Thymus-derived cytokine(s) including interleukin-7 induce increase of T cell receptor α/β+ CD4−CD8− T cells which are extrathymically differentiated in athymic nude mice

Extrathymic T cell differentiation pathways have been reported, although the thymus is the main site of T cell differentiation. The thymus is also known to produce several cytokines that induce proliferation of thymocytes. In the present study, we investigated the influence of thymus-derived cytokines on extrathymic T cell differentiation by intraperitoneal implantation with a diffusion chamber which encloses fetal thymus (we named it fetal thymus-enclosed diffusion chamber, FTEDC) in athymic BALB/c nu/nu mice. Increase in number of T cells bearing T cell receptor (TcR) α/β was detected in lymph nodes and spleens of FTEDC-implanted nude mice 1 week after implantation, whereas no such increase was detected in control nude mice implanted with a diffusion chamber without thymus. The FTEDC-induced increase of T cells was suppressed by intraperitoneal injection of anti-interleukin-7 monoclonal antibody (mAb). The TcR α/β T cells in FTEDC-inplanted BALB/c nu/nu mice preferentially expressed Vβ11, although Vβ11-positive T cells are deleted in the thymus of euthymic BALB/c mice by clonal elimination of self-superantigen Dvb 11-specific T cells. TcR α/β T cells in FTEDC-implanted nude mice were of CD4^?CD8^? phenotype and showed no proliferative response against anti-TcR monoclonal antibody stimulation. These results suggest that the thymus can induce extrathymic T cell differentiation through the influence of thymus-derived cytokine(s) including interleukin-7, and that such extrathymically differentiated T cells have acquired only a little or no ability for proliferation when they recognize antigen by their TcR.     

Frequent occurrence of in vivo clonal expansion of CD4− CD8− T cells bearing T cell receptor αβ chains in adult humans

We have previously reported 2 cases of healthy men showing in vivo monoclonal expansion of mature CD4^? CD8^? αβ T cells. In the present study, an additional 3 adults were found to exhibit such an expansion, among a total 464 adult donors studied. These 5 individuals were otherwise physiologically normal, with no history of severe illness and autoimmune disease at the time of examination. To investigate the mechanisms of the clonal expansion, further characterization of the clonal cells was attempted. No apparent preference for usage of the Tcell receptor β chain variable region was observed in the clonal T cells. These clonal T cells showed lectin-dependent or redirected antibody-dependent cell-mediated cytotoxicities, whereas they could not lyse autologous lymphoblastoid cell lines. Failure of Fas antigen expression was not observed for any of these clones. These results suggest that clonal expansion of CD4^? CD8^? αβ T cells frequently occurs in the periphery without any T cell abnormalities.     

A novel peripheral CD4+CD8+ T cell population: Inheritance of CD8α expression on CD4+ T cells

In this study we show the inheritance of a CD4⁺CD8⁺ peripheral T cell population in the H.B15 chicken strain. A large proportion of αβ T cells in peripheral blood (20–40%), spleen (10–20%) and intestinal epithelium (5–10%) co-express CD4 and CD8α, but not CD8β. CD4⁺ CD8αα cells are functionally normal T cells, since they proliferate in response to mitogens and signals delivered via the αβT cell receptor as well as via the CD28 co-receptor. These cells induce in vivo a graft versus host-reaction, providing further evidence for their function as CD4⁺ T cells. The CD4⁺CD8αα T cell population was found in 75% of the first progeny and in 100% of further progenies, demonstrating that co-expression of CD4 and CD8 on peripheral T cells is an inherited phenomenon. In addition, cross-breeding data suggest a dominant Mendelian form of inheritance. The hereditary expression of CD8α on peripheral CD4⁺ T cells in chicken provides a unique model in which to study the regulation of CD4 and CD8 expression.     

