Peripheral Thy1+ lymphocytes rearranging TCR‐γδ genes in LAT‐deficient mice

Linker for activation of T cells (LAT) is an adaptor molecule indispensable for development of αβ and γδ T lymphocytes. Surprisingly, using a new model of LAT‐deficient mice we found that despite arrested thymic development, a discrete population of cells with active Lat promoter, expressing Thy1 molecules, accumulated in peripheral lymphoid organs of homozygous (Lat^Inv/Inv) mutant mice. By measuring frequencies of TCR gene rearrangements in conjunction with a panel of cell surface Ag, we dissected two subsets of these Thy1⁺ cells. Thy1^dull cells expressed markers of NK lymphocytes and contained low frequency of TCR‐γ gene rearrangements without detectable TCR‐δ rearrangements. Thy1^high cells resembled immature CD44⁺CD25⁺ thymocytes and contained high frequency of non‐productive TCR‐γ and TCR‐δ rearrangements, indicating that cells displaying molecular signatures of commitment toward γδ T‐cell lineage can develop and populate lymphoid tissues of LAT‐deficient mice. Phenotypically similar Thy1^high cells were also found in lymph nodes of lymphocyte‐deficient (Rag2^?/?) mice but not in T lymphocyte proficient, heterozygous Lat^+/Inv mice suggesting that Thy1^high cells of LAT‐deficient mice identified in this study accumulate in peripheral lymphoid organs as a result of congenital lymphopenia.     

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.     

Separately expressed T cell receptor α and β chain transgenes exert opposite effects on T cell differentiation and neoplastic transformation

Two aspects of T cell differentiation in T cell receptor (TCR)-transgenic mice, the generation of an unusual population of CD4^?CD8^?TCR⁺ thymocytes and the absence of γδ cells, have been the focus of extensive investigation. To examine the basis for these phenomena, we investigated the effects of separate expression of a transgenic TCR α chain and a transgenic TCR β chain on thymocyte differentiation. Our data indicate that expression of a transgenic TCR α chain causes thymocytes to differentiate into a CD4^?CD8^?TCR⁺ lineage at an early developmental stage, depleting the number of thymocytes that differentiate into the αβ lineage. Surprisingly, expression of the TCR α chain transgene is also associated with the development of T cell lymphosarcoma. In contrast, expression of the transgenic TCR β chain causes immature T cells to accelerate differentiation into the αβ lineage and thus inhibits the generation of γδ cells. Our observations provide a model for understanding T cell differentiation in TCR-transgenic mice.     

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.     

Germinal center formation in mice lacking αβ T cells

T cells are essential for inducing clonal B cell expansion in germinal centers during T cell-dependent antibody responses. However, class-switched antibodies are readily detectable in TCRα-deficient mice that congenitally lack αβ T cells, including those such as IgG1 that are considered to be dependent on collaboration between B cells and αβ T cells. This observation suggests that a novel form of B:T collaboration may be evident in TCRα^?/? mice. We report that germinal centers develop spontaneously in mice lacking T cell receptor α genes (TCRα^?/?), despite the absence of αβ T cells. They are not seen in TCRβ^?/? mice kept in similar conditions. Both strains of mice have γδ T cells, but it is a subset of T cells expressing TCRβ and CD4 that is dominant in the germinal centers of TCRα^?/? mice. Exceptionally, germinal centers were associated with CD4⁺ γδ T cells. The expression of CD4 seems to be important, for few extrafollicular T cells have CD4 and CD4 is largely absent from TCRβ^?/? T cells. The CD4⁺ TCRβ cells may help B cells produce autoantibodies that have been identified in TCRα^?/? mice.     

