An essential role for the IL-7 receptor during intrathymic expansion of the positively selected neonatal T cell repertoire

Intrathymic T cell development is a multistage process involving discrete phases of proliferation as well as differentiation. From studies on IL-7 or IL-7Ralpha-deficient mice, it is clear that the IL-7 receptor (IL-7R) plays a critical role during the initial stages of intrathymic CD4-8- precursor development. In contrast, the role of IL-7R in later stages of thymocyte development are unclear. Here, we have used various approaches to investigate directly the role of the IL-7R in thymocyte positive selection and the recently described phase of postselection proliferation. First, we show that positive selection involves selective up-regulation of IL-7Ralpha- and IL-7Rgamma-chains, with the majority of CD4+ and CD8+ cells being IL-7R+. Second, MHC class II+ thymic epithelium-which drives postselection proliferation-expresses IL-7 mRNA. Finally, analysis of positive selection and postselection proliferation in thymocytes from IL-7Ralpha-/- neonates shows that positive selection occurs normally, whereas postselection expansion is drastically reduced. Thus, our data provide the first evidence that, as well as playing a role during early phases of thymic development, IL-7R mediates intrathymic expansion of positively selected thymocytes, which may aid in establishment of the neonatal peripheral T cell pool.     

Developmental alterations in thymocyte sensitivity are actively regulated by MHC class II expression in the thymic medulla

Developing thymocytes are positively selected if they respond to self-MHC-peptide complexes, yet mature T cells are not activated by those same self-complexes. To avoid autoimmunity, positive selection must be followed by a period of maturation when the cellular response to TCR signals is altered. The mechanisms that mediate this postselection developmental tuning remain largely unknown. Specifically, it is unknown whether developmental tuning is a preprogrammed outcome of positive selection or if it is sensitive to ongoing interactions between the thymocyte and the thymic stroma. We probed the requirement for MHC class II-TCR interactions in postselection maturation by studying single positive (SP) CD4 thymocytes from K14/A(beta)(b) mice, in which CD4 T cells cannot interact with MHC class II in the thymic medulla. We report here that SP CD4 thymocytes must receive MHC class II signals to avoid hyperactive responses to TCR signals. This hyperactivity correlates with decreased expression of CD5; however, developmental tuning can occur independently of CD5, correlating instead with differences in the distribution of Lck. Thus, the maturation of postselection SP CD4 thymocytes is an active process mediated by ongoing interactions between the T cell and MHC class II molecules. This represents a novel mechanism by which the thymic medulla prevents autoreactivity.     

Specialisation of thymic epithelial cells for positive selection of CD4+8+ thymocytes.

Following their migration into the thymus, hemopoeitic stem cell precursors enter a complex developmental pathway involving proliferation, differentiation and alphabetaT-cell receptor (alphabetaTCR)-mediated selection procedures, in order to generate mature T-cell populations ready for export to the periphery. Thus, a critical stage during intrathymic T-cell development involves the generation of functionally mature CD4+8- and CD4-8+ cells from immature CD4+8- precursor thymocytes, a poorly understood process referred to as positive selection. While interactions between the alphabetaTCR and MHC-peptide complexes are known to be essential for the initiation of positive selection, additional unknown signals are also required. Using an in vitro reaggregate thymic organ culture system which allows comparison of the abilities of various cell types to induce maturation of CD4+8+ precursors, we provide evidence that both MHC-peptide complexes and specialised accessory molecules must be provided by thymic epithelium for efficient mediation of positive selection. Moreover, analysis of positive selection in the presence of thymic and non-thymic stromal cells expressing MHC class II molecules with the same limited peptide array suggests that this unique ability of thymic epithelium to mediate positive selection of CD4+8- cells is not solely due to presentation of a specialised peptide repertoire, but is dependent upon provision of specialised accessory interactions.     

