Abstract
The non-pathogenic TH17 subset of helper T cells clears fungal infections, whereas pathogenic TH17 cells cause inflammation and tissue damage; however, the mechanisms controlling these distinct responses remain unclear. Here we found that fungi sensing by the C-type lectin dectin-1 in human dendritic cells (DCs) directed the polarization of non-pathogenic TH17 cells. Dectin-1 signaling triggered transient and intermediate expression of interferon (IFN)-β in DCs, which was mediated by the opposed activities of transcription factors IRF1 and IRF5. IFN-β-induced signaling led to integrin αvβ8 expression directly and to the release of the active form of the cytokine transforming growth factor (TGF)-β indirectly. Uncontrolled IFN-β responses as a result of IRF1 deficiency induced high expression of the IFN-stimulated gene BST2 in DCs and restrained TGF-β activation. Active TGF-β was required for polarization of non-pathogenic TH17 cells, whereas pathogenic TH17 cells developed in the absence of active TGF-β. Thus, dectin-1-mediated modulation of type I IFN responses allowed TGF-β activation and non-pathogenic TH17 cell development during fungal infections in humans.
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Main
DCs orchestrate differentiation of helper T (TH) cells for host immunity and tolerance1. Pathogen-recognition receptors (PRRs) expressed by DCs sense invading pathogens and induce cytokine profiles that direct the development of appropriate TH cell subsets2. The C-type lectin receptor (CLR) dectin-1 recognizes the fungal cell wall polysaccharide β-glucan3,4 and triggers signaling through both Syk-CARD9 and LSP1-Raf-1 to induce interleukin (IL)-12 to instruct TH1 differentiation and IL-1β, IL-23 and IL-6 to induce TH17 differentiation5,6,7. IL-17A and IL-17F production by TH17 cells is crucial for clearing fungal infections through the recruitment of neutrophils and the generation of antimicrobial peptides by epithelial cells8. Patients with dectin-1 or CARD9 deficiencies have recurrent and often severe fungal infections due to impaired TH17 responses9,10, underscoring the importance of dectin-1 signaling for antifungal immunity.
In addition to their key role in host defense and mucosal tissue homeostasis, TH17 cells are also the driving force behind several inflammatory and autoimmune disorders. Cellular heterogeneity underlies these differences as TH17 cells adopt different functional phenotypes depending on environmental cues and genetic factors11,12. TH17 cells coexpressing anti-inflammatory IL-10 are considered non-pathogenic, restrain pro-inflammatory responses and limit host tissue damage11,13, whereas TH17 cells expressing IFN-γ and its transcriptional regulator T-bet are commonly linked with inflammatory immunopathogenesis in for example Crohn’s disease, diabetes and multiple sclerosis14,15,16. Adoptive transfer of in vitro polarized T cells in mice revealed that IL-6 and TGF-β1 induces non-pathogenic TH17 cells, whereas IL-6/IL-1β/IL-23 or IL-6/TGF-β3 induces pathogenic TH17 responses17,18,19. The polarization requirements for human pathogenic TH17 cells remain poorly defined. Furthermore, it is unclear whether or how PRRs expressed by DCs instruct TH17 immune responses toward a specific phenotype.
DCs produce type I IFNs to different classes of pathogens. While type I IFN responses are essential in antiviral immunity through the induction of antiviral effector molecules encoded by IFN-stimulated genes (ISGs)20, their role in fungal infections is still unknown. Candida albicans stimulation of human peripheral blood mononuclear cells leads to type I IFN responses21. In mice, dectin-1, and to a lesser extent dectin-2, contribute to type I IFN expression by DCs during C. albicans infection, which results in recruitment of inflammatory cells but also causes hyper-inflammation and lethal kidney pathology22,23.
Here, we demonstrated that recognition of curdlan and C. albicans by human dectin-1 initiated mostly non-pathogenic TH17 responses. Dectin-1 triggering led to transient and intermediate expression of IFN-β by balancing the activities of the transcription factors IRF1 and IRF5. Type I IFN signaling induced the expression of integrin αvβ8, which allowed the MMP14-mediated cleavage of the latent TGF-β complex to release active TGF-β, which in turn resulted in the development of primarily non-pathogenic TH17 cells. Our data underscore the importance of a tightly controlled type I IFN response, as high amounts of IFN-β inhibited MMP14 through the ISG BST2 and increased pathogenic TH17 polarization. Thus, dectin-1 regulated type I IFN expression to allow the TGF-β-mediated development of non-pathogenic TH17 responses during fungal infections in humans.
Results
Dectin-1 induces transient intermediate IFN-β expression
In vitro stimulation of human monocyte-derived DCs (hereafter referred to as DCs) with the dectin-1-specific β-glucan ligand curdlan induced the transient expression of IFNB messenger RNA (mRNA) that peaked at 2 h post-stimulation (Fig. 1a). For comparison, the Toll-like receptor (TLR) 4 ligand lipopolysaccharide (LPS) induced a higher peak of IFNB mRNA at 2 h, followed by a secondary peak at 6 h post-stimulation, whereas RIG-I-like receptor ligand poly(I:C)-LyoVec induced higher expression of IFNB mRNA that plateaued 4 h post-stimulation (Fig. 1a). Various commensal and pathogenic yeast and filamentous fungal species, such as C. albicans, C. dubliniensis, C. lusitaniae and Aspergillus fumigatus induced transient IFNB transcription (Fig. 1b). Both curdlan- and fungi-induced, but not LPS-induced, IFNB responses were inhibited by blocking antibodies to dectin-1, but not isotype control antibodies, and were absent in DCs derived from donors without functional dectin-1 expression due to the Y238X mutation (Fig. 1c). Dectin-1 triggers signaling through Syk-CARD9-Bcl10-Malt1 and LSP1-Raf-1 (ref. 2). Silencing of either Syk, CARD9, Bcl10 or Malt1 expression in DCs by transduction of specific short interfering RNAs (siRNAs) (Extended Data Fig. 1) blocked curdlan-induced IFNB expression, whereas silencing of LSP1 or Raf-1 had no effect (Fig. 1d). Curdlan and C. albicans strain CBS2712 (hereafter referred to as C. albicans) also induced mRNA expression for the ISGs MX1, ISG15, TRIM22, IRF7 and IL27A (encoding IL-27 subunit p28)20,24 (Fig. 1e), which was completely abrogated by blocking antibodies to dectin-1 or IFN-α/βR, but not isotype control antibodies (Fig. 1f). Thus, fungal ligands trigger transient and intermediate type I IFN responses through dectin-1 in human DCs.
Dectin-1 induces non-pathogenic TH17 cells through IFN-β
To investigate the role of type I IFN responses in dectin-1-induced TH17 differentiation, we co-cultured DCs that were primed for 48 h with curdlan or C. albicans with naive CD45RA+CD4+ T cells and determined the proliferation and intracellular expression of IL-17 and IFN-γ of the cultured T cells. Curdlan- and C. albicans-primed, but not immature DCs, induced strong T cell proliferation as measured by cell count and tracking cell division by carboxyfluorescein succinimidyl ester staining (Extended Data Fig. 2). At day 5, curdlan- and C. albicans-primed DCs mainly induced IFN-γ−IL-17+ T cells (81 ± 6.1% and 80 ± 5.5% of IL-17+ cells, respectively) (Fig. 2a–d and Extended Data Fig. 3). Development of IL-17+ cells directed by curdlan- or C. albicans-primed DCs (6.3 ± 1.1% and 6.7 ± 1.0% of total cells, respectively) was partly blocked by neutralizing antibodies against IL-1β (3.4 ± 0.9% and 3.5 ± 0.7%) or IL-23 (2.9 ± 1.0% and 3.0 ± 1.1%), but not IL-12 (6.9 ± 0.8% and 6.7 ± 0.9%) (Extended Data Fig. 4). T cell proliferation (Extended Data Fig. 2) or the overall differentiation of IL-17+ cells induced by curdlan- and C. albicans-primed DCs (11 ± 4.0% and 9.6 ± 3.5% of total cells, respectively) was not affected by blocking IFN-α/βR antibodies (11 ± 3.4% and 11 ± 2.9%) (Fig. 2a,c). In contrast, the addition of recombinant human (rh)IFN-β decreased the overall differentiation of TH17 cells induced by curdlan- and C. albicans-primed DCs (2.5 ± 0.9% and 2.8 ± 1.1% of total cells, respectively) (Fig. 2b,c), while not affecting their proliferation (Extended Data Fig. 2), suggesting that type I IFN was not required for the production of IL-17 in CD4+ T cells, whereas high amounts of IFN-β blocked it, with dectin-1-induced IFN-β expression too low to affect TH17 cell development. Notably, the frequency of IFN-γ+IL-17+ T cells induced by curdlan- and C. albicans-primed DCs (19 ± 6.1% and 21 ± 5.5% of IL-17+ cells, respectively) was increased by blocking IFN-α/βR antibodies (65 ± 5.5% and 67 ± 4.0%) (Fig. 2a,d). Supplementary rhIFN-β, while suppressing overall TH17 differentiation, also increased the frequency of IFN-γ+IL-17+ T cells induced by curdlan- and C. albicans-primed DCs (61 ± 14% and 56 ± 6.4% of IL-17+ cells, respectively) (Fig. 2b,d).
