The lck promoter-driven expression of the Wilms tumor gene WT1 blocks intrathymic differentiation of T-lineage cells

In the thymi of WT1-transgenic (Tg) mice with the 17AA+/KTS- spliced form of the Wilms tumor gene WT1 driven by the lck promoter, the frequencies of CD4-CD8- double-negative (DN) thymocytes were significantly increased relative to those in normal littermates. Of the 4 subsets of CD4-CD8- DN thymocytes, the DN1 (CD44+CD25-) subset increased in both frequency and absolute cell number, whereas the DN2 (CD44+CD25+) and DN3 (CD44-CD25+) subsets decreased, indicating the blocking of thymocyte differentiation from the DN1 to the DN2 subsets. Furthermore, CD4-CD8+ T-cell receptor (TCR) -gammadelta T-cells increased in both frequency and absolute cell number in the spleen and peripheral blood of the WT1-Tg mice relative to those of normal littermates. The CD8 molecules of these CD4-CD8+ TCRgammadelta T-cells were CD8alphabeta, suggesting that they originated from the thymus. These results are the first direct evidence demonstrating that the WT1 gene is involved in the development and differentiation of T-lineage cells.     

Bcl-2 expression during T-cell development: early loss and late return occur at specific stages of commitment to differentiation and survival.

During T-cell development CD3-CD4-CD8- (double-negative) thymocytes proliferative and produce an enormous number of CD3loCD4+CD8+ (double-positive) thymocytes which are destined to die intrathymically unless rescued by positive selection. Those which survive become mature CD3hiCD4/8+ (single-positive) cells and are the precursor of peripheral blood lymphocytes. The product of the bcl-2 protooncogene has been implicated in preventing programmed cell death and is required for prolonged lymphocyte survival following maturation. Previously we and others have reported that Bcl-2 protein expression is biphasic, being high in proliferating double-negative stem cells, low in all double-positive thymocytes except for 1-5% of these cells, and restored in mature, single-positive thymocytes. However, it remained unclear which signaling and selection events regulate Bcl-2 during T-cell maturation. Now we have utilized four-color flow cytometry in normal and genetically altered mice for a detailed analysis of Bcl-2 expression as it relates to T-cell receptor (TCR) expression and positive selection. These studies show that (i) expression of a transgenic TCR in double-negative thymocytes does not lead to premature loss of Bcl-2; thus, Bcl-2 downregulation is not solely due to TCR expression; (ii) Bcl-2 expression is lost at the early transitional CD3-/loCD4-CD8+ stage, prior to expression of CD4; (iii) the Bcl-2+ double-positive thymocytes are those which have undergone positive selection; and (iv) upregulation of Bcl-2 during positive selection requires participation of the CD4 or CD8 co-receptor. These results demonstrate that Bcl-2 and TCR expression are regulated independently during T-cell development, and suggest a role for the CD4 or CD8 co-receptor in Bcl-2 induction during positive selection.     

Early human thymocyte proliferation is regulated by an externally controlled autocrine transforming growth factor-beta 1 mechanism

Early thymocytes undergo extensive proliferation after their entry into the thymus, but cellular interactions and cytokines regulating this intrathymic step remain to be determined. We analyzed the effects of various T-cell growth factors and cellular interactions on in vitro proliferation of early CD2+CD3/TCR-CD4-CD8- (triple negative [TN]) human thymocytes. Freshly isolated TN cells were then assayed for their growth capacity after incubation with CD2I+III-monoclonal antibody (MoAb), recombinant human interleukin-2 (IL-2), IL-7, and/or IL-4. These cells displayed significant proliferative responses with IL-4, IL- 7, or CD2-MoAb+IL-2. The addition of recombinant transforming growth factor beta (TGF beta) or autologous irradiated CD3+CD8+CD4- cells to TN cell cultures dramatically decreased their growth responses to IL-2 and IL-7, whereas IL-4-induced proliferation was less sensitive to growth inhibition. We thus asked whether the CD8+ cell-derived inhibitory effect was due to TGF beta. The addition of neutralizing anti-TGF beta MoAb completely abolished CD8+ cell-derived inhibition of TN cell growth. Analysis of CD8+ cell-derived supernatants indicated that these cells had low TGF beta 1 production capacity, whereas TN cells secrete significantly high levels of TGF beta 1. Cell fixation studies showed that TN cells were the source of the TGF beta. TGF beta 1 released from TN cells was in the latent form that became the active inhibitory form through interaction of TN cells with CD8+ cells. Together, these data suggest a role for TGF beta 1 as an externally controlled, autocrine inhibitory factor for human early thymocytes, with a regulatory role in thymic T-cell output.     

