Your search keyword '"Segmented filamentous bacteria"' showing total 1,223 results

1. Dietary fibre fermentability quantitatively modulates faecal bacterial pathogens in sows and their offspring

Author

Grześkowiak, Łukasz, Vahjen, Wilfried, and Zentek, Jürgen

Published

2025

2. Layer segmented filamentous bacteria colonize and impact gut health of broiler chickens

Author

Jared Meinen-Jochum, Caleb J. Skow, and Melha Mellata

Subjects

segmented filamentous bacteria, Enterobacteriaceae, Campylobacter jejuni, intestinal barrier function, cytokines, broiler chickens, Microbiology, QR1-502

Abstract

ABSTRACT In commercial poultry farms, chicks hatch away from their progenitors from which they acquire key host-specific microbiota, like segmented filamentous bacteria (SFB) involved in gut maturation in early life. This study investigated whether providing chicken SFB to newly hatched broilers would increase their gut maturation and resistance to bacteria relevant to broiler and human health. One-day-old Ross308 broilers were orally treated with either phosphate-buffered saline (CON) or layer-derived SFB (D-SFB). On days 5, 10, 17, and 24, feces were collected to detect and enumerate SFB and Enterobacteriaceae. On days 8, 15, 22, and 29, birds were euthanized, intestinal samples were collected to detect and enumerate SFB through quantitative PCR (qPCR) and microscopy and expression of genes associated with gut immune function through reverse transcription-qPCR. This study showed that, despite their host specificity, layer SFB can colonize their genetically distinct relative broilers. Ileal SFB colonization was accelerated by a week with the SFB treatment and covered the proximal, medial, and distal sections of the ileum. Colonization of the ileum by SFB in early life highly activated gene expression of intestinal barrier proteins and cytokines, e.g., IL-10 and IFNγ but not IL-17. SFB treatment reduced the level of Enterobacteriaceae in the gut and provided superior resistance to intestinal and extraintestinal pathogens as tested in vitro. Overall, early gut colonization of SFB is imperative for the maturation of the gut immune system and the establishment of a homeostatic gut environment. Improving our understanding of gut immune maturation in food-producing animals is crucial for both human and animal health.IMPORTANCEIn commercial farms, newly hatched chicks may lack host-specific microbiota that help mature their gut immune system for lifelong health benefits. Here, introducing an avian segmented filamentous bacteria (SFB) to commercially sourced chickens orally at hatch accelerated SFB colonization of the ileum. Remarkably, SFB from layers were able to colonize broilers and enhance gut immune maturation, and this immunomodulation impacted the ability to increase intestinal and extraintestinal resistance to bacteria relevant to poultry and human health. With the antibiotic restrictions in animal production, strategies that will help mitigate infections are urgently needed. In summary, we developed a live prophylactic for newly hatched chicks to improve animal health and food safety. Due to the host specificity of SFB, our data highlight the importance of investigating the molecular mechanism of SFB interaction in their own host.

Published

2024

3. A purified diet affects intestinal epithelial proliferation and barrier functions through gut microbial alterations.

Author

Shiratori, Hiroaki, Hattori, Kisara M, Nakata, Kazuaki, Okawa, Takuma, Komiyama, Seiga, Kinashi, Yusuke, Kabumoto, Yuma, Kaneko, Yuria, Nagai, Motoyoshi, Shindo, Tomoko, Moritoki, Nobuko, Kawamura, Yuki I, Dohi, Taeko, Takahashi, Daisuke, Kimura, Shunsuke, and Hase, Koji

Subjects

*FATTY acid oxidation, *BACTERIAL colonies, *INNATE lymphoid cells, *DIET, *REDUCING diets

Abstract

The gut microbiota plays a crucial role in maintaining epithelial barrier function. Although multiple studies have demonstrated the significance of dietary factors on the gut microbiota and mucosal barrier function, the impact of a purified diet, which has long been used in various animal experiments, on intestinal homeostasis remains to be elucidated. Here, we compared the impact of two different types of diets, a crude diet and an AIN-93G-formula purified diet, on epithelial integrity and the gut microbiota. Purified diet-fed mice exhibited shorter villi and crypt lengths and slower epithelial turnover, particularly in the ileum. In addition, antimicrobial products, including REG3γ, were substantially decreased in purified diet-fed mice. Purified diet feeding also suppressed α1,2-fucosylation on the epithelial surface. Furthermore, the purified diet induced metabolic rewiring to fatty acid oxidation and ketogenesis. 16S ribosomal RNA gene sequencing of the ileal contents and mucus layer revealed distinct gut microbiota compositions between the purified and crude diet-fed mice. Purified diet feeding reduced the abundance of segmented filamentous bacteria (SFB), which potently upregulate REG3γ and fucosyltransferase 2 (Fut2) by stimulating group 3 innate lymphoid cells (ILC3s) to produce IL-22. These observations illustrate that the intake of a crude diet secures epithelial barrier function by facilitating SFB colonization, whereas a purified diet insufficiently establishes the epithelial barrier, at least partly owing to the loss of SFB. Our data suggest that the influence of purified diets on the epithelial barrier integrity should be considered in experiments using purified diets. [ABSTRACT FROM AUTHOR]

Published

2024

4. Select Gut Microbiota Impede Rotavirus Vaccine EfficacySummary

Author

Vu L. Ngo, Yanling Wang, Yadong Wang, Zhenda Shi, Robert Britton, Jun Zou, Sasirekha Ramani, Baoming Jiang, and Andrew T. Gewirtz

Subjects

Microbiota, Segmented Filamentous Bacteria, Seroconversion, Diseases of the digestive system. Gastroenterology, RC799-869

Abstract

Background & Aims: The protection provided by rotavirus (RV) vaccines is highly heterogeneous among individuals. We hypothesized that microbiota composition might influence RV vaccine efficacy. Methods: First, we examined the potential of segmented filamentous bacteria (SFB) colonization to influence RV vaccine efficacy in mice. Next, we probed the influence of human microbiomes on RV vaccination via administering mice fecal microbial transplants (FMTs) from children with robust or minimal RV vaccine responsiveness. Post-FMT, mice were subjected to RV vaccination followed by RV challenge. Results: SFB colonization induced a phenotype that was reminiscent of RV vaccine failure (ie, failure to generate RV antigens and, consequently, anti-RV antibodies following RV vaccination resulting in proneness to RV challenge after SFB levels diminished). FMTs from children to mice recapitulated donor vaccination phenotype. Specifically, mice receiving FMTs from high-responsive vaccinees copiously shed RV antigens and robustly generated anti-RV antibodies following RV vaccination. Concomitantly, such mice were impervious to RV challenge. In contrast, mice receiving FMTs from children who had not responded to RV vaccination exhibited only modest responses to RV vaccination and, concomitantly, remained prone to RV challenge. Microbiome analysis ruled out a role for SFB but suggested involvement of Clostridium perfringens. Oral administration of cultured C. perfringens to gnotobiotic mice partially recapitulated the RV vaccine non-responder phenotype. Analysis of published microbiome data found C. perfringens abundance in children modestly associated with RV vaccine failure. Conclusion: Microbiota composition influences RV vaccine efficacy with C. perfringens being one, perhaps of many, potential contributing taxa.

Published

2024

5. Segmented filamentous bacteria-based treatment to elicit protection against Enterobacteriaceae in Layer chickens.

Author

Meinen-Jochum, Jared, Ott, Logan C., and Mellata, Melha

Subjects

FILAMENTOUS bacteria, BACTERIAL colonies, ENTEROBACTERIACEAE, SALMONELLA typhimurium, ANTIMICROBIAL peptides, CHICKENS

Abstract

Introduction: Gut microbes like segmented filamentous bacteria (SFB) play a key role in gut maturation during early life, as demonstrated in humans and mice. Our previous study demonstrated oral inoculation of ileum-spores containing SFB to chickens after hatch increases early SFB gut colonization, which increases immune maturation and resistance to bacteria, like Salmonella, as tested in vitro; however, more studies are needed for treatment optimization and in vivo testing. The objectives of this study were to (1) test a treatment that includes both spores and filamentous SFB, (2) validate antimicrobial ability of the treatment in layer hens in vivo, and (3) elucidate its molecular mechanism. Methods: One-day-old specific pathogen-free layers (n = 12 per group) were orally treated with either PBS (CON) or SFB-based treatment (SFB). At 4 days post-inoculation (DPI), both CON and SFB groups were orally challenged with Salmonella Typhimurium. Total Enterobacteriaceae and Salmonella were examined by plating and enumeration in feces at 7,10 and 14 dpi; and in the ileum, cecum, and spleen at 16 dpi in euthanized birds. The presence and levels of SFB were determined from ilea scrapings via microscopy and qPCR, respectively. Relative gene expression of host-derived antimicrobial peptides and cytokines in the distal ileum was determined by RT-qPCR. Results: At 10 and 14 dpi, a significant decrease in total Enterobacteriaceae was observed in the feces of the SFB group. At necropsy, the level of SFB was significantly higher in the SFB group than in the CON group, while a significant decrease in total Enterobacteriaceae and Salmonella was observed in the ceca of the SFB group. RT-qPCR revealed increased expression of β-defensin 14, and cytokines IL-10 and IFNγ. Discussion: The introduction of SFB at hatch as a prophylactic treatment may benefit commercial partners as well as consumers by reducing the incidence of Enterobacteriaceae in food animals. Reduction of these bacteria in animals would, in turn, increase animal health, productivity, and safety for consumers. Studies to optimize the treatment for poultry industry applications are ongoing in our lab. [ABSTRACT FROM AUTHOR]

Published

2023

6. Diet prevents the expansion of segmented filamentous bacteria and ileo-colonic inflammation in a model of Crohn’s disease

Author

Amira Metwaly, Jelena Jovic, Nadine Waldschmitt, Sevana Khaloian, Helena Heimes, Deborah Häcker, Mohamed Ahmed, Nassim Hammoudi, Lionel Le Bourhis, Aida Mayorgas, Kolja Siebert, Marijana Basic, Tobias Schwerd, Matthieu Allez, Julian Panes, Azucena Salas, André Bleich, Sebastian Zeissig, Pamela Schnupf, Fabio Cominelli, and Dirk Haller

Subjects

Crohn’s disease, Segmented filamentous bacteria, Purified diet, Tnf ΔARE mice, Inflammation, Pathobiont, Microbial ecology, QR100-130

Abstract

Abstract Background Crohn’s disease (CD) is associated with changes in the microbiota, and murine models of CD-like ileo-colonic inflammation depend on the presence of microbial triggers. Increased abundance of unknown Clostridiales and the microscopic detection of filamentous structures close to the epithelium of Tnf ΔARE mice, a mouse model of CD-like ileitis pointed towards segmented filamentous bacteria (SFB), a commensal mucosal adherent bacterium involved in ileal inflammation. Results We show that the abundance of SFB strongly correlates with the severity of CD-like ileal inflammation in two mouse models of ileal inflammation, including Tnf ΔARE and SAMP/Yit mice. SFB mono-colonization of germ-free Tnf ΔARE mice confirmed the causal link and resulted in severe ileo-colonic inflammation, characterized by elevated tissue levels of Tnf and Il-17A, neutrophil infiltration and loss of Paneth and goblet cell function. Co-colonization of SFB in human-microbiota associated Tnf ΔARE mice confirmed that SFB presence is indispensable for disease development. Screening of 468 ileal and colonic mucosal biopsies from adult and pediatric IBD patients, using previously published and newly designed human SFB-specific primer sets, showed no presence of SFB in human tissue samples, suggesting a species-specific functionality of the pathobiont. Simulating the human relevant therapeutic effect of exclusive enteral nutrition (EEN), EEN-like purified diet antagonized SFB colonization and prevented disease development in Tnf ΔARE mice, providing functional evidence for the protective mechanism of diet in modulating microbiota-dependent inflammation in IBD. Conclusions 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 Tnf ΔARE mice. A purified diet antagonized SFB colonization and prevented disease development in Tnf ΔARE mice in contrast to a fiber-containing chow diet, clearly demonstrating the important role of diet in modulating a novel IBD-relevant pathobiont and supporting a direct link between diet and microbial communities in mediating protective functions. Video Abstract

