TLR ligands induce synergistic interferon-β and interferon-λ1 gene expression in human monocyte-derived dendritic cells

Toll-like receptors (TLRs) are pattern-recognition receptors of the innate immune system that recognize various pathogen-associated molecules. TLR ligands are potent activators of immune cells and certain TLR ligands have a synergistic ability to induce the production of pro-inflammatory cytokines. In the present study we have analyzed the potential synergy between TLR3, TLR4 and TLR7/8 ligands in type I and type III interferon (IFN) gene expression in human monocyte-derived dendritic cells (moDCs). We show that stimulation of moDCs with TLR7/8 ligand R848 together with TLR3 or TLR4 ligands, polyI:C or LPS, respectively, leads to a synergistic expression of IFN-β and IFN-λ1 mRNAs. Neutralization of type I IFNs as well as IFN priming prior to stimulation suggest that IFN-dependent positive feedback loop is at least partly responsible for the mechanism of synergy. Enhanced expression of TLR3 and especially TLR7, which are both under the regulation of type I IFNs, correlated to synergistic TLR ligand-dependent induction of IFN-β and IFN-λ1 genes. NF-κB, PI3 kinase and MAP kinase pathways were involved in TLR ligand-induced IFN gene expression as evidenced by pharmacological signaling inhibitors. The data indicates that IFNs contribute to TLR-dependent gene activation in human DCs stimulated with multiple TLR ligands.     

TLR‐Stimulated Eosinophils Mediate Recruitment and Activation of NK Cells In Vivo

Eosinophils like many myeloid innate immune cells can provide cytokines and chemokines for the activation of other immune cells upon TLR stimulation. When TLR‐stimulated eosinophils were inoculated i.p. into wild‐type mice, and NK cells were rapidly recruited and exhibited antitumour cytotoxicity. However, when mice depleted of CD11c⁺ cells were used, a marked decrease in the number of recruited NK cells was observed. We postulated that CpG or LPS from the injected eosinophils could be transferred to host cells, which in turn could recruit NK cells. However, by inoculating mice deficient in TLR4 or TLR9 with LPS or CpG‐stimulated eosinophils respectively, NK cell recruitment was still observed alongside cytotoxicity and IFNγ production. CpG stimulation of eosinophils produced the pro‐inflammatory cytokine IL‐12 and the chemokine CXCL10, which are important for NK cell activation and recruitment in vivo. To demonstrate the importance of CXCL10 in NK cell recruitment, we found that CpG‐stimulated eosinophils pretreated with the gut microbial metabolite butyrate had reduced expression and production of CXCL10 and IL‐12 and concomitantly were poor at recruitment of NK cells and inducing IFNγ in NK cells. Therefore, eosinophils like other innate immune cells of myeloid origin can conceivably stimulate NK cell activity. In addition, products of the gut microbiota can be potential inhibitors of NK cell.     

B‐cell‐activating factor expressions in salivary epithelial cells after dsRNA virus infection depends on RNA‐activated protein kinase activation

B‐cell‐activating factor (BAFF) plays a key role in promoting activation of autoimmune B cells. This cytokine may be expressed in and secreted by salivary gland epithelial cells (SGEC) after stimulation with type I IFN or viral or synthetic dsRNA. Because this BAFF expression depends only in part on endosomal TLR and type I IFN, we investigated whether other dsRNA sensors could be implicated in BAFF expression. Using human SGEC, we confirmed the partial dependence of BAFF expression on TLR‐3 by replicating the partial inhibition of BAFF expression observed upon endosomal inhibition using TLR‐3 or Toll/IL‐1R domain‐containing protein inducing IFN‐β silencing mRNA, but not with TLR‐7 silencing mRNA. Melanoma differentiation‐associated gene 5 silencing mRNA had no effect on BAFF expression, but retinoic acid‐inducible gene I silencing mRNA had a slight effect observed following infection with dsRNA reovirus‐1. Inhibition of RNA‐activated protein kinase (PKR) by 2‐aminopurine completely abolished both BAFF mRNA and protein production after reovirus‐1 infection and poly(I:C) stimulation through NF‐κB and p38 MAPK pathways, with the latter implicated only after poly(I:C) stimulation. Thus, PKR is the dsRNA sensor implicated in BAFF induction in SGEC after dsRNA stimulation. In autoimmune diseases, PKR may be an interesting target for preventing BAFF following the induction of innate immunity.     

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.     

