Project description:We set up to characterize the global transcriptome of splenic follicular (FO) B cells from control wild type (Wt) and Igha-deficient (IgAKO) mice with the aim of gaining new insights into how translocated gut antigens may impair IgG production to vaccines in the absence of IgA. Splenic Marginal zone (MZ) B cells were also included in this study, as IgA deficiency impaired IgG responses to T-independent immunogens as well.

Project description:In humans, several grams of IgA are secreted every day in the intestinal lumen. While only one IgA isotype exists in mice, humans secrete IgA1 and IgA2, whose respective relations with the microbiota remain elusive. We compared the binding patterns of both polyclonal IgA subclasses to commensals and glycan arrays and determined the reactivity profile of native human monoclonal IgA antibodies. While most commensals are dually targeted by IgA1 and IgA2 in the small intestine, IgA1+IgA2+ and IgA1-IgA2+ bacteria coexist in the colon lumen, where Bacteroidetes is preferentially targeted by IgA2. We also observed that galactose-? terminated glycans are almost exclusively recognized by IgA2. Although bearing signs of affinity maturation, gut-derived IgA monoclonal antibodies are cross-reactive in the sense that they bind to multiple bacterial targets. Private anticarbohydrate-binding patterns, observed at clonal level as well, could explain these apparently opposing features of IgA, being at the same time cross-reactive and selective in its interactions with the microbiota.

Project description:The host genotype has been proposed to contribute to individually composed bacterial communities in the gut. To provide deeper insight into interactions between gut bacteria and their host, we associated germ-free C3H and C57BL/10 mice with intestinal bacteria from a C57BL/10 donor mouse. Analysis of microbiota similarity between the experimental animals with denaturing gradient gel electrophoresis (DGGE) 13 weeks after association revealed the development of a mouse strain specific microbiota. Gene expression in the colonic mucosa was analyzed with a microarray approach taking advantage of a modified Affymetrix mouse genome chip. We detected 202 genes whose expression differed significantly by a factor of < 2. Application of bioinformatics tools demonstrated that functional terms including signaling/secretion, lipid degradation/catabolism, guanine nucleotide/guanylate binding and immune response were significantly enriched in differentially expressed genes. We had a closer look at the 56 genes with expression differences of < 4 and observed a higher expression in C57BL/10 mice of the genes coding for toll-like receptor 1 (4-fold) and angiogenin 4 (33-fold) which are involved in the recognition and response to gut bacteria. In contrast, a 70-fold higher expression of the phospholipase A2, group IIA-encoding gene (Pla2g2a) was detected in C3H mice. In addition, a number of interferon-inducible genes were higher expressed in C3H than in C57BL/10 mice including Gbp1 (18-fold), Mal (7-fold), Oasl2 (7-fold), Ifi202b (7-fold), Rtp4 (6-fold), Ly6g6c (5-fold), Ifi27l2a (5-fold), Usp18 (5-fold), Ifit1 (5-fold), Ifi44 (4-fold), and Ly6g (4-fold) indicating that these cytokines play an essential role in microbiota regulation. However, genes coding for interferons, their receptors or factors involved in interferon signaling pathways were not differentially expressed between the two mouse strains. Taken together, our study confirms that the host genotype is involved in the establishment of host-specific bacterial communities in the gut. Based on expression differences after colonization with the same bacterial inoculum, we propose that Pla2g2a and interferon-dependent genes may contribute to this phenomenon. Total RNA was extracted from the colonic mucosa and hybridization was performed using 12.5M-BM- M-bM-^@M-^SM-BM- 20M-BM- M-BM-5g of cDNA on a customized Affymetrix nugomm 1a520177 chip.

