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.     

IL‐23 Activated γδ T Cells Affect Th17 Cells and Regulatory T Cells by Secreting IL‐21 in Children with Primary Nephrotic Syndrome

This study (1) analysed the percentage of γδ T cells, γδ T cell subsets, Th17 cells and regulatory T cells (Treg cells) and (2) determined the role of IL ‐23 in primary nephrotic syndrome (PNS ) patients with active disease and in remission. Eighty‐four patients with PNS and 51 healthy age‐matched controls were included in this study. The percentage of γδ T cells, γδ T cell subsets, Th17 cells and Treg cells in peripheral blood mononuclear cells (PBMC s) were analysed by fluorescence‐activated cell sorting. PMBC s from PNS patients with active disease were cultured in the presence of IL ‐23, IL ‐23 and an IL ‐23 antagonist, or IL 23 and an anti‐IL ‐21 monoclonal antibody (mA b). The percentage of γδ T cells, IL ‐23R⁺ γδ T cells and IL ‐17⁺ γδ T cells were significantly increased in PNS patients with active disease. There was a positive correlation between the percentage of γδ T cells, IL ‐23R⁺ γδ T cells, IL ‐17⁺ γδ T cells and the Th17/Treg ratio. IL ‐23 increased the percentage of γδ T cells and Th17 cells and decreased the percentage of Treg cells in PBMC s isolated from PNS patients with active disease. Anti‐IL ‐21 mA b reduced the percentage of γδ T cells and Th17 cells, but increased the percentage of Treg cells. γδ T cells, IL ‐17⁺ γδ T cells and IL ‐23R⁺ γδ T cells may be involved in the pathogenesis of paediatric PNS by modulating the balance of Th17/Treg cells. γδ T cells may cause an imbalance in Th17/Treg cells by secreting IL ‐21 in the presence of IL ‐23.     

Commensal A4 bacteria inhibit intestinal Th2‐cell responses through induction of dendritic cell TGF‐β production

It has been shown that while commensal bacteria promote Th1, Th17 and Treg cells in lamina propria (LP) in steady‐state conditions, they suppress mucosal Th2 cells. However, it is still unclear whether there are specific commensal organisms down‐regulating Th2 responses, and the mechanism involved. Here we demonstrate that commensal A4 bacteria, a member of the Lachnospiraceae family, which produce an immunodominant microbiota CBir1 antigen, inhibits LP Th2‐cell development. When transferred into the intestines of RAG^?/? mice, CBir1‐specific T cells developed predominately towards Th1 cells and Th17 cells, but to a lesser extent into Th2 cells. The addition of A4 bacterial lysates to CD4⁺ T‐cell cultures inhibited production of IL‐4. A4 bacteria stimulated dendritic cell production of TGF‐β, and blockade of TGF‐β abrogated A4 bacteria inhibition of Th2‐cell development in vitro and in vivo. Collectively, our data show that A4 bacteria inhibit Th2‐cell differentiation by inducing dendritic cell production of TGF‐β.     

Role of CD4 T cell helper subsets in immune response and deviation of CD8 T cells in mice*

The ability of different CD4⁺ T cell subsets to help CD8⁺ T‐cell response is not fully understood. Here, we found using the murine system that Th17 cells induced by IL‐1β, unlike Th1, were not effective helpers for antiviral CD8 responses as measured by IFNγ‐producing cells or protection against virus infection. However, they skewed CD8 responses to a Tc17 phenotype. Thus, the apparent lack of help was actually immune deviation. This skewing depended on both IL‐21 and IL‐23. To overcome this effect, we inhibited Th17 induction by blocking TGF‐β. Anti‐TGF‐β allowed the IL‐1β adjuvant to enhance CD8⁺ T‐cell responses without skewing the phenotype to Tc17, thereby providing an approach to harness the benefit of common IL‐1‐inducing adjuvants like alum without immune deviation.     