Murine thymocytes proliferate in direct response to interleukin-7

The ability of interleukin-7 (IL-7) to stimulate murine thymocyte proliferation was investigated. IL-7, either alone or in concert with lectin, induced proliferation of adult thymocytes as well as day 13 fetal and adult CD4-/CD8-thymocytes. The IL-7-induced proliferative response of unfractionated thymocytes could not be inhibited by antibodies to IL-2, or IL-4, IL-6, or the IL-2 receptor. In addition, IL-2, IL-4, and IL-6 were not produced by thymocytes activated with IL- 7, as judged by the absence of biologically active cytokine in IL-7- stimulated culture supernatants. IL-7 could act in concert with IL-2 and IL-4 or with IL-4 to enhance the proliferative response of thymocyte cultures. Thus, IL-7 may cause proliferation of thymocytes directly, not indirectly, through production of IL-2, IL-4, or IL-6. IL- 7 may then play a significant role in differentiation of T lymphocytes.     

CD34-expressing human thymocyte precursors proliferate in response to interleukin-7 but have lost myeloid differentiation potential

CD34 is a marker for pluripotent stem cells also present on lineage- committed hematopoietic progenitors from bone marrow and a subpopulation of immature thymocytes. To characterize these early immature thymocytes, we have studied 24 pediatric thymus samples for CD34/7 expression. Three subpopulations could be defined from these T- cell receptor (TcR-) immature thymocytes: CD34+7++ (12.0 +/- 5.8), CD34- 7++ (12.6 +/- 8.6), and CD34-7+ (71.5 +/- 17.0%). CD7++ represents upregulation of this antigen and is expressed by cells of a blast-like morphology. Three-color flow cytometric analysis of these three subsets suggests the following ordered differentiation sequence: CD34+7++1-4-8- 45RA+-->CD34+7++1+ 4+8-45RA+/- -->CD34-7++1+4+8-+45RO+-->CD34- 7+1++4+8+45RO+. Early immature thymocyte cell division is essential in the thymus to generate a large number of precursors before the initiation of the selection process. We observed that both CD2 as well CD28 activation pathways were inefficient to serve as costimulant with phorbol ester 12-O-tetradecanoyl phorbol 13-acetate or interleukin-2 (IL-2) to induce the proliferation of the three CD34/7 subsets isolated by cell sorting. However, whereas IL-1, IL-2, IL-3, IL-4, granulocyte colony-stimulating factor, and granulocyte-macrophage colony- stimulating factor were ineffective, IL-7 was a potent cytokine, alone or in synergy with stem cell factor (SCF) to induce immature thymocyte proliferation. The proliferation induced by IL-7 or IL-7 + SCF is restricted to the CD34+ cells and, after 4 or 8 days of culture with IL- 7, some CD34+7++ acquire the expression of CD4 and/or CD8, but remain CD3/TcR-. We also tested the myeloid differentiation capacity of these CD34 immature thymocytes. Using two different approaches, myeloid colony formation in methylcellulose and limiting dilution analysis in the presence of myeloid growth factors, we were unable to detect myeloid differentiation capacity from CD34+ early thymocytes, whereas CD34+7+ from bone marrow contained about 10% of the clonogenic cells present in the CD34+7- fraction. Together, these data support the concept that thymic CD34+7++ represents the earliest thymic subset of fully committed T-lineage cells, capable of proliferating specifically to IL-7.     

Murine recombinant interleukin-3 induces recovery of T and B cells in irradiated mice

Injection of murine recombinant interleukin-3 (IL-3) into (C57BL/10 x DBA/2)F1 mice, sublethally irradiated with 300 cGy and killed 14 days later, induced in the thymus recovery of the cell number and mitotic responsiveness to concanavalin A (Con A), as well as an increase in number of double-negative CD4-CD8-, double-positive CD4+ CD8+, and single-positive CD4+CD8- and CD4-CD8+ cells. Also in the spleen, the cell count and mitotic responsiveness to Con A and lipopolysaccharide were increased to normal levels by IL-3 treatment. If the assays were performed 21 or 28 days after irradiation, IL-3 treatment was able to restore thymus and spleen cell counts as well as T- and B-cell mitotic responsiveness, even when mice were exposed to 400 or 500 cGy, respectively. These results altogether indicate that IL-3 induces differentiation and growth of thymocytes and recovery of T- and B-cell functions in mice exposed to sublethal irradiation.     