In vivo application of mAb directed against the γδ TCR does not deplete but generates “invisible” γδ T cells

mAb targeting the γδ TCR have been used for γδ T‐cell depletion with varying success. Although the depletion‐capacity of the anti‐γδ TCR mAb clone GL3 has been disputed repeatedly, many groups continue to use γδ T‐cell depletion protocols involving the mAb clone UC7‐13D5 and find significant biological effects. We show here that treatment with both GL3 and UC7‐13D5 antibodies does not deplete γδ T cells in vivo, but rather leads to TCR internalization and thereby generates “invisible” γδ T cells. We addressed this issue using anti‐γδ TCR mAb injections into WT mice as well as into reporter TCR delta locus‐histone 2B enhanced GFP knock‐in mice, in which γδ T cells can be detected based on an intrinsic green fluorescence. Importantly, the use of TCR delta locus‐histone 2B enhanced GFP mice provided here for the first time direct evidence that the “depleted” γδ T cells were actually still present. Our results show further that GL3 and UC7‐13D5 mAb are in part cross‐competing for the same epitope. Assessed by activation markers, we observed in vitro and in vivo activation of γδ T cells through mAb. We conclude that γδ T‐cell depletion experiments must be evaluated with caution and discuss the implications for future studies on the physiological functions of γδ T cells.     

Evidence for programmed cell death of self-reactive γδ T cell receptor-positive thymocytes

The negative selection of T cells expressing the γδ T cell antigen receptor (γδ T cells) was studied using transgenic mice expressing a γδ receptor with specificity for an H-2T-linked class I major histocompatibility complex molecule from H-2^b mice. The potentially self-reactive γδ thymocytes in H-2^b/d transgenic mice are larger and have lower levels of γδ T cell receptor expression than γδ thymocytes from H-2^d mice. H-2^b/d γδ thymocytes do not respond to H-2^b antigen-presenting cells, and thus are inactive compared to H-2^d γδ thymocytes. However, the H-2^b/d γδ thymocyte population, but not the H-2^d γδ thymocyte population, undergoes a high rate of programmed cell death when placed in overnight culture. These observations constitute the first direct evidence that self-reactive γδ thymocytes undergo programmed cell death. This in vitro programmed cell death of self-reactive γδ thymocytes may reflect the clonal deletion process that results in a depletion of γδ T cells in the peripheral lymphoid organs of adult H-2^b/d mice. We also present evidence that self-reactive γδ T cells, similarly to αβ T cells, undergo a lesser degree of clonal deletion in neonatal mice compared to adult mice.     

γδ T cells come to stay: Innate skin memory in the Aldara model

The term immunological memory has long been a trademark restricted to adaptive lymphocytes such as memory B cells and plasma cells as well as memory CD8⁺ αβ T cells. In recent years, innate lymphocytes such as NK cells have also been shown to adapt to their environment by antigen‐specific expansion and selective survival. However, whether γδ T cells mount comparable memory responses to pathogenic stimuli is less well understood. In this issue of European Journal of Immunology, Hartwig et al. [Eur. J. Immunol. 2015. 45: 3022–3033] identify a subset of IL‐17‐producing γδ T cells that are capable of establishing long‐lived memory in the skin of mice exposed to imiquimod in the Aldara psoriasis model. These γδ T cells uniformly express a Vγ4⁺Vδ4⁺ TCR. They produce IL‐17A/F and persist in the dermis for long periods of time, also at untreated distal sites. Upon secondary challenge, experienced Vγ4⁺Vδ4⁺ cells show enhanced effector functions and mediate exacerbated secondary inflammation. These findings showcase innate γδ T‐cell memory that uses a single conserved public TCR combination. Furthermore, they provide mechanistic insight to the observed psoriatic relapses in patients in response to topical treatment with imiquimod.     

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.     

Neonates harbour highly active γδ T cells with selective impairments in preterm infants

Acknowledgement of the breadth of T‐cell pleiotropy has provoked increasing interest in the degree to which functional responsiveness is elicited by environmental cues versus differentiation. This is particularly relevant for young animals requiring rapid responses to acute environmental exposure. In young mice, γδ T cells are disproportionately important for immuno‐protection. To examine the situation in humans, we compared populations and clones of T cells from term and preterm babies, and adults. By comparison with αβ T cells, neonate‐derived γδ cells show stronger, pleiotropic functional responsiveness, and lack signatory deficits in IFN‐γ production. Emphasising the acquisition of functional competence in utero, IFN‐γ was produced by γδ cells sampled from premature births, and, although one month's post‐partum environmental exposure invariably increased their TNF‐α production, it had no consistent effect on IFN‐γ or IL‐2. In sum, γδ cells seem well positioned at birth to contribute to immuno‐protection and immuno‐regulation, possibly compensating for selective immaturity in the αβ compartment. With regard to the susceptibilities of preterm babies to viral infection, γδ cells from preterm neonates were commonly impaired in Toll‐like receptor‐3 and ‐7 expression and compared with cells from term babies failed to optimise cytokine production in response to coincident TCR and TLR agonists.     

