Tolerance induction by clonal deletion of CD4+8+ thymocytes in vitro does not require dedicated antigen-presenting cells

Peptide-induced T cell receptor down-regulation on naive T cells predicts agonist/partial agonist properties and strictly correlates with T cell activation

Recent experiments defining T cell agonists, partial agonists and antagonists have suggested that the T cell can discriminate between subtle differences in interactions leading to T cell activation. To further understand the complexities of T cell activation, we have analyzed the requirements for the induction of a variety of effector functions using naive T cells and a variety of altered peptide ligands. Using a strong agonist peptide, massive T cell receptor (TCR) down-regulation correlated with a wide range of effector functions that were all induced above the same threshold peptide concentration. Interestingly, the kinetics of TCR down-regulation correlated with the concentration of the peptide, whereas the maximal degree of TCR down-regulation correlated with the induction of all monitored effector functions. A selected group of altered peptide ligands was also examined that were able to render target cells susceptible for lysis by effector cytotoxic T lymphocytes. The extent of TCR down-regulation induced by these peptides corresponded to the induction of a subset of effector functions. These studies have shown that the extent of TCR down-regulation defines the strength of TCR-mediated "signal 1" which correlates with the spectrum of effector functions activated within the T cell. Thus, activation of different T cell functions requires the triggering of distinct numbers of TCR. The different parameters that influence TCR down-regulation define important distinctions between our results and previously reported findings with T cell clones and may outline decisive parameters for the consequences of T cell activation in vivo.

Functional management of an antiviral cytotoxic T-cell response

Lymphocytic choriomeningitis virus (LCMV) is known to induce strong, polyclonal cytotoxic T-lymphocyte (CTL) responses. Using a set of variant peptides derived from the major CTL epitope of LCMV, we analyzed the functional fine specificity of the LCMV-specific CTL response. During the primary response, almost all the tested peptides were recognized. In contrast, the secondary response was purged of all minor cross-reactivities and very few peptides were significantly recognized. This study is the first demonstration of the functional maturation of a T-cell response and has important clinical and biological implications.

Thymic epithelial cell culture

Culture of epithelial cells from the thymus of children and laboratory animals has been used for more than two decades to evaluate both the nature of these cells and their importance in the selection and maturation of functional T cells. Especially by the use of serum-free cultures and by establishment of cell lines from cultured thymic epithelial cells (TEC), it has been possible to obtain basic information on morphology of subpopulations of TEC, including surface determinants of importance for interactions with T-cell precursors, and on the repertoire of cytokines secreted by different types of TEC. The available information, obtained by co-culture of pre-T cells and TEC, on the effects of TEC on the fate of pre-T cells suggests that cultured TEC/TEC lines are able both to secrete needed cytokines for T-cell development, and to deliver signals needed for T-cell selection. In vivo results showing cross-talk between TEC and T cells indicate that more careful evaluation of interactions between well-defined subtypes of cultured TEC and co-cultured subpopulations of pre-T cells (as well as macrophages/dendritic cells) will be of importance in evaluation of the function of the thymus.

Thymic nurse cells: their functional ultrastructure

Thymic nurse cells are defined in vitro as multicellular complexes of epithelial cells and thymocytes. Although these structures have been implicated in the intrathymic differentiation of thymocytes, little is known about the biology of this cell complex and about the occurrence of the cells in the thymus in situ. Therefore, to clarify the matter, in this review we have presented characteristics of epithelial cells capable of forming complexes with thymocytes, in light of the literature data and the experience of the authors. The structure of cells within the complexes allowed us to distinguish three types of thymic nurse cells. Three-dimensional reconstruction of the thymus and observations employing TEM and SEM demonstrated the presence of distinct types of complexes in various topographic regions of the thymus. Where possible, the functional relevance of the morphological data was analyzed.

