CD45 enhances positive selection and is expressed at a high level in large, cycling, positively selected CD4+CD8+ thymocytes.

T-cell development is arrested at the CD4+CD8+ (DP; double-positive) stage of thymocyte development in CD45 null mice. However, the mechanism by which CD45 participates in the positive selection of T cells remains to be investigated. In this report we describe a DP thymocyte population that associates positive selection with expression of high levels of CD45, CD4 and CD8. DP thymocytes of this phenotype are large, cycling cells and represent approximately 20% of DP thymocytes in normal mice. In mice expressing a transgenic T-cell receptor (TCR) specific for the male antigen presented by H-2Db (H-Y TCR), the up-regulation of TCR, CD5 and CD69 in this large DP population occurred in a major histocompatibility complex (MHC)-restricted manner. To investigate further the role of CD45 in positive selection, we determined whether thymocytes that expressed a transgenic CD45RO molecule under the control of the proximal lck promoter can influence the positive selection of T cells in H-Y TCR transgenic mice. It was found that in female H-Y TCR transgenic mice, MHC-restricted positive selection of CD4- CD8+ H-Y TCR+ thymocytes was enhanced by increased CD45RO expression. Thus, CD45 increases the efficacy of positive selection of CD4- CD8+ thymocytes that express H-Y TCR.     

Reduced CD4 and CD8 Expression in Human Thymuses Treated with Soluble CD4

Recent data suggest that accessory molecules like CD4 and CD8 act as co-receptors in intrathymic T-cell development. Soluble CD4 (sCD4) molecules offer a novel experimental approach to investigate the relevance of CD4 interaction with its putative intrathymic receptor for T-cell maturation. We attempted to inhibit binding of surface CD4 on thymocytes to its intrathymic receptor competitively by introduction of human sCD4 into human thymus tissue cultures. Our results demonstrate that sCD4, while not affecting peripheral T-cell responses as shown in control experiments, significantly affects intrathymic development of T lymphocytes. Immature CD4CD8 double positive (DP) thymocytes responded with reduced expression of both CD4 and CD8 molecules. This phenomenon could be followed up to the stage of single positive (SP) thymocytes: density of CD4 molecules on CD4 SP thymocytes and, even more interestingly, CD8 expression on CD8 SP cells, were reduced, indicating that the effect observed in immature DP thymocytes persists during their further development. Beyond that, analysis of T-cell receptor (TCR) expression in the low density CD4CD8 DP population revealed a slight decrease of alpha beta-TCR surface expression, suggesting a possible role of CD4 engagement in the generation of TCR in man. Since sCD4 is considered a therapeutical agent in HIV infections, these findings are not only of basic but also of clinical interest.     

Antigen-specific and nonspecific deletion of immature cortical thymocytes caused by antigen injection

Analysis of antigen-induced negative selection of thymocytes in T cell receptor (TCR)-transgenic mice is complicated by the presence of an antigen-responsive peripheral T cell compartment. Our experiments address the question of whether and how peripheral T cell activation can affect immature thymocytes. Following three daily injections of peptide antigen into mice expressing a peptide-specific transgenic TCR and deficient for TAP1, we and others have found profound deletion of the CD4⁺CD8⁺ (DP) thymocyte subset. However, our work shows that even though mature CD8⁺ T cells are inefficiently selected in TAP1-deficient mice, there was a striking degree of peripheral expansion and activation of CD8⁺ peripheral T cells. Furthermore, when cells from TCR-transgenic mice were adoptively transferred, we found that deletion of non-transgenic DP thymocytes occurred in Thy-1-congenic and even more efficiently in TAP1-deficient recipients after repeated peptide injection resulting in peripheral T cell activation. In the adoptive transfer experiments the degree of deletion of immature bystander thymocytes was decreased upon blocking of TNF. These data show that deletion of DP thymocytes can result from excessive peripheral T cell activation and identify TNF as an important effector molecule for this process. When steps are taken to avoid peripheral T cell activation, peptide antigen can induce TCR-mediated thymocyte deletion, presumably in the thymus cortex, since injection of TAP1-deficient TCR-transgenic mice resulted in deletion of immature DP thymocytes prior to detectable peripheral T cell expansion and activation. This effect was not blocked by inhibiting tumor necrosis factor activity. In addition, DP depletion was seen in the absence of peripheral T cell activation when antibody-mediated depletion of CD8⁺ T cells was performed. Our work clearly shows that two mechanisms for deletion of DP thymocytes exist: deletion induced by antigen presentation in the thymus and deletion as a consequence of repeated stimulation of mature peripheral T cells.     