γδ T Cell Receptor Deficiency Attenuated Cardiac Allograft Vasculopathy and Promoted Regulatory T cell Expansion

γδ T cell comprises about 5% of the overall T cell population, and they differ from conventional αβ T cells. Previous studies have indicated the contribution of γδ T cell to acute allograft rejection, but the role of γδ T cell in cardiac allograft vasculopathy (CAV) is not investigated. Hearts of adult B6.C‐H‐2^bm12KhEg were heterotopically transplanted into major histocompatibility complex (MHC) class II‐mismatched C57BL/6 mice (wild‐type, γδ TCR^?/?), which is an established murine model of chronic allograft rejection without immunosuppression. The survival of grafts was monitored daily by abdominal palpation until the complete cessation of cardiac contractility. Our current study demonstrated that γδ T cell receptor (TCR) deficiency significantly attenuated CAV, and this effect coincides with low expression of Hmgb1, IFN‐γ and IL‐17 while increased number of CD4⁺CD25⁺Foxp3⁺ regulatory T cells, and depletion of regulatory T cells abrogated the prolonged allograft survival induced by γδ TCR deficiency. γδ TCR deficiency resulted in attenuated CAV and prolonged graft survival in murine models of cardiac transplantation, and this effect was associated with enhanced expansion of regulatory T cells.     

4–1BB signal stimulates the activation,expansion, and effector functions of γδ T cells in mice and humans

We show here that the expression of 4–1BB is rapidly induced in γδ T cells following antigenic stimulation in both mice and humans, and ligation of the newly acquired 4–1BB with an agonistic anti‐4–1BB augments cell division and cytokine production. We further demonstrate that γδ rather than αβ T cells protect mice from Listeria monocytogenes (LM) infection and 4–1BB stimulation enhances the γδ T‐cell activities in the acute phase of LM infection. IFN‐γ produced from γδ T cells was the major soluble factor regulating LM infection. Vγ1⁺ T cells were expanded in LM‐infected mice and 4–1BB signal triggered an exclusive expansion of Vγ1⁺ T cells and induced IFN‐γ in these Vγ1⁺ T cells. Similarly, 4–1BB was induced on human γδ T cells and shown to be fully functional. Combination treatment with human γδ T cells and anti‐hu4–1BB effectively protected against LM infection in human γδ T cell‐transferred NOD‐SCID mice. Taken together, these data provide evidence that the 4–1BB signal is an important regulator of γδ T cells and induces robust host defense against LM infection.     

CCR6 and NK1.1 distinguish between IL‐17A and IFN‐γ‐producing γδ effector T cells

γδ T cells are a potent source of innate IL‐17A and IFN‐γ, and they acquire the capacity to produce these cytokines within the thymus. However, the precise stages and required signals that guide this differentiation are unclear. Here we show that the CD24^low CD44^high effector γδ T cells of the adult thymus are segregated into two lineages by the mutually exclusive expression of CCR6 and NK1.1. Only CCR6⁺ γδ T cells produced IL‐17A, while NK1.1⁺ γδ T cells were efficient producers of IFN‐γ but not of IL‐17A. Their effector phenotype correlated with loss of CCR9 expression, particularly among the NK1.1⁺ γδ T cells. Accordingly, both γδ T‐cell subsets were rare in gut‐associated lymphoid tissues, but abundant in peripheral lymphoid tissues. There, they provided IL‐17A and IFN‐γ in response to TCR‐specific and TCR‐independent stimuli. IL‐12 and IL‐18 induced IFN‐γ and IL‐23 induced IL‐17A production by NK1.1⁺ or CCR6⁺ γδ T cells, respectively. Importantly, we show that CCR6⁺ γδ T cells are more responsive to TCR stimulation than their NK1.1⁺ counterparts. In conclusion, our findings support the hypothesis that CCR6⁺ IL‐17A‐producing γδ T cells derive from less TCR‐dependent selection events than IFN‐γ‐producing NK1.1⁺ γδ 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.     

