Automated, scaled, transposon-based production of CAR T cells

Dominik Lock; Razieh Monjezi; Caroline Brandes; Stephan Bates; Simon Lennartz; Karin Teppert; Leon Gehrke; Rafailla Karasakalidou-Seidt; Teodora Lukic; Marco Schmeer; Martin Schleef; Niels Werchau; Matthias Eyrich; Mario Assenmacher; Andrew Kaiser; Sabrina Prommersberger; Thomas Schaser; Michael Hudecek

doi:10.1136/jitc-2022-005189

Automated, scaled, transposon-based production of CAR T cells

J Immunother Cancer. 2022 Sep;10(9):e005189. doi: 10.1136/jitc-2022-005189.

Authors

Dominik Lock^#¹, Razieh Monjezi^#², Caroline Brandes³, Stephan Bates², Simon Lennartz³, Karin Teppert³, Leon Gehrke², Rafailla Karasakalidou-Seidt², Teodora Lukic², Marco Schmeer⁴, Martin Schleef⁴, Niels Werchau³, Matthias Eyrich⁵, Mario Assenmacher³, Andrew Kaiser³, Sabrina Prommersberger^#², Thomas Schaser^#³, Michael Hudecek²

Affiliations

¹ Miltenyi Biotec BV & Co KG, Bergisch Gladbach, Germany dominiklo@miltenyi.com.
² Medizinische Klinik und Poliklinik II, Universitätsklinikum Würzburg, Würzburg, Germany.
³ Miltenyi Biotec BV & Co KG, Bergisch Gladbach, Germany.
⁴ PlasmidFactory GmbH und Co KG, Bielefeld, Germany.
⁵ Universitätskinderklinik, Universitätsklinikum Würzburg, Würzburg, Germany.

^# Contributed equally.

Abstract

Background: There is an increasing demand for chimeric antigen receptor (CAR) T cell products from patients and care givers. Here, we established an automated manufacturing process for CAR T cells on the CliniMACS Prodigy platform that is scaled to provide therapeutic doses and achieves gene-transfer with virus-free Sleeping Beauty (SB) transposition.

Methods: We used an advanced CliniMACS Prodigy that is connected to an electroporator unit and performed a series of small-scale development and large-scale confirmation runs with primary human T cells. Transposition was accomplished with minicircle (MC) DNA-encoded SB100X transposase and pT2 transposon encoding a CD19 CAR.

Results: We defined a bi-pulse electroporation shock with bi-directional and unidirectional electric field, respectively, that permitted efficient MC insertion and maintained a high frequency of viable T cells. In three large scale runs, 2E8 T cells were enriched from leukapheresis product, activated, gene-engineered and expanded to yield up to 3.5E9 total T cells/1.4E9 CAR-modified T cells within 12 days (CAR-modified T cells: 28.8%±12.3%). The resulting cell product contained highly pure T cells (97.3±1.6%) with balanced CD4/CD8 ratio and a high frequency of T cells with central memory phenotype (87.5%±10.4%). The transposon copy number was 7.0, 9.4 and 6.8 in runs #1-3, respectively, and gene analyses showed a balanced expression of activation/exhaustion markers. The CD19 CAR T cell product conferred potent anti-lymphoma reactivity in pre-clinical models. Notably, the operator hands-on-time was substantially reduced compared with conventional non-automated CAR T cell manufacturing campaigns.

Conclusions: We report on the first automated transposon-based manufacturing process for CAR T cells that is ready for formal validation and use in clinical manufacturing campaigns. This process and platform have the potential to facilitate access of patients to CAR T cell therapy and to accelerate scaled, multiplexed manufacturing both in the academic and industry setting.

Keywords: Cell Engineering; Immunotherapy; Receptors, Chimeric Antigen; Translational Medical Research.

Publication types

Research Support, Non-U.S. Gov't

MeSH terms

Antigens, CD19 / genetics
Antigens, CD19 / metabolism
Humans
Immunotherapy, Adoptive* / methods
Receptors, Antigen, T-Cell
Receptors, Chimeric Antigen*
T-Lymphocytes

Substances

Antigens, CD19
Receptors, Antigen, T-Cell
Receptors, Chimeric Antigen