TGF-beta requires CTLA-4 early after T cell activation to induce FoxP3 and generate adaptive CD4+CD25+ regulatory cells

Although positive CD28 costimulation is needed for the generation of natural CD4+CD25+ regulatory T cells, we report that negative CTLA-4 costimulation is necessary for generating phenotypically and functionally similar adaptive CD4+CD25+ suppressor cells. TGF-beta could not induce CD4+CD25- cells from CTLA-4(-/-) mice to express normal levels of FoxP3 or to develop suppressor activity. Moreover, blockade of CTLA-4 following activation of wild-type CD4+ cells abolished the ability of TGF-beta to induce FoxP3-expressing mouse suppressor cells. TGF-beta accelerated expression of CTLA-4, and time course studies suggested that CTLA-4 ligation of CD80 shortly after T cell activation enables TGF-beta to induce CD4+CD25- cells to express FoxP3 and develop suppressor activity. TGF-beta also enhanced CD4+ cell expression of CD80. Thus, CTLA-4 has an essential role in the generation of acquired CD4+CD25+ suppressor cells in addition to its other inhibitory effects. Although natural CD4+CD25+ cells develop normally in CTLA-4(-/-) mice, the lack of TGF-beta-induced, peripheral CD4+CD25+ suppressor cells in these mice may contribute to their rapid demise.     

Neuron-mediated generation of regulatory T cells from encephalitogenic T cells suppresses EAE

Neurons have been neglected as cells with a major immune-regulatory function because they do not express major histocompatibility complex class II. Our data show that neurons are highly immune regulatory, having a crucial role in governing T-cell response and central nervous system (CNS) inflammation. Neurons induce the proliferation of activated CD4+ T cells through B7-CD28 and transforming growth factor (TGF)-beta1-TGF-beta receptor signaling pathways, resulting in amplification of T-cell receptor signaling through phosphorylated ZAP-70, interleukin (IL)-2 and IL-9. The interaction between neurons and T cells results in the conversion of encephalitogenic T cells to CD25+ TGF-beta1+ CTLA-4+ FoxP3+ T regulatory (Treg) cells that suppress encephalitogenic T cells and inhibit experimental autoimmune encephalomyelitis. Suppression is dependent on cytotoxic T lymphocyte antigen (CTLA)-4 but not TGF-beta1. Autocrine action of TGF-beta1, however, is important for the proliferative arrest of Treg cells. Blocking the B7 and TGF-beta pathways prevents the CNS-specific generation of Treg cells. These findings show that generation of neuron-dependent Treg cells in the CNS is instrumental in regulating CNS inflammation.     

Human CD4+CD25low adaptive T regulatory cells suppress delayed-type hypersensitivity during transplant tolerance

Adaptive T regulatory (T(R)) cells mediate the suppression of donor-specific, delayed-type hypersensitivity (DTH) in tolerant organ transplant recipients. We hypothesized that cells belonging to the CD4(+)CD25(+) T cell subset but distinct from natural T(R) cells may fulfill this role. To test this hypothesis, PBMC and biopsy samples from two tolerant kidney transplant recipients (K1 and K2) were analyzed. When transferred with recipient APC into a SCID mouse footpad, CD4(+) T cells were hyporesponsive in DTH to donor type HLA-B Ags and derivative allopeptides. However, anti-human TGF-beta1 Ab revealed a response to immunodominant allopeptides in both patients, suggesting that CD4(+) T effector (T(E)) cells coexisted with suppressive, TGF-beta1-producing CD4(+) T(R) cells. During in vitro culture, allopeptide stimulation induced both IFN-gamma-producing and surface TGF-beta1(+) T cells. The relative strength of the latter response in patient K1 was inversely correlated with the level of systemic anti-donor DTH, which varied over a 6-year interval. Allopeptide-induced surface TGF-beta1 expression was found primarily in Forkhead box P3 (FoxP3)-negative CD4(+)CD25(low) T cells, which could adoptively transfer suppression of donor-specific DTH. Biopsy samples contained numerous surface TGF-beta1(+) mononuclear cells that costained for CD4 and, less frequently CD25, but were negative for FoxP3. The CD4(+)TGF-beta1(+) T cells were localized primarily to the tubulointerstitium, whereas TGF-beta1(-)FoxP3(+)CD25(+) cells were found mainly in lymphoid aggregates. Thus, adaptive T(R) cells suppressing T(E) cell responses to donor allopeptides in two tolerant patients appear to be functionally and phenotypically distinct from CD4(+)CD25(high)FoxP3(+) T cells.     

