Helper activity of CD4+ αβ T cells is required for the avian γδ T cell response

We have studied the in vitro activation of chicken γδ T cells. Both splenic αβ and γδ T cells obtained from complete Freund's adjuvant-primed chickens proliferated in vitro when stimulated with mycobacterial sonicate or purified protein derivative of Mycobacterium tuberculosis. When CD4⁺ cells or αβ T cell receptor (TcR)-positive cells were removed, both the proliferation and the blast formation of γδ T cells in response to mycobacterial antigens were abrogated. The response was restored if supernatant from concanavalin A (Con A)-activated lymphocyte cultures (CAS) as a source of helper factors was added together with the specific antigen purified protein derivative. The CD4- or αβ TcR-depleted cells still proliferated in response to Con A, although a decrease of the response was observed. To analyze the γδ T cell response more specifically we stimulated peripheral blood cells with immobilized monoclonal antibodies against T cell receptor. Anti-γδ TcR antibody alone did not induce significant proliferation. When CAS was added together with the anti-γδ TcR monoclonal antibody, a strong proliferation of γδ T cells was observed. In contrast, both Vβ1- and Vβ2-expressing αβ T cells proliferated in vitro in response to stimulation with the relevant anti-TcR monoclonal antibody alone. Depletion of either Vβ1⁺ or Vβ2⁺ T cell subset alone had no negative effect on the proliferation or blast formation of γδ T cells stimulated with mycobacterial antigens. Taken together our results suggest that CD4⁺ αβ T cells (both Vβl- and Vβ2-expressing) play a role in the activation and response of chicken γδ T cells.     

Murine T Cell Determination of Pregnancy Outcome: I. Effects of Strain, αβ T Cell Receptor, γδ T Cell Receptor,and γδ T Cell Subsets

PROBLEM: T cells bearing αβ T cell receptor (TcR) and γδ TcR are present at the fetomaternal interface, and the latter, which express surface activation markers, can react with fetal trophoblast cell antigens. What is the role of these cells? METHOD: Using stress-abortion-prone DBA/2-mated CBA/J and abortion-resistant C57/B16 mice, αβ, γδ, and CD8^+/- T cell subsets were measured in spleen and uterine decidua. The effect of immunization against abortion and administration of anti-TcR antibody in vivo was examined. Cytokine synthesis was measured by intracellular staining of Brefeldin A-treated cells. RESULTS: Abortion-prone matings showed an unexpected accumulation of γδ T cells beginning in the peri-implantation period and this was suppressed by immunization against abortion. The immunization deleted γδ T cells producing the abortogenic cytokines, TNF-α and γ-interferon, and increased production of the anti-abortive cytokines, IL-10 and transforming growth factor-β2 (TGF-β2). Immunization also boosted the number of αβ T cells which were present in the decidua as early as 2 days after implantation. In vivo injection of GL4 (anti-δ) depleted γδ T cells producing Th1 cytokines in the peri-implantation period, and prevented abortions, whereas H57 (anti-β) decreased the number of αβ T cells and led to 100% abortions. CD8⁺ T cells present in peri-implant decidua before onset of abortions were mostly αβ TcR⁺, although some were γδ⁺. Changes in γδ and αβ T cells in pregnancy were most dramatic in uterine tissue. CONCLUSION: Although decidual γδ T cells after formation of a distinct placenta and fetus produce anti-abortive TGF-β2-like molecules and IL-10, prior events can lead to abortion. High local production of TNF-α and γ-interferon develop during the peri-implantation phase because of an excessive increase in the Th1 cytokine⁺ subset of γδ cells; these cytokines may be contributed by other tissues in decidua, and the contribution of bioactive factors by γδ T cells may augment the cytokine pool. In contrast, αβ T cells (which may be inactivated by stress that causes abortions) may mediate the anti-abortive effect of alloimmunization. Alloimmunization involves a shift from a Th1 to a Th2 pattern in the γδ T cells in decidua.     

Lymphocytes bearing the γδ T cell receptor in acute Brucella melitensis infection

A phenotypical analysis carried out by indirect immunofluorescence and two-color cytofluorometry showed that the number of lymphocytes bearing the γδ T cell receptor (TcR) heterodimer was dramatically increased in the blood of six children with Brucella melitensis infection. Most in vivo expanded γδ T cells reacted with a monoclonal antibody which identifies Vδ2 gene products and a significant proportion expressed CD25 and HLA-DR activation antigens. In addition, whereas only a few γδ T lymphocytes were CD8⁺, nearly all were CD4^?. Highly enriched populations of both αβ and γδ T cells were obtained by negative immunoselection from three subjects with brucellosis sampled during convalescence. Despite the different form of their TcR, the proliferation of these two major T cell subsets in response to a mitogenic anti-CD3 monoclonal reagent (OKT3) was optimal. In contrast, αβ, but not γδ, T lymphocytes proliferated vigorously in response to the antigenic stimulus elicited by heat-killed Brucella. Further studies are, therefore, needed to determine whether the selective expansion of the γδ T cell subpopulation observed during the clinical course of the infection is driven by antigenic determinant(s) borne by the pathogen in vivo or is due to host-derived stimuli, such as autologous heat-shock proteins expressed on the surface of the infected cells.     