Thymic selection and peripheral activation of CD8 T cells by the same class I MHC/peptide complex

Thymic selection is controlled by the interaction between TCR and MHC/peptide. Strength and quality of the signal determine whether thymocytes are selected or deleted. The factors that contribute to this signal remain poorly defined. Here we show that fetal thymic organ cultures (FTOCs) derived from OT-I transgenic mice (the OT-I TCR is restricted by K(b)-SIINFEKL) on a K(b)D(b-/-) background support positive selection, but only when provided with soluble H-2K(b)-SIINFEKL complexes. Selection of CD8 T cells is independent of the valency of the ligand or its capability to coengage CD8 molecules. Both CD8alphaalpha and CD8alphabeta T cells are selected by H-2K(b)-SIINFEKL, but only CD8alphabeta cells are capable of releasing IFN-gamma in response to the same ligand. The alpha(4)beta(7) integrin is up-regulated on postselection thymocytes from FTOCs. After adoptive transfer, FTOC-derived OT-I CD8 T cells divide in response to the agonist peptide SIINFEKL. These results establish that CD8 T cells responsive to their nominal peptide-Ag can be generated in FTOC supplemented with soluble MHC class I molecules equipped with the same peptide.     

Signal transduction via CD4, CD8, and CD28 in mature and immature thymocytes. Implications for thymic selection.

The positive and negative selection of immature thymocytes that shapes the mature T cell repertoire appears to occur at an intermediate stage of development when the cells express low levels of TCR/CD3. These cells are also CD4+CD8+ and CD28+ (dull), and signals delivered by these three accessory molecules have been implicated in the selection process. We have examined the regulatory function of these accessory molecules on responses of immature thymocytes stimulated through the TCR/CD3 complex. Cross-linking CD4 or CD8 with CD3 strongly enhanced signal transduction via CD3 as assessed by protein tyrosine phosphorylation and calcium mobilization. Subsequent cell proliferation could be induced by soluble anti-CD28 mAb, which was comitogenic for cells stimulated with CD3 x CD4 or CD3 x CD8 cross-linking, but was without effect on cells stimulated with CD3 x CD3 cross-linking. A potential role for CD28 signal transduction in thymic maturation is suggested by the demonstration that the BB-1 molecule, a natural ligand for CD28, is expressed on thymic stromal cells. Taken together, our data suggest a model of thymic development in which CD4 or CD8 may enhance TCR/CD3 signaling upon coligation by an MHC molecule. If the CD28 surface receptor is simultaneously stimulated by a BB-1 expressing stromal cell, this set of interactions could lead to proliferation and positive selection. In the absence of CD28 stimulation the enhanced TCR/CD3 signals might lead to apoptosis and negative selection.     

Delineation of signals required for thymocyte positive selection

Peptide/MHC complexes capable of inducing positive selection in mouse fetal thymic organ cultures fail to do so in suspension culture. Furthermore, this type of culture does not promote initial stages of differentiation, such as coreceptor down-modulation, unless peptides used for stimulation have (at least) weak agonist activity. We show in this study that signals provided in suspension culture by nonagonist peptide/MHC complexes on the surface of macrophages, even though apparently silent, are sufficient to promote complete phenotypic differentiation when CD4+CD8+ thymocytes are subsequently placed in a proper anatomical setting. Furthermore, the synergistic actions of suboptimal concentrations of phorbol esters and nonagonist peptide/MHC complexes can make the initial stages of positive selection visible, without converting maturation into negative selection. Thus, the correlation between efficiency of positive selection and the degree of coreceptor down-modulation on CD4+CD8+ thymocytes is not linear. Furthermore, these results suggest that the unique role of thymic stromal cells in positive selection is related not to presentation of self-peptide/MHC complexes, but most likely to another ligand.     

Soluble factor-mediated differentiation of CD4+CD8+ thymocytes to single positives in vitro

Although the thymic microenvironment provides the necessary elements for T-cell differentiation, the precise role of individual components remains to be determined. In this paper, attempts were made to address the possibility that CD4 or CD8 single-positive (SP) thymocytes could be developed from immature CD4+CD8+ (double-positive; DP) thymocytes in a suspension culture in the presence of soluble factors. We observed that IL-4 and IFN-gamma weakly induced DP cells to differentiate to CD4 cells, but not to CD8. In contrast, IL-2 weakly induced differentiation to CD8. Interestingly, Con A sup strongly induced differentiation to CD8 SP from the purified DP thymocytes prepared from C57BL/6 or LCMV TCRtg mice. In particular, it was found that thymocyte culture with Con A sup generated CD69+DP cells, and the CD69+DP differentiated to CD8 SP under the suspension culture with soluble factors. Thus, Con A sup or combinations of IL-2, IL-4 and IL-7 strongly induced differentiation of CD69+DP to CD8 SP, whereas individual cytokines did not. These results suggest that soluble factors like cytokines play an important role in the generation of SP thymocytes in the absence of thymic stromal cells, at least from a distinctive subpopulation like CD69+DP thymocytes, and perhaps from those of broader range when in conjunction with TCR/MHC interaction.     

