Efficient and Non-genotoxic RNA-Based Engineering of Human T Cells Using Tumor-Specific T Cell Receptors With Minimal TCR Mispairing.

Diana Campillo-Davo,Eva Lion,Haruo Sugiyama,Hans De Reu,Herman Goossens,Viggo Van Tendeloo,Evelien L J M Smits,Johan M J Van Den Bergh,Zwi N Berneman,Fumihiro Fujiki

doi:10.3389/fimmu.2018.02503

Diana Campillo-Davo, Eva Lion + Show 8 more

Open Access

https://doi.org/10.3389/fimmu.2018.02503

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Abstract

Genetic engineering of T cells with tumor specific T-cell receptors (TCR) is a promising strategy to redirect their specificity against cancer cells in adoptive T cell therapy protocols. Most studies are exploiting integrating retro- or lentiviral vectors to permanently introduce the therapeutic TCR, which can pose serious safety issues when treatment-related toxicities would occur. Therefore, we developed a versatile, non-genotoxic transfection method for human unstimulated CD8+ T cells. We describe an optimized double sequential electroporation platform whereby Dicer-substrate small interfering RNAs (DsiRNA) are first introduced to suppress endogenous TCR α and β expression, followed by electroporation with DsiRNA-resistant tumor-specific TCR mRNA. We demonstrate that double sequential electroporation of human primary unstimulated T cells with DsiRNA and TCR mRNA leads to unprecedented levels of transgene TCR expression due to a strongly reduced degree of TCR mispairing. Importantly, superior transgenic TCR expression boosts epitope-specific CD8+ T cell activation and killing activity. Altogether, DsiRNA and TCR mRNA double sequential electroporation is a rapid, non-integrating and highly efficient approach with an enhanced biosafety profile to engineer T cells with antigen-specific TCRs for use in early phase clinical trials.

Highlights

Cancer is one of the leading causes of death in the world, according to the World Health Organization
We present a double sequential electroporation of Dicer-substrate small interfering RNAs (DsiRNA) and codon-optimized T cell receptor (TCR) mRNA as a non-genotoxic, highly efficient and versatile non-viral platform with an enhanced biosafety profile to engineer T cells with TCRs for adoptive T cell immunotherapy
WT1126 TCR expression was higher after transfection with TCR-co mRNA as compared to TCR-wt mRNA at most time points post-electroporation, whilst transgenic TCR was lost 5 days after transfection with either mRNA (Figure S1A)

Summary

Introduction

Cancer is one of the leading causes of death in the world, according to the World Health Organization. Concomitant expression of endogenous and transgenic TCR genes produces two sets of TCR alpha (TCRα) and beta (TCRβ) chains that can pair incorrectly [9], generating two mispaired TCR heterodimers that reduce transgenic TCR levels [10] and may lead to on-target and offtarget toxicities in patients [11]. These data have prompted us to develop a safer, faster and more widely applicable method for TCR engineering of T cells. We present a double sequential electroporation of DsiRNA and codon-optimized TCR mRNA as a non-genotoxic, highly efficient and versatile non-viral platform with an enhanced biosafety profile to engineer T cells with TCRs for adoptive T cell immunotherapy

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