CD4-negative cytotoxic T cells with a T cell receptor α/βintermediate expression in CD8-deficient mice

Targeted disruption of the CD8 gene results in a profound block in cytotoxic T cell (CTL) development. Since CTL are major histocompatibility complex (MHC) class I restricted, we addressed the question of whether CD8–/– mice can reject MHC class I-disparate allografts. Studies have previously shown that skin allografts are rejected exclusively by T cells. We therefore used the skin allograft model to answer our question and grafted CD8–/– mice with skins from allogeneic mice deficient in MHC class II or in MHC class I (MHC-I or MHC-II-disparate, respectively). CD8–/– mice rejected MHC-I-disparate skin rapidly even if they were depleted of CD4⁺ cells in vivo (and were thus deficient in CD4⁺ and CD8⁺ T cells). By contrast, CD8+/+ controls depleted of CD4⁺ and CD8⁺ T cells in vivo accepted the MHC-I-disparate skin. Following MHC-I, but not MHC-II stimulation, allograft-specific cytotoxic activity was detected in CD8–/– mice even after CD4 depletion. A population expanded in both the lymph nodes and the thymus of grafted CD8–/– animals which displayed a CD4^?8^?3^intermediateTCRα/β^intermediate phenotype. Indeed its T cell receptor (TCR) density was lower than that of CD4⁺ cells in CD8–/– mice or of CD8⁺ cells in CD8+/+ mice. Our data suggest that this CD4^?8^?T cell population is responsible for the CTL function we have observed. Therefore, MHC class I-restricted CTL can be generated in CD8–/– mice following priming with MHC class I antigens in vivo. The data also suggest that CD8 is needed to up-regulate TCR density during thymic maturation. Thus, although CD8 plays a major role in the generation of CTL, it is not absolutely required.     

Encephalitogenic,myelin basic protein-specific T cells from naive rat thymus: preferential use of the T cell receptor gene Vβ8.2 and expression of the CD4− CD8− phenotype

Using a primary limiting dilution approach to generate T cell lines, we compared myelin basic protein (MBP)-specific T cell clones from naive unprimed Lewis rat thymuses with the corresponding T cell repertoire of primed rats. We found that in the naive thymus repertoire MBP-specific, encephalitogenic T cell clones preferentially use T cell receptor Vβ8.2 genes, along with CDR3 sequences typical for the primed Lewis anti-MBP response. In contrast to T cells from primed immune organs, which all display the CD4⁺ CD8^? phenotype, the majority of naive thymus-derived T cell clones expressed reduced levels of the CD4 co-receptor. Some clones were completely CD4^?CD8^?, while others included CD4^? CD8^? subpopulations along with CD4⁺CD8^? T cells. In the one mixed population examined in detail, the CD4^?CD8^? and CD4⁺CD8^? T cell subpopulations used a T cell receptor with identical β chain sequence. The data suggest that in the Lewis rat the biased T cell receptor gene usage by encephalitogenic T cells is a property of the natural thymic T cell repertoire, possibly as a consequence of positive selection. The unusually low expression of CD4 in the major histocompatibility complex class II-restricted autoreactive T cells could be related to their escape from negative selection within the thymus.     

Selective activation of resting human γδ T lymphocytes by interleukin-2

In rheumatoid arthritis and other inflammatory diseases we and others have found that γδ T cells express activation antigens, suggesting that they are involved in the pathogenesis of these disorders. In this study we have stimulated peripheral blood mononuclear cells from normal donors with recombinant interleukin-2 (rIL-2) to see whether such a stimulus alone could activate γδ T cells. Short-term exposure (24-96 h) to rIL-2 selectively stimulated the γδ but not the αβ T cells to express activation antigens (CD69, CD25 and HLA-DR). Long-term culture (2 weeks) in rIL-2-containing medium caused a selective increase in the proportion of the γδ T cells and a corresponding reduction of the fraction of αβ T cells. Limiting dilution analysis revealed that approximately 1/60 of the γδ T cells responded to IL-2 in contrast to only 1/250 of the αβ T cells. Comparison of the expression of the IL-2 receptor (IL-2R) a and P chains showed that there was a similar expression of the α chain on γδ and αβ T cells whereas the relative density of the β chain was more than twice as high on γδ T cells. Both the IL-2-induced proliferation of γδ T cells and the expression of activation antigens on these cells could be inhibited by an anti-IL-2Rβ monoclonal antibody (mAb) but not by an anti-IL-2Rα mAb. Expression of CD69 on γδ T cells was dependent neither on the presence of B cells, monocytes, nor αβ T cells. Finally, we found that the IL-2-induced expression of CD69 was inhibited by activation of cAMP-dependent protein kinase and by inhibition of the Src-family of the tyrosine protein kinase, but not by inhibition of protein kinase C or by activation of the CD45 associated tyrosine phosphatase. The ability of γδ T cells to be activated by IL-2 is a feature which they have in common with natural killer cells. Moreover, it may be possible that the expression of activation antigens on γδ T cells in inflammatory diseases is an epiphenomenon secondary to IL-2 produced by activated αβ T cells.     