We next co-cultured curdlan- or C. albicans-primed DCs with memory CD45RO+CD4+ T cells together with Staphylococcus aureus enterotoxin B (SEB), which induces antigen-independent T cell activation, to examine how dectin-1-induced cytokines affect the phenotype of differentiated TH cells. Immature as well as curdlan- and C. albicans-primed DCs induced strong T cell proliferation (Extended Data Fig. 2). At day 5, we detected IL-17+ cell differentiation in response to curdlan- and C. albicans-primed DCs (3.6 ± 0.9% and 3.1 ± 0.6% of total cells, respectively), but not immature DCs, whereas at day 11–14, when T cells were quiescent, IL-17+ cells represented 6.2 ± 2.9% and 5.9 ± 3.2% of total cells (Extended Data Figs. 3 and 4). Induction of IL-17+ cells at day 11–14 by curdlan- and C. albicans-primed DCs was blocked by IL-1β (1.4 ± 0.5% and 1.6 ± 0.8% of total cells, respectively) and IL-23 (1.5 ± 0.7% and 1.5 ± 0.8%), but not IL-12 (6.9 ± 1.8% and 6.9 ± 2.2%) neutralizing antibodies (Extended Data Fig. 4), explaining the lack of TH17 induction by immature DCs, despite SEB-mediated T cell activation. Overall differentiation of IL-17+ cells induced by curdlan- and C. albicans-primed DCs (12 ± 4.5% and 11.9 ± 4.2% of total cells, respectively) was reduced by supplementary rhIFN-β (5.1 ± 2.4% and 4.2 ± 1.6%), whereas blocking IFN-α/βR antibodies had no effect (14 ± 6.2% and 13 ± 5.6%) (Fig. 2e–h); however, the frequency of IFN-γ+IL-17+ T cells induced by curdlan- and C. albicans-primed DCs (17 ± 4.2% and 20 ± 10.4% of IL-17+ cells, respectively) significantly increased by the addition of blocking IFN-α/βR antibodies (43 ± 4.1% and 45 ± 4.8%) or supplementary rhIFN-β (41 ± 5.0% and 41 ± 4.8%) (Fig. 2e–h), suggesting that type I IFN strongly influenced the phenotype of differentiated TH17 cells.
Next, we compiled a panel of molecular markers to discriminate between TH17 cell subtypes through real-time qPCR analyses, including transcription factors c-Maf (encoded by MAF), which regulates the expression of anti-inflammatory cytokine IL-10 and effector molecule prostaglandin D synthase (encoded by PTGDS)13,25, and T-bet (encoded by TBX21); IL-1R; inflammatory cytokines IFN-γ, IL-22 and GM-CSF (encoded by CSF2); and the effector molecules CXCL3, CCL3 and CCL5, which are expressed by mouse pathogenic TH17 cells13,17,26,27,28. The expression of these molecular markers was analyzed in peripheral blood IL-17+CD4+ T cells isolated from healthy individuals, to provide a reference point for non-pathogenic TH17 cells, and patients with acute untreated Crohn’s disease (CD), in whom pathogenic TH17 cells are the main mediators of gastrointestinal tract inflammation29. Expression of TBX21, IFNG, IL1R1 and CXCL3 expression was high in IL-17+CD4+ T cells from patients with acute untreated CD and low to moderate in IL-17+CD4+ T cells from healthy individuals (Fig. 2i and Extended Data Fig. 5). Expression of CSF2, IL22 and CCL3 was consistently higher for CD patients, whereas expression of CCL5 was similar in IL-17+CD4+ T cells compared to healthy controls (Fig. 2i and Extended Data Fig. 5). Expression of IL10, MAF and PTGDS was high in IL-17+CD4+ T cells from healthy donors and minimal or absent in patients with CD (Fig. 2i,j and Extended Data Fig. 5). Of note, expression of TBX21, IFNG, IL1R1 and CXCL3 was much less pronounced, whereas expression of IL10, MAF and PTGDS was clearly detected in IL-17+CD4+ T cells from treated patients with CD (Extended Data Fig. 5). Expression of IL17A, IL17F and RORC (which encodes the transcription factor RORγt) was similar in IL-17+CD4+ T cells from healthy and all CD donors (Fig. 2i,j and Extended Data Fig. 5). These data suggested that expression of IFNG, TBX21, IL1R1 and CXCL3 defined a pathogenic signature, while expression of IL10, MAF and PTGDS defined non-pathogenic human TH17 cells. IFN-γ+IL-17+ T cells purified from in vitro co-cultures of curdlan- or C. albicans-primed DCs with either naive CD45RA+CD4+ or memory CD45RO+CD4+ T cells (Extended Data Fig. 3) showed high expression of the pathogenic signature genes IFNG, TBX21, IL1R1 and CXCL3, which were almost completely absent in IFN-γ−IL-17+ T cells purified from the same co-cultures (Fig. 2j and Extended Data Fig. 5). In contrast, IL10, MAF and PTGDS were highly expressed in IFN-γ−IL-17+ T cells and almost absent in IFN-γ+IL-17+ T cells (Fig. 2j and Extended Data Fig. 5). CSF2, IL22 and CCL3 were detected in both subtypes, but significantly higher in IFN-γ+IL-17+ T cells (Fig. 2j and Extended Data Fig. 5). The signatures were similar across both naive and memory T cells co-cultures (Fig. 2j and Extended Data Fig. 5).
Curdlan- and C. albicans-primed DCs induced IL-17+ T cells with a predominantly non-pathogenic signature characterized by high IL10, MAF and PTGDS expression and low, but not absent, expression of IFNG, TBX21, IL1R1 and CXCL3 mRNA (Fig. 2k and Extended Data Fig. 6) and protein (Extended Data Fig. 7). Addition of blocking IFN-α/βR antibodies or rhIFN-β to curdlan- or C. albicans-primed DCs induced IL-17+ T cells with mixed molecular signatures (Fig. 2k and Extended Data Fig. 6). Thus, both loss of or high IFN-β promoted the polarization of naive and memory T cells into IFN-γ+IL-17+ T cells by dectin-1-stimulated DCs.
Dectin-1 controls IFNB transcription through IRF1 and IRF5
IFNB transcription is mainly regulated through different transcription factors from the IRF family that bind the IFN-stimulated response element (ISRE) within its promoter30. IRF5 is involved in dectin-1-mediated IFN-β expression22, while dectin-1 is known to activate IRF131. Curdlan and C. albicans stimulation of DCs led to the nuclear translocation of IRF1 and IRF5 but not IRF3 at 2 h post-stimulation (Fig. 3a–c). IRF1, but not IRF5, was detected in the nucleus at 6 h post-stimulation (Fig. 3a–c). IRF7 expression was induced by curdlan or C. albicans stimulation and also detected in the nucleus at 6 h post-stimulation (Fig. 3a–c). Blocking antibodies to dectin-1 abrogated IRF1 and IRF5 nuclear translocation (Fig. 3d). Chromatin immunoprecipitation (ChIP) indicated that IRF1 and IRF5 were bound to the IFNB ISRE within 2 h after curdlan stimulation, whereas only IRF1 was detected 6 h post-stimulation (Fig. 3e). IRF7 did not bind IFNB ISRE, despite being present in the nucleus at 6 h post-stimulation (Fig. 3e). IRF5 silencing in DCs completely abrogated curdlan- or C. albicans-induced expression of IFNB mRNA and protein (Fig. 3f,g) as well as the transcription of ISGs MXA and TRIM22 (Fig. 3h), indicating that IRF5 was critically required for dectin-1-mediated induction of IFNB. In contrast, IRF1 silencing enhanced both IFNB mRNA and protein and ISG mRNA after curdlan or C. albicans stimulation (Fig. 3f–h), suggesting that IRF1 has a negative regulatory role in dectin-1-mediated IFNB transcription. IRF1 silencing furthermore resulted in a secondary IFNB mRNA peak (Fig. 3f). ChIP analyses in IRF1-silenced DCs indicated that the IFNB ISRE was exclusively bound by IRF5 at 2 h post-stimulation, whereas IRF7 bound the IFNB ISRE at 6 h post-stimulation (Fig. 3i), at the time of the secondary IFNB transcription peak (Fig. 3f). These data indicated that IRF1 acted as a negative regulator of dectin-1-induced IFNB transcription by blocking optimal binding of IRF5 and IRF7 to the IFNB promoter.
