Extrathymic induction of Foxp3+ regulatory T cells declines with age in a T‐cell intrinsic manner

Extrathymically induced Foxp3⁺ regulatory T (Treg) cells contribute to the pool of Treg cells and are implicated in the maintenance of immune tolerance at environmental interfaces. The impact of T‐cell senescence on their generation and function is, however, poorly characterized. We report here that steady‐state induction of Foxp3 is impaired in aged T cells in vivo. In vitro assays further revealed that this defective generation of Treg cells was independent from the strength of TCR stimulation and arose before T‐cell proliferation. Importantly, they also revealed that this impairment of Foxp3 induction is unrelated to known age‐related T‐cell defects, such as IL‐2 secretion impairment, accumulation of activated T‐cell populations, or narrowing of the T‐cell repertoire. Finally, a loss of extrathymic induction of Foxp3 and tolerance to minor‐mismatched skin graft were observed in aged mice treated by nondepleting anti‐CD4 antibody. The T‐cell intrinsic impairment of Treg‐cell generation revealed here highlights age as a key factor to be considered in immune tolerance induction.     

Expansion of Foxp3+ T‐cell populations by Candida albicans enhances both Th17‐cell responses and fungal dissemination after intravenous challenge

Candida albicans remains the fungus most frequently associated with nosocomial bloodstream infection. In disseminated candidiasis, the role of Foxp3⁺ regulatory T (Treg) cells remains largely unexplored. Our aims were to characterize Foxp3⁺ Treg‐cell activation in a murine intravenous challenge model of disseminated C. albicans infection, and determine the contribution to disease. Flow cytometric analyses demonstrated that C. albicans infection drove in vivo expansion of a splenic CD4⁺Foxp3⁺ population that correlated positively with fungal burden. Depletion from Foxp3^hCD2 reporter mice in vivo confirmed that Foxp3⁺ cells exacerbated fungal burden and inflammatory renal disease. The CD4⁺Foxp3⁺ population expanded further after in vitro stimulation with C. albicans antigens (Ags), and included at least three cell types. These arose from proliferation of the natural Treg‐cell subset, together with conversion of Foxp3^? cells to the induced Treg‐cell form, and to a cell type sharing effector Th17‐cell characteristics, expressing ROR‐γt, and secreting IL‐17A. The expanded Foxp3⁺ T cells inhibited Th1 and Th2 responses, but enhanced Th17‐cell responses to C. albicans Ags in vitro, and in vivo depletion confirmed their ability to enhance the Th17‐cell response. These data lead to a model for disseminated candidiasis whereby expansion of Foxp3⁺ T cells promotes Th17‐cell responses that drive pathology.     

CD4+FoxP3+ regulatory T cells suppress fatal T helper 2 cell immunity during pulmonary fungal infection

The opportunistic fungal pathogen Cryptococcus neoformans causes lung inflammation and fatal meningitis in immunocompromised patients. Regulatory T (Treg) cells play an important role in controlling immunity and homeostasis. However, their functional role during fungal infection is largely unknown. In this study, we investigated the role of Treg cells during experimental murine pulmonary C. neoformans infection. We show that the number of CD4⁺FoxP3⁺ Treg cells in the lung increases significantly within the first 4 weeks after intranasal infection of BALB/c wild‐type mice. To define the function of Treg cells we used DEREG mice allowing selective depletion of CD4⁺FoxP3⁺ Treg cells by application of diphtheria toxin. In Treg cell‐depleted mice, stronger pulmonary allergic inflammation with enhanced mucus production and pronounced eosinophilia, increased IgE production, and elevated fungal lung burden were found. This was accompanied by higher frequencies of GATA‐3⁺ T helper (Th) 2 cells with elevated capacity to produce interleukin (IL)‐4, IL‐5, and IL‐13. In contrast, only a mild increase in the Th1‐associated immune response unrelated to the fungal infection was observed. In conclusion, the data demonstrate that during fungal infection pulmonary Treg cells are induced and preferentially suppress Th2 cells thereby mediating enhanced fungal control.     

