Author
Listed:
- Sharyn Thomas
(Royal Free Hospital)
- Fiyaz Mohammed
(University of Birmingham, Edgbaston)
- Rogier M. Reijmers
(Leiden University Medical Center)
- Annemarie Woolston
(Royal Free Hospital)
- Theresa Stauss
(Royal Free Hospital)
- Alan Kennedy
(Royal Free Hospital)
- David Stirling
(Royal Free Hospital)
- Angelika Holler
(Royal Free Hospital)
- Louisa Green
(Royal Free Hospital)
- David Jones
(University College London)
- Katherine K. Matthews
(Cardiff University School of Medicine)
- David A. Price
(Cardiff University School of Medicine)
- Benjamin M. Chain
(Royal Free Hospital)
- Mirjam H. M. Heemskerk
(Leiden University Medical Center)
- Emma C. Morris
(Royal Free Hospital)
- Benjamin E. Willcox
(University of Birmingham, Edgbaston)
- Hans J. Stauss
(Royal Free Hospital)
Abstract
TCR-gene-transfer is an efficient strategy to produce therapeutic T cells of defined antigen specificity. However, there are substantial variations in the cell surface expression levels of human TCRs, which can impair the function of engineered T cells. Here we demonstrate that substitutions of 3 amino acid residues in the framework of the TCR variable domains consistently increase the expression of human TCRs on the surface of engineered T cells.The modified TCRs mediate enhanced T cell proliferation, cytokine production and cytotoxicity, while reducing the peptide concentration required for triggering effector function up to 3000-fold. Adoptive transfer experiments in mice show that modified TCRs control tumor growth more efficiently than wild-type TCRs. Our data indicate that simple variable domain modifications at a distance from the antigen-binding loops lead to increased TCR expression and improved effector function. This finding provides a generic platform to optimize the efficacy of TCR gene therapy in humans.
Suggested Citation
Sharyn Thomas & Fiyaz Mohammed & Rogier M. Reijmers & Annemarie Woolston & Theresa Stauss & Alan Kennedy & David Stirling & Angelika Holler & Louisa Green & David Jones & Katherine K. Matthews & David, 2019.
"Framework engineering to produce dominant T cell receptors with enhanced antigen-specific function,"
Nature Communications, Nature, vol. 10(1), pages 1-15, December.
Handle:
RePEc:nat:natcom:v:10:y:2019:i:1:d:10.1038_s41467-019-12441-w
DOI: 10.1038/s41467-019-12441-w
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