Human thymus medullary epithelial cells promote regulatory T-cell generation by stimulating interleukin-2 production via ICOS ligand.

Natural thymic T regulatory (tTreg) cells maintain tolerance to self-antigen. These cells are generated in the thymus, but how this generation occurs is still controversial. Furthermore, the contribution of thymus epithelial cells to this process is still unclear, especially in humans. Using an exceptional panel of human thymic samples, we demonstrated that medullary thymus epithelial cells (mTECs) promote the generation of tTreg cells and favor their function. These effects were mediated through soluble factors and were mTEC specific since other cell types had no such effect. By evaluating the effects of mTECs on the absolute number of Treg cells and their state of proliferation or cell death, we conclude that mTECs promote the proliferation of newly generated CD25+ cells from CD4+CD25- cells and protect Treg cells from cell death. This observation implicates Bcl-2 and mitochondrial membrane potential changes, indicating that the intrinsic cell death pathway is involved in Treg protection by mTECs. Interestingly, when the mTECs were cultured directly with purified Treg cells, they were able to promote their phenotype but not their expansion, suggesting that CD4+CD25- cells have a role in the expansion process. To explore the mechanisms involved, several neutralizing antibodies were tested. The effects of mTECs on Treg cells were essentially due to interleukin (IL)-2 overproduction by thymus CD4+ T cells. We then searched for a soluble factor produced by mTECs able to increase IL-2 production by CD4+ cells and could identify the inducible T-cell costimulator ligand (ICOSL). Our data strongly suggest a « ménage à trois ¼: mTEC cells (via ICOSL) induce overproduction of IL-2 by CD25- T cells leading to the expansion of tTreg cells. Altogether, these results demonstrate for the first time a role of mTECs in promoting Treg cell expansion in the human thymus and implicate IL-2 and ICOSL in this process.

In vivo and in vitro apoptosis of human thymocytes are associated with nitrotyrosine formation.

Most thymocytes are deleted by thymic selection. The mechanisms of cell death are far from being clear. Peroxynitrite is a powerful oxidant produced in vivo by the reaction of superoxide (O2*-) with nitric oxide (NO*) and is able to mediate apoptosis. The aim of this study was to analyze whether NO and peroxynitrite could play a role in human thymocyte apoptosis. The results indicate that 3-(4-morpholinyl)-sydnonimine (SIN-1, an O2*- and NO* donor) and chemically synthesized peroxynitrite, but not S-nitroso-N-acetyl-D,L-penicillamine (SNAP, an NO* donor), have a strong apoptotic effect on human thymocytes (annexin V staining and TUNEL reaction). This effect was inhibited by exogenous superoxide dismutase (SOD), which interacts with O2*- and inhibits the formation of peroxynitrite. Because peroxynitrite formation requires NO*, thymic stromal cells were investigated to determine if they produced NO*. Inducible NOS was synthesized in cultured thymic epithelial cells in certain conditions of cytokine stimulation, as shown by messenger RNA levels, protein analysis, and nitrite production in the supernatants. SIN-1-treated thymocytes had high levels of tyrosine nitration, abolished by the addition of exogenous SOD. Tyrosine nitration was also detected in thymus extracts and sections, suggesting the presence of peroxynitrite in situ. In thymus sections, clusters of nitrotyrosine-positive cells were found in the cortex and corticomedullary areas colocalized with cells positive in the TUNEL reaction. These data indicate an association between human thymocyte apoptosis and nitrotyrosine formation. Thus, the results support the notion of a physiologic role for peroxynitrite in human thymocyte apoptosis. (Blood. 2001;97:3521-3530)

Altered intrathymic T-cell repertoire in human myasthenia gravis.

In myasthenia gravis, the thymus is thought to be the primary site of autosensitization. We investigated the V beta T-cell repertoire at different intrathymic differentiation stages in 17 patients with myasthenia gravis and 8 age-matched control subjects by tricolor immunofluorescence, using a panel of six anti-V beta antibodies. We observed an increased expression of V beta 5.1 and V beta 8 subfamilies in the patients compared to the control subjects. These increases were observed not only in mature cells but also in the latest thymic precursors of mature cells (double-positive CD3 high), while there was no change in intermediate precursors (double-positive CD3 low), pointing to biased selection during intrathymic differentiation. In addition, there was a strong correlation between the percentage of V beta 5.1+ and V beta 8+ cells among both the CD4 and CD8 subsets in the patients, but not in control subjects, suggesting that thymic events relevant to the disease lead to these selected populations. Finally, location studies of V beta 5.1+ cells on thymic sections indicated that these cells were overrepresented both in the core of germinal centers and in perifollicular areas of hyperplastic thymuses, suggesting a role in the autoimmune response. Taken together, these findings are compatible with the hypothesis of a biased intrathymic selection in myasthenia gravis.