Pertussis toxin by inducing IL-6 promotes the generation of IL-17-producing CD4 cells

Compelling evidence has now demonstrated that IL-17-producing CD4 cells (Th17) are a major contributor to autoimmune pathogenesis, whereas CD4+CD25+ T regulatory cells (Treg) play a major role in suppression of autoimmunity. Differentiation of proinflammatory Th17 and immunosuppressive Treg from naive CD4 cells is reciprocally related and contingent upon the cytokine environment. We and others have reported that in vivo administration of pertussis toxin (PTx) reduces the number and function of mouse Treg. In this study, we have shown that supernatants from PTx-treated mouse splenic cells, which contained IL-6 and other proinflammatory cytokines, but not PTx itself, overcame the inhibition of proliferation seen in cocultures of Treg and CD4+CD25- T effector cells. This stimulatory effect could be mimicked by individual inflammatory cytokines such as IL-1beta, IL-6, and TNF-alpha. The combination of these cytokines synergistically stimulated the proliferation of CD4+CD25- T effector cells despite the presence of Treg with a concomitant reduction in the percentage of FoxP3+ cells and generation of IL-17-expressing cells. PTx generated Th17 cells, while inhibiting the differentiation of FoxP+ cells, from naive CD4 cells when cocultured with bone marrow-derived dendritic cells from wild-type mice, but not from IL-6-/- mice. In vivo treatment with PTx induced IL-17-secreting cells in wild-type mice, but not in IL-6-/- mice. Thus, in addition to inhibiting the development of Treg, the immunoadjuvant activity of PTx can be attributable to the generation of IL-6-dependent IL-17-producing CD4 cells.     

CD4+CD25+FoxP3+ 调节性T 细胞与黑龙江省HIV/AIDS 患者病情 相关性的研究

目的:比较黑龙江省HIV/AIDS患者与健康对照者(healthy controls,HCs)外周血CD4+CD25+FoxP3+调节性T细胞数量、免疫抑制功能的变化,探讨CD4+CD25+FoxP3+调节性T细胞在HIV/AIDS感染过程中的作用。方法:采用流式细胞仪检测21例HIV/AIDS患者及20例健康对照组的外周血CD4+CD25+FoxP3+调节性T细胞数量的百分比及绝对数量;采用共同培养方法检测HIV/AIDS患者外周血CD4+CD25+FoxP3+调节性T细胞免疫抑制功能的变化;实时荧光定量聚合酶链反应(RT-FQ-PCR)检测HIV/AIDS患者外周血CD4+CD25+FoxP3+调节性T细胞中FoxP3mRNA的表达。结果:黑龙江省HIV/AIDS患者外周血CD4+CD25+FoxP3+调节性T细胞比率明显高于HCs(P<0.01),而CD4+CD25+FoxP3+调节性T细胞的绝对计数显著下降,且与CD4+T细胞绝对计数成反比;混合淋巴细胞共同培养结果显示,HIV/AIDS患者外周血CD4+CD25+FoxP3+调节性T细胞的抑制功能无明显变化;HIV/AIDS患者外周血CD4+CD25+FoxP3+调节性T细胞的FoxP3 mRNA相对表达量无显著变化。结论:黑龙江省HIV/AIDS患者CD4+CD25+FoxP3+调节性T细胞的数量变化与病情相关。     

Generation of mucosal dendritic cells from bone marrow reveals a critical role of retinoic acid