Interleukin-2 receptor β and γ chain dysregulation during the inhibition of CD4 T cell activation by human immunodeficiency virus-1 gp120

We have observed that CD4 T lymphocytes from human immunodeficiency virus (HIV)-infected patients marginally express interleukin-2 receptor (IL-2R)β and IL-2Rγ chains which are essential for IL-2 signal transduction. To analyze this observation further, we studied the influence of gp120 on the cell surface expression of IL-2Rβ and IL-2Rγ by purified CD4 lymphocytes in vitro. Cross-linking of the T cell receptors of these lymphocytes initiates entry into the cell cycle as measured by CD69 and CD71 cell surface expression and [³H]thymidine incorporation. It also induces the cell surface expression of IL-2Rβ and IL-2Rγ. We have shown that treatment of the CD4 T lymphocytes with HIV-1 gp120 before anti-CD3 stimulation impedes cell cycle progression as measured by reduced CD71 expression and inhibition of [³H]thymidine incorporation. Furthermore, cell surface expression of IL-2Rβ and IL-2Rγ subunits, which form the functional intermediate-affinity IL-2R, are significantly inhibited. More importantly, addition of exogenous IL-2 does not restore the proliferation of the CD4 T cells treated with gp120, suggesting that cells are anergic and/or that the remaining IL-2R are not functional. This is the first study of IL-2Rβ and IL-2Rγ dysregulation in the context of HIV infection and shows that CD4 is also involved in IL-2R expression.     

Expansion of the CD4−, CD8− γδ T cell subset in the spleens of mice during non-lethal blood-stage malaria

Splenic γδ T cells (CD4^?, CD8^?) increased more that 10-fold upon resolution of either Plasmodium chabaudi adami or P. c. chabaudi infections in C57BL/6 mice compared to controls. Similarly, a 10- to 20-fold expansion of the γδ T cell population was observed in β₂-microglobulin deficient (β²-m^0.0) mice that had resolved P. c. adami, P. c. chabaudi or P. yoelii yoelii infections. In contrast, increases in the number of splenic αβ T cells in these infected mice were only two to three-fold indicating a differential expansion of the γδ T cell subset during malaria. Because nucleated cells of β₂-m^0/0 mice lack surface expression of major histocompatibility complex class I and class Ib glycoproteins, our findings suggest that antigen presentation by these glycoproteins is not necessary for the increasing number of γδ T cells. Our observation that after resolution of P. c. adami malaria, C57BL/6 mice depleted of CD8⁺ cells by monoclonal antibody treatment had lower numbers of γδ T. cells than untreated controls suggests that the demonstrated lack of CD8⁺ cells in β₂-m^0/0 mice does not contribute to the expansion of the γδ T cell population during non-lethal malaria.     

A human CD4 transgene rescues CD4−CD8+ cells in β2-microglobulin-deficient mice

The specificity of the αβ T cell receptor for class I or class II major histocompatibility complex (MHC) molecules determines whether a mature T cell will be of the CD4^?CD8⁺ or CD4⁺CD8^? phenotype, respectively. We show here that a human CD4 transgene can rescue a significant fraction of CD4^?CD8⁺ T cells in β2-microglobulin-deficient mice. Cells with this phenotype could be induced to become potent killers of targets expressing allogeneic MHC antigens, indicating that lineage commitment can precede the rescue of developing cells by the T cell receptor for antigen and the CD4 coreceptor.     