IFN-β directs the polarization of non-pathogenic TH17 cells through TGF-β
We next focused on how dectin-1-induced IFN-β modulated the polarization of TH17 cells. Blocking IFN-α/βR antibodies did not significantly affect the secretion of IL-1β, IL-23, IL-6 and IL-12 by curdlan- or C. albicans-stimulated DCs (Fig. 4a), but blocked IL-27 secretion, while supplementary rhIFN-β increased IL-27 expression (Fig. 4b). IL-27 is a known negative regulator of TH17 differentiation32; however, neutralizing IL-27 antibodies did not affect the numbers or phenotype of TH17 cells induced by curdlan- or C. albicans-primed DCs (Fig. 4c–e), suggesting that dectin-1-induced IL-27 secretion by DCs was too low to affect IL-17 production. The development of IL-17+ cells induced by curdlan- and C. albicans-primed DCs (8.7 ± 1.8% and 8.2 ± 1.0% of total cells, respectively) was reduced by supplementary rhIL-27 (4.6 ± 1.3% and 5.2 ± 0.8%), but did not affect the phenotype of the induced TH17 cells (Fig. 4c–e and Extended Data Fig. 6), suggesting that dectin-1-induced IL-27 did not affect TH17 cell development.
The role of TGF-β in TH17 development continues to be a topic of debate33. TGF-β activation requires disengagement of its active form from the large latent complex (LLC) that is sequestered within the extracellular matrix after secretion. Curdlan or C. albicans stimulation of DCs did not affect the total amount of TGF-β, but resulted in release of active TGF-β, which was inhibited by blocking antibodies against dectin-1 (Fig. 5a,b). Blocking IFN-α/βR antibodies completely abrogated TGF-β activation by curdlan- or C. albicans-stimulated DCs (Fig. 5b). Supplementary rhIFN-β blocked TGF-β activation by curdlan- or C. albicans-stimulated DCs in a concentration-dependent manner (Fig. 5c). Furthermore, enhancing or blocking the expression of IFN-β by silencing of IRF1 or IRF5 in DCs, respectively, completely blocked TGF-β activation by curdlan- or C. albicans-stimulated DCs (Fig. 5d). Thus, tightly regulated and intermediate IFN-β responses were required for the release of active TGF-β by DCs.
We next investigated the effect of TGF-β on TH17 cell polarization. Overall differentiation of IL-17+ cells induced by curdlan- and C. albicans-primed DCs (13 ± 4.3% and 14 ± 3.5% of total cells, respectively) was not affected by the addition of blocking TGF-βR antibodies during co-culture with memory CD45RO+CD4+ T cells (18 ± 4.2% and 18 ± 2.6%); however, the frequency of IFN-γ+IL-17+ T cells (18 ± 3.7% and 22 ± 12% of IL-17+ cells, respectively) strongly increased by blocking TGF-βR antibodies (43 ± 3.0% and 44 ± 3.1%) (Fig. 5e–h and Extended Data Fig. 6). Supplementary rhTGF-β1 did not affect the number (13 ± 1.8% and 14 ± 3.8% of total cells, respectively) or phenotype (18 ± 4.2% and 18 ± 2.6% IFN-γ+ cells of IL-17+ cells) of TH17 cells induced by curdlan- or C. albicans-primed DCs, but reduced the increased development of IFN-γ+IL-17+ T cells after blocking IFN-α/βR signaling (43 ± 4.1% and 45 ± 4.8% of IL-17+ cells) to the frequencies observed with untreated curdlan- or C. albicans-primed DCs (20 ± 3.0% and 16 ± 1.4% IFN-γ+ cells of IL-17+ cells) (Fig. 5e–h and Extended Data Fig. 6). Similarly, the frequency of IFN-γ+IL-17+ T cells induced by curdlan- and C. albicans-primed DCs during co-culture with naive CD45RA+CD4+ T cells (18 ± 6.5% and 18 ± 2.2% of IL-17+ cells, respectively) increased in the presence of blocking TGF-βR antibodies (63 ± 1.4% and 68 ± 5.1%), whereas supplementary rhTGF-β1 reduced the increase in frequency of IFN-γ+IL-17+ T cells after blocking IFN-α/βR signaling (65 ± 5.5% and 67 ± 4.0%) to the frequencies observed with untreated curdlan- or C. albicans-primed DCs (14 ± 7.4% and 15 ± 7.7% IFN-γ+ cells of IL-17+ cells) (Extended Data Fig. 8). Notably, predominantly IFN-γ+IL-17+ T cells (77 ± 4.4% and 73 ± 11% of IL-17+ cells, respectively) developed when naive CD45RA+CD4+ T cells were co-cultured with DCs that were primed with curdlan or C. albicans for only 3 h, a time point where we could not yet detect release of active TGF-β (Fig. 5b), whereas mainly IFN-γ−IL-17+ T cells (81 ± 3.3% and 78 ± 3.5% of IL-17+ cells, respectively) developed when rhTGF-β1 was added to these co-cultures (Extended Data Fig. 8). These data suggested that TGF-β activation limited the development of pathogenic TH17 cells downstream of dectin-1-induced IFN-α/βR signaling in DCs.
IFN-β-induced αvβ8 expression is critical for TGF-β activation
Release of active TGF-β from the LLC requires conformational changes in LAP, a component of the LLC, through either traction force or proteolysis, which is applied when LAP is bound by αv-containing integrins34. Blocking antibodies to the DC-expressed heterodimeric integrins αvβ1, αvβ3, αvβ5, αvβ6 and αvβ8 showed that only blocking of αvβ8 interfered with release of active TGF-β by curdlan- or C. albicans-stimulated DCs (Fig. 6a), whereas silencing of αv or β8 expression in DCs completely blocked curdlan- or C. albicans-stimulated TGF-β activation (Fig. 6b). Immature DCs constitutively expressed αv but not β8 integrin (Fig. 6c,d). ITGB8 transcription was induced in DCs within 5 h post-stimulation with curdlan or C. albicans (Fig. 6e), whereas β8 protein was detected after 8 h, reached maximum expression after 16 h and was still expressed at 24 h post-stimulation (Fig. 6d). Blocking antibodies to dectin-1 and IFN-α/βR completely inhibited ITGB8 mRNA (Fig. 6f) and protein expression (Fig. 6g). Similarly, inhibition of IFN-β expression through silencing of IRF5 abrogated the induction of β8 (Fig. 6f,h), whereas increasing IFN-β expression through IRF1 silencing significantly boosted ITGB8 transcription (Fig. 6f) and quickened and increased β8 expression (Fig. 6h). The addition of blocking antibodies against αvβ8 during co-culture with memory CD45RO+CD4+ T cells resulted in the development of both IL-10+IL-17+ and IFN-γ+IL-17+ T cells by curdlan- and C. albicans-primed DCs, while supplementary rhTGF-β1 restored the differentiation into predominantly IL-10+IL-17+ T cells (Fig. 6i and Extended Data Fig. 6). Thus, ITGB8 was an ISG induced by dectin-1 signaling and the expression of αvβ8 was required for non-pathogenic TH17 differentiation through the release of active TGF-β by DCs.