Foxp3+ regulatory T‐cell homeostasis quantitatively differs in murine peripheral lymph nodes and spleen

Regulatory T (Treg) cells are essential for maintaining self‐tolerance and modulating inflammatory immune responses. Treg cells either develop within the thymus or are converted from CD4⁺ naive T (Tnaive) cells in the periphery. The Treg‐cell population size is tightly controlled and Treg‐cell development and homeostasis have been intensively studied; however, quantitative information about mechanisms of peripheral Treg‐cell homeostasis is lacking. Here we developed the first mathematical model of peripheral Treg‐cell homeostasis, incorporating secondary lymphoid organs as separate entities and encompassing factors determining the size of the Treg‐cell population, namely thymic output, homeostatic proliferation, peripheral conversion, transorgan migration, apoptosis, and the Tnaive‐cell population. Quantitative data were collected by monitoring Tnaive‐cell homeostasis and Treg‐cell rebound after selective in vivo depletion of Treg cells. Our model predicted the previously unanticipated possibility that Treg cells regulate migration of Tnaive cells between spleen and peripheral lymph nodes (LNs), whereas migration of Treg cells between these organs can largely be neglected. Furthermore, our simulations suggested that peripheral conversion significantly contributed to the maintenance of the Treg‐cell population, especially in LNs. Hence, we provide the first estimation of the peripheral Treg‐cell conversion rate and propose additional facets of Treg‐cell‐mediated immune regulation that may previously have escaped attention.     

GITR/GITRL: more than an effector T cell co-stimulatory system

Glucocorticoid-induced TNFR-related protein (GITR) is a member of the TNFR superfamily, expressed in several cells and tissues including T lymphocytes, NK cells and antigen-presenting cells (APC). GITR activation, upon interaction with its ligand (GITRL), functions as a co-activating signal. GITRL is mainly expressed on APC and GITR/GITRL interaction is important for the development of immune response. This review summarizes recent results about the GITR/GITRL system, focusing on the interplay between APC, effector and regulatory T cells.     

Selective antigen‐specific CD4+ T‐cell,but not CD8+ T‐ or B‐cell,tolerance corrupts cancer immunotherapy

Self‐tolerance, presumably through lineage‐unbiased elimination of self‐antigen‐specific lymphocytes (CD4⁺ T, CD8⁺ T, and B cells), creates a formidable barrier to cancer immunotherapy. In contrast to this prevailing paradigm, we demonstrate that for some antigens, self‐tolerance reflects selective elimination of antigen‐specific CD4⁺ T cells, but preservation of CD8⁺ T‐ and B‐cell populations. In mice, antigen‐specific CD4⁺ T‐cell tolerance restricted CD8⁺ T‐ and B‐cell responses targeting the endogenous self‐antigen guanylyl cyclase c (GUCY2C) in colorectal cancer. Although selective CD4⁺ T‐cell tolerance blocked GUCY2C‐specific antitumor immunity and memory responses, it offered a unique solution to the inefficacy of GUCY2C vaccines through recruitment of self‐antigen‐independent CD4⁺ T‐cell help. Incorporating CD4⁺ T‐cell epitopes from foreign antigens into vaccines against GUCY2C reconstituted CD4⁺ T‐cell help, revealing the latent functional capacity of GUCY2C‐specific CD8⁺ T‐ and B‐cell pools, producing durable antitumor immunity without autoimmunity. Incorporating CD4⁺ T‐cell epitopes from foreign antigens into vaccines targeting self‐antigens in melanoma (Trp2) and breast cancer (Her2) produced similar results, suggesting selective CD4⁺ T‐cell tolerance underlies ineffective vaccination against many cancer antigens. Thus, identification of self‐antigens characterized by selective CD4⁺ T‐cell tolerance and abrogation of such tolerance through self‐antigen‐independent T‐cell help is essential for future immunotherapeutics.     

