Immunoglobulin A is the dominant antibody isotype found in mucosal secretions and enforces host-microbiota symbiosis in mice, yet selective IgA-deficiency (sIgAd) in humans is often described as asymptomatic. Here, we determined the effects of IgA deficiency on human gut microbiota composition and evaluated the possibility that mucosal secretion of IgM can compensate for a lack of secretory IgA. We used 16S rRNA gene sequencing and bacterial cell sorting to evaluate gut microbiota composition and taxa-specific antibody coating of the gut microbiota in 15 sIgAd subjects and matched controls. Despite the secretion of compensatory IgM into the gut lumen, sIgAd subjects displayed an altered gut microbiota composition as compared to healthy controls. These alterations were characterized by a trend towards decreased overall microbial diversity as well as significant shifts in the relative abundances of specific microbial taxa. While secretory IgA in healthy controls targeted a defined subset of the microbiota via high-level coating, compensatory IgM in sIgAd subjects showed less specificity than IgA and bound a broader subset of the microbiota. We conclude that IgA plays a critical and non-redundant role in controlling gut microbiota composition in humans and that secretory IgA has evolved to maintain a diverse and stable gut microbial community.
Oral treatment with a broad spectrum antibiotic modifies gut microbiota composition and promotes anti-inflammatory response, suggesting that manipulation of gut microbiota can be a powerful tool to modulate the course of CS.
Carcinoembryonic antigen (CEA), one of the most clinically important tumor markers, is mainly used in the post-surgical surveillance of patients with colorectal carcinomas. CEA belongs to a large protein family, which includes cross-reacting antigens, e.g., non-specific cross-reacting antigens (NCAs) and biliary glycoprotein (BGP) as well as pregnancy-specific glycoproteins (PSGs). The genes encoding these proteins can be subdivided into the CEA and PSG subgroups. The members of the subgroups share antigenic determinants and show high similarity in amino-acid sequences. Their derived secondary structures show them to belong to the immunoglobulin superfamily. Due to the close relationship of the members of the CEA subgroup, it is very difficult to distinguish between the individual members with MAbs. Here we have used flow cytometric analysis of transfectants expressing individual members of the CEA subgroup as an alternative approach to determine the specificities of 13 MAbs. This allows us to examine the specificities of these antibodies for members of the CEA family, even of those which have not yet been characterized at the protein level. In addition, binding of the MAbs to NCAs expressed by polymorphonuclear cells (PMN) was tested by Western-blot analysis, immunoprecipitation and flow cytometry. Four antibodies bound exclusively to NCA-50/90 and one MAb (80H3) only to NCA-95. MAb 4/3/17 recognizes CEA and BGP on the surface of transfectants and NCA-160 from granulocytes. We assume that NCA-160 is a product of the BGP gene. On granulocytes, which do not express CEA, MAb 4/3/17 is specific for NCA-160 (BGP). Mutual inhibition of the MAbs binding to NCA-50/90 revealed 3 different epitope groups.
Background
Subcutaneous allergen-specific immunotherapy is a standard route for the immunotherapy of allergic diseases. It modulates the course of allergy and can generate long-term remission. However, subcutaneous allergen-specific immunotherapy can also induce anaphylaxis in some patients, and therefore additional routes of administration should be investigated to improve the safety and tolerability of immunotherapy.
Objective
We sought to determine whether epicutaneous treatment with antigen in the presence of a Toll-like receptor 9 agonist can suppress TH2-mediated responses in an antigen-specific manner.
Methods
Epicutaneous immunization was performed by applying a skin patch soaked with ovalbumin (OVA) plus CpG, and its suppressor activity was determined by using the mouse model of atopic dermatitis. Finally, adoptive cell transfers were implemented to characterize the regulatory cells that are induced by epicutaneous immunization.
Results
Epicutaneous immunization with OVA and CpG reduces the production of OVA-specific IgE and increases the synthesis of OVA-specific IgG2a antibodies in an antigen-specific manner. Moreover, eosinophil peroxidase activity in the skin and production of IL-4, IL-5, IL-10, and IL-13 are suppressed. The observed reduction of IgE synthesis is transferable with T-cell receptor (TCR) αβ+CD4+CD25− cells, whereas IgG2a production is dependent on both TCRαβ+ and TCRγδ+ T cells. Further experiments show that the described phenomenon is myeloid differentiation primary response 88, IFN-γ, and IL-17A dependent. Finally, the results suggest that epicutaneous immunization with OVA and CpG decreases the synthesis of OVA-specific IgE and skin eosinophil peroxidase activity in mice with ongoing skin allergy.
Conclusion
Epicutaneous application of protein antigen in the presence of adjuvant could be an attractive needle-free and self-administered immunotherapy for allergic diseases.
Background: Epicutaneous (EC) immunization with protein antigens has been shown to induce antigen nonspecific suppression of subsequent T cell-dependent contact hypersensitivity (CS) reactions after active immunization. The aim of this work was to test if EC application of Toll-like receptor (TLR) ligands together with protein antigen could reverse suppression of CS. Methods: Mice were EC immunized by applying gauze patches soaked with a solution of protein antigen alone or in the presence of crude bacterial material (bacterial lysates or heat-killed bacteria) or purified TLR ligands and then tested for CS response. To test if reversal of EC-induced suppression is antigen-specific, mice were patched with TNP- or OX-substituted mouse Ig alone or together with LPS and then tested for CS with corresponding or non-cross-reacting hapten. Influence of EC immunization on cytokine production by lymph node cells was measured by ELISA. Results: EC immunization with protein antigen induces antigen nonspecific suppression that can be reversed by crude bacterial material as well as purified TLR-2, TLR-3, TLR-4, and TLR-9 ligands. The effect of TLR-4 ligand LPS was not observed in the Tlr-4 mutant C3H/HeJ mouse, indicating that this effect was dependent upon intact TLR-4 signaling. Unlike the antigen nonspecific suppression of CS by EC immunization with antigen alone, the reversal of suppression by TLR ligands was specific for the protein antigen applied in the EC protocol. Conclusions: Our results strongly suggest that EC immunization with protein antigen together with TLR ligands induces a particular antigen-specific cell population, akin to previously described contrasuppressor cells, which protects immune cells against the action of suppressor cells but have no direct influence on antigen nonspecific suppressor cells induced by antigen alone.
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