IFN-β-induced BST2 obstructs TGF-β activation through MMP14
Cleavage of LAP after its capture by αvβ8 is dependent on the proteolytic activity of the membrane-anchored metalloproteinase MMP14, which colocalizes with LAP-bound αvβ8 (refs. 35,36). Inhibition of MMP14 activity with the specific inhibitor NSC405020 abrogated the release of active TGF-β by curdlan- or C. albicans-stimulated DCs (Fig. 7a). Immature DCs showed constitutive MMP14 activity as measured by the cleavage of a fluorescent substrate, which decreased after stimulation with curdlan or C. albicans and was abrogated by MMP14 inhibition (Fig. 7b). Blocking antibodies against IFN-α/βR increased MMP14 activity in curdlan- or C. albicans-stimulated, but not immature DCs (Fig. 7c), whereas supplementary rhIFN-β blocked MMP14 activity in a concentration-dependent manner (Fig. 7d). Blocking or increasing expression of IFN-β through silencing of IRF5 or IRF1 in DCs, respectively, slightly enhanced or significantly blocked MMP14 activity in curdlan- or C. albicans-stimulated DCs (Fig. 7e). These results indicated that excess type I IFN responses negatively impacted MMP14 activity and thereby TGF-β activation.
The ISG BST2 (ref. 20) is a transmembrane protein that negatively modulates MMP14 activity through interactions between their cytoplasmic domains37. BST2 mRNA and protein expression were induced 4 h and 8 h post-stimulation, respectively, in curdlan- or C. albicans-stimulated DCs and these were completely abrogated by blocking antibodies to dectin-1 or IFN-α/βR or through IRF5 silencing (Fig. 8a–e). In contrast, IRF1 silencing in DCs increased BST2 transcription and expression of BST2 protein up to 24 h post-stimulation (Fig. 8b,e). Curdlan- or C. albicans-induced MMP14 activity increased slightly after silencing of BST2 in DCs (Fig. 8f), without significantly affecting TGF-β activation (Fig. 8g). Notably, silencing the expression of BST2 in IRF1-silenced DCs restored baseline MMP14 activity (Fig. 8f), whereas active TGF-β release was not only restored, as compared to IRF1-silenced DCs, but increased compared to control-silenced DCs after curdlan or C. albicans stimulation (Fig. 8g). BST2 silencing did not affect IFNB expression after stimulation (Extended Data Fig. 9). These results indicated that only high amounts of BST2 inhibited MMP14 activity and TGF-β activation.
To examine how high amounts of BST2 expression affect the differentiation of TH17 cells by primed DCs, we transiently transfected DCs with a plasmid that encodes both eGFP and BST2 and separated them based on their eGFP expression; eGFP−DCs only expressed BST2 after curdlan or C. albicans stimulation, whereas eGFP+ DCs contained high amounts of BST2 without stimulation (Fig. 8h). IFNB expression after curdlan or C. albicans stimulation in either eGFP− or eGFP+ DCs was unaffected (Extended Data Fig. 9). MMP14 activity was almost completely inhibited in unstimulated eGFP+ but not eGFP− DCs (Fig. 8i), whereas TGF-β activation was almost absent after curdlan or C. albicans stimulation by eGFP+ but not eGFP− DCs (Fig. 8j). Curdlan-primed eGFP+ DCs induced both IL-10+IL-17+ T cells and IFN-γ+IL-17+ T cells, whereas curdlan-primed eGFP− cells instructed predominantly IL-10+IL-17+ T cells (Fig. 8k and Extended Data Fig. 6). The addition of rhTGF-β1 to curdlan-primed eGFP+ cells in co-culture with memory T cells resulted in the induction of predominantly IL-10+IL-17+ T cells (Fig. 8k). These results indicated that high amounts of BST2 blocked MMP14-mediated release of active TGF-β and the polarization of non-pathogenic TH17 cells after dectin-1 stimulation.
Thus, dectin-1 regulated type I IFN expression to allow the TGF-β-mediated development of non-pathogenic TH17 responses during fungal infections in humans (Extended Data Fig. 10).
Discussion
Here, we demonstrated that dectin-1 signaling in human DCs specifically instructed the differentiation of non-pathogenic IFN-γ− TH17 cells. Strict regulation of type I IFN responses downstream of dectin-1 during fungal infections was required for the development of non-pathogenic IFN-γ− TH17 cells by controlling the release of active TGF-β by DCs.
Dectin-1 signaling in human DCs induced the release of cytokines such as IL-12, IL-1β, IL-23 and IL-6, but also active TGF-β. This combination of cytokines predominantly instructed the development of TH17 cells with high expression of IL10, MAF and PTGDS and low expression of IFNG, TBX21, IL1R1 and CXCL3, which define a non-pathogenic molecular signature for human TH17 cells13,17,18,19,25,26,27,28. Active TGF-β was critical for non-pathogenic TH17 cell differentiation, likely by blocking the expression of T-bet expression and transcription of IFNG, while also stimulating the expression of c-Maf and IL10 transcription38,39. While signaling through IL-27R in T cells induces IL-10 production by T cells40, excess IL-27 along with high amounts of type I IFN, did not induce the differentiation of non-pathogenic TH17 cells, probably because IFN-γ expression in T cells counteracted the effects of IL-27R signaling41. Our study corroborates previous reports that circulating C. albicans-specific TH17 cells in the blood of healthy people do not co-produce IFN-γ42. In contrast, in vitro differentiated C. albicans-specific T cells were reported to co-produce IL-17 and IFN-γ43. This apparent discrepancy was in fact due to the absence of active TGF-β at 3 h post-stimulation when antigen-presenting cells were co-cultured with T cells.
Type I IFN responses induced by dectin-1 stimulation were indispensable for TGF-β activation, but also required strict regulation, as higher amounts of IFN-β obstructed the release of active TGF-β. Dectin-1-induced, IFN-α/βR-dependent expression of αvβ8 allowed processing of the latent TGF-β complex by MMP14, thereby creating an environment that favored non-pathogenic TH17 cell differentiation. In line with these observations, mice with specific deletion of αvβ8 in DCs but not T cells suffer from inflammatory bowel disease and autoimmunity44 diseases that are now largely linked to pathogenic TH17 cells11,12. Dectin-1-induced expression of IFN-β also led to expression of BST2. While BST2 expression induced by dectin-1 stimulation was too low to affect TGF-β activation, increased expression of BST2 on activated DCs impaired the activity of MMP14 and hence TGF-β activation, leading to pathogenic TH17 cell polarization. MMP14 requires dynamic homodimerization for its proteolytic activity45 and as such MMP14 repression might only occur after BST2 associates with both cytoplasmic domains of MMP14; such a titration effect might explain why high but not normal amounts of BST2 inhibit MMP14-mediated release of active TGF-β. Our data suggest that targeting the intracellular domain of BST2 in IFN-mediated inflammatory and autoimmune disorders might attenuate disease by redirecting TH17 cell responses toward a non-pathogenic phenotype.
The balanced expression of IFN-β that was key to non-pathogenic TH17 cell polarization after dectin-1 stimulation requires highly precise regulation of the IFNB promoter30. Opposite actions of IRF5 and IRF1 on the IFNB ISRE ensured a pattern of transient and intermediate IFN-β expression, in which only IRF5 drove transcription. IRF1 is mostly known as a transcriptional activator of IFNB and other promoters46. It remains to be determined how dectin-1 signaling renders IRF1 transcriptionally inept and this could be used for therapeutic intervention in autoimmune diseases that are characterized by enhanced type I IFN responses. Loss of negative regulation of IRF5 activity causes hyperproduction of type I IFN and development of systemic lupus erythematosus in mouse models47. The fine-tuning of type I IFN responses after dectin-1 stimulation might serve several purposes in antifungal immunity such as ensuring robust TH17 cell differentiation as expression of IL-1β and IL-23 remains unaffected by IFN-α/βR signaling, while preventing the impairment of overall TH17 cell development by limiting the production of IL-27 and promoting the development of non-pathogenic TH17 cells by TGF-β activation.
Although dectin-1 is the main receptor for fungal detection on DCs, it is not the only PRR that senses fungal infections. Other CLRs, such as dectin-2, Mincle and DC-SIGN, as well as various TLRs, bind different fungal ligands48. How collaborations between these PRRs shape the environmental conditions in which TH17 cell differentiation is primed during distinct fungal infections needs to be investigated as it might profoundly affect immunopathogenicity.
