DX5+CD4+ T cells modulate CD4+ T‐cell response via inhibition of IL‐12 production by DCs

DX5⁺CD4⁺ T cells have been shown to dampen collagen‐induced arthritis and delayed‐type hypersensitivity reactions in mice. These cells are also potent modulators of T‐helper cell responses through direct effects on CD4⁺ T cells in an IL‐4 dependent manner. To further characterize this T‐cell population, we studied their effect on DCs and the potential consequences on T‐cell activation. Here, we show that mouse DX5⁺CD4⁺ T cells modulate DCs by robustly inhibiting IL‐12 production. This modulation is IL‐10 dependent and does not require cell contact. Furthermore, DX5⁺CD4⁺ T cells modulate the surface phenotype of LPS‐matured DCs. DCs modulated by DX5⁺CD4⁺ T‐cell supernatant express high levels of the co‐inhibitor molecules PDL‐1 and PDL‐2. OVA‐specific CD4⁺ T cells primed with DCs exposed to DX5⁺CD4⁺ T‐cell supernatant produce less IFN‐γ than CD4⁺ T cells primed by DCs exposed to either medium or DX5^?CD4⁺ T‐cell supernatant. The addition of IL‐12 to the co‐culture with DX5⁺ DCs restores IFN‐γ production. When IL‐10 present in the DX5⁺CD4⁺ T‐cell supernatant is blocked, DCs re‐establish their ability to produce IL‐12 and to efficiently prime CD4⁺ T cells. These data show that DX5⁺CD4⁺ T cells can indirectly affect the outcome of the T‐cell response by inducing DCs that have poor Th1 stimulatory function.     

CD161++CD8+ T cells,including the MAIT cell subset,are specifically activated by IL‐12+IL‐18 in a TCR‐independent manner

CD161⁺⁺CD8⁺ T cells represent a novel subset that is dominated in adult peripheral blood by mucosal‐associated invariant T (MAIT) cells, as defined by the expression of a variable‐α chain 7.2 (Vα7.2)‐Jα33 TCR, and IL‐18Rα. Stimulation with IL‐18+IL‐12 is known to induce IFN‐γ by both NK cells and, to a more limited extent, T cells. Here, we show the CD161⁺⁺ CD8⁺ T‐cell population is the primary T‐cell population triggered by this mechanism. Both CD161⁺⁺Vα7.2⁺ and CD161⁺⁺Vα7.2^? T‐cell subsets responded to IL‐12+IL‐18 stimulation, demonstrating this response was not restricted to the MAIT cells, but to the CD161⁺⁺ phenotype. Bacteria and TLR agonists also indirectly triggered IFN‐γ expression via IL‐12 and IL‐18. These data show that CD161⁺⁺ T cells are the predominant T‐cell population that responds directly to IL‐12+IL‐18 stimulation. Furthermore, our findings broaden the potential role of MAIT cells beyond bacterial responsiveness to potentially include viral infections and other inflammatory stimuli.     

Differential T‐cell receptor signals for T helper cell programming

Upon encounter with their cognate antigen, naive CD4 T cells become activated and are induced to differentiate into several possible T helper (Th) cell subsets. This differentiation depends on a number of factors including antigen‐presenting cells, cytokines and co‐stimulatory molecules. The strength of the T‐cell receptor (TCR) signal, related to the affinity of TCR for antigen and antigen dose, has emerged as a dominant factor in determining Th cell fate. Recent studies have revealed that TCR signals of high or low strength do not simply induce quantitatively different signals in the T cells, but rather qualitatively distinct pathways can be induced based on TCR signal strength. This review examines the recent literature in this area and highlights important new developments in our understanding of Th cell differentiation and TCR signal strength.     