Published

2023

7. Comparative genome analysis of commensal segmented filamentous bacteria (SFB) from turkey and murine hosts reveals distinct metabolic features

Author

Grant A. Hedblom, Kamal Dev, Steven D. Bowden, and David J. Baumler

Subjects

SFB, Segmented Filamentous Bacteria, Turkey, Comparative genomics, Metabolic capabilities, In Silico, Biotechnology, TP248.13-248.65, Genetics, QH426-470

Abstract

Abstract Background Segmented filamentous bacteria (SFB) are intestinal commensal microorganisms that have been demonstrated to induce the innate and adaptive immune responses in mouse and rat hosts. SFB are Gram-positive, spore-forming bacteria that fail to grow optimally under in vitro conditions due to unique metabolic requirements. Recently, SFB have been implicated in improved health and growth outcomes in commercial turkey flocks. To assess the nature and variations in SFB of turkeys and how they may differ from mammalian-associated SFB, the genome of turkey-associated SFB was compared with six representative genomes from murine hosts using an in silico approach. Results The SFB-turkey genome is 1.6 Mb with a G + C content of 26.14% and contains 1,604 coding sequences (CDS). Comparative genome analyses revealed that all the seven SFB strain possesses a common set of metabolic deficiencies and auxotrophies. Specifically, the inability of all the SFB strains to synthesize most of the amino acids, nucleotides and cofactors, emphasizing the importance of metabolite acquisition from the host intestinal environment. Among the seven SFB genomes, the SFB-turkey genome is the largest and contains the highest number of 1,604 predicted CDS. The SFB-turkey genome possesses cellular metabolism genes that are absent in the rodent SFB strains, including catabolic pathways for sucrose, stachyose, raffinose and other complex glycans. Other unique genes associated with SFB-turkey genome is loci for the biosynthesis of biotin, and degradation enzymes to recycle primary bile acids, both of which may play an important role to help turkey associated SFB survive and secure mutualism with its avian host. Conclusions Comparative genomic analysis of seven SFB genomes revealed that each strain have a core set of metabolic capabilities and deficiencies that make these bacteria challenging to culture under ex vivo conditions. When compared to the murine-associated strains, turkey-associated SFB serves as a phylogenetic outgroup and a unique member among all the sequenced strains of SFB. This turkey-associated SFB strain is the first reported non-mammalian SFB genome, and highlights the impact of host specificity and the evolution of metabolic capabilities.

Published

2022

8. Segmented filamentous bacteria-based treatment to elicit protection against Enterobacteriaceae in Layer chickens

Author

Jared Meinen-Jochum, Logan C. Ott, and Melha Mellata

Subjects

segmented filamentous bacteria, Enterobacteriaceae, antimicrobial peptides, cytokines, layer chickens, Microbiology, QR1-502

Abstract

IntroductionGut microbes like segmented filamentous bacteria (SFB) play a key role in gut maturation during early life, as demonstrated in humans and mice. Our previous study demonstrated oral inoculation of ileum-spores containing SFB to chickens after hatch increases early SFB gut colonization, which increases immune maturation and resistance to bacteria, like Salmonella, as tested in vitro; however, more studies are needed for treatment optimization and in vivo testing. The objectives of this study were to (1) test a treatment that includes both spores and filamentous SFB, (2) validate antimicrobial ability of the treatment in layer hens in vivo, and (3) elucidate its molecular mechanism.MethodsOne-day-old specific pathogen-free layers (n = 12 per group) were orally treated with either PBS (CON) or SFB-based treatment (SFB). At 4 days post-inoculation (DPI), both CON and SFB groups were orally challenged with Salmonella Typhimurium. Total Enterobacteriaceae and Salmonella were examined by plating and enumeration in feces at 7,10 and 14 dpi; and in the ileum, cecum, and spleen at 16 dpi in euthanized birds. The presence and levels of SFB were determined from ilea scrapings via microscopy and qPCR, respectively. Relative gene expression of host-derived antimicrobial peptides and cytokines in the distal ileum was determined by RT-qPCR.ResultsAt 10 and 14 dpi, a significant decrease in total Enterobacteriaceae was observed in the feces of the SFB group. At necropsy, the level of SFB was significantly higher in the SFB group than in the CON group, while a significant decrease in total Enterobacteriaceae and Salmonella was observed in the ceca of the SFB group. RT-qPCR revealed increased expression of β-defensin 14, and cytokines IL-10 and IFNγ.DiscussionThe introduction of SFB at hatch as a prophylactic treatment may benefit commercial partners as well as consumers by reducing the incidence of Enterobacteriaceae in food animals. Reduction of these bacteria in animals would, in turn, increase animal health, productivity, and safety for consumers. Studies to optimize the treatment for poultry industry applications are ongoing in our lab.

Published

2023

9. Diet prevents the expansion of segmented filamentous bacteria and ileo-colonic inflammation in a model of Crohn's disease.

Author

Metwaly, Amira, Jovic, Jelena, Waldschmitt, Nadine, Khaloian, Sevana, Heimes, Helena, Häcker, Deborah, Ahmed, Mohamed, Hammoudi, Nassim, Le Bourhis, Lionel, Mayorgas, Aida, Siebert, Kolja, Basic, Marijana, Schwerd, Tobias, Allez, Matthieu, Panes, Julian, Salas, Azucena, Bleich, André, Zeissig, Sebastian, Schnupf, Pamela, and Cominelli, Fabio

Subjects

INFLAMMATORY bowel diseases, CROHN'S disease, FILAMENTOUS bacteria, BACTERIAL colonies, DIET, INFLAMMATION

Abstract

Background: Crohn's disease (CD) is associated with changes in the microbiota, and murine models of CD-like ileo-colonic inflammation depend on the presence of microbial triggers. Increased abundance of unknown Clostridiales and the microscopic detection of filamentous structures close to the epithelium of TnfΔARE mice, a mouse model of CD-like ileitis pointed towards segmented filamentous bacteria (SFB), a commensal mucosal adherent bacterium involved in ileal inflammation. Results: We show that the abundance of SFB strongly correlates with the severity of CD-like ileal inflammation in two mouse models of ileal inflammation, including TnfΔARE and SAMP/Yit mice. SFB mono-colonization of germ-free TnfΔARE mice confirmed the causal link and resulted in severe ileo-colonic inflammation, characterized by elevated tissue levels of Tnf and Il-17A, neutrophil infiltration and loss of Paneth and goblet cell function. Co-colonization of SFB in human-microbiota associated TnfΔARE mice confirmed that SFB presence is indispensable for disease development. Screening of 468 ileal and colonic mucosal biopsies from adult and pediatric IBD patients, using previously published and newly designed human SFB-specific primer sets, showed no presence of SFB in human tissue samples, suggesting a species-specific functionality of the pathobiont. Simulating the human relevant therapeutic effect of exclusive enteral nutrition (EEN), EEN-like purified diet antagonized SFB colonization and prevented disease development in TnfΔARE mice, providing functional evidence for the protective mechanism of diet in modulating microbiota-dependent inflammation in IBD. Conclusions: 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 TnfΔARE mice. A purified diet antagonized SFB colonization and prevented disease development in TnfΔARE mice in contrast to a fiber-containing chow diet, clearly demonstrating the important role of diet in modulating a novel IBD-relevant pathobiont and supporting a direct link between diet and microbial communities in mediating protective functions. 8ntX7JCRAmgBnFgN24WWkM Video Abstract [ABSTRACT FROM AUTHOR]

Published

2023

10. Small Intestinal Microbiota Oscillations, Host Effects and Regulation—A Zoom into Three Key Effector Molecules.

Author

Ratiner, Karina, Fachler-Sharp, Tahel, and Elinav, Eran

Subjects

*GUT microbiome, *HIGH-fat diet, *CIRCADIAN rhythms, *MOLECULES, *HUMAN behavior, *FASTING

Abstract

Simple Summary: The gut microbiota and its secreted molecules feature a daily rhythm that interacts with the host and influences its function in health and disease. Immune-related molecules are involved in the daily interaction between the microbiota and the host and can be influenced by diet, including fasting and feeding cycles. In this review, we delve into the specific impacts of Reg3γ, IgA, and MHCII to showcase the varied effects of the gut microbiota's daily activity on the host. We also discuss current challenges, remaining questions, and perspectives in understanding the relationship between the microbiome and circadian rhythms. The gut microbiota features a unique diurnal rhythmicity which contributes to modulation of host physiology and homeostasis. The composition and activity of the microbiota and its secreted molecules influence the intestinal milieu and neighboring organs, such as the liver. Multiple immune-related molecules have been linked to the diurnal microbiota-host interaction, including Reg3γ, IgA, and MHCII, which are secreted or expressed on the gut surface and directly interact with intestinal bacteria. These molecules are also strongly influenced by dietary patterns, such as high-fat diet and time-restricted feeding, which are already known to modulate microbial rhythms and peripheral clocks. Herein, we use Reg3γ, IgA, and MHCII as test cases to highlight the divergent effects mediated by the diurnal activity of the gut microbiota and their downstream host effects. We further highlight current challenges and conflicts, remaining questions, and perspectives toward a holistic understanding of the microbiome's impacts on circadian human behavior. [ABSTRACT FROM AUTHOR]

Published

2023

11. Dietary fiber promotes antigen presentation on intestinal epithelial cells and development of small intestinal CD4 + CD8αα + intraepithelial T cells.

Author

Rodriguez-Marino N, Royer CJ, Rivera-Rodriguez DE, Seto E, Gracien I, Jones RM, Scharer CD, Gracz AD, and Cervantes-Barragan L

Subjects

Animals, Mice, Histocompatibility Antigens Class II metabolism, Histocompatibility Antigens Class II immunology, CD8 Antigens metabolism, Interferon-gamma metabolism, Gastrointestinal Microbiome immunology, Mice, Inbred C57BL, Bifidobacterium, Cell Differentiation, Epithelial Cells immunology, Dietary Fiber, Antigen Presentation, Intraepithelial Lymphocytes immunology, Intraepithelial Lymphocytes metabolism, Intestine, Small immunology, Intestinal Mucosa immunology, Intestinal Mucosa microbiology

Abstract

The impact of dietary fiber on intestinal T cell development is poorly understood. Here we show that a low fiber diet reduces MHC-II antigen presentation by small intestinal epithelial cells (IECs) and consequently impairs development of CD4 + CD8αα + intraepithelial lymphocytes (DP IELs) through changes to the microbiota. Dietary fiber supports colonization by Segmented Filamentous Bacteria (SFB), which induces the secretion of IFNγ by type 1 innate lymphoid cells (ILC1s) that lead to MHC-II upregulation on IECs. IEC MHC-II expression caused either by SFB colonization or exogenous IFNγ administration induced differentiation of DP IELs. Finally, we show that a low fiber diet promotes overgrowth of Bifidobacterium pseudolongum, and that oral administration of B. pseudolongum reduces SFB abundance in the small intestine. Collectively we highlight the importance of dietary fiber in maintaining the balance among microbiota members that allow IEC MHC-II antigen presentation and define a mechanism of microbiota-ILC-IEC interactions participating in the development of intestinal intraepithelial T cells., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

12. Layer segmented filamentous bacteria colonize and impact gut health of broiler chickens.

Author

Meinen-Jochum J, Skow CJ, and Mellata M

Subjects

Animals, Bacteria classification, Bacteria genetics, Bacteria isolation & purification, Feces microbiology, Enterobacteriaceae, Chickens microbiology, Chickens immunology, Gastrointestinal Microbiome

