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.     

The expression of Bcl-2 family proteins (Bcl-2, Bcl-x, Bax, Bak and Bim) in human lymphocytes

Bcl-2 family proteins regulate programmed cell death, and may play an important role in the selection of lymphocytes. We investigated the expression of Bcl-2, Bcl-x, Bax, Bak and Bim in human lymphocytes using flow-cytometry. Bcl-2 was down-regulated in CD4(+)8(+) (DP) thymocytes and CD19(+)38(+) tonsillar lymphocytes (GC B cells). Among DP thymocytes, cells co-expressing CD69 up-regulated Bcl-2, suggesting that the role of Bcl-2 is promoting survival of positively selected DP cells. Unexpectedly, the expression level of Bcl-x was higher in DP cells than in Single Positive (SP) cells and in CD69(+) DP thymocytes it was lower than in CD69(+) DP thymocytes. Expression of Bim was low in DP thymocytes but high in a subset of GC B cells. Bim and Bax were expressed more highly in SP than in DP thymocytes. Among peripheral blood lymphocytes (PBL), CD8(+) T cells expressed an approximately ten-fold higher level of Bcl-x than CD4(+) T cells while both subsets expressed similar levels of Bcl-2. Bak expression was low and Bim expression was absent in PBL. These results suggest that not only Bcl-2 but other members of the Bcl-2 family are involved in T cell development in the thymus and affinity maturation of B cells in the germinal center.     

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.     

Involvement of CCR9 at multiple stages of adult T lymphopoiesis

The chemokine CCL25 is constitutively expressed in the thymus, and its receptor CCR9 is expressed on subsets of developing thymocytes. Nevertheless, the function of CCL25/CCR9 in adult thymopoiesis remains unclear. Here, we demonstrate that purified CCR9(-/-) hematopoietic stem cells are deficient in their ability to generate all major thymocyte subsets including double-negative 1 (DN1) cells in competitive transfers. CCR9(-/-) bone marrow contained normal numbers of lineage(-) Sca-1+c-kit+, common lymphoid progenitors, and lymphoid-primed multipotent progenitors (LMPP), and CCR9(-/-) LMPP showed similar T cell potential as their wild-type (WT) counterparts when cultured on OP9-delta-like 1 stromal cells. In contrast, early thymic progenitor and DN2 thymocyte numbers were reduced in the thymus of adult CCR9(-/-) mice. In fetal thymic organ cultures (FTOC), CCR9(-/-) DN1 cells were as efficient as WT DN1 cells in generating double-positive (DP) thymocytes; however, under competitive FTOC, CCR9(-/-) DP cell numbers were reduced significantly. Similarly, following intrathymic injection into sublethally irradiated recipients, CCR9(-/-) DN cells were out-competed by WT DN cells in generating DP thymocytes. Finally, in competitive reaggregation thymic organ cultures, CCR9(-/-) preselection DP thymocytes were disadvantaged significantly in their ability to generate CD4 single-positive (SP) thymocytes, a finding that correlated with a reduced ability to form TCR-MHC-dependent conjugates with thymic epithelial cells. Together, these results highlight a role for CCR9 at several stages of adult thymopoiesis: in hematopoietic progenitor seeding of the thymus, in the DN-DP thymocyte transition, and in the generation of CD4 SP thymocytes.     

Cyclosporine A prevents the generation of single positive mature T cells in newborn mice

The effect of Cyclosporin A (CsA) during T cell development was investigated in newborn mice. CsA treatment completely blocked the generation of peripheral single positive (SP) mature T cells: the lymphatic tissues were hypoplastic. However, double negative (DN) T3 expressing lymphocytes were still detectable. Thymuses from CsA-treated mice lacked the SP L3T4(CD4)+ subset, DN and double positive (DP) thymocytes were still present. We further defined a SP Lyt2(CD8)+ thymic subpopulation which lacked CD3 expression and displayed no functional activity in vitro. Thus, CsA critically interferes with the maturation of SP T lymphocytes; we found no evidence for 'leaky' autoreactive peripheral SP T cells in CsA-treated newborn mice.     

Metalloproteinase-dependent control of thymocyte differentiation and proliferation

The development of T cells in the thymus is dependent on interactions between thymocytes and thymic stromal cells, on stimulation by growth factors, and on the binding to and migration along extracellular matrix (ECM) components. As metalloproteinases (MP) are involved in processes such as growth factor release and ECM modelling, we assessed the effect of MP inhibitors on T-cell development using fetal thymic organ culture systems. MP inhibitors significantly reduced the numbers of CD4/CD8 double-positive (DP) and mature single-positive thymocytes generated, correlated with a reduced number of cell cycles between the double-negative (DN)3 and DP stages. The progression of early thymocyte progenitors through the DN1-4 stages of development was also severely affected, including incomplete upregulation of CD25, decreased DN3 cell numbers, reduced rearrangement of the T-cell receptor (TCR)-beta locus and expression of intracellular TCR-beta by fewer DN3 cells. When purified DN1 cells were utilized as donor cells in reaggregate thymic organ cultures, essentially no DP thymocytes were produced in the presence of MP inhibitors. The results suggest that MP inhibitors affect the differentiation of developing thymocytes before, and reduce proliferation after, pre-TCR-mediated selection.     

