CX3CR1+ mononuclear phagocytes control immunity to intestinal fungi

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Science  12 Jan 2018:
Vol. 359, Issue 6372, pp. 232-236
DOI: 10.1126/science.aao1503

Phagocytes patrol intestinal fungi

Maintaining a healthy balance of gut bacteria can promote good health. Leonardi et al. show that fungi can also interact with gut immune cells to maintain intestinal well-being. CX3CR1+ mononuclear phagocytes (MNPs) patrol the intestine and promote antifungal immunity. Genetic deletion of CX3CR1 in MNPs caused colitis-like symptoms in mice. CX3CR1 polymorphisms were detected in Crohn's disease patients that were unable to produce antibodies against multiple fungal species. Thus, commensal fungi may be as important as bacteria in maintaining gut health, and antifungal therapy could hold promise for treating intestinal inflammation.

Science, this issue p. 232


Intestinal fungi are an important component of the microbiota, and recent studies have unveiled their potential in modulating host immune homeostasis and inflammatory disease. Nonetheless, the mechanisms governing immunity to gut fungal communities (mycobiota) remain unknown. We identified CX3CR1+ mononuclear phagocytes (MNPs) as being essential for the initiation of innate and adaptive immune responses to intestinal fungi. CX3CR1+ MNPs express antifungal receptors and activate antifungal responses in a Syk-dependent manner. Genetic ablation of CX3CR1+ MNPs in mice led to changes in gut fungal communities and to severe colitis that was rescued by antifungal treatment. In Crohn’s disease patients, a missense mutation in the gene encoding CX3CR1 was identified and found to be associated with impaired antifungal responses. These results unravel a role of CX3CR1+ MNPs in mediating interactions between intestinal mycobiota and host immunity at steady state and during inflammatory disease.

Extensive studies on intestinal bacteria have demonstrated that alterations in the microbiome have a dramatic impact on host immunity and contribute to several diseases of inflammatory origin. Fungi are present in the mammalian intestine (15), yet little is known about their ability to influence immune homeostasis. Recent advances in deep sequencing technologies have redefined our understanding of fungal communities (mycobiota) colonizing mammalian barrier surfaces (2). Intestinal fungal dysbiosis has been shown to influence colitis, alcoholic liver disease, and allergic lung disease (36), providing evidence for its potential to influence both local and distal inflammation. Moreover, serum antibodies against Saccharomyces cerevisiae mannan (ASCA) are elevated in several inflammatory diseases, including Crohn’s disease (CD) (79). Systemic ASCA can develop in response to intestinal fungi (3, 7), providing a possible link between the gut mycobiota and host immunity. Despite the identification of receptors involved in the recognition and immunity to intestinal fungi (3, 10), the cell subsets that initiate and regulate mucosal immune responses to the mycobiota remain unknown.

In the intestinal lamina propria (LP), several subsets of phagocytes respond to bacterial infections or to fluctuations in the commensal bacterial communities (1113). Among those, mononuclear phagocytes (MNPs), expressing the fractalkine receptor CX3CR1 (CX3CR1+ MNPs), and subsets of dendritic cells (DCs) marked by differential expression of the integrins CD11b and CD103 can initiate immunity and prime T helper 17 (TH17) responses to both commensal and pathogenic bacteria in the gut (11, 12, 14). Despite their well-described ability to respond to gut bacteria, their role in mucosal immunity to gut fungi remains unknown.