Induction of peripheral CD4+ T‐cell tolerance and CD8+ T‐cell cross‐tolerance by dendritic cells

DC can present and cross‐present self‐antigens to autoreactive CD4⁺ and CD8⁺ T cells, respectively, and incapacitate them by inducing anergy, deletion or converting them into Treg. In this review, we summarize the recent progress in immune tolerance research, which has been achieved by employing antigen‐ and TCR‐transgenic mice. We cover the numerous discoveries that have furthered our knowledge of the DC subsets and maturation pathways involved in tolerance; the signals, such as CD70, TGF‐β, B7‐H1/PD‐L1, which dictate the decision between immunity and tolerance; and the in vivo role of DC in the maintenance of CD4⁺ T‐cell tolerance and CD8⁺ T‐cell cross‐tolerance.     

Modelling pathways of CD8+ T‐cell differentiation

In an immune response to infection, naïve T lymphocytes proliferate and give rise to a heterogeneous population of effector and memory cells. How is this diversity generated, and how can it be manipulated? Answering these questions requires an understanding of the lineage relationships between different effector and memory‐cell subsets, but these relationships remain to be identified definitively. In this issue of the European Journal of Immunology, a study moves us closer to this goal by combining a mathematical model and data from influenza infections in mice to support the hypothesis that CD8⁺ T‐cell differentiation is strongly coupled to cell division.     

Overexpression of IL-21 promotes massive CD8+ memory T cell accumulation

The ability of IL-21 to promote in vitro T cell survival led us to investigate its biological activity in vivo. We report that overexpression of IL-21 in transgenic mice drives CD8(+) memory T cell accumulation with a concomitant reduction in naive T cell numbers. These memory T cells are functional, given their ability to rapidly produce IFN-gamma and proliferate following stimulation. Since the homeostasis of naive and memory T cells is controlled by cytokines, we evaluated whether IL-21 influences cytokine receptor expression. We show that IL-21 inhibits IL-7R expression on naive T cells in vitro, suggesting impaired IL-7-mediated naive T cell survival in IL-21-transgenic mice. In contrast, IL-7R expression on CD4(+) memory T cells is not affected, allowing their IL-7-dependent survival in IL-21-transgenic mice. Although IL-21 decreases IL-7R expression on CD8(+) memory T cells, this has no impact on their survival since their maintenance in the T cell pool is IL-7-independent. Rather, we demonstrate that CD8(+) memory T cells are receptive to IL-21 survival signals allowing for their accumulation in IL-21-transgenic mice. This study identifies new roles for IL-21 in T cell homeostasis and in the regulation of T cell responses to cytokines.     

Type I interferon potentiates T‐cell receptor mediated induction of IL‐10‐producing CD4+ T cells

Type I interferons (IFNs) have the dual ability to promote the development of the immune response and exert an anti‐inflammatory activity. We analyzed the integrated effect of IFN‐α, TCR signal strength, and CD28 costimulation on human CD4⁺ T‐cell differentiation into cell subsets producing the anti‐ and proinflammatory cytokines IL‐10 and IFN‐γ. We show that IFN‐α boosted TCR‐induced IL‐10 expression in activated peripheral CD45RA⁺CD4⁺ T cells and in whole blood cultures. The functional cooperation between TCR and IFN‐α efficiently occurred at low engagement of receptors. Moreover, IFN‐α rapidly cooperated with anti‐CD3 stimulation alone. IFN‐α, but not IL‐10, drove the early development of type I regulatory T cells that were mostly IL‐10⁺ Foxp3^? IFN‐γ^? and favored IL‐10 expression in a fraction of Foxp3⁺ T cells. Our data support a model in which IFN‐α costimulates TCR toward the production of IL‐10 whose level can be amplified via an autocrine feedback loop.     