Lack of intermediate-affinity interleukin-2 receptor in mice leads to dependence on interleukin-2 receptor α, β and γ chain expression for T cell growth

An interleukin (IL)-4 dependant mouse T cell clone 8.2 derived from an IL-2-dependent T cell line was characterized. As measured by flow cytometric analysis and Northern blotting, it expresses IL-2 receptor β (IL-2Rβ) and γ (IL-2Rγ) chains, but has lost expression of IL-2 receptor α chain (IL-2Rα). To investigate the properties of the mouse IL-2Rβγ complex and the role of IL-2Rα gene expression, this clone was further studied. T cell clone 8.2 has lost the capacity to bind ¹²⁵I-labeled human IL-2 under experimental conditions able to detect intermediate-affinity IL-2R in human cells. Mouse IL-2 is unable to block the binding of mAb TMβ1 to 8.2 cells. Under the same experimental conditions, mouse IL-2 blocks the binding of TMβ1 to C30-1 cells expressing the IL-2αβγ complex. Since TMβ1 recognizes an epitope related to the IL-2 binding site of IL-2Rβ, these results can be taken as a demonstration that mouse IL-2Rβγ does not bind mouse IL-2. Furthermore, T cell clone 8.2 does not proliferate in response to recombinant mouse or human IL-2. On the other hand, T cell transfectant lines expressing heterospecific receptors made of the human IL-2Rβ and mouse IL-2Rγ chains bind ¹²⁵I-labeled human IL-2 and proliferate in response to IL-2. This establishes the difference between mouse and human IL-2Rβ chains. Transfection of T cell clone 8.2 with human IL-2Rα genes restores their capacity to proliferate in response to IL-2. In addition, all transfectants grown in IL-2 express the endogeneous mouse IL-2Rα chain. When grown in IL-4, the endogeneous mouse IL-2Rα gene remains silent in all these transfectants. These results show that, contrary to the human, the mouse does not express an intermediate-affinity IL-2R. Expression of the IL-2Rα gene is therefore required for the formation of the functional IL-2R in mice.     

Antigen-specific CD8+ T cells inhibit IgE responses and interleukin-4 production by CD4+ T cells

There is a growing body of evidence which suggests that CD8⁺ T cells play an important part in regulating the IgE response to non-replicating antigens. In this study we have systematically investigated their role in the regulation of IgE and of CD4⁺ T cell responses to ovalbumin (OVA) by CD8⁺ T cell depletion in vivo. Following intraperitoneal immunization with alum-precipitated OVA, OVA-specific T cell responses were detected in the spleen and depletion of CD8⁺ T cells in vitro significantly enhanced the proliferative response to OVA. Depletion of CD8⁺ T cells in vivo 7 days after immunization failed to enhance IgE production, while depletion of CD8⁺ T cells on days 12–18 greatly enhanced the IgE response, which rose to 26 μ/ml following a second injection of anti-CD8 on day 35 and remained in excess of 1 μ/ml over 300 days afterwards. Reconstitution on day 21 of rats CD8-depleted on day 12 with purified CD8⁺ T cells from animals immunized on day 12 completely inhib ited the IgE response. This effect was antigen specific; CD8⁺ T cells from OVA-primed animals had little effect on the IgE response of bovine serum albumin immunized rats. In vivo, CD8⁺ T cell depletion decreased interferon (IFN)-γ production but enhanced interleukin (IL)-4 production by OVA-stimulated splenic CD4⁺ T cells. Furthermore, CD8⁺ T cell depletion and addition of anti-IFN-γ antibody enhanced IgE production in vitro in an IL-4-supplemented mixed lymphocyte reaction. These data clearly show that antigen-specific CD8⁺ T cells inhibit IgE in the immune response to non-replicating antigens. The data indicate two possible mechanisms: first, CD8⁺ T cells have direct inhibitory effects on switching to IgE in B cells and second, they inhibit OVA-specific IL-4 production but enhance IFN-γ production by CD4⁺ T cells.     