Gene expression analysis of thymocyte selection in vivo

Self versus non-self discrimination is a key feature of immunorecognition. Through TCR-activated apoptotic mechanisms, autoreactive thymocytes are purged at the CD4(+)CD8(+) double-positive (DP) precursor stage prior to maturation to CD4(+) or CD8(+) single-positive (SP) thymocytes. To investigate this selection process in vivo, gene expression analysis by oligonucleotide array was performed in TCR transgenic mice. In total, 244 differentially expressed DP thymocyte genes induced or repressed by TCR triggering in vivo were identified. Genes involved in the biological processes of apoptosis, DNA recombination, antigen processing and adhesion are coordinately engaged. Moreover, analysis of gene expression in thymocyte subsets revealed that TCR ligand-induced expression profiles vary according to their developmental stage, with 48 genes showing DP preference and nine showing SP thymocyte preference. Finally, our data suggest that both the extrinsic and the intrinsic apoptosis pathways are operating in thymic selection.     

Accelerated transition from the double-positive to single-positive thymocytes in G alpha i2-deficient mice

Deletion of alpha i2 subunit of heterotrimeric G proteins induces a 2-4-fold increase in the proportions of CD4 and CD8 single-positive (SP) thymocytes as compared with wild-type littermates, but how G alpha i2 is involved in thymocyte development is unknown. To determine a role for G alpha i2 in a specific developmental stage of thymocyte differentiation, we studied the ontogeny of thymocytes in G alpha i2-deficient mice. Our data show that an accelerated transition from the double-positive (DP) to SP thymocytes, rather than impairment in thymic emigration, accounts for a high proportion of the SP thymocytes in the absence of G alpha i2. Lack of G alpha i2 greatly augmented a response of thymocytes to TCR-mediated stimulation, as evidenced by enhanced proliferation of the DP thymocytes upon ligation of the TCRs. The augmented response may be the reason behind the expedited transition from the DP to SP thymocytes in the animal. In accordance with this, effects of G alpha i2 deficiency on CD8 or CD4 SP thymocyte differentiation required engagement of the TCRs with either MHC class I or MHC class II molecule. The abnormal thymocyte development resulted in an increase in positive selection, altered usage of TCR Vbeta gene, aberrant development of CD4+ CD25+ T regulatory cells and untimely thymic involution, the contribution of which to colitis development in the animal is discussed. These findings reveal a previously unappreciated role for G alpha i2 protein in clonal selection and functionality of thymocytes.     

V?Gene Family Usage in Spontaneous Lymphomas of AKR Mice: Evidence for Defective Clonal Deletion

T-cell receptor (TCR) ß-chain usage and expression of the CD3, CD4, and CD8 differentiation antigens were analyzed in 14 spontaneous AKR lymphomas. Lymphoma cells massively infiltrated and/or proliferated in the organs analyzed (thymus, spleen, and mesenteric lymph nodes), giving rise to a loss of organ structure. One lymphoma occurred only in the thymus, and failed to express CD3, CD4, and CD8. All other lymphomas expressed the CD3/TCR complex. With respect to CD4 and CD8 expression, the lymphomas were either double-negative (DN), double-positive (DP), or single-positive (SP). The frequency of DP (CD4⁺8⁺) lymphomas was low compared to the frequency of DP thymocytes in a normal AKR thymus. A substantial heterogeneity was seen in the intensity of CD4 and CD8 expression among various lymphomas, which was independent of the level of CD3 expression. Considering TCR V ß gene family usage, 2 out of 14 lymphomas expressed V ß6. Normally, V ß6⁺ thymocytes are deleted from the thymocyte pool at the immature DP stage of T-cell development in AKR mice. These data support the hypothesis that the lymphocytes in the immature DP stage of T-cell development are susceptible to the induction of AKR lymphomagenesis. The presence of V ß6⁺ lymphoma cells indicates that the lymphomagenesis is accompanied by a defective clonal deletion of cells expressing a possible autoreactive TCR.     