In vitro differentiation and commitment of CD4+ thymocytes to the CD4+ lineage without TCR engagement

Thymocyte positive selection is based on protection of immatureCD4/CD8 double-positive (DP) thymocytes from apoptosis and theirdifferentiation into CD4 or CD8 single-positive (SP) cells.Intracellular signals essential for positive selection appearto be induced through the TCR and some of the accessory moleculesincluding LFA-1, CD4 and CD8 upon Interaction with thymic stromalcells. The signals, however, still remain to be identified.Since physiological levels of glucocorticoids potentially induceor enhance thymocyte apoptosis even in vivo, the signals arelikely to inhibit the apoptotic effect of glucocorticoids. Wehave previously shown that proper cross-linking of TCR-CD3 withLFA-1, CD4 or CD8 inhibited glucocortlcold-lnduced thymocyteapoptosis in vitro, and that a proper combination of the calciumionophore, ionomycin and the protein kinase C (PKC) activator,phorbol 12-myrlstate 13-acetate (PMA), mimicked the inhibitoryeffect. Here we determined whether this combination of ionomycinand PMA induces differentiation of isolated DP thymocytes fromnormal and TCR transgenic mice. We found that pretreatment ofDP thymocytes with ionomycin and PMA followed by 1 day cultureof the cells without the reagents resulted in the differentiationof the cells into CD4 SP and CD4⁺ CD8^lo T cells that have mostlycommitted to the CD4 lineage. The changes in expression of otherdifferentiation markers were also in good accordance with thoseassociated with positive selection, except the final maturation.The results indicate that moderate and transient increases inintracellular Ca²⁺ level and PKC activity induce differentiationand commitment of DP thymocytes to the CD4 lineage, and suggestedthat the biochemical pathway leading to positive selection isbased on a similar mechanism.     

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.     

Protein phosphatase subunit G5PR that regulates the JNK-mediated apoptosis signal is essential for the survival of CD4 and CD8 double-positive thymocytes

Early T lineage cells are selected in the thymus by the specific recognition of peptide components presented by MHC molecules on the surface of thymic epithelial cells and dendritic cells. As a potential regulator of the apoptotic and survival signals, the protein phosphatase 2A-component G5PR regulates Bim phosphorylation in B-cells. Here, we studied whether G5PR is involved in the regulation of the similar apoptotic pathway for cell survival during the selection of thymocytes. T-cell-specific G5PR knockout (G5pr(-/-)) mice displayed thymic atrophy, significant reduction in thymocyte numbers, particularly a 10-fold decrease in the number of CD4 and CD8 double-positive (DP) thymocytes and few mature single-positive (SP) cells. G5pr(-/-) thymocytes exhibited normal potential of proliferation and differentiation during the transition from double-negative (DN) to DP stage, but significantly increased susceptibility to apoptosis at the DP stage. G5PR deficiency did not affect on Bim activation in thymocytes, but caused hyper-activation of JNK and Caspase-3 with augmented Fas ligand (FasL) expression, indicating that G5PR regulates the thymocyte unique apoptotic signal involved in JNK-mediated Caspase-3 activation but not in Bim activation. G5PR is essential for the survival of DP cells during thymocyte development.     

Effect of murine thymic epithelial cell line (MTEC1) on the functional expression of CD4(+)CD8(-) thymocyte subgroups