Normal thymic selection, normal viability and decreased lymphoproliferation in T cell receptor-transgenic CTLA-4-deficient mice

CTLA-4 is a T cell surface receptor essential for the negative regulation of T cell activation. In the CTLA-4-deficient mouse, a dramatic accumulation of activated peripheral T cells effects extensive damage to host tissues, resulting in mortality within 5 weeks of age. To determine whether the accumulation of activated T cells in CTLA-4(-/-) mice is due to a defect in thymic selection, we examined negative selection in CTLA-4(-/-) mice using two transgenic T cell receptor (TCR) models of thymic selection. Neither the H-Y-specific TCR nor the lymphocytic choriomeningitis virus (LCMV)-specific TCR transgenic models revealed a defect in positive or negative selection in CTLA-4(-/-) mice in vivo or in vitro. In fact, the negatively selecting phenotype of male H-YTCR-transgenic mice greatly mitigated the accumulation of activated peripheral T cells. Further, peripheral CTLA-4(-/-) T cells expressing a single LMCV-specific transgenic TCR did not have an activated phenotype, indicating that CTLA-4(-/-) T cells require specific antigen for proliferation. These results demonstrate that specific antigen is required for the lymphoproliferation observed in CTLA-4(-/-) mice, and that CTLA-4 deficiency does not lead to a gross defect in negative selection.

The interferon regulatory transcription factor IRF-1 controls positive and negative selection of CD8+ thymocytes

Little is known about the molecular mechanisms and transcriptional regulation that govern T cell selection processes and the differentiation of CD4+ and CD8+ T cells. Mice lacking the interferon regulatory transcription factor-1 (IRF-1) have reduced numbers of mature CD8+ cells within the thymus and peripheral lymphatic organs. Here we show that positive and negative T cell selection of two MHC class I-restricted TCR alphabeta transgenes, H-Y and P14, are impaired in IRF-1-/- mice. The absence of IRF-1 resulted in decreased expression of LMP2, TAP1, and MHC class I on thymic stromal cells. Despite decreased MHC class I expression on IRF-1-/- thymic stromal cells, the defect in CD8+ T cells development did not reside in the thymic environment, and IRF-1-/- stromal cells can fully support development of CD8+ thymocytes in in vivo bone marrow chimeras and in vitro reaggregation cultures. Moreover, IRF-1-/- thymocytes displayed impaired TCR-mediated signal transduction, and the induction of negative selection in TCR Tg thymocytes from IRF-1-/- mice required a 1000-fold increase in selecting peptide. We also provide evidence that IRF-1 is mainly expressed in mature, but not immature, thymocytes and that expression of IRF-1 in immature thymocytes is induced after peptide-specific TCR activation. These results indicate that IRF-1 regulates gene expression in developing thymocytes required for lineage commitment and selection of CD8+ thymocytes.

Differential effects of 2,3,7,8-tetrachlorodibenzo-p-dioxin, bis(tri-n-butyltin) oxide and cyclosporine on thymus histophysiology

Recent advances in the histophysiology of the normal thymus have revealed its complex architecture, showing distinct microenvironments at the light and electron microscopic level. The epithelium comprising the major component of the thymic stroma is not only involved in the positive selection of thymocytes, but also in their negative selection. Dendritic cells, however, are more efficient than epithelial cells in mediating negative selection. Thymocytes are dependent on the epithelium for normal development. Conversely, epithelial cells need the presence of thymocytes to maintain their integrity. The thymus rapidly responds to immunotoxic injury. Both the thymocytes and the nonlymphoid compartment of the organ can be targets of exposure. Disturbance of positive and negative thymocyte selection may have a major impact on the immunological function of the thymus. Suppression of peripheral T-cell-dependent immunity as a consequence of thymus toxicity is primarily seen after perinatal exposure when the thymus is most active. Autoimmunity may be another manifestation of chemically mediated thymus toxicity. Although the regenerative capacity of thymus structure is remarkable, it remains to be clarified whether this also applies to thymus function. In-depth mechanistic studies on chemical-induced dysfunction of the thymus have been conducted with the environmental contaminants 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) and bis(tri-n-butyltin)oxide (TBTO) as well as the pharmaceutical immunosuppressant cyclosporine (CsA). Each of these compounds exerts a differential effect on the morphology of the thymus, depending on the cellular targets for toxicity. TCDD and TBTO exposure results in cortical lymphodepletion, albeit by different mechanisms. An important feature of TCDD-mediated thymus toxicity is the disruption of epithelial cells in the cortex. TBTO primarily induces cortical thymocyte cell death. In contrast CsA administration results in major alterations in the medulla, the cortex remaining largely intact. Medullary epithelial cells and dendritic cells are particularly sensitive to CsA. The differential effects of these three immunotoxicants suggest unique susceptibilities of the various cell types and regions that make up the thymus.

