Unusual selection and peripheral homeostasis for immunoregulatory CD4− CD8− T cells

Immunoregulatory CD4^? CD8^? (double‐negative; DN) T cells exhibit a unique antigen‐specific mode of suppression, yet the ontogeny of DN T cells remains enigmatic. We have recently shown that 3A9 T‐cell receptor (TCR) transgenic mice bear a high proportion of immunoregulatory 3A9 DN T cells, facilitating their study. The 3A9 TCR is positively selected on the H2^k MHC haplotype, is negatively selected in mice bearing the cognate antigen, namely hen egg lysozyme, and there is absence of positive selection on the H2^b MHC haplotype. Herein, we take advantage of this well‐defined 3A9 TCR transgenic model to assess the thymic differentiation of DN T cells and its impact on determining the proportion of these cells in secondary lymphoid organs. We find that the proportion of DN T cells in the thymus is not dictated by the nature of the MHC‐selecting haplotype. By defining DN T‐cell differentiation in 3A9 TCR transgenic CD47‐deficient mice as well as in mice bearing the NOD.H2^k genetic background, we further demonstrate that the proportion of 3A9 DN T cells in the spleen is independent of the MHC selecting haplotype. Together, our findings suggest that immunoregulatory DN T cells are subject to rules distinct from those imposed upon CD4 T cells.     

Pro‐inflammatory self‐reactive T cells are found within murine TCR‐αβ+CD4−CD8−PD‐1+ cells

TCR‐αβ⁺ double negative (DN) T cells (CD3⁺TCR‐αβ⁺CD4^?CD8^?NK1.1^?CD49b^?) represent a minor heterogeneous population in healthy humans and mice. These cells have been ascribed pro‐inflammatory and regulatory capacities and are known to expand during the course of several autoimmune diseases. Importantly, previous studies have shown that self‐reactive CD8⁺ T cells become DN after activation by self‐antigens, suggesting that self‐reactive T cells may exist within the DN T‐cell population. Here, we demonstrate that programmed cell death 1 (PD‐1) expression in unmanipulated mice identifies a subset of DN T cells with expression of activation‐associated markers and a phenotype that strongly suggests they are derived from self‐reactive CD8⁺ cells. We also found that, within DN T cells, the PD‐1⁺ subset generates the majority of pro‐inflammatory cytokines. Finally, using a TCR‐activation reporter mouse (Nur77‐GFP), we confirmed that in the steady‐state PD‐1⁺ DN T cells engage endogenous antigens in healthy mice. In conclusion, we provide evidence that indicates that the PD‐1⁺ fraction of DN T cells represents self‐reactive cells.     

Control of Schistosoma mansoni egg‐induced inflammation by IL‐4‐responsive CD4+CD25−CD103+Foxp3− cells is IL‐10‐dependent

Host protection to helminth infection requires IL‐4 receptor α chain (IL‐4Rα) signalling and the establishment of finely regulated Th2 responses. In the current study, the role of IL‐4Rα‐responsive T cells in Schistosoma mansoni egg‐induced inflammation was investigated. Egg‐induced inflammation in IL‐4Rα‐responsive BALB/c mice was accompanied with Th2‐biased responses, whereas T‐cell‐specific IL‐4Rα‐deficient BALB/c mice (iLck^creIl4ra^?/lox) developed Th1‐biased responses with heightened inflammation. The proportion of Foxp3⁺ Treg in the draining LN of control mice did not correlate with the control of inflammation and was reduced in comparison to T‐cell‐specific IL‐4Rα‐deficient mice. This was due to IL‐4‐mediated inhibition of CD4⁺Foxp3⁺ Treg conversion, demonstrated in adoptively transferred Rag2^?/? mice. Interestingly, reduced footpad swelling in Il4ra^?/lox mice was associated with the induction of IL‐4 and IL‐10‐secreting CD4⁺CD25^?CD103⁺Foxp3^? cells, confirmed in S. mansoni infection studies. Transfer of IL‐4Rα‐responsive CD4⁺CD25^?CD103⁺ cells, but not CD4⁺CD25^high or CD4⁺CD25^?CD103^? cells, controlled inflammation in iLck^creIl4ra^?/lox mice. The control of inflammation depended on IL‐10, as transferred CD4⁺CD25^?CD103⁺ cells from IL‐10‐deficient mice were not able to effectively downregulate inflammation. Together, these results demonstrate that IL‐4 signalling in T cells inhibits Foxp3⁺ Treg in vivo and promotes CD4⁺CD25^?CD103⁺Foxp3^? cells that control S. mansoni egg‐induced inflammation via IL‐10.     

