What is the problem/issue being addressed?
T cells and B cells, the two main components of adaptive immunity, express highly diverse antigen receptors generated by somatic gene rearrangement during their development. T cell development is restricted to the specialized environment of the thymus. Two types of T cells are conserved throughout evolution and across species: alphabeta and gammadelta T cells. In the thymus, alphabeta T cells develop through discrete steps from co-receptor CD4-CD8- (double negative, DN) T-cell receptor (TCR)- via CD4+CD8+ thymocytes into mature CD4+ or CD8+ single positive TCRalphabeta+ T cells, which populate the peripheral lymphoid tissues and are restricted to recognize antigens as peptides bound to major histocompartibility complex (pMHC). gammadelta T cells develop in the thymus alongside alphabeta T cells, but rearrange a distinct TCR (TCRgammadelta) that is not restricted by classical MHC. Successive waves of gammadelta T cells develop in the fetal and later in the adult thymus and different waves are associated with variable TCR-Vgamma segment usage, functional differentiation and localization in different tissues. Unique antigen-specificities of gammadelta T cells, their high clonal frequency and pre-activated differentiation status allows for their rapid, innate-like responses and confers them non-redundant roles in immune responses to infections and tumours.
Why is it important for society?
gammadelta T cells can effectively kill tumour cells and provide IFNgamma-mediated protective responses against cancer. Still, in some cases they can promote tumour growth via IL-17A production. Together with the recent advancements in T cell-based immunotherapy for cancer, gammadelta T cells are becoming an attractive tool for clinical treatments. Still, our knowledge of gammadelta T cells biology and development is rather limited and requires investigation to improve fine-tuning and manipulation for their clinical use.
What are the overall objectives?
This research project aims to elucidate the developmental trajectories and requirements of different gammadelta T cell subsets. To this end, we investigate i) the lineage relationship from uncommitted thymic progenitor cells to mature gammadelta T cell effector subsets producing either IL-17 (named gd17) or IFNgamma (named gdIFN), ii) the impact of TCRgammadelta signalling during thymic development and iii) the role of on candidate genes differentially expressed between gd17 and gdIFN cells and their role in gammadelta T cell subsets development.