Galectin-1, an endogenous lectin produced by thymic epithelial cells, induces apoptosis of human thymocytes

Galectin-1, a beta-galactoside binding protein, is produced by thymic epithelial cells and binds to human thymocytes. We have previously reported that galectin-1 induces the apoptosis of activated T lymphocytes. Because the majority of thymocytes die via apoptosis while still within the thymus, we tested whether galectin-1 could induce the apoptosis of these cells. We now report that in vitro exposure to galectin-1 induced apoptosis of two subsets of CD4(lo) CD8(lo) thymocytes. The phenotypes of susceptible thymocytes were consistent with that of both negatively selected and nonselected cells. Galectin-1-induced apoptosis was enhanced by preexposure of thymocytes to antibody to CD3, suggesting that galectin-1 may be a participant in T-cell- receptor mediated apoptosis. In contrast, pretreatment of thymocytes with dexamethasone had no effect on galectin-1 susceptibility. We noted that 71% of the cells undergoing apoptosis after galectin-1 treatment had a DNA content greater than 2N, indicating that proliferating thymocytes were most sensitive to galectin-1. We propose that galectin-1 plays a role in the apoptosis of both negatively selected and nonselected thymocytes, and that the susceptibility of thymocytes to galectin-1 is regulated, in part, by entry or exit from the cell cycle.

Targeted expression of major histocompatibility complex (MHC) class II molecules demonstrates that dendritic cells can induce negative but not positive selection of thymocytes in vivo

It is well established that lymphoid dendritic cells (DC) play an important role in the immune system. Beside their role as potent inducers of primary T cell responses, DC seem to play a crucial part as major histocompatibility complex (MHC) class II+ "interdigitating cells" in the thymus during thymocyte development. Thymic DC have been implicated in tolerance induction and also by some authors in inducing major histocompatibility complex restriction of thymocytes. Most of our knowledge about thymic DC was obtained using highly invasive and manipulatory experimental protocols such as thymus reaggregation cultures, suspension cultures, thymus grafting, and bone marrow reconstitution experiments. The DC used in those studies had to go through extensive isolation procedures or were cultured with recombinant growth factors. Since the functions of DC after these in vitro manipulations have been reported to be not identical to those of DC in vivo, we intended to establish a system that would allow us to investigate DC function avoiding artificial interferences due to handling. Here we present a transgenic mouse model in which we targeted gene expression specifically to DC. Using the CD 11c promoter we expressed MHC class II I-E molecules specifically on DC of all tissues, but not on other cell types. We report that I-E expression on thymic DC is sufficient to negatively select I-E reactive CD4+ T cells, and to a less complete extent, CD8+ T cells. In contrast, it only DC expressed I-E in a class II-deficient background, positive selection of CD4+ T cells could not be observed. Thus negative, but not positive, selection events can be induced by DC in vivo.

