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.     

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.     

The siRNA cocktail targeting interleukin 10 receptor and transforming growth factor‐β receptor on dendritic cells potentiates tumour antigen‐specific CD8+ T cell immunity

Dendritic cells (DCs) are promising therapeutic agents in the field of cancer immunotherapy due to their intrinsic immune‐priming capacity. The potency of DCs, however, is readily attenuated immediately after their administration in patients as tumours and various immune cells, including DCs, produce various immunosuppressive factors such as interleukin (IL)‐10 and transforming growth factor (TGF)‐β that hamper the function of DCs. In this study, we used small interfering RNA (siRNA) to silence the expression of endogenous molecules in DCs, which can sense immunosuppressive factors. Among the siRNAs targeting various immunosuppressive molecules, we observed that DCs transfected with siRNA targeting IL‐10 receptor alpha (siIL‐10RA) initiated the strongest antigen‐specific CD8⁺ T cell immune responses. The potency of siIL‐10RA was enhanced further by combining it with siRNA targeting TGF‐β receptor (siTGF‐βR), which was the next best option during the screening of this study, or the previously selected immunoadjuvant siRNA targeting phosphatase and tensin homologue deleted on chromosome 10 (PTEN) or Bcl‐2‐like protein 11 (BIM). In the midst of sorting out the siRNA cocktails, the cocktail of siIL‐10RA and siTGF‐βR generated the strongest antigen‐specific CD8⁺ T cell immunity. Concordantly, the knock‐down of both IL‐10RA and TGF‐βR in DCs induced the strongest anti‐tumour effects in the TC‐1 P0 tumour model, a cervical cancer model expressing the human papillomavirus (HPV)‐16 E7 antigen, and even in the immune‐resistant TC‐1 (P3) tumour model that secretes more IL‐10 and TGF‐β than the parental tumour cells (TC‐1 P0). These results provide the groundwork for future clinical development of the siRNA cocktail‐mediated strategy by co‐targeting immunosuppressive molecules to enhance the potency of DC‐based vaccines.     

TLR2‐activated human langerhans cells promote Th17 polarization via IL‐1β, TGF‐β and IL‐23

The cytokines IL‐6, IL‐1β, TGF‐β, and IL‐23 are considered to promote Th17 commitment. Langerhans cells (LC) represent DC in the outer skin layers of the epidermis, an environment extensively exposed to pathogenic attack. The question whether organ‐resident DC like LC can evoke Th17 immune response is still open. Our results show that upon stimulation by bacterial agonists, epidermal LC and LC‐like cells TLR2‐dependently acquire the capacity to polarize Th17 cells. In Th17 cells, expression of retinoid orphan receptor γβ was detected. To clarify if IL‐17⁺cells could arise per se by stimulated LC we did not repress Th1/Th2 driving pathways by antibodies inhibiting differentiation. In CD1c⁺/langerin⁺ monocyte‐derived LC‐like cells (MoLC), macrophage‐activating lipopeptide 2, and peptidoglycan (PGN) induced the release of the cytokines IL‐6, IL‐1β, and IL‐23. TGF‐β, a cytokine required for LC differentiation and survival, was found to be secreted constitutively. Anti‐TLR2 inhibited secretion of IL‐6, IL‐1β, and IL‐23 by MoLC, while TGF‐β was unaffected. The amount of IL‐17 and the ratio of IL‐17 to IFN‐γ expression was higher in MoLC‐ than in monocyte‐derived DC‐cocultured Th cells. Anti‐IL‐1β, ‐TGF‐β and ‐IL‐23 decreased the induction of Th17 cells. Interestingly, blockage of TLR2 on PGN‐stimulated MoLC prevented polarization of Th cells into Th17 cells. Thus, our findings indicate a role of TLR2 in eliciting Th17 immune responses in inflamed skin.     