Abstract

In commercial poultry farms, chicks hatch away from their progenitors from which they acquire key host-specific microbiota, like segmented filamentous bacteria (SFB) involved in gut maturation in early life. This study investigated whether providing chicken SFB to newly hatched broilers would increase their gut maturation and resistance to bacteria relevant to broiler and human health. One-day-old Ross308 broilers were orally treated with either phosphate-buffered saline (CON) or layer-derived SFB (D-SFB). On days 5, 10, 17, and 24, feces were collected to detect and enumerate SFB and Enterobacteriaceae . On days 8, 15, 22, and 29, birds were euthanized, intestinal samples were collected to detect and enumerate SFB through quantitative PCR (qPCR) and microscopy and expression of genes associated with gut immune function through reverse transcription-qPCR. This study showed that, despite their host specificity, layer SFB can colonize their genetically distinct relative broilers. Ileal SFB colonization was accelerated by a week with the SFB treatment and covered the proximal, medial, and distal sections of the ileum. Colonization of the ileum by SFB in early life highly activated gene expression of intestinal barrier proteins and cytokines, e.g., IL-10 and IFNγ but not IL-17. SFB treatment reduced the level of Enterobacteriaceae in the gut and provided superior resistance to intestinal and extraintestinal pathogens as tested in vitro . Overall, early gut colonization of SFB is imperative for the maturation of the gut immune system and the establishment of a homeostatic gut environment. Improving our understanding of gut immune maturation in food-producing animals is crucial for both human and animal health.IMPORTANCEIn commercial farms, newly hatched chicks may lack host-specific microbiota that help mature their gut immune system for lifelong health benefits. Here, introducing an avian segmented filamentous bacteria (SFB) to commercially sourced chickens orally at hatch accelerated SFB colonization of the ileum. Remarkably, SFB from layers were able to colonize broilers and enhance gut immune maturation, and this immunomodulation impacted the ability to increase intestinal and extraintestinal resistance to bacteria relevant to poultry and human health. With the antibiotic restrictions in animal production, strategies that will help mitigate infections are urgently needed. In summary, we developed a live prophylactic for newly hatched chicks to improve animal health and food safety. Due to the host specificity of SFB, our data highlight the importance of investigating the molecular mechanism of SFB interaction in their own host., Competing Interests: M.M. is listed as an inventor of a pending patent covering research presented in this paper.

Published

2024

13. Comparative genome analysis of commensal segmented filamentous bacteria (SFB) from turkey and murine hosts reveals distinct metabolic features.

Author

Hedblom, Grant A., Dev, Kamal, Bowden, Steven D., and Baumler, David J.

Subjects

*FILAMENTOUS bacteria, *GENOMICS, *SPOREFORMING bacteria, *COMPARATIVE studies, *OUTGROUPS (Social groups)

Abstract

Background: Segmented filamentous bacteria (SFB) are intestinal commensal microorganisms that have been demonstrated to induce the innate and adaptive immune responses in mouse and rat hosts. SFB are Gram-positive, spore-forming bacteria that fail to grow optimally under in vitro conditions due to unique metabolic requirements. Recently, SFB have been implicated in improved health and growth outcomes in commercial turkey flocks. To assess the nature and variations in SFB of turkeys and how they may differ from mammalian-associated SFB, the genome of turkey-associated SFB was compared with six representative genomes from murine hosts using an in silico approach. Results: The SFB-turkey genome is 1.6 Mb with a G + C content of 26.14% and contains 1,604 coding sequences (CDS). Comparative genome analyses revealed that all the seven SFB strain possesses a common set of metabolic deficiencies and auxotrophies. Specifically, the inability of all the SFB strains to synthesize most of the amino acids, nucleotides and cofactors, emphasizing the importance of metabolite acquisition from the host intestinal environment. Among the seven SFB genomes, the SFB-turkey genome is the largest and contains the highest number of 1,604 predicted CDS. The SFB-turkey genome possesses cellular metabolism genes that are absent in the rodent SFB strains, including catabolic pathways for sucrose, stachyose, raffinose and other complex glycans. Other unique genes associated with SFB-turkey genome is loci for the biosynthesis of biotin, and degradation enzymes to recycle primary bile acids, both of which may play an important role to help turkey associated SFB survive and secure mutualism with its avian host. Conclusions: Comparative genomic analysis of seven SFB genomes revealed that each strain have a core set of metabolic capabilities and deficiencies that make these bacteria challenging to culture under ex vivo conditions. When compared to the murine-associated strains, turkey-associated SFB serves as a phylogenetic outgroup and a unique member among all the sequenced strains of SFB. This turkey-associated SFB strain is the first reported non-mammalian SFB genome, and highlights the impact of host specificity and the evolution of metabolic capabilities. [ABSTRACT FROM AUTHOR]

Published

2022

14. Secretory IgA in breast milk protects against asthma through modulation of the gut microbiota.

Author

Donald, Katherine, Serapio-Palacios, Antonio, Gerbec, Zachary, Bozorgmehr, Tahereh, Holani, Ravi, Cruz, Ana Raquel, Schnupf, Pamela, and Finlay, B. Brett

Abstract

Asthma susceptibility is linked to dysbiosis in early-life gut microbiota, and the antibody secretory immunoglobulin (Ig)A (SIgA) is a key determinant of gut microbiota composition. SIgA is obtained through breast milk during the critical early-life window. We use a mouse model of SIgA deficiency and the house dust mite (HDM) model of asthma to elucidate the role of maternal SIgA in modulating the early-life gut microbiota and asthma protection. Mice that do not receive maternal SIgA display a transient bloom of segmented filamentous bacteria (SFB) in the small intestine during the early post-weaning period. Mice that do not receive maternal SIgA also display elevated T helper type 17 (Th17) cell activation in the intestine, which persists into adulthood and is associated with more severe inflammation in response to the HDM model of asthma. This study demonstrates a mechanism by which breast-milk-derived SIgA influences immune development and asthma susceptibility by modulating the early-life gut microbiota. [Display omitted] • Milk-derived SIgA limits SFB colonization in the offspring small intestine • SFB drives premature and elevated Th17 responses in the intestine • Milk SIgA protects against a mouse model of allergic asthma by limiting SFB Donald et al. show that maternal-milk-derived SIgA limits colonization with the immunogenic genus segmented filamentous bacteria (SFB) in the neonatal gut. In the absence of maternal SIgA, a transient bloom of SFB is associated with long-term immune alterations, contributing to elevated susceptibility to a mouse model of asthma. [ABSTRACT FROM AUTHOR]

Published

2024

15. T Cell Responses to the Microbiota.

Author

Ivanov, Ivaylo I., Tuganbaev, Timur, Skelly, Ashwin N., and Honda, Kenya

Abstract

The immune system employs recognition tools to communicate with its microbial evolutionary partner. Among all the methods of microbial perception, T cells enable the widest spectrum of microbial recognition resolution, ranging from the crudest detection of whole groups of microbes to the finest detection of specific antigens. The application of this recognition capability to the crucial task of combatting infections has been the focus of classical immunology. We now appreciate that the coevolution of the immune system and the microbiota has led to development of a lush immunological decision tree downstream of microbial recognition, of which an inflammatory response is but one branch. In this review we discuss known T cell–microbe interactions in the gut and place them in the context of an algorithmic framework of recognition, context-dependent interpretation, and response circuits across multiple levels of microbial recognition resolution. The malleability of T cells in response to the microbiota presents an opportunity to edit immune response cellularity, identity, and functionality by utilizing microbiota-controlled pathways to promote human health. [ABSTRACT FROM AUTHOR]

Published

2022

16. The Role of Segmented Filamentous Bacteria in Immune Barrier Maturation of the Small Intestine at Weaning

Author

Linda A. Oemcke, Rachel C. Anderson, Eric Altermann, Nicole C. Roy, and Warren C. McNabb

Subjects

gastrointestinal tract, segmented filamentous bacteria, interleukin 17, immunoglobulin A, immunological barrier, food substrate, Nutrition. Foods and food supply, TX341-641

Abstract

The microbiological, physical, chemical, and immunological barriers of the gastrointestinal tract (GIT) begin developing in utero and finish maturing postnatally. Maturation of these barriers is essential for the proper functioning of the GIT. Maturation, particularly of the immunological barrier, involves stimulation by bacteria. Segmented filamentous bacteria (SFB) which are anaerobic, spore-forming commensals have been linked to immune activation. The presence and changes in SFB abundance have been positively correlated to immune markers (cytokines and immunoglobulins) in the rat ileum and stool samples, pre- and post-weaning. The abundance of SFB in infant stool increases from 6 months, peaks around 12 months and plateaus 25 months post-weaning. Changes in SFB abundance at these times correlate positively and negatively with the production of interleukin 17 (IL 17) and immunoglobulin A (IgA), respectively, indicating involvement in immune function and maturation. Additionally, the peak in SFB abundance when a human milk diet was complemented by solid foods hints at a diet effect. SFB genome analysis revealed enzymes involved in metabolic pathways for survival, growth and development, host mucosal attachment and substrate acquisition. This narrative review discusses the current knowledge of SFB and their suggested effects on the small intestine immune system. Referencing the published genomes of rat and mouse SFB, the use of food substrates to modulate SFB abundance is proposed while considering their effects on other microbes. Changes in the immune response caused by the interaction of food substrate with SFB may provide insight into their role in infant immunological barrier maturation.

Published

2021

17. Small Intestinal Microbiota Oscillations, Host Effects and Regulation—A Zoom into Three Key Effector Molecules

Author

Karina Ratiner, Tahel Fachler-Sharp, and Eran Elinav

Subjects

circadian clock, small intestine, microbiome, dietary timing, segmented filamentous bacteria, Biology (General), QH301-705.5

Abstract

The gut microbiota features a unique diurnal rhythmicity which contributes to modulation of host physiology and homeostasis. The composition and activity of the microbiota and its secreted molecules influence the intestinal milieu and neighboring organs, such as the liver. Multiple immune-related molecules have been linked to the diurnal microbiota-host interaction, including Reg3γ, IgA, and MHCII, which are secreted or expressed on the gut surface and directly interact with intestinal bacteria. These molecules are also strongly influenced by dietary patterns, such as high-fat diet and time-restricted feeding, which are already known to modulate microbial rhythms and peripheral clocks. Herein, we use Reg3γ, IgA, and MHCII as test cases to highlight the divergent effects mediated by the diurnal activity of the gut microbiota and their downstream host effects. We further highlight current challenges and conflicts, remaining questions, and perspectives toward a holistic understanding of the microbiome’s impacts on circadian human behavior.

Published

2023

18. Antigen-level resolution of commensal-specific B cell responses can be enabled by phage display screening coupled with B cell tetramers.

Author

Verma, Sheenam, Dufort, Matthew J., Olsen, Tayla M., Kimmel, Samantha, Labuda, Jasmine C., Scharffenberger, Sam, McGuire, Andrew T., and Harrison, Oliver J.

