Your search keyword '"Clostridium scindens"' showing total 39 results

1. Strain-dependent induction of primary bile acid 7-dehydroxylation by cholic acid

Author

Eduard Vico-Oton, Colin Volet, Nicolas Jacquemin, Yuan Dong, Siegfried Hapfelmeier, Karin Lederballe Meibom, and Rizlan Bernier-Latmani

Subjects

7-dehydroxylation, Clostridium scindens, Extibacter muris, Gut microbiome, Deoxycholic acid (DCA), Lithocholic acid (LCA), Microbiology, QR1-502

Abstract

Abstract Background Bile acids (BAs) are steroid-derived molecules with important roles in digestion, the maintenance of host metabolism, and immunomodulation. Primary BAs are synthesized by the host, while secondary BAs are produced by the gut microbiome through transformation of the former. The regulation of microbial production of secondary BAs is not well understood, particularly the production of 7-dehydroxylated BAs, which are the most potent agonists for host BA receptors. The 7-dehydroxylation of cholic acid (CA) is well established and is linked to the expression of a bile acid-inducible (bai) operon responsible for this process. However, little to no 7-dehydroxylation has been reported for other host-derived BAs (e.g., chenodeoxycholic acid, CDCA or ursodeoxycholic acid, UDCA). Results Here, we demonstrate that the 7-dehydroxylation of CDCA and UDCA by the human isolate Clostridium scindens is induced when CA is present, suggesting that CA-dependent transcriptional regulation is required for substantial 7-dehydroxylation of these primary BAs. This is supported by the finding that UDCA alone does not promote expression of bai genes. CDCA upregulates expression of the bai genes but the expression is greater when CA is present. In contrast, the murine isolate Extibacter muris exhibits a distinct response; CA did not induce significant 7-dehydroxylation of primary BAs, whereas BA 7-dehydroxylation was promoted upon addition of germ-free mouse cecal content in vitro. However, E. muris was found to 7-dehydroxylate in vivo. Conclusions The distinct expression responses amongst strains indicate that bai genes are regulated differently. CA promoted bai operon gene expression and the 7-dehydroxylating activity in C. scindens strains. Conversely, the in vitro activity of E. muris was promoted only after the addition of cecal content and the isolate did not alter bai gene expression in response to CA. The accessory gene baiJ was only upregulated in the C. scindens ATCC 35704 strain, implying mechanistic differences amongst isolates. Interestingly, the human-derived C. scindens strains were also capable of 7-dehydroxylating murine bile acids (muricholic acids) to a limited extent. This study shows novel 7-dehydroxylation activity in vitro resulting from the presence of CA and suggests distinct bai gene expression across bacterial species.

Published

2024

2. Strain-dependent induction of primary bile acid 7-dehydroxylation by cholic acid.

Author

Vico-Oton, Eduard, Volet, Colin, Jacquemin, Nicolas, Dong, Yuan, Hapfelmeier, Siegfried, Meibom, Karin Lederballe, and Bernier-Latmani, Rizlan

Abstract

Background: Bile acids (BAs) are steroid-derived molecules with important roles in digestion, the maintenance of host metabolism, and immunomodulation. Primary BAs are synthesized by the host, while secondary BAs are produced by the gut microbiome through transformation of the former. The regulation of microbial production of secondary BAs is not well understood, particularly the production of 7-dehydroxylated BAs, which are the most potent agonists for host BA receptors. The 7-dehydroxylation of cholic acid (CA) is well established and is linked to the expression of a bile acid-inducible (bai) operon responsible for this process. However, little to no 7-dehydroxylation has been reported for other host-derived BAs (e.g., chenodeoxycholic acid, CDCA or ursodeoxycholic acid, UDCA). Results: Here, we demonstrate that the 7-dehydroxylation of CDCA and UDCA by the human isolate Clostridium scindens is induced when CA is present, suggesting that CA-dependent transcriptional regulation is required for substantial 7-dehydroxylation of these primary BAs. This is supported by the finding that UDCA alone does not promote expression of bai genes. CDCA upregulates expression of the bai genes but the expression is greater when CA is present. In contrast, the murine isolate Extibacter muris exhibits a distinct response; CA did not induce significant 7-dehydroxylation of primary BAs, whereas BA 7-dehydroxylation was promoted upon addition of germ-free mouse cecal content in vitro. However, E. muris was found to 7-dehydroxylate in vivo. Conclusions: The distinct expression responses amongst strains indicate that bai genes are regulated differently. CA promoted bai operon gene expression and the 7-dehydroxylating activity in C. scindens strains. Conversely, the in vitro activity of E. muris was promoted only after the addition of cecal content and the isolate did not alter bai gene expression in response to CA. The accessory gene baiJ was only upregulated in the C. scindens ATCC 35704 strain, implying mechanistic differences amongst isolates. Interestingly, the human-derived C. scindens strains were also capable of 7-dehydroxylating murine bile acids (muricholic acids) to a limited extent. This study shows novel 7-dehydroxylation activity in vitro resulting from the presence of CA and suggests distinct bai gene expression across bacterial species. [ABSTRACT FROM AUTHOR]