Expression of interleukin (IL)‐19 and IL‐24 in inflammatory bowel disease patients: a cross‐sectional study

Interleukin (IL)‐19 and IL‐24 belong to the IL‐20 subfamily, and are involved in host defence against bacteria and fungi, tissue remodelling and wound healing. Nevertheless, no previous studies have explored their expression in Mexican mestizo patients with inflammatory bowel disease (IBD). The aim of the study was to characterize and to enumerate peripheral and tissue IL‐19‐ and IL‐24‐producing cells, as well as gene expression in patients with IBD with regard to its clinical activity. We studied a total of 77 patients with ulcerative colitis (UC), 36 Crohn's disease (CD) and 33 patients as control group (without endoscopic evidence of intestinal inflammation). Gene expression was measured by real‐time–polymerase chain reaction (RT–PCR). Protein expression was detected in biopsies by immunohistochemistry and in freshly isolated peripheral blood mononuclear cells by flow cytometry. IL‐19 and IL‐24 gene expression was elevated significantly in patients with active IBD versus the inactive disease and non‐inflammatory control groups (P < 0·05). However, IL‐19‐ and IL‐24‐producing cells were only increased in active CD versus active UC and non‐inflammatory tissues (P < 0·05). IL‐19 was produced conspicuously by circulating B cells and monocytes in patients with inactive disease (P < 0·05). Conversely, IL‐24 was noticeably synthesized by peripheral B cells, CD4⁺ T cells, CD8⁺ T cells and monocytes in patients with active disease. In conclusion, IL‐19‐ and IL‐24‐producing cells in active CD patients were increased compared with active UC and non‐inflammatory tissues. These cytokines could significantly shape and differentiate inflammatory process, severity and tolerance loss between UC and CD pathophysiology.     

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.     

TGF-β limits IL-33 production and promotes the resolution of colitis through regulation of macrophage function

M?s promote tissue injury or repair depending on their activation status and the local cytokine milieu. It remains unclear whether the immunosuppressive effects of transforming growth factor β (TGF‐β) serve a nonredundant role in M? function in vivo. We generated M?‐specific transgenic mice that express a truncated TGF‐β receptor II under control of the CD68 promoter (CD68TGF‐βDNRII) and subjected these mice to the dextran sodium sulfate (DSS) model of colitis. CD68TGF‐βDNRII mice have an impaired ability to resolve colitic inflammation as demonstrated by increased lethality, granulocytic inflammation, and delayed goblet cell regeneration compared with transgene negative littermates. CD68TGF‐βDNRII mice produce significantly less IL‐10, but have increased levels of IgE and numbers of IL‐33⁺ M?s than controls. These data are consistent with associations between ulcerative colitis and increased IL‐33 production in humans and suggest that TGF‐β may promote the suppression of intestinal inflammation, at least in part, through direct effects on M? function.     

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.     

Soluble HLA‐I‐mediated secretion of TGF‐β1 by human NK cells and consequent down‐regulation of anti‐tumor cytolytic activity

Soluble HLA class I (sHLA‐I) molecules can regulate survival of NK cells and their anti‐tumor killing activity. Herein, we have analysed whether interaction of sHLA‐I with CD8 and/or different isoforms of killer Ig‐like receptors (KIR) induced secretion of transforming growth factor (TGF)‐β1. CD8⁺KIR^? NK cell clones secreted TGF‐β1 upon the interaction of sHLA‐I with CD8 molecule. sHLA‐Cw4 or sHLA‐Cw3 alleles engaging inhibitory isoforms of KIR, namely KIR2DL1 or KIR2DL2, strongly downregulated TGF‐β1 production elicited through CD8. On the other hand, sHLA‐Cw4 or sHLA‐Cw3 alleles induced secretion of TGF‐β1 by ligation of stimulatory KIR2DS1 or KIR2DS2 isoforms. TGF‐β1 strongly reduced NK cell‐mediated tumor cell lysis and production of pro‐inflammatory cytokines such as TNF‐α and IFN‐γ. Also, TGF‐β1 inhibited NK cell cytolysis induced by the engagement of stimulatory receptors including NKG2D, DNAM1, 2B4, CD69, NKp30, NKp44 and NKp46. The IL‐2‐dependent surface upregulation of some of these receptors was prevented by TGF‐β1. Furthermore, TGF‐β1 hampered IL‐2‐induced NK cell proliferation but not IL‐2‐mediated rescue from apoptosis of NK cells. Depletion of TGF‐β1 restored all the NK cell‐mediated functional activities analysed. Taken together these findings suggest that sHLA‐I antigens may downregulate the NK cell‐mediated innate response by inducing TGF‐β1 release.     