Ectopic expression of rhombotin-2 causes selective expansion of CD4-CD8- lymphocytes in the thymus and T-cell tumors in transgenic mice

Although the proto-oncogene rhombotin-2 (RBTN-2) is widely expressed in most tissues, it is not expressed in T cells. We investigated the potential for overexpression of RBTN-2 to cause tumors in T cells and other tissues by constructing transgenic mice that expressed RBTN-2 under control of the metallothionein-1 promoter. Despite overexpression of RBTN-2 in all tissues, transgenic mice developed T-cell tumors only, thus indicating that tumorigenesis caused by RBTN-2 is T-cell-specific. Thymic tumors were found between 37 and 71 weeks and were invariably associated with metastasis to nonlymphoid organs. Thymuses from apparently healthy transgenic mice were also examined. In some mice there was an 10-fold increase in the CD4-CD8- thymocyte subset, yet the total number of thymocytes was the same as that in wild-type mice. Thymic homeostasis was maintained by a compensatory reduction in the CD4+CD8+ subset. The expansion of CD4-CD8- thymocytes was associated with increased expression of RBTN-2 and with increased cell proliferation. No differences were found in the proportion of thymocytes undergoing apoptosis in transgenic mice. Furthermore, RBTN-2- induced expansion of CD4-CD8- cells did not block differentiation of these cells. Thymuses with 30% CD4-CD8- cells were essentially monoclonal, indicating that all thymic immunophenotypes were derived from a single clone. Overall, our data are consistent with the following scenario: (1) RBTN-2 expression in T cells causes selective and polyclonal proliferation of CD4-CD8- thymocytes accompanied by a compensatory decrease in other thymocyte subsets; (2) a clone with growth advantage and differentiation potential is selected and populates the thymus; and (3) this clone eventually breaches homeostasis of the thymus, accompanied or followed by metastasis to other organs.     

Instability of assembled T-cell receptor complex that is associated with rapid degradation of zeta chains in immature CD4+CD8+ thymocytes.

The intracellular fate of newly synthesized T-cell receptor (TCR) chains was compared in CD4+CD8+ (double positive; DP) thymocytes and in CD4+CD8- or CD4-CD8+ (single positive; SP) thymocytes. Purified DP and SP thymocytes from normal adult mice were analyzed by pulse-chase metabolic labeling and immunoprecipitation with specific anti-TCR antibodies. Biosynthesis of invariant chains (CD3 gamma, -delta, -epsilon, and zeta) was comparable between DP and SP thymocytes, whereas DP thymocytes synthesized TCR alpha and TCR beta chains at lower and higher levels than SP thymocytes, respectively. These newly synthesized TCR chains were degraded at different rates in SP thymocytes based on their sensitivities for degradation as previously reported: TCR alpha, TCR beta, CD3 gamma, and CD3 delta chains were rapidly degraded and CD3 epsilon and zeta chains were stable. Although the degradation rates of clonotypic and invariant CD3 chains were similar in DP and SP thymocytes, the zeta subunit was rapidly degraded in DP thymocytes (t1/2, approximately 1.5 hr). Degradation of zeta was inhibited by NH4Cl, implicating lysosomes as the site of degradation. Comparison of TCR subunit assembly in DP and SP thymocytes demonstrated that, despite the same relative rate of formation of TCR complexes in a pulse period (30 min), complete complexes were unstable and degraded during the subsequent 6 hr of chase in DP thymocytes. This contrasted with the stability and a progressive increase in the levels of completely assembled complexes in SP thymocytes. Thus, these results demonstrate that a unique posttranslational regulation operates in the formation of TCR complexes in DP thymocytes and that lack of stability of complete TCR complexes is a crucial mechanism that may account for the limited surface TCR expression on this thymocyte subset.     

The effect of TGF-beta on the induction CD8 and NK1.1 expression in CTLL-2 cell line.