Self‐priming determines high type I IFN production by plasmacytoid dendritic cells

Plasmacytoid dendritic cells (pDCs) are responsible for the robust and immediate production of type I IFNs during viral infection. pDCs employ TLR7 and TLR9 to detect RNA and CpG motifs present in microbial genomes. CpG‐A was the first synthetic stimulus available that induced large amounts of IFN‐α (type I IFN) in pDCs. CpG‐B, however, only weakly activates pDCs to produce IFN‐α. Here, we demonstrate that differences in the kinetics of TLR9 activation in human pDCs are essential for the understanding of the functional difference between CpG‐A and CpG‐B. While CpG‐B quickly induces IFN‐α production in pDCs, CpG‐A stimulation results in delayed yet maximal IFN‐α induction. Constitutive production of low levels of type I IFN in pDCs, acting in a paracrine and autocrine fashion, turned out to be the key mechanism responsible for this phenomenon. At high cell density, pDC‐derived, constitutive type I IFN production primes pDCs for maximal TLR responsiveness. This accounts for the high activity of higher structured TLR agonists that trigger type I IFN production in a delayed fashion. Altogether, these data demonstrate that high type I IFN production by pDCs cannot be simply ascribed to cell‐autonomous mechanisms, yet critically depends on the local immune context.     

IFN‐β therapy modulates B‐cell and monocyte crosstalk via TLR7 in multiple sclerosis patients

The implication of B lymphocytes in the immunopathology of multiple sclerosis (MS) is increasingly recognized. Here we investigated the response of B cells to IFN‐β, a first‐line therapy for relapsing‐remitting MS patients, upon stimulation with TLR. IFN‐β restored the frequency of TLR7‐induced IgM and IgG‐secreting cells in MS patients to the levels found in healthy donors, showing a specific deficiency in the TLR7 pathway. However, no difference was observed in the TLR9 response. Furthermore, in MS‐derived PBMCs, TLR7‐mediated production of IL‐6 and the ex vivo expression of B‐cell‐activating factor of the TNF family, two crucial cytokines for B‐cell differentiation and survival, were induced by IFN‐β. Depletion of monocytes, which are key producers of both IL‐6 and B‐cell‐activating factor of the TNF family, showed that TLR7‐mediated B‐cell differentiation into Ig‐secreting cells is strongly dependent on the cross‐talk between B cells and monocytes. Accordingly, impaired expression of TLR7 mRNA was observed in PBMCs and monocytes isolated from MS‐affected individuals as compared with those from healthy donors, which was rescued by IFN‐β therapy. Collectively, our data unveil a novel TLR7‐regulated mechanism in in vivo IFN‐β‐stimulated whole leukocytes that could be exploited to define new TLR7‐based strategies for the treatment of MS.     

Modulation of 2B4 (CD244) activity and regulated SAP expression in human NK cells

The adapter protein SAP is important for the signal transduction of the family of SLAM-related receptors (SRR), which have important immune-modulating functions. The importance of SAP and SRR for a functional immune reaction becomes obvious in patients suffering from X-linked lymphoproliferative disease, which is characterized by non-functional SAP. Here we investigate the regulation of SAP expression in human NK cells. We demonstrate that SAP mRNA expression and protein levels are low in freshly isolated resting NK cells. IL-2 stimulation leads to an up-regulation of SAP expression, which can be enhanced by IL-12, the stimulation of TLR3 by polyinosinic-polycytidylic acid (poly(I:C))and to a lesser extent by IFN-alpha. EAT-2, a SAP-related adapter protein, is already detectable in resting NK cells and does not change its expression after IL-2 stimulation. The regulation of SAP has functional consequences for the stimulation of NK cell cytotoxicity by 2B4. In resting NK cells, 2B4 stimulation can only enhance NK cell lysis when co-triggered with other activating NK cell receptors. In IL-2-activated NK cells with high SAP expression the triggering of 2B4 alone is sufficient to induce NK cell cytotoxicity, demonstrating a correlation between the regulated SAP expression and the function of 2B4.     

Cell-autonomous control of interferon type I expression by indoleamine 2,3-dioxygenase in regulatory CD19+ dendritic cells

Following CD80/86 (B7) and TLR9 ligation, small subsets of splenic dendritic cells expressing CD19 (CD19(+) DC) acquire potent T cell regulatory functions due to induced expression of the intracellular enzyme indoleamine 2,3-dioxygenase (IDO), which catabolizes tryptophan. In CD19(+) DC, IFN type I (IFN-alpha) is the obligate inducer of IDO. We now report that IFN-alpha production needed to stimulate high-level expression of IDO following B7 ligation is itself dependent on basal levels of IDO activity. Genetic and pharmacologic ablation of IDO completely abrogated IFN-alpha production by CD19(+) DC after B7 ligation. In contrast, IDO ablation did not block IFN-alpha production by CD19(+) DC after TLR9 ligation. IDO-mediated control of IFN-alpha production depended on tryptophan depletion as adding excess tryptophan also blocked IFN-alpha expression after B7 ligation. Consistent with this, DC from mice deficient in general control of non-derepressible-2 (GCN2)-kinase, a component of the cellular stress response to amino acid withdrawal, did not produce IFN-alpha following B7 ligation, but produced IFN-alpha after TLR9 ligation. Thus, B7 and TLR9 ligands stimulate IFN-alpha expression in CD19(+) DC via distinct signaling pathways. In the case of B7 ligation, IDO activates cell-autonomous signals essential for IFN-alpha production, most likely by activating the GCN2-kinase-dependent stress response.     

