Analysis of thymic generation of shared T-cell receptor α repertoire associated with recognition of tumor antigens shows no preference for neoantigens over wild-type antigens.

BACKGROUND: The number of mutations in cancer cells is an important predictor of a positive response to cancer immunotherapy. It has been suggested that the neoantigens produced by these mutations are more immunogenic than nonmutated tumor antigens, which are likely to be protected by immunological tolerance. However, the mechanisms of tolerance as regards tumor antigens are incompletely understood. METHODS: Here, we have analyzed the impact of thymic negative selection on shared T-cell receptor (TCR) repertoire associated with the recognition of either mutated or nonmutated tumor antigens by comparing previously known TCR-antigen-pairs to TCR repertoires of 21 immunologically healthy individuals. RESULTS: Our results show that TCRα chains associated with either type of tumor antigens are readily generated in the thymus, at a frequency similar to TCRα chains associated with nonself. In the peripheral repertoire, the relative clone size of nonself-associated chains is higher than that of the tumor antigens, but importantly, there is no difference between TCRα chains associated with mutated or nonmutated tumor antigens. CONCLUSION: This suggests that the tolerance mechanisms protecting nonmutated tumor antigens are non-deletional and therefore potentially reversible. As unmutated antigens are, unlike mutations, shared by a large number of patients, they may offer advantages in designing immunological approaches to cancer treatment.

Generation of self-reactive, shared T-cell receptor α chains in the human thymus.

The T-cell receptor (TCR) repertoire is generated in a semistochastic process of gene recombination and pairing of TCRα to TCRß chains with the estimated total TCR diversity of >108. Despite this high diversity, similar or identical TCR chains are found to recur in immune responses. Here, we analyzed the thymic generation of TCR sequences previously associated with recognition of self- and nonself-antigens, represented by sequences associated with autoimmune diabetes and HIV, respectively. Unexpectedly, in the CD4+ compartment TCRα chains associated with the recognition of self-antigens were generated in significantly higher numbers than TCRα chains associated with the recognition of nonself-antigens. The analysis of the circulating repertoire further showed that these chains are not lost in negative selection nor predominantly converted to the regulatory T-cell lineage. The high abundance of self-reactive TCRα chains in multiple individuals suggests that the human thymus has a predilection to generate self-reactive TCRα chains independently of the HLA-type and that the individual risk of autoimmunity may be modulated by the TCRß repertoire associated with these chains.

Common gamma chain cytokines promote regulatory T cell development and survival at the CD4+ CD8+ stage in the human thymus.

Thymic commitment of human FOXP3+ regulatory T cells begins at the double positive (DP) CD4+ CD8+ stage. In the current study we show that interleukin-2 promotes the development of FOXP3+ thymocytes and enhances their survival at the DP phase. IL-2 increases the frequency of FOXP3+ cells and promotes the Treg phenotype after TCR-mediated positive selection at the most mature DP stage. However, it has no effect on FOXP3+ cells at the earlier maturation steps before positive selection. DP FOXP3+ are highly susceptible to cell death but IL-2 promotes their survival. The anti-apoptotic protein BCL-2 (B Cell Lymphoma 2) is also upregulated by IL-2 at the most mature DP stage. In addition to IL-2, we identify IL-15 to have a significant role in the upregulating FOXP3 and survival of Tregs at the DP phase. IL-7 also increases the expression of BCL-2 in the DP FOXP3+ thymocytes. Our results indicate that common gamma chain cytokines IL-2, IL-7 and IL-15 promote the development of regulatory T cells at the most mature DP stage after TCR-mediated positive selection through suppressing cell death. This article is protected by copyright. All rights reserved.