Paracoccidioides brasiliensis infection increases regulatory T cell counts in female C57BL/6 mice infected via two distinct routes

Studies that show an overview of the peripheral immune response in a model of Paracoccidioides brasiliensis (Pb) infection in females are scarce in the literature. We sought to characterize the innate and adaptive immune responses in female C57BL/6 mice infected with Pb through two distinct routes of administration, intranasal and intravenous. In addition to the lung, P. brasiliensis yeast cells were observed in liver and brain tissues of females infected intravenously. To our knowledge, our study is the first to prove the presence of this pathogenic fungus in the cerebral cortex of female mice. During the initial stages of infection, augmented expression of both MHCII and CD86 was observed on the surface of CD11c⁺ pulmonary antigen-presenting cells (APCs) in intranasally and intravenously infected females. However, CD40 expression was downregulated in these cells. Concomitantly with increasing serum IL-10 levels, we noted that splenic dendritic cells (DCs) from both intravenously- and intranasally-infected female mice had acquired an immature phenotype. Further, increased T regulatory cell counts were observed in female mice infected via both routes, along with an increase in the infiltration of IL-10-producing CD8⁺ T cells into the lungs. Moreover, we noted that P. brasiliensis infection resulted in enhanced IL-10 production – by CD11c⁺ APCs in the lung tissue – and induction of Th17 polarization. Taken together, our results suggest that P. brasiliensis could modulates the immune response in female mice by influencing the balance between regulatory T cells (Tregs) and Th17 polarization.     

The soluble isoform of CTLA‐4 as a regulator of T‐cell responses

CTLA‐4 is a crucial immune regulator that mediates both negative costimulation signals to T cells, and regulatory T (Treg)‐cell extrinsic control of effector responses. Here we present evidence supporting a novel mechanism for this extrinsic suppression, executed by the alternatively spliced soluble CTLA‐4 isoform (sCTLA‐4). Analyses of human T cells in vitro show that sCTLA‐4 secretion can be increased during responses, and has potent inhibitory properties, since isoform‐specific blockade of its activity significantly increased Ag‐driven proliferation and cytokine (IFN‐γ, IL‐17) secretion. Treg cells were demonstrated to be a prominent source of sCTLA‐4, which contributed to suppression in vitro when their numbers were limiting. The soluble isoform was also produced by, and inhibited, murine T cells responding to Ag in vitro, and blockade of its activity in vivo protected against metastatic spread of melanoma in mice. We conclude that sCTLA‐4 is an important immune regulator, responsible for at least some of the inhibitory effects previously ascribed to the membrane‐bound isoform. These results suggest that the immune system exploits the different CTLA‐4 isoforms for either intrinsic or extrinsic regulation of T‐cell activity.     

CD161 expression characterizes a subpopulation of human regulatory T cells that produces IL‐17 in a STAT3‐dependent manner

Treg cells are critical for the prevention of autoimmune diseases and are thus prime candidates for cell‐based clinical therapy. However, human Treg cells are “plastic”, and are able to produce IL‐17 under inflammatory conditions. Here, we identify and characterize the human Treg subpopulation that can be induced to produce IL‐17 and identify its mechanisms. We confirm that a subpopulation of human Treg cells produces IL‐17 in vitro when activated in the presence of IL‐1β, but not IL‐6. “IL‐17 potential” is restricted to population III (CD4⁺CD25^hiCD127^loCD45RA^?) Treg cells expressing the natural killer cell marker CD161. We show that these cells are functionally as suppressive and have similar phenotypic/molecular characteristics to other subpopulations of Treg cells and retain their suppressive function following IL‐17 induction. Importantly, we find that IL‐17 production is STAT3 dependent, with Treg cells from patients with STAT3 mutations unable to make IL‐17. Finally, we show that CD161⁺ population III Treg cells accumulate in inflamed joints of patients with inflammatory arthritis and are the predominant IL‐17‐producing Treg‐cell population at these sites. As IL‐17 production from this Treg‐cell subpopulation is not accompanied by a loss of regulatory function, in the context of cell therapy, exclusion of these cells from the cell product may not be necessary.     

