A functional complement system is required for normal T helper cell differentiation.

Complement is a fundamental part of the innate immune system, and also modulates B cell responses. Its effects on T cells, however, are less well studied. Here we have studied antigen-specific T cell responses in C3-knockout (C3-KO) C57BL/6 mice. The animals were immunized with ovalbumin (OVA) in complete Freund's adjuvant, which favors T helper 1 (Th1)-type responses. Splenic lymphocytes from C3-KO mice proliferated less in response to OVA stimulation than splenocytes from control wild type (WT) mice. The response in the C3-KO mice was also qualitatively different. The expression of Th1 lineage determining transcription factor T-bet was decreased in OVA-stimulated splenocytes, and the induction of Th1-associated IgG subclasses impaired. In WT mice T cell proliferation in response to OVA was positively correlated with antigen-specific IgG2a and IgG3 levels. In C3-KO mice the proliferative response correlated with antigen-specific IgE levels, consistent with Th2 deviation. The expression of Th1-inducing cytokines IL-12 and IFN-γ was also decreased in the collecting lymph nodes in the C3-KO mice after immunization. Our results show that the complement system and its component C3 participate in the regulation of T cell responses, and that complement function is required for normal T helper cell differentiation.

gammadelta T cells develop independently of Aire.

Mutations in the transcriptional regulator Aire disrupt thymic alphabeta T cell selection, causing in humans Autoimmune polyendocrinopathy-candidiasis-ectodermal dystrophy (APECED). However, it is not known whether Aire is needed for normal gammadelta T cell development. We show that Aire(-/-) mice have a normal frequency of gammadelta T cells, with TCR repertoire comparable to that of wild-type mice, and normal amount of TCR Cdelta mRNA in ileum and skin. gammadelta T cells did not express increased amounts of CD25 or display hyperproliferation, and were not involved in pathological salivary gland infiltrates. Lastly, the frequency of circulating gammadelta T cells was similar in APECED patients and healthy controls. These data indicate that gammadelta T cells develop independently of Aire and are unlikely to have a significant pathogenetic or protective role in APECED. The antigens responsible for gammadelta and alphabeta T cell selection are thus probably largely different.

The FOXP3+ subset of human CD4+CD8+ thymocytes is immature and subject to intrathymic selection.

FOXP3, believed to be the regulatory T (Treg)-cell determining factor, is already expressed at the CD4+CD8+ thymocyte stage, but there is disagreement whether these cells are the precursors of mature CD4+CD8(-) Treg cells. Here, we provide a quantitative analysis of FOXP3 expression in the human thymus. We show that a subset of CD4+CD8+ cells already expressed as much FOXP3 as the FOXP3+ CD4+CD8(-) cells, and like mature Treg cells were CD127 low. In contrast to earlier data, CD8+CD4(-) thymocytes expressed significantly lower levels of FOXP3 than either the CD4+CD8+ or CD4+CD8(-) subsets. The CD4+CD8+ double-positive cells also expressed recombination-activating gene-2, suggesting that they were still immature. Although the FOXP3+ double-positive cells are thus putatively the precursors of the mature CD4+CD8(-)FOXP3+ subset, their frequency did not predict the frequency of more mature Treg cells, and analysis of T-cell antigen receptor repertoire showed clear differences between the two subsets. Although these data do not rule out an independent CD4+CD8+ Treg cell subset, they are consistent with a model of human Treg cell development in which the upregulation of FOXP3 is an early event, but the first FOXP3+ population is still immature and subject to further selection. The upregulation of FOXP3 may thus not be the final determining factor in the commitment of human thymocytes to the Treg cell lineage.

Thymic production of human FOXP3(+) regulatory T cells is stable but does not correlate with peripheral FOXP3 expression.