Subjects

*B cells, *HOMEOSTASIS, *LYMPHOID tissue, *IMMUNE response, *FILAMENTOUS bacteria

Abstract

Induction of commensal-specific immunity contributes to tissue homeostasis, yet the mechanisms underlying induction of commensal-specific B cells remain poorly understood in part due to a lack of tools to identify these cells. Using phage display, we identified segmented filamentous bacteria (SFB) antigens targeted by serum and intestinal antibodies and generated B cell tetramers to track SFB-specific B cells in gut-associated lymphoid tissues. We revealed a compartmentalized response in SFB-specific B cell activation, with a gradient of immunoglobulin A (IgA), IgG1, and IgG2b isotype production along Peyer's patches contrasted by selective production of IgG2b within mesenteric lymph nodes. V(D)J sequencing and monoclonal antibody generation identified somatic hypermutation driven affinity maturation to SFB antigens under homeostatic conditions. Combining phage display and B cell tetramers will enable investigation of the ontogeny and function of commensal-specific B cell responses in tissue immunity, inflammation, and repair. [Display omitted] • Phage display screening identifies immunogenic commensal antigens • B cell antigen tetramers enable identification of SFB-specific B cells • SFB-specific B cells display anatomically compartmentalized effector functions • Affinity maturation of SFB-specific B cells occurs under homeostatic conditions Adaptive immunity to commensal microbes promotes tissue homeostasis, immunity, and repair, but approaches to identify commensal-specific B cell responses are lacking. Verma et al. utilize phage display screening and subsequent generation of B cell tetramers to identify anatomical compartmentalization of SFB-specific B cell responses in gut-associated lymphoid tissues. [ABSTRACT FROM AUTHOR]

Published

2024

19. A study of the aetiology and control of rainbow trout gastroenteritis

Author

Gonzalez, Jorge Del Pozo, Turnbull, James F., Crumlish, Margaret, and Ferguson, Hugh W.

Subjects

636.089, Rainbow Trout, Fish disease, enteritis, RTGE, Oncorhynchus mykiss, Candidatus arthromitus, Epidemiology, segmented filamentous bacteria, Pathogenesis, Molecular epidemiology, Fishes Diseases, Histology, Pathological, Rainbow trout

Abstract

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.

Published

2009

20. A Proteomic View of the Cross-Talk Between Early Intestinal Microbiota and Poultry Immune System

Author

D. R. Rodrigues, K. M. Wilson, M. Trombetta, W. N. Briggs, A. F. Duff, K. M. Chasser, W. G. Bottje, and L. Bielke

Subjects

segmented filamentous bacteria, probiotic in ovo, immunity, inflammation, Enterobacteriaceae, pioneer colonizers, Physiology, QP1-981

Abstract

Proteomics has been used to investigate cross-talk between the intestinal microbiome and host biological processes. In this study, an in ovo technique and a proteomics approach was used to address how early bacterial colonization in the gastrointestinal tract (GIT) could modulate inflammatory and immune responses in young broilers. Embryos at 18 embryogenic days were inoculated with saline (S), 102 CFU of Citrobacter freundii (CF), Citrobacter species (C2), or lactic acid bacteria mixture (L) into the amnion. At 10 days posthatch, ileum samples from 12 birds per treatment were selected for tandem mass spectrometry analysis. Our further findings indicated that treatment-specific influences on early GIT microbiota resulted in different immune responses in mature broilers. Predicted functional analyses revealed activation of inflammation pathways in broilers treated in ovo with L and CF. Exposure to L enhanced functional annotation related to activation, trafficking of immune cells, and skeletal growth based-network, while CF inhibited biological functions associated with immune cell migration and inflammatory response. These results highlighted that proper immune function was dependent on specific GIT microbiota profiles, in which early-life exposure to L-based probiotic may have modulated the immune functions, whereas neonatal colonization of Enterobacteriaceae strains may have led to immune dysregulation associated with chronic inflammation.

Published

2020

21. Acute high‐dose titanium dioxide nanoparticle exposure alters gastrointestinal homeostasis in mice.

Author

Kurtz, Courtney C., Mitchell, Samantha, Nielsen, Kaitlyn, Crawford, Kevin D., and Mueller‐Spitz, Sabrina R.

Subjects

TITANIUM dioxide, INFLAMMATORY bowel diseases, WEIGHT gain, MICE, HOMEOSTASIS

Abstract

Human exposure to a wide variety of engineered nanoparticles (NPs) is on the rise and use in common food additives increases gastrointestinal (GI) exposure. Host health is intricately linked to the GI microbiome and immune response. Perturbations in the microbiota can affect energy harvest, trigger inflammation and alter the mucosal barrier leading to various disease states such as obesity and inflammatory bowel diseases. We hypothesized that single high‐dose titanium dioxide (TiO2) NP exposure in mice would lead to dysbiosis and stimulate mucus production and local immune populations. Juvenile mice (9‐10 weeks) were gavaged with 1 g/kg TiO2 NPs and examined for changes in mucosa‐associated bacteria abundance, inflammatory cytokines, mucin expression and body mass. Our data provide support that TiO2 NP ingestion alters the GI microbiota and host defenses promoting metabolic disruption and subsequently weight gain in mice. We evaluated gut homeostasis of juvenile mice following a high, acute dose of TiO2 nanoparticles (NPs). The treatment promoted weight gain, possibly due to an overgrowth of Firmicutes, an important player in energy harvest from the diet. Increased expression of mucin and production of immune mediators illustrates activation of inflammatory signaling. In conclusion, our study points to a possible role of environmental exposure to TiO2 NPs in dysbiosis and weight gain, particularly in growing mammals. [ABSTRACT FROM AUTHOR]

Published

2020

22. Un Sistema Modelo para la Suspensión Fecal Humana en Bacterias Filamentosas Segmentadas.

Author

Jilliana, Rogers, Pérez, Rodríguez, and Mahfuz, Basheti

Abstract

Nowadays various kinds of functional foods, including probiotics and prebiotics, are tested for immunological modulation or activation of the gastrointestinal functions in rodent models as the first-step experiment towards the human study. Generally, these foodstuffs are expected to influence the host functions through the compounds metabolized by the intestinal microbes or the microbes themselves. [ABSTRACT FROM AUTHOR]

Published

2020

23. Distribution and Strain Diversity of Immunoregulating Segmented Filamentous Bacteria in Human Intestinal Lavage Samples.

Author

Chen, Huahai, Wang, Ling, Wang, Xing, Wang, Xin, Liu, Haifeng, and Yin, Yeshi

Subjects

*FILAMENTOUS bacteria, *IMMUNOGLOBULIN M, *T helper cells, *ANIMAL weaning, *IRRIGATION (Medicine), *SCANNING electron microscopy

Abstract

Segmented filamentous bacteria (SFB) are well known for their functions in the immunoregulation of hosts including the promotion of Th17 cell differentiation, B cell maturation, and immune system development. However, most analyses of SFB have focused on animal models, and thus, investigation of SFB prevalence in humans and their roles in human immunoregulation and health is needed. Although little is known overall of SFB prevalence in humans, they are characteristically abundant in animals during weaning. In this study, SFB-like bacteria were detected in ileal lavage samples from human children that were aged between 1 to 17 years old by scanning electron microscopy (SEM) analysis, and their insertion into the mucosa was also observed. In addition, the expression of SFB flagellin at the human bacterial interface was observed by immunohistochemistry (IHC) and western blot. Moreover, two pairs of primers specific for SFB, but targeting different genes, were used to detect SFB in human intestinal lavage samples. These analyses indicated that SFB were present in over 50% of patient ileal samples independent of age. High-throughput gene sequencing indicated that different SFB strains were detected among samples. Between nine and 23 SFB flagellin gene operational taxonomic units were identified. In addition to evaluating the prevalence of SFB in human samples, correlations between SFB presence and chief complaints of clinical symptoms were evaluated, as well as the relationship between SFB and patient serum immunoglobulin concentrations. SFB prevalence was significantly higher in hematochezia patients (68%) than in abdominal pain (56.10%) and diarrhea (43.75%) patients. Furthermore, the concentrations of serum IgA, IgM, and IgE, were similar between SFB-positive and SFB-negative patient groups, although IgG concentrations were significantly higher in the SFB-negative group. [ABSTRACT FROM AUTHOR]

Published

2020

24. A Proteomic View of the Cross-Talk Between Early Intestinal Microbiota and Poultry Immune System.

Author

Rodrigues, D. R., Wilson, K. M., Trombetta, M., Briggs, W. N., Duff, A. F., Chasser, K. M., Bottje, W. G., and Bielke, L.

Subjects

GUT microbiome, LACTIC acid bacteria, TANDEM mass spectrometry, MASS analysis (Spectrometry), IMMUNE system

Abstract

Proteomics has been used to investigate cross-talk between the intestinal microbiome and host biological processes. In this study, an in ovo technique and a proteomics approach was used to address how early bacterial colonization in the gastrointestinal tract (GIT) could modulate inflammatory and immune responses in young broilers. Embryos at 18 embryogenic days were inoculated with saline (S), 102 CFU of Citrobacter freundii (CF), Citrobacter species (C2), or lactic acid bacteria mixture (L) into the amnion. At 10 days posthatch, ileum samples from 12 birds per treatment were selected for tandem mass spectrometry analysis. Our further findings indicated that treatment-specific influences on early GIT microbiota resulted in different immune responses in mature broilers. Predicted functional analyses revealed activation of inflammation pathways in broilers treated in ovo with L and CF. Exposure to L enhanced functional annotation related to activation, trafficking of immune cells, and skeletal growth based-network, while CF inhibited biological functions associated with immune cell migration and inflammatory response. These results highlighted that proper immune function was dependent on specific GIT microbiota profiles, in which early-life exposure to L-based probiotic may have modulated the immune functions, whereas neonatal colonization of Enterobacteriaceae strains may have led to immune dysregulation associated with chronic inflammation. [ABSTRACT FROM AUTHOR]

Published

2020

25. Intestinal microbiota programming of alveolar macrophages influences severity of respiratory viral infection.

Author

Ngo, Vu L., Lieber, Carolin M., Kang, Hae-ji, Sakamoto, Kaori, Kuczma, Michal, Plemper, Richard K., and Gewirtz, Andrew T.

Abstract

Susceptibility to respiratory virus infections (RVIs) varies widely across individuals. Because the gut microbiome impacts immune function, we investigated the influence of intestinal microbiota composition on RVI and determined that segmented filamentous bacteria (SFB), naturally acquired or exogenously administered, protected mice against influenza virus (IAV) infection. Such protection, which also applied to respiratory syncytial virus and severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), was independent of interferon and adaptive immunity but required basally resident alveolar macrophages (AMs). In SFB-negative mice, AMs were quickly depleted as RVI progressed. In contrast, AMs from SFB-colonized mice were intrinsically altered to resist IAV-induced depletion and inflammatory signaling. Yet, AMs from SFB-colonized mice were not quiescent. Rather, they directly disabled IAV via enhanced complement production and phagocytosis. Accordingly, transfer of SFB-transformed AMs into SFB-free hosts recapitulated SFB-mediated protection against IAV. These findings uncover complex interactions that mechanistically link the intestinal microbiota with AM functionality and RVI severity. [Display omitted] • Gut microbiota composition influences severity of respiratory viral infection • Gut-restricted segmented filamentous bacteria reprograms lung macrophages • Expression levels of complement and Notch4 expression impact viral infection severity • Transplant of lung macrophages transfers proneness to respiratory viral infection Ngo, Lieber, and colleagues report that colonization of the intestine by segmented filamentous bacteria reprograms lung macrophages conferring them with enhanced ability to combat respiratory viruses, resulting in ameliorated disease. These findings demonstrate the potential of gut microbiome to influence the severity of respiratory viral infection via influencing lung macrophages. [ABSTRACT FROM AUTHOR]

Published

2024

26. Induction of Intestinal Th17 Cells by Flagellins From Segmented Filamentous Bacteria

Author

Yanling Wang, Yeshi Yin, Xin Chen, Yongjia Zhao, Yichen Wu, Yifei Li, Xin Wang, Huahai Chen, and Charlie Xiang

Subjects

segmented filamentous bacteria, flagellin, Th17 cells, IL-17A, SI EC, Immunologic diseases. Allergy, RC581-607

Abstract

T-helper-17 (Th17) cells are a subset of CD4+ T cells that can produce the cytokine interleukin (IL)-17 and play vital roles in protecting the host from bacterial and fungal infections, especially at the mucosal surface. These are abundant in the small intestinal lamina propria (SILP) and their differentiation are associated with the colonization of the intestinal flora. Segmented filamentous bacteria (SFB) drew the attention of researchers due to their unique ability to drive the accumulation of Th17 cells in the SI LP of mice. Recent work has highlighted that SFB used microbial adhesion-triggered endocytosis (MATE) to transfer SFB antigenic proteins into small intestinal epithelial cells (SI ECs) and modulate host immune homeostasis. However, which components of SFB are involved in this immune response process remains unclear. Here, we examined the roles of SFB flagellins in Th17 cells induction using various techniques, including ELISA, ELISPOT, and RNA-seq in vitro and in vivo. The results show that the immune function of SFB flagellins is similar to SFB, i.e., induces the appearance of CD4+ T helper cells that produce IL-17 and IL-22 (Th17 cells) in the SI LP. Furthermore, treatment of mice with SFB flagellins lead to a significant increase in the expression of genes associated with the IL-17 signaling pathway, such as IL-6, IL-1β, TNF-α, IL-17A, IL-17F, and IL-22. In addition, SFB flagellins have an intimate relationship with intestinal epithelial cells, influencing the expression of epithelial cell-specific genes such as Nos2, Duox2, Duoxa2, SAA3, Tat, and Lcn2. Thus, we propose that SFB flagellins play a significant role in the involvement of SFB in the induction of intestinal Th17 cells.