Quantitative impact of thymic clonal deletion on the T cell repertoire

Interactions between major histocompatibility complex (MHC) molecules expressed on stromal cells and antigen-specific receptors on T cells shape the repertoire of mature T lymphocytes emerging from the thymus. Some thymocytes with appropriate receptors are stimulated to undergo differentiation to the fully mature state (positive selection), whereas others with strongly autoreactive receptors are triggered to undergo programmed cell death before completing this differentiation process (negative selection). The quantitative impact of negative selection on the potentially available repertoire is currently unknown. To address this issue, we have constructed radiation bone marrow chimeras in which MHC molecules are present on radioresistant thymic epithelial cells (to allow positive selection) but absent from radiosensitive hematopoietic elements responsible for negative selection. In such chimeras, the number of mature thymocytes was increased by twofold as compared with appropriate control chimeras This increase in steady-state numbers of mature thymocytes was not related to proliferation, increased retention, or recirculation and was accompanied by a similar two- to threefold increase in the de novo rate of generation of mature cells. Taken together, our data indicate that half to two-thirds of the thymocytes able to undergo positive selection die before full maturation due to negative selection.

T cell responses are governed by avidity and co-stimulatory thresholds

We analyzed the avidity and CD28-mediated co-stimulatory requirements for the activation of T cells in vivo and in vitro. The strength of the T cell/antigen-presenting cell interaction was varied by using altered peptide ligands for stimulation. Co-stimulatory requirements were studied using T cells from CD28-deficient mice. The results indicate that T cell activation is not an all-or-nothing event, but occurs in distinct steps. For each step, a certain avidity, co-stimulatory threshold or both, must be met. Depending upon the strength of the interaction between the T cell receptor and the major histocompatibility complex/peptide and the presence of CD28 co-stimulatory signals, T cells may undergo blast formation alone or proliferate or eventually both proliferate and differentiate to effector cells. Thus, T cell activation is governed by both avidity and co-stimulatory thresholds.

Cellular interactions in thymocyte development

Interactions between stromal cells and thymocytes play a crucial role in T cell development. The thymic stroma is complex and consists of epithelial cells derived from the pharyngeal region during development, together with macrophages and dendritic cells of bone marrow origin. In addition, fibroblasts and matrix molecules permeate the whole framework. It is now apparent that these individual stromal components play specialized roles at different stages of T cell differentiation. Thus, at the early CD4-8- stage of development, T cell precursors require fibroblast as well as epithelial cell interactions. Later, at the CD4+8+ stage, as well as providing low avidity TCR/MHC-peptide interactions, thymic epithelial cells have been shown to possess unique properties essential for positive selection. Dendritic cells, on the other hand, are probably efficient mediators of negative selection, but they may not be solely responsible for this activity. Alongside the functional roles of stromal cells, considerable progress is being made in unraveling the nature of the signaling pathways involved in T cell development. Identification of the pre-T cell receptor (pre-TCR) and associated signaling molecules marks an important advance in understanding the mechanisms that control gene rearrangement and allelic exclusion. In addition, a better understanding of the signaling pathways that lead to positive selection on the one hand and negative selection on the other is beginning to emerge. Many issues remain unresolved, and some are discussed in this review. What, for example, is the nature of the chemotactic factor(s) that attract stem cells to the thymus? What is the molecular basis of the essential interactions between early thymocytes and fibroblasts, and early thymocytes and epithelial cells? What is special about cortical epithelial cells in supporting positive selection? These and other issues are ripe for analysis and can now be approached using a combination of modern molecular and cellular techniques.

Clonal deletion of major histocompatibility complex class I-restricted CD4+CD8+ thymocytes in vitro is independent of the CD95 (APO-1/Fas) ligand