Pathways of memory CD8+ T‐cell development

CD8⁺ T‐cell responses must have at least two components, a replicative cell type that proliferates in the secondary lymphoid tissue and that is responsible for clonal expansion, and cytotoxic cells with effector functions that mediate the resolution of the infection in the peripheral tissues. To confer memory, the response must also generate replication‐competent T cells that persist in the absence of antigen after the primary infection is cleared. The current models of memory differentiation differ in regards to whether or not memory CD8⁺ T cells acquire effector functions during their development. In this review we discuss the existing models for memory development and the consequences that the recent finding that memory CD8⁺ T cells may express granzyme B during their development has for them. We propose that memory CD8⁺ T cells represent a self‐renewing population of T cells that may acquire effector functions but that do not lose the naïve‐like attributes of lymphoid homing, antigen‐independent persistence or the capacity for self‐renewal.     

Division‐linked differentiation can account for CD8+ T‐cell phenotype in vivo

The CD8⁺ T‐cell response to infection involves a large initial expansion in the numbers of responding cells, accompanied by differentiation of these cells. Expression of the adhesion molecule CD62L is high on naïve cells and rapidly downregulated on the surface of the majority (～90%) of cells during the ‘effector’ phase of acute infection. Adoptive transfer studies have been used to study differentiation in this system; however, relatively little work has investigated the phenotype of cells in the endogenous repertoire. We demonstrate that the extent of CD62L down‐regulation is positively correlated with clone size in vivo, consistent with division‐linked differentiation of responding cells. Other features of the endogenous CD62L^hi and CD62L^lo repertoire are that the CD62L^lo repertoire is less diverse than the CD62L^hi repertoire and represents a subset of clonotypes found in the CD62L^hi repertoire. To test whether these observations are compatible with a mechanism of division‐linked differentiation, we developed a mathematical model, where there is a probability of CD62L down‐regulation associated with cell division. Comparison of model results with experimental data suggests that division‐linked differentiation provides a simple mechanism to explain the relationship between clone size and phenotype of CD8⁺ T cells during acute infection.     

IL‐15‐dependent CD8+CD122+ T cells ameliorate experimental autoimmune encephalomyelitis by modulating IL‐17 production by CD4+ T cells

Interleukin‐15 (IL‐15) is an inflammatory cytokine whose role in autoimmune diseases has not been fully elucidated. Th17 cells have been shown to play critical roles in experimental autoimmune encephalomyelitis (EAE) models. In this study, we demonstrate that blockade of IL‐15 signaling by TMβ‐1 mAb treatment aggravated EAE severity. The key mechanism was not NK‐cell depletion but depletion of CD8⁺CD122⁺ T cells. Adoptive transfer of exogenous CD8⁺CD122⁺ T cells to TMβ‐1‐treated mice rescued animals from severe disease. Moreover, transfer of preactivated CD8⁺CD122⁺ T cells prevented EAE development and significantly reduced IL‐17 secretion. Naïve effector CD4⁺CD25^? T cells cultured with either CD8⁺CD122⁺ T cells from wild‐type mice or IL‐15 transgenic mice displayed lower frequencies of IL‐17A production with lower amounts of IL‐17 in the supernatants when compared with production by effector CD4⁺CD25^? T cells cultured alone. Addition of a neutralizing antibody to IL‐10 led to recovery of IL‐17A production in Th17 cultures. Furthermore, coculture of CD8⁺CD122⁺ T cells with effector CD4⁺ T cells inhibited their proliferation significantly, suggesting a regulatory function for IL‐15 dependent CD8⁺CD122⁺ T cells. Taken together, these observations suggest that IL‐15, acting through CD8⁺CD122⁺ T cells, has a negative regulatory role in reducing IL‐17 production and Th17‐mediated EAE inflammation.     