TCR and Notch signaling in CD4 and CD8 T-cell development

Summary:  The generation of CD4 and CD8 αβ T-cell lineages from CD4⁺CD8⁺ double-positive (DP) thymocyte precursors is a complex process initiated by engagement of major histocompatibility complex (MHC) by T-cell receptor (TCR) and coreceptor. Quantitative differences in TCR signaling induced by this interaction impose an instructional bias on CD4/CD8 lineage commitment that must be reinforced by MHC recognition and TCR signaling over subsequent selection steps in order for the thymocyte to progress and mature in the adopted lineage. Our studies show that the transmembrane receptor Notch plays a role in this process by modifying TCR signal transduction in DP thymocytes. In this review, we consider the functional relationship of TCR and Notch signaling pathways in the selection and specification of CD4 and CD8 T-cell lineages.     

Expression of the Bcl-2 family member A1 is developmentally regulated in T cells.

During T cell development, cells that fail to meet stringent selection criteria undergo programmed cell death. Thymocyte and peripheral T cell susceptibility to apoptosis is influenced by expression of Bcl-2 family members, some of which are expressed in a developmentally patterned manner. We previously showed developmentally regulated expression of A1, an anti-apoptotic Bcl-2 family member, among B cell developmental subsets. Here we show that cells of the T lineage also express A1 in a developmentally regulated manner. Both A1 mRNA and A1 protein are readily detectable in the thymus, and while present among DN cells, A1 mRNA is up-regulated to very high levels among double-positive (DP) thymocytes. It is then down-regulated to moderate levels among single-positive (SP) thymocytes, and finally expressed at approximately 25-fold lower levels among mature SP CD4(+) and CD8(+) lymph node T cells than among DP thymocytes. Furthermore, we find that in vitro TCR ligation up-regulates A1 expression among both DP and SP thymocytes. Together, these data show that A1 expression is developmentally regulated in T lymphocytes and is responsive to TCR signaling, suggesting that A1 may play a role in maintaining the viability of DP thymocytes.     

Vascular cell adhesion molecule-1 (VCAM-1) and intercellular adhesion molecule-1 (ICAM-1) provide co-stimulation in positive selection along with survival of selected thymocytes

T-cell differentiation in the thymus depends on positive selection of CD4+CD8+ double positive (DP) thymocytes by thymic major histocompatibility complex (MHC) molecules. Positive selection allows maturation of only those thymocytes that are capable of self-peptide-MHC recognition. Thymocytes that fail to bind self-peptide-MHC die by apoptosis. An important question in thymocyte differentiation is whether co-stimulation is required for positive selection and on which cells co-stimulatory molecules may be expressed in the thymus. The vascular cell adhesion molecule (VCAM-1) and the intercellular cell adhesion molecule (ICAM-1) are known to be potent co-stimulatory molecules in activation of peripheral T-cells by interacting with the integrins VLA-4 and LFA-1, respectively. We were prompted to investigate whether VCAM-1 and ICAM-1 may also act as co-stimulators during selection of thymocytes. By using recombinant proteins of murine VCAM-1 and ICAM-1 fused to the Fc region of human IgG1 (rVCAM-1, rICAM-1) we examined the capacity of VCAM-1 and ICAM-1 to act as co-stimulatory molecules in positive selection in vitro. Triggering the CD3/TCR complex together with co-stimulation applied by rVCAM-1 or rICAM-1 induced the generation of CD4+ single positive (SP) thymocytes from CD4+CD8+ DP thymocytes whereas either signal alone did not result in generation of CD4+ SP thymocytes. VCAM-1 and ICAM-1 act therefore as co-stimulatory molecules in thymocyte positive selection in vitro. The generation of CD4+ SP cells is accompanied by cell survival both when it was co-stimulated with rVCAM-1 and with rICAM-1. Importantly we show here that VCAM-1 expression in the murine thymus is restricted to cortical F4/80 positive hematopoietic antigen presenting cells (hAPC) present exclusively in the cortex whereas expression of ICAM-1 has been reported on the epithelium both in cortex and medulla. This suggests that not only the cortical epithelium may use the co-stimulatory molecule ICAM-1 to mediate positive selection, but also cortical hAPCs may contribute to positive selection of thymocytes by using the co-stimulator VCAM-1.     