BACKGROUND: The presence of CD8+ T-cells expressing NK cell associated markers (TNK cells) has been observed in several experimental models, which suggests that NK cells may belong to the T-cell lineage. We used the CTLL-2 cell line, which is NK1.1+ CD3- TCR+ CD4- CD8- cells in the presence of IL-2, to investigate whether these cells can be switched to CD8+ or CD4+ cells, like TNK cells, by the TGF-beta. METHODS: CTLL-2 cells were cultured with TGF-beta or other cytokines and activators in the presence of IL-2. In order to see the surface and intracytoplasmic antigen expression in a single-cell level, simultaneous surface CD4, CD8, TCR with NK1.1, and intracytoplasmic NK1.1 staining was performed and three-color flow cytometric analysis was performed. RESULTS: During routine passage, less than 5% of cells were CD8a+, although 20-40% of cells expressed CD8a when treated with IL-2 + TGF-beta, whereas TPA + Calcium ionophore, IFN-gamma, and TNF-alpha cause no significant changes in the proportion of CD8+ cells. Twenty percent of CTLL-2 cells expressed NK1.1 with IL-2 treatment, and this expression was also increased up to 65%-70% with IL-2 + TNF-beta. Furthermore, most of the CD8 positive cells showed intracytoplasmic NK1.1. CONCLUSION: Our results indicated that these would be useful models to investigate CD8 precursor potentials in populations of CD4-CD8- (double negative) cells and the relationship of NK1.1. These results also support a role for TGF-beta in T-cell differentiation and the hypothesis that T-cells and NK cells may have the same ontogeny.     

Kinetics of mature T-cell development in the thymus.

We have reexamined the balance between cell birth, cell maturation, and cell death in the thymus by labeling dividing thymocytes and their progeny in vivo with [3H]-thymidine, isolating clearly defined subpopulations by fluorescence-activated cell sorting, and determining the distribution of label by autoradiography. When mature thymocytes were precisely defined (as CD4+CD8- CD3+ or CD4-CD8+ CD3+) and separated from immature single positives (CD4+CD8- CD3- and CD4-CD8+ CD3-), a lag was observed in the rate of entry of [3H]thymidine into mature cells. Thus, many of the mature thymocytes appear to derive from a small nondividing cortical thymocyte pool, rather than originating directly from the earliest dividing CD4+CD8+ blasts. There was little evidence for cell division during or after mature thymocyte formation, suggesting a one-for-one differentiation from cortical cells rather than selective clonal expansion. The rate of production of mature single positive thymocytes agreed closely with estimates of the rate of export of mature T cells from the thymus and was only 3% of the rate of production of double-positive cortical thymocytes. This was compatible with a stringent selection process and extensive intrathymic cell death and suggested that no extensive negative selection occurred after the mature cells were formed.     

Differentiation of thymocytes from CD3-CD4-CD8- through CD3-CD4-CD8+ into more mature stages induced by a thymic stromal cell clone.

We have investigated the capacity of our established thymic stromal cell clone (MRL104.8a) or its derived factor(s) to induce the differentiation of immature thymocytes. Culture of purified adult murine double-negative (CD4-CD8-, indicated here as CD4-8-) thymocytes on the MRL104.8a thymic stromal cell monolayer for 1 day resulted in the induction of an appreciable percentage of CD4-8+ thymocytes. A bone marrow-derived stromal cell monolayer or a L929 fibroblast monolayer failed to generate CD4-8+ cells. This differentiation could also be induced by a semipurified sample of the MRL104.8a culture supernatant, which contained a thymic stroma-derived T-cell growth factor capable of contributing to the growth of double-negative immature thymocytes. CD4-8+ thymocytes generated 1 day after coculture with the MRL104.8a cells or the sample containing thymic stroma-derived T-cell growth factor were found to be CD3- and J11d+, excluding the possibility of expansion of mature (CD3+4-8+) thymocytes present in the thymus. More importantly, when the culture period was extended to 2 or 3 days, an appreciable number of CD4+8+ and single-positive (CD4+) cells were generated on the MRL104.8a monolayer. Thus, these results provide the direct demonstration that CD3-4-8- immature thymocytes are promoted to differentiate through a rapidly cycling intermediate (CD3-4-8+) into double- and single-positive cells by a specialized thymic stromal component.     