DX5+CD4+ T cells modulate cytokine production by CD4+ T cells towards IL‐10 via the production of IL‐4

CD4⁺ Th cells play a critical role in orchestrating the adaptive immune response. Uncontrolled Th1 responses are implicated in the pathogenesis of autoimmune diseases. T cells with immune‐modulatory properties are beneficial for inhibiting such inflammatory responses. Previously we demonstrated that repetitive injections of immature DC induce expansion of DX5⁺CD4⁺ T cells, which upon adoptive transfer show potent regulatory properties in murine collagen‐induced arthritis as well as in delayed‐hypersensitivity models. However, their regulatory mechanism remains to be defined. Here, we analyzed the effect of DX5⁺CD4⁺ T cells on other CD4⁺ T cells in vitro. Although proliferation of naïve CD4⁺ T cells upon antigenic triggering was not altered in the presence of DX5⁺CD4⁺ T cells, there was a striking difference in cytokine production. In the presence of DX5⁺CD4⁺ T cells, an IL‐10‐producing CD4⁺ T‐cell response was induced instead of a predominant IFN‐γ‐producing Th1 response. This modulation did not require cell–cell contact. Instead, IL‐4 produced by DX5⁺CD4⁺ T cells was primarily involved in the inhibition of IFN‐γ and promotion of IL‐10 production by CD4⁺ T cells. Together, our data indicate that DX5⁺CD4⁺ T cells modulate the outcome of Th‐responses by diverting Th1‐induction into Th responses characterized by the production of IL‐10.     

Human CD8+CXCR3+ T cells have the same function as murine CD8+CD122+ Treg

The importance of CD8⁺CD122⁺ Treg in the maintenance of immune homeostasis has been previously demonstrated in mice. Because the expression pattern of CD8 and CD122 in humans is different from that in mice, human CD8⁺ Treg that correspond to the murine CD8⁺CD122⁺ Treg have not been identified. In this study, we performed DNA microarray analyses to compare the gene expression profiles of CD8⁺CD122⁺ cells and CD8⁺CD122^? cells in mice and found that CXCR3 was preferentially expressed in CD8⁺CD122⁺ cells. When we analyzed the expression of CD122 and CXCR3 in murine CD8⁺ cells, we observed a definite population of CD122⁺CXCR3⁺ cells. CD8⁺CXCR3⁺ cells in mice showed similar regulatory activities to CD8⁺CD122⁺ cells by in vivo and in vitro assays. While CD8⁺CD122⁺CXCR3⁺ cells are present in mice, CD8⁺CXCR3⁺ cells, but not CD8⁺CD122⁺ cells, are present in humans. In the in vitro assay, human CD8⁺CXCR3⁺ cells showed the regulatory activity of producing IL‐10 and suppressing IFN‐γ production from CD8⁺CXCR3^? cells. These results suggest that human CD8⁺CXCR3⁺ T cells are the counterparts of murine CD8⁺CD122⁺ Treg.     

IL‐12 and IL‐4 activate a CD39‐dependent intrinsic peripheral tolerance mechanism in CD8+ T cells

Immune responses to protein antigens involve CD4⁺ and CD8⁺ T cells, which follow distinct programs of differentiation. Naïve CD8 T cells rapidly develop cytotoxic T‐cell (CTL) activity after T‐cell receptor stimulation, and we have previously shown that this is accompanied by suppressive activity in the presence of specific cytokines, i.e. IL‐12 and IL‐4. Cytokine‐induced CD8⁺ regulatory T (Treg) cells are one of several Treg‐cell phenotypes and are Foxp3^? IL‐10⁺ with contact‐dependent suppressive capacity. Here, we show they also express high level CD39, an ecto‐nucleotidase that degrades extracellular ATP, and this contributes to their suppressive activity. CD39 expression was found to be upregulated on CD8⁺ T cells during peripheral tolerance induction in vivo, accompanied by release of IL‐12 and IL‐10. CD39 was also upregulated during respiratory tolerance induction to inhaled allergen and on tumor‐infiltrating CD8⁺ T cells. Production of IL‐10 and expression of CD39 by CD8⁺ T cells was independently regulated, being respectively blocked by extracellular ATP and enhanced by an A2A adenosine receptor agonist. Our results suggest that any CTL can develop suppressive activity when exposed to specific cytokines in the absence of alarmins. Thus negative feedback controls CTL expansion under regulation from both nucleotide and cytokine environment within tissues.     

