A threshold level of NFATc1 activity facilitates thymocyte differentiation and opposes notch-driven leukaemia development.

International audienceNFATc1 plays a critical role in double-negative thymocyte survival and differentiation. However, the signals that regulate Nfatc1 expression are incompletely characterized. Here we show a developmental stage-specific differential expression pattern of Nfatc1 driven by the distal (P1) or proximal (P2) promoters in thymocytes. Whereas, preTCR-negative thymocytes exhibit only P2 promoter-derived Nfatc1beta expression, preTCR-positive thymocytes express both Nfatc1beta and P1 promoter-derived Nfatc1alpha transcripts. Inducing NFATc1alpha activity from P1 promoter in preTCR-negative thymocytes, in addition to the NFATc1beta from P2 promoter impairs thymocyte development resulting in severe T-cell lymphopenia. In addition, we show that NFATc1 activity suppresses the B-lineage potential of immature thymocytes, and consolidates their differentiation to T cells. Further, in the pTCR-positive DN3 cells, a threshold level of NFATc1 activity is vital in facilitating T-cell differentiation and to prevent Notch3-induced T-acute lymphoblastic leukaemia. Altogether, our results show NFATc1 activity is crucial in determining the T-cell fate of thymocytes

The impact of negative selection on thymocyte migration in the medulla

Developing thymocytes are screened for self-reactivity before they exit the thymus, but how thymocytes scan the medulla for self antigens is unclear. Using two-photon microscopy, we observed that medullary thymocytes migrated rapidly and made frequent, transient contacts with dendritic cells. In the presence of a negative selecting ligand, thymocytes slowed, became confined to areas of approximately 30 mum in diameter and had increased contact with dendritic cells surrounding confinement zones. One third of polyclonal medullary thymocytes also showed confined, slower migration and may correspond to autoreactive thymocytes. Our data suggest that many autoreactive thymocytes do not undergo immediate arrest and death after encountering a negative selecting ligand but instead adopt an altered migration program while remaining in the medullary microenvironment

Myasthenia gravis thymus: complement vulnerability of epithelial and myoid cells, complement attack on them, and correlations with autoantibody status.

Am J Pathol. 2007 Sep;171(3):893-905. Epub 2007 Aug 3. Myasthenia gravis thymus: complement vulnerability of epithelial and myoid cells, complement attack on them, and correlations with autoantibody status. Leite MI, Jones M, Ströbel P, Marx A, Gold R, Niks E, Verschuuren JJ, Berrih-Aknin S, Scaravilli F, Canelhas A, Morgan BP, Vincent A, Willcox N. Department of Clinical Neurology, University of Oxford, Oxford, United Kingdom. Abstract In early-onset myasthenia gravis, the thymus contains lymph node-type infiltrates with frequent acetylcholine receptor (AChR)-specific germinal centers. Our recent evidence/two-step hypothesis implicates hyperplastic medullary thymic epithelial cells (expressing isolated AChR subunits) in provoking infiltration and thymic myoid cells (with intact AChR) in germinal center formation. To test this, we screened for complement attack in a wide range of typical generalized myasthenia patients. Regardless of the exact serology, thymi with sizeable infiltrates unexpectedly showed patchy up-regulation of both C5a receptor and terminal complement regulator CD59 on hyperplastic epithelial cells. These latter also showed deposits of activated C3b complement component, which appeared even heavier on infiltrating B cells, macrophages, and especially follicular dendritic cells. Myoid cells appeared particularly vulnerable to complement; few expressed the early complement regulators CD55, CD46, or CR1, and none were detectably CD59(+). Indeed, when exposed to infiltrates, and especially to germinal centers, myoid cells frequently labeled for C1q, C3b (25 to 48%), or even the terminal C9, with some showing obvious damage. This early/persistent complement attack on both epithelial and myoid cells strongly supports our hypothesis, especially implicating exposed myoid cells in germinal center formation/autoantibody diversification. Remarkably, the similar changes place many apparent AChR-seronegative patients in the same spectrum as the AChR-seropositive patients. PMID: 17675582 [PubMed - indexed for MEDLINE]PMCID: PMC1959483Free PMC Article Images from this publication.See all images (6) Free text Figure 1 Distribution of complement receptors C3aR, C5aR, and CR1 (receptor for C3b and C4b) (all in red) in epithelial areas and/or infiltrates in thymi from non-MG controls (A and B), AChRAb+ (C–E), or SNMG (F) MG patients. A and B: In control thymi, occasional mTECs are weakly C5aR+, as in some areas in MG thymi, bu... Myasthenia Gravis Thymus Am J Pathol. 2007 September;171(3):893-905.Figure 2 Distribution of complement regulators CD46, CD55, and CD59 (all in red) in epithelial areas and infiltrates in control (A and D) and MG thymi (B, C, and E–I). Cytokeratin (CK, green). A: In controls, CD46 (A) and CD55 (not shown) expression is minimal; in MG, both are much stronger in the MEBs than in the nMe... Myasthenia Gravis Thymus Am J Pathol. 2007 September;171(3):893-905.Figure 3 Labeling for C1q and C3b complement fragments (both in red) in epithelial areas and infiltrates in MG and control thymi. Cytokeratin (CK, green). A and B: In MG, there is extensive patchy labeling for C1q in mTECs and other cells in MEBs and in infiltrates and GC in AChRAb+ (A) or SNMG (B) samples. C: In co... Myasthenia Gravis Thymus Am J Pathol. 2007 September;171(3):893-905.Figure 4 Rarity of complement regulators on myoid cells. In both control (not shown) and MG thymi (A), myoid cells (MC) are uniformly CD59− (red), even when exposed to infiltrates, but ∼5% of the latter express detectable CD55 (red) (B, inset). (Donors both female: A, 20 years of age; B, 16 years of age). Desmin (De, ... Myasthenia Gravis Thymus Am J Pathol. 2007 September;171(3):893-905.Figure 5 Labeling for C1q, C3b, or C9 (all in red) on exposed myoid cells (MC) in MG thymi. Desmin (De, green). A and B: Some exposed myoid cells label for C1q in AChRAb+ (A) or SNMG (B) MG samples, in which many of them label for C3b (C and D; enlarged in insets) and some for C9 in AChRAb+ (E) or SNMG (F) samples. Note aggr... Myasthenia Gravis Thymus Am J Pathol. 2007 September;171(3):893-905.Figure 6 Percentages of myoid cells exposed to the infiltrates in non-MG controls and MG patient subgroups. Their rarity in the control and MuSKAb+ samples reflects the paucity of infiltrates. There were significantly fewer myoid cells/mm2 in the AChRAb+ group than in the controls (see mini-table below; *P < 0.0... Myasthenia Gravis Thymus Am J Pathol. 2007 September;171(3):893-905