CD45RA expression on γδ and αβ T cells emigrating from the fetal and postnatal thymus

We have compared the expression of CD45RA on αβ and γδ T cells emigrating from the fetal and postnatal thymus. The fetal and postnatal thymus export both CD45RA⁺ and CD45RA^- T cells. The number of γδ⁺CD45RA⁺ T cells was remarkably constant regardless of stage of ontogeny or T cell maturity. Around 5--8% of γδ thymic emigrants, thymocytes and peripheral blood lymphocytes expressed CD45RA in both fetal and postnatal animals. In contrast to γδ T cells, up to one quarter of both fetal and postnatal αβ emigrants expressed CD45RA. Post-thymic maturation of CD45RA expression on αβ emigrants, which occurred both before and after birth, appeared to be antigen independent.     

Co-stimulation with LFA-1 triggers apoptosis in γδ T cells on T cell receptor engagement

Stimulation of T cells through the T cell receptor (TcR) initiate activation pathways, and paradoxically can also result in activation-induced cell death. Many factors influence a stimulated cell's decision to manifest one or the other. Here we show that co-stimulation with LFA-1 plays a key role in the choice between the two fates, differentiating between αβ and γδ T cells. Peripheral γδ T cells but not αβ T cells undergo apoptosis upon co-cross-linking of TcR and LFA-1 in MRL lpr/lpr mice as well as +/+ mice. Our results suggest that apoptosis of γδ T cells is inducible by combined stimuli independent of the Fas-mediated pathway.     

Changes in thymic export of γδ and αβ T cells during fetal and postnatal development

The thymus plays an essential role in the generation and selection of T cells and exports approximately 0.5–1% of thymocytes per day in young animals and considerably fewer in older animals. To date there have been no studies directly examining fetal thymic export in any species. Using the technique of intrathymic injection of fluorescein isothiocyanate, followed by an assay for green fluorescent cells in the periphery and for the expression of cell surface antigens on these cells, we have compared directly the export of T cells from the fetal and postnatal ovine thymus. While the thymus exports both αβ and γδ T cells, our results demonstrate that the proportion of thymic γδ T cells that are exported per day is much higher than that of thymic αβ T cells. Moreover, the export rate of γδ T cells increased from approximately 1 in every 60 γδ thymocytes per day emigrating from the fetal thymus to 1 in every 20 from the postnatal thymus. In addition, we identify a population of CD5⁺CD4^?CD8^?γδ^? T cells emigrating from the fetal thymus but greatly reduced among thymic emigrants after birth. These findings have several implications regarding the mechanisms and control of selection of both γδ and αβ T cells.     

Changes in thymic export of L-selectin+ γδ and αβ T cells during fetal and postnatal development

We have used the technique of in situ intrathymic injection of fluorescein isothiocyanate to examine L-selectin expression on γδ and αβ T cells immediately after emigrating from the thymus of fetal and postnatal animals. We found that the percentage of L-selectin⁺ thymocytes exported per day decreased by half after birth and that the export of T cells from the thymus does not rely on expression of the peripheral lymph node homing receptor, L-selectin. Analysis of L-selectin on emigrant and mature T cell subsets revealed a remarkable heterogeneity of expression, both in terms of the numbers of cells expressing this molecule as well as the level of expression. γδ T cells, reportedly not having a propensity for homing to lymph nodes, not only contained the highest proportion of L-selectin⁺ cells, but also expressed far more of this molecule than either CD4⁺CD8^? or CD4^?CD8⁺ αβ T cells. Furthermore, those emigrant T cells expressing L-selectin are somewhat immature in their expression of this molecule. Subsequent maturation resulted in up-regulation of L-selectin on mature peripheral blood T cells, maturation that was clearly independent of extrinsic antigen. This antigen-independent post-thymic maturation appeared to occur as part of the normal progression from immature thymocyte to mature peripheral T cell in both fetal and postnatal animals.     