Published

2019

27. Profiling the Gut Microbiome Unraveled Signature Bacterial Groups in Autoimmune Diabetes, which Remain Unperturbed by the Low Ionic Strength of the Drinking Water in NOD mice.

Author

Jayaraman S, Babu M, Saw TA, and Jayaraman AK

Subjects

Female, Animals, Mice, Mice, Inbred NOD, RNA, Ribosomal, 16S genetics, Bacteria genetics, DNA, Diabetes Mellitus, Type 1 etiology, Diabetes Mellitus, Type 1 pathology, Drinking Water, Gastrointestinal Microbiome

Abstract

Background: Non-obese diabetic (NOD) mice develop type 1 diabetes (T1D) spontaneously and serve as a good model for investigating the underlying pathological mechanisms and devising novel treatment procedures. Although acid water consumption has been reported to exaggerate or reduce diabetes incidence in female NOD mice by two groups, the causative bacteria responsible for these contrasting changes remain unclear. On the contrary, we and others failed to observe the effect of acid water consumption on diabetes incidence. This study aimed to determine whether the consumption of low-pH drinking water could alter the frequencies of prominent bacterial groups independent of diabetes manifestation., Methods: Six-week-old female NOD mice maintained on acidified drinking water at the Jackson Laboratories were transferred to neutral pH water or continuously provided with low pH drinking water at our facility. Diabetes was monitored weekly using a glucometer. Using the 454-pyrosequencing methodology, we profiled the gut microbiome of mice transferred to neutral water and developed diabetes. Further, we performed quantitative real-time polymerase chain reactions (qRT-PCR) using primers specific for prominent 16S rRNA genes on the fecal DNA of mice provided with low pH or neutral water and displayed diabetes similarly., Results: Consistent with our earlier report, the incidence of T1D was robust (80-100%) regardless of whether female NOD mice consumed acid (~pH 2.9) or neutral water. The 454-pyrosequencing of fecal DNA indicated no substantial influence of transferring mice to neutral pH drinking water on the gut microbiome. To validate these findings, we conducted qRT-PCR on the fecal DNA of mice longitudinally from six weeks of age to adulthood that consumed acidic or neutral pH water and developed diabetes similarly. Among the 15 selected bacterial groups examined, the frequency of Lactobacillus sp. remained consistently lower ( p < 0.05) throughout the life of NOD mice compared to that found in young (6-week-old) mice, regardless of the pH of the drinking water. The relative frequencies of the Firmicutes Ruminococcaceae and the Bactereoidetes members Anaerophaga sp. and Paludibacter sp. increased significantly ( p < 0.05) during the transition to the overtly diabetic stage irrespective of the ionic strength of the drinking water. Interestingly, the Firmicutes members Clostridium coccoides , C. leptum , and Lachnospiraceae and the Bacteroidetes members Bacteroides sp. and Prevottella sp. remained unchanged throughout the analysis irrespective of the pH of the drinking water. Paradoxically, the representations of Akkermansia muciniphila and the segmented filamentous bacteria implicated in diabetes protection did not differ regardless of the age or the ionic strength of the drinking water., Conclusions: The data presented herein validate the lack of influence of acidic drinking water on T1D development in female NOD mice. Diabetes was associated with the lower representation of Lactobacillus sp. throughout life, which was not influenced by the differing pH of the drinking water. Significantly, segmented filamentous bacteria and A. muciniphila , previously implicated in protection against T1D, were not perturbed by the varying pH of the water consumed. These data indicate that although acidified water consumption was reported previously to diminish specific gastrointestinal pathogens, it failed to perturb gut commensals that influence diabetes development.

Published

2024

28. Intestinal Pioneer Colonizers as Drivers of Ileal Microbial Composition and Diversity of Broiler Chickens.

Author

Rodrigues, Denise R., Winson, Emily, Wilson, Kim M., Briggs, Whitney N., Duff, Audrey F., Chasser, Kaylin M., and Bielke, Lisa R.

Subjects

BROILER chickens, LACTIC acid bacteria, MICROBIAL diversity, FILAMENTOUS bacteria, CITROBACTER freundii, NECROTIC enteritis, POULTRY growth, GUT microbiome

Abstract

Given that recent advances in metagenomics have highlighted the importance of intestinal microbes for poultry health, there has been a corresponding search for early manipulation strategies of intestinal microbiota in order to advance immune system development and optimize functional properties of growth. In this study, we used the in ovo technique as an experimental model to address how early bacterial intestinal colonization could affect the development and establishment of the mature ileal microbiota. Inoculations containing one of the following: 0.2 mL of 0.9% sterile saline (S), approximately 102 cells of Citrobacter freundii (CF), Citrobacter species (C2) or lactic acid bacteria mixture (L) were administered via in ovo into the amnion. Results showed that Enterobacteriaceae abundance was negatively correlated with aging, although its high population at day of hatch affected the microbiota composition, delaying mature microbiota establishment. L treatment increased colonization of butyrate-producing bacteria by 3 and 10 days, and segmented filamentous bacteria in the lower ileum by 10 days. On the other hand, L-probiotic decreased the population of Enterococcaceae. In addition, L and C2 microbial communities were less diverse at 10 than 3 days of age in the upper ileum. Importantly, these findings provide a valuable resource for a potential study model for interactions between microbial colonization and associated immune responses. In conclusion, our analysis demonstrates that intestinal pioneer colonizers play a critical role in driving the course of microbial community composition and diversity over time, in which early life exposure to L-based probiotic supported selection alongside greater colonization of symbiotic populations in the ileum of young broilers. [ABSTRACT FROM AUTHOR]

Published

2020

29. Induction of Intestinal Th17 Cells by Flagellins From Segmented Filamentous Bacteria.

Author

Wang, Yanling, Yin, Yeshi, Chen, Xin, Zhao, Yongjia, Wu, Yichen, Li, Yifei, Wang, Xin, Chen, Huahai, and Xiang, Charlie

Subjects

T helper cells, FILAMENTOUS bacteria, EPITHELIAL cells, T cells, REOVIRUSES, MYCOSES

Abstract

T-helper-17 (Th17) cells are a subset of CD4+ T cells that can produce the cytokine interleukin (IL)-17 and play vital roles in protecting the host from bacterial and fungal infections, especially at the mucosal surface. These are abundant in the small intestinal lamina propria (SILP) and their differentiation are associated with the colonization of the intestinal flora. Segmented filamentous bacteria (SFB) drew the attention of researchers due to their unique ability to drive the accumulation of Th17 cells in the SI LP of mice. Recent work has highlighted that SFB used microbial adhesion-triggered endocytosis (MATE) to transfer SFB antigenic proteins into small intestinal epithelial cells (SI ECs) and modulate host immune homeostasis. However, which components of SFB are involved in this immune response process remains unclear. Here, we examined the roles of SFB flagellins in Th17 cells induction using various techniques, including ELISA, ELISPOT, and RNA-seq in vitro and in vivo. The results show that the immune function of SFB flagellins is similar to SFB, i.e., induces the appearance of CD4+ T helper cells that produce IL-17 and IL-22 (Th17 cells) in the SI LP. Furthermore, treatment of mice with SFB flagellins lead to a significant increase in the expression of genes associated with the IL-17 signaling pathway, such as IL-6, IL-1β, TNF-α, IL-17A, IL-17F, and IL-22. In addition, SFB flagellins have an intimate relationship with intestinal epithelial cells, influencing the expression of epithelial cell-specific genes such as Nos2, Duox2, Duoxa2, SAA3, Tat, and Lcn2. Thus, we propose that SFB flagellins play a significant role in the involvement of SFB in the induction of intestinal Th17 cells. [ABSTRACT FROM AUTHOR]

Published

2019

30. Microbiota of the Gut-Lymph Node Axis: Depletion of Mucosa-Associated Segmented Filamentous Bacteria and Enrichment of Methanobrevibacter by Colistin Sulfate and Linco-Spectin in Pigs.

Author

Zwirzitz, Benjamin, Pinior, Beate, Metzler-Zebeli, Barbara, Handler, Monika, Gense, Kristina, Knecht, Christian, Ladinig, Andrea, Dzieciol, Monika, Wetzels, Stefanie U., Wagner, Martin, Schmitz-Esser, Stephan, and Mann, Evelyne

Subjects

COLISTIN, FILAMENTOUS bacteria, LYMPHOID tissue, INTESTINAL physiology, AMINO acid metabolism, DNA replication

Abstract

Microorganisms are translocated from the gut to lymphatic tissues via immune cells, thereby challenging and training the mammalian immune system. Antibiotics alter the gut microbiome and consecutively might also affect the corresponding translocation processes, resulting in an imbalanced state between the intestinal microbiota and the host. Hence, understanding the variant effects of antibiotics on the microbiome of gut-associated tissues is of vital importance for maintaining metabolic homeostasis and animal health. In the present study, we analyzed the microbiome of (i) pig feces, ileum, and ileocecal lymph nodes under the influence of antibiotics (Linco-Spectin and Colistin sulfate) using 16S rRNA gene sequencing for high-resolution community profiling and (ii) ileocecal lymph nodes in more detail with two additional methodological approaches, i.e., cultivation of ileocecal lymph node samples and (iii) metatranscriptome sequencing of a single lymph node sample. Supplementation of medicated feed showed a local effect on feces and ileal mucosa-associated microbiomes. Pigs that received antibiotics harbored significantly reduced amounts of segmented filamentous bacteria (SFB) along the ileal mucosa (p = 0.048; 199.17-fold change) and increased amounts of Methanobrevibacter , a methanogenic Euryarchaeote in fecal samples (p = 0.005; 20.17-fold change) compared to the control group. Analysis of the porcine ileocecal lymph node microbiome exposed large differences between the viable and the dead fraction of microorganisms and the microbiome was altered to a lesser extent by antibiotics compared with feces and ileum. The core microbiome of lymph nodes was constituted mainly of Proteobacteria. RNA-sequencing of a single lymph node sample unveiled transcripts responsible for amino acid and carbohydrate metabolism as well as protein turnover, DNA replication and signal transduction. The study presented here is the first comparative study of microbial communities in feces, ileum, and its associated ileocecal lymph nodes. In each analyzed site, we identified specific phylotypes susceptible to antibiotic treatment that can have profound impacts on the host physiological and immunological state, or even on global biogeochemical cycles. Our results indicate that pathogenic bacteria, e.g., enteropathogenic Escherichia coli , could escape antibiotic treatment by translocating to lymph nodes. In general ileocecal lymph nodes harbor a more diverse and active community of microorganisms than previously assumed. [ABSTRACT FROM AUTHOR]

Published

2019

31. Intestinal microbiota-specific Th17 cells possess regulatory properties and suppress effector T cells via c-MAF and IL-10.

