Добірка наукової літератури з теми "Segmented filamentous bacteria (SFB)"

ABSTRACT Segmented filamentous bacteria (SFB) are found in multiple species and play an important role in the development of mucosal immunity. The mechanism by which the bacteria interact with the immune system has not been well defined. We provide morphologic evidence of direct interaction between SFB and intraepithelial mononuclear cells.

Abstract IgA is a component of the mucosal barrier surface and plays an important part in maintaining separation between the host and the commensal microbiota. Mucosal IgA responses are considered short-lived and restricted to mucosal sites with no systemic dissemination. However, there is little known about the regulation and maintenance of IgA secreting plasma cells (PCs) and how they compare to bone marrow PCs. Interestingly, we find that IgA secreting PCs make up a large proportion of the bone marrow PC pool in mice colonized with segmented filamentous bacteria (SFB), but not in germ-free or conventional SFB free mice. The increase in IgA PCs in the bone marrow correlates with a large increase in serum IgA. The co-housing of SFB free mice with SFB colonized mice results in significantly increased levels of IgA in the serum and higher numbers of IgA+ PCs in the bone marrow. This process is dependent upon T cells, because SFB colonized TCRβ-/-δ-/- mice have similar levels of IgA bone marrow PCs as wild-type SFB free mice. The SFB associated increase of IgA antibody titers coincides with the ability to detect commensal bacteria specific IgA in the serum. These data suggest that the induction of systemic IgA is influenced by the composition of the commensal microbiota. These results highlight the need for greater understanding of the role commensal bacteria play in systemic immunity, which could impact oral vaccine development and autoimmunity.

Unlike most other indigenous bacteria, segmented filamentous bacteria (SFB) are potent activators of the mucosal immune system. SFB are strongly anchored to the epithelial cells of the small intestine where they have a preference for mucosal lymphoid epithelium. Since SFB are only present in high numbers shortly after weaning, it was investigated whether an SFB-induced immune reaction results in the removal of these bacteria from the small intestine. A correlation was found between age and colonization levels in the small intestines of SFB monoassociated Swiss mice. Five-week-old athymic BALB/c (nu/nu) mice showed lower colonization levels than their heterozygous littermates, but the opposite was found at the age of 12 weeks. However, SFB inoculation of germfree Swiss mice resulted in higher colonization levels in 5-week-old mice when compared with 4-month-old mice. We conclude that SFB colonization levels in the small intestine are likely influenced by the activity of the mucosal immune system. However, an additional age-dependent factor that modulates SFB colonization levels cannot be excluded.Key words: segmented filamentous bacteria, small intestine, gut-associated lymphoid tissue.

AbstractSegmented filamentous bacteria (SFB) are present in various animal species including pigs. The aim of this work was to analyze the occurrence of SFB in different parts of the gastrointestinal tract of piglets of different ages. A total of 377 DNA extracts from stomach, jejunum, ileum, cecum and colon digesta, and from feces collected on different time points, originating from 155 animals, were screened by qPCR method with primers specific for the SFB. SFB sequences were detected in 74 of 377 samples (19.6%) from 155 animals in total. SFB were most abundant in ileum (50.0%), cecum (45.0%), and colon (37.0%), followed by feces (14.6%). SFB prevalence in sows was 12.9% (13/101) and 75.9% (41/54) in individual piglets. Of the 41 SFB-positive piglets, only two samples were from pre-weaning animals, while the rest of samples originated from post-weaning piglets. SFB sequences are abundant in post-weaning piglets, but not in suckling or adult animals. They are most abundant in the ileum and cecum of pigs. Further studies are warranted to reveal the role of SFB in pigs.