Antigen dose‐dependent suppression of murine IgE responses is mediated by CD4−CD8− double‐negative T cells

Background The IgE response against protein antigens is profoundly influenced by the dose used for sensitization. Objective The aim of the study was to identify immune cells that are involved in antigen dose‐dependent regulation of IgE formation. Methods Wild‐type mice as well as T helper (Th)1‐deficient IL‐12p40^?/? and IFN‐γ^?/? mice were immunized by repeated intraperitoneal injection of either low doses (K01 mice) or high doses (K100 mice) of keyhole limpet haemocyanin adsorbed to aluminium hydroxide. Splenocytes of immunized mice were restimulated in vitro and antigen‐dependent T cell proliferation and cytokine production were measured. The frequency of regulatory T cell subsets among splenocytes from K01 and K100 mice was compared using fluorocytometry and RT‐PCR analysis. Splenocytes or T cell subpopulations were transferred into naïve mice and the effect of lymphocyte transfer on IgE production after priming of recipients with low antigen doses was determined. Results Specific IgE production was considerably impaired in K100 mice. Antigenic restimulation revealed hypoproliferation of K100 splenocytes and reduced production of Th2 cytokines IL‐4, IL‐5 and IL‐13, but no induction of IFN‐γ production. Moreover, lymphocytes from K01 and K100 mice did not show significant differences in the expression of molecules associated with the phenotype or activity of conventional regulatory T cells. Transfer of splenocytes or purified T cells from K100 mice substantially suppressed the induction of IgE production in the recipients in an antigen‐ and isotype‐specific manner. Neither CD4⁺ nor CD8⁺ T cells from K100 mice were able to inhibit IgE formation; instead, we identified CD4^?CD8^? double‐negative T cells (dnT cells) as the principal T cell population, which potently suppressed IgE production. Conclusion Our data demonstrate that CD4^?CD8^? dnT cells play a major role in the regulation of IgE responses induced by high antigen doses.     

HIV gag‐specific immune response mediated by double negative (CD3+CD4−CD8−) T cells in HIV‐exposed seronegative individuals

Double negative (DN) T cells are CD3⁺, CD4^?, CD8^? cells with either T‐cell receptors (TCR) αβ or TCR γδ whose importance on protection against HIV infection is unknown. Since HIV‐exposed seronegative individuals correspond to an ideal group in whom correlates of protection are expected, the role of these cells was studied in 13 HIV‐serodiscordant couples in a stable relationship and reporting unprotected sexual intercourses. HIV‐specific immune responses mediated by DN T‐cells were evaluated by measuring intracellular IFNγ and MIP1β (CCL4) production in response to HIV‐Gag peptides. Thirty‐five healthy controls not exposed to HIV were tested similarly and used to define a threshold for positive responses. Interestingly, Gag‐specific DN T‐cell responses were found in 3/13 (23%) HIV‐exposed seronegative individuals (Group A), involving both DN/αβ⁺ and DN/γδ⁺ T‐cells through MIP1β and IFNγ production. 4/13 (30%) of partners infected with HIV (Group B) also showed Gag‐specific responses but were mediated exclusively by DN/γδ⁺ T‐cells, mainly through IFNγ production. DN T‐cells in Group A individuals can display differential HIV‐specific immune responses, which might contribute to the low susceptibility to infection with HIV shown by individuals in Group A. J. Med. Virol. 85:200–209, 2013. © 2012 Wiley Periodicals, Inc.     

Cytokine‐dependent regulation of dendritic cell differentiation in the splenic microenvironment

The DC‐derived chemokine CCL17, a ligand of CCR4, has been shown to promote various inflammatory diseases such as atopic dermatitis, atherosclerosis, and inflammatory bowel disease. Under steady‐state conditions, and even after systemic stimulation with LPS, CCL17 is not expressed in resident splenic DCs as opposed to CD8α^?CD11b⁺ LN DCs, which produce large amounts of CCL17 in particular after maturation. Upon systemic NKT cell activation through α‐galactosylceramide stimulation however, CCL17 can be upregulated in both CD8α^? and CD8α⁺ splenic DC subsets and enhances cross‐presentation of exogenous antigens. Based on genome‐wide expression profiling, we now show that splenic CD11b⁺ DCs are susceptible to IFN‐γ‐mediated suppression of CCL17, whereas LN CD11b⁺CCL17⁺ DCs downregulate the IFN‐γR and are much less responsive to IFN‐γ. Under inflammatory conditions, particularly in the absence of IFN‐γ signaling in IFN‐γRKO mice, CCL17 expression is strongly induced in a major proportion of splenic DCs by the action of GM‐CSF in concert with IL‐4. Our findings demonstrate that the local cytokine milieu and differential cytokine responsiveness of DC subsets regulate lymphoid organ specific immune responses at the level of chemokine expression.     

