Efficient Gene Transduction and Reprogramming of Hematopoietic Cells Including T-Cells By Using a Non-Integrating Measles Virus Vector

In this study, we developed a new non-integrating measles virus (MV) vector-based delivery system with F deletion to eliminate cell membrane fusion-associated cytotoxicity. MV vectors transduced genes through MV receptors including CD46 and signaling lymphocyte activation molecule (CD150/SLAM). First, we examined transduction efficiencies of MV vectors and SV vectors in hematopoietic cells by using GFP expression vectors (MV-Gs and SV-Gs). Compared to SV-Gs, our MV-Gs allowed more efficient gene transfer into most hematopoietic cell type including T (3-fold) and B cells (7-fold) (Fig. 1). Furthermore, at the same multiplicity of infection (MOI) of viral transduction, MV-Gs induced less apoptosis in T cell subset compared to SV-Gs (Fig. 2) due to the slower kinetics of viral RNA amplification in the transduced cells 24 h ,48 h and 72 h post transduction.Those results encouraged us to examined if MV vectors are more potent than SV vectors in iPSC generation from unstimulated T cells. To address this question, we developed MV vectors harboring four reprogramming genes (MV-OKSMGs) and compared with SV vectors harboring these genes (SV-OKSMGs). As expected, with the MV-OKSMGs, we could generate high-quality iPSCs with the similar morphology, pluripotency markers, karyotype and differentiation capacity as human embryonic stem cells. Upon the less cytotoxicity, iPSC generation efficiency of MV-OKSMGs was much higher than that of SV-OKSMGs for unstimulated T cells (0.47 ± 0.25...
Source: Blood - Category: Hematology Authors: Tags: 801. Gene Therapy and Transfer: Poster II Source Type: research