Abstract Background Crohn’s disease (CD)-like inflammation in TNFdeltaARE mice (ARE) mice is triggered by dysbiotic gut microbial communities. Similar to the therapeutic effect of exclusive enteral nutrition in CD, dietary intervention using semi-synthetic experimental diet prevents disease development in ARE mice. The aim of this study is to identify the causal microbial cues responsible for CD-like inflammation and to dissect the protective role of diet in ARE mice. Methods Bacterial communities in ARE and wildtype (WT) mice were profiled by 16S rRNA gene sequencing, FISH and qPCR. Germfree WT and ARE mice were colonized with segmented filamentous bacteria (SFB) from dysbiotic ARE mice. Disease activity, cytokine expression, mucosal immune cell infiltrates as well as Paneth and goblet cells phenotypes were assessed in murine ileal and colonic tissue. To assess the influence of diet on disease development, ARE mice were fed either chow, purified semi-synthetic experimental diet (SED) or fiber-rich diet. Impact of SFB on ileo-colonic inflammation was tested in additional mouse models (XIAP-/- and IL10 -/-). Mucosal biopsies from adult and pediatric IBD patients (N=407) were screened for the presence of human SFB using SFB-specific PCR primers. Results Under specific pathogen-free (SPF) conditions, ARE mice developed CD-like ileal inflammation which correlated strongly with increasing abundance of SFB. Mono-colonization of germfree ARE mice with SFB resulted in severe enterocolitis. Parallel to high tissue levels of TNF and IL-17, SPF-mediated inflammation was associated with neutrophil infiltration and the expansion of IFNγ expressing Th1 cells in the mucosa. Loss of Paneth and goblet cell function allowed SFB to penetrate mucus layers towards the epithelium. SED eradicated SFB and completely abolished inflammation in ARE mice. In contrast, fiber-rich diet partially restored SFB colonization and led to increased levels of inflammatory cytokines. SFB mono-colonization of GF XIAP-/- and IL10 -/- failed to induce inflammation, emphasizing host specificity to the mucosa-adherent SFB. Presence of SFB was confirmed in 12 ileal and 11 colonic mucosal biopsies from IBD patients with active or inactive disease. Conclusion We identified a novel pathogenic role of SFB in driving severe CD-like ileo-colonic inflammation characterized by loss of Paneth and goblet cell functions in ARE mice. Detection of SFB in mucosal biopsies of patients with IBD opens new perspectives about therapeutic strategies targeting SFB-mediated processes. Purified diet antagonized SFB colonization and prevented disease development in ARE mice in contrast to fiber-rich diet, clearly demonstrating the important role of diet in modulating a novel IBD-relevant pathobiont.

Abstract Th17 cells have significant roles in maintaining homeostasis and regulating host defense against various pathogens in our bodies. Our laboratory initially identified segmented filamentous bacteria (SFB) as a unique commensal that is sufficient for Th17 cell differentiation and promotion of Th17-dependent autoimmune diseases such as a mouse model of spontaneous arthritis. The molecular and cellular requirements of SFB-induced Th17 cell differentiation are still unclear. To understand the whole process of Th17 cells differentiation in vivo, we developed SFB-specific T cell receptor transgenic (7B8) mice. We can trace SFB-specific Th17 cell differentiation and response by transferring fluorescently-labeled 7B8 naïve T cells into SFB-gavaged host mice. Using this approach, we have elucidated the requirements for cytokines and antigen presenting cells (APCs) to understand the process of Th17 cell differentiation. Here, we describe that initial induction and expansion of Th17 cells occurs in mesenteric lymph nodes (MLN), and their subsequent migration to intestine is integrin β7-dependent. Although RORγt expression in Th17 cells is mainly dependent on IL-6 signaling in the MLN, IL-23R signaling also contributes to RORγt expression in Th17 cells in the ileum in the absence of IL-6. CD103+ CD11b+ APCs are not important for induction and initial expansion of SFB-specific Th17 cells in MLN, but play important roles in maintenance of SFB-specific Th17 cells in the ileum. Taken together, these results indicate that Th17 cell differentiation proceeds in multiple discrete stages.

Abstract Blockade or genetic deletion of IL-17RA resulted in marked increases in IL-17 response by T-cells. We hypothesize that the hyper Th17 response in IL-17 deficient mice is due to alterations of the gut microbiome particularly overgrowth of segmented filamentous bacteria (SFB). Our data shows that Il17ra-/- and Il17rc-/- mice have overgrowth of SFB (10 fold higher than WT.Taconic), suggesting a critical role of IL-17 signaling in SFB colonization. Higher SFB colonization in Il17ra-/- and Il17rc-/- mice results in expansion of IL-17A and IL-22 producing Th17 cells. As further evidence that this expansion was not T-cell intrinsic, we observed similar frequencies of IL-17 producing cells in WT and Il17ra-/- when naïve T-cells were polarized in vitro to Th17 cells. Furthermore, vancomycin depletion of SFB in Il17ra-/- mice resulted into fewer Th17 cells in the lamina propria and spleen, suggesting gut microflora responsible for hyper Th17 response. SFB-colony free WT mice with intact IL-17 signaling can control SFB overgrowth but IL-17 deficient mice could not following SFB inoculation. To further define the role of IL-17 in SFB colonization, we have generated SFB-free Il17ra conditional knockout (Il17rafl/flxe2a cre) mice. SFB-free Il17rafl/flxe2a cre mice are devoid of hyper Th17 responses, and SFB inoculation resulted into acquisition of hyper Th17 phenotype as observed in Il17ra-/-. Our data suggest that IL-17 signaling regulates SFB colonization and associated Th17 responses.