Synthetic double-stranded RNA oligonucleotides are immunostimulatory for chicken spleen cells

Toll-like receptors (TLRs) are an integral part of the innate immune system that recognize microbe-derived molecular patterns and initiate innate and adaptive defenses against invading pathogens. TLR3 and TLR7 are involved in sensing virus-associated single-stranded and double-stranded RNA (dsRNA) molecules in cellular endosomes to activate the type I interferon pathway in mammals. Although certain synthetic dsRNA molecules have been identified to show immunostimulation in mammalian cells, very little is known about the ability of these sequences to stimulate avian cells. The current study investigated immunostimulatory properties of four synthetic oligonucleotide sequences using chicken splenocytes. Expression of TLR3 and 7, type I interferons and several other cytokines as well as TLR signaling pathway-related genes at different time points post-stimulation was quantified by real-time PCR. A dose-dependent increase in expression of TLR3 was observed in splenocytes treated with poly-UGUGU (poly-UG) and β-galactosidase dsRNA molecules. TLR3 and TLR7 gene expression was significantly up-regulated upon stimulation with all four dsRNA molecules. Furthermore, in a time course study, a significant increase was noted in the expression of TLR3, TLR7, interferon (IFN)-α, IFN-β, interleukin (IL)-1β, IL-6 as well as 2′,5′-OAS in splenocytes treated with poly-UG. In conclusion, the present study demonstrated the immunostimulatory properties of dsRNA oligonucleotides, especially those that contain a poly-UG motif, in chickens.     

Hematopoietic and nonhematopoietic cells promote Type I interferon‐ and TLR7‐dependent monocytosis during low‐dose LCMV infection

Release of inflammatory monocytes from the bone marrow (BM) into the blood is an important physiological response to infection, but the mechanisms regulating this phenomenon during viral infection are not completely defined. Here, we show that low‐dose infection with lymphocytic choriomeningitis virus (LCMV) caused rapid, transient inflammatory monocytosis that required type I interferon (IFN) and Toll‐like receptor (TLR) 7 signaling. Type I IFN and TLR7 signals were critical for induction of IFN‐stimulated gene expression and CCR2 ligand upregulation in the BM microenvironment in response to LCMV infection. Experiments utilizing BM chimeric mice demonstrated that type I IFN and TLR7 signaling on either hematopoietic or nonhematopoietic cells was sufficient to initiate monocytosis in response to LCMV infection. BM plasmacytoid dendritic cells (pDCs) generated type I IFN directly ex vivo, suggesting that pDCs are a hematopoietic contributor of type I IFN in the BM early during LCMV infection. Overall, we describe novel roles for type I IFN and TLR7 signaling in nonhematopoietic cells and BM pDCs in directing IFN‐stimulated gene and CCR2 ligand expression in the BM to initiate an increase in blood inflammatory monocytes during viral infection.     

Interaction of Mycobacterium tuberculosis Cell Wall Components with the Human Natural Killer Cell Receptors NKp44 and Toll‐Like Receptor 2

We have previously demonstrated that a soluble form of the human NK cell natural cytotoxicity receptor NKp44, binds to the surface of Mycobacterium tuberculosis (MTB). Herein, we investigated the interaction of MTB cell wall components (CWC) with NKp44 or with Toll‐like receptor 2 (TLR2) and the role of NKp44 and TLR2 in the direct activation of NK cells upon stimulation with MTB CWC. By using several purified bacterial CWC in an ELISA, we demonstrated that NKp44 was able to bind to the MTB cell wall core mycolyl‐arabinogalactan‐peptidoglycan (mAGP) as well as to mycolic acids (MA) and arabinogalactan (AG), while soluble TLR2 bound to MTB peptidoglycan (PG), but not to MA or AG. The mAGP complex induced NK cell expression of CD25, CD69, NKp44 and IFN‐γ production at levels comparable to M. bovis Bacillus Calmette–Guérin‐stimulated (BCG) cells. While AG and MA used alone failed to induce NK cell activation, mycobacterial PG‐exhibited NK cell stimulatory capacity. Activation of resting NK cells by mAGP and IFN‐γ production were inhibited by anti‐TLR2 MAb, but not by anti‐NKp44 MAb. Differently, anti‐NKp44 MAb partially inhibited CD69 expression on NK cells pre‐activated with IL‐2 and then stimulated with mAGP or whole BCG. Overall, these results provide evidence that components abundant in mycobacterial cell wall are able to interact with NKp44 (AG, MA) and TLR‐2 (PG), respectively. While interaction of TLR2 with mycobacterial cell wall promotes activation of resting NK cells and IFN‐γ production, NKp44 interaction with its putative ligands could play a secondary role in maintaining cell activation.     