Author

Brockmann, Leonie, Tran, Alexander, Huang, Yiming, Edwards, Madeline, Ronda, Carlotta, Wang, Harris H., and Ivanov, Ivaylo I.

Subjects

*T helper cells, *T cells, *INTERLEUKIN-10, *PROGENITOR cells, *CELL populations

Abstract

Commensal microbes induce cytokine-producing effector tissue-resident CD4+ T cells, but the function of these T cells in mucosal homeostasis is not well understood. Here, we report that commensal-specific intestinal Th17 cells possess an anti-inflammatory phenotype marked by expression of interleukin (IL)-10 and co-inhibitory receptors. The anti-inflammatory phenotype of gut-resident commensal-specific Th17 cells was driven by the transcription factor c-MAF. IL-10-producing commensal-specific Th17 cells were heterogeneous and derived from a TCF1+ gut-resident progenitor Th17 cell population. Th17 cells acquired IL-10 expression and anti-inflammatory phenotype in the small-intestinal lamina propria. IL-10 production by CD4+ T cells and IL-10 signaling in intestinal macrophages drove IL-10 expression by commensal-specific Th17 cells. Intestinal commensal-specific Th17 cells possessed immunoregulatory functions and curbed effector T cell activity in vitro and in vivo in an IL-10-dependent and c-MAF-dependent manner. Our results suggest that tissue-resident commensal-specific Th17 cells perform regulatory functions in mucosal homeostasis. [Display omitted] • SFB-specific Th17 cells have anti-inflammatory phenotype driven by c-MAF and IL-10 • Commensal-induced Th17 cells regulate T cell activity in an IL-10-dependent manner • TCF1+ progenitor Th17 cells generate IL-10+ SFB-induced Th17 cells locally in the gut • IL-10 signaling in gut macrophages drives anti-inflammatory Th17 cell phenotype The function of commensal-specific Th17 cells in host homeostasis is unclear. Brockmann et al. report that tissue-resident commensal-induced Th17 cells have an anti-inflammatory phenotype and can regulate effector T cell responses. Anti-inflammatory Th17 cells are sustained locally from a resident gut TCF1+ progenitor population and signals from intestinal macrophages. [ABSTRACT FROM AUTHOR]

Published

2023

32. Osteoarthritis Can Also Start in the Gut: The Gut–Joint Axis

Author

Brendan Gleason, Emanuele Chisari, and Javad Parvizi

Subjects

Inflammation, CHRONIC ENTEROCOLITIS, INTESTINAL BACTERIA, Review Article, Gut-joint axis, MICROBIOTA, PEPTIDOGLYCAN, Diet, COLONIZATION, SEGMENTED FILAMENTOUS BACTERIA, Joint, Osteoarthritis, Dysbiosis, Orthopedics and Sports Medicine, Microbiome, Obesity, HEALTH, Immune response, MACROPHAGES, COLITIS

Abstract

Background Osteoarthritis is a common cause of pain and disability with an increasing prevalence among the global population (Hunter and Bierma-Zeinstra in Lancet 393(10182):1745-1759, 2019; Zhang and Jordan in Clinics in Geriatric Medicine 26( 3):355-369, 2010). Altered immune responses and low-grade systemic inflammation driven by gut dysbiosis are being increasingly recognized as contributing factors to the pathophysiology of OA (Tan et al. in International Journal of Rheumatic Diseases. https://doi.org/10.1111/1756-185X.14123, 2021; Binvignat et al. in Joint, Bone, Spine 88(5):105203, 2021; Ramasamy et al. in Nutrients 13(4): 1272, 2021), which increased the interest in the so-called "gut-joint axis". The various microbiota in the gastrointestinal tract is commonly referred to as the gut microbiome. The gut microbiome is affected by age, sex, and immune system activity as well as medications, environment, and diet (Arumugam in Nature. https://doi.org/ 10.1038/nature09944, 2011). The microbiome is pivotal to maintain host health and contributes to nutrition, host defense, and immune development (Nishida et al. in Clinical Journal of Gastroenterology 11:1-10, 2018). Alterations in this microbiome can induce dysbiosis, which is associated with many human disease states including allergies, autoimmune disease, diabetes, and cancer (Lin and Zhang in BMC Immunology 18(1):2, 2017). A gut-joint axis is proposed as a link involving the gastrointestinal microbiome, the immune response that it induces, and joint health. Results Emerging evidence has shown that there are specific changes in the microbiome that are associated with osteoarthritis, including increased Firmicutes/Bacteroides ratio, Streptococcus spp. prevalence, and local inflammation (Collins in Osteoarthritis and Cartilage. https://doi.org/10.1016/j.joca.2015.03.014, 2015; Rios in Science and Reports. https://doi.org/ 10.1038/s41598-019-40601-x, 2019; Schott in JCI insight. https://doi.org/10.1172/jci.insight.95997, 2018; Boer et al. in Nature Communications 10:4881, 2019). Both the innate and adaptive immune systems are affected by the gut microbiome and can become dysregulated in dysbiosis which ultimately triggers events associated with joint OA. Conclusions The gut is an intriguing and novel target for OA therapy. Dietary modification or supplementation with fiber, probiotics, or prebiotics could provide a positive impact on the gut joint axis.

Published

2022

33. Segmented Filamentous Bacteria – Metabolism Meets Immunity

Author

Grant A. Hedblom, Holly A. Reiland, Matthew J. Sylte, Timothy J. Johnson, and David J. Baumler

Subjects

segmented filamentous bacteria, SFB, Candidatus Arthromitus, turkey (Meleagris gallopavo), microbiome and immune system, Microbiology, QR1-502

Abstract

Segmented filamentous bacteria (SFB) are a group of host-adapted, commensal organisms that attach to the ileal epithelium of vertebrate and invertebrate hosts. A genetic relative of the genus Clostridium, these morphologically unique bacteria display a replication and differentiation lifecycle initiated by epithelial tissue binding and filamentation. SFB intimately bind to the surface of absorptive intestinal epithelium without inducing an inflammatory response. Rather, their presence impacts the generation of innate and differentiation of acquired immunity, which impact the clearance of extracellular bacterial or fungal pathogens in the gastrointestinal and respiratory tracts. SFB have recently garnered attention due to their role in promoting adaptive and innate immunity in mice and rats through the differentiation and maturation of Th17 cells in the intestinal tract and production of immunoglobulin A (IgA). SFB are the first commensal bacteria identified that impact the maturation and development of Th17 cells in mice. Recently, microbiome studies have revealed the presence of Candidatus Arthromitus (occasionally designated as Candidatus Savagella), a proposed candidate species of SFB, in higher proportions in higher-performing flocks as compared to matched lower-performing flocks, suggesting that SFB may serve to establish a healthy gut and protect commercial turkeys from pathogens resulting in morbidity and decreased performance. In this review we seek to describe the life cycle, host specificity, and genetic capabilities of SFB, such as bacterial metabolism, and how these factors influence the host immunity and microbiome. Although the role of SFB to induce antigen-specific Th17 cells in poultry is unknown, they may play an important role in modulating the immune response in the intestinal tract to promote resistance against some infectious diseases and promote food-safety. This review demonstrates the importance of studying and further characterizing commensal, host-specific bacteria in food-producing animals and their importance to animal health.

Published

2018

34. Antimicrobial Peptides in Inflammatory Bowel Disease

Author

Bevins, Charles L. and Baumgart, Daniel C., editor

Published

2012

35. Select Gut Microbiota Impede Rotavirus Vaccine Efficacy.

Author

Ngo VL, Wang Y, Wang Y, Shi Z, Britton R, Zou J, Ramani S, Jiang B, and Gewirtz AT

Subjects

Animals, Humans, Mice, Female, Antibodies, Viral immunology, Antibodies, Viral blood, Vaccination, Male, Feces microbiology, Feces virology, Child, Preschool, Disease Models, Animal, Rotavirus Vaccines immunology, Rotavirus Vaccines administration & dosage, Gastrointestinal Microbiome immunology, Rotavirus Infections prevention & control, Rotavirus Infections immunology, Rotavirus Infections virology, Rotavirus Infections microbiology, Vaccine Efficacy, Rotavirus immunology, Fecal Microbiota Transplantation

Abstract

Background & Aims: The protection provided by rotavirus (RV) vaccines is highly heterogeneous among individuals. We hypothesized that microbiota composition might influence RV vaccine efficacy., Methods: First, we examined the potential of segmented filamentous bacteria (SFB) colonization to influence RV vaccine efficacy in mice. Next, we probed the influence of human microbiomes on RV vaccination via administering mice fecal microbial transplants (FMTs) from children with robust or minimal RV vaccine responsiveness. Post-FMT, mice were subjected to RV vaccination followed by RV challenge., Results: SFB colonization induced a phenotype that was reminiscent of RV vaccine failure (ie, failure to generate RV antigens and, consequently, anti-RV antibodies following RV vaccination resulting in proneness to RV challenge after SFB levels diminished). FMTs from children to mice recapitulated donor vaccination phenotype. Specifically, mice receiving FMTs from high-responsive vaccinees copiously shed RV antigens and robustly generated anti-RV antibodies following RV vaccination. Concomitantly, such mice were impervious to RV challenge. In contrast, mice receiving FMTs from children who had not responded to RV vaccination exhibited only modest responses to RV vaccination and, concomitantly, remained prone to RV challenge. Microbiome analysis ruled out a role for SFB but suggested involvement of Clostridium perfringens. Oral administration of cultured C. perfringens to gnotobiotic mice partially recapitulated the RV vaccine non-responder phenotype. Analysis of published microbiome data found C. perfringens abundance in children modestly associated with RV vaccine failure., Conclusion: Microbiota composition influences RV vaccine efficacy with C. perfringens being one, perhaps of many, potential contributing taxa., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

36. Isolation of segmented filamentous bacteria from complex gut microbiota

Author

Aaron C. Ericsson, Giedre Turner, Lisa Montoya, Annie Wolfe, Stacey Meeker, Charlie Hsu, Lillian Maggio-Price, and Craig L. Franklin

Subjects

segmented filamentous bacteria, SFB, Candidatus Arthromitus, culture, microbiota, commensal, Biology (General), QH301-705.5

Abstract

Segmented filamentous bacteria (SFB) modulate the ontogeny of the immune system, and their presence can significantly affect mouse models of disease. Until recently, the inability to successfully culture SFB has made controlled studies on the mechanisms by which these bacteria exert their influence problematic. Here, we report a new method for selecting SFB from complex microbial mixtures, providing researchers a simple and cost-effective means to prepare pure infective inocula for prospective studies and also to compare individual SFB isolates.

Published

2015

37. Segmented Filamentous Bacteria – Metabolism Meets Immunity.

Author

Hedblom, Grant A., Reiland, Holly A., Sylte, Matthew J., Johnson, Timothy J., and Baumler, David J.