Deciphering how dectin-1 signaling finds a balance in type I IFN responses to orchestrate immunoprotective responses while restraining pathological responses during fungal infections will help to understand inflammatory and autoimmune disorders and identify targets for therapeutical intervention.
Methods
Ethics statement
This study was performed in accordance with the ethical guidelines of the Amsterdam UMC, location Academic Medical Center (AMC) and human material was obtained in accordance with the AMC Medical Ethics Review Committee (Institutional Review Committee) according to the Medical Research Involving Human Subjects Act. Buffy coats obtained after blood donation (Sanquin) are not subjected to informed consent according to the Medical Research Involving Human Subjects Act and the AMC Medical Ethics Review Committee. Blood obtained from healthy volunteers was covered by the BACON protocol. Patients with active CD were recruited at the IBD clinic of Amsterdam UMC, location AMC. After providing written informed consent, an additional blood sample was drawn in addition to routine blood draws. The project was covered by the Future-IBD Biobank protocol. All samples were handled anonymously.
DC isolation and stimulation
Peripheral blood mononuclear cells were isolated from buffy coats of healthy volunteer blood donors (Sanquin) by a Lymphoprep (Axis-Shield) gradient step and monocytes were subsequently isolated by a Percoll (Amersham) gradient step. Monocytes were differentiated into immature DCs in the presence of 500 U ml−1 IL-4 and 800 U ml−1 GM-CSF (both Invitrogen) and used on day 6 or 7. Donors were routinely screened for dectin-1 single nucleotide polymorphism rs16910526 using TaqMan SNP Genotyping Assays (Assay ID C_33748481_10; Applied Biosystems); only dectin-1 wild-type DCs were used for experiments, unless otherwise indicated. DCs were stimulated with curdlan (10 μg ml−1; Sigma), Salmonella typhosa LPS (10 ng ml−1; Sigma), poly(I:C)-LyoVec (1 µg ml−1; Invivogen), heat-killed Candida or Aspergillus species at multiplicity of infection (MOI) 10, rhIFN-β (0.2–125 ng ml−1; Peprotech). DCs were preincubated for 2 h with MMP14 inhibitor NSC405020 (100 µM; Tocris) or blocking antibodies, anti-dectin-1 (20 μg ml−1; clone 259931, MAB1859, R&D Systems), anti-IFN-α/βR2 (20 μg ml−1; clone MMHAR-2, PBL Assay Science), anti-αvβ1 (10 μg ml−1; clone P5D2, MAB17781, R&D Systems), anti-αvβ3 (10 μg ml−1; clone 23C6, MAB3050, R&D Systems), anti-αvβ5 (10 μg ml−1; clone P5H9, MAB2528, R&D Systems), anti-αvβ6 (10 μg ml−1; clone 10D5, ab77906, Abcam), anti-αvβ8 (10 μg ml−1; kind gift from S.L. Nishimura49) or isotype control antibodies, mouse IgG1 (20 μg ml−1; clone MOPC-21, 555746, BD Pharmingen), mouse IgG2a (20 μg ml−1; clone G155-178, 555571, BD Bioscience) and mouse IgG2b (20 μg ml−1; clone 20116, MAB004, R&D Systems). DCs were transfected with 25 nM siRNA using transfection reagents DF4 (Dharmacon) according to the manufacturer’s instructions and used for experiments 72 h after transfection. SMARTpool siRNAs used were Syk (M-003176-03), CARD9 (M-004400-01), Bcl10 (M-004381-02), Malt1 (M-005936-02), LSP1 (M-012640-00), Raf-1 (M-003601-02), IRF1 (M-011704-01), IRF5 (M-011706-00), IRF7 (M-011810-02), ITGAV (M-004565-03), ITGB8 (M-008014-02), BST2 (M-011817-00) and non-targeting siRNA (D-001206-13) as a control (all Dharmacon). Silencing of expression was verified by real-time PCR and flow cytometry (Extended Data Fig. 1 and refs. 7,50,51); antibodies used for verification were anti-IRF1 (1:50 dilution; ab26109, Abcam), anti-IRF5 (1:50 dilution; ab124792, Abcam), anti-αv (1:50 dilution; AF1219, R&D Systems), anti-β8 (1:50 dilution; ab80673, Abcam), anti-BST2 (1:100 dilution; NIH AIDS Reagent Program 11721), followed by incubation with either PE-conjugated anti-rabbit (1:200 dilution; 711-116-152, Jackson Immunoresearch) or Alexa Fluor 488-conjugated anti-goat (1:400 dilution; A11055, Invitrogen). DCs were also transfected with a pCG–BST2–IRES–eGFP expression plasmid (a kind gift from F. Kirchhoff52) coupled to LyoVec (Invivogen), as described by the manufacturer. eGFP− and eGFP+ cells were selected 24–40 h after transfection by sorting on a FACSAria IIu Cell Sorter (BD Biosciences) and used for experiments; BST2 (over)expression was determined in both cell subsets after staining with anti-BST2 and PE-conjugated anti-rabbit (described above) by flow cytometry on a FACS Calibur or Canto (BD Biosciences). All flow cytometry data analysis was performed using FlowJo v.10.8.1 (BD Biosciences).
Fungal strains
Candida strains were grown in Sabouraud dextrose broth and incubated at 25 °C for 3 d, while shaking. A. fumigatus was grown on potato dextrose agar at 37 °C for 3 d. Conidia were dislodged from slants by gentle tapping and then resuspended in PBS/0.1% Tween-80. Hyphal contamination was removed by straining the cell solution through a glass filter. Fungi were heat inactivated at 56 °C for 1 h.
Cytokine and ISG expression
Transcript levels in DCs were quantified with the SYBR green method in an ABI 7500 Fast PCR detection system (Applied Biosystems), after mRNA isolation using the mRNA capture kit (Roche) and cDNA synthesis using the Reverse Transcription System (Promega). Specific primers were designed using Primer Express 2.0 (Applied Biosystems; Supplementary Table 1). The Ct value is defined as the number of PCR cycles where the fluorescence signal exceeds the detection threshold value. The normalized amount of target mRNA was calculated from the obtained Ct values for both target and GAPDH mRNA with Nt = 2Ct(GAPDH) − Ct(target). The relative mRNA expression in DCs was obtained by setting Nt in either 2 h (IFNB) or 6 h (ISGs) curdlan-stimulated samples at 1 within one experiment and for each donor, except when donors were used that were homozygous for the minor alleles of rs16910526 where Nt in 2 h LPS-stimulated samples was set at 1.
Secreted IL-1β, IL-12p70, IL-6, IL-23 and IL-27 levels in DC culture supernatants that were collected 28 h post-stimulation were determined by ELISA (Invitrogen). Intracellular IFN-β, αv, β8 and BST2 levels were determined by flow cytometry. Cells were first fixated in 3% paraformaldehyde for 10 min and permeabilized in 90% methanol at 4 °C for 30 min. Staining with anti-αv, anti-β8, anti-BST2, followed by PE-conjugated anti-rabbit was conducted as described above. IFN-β was stained directly with FITC-conjugated anti-IFN-β (1:20 dilution; clone MMHB-3, 21400-3, PBL Assay Science), while FITC-conjugated IgG1κ mouse antibody (1:250 dilution; clone P3.6.2.8.1, 11-4714-81, eBioscience) was used as isotype control. Expression was analyzed on a FACS Calibur or Canto (BD Biosciences). All flow cytometry data analyses were performed using FlowJo v.10.8.1 (BD Biosciences). Total TGF-β levels in DC culture supernatants that were collected 24 h post-stimulation were determined by ELISA with anti-pan TGF-β (2 µg ml−1, coating antibody; clone 1D11, MAB1835, R&D Systems) and biotinylated anti-TGF-β1 (0.2 µg ml−1, detecting antibody; BAF240, R&D Systems), followed by streptavidin-HRP (Invitrogen). Supernatants were treated with 0.2 N HCl before ELISA to expose epitopes obscured within the LLC. Bioactive TGF-β levels in DC culture supernatants were measured by transferring supernatant at 4, 8 or 24 h post-stimulation to HEK-Blue TGF-β reporter cells (Invivogen), after which secreted SEAP in the reporter cell culture supernatants was determined 24 h later using the SEAP Reporter Assay kit (Invivogen). HEK-Blue TGF-β reporter cells were also stimulated with a concentration range of rhTGF-β1 (R&D Systems) to generate a standard curve.
