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.     

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.     

Interaction of KLRG1 with E‐cadherin: New functional and structural insights

The killer cell lectin‐like receptor G1 (KLRG1) is an inhibitory receptor expressed by memory T cells and NK cells in man and mice. It is frequently used as a cell differentiation marker and members of the cadherin family are ligands for KLRG1. The present study provides new insights into the interaction of mouse KLRG1 with E‐cadherin. Firstly, we demonstrate that co‐engagement of KLRG1 and CD3/TCR in a spatially linked manner was required for inhibition arguing against the notion that KLRG1‐ligation per se transmits inhibitory signals. Secondly, experiments with T cells carrying Y₇F‐mutant KLRG1 molecules with a replacement of the tyrosine residue to phenylalanine in the single ITIM indicated that the inhibitory activity of KLRG1 is counteracted to some degree by increased interaction of KLRG1⁺ T cells with E‐cadherin expressing target cells. Thirdly, we demonstrate that deletion of the first or the second external domain of E‐cadherin abolished reactivity in KLRG1‐reporter cell assays. Finally, we made the intriguing observation that KLRG1 formed multimeric protein complexes in T cells in addition to the previously described mono‐ and dimeric molecules.     

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.     

Cytomegalovirus vector expressing RAE‐1γ induces enhanced anti‐tumor capacity of murine CD8+ T cells

Designing CD8⁺ T‐cell vaccines, which would provide protection against tumors is still considered a great challenge in immunotherapy. Here we show the robust potential of cytomegalovirus (CMV) vector expressing the NKG2D ligand RAE‐1γ as CD8⁺ T cell‐based vaccine against malignant tumors. Immunization with the CMV vector expressing RAE‐1γ, delayed tumor growth or even provided complete protection against tumor challenge in both prophylactic and therapeutic settings. Moreover, a potent tumor control in mice vaccinated with this vector can be further enhanced by blocking the immune checkpoints TIGIT and PD‐1. CMV vector expressing RAE‐1γ potentiated expansion of KLRG1⁺ CD8⁺ T cells with enhanced effector properties. This vaccination was even more efficient in neonatal mice, resulting in the expansion and long‐term maintenance of epitope‐specific CD8⁺ T cells conferring robust resistance against tumor challenge. Our data show that immunomodulation of CD8⁺ T‐cell responses promoted by herpesvirus expressing a ligand for NKG2D receptor can provide a powerful platform for the prevention and treatment of CD8⁺ T‐cell sensitive tumors.     

High frequency of CD8αα homodimer-bearing T cells in human fetal intestine

Immunohistochemistry on frozen sections was used to identify CD8αα cells and CD8αβ cells in human intestine. As observed previously, CD8αβ cells predominate (>95%) in tonsil and post-natal intestine. However in human fetal intestine (16–24 weeks gestation), almost half the CD8⁺ cells in the lamina propria are CD8αα, and many CD8αα cells can be identified in the epithelium. In contrast, in the T cell zones of the Peyer's patches, CD8αβ cells are dominant. The CD8αα cells are virtually all αβ T cell receptor positive. By analogy with the murine system, these CD8αα cells in the fetal gut may be directly derived from the marrow, undergoing thymus-independent differentiation in the gut mucosa.     

The NK receptor KLRG1 is dispensable for virus‐induced NK and CD8+ T‐cell differentiation and function in vivo

The killer cell lectin‐like receptor G1 (KLRG1) is expressed by NK and T‐cell subsets and recognizes members of the classical cadherin family. KLRG1 is widely used as a lymphocyte differentiation marker in both humans and mice but the physiological role of KLRG1 in vivo is still unclear. Here, we generated KLRG1‐deficient mice by homologous recombination and used several infection models for their characterization. The results revealed that KLRG1 deficiency did not affect development and function of NK cells examined under various conditions. KLRG1 was also dispensable for normal CD8⁺ T‐cell differentiation and function after viral infections. Thus, KLRG1 is a marker for distinct NK and T‐cell differentiation stages but it does not play a deterministic role in the generation and functional characteristics of these lymphocyte subsets. In addition, we demonstrate that E‐cadherin expressed by K562 target cells inhibited NK‐cell reactivity in transgenic mice over‐expressing KLRG1 but not in KLRG1‐deficient or WT mice. Hence, the inhibitory potential of KLRG1 in mice is rather weak and strong activation signals during viral infections may override the inhibitory signal in vivo.     

Carbon monoxide‐treated dendritic cells decrease β1‐integrin induction on CD8+ T cells and protect from type 1 diabetes

Carbon monoxide (CO) treatment improves pathogenic outcome of autoimmune diseases by promoting tolerance. However, the mechanism behind this protective tolerance is not yet defined. Here, we show in a transgenic mouse model for autoimmune diabetes that ex vivo gaseous CO (gCO)‐treated DCs loaded with pancreatic β‐cell peptides protect mice from disease. This protection is peptide‐restricted, independent of IL‐10 secretion by DCs and of CD4⁺ T cells. Although no differences were observed in autoreactive CD8⁺ T‐cell function from gCO‐treated versus untreated DC‐immunized groups, gCO‐treated DCs strongly inhibited accumulation of autoreactive CD8⁺ T cells in the pancreas. Interestingly, induction of β1‐integrin was curtailed when CD8⁺ T cells were primed with gCO‐treated DCs, and the capacity of these CD8⁺ T cells to lyse isolated islet was dramatically impaired. Thus, immunotherapy using CO‐treated DCs appears to be an original strategy to control autoimmune disease.     

