288. Development of Cocal Glycoprotein Envelope Producer Cell Lines for Robust Lentiviral Gene Transfer into Hematopoietic Stem Cells and T Cells

Abstract

Lentiviral vectors (LVs) are routinely used for stable gene transfer and have demonstrated great promise in hematopoietic stem cell gene therapy and also immunotherapy using genetically modified T cells. LVs are commonly pseudotyped with vesicular stomatitis virus envelope glycoprotein (VSV-G), which confers broad tropism to the vector and allows for vector concentration by centrifugation. However, the use of VSV-G has several limitations, such as susceptibility to inactivation by human serum complement making it unsuitable for in vivo delivery. Furthermore, VSV-G is toxic when constitutively expressed, which has impeded efforts to generate stable producer cell lines. In this study, we first validate the use of cocal vesiculovirus envelope to pseudotype LVs by demonstrating that cocal LVs transduce hematopoietic stem cells and CD4+ T cells more efficiently than VSV-G LVs. We also provide evidence that cocal and VSV-G envelopes use the same receptor for cell entry. We then describe the development of two high-titer, cocal-pseudotyped, LV producer cell lines for a GFP reporter and for a WT1 tumor-specific T cell receptor (TCR). The different 3rd generation lentiviral helper genes were sequentially introduced in HEK293T cells by co-transfection with plasmids encoding antibiotic resistance genes followed by selection to allow for stable protein expression. Cells expressing the cocal envelope produced over 10-times more infectious LV particles as compared to VSV-G expressing cells. High-titer cocal producer cells were isolated by screening for best single clones, which were capable of generating concentrated titers above 108 infectious units per mL. We found that these producer cells were stable after serial passages for over 3 months, with no drop in titer detected over time. The resulting GFP and WT1-TCR vectors performed at least as well as identical vectors made with our standard transient transfection protocol for the transduction of CD34+ and CD4+ T cells, respectively. Cocal LV producer cells were also adapted for growth in suspension, serum-free culture, which will facilitate efforts for the scaling up of vector production. In summary, we have successfully developed two independent LV producer cells lines with clinically usable titers. The broad applicability of our cocal packaging cell line offers a promising tool toward the generation of large-scale, clinical grade LV.