IRF activation and DNA binding
Nuclear and cytoplasmic extracts of DCs were prepared 2 or 6 h post-stimulation using NucBuster protein extraction kit (Novagen) as described by the manufacturer. Then, 20 μg of extract was resolved by SDS–PAGE and cellular localization of IRF1, IRF3, IRF5 or IRF7 was determined by immunoblotting with anti-IRF1 (1:1,000 dilution; 8478, Cell Signaling), anti-IRF3 (1:1,000 dilution, sc-9082, Santa Cruz), anti-IRF5 (1:1,000 dilution, ab124792, Abcam) or anti-IRF7 (1:1,000 dilution; 4920, Cell Signaling), followed by incubation with HRP-conjugated Clean-Blot IP Detection Reagent (1:2,500 dilution; 21230, Pierce) and ECL detection (Pierce). Membranes were also probed with anti-β-actin (1:2,000 dilution; clone ACTBD11B7, sc-81178, Santa Cruz), followed by HRP-conjugated anti-mouse (1:1,000 dilution; sc-2314, Santa Cruz) to ensure equal protein loading among cytoplasmic and nuclear extracts, respectively. Nuclear IRF1, IRF5 and IRF7 levels were further quantified by ELISA (USCN Life Science). IRF1 and IRF5 localization was also determined by immunofluorescence staining; DCs were fixated with 4% paraformaldehyde 2 h post-stimulation, permeabilized with 0.2% (v/v) Triton X-100 in PBS, stained with anti-IRF1 (1:100 dilution; ab26109, Abcam) or anti-IRF5 (1:100 dilution; ab2932, Abcam), followed by incubation with Alexa Fluor 546-conjugated anti-rabbit (1:400 dilution; A10040, Invitrogen) or Alexa Fluor 546-conjugated anti-goat (1:400 dilution; A21085, Invitrogen), respectively. After staining nuclei with DAPI (300 nM; Invitrogen), cells were preserved in ProLong Diamond Antifade Mountant (Molecular probes) and IRF localization was visualized with a TCS SP8 X confocal microscope (Leica).
Binding of IRF factors to the IFNB promoter was assessed by ChIP assays using the ChIP-IT Express Enzymatic Shearing and ChIP-IT Express HT kits (both from Active Motif). Briefly, cells were fixated with 1% (v/v) paraformaldehyde 2 or 6 h post-stimulation, nuclei were isolated and chromatin DNA fragmented by enzymatic shearing (10 min, 37 °C). Protein-DNA complexes were immunoprecipitated using 2 µg anti-IRF1 (sc-640X, Santa Cruz), anti-IRF5 (abcam2932, Abcam), anti-IRF7 (sc-9083X, Santa Cruz) or negative control IgG (sc-2025; Santa Cruz) and protein G-coated magnetic beads. DNA was purified after reversal of crosslinks. Quantitative real-time PCR using SYBR green (Applied Biosystems) as described above was performed with a primer set spanning the ISRE of the IFNB promoter (Supplementary Table 1). Negative Control Primer Set 1 (active motif) was used as a negative control. To normalize for DNA input, a sample for each condition was taken that had not undergone immunoprecipitation (‘input DNA’) and results wre expressed as percentage input DNA.
MMP14 activity
MMP14 activity was measured by adding 4 µM of the MMP14-specific FRET peptide substrate MMP14 substrate I (Calbiochem) to DCs 4, 8 or 24 h post-stimulation for 30 min at 37 °C. Supernatant containing (cleaved) substrate was then transferred to a black 96-well plate and fluorescence intensity was measured at 320 nm excitation and 420 nm emission wavelength using a Synergy HT reader (Biotek); the detected relative fluorescence units are a measure for MMP14 activity.
TH17 cell isolation, in vitro outgrowth and characterization
CD4+ T cells were isolated by negative selection from blood donated by healthy donors or Crohn’s disease patients with the human CD4+ T cell isolation kit II (Miltenyi) and then stimulated for 6 h with 100 ng ml−1 PMA (Sigma) and 1 μg ml−1 ionomycin (Sigma), the last 4 h in the presence of 10 μg ml−1 brefeldin A (Sigma). After fixation in 4% paraformaldehyde for 10 min, permeabilization with 0.5% (v/v) saponin and staining with APC-conjugated anti-IL-17 (1:25 dilution; clone eBio64DEC17, 17-7179-42, eBioscience), IL-17+ cells were selected by sorting on a FACSAria IIu Cell Sorter (BD Biosciences). After reversal of crosslinks by proteinase K (QIAGEN) treatment at 56 °C for 16 h in PKD buffer (QIAGEN), mRNA isolation and complementary DNA synthesis was performed as described above for DCs. Transcript levels in T cells were measured with quantitative real-time PCR using SYBR green as described above. Specific primers were designed using Primer Express 2.0 (Applied Biosystems; Supplementary Table 1). A standard curve was created for all target transcripts from known quantities of human TrueClone or TrueORF expression plasmids (all from Origene). The absolute amount of target mRNA was normalized based on the absolute amount of ACTB mRNA within each sample.
For in vitro TH17 cell outgrowth assays, both naive and memory CD4+ T cells were isolated from buffy coats of healthy blood donors (Sanquin) with the human CD4+ T cell isolation kit II (Miltenyi), combined with staining with PE-conjugated anti-CD45RO (200 µg ml−1; clone UCHL1, R084301-2, Agilent), captured on anti-PE beads (Miltenyi). Isolated naive T cells were routinely >99% CD4+ (stained with Alexa Fluor 488-conjugated anti-CD4, 1:50 dilution; clone RPA-T4, 300519, BioLegend) and contained <1% CD45RO+ cells, whereas memory T cells were routinely >99% CD4+ and contained <1% CD45RA+ cells (stained with APC-conjugated anti-CD45RA, 1:50 dilution; clone HI100, 550855, BD). DCs were either silenced for indicated proteins or preincubated for 2 h with blocking antibodies and then activated for 48 h as indicated, as described above. When DCs were activated for only 3 h before co-culture, this is mentioned explicitly in the text. Primed DCs were co-cultured with either naive CD4+ T cells (200,000 T cells to 200,000 DCs) for 5 d before restimulation or memory CD4+ T cells (20,000 T cells to 5,000 DCs) in the presence of 10 pg ml−1 SEB (Sigma) and 10 U ml−1 IL-2 (Chiron) (added after 5 d) until they became quiescent, typically after 11–14 d, before restimulation. During co-culture, cells were treated with either rhIL-27 (300 ng ml;−1 R&D Systems), rhTGF-β1 (20 ng ml−1; R&D Systems), neutralizing antibodies (5 μg ml−1) to IL-1β (AF-201-NA, R&D Systems), IL-23 (AF1716, R&D Systems), IL-12 (AF-219-NA, R&D Systems), IL-27 (AF2526, R&D Systems) or TGF-βRII (AF-241-NA, R&D Systems) or normal goat IgG (AB-108-C; R&D Systems) as a control. Proliferation and survival of co-cultures was monitored by loading naive or memory T cells with 2 μM CFSE (Molecular Probes) and measured every other day in combination with Fixable Viability Dye eFluor 780 (1:833 dilution; 65-0865-14, eBioscience) staining by flow cytometry on a FACS Canto (BD Biosciences). All flow cytometry data analyses were performed using FlowJo v.10.8.1 (BD Biosciences). Additionally, cell counts were determined every other day using the CASY cell counter and analyzer (OMNI Life Science). Restimulation of T cells occurred for 6 h with PMA and ionomycin in the presence of brefeldin A as described above. After fixation, permeabilization and staining with either APC-conjugated anti-IL-17 or eFluor506-conjugated anti-IL-17 (1:50 dilution; clone eBio64DEC17, 69-7179-42, eBioscience) alone or in combination with FITC-conjugated anti-IFN-γ (1:5 dilution; clone 25723.11, 340449, BD), total IL-17+ or separate IFN-γ-IL-17+ and IFN-γ+IL-17+ cells were measured by flow cytometry and subsequently selected by sorting and used for either mRNA isolation, cDNA synthesis and quantitative real-time PCR as described above. Gating strategies for analyses and sorting are shown in Extended Data Fig. 3. Sorted total IL-17+ cells were also subjected to further flow cytometry analyses, after permeabilization using the Foxp3/transcription factor staining kit (eBioscience), by staining with (combinations of) the following antibodies: FITC-conjugated anti-IFN-γ, PE-conjugated anti-IL-10 (1:10 dilution; clone JES3-9D7, 12-7108-82, Invitrogen), Alexa Fluor 647-conjugated anti-RORγt (1:10 dilution; clone Q21-559, 563620, BD), APC-conjugated anti-T-bet (1:10 dilution; clone 4B10, 644814, BioLegend), eFluor660-conjugated anti-c-Maf (1:10 dilution; clone sym0F1, 50-9855-82, Invitrogen), APC-conjugated anti-IL-1R1 (1:10 dilution; FAB269A, R&D Systems) and APC-conjugated anti-GM-CSF (1:10 dilution; clone BVD2-21C11, 502310, BioLegend) or matching isotype control antibodies: Alexa Fluor 647-conjugated mouse IgG2b (1:5 dilution; clone 27–35, 558713, BD), APC-conjugated mouse IgG1 (10 μg ml−1; clone P3.6.2.8.1, 17-4714-42, Invitrogen), eFluor660-conjugated mouse IgG2b (10 μg ml−1; clone eBMG2b, 50-4732-82, Invitrogen), APC-conjugated goat IgG (1:5 dilution; IC108A, R&D Systems) and APC-conjugated rat IgG2a (2.5 μg ml−1; 402305, BioLegend).