To determine the effect of thymic stromal cells on the functional maturation of CD4 single-positive (SP) thymocytes, the functional status of isolated CD4 SP thymocyte subgroups was investigated by means of cell proliferation and cytokine production in response to concanavalin A (Con A) prior and after co-culturing with a murine thymic epithelial cell line (MTEC1). Mouse medullary CD4 SP thymocytes were phenotypically divided into seven discrete subgroups predicted to reflect the maturation pathway from newly emerging CD4 SP thymocytes to terminally differentiated cells. For functional analysis, six major subgroups (6C10(+)CD69(+), 6C10(-)CD69(+), 6C10(-)CD69(-)3G11(+)Qa-2(-), 6C10(-)CD69(-)3G11(+)Qa-2(+), 6C10(-)CD69(-)3G11(-)Qa-2(-) and 6C10(-)CD69(-)3G11(-)Qa-2(+)) cells were isolated and their functional status in response to Con A stimulation assessed. A functional hierarchy is revealed among these subgroups, consistent with their phenotypic maturation status, which may imply that these cells undergo a functional maturation process within thymic medulla. The function of cytokine production by CD4 SP thymocytes is acquired in a stepwise manner from a low to high level and characterized by T(h)0-type cytokines in the main stream of differentiation pathway. However, a minor subgroup that appeared at the late stage as 3G11(-)6C10(-) cells was biased to produce T(h)2-type cytokines. Nevertheless, the functional capacity of the final two Qa-2(+) subgroups of CD4 SP thymocytes was still significantly lower than that of spleen CD4(+) T cells. After co-cultivation with MTEC1 cells, four subgroups of TCRalphabeta(+)CD4(+)CD8(-) thymocytes exhibited significantly higher levels of proliferation capability and modulation in cytokine production capability. However, co-culturing with MTEC1 cells did not change the pattern of T(h)0- or T(h)2-like cytokine production by respectively medullary CD4 SP thymocyte subgroups nor could MTEC1 induce CD4 SP thymocytes to secrete T(h)1-type cytokines. The results suggest that MTEC1 can regulate the functional status of these thymocyte subgroups.     

Maturation of CD4-8- alpha/beta TCR+ T cells induced by CD2-stimulation in vivo and in vitro.

Newly generated ('virgin') rat thymocytes of the immature CD4+8+ double positive (DP) subset were treated in suspension culture for 2 days with the stimulatory pair of anti-CD2 monoclonal antibodies OX-54 and OX-55. Approximately 50% of the recovered cells had downregulated CD4 and CD8 and upregulated the T cell antigen receptor (TCR). CD2-stimulated, but not control thymocytes proliferated in response to TCR plus IL-2 stimulation. In vivo, postnatal injection of OX-54/55 led to a dramatic and selective increase in functionally mature CD4-CD8- double negative (DN) alpha/beta--TCR(high) thymocytes and peripheral T cells. These findings show that CD2 stimulation can promote T cell differentiation and suggest that DN TCR(high) thymocytes can be generated from DP thymocytes via alternative pathways of T cell maturation.     

Development of autoreactive diabetogenic T cells in the thymus of NOD mice

Type 1 diabetes results from destruction of pancreatic beta cells by beta cell-specific autoreactive T cells in the nonobese diabetic (NOD) mouse. Defects in thymic negative selection are thought to result in failure to delete potential beta cell-reactive T cells, contributing to the development of autoimmune diabetes. We investigated this possibility by comparing the deletion profile of double-positive (DP) thymocytes in NOD mice with diabetes-resistant strains of mice after anti-CD3 Ab treatment to trigger the TCR-mediated signaling pathway. We found that immature NOD CD4+CD8+ DP thymocytes have a lower activation threshold than C57BL/6 and Balb/c thymocytes. This was confirmed by showing that NOD DP thymocytes have a higher level of ERK and JNK phosphorylation. The low activation threshold of immature thymocytes resulted in rapid deletion of strongly activated immature DP thymocytes by negative selection, whereas weakly activated immature thymocytes differentiated more efficiently into CD69+CD3high DP thymocytes by positive selection. SP thymocytes, particularly CD4-CD8+ T cells that were efficiently generated from activated DP thymocytes, could induce severe insulitis and diabetes in NOD.scid mice. We conclude that the development of autoreactive diabetogenic T cells results from inordinate positive selection due to the low activation threshold of DP thymocytes in NOD mice.     

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.     

Alterations during positive selection in the thymus of nackt CD4-deficient mice

The T-cell repertoire is shaped by the positive and negative selection of immature CD4(+) CD8(+) double positive (DP) thymocytes. Positive selection of DP T cells to the CD4(+) CD8(-) and CD4(-) CD8(+) simple positive (SP) lineages is a multistep process which involves cellular interactions between thymocytes and stromal cells. Mutant nackt (nkt/nkt) mice have been shown to have a deficiency in the CD4(+) CD8(-) T-cell subset both in the thymus and in the periphery. The present report suggests that nkt/nkt mice present alterations in early steps of positive selection because they show decreases in the percentages of CD69(+) and CD5(+) cells within the DP subset. Experiments involving bone marrow transfer and thymic chimeras demonstrate that the thymic epithelium of nkt/nkt mice is involved in the alterations registered during positive selection and dictates the ultimate fate of CD4(+) SP cells.     

