A closed, autologous bioprocess optimized for TCR-T cell therapies.

Autologous cell therapy has proven to be an effective treatment for hematological malignancies. Cell therapies for solid tumors are on the horizon, however the high cost and complexity of manufacturing these therapies remain a challenge. Routinely used open steps to transfer cells and reagents through unit operations further burden the workflow reducing efficiency and increasing the chance for human error. Here we describe a fully closed, autologous bioprocess generating engineered TCR-T cells. This bioprocess yielded 5-12 × 10e9 TCR-expressing T cells, transduced at low multiplicity of infections, within 7-10 days, and cells exhibited an enriched memory T-cell phenotype and enhanced metabolic fitness. It was demonstrated that activating, transducing, and expanding leukapheresed cells in a bioreactor without any T-cell or peripheral blood mononuclear cell enrichment steps had a high level of T-cell purity (~97%). Several critical process parameters of the bioreactor, including culturing at a high cell density (7e6 cells/mL), adjusting rocking agitations during phases of scale-up, lowering glycolysis through the addition of 2-deoxy- d-glucose, and modulating interleukin-2 levels, were investigated on their roles in regulating transduction efficiency, cell growth, and T-cell fitness such as T-cell memory phenotype and resistance to activation-induced cell death. The bioprocess described herein supports scale-out feasibility by enabling the processing of multiple patients' batches in parallel within a Grade C cleanroom.

Systematically optimized BCMA/CS1 bispecific CAR-T cells robustly control heterogeneous multiple myeloma.

Chimeric antigen receptor (CAR)-T cell therapy has shown remarkable clinical efficacy against B-cell malignancies, yet marked vulnerability to antigen escape and tumor relapse exists. Here we report the rational design and optimization of bispecific CAR-T cells with robust activity against heterogeneous multiple myeloma (MM) that is resistant to conventional CAR-T cell therapy targeting B-cell maturation antigen (BCMA). We demonstrate that BCMA/CS1 bispecific CAR-T cells exhibit superior CAR expression and function compared to T cells that co-express individual BCMA and CS1 CARs. Combination therapy with anti-PD-1 antibody further accelerates the rate of initial tumor clearance in vivo, while CAR-T cell treatment alone achieves durable tumor-free survival even upon tumor re-challenge. Taken together, the BCMA/CS1 bispecific CAR presents a promising treatment approach to prevent antigen escape in CAR-T cell therapy against MM, and the vertically integrated optimization process can be used to develop robust cell-based therapy against novel disease targets.

TGF-ß-responsive CAR-T cells promote anti-tumor immune function.

A chimeric antigen receptor (CAR) that responds to transforming growth factor beta (TGF-ß) enables the engineering of T cells that convert this immunosuppressive cytokine into a potent T-cell stimulant. However, clinical translation of TGF-ß CAR-T cells for cancer therapy requires the ability to productively combine TGF-ß responsiveness with tumor-targeting specificity. Furthermore, the potential concern that contaminating, TGF-ß?producing regulatory T (Treg) cells may preferentially expand during TGF-ß CAR-T cell manufacturing and suppress effector T (Teff) cells demands careful evaluation. Here, we demonstrate that TGF-ß CAR-T cells significantly improve the anti-tumor efficacy of neighboring cytotoxic T cells. Furthermore, the introduction of TGF-ß CARs into mixed T-cell populations does not result in the preferential expansion of Treg cells, nor do TGF-ß CAR-Treg cells cause CAR-mediated suppression of Teff cells. These results support the utility of incorporating TGF-ß CARs in the development of adoptive T-cell therapy for cancer.

T Cells Expressing CD19/CD20 Bispecific Chimeric Antigen Receptors Prevent Antigen Escape by Malignant B Cells.

The adoptive transfer of T cells expressing anti-CD19 chimeric antigen receptors (CARs) has shown remarkable curative potential against advanced B-cell malignancies, but multiple trials have also reported patient relapses due to the emergence of CD19-negative leukemic cells. Here, we report the design and optimization of single-chain, bispecific CARs that trigger robust cytotoxicity against target cells expressing either CD19 or CD20, two clinically validated targets for B-cell malignancies. We determined the structural parameters required for efficient dual-antigen recognition, and we demonstrate that optimized bispecific CARs can control both wild-type B-cell lymphoma and CD19(-) mutants with equal efficiency in vivo To our knowledge, this is the first bispecific CAR capable of preventing antigen escape by performing true OR-gate signal computation on a clinically relevant pair of tumor-associated antigens. The CD19-OR-CD20 CAR is fully compatible with existing T-cell manufacturing procedures and implementable by current clinical protocols. These results present an effective solution to the challenge of antigen escape in CD19 CAR T-cell therapy, and they highlight the utility of structure-based rational design in the development of receptors with higher-level complexity. Cancer Immunol Res; 4(6); 498-508. ©2016 AACR