Molecular cloning and characterization of Toll-like receptor 3 in Japanese flounder, Paralichthys olivaceus

Mammalian Toll-like receptor 3 (TLR3) recognizes extracellular and intracellular viral dsRNA, and then initiates signaling cascades leading to NF-κB activation and interferon (IFN) production. To understand the roles of TLR3 in the fish immune system, TLR3 gene (JfTLR3) was identified from Japanese flounder (Paralichthys olivaceus), which consisted of 4 exons and 3 introns. Its expression in peripheral blood leukocytes increased upon stimulation with poly I:C and CpG ODN 1668. Exposure to viral hemorrhagic septicemia virus increased expression of JfTLR3 in the blood, liver, head kidney and spleen. Intracellular poly I:C stimulation in JfTLR3-overexpressing YO-K cells significantly induced IFN-inducible and NF-κB-regulated genes. NF-κB activity in JfTLR3-overexpressing YO-K cells was significantly induced by intracellular poly I:C while expression of IFN-inducible genes and NF-κB reporter activity in JfTLR3-overexpressing HINAE cells increased upon stimulation by extracellular poly I:C. These results suggest that JfTLR3 plays an important role in the induction of antiviral immune response.     

TLR‐mediated STAT3 and ERK activation controls IL‐10 secretion by human B cells

IL‐10‐producing B cells have a regulatory effect in various mouse models for immune‐mediated disorders via secretion of IL‐10, a potent immunoregulatory cytokine. However, currently, the signaling pathways that regulate IL‐10 production in B cells are not well understood. Here, we show that TLR signaling, but not BCR activation or CD40 ligation, induces potent production of IL‐10 in human B cells. We demonstrate that the activation of STAT3 and ERK is required for TLR‐induced IL‐10 production by B cells, since inhibition of STAT3 or ERK activation abrogates TLR‐induced IL‐10 production. We also uncover a novel function of the TLR‐MyD88‐STAT3 pathway in B cells, namely controlling IL‐10 production, in addition to the known role for this pathway in antibody production. Furthermore, IFN‐α, a member of the type I IFN family, differentially modulates TLR7/8‐ and TLR9‐activated STAT3 and ERK in B cells, which provides an explanation for our findings that IFN‐α enhances TLR7/8‐induced, but not TLR9‐induced IL‐10 production. These results yield insights into the mechanisms by which TLR signaling regulates IL‐10 production in B cells and how type I IFN modulates TLR‐mediated IL‐10 production by B cells, therefore providing potential targets to modulate the function of IL‐10‐producing B cells.     

Expression of type III interferons (IFNλs) and their receptor in Sjögren's syndrome

Type III interferons (IFNs) or IFN‐λs (IFN‐λ1/IL29, IFN‐λ2/interleukin (IL)?28A and IFN‐λ3/IL‐28B) consist of a recently identified group of IFNs, implicated initially in several human diseases, including cancer and autoimmunity. In this study, we sought to investigate the expression of type III IFNs and their common receptor IFN‐λR1/IL‐28Ra in Sjögren's syndrome (SS). Type III IFN expression was examined in minor salivary gland tissues (MSG), peripheral blood mononuclear cells (PBMCs), sera and resting or Toll‐like receptor (TLR)‐stimulated salivary gland epithelial cells (SGEC) from SS patients and sicca‐complaining controls. All type III IFN family members were detected in ductal and acinar epithelia of MSGs from both SS patients and sicca controls. IFN‐λ2/IL‐28A and IFN‐λ3/IL‐28B were also expressed in infiltrating mononuclear cells. In SS patients with intermediate MSG lesions, the epithelial expression of IFN‐λ2/IL‐28A was more intense compared to sicca controls (P < 0·05). The receptor IFN‐λR1/IL‐28Ra was detected in all types of cells except fibroblasts, and was exceptionally strong in plasmatocytoid dendritic cells, indicating that they are susceptible to type III IFN‐mediated regulation. In the periphery, only IFN‐λ1/IL‐29 was detected in the sera and was elevated significantly in SS patients with intermediate MSG inflammatory lesions compared to sicca controls (P = 0·0053). None of the type III IFNs was expressed constitutively in resting SGECs; they were all induced readily by TLR‐3 stimulation, suggesting that the in‐situ epithelial expression can be attributed to local microenvironment. Type III IFNs are expressed in MSGs in a similar pattern to type I IFNs and their expression is probably subjected to micro‐environmental regulation, suggesting that they are implicated in the inflammatory processes occurring in the affected exocrine glands.