Thymic selection in CD8 transgenic mice supports an instructive model for commitment to a CD4 or CD8 lineage

Immature thymocytes, which coexpress CD4 and CD8, give rise to mature CD4+CD8- and CD4-CD8+ T cells. Only those T cells that recognize self-MHC are selected to mature, a process known as positive selection. The specificity of the T cell antigen receptor (TCR) for class I or class II MHC influences the commitment to a CD4 or CD8 lineage. This may occur by a directed mechanism or by stochastic commitment followed by a selection step that allows only CD8+, class I-specific and CD4+, class II-specific cells to survive. We have generated a mouse line expressing a CD8 transgene under the control of the T cell-specific CD2 regulatory sequences. Although constitutive CD8 expression does not affect thymic selection of CD4+ cells, selection of a class I-specific TCR in the CD8 subset is substantially improved. This outcome is consistent with a model for positive selection in which selection occurs at a developmental stage in which both CD4 and CD8 are expressed, and positive selection by class I MHC generates an instructive signal that directs differentiation to a CD8 lineage.     

IL-2 protects against anti-CD3-induced cell death in human medullary thymocytes

In recent years, several studies have confirmed the clonal elimination of thymocytes with receptors that recognize Ag and MHC molecules present on the membrane of thymic stromal cells, a process that may be relevant to the establishment of self-tolerance. In our work, we show that anti-CD3 treatment of single positive CD4+ or CD8+ human medullary thymocytes (obtained by anti-CD1a plus C) induces their apoptotic death. Some events commonly associated with the early steps of normal activation (IL-2R expression, increase in cytoplasmic Ca2+) are also induced after anti-CD3 treatment. Nevertheless, IL-2 is not secreted by these activated cells. The addition of exogenous IL-2 inhibits the apoptosis induced by anti-CD3. We suggest that the lack of secretion of IL-2 by medullary thymocytes may be a physiologic mechanism implicated in the process of negative selection that leads to tolerance.     

Engagement of CD4 and CD8 accessory molecules is required for T cell maturation

In order to address the role of CD4 and CD8 Ag in the process of positive selection in the thymus, antibodies against these molecules, which do not result in the elimination of mature lymph node T cells, were injected in vivo. The results indicate that even long-term injection of nondepleting anti-CD4 and anti-CD8 antibodies does not cause the loss of CD4 or CD8 positive lymph node cells, but it completely blocks the development of the corresponding subpopulation of mature thymocytes. Thus, it appears that the interaction of the CD4 and CD8 accessory molecules on developing thymocytes with a ligand in the thymic environment (probably MHC Ag) is necessary for the positive selection of thymocytes into the appropriate T cell lineage.     

Altered thymocyte development resulting from expressing a deleting ligand on selecting thymic epithelium.

