Improving TCR affinity on 293 T cells.

This study presents an efficient method to improve TCR affinity, comprising 1) CDR-directed saturation mutation of TCR cDNA, 2) transient TCR display on CD3-expressing HEK293T (CD3-293 T) cells by simple plasmid transfection, 3) staining with HLA-tetramers, and 4) multi-round sorting of cells with CD8-independent tetramer binding on a flow cytometer. Using these procedures, we successfully identified mutant TCRs with enhanced binding from an HLA-A*24:02-restricted, human telomerase reverse transcriptase (hTERT)-specific TCR. Two such clones, 2A7A and 2D162, harboring mutations in CDR1 and CDR2 of TCRβ, respectively, were isolated with both showing sequential four amino acid substitutions. When expressed on CD3-293 T cells along with wild-type TCRα, the TCR molecules of these mutants as well as their combinatory mutation, bound to HLA-A24/hTERT-tetramers more strongly than the wild-type TCRs, without binding to control tetramers. Besides, in order to facilitate a functional study of TCR, we established an artificial T cell line, designated as CD8I-J2, which expresses a human CD8 and IFN-γ producing cassette by modifying Jurkat-derived J.RT3-T3.5 cells. CD8I-J2 cells expressing wild-type or affinity-enhanced hTERT-specific TCRs were analyzed for their recognition of serially diluted cognate peptide on HLA-A*24:02-transduced T2 cells. CD8I-J2 cells expressing each mutant TCR recognized the hTERT peptide at lower concentrations than wild-type TCR. The hierarchy of peptide recognition is concordant with tetramer binding on CD3-293 T cells and none of these mutant TCRs were cross-reactive with irrelevant peptides reported to be present on HLA-A*24:02 molecules as far as tested. These methods might thus be useful for obtaining high affinity mutants from other TCRs of interest.