To assess the in vivo ability of gut resident phagocytes to respond to fungi, we colonized mice with the opportunistic human fungal commensal Candida albicans and analyzed the changes in the surface expression of the costimulatory molecules. We found that colonization with C. albicans altered the surface expression of CD40 and CD86 among CX3CR1+ MNPs but not among the other subsets (fig. S1, A and B). We thus assessed the ability of CX3CR1+ MNPs to recognize intestinal fungi. We purified CX3CR1+ MNPs from the intestinal LP and compared their RNA-sequencing (RNA-seq) expression profile to those of CD11b+CD103+ DCs (Fig. 1, A and B, and fig. S2A) that have been shown to respond to lung fungal infection (14, 15). Whereas both CD11b+CD103+ DCs and CX3CR1+ MNPs expressed genes involved in antigen presentation, CX3CR1+ MNPs showed a higher expression of genes involved in fungal recognition (Fig. 1B, and fig. S2B). Quantitative polymerase chain reaction (PCR) and flow cytometric analysis confirmed that transcripts encoding the fungal C-type lectin receptors (CLRs) dectin-1 (Clec7a), dectin-2 (Clec6a), and mincle (Clec4e) were highly present in CX3CR1+ MNPs (Fig. 1, C and D, and fig. S3, A and B). Further, we examined the in vivo intake of Candida by phagocytes in the mouse intestine. Confocal microscopy examination revealed that Candida was efficiently recognized by intestinal phagocytes in vivo, with over 80% of all CX3CR1+ MNPs intaking Candida (Fig. 1E; fig. S3, C and D; and movie S1). These results indicate that gut-resident CX3CR1+ MNPs are equipped to efficiently recognize and respond to intestinal fungi in vivo.

Fig. 1 CX3CR1 mononuclear cells express antifungal receptors and recognize fungi in the intestine.

(A) RNA-seq analysis was performed on sorted CD11b+ CD103+ dendritic cells and CX3CR1+ mononuclear phagocytes. Shown is a volcano plot of P value versus fold-change (FC) comparing gene expression in the two cell subsets; red dots indicate a false discovery rate (FDR) of <0.05. (B) Logarithmic count per million [log(cpm)] normalization of genes involved in antigen presentation (left) or fungal recognition (right). (C) The expression of antifungal CLRs was confirmed by means of quantitative reverse transcription–PCR. (D) Representative flow cytometry histogram of dectin-1, dectin-2, and Syk expression among CD11b CD103+, CD11b+ CD103+, and CD11b+ CX3CR1+ cells in colons of WT mice. (E) Representative confocal imaging of the intake of C. albicans–red fluorescent protein (RFP) (red) by CX3CR1+ MNPs [green; CX3CR1+, 4′,6-diamidino-2-phenylindole+ (DAPI+)] and other cell types (blue; CX3CR1, DAPI+) in the intestine. Bar graphs represent mean ± SEM of individual mice (n = 4 to 7 mice), representative of at least two independent experiments. *P < 0.05, **P < 0.01, one-way analysis of variance (ANOVA).

Both CX3CR1+ MNPs and CD11b+CD103+ DCs have been shown to play a role in the regulation of adaptive immunity to commensal and pathogenic bacteria (12, 14, 16, 17). CX3CR1+ MNPs are involved in the induction of TH17 responses to intestinal bacteria (18) and are essential for the killing of Candida in the kidneys during systemic infection (19). Conversely, several studies have suggested a central role for interferon regulatory factor–4 (IRF4)–dependent CD11b+CD103+ DCs in intestinal TH17 cell differentiation, as well as TH17-induced bacterial and fungal clearance in the lung (12, 14). Further, conventional migratory CD11b CD103+ DCs have been shown to be a cellular entry point to opportunistic pathogens and are absent in Batf3−/− mice (fig S10, A and B) (20). To directly assess the role of different phagocytic subsets in the induction of antifungal immune responses, we crossed inducible floxed Irf4fl/fl mice or inducible floxed Cx3cr1DTR mice (11) with transgenic Cd11c-Cre mice. The first strategy allowed the specific ablation of Irf4 in DCs, leading to the loss of intestinal CD11b+CD103+ DCs (referred as ΔIrf4 mice) but intact CX3CR1+ MNPs (fig. S4, A and B) (14). The second strategy allowed for the selective depletion of intestinal CX3CR1+ MNPs upon administration of diphtheria toxin (DT; mice referred as ΔCX3CR1), without affecting CD11b+ CD103+ DCs (fig. S4, C to E) (11).