In humans functionally mature FOXP3(+) regulatory T (Treg) cells can be found already in the fetus, but the kinetics of their maturation is still unknown. Here, we show that from birth to until 10 years of age the thymic production of FOXP3(+) Treg cells is very stable and correlates with T-lymphopoiesis in general. The level of FOXP3 expression in the blood was also very stable, even when children and adults were compared, but there was no correlation between thymic and peripheral FOXP3 levels. Analysis of the cell cycle-associated marker Ki67 showed that a substantial fraction of peripheral FOXP3(+) cells is dividing. This characteristic was obtained in the periphery, since it was not observed in thymic CD4(+) FOXP3(+) cells. These data suggest that the thymic output of human Treg cells is intrinsically stable, while in the periphery the increased rate of proliferation severs the connection between production and homeostatic maintenance of the FOXP3(+) Treg cell population.

Cutting edge: human CD4-CD8- thymocytes express FOXP3 in the absence of a TCR.

The best candidate for regulatory T (Treg) cell lineage-determining factor is currently the Forkhead box transcription factor FOXP3. FOXP3 up-regulation has been linked to TCR-mediated signals, and in mice the abrogation of TCR expression or signals also prevents FoxP3 expression. In contrast, the TCR dependence of human FOXP3 is assumed but not established. In this study we show on a single cell level that 1.4% (range 0.1-3.8%) of CD4(-)CD8(-) thymocytes in healthy humans express FOXP3, two thirds of them without any detectable alphabeta TCR. These TCR(-)FOXP3(+) cells were mostly CD25(-) and did not express gammadelta TCR or B cell, NK cell, or monocyte-associated markers. Like mature Treg cells, they were mostly CD2(+)CD127(low) and expressed cytoplasmic CTLA-4. Our results suggest that in immature human thymocytes the expression of FOXP3 precedes surface TCR, in which case TCR-mediated signals cannot be responsible for the thymic up-regulation of FOXP3.

A defect of regulatory T cells in patients with autoimmune polyendocrinopathy-candidiasis-ectodermal dystrophy.

Autoimmune polyendocrinopathy-candidiasis-ectodermal dystrophy (APECED), a monogenic recessive disease characterized by autoimmunity against multiple tissues, offers a unique possibility to study the breakdown of self-tolerance in humans. It is caused by mutations in the autoimmune regulator gene (AIRE), which encodes a transcriptional regulator. Work using Aire(-/-) mice suggests that Aire induces ectopic expression of peripheral Ags and promotes their presentation in the thymus. We have explored reasons for the difference between the comparatively mild phenotype of Aire-deficient mice and human APECED patients. We provide evidence that, unlike in the Aire(-/-) mice, in the patients a key mediator of active tolerance, the CD4(+)CD25(+) regulatory T (Treg) cell subset is impaired. This was shown by significantly decreased expression of FOXP3 mRNA and protein, decreased function, and alterations in TCR repertoire. Also, in the normal human thymus a concentric accumulation of AIRE(+) cells was seen around thymic Hassall's corpuscles, suggesting that in the patients these cells may be involved in the observed Treg cell failure. In Aire(-/-) mice the expression of FoxP3 was normal and even increased in target tissues in parallel with the lymphocyte infiltration process. Our results suggest that a Treg cell defect is involved in the pathogenesis of APECED and emphasize the importance of active tolerance mechanisms in preventing human autoimmunity.

Most human thymic and peripheral-blood CD4+ CD25+ regulatory T cells express 2 T-cell receptors.

Lack of allelic exclusion in the T-cell receptor (TCR) alpha locus gives rise to 2 different TCRs in 10% to 30% of all mature T cells, but the significance of such dual specificity remains controversial. Here we show that human CD4+ CD25+ regulatory T (Treg) cells express 2 distinct Valpha chains and thus 2 TCRs at least 3 times as often as other T cells. Extrapolating from flow cytometric analysis using Valpha2-, Valpha12-, and Valpha24-specific monoclonal antibodies (mAbs), we estimated that between 50% and 99% of the CD25+ Treg cells were dual specific, as compared with about 20% of their CD25- counterparts. Moreover, both TCRs were equally capable of transmitting signals upon ligation. Cells with 2 TCRs also expressed more FOXP3, the Treg-cell lineage specification factor, than cells with a single TCR. Our findings suggest that expression of 2 TCRs favors differentiation to the Treg-cell lineage in humans and raise the question of the potential functional consequences of dual specificity.