Sensitive and adaptable pharmacological control of CAR T cells through extracellular receptor dimerization
Wai-Hang Leung, Joel Gay, Unja Martin, Tracy E. Garrett, Holly M. Horton, Michael T. Certo, Bruce R. Blazar, Richard A. Morgan, Philip D. Gregory, Jordan Jarjour, Alexander Astrakhan
Wai-Hang Leung, Joel Gay, Unja Martin, Tracy E. Garrett, Holly M. Horton, Michael T. Certo, Bruce R. Blazar, Richard A. Morgan, Philip D. Gregory, Jordan Jarjour, Alexander Astrakhan
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Research Article Oncology Therapeutics

Sensitive and adaptable pharmacological control of CAR T cells through extracellular receptor dimerization

Abstract

Chimeric antigen receptor (CAR) T cell therapies have achieved promising outcomes in several cancers; however, more challenging oncology indications may necessitate advanced antigen receptor designs and functions. Here we describe a bipartite receptor system composed of separate antigen-targeting and signal transduction polypeptides, each containing an extracellular dimerization domain. We demonstrate that T cell activation remains antigen dependent but can only be achieved in the presence of a dimerizing drug, rapamycin. Studies performed in vitro and in xenograft mouse models illustrate equivalent to superior antitumor potency compared with currently used CAR designs, and at rapamycin concentrations well below immunosuppressive levels. We further show that the extracellular positioning of the dimerization domains enables the administration of recombinant retargeting modules, potentially extending antigen targeting. Overall, this regulatable CAR design has exquisite drug sensitivity, provides robust antitumor responses, and is flexible for multiplex antigen targeting or retargeting, which may further assist the development of safe, potent, and durable T cell therapeutics.

Authors

Wai-Hang Leung, Joel Gay, Unja Martin, Tracy E. Garrett, Holly M. Horton, Michael T. Certo, Bruce R. Blazar, Richard A. Morgan, Philip D. Gregory, Jordan Jarjour, Alexander Astrakhan

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Figure 4

DARIC T cells recognize secondary antigens through the DARIC plug-in system.

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DARIC T cells recognize secondary antigens through the DARIC plug-in sys...
(A) Schematic of a DARIC signaling architecture in the presence or absence of a DARIC plug-in targeting a secondary antigen. (B) The recombinant CD19-DARIC plug-in was produced and purified from 293T cells using a rapamycin-based affinity column. The purified protein was analyzed using Coomassie blue staining. (C) Unmodified CD19-DARIC T cells were cocultured with K562-BCMA cells alone, in the presence of rapamycin, or in the presence of increasing concentration of rapamycin-preloaded BCMA plug-in. Cytokine production was analyzed by iQue QBeads. (D) The cytotoxicity and (E) cytokine production of BCMA-DARIC T cells cocultured with CD19+ Nalm-6 cells in the presence or absence of rapamycin-preloaded CD19 DARIC plug-in. (F) Schematic of adaptable CAR architecture, with an extracellular FRB* domain located next to the scFv able to bind recombinant DARIC plug-in scFv to target a secondary antigen. (G) The cytotoxicity and (H) IFN-γ cytokine production of BCMA-adaptable CAR following 24-hour coculture with K562-BCMA target cells was analyzed by FACS and QBeads, respectively. (I) The cytotoxicity and (J) cytokine production of control and BCMA-adaptable CAR in the presence of recombinant CD19-DARIC plug-in was analyzed after 24-hour coculture with Nalm-6 target cells. Data points represent 3 different donors.