TH17 cells are crucial for the control of fungi at other gastrointestinal sites such as the oral cavity, whereas regulatory T cells (Treg cells) suppress fungal infection–related host damage (21, 22). Upon colonization with C. albicans, we observed a strong TH17 response in the colon and mesenteric lymph nodes (mLNs) that was consistent with other studies (Fig. 2, A and B, and fig. S5A) (23), whereas the frequency of Foxp3+ Treg cells was not affected (fig. S5B). We next determined whether specific phagocytic subsets are involved in TH17 responses to intestinal fungi. Candida colonization induced a consistent increase in TH17 cell frequencies that were not affected by depletion of CD11b+CD103+ DCs (Fig. 2, A and B, and figs. S5C and S6A) or lack of CD11bCD103+ DCs (fig. S10, C to J). By contrast, a dramatic decrease in TH17 cells was observed upon depletion of CX3CR1+ MNPs in the colon and mLN (Fig. 2, C and D, and fig. S6B) but not in the small intestine (fig. S7, A and B). The observed TH17 induction was independent from segmented filamentous bacteria (SFB) that were absent in our colony (fig. S8, A to C). Foxp3+ Treg cells were not affected by the absence of either phagocytic subset (figs. S5D, S6C, S7C, and S10, F and J).

Fig. 2 CX3CR1+ MNPs control gut antifungal immunity.

Colonic LP cells were collected from ΔIrf4 mice (orange bars) or littermates (litt, gray bars) fed (C.a) or not (NT) with 5 × 107 C. albicans at day 10. (A and B) Expression of RAR-related orphan receptor–γt (RORγt) and interleukin-17 (IL-17) by CD4+ T cells (pooled from two independent experiments). Cd11c-Cre+/− CX3CR1DTR mice (ΔCX3CR1, green bars) or Cd11c-Cre−/− CX3CR1DTR littermates (litt, gray bars) were treated with DT and fed with C. albicans. (C and D) RORγt and IL-17 expression by the CD4+ T cells in the colon (pooled from three independent experiments). (E) IgG against the commensal C. tropicalis and flagellin. (F) Systemic IgG responses after intraperitoneal injection with C. albicans at day 1, 2, and 5 (pooled from two independent experiments). (G) C. albicans in the feces of control, ΔIrf4, and ΔCX3CR1 mice at day 10 (dots represent individual mice). ΔCX3CR1 mice and littermates were transferred with purified CD4+ Thy1.1+ OT-II cells, fed C. albicans–OVA, and euthanized after 10 days. (H) Representative plots of CD4+ Thy1.1+ OT-II cells proliferation in the colon (pooled from three independent experiments). Cx3cr1-Cre-ERT+/− Sykfl/fl mice (ΔSyk) or littermates (Litt) treated with tamoxifen and fed with C. albicans. (I) RORγt expression by CD4+ T cells in the colon (pooled from two independent experiments). (J) C. albicans in the feces at day 10. Dots represent individual mice. (K) IgG responses against C. tropicalis at day 10 (n = 5 mice per group). (L) Quantification of proliferating CFSE CD4+ Thy1.1+ OT-II cells in the colon (pooled from two independent experiments). Data are presented as mean ± SEM; *P < 0.05, **P < 0.01, ***P < 0.001; Mann-Whitney Test in (E), (G), (J), (K), and (L) and one-way ANOVA in (B), (C), (D), and (F).

Besides TH17 responses, the development of systemic ASCA during intestinal inflammation is another hallmark of adaptive immunity activation in response to intestinal fungi (3, 7). In addition to S. cerevisiae, Candida can act as an immunogen for ASCA production (7). Thus, we assessed whether lack of CX3CR1+ MNPs also alters the production of systemic immunoglobulin G (IgG) antibodies against the commensal fungus C. tropicalis (3) during steady state (fig. S8D). We found that CX3CR1+ MNPs depletion reduced IgG-antibody responses against C. tropicalis without affecting the response against the commensal bacterial antigen flagellin (Fig. 2E). To assess whether the induction of antifungal IgG is dependent on recognition of luminal fungal antigens by CX3CR1+ MNPs, we compared the induction of systemic IgG after intestinal colonization or systemic infection with C. albicans. Although both approaches led to the generation of systemic anti–C. albicans IgG in wild-type (WT) littermates, depletion of CX3CR1+ MNPs led to a significant decrease of antibody production against intestinal C. albicans (fig. S9) without affecting the antibody production upon systemic infection (Fig. 2F). This suggests that the defect in antifungal antibody production in ΔCX3CR1 mice is specific to the gut. By contrast, neither the depletion of CD11b+CD103+ DCs nor the lack of CD11bCD103+ DCs influenced systemic production of antibody to Candida (figs. S9 and S10K). Consistent with the decreased antifungal responses, C. albicans burdens are increased in ΔCX3CR1 mice but not in ΔIrf4 and Batf3−/− mice (Fig. 2G and fig. S10L).