Project description:Antiviral Abs, for example those produced in response to influenza virus infection, are critical for virus neutralization and defense against secondary infection. While the half-life of Abs is short, Ab titers can last a lifetime due to a subset of the Ab-secreting cells (ASCs) that is long lived. However, the mechanisms governing ASC longevity are poorly understood. Here, we have identified a critical role for extrinsic cytokine signals in the survival of respiratory tract ASCs in a mouse model of influenza infection. Irradiation of mice at various time points after influenza virus infection markedly diminished numbers of lung ASCs, suggesting that they are short-lived and require extrinsic factors in order to persist. Neutralization of the TNF superfamily cytokines B lymphocyte stimulator (BLyS; also known as BAFF) and a proliferation-inducing ligand (APRIL) reduced numbers of antiviral ASCs in the lungs and bone marrow, whereas ASCs in the spleen and lung-draining lymph node were surprisingly unaffected. Mice deficient in transmembrane activator and calcium-modulator and cyclophilin ligand interactor (TACI), a receptor for BLyS and APRIL, mounted an initial antiviral B cell response similar to that generated in WT mice but failed to sustain protective Ab titers in the airways and serum, leading to increased susceptibility to secondary viral challenge. These studies highlight the importance of TACI signaling for the maintenance of ASCs and protection against influenza virus infection.

Project description:The host genotype has been proposed to contribute to individually composed bacterial communities in the gut. To provide deeper insight into interactions between gut bacteria and their host, we associated germ-free C3H and C57BL/10 mice with intestinal bacteria from a C57BL/10 donor mouse. Analysis of microbiota similarity between the experimental animals with denaturing gradient gel electrophoresis (DGGE) 13 weeks after association revealed the development of a mouse strain specific microbiota. Gene expression in the colonic mucosa was analyzed with a microarray approach taking advantage of a modified Affymetrix mouse genome chip. We detected 202 genes whose expression differed significantly by a factor of < 2. Application of bioinformatics tools demonstrated that functional terms including signaling/secretion, lipid degradation/catabolism, guanine nucleotide/guanylate binding and immune response were significantly enriched in differentially expressed genes. We had a closer look at the 56 genes with expression differences of < 4 and observed a higher expression in C57BL/10 mice of the genes coding for toll-like receptor 1 (4-fold) and angiogenin 4 (33-fold) which are involved in the recognition and response to gut bacteria. In contrast, a 70-fold higher expression of the phospholipase A2, group IIA-encoding gene (Pla2g2a) was detected in C3H mice. In addition, a number of interferon-inducible genes were higher expressed in C3H than in C57BL/10 mice including Gbp1 (18-fold), Mal (7-fold), Oasl2 (7-fold), Ifi202b (7-fold), Rtp4 (6-fold), Ly6g6c (5-fold), Ifi27l2a (5-fold), Usp18 (5-fold), Ifit1 (5-fold), Ifi44 (4-fold), and Ly6g (4-fold) indicating that these cytokines play an essential role in microbiota regulation. However, genes coding for interferons, their receptors or factors involved in interferon signaling pathways were not differentially expressed between the two mouse strains. Taken together, our study confirms that the host genotype is involved in the establishment of host-specific bacterial communities in the gut. Based on expression differences after colonization with the same bacterial inoculum, we propose that Pla2g2a and interferon-dependent genes may contribute to this phenomenon.

Project description:The mechanism to maintain homeostasis of the gut microbiota remains largely unknown despite its critical role in the body defense. In the intestines of mice with deficiency of activation-induced cytidine deaminase (AID), the absence of hypermutated IgA is partially compensated for by the presence of large amounts of unmutated IgM and normal expression levels of defensins and angiogenins. We show here a predominant and persistent expansion of segmented filamentous bacteria throughout the small intestine of AID(-/-) mice. Reconstitution of lamina propria IgA production in AID(-/-) mice recovered the normal composition of gut flora and abolished the local and systemic activation of the immune system. The results indicate that secretions of IgAs rather than innate defense peptides are critical to regulation of commensal bacterial flora and that the segmented filamentous bacteria antigens are strong stimuli of the mucosal immune system.

