Orthotopic replacement of T-cell receptor α- and β-chains with preservation of near-physiological T-cell function

Kilian Schober; Thomas R. Müller; Füsun Gökmen; Simon Grassmann; Manuel Effenberger; Mateusz Poltorak; Christian Stemberger; Kathrin Schumann; Theodore L. Roth; Alexander Marson; Dirk H. Busch

doi:10.1038/s41551-019-0409-0

Orthotopic replacement of T-cell receptor α- and β-chains with preservation of near-physiological T-cell function

Kilian Schober, Thomas R. Müller, Füsun Gökmen, Simon Grassmann, Manuel Effenberger, Mateusz Poltorak, Christian Stemberger, Kathrin Schumann, Theodore L. Roth, Alexander Marson, Dirk H. Busch

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128 Scopus citations

Abstract

Therapeutic T cells with desired specificity can be engineered by introducing T-cell receptors (TCRs) specific for antigens of interest, such as those from pathogens or tumour cells. However, TCR engineering is challenging, owing to the complex heterodimeric structure of the receptor and to competition and mispairing between endogenous and transgenic receptors. Additionally, conventional TCR insertion disrupts the regulation of TCR dynamics, with consequences for T-cell function. Here, we report the outcomes and validation, using five different TCRs, of the use of clustered regularly interspaced short palindromic repeats (CRISPR)–CRISPR-associated protein 9 (Cas9) with non-virally delivered template DNA for the elimination of endogenous TCR chains and for the orthotopic placement of TCRs in human T cells. We show that, whereas the editing of a single receptor chain results in chain mispairing, simultaneous editing of α- and β-chains combined with orthotopic TCR placement leads to accurate αβ-pairing and results in TCR regulation similar to that of physiological T cells.

Original language	English
Pages (from-to)	974-984
Number of pages	11
Journal	Nature Biomedical Engineering
Volume	3
Issue number	12
DOIs	https://doi.org/10.1038/s41551-019-0409-0
State	Published - 1 Dec 2019

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Schober, K., Müller, T. R., Gökmen, F., Grassmann, S., Effenberger, M., Poltorak, M., Stemberger, C., Schumann, K., Roth, T. L., Marson, A., & Busch, D. H. (2019). Orthotopic replacement of T-cell receptor α- and β-chains with preservation of near-physiological T-cell function. Nature Biomedical Engineering, 3(12), 974-984. https://doi.org/10.1038/s41551-019-0409-0

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title = "Orthotopic replacement of T-cell receptor α- and β-chains with preservation of near-physiological T-cell function",

abstract = "Therapeutic T cells with desired specificity can be engineered by introducing T-cell receptors (TCRs) specific for antigens of interest, such as those from pathogens or tumour cells. However, TCR engineering is challenging, owing to the complex heterodimeric structure of the receptor and to competition and mispairing between endogenous and transgenic receptors. Additionally, conventional TCR insertion disrupts the regulation of TCR dynamics, with consequences for T-cell function. Here, we report the outcomes and validation, using five different TCRs, of the use of clustered regularly interspaced short palindromic repeats (CRISPR)–CRISPR-associated protein 9 (Cas9) with non-virally delivered template DNA for the elimination of endogenous TCR chains and for the orthotopic placement of TCRs in human T cells. We show that, whereas the editing of a single receptor chain results in chain mispairing, simultaneous editing of α- and β-chains combined with orthotopic TCR placement leads to accurate αβ-pairing and results in TCR regulation similar to that of physiological T cells.",

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AU - Grassmann, Simon

AU - Effenberger, Manuel

AU - Poltorak, Mateusz

AU - Stemberger, Christian

AU - Schumann, Kathrin

AU - Roth, Theodore L.

AU - Marson, Alexander

AU - Busch, Dirk H.

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AB - Therapeutic T cells with desired specificity can be engineered by introducing T-cell receptors (TCRs) specific for antigens of interest, such as those from pathogens or tumour cells. However, TCR engineering is challenging, owing to the complex heterodimeric structure of the receptor and to competition and mispairing between endogenous and transgenic receptors. Additionally, conventional TCR insertion disrupts the regulation of TCR dynamics, with consequences for T-cell function. Here, we report the outcomes and validation, using five different TCRs, of the use of clustered regularly interspaced short palindromic repeats (CRISPR)–CRISPR-associated protein 9 (Cas9) with non-virally delivered template DNA for the elimination of endogenous TCR chains and for the orthotopic placement of TCRs in human T cells. We show that, whereas the editing of a single receptor chain results in chain mispairing, simultaneous editing of α- and β-chains combined with orthotopic TCR placement leads to accurate αβ-pairing and results in TCR regulation similar to that of physiological T cells.

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Orthotopic replacement of T-cell receptor α- and β-chains with preservation of near-physiological T-cell function

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