Published

2024

3. BaiJ and BaiB are key enzymes in the chenodeoxycholic acid 7α-dehydroxylation pathway in the gut microbe Clostridium scindens ATCC 35704

Author

Karin Lederballe Meibom, Solenne Marion, Colin Volet, Théo Nass, Eduard Vico-Oton, Laure Menin, and Rizlan Bernier-Latmani

Subjects

Clostridium scindens, bile acids, 7α-dehydroxylation, gut microbes, bai genes, chenodeoxycholic acid, Diseases of the digestive system. Gastroenterology, RC799-869

Abstract

ABSTRACTBile acid transformation is a common gut microbiome activity that produces secondary bile acids, some of which are important for human health. One such process, 7α-dehydroxylation, converts the primary bile acids, cholic acid and chenodeoxycholic acid, to deoxycholic acid and lithocholic acid, respectively. This transformation requires a number of enzymes, generally encoded in a bile acid-inducible (bai) operon and consists of multiple steps. Some 7α-dehydroxylating bacteria also harbor additional genes that encode enzymes with potential roles in this pathway, but little is known about their functions. Here, we purified 11 enzymes originating either from the bai operon or encoded at other locations in the genome of Clostridium scindens strain ATCC 35704. Enzyme activity was probed in vitro under anoxic conditions to characterize the biochemical pathway of chenodeoxycholic acid 7α-dehydroxylation. We found that more than one combination of enzymes can support the process and that a set of five enzymes, including BaiJ that is encoded outside the bai operon, is sufficient to achieve the transformation. We found that BaiJ, an oxidoreductase, exhibits an activity that is not harbored by the homologous enzyme from another C. scindens strain. Furthermore, ligation of bile acids to coenzyme A (CoA) was shown to impact the product of the transformation. These results point to differences in the 7α-dehydroxylation pathway among microorganisms and the crucial role of CoA ligation in the process.

Published

2024

4. SIMMER employs similarity algorithms to accurately identify human gut microbiome species and enzymes capable of known chemical transformations

Author

Bustion, Annamarie E, Nayak, Renuka R, Agrawal, Ayushi, Turnbaugh, Peter J, and Pollard, Katherine S

Subjects

Microbiology, Biochemistry and Cell Biology, Biological Sciences, Microbiome, Bioengineering, Networking and Information Technology R&D (NITRD), 5.1 Pharmaceuticals, 2.2 Factors relating to the physical environment, Oral and gastrointestinal, Infection, Humans, Gastrointestinal Microbiome, Microbiota, Bacteria, Food, Algorithms, microbiome metabolism, enzyme prediction, methotrexate, Clostridium scindens, biochemistry, chemical biology, computational biology, systems biology, Biological sciences, Biomedical and clinical sciences, Health sciences

