Segmented Filamentous Bacteria Provoke Lung Autoimmunity by Inducing Gut-Lung Axis Th17 Cells Expressing Dual TCRs

Bradley, Caroline; Teng, Fei; Felix, Krysta M.; Sano, Teruyuki; Naskar, Debdut; Block, Katharine E.; Huang, Haochu; Knox, Kenneth S.; Littman, Dan R.; Wu, Ho‐Ting

doi:10.1016/j.chom.2017.10.007

Cited by 149 publications

(121 citation statements)

References 46 publications

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“…We anticipate that there are additional factors and immune cell networks downstream of CX3CR1 + MNPs that may contribute to the effect of gut fungal dysbiosis on AAD. A recent study has indeed demonstrated that lung autoimmune inflammation can be triggered by segmented filamentous bacteria gut-lung axis Th17 cell induction (Bradley et al, 2017). While our study exploring the innate immune events affecting lung allergy during gut fungal dysbiosis, it will be important for future studies to determine how adaptive antifungal responses generated upon CX3CR1 + MNP activation affect systemic and distal site immunity.…”

Section: Discussionmentioning

confidence: 99%

“…While our study exploring the innate immune events affecting lung allergy during gut fungal dysbiosis, it will be important for future studies to determine how adaptive antifungal responses generated upon CX3CR1 + MNP activation affect systemic and distal site immunity. Gut–lung axis migration of T cells, innate lymphoid cells or inflammation-related factors have been shown to occur (Bradley et al, 2017; Huang et al, 2018; Kim et al, 2014) and could be possible avenues to pursue in future studies investigating the role of fungal dysbiosis on peripheral immunity and inflammatory diseases at gut distal sites.…”

Section: Discussionmentioning

confidence: 99%

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Response to Fungal Dysbiosis by Gut-Resident CX3CR1+ Mononuclear Phagocytes Aggravates Allergic Airway Disease

Leonardi

Semon

et al. 2018

Cell Host & Microbe

101

104

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Summary Sensing of the gut microbiota, including fungi, regulates mucosal immunity. Whether fungal sensing in the gut can influence immunity at other body sites is unknown. Here we show that fluconazole-induced gut fungal dysbiosis has persistent effects on allergic airway disease in a house dust mite challenge model. Mice with a defined community of bacteria, but lacking intestinal fungi were not susceptible to fluconazole-induced dysbiosis, while colonization with a fungal mixture recapitulated the detrimental effects. Gut resident mononuclear phagocytes (MNPs) expressing the fractalkine receptor CX3CR1 were essential for the effect of gut fungal dysbiosis on peripheral immunity. Depletion of CX3CR1+ MNPs or selective inhibition of Syk signaling downstream of fungal sensing in these cells ameliorated lung allergy. These results indicate that disruption of intestinal fungal communities can have persistent effects on peripheral immunity and aggravate disease severity through fungal sensing by gut resident CX3CR1+ MNPs.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Response to Fungal Dysbiosis by Gut-Resident CX3CR1+ Mononuclear Phagocytes Aggravates Allergic Airway Disease

Leonardi

Semon

et al. 2018

Cell Host & Microbe

101

104

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“…SFB‐specific Th17 cells are found in the peripheral lymphoid organs beyond the intestine, which could potentially contribute to the vulnerability to some autoimmune diseases in genetically susceptible hosts . In addition to previously proposed molecular mimicry and bystander activation theories as to the mechanism for microbiota‐reactive T cells to trigger autoimmunity, a recent study in a lung autoimmune mouse model showed that SFB selectively expanded Th17 cells that expressed dual TCR, one of which recognized SFB peptide and the other directed at a self‐antigen …”

Section: T Cell–gut Microbiota Interactionsmentioning

confidence: 99%

Adaptive immune education by gut microbiota antigens

2018

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SummaryHost-microbiota mutualism has been established during long-term coevolution. A diverse and rich gut microbiota plays an essential role in the development and maturation of the host immune system. Education of the adaptive immune compartment by gut microbiota antigens is important in establishing immune balance. In particular, a critical time frame immediately after birth provides a 'window of opportunity' for the development of lymphoid structures, differentiation and maturation of T and B cells and, most importantly, establishment of immune tolerance to gut commensals. Depending on the colonization niche, antigen type and metabolic property of different gut microbes, CD4 T-cell responses vary greatly, which results in differentiation into distinct subsets. As a consequence, certain bacteria elicit effector-like immune responses by promoting the production of pro-inflammatory cytokines such as interferon-c and interleukin-17A, whereas other bacteria favour the generation of regulatory CD4 T cells and provide help with gut homeostasis. The microbiota have profound effects on B cells also. Gut microbial exposure leads to a continuous diversification of B-cell repertoire and the production of Tdependent and -independent antibodies, especially IgA. These combined effects of the gut microbes provide an elegant educational process to the adaptive immune network. Contrariwise, failure of this process results in a reduced homeostasis with the gut microbiota, and an increased susceptibility to various immune disorders, both inside and outside the gut. With more definitive microbial-immune relations waiting to be discovered, modulation of the host gut microbiota has a promising future for disease intervention.

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“…There is also growing evidence that gut-lung axis and gut microbiota induced inflammation may lead to the development of chronic inflammatory disorders of the respiratory as well as GI tract [111]. It has been demonstrated that autoimmunity of the lungs can be driven by Th17 cells that are induced by SFB in the gut by promoting inducible bronchus associated lymphoid tissues, a type of ectopic lymphoid tissues in the lung of rheumatoid arthritis patients [112]. Therefore, manipulating the gut microbiota may also be useful in the treatment of respiratory diseases.…”

Section: The Respiratory Microbiome-asthma and Respiratory Diseasesmentioning

confidence: 99%

The microbiota and immune‐mediated diseases: Opportunities for therapeutic intervention

Fitzgibbon

Mills

2020

Eur J Immunol

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A multitude of diverse microorganisms, termed the microbiota, reside in the gut, respiratory tract, skin, and genital tract of humans and other animals. Recent advances in metagenomic sequencing and bioinformatics have enabled detailed characterization of these vital microbial communities. Studies in animal models have uncovered vital previously unrecognized roles for the microbiota in normal function of the immune responses, and when perturbed, in the pathogenesis of diseases of the gastrointestinal tract and lungs, but also at distant sites in the body including the brain. The composition of gut and respiratory microbiota can influence systemic inflammatory responses that mediate asthma, allergy, inflammatory bowel disease, obesity‐related diseases, and neurodevelopmental or neurodegenerative conditions. Experiments in mouse models as well as emerging clinical studies have revealed that therapeutic manipulation of the microbiota, using fecal microbiota transplantation, probiotics, or engineered probiotics represent effective nontoxic approaches for the treatment or prevention of Clostridium difficile infection, allergy, and autoimmune diseases and may enhance the efficacy of certain cancer immunotherapeutics. This review discusses how commensal bacteria can influence immune responses that mediate a range of human diseases and how the microbiota are being targeted to treat these diseases, especially those resistant to pharmacological therapies.

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Segmented Filamentous Bacteria Provoke Lung Autoimmunity by Inducing Gut-Lung Axis Th17 Cells Expressing Dual TCRs

Cited by 149 publications

References 46 publications

Response to Fungal Dysbiosis by Gut-Resident CX3CR1+ Mononuclear Phagocytes Aggravates Allergic Airway Disease

Response to Fungal Dysbiosis by Gut-Resident CX3CR1+ Mononuclear Phagocytes Aggravates Allergic Airway Disease

Adaptive immune education by gut microbiota antigens

The microbiota and immune‐mediated diseases: Opportunities for therapeutic intervention

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