γδ T cells are secondary participants in acute graft-versus-host reactions initiated by CD4+ αβT cells

To examine the role of T cell subpopulations in an acute graft-versus-host (GVH) reaction, γδ T cells and αβ T cells expressing one of the two prototypic Vβ gene families were negatively isolated from adult blood samples and injected into allogeneic chick embryos. CD4⁺ αβ T cells expressing either Vβ1 or Vβ2 receptors were equally capable of inducing acute GVH reactions, consistent with the idea that αβ T cell alloreactivity is determined by CDR3 variability. By themselves, the γδ T cells were incapable of inducing GVH reactions. However, host γδ T cells were recruited into the donor αβ T cell-initiated lesions, where they were activated and induced to proliferate. The data suggest that γβ T cells may play a secondary role in GVH reactions.     

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.     

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.     

Expression of an avian CD6 candidate is restricted to αβ T cells,splenic CD8+ γδ T cells and embryonic natural killer cells

A candidate avian CD6 homolog is identified by the S3 monoclonal antibody. The S3 antigen exists in a phosphorylated glycoprotein form of 130 kDa and a nonphosphorylated form of 110 kDa. Removal of phosphate groups and N-linked carbohydrates indicates a 78-kDa protein core. During thymocyte differentiation, the γδ T cells do not express S3, whereas mature CD4⁺ and CD8⁺ cells of αβ lineage acquire S3 antigen. All αβ T cells in the blood and spleen express the S3 antigen at relatively high levels. In contrast, only the CD8⁺ sub-population of γδ T cells in the spleen expresses the antigen and neither αβ nor γδ T cells in the intestinal epithelium express the S3 antigen. The S3 antigen is also found on embryonic splenocytes with a phenotypic profile characteristic of avian natural killer cells. The biochemical characteristics and this cellular expression pattern imply that the S3 antigen is the chicken CD6 homolog.     

Interleukin-12 activates human γδ T cells: synergistic effect of tumor necrosis factor-α

γδ T cell populations are known to expand in response to intracellular bacterial infectious agents regardless of previous priming. We have shown previously that soluble factor(s) produced by Mycobacterium-stimulated monocytes activate cord blood γδ T cells to proliferate. In this study, we investigated whether cytokines produced by monocytes are responsible for γδ T cell activation in vitro: interleukin (IL)-1β, IL-6, IL-8, IL-12, tumor necrosis factor (TNF)-α and granulocyte/macrophage colony-stimulating factor were examined. Recombinant human IL-12 stimulated γδ T cells, but not αβ T cells in peripheral blood mononuclear cells, to express CD25 on their surfaces, and to expand in number in vitro. IL-12-primed γδ T cell numbers increased to a greater extent in the culture to which exogenous IL-2 (5 U/ml) was added. Anti-TNF-α monoclonal antibody inhibited IL-12-induced up-regulation of CD25 on γδ T cells, suggesting that endogenous TNF-α may play a role in IL-12-induced activation of γδ T cells. Recombinant TNF-α synergistically augmented IL-12-induced activation of γδ T cells. Furthermore, IL-12 up-regulated TNF receptors on γδ T cells in vitro: TNF-α binding to its receptor induced CD25 expression on the γδ T cells in an autocrine or paracrine fashion, or perhaps both. It also became evident that both IL-12 and TNF-α were produced by mycobacterial lysate-stimulated monocytes. Taken together, these results suggest that upon confrontation with mycobacterial organisms, γδ T cells can be quickly and antigen-nonspecifically activated by soluble factors including IL-12 and TNF-α, both of which are produced by mononuclear phagocytes in response to mycobacterial organisms.     

Inhibition of murine γδ lymphocyte expansion and effector function by regulatory αβ T cells is cell‐contact‐dependent and sensitive to GITR modulation

γδ T cells are highly cytolytic lymphocytes that produce large amounts of pro‐inflammatory cytokines during immune responses to multiple pathogens. Furthermore, their ability to kill tumor cells has fueled the development of γδ‐T‐cell‐based cancer therapies. Thus, the regulation of γδ‐T‐cell activity is of great biological and clinical relevance. Here, we show that murine CD4⁺CD25⁺ αβ T cells, the vast majority of which express the Treg marker, Foxp3, abolish key effector functions of γδ T cells, namely the production of the pro‐inflammatory cytokines, IFN‐γ and IL‐17, cytotoxicity, and lymphocyte proliferation in vitro and in vivo. We further show that suppression is dependent on cellular contact between Treg and γδ T cells, results in the induction of an anergic state in γδ lymphocytes, and can be partially reversed by manipulating glucocorticoid‐induced TNF receptor‐related protein (GITR) signals. Our data collectively dissect a novel mechanism by which the expansion and pro‐inflammatory functions of γδ T cells are regulated.     