It is unknown how dendritic cells (DCs) become specialized as mucosal DCs and maintain intestinal homeostasis. We report that a subset of bone marrow cells freshly isolated from C57BL/6 mice express the retinoic acid (RA)-synthesizing enzyme aldehyde dehydrogenase family 1, subfamily A2 (ALDH1a2) and are capable of providing RA to DC precursors in the bone marrow microenvironment. RA induced bone marrow-derived DCs to express CCR9 and ALDH1a2 and conferred upon them mucosal DC functions, including induction of Foxp3(+) regulatory T cells, IgA-secreting B cells, and gut-homing molecules. This response of DCs to RA was dependent on a narrow time window and stringent dose effect. RA promoted bone marrow-derived DC production of bioactive TGF-β by inhibiting suppressor of cytokine signaling 3 expression and thereby enhancing STAT3 activation. These RA effects were evident in vivo, in that mucosal DCs from vitamin A-deficient mice had reduced mucosal DC function, namely failure to induce Foxp3(+) regulatory T cells. Furthermore, MyD88 signaling enhanced RA-educated DC ALDH1a2 expression and was required for optimal TGF-β production. These data indicate that RA plays a critical role in the generation of mucosal DCs from bone marrow and in their functional activity.     

Natural and induced CD4+CD25+ cells educate CD4+CD25- cells to develop suppressive activity: the role of IL-2, TGF-beta, and IL-10

Thymus-derived, natural CD4(+)CD25(+) regulatory T cells can educate peripheral CD4(+)CD25(-) cells to develop suppressive activity by poorly understood mechanisms. TGF-beta has IL-2-dependent costimulatory effects on alloactivated naive, human CD4(+) T cells and induces them ex vivo to become potent contact-dependent, cytokine-independent suppressor cells. In this study, we report that CD4(+)CD25(+) cells are the targets of the costimulatory effects of IL-2 and TGF-beta. These cells do not divide, but, instead, greatly increase the numbers of CD4(+)CD25(-) cells that become CD25(+) cytokine-independent suppressor cells. These CD4(+)CD25(+) regulatory cells, in turn, induce other alloactivated CD4(+)CD25(-) cells to become potent suppressor cells by mechanisms that, surprisingly, require both cell contact and TGF-beta and IL-10. The suppressive effects of these secondary CD4(+)CD25(+) cells depend upon TGF-beta and IL-10. Moreover, both the naive CD4(+) cells induced by IL-2 and TGF-beta to become suppressor cells, and the subsequent CD4(+)CD25(-) cells educated by them to become suppressors express FoxP3. We suggest that the long-term effects of adoptively transferred natural-like CD4(+)CD25(+) regulatory cells induced ex vivo are due to their ability to generate new cytokine-producing CD4(+) regulatory T cells in vivo.     

Vitamin D regulation of immune function in the gut: why do T cells have vitamin D receptors?

Low vitamin D status is associated with an increased risk of immune-mediated diseases like inflammatory bowel disease (IBD) in humans. Experimentally vitamin D status is a factor that shapes the immune response. Animals that are either vitamin D deficient or vitamin D receptor (VDR) deficient are prone to develop IBD. Conventional T cells develop normally in VDR knockout (KO) mice but over-produce IFN-γ and IL-17. Naturally occurring FoxP3+ regulatory T cells are present in normal numbers in VDR KO mice and function as well as wildtype T regs. Vitamin D and the VDR are required for the development and function of two regulatory populations of T cells that require non-classical MHC class 1 for development. The two vitamin D dependent cell types are the iNKT cells and CD4/CD8αα intraepithelial lymphocytes (IEL). Protective immune responses that depend on iNKT cells or CD8αα IEL are therefore impaired in the vitamin D or VDR deficient host and the mice are more susceptible to immune-mediated diseases in the gut.     

Polyclonal adaptive regulatory CD4 cells that can reverse type I diabetes become oligoclonal long-term protective memory cells

Type 1 diabetes is a CD4 cell-dependent disease that results from destruction of insulin-producing beta cells in pancreatic islets. An ideal therapy would reverse diabetes shortly after onset when islet function in not yet fully ablated, and also prevent re-emergence of disease through the generation of memory cells that control the autoimmune response. In this study, we show that adaptive/induced polyclonal regulatory (TR) cells, which contain islet-reactive cells, fulfill these criteria in the NOD mouse model. CD4 cells induced to express FoxP3, IL-10, and TGF-beta1 in response to TCR signaling and TGF-beta1 can reverse diabetes with clinical restoration of prediabetic serum levels of IL-10. Unlike naturally occurring TR cells, these adaptive TR cells persist indefinitely (>1 year) as FoxP3(+), CD25(-) memory cells that self-renew. Establishment of memory is accompanied by narrowing of the T cell repertoire to usage of a single TCR beta-chain, Vbeta11, implying selection by Ag. With islet-specific adaptive TR cells, we show that memory is functionally stable and transferable. Therefore, adaptive TR cells, which can be readily generated from normal CD4 populations and become focused by Ag with induction of memory, may provide a treatment and a vaccine for the long-term cure of diabetes making them attractive as immunotherapeutic agents.     