Subjects

FILAMENTOUS bacteria, HEALTH of food animals, IMMUNOREGULATION

Abstract

Segmented filamentous bacteria (SFB) are a group of host-adapted, commensal organisms that attach to the ileal epithelium of vertebrate and invertebrate hosts. A genetic relative of the genus Clostridium , these morphologically unique bacteria display a replication and differentiation lifecycle initiated by epithelial tissue binding and filamentation. SFB intimately bind to the surface of absorptive intestinal epithelium without inducing an inflammatory response. Rather, their presence impacts the generation of innate and differentiation of acquired immunity, which impact the clearance of extracellular bacterial or fungal pathogens in the gastrointestinal and respiratory tracts. SFB have recently garnered attention due to their role in promoting adaptive and innate immunity in mice and rats through the differentiation and maturation of Th17 cells in the intestinal tract and production of immunoglobulin A (IgA). SFB are the first commensal bacteria identified that impact the maturation and development of Th17 cells in mice. Recently, microbiome studies have revealed the presence of Candidatus Arthromitus (occasionally designated as Candidatus Savagella), a proposed candidate species of SFB, in higher proportions in higher-performing flocks as compared to matched lower-performing flocks, suggesting that SFB may serve to establish a healthy gut and protect commercial turkeys from pathogens resulting in morbidity and decreased performance. In this review we seek to describe the life cycle, host specificity, and genetic capabilities of SFB, such as bacterial metabolism, and how these factors influence the host immunity and microbiome. Although the role of SFB to induce antigen-specific Th17 cells in poultry is unknown, they may play an important role in modulating the immune response in the intestinal tract to promote resistance against some infectious diseases and promote food-safety. This review demonstrates the importance of studying and further characterizing commensal, host-specific bacteria in food-producing animals and their importance to animal health. [ABSTRACT FROM AUTHOR]

Published

2018

38. Segmented filamentous bacteria‐induced immune responses: a balancing act between host protection and autoimmunity.

Author

Flannigan, Kyle L. and Denning, Timothy L.

Subjects

*IMMUNE response, *FILAMENTOUS bacteria, *AUTOIMMUNITY, *AUTOIMMUNE diseases, *EPITHELIAL cells

Abstract

Summary: Segmented filamentous bacteria (SFB) are Gram‐positive, spore‐forming, bacteria that primarily colonize the ileum of the small intestine. Upon direct adherence to intestinal epithelial cells, SFB actively stimulate innate and adaptive immune cell activation. The cardinal features of SFB‐induced gut immunity – T helper type 17 (Th17) cell differentiation, IgA production and barrier protection – lead to the containment of SFB and further afford protection against invading pathogens. Th17 cells and interleukin‐17A, however, can also reach peripheral sites and exacerbate autoimmunity. In this review, we highlight salient characteristics of SFB–host interactions and detail the cellular and molecular immune mechanisms involved in coordinating these responses. [ABSTRACT FROM AUTHOR]

Published

2018

39. Transcription factor c-Rel mediates communication between commensal bacteria and mucosal lymphocytes

Author

Meike Kespohl, Sabrina Hartmann, Jasmin Bazant, Ulrich Steinhoff, Maik Luu, Kai Binder, Rossana Romero, Burkhard Schütz, and Alexander Visekruna

Subjects

Bacteria, Communication, Segmented filamentous bacteria, Cellular differentiation, Immunology, Germinal center, Inflammation, T-Lymphocytes, Helper-Inducer, Cell Biology, Biology, Immunoglobulin A, Cell biology, Mice, Peyer's Patches, Immune system, Transcriptional regulation, medicine, Animals, Immunology and Allergy, Lymphocytes, medicine.symptom, REL, Transcription factor, Transcription Factors

Abstract

The NF-κB transcription factor c-Rel plays a crucial role in promoting and regulating immune responses and inflammation. However, the function of c-Rel in modulating the mucosal immune system is poorly understood. T follicular helper (Tfh) cells and IgA production in gut-associated lymphoid tissues (GALT) such as Peyer's patches (PPs) are important for maintaining the intestinal homeostasis. Here, c-Rel was identified as an essential factor regulating intestinal IgA generation and function of Tfh cells. Genetic deletion of c-Rel resulted in the aberrant formation of germinal centers (GCs) in PPs, significantly reduced IgA generation and defective Tfh cell differentiation. Supporting these findings, the Ag-specific IgA response to Citrobacter rodentium was strongly impaired in c-Rel-deficient mice. Interestingly, an excessive expansion of segmented filamentous bacteria (SFB) was observed in the small intestine of animals lacking c-Rel. Yet, the production of IL-17A, IgA, and IL-21, which are induced by SFB, was impaired due to the lack of transcriptional control by c-Rel. Collectively, the transcriptional activity of c-Rel regulates Tfh cell function and IgA production in the gut, thus preserving the intestinal homeostasis.

Published

2021

40. Molecular Identification of Some Filamentous Bacteria Isolated from Contaminated soil for Poly Hydroxyl Butyrate Degradation

Author

Majdah Aboras

Subjects

Butyrate degradation, Biochemistry, Chemistry, Segmented filamentous bacteria, General Medicine, Soil contamination, Molecular identification

Published

2021

41. Low dietary fiber intake impairs small intestinal Th17 and intraepithelial T cell development over generations.

Author

Royer, Charlotte J., Rodriguez-Marino, Naomi, Yaceczko, Madelyn D., Rivera-Rodriguez, Dormarie E., Ziegler, Thomas R., and Cervantes-Barragan, Luisa

Abstract

Dietary fiber strongly impacts the microbiota. Here, we show that a low-fiber diet changes the small intestinal (SI) microbiota and impairs SI Th17, TCRαβ+CD8αβ+ and TCRαβ+CD8αα+ intraepithelial T cell development. We restore T cell development with dietary fiber supplementation, but this defect becomes persistent over generations with constant low-fiber diets. Offspring of low-fiber diet-fed mice have reduced SI T cells even after receiving a fiber-rich diet due to loss of bacteria important for T cell development. In these mice, only a microbiota transplant from a fiber-rich diet-fed mouse and a fiber-rich diet can restore T cell development. Low-fiber diets reduce segmented filamentous bacteria (SFB) abundance, impairing its vertical transmission. SFB colonization and a fiber-rich diet partially restore T cell development. Finally, we observe that low-fiber diet-induced T cell defects render mice more susceptible to Citrobacter rodentium infection. Together, these results demonstrate the importance of fiber to microbiota vertical transmission and host immune system development. [Display omitted] • Low-fiber diet changes the microbiota and impair the development of intestinal T cells • Mice fed low-fiber diet over generations have persistent defects in intestinal T cells • Low-fiber diet reduces the abundance and impairs the vertical transmission of SFB • Dietary fiber and SFB are needed for the development of CD8αβ intraepithelial T cells Royer et al. show that low-fiber diets change the small intestinal microbiota and impairs the development of intestinal T cells. This defect becomes persistent over generations of mice fed low-fiber diets due to impaired vertical transmission of SFB. This study demonstrates the importance of fiber for microbiota transmission and immune system development. [ABSTRACT FROM AUTHOR]

Published

2023

42. Modulatory Influence of Segmented Filamentous Bacteria on Transcriptomic Response of Gnotobiotic Mice Exposed to TCDD

Author

Robert D. Stedtfeld, Benli Chai, Robert B. Crawford, Tiffany M. Stedtfeld, Maggie R. Williams, Shao Xiangwen, Tomomi Kuwahara, James R. Cole, Norbert E. Kaminski, James M. Tiedje, and Syed A. Hashsham

Subjects

TCDD, segmented filamentous bacteria, gnotobiotic mice, regulatory T-cells, gut dysbiosis, host microbe response, Microbiology, QR1-502

Abstract

Environmental toxicants such as 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD), an aryl hydrocarbon receptor (AhR), are known to induce host toxicity and structural shifts in the gut microbiota. Key bacterial populations with similar or opposing functional responses to AhR ligand exposure may potentially help regulate expression of genes associated with immune dysfunction. To examine this question and the mechanisms for AhR ligand-induced bacterial shifts, C57BL/6 gnotobiotic mice were colonized with and without segmented filamentous bacteria (SFB) – an immune activator. Mice were also colonized with polysaccharide A producing Bacteroides fragilis – an immune suppressor to serve as a commensal background. Following colonization, mice were administered TCDD (30 μg/kg) every 4 days for 28 days by oral gavage. Quantified with the nCounter® mouse immunology panel, opposing responses in ileal gene expression (e.g., genes associated with T-cell differentiation via the class II major histocompatibility complex) as a result of TCDD dosing and SFB colonization were observed. Genes that responded to TCDD in the presence of SFB did not show a significant response in the absence of SFB, and vice versa. Regulatory T-cells examined in the mesenteric lymph-nodes, spleen, and blood were also less impacted by TCDD in mice colonized with SFB. TCDD-induced shifts in abundance of SFB and B. fragilis compared with previous studies in mice with a traditional gut microbiome. With regard to the mouse model colonized with individual populations, results indicate that TCDD-induced host response was significantly modulated by the presence of SFB in the gut microbiome, providing insight into therapeutic potential between AhR ligands and key commensals.

Published

2017

43. Comparative genome analysis of commensal segmented filamentous bacteria (SFB) from turkey and murine hosts reveals distinct metabolic features

Author

Kamal Dev, David J. Baumler, Grant A. Hedblom, and Steven D. Bowden

Subjects

Mammals, Genetics, Sucrose, Bacteria, Nucleotides, Segmented filamentous bacteria, Biotin, Biology, Genome, Rats, Bile Acids and Salts, Mice, Raffinose, Animals, Amino Acids, Symbiosis, METABOLIC FEATURES, Phylogeny, Biotechnology

Abstract

Background Segmented filamentous bacteria (SFB) are intestinal commensal microorganisms that have been demonstrated to induce the innate and adaptive immune responses in mouse and rat hosts. SFB are Gram-positive, spore-forming bacteria that fail to grow optimally under in vitro conditions due to unique metabolic requirements. Recently, SFB have been implicated in improved health and growth outcomes in commercial turkey flocks. To assess the nature and variations in SFB of turkeys and how they may differ from mammalian-associated SFB, the genome of turkey-associated SFB was compared with six representative genomes from murine hosts using an in silico approach. Results The SFB-turkey genome is 1.6 Mb with a G + C content of 26.14% and contains 1,604 coding sequences (CDS). Comparative genome analyses revealed that all the seven SFB strain possesses a common set of metabolic deficiencies and auxotrophies. Specifically, the inability of all the SFB strains to synthesize most of the amino acids, nucleotides and cofactors, emphasizing the importance of metabolite acquisition from the host intestinal environment. Among the seven SFB genomes, the SFB-turkey genome is the largest and contains the highest number of 1,604 predicted CDS. The SFB-turkey genome possesses cellular metabolism genes that are absent in the rodent SFB strains, including catabolic pathways for sucrose, stachyose, raffinose and other complex glycans. Other unique genes associated with SFB-turkey genome is loci for the biosynthesis of biotin, and degradation enzymes to recycle primary bile acids, both of which may play an important role to help turkey associated SFB survive and secure mutualism with its avian host. Conclusions Comparative genomic analysis of seven SFB genomes revealed that each strain have a core set of metabolic capabilities and deficiencies that make these bacteria challenging to culture under ex vivo conditions. When compared to the murine-associated strains, turkey-associated SFB serves as a phylogenetic outgroup and a unique member among all the sequenced strains of SFB. This turkey-associated SFB strain is the first reported non-mammalian SFB genome, and highlights the impact of host specificity and the evolution of metabolic capabilities.