A novel role for CD28 in thymic selection: elimination of CD28/B7 interactions increases positive selection

While the importance of the CD28/B7 costimulation pathway is well established for mature T cells, the role of CD28 in thymocyte selection is less well defined. The role of CD28 in both negative and positive selection was assessed using H-Y-specific TCR-transgenic (Tg) RAG-2-deficient (H-Yrag) mice. Negative selection in male H-Yrag mice was not affected by deficiency in CD28 or B7. Surprisingly, absence of CD28 or B7 in H-Yrag females resulted in increased numbers of CD8 single-positive (SP) thymocytes. The CD8 SP thymocytes found in these females were mature and functionally competent. Furthermore, double-positive (DP) thymocytes from CD28-knockout (CD28KO) or B7.1/B7.2 double-KO (B7DKO) females had higher levels of both CD5 and TCR than those from WT females, consistent with a stronger selecting signal. CD28KO H-Yrag fetal thymic organ cultures also had elevated numbers of thymic CD8 SP cells, reflecting increased thymic differentiation and not recirculation of peripheral T cells. Finally, increased selection of mature CD4 and CD8 SP T cells was observed in non-TCR-Tg CD28KO and B7DKO mice, indicating that this function of CD28-B7 interaction is not unique to a TCR-Tg model. Together these findings demonstrate a novel negative regulatory role for CD28 in inhibiting differentiation of SP thymocytes, probably through inhibition of thymic selection.     

Strength of TCR signal from self‐peptide modulates autoreactive thymocyte deletion and Foxp3+ Treg‐cell formation

Autoreactive CD4⁺CD8^? (CD4SP) thymocytes can be subjected to deletion when they encounter self‐peptide during their development, but they can also undergo selection to become CD4SPFoxp3⁺ Treg cells. We have analyzed the relationship between these distinct developmental fates using mice in which signals transmitted by the TCR have been attenuated by mutation of a critical tyrosine residue of the adapter protein SLP‐76. In mice containing polyclonal TCR repertoires, the mutation caused increased frequencies of CD4SPFoxp3⁺ thymocytes. CD4SP thymocytes expressing TCR Vβ‐chains that are subjected to deletion by endogenous retroviral superantigens were also present at increased frequencies, particularly among Foxp3⁺ thymocytes. In transgenic mice in which CD4SP thymocytes expressing an autoreactive TCR undergo both deletion and Treg‐cell formation in response to a defined self‐peptide, SLP‐76 mutation abrogated deletion of autoreactive CD4SP thymocytes. Notably, Foxp3⁺ Treg‐cell formation still occurred, albeit with a reduced efficiency, and the mutation was also associated with decreased Nur77 expression by the autoreactive CD4SP thymocytes. These studies provide evidence that the strength of the TCR signal can play a direct role in directing the extent of both thymocyte deletion and Treg‐cell differentiation, and suggest that distinct TCR signaling thresholds and/or pathways can promote CD4SP thymocyte deletion versus Treg‐cell formation.     

Exogenous Thy-1.1 expression as a marker for thymocyte maturation in transgenic mice.

We established a line of transgenic mice carrying the exogenous mouse Thy-1.1 gene (8.2 Kb Eco RI genomic DNA fragment). In these mice, Thy-1.1 was expressed on thymocytes but not on peripheral T cells, presumably due to the lack of cis-acting element(s) on the microinjected genomic DNA. Even in the thymus, however, while most of the CD3/TCR- thymocytes were positive for the transgenic Thy-1.1 gene expression, the CD4+ or CD8+ single positive (SP) thymocytes were composed of two groups, one Thy-1.1+ and one Thy-1.1-, suggesting that the former belongs to cells at premature stages of terminal T cell differentiation. There was no difference in the amount of CD3/TCR complexes expressed on two such SP thymocyte subsets. In the double negative (DN) thymocytes, all the CD3/TCR+ cells were Thy-1.1-. These results suggest that the maturational process of CD3+ DN thymocytes differs from that of SP thymocytes. The unique distribution of Thy-1.1+ population among CD3+ thymocytes suggests that the transgenic Thy-1.1 gene expression can serve as a useful marker to examine terminal maturation processes of CD3+ thymocytes.     