The CD95 (APO-1/Fas) ligand (CD95L) mediates apoptosis in sensitive target cells, Ca(2+)-independent cytotoxicity of cells from perforin knock-out mice, and peripheral deletion of activated T cells through engagement of its cognate receptor CD95. Double-positive thymocytes show a high constitutive expression of CD95. Therefore, we used a model system and investigated whether negative selection through apoptosis might involve CD95/CD95L. We analyzed whether CD95L may induce antigen-specific deletion of double-positive thymocytes from mice transgenic for a lymphocytic choriomeningitis virus (LCMV)/H2b-specific T cell receptor (TCR). These cells are deleted in vitro upon addition of the LCMV-peptide 33-41 in a major histocompatibility complex-class I-restricted fashion. Deletion was not blocked by soluble mouse and human CD95-Fc receptor decoys. CD95-Fc receptor decoys, however, were effective in blocking apoptosis induced by mouse CD95L-transfected L929 cells in sensitive CD95+ target cells and in thymocytes. These results suggest that TCR-induced deletion of immature thymocytes in vitro is independent of CD95L. Thus, our data argue against a role of CD95L in negative selection of MHC-class I-restricted autoreactive thymocytes.

Strong agonist ligands for the T cell receptor do not mediate positive selection of functional CD8+ T cells

Positive selection of functional CD8+ T cells expressing an MHC class I-restricted T cell receptor can be induced in fetal thymus organ culture by class I-binding peptides related to the antigenic peptide ligand. Peptides that act as antagonist or weak agonist/antagonist ligands for mature T cells work efficiently in this regard. In the present study, we have investigated whether low concentrations of the original agonist peptide, or variants that still have a strong agonist activity can also mediate positive selection. The antigenic peptide did not induce positive selection at any concentration tested. A strong agonist variant was capable of stimulating the differentiation of TCRhi CD8+ cells, giving the appearance of phenotypic positive selection. However, these cells lacked biological function, since they could not proliferate in response to antigen. The most efficient positive selection resulted with ligands that did not activate mature T cells or stimulate negative selection.

The role of the thymus during T-lymphocyte development in vitro

To date, fetal thymic organ culture is the only in-vitro system capable of supporting a complete programme of T-lymphocyte development in a manner comparable to that seen in vivo. In this review, we will summarise recent studies in which thymic organ cultures have been used to investigate the regulatory mechanisms of particular stages of thymocyte development. In addition, the use of other culture systems of T-cell maturation will be discussed in an attempt to define the optimal conditions for T-cell development in vitro.

Murine nursing thymic epithelial cell lines capable of inducing thymocyte apoptosis express the self-superantigen Mls-1a

Two cloned thymic epithelial cell (TEC) lines, D2.TEC-A3 and AKR TEC-K1, were established from minor lymphocyte-stimulating (Mls)-1a-positive normal, 4-week-old DBA/2 (H-2d, Mls-1a2a) mice and AKR (H-2k, Mls-1a2b) mice, respectively. Both cell lines were MHC class I and class II (both I-A and I-E) positive without stimulation by interferon-gamma. They were capable of infolding immature thymocytes to form thymic nurse cells (TNC; we call this type of TEC "nursing TEC") and induced apoptosis with DNA fragmentation in immature thymocytes. Using a primary Mls mixed lymphocyte reaction (MLR) we demonstrated that self-superantigen Mls-1a was expressed on these cloned nursing TEC lines. D2.TEC-A3 cells stimulated nylon-wool-purified splenic T cells obtained from H-2d-compatible BALB/c (Mls-1b2a) and B10.D2 (Mls-1b2b) mice with a maximal response at a stimulator:responder ratio of 1:40 after 4 days of the coculture. AKR TEC-K1 cells also stimulated purified T cells from H-2k-compatible C3H/He mice (Mls-1b2a) in a similar manner. The Mls MLR induced by the nursing TEC lines was completely inhibited in the presence of anti-mouse I-A and anti-mouse I-E monoclonal antibodies. These results suggest that nursing TEC/TNC could be involved in negative selection due to apoptosis.

T-cell tolerance and autoimmunity in transgenic models of central and peripheral tolerance

Experiments with transgenic mice expressing genes encoding both antigens in defined tissues and T-cell receptor genes of known specificities have enhanced our understanding of the mechanisms involved in the pathogenesis of autoimmune states. They have also shed light on the means by which potentially autoreactive cells may be prevented from exerting their autoaggressive potential. The value of the transgenic approach is that it can overcome the low frequency of peptide-specific T cells occurring in normal animals, and also provide a tissue-specific, cognate antigen that is absent in controls. These factors allow reactive T cells to be isolated or quantified by flow cytometry and their responses to antigen in vitro and in vivo be defined.