ABSTRACT The presence of microflora in the digestive tract promotes the development of the intestinal immune system. In this study, to evaluate the roles of two types of indigenous microbe, segmented filamentous bacteria (SFB) and clostridia, whose habitats are the small and large intestines, respectively, in this immunological development, we analyzed three kinds of gnotobiotic mice contaminated with SFB, clostridia, and both SFB and clostridia, respectively, in comparison with germfree (GF) or conventionalized (Cvd) mice associated with specific-pathogen-free flora. In the small intestine, the number of αβ T-cell receptor-bearing intraepithelial lymphocytes (αβIEL) increased in SFB-associated mice (SFB-mice) but not in clostridium-associated mice (Clost-mice). There was no great difference in Vβ usage among GF mice, Cvd mice, and these gnotobiotic mice, although the association with SFB decreased the proportion of Vβ6+ cells in CD8β− subsets to some extent, compared to that in GF mice. The expression of major histocompatibility complex class II molecules on the epithelial cells was observed in SFB-mice but not in Clost-mice. On the other hand, in the large intestine, the ratio of the number of CD4−CD8+ cells to that of CD4+ CD8−cells in αβIEL increased in Clost-mice but not in SFB-mice. On association with both SFB and clostridia, the numbers and phenotypes of IEL in the small and large intestines changed to become similar to those in Cvd mice. In particular, the ratio of the number of CD8αβ+ cells to that of CD8αα+ cells in αβIEL, unusually elevated in the small intestines of SFB-mice, decreased to the level in Cvd mice on contamination with both SFB and clostridia. The number of immunoglobulin A (IgA)-producing cells in the lamina propria was more elevated in SFB-mice than in Clost-mice, not only in the ileum but also in the colon. The number of IgA-producing cells in the colons of Clost-mice was a little increased compared to that in GF mice. Taken together, SFB and clostridia promoted the development of both IEL and IgA-producing cells in the small intestine and that of only IEL in the large intestine, respectively, suggesting the occurrence of compartmentalization of the immunological responses to the indigenous bacteria between the small and large intestines.

Th17 cells accrue in the intestine in response to particular microbes. In rodents, segmented filamentous bacteria (SFB) induce intestinal Th17 cells, but analogously functioning microbes in humans remain undefined. Here, we identified human symbiont bacterial species, in particularBifidobacterium adolescentis, that could, alone, induce Th17 cells in the murine intestine. Similar to SFB,B. adolescentiswas closely associated with the gut epithelium and engendered cognate Th17 cells without attendant inflammation. However,B. adolescentiselicited a transcriptional program clearly distinct from that of SFB, suggesting an alternative mechanism of promoting Th17 cell accumulation. Inoculation of mice withB. adolescentisexacerbated autoimmune arthritis in the K/BxN mouse model. Several off-the-shelf probiotic preparations that includeBifidobacteriumstrains also drove intestinal Th17 cell accumulation.

Segmented, filamentous bacteria (SFBs) form a group of bacteria with similar morphology and are identified on the basis of their morphology only. The relationships of these organisms are unclear as the application of formal taxonomic criteria is impossible currently due to the lack of an in vitro technique to culture SFBs. The intestine of laboratory animals such as mice, rats, chickens, dogs, cats and pigs is known to harbour SFBs. To see whether this extends to other animal species, intestines from 18 vertebrate species, including man, were examined. SFBs were detected with light microscopy in the cat, dog, rhesus monkey, crab-eating macaque, domestic fowl, South African claw-footed toad, carp, man, laboratory mouse and rat, wood mouse, jackdaw and magpie. These results suggest that non-pathogenic SFBs are ubiquitous in the animal kingdom. Among apparently identical animals, there was considerable variation in the degree of SFB colonization. It is suggested that SFB colonization could serve as a criterion of standardization of laboratory animals.

