Large-scale Clinical-grade Retroviral Vector Production in a Fixed-Bed Bioreactor

The successful genetic engineering of patient T cells with &ggr;-retroviral vectors expressing chimeric antigen receptors or T-cell receptors for phase II clinical trials and beyond requires the large-scale manufacture of high-titer vector stocks. The production of retroviral vectors from stable packaging cell lines using roller bottles or 10- to 40-layer cell factories is limited by a narrow harvest window, labor intensity, open-system operations, and the requirement for significant incubator space. To circumvent these shortcomings, we optimized the production of vector stocks in a disposable fixed-bed bioreactor using good manufacturing practice–grade packaging cell lines. High-titer vector stocks were harvested over 10 days, representing a much broader harvest window than the 3-day harvest afforded by cell factories. For PG13 and 293Vec packaging cells, the average vector titer and the vector stocks’ yield in the bioreactor were higher by 3.2- to 7.3-fold, and 5.6- to 13.1-fold, respectively, than those obtained in cell factories. The vector production was 10.4 and 18.6 times more efficient than in cell factories for PG13 and 293Vec cells, respectively. Furthermore, the vectors produced from the fixed-bed bioreactors passed the release test assays for clinical applications. Therefore, a single vector lot derived from 293Vec is suitable to transduce up to 500 patients cell doses in the context of large clinical trials using chimeric antigen receptors or T-cell receptors. These findings demonstrate for the first time that a robust fixed-bed bioreactor process can be used to produce &ggr;-retroviral vector stocks scalable up to the commercialization phase.

[1]  J. Garcia,et al.  Construction and properties of retrovirus packaging cells based on gibbon ape leukemia virus , 1991, Journal of virology.

[2]  J. Olsen,et al.  Use of sodium butyrate to enhance production of retroviral vectors expressing CFTR cDNA. , 1995, Human gene therapy.

[3]  I. Plavec,et al.  A novel human amphotropic packaging cell line: high titer, complement resistance, and improved safety. , 1996, Virology.

[4]  J. Chen,et al.  Novel retroviral packaging cell lines: complementary tropisms and improved vector production for efficient gene transfer , 1997, Gene Therapy.

[5]  P. Searle,et al.  Improved titers of retroviral vectors from the human FLYRD18 packaging cell line in serum- and protein-free medium. , 1999, Human gene therapy.

[6]  Y. Takeuchi,et al.  Progress with retroviral gene vectors , 2000, Reviews in medical virology.

[7]  M. Al‐Rubeai,et al.  Effects of Culture Parameters on the Production of Retroviral Vectors by a Human Packaging Cell Line , 2000, Biotechnology progress.

[8]  K. Cornetta,et al.  Packaging cell line characteristics and optimizing retroviral vector titer: the National Gene Vector Laboratory experience. , 2000, Human gene therapy.

[9]  P. Mangeot,et al.  Development of Minimal Lentivirus Vectors Derived from Simian Immunodeficiency Virus (SIVmac251) and Their Use for Gene Transfer into Human Dendritic Cells , 2000, Journal of Virology.

[10]  K. Kühlcke,et al.  Optimization of retroviral vector generation for clinical application , 2001, The journal of gene medicine.

[11]  P. Cruz,et al.  Comparison of Different Bioreactor Systems for the Production of High Titer Retroviral Vectors , 2001, Biotechnology progress.

[12]  B. Palsson,et al.  Kinetics of retroviral production from the amphotropic ΨCRIP murine producer cell line , 2004, Cytotechnology.

[13]  M. Sadelain,et al.  Production scale-up and validation of packaging cell clearance of clinical-grade retroviral vector stocks produced in Cell Factories , 2006, Gene Therapy.

[14]  S. Larson,et al.  Genetically Targeted T Cells Eradicate Systemic Acute Lymphoblastic Leukemia Xenografts , 2007, Clinical Cancer Research.

[15]  S. Sleijfer,et al.  Retroviral vectors for clinical immunogene therapy are stable for up to 9 years , 2008, Cancer Gene Therapy.

[16]  A. Kamen,et al.  Efficient human hematopoietic cell transduction using RD114- and GALV-pseudotyped retroviral vectors produced in suspension and serum-free media. , 2009, Human gene therapy.

[17]  Michel Sadelain,et al.  Manufacturing Validation of Biologically Functional T Cells Targeted to CD19 Antigen for Autologous Adoptive Cell Therapy , 2009, Journal of immunotherapy.

[18]  A. Fischer,et al.  Gene therapy for primary immunodeficiencies. , 2010, Immunology and allergy clinics of North America.

[19]  Michel Sadelain,et al.  Safety and persistence of adoptively transferred autologous CD19-targeted T cells in patients with relapsed or chemotherapy refractory B-cell leukemias. , 2011, Blood.

[20]  A. Schambach,et al.  Genetic modification of lymphocytes by retrovirus-based vectors. , 2012, Current opinion in immunology.

[21]  Qing He,et al.  CD19-Targeted T Cells Rapidly Induce Molecular Remissions in Adults with Chemotherapy-Refractory Acute Lymphoblastic Leukemia , 2013, Science Translational Medicine.

[22]  K. Curran,et al.  Chimeric antigen receptors for the adoptive T cell therapy of hematologic malignancies , 2014, International Journal of Hematology.

[23]  Qing He,et al.  Efficacy and Toxicity Management of 19-28z CAR T Cell Therapy in B Cell Acute Lymphoblastic Leukemia , 2014, Science Translational Medicine.