Peptide antagonists that promote positive selection are inefficient at T cell activation and thymocyte deletion

We set out to determine whether thymocytes from T cell receptor (TCR) transgenic animals specific for a class I-restricted determinant from ovalbumin (OVA) showed the same fine specificity for antigen-driven deletion in single-cell suspension culture as required for mature T cell activation. The transgenic TCR is specific for the Kb-restricted peptide OVA257-264 (SIINFEKL) which is known to have four TCR contact residues at position 1, 4, 6, and 7 from the crystal structure of this fragment in complex with Kb. OVA257-264 analogs systematically substituted at each of these positions were assayed for their ability to promote immature double-positive thymocyte deletion or mature T cell activation of a cytotoxic T lymphocyte line derived from this transgenic mouse. In the absence of additional antigen-presenting cells, single-cell thymocyte suspensions showed that the specificity for double-positive thymocyte deletion and mature T cell activation was virtually identical, demonstrating a limited cross-reactivity with a number of variants having conservative substitutions at these exposed residues. These peptides were considerably more efficient at both thymic deletion and mature T cell activation than a number of non-conservative substitution analogs known to act as antagonists of OVA257-264 and capable of selecting transgenic T cells in thymic organ culture. Therefore, both peripheral T cell activation and thymic deletion have an overall similar pattern of peptide specificity which differs from that required for positive selection. This suggests that a subset of major histocompatibility complex-presented peptides could promote positive selection without causing either thymic deletion or peripheral activation of those selected T cells.

A differential-avidity model for T-cell selection

The processes of positive and negative selection during thymic development shape the repertoires of antigen specificities displayed by T cells. This rids the animal of potentially autoreactive T cells and, at the same time, ensures that they are capable of major histocompatibility complex (MHC)-restricted recognition of antigen. Paradoxically, both processes involve the engagement of the T-cell recepetor (TCR) on immature thymocytes with peptide/MHC complexes expressed on thymic stromal cells. Here, Philip Ashton-Rickardt and Susumu Tonegawa suggest that the critical parameter determining the outcome of this interaction is the number of TCRs occupied by peptide/MHC complexes and that this, in turn, is determined by the avidity of the TCR-MHC interaction: low avidity resulting in positive selection and high avidity resulting in negative selection.

Positive selection of self- and alloreactive CD8+ T cells in Tap-1 mutant mice

Mice with a homozygous deletion in their Tap-1 gene (-/- mice) express very low levels of cell membrane major histocompatibility complex class I molecules and have < 1% peripheral CD8+ T cells. We show that these -/- mice but not their +/- littermates display strong primary syngeneic anti-H-2Kb and -Db-specific responses mediated by CD8+ T cells. These responses are augmented by in vivo priming. Further, -/- mice primed in vivo with H-2d alloantigens generate an anti-H-2d response which appears nearly as strong as that found in +/- littermates. Both -/- anti-H-2b and anti-H-2d T cells do not recognize target cells from Tap-1 -/- animals or Tap-2-deficient RMA-S cells. Thus, some CD8+ anti-self and alloreactive T cells can be selected in the absence of Tap proteins.

Intracellular signals that mediate thymic negative selection

Antigenic stimulation of CD4/CD8 double positive (DP) thymocytes results in programmed cell death, while the identical stimulation of mature T cells results in proliferation and lymphokine secretion. Using thymocytes from transgenic mice expressing pigeon cytochrome c-specific T cell receptors, we previously demonstrated that major histocompatibility complex class II-transfected L cells were capable of presenting peptide antigen and inducing programmed cell death in DP thymocytes, as well as proliferation and lymphokine secretion in mature CD4 single positive (SP) T cells. We therefore were interested in utilizing this system to compare antigen-induced signal transduction events in DP thymocytes and mature SP T cells. In this report, we demonstrate that significant distinctions between thymocytes and mature T cells are seen upon examination of antigen sensitivity and the phosphatidylinositol signaling cascade.