Inhibition of R5‐tropic HIV type‐1 replication in CD4+ natural killer T cells by γδ T lymphocytes

After the development of highly active anti‐retroviral therapy, it became clear that the majority of emergent HIV‐1 is macrophage‐tropic and infects CD4⁺, CCR5‐expressing cells (R5‐tropic). There are three distinct cell populations, R5‐tropic, HIV‐1‐susceptible CD4⁺ cells: (i) natural killer T (NKT) cells, (ii) dendritic cells and macrophages, and (iii) tissue‐associated T cells residing primarily at mucosal surfaces. We have confirmed that CD4⁺ NKT cells derived from peripheral blood mononuclear cells (PBMCs) predominantly express CCR5 rather than CXCR4, whereas the reverse is true for CD4⁺ T cells derived from circulating PBMCs, and that R5‐tropic HIV‐1 expands efficiently in the CD4⁺ NKT cells. Moreover, when PBMCs depleted of CD8α⁺ cells were stimulated in the presence of α‐galactosylceramide (α‐GalCer) and R5‐tropic HIV‐1 [NL(AD8)], the production of HIV‐1 virions was not suppressed, whereas, similar to the untreated PBMCs, depletion of CD8β⁺ cells from PBMCs significantly inhibited virion production. These findings suggest that CD8αα⁺ but not CD8αβ⁺ cells may have the ability to inhibit R5‐tropic HIV‐1 replication in CD4⁺ NKT cells. Here, we show that co‐culturing R5‐tropic HIV‐1‐infected CD4⁺ NKT cells with CD8αα⁺ γδ T cells, in particular Vγ1Vδ1 cells, but not with CD8αα⁺ NKT cells or CD8αα⁺ dendritic cells, inhibits HIV‐1 replication mainly by secreting chemokines, such as macrophage inflammatory proteins 1α and 1β and RANTES. Collectively, these results indicate the importance of CD8αα⁺ γδ T cells in the control of R5‐tropic HIV‐1 replication and persistence in CD4⁺ NKT cells.     

Sympathetic neural signaling via the β2‐adrenergic receptor suppresses T‐cell receptor‐mediated human and mouse CD8+ T‐cell effector function

Postganglionic sympathetic neurons innervate secondary lymphoid organs and secrete norepinephrine (NE) as the primary neurotransmitter. NE binds and signals through five distinct members of the adrenergic receptor family. In this study, we show elevated expression of the β2‐adrenergic receptor (ADRB2) on primary human CD8⁺ effector memory T cells. Treatment of both human and murine CD8⁺ T cells with NE decreased IFN‐γ and TNF‐α secretion and suppressed their cytolytic capacity in response to T‐cell receptor (TCR) activation. The effects of NE were specifically reversed by β 2‐specific antagonists. Adrb2^?/? CD8⁺ T cells were completely resistant to the effects of NE. Further, the ADRB2‐specific pharmacological ligand, albuterol, significantly suppressed effector functions in both human and mouse CD8⁺ T cells. While both TCR activation and stimulation with IL‐12 + IL‐18 were able to induce inflammatory cytokine secretion, NE failed to suppress IFN‐γ secretion in response to IL‐12 + IL18. Finally, the long‐acting ADRB2‐specific agonist, salmeterol, markedly reduced the cytokine secretion capacity of CD8⁺ T cells in response to infection with vesicular stomatitis virus. This study reveals a novel intrinsic role for ADRB2 signaling in CD8⁺ T‐cell function and underscores the novel role this pathway plays in adaptive T‐cell responses to infection.     

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.     

TGF‐β interactions with IL‐1 family members trigger IL‐4‐independent IL‐9 production by mouse CD4+ T cells

TGF‐β and IL‐4 were recently shown to selectively upregulate IL‐9 production by naïve CD4⁺ T cells. We report here that TGF‐β interactions with IL‐1α, IL‐1β, IL‐18, and IL‐33 have equivalent IL‐9‐stimulating activities that function even in IL‐4‐deficient animals. This was observed after in vitro antigenic stimulation of immunized or unprimed mice and after polyclonal T‐cell activation. Based on intracellular IL‐9 staining, all IL‐9‐producing cells were CD4⁺ and 80–90% had proliferated, as indicated by reduced CFSE staining. In contrast to IL‐9, IL‐13 and IL‐17 were strongly stimulated by IL‐1 and either inhibited (IL‐13) or were unaffected (IL‐17) by addition of TGF‐β. IL‐9 and IL‐17 production also differed in their dependence on IL‐2 and regulation by IL‐1/IL‐23. As IL‐9 levels were much lower in Th2 and Th17 cultures, our results identify TGF‐β/IL‐1 and TGF‐β/IL‐4 as the main control points of IL‐9 synthesis.     

