A blood-borne antigen induces rapid T–B cell contact: a potential mechanism for tolerance induction

Understanding the difference between the development of a productive T-cell response and tolerance is central to discerning how the immune system functions. Intravenous injection of soluble protein is thought to mimic the presentation of self-serum and orally introduced antigens. It is generally toleragenic. The current view is that this outcome reflects the failure of ‘immunogenic’ dendritic cells to relocate to the T-cell zone of the secondary lymphoid tissues. Here, using a peptide/I-E(k) tetramer and antibodies to stain splenic sections, we showed that antigen-specific T cells were activated in the spleen within hours of injection or feeding of protein. The activated T cells were found to be located at the T–B junction, the bridging zone and the B-cell area, interacting directly with B cells. In addition, B cells gain the ability to present antigen. Our results suggest a way for T cells to be stimulated by blood-borne antigen presented by naïve B cells, a potential mechanism of tolerance induction

T-cell activation occurs simultaneously in local and peripheral lymphoid tissue following oral administration of a range of doses of immunogenic or tolerogenic antigen although tolerized T cells display a defect in cell division

How the mucosal immune system promotes active immunity against harmful organisms but tolerance to commensal bacteria or dietary antigens is poorly understood. Thus, the antigen-presenting cell (APC), site of antigen presentation, and effector mechanisms responsible for oral priming and tolerance remain unclear. Characterizing differences between oral priming and tolerance may improve the exploitation of oral tolerance for therapeutic applications and aid the design of oral vaccines. To address these questions we compared the mucosal and systemic activation and localization of antigen-specific T cells during the induction of oral priming and tolerance. Activation marker expression and cell division by tg T cells was determined in conjunction with their anatomical location. These studies show that after feeding, T cells are activated in both peripheral and local lymphoid tissues within 6 hr, irrespective of the presence of adjuvant. Subsequently, T-cell accumulation can be detected simultaneously in peripheral and mesenteric lymph nodes and Peyer's patches within 24 hr of feeding, but only after 3 days post feeding in the lamina propria. Primed and tolerized T cells adopted similar phenotypes as assessed by activation marker expression. However, within the mesenteric lymph nodes (MLN) tolerized T cells underwent significantly fewer divisions than primed T cells. Thus, T-cell activation and expansion occurs throughout the animal after feeding a range of doses of antigen, irrespective of whether priming or tolerance is the eventual outcome. However, the presence of an adjuvant enhances clonal expansion in the MLN while tolerized T cells display defective cell division

Administration of exogenous interleukin-18 and interleukin-12 prevents the induction of oral tolerance

Interleukin-18 (IL-18), a pro-inflammatory member of the IL-1 family, has been associated with autoimmunity and allergic disease. This type of pathology is thought to be the result of a defect in immunological tolerance and is often observed in inflammatory disorders of the gut such as coeliac disease, Crohn's disease and ulcerative colitis. IL-18 has been implicated in a number of mucosal immune disorders, where it synergizes with IL-12 to induce the production of interferon-γ (IFN-γ). We have therefore investigated the effects of IL-18 and IL-12 administration on the induction of oral tolerance to ovalbumin. The suppression of specific Ig G2a production, delayed-type hypersensitivity responses and IFN-γ production by antigen-specific T cells were all abrogated by the presence of exogenous IL-12 and IL-18, suggesting that oral tolerance was broken. The expression of the co-stimulatory molecule CD80 on dendritic cells was also shown to be increased by this combination of cytokines. As dendritic cells are thought to be of major importance in the induction of tolerance, this suggests a mechanism by which tolerance to mucosal antigens may be broken in vivo

CD25+CD4+ regulatory T cells develop in mice not only during spontaneous acceptance of liver allografts but also after acute allograft rejection.

BACKGROUND: Liver grafts transplanted across a major histocompatibility barrier are accepted spontaneously and induce donor specific tolerance in some species. Here, we investigated whether liver allograft acceptance is characterized by, and depends upon, the presence of donor reactive CD25CD4 regulatory T cells. METHODS: CD25 and CD25CD4 T cells, isolated from CBA. Ca (H2) recipients of C57BL/10 (B10; H2) liver and heart allografts 10 days after transplantation, were transferred into CBA. Rag1 mice to investigate their influence on skin allograft rejection mediated by CD45RBCD4 effector T Cells. RESULTS: Fully allogeneic B10 liver allografts were spontaneously accepted by naive CBA.Ca recipient mice, whereas B10 cardiac allografts were acutely rejected (mean survival time=7 days). Strikingly, however, CD25CD4 T cells isolated from both liver and cardiac allograft recipients were able to prevent skin allograft rejection in this adoptive transfer model. Interestingly, CD25CD4 T cells isolated from liver graft recipients also showed suppressive potency upon adoptive transfer. Furthermore, depletion of CD25CD4 T cells in primary liver allograft recipients did not prevent the acceptance of a secondary donor-specific skin graft. CONCLUSIONS: Our data provide evidence that the presence of CD25CD4 regulatory T cells is not a unique feature of allograft acceptance and is more likely the result of sustained exposure to donor alloantigens in vivo

Impedance-based analysis of Natural Killer cell stimulation

The use of impedance-based label free cell analysis is increasingly popular and has many different applications. Here, we report that a real-time cell analyzer (RTCA) can be used to study the stimulation of Natural Killer (NK) cells. Engagement of NK cells via plate-bound antibodies directed against different activating surface receptors could be measured in real time using the label-free detection of impedance. The change in impedance was dependent on early signal transduction events in the NK cells as it was blocked by inhibitors of Src-family kinases and by inhibiting actin polymerization. While CD16 was the only receptor that could induce a strong change in impedance in primary NK cells, several activating receptors induced changes in impedance in expanded NK cells. Using PBMCs we could detect T cell receptor-mediated T cell activation and CD16-mediated NK cell activation in the same sample. Performing a dose-response analysis for the Src-family kinases inhibitor PP1 we show that T cells are more sensitive to inhibition compared to NK cells. Our data demonstrate that the RTCA can be used to detect physiological activation events in NK cells in a label-free and real-time fashion