αβ Lineage-committed thymocytes can be rescued by the γδ T cell receptor (TCR) in the absence of TCR β chain

Commitment of the αβ and γδ T cell lineages within the thymus has been studied in T cell receptor (TCR)-transgenic and TCR mutant murine strains. TCRγδ-transgenic or TCRβ knockout mice, both of which are unable to generate TCRαβ-positive T cells, develop phenotypically αβ-like thymocytes in significant proportions. We provide evidence that in the absence of functional TCRβ protein, the γδTCR can promote the development of αβ-like thymocytes, which, however, do not expand significantly and do not mature into γδ T cells. These results show that commitment to the αβ lineage can be determined independently of the isotype of the TCR, and suggest that αβ versus γδ T cell lineage commitment is principally regulated by mechanisms distinct from TCR-mediated selection. To accommodate our data and those reported previously on the effect of TCRγ and δ gene rearrangements on αβ T cell development, we propose a model in which lineage commitment occurs independently of TCR gene rearrangement.     

T cell receptor-γδ-expressing fetal mouse thymocytes are generated without T cell receptor Vβ selection

We investigated whether fetal mouse T cell receptor (TCR) γδ cells have been subjected to so-called TCRβ selection at the CD25 stage of thymus development. To this end, we carried out a comparative three-color flow microfluorimetric analysis of TCRβδ cells developing in the fetal, neonatal and adult thymus using monoclonal antibodies to CD2, CD8, CD24, CD25 and CD44. Day-15 fetal TCRγδ cells were CD2⁺, suggesting an origin at a post-CD25 stage. Molecular analysis of TCRβ rearrangements were also carried out. Thus, by semi-quantitative polymerase chain reaction (PCR) amplification of Vβ6 and Vβ8 to Jβ2 rearrangements day-15 fetal TCRγδ showed extensive TCRβ rearrangements, a finding confirmed by PCR amplification from single micromanipulated cells. Finally, sequencing analysis of 104 PCR-amplified TCR VDJβ2 fragments showed that the majority (58%) were rearranged out of frame. Taken together, these phenotypic and molecular analyses suggest that fetal TCRγδ cells have not been subject to TCRβ selection.     

Evaluation of functional heterogeneity in the CD8 subset with T cells from T cell receptor-transgenic mice

The question of functional differentiation within the CD8 subset has been addressed in a model of TcR-transgenic (TcR-tg) mice expressing a TcR specific for H-2K^b (Ti). CD8⁺ Ti⁺ T cells present in the periphery of these mice have no cytotoxic T lymphocyte (CTL) activity unless they are stimulated with H-2K^b-expressing cells. In contrast to T cells from normal H-2^k littermates, alloantigen induction of CTL from TcR-tg mice is independent of CD4⁺ T helper (T_h) cells and is accompanied by high level secretion of interleukin-(IL)-2 by Ti⁺ CD8⁺ T cells. Precursor frequency analysis performed on CD8⁺ cells from TcR-tg mice revealed a high frequency of T_h as compared to CTL precursors. This raised the possibility of the existence of distinct subpopulations within CD8⁺ precursors with different requirements for differentiation to functional CTL. FACS analyses (performed on resting and on in vitro stimulated T cells from normal and TcR-tg mice) demonstrated a heterogeneous expression of Ly-6C on CD8⁺ cells with a large enrichment of Ly-6C^? cells among the Ti⁺ cells which persisted after stimulation with H-2^b cells in conditions that led to a homogeneous expression of the activation markers pgp-1 and CD69. The possibility that Ly-6C expression could mark functionally different subpopulations in CD8⁺ T cells was investigated. Stimulation of sorted populations of Ly-6C^? and Ly-6C⁺ cells allowed detection of CTL precursors in both these subsets and the majority of limiting dilution wells containing one pCTL also scored positive for IL-2 secretion. Thus, for CD8⁺ T cells expressing the same TcR, differentiation led to acquisition of both IL-2 secretion and CTL function and there was no evidence for the existence of a distinct population of helper-dependent CTL precursors.