Peripheral T cell lymphopenia and concomitant enrichment in naturally arising regulatory T cells: the case of the pre-Talpha gene-deleted mouse

In pre-Talpha (pTalpha) gene-deleted mice, the positively selectable CD4+ CD8+ double-positive thymocyte pool is only 1% that in wild-type mice. Consequently, their peripheral T cell compartment is severely lymphopenic with a concomitant increase in proportion of CD25+ FoxP3+ regulatory T cells. Using mixed bone marrow chimeras, where thymic output was 1% normal, the pTalpha(-/-) peripheral T cell phenotype could be reproduced with normal cells. In the pTalpha(-/-) thymus and peripheral lymphoid organs, FoxP3+ CD4+ cells were enriched. Parabiosis experiments showed that many pTalpha(-/-) CD4+ single-positive thymocytes represented recirculating peripheral T cells. Therefore, the enrichment of FoxP3+ CD4+ single-positive thymocytes was not solely due to increased thymic production. Thus, the pTalpha(-/-) mouse serves as a model system with which to study the consequences of chronic decreased thymic T cell production on the physiology of the peripheral T cell compartment.     

TGFβ and Retinoic Acid Intersect in Immune-Regulation

Transforming growth factor (TGFβ) prevents TH1 and TH2 differentiation and converts naïve CD4 cells into Foxp3-expressing T regulatory (Treg) cell1, 2. In sharp contrast, in the presence of pro-inflammatory cytokines, including IL-6, TGFβ not only inhibits Foxp3 expression but also promotes the differentiation of pro-inflammatory IL17-producing CD4 effector T (TH17) cells3-5. This reciprocal TGFβ-dependent differentiation imposes a critical dilemma between pro- and anti-inflammatory immunity and suggests that a sensitive regulatory mechanism must exist to control TGFβ-driven TH17 effector and Treg differentiation. A vitamin A metabolite, retinoic acid (RA), was recently identified as a key modulator of TGFβ-driven immune deviation capable of suppressing TH17 differentiation while promoting Foxp3+Treg generation 6-10.     

Regulatory NK cells suppress antigen-specific T cell responses

The immune system has a variety of regulatory/suppressive processes, which are decisive for the development of a healthy or an allergic immune response to allergens. NK1 and NK2 subsets have been demonstrated to display counterregulatory and provocative roles in immune responses, similar to Th1 and Th2 cells. T regulatory cells suppressing both Th1 and Th2 responses have been the focus of intensive research during the last decade. In this study, we aimed to investigate regulatory NK cells in humans, by characterization of NK cell subsets according to their IL-10 secretion property. Freshly purified IL-10-secreting NK cells expressed up to 40-fold increase in IL-10, but not in the FoxP3 and TGF-beta mRNAs. PHA and IL-2 stimulation as well as vitamin D3/dexamethasone and anti-CD2/CD16 mAbs are demonstrated to induce IL-10 expression in NK cells. The effect of IL-10+ NK cells on Ag-specific T cell proliferation has been examined in bee venom major allergen, phospholipase A2- and purified protein derivative of Mycobecterium bovis-induced T cell proliferation. IL-10+ NK cells significantly suppressed both allergen/Ag-induced T cell proliferation and secretion of IL-13 and IFN-gamma, particularly due to secreted IL-10 as demonstrated by blocking of the IL-10 receptor. These results demonstrate that a distinct small fraction of NK cells display regulatory functions in humans.     