Statistical analysis
Statistical analyses were performed using the Student’s t-test for paired and two-tailed observations using Office Professional Plus 2019, Excel (Microsoft) and GraphPad Prism v.8.3.1 (Dotmatics). Statistical significance was set at P < 0.05.
Reporting summary
Further information on research design is available in the Nature Portfolio Reporting Summary linked to this article.
Data availability
Source data are provided with this paper.
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Acknowledgements
We thank X. Yocarini and R.K. Ramkisoen (both Amsterdam University Medical Center) for providing blood from patients with CD. The pCG–BST2–IRES–eGFP expression plasmid was kindly provided by F. Kirchhoff (Ulm University Medical Center). β8 (B5) antibodies were a kind gift from S.L. Nishimura (University of California). This work was supported by the European Research Council (advanced grant 670424 to T.B.H.G.). The funders had no role in study design, data collection and analysis, decision to publish or preparation of the manuscript.
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S.I.G. designed and supervised the research, performed experiments and wrote the manuscript. T.M.K., A.D. and B.A.W. performed experiments. E.B.M.R. assisted with flow cytometry experiments. G.R.A.M. D’H. provided blood from patients with CD. B.T. and T.B. provided fungal preparations. T.B.H.G. supported the research, provided feedback and helped prepare the manuscript.
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Nature Immunology thanks Matteo Iannacone, Thomas Korn and Alexander Scheffold for their contribution to the peer review of this work. Primary Handling Editor: Ioana Visan, in collaboration with Nature Immunology team. Peer reviewer reports are available.
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Extended data
Extended Data Fig. 1 Silencing of proteins in human DCs by RNA interference.
a, Real-time PCR analyses of relative mRNA levels of indicated genes in unstimulated DCs or after 6 h stimulation of DCs with curdlan, after transduction with non-targeting (control) or specific siRNAs to silence protein expression (Syk, CARD9, Bcl10, Malt1 siRNA n = 4; LSP1, Raf-1 siRNA n = 2; IRF1 siRNA n = 26; IRF5 siRNA n = 18; ITGAV siRNA n = 3; ITGB8 siRNA n = 6; BST2 siRNA n = 9). Results from real-time PCR were normalized to the expression of reference household gene GAPDH and shown relative to either unstimulated or 6 h curdlan stimulation. Data represent mean ± s.d. of independent donors. **P < 0.01 (Student’s t-test, paired, two-tailed), calculated between control and specific siRNA-transduced samples that were likewise stimulated. b, Flow cytometry analyses by staining for specific protein expression (FI, fluorescence intensity) in unstimulated DCs or after 6 h stimulation of DCs with curdlan, after silencing of specific protein expression (n = 3). Isotype control indicates negative control staining. Representative histograms for independent donors are shown.
Extended Data Fig. 2 Proliferation and survival during co-culture of curdlan- or C. albicans-primed DCs with naive or memory CD4+ T cells are not altered by either attenuated or enhanced type I IFN responses.
a,b,d-f, Flow cytometry analyses of proliferation and survival by carboxyfluorescein succinimidyl ester (CFSE) dilution (FI, fluorescence intensity) and staining with a live/dead dye after T cells were outgrown in vitro by co-culture of either naive (Tn, a,b) or memory (Tm, c-e) CD4+ T cells with immature DCs (iDC) or DCs primed for 48 h with curdlan or C. albicans, in the presence of blocking IFN-α/βR antibodies (Ab) or recombinant human (rh) IFN-β, at day 3 (a,d, n = 3), day 5 (b,e, n = 3) or day 12 (f, n = 3). DC-memory T cell co-cultures (c-e) were done in the presence of bacterial superantigen Staphylococcus aureus enterotoxin B, resulting in antigen-independent T cell activation. Representative dot plots for independent donors are shown, with the percentage dead cells indicated in the upper part. The red histogram plots show the calculated CFSE division peaks. c,g, T cell counts at indicated time points after T cells were outgrown in vitro by co-culture of either naive (c) or memory (g) CD4+ T cells with immature DCs (iDC) or primed DCs, as described for a,b,d-f (n = 3). Data represent mean ± s.d. of independent donors.
Extended Data Fig. 3 Flow cytometry analysis strategies.
a, b, Strategies for flow cytometry analyses of TH polarization by staining for intracellular IL-17 (APC) and/or IFN-γ (FITC) expression (FI, fluorescence intensity) in restimulated T cells, outgrown in vitro by co-culture of naive (a) or memory (b) CD4+ T cells with immature or primed DCs: 1. Live lymphocytes were selected based on FSC-A/SSC-A, followed by 2. single cell selection based on FSC-A/FSC-H. 3. During sorting, all IL-17+, IFNγ-IL-17+ or IFN-γ+IL-17+ T cells were selected via respectively gate P1, P2 or P3. In a, restimulated T cells after DC-naive T cell co-cultures were further divided in resting and blast cell populations and analyzed separately for IL-17 and IFN-γ expression. Fluorescence minus one (FMO) stainings were performed to determine gate borders. This was necessary as IFN-γ-IL-17+ blast T cells coincided with IFN-γ+IL-17+ resting T cells. These separate analyses were used to calculate the total percentages of IFN-γ-IL-17+ and IFN-γ+IL-17+ T cells present after restimulation, while accounting for the percentages of resting and blast cells. The percentage blast cells varied between 10-40% between experiments. In the IL-17/IFN-γ dot plots, the percentage positive cells are indicated in each quadrant.
Extended Data Fig. 4 Dectin-1 directs TH17 polarization via release of IL-1β and IL-23.
a-e, Flow cytometry analyses of TH polarization by staining for intracellular IL-17 and IFN-γ expression (FI, fluorescence intensity) in restimulated T cells, outgrown in vitro by co-culture of either naive (Tn, a,b,) or memory (Tm, c-e,) CD4+ T cells with immature DCs (iDC) or DCs primed for 48 h with curdlan or C. albicans, in the presence of blocking IL-1β, IL-23 or IL-12 antibodies (Ab) or isotype IgG control antibodies, at day 5 (a,b, n = 3; c-e, n = 6) or day 11–14 (c-e, n = 6). In a,c,d, representative dot plots for independent donors are shown, with the percentage positive cells indicated in each quadrant. In b,e, the percentage IL-17+ cells per total amount of T cells are shown. Data in b,e represent mean ± s.d. of independent donors. **P < 0.01 (Student’s t-test, paired, two-tailed), calculated between untreated and treated samples that were likewise stimulated.