Th2 cells are less susceptible than Th1 cells to the suppressive activity of CD25+ regulatory thymocytes because of their responsiveness to different cytokines

T-cell clones generated from both CD4+CD25+ and CD8+CD25+ human thymocytes were assessed for their ability to suppress the proliferative response to allogeneic stimulation of type 1 T-helper (Th1) or type 2 T-helper (Th2) clones derived from autologous CD4+CD25- thymocytes. Both CD4+ and CD8+ T-regulatory (Treg) cells completely suppressed the proliferation of Th1 clones but exhibited significantly lower suppressive activity on the proliferation of Th2 clones. The partial suppressive effect on Th2 cells was further reduced by the addition in culture of interleukin-4 (IL-4), whereas it was increased in the presence of an anti-IL-4 monoclonal antibody (mAb). The suppressive activity on Th2 clones was also completely inhibited by the addition of IL-7, IL-9, and IL-15 but not of IL-2, whereas the suppressive effect on Th1 clones was only reverted by the addition of IL-15. Of note, Th2 clones expressed significantly higher amounts of mRNA for IL-4 receptor (IL-4R) and IL-9R alpha chains than Th1 clones, whereas the expression of mRNA for IL-2R, IL-7R, and IL-15R alpha chains was comparable. Taken together, these findings demonstrate that Th2 cells have a lower susceptibility than Th1 cells to the suppressive activity of human CD25+ regulatory thymocytes, because they are able to produce, and to respond to, growth factors distinct from IL-2, such as IL-4 and IL-9.     

Altered IL-7Ralpha expression with aging and the potential implications of IL-7 therapy on CD8+ T-cell immune responses

We investigated the effects of aging on the IL-7-mediated CD8+ T-cell survival pathway and of IL-7 therapy on T-cell immunity. Cells expressing IL-7 receptor (IL-7R) alphahigh and alphalow were identified in a CD45RA+ effector memory (EM(CD45RA+), CD45RA+CCR7-) CD8+ T-cell subset. Elderly subjects (65 years and older) had an increased frequency of EM(CD45RA+) IL-7Ralphalow) CD8+ T cells, leading to decreased STAT5 phosphorylation and survival responses to IL-7 compared with young subjects (40 years and younger). These EM(CD45RA+) IL-7Ralphalow cells were largely antigen experienced (CD27-CD28-), replicatively senescent (CD57+), and perforinhigh CD8+ T cells that had decreased IL-7Ralpha mRNA, independent of guanine and adenine binding protein alpha (GABPalpha) and growth factor independence-1 (GFI1) expression. In measuring T-cell receptor (TCR) repertoires of EM(CD45RA+) CD8+ T cells, the elderly had a limited repertoire in IL-7Ralphahigh and IL-7Ralphalow cells, whereas the young had a diverse repertoire in IL-7Ralphahigh but not in IL-7Ralphalow cells. These findings suggest that aging affects IL-7Ralpha expression by EM(CD45RA+) CD8+ T cells, leading to impaired signaling and survival responses to IL-7, and that IL-7 therapy may improve the survival of EM(CD45RA+) CD8+ T cells with a diverse TCR repertoire in the young but not in the elderly.     

A murine early thymocyte developmental sequence is marked by transient expression of the interleukin 2 receptor.

Precursors of all T-lineage cells are found in the population of thymocytes that lacks the CD4 and CD8 surface markers. These "double-negative" thymocytes are heterogeneous and can be divided into discrete subpopulations based on their expression of other surface markers. We have determined the relative maturity of these subpopulations based on the extent of rearrangement and expression of their T-cell receptor genes, their cell cycle status, and their thymus reconstitution capacity. Within the subpopulation of double negatives expressing high levels of the heat-stable antigen, the additional markers phagocytic glycoprotein 1 (Pgp-1) and interleukin 2 receptor (IL-2R) can be used to define the sequence IL-2R- Pgp-1+----IL-2R+ Pgp-1-----IL-2R- Pgp-1-, which occurs before the expression of CD4 and CD8. Transient expression of the IL-2R marks an important developmental point in the sequence just prior to a burst of cell proliferation and a loss of thymus reconstitution ability. The earliest cells in this sequence are already partially rearranged for genes in the C beta 1 region. IL-2R expression marks a second wave of T-cell antigen receptor of beta-chain gene rearrangement and the initiation of T-cell antigen receptor alpha- and beta-chain gene expression.     