Epitope-Specific Tolerance Modes Differentially Specify Susceptibility to Proteolipid Protein-Induced Experimental Autoimmune Encephalomyelitis

Immunization with myelin components can elicit experimental autoimmune encephalomyelitis (EAE). EAE susceptibility varies between mouse strains, depending on the antigen employed. BL/6 mice are largely resistant to EAE induction with proteolipid protein (PLP), probably a reflection of antigen-specific tolerance. However, the extent and mechanism(s) of tolerance to PLP remain unclear. Here, we identified three PLP epitopes in PLP-deficient BL/6 mice. PLP-sufficient mice did not respond against two of these, whereas tolerance was "leaky" for an epitope with weak predicted MHCII binding, and only this epitope was encephalitogenic. In TCR transgenic mice, the "EAE-susceptibilityassociated" epitope was "ignored" by specific CD4 T cells, whereas the "resistanceassociated" epitope induced clonal deletion and Treg induction in the thymus. Central tolerance was autoimmune regulator dependent and required expression and presentation of PLP by thymic epithelial cells (TECs). TEC-specific ablation of PLP revealed that peripheral tolerance, mediated by dendritic cells through recessive tolerancemechanisms (deletion and anergy), could largely compensate for a lack of central tolerance. However, adoptive EAE was exacerbated in mice lacking PLP in TECs, pointing toward a non-redundant role of the thymus in dominant tolerance to PLP. Our findings reveal multiple layers of tolerance to a central nervous system autoantigen that vary among epitopes and thereby specify disease susceptibility. Understanding how different modalities of tolerance apply to distinct T cell epitopes of a target in autoimmunity has implications for antigen-specific strategies to therapeutically interfere with unwanted immune reactions against self

Insulin gene VNTR genotype associates with frequency and phenotype of the autoimmune response to proinsulin

Immune responses to autoantigens are in part controlled by deletion of autoreactive cells through genetically regulated selection mechanisms. We have directly analyzed peripheral CD4+ proinsulin (PI) 76–90 (SLQPLALEGSLQKRG)-specific T cells using soluble fluorescent major histocompatibility complex class II tetramers. Subjects with type I diabetes and healthy controls with high levels of peripheral proinsulin-specific T cells were characterized by the presence of a disease-susceptible polymorphism in the insulin variable number of tandem repeats (INS-VNTR) gene. Conversely, subjects with a ‘protective' polymorphism in the INS-VNTR gene had nearly undetectable levels of proinsulin tetramer-positive T cells. These results strongly imply a direct relationship between genetic control of autoantigen expression and peripheral autoreactivity, in which proinsulin genotype restricts the quantity and quality of the potential T-cell response. Using a modified tetramer to isolate low-avidity proinsulin-specific T cells from subjects with the susceptible genotype, transcript arrays identified several induced pro-apoptotic genes in the control, but not diabetic subjects, likely representing a second peripheral mechanism for maintenance of tolerance to self antigens