α4β1 integrin promotes accumulation of tissue‐resident memory CD8+ T cells in salivary glands

The salivary glands (SGs) of virus‐immune mice contain substantial numbers of tissue‐resident memory CD8⁺ T cells (T_RM cells) that can provide immunity to local infections. Integrins regulate entry of activated T cells into nonlymphoid tissues but the molecules that mediate migration of virus‐specific CD8⁺ T cells to the SGs have not yet been defined. Here, we found that polyinosinic‐polycytidylic acid (poly(I:C)) strongly promoted the accumulation of P14 TCR‐transgenic CD8⁺ T_RM cells in SGs in an α₄β₁ integrin‐dependent manner. After infection with lymphocytic choriomeningitis virus, accumulation of P14 T_RM cells in SGs and intestine but not in kidney was also α₄ integrin dependent. Blockade of α₄β₇ by monoclonal antibodies (mAbs) inhibited lymphocytic choriomeningitis virus‐induced accumulation of P14 T_RM cells in the intestine but not in SGs. In conclusion, our data reveal that α₄β₁ integrin mediates CD8⁺ T_RM accumulation in SGs and that poly(I:C) can be used to direct activated CD8⁺ T cells to this organ.     

Impaired cross‐presentation of CD8α+CD11c+ dendritic cells by Japanese encephalitis virus in a TLR2/MyD88 signal pathway‐dependent manner

Cross‐presentation is the pathway by which exogenous antigens are routed for presentation by MHC class I molecules leading to activation of antiviral CD8⁺ T‐cell responses. However, there is little information describing the modulation of cross‐presentation and the impact of pathogen‐derived signals associated with Japanese encephalitis virus (JEV), which is one of the most common causes of encephalitis in humans. In this study, we demonstrate that JEV infection could suppress in vivo cross‐presentation of soluble and cell‐associated antigens, thereby generating weak CD8⁺ T‐cell responses to exogenous antigens, as evaluated by CFSE dilution of adoptively transferred CD8⁺ T cells and in vivo CTL killing activity. Furthermore, CD8α⁺CD11c⁺ dendritic cells (DCs), which are known to be far more efficient at cross‐presenting soluble antigens, played a specific role in contributing to JEV‐mediated inhibition of the cross‐presentation of exogenous antigens through interference with effective antigen uptake. Finally, this study provides evidence that TLR2‐MyD88 and p38 MAPK signal pathway might be involved in JEV‐mediated inhibition of cross‐presentation of soluble and cell‐associated antigens. These observations suggest that the modulation of cross‐presentation of exogenous antigens through TLR signaling has important implications for antiviral immune responses against JEV infection and the development of effective vaccination strategies.     

CD8+ CD122+ regulatory T cells contain clonally expanded cells with identical CDR3 sequences of the T‐cell receptor β‐chain

We identified CD8⁺ CD122⁺ regulatory T cells (CD8⁺ CD122⁺ Treg cells) and reported their importance in maintaining immune homeostasis. The absence of CD8⁺ CD122⁺ Treg cells has been shown to lead to severe systemic autoimmunity in several mouse models, including inflammatory bowel diseases and experimental autoimmune encephalomyelitis. The T‐cell receptors (TCRs) expressed on CD8⁺ CD122⁺ Treg cells recognize the target cells to be regulated. To aid in the identification of the target antigen(s) recognized by TCRs of CD8⁺ CD122⁺ Treg cells, we compared the TCR diversity of CD8⁺ CD122⁺ T cells with that of conventional, naive T cells in mice. We analysed the use of TCR‐Vβ in the interleukin 10‐producing population of CD8⁺ CD122⁺ T cells marked by high levels of CD49d expression, and found the significantly increased use of Vβ13 in these cells. Immunoscope analysis of the complementarity‐determining region 3 (CDR3) of the TCR β‐chain revealed remarkable skewing in a pair of Vβ regions, suggesting the existence of clonally expanded cells in CD8⁺ CD122⁺ T cells. Clonal expansion in Vβ13⁺ cells was confirmed by determining the DNA sequences of the CDR3s. The characteristic TCR found in this study is an important building block for further studies to identify the target antigen recognized by CD8⁺ CD122⁺ Treg cells.     

TGF‐β regulation of encephalitogenic and regulatory T cells in multiple sclerosis

Transforming growth factor beta (TGF‐β) is a pleiotropic cytokine that has been shown to influence the differentiation and function of T cells. The role that TGF‐β plays in immune‐mediated disease, such as multiple sclerosis (MS), has become a major area of investigation since CD4⁺ T cells appear to be a major mediator of autoimmunity. This review provides an analysis of the literature on the role that TGF‐β plays in the generation and regulation of encephalitogenic and regulatory T cells (Treg) in experimental autoimmune encephalomyelitis (EAE), an animal model of MS, as well as in T cells of MS patients. Since TGF‐β plays a major role in the development and function of both CD4⁺ effector and Treg, which are defective in MS patients, recent studies have found potential mechanisms to explain the basis for these T‐cell defects to establish a foundation for potentially modulating TGF‐β signaling to restore normal T‐cell function in MS patients.