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.     

Flt3 ligand expands CD4+FoxP3+ regulatory T cells in human subjects

CD4⁺CD25⁺FoxP3⁺ naturally occurring regulatory T (Treg) cells play a crucial role in the maintenance of immune tolerance and in preventing autoimmune pathology. Interventions that expand Treg cells are highly desirable, as they may offer novel treatment options in a variety of autoimmune and transplantation settings. Paralleling previous preclinical studies, we demonstrate here that administration of the hematopoietic growth factor Flt3L to human subjects increases the frequency and absolute number of Treg cells, and reduces the ratio of CD8⁺ T cells to Treg cells in the peripheral blood. The increase in Treg cells was due to enhanced Treg‐cell proliferation rather than release of Treg cells from the thymus. Further studies revealed that Flt3L‐induced proliferation of Treg cells was an indirect effect that occurred via the interaction of Treg cells with the Flt3L‐expanded pool of CD1c⁺ myeloid dendritic cells. On the basis of these findings, Flt3L may represent a promising agent for promoting immune tolerance in a variety of clinical settings.     

The role of 1α,25‐dihydroxyvitamin D3 and cytokines in the promotion of distinct Foxp3+and IL‐10+ CD4+ T cells

1α,25‐Dihydroxyvitamin D3 (1α25VitD3) has potent immunomodulatory properties. We have previously demonstrated that 1α25VitD3 promotes human and murine IL‐10‐secreting CD4⁺ T cells. Because of the clinical relevance of this observation, we characterized these cells further and investigated their relationship with Foxp3⁺ regulatory T (Treg) cells. 1α25VitD3 increased the frequency of both Foxp3⁺ and IL‐10⁺ CD4⁺T cells in vitro. However, Foxp3 was increased at high concentrations of 1α25VitD3 and IL‐10 at more moderate levels, with little coexpression of these molecules. The Foxp3⁺ and IL‐10⁺ T‐cell populations showed comparable suppressive activity. We demonstrate that the enhancement of Foxp3 expression by 1α25VitD3 is impaired by IL‐10. 1α25VitD3 enables the selective expansion of Foxp3⁺ Treg cells over their Foxp3^? T‐cell counterparts. Equally, 1α25VitD3 maintains Foxp3⁺ expression by sorted populations of human and murine Treg cells upon in vitro culture. A positive in vivo correlation between vitamin D status and CD4⁺Foxp3⁺ T cells in the airways was observed in a severe pediatric asthma cohort, supporting the in vitro observations. In summary, we provide evidence that 1α25VitD3 enhances the frequency of both IL‐10⁺ and Foxp3⁺ Treg cells. In a translational setting, these data suggest that 1α25VitD3, over a broad concentration range, will be effective in enhancing the frequency of Treg cells.     

Diversification and senescence of Foxp3+ regulatory T cells during experimental autoimmune encephalomyelitis

