - 30694219
AN - SCOPUS:85064932353
SN - 0021-9738
VL - 129
SP - 1551
EP - 1565
JO - Journal of Clinical Investigation
JF - Journal of Clinical Investigation
IS - 4
ER -