Mucosal IL‐10 and IL‐10 receptor expression patterns in paediatric patients with ulcerative colitis

Interleukin‐10 (IL‐10) is a key anti‐inflammatory cytokine. We aimed to assess IL‐10 and IL‐10 receptor (IL‐10R) expression in the gut, and determine whether these patterns are altered in patients with ulcerative colitis (UC). Formalin‐fixed paraffin‐embedded rectal and transverse colon sections were collected from three groups of patients: (a) control subjects with normal colonoscopy and without history of inflammatory bowel disease; (b) UC patients with extensive colitis or pancolitis (E3/E4 phenotype); and (c) UC patients with limited distal disease (E1/E2 phenotype; n = 8‐10 subjects per group). Immunohistochemistry (IHC) was performed to assess expression patterns of IL‐10, IL‐10R1 and IL‐10R2, and was correlated with clinical, endoscopic and histologic severity indices among patients. A trend towards increased IL‐10 expression was noted in rectal biopsies of patients with active UC, compared with controls. Moreover, IL‐10 levels were significantly increased in transverse colon biopsies of patients with extensive/pancolitis, compared with control subjects and patients with limited distal disease. Rectal IL‐10R1 and IL‐10R2 levels were comparable between control subject and patients with active UC. However, transverse colon IL‐10R1 levels were significantly higher in patients with E3/E4 colitis, compared with controls. Finally, we found no correlation between clinical, endoscopic and histologic severity of inflammation among UC patients and IL‐10, IL‐10R1 or IL‐10R2 expression in rectal sections. Mucosal expression patterns of IL‐10 and IL‐10R, evaluated by IHC, were overall similar between control subjects and patients with active UC. Given IL‐10’s anti‐inflammatory properties, additional studies are required to determine whether signalling through the IL‐10R is altered among these patients.     

Generation of highly effective and stable murine alloreactive Treg cells by combined anti‐CD4 mAb,TGF‐β, and RA treatment

The transfer of alloreactive regulatory T (aTreg) cells into transplant recipients represents an attractive treatment option to improve long‐term graft acceptance. We recently described a protocol for the generation of aTreg cells in mice using a nondepleting anti‐CD4 antibody (aCD4). Here, we investigated whether adding TGF‐β and retinoic acid (RA) or rapamycin (Rapa) can further improve aTreg‐cell generation and function. Murine CD4⁺ T cells were cultured with allogeneic B cells in the presence of aCD4 alone, aCD4+TGF‐β+RA or aCD4+Rapa. Addition of TGF‐β+RA or Rapa resulted in an increase of CD25⁺Foxp3⁺‐expressing T cells. Expression of CD40L and production of IFN‐γ and IL‐17 was abolished in aCD4+TGF‐β+RA aTreg cells. Additionally, aCD4+TGF‐β+RA aTreg cells showed the highest level of Helios and Neuropilin‐1 co‐expression. Although CD25⁺Foxp3⁺ cells from all culture conditions displayed complete demethylation of the Treg‐specific demethylated region, aCD4+TGF‐β+RA Treg cells showed the most stable Foxp3 expression upon restimulation. Consequently, aCD4+TGF‐β+RA aTreg cells suppressed effector T‐cell differentiation more effectively in comparison to aTreg cells harvested from all other cultures, and furthermore inhibited acute graft versus host disease and especially skin transplant rejection. Thus, addition of TGF‐β+RA seems to be superior over Rapa in stabilising the phenotype and functional capacity of aTreg cells.     

IL‐10 interferes directly with TCR‐induced IFN‐γ but not IL‐17 production in memory T cells

IL‐10 is a potent immunoregulatory and anti‐inflammatory cytokine. However, therapeutic trials in chronic inflammation have been largely disappointing. It is well established that IL‐10 can inhibit Th1 and Th2 cytokine production via indirect effects on APC. Less data are available about the influence of IL‐10 on IL‐17 production, a cytokine which has been recently linked to chronic inflammation. Furthermore, there are only few reports about a direct effect of IL‐10 on T cells. We demonstrate here that IL‐10 can directly interfere with TCR‐induced IFN‐γ production in freshly isolated memory T cells in the absence of APC. This effect was independent of the previously described effects of IL‐10 on T cells, namely inhibition of IL‐2 production and inhibition of CD28 signaling. In contrast, IL‐10 did not affect anti‐CD3/anti‐CD28‐induced IL‐17 production from memory T cells even in the presence of APC. This might have implications for the interpretation of therapeutic trials in patients with chronic inflammation where Th17 cells contribute to pathogenesis.     