Glucocorticoid (GC) sensitivity and GC receptor expression differ in thymocyte subpopulations

Positive and negative selection steps in the thymus prevent non-functional or harmful T cells from reaching the periphery. To examine the role of glucocorticoid (GC) hormone and its intracellular receptor (GCR) in thymocyte development we measured the GCR expression in different thymocyte subpopulations of BALB/c mice with or without previous dexamethasone (DX), anti-CD3 mAb, RU-486 and RU-43044 treatment. Four-color labeling of thymocytes allowed detection of surface CD4/CD8/CD69 expression in parallel with intracellular GCR molecules by flow cytometry. Double-positive (DP) CD4+CD8+ thymocytes showed the lowest GCR expression compared to double-negative (DN) CD4-CD8- thymocytes and mature single-positive (SP) cells. DX treatment caused a concentration-dependent depletion of the DP cell population and increased appearance of mature SP cells with reduced GCR levels. GCR antagonists (RU-486 or RU-43044) did not influence the effect of DX on thymocyte composition; however, RU-43044 inhibited the high-dose GC-induced GCR down-regulation in SP and DN cells. GCR antagonists alone did not influence the maturation of thymocytes and receptor numbers. Combined low-dose anti-CD3 mAb and DX treatment caused an enhanced maturation (positive selection) of thymocytes followed by the elevation of CD69+ DP cells. The sensitivity of DP thymocytes with a GCRlow phenotype to GC action and the ineffectiveness of the GCR antagonist treatment may reflect a non-genomic GC action in the thymic selection steps.     

Death of T cell precursors in the human thymus: a role for CD38

Thymic T cell maturation depends on interactions between thymocytes and cells of epithelial and hematopoietic lineages that control a selective process whereby developing T cells with inappropriate or self-reactive receptors die. Molecules involved in this process are the TCR expressed on thymocytes together with the CD3 complex and MHC-peptide on accessory cells. However, other molecules may favor or prevent death of thymocytes, thus playing a role in selection. CD38 is expressed by the majority of human thymocytes, mainly at the double-positive (DP) stage. In contrast, CD38 is not found on subcapsular double-negative (DN) thymocytes and on a proportion of medullary single-positive (SP) thymocytes. CD38 enhances death of thymocytes when it is cross-linked by goat anti-mouse (GAM) antiserum or by one of its ligands, CD31, expressed by thymic epithelial cells or transfected into murine fibroblasts (L cells). As most thymocytes are at an intermediate (DP) stage of development, it is likely that these cells are most vulnerable to death mediated via MHC-peptide-TCR interactions that is increased by CD38 cross-linking. DN and SP thymocytes are refractory to CD38-induced apoptosis. Accessory molecules, e.g. CD38, are expressed during thymic cell maturation and their presence is relevant for the survival or death of DP T cells in the course of selection. Based on our data, CD38 enhances thymocyte death by interacting with CD31 expressed by accessory cells. In addition, CD28 expression on developing thymocytes also appears to play a role for their selection and it synergizes with CD38 to induce apoptosis of DP thymocytes.     

Thymocyte‐derived BDNF influences T‐cell maturation at the DN3/DN4 transition stage

Brain‐derived neurotrophic factor (BDNF) promotes neuronal survival, regeneration, and plasticity. Emerging evidence also indicates an essential role for BDNF outside the nervous system, for instance in immune cells. We therefore investigated the impact of BDNF on T cells using BDNF knockout (KO) mice and conditional KO mice lacking BDNF specifically in this lymphoid subset. In both settings, we observed diminished T‐cell cellularity in peripheral lymphoid organs and an increase in CD4⁺CD44⁺ memory T cells. Analysis of thymocyte development revealed diminished total thymocyte numbers, accompanied by a significant increase in CD4/CD8 double‐negative (DN) thymocytes due to a partial block in the transition from the DN3 to the DN4 stage. This was neither due to increased thymocyte apoptosis nor defects in the expression of the TCR‐β chain or the pre‐TCR. In contrast, pERK but not pAKT levels were diminished in DN3 BDNF‐deficient thymocytes. BDNF deficiency in T cells did not result in gross deficits in peripheral acute immune responses nor in changes of the homeostatic proliferation of peripheral T cells. Taken together, our data reveal a critical autocrine and/or paracrine role of T‐cell‐derived BDNF in thymocyte maturation involving ERK‐mediated TCR signaling pathways.