Murine thymic stromal lymphopoietin promotes the differentiation of regulatory T cells from thymic CD4(+)CD8(-)CD25(-) naïve cells in a dendritic cell-independent manner

Human thymic stromal lymphopoietin (TSLP) activates dendritic cells (DCs), which promote the proliferation and differentiation of CD4+ T cells. However, murine TSLP (mTSLP) can act directly on CD4+ T cells and bring about their differentiation. We studied the role of mTSLP in the generation of CD4+CD25+FoxP3+ T cells from thymocytes. mTSLP promoted the differentiation of CD4+ single-positive thymocytes into CD4+CD25+FoxP3+ T cells. Although we cannot exclude an effect of TSLP mediated through DCs due to co-stimulatory effects, mTSLP appears to act directly on thymocytes. T-cell receptor and TSLP receptor signaling act synergistically on thymocytes to generate CD4+CD25+FoxP3+ T cells. mTSLP may play an important role in maintaining immune tolerance by promoting the conversion of thymocytes into natural regulatory T cells via escape from negative selection.     

Immunomodulatory effects of transforming growth factor-beta on T lymphocytes. Induction of CD8 expression in the CTLL-2 cell line and in normal thymocytes.

We investigated the role of transforming growth factor-beta 1 (TGF-beta) in regulation of T cell growth and differentiation. Treatment of CTLL-2 cells with TGF-beta inhibited IL-2-dependent proliferation and caused morphologic changes as well as increased adherence. A major change of phenotype in TGF-beta-treated cells was the de novo expression of CD8 alpha chain in 35% of cells, which required the continuous presence of TGF-beta. Of the CD8 alpha+ cells, 20 to 30% co-expressed CD8 beta chain. Increased CD8 expression occurred even in the total absence of cell growth, was not a consequence of growth inhibition, and was not a result of selective growth or survival of CD8+ cells. New RNA synthesis was required for TGF beta-induced CD8 alpha surface expression, inasmuch as this was prevented by treatment with actinomycin D. Northern blot analysis demonstrated that cells treated with IL-2 + TGF-beta rapidly accumulated mRNA encoding both chains of the CD8 dimer, to a level fourfold greater than control by 6 to 12 h. In contrast, the IL-2-dependent increases in IL-2R alpha, IL-2R beta, and Granzyme B mRNA levels in these cultures were profoundly inhibited by TGF-beta. When unfractionated murine thymocytes were stimulated with phorbol dibutyrate plus ionomycin and cultured with IL-2 + TGF-beta, an increase in CD8 alpha mRNA was seen and greater numbers of CD8+ cells with higher levels of CD8 alpha and CD8 beta surface expression resulted, as compared to controls treated with IL-2 alone. Furthermore, similar treatment of CD4-CD8-(double negative) thymocytes with TGF-beta induced de novo CD8 alpha expression by a substantial number of cells, and the majority of these CD8+ cells lacked TCR/CD3. These data suggest that TGF-beta has both positive and negative regulatory effects on the expression of gene products important for T lymphocyte differentiation and function.     

NF-AT-mediated expression of TGF-beta1 in tolerant T cells

During T cell development in the thymus, a certain population of self-reactive thymocytes differentiates into regulatory T cells that suppress otherwise harmful self-reactive T cells. In transgenic mice expressing both TCR that specifically recognizes moth cytochrome c and the moth cytochrome c ligand, a large proportion of CD4+ T cells expresses CD25 and secretes TGF-beta1 upon Ag stimulation. Because TGF-beta1 expression by these T cells can be decreased by cyclosporin A, a NF-AT inhibitor, NF-AT-mediated TGF-beta1 expression in T cells was addressed by characterizing a NF-AT response element in the TGF-beta1 promoter. Analysis of the mouse TGF-beta1 promoter (-1799 to +793) in transfection experiments in T cell 68-41 hybridoma cells detected NF-AT binding sites at positions +268 and +288 in the proximal promoter region. Binding of NF-AT to this region was detected only in tolerant CD4+ T cells, but not in fully activated CD4+ T cells by chromatin immunoprecipitation assays. Activation of these NF-AT sites was sufficient to induce TGF-beta1 promoter activity; however, additional signaling due to full Ag stimulation blocked NF-AT-mediated TGF-beta1 expression. This suppression of the TGF-beta1 promoter is mediated by the -1079 to -406 region, in which deletion of a GATA-binding motif at position -821 abrogates NF-AT-mediated activation of the TGF-beta1 promoter. Therefore, TGF-beta1 expression in T cells is controlled by multiple regulatory factors that have distinct functions in response to partial or full TCR activation.