TGF‐β indirectly favors the development of human Th17 cells by inhibiting Th1 cells

Human Th17 clones and circulating Th17 cells showed lower susceptibility to the anti‐proliferative effect of TGF‐β than Th1 and Th2 clones or circulating Th1‐oriented T cells, respectively. Accordingly, human Th17 cells exhibited lower expression of clusterin, and higher Bcl‐2 expression and reduced apoptosis in the presence of TGF‐β, in comparison with Th1 cells. Umbilical cord blood naïve CD161⁺CD4⁺ T cells, which contain the precursors of human Th17 cells, differentiated into IL‐17A‐producing cells only in response to IL‐1β plus IL‐23, even in serum‐free cultures. TGF‐β had no effect on constitutive RORγt expression by umbilical cord blood CD161⁺ T cells but it increased the relative proportions of CD161⁺ T cells differentiating into Th17 cells in response to IL‐1β plus IL‐23, whereas under the same conditions it inhibited both T‐bet expression and Th1 development. These data suggest that TGF‐β is not critical for the differentiation of human Th17 cells, but indirectly favors their expansion because Th17 cells are poorly susceptible to its suppressive effects.     

Role of T cell TGF‐β signaling in intestinal cytokine responses and helminthic immune modulation

Colonization with helminthic parasites induces mucosal regulatory cytokines, like IL‐10 or TGF‐β, that are important in suppressing colitis. Helminths induce mucosal T cell IL‐10 secretion and regulate lamina propria mononuclear cell (LPMC) Th1 cytokine generation in an IL‐10‐dependent manner in WT mice. Helminths also stimulate mucosal TGF‐β release. As TGF‐β exerts major regulatory effects on T lymphocytes, we investigated the role of T lymphocyte TGF‐β signaling in helminthic modulation of intestinal immunity. T cell TGF‐β signaling is interrupted in TGF‐β receptor II dominant negative (TGF‐βRII DN) mice by T‐cell‐specific over‐expression of a TGF‐βRII DN. We studied LPMC responses in WT and TGF‐βRII DN mice that were uninfected or colonized with the nematode, Heligmosomoides polygyrus. Our results indicate an essential role of T cell TGF‐β signaling in limiting mucosal Th1 and Th2 responses. Furthermore, we demonstrate that helminthic induction of intestinal T cell IL‐10 secretion requires intact T cell TGF‐β‐signaling pathway. Helminths fail to curtail robust, dysregulated intestinal Th1 cytokine production and chronic colitis in TGF‐βRII DN mice. Thus, T cell TGF‐β signaling is essential for helminthic stimulation of mucosal IL‐10 production, helminthic modulation of intestinal IFN‐γ generation and H. polygyrus‐mediated suppression of chronic colitis.     

Reverse plasticity: TGF‐β and IL‐6 induce Th1‐to‐Th17‐cell transdifferentiation in the gut

Th17 cells are a heterogeneous population of pro‐inflammatory T cells that have been shown to mediate immune responses against intestinal bacteria. Th17 cells are highly plastic and can transdifferentiate to Th1/17 cells or unconventional Th1 cells, which are highly pathogenic in animal models of immune‐mediated diseases such as inflammatory bowel diseases. A recent European Journal of Immunology article by Liu et al. (Eur. J. Immunol. 2015. 45:1010–1018) showed, surprisingly, that Th1 cells have a similar plasticity, and could transdifferentiate to Th17 cells. Thus, IFN‐γ‐producing Th1 effector cells specific for an intestinal microbial antigen were shown to acquire IL‐17‐producing capacities in the gut in a mouse model of colitis, and in response to TGF‐β and IL‐6 in vitro. TGF‐β induced Runx1, and together with IL‐6 was shown to render the ROR‐γt and IL‐17 promoters in Th1 cells accessible for Runx1 binding. In this commentary, we discuss how this unexpected plasticity of Th1 cells challenges our view on the generation of Th1/17 cells with the capacity to co‐produce IL‐17 and IFN‐γ, and consider possible implications of this Th1‐to‐Th17‐cell conversion for therapies of inflammatory bowel diseases and protective immune responses against intracellular pathogens.     