Epithelial expression of interleukin‐37b in inflammatory bowel disease

Interleukin (IL)‐37 is a member of the IL‐1 cytokine family. We investigated IL‐37b expression in the inflamed mucosa of inflammatory bowel disease (IBD) patients. Furthermore, we analysed IL‐37b expression in human colonic epithelial cells. The human colonic epithelial cell line T84 and human colonic subepithelial myofibroblasts (SEMFs) were used. IL‐37b expression in the IBD mucosa was evaluated by immunohistochemistry. IL‐37b mRNA and protein expression were determined by real time‐polymerase chain reaction (PCR) and Western blotting, respectively. IL‐37b was not detected in the normal colonic mucosa. In the inflamed mucosa of IBD patients, epithelial IL‐37b expression was increased markedly. In ulcerative colitis (UC) and Crohn's disease (CD) patients, IL‐37b expression was enhanced in the affected mucosa. In the intestinal epithelial cell line T84, the expression of IL‐37b mRNA and protein was enhanced by tumour necrosis factor (TNF)‐α. This IL‐37b induction by TNF‐α was mediated by nuclear factor (NF)‐κB and activator protein (AP)‐1 activation. Furthermore, IL‐37b inhibited TNF‐α‐induced interferon‐γ‐inducible protein (IP)‐10 expression significantly in human colonic SEMFs. Epithelial IL‐37b expression was increased in IBD patients, especially UC patients. IL‐37b may be involved in the pathophysiology of IBD as an anti‐inflammatory cytokine and an inhibitor of both innate and acquired immune responses.     

Pro‐ and anti‐inflammatory cytokine gene single‐nucleotide polymorphisms in inflammatory bowel disease

Anti‐inflammatory cytokines have an important role in disease, tumour and transplant processes. Alterations in the regulation of several cytokines have been implicated in a variety of inflammatory disorders, including IBD (inflammatory bowel disease) [Crohn′s disease (CD) and ulcerative colitis (UC)]. Cytokine polymorphisms are also known to affect the level of gene expression. Thus, the aim of this study was to determine the relationship between cytokine polymorphisms and the IBD pathologies in a Spanish population. Polymorphisms analysis was performed using PCR‐SSOP using a microbeads luminex assay. The following polymorphisms were determined: TNFα [?238G/A (rs361525) and ?308G/A (rs1800629)], IFNγ [+874A/T (rs62559044)], TGFβ [+869C/T (rs1982073) and +915G/C (rs1800471)], IL10 [?1082A/A (rs1800896), ?592A/C (rs1800872), ?819C/T (rs1800871)], IL6 [?174C/G (rs1800795)], IL12p40 [3′UTR ?1188A/C (rs3212227)], IL1α [?889C/T (rs1800587)], IL1β [?511C/T (rs1143634) and +3962C/T (rs1143633)], IL1R [Pst‐1 1970C/T] and IL1RA [Mspa‐1 11100C/T]. No statistical differences in TNFα, IFNγ, TGFβ, IL10, IL6, IL1α, IL1β, IL1R and IL1Ra genotypes and allele distributions between the IBD groups and healthy controls were found. However, we observed significant differences in the 3′UTR ?1188A/C polymorphism of IL12p40. So ?1188A allele was increased in patients with UC and the ?1188C allele (high IL12p40 production) was increased in patients with CD with respect to controls. These data are in concordance with the fact that CD has been shown to be associated with a Th1 T‐cell‐mediated inflammation model and high IL12/IFNγ production at histological affected sites. These data suggest that cytokine polymorphisms in TNFα, IFNγ, TGFβ, IL10, IL6 and IL1α, IL1β, IL1R and IL1Ra cytokine gene do not seem to be relevant in IBD susceptibility and IL12p40 3′UTR ?1188A/C polymorphism seems to be associated with a differential IBD development.