Extended Data Fig. 5 Dectin-1 directs polarization of predominantly TH17 cells with high IL10, MAF and PTGDS and low IFNG, TBX21, IL1R1 and CXCL3 mRNA expression.
a-c, Real-time PCR analyses of IFNG, TBX21, IL1R1, CXCL3, CCL3, CSF2, IL22, CCL5, IL17A, IL17F, RORC, IL10, MAF and PTGDS normalized mRNA levels in IL-17+ T cells, isolated by flow cytometry-based sorting from peripheral blood of healthy donors (a, n = 4) or active Crohn’s disease patients, either treated (a, n = 4) or acute and untreated (a, n = 4), or after restimulation of T cells, outgrown in vitro by co-culture of either naive (b) or memory (c) CD4+ T cells with immature DCs (iDC) or DCs primed for 48 h with curdlan or C. albicans (c), at day 5 (b, n = 4) or day 11–14 (c, n = 12). In b,c, IL-17+ cells were further separated during sorting based on intracellular IFN-γ expression. Results from real-time PCR were quantified using standard curves for all genes and normalized to the expression of reference household gene ACTB. These data are an addendum to the data presented in Fig. 2i (a) and Fig. 2j (b,c). Data represent mean ± s.d. of independent donors. **P < 0.01, *P < 0.05 (Student’s t-test, paired, two-tailed), calculated between IFN-γ-IL-17+ and IFN-γ-IL-17+ T cells as indicated by brackets (b,c).
Extended Data Fig. 6 Dectin-1 directs non-pathogenic TH17 polarization via tightly regulated expression of the IFN-stimulated genes β8 and BST2, that are crucial for TGF-β activation.
a,b, Real-time PCR analyses of IFNG, TBX21, IL1R1, CXCL3, CCL3, CSF2, IL22, CCL5, IL17A, IL17F, RORC, IL10, MAF and PTGDS normalized mRNA levels in IL-17+ T cells, isolated by flow cytometry-based sorting after restimulation of T cells, outgrown in vitro by co-culture of memory CD4+ T cells with immature DCs (iDC) or DCs primed for 48 h with curdlan (a,b) or C. albicans (a), in the presence of blocking IFN-α/βR antibodies (Ab, a), rhIFN-β (a) (both during DC stimulation), neutralizing IL-27 antibodies (a), rhIL-27 (a), blocking TGF-βR antibodies (a), rhTGF-β1 (a,b) (all during DC-T co-culture), blocking αvβ8 antibodies (during DC stimulation) (a), or after overexpression of BST2 (eGFP+ cells) by transfecting DCs with mammalian expression plasmid pCG–BST2-IRES–eGFP and subsequent sorting based on eGFP expression (eGFP−, eGFP+) 24 h later (b), at day 11–14 (a, untreated n = 12; d, IFN-α/βR Ab n = 11, rhIFN-β n = 4; e, n = 4; f, TGF-βR Ab n = 6, rhTGF-β1 n = 4, αvβ8 Ab n = 3; b, n = 3). Results from RT–PCR were quantified using standard curves for all genes and normalized to the expression of reference household gene ACTB. These data are an addendum to the data presented in Fig. 2k (a), Fig. 4c (a), Fig. 5h (a), Fig. 6i (a) and Fig. 8k (b). Data represent mean ± s.d. of independent donors. **P < 0.01, *P < 0.05 (Student’s t-test, paired, two-tailed), calculated between untreated and treated samples that were likewise stimulated (a,b) and eGFP− and eGFP+ DCs primed with curdlan as indicated by brackets (b).
Extended Data Fig. 7 Flow cytometry analyses of IL-17+ T cells induced by curdlan- or C. albicans-primed DCs.
Flow cytometry analyses by staining for intracellular expression (FI, fluorescence intensity) of IL-10, IFN-γ, RORγt, c-Maf, T-bet, IL-1R1 and GM-CSF in restimulated IL-17+ T cells, by flow cytometry-based sorting after in vitro TH polarization by co-culture of memory CD4+ T cells with DCs primed for 48 h with curdlan or C. albicans at day 11–14. Isotype indicates negative control staining. Representative dot plots - with the percentage positive cells indicated - or histograms for independent donors are shown.
Extended Data Fig. 8 Dectin-1-mediated IFNβ expression regulates TGFβ activation that is required for non-pathogenic TH17 polarization.
a-d, Flow cytometry analyses of TH polarization by staining for intracellular IL-17 and IFN-γ expression (FI, fluorescence intensity) in restimulated T cells, outgrown in vitro by co-culture of naive CD4+ T cells with immature DCs (iDC) or DCs primed for either 48 h (a,c,d, n = 4) or 3 h (b–d, n = 3) with curdlan or C. albicans, in the presence of blocking IFN-α/βR antibodies (Ab; during DC stimulation) (a,c,d) and/or blocking TGFβR antibodies (a,c,d) or rhTGFβ1 (a-d) (both during DC-T co-culture), at day 5. In a,b, representative dot plots for independent donors are shown, with the percentage positive cells indicated in each quadrant. In c, the percentage IL-17+ cells per total amount of T cells are shown and in d, the percentage IFNγ- and percentage IFNγ+ cells per IL-17+ T cells are shown. Data in c,d represent mean ± s.d. of independent donors. **P < 0.01, *P < 0.05 (Student’s t-test, paired, two-tailed), calculated between untreated and treated samples that were likewise stimulated.
Extended Data Fig. 9 BST2 expression has no effect on dectin-1-induced IFNB expression.
a,b, Real-time PCR analyses of IFNB relative mRNA levels in unstimulated DCs after stimulation of DCs with curdlan or C. albicans, after transduction with non-targeting (control) or specific siRNAs to silence expression of BST2 and/or IRF1 (a) or after overexpression of BST2 (eGFP+ cells) by transfecting DCs with mammalian expression plasmid pCG–BST2-IRES–eGFP and subsequent sorting based on eGFP expression 24 h later (b), at 2 or 6 h (a, n = 4; b, n = 3). Results from real-time PCR were normalized to the expression of reference household gene GAPDH and shown relative to 2 h curdlan stimulation. Data represent mean ± s.d. of independent donors. **P < 0.01 (Student’s t-test, paired, two-tailed), calculated between control and specific siRNA-transduced samples that were likewise stimulated.
Extended Data Fig. 10 Dectin-1 signaling tightly regulates IFNβ expression to control the release of active TGFβ for non-pathogenic TH17 polarization.
Dectin-1 ligation by its specific ligand curdlan or fungi like Candida albicans induce Syk-CARD9-Bcl10-Malt1-mediated signaling pathways, which lead to activation of the transcription factors IRF1 and IRF5. The antagonistic actions of IRF1 and IRF5 on the promoter of the IFNB gene result in strictly controlled expression of IFNβ. Autocrine signaling through the IFN-α/βR induces expression of various IFN-stimulated genes, such as integrin chain β8 and BST2. Expression of αvβ8 integrin on the outer membrane of DCs allows binding of the large latent complex (LLC) consisting of TGFβ, latency-associated peptide (LAP) and latent TGFβ-binding protein (LTBP), that is sequestered within the extracellular matrix (ECM) after secretion. Upon binding of the LLC by αvβ8, matrix metalloproteinase MMP14 cleaves LAP, which frees the bio-active TGF-β dimer from the restraints of the LLC and allows it to bind to the TGF-βR expressed on T cells, thereby influencing the polarization of T helper (TH) cells towards TH17 cells with a non-pathogenic signature, characterized by expression of the transcription factor c-Maf, anti-inflammatory cytokine IL-10 and effector protein prostaglandin D2 synthase (PTGDS). Expression of IFN-induced BST2 interferes with the proteolytic activity of MMP14, thereby attenuating the release of active TGF-β. An imbalance in IFN-β expression will result in loss of TGF-β activation and differentiation of TH17 cells with a pathogenic molecular signature, when either αvβ8 expression is lost or when enhanced BST2 expression increasingly blocks MMP14 activity.
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Gringhuis, S.I., Kaptein, T.M., Remmerswaal, E.B.M. et al. Fungal sensing by dectin-1 directs the non-pathogenic polarization of TH17 cells through balanced type I IFN responses in human DCs. Nat Immunol 23, 1735–1748 (2022). https://doi.org/10.1038/s41590-022-01348-2
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DOI: https://doi.org/10.1038/s41590-022-01348-2
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