To further assess the role of CX3CR1+ MNPs in the induction of responses to antigens delivered by intestinal fungi, we fed ΔCX3CR1 mice and control littermates a recombinant C. albicans strain expressing a model major histocompatibility complex II–restricted OT-II peptide (C.a-OVA) (fig. S11) and adoptively transferred mice with carboxyfluorescein diacetate succinimidyl ester (CFSE)–labeled CD4+ Thy1.1+ OT-II T cells (fig. S12, A and B). CX3CR1+ MNPs depletion lead to decreased antigen-specific proliferation of TH17 cells in response to C. albicans in both the colon and the mLN (Fig. 2H and fig. S12, C to E). CX3CR1+ MNPs might either directly transport fungal antigens to the mLNs for T cell priming or pass the antigens to other migratory phagocytes, although both scenarios are possible (11, 24). Nevertheless, those data demonstrate that CX3CR1+ MNPs play an important role in the induction of TH17 and antibody responses to intestinal fungi, whereas CD11b+ CD103+ DCs and CD11b CD103+ DCs are not crucial.

Spleen tyrosine kinase (Syk) is crucial for the initiation of the signaling cascade downstream of several CLRs (fig. S2) and is highly expressed in CX3CR1+ MNPs (Fig. 1, B and D, and fig S3B). We thus generated ΔSyk CX3CR1 mice (Sykfl/fl x Cx3cr1-cre/ERT2+/−) to selectively delete Syk in CX3CR1+ cells (fig. S13). Consistently, we observed fungal outgrowth but impaired TH17 and antifungal antibody responses to intestinal Candida colonization (Fig. 2, I to L, and figs. S12F and S14), suggesting that intact CLR signaling in CX3CR1+ cells is required to control fungal colonization and to induce effective adaptive immunity to fungi in the gut.

Having determined that CX3CR1+ MNPs recognize intestinal fungi and control gut antifungal immunity, we explored whether these cells play a role in shaping the composition of gut fungal communities. We characterized the microbiota upon CX3CR1+ MNPs depletion using high-throughput internal transcribed spacer 1 and 16S sequencing of fungal and bacterial ribosomal DNA. Despite their role in the control of commensal and pathogenic bacteria (11, 16, 25), ablation of CX3CR1+ MNPs did not affect β and α diversity of the intestinal bacterial community (figs. S15, A to E, and S16A). By contrast, ablation of CX3CR1+ MNPs, but not CD11b+ CD103+ DCs, altered the fungal community composition of these mice as compared with control littermates (Fig. 3A and figs. S15B; S16, B to D; S17; and S18). CX3CR1+ MNPs depletion also led to an increase in fungal α-diversity that was mainly driven by an increased abundance and diversity among the Ascomycota phylum (Fig. 3B and figs. S15, B and E, and S16, C and D). This suggests that CX3CR1+ MNPs play a role in immune surveillance and maintenance of a balanced gut fungal community.

Fig. 3 Depletion of CX3CR1+ MNP affects gut mycobiota and results in exacerbated intestinal disease.