The maturation of CD4+8- and CD4-8+ thymocytes from CD4+8+ thymocytes is dependent on the mandatory interaction of their alpha beta TCR with selecting ligands expressed on thymic epithelial cells (TE). This is referred to as positive selection. The deletion of CD4+8+ thymocytes that express autospecific TCR (negative selection) is mediated primarily by bone marrow-derived cells. Previous studies have shown that TE is relatively ineffective in mediating the deletion of CD4+8- thymocytes expressing autospecific TCR but TE can render them anergic, i.e., nonresponsive, to the self Ag. The mechanism by which anergy is induced in these cells is unknown. In this study, we used thymocytes expressing a transgenic TCR specific for the male Ag presented by H-2Db class I MHC molecules to examine how expression of the deleting ligand by TE affects thymocyte development and phenotype. The development of female TCR-transgenic thymocytes was examined in irradiated male hosts or in female hosts that had received male fetal thymic epithelial implants. It was observed that the development of transgenic-TCR+ thymocytes was affected in mice with male TE. CD4+8+ thymocytes with reduced CD8 expression and markedly enhanced transgenic TCR expression accumulated in mice with male TE. Development of CD4-8+ thymocytes was also affected in these mice in that fewer were present and they expressed an intermediate CD8 coreceptor level. These CD4-8+ thymocytes expressed a high level of the transgenic TCR, retained the ability to respond to anti-TCR antibodies, but were nonresponsive to male APC. However, the maturation of CD4+8- thymocytes, which are also derived from CD4+8+ precursor cells, was relatively unaffected. In an in vitro assay for assessing negative selection, male TE failed to delete CD4+8+ thymocytes expressing the transgenic TCR under conditions where they were efficiently deleted by male dendritic cells. Collectively these results support the conclusion that male TE was inefficient in mediating deletion. Furthermore, expression of the deleting ligand on thymic epithelium interferes with the maturation of functional male-specific T cells and results in the accumulation of CD4+8+ and CD4-8+ thymocytes expressing a lower level of the CD8 coreceptor but a high level of the transgenic TCR.     

Expression of VLA-4 on thymocytes. Maturation stage-associated transition and its correlation with their capacity to adhere to thymic stromal cells.

The present study investigates the expression of VLA-4 on thymocytes at various stages of maturation and their capacity to adhere to thymic stromal cells. Whole thymocytes were stained with anti-CD4 and anti-CD8, as well as anti-VLA-4 antibodies. Flow microfluorometric analyses revealed that a) most of CD4-8- (double negative DN) and CD4-8intermediate thymocyte populations expressed large amounts of VLA-4, b) the levels of VLA-4 were considerably and markedly reduced on CD4+8+ (double positive DP) and single positive (SP) (CD4+8- or CD4-8+) populations, respectively. This contrasted with an increase in the levels of LFA-1 along with thymocyte maturation. DN, DP, and SP subsets were isolated and examined for their capacity to express VLA-4 and to adhere to fibronectin (FN) molecules as well as thymic stromal cells expressing FN. DN, DP, and SP subsets were confirmed to express the respective high, low, and very low levels of VLA-4, respectively. Approximately 70% of DN thymocytes became bound to FN-precoated culture plates, whereas 30 to 40% of DP and only 10 to 20% of SP cells adhered to FN. Similar patterns of adhesion were observed between these thymocyte subsets and thymic stromal monolayers. The binding of the DN subset to FN-plates or thymic stromal monolayers was inhibited only marginally by the RGDS peptide, but was efficiently inhibited by V10 peptide (cell-binding sequence that is located in the V region on FN and reacts with the VLA-4 integrin) or anti-VLA-4 antibody. Anti-VLA-4 antibody plus RGDS peptide strongly inhibited DN cell binding to FN-coated plates and thymic stromal monolayers. These results indicate that i) VLA-4 expressed on DN thymocytes functions as an important integrin for interacting with thymic stromal cells; ii) the expression level of this integrin decreases with the progress of thymocyte maturation, and iii) most of the mature thymocytes (SP) are rendered less adhesive to thymic stromal cells by reducing the level of VLA-4 expression.     

Differentiation of an immature T cell line: a model of thymic positive selection.

Thymocyte differentiation is dependent upon recognition of major histocompatibility complex (MHC) molecules on thymic stroma, a process called positive selection. Here we describe an immature CD4+8+ T cell line derived from a TCR transgenic mouse that differentiates into CD4+8- cells in response to antigen and nonthymic antigen-presenting cells. When injected intrathymically, these cells differentiate in the absence of antigen. The ability of immature T cells to recognize MHC molecules in the absence of foreign antigen in the thymus can thus be attributed to a unique property of thymic antigen-presenting cells. These studies also demonstrate the phenotypic and functional changes associated with TCR-mediated T cell maturation and establish an in vitro model system of positive selection.     

Deletion of antigen-specific immature thymocytes by dendritic cells requires LFA-1/ICAM interactions.