Critical role of CCL22/CCR4 axis in the maintenance of immune homeostasis during apoptotic cell clearance by splenic CD8α+ CD103+ dendritic cells

Macrophages and dendritic cells (DCs) in murine spleen are essential for the maintenance of immune homeostasis by elimination of blood‐borne foreign particles and organisms. It has been reported that splenic DCs, especially CD8α⁺ CD103⁺ DCs, are responsible for tolerance to apoptosis‐associated antigens. However, the molecular mechanism by which these DCs maintain immune homeostasis by blood‐borne apoptotic cell clearance remains elusive. Here, we found that the CCL22/CCR4 axis played a critical role in the maintenance of immune homeostasis during apoptotic cell clearance by splenic CD8α⁺ CD103⁺ DCs. The present results revealed that systemic administration of apoptotic cells rapidly induced a large number of CCL22 and CCR4⁺ regulatory T (Treg) cells in the spleen of C57BL/6J mice. Further study demonstrated that CD8α⁺ CD103⁺ DCs dominantly produce much higher CCL22 than CD8α⁺ CD103^? DCs. Moreover, the transient deletion of CD8α⁺ CD103⁺ DCs caused a decrease in CCL22 levels together with CCR4⁺ Treg cell percentage. Subsequently, the levels of some pro‐inflammatory cytokines, such as interleukin‐17 and interferon‐γ in the spleen with the absence of CD8α⁺ CD103⁺ DCs increased in response to the administration of apoptotic cells. Hence, intravenous injection of apoptotic cells induced a subsequent increase in CCL22 expression and CCR4⁺ Treg cells, which contribute to the maintenance of immune homeostasis at least partially by splenic CD8α⁺ CD103⁺ DCs.     

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.     

Vitamin A notches up CD11bhi DC development

Vitamin A and its metabolite retinoic acid influence various aspects of immunity. Although the capacity of vitamin A to condition intestinal CD103⁺ DCs to imprint tissue‐specific homing programs onto activated lymphocytes is well documented, it is unclear whether vitamin A also regulates DC populations in other tissues. A study published in this issue of the European Journal of Immunology, Beijer et al. [Eur. J. Immunol. 2013. 43: 1608–1616] now demonstrates that vitamin A exerts profound effects on the subset composition of splenic DCs. By resolving that splenic ESAM^hi CD11b^hi DCs are preferentially responsive to regulation by vitamin A, these novel insights not only further support the notion that ESAM expression marks two distinct lineages of splenic CD11b^hi DCs, but also provide an important extension to our understanding of how vitamin A influences the immune system.     

Retinoic acid receptor signaling levels and antigen dose regulate gut homing receptor expression on CD8+ T cells

Recent studies have highlighted a central role for intestinal dendritic cells (DCs) and vitamin A metabolite retinoic acid (RA) in the generation of α4β7⁺ CCR9⁺“gut tropic” effector T cells. Here, using RA-responsive element reporter mice, we demonstrate that both splenic and mesenteric lymph node (MLN) DCs enhanced retinoic acid receptor (RAR) signaling in CD8⁺ T cells; however, only a subset of MLN DCs, expressing the integrin α-chain CD103, induced an early RAR signal that is required for efficient CCR9 induction. MLN-primed CD8⁺ T cells also received enhanced RAR-dependent signals compared with splenic-primed CD8⁺ T cells in vivo. Further DC-mediated induction of gut homing receptors was inhibited at a high antigen dose without influencing RAR signaling events, and resulted in less efficient CD8⁺ T-cell entry into the small intestinal mucosa. These results highlight a complex interplay between antigen dose and DC subset-induced RAR signaling events in the generation of tissue tropic effector T-cell subsets.     

