Investigate the impact of MHC-I cytoplasmic tail on CD8 T cell function and fate

Abstract

Abstract Mutational studies have revealed that the cytoplasmic tail of MHC-I plays an important role in the generation of CD8+ T cell mediated immunity. Although the MHC-I tail contains highly conserved serine and tyrosine phosphorylation sites that can potentially harbor signals or ‘instructional payloads’, little is known about how these post-translational modifications are induced, or the impact they may have on immune responses. In this study, we established the artificial antigen presenting cells K562 that express HLA-A2 with different cytoplasmic tail mutations on serine and tyrosine sites. We demonstrated that the deletion of exon 7 on HLA-A2 tail led to a higher T cell killing in the 4-hour assay, while mutating serine 335 to glutamic acid (S335E) increased long-term T cell killing. We further found that S335E has the highest expression of HLA-A2 on K562 cell surface compared to wild type and all the other tail mutants. As a result, the robust CD8 T cell killing to S335E K562 cells can be partially explained by the high expression level of HLA-A2 on the cell surface. We then conducted a T cell priming experiment using cytoplasmic tail mutated KG-1 cells. All the tail mutants generated low number of antigen specific CD8 T cells from healthy donor PBMC when compared to the wild type. However, T cells primed by KG-1 that bearing tyrosine 320 mutation (Y320E) expanded at a higher level after sorting. Together, our data showed that the MHC-I cytoplasmic tail might have an impact on CD8 T cell priming and effector function through the conserved amino acids S335 and Y320.