An in vitro assay was used for assessing the participation of various cell surface molecules and the efficacy of various cell types in the deletion of Ag-specific immature thymocytes. Thymocytes from mice expressing a transgenic TCR specific for the male Ag presented by the H-2Db class I MHC molecule were used as a target for deletion. In H-2d transgenic mice, cells bearing the transgenic TCR are not subjected to thymic selection as a consequence of the absence of the restricting H-2Db molecule but, nevertheless, express this TCR on the vast majority of immature CD4+8+ thymocytes. In this report we show that CD4+8+ thymocytes from H-2d TCR-transgenic mice are preferentially killed upon in vitro culture with male APC; DC were particularly effective in mediating in vitro deletion when compared with either B cells or T cells. Deletion of CD4+8+ thymocytes by DC was H-2b restricted and could be inhibited by mAb to either LFA-1 alpha or CD8. Partial inhibition was observed with mAb to ICAM-1, whereas mAb to CD4 and LFA-1 beta were without effect. These results are the first direct evidence of LFA-1 involvement in negative selection and provide further direct support for the participation of CD8/class I MHC interactions in this process. Like the requirements for deletion, activation of mature male-specific CD4-8+ T cells from female H-2b TCR-transgenic mice was also largely dependent on Ag presentation by DC and required both LFA-1/ICAM and CD8/class I MHC interactions; these results support the view that activation and deletion may represent maturation stage-dependent consequences of T cells encountering the same APC. Finally, our results also support the hypothesis that negative selection (deletion) does not require previous positive selection because deletion was observed under conditions where positive selection had not occurred.     

Involvement of Rho GTPases and their effectors in the secretory process of PC12 cells

Intrathymic maturation of thymocytes is essential for the proper formation of T-cell repertoire. This process involves two major biochemical pathways, one initiated by the recognition of MHC/peptide by the T-cell receptor and the other mediated by glucocorticoids. These hormones seem to affect thymocyte maturation by increasing the threshold of TCR-mediated positive and negative selection, and by inducing apoptosis of nonselected thymocytes. We have previously reported that an SV40-immortalized murine thymic epithelial cell line, namely 2BH4, was able to protect thymocytes from dexamethasone-induced apoptosis. Here we show that this protection is independent of cell-to-cell contact and does not seem to involve a Bcl-2-mediated resistance, since incubation of thymocytes with 2BH4 cells or its supernatant does not interfere with the levels of this antiapoptotic molecule. The protection conferred by 2BH4 cells, or by a primary culture of thymic stromal cells, is specific for the CD4(+)CD8(-) and CD4(-)CD8(+) single-positive thymocytes, whereas the broad-spectrum caspase inhibitor z-VAD-fmk blocks apoptosis induced by dexamethasone in all thymocyte subpopulations. Our results suggest that positively selected single-positive thymocytes are still susceptible to glucocorticoid-induced apoptosis but are protected from it through the action of a heat-stable protein(s) released by thymic stromal cells.     

Cross-positive selection of thymocytes expressing a single TCR by multiple major histocompatibility complex molecules of both classes: implications for CD4+ versus CD8+ lineage commitment

This study has investigated the cross-reactivity upon thymic selection of thymocytes expressing transgenic TCR derived from a murine CD8+ CTL clone. The Idhigh+ cells in this transgenic mouse had been previously shown to mature through positive selection by class I MHC, Dq or Lq molecule. By investigating on various strains, we found that the transgenic TCR cross-reacts with three different MHCs, resulting in positive or negative selection. Interestingly, in the TCR-transgenic mice of H-2q background, mature Idhigh+ T cells appeared among both CD4+ and CD8+ subsets in periphery, even in the absence of RAG-2 gene. When examined on beta2-microglobulin-/- background, CD4+, but not CD8+, Idhigh+ T cells developed, suggesting that maturation of CD8+ and CD4+ Idhigh+ cells was MHC class I (Dq/Lq) and class II (I-Aq) dependent, respectively. These results indicated that this TCR-transgenic mouse of H-2q background contains both classes of selecting MHC ligands for the transgenic TCR simultaneously. Further genetic analyses altering the gene dosage and combinations of selecting MHCs suggested novel asymmetric effects of class I and class II MHC on the positive selection of thymocytes. Implications of these observations in CD4+/CD8+ lineage commitment are discussed.     