Disease has been identified as a major problem in the aquaculture industry for the welfare of the fish stocked as well as for its economic impact. The number of diseases affecting cultured fish has increased significantly during recent years with the emergence of several conditions that have added to the overall impact of disease on the industry. Frequently, a lack of scientific knowledge about these diseases is compounded by an absence of effective treatment and control strategies. This has been the case with rainbow trout gastroenteritis (RTGE), an emerging disease of rainbow trout (Oncorhynchus mykiss Walbaum). This study investigated several aspects related to its aetiology and control. A retrospective survey of UK rainbow trout farmers was undertaken to ascertain the extent and severity of RTGE in the UK as well as to identify RTGE risk factors at the site level. Participants in this study accounted for over 85% of UK rainbow trout production in 2004. It was found that the total number of RTGE-affected sites had risen from 2 in the year 2000 to 7 in 2005. The disease was only reported from sites producing more than 200 tonnes of trout/year for the table market. Analysis of risk factors associated with RTGE at the site level showed that this syndrome was associated with large tonnage and rapid production of rainbow trout for the table market. The data collected during this study enabled the identification of those sites that were most likely to present with RTGE the following year and this information was used to study the epidemiology of RTGE at the unit level. A prospective longitudinal study was undertaken in 12 RTGE-affected UK sites. It described in detail the impact, presentation, current control strategies and spread pattern of RTGE within affected UK sites. The risk factors associated with RTGE presence and severity were also investigated. Data were collected for each productive unit (i.e. cage, pond, raceway or tank) on the mortalities, fish origin, site management and environmental factors. RTGE was identified using a case definition based on gross pathological lesions. Analysis of these data revealed that RTGE behaved in an infectious manner. This conclusion was supported by the presence of a pattern typical of a propagating epidemic within affected units. Also, the risk of an unaffected unit becoming RTGE positive was increased if it had received fish from or was contiguous to a RTGE-affected unit. The presentation also suggested an incubation period of 20-25 days. Risk factor analysis identified management and environmental risk factors for RTGE, including high feed input and stressful events, which could be used to generate a list of control strategies. A study of the histopathological and ultrastructural presentation of RTGE was conducted. The location of segmented filamentous bacteria (SFB) and pathological changes found in affected fish were examined. Pyloric caeca were the digestive organ where SFB were found more frequently and in higher numbers, suggesting that this was the best location to detect SFB in RTGE-affected trout. Scanning and transmission electron microscopy revealed a previously undescribed interaction of SFB with the mucosa of distal intestine and pyloric caeca and this included the presence of attachment sites and SFB engulfment by enterocytes, as previously described in other host species. The SFB were not always adjacent to the pathological changes observed in the digestive tract of RTGE-affected trout. Such changes included cytoskeletal damage and osmotic imbalance of enterocytes, with frequent detachment. These observations suggested that if SFB are indeed the cause of RTGE their pathogenesis must involve the production of extracellular products. Analysis of the gross presentation and blood biochemistry in RTGE-affected fish was used to examine the patho-physiologic mechanisms of RTGE. To enable identification of positive RTGE cases for this study, a case definition was created from the information available on RTGE gross presentation in the literature. This case definition was assessed in a sample including 152 fish cases and 152 fish controls from 11 RTGE-affected UK sites, matched by unit of origin. The analysis of these fish using bacteriology, packed cell volume (PCV) and histopathology revealed that RTGE occurred simultaneously with other parasitic and bacterial diseases in a percentage of fish identified with this case definition. With the information gained after analysing the gross presentation, RTGE-affected fish without concurrent disease were selected for the study of the pathogenesis, which included blood biochemical analyses. These analyses revealed a severe osmotic imbalance, and a reduced albumin/globulin ratio suggesting selective loss of albumin, typical for a protein losing enteropathy. The role of the SFB “Candidatus arthromitus” in the aetiology of RTGE was assessed using a newly developed “C. arthromitus”-specific polymerase chain reaction assay (PCR) in conjunction with histological detection. This technique was applied to eight different groups of trout, including an RTGE-affected group and seven negative control groups. This analysis was conducted on DNA extracted from paraffin wax-embedded tissues as well as fresh intestinal contents. The results revealed the presence of “C. arthromitus” DNA in apparently healthy fish from sites where RTGE had never been reported. Additionally, SFB were observed histologically in two trout from an RTGE-free hatchery. These findings do not permit the exclusion of “C. arthromitus” as the aetiological agent for RTGE, although they suggest that the presence of these organisms in the digestive system of healthy trout is not sufficient to cause clinical disease, and therefore other factors are necessary. In conclusion, this study has used a multidisciplinary approach to the study of RTGE which has generated scientific information related to the epidemiology, pathogenesis and aetiology of this syndrome. The results of this project have suggested priority areas where further work is required, including experimental transmission of RTGE, field assessment of the control strategies proposed and further investigation into the aetiology of RTGE.