Attenuated TGF‐β1 responsiveness of dendritic cells and their precursors in atopic dermatitis

The responsiveness of DCs and their precursors to transforming growth factor beta1 (TGF‐β1) affects the nature of differentiating DC subsets, which are essential for the severity of atopic dermatitis (AD). To evaluate TGF‐β signaling in monocytes and monocyte‐derived DCs of AD patients compared with that of controls, in vitro generated Langerhans cell (LC) like DCs, expression of TGF‐β receptors, phospho‐Smad2/3 and Smad7 were evaluated. Furthermore, TNF‐α expression and synergistic effects of TNF‐α upon TGF‐β signaling and DC generation were evaluated. We found LC‐like DC differentiation of monocytes from AD patients in response to TGF‐β1 was remarkably reduced and TGF‐β1 receptor expression was significantly lower compared with that of healthy controls. Attenuated TGF‐β1 responsiveness mirrored by lower phospho‐Smad2/3 expression after TGF‐β1 stimulation and higher expression of inhibitory Smad7 was observed in monocytes from AD patients. During DC generation, mRNA expression of Smad7 was relatively higher in LC‐like DCs of AD patients. Lower TNF‐α expression of monocytes from AD patients might further contribute to attenuated TGF‐β signaling in the disease since TNF‐α had synergistic effects on TGF‐β1 signaling and LC generation through mediating the degradation of Smad7. Our results demonstrate alleviated TGF‐β1 signaling together with the amount of soluble co‐factors might direct the nature of differentiating DCs.     

C5a receptor‐deficient dendritic cells promote induction of Treg and Th17 cells

C5a is a proinflammatory mediator that has recently been shown to regulate adaptive immune responses. Here we demonstrate that C5a receptor (C5aR) signaling in DC affects the development of Treg and Th17 cells. Genetic ablation or pharmacological targeting of the C5aR in spleen‐derived DC results in increased production of TGF‐β leading to de novo differentiation of Foxp3⁺ Treg within 12 h after co‐incubation with CD4⁺ T cells from DO11.10/RAG2^?/? mice. Stimulation of C5aR^?/? DC with OVA and TLR2 ligand Pam₃CSK₄ increased TGF‐β production and induced high levels of IL‐6 and IL‐23 but only minor amounts of IL‐12 leading to differentiation of Th cells producing IL‐17A and IL‐21. Th17 differentiation was also found in vivo after adoptive transfer of CD4⁺ Th cell into C5aR^?/? mice immunized with OVA and Pam₃CSK₄. The altered cytokine production of C5aR^?/? DC was associated with low steady state MHC class II expression and an impaired ability to upregulate CD86 and CD40 in response to TLR2. Our data suggest critical roles for C5aR in Treg and Th17‐cell differentiation through regulation of DC function.     

Interleukin‐21 (IL‐21) synergizes with IL‐2 to enhance T‐cell receptor‐induced human T‐cell proliferation and counteracts IL‐2/transforming growth factor‐β‐induced regulatory T‐cell development

Interleukin‐2 (IL‐2) is a mainstay for current immunotherapeutic protocols but its usefulness in patients is reduced by severe toxicities and because IL‐2 facilitates regulatory T (Treg) cell development. IL‐21 is a type I cytokine acting as a potent T‐cell co‐mitogen but less efficient than IL‐2 in sustaining T‐cell proliferation. Using various in vitro models for T‐cell receptor (TCR)‐dependent human T‐cell proliferation, we found that IL‐21 synergized with IL‐2 to make CD4⁺ and CD8⁺ T cells attain a level of expansion that was impossible to obtain with IL‐2 alone. Synergy was mostly evident in naive CD4⁺ cells. IL‐2 and tumour‐released transforming growth factor‐β (TGF‐β) are the main environmental cues that cooperate in Treg cell induction in tumour patients. Interleukin‐21 hampered Treg cell expansion induced by IL‐2/TGF‐β combination in naive CD4⁺ cells by facilitating non‐Treg over Treg cell proliferation from the early phases of cell activation. Conversely, IL‐21 did not modulate the conversion of naive activated CD4⁺ cells into Treg cells in the absence of cell division. Treg cell reduction was related to persistent activation of Stat3, a negative regulator of Treg cells associated with down‐modulation of IL‐2/TGF‐β‐induced phosphorylation of Smad2/3, a positive regulator of Treg cells. In contrast to previous studies, IL‐21 was completely ineffective in counteracting the suppressive activity of Treg cells on naive and memory, CD4⁺ and CD8⁺ T cells. Present data provide proof‐of‐concept for evaluating a combinatorial approach that would reduce the IL‐2 needed to sustain T‐cell proliferation efficiently, thereby reducing toxicity and controlling a tolerizing mechanism responsible for the contraction of the T‐cell response.     