The fate of Foxp3⁺ regulatory T (Treg) cells responding during autoimmunity is not well defined. We observed a marked elevation in KLRG1⁺ (where KLRG1 stands for killer cell lectin‐like receptor G1) CNS‐infiltrating Treg cells in experimental autoimmune encephalomyelitis (EAE), and assessed their origin and properties. KLRG1⁺ Treg cells showed increased activation marker expression, Foxp3 and CD25 levels, and more rapid cell cycling than KLRG1^? cells. KLRG1^? Treg cells converted into KLRG1⁺ cells and this was increased in autoimmune inflammation. Conversion was unidirectional; KLRG1⁺ Treg cells did not revert to a KLRG1^? state. KLRG1⁺ but notKLRG1^?Treg cells survived poorly, indicative of terminal differentiation. This was associated with diminished BCL2 and increased apoptosis of isolated cells. KLRG1 was also upregulated on iTreg cells after transfer and EAE induction or on iTreg cells developing spontaneously during EAE. KLRG1⁺ Treg cells produced more IL‐10 and had altered effector cytokine production compared with their KLRG1^? counterparts. Despite their differences, KLRG1⁺ and KLRG1^? Treg cells proved similarly potent in suppressing EAE. KLRG1⁺ and KLRG1^? populations were phenotypically heterogeneous, with the extent and pattern of activation marker expression dependent both on cellular location and inflammation. Our results support an extensive diversification of Treg cells during EAE, and associate KLRG1 with altered Treg‐cell function and senescence.     

Transient Treg‐cell depletion in adult mice results in persistent self‐reactive CD4+ T‐cell responses

Depletion of Foxp3⁺CD4⁺ regulatory T cells (Treg) in adults results in chronic inflammation and autoimmune disease. However, the impact of transient Treg‐cell depletion on self‐reactive responses is poorly defined. Here, we studied the effect of transient depletion of Treg cells on CD4⁺ T‐cell responses to endogenous self‐antigens. Short‐term ablation of Treg cells in mice resulted in rapid activation of CD4⁺ T cells, increased percentage of IFN‐γ⁺ and Th17 cells in lymphoid organs, and development of autoimmune gastritis. To track self‐reactive responses, we analyzed the activation of naïve gastric‐specific CD4⁺ T cells. There was a dramatic increase in proliferation and acquisition of effector function of gastric‐specific T cells in the stomach draining LNs of Treg‐cell‐depleted mice, compared with untreated mice, either during Treg‐cell depletion or after Treg‐cell reconstitution. Moreover, the hyperproliferation of gastric‐specific T cells in the Treg‐cell‐ablated mice was predominantly antigen‐dependent. Transient depletion of Treg cells resulted in a shift in the ratio of peripheral:thymic Treg cells in the reemerged Treg‐cell population, indicating an altered composition of Treg cells. These findings indicate that transient Treg‐cell depletion results in ongoing antigen‐driven self‐reactive T‐cell responses and emphasize the continual requirement for an intact Treg‐cell population.     

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.     

Enhanced suppressor function of TIM‐3+FoxP3+ regulatory T cells

T‐cell immunoglobulin and mucin domain 3 (TIM‐3) is an Ig‐superfamily member expressed on IFN‐γ‐secreting Th1 and Tc1 cells and was identified as a negative regulator of immune tolerance. TIM‐3 is expressed by a subset of activated CD4⁺ T cells, and anti‐CD3/anti‐CD28 stimulation increases both the level of expression and the number of TIM‐3⁺ T cells. In mice, TIM‐3 is constitutively expressed on natural regulatory T (Treg) cells and has been identified as a regulatory molecule of alloimmunity through its ability to modulate CD4⁺ T‐cell differentiation. Here, we examined TIM‐3 expression on human Treg cells to determine its role in T‐cell suppression. In contrast to mice, TIM‐3 is not expressed on Treg cells ex vivo but is upregulated after activation. While TIM‐3⁺ Treg cells with increased gene expression of LAG3, CTLA4, and FOXP3 are highly efficient suppressors of effector T (Teff) cells, TIM‐3^? Treg cells poorly suppressed Th17 cells as compared with their suppression of Th1 cells; this decreased suppression ability was associated with decreased STAT‐3 expression and phosphorylation and reduced gene expression of IL10, EBI3, GZMB, PRF1, IL1Rα, and CCR6. Thus, our results suggest that TIM‐3 expression on Treg cells identifies a population highly effective in inhibiting pathogenic Th1‐ and Th17‐cell responses.