Thymocyte Fas expression is dysregulated in myasthenia gravis patients with anti-acetylcholine receptor antibody.

Myasthenia gravis (MG) is a human autoimmune disease mediated by anti-acetylcholine receptor (AChR) antibodies. The thymus is probably the site where the autoimmune response is triggered and maintained. Recent reports have linked various autoimmune disease with defective Fas expression. We thus analyzed Fas expression in thymocytes and peripheral blood lymphocytes (PBL) from MG patients. The proportion of a thymocyte subpopulation with strong Fas expression (Fas(hi)) was markedly enhanced in MG patients with anti-AChR antibodies (P < .0003, compared with controls). In this group of patients, the proportion of CD4+ Fas(hi) and CD4+ CD8+ Fas(hi) thymocytes were significantly increased (P < .002 for both subsets). Fas(hi) thymocytes were enriched in activated cells and showed intermediate CD3 expression. They were preferentially Vbeta5.1-expressing cells, previously shown to be enriched in potentially autoreactive cells. The proliferative response of thymocytes from MG patients to peptides from the AChR was abolished after depletion of Fas(hi) cells. Fas(hi) thymocytes were sensitive to an agonistic anti-Fas antibody. In peripheral blood, Fas(hi) lymphocytes proportion was not significantly modified in MG patients whatever their anti-AChR antibody titer, compared with controls. Altogether, these results indicate that Fas(hi) thymocytes, which accumulate in MG patients with anti-AChR antibodies, could be involved in the autoimmune response that targets the AChR.

In vivo preferential usage of TCR V beta 8 in Torpedo acetylcholine receptor immune response in the murine experimental model of myasthenia gravis.

The aim of our study was to determine the T cell receptor (TCR) V beta gene usage involved in the T cell response to Torpedo AChR in C57BL/6 mice. The specific proliferation towards AChR was found to be blocked by anti-V beta 8.1,2,3 and to a lesser extent by anti-V beta 5 mAbs, but not by the other antibodies used (anti-V beta 2, V beta 6, V beta 9). In addition, a significant expansion of CD4+ V beta 8+ cells was observed when lymph node cells from these primed mice were stimulated in vitro with purified AChR. Involvement of V beta 8 subfamilies was also explored in vivo. After 7 days of treatment, there was a striking inhibition of the proliferative response of cells from anti-V beta 8.1,2,3-treated mice and a moderate inhibition when using anti-V beta 8.1,2 and anti-V beta 8.2 antibodies. Thus our in vitro and in vivo analysis indicate that in C57Bl/6 mice, T cell response to AChR is restricted to few V beta TCR, mostly belonging to the V beta 8 sub-families.

Regulation of acetylcholine receptor alpha subunit variants in human myasthenia gravis. Quantification of steady-state levels of messenger RNA in muscle biopsy using the polymerase chain reaction.

Myasthenia gravis (MG) is an autoimmune disease mediated by auto-antibodies that attack the nicotinic acetylcholine receptor (AChR). To elucidate the molecular mechanisms underlying the decrease in AChR levels at the neuromuscular junction, we investigated the regulation of AChR expression by analyzing mRNA of the two AChR alpha subunit isoforms (P3A+ and P3A-) in muscle samples from myasthenic patients relative to controls. We applied a quantitative method based on reverse transcription of total RNA followed by polymerase chain reaction (PCR), using an internal standard we constructed by site-directed mutagenesis. An increased expression of mRNA coding for the alpha subunit of the AChR isoforms was observed in severely affected patients (P < 0.003 versus controls) but not in moderately affected patients, independently of the anti-AChR antibody titer. Study of mRNA precursor levels indicates a higher expression in severely affected patients compared to controls, suggesting an enhanced rate of transcription of the message coding for the alpha subunit isoforms in these patients. We have also reported that mRNA encoding both isoforms are expressed at an approximate 1:1 ratio in controls and in patients. We have thus identified a new biological parameter correlated with disease severity, and provide evidence of a compensatory mechanism to balance the loss of AChR in human myasthenia gravis, which is probably triggered only above a certain degree of AChR loss.