Abstract

Bacteria within the gut microbiota possess the ability to metabolize a wide array of human drugs, foods, and toxins, but the responsible enzymes for these chemical events remain largely uncharacterized due to the time-consuming nature of current experimental approaches. Attempts have been made in the past to computationally predict which bacterial species and enzymes are responsible for chemical transformations in the gut environment, but with low accuracy due to minimal chemical representation and sequence similarity search schemes. Here, we present an in silico approach that employs chemical and protein Similarity algorithms that Identify MicrobioMe Enzymatic Reactions (SIMMER). We show that SIMMER accurately predicts the responsible species and enzymes for a queried reaction, unlike previous methods. We demonstrate SIMMER use cases in the context of drug metabolism by predicting previously uncharacterized enzymes for 88 drug transformations known to occur in the human gut. We validate these predictions on external datasets and provide an in vitro validation of SIMMER's predictions for metabolism of methotrexate, an anti-arthritic drug. After demonstrating its utility and accuracy, we made SIMMER available as both a command-line and web tool, with flexible input and output options for determining chemical transformations within the human gut. We present SIMMER as a computational addition to the microbiome researcher's toolbox, enabling them to make informed hypotheses before embarking on the lengthy laboratory experiments required to characterize novel bacterial enzymes that can alter human ingested compounds.

Published

2023

5. Clostridium scindens exacerbates experimental necrotizing enterocolitis via upregulation of the apical sodium-dependent bile acid transporter.

Author

Calton, Christine M., Carothers, Katelyn, Ramamurthy, Shylaja, Jagadish, Neha, Phanindra, Bhumika, Garcia, Anett, Viswanathan, V. K., and Halpern, Melissa D.

Subjects

*BILE acids, *CLOSTRIDIA, *ENTEROCOLITIS, *PREMATURE infants, *CLOSTRIDIUM, *RAT diseases, *DEOXYCHOLIC acid

Abstract

Necrotizing enterocolitis (NEC) is the most common gastrointestinal emergency in premature infants. Evidence indicates that bile acid homeostasis is disrupted during NEC: ileal bile acid levels are elevated in animals with experimental NEC, as is expression of the apical sodium-dependent bile acid transporter (Asbt). In addition, bile acids, which are synthesized in the liver, are extensively modified by the gut microbiome, including via the conversion of primary bile acids to more cytotoxic secondary forms. We hypothesized that the addition of bile acid-modifying bacteria would increase susceptibility to NEC in a neonatal rat model of the disease. The secondary bile acid-producing species Clostridium scindens exacerbated both incidence and severity of NEC. C. scindens upregulated the bile acid transporter Asbt and increased levels of intraenterocyte bile acids. Treatment with C. scindens also altered bile acid profiles and increased hydrophobicity of the ileal intracellular bile acid pool. The ability of C. scindens to enhance NEC requires bile acids, as pharmacological sequestration of ileal bile acids protects animals from developing disease. These findings indicate that bile acid-modifying bacteria can contribute to NEC pathology and provide additional evidence for the role of bile acids in the pathophysiology of experimental NEC. NEW & NOTEWORTHY: Necrotizing enterocolitis (NEC), a life-threatening gastrointestinal emergency in premature infants, is characterized by dysregulation of bile acid homeostasis. We demonstrate that administering the secondary bile acid-producing bacterium Clostridium scindens enhances NEC in a neonatal rat model of the disease. C. scindens-enhanced NEC is dependent on bile acids and driven by upregulation of the ileal bile acid transporter Asbt. This is the first report of bile acid-modifying bacteria exacerbating experimental NEC pathology. [ABSTRACT FROM AUTHOR]

Published

2024

6. Clostridium scindens metabolites trigger prostate cancer progression through androgen receptor signaling

Author

Ngoc-Niem Bui, Chen-Yi Li, Ling-Yu Wang, Yu-An Chen, Wei-Hsiang Kao, Li-Fang Chou, Jer-Tsong Hsieh, Ho Lin, and Chih-Ho Lai

Subjects

Clostridium scindens, Bacterial metabolite, Prostate cancer, Androgen, Microbiology, QR1-502

Abstract

Prostate cancer (PCa) is one of the most common malignancies in men; recently, PCa-related mortality has increased worldwide. Although androgen deprivation therapy (ADT) is the standard treatment for PCa, patients often develop aggressive castration-resistant PCa (CRPC), indicating the presence of an alternative source of androgen. Clostridium scindens is a member of the gut microbiota and can convert cortisol to 11β-hydroxyandrostenedione (11β-OHA), which is a potent androgen precursor