CD8α+ dendritic cells prime TCR‐peptide‐reactive regulatory CD4+FOXP3− T cells

CD4⁺ T cells with immune regulatory function can be either FOXP3⁺ or FOXP3^?. We have previously shown that priming of naturally occurring TCR‐peptide‐reactive CD4⁺FOXP3^? Treg specifically controls Vβ8.2⁺CD4⁺ T cells mediating EAE. However, the mechanism by which these Treg are primed to recognize their cognate antigenic determinant, which is derived from the TCRVβ8.2‐chain, is not known. In this study we show that APC derived from splenocytes of naïve mice are able to stimulate cloned CD4⁺ Treg in the absence of exogenous antigen, and their stimulation capacity is augmented during EAE. Among the APC populations, DC were the most efficient in stimulating the Treg. Stimulation of CD4⁺ Treg was dependent upon processing and presentation of TCR peptides from ingested Vβ8.2TCR⁺CD4⁺ T cells. Additionally, DC pulsed with TCR peptide or apoptotic Vβ8.2⁺ T cells were able to prime Treg in vivo and mediate protection from disease in a CD8‐dependent fashion. These data highlight a novel mechanism for the priming of CD4⁺ Treg by CD8α⁺ DC and suggest a pathway that can be exploited to prime antigen‐specific regulation of T‐cell‐mediated inflammatory disease.     

BDCA3 expression is associated with high IFN‐λ production by CD34+‐derived dendritic cells generated in the presence of GM‐CSF,IL‐4, and/or TGF‐β

High BDCA3 expression is associated with a specific human IFN‐λ‐producing dendritic cell (DC) subset. However, BDCA3 has also been detected on other DC subsets. Thus far, development and function of BDCA3 expression on DCs remains poorly understood. Human Langerhans cells (LCs) and interstitial DCs (intDCs) can be generated in vitro by differentiation of CD34⁺ hematopoietic progenitors via distinct precursor DCs (preDCs), CD1a⁺ preDCs, and CD14⁺ preDCs, respectively. Here, we identified BDCA3 expression in this well‐known GM‐CSF/TNF‐α‐driven culture system and described the effect of IL‐4 and/or TGF‐β on induction of BDCA3 expression. In control or TGF‐β cultures, BDCA3 was only detected on CD14⁺ preDC‐derived intDCs. IL‐4 induced BDCA3 expression in both CD14⁺‐derived and CD1a⁺‐derived cultures. TGF‐β and IL‐4 together further increased CD14⁺‐derived and CD1a⁺‐derived BDCA3⁺ DC frequencies, which partly expressed CLEC9A, but were not identical to the BDCA3^highCLEC9A⁺ DC subset in vivo. Importantly, BDCA3⁺ cells, but not BDCA3^? cells, in this system produced high IFN‐λ levels upon polyinosinic:polycytidylic acid (polyI:C) stimulation. This culture system, in which BDCA3 expression is preferentially associated with the intDC lineage and IFN‐λ‐producing capacity, will greatly contribute to further research on the function and regulation of BDCA3 expression and IFN‐λ production by DCs.     

Dendritic cell activation,phagocytosis and CD69 expression on cognate T cells are suppressed by n‐3 long‐chain polyunsaturated fatty acids

Docosahexaenoic acid (DHA) and eicosapentaenoic acid (EPA) are bioactive n‐3 long‐chain polyunsaturated fatty acids (LCPUFAs) in fish oil that exert immunosuppressive effects. A significant amount of literature shows that n‐3 LCPUFAs suppress dendritic cell (DC) function in vitro; however, few studies have determined if the effects are emulated at the animal level. In this study, we first focused on the functional consequences of 5% (weight/weight) fish oil on splenic CD11c⁺ DCs. Administration of n‐3 LCPUFAs, modelling human pharmacological intake (2% of total kcal from EPA,1·3% from DHA), to C57BL/6 mice for 3 weeks reduced DC surface expression of CD80 by 14% and tumour necrosis factor‐α secretion by 29% upon lipopolysaccharide stimulation relative to a control diet. The n‐3 LCPUFAs also significantly decreased CD11c⁺ surface expression and phagocytosis by 12% compared with the control diet. Antigen presentation studies revealed a 22% decrease in CD69 surface expression on transgenic CD4⁺ T lymphocytes activated by DCs from mice fed fish oil. We then determined if the functional changes were mechanistically associated with changes in lipid microdomain clustering or plasma membrane microviscosity with n‐3 LCPUFAs, as reported for B and T lymphocytes. Fish oil administration to mice did not influence cholera‐toxin induced lipid microdomain clustering or microviscosity, even though EPA and DHA levels were significantly elevated relative to the control diet. Overall, our data show that n‐3 LCPUFAs exert immunosuppressive effects on DCs, validating in vitro studies. The results also show that DC microdomain clustering and microviscosity were not changed by the n‐3 LCPUFA intervention used in this study.     