Expression of CD1 and class I MHC antigens by human thymocytes

The acquisition of surface class I MHC molecules is associated with the maturation of thymocytes. Here, surface expression of class I MHC and CD1, which represents a family of MHC-related molecules, was analyzed on various human immature and mature thymocyte subpopulations. Class I expression was inversely related to the expression of CD1. The majority of CD4+ CD8+ cortical type thymocytes expressed low levels of class I MHC Ag, the previously described CD4+ CD8+ thymocyte subpopulation with low CD8 expression exhibited intermediate levels of class I MHC, whereas most of the single positive CD4 and CD8 thymocytes displayed high levels of class I MHC. Biochemical comparison of CD1 and class I showed that thymic class I molecules were post-translationally modified by phosphorylation, whereas CD1 was not phosphorylated. Furthermore, our studies suggested that in addition to CD1/CD8 complexes, thymocytes bear CD8/class I complexes. Chemical cross-linking and peptide mapping studies clearly identified the CD8-associated protein on thymic clones as the class I MHC molecule.     

The thymic stromal cell line MTSC4 induced thymocyte apoptosis in a non-MHC-restricted manner

Mouse thymic stromal cell line 4 (MTSC4) is one of the stromal cell lines established in our laboratory. While losing the characteristics of epithelial cells, they express some surface markers shared with thymic dendritic cells (TDCs). To further study the biological functions of these cells, we compared the capability of MTSC4 with TDCs in the induction of thymocyte apoptosis, using thymic reaggregation culture system. Apoptosis of thymocytes induced by MTSC4 and TDCs was measured by Annexin V and PI staining and analyzed by flow cytometry. We found that MTSC4 selectively augmented the apoptosis of CD4^ 8^ (DP) thymocytes. This effect was Fas/FasL independent and could not be blocked by antibodies to MHC class I and class II molecules. In addition, MTSC4 enhanced the apoptosis of DP thymocytes from different strains of mice, which implies that MTSC4-induced thymocyte apoptosis is not mediated by the TCR recognition of self peptide/MHC molecules. In contrast to MTSC4, thymocyte apoptosis induced by TDCs was MHC-restricted. Thus, MHC-independent fashion of stromal-DP thymocyte interaction may be one of the ways to induce thymocyte apoptosis in thymus. Our study has also shown that the interaction of MTSC4 stromal cells and thymocytes is required for the induction of thymocyte apoptosis.     

Autoantigen-independent deletion of diabetogenic CD4+ thymocytes by protective MHC class II molecules

Some MHC class II genes provide dominant resistance to certain autoimmune diseases via mechanisms that remain unclear. We have shown that thymocytes bearing a highly diabetogenic, I-Ag7-restricted beta-cell-reactive TCR (4.1-TCR) undergo negative selection in diabetes-resistant H-2g7/x mice by engaging several different antidiabetogenic MHC class II molecules on thymic (but not peripheral) hemopoietic cells, independently of endogenous superantigens. Here we have investigated 1) whether this TCR can also engage protective MHC class II molecules (I-Ab) on cortical thymic epithelial cells in the absence of diabetogenic (I-Ag7) molecules, and 2) whether deletion of 4.1-CD4+ thymocytes in I-Ab-expressing mice might result from the ability of I-Ab molecules to present the target beta-cell autoantigen of the 4.1-TCR. We show that, unlike I-Ag7 molecules, I-Ab molecules can restrict neither the positive selection of 4.1-CD4+ thymocytes in the thymic cortex nor the presentation of their target autoantigen in the periphery. Deletion of 4.1-CD4+ thymocytes by I-Ab molecules in the thymic medulla, however, is a peptide-specific process, since it can be triggered by hemopoietic cells expressing heterogeneous peptide/I-Ab complexes, but not by hemopoietic cells expressing single peptide/I-Ab complexes. Thus, unlike MHC-autoreactive or alloreactive TCRs, which can engage deleting MHC molecules in the thymic cortex, thymic medulla, and peripheral APCs, the 4.1-TCR can only engage deleting MHC molecules (I-Ab) in the thymic medulla. We therefore conclude that this form of MHC-induced protection from diabetes is based on the presentation of an anatomically restricted, nonautoantigenic peptide to highly diabetogenic thymocytes.