Positive and negative thymocyte selection induced by different concentrations of a single peptide

T lymphocyte maturation is dependent on interactions between the T cell receptor (TCR) expressed on the developing thymocyte and intrathymic major histocompatibility complex (MHC)-peptide ligands. The relation between the peptide-MHC complex that results in negative or positive selection has not been identified. Here, the requirements for the maturation of thymocytes expressing a defined transgenic TCR specific for a viral peptide are studied in fetal thymic organ culture. Low concentrations of the viral peptide antigen recognized by this transgenic TCR can mediate positive selection, whereas high concentrations result in thymocyte tolerance. These findings support the affinity-avidity model of thymocyte selection.

Evidence for a differential avidity model of T cell selection in the thymus

Positive and negative selection of a lymphocytic choriomeningitis virus (LCMV) peptide-specific, H-2Db-restricted T cell clone (P14) was studied using TAP1- and TAP1+ mice transgenic for P14 T cell receptor (TCR) alpha and beta genes. Positive selection of transgenic CD8+ P14 cells was impaired in TAP1- mice. Addition of the LCMV peptide to TAP1- fetal thymic organ cultures (FTOCs) at low and high concentrations induced positive and negative selection of CD8+ P14 cells, respectively, while addition of the same peptide to TAP1+ FTOCs induced negative selection even at low concentrations. Both types of selection were peptide specific. Thus, a critical parameter that controls the fate of a thymocyte seems to be the number of TCRs engaged with complexes of peptide and major histocompatibility complex. When this number is low, positive selection occurs, and when it is high, negative selection takes place. These findings support a differential avidity model of T cell selection.

Regulation of RAG-1 and CD69 expression in the thymus during positive and negative selection

Successful interaction of the T cell receptor (TCR) with major histocompatibility complex (MHC) molecules during thymic selection down-regulates the expression of the recombination activating genes (RAG)-1 and -2 in cortical thymocytes and thereby prevents further endogenous TCR alpha-chain gene rearrangements (Borgulya, P., Kishi, H., Uematsu, Y. and von Boehmer, H., Cell. 1992. 69: 529-537; Brändle, D., Müller, C., Rülicke, T., Hengartner, H. and Pircher, H., Proc. Natl. Acad. Sci. USA 1992. 89: 9529-9533). To address the question whether down-regulation of RAG-1 activity represents an irreversible process we have blocked TCR-MHC interactions of thymocytes with thymic stromal cells. Firstly, transgenic (Tg) mice expressing a virus-specific MHC class I (H-2Db)-restricted TCR were injected with anti-Db or anti-CD8 monoclonal antibodies and RAG-1 expression was examined by in situ hybridization on thymus sections. The results show that cortical thymocytes up-regulated RAG-1 expression within 24 h after antibody administration. Secondly, immature thymocytes from TCR Tg mice were released from the thymic microenvironment and cultured in vitro for 14 h in single-cell suspension. The amount of RAG-1 mRNA was increased sixfold in cultured cells when compared to freshly isolated thymocytes. In addition, we show that immature thymocytes from TCR transgenic mice bearing non-selective MHC molecules (H-2d) down-regulated RAG-1 expression after antigen-induced TCR engagement. Cytofluorometric analysis further revealed that surface expression of CD69 on immature thymocytes inversely correlated with RAG-1 expression during positive and negative selection processes.

T-cell tolerance

As the consequences of autoimmunity are so damaging to an individual, both deletional and non-deletional forms of T-cell tolerance are observed in the thymus as well as the periphery. Although the relationship between these types of tolerance is not clear, recent studies in vivo and in vitro have begun to identify the cellular and molecular interactions involved. Whereas thymic development must account for both positive and negative selection, it is now apparent that T-cell responses in the periphery must also strike a balance between the generation of effector function and activation-induced tolerance.