Blockade of PD‐1 or p38 MAP kinase signaling enhances senescent human CD8+ T‐cell proliferation by distinct pathways

Immune enhancement is desirable in situations where decreased immunity results in increased morbidity. We investigated whether blocking the surface inhibitory receptor PD‐1 and/or p38 MAP kinase could enhance the proliferation of the effector memory CD8⁺ T‐cell subset that re‐expresses CD45RA (EMRA) and exhibits characteristics of senescence, which include decreased proliferation and telomerase activity but increased expression of the DNA damage response related protein γH2AX. Blocking of both PD‐1 and p38 MAPK signaling in these cells enhanced proliferation and the increase was additive when both pathways were inhibited simultaneously in both young and old human subjects. In contrast, telomerase activity in EMRA CD8⁺ T cells was only enhanced by blocking the p38 but not the PD‐1 signaling pathway, further indicating that nonoverlapping signaling pathways were involved. Although blocking p38 MAPK inhibits TNF‐α secretion in the EMRA population, this decrease was counteracted by the simultaneous inhibition of PD‐1 signaling in these cells. Therefore, end‐stage characteristics of EMRA CD8⁺ T cells are stringently controlled by distinct and reversible cell signaling events. In addition, the inhibition of PD‐1 and p38 signaling pathways together may enable the enhancement of proliferation of EMRA CD8⁺ T cells without compromising their capacity for cytokine secretion.     

Chronic myelogenous leukemia maintains specific CD8+ T cells through IL‐7 signaling

Chronic myelogenous leukemia (CML) is a malignant myeloproliferative disease of hematopoietic stem cells. The disease progresses after several years from an initial chronic phase to a blast phase. Leukemia‐specific T cells are regularly detected in CML patients and may be involved in the immunological control of the disease. Here, we analyzed the role of leukemia‐specific CD8⁺ T cells in CML disease control and the mechanism that maintains CD8⁺ T‐cell immunosurveillance in a retroviral‐induced murine CML model. To study antigen‐specific immune responses, the glycoprotein of the lymphocytic choriomeningitis virus was used as model leukemia antigen. Leukemia‐specific CTL activity was detectable in vivo in CML mice and depletion of CD8⁺ T cells rapidly led to disease progression. CML‐specific CTL were characterized by the expression of the IL‐7 receptor α‐chain. In addition, leukemia cells produced IL‐7 that was crucial for the maintenance of leukemia‐specific CTL and for disease control. Therefore, CML cells maintain the specific CD8⁺ T‐cell‐mediated immune control by IL‐7 secretion. This results in prolonged control of disease and probably contributes to the characteristic chronic phase of the disease.     

IL‐7 is superior to IL‐2 for ex vivo expansion of tumour‐specific CD4+ T cells

It is well established that tumours hinder both natural and vaccine‐induced tumour‐specific CD4⁺ T‐cell responses. Adoptive T‐cell therapy has the potential to circumvent functional tolerance and enhance anti‐tumour protective responses. While protocols suitable for the expansion of cytotoxic CD8⁺ T cells are currently available, data on tumour‐specific CD4⁺ T cells remain scarce. We report here that CD4⁺ T cells sensitized to tumour‐associated Ag in vivo, proliferate in vitro in response to IL‐7 without the need for exogenous Ag stimulation and accumulate several folds while preserving a memory‐like phenotype. Both cell proliferation and survival accounts for the outgrowth of tumour‐sensitized T cells among other memory and naive lymphocytes following exposure to IL‐7. Also IL‐2, previously used to expand anti‐tumour CTL, promotes tumour‐specific CD4⁺ T‐cell accumulation. However, IL‐7 is superior to IL‐2 at preserving lymphocyte viability, in vitro and in vivo, maintaining those properties, that are required by helper CD4⁺ T cells to confer therapeutic efficacy upon transplantation in tumour‐bearing hosts. Together our data support a unique role for IL‐7 in retrieving memory‐like CD4⁺ T cells suitable for adoptive T‐cell therapy.