Karen Tran, Alex Storer, Michelle Ols, Elizabeth Jane Weisman, Vipin Suri, Kutlu G. Elpek, Sethi Dhruv Kam, Steven M. Shamah, Dexue Sun, Heller Scott Francis, Dan Jun Li, Michael Schebesta, Jennifer Leah Gori, Benjamin Primack, Emily Brideau, Christopher Reardon, Michael Briskin, Celeste Richardson, and Michelle Fleury
Adoptive cell therapy with chimeric antigen receptor (CAR) modified T cells has demonstrated remarkable clinical efficacy in the treatment of certain B cell malignancies, and more recently in multiple myeloma. However, CAR-T therapy has been less successful in treating solid tumors due to multiple obstacles, including the lack of robust CAR-T cell expansion, the immunosuppressive tumor microenvironment, and tumor escape due to the loss of targeted antigen. Engineering CAR-T cells to produce immunomodulatory factors such as Interleukin 12 (IL12) and Cluster of Differentiation 40 Ligand (CD40L) has been shown to enhance functional activity by driving T cell expansion, conferring resistance to immunosuppression, improving antigen presentation, and inducing antigen spread. However, the clinical utility of both IL12 and activators of the CD40 signaling pathway have been limited by systemic toxicity associated with their potent pharmacological activities. Providing precise tuning of the timing and level of expression of these immunomodulatory factors in CAR-T cells could significantly enhance safety and therapeutic efficacy, in particular against solid tumor malignancies. We describe here the implementation of ligand-controlled regulation of IL12 and CD40L in vitro and in vivo in engineered primary human T cells via the use of destabilizing domain (DD) technology. DDs are small protein domains that are misfolded and inherently unstable in the cell, but which can be reversibly stabilized by the binding of approved pharmacologic agents. This conditional stability of DDs can be readily conferred to any protein of interest by fusing it to the DD, thus providing fine-tuned, exogenous regulation of protein expression and function. We have identified mutations in several human protein substrates, including phosphodiesterase 5 (PDE5), dihydrofolate reductase (DHFR), and estrogen receptor (ER), which convey DD activity and can be regulated by FDA-approved drugs. We show that transduction of human T cells with either DD-IL12 or DD-CD40L fusion constructs yields low expression levels in the basal state and a rapid, dose-dependent induction of IL12 or CD40L protein in the presence of the corresponding stabilizing ligand. Moreover, kinetically precise, on-demand production of either factor from CAR-T cells can be achieved in mice by oral dosing of stabilizing drugs. A CD19 CAR-T Nalm6 mouse model has been established that measures potent CAR-T expansion and enhanced anti-tumor efficacy with armored immunomodulatory constructs. Studies are underway in this model, as well as in solid tumor models, to test for enhanced CAR-T activity via drug-induced activation of IL12 and CD40L towards the development of next generation cell therapies with more favorable efficacy and safety profiles. Citation Format: Michelle Ols, Michael Schebesta, Emily Brideau, Kutlu Elpek, Michelle Fleury, Jennifer Gori, Scott Heller, Dan Jun Li, Benjamin Primack, Christopher Reardon, Dhruv Sethi, Alex Storer, Dexue Sun, Karen Tran, Elizabeth Weisman, Michael Briskin, Celeste Richardson, Vipin Suri, Steven Shamah. CAR-Ts armored with small molecule-regulated IL12 or CD40L cassettes for enhanced activity against solid tumors [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2019; 2019 Mar 29-Apr 3; Atlanta, GA. Philadelphia (PA): AACR; Cancer Res 2019;79(13 Suppl):Abstract nr LB-013.