GATA-3 expression is controlled by TCR signals and regulates CD4/CD8 differentiation

GATA-3 is expressed at higher levels in CD4 than in CD8 SP thymocytes. Here we show that upregulation of GATA-3 expression in DP thymocytes is triggered by TCR stimulation, and the extent of upregulation correlates with the strength of the TCR signal. Overexpression of GATA-3 or a partial GATA-3 agonist during positive selection inhibits CD8 SP cell development but is not sufficient to divert class I-restricted T cell precursors to the CD4 lineage. Conversely, expression of the GATA-3 antagonist ROG or of a GATA-3 siRNA hairpin markedly enhances development of CD8 SP cells and reduces CD4 SP development. We propose that GATA-3 contributes to linking the TCR signal strength to the differentiation program of CD4 and CD8 thymocytes.     

Heterogeneity of the DN4 (CD44-CD25-) subset of CD4-CD8- double negative thymocytes; dependence on CD3 signaling

Recent studies have shown that apoptotic cell death associated with selection for thymocytes that express clonotypic TCRbeta or TCRgammadelta proteins takes place in the DN4 (CD44-CD25-) subset of CD4-CD8- double negative (DN) thymocytes. A detailed analysis of the DN4 subset is therefore of interest. Using intracellular (IC) staining for clonotypic TCR and CD3varepsilon proteins we find that DN4 cells consist of five subpopulations: TCRbetaIC(high)/CD3varepsilonIC(high)/TCRgammadeltaIC-, TCRbetaI-C-/CD3varepsilonIC(high)/TCRgammadeltaIC(+), TCRbetaIC(high)/CD3varepsilonIC(high)/TCRgammadeltaIC(+), TCRbetaIC(low)/CD3varepsilonIC(low)/TCRgammadeltaIC(-), and TCRbetaIC(-)/CD3varepsilonIC(-)/TCRgammadeltaIC(-). Expression levels of IC TCRbeta/CD3varepsilon, and of Thy1.2, CD2, and CD69 at the cell surface suggest that the TCRbetaIC(low)/CD3varepsilonIC(low)/TCRgammadeltaIC(-) subset harbors the direct precursors of DP cells, and is critical for life/death decisions in early thymic selection. TCRbeta/CD3varepsilon downregulation is less pronounced in DN4 and DP cells of mice deficient for CD3zeta or for p56(lck), suggesting that the dynamics of TCR protein regulation in the DN4 subset is dependent on CD3 signaling.     

Developmentally Regulated Expression of the Transmembrane Adaptor Protein TRIM in Fetal and Adult T Cells

TRIM is a recently identified transmembrane adaptor protein which is exclusively expressed in T cells and natural killer (NK) cells. In peripheral blood T cells TRIM has been reported to coprecipitate, comodulate, and cocap with the T-cell receptor (TCR), suggesting that it is an integral component of the TCR/CD3/zeta complex. Here we investigate the expression of TRIM mRNAs and proteins in developing thymocytes. Two splicing isoforms with open reading frames are observed, namely a full length (TRIM) and a truncated version (DeltaTM-TRIM). The latter lacks the extracellular and transmembrane domains as well as the first 10 cytoplasmic aminoacids and is significantly expressed only as mRNA in early fetal thymocytes. TRIM mRNA is detected in all mainstream thymocyte subsets in adult mice. TRIM protein, in contrast, first appears in the DN2 (CD44+ CD25+) subset of adult double negative (DN) cells. In fetal thymocyte development, TRIM mRNA is seen from dg 14.5 onwards whereas TRIM protein appears first on dg 16.5. In contrast to the adult, the TRIM protein was seen in a subset of fetal DN1 cells. In fetal and adult thymocytes, TRIM protein expression was highest in DN2, DN3 (CD44-25+) and in DP cells, compatible with a functional role at or around phases of thymic selection.     

A cortisone sensitive CD3low subset of CD4+CD8- thymocytes represents an intermediate stage in intrathymic repertoire selection.

Two populations of CD4 single positive (SP) thymocytes were found in transgenic mice bearing class I-restricted Mls-1a reactive (V beta 8.1) TCR genes in the absence of the restriction element. CD3high CD4 SP cells were deleted in the presence of Mls-1a and were cortisone resistant, whereas CD3low CD4 SP cells were not deleted in the presence of Mls-1a and were cortisone sensitive. Intravenous transfer of CD3low CD4 SP cells into nude mice resulted in significant peripheral expansion of these cells with apparent upregulation of CD3. These data indicate that CD3low CD4 SP thymocytes represent an intermediate stage in the transition from CD3low double positive (DP) to CD3high SP thymocytes and raise the possibility that these cells may hve undergone positive but not negative selection events (at least to Mls-1a). Furthermore the fact that CD3high DP thymocytes were also deleted by Mls-1a in these mice suggests strongly that sensitivity to Mls-1a deletion is dependent upon stage of thymic maturation (as revealed by TCR density) rather than CD4/CD8 phenotype.