Interleukin-7 and infection itself by human immunodeficiency virus 1 favor virus persistence in mature CD4(+)CD8(-)CD3(+) thymocytes through sustained induction of Bcl-2

The sequence of events and the mechanisms leading to the destruction of the thymus during human immunodeficiency virus (HIV) infection are still poorly characterized. Investigated here are the survival capacity on HIV-1 infection of the mature single-positive CD4(+)CD8(-)CD3(+) (SP CD4(+)) and the intermediate CD4(+) CD8(-)CD3(-) thymocytes previously shown to be able to replicate the virus in the thymic microenvironment. It is demonstrated that the mature SP CD4(+) thymocytes exhibit a high survival capacity despite the production of a high yield of viruses. Interleukin-7, reported to be a crucial cofactor of tumor necrosis factor (TNF) to promote HIV replication, is shown here to counteract the apoptotic activity of TNF. Resistance to apoptosis of SP CD4(+) cells is conferred by a high expression of the IL-7 receptor (IL-7R) associated with the capacity of IL-7 to permanently up-regulate Bcl-2. In addition, this high Bcl-2 level is further enhanced by infection itself. In contrast, intermediate thymocytes, which replicate the virus at a lower level, are more sensitive to apoptosis, and their differentiation into double-positive CD4(+)CD8(+)CD3(-) (DP CD3(-)) cells strongly increases their death rate on infection. This sensitivity is related to a lower expression of IL-7R and Bcl-2 in intermediate thymocytes, which further decreases at the DP CD3(-) stage. In addition, a decreased level of Bcl-2 is observed in this subset during infection. Altogether these data suggest that in vivo, HIV infection might create a persistent virus reservoir within the SP CD4(+) thymocytes, whereas the later infection of intermediate cells might lead to thymopoiesis failure.     

Engagement of the external domains of CD45 tyrosine phosphatase can regulate the differentiation of immature CD4+CD8+ thymocytes into mature T cells.

Immature precursor cells are induced in the thymus to express clonotypic T-cell antigen receptors (TCRs) and to differentiate into mature T cells. Perhaps the least understood event which occurs during intrathymic development is the positive selection of immature CD4+CD8+ thymocytes for differentiation into mature CD4+ and CD8+ T cells based on the TCR specificity individual thymocytes express. TCR expression by CD4+CD8+ thymocytes is quantitatively regulated by CD4-mediated activation of p56lck protein-tyrosine kinase whose activity can in turn be regulated by the membrane-bound protein-tyrosine-phosphatase CD45. Here we show that antibody engagement of CD45 external domains enhances Lck tyrosine kinase activity in CD4+CD8+ thymocytes, inhibits TCR expression, and inhibits differentiation of immature CD4+CD8+ thymocytes into mature T cells. Thus, engagement of the external domains of CD45 tyrosine phosphatase can regulate the ability of immature CD4+CD8+ thymocytes to undergo positive selection, suggesting an important regulatory role for intrathymic ligands that are capable of engaging CD45 within the thymus.     

Characterization of immature thymocyte lines derived from T-cell receptor or recombination activating gene 1 and p53 double mutant mice.

The T-cell receptor (TCR) beta chain is instrumental in the progression of thymocyte differentiation from the CD4-CD8- to the CD4+CD8+ stage. This differentiation step may involve cell surface expression of novel CD3-TCR complexes. To facilitate biochemical characterization of these complexes, we established cell lines from thymic lymphomas originating from mice carrying a mutation in the p53 gene on the one hand and a mutation in TCR-alpha, TCR-beta, or the recombination activating gene 1 (RAG-1) on the other hand. The cell lines were CD4+CD8+ and appeared to be monoclonal. A cell line derived from a RAG-1 x p53 double mutant thymic lymphoma expressed low levels of CD3-epsilon, -gamma, and -delta on the surface. TCR-alpha x p53 double mutant cell lines were found to express complexes consisting of TCR-beta chains associated with CD3-epsilon, -gamma, and -delta chains and CD3-zeta zeta dimers. These lines will be useful tools to study the molecular structure and signal transducing properties of partial CD3-TCR complexes expressed on the surface of immature thymocytes.