Half-life of antigen/major histocompatibility complex class II complexes in vivo: intra- and interorgan variations

We have determined the half-life in vivo of antigen/MHC class II complexes in different organ microenvironments. Mice were "pulsed" with myoglobin intravenously and MHC class II-positive antigen-presenting cell (APC) populations from different organs were isolated after various time intervals. Specific antigen/MHC complexes were quantitated by co-cultivation of the APC subsets with myoglobin-specific T-T hybridoma cells in vitro. Half-lives of antigen/MHC complexes differed both between organs and between compartments of the same organ. Half-lives in peripheral organs (spleen and bone marrow) ranged between 3 and 8 h, whereas in the thymus half-lives between 13 h (cortical epithelial cells) and 22 h (medullary dendritic cells) were observed. Half lives in vivo were independent of antigen processing, since intact protein or antigenic peptides yielded similar values. The considerably longer half-life of peptide/MHC complexes in the thymus as compared to peripheral organs may reflect the distinct role which antigen presentation plays in both organs, i.e. induction of tolerance versus induction of immunity.

In vitro negative selection of alpha beta T cell receptor transgenic thymocytes by conditionally immortalized thymic cortical epithelial cell lines and dendritic cells

We have established conditionally immortalized thymic cortical epithelial cell lines from transgenic mice carrying a temperature-sensitive SV40 large T antigen. One of these cell lines expresses cortical markers and produces IL-1 alpha, IL-6, IL-7, and TGF-beta 1. These cells express class I major histocompatibility complex (MHC) constitutively and class II MHC upon induction with IFN-gamma. The cells appear to have a normal class I antigen presenting pathway since messages for both peptide transporter genes (TAP1, TAP2) were detected. The ability of these cortical epithelial cells to present peptide antigen was compared to that of thymic dendritic cells. In suspension culture with alpha beta T cell receptor (TcR) transgenic thymocytes, these epithelial cells and dendritic cells (pre-pulsed with peptide cognate for the transgenic TcR) caused down-regulation of CD4, CD8, and TcR in an antigen dose-dependent and MHC-restricted manner. CD4dullCD8dull cells were taken as evidence for negative selection because these cells contained apoptotic DNA. Concentration of peptide required for negative selection of thymocytes was similar between dendritic cells and cortical epithelial cells. In contrast, alpha beta TcR transgenic spleen cells were activated only by dendritic cells but not by cortical epithelial cells.

T cell receptor targeting to thymic cortical epithelial cells in vivo induces survival, activation and differentiation of immature thymocytes

We report that targeting of T cell receptors (TcR) to non-major histocompatibility complex (MHC) molecules on thymic cortical epithelial cells by hybrid antibodies in vivo and in fetal thymic organ cultures results in phenotypic and functional differentiation of thymocytes. A single pulse with hybrid antibodies rescues immature, CD4/8 double-positive thymocytes from their programmed death in vivo, induces expression of the early activation antigen CD69 followed by TcR up-regulation, concomitant down-regulation of CD8 or CD4 and their conversion to functional mature T cells by day 3. This temporal sequence of maturation only affects small thymocytes without co-induction of blastogenesis. TcR targeting to MHC class II-positive epithelial cells predominantly induces CD4-positive T cells. This generation of CD4 single-positive T cells occurs also in MHC class II-deficient mice and thus is independent of CD4-MHC class II interactions. Moreover, in the presence of a specific deleting antigen (Mls 1a), TcR targeting results in transient activation of immature thymocytes, however, not in subsequent TcR (V beta 6) up-regulation and development of single-positive T cells. Our findings imply that TcR cross-linking to cortical epithelial cells is sufficient to confer a differentiation signal to immature thymocytes. Furthermore, this approach distinguishes two independent TcR-mediated intrathymic events: activation and subsequent deletion of the same thymocyte subset.