Regulatory effects of IFN‐β on production of osteopontin and IL‐17 by CD4+ T Cells in MS

IFN‐β currently serves as one of the major treatments for MS. Its anti‐inflammatory mechanism has been reported as involving a shift in cytokine balance from Th1 to Th2 in the T‐cell response against elements of the myelin sheath. In addition to the Th1 and Th2 groups, two other important pro‐inflammatory cytokines, IL‐17 and osteopontin (OPN), are believed to play important roles in CNS inflammation in the pathogenesis of MS. In this study, we examined the potential effects of IFN‐β on the regulation of OPN and IL‐17 in MS patients. We found that IFN‐β used in vitro at 0.5–3 ng/mL significantly inhibited the production of OPN in primary T cells derived from PBMC. The inhibition of OPN was determined to occur at the CD4⁺ T‐cell level. In addition, IFN‐β inhibited the production of IL‐17 and IL‐21 in CD4⁺ T cells. It has been described that IFN‐β suppresses IL‐17 production through the inhibition of a monocytic cytokine, the intracellular translational isoform of OPN. Our further investigation demonstrated that IFN‐β also acted directly on the CD4⁺ T cells to regulate OPN and IL‐17 expression through the type I IFN receptor‐mediated activation of STAT1 and suppression of STAT3 activity. Administration of IFN‐β to EAE mice ameliorated the disease severity. Furthermore, spinal cord infiltration of OPN⁺ and IL‐17⁺ cells decreased in IFN‐β‐treated EAE mice along with decreases in serum levels of OPN and IL‐21. Importantly, decreased OPN production by IFN‐β treatment contributes to the reduced migratory activity of T cells. Taken together, the results from both in vitro and in vivo experiments indicate that IFN‐β treatment can down‐regulate the OPN and IL‐17 production in MS. This study provides new insights into the mechanism of action of IFN‐β in the treatment of MS.     

Synergistic effect of TGF‐β superfamily members on the induction of Foxp3+ Treg

TGF‐β plays an important role in the induction of Treg and maintenance of immunologic tolerance, but whether other members of TGF‐β superfamily act together or independently to achieve this effect is poorly understood. Although others have reported that the bone morphogenetic proteins (BMP) and TGF‐β have similar effects on the development of thymocytes and T cells, in this study, we report that members of the BMP family, BMP‐2 and ‐4, are unable to induce non‐regulatory T cells to become Foxp3⁺ Treg. Neutralization studies with Noggin have revealed that BMP‐2/4 and the BMP receptor signaling pathway is not required for TGF‐β to induce naïve CD4⁺CD25^? cells to express Foxp3; however, BMP‐2/4 and TGF‐β have a synergistic effect on the induction of Foxp3⁺ Treg. BMP‐2/4 affects non‐Smad signaling molecules including phosphorylated ERK and JNK, which could subsequently promote the differentiation of Foxp3⁺ Treg induced by TGF‐β. Data further advocate that TGF‐β is a key signaling factor for Foxp3⁺ Treg development. In addition, the synergistic effect of BMP‐2/4 and TGF‐β indicates that the simultaneous manipulation of TGF‐β and BMP signaling might have considerable effects in the clinical setting for the enhancement of Treg purity and yield.     