Immature dendritic cells convert anergic nonregulatory T cells into Foxp3−IL‐10+ regulatory T cells by engaging CD28 and CTLA‐4

Anergic T cells can survive for long time periods passively in a hyporesponsive state without obvious active functions. Thus, the immunological reason for their maintenance is unclear. Here, we induced peptide‐specific anergy in T cells from mice by coculturing these cells with immature murine dendritic cells (DCs). We found that these anergic, nonsuppressive IL‐10^?Foxp3^?CTLA‐4⁺CD25^lowEgr2⁺ T cells could be converted into suppressive IL‐10⁺Foxp3^?CTLA‐4⁺CD25^highEgr2⁺ cells resembling type‐1 Treg cells (Tr1) when stimulated a second time by immature DCs in vitro. Addition of TGF‐β during anergy induction favored Foxp3⁺ Treg‐cell induction, while TGF‐β had little effect when added to the second stimulation. Expression of both CD28 and CTLA‐4 molecules on anergic T cells was required to allow their conversion into Tr1‐like cells. Suppressor activity was enabled via CD28‐mediated CD25 upregulation, acting as an IL‐2 sink, together with a CTLA‐4‐mediated inhibition of NFATc1/α activation to shut down IL‐2‐mediated proliferation. Together, these data provide evidence and mechanistical insights into how persistent anergic T cells may serve as a resting memory pool for Tr1‐like cells.     

Mesenteric lymph node CD11b− CD103+ PD‐L1High dendritic cells highly induce regulatory T cells

Dendritic cells (DCs) in mesenteric lymph nodes (MLNs) induce Foxp3⁺ regulatory T cells to regulate immune responses to beneficial or non‐harmful agents in the intestine, such as commensal bacteria and foods. Several studies in MLN DCs have revealed that the CD103⁺ DC subset highly induces regulatory T cells, and another study has reported that MLN DCs from programmed death ligand 1 (PD‐L1) ‐deficient mice could not induce regulatory T cells. Hence, the present study investigated the expression of these molecules on MLN CD11c⁺ cells. Four distinct subsets expressing CD103 and/or PD‐L1 were identified, namely CD11b⁺ CD103⁺ PD‐L1^High, CD11b⁻ CD103⁺ PD‐L1^High, CD11b⁻ CD103⁺ PD‐L1^Low and CD11b⁺ CD103⁻ PD‐L1^Int. Among them, the CD11b⁻ CD103⁺ PD‐L1^High DC subset highly induced Foxp3⁺ T cells. This subset expressed Aldh1a2 and Itgb8 genes, which are involved in retinoic acid metabolism and transforming growth factor‐β (TGF‐β) activation, respectively. Exogenous TGF‐β supplementation equalized the level of Foxp3⁺ T‐cell induction by the four subsets whereas retinoic acid did not, which suggests that high ability to activate TGF‐β is determinant for the high Foxp3⁺ T‐cell induction by CD11b⁻ CD103⁺ PD‐L1^High DC subset. Finally, this subset exhibited a migratory DC phenotype and could take up and present orally administered antigens. Collectively, the MLN CD11b⁻ CD103⁺ PD‐L1^High DC subset probably takes up luminal antigens in the intestine, migrates to MLNs, and highly induces regulatory T cells through TGF‐β activation.     

Impaired dendritic cell differentiation of CD16‐positive monocytes in tuberculosis: Role of p38 MAPK

Tuberculosis (TB) is one of the world's most pernicious diseases mainly due to immune evasion strategies displayed by its causative agent Mycobacterium tuberculosis (Mtb). Blood monocytes (Mos) represent an important source of DCs during chronic infections; consequently, the alteration of their differentiation constitutes an escape mechanism leading to mycobacterial persistence. We evaluated whether the CD16⁺/CD16^? Mo ratio could be associated with the impaired Mo differentiation into DCs found in TB patients. The phenotype and ability to stimulate Mtb‐specific memory clones DCs from isolated Mo subsets were assessed. We found that CD16^? Mos differentiated into CD1a⁺DC‐SIGN^high cells achieving an efficient recall response, while CD16⁺ Mos differentiated into a CD1a^?DC‐SIGN^low population characterized by a poor mycobacterial Ag‐presenting capacity. The high and sustained phosphorylated p38 expression observed in CD16⁺ Mos was involved in the altered DC profile given that its blockage restored DC phenotype and its activation impaired CD16^? Mo differentiation. Furthermore, depletion of CD16⁺ Mos indeed improved the differentiation of Mos from TB patients toward CD1a⁺DC‐SIGN^high DCs. Therefore, Mos from TB patients are less prone to differentiate into DCs due to their increased proportion of CD16⁺ Mos, suggesting that during Mtb infection Mo subsets may have different fates after entering the lungs.     

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.