T cells expressing the γδ T cell receptor are not required for egg granuloma formation in schistosomiasis

Immunopathology in schistosomiasis consists of a granulomatous response around parasite eggs. It has been established that granuloma formation is mediated by CD4⁺ T helper cells. However, the role of T cells bearing the γδ T cell receptor (TCR) has not been determined. In this study we utilized mutant mice that lack either αβ or γδ T cells as a result of gene targeting to investigate the relative roles of αβ and γδ T cells in the induction of immunopathology related to schistosomiasis. Mutant and control mice were infected with Schistosoma mansoni and granuloma formation as well as lymph node cell proliferative responses to egg antigens were analyzed after 8 weeks. TCR δ mutant mice (lacking γδ T cells) displayed vigorous formation of egg granulomas that were not significantly different from those observed in normal controls, both in terms of granuloma size and cellular composition. In contrast, TCR α and TCR β mutant mice (lacking αβ T cells) were unable to form granulomas. Moreover, mesenteric lymph node cells from TCR δ mutant and control mice responded strongly to egg antigens in vitro, while TCR α and β mutant mice did not. Our studies show that in schistosomiasis granuloma formation and proliferative responses to egg antigens are strictly dependent on αβ T cells. They also suggest that γδ T cells by themselves can neither mediate a granulomatous inflammation, nor significantly modify one mediated by αβ T cells.     

Preferentially expanding Vγ1+ γδ T cells are associated with protective immunity against Plasmodium infection in mice

γδ T cells play a crucial role in controlling malaria parasites. Dendritic cell (DC) activation via CD40 ligand (CD40L)‐CD40 signaling by γδ T cells induces protective immunity against the blood‐stage Plasmodium berghei XAT (PbXAT) parasites in mice. However, it is unknown which γδ T‐cell subset has an effector role and is required to control the Plasmodium infection. Here, using antibodies to deplete TCR Vγ1⁺ cells, we saw that Vγ1⁺ γδ T cells were important for the control of PbXAT infection. Splenic Vγ1⁺ γδ T cells preferentially expand and express CD40L, and both Vγ1⁺ and Vγ4⁺ γδ T cells produce IFN‐γ during infection. Although expression of CD40L on Vγ1⁺ γδ T cells is maintained during infection, the IFN‐γ positivity of Vγ1⁺ γδ T cells is reduced in late‐phase infection due to γδ T‐cell dysfunction. In Plasmodium‐infected IFN‐γ signaling‐deficient mice, DC activation is reduced, resulting in the suppression of γδ T‐cell dysfunction and the dampening of γδ T‐cell expansion in the late phase of infection. Our data suggest that Vγ1⁺ γδ T cells represent a major subset responding to PbXAT infection and that the Vγ1⁺ γδ T‐cell response is dependent on IFN‐γ‐activated DCs.     

IL‐17‐producing γδ T cells

IL‐17 is produced not only by CD4⁺ αβ T cells, but also CD8⁺ αβ T cells, NKT cells, and γδ T cells, plus some non‐T cells, including macrophages and neutrophils. The ability of IL‐17 to deploy neutrophils to sites of inflammation imparts this cytokine with a key role in diseases of several types. Surprisingly, γδ T cells are responsible for much of the IL‐17 produced in several disease models, particularly early on.     

Different cytokine production profiles of γδ T cell clones: Relation to inflammatory arthritis

This study was performed to investigate whether γδ T cells could also be divided into subsets, identified by a cytokine profile, as described for αβ T helper (Th) cell subsets. Cytokine production was studied in 22 γδ T cell clones obtained from the synovial fluid and peripheral blood of one patient with inflammatory arthritis and compared to that of 26 αβ T cell clones of the same and different patients. Interferon-γ (IFN-γ) was produced by 18 (82%) and interleukin-4 (IL-4) by 17 (77%) out of 22 γδ T cell clones, respectively. In contrast, IL-10 was not produced, except at very low level in one case. The mean levels of IL-4 were lower for clones derived from synovial fluid. When considering the production of IFN-γ as an indicator of Th1 and that of IL-4 as an indicator of Th2, respectively, the most common pattern was a γδTh1-like pattern, with the combination of high levels of IFN-γ and low levels of IL-4. This pattern was found in Vδ1⁺ clones, all from synovial fluid. Additional patterns were also observed: a mixed, probably γδ Th0-like pattern with a more balanced production of both IFN-γ and IL-4; a γδTh1 pattern with the production of IFN-γ alone; a γδTh2 pattern with the production of IL-4 alone. These three patterns were also seen in blood γδ T cells which were all Vδ2, indicating that these patterns were independent of the γδ phenotype. γδ T cell clones produced lower levels of IFN-γ (p = 0.001) and higher levels of IL-4 than αβ clones (p < 0.02). These differences in cytokine production between αβ and γδ subsets and within these subsets may contribute to their respective role in chronic inflammation.