Induction and mechanism of action of transforming growth factor-β-secreting Th3 regulatory cells

Summary: Th3 CD4⁺ regulatory cells were identified during the course of investigating mechanisms associated with oral tolerance. Different mechanisms of tolerance are induced following oral antigen administration, including active suppression, clonal anergy and deletion. Low doses favor active suppression whereas high doses favor anergy/deletion. Th3 regulatory cells form a unique T‐cell subset which primarily secretes transforming growth factor (TGF)‐β, provides help for IgA and has suppressive properties for both Th1 and Th2 cells. Th3 type cells are distinct from the Th2 cells, as CD4⁺ TGF‐β‐secreting cells with suppressive properties have been generated from interleukin (IL)‐4‐deficient animals. In vitro differentiation of Th3 cells from Th precursors from T‐cell antigen receptor (TCR) transgenic mice is enhanced by culture with TGF‐β, IL‐4, IL‐10, and anti‐IL‐12. Th3 CD4⁺ myelin basic protein regulatory clones are structurally identical to Th1 encephalitogenic clones in TCR usage, MHC restriction and epitope recognition, but produce TGF‐β with various amounts of IL‐4 and IL‐10. Because Th3 regulatory cells are triggered in an antigen‐specific fashion but suppress in an antigen‐non‐specific fashion, they mediate “bystander suppression” when they encounter the fed autoantigen at the target organ. In vivo induction of Th3 cells and low dose oral tolerance is enhanced by oral administration of IL‐4. Anti‐CD86 but not anti‐CD80 blocks the induction of Th3 cells associated with low dose oral tolerance. Th3 regulatory cells have been described in other systems (e.g. recovery from experimental allergic encephalomyelitis) but may be preferentially generated following oral antigen administration due to the gut immunologic milieu that is rich in TGF‐β and has a unique class of dendritic cells. CD4⁺CD25⁺ regulatory T‐cell function also appears related to TGF‐β.     

PolyI:C plus IL‐2 or IL‐12 induce IFN‐γ production by human NK cells via autocrine IFN‐β

NK lymphocytes and type I IFN (IFN‐α/β) are major actors of the innate anti‐viral response that also influence adaptive immune responses. We evaluated type I IFN production by human NK cells in response to polyI:C, a potent type I IFN‐inducing TLR3 agonist. PolyI:C plus IL‐2/IL‐12 induced IFN‐β (but not IFN‐α) mRNA expression and protein production by highly pure human NK cells and by the human NK cell line NK92. Neutralizing anti‐IFNAR1 or anti‐IFN‐β Ab prevented the production of IFN‐γ induced by polyI:C plus IL‐2/IL‐12. Similarly, IFN‐γ production induced by polyI:C plus IL‐12 was reduced in NK cells isolated from IFNAR1^?/? compared with WT mice. The ability of polyI:C plus IL‐12 to induce IFN‐γ production was related to an increase of TLR3, Mda5 and IFNAR expression and by an increase of STAT1 and STAT4 phosphorylation. Collectively, these data demonstrate that NK cells, in response to polyI:C plus IL‐2/IL‐12, produce IFN‐β that induce, in an autocrine manner, the production of IFN‐γ and thereby highlight that NK cells may control the outcome of protective or injurious immune responses through type I IFN secretion.     

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.     

Coincident diabetes mellitus modulates Th1‐, Th2‐, and Th17‐cell responses in latent tuberculosis in an IL‐10‐ and TGF‐β‐dependent manner

Type 2 diabetes mellitus (DM) is a risk factor for the development of active tuberculosis (TB), although its role in the TB‐induced responses in latent TB (LTB) is not well understood. Since Th1, Th2, and Th17 responses are important in immunity to LTB, we postulated that coincident DM could alter the function of these CD4⁺ T‐cell subsets. To this end, we examined mycobacteria‐induced immune responses in the whole blood of individuals with LTB‐DM and compared them with responses of individuals without DM (LTB‐NDM). T‐cell responses from LTB‐DM are characterized by diminished frequencies of mono‐ and dual‐functional CD4⁺ Th1, Th2, and Th17 cells at baseline and following stimulation with mycobacterial antigens‐purified protein derivative, early secreted antigen‐6, and culture filtrate protein‐10. This modulation was at least partially dependent on IL‐10 and TGF‐β, since neutralization of either cytokine resulted in significantly increased frequencies of Th1 and Th2 cells but not Th17 cells in LTB‐DM but not LTB individuals. LTB‐DM is therefore characterized by diminished frequencies of Th1, Th2, and Th17 cells, indicating that DM alters the immune response in latent TB leading to a suboptimal induction of protective CD4⁺ T‐cell responses, thereby providing a potential mechanism for increased susceptibility to active disease.