Dermal IL‐17‐producing γδ T cells establish long‐lived memory in the skin

Conventional αβ T cells have the ability to form a long‐lasting resident memory T‐cell (T_RM) population in nonlymphoid tissues after encountering foreign antigen. Conversely, the concept of ‘innate memory’, where the ability of nonadaptive branches of the immune system to deliver a rapid, strengthened immune response upon reinfection or rechallenge, is just emerging. Using the αβ T‐cell‐independent Aldara psoriasis mouse model in combination with genetic fate‐mapping and reporter systems, we identified a subset of γδ T cells in mice that is capable of establishing a long‐lived memory population in the skin. IL‐17A/F‐producing Vγ4⁺Vδ4⁺ T cells populate and persist in the dermis for long periods of time after initial stimulation with Aldara. Experienced Vγ4⁺Vδ4⁺ cells show enhanced effector functions and mediate an exacerbated secondary inflammatory response. In addition to identifying a unique feature of γδ T cells during inflammation, our results have direct relevance to the human disease as this quasi‐innate memory provides a mechanistic insight into relapses and chronification of psoriasis.     

Differential dependence on nuclear factor‐κB‐inducing kinase among natural killer T‐cell subsets in their development

Natural killer T cells (NKT cells) are comprised of several subsets. However, the possible differences in their developmental mechanisms have not been fully investigated. To evaluate the dependence of some NKT subpopulations on nuclear factor-κB-inducing kinase (NIK) for their generation, we analysed the differentiation of NKT cells, dividing them into subsets in various tissues of alymphoplasia (aly/aly), a mutant mouse strain that lacks functional NIK. The results indicated that the efficient differentiation of both invariant NKT (iNKT) and non-iNKT cells relied on NIK expression in non-haematopoietic cells; however, the dependence of non-iNKT cells was lower than that of iNKT cells. Especially, the differentiation of CD8⁺ non-iNKT cells was markedly resistant to the aly mutation. The proportion of two other NKT cell subsets, NK1.1⁺ γδ T cells and NK1.1⁻ iNKT cells, was also significantly reduced in aly/aly mice, and this defect in their development was reversed in wild-type host mice given aly/aly bone marrow cells. In exerting effector functions, NIK in NKT-αβ cells appeared dispensable, as NIK-deficient NKT-αβ cells could secrete interleukin-4 or interferon-γ and exhibit cytolytic activity at a level comparable to that of aly/+ NKT-αβ cells. Collectively, these results imply that the NIK in thymic stroma may be critically involved in the differentiation of most NKT cell subsets (although the level of NIK dependence may vary among the subsets), and also that NIK in NKT-αβ cells may be dispensable for their effector function.     

CCR7‐mediated migration in the thymus controls γδ T‐cell development

αβ T‐cell development and selection proceed while thymocytes successively migrate through distinct regions of the thymus. For γδ T cells, the interplay of intrathymic migration and cell differentiation is less well understood. Here, we crossed C‐C chemokine receptor (CCR)7‐deficient (Ccr7^?/?) and CCR9‐deficient mice (Ccr9^?/?) to mice with a TcrdH2BeGFP reporter background to investigate the impact of thymic localization on γδ T‐cell development. γδ T‐cell frequencies and numbers were decreased in CCR7‐deficient and increased in CCR9‐deficient mice. Transfer of CCR7‐ or CCR9‐deficient BM into irradiated C57BL/6 WT recipients reproduced these phenotypes, pointing toward cell‐intrinsic migration defects. Monitoring recent thymic emigrants by intrathymic labeling allowed us to identify decreased thymic γδ T‐cell output in CCR7‐deficient mice. In vitro, CCR7‐deficient precursors showed normal γδ T‐cell development. Immunohistology revealed that CCR7 and CCR9 expression was important for γδ T‐cell localization within thymic medulla or cortex, respectively. However, γδ T‐cell motility was unaltered in CCR7‐ or CCR9‐deficient thymi. Together, our results suggest that proper intrathymic localization is important for normal γδ T‐cell development.     

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.