Feces from ΔCX3CR1 or WT littermates (Litt) mice were collected 7 days after administration of the first DT dose. (A) Nonmetric multidimensional scaling (NMDS) plot of distance ordination based on Bray-Curtis dissimilarities in the colon for fungal OTUs (WT n = 5 mice; ΔCX3CR1 n = 6 mice). (B) α diversity (Simpson diversity index) among the Ascomycota (left) and Basidiomycota (right) phyla. Data are pooled from two independent experiments and show mean ± SEM. Each circle denotes one mouse. (C) Weight change during DSS colitis in ΔCX3CR1 mice or control littermates after short-term treatment with fluconazole (Fl) or no treatment (NT) (pooled from two independent experiments). (D) Representative plots of neutrophil infiltration (CD11b+ Gr-1high) in the colon after DSS administration. (E) Weight change during DSS colitis in ΔCX3CR1 mice or control littermates fed with C. tropicalis (C.t). Data show mean ± SEM (litt n = 5 mice; ΔCX3CR1 n = 5 mice). (F) C. tropicalis colony-forming units (cfu) per gram in the feces of ΔCX3CR1 or control littermates at day 7. Dots represent individual mice, mean ± SEM. Systemic IgG responses against C. tropicalis were assessed by means of enzyme-linked immunosorbent assay (ELISA). Statistical analysis: *P < 0.05, **P < 0.01, ***P < 0.001; Mann-Whitney test in (B) and (F) and two-way ANOVA in (C) and (E).

Fungi are present at highest densities in the colon (3), where fungal colonization induced a strong TH17 response (fig. S5A). Thus, we next tested whether ΔCX3CR1 mice are more susceptible to dextran sulfate sodium (DSS)–induced colitis. Consistent with their inability to mount an efficient antifungal response, we found that ΔCX3CR1 mice were more susceptible to DSS colitis as compared with their littermate controls (Fig. 3, C and D, and fig. S19, A and B). Fluconazole targets most Candida species and other dimorphic fungi and ameliorates colitis in mice with defects in antifungal immunity when used during the onset of intestinal disease (2, 3, 10). Because CX3CR1+ MNPs depletion had a strong effect on Ascomycota, we treated ΔCX3CR1 mice with fluconazole. Fluconazole treatment ameliorated intestinal disease in ΔCX3CR1 mice (Fig. 3, C and D, and fig. S19, A and B). Transfer of feces from ΔCX3CR1 mice did not affect the outcome of colitis in ex-germ-free mice (fig. S19, C to H), indicating that ΔCX3CR1 microbiota is not per se pathogenic. Further supplementation with C. tropicalis, previously shown to affect intestinal conditions in dectin-1– and dectin-3–deficient mice (3, 10, 26), or with C. albicans led to severe wasting disease, colon shortening, and fungal overgrowth in the intestines of ΔCX3CR1 mice without worsening the disease in littermate controls (Fig. 3E and fig. S20, A and B). Despite the increased disease susceptibility and augmented Candida burden, ΔCX3CR1 mice failed to mount a systemic antifungal IgG antibody response (Fig. 3F and fig. S20, C and D), which is consistent with the defective antifungal immunity that we observed during the steady state. These results indicate that CX3CR1+ MNPs play a crucial role in controlling fungal microbiota during intestinal disease.

Having established a role for CX3CR1+ MNPs in the control of gut fungi during intestinal disease, and finding that CX3CR1+ MNPs have the potential to intake other species of mouse and human commensal fungi (Fig. 4A), we explored whether genetic variations of the human CX3CR1 gene affect immunity to fungi in inflammatory bowel disease (IBD). Defects in CX3CR1 have been shown to increase susceptibility of mice and humans to systemic candidiasis (19) but not to vulvovaginal and oral candidiasis (27). By contrast, the role of CX3CR1 in the initiation of antifungal responses in the gut is unknown. We focused on polymorphisms in the coding region of the CX3CR1 gene (fig. S21) that have been previously associated with human inflammatory diseases such as arteriosclerosis and coronary artery disease (28, 29). Although none of these polymorphisms were associated with a predisposition to IBD (table S1), we identified a striking association of CX3CR1 T280M (rs3732378) polymorphism specifically with IgG ASCA positivity in a cohort of 503 CD patients [odds ratio (OR) = 0.59, logistic regression P = 3.73 × 10−03] (Fig. 4B). By contrast, antibodies against bacterial and host antigens previously shown to increase in IBD (7) were not affected by this mutation (Fig. 4B and table S2). Because ASCA antibodies are directed against both S. cerevisiae and C. albicans (7), we next assessed whether antifungal antibody responses to common human commensals are also affected by CX3CR1 T280M. Compared with nonaffected individuals, patients homozygous for CX3CR1 T280M were severely impaired in their ability to generate systemic IgG recognizing a variety of gut-relevant fungi belonging to the phylum Ascomycota, while producing normal antibody responses against the bacterial antigen flagellin (Fig. 4, C and D, and fig. S22), which is consistent with the hypothesis that this mutation in CX3CR1 leads to impaired responses to fungi in the gut.