Published

2022

44. Improvement of natamycin production by controlling the morphology of <scp> Streptomyces gilvosporeus Z8 </scp> with microparticle talc in seed preculture

Author

Li Feng, Zeng Xin, Xin Yu, Zixian Ding, Yingying Yu, Min Yu, Qian You, Shaofan Xia, Chaoping Yue, Chen Zhang, Haitao Xu, and Hao Fu

Subjects

Preservative, Renewable Energy, Sustainability and the Environment, Chemistry, General Chemical Engineering, Segmented filamentous bacteria, Organic Chemistry, Talc, Pollution, Spore, Inorganic Chemistry, Fuel Technology, Natamycin, medicine, Fermentation, Food science, Microparticle, Waste Management and Disposal, Mycelium, Biotechnology, medicine.drug

Abstract

BACKGROUND: Natamycin, an antifungal agent, has been widely used as a food preservative and medicine for fungal disease therapy. Seed preculture plays a crucial role in natamycin production, while studies on the effects of seed morphology on natamycin biosynthesis and corresponding regulation approaches are still absent. RESULTS: Correlation analyses among spore age, seed morphology and natamycin production showed that old spores tended to form larger mycelial pellets, which gave rise to a significant reduction of natamycin biosynthesis. To solve this problem, microparticle talc was added to regulate the mycelial morphology in seed preculture. Optimal talc addition led to small mycelial pellets with hairy superficial mycelia and loose structure, resulting in higher glucose‐6‐phosphate dehydrogenase activity and energy charge. The seed morphology regulation effectively improved the natamycin titer and decreased the culture time, especially for old spores (age 28 days), with a 1.7‐fold higher natamycin titer and 16.9% culture time reduction. Unfortunately, direct talc addition proved to be infeasible for natamycin fermentation in a 5 L fermentor, which was attributed to physical damage from rapid agitation and excessive talc crashing. Therefore, the morphology engineering strategy was preferred in the seed preculture process rather than formal fermentation for natamycin production. CONCLUSION: The new strategy proposed in this study could not only improve natamycin production, but also reduced the culture time. Furthermore, this work could provide references for other biochemicals production by filamentous bacteria or fungi, which would be of great significance in industrial antibiotic fermentation. © 2021 Society of Chemical Industry

Published

2021

45. Regulation of autoimmune myocarditis by host responses to the microbiome.

Author

Barin, Jobert G., Talor, Monica V., Diny, Nicola L., Ong, SuFey, Schaub, Julie A., Gebremariam, Elizabeth, Bedja, Djahida, Chen, Guobao, Choi, Hee Sun, Hou, Xuezhou, Wu, Lei, Cardamone, Ashley B., Peterson, Daniel A., Rose, Noel R., and Čiháková, Daniela

Subjects

*MYOCARDITIS, *HUMAN microbiota, *AUTOIMMUNE diseases, *VENTRICULAR remodeling, *ANIMAL models in research

Abstract

The extensive, diverse communities that constitute the microbiome are increasingly appreciated as important regulators of human health and disease through inflammatory, immune, and metabolic pathways. We sought to elucidate pathways by which microbiota contribute to inflammatory, autoimmune cardiac disease. We employed an animal model of experimental autoimmune myocarditis (EAM), which results in inflammatory and autoimmune pathophysiology and subsequent maladaptive cardiac remodeling and heart failure. Antibiotic dysbiosis protected mice from EAM and fibrotic cardiac dysfunction. Additionally, mice derived from different sources with different microbiome colonization profiles demonstrated variable susceptibility to disease. Unexpectedly, it did not track with segmented filamentous bacteria (SFB)-driven Th17 programming of CD4 + T cells in the steady-state gut. Instead, we found disease susceptibility to track with presence of type 3 innate lymphoid cells (ILC3s). Ablating ILCs by antibody depletion or genetic tools in adoptive transfer variants of the EAM model demonstrated that ILCs and microbiome profiles contributed to the induction of CCL20/CCR6-mediated inflammatory chemotaxis to the diseased heart. From these data, we conclude that sensing of the microbiome by ILCs is an important checkpoint in the development of inflammatory cardiac disease processes through their ability to elicit cardiotropic chemotaxis. [ABSTRACT FROM AUTHOR]

Published

2017

46. TCDD administered on activated carbon eliminates bioavailability and subsequent shifts to a key murine gut commensal.

Author

Stedtfeld, Robert, Brett Sallach, J., Crawford, Robert, Stedtfeld, Tiffany, Williams, Maggie, Waseem, Hassan, Johnston, Cliff, Li, Hui, Teppen, Brian, Kaminski, Norbert, Boyd, Stephen, Tiedje, James, and Hashsham, Syed

Subjects

*ACTIVATED carbon, *BIOAVAILABILITY, *TETRACHLORODIBENZODIOXIN, *GUT microbiome, *RNA sequencing

Abstract

Activated carbon (AC) is an increasingly attractive remediation alternative for the sequestration of dioxins at contaminated sites globally. However, the potential for AC to reduce the bioavailability of dioxins in mammals and the residing gut microbiota has received less attention. This question was partially answered in a recent study examining 2,3,7,8-tetrachlorodibenzo- p-dioxin (TCDD)-induced hallmark toxic responses in mice administered with TCDD sequestered by AC or freely available in corn oil by oral gavage. Results from that study support the use of AC to significantly reduce the bioavailability of TCDD to the host. Herein, we examined the bioavailability of TCDD sequestered to AC on a key murine gut commensal and the influence of AC on the community structure of the gut microbiota. The analysis included qPCR to quantify the expression of segmented filamentous bacteria (SFB) in the mouse ileum, which has responded to TCDD-induced host toxicity in previous studies and community structure via sequencing the 16S ribosomal RNA (rRNA) gene. The expression of SFB 16S rRNA gene and functional genes significantly increased with TCDD administered with corn oil vehicle. Such a response was absent when TCDD was sequestered by AC. In addition, AC appeared to have a minimal influence on murine gut community structure and diversity, affecting only the relative abundance of Lactobacillaceae and two other groups. Results of this study further support the remedial use of AC for eliminating bioavailability of TCDD to host and subsequent influence on the gut microbiome. [ABSTRACT FROM AUTHOR]

Published

2017

47. Host Specificity of Flagellins from Segmented Filamentous Bacteria Affects Their Patterns of Interaction with Mouse Ileal Mucosal Proteins.

Author

Huahai Chen, Yeshi Yin, Yanling Wang, Xin Wang, and Xiang, Charlie

Subjects

*FILAMENTOUS bacteria, *PROKARYOTES, *ANTIBIOTICS, *BIOSYNTHESIS, *BIOMOLECULES

Abstract

Segmented filamentous bacteria (SFB) are known modulators of the mammalian immune system. Currently, the technology for investigating SFB culture in vitro is immature, and as a result, the mechanisms of SFB colonization and immune regulation are not yet fully elucidated. In this study, we investigated the gene diversity and host specificity of SFB flagellin genes. The fliC1 and fliC2 genes are relatively conserved, while the fliC3 and fliC4 genes are more variable, especially at the central and C-terminal regions. Host specificity analysis demonstrated that the fliC1 genes do not cluster together based on the host organism, whereas the fliC3 and fliC4 genes were host specific at the nucleotide and deduced amino acid levels. SFB flagellin protein expression in the ileum mucosa and cecal contents was detected by using fluorescence in situ hybridization (FISH) combined with immunohistochemical (IHC) analysis, immunoblotting, and liquid chromatography-tandem mass spectrometry (LC-MS/MS). Although the purified SFB FliC3 protein originating from both mouse and rat was able to activate Toll-like receptor 5 (TLR5)-linked NF-κB signaling, no host specificity was observed. Interestingly, the patterns of interaction with mouse ileum mucosal proteins were different for mouse FliC3 (mFliC3) and rat FliC3 (rFliC3). Gene Ontology (GO) and KEGG analyses indicated that more adherence-related proteins interacted with mFliC3, while more lysosome- and proteolysis-related proteins interacted with rFliC3. In vitro degradation experiments indicated that the stability of rFliC3 was lower than that of mFliC3 when they were incubated with mouse ileum mucosal proteins. In summary, the gene diversity and host specificity of SFB flagellin genes were investigated, and SFB flagellin expression was detected in gut samples. [ABSTRACT FROM AUTHOR]

Published

2017

48. Modulatory Influence of Segmented Filamentous Bacteria on Transcriptomic Response of Gnotobiotic Mice Exposed to TCDD.

Author

Stedtfeld, Robert D., Chai, Benli, Crawford, Robert B., Stedtfeld, Tiffany M., Williams, Maggie R., Shao Xiangwen, Tomomi Kuwahara, Cole, James R., Kaminski, Norbert E., Tiedje, James M., and Hashsham, Syed A.

Abstract

Environmental toxicants such as 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD), an aryl hydrocarbon receptor (AhR), are known to induce host toxicity and structural shifts in the gut microbiota. Key bacterial populations with similar or opposing functional responses to AhR ligand exposure may potentially help regulate expression of genes associated with immune dysfunction. To examine this question and the mechanisms for AhR ligand-induced bacterial shifts, C57BL/6 gnotobiotic mice were colonized with and without segmented filamentous bacteria (SFB) – an immune activator. Mice were also colonized with polysaccharide A producing Bacteroides fragilis – an immune suppressor to serve as a commensal background. Following colonization, mice were administered TCDD (30 μg/kg) every 4 days for 28 days by oral gavage. Quantified with the nCounter® mouse immunology panel, opposing responses in ileal gene expression (e.g., genes associated with T-cell differentiation via the class II major histocompatibility complex) as a result of TCDD dosing and SFB colonization were observed. Genes that responded to TCDD in the presence of SFB did not show a significant response in the absence of SFB, and vice versa. Regulatory T-cells examined in the mesenteric lymph-nodes, spleen, and blood were also less impacted by TCDD in mice colonized with SFB. TCDD-induced shifts in abundance of SFB and B. fragilis compared with previous studies in mice with a traditional gut microbiome. With regard to the mouse model colonized with individual populations, results indicate that TCDD-induced host response was significantly modulated by the presence of SFB in the gut microbiome, providing insight into therapeutic potential between AhR ligands and key commensals. [ABSTRACT FROM AUTHOR]

Published

2017

49. Metabolic adaptation to the aqueous leaf extract of Moringa oleifera Lam.-supplemented diet is related to the modulation of gut microbiota in mice.

Author

Gao, Xiaoyu, Xie, Qiuhong, Liu, Ling, Kong, Ping, Sheng, Jun, and Xiang, Hongyu

Subjects

*MORINGA oleifera, *BODY weight, *FILAMENTOUS bacteria, *GLUCOSINOLATES, *HYPOCHOLESTEREMIA

Abstract

The aqueous leaf extract of Moringa oleifera Lam. (LM-A) is reported to have many health beneficial bioactivities and no obvious toxicity, but have mild adverse effects. Little is known about the mechanism of these reported adverse effects. Notably, there has been no report about the influence of LM-A on intestinal microecology. In this study, animal experiments were performed to explore the relationships between metabolic adaptation to an LM-A-supplemented diet and gut microbiota changes. After 8-week feeding with normal chow diet, the body weight of mice entered a stable period, and one of the group received daily doses of 750-mg/kg body weight LM-A by gavage for 4 weeks (assigned as LM); the other group received the vehicle (assigned as NCD). The liver weight to body weight ratio was enhanced, and the ceca were enlarged in the LM group compared with the NCD group. LM-A-supplemented-diet mice elicited a uniform metabolic adaptation, including slightly influenced fasting glucose and blood lipid profiles, significantly reduced liver triglycerides content, enhanced serum lipopolysaccharide level, activated inflammatory responses in the intestine and liver, compromised gut barrier function, and broken intestinal homeostasis. Many metabolic changes in mice were significantly correlated with altered specific gut bacteria. Changes in Firmicutes, Eubacterium rectale/ Clostridium coccoides group, Faecalibacterium prausnitzii, Akkermansia muciniphila, segmented filamentous bacteria, Enterococcus spp., and Sutterella spp. may play an important role in the process of host metabolic adaptation to LM-A administration. Our research provides an explanation of the adverse effects of LM-A administration on normal adult individuals in the perspective of microecology. [ABSTRACT FROM AUTHOR]

Published

2017

50. Microbe Hunting Hits Home.

Author

Ivanov, Ivaylo I.

Abstract

Ten years ago, we discovered that microbiota composition controls intestinal T cell homeostasis and alters T cell responses of mice in different animal facilities. Here I discuss how these discoveries, reported in Cell Host & Microbe in 2008, came to be and contributed to our understanding of microbiota immune effects. [ABSTRACT FROM AUTHOR]

Published

2017