Refine
Document Type
- Article (1)
- Doctoral Thesis (1)
Language
- English (2) (remove)
Has Fulltext
- yes (2) (remove)
Is part of the Bibliography
- no (2) (remove)
Keywords
- T-cell development (2) (remove)
Institute
- Biowissenschaften (1)
- Medizin (1)
The thymus hosts the development of a specific type of adaptive immune cells called T cells. T cells orchestrate the adaptive immune response through recognition of antigen by the highly variable T-cell receptor (TCR). T-cell development is a tightly coordinated process comprising lineage commitment, somatic recombination of Tcr gene loci and selection for functional, but non-self-reactive TCRs, all interspersed with massive proliferation and cell death. Thus, the thymus produces a pool of T cells throughout life capable of responding to virtually any exogenous attack while preserving the body through self-tolerance. The thymus has been of considerable interest to both immunologists and theoretical biologists due to its multi-scale quantitative properties, bridging molecular binding, population dynamics and polyclonal repertoire specificity. Here, we review experimental strategies aimed at revealing quantitative and dynamic properties of T-cell development and how they have been implemented in mathematical modeling strategies that were reported to help understand the flexible dynamics of the highly dividing and dying thymic cell populations. Furthermore, we summarize the current challenges to estimating in vivo cellular dynamics and to reaching a next- generation multi-scale picture of T-cell development.
The balance between peripheral T-cell reactivity and self-tolerance is achieved during T-cell development in the thymus. During thymic development T-cell sensitivity to self-antigens drives their selection and is dynamically regulated via multiple mechanisms. The microRNA miR-181 has been implicated as a post-transcriptional modulator of T-cell sensitivity due to its suppression of several negative regulators of T-cell receptor (TCR) signalling. By tuning developing thymocytes to be exquisitely sensitive to signals transduced through their TCR, miR-181 has previously been shown to be essential for the agonist selection of invariant natural killer T (iNKT) cells. In this thesis, we extend the knowledge on the developmental control elicited by miR-181 in the thymus to cover mucosal-associated invariant T (MAIT), regulatory T (Treg) and conventional T cells. Using a germline knock-out of mature miR-181a/b-1, we could show that all agonist-selected T cell populations are critically dependant on miR-181a/b-1, noting an absence of MAIT and a reduction of thymic-derived Tregs in miR-181a/b-1-deficient mice. Furthermore, we provided evidence that miR-181 is also required for the negative selection of conventional T cells, with miR-181a/b-1-deficient mice presenting with a near absence of apoptotic markers. Therefore, by heightening the TCR sensitivity to self-antigens, miR-181a/b-1 aids in the detection and subsequent elimination of autoreactive thymocytes. In addition, we characterised the murine primary miR-181a/b-1 transcript, which surprisingly has a transcription start site (TSS) more than 70kB upstream of the mature miRNA sequences. This shall hopefully lead to future research aimed at deciphering the upstream regulatory networks that promote dynamic miR-181a/b-1 expression in developing thymocytes. In summary, we present here a single miRNA subset with broad implications in T-cell development. In disagreement with central dogma that individual miRNAs generally provide weak to moderate modulation over cellular pathways, we showcase the miR-181 family subset, miR-181a/b-1, as an efficient regulator of TCR signalling pathways. Due to the sensitive nature of TCR signalling during thymocyte selection, miR-181a/b-1 elicits gross effects, which are essential for agonist selection, central tolerance and generating a functional self-tolerant peripheral T cell repertoire. We therefore conclude that miR-181a/b-1 is fundamental in T-cell development as a whole.