Fig. 4 Polymorphisms in the coding region of the CX3CR1 gene are associated with decreased antifungal IgG responses in CD patients.

(A) Representative images of the intake of fungal species (colored) by CX3CR1+ MNPs (gray) in the colon. (B) Association between the missense mutation rs3732378 and the systemic serologic markers anti-neutrophil cytoplasmic antibodies (anca), flagellin (cbir), Pseudomonas fluorescens–associated sequence I-2 (i2), and antibodies to S. cerevisiae IgG (igg.asca) among 503 CD patients. FA, frequency affected; FU, frequency unaffected; L95 and U95, lower and upper 95th confidence interval. (C) IgG ASCA and antiflagellin (cbir) IgG responses were assessed in the sera from rs3732378 homozygous (AA), heterozygous (AG), and control (GG) CD patients by means of ELISA. Dots represent individual patients, and bars represent mean. (D) IgG responses against different commensal fungi. C. albicans, Pichia kudrazevii, S. cerevisiae, Aspergillus amstellodamii, Wallemia sebi, and Malassezia restricta were assessed. Dots represent individual patients, and bars represent mean. Statistical analysis: *P < 0.05, **P < 0.01, ***P < 0.001; Mann-Whitney test in (D) and one-way ANOVA in (C).

We identified a specific subset of gut-resident phagocytes—namely, the CX3CR1+ MNPs—that are able to recognize and respond to the gut mycobiota in a Syk-dependent manner. CX3CR1+ MNPs can influence adaptive immune responses to gut fungi and control the mycobiota during experimental colitis. In humans, we found that a CX3CR1 polymorphism is strongly associated with a decrease of antifungal antibody responses in CD patients. CX3CR1 T280M is a common polymorphism [23.3% heterozygous and 4.4% homozygous (30)] and has been previously associated with extraintestinal inflammatory diseases (28, 29). Conceivably, gut mycobiota and CX3CR1-dependent immune responses might further contribute to extraintestinal manifestations of inflammatory diseases. In support of this notion, antifungal antibodies are increased in patients with alcoholic liver disease, spondyloarthritis, Graves’ disease, and systemic lupus erythematosus (69). Altogether, our findings provide evidence for the influence of gut fungal communities on both local and systemic immunity, which is mediated by the recognition of intestinal fungi by CX3CR1+ MNPs.

Supplementary Materials

Materials and Methods

Figures S1 to S22

Tables S1 and S2

References (3151)

Movie S1

References and Notes

Acknowledgments: This work was funded by the U.S. National Institutes of Health (grants DK113136, DK098310, and AI123819 to I.D.I; P01 DK046763 and U01 DK062413 to D.P.B.M.), Infect-ERA FUNCOMPATH (PCIN-2014-052 to J.P), Ministerio de Economía y Competitividad (BIO2015-6477-P to J.P.), Swiss National Science Foundation (fellowship P2ZHP3_164850 to I.L), Kenneth Rainin Foundation (Innovator and Breakthrough awards to I.D.I), and support from the Jill Roberts Institute for Research in IBD. The data presented in this study are tabulated in the main text and supplementary materials. Microbiota sequencing data are deposited in National Center for Biotechnology Information (NCBI) Sequence Read Archive (SRA;, run numbers SRP124782, SRP124783, SRP124736, and SRP124742). RNA-seq data are deposited in the NCBI Gene Expression Omnibus under accession no. GSE106594.

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