Project description:Flagellins from commensal bacteria can be weak Toll-like receptor (TLR)5 agonists despite high affinity binding to TLR5, ligands we termed “silent flagellins”. To determine if silent flagellins are detectable in the human gut, endogenous flagellins produced by the microbiota were isolated from stool obtained from a healthy adult female donor. TLR5 was used as bait to enrich for silent flagellins and TLR5-bound flagellins were identified by searching peptides against a custom flagellin database built from metagenome sequences.

Project description:Serum immunoglobulin A (IgA) antibodies are readily detected in mice and people, but the mechanisms underlying the induction of serum IgA and its role in host protection remain uncertain. We report that select commensal bacteria induce several facets of systemic IgA-mediated immunity. Exposing conventional mice to a unique but natural microflora that included several members of the Proteobacteria phylum led to T cell-dependent increases in serum IgA levels and the induction of large numbers of IgA-secreting plasma cells in the bone marrow. The resulting serum IgA bound to a restricted collection of bacterial taxa, and antigen-specific serum IgA antibodies were readily induced after intestinal colonization with the commensal bacterium Helicobacter muridarum. Finally, movement to a Proteobacteria-rich microbiota led to serum IgA-mediated resistance to polymicrobial sepsis. We conclude that commensal microbes overtly influence the serum IgA repertoire, resulting in constitutive protection against bacterial sepsis.

Project description:Aim: Microbial colonization of the intestine in newborns is a critical event that regulates host physiology with lifelong consequences. However, there is a need to identify microbial molecules and mechanisms that play a role in this process. We aimed to elucidate the effects of flagellin, an important immunomodulatory component involved in bacterial motility, on intestinal epithelial functions. Methods: Germfree mice were colonized with synthetic bacterial communities, including a flagellated mouse gut isolate of Escherichia coli or a ΔfliC mutant thereof that lacks flagella. The offspring of these mice were studied at 7 days of age by single-cell RNA sequencing of epithelial cells isolated from the small intestine. Results: Enterococcus faecalis was the most dominant species in the small intestine of newborn mice. Blautia pseudococcoides was detected at low relative abundances. Colonization by either E. coli strain reduced the relative abundance of E. faecalis to 10% on average, and E. coli became the dominant member, with no substantial differences between mice colonized with the wildtype or mutant strain. The distribution of cell types within the small intestinal epithelium was skewed toward specialized cells (goblet, enteroendocrine, stem cells) at the expense of enterocytes in mice colonized with flagellated bacteria. These mice were characterized by higher expression of genes involved in cell-cell interactions (Npl, Epcam) and responses to infection (Ctsl) in enterocytes and enhanced translation (ribosomal proteins) in stem cells. In contrast, genes involved in lipid homeostasis (transport and metabolism; Apoc 2/4, Dgat2, Fabp 1/2, Mttp) in all cell types and inflammatory and androgen-related pathways in specialized cell types were less expressed in epithelial cells exposed to wildtype E. coli. Conclusion: These findings suggest that early life exposure to flagellated commensal bacteria influences cellular processes underlying tissue metabolism and remodeling in the small intestine.

Project description:The influence of the microbiota on viral transmission and replication is well appreciated. However, its impact on retroviral pathogenesis outside of transmission/replication control remained unknown. Using Murine Leukemia Virus (MuLV), we found that some commensal bacteria promoted the development of leukemia induced by this retrovirus. The promotion of leukemia development by commensals was due to suppression of the adaptive immune response through upregulation of several negative regulators of immunity. These negative regulators included Serpinb9b and Rnf128, which are associated with a poor prognosis of some spontaneous human cancers. Upregulation of Serpinb9b was mediated by sensing of bacteria by NOD1/NOD2/RIPK2 pathway. This work describes a novel mechanism by which the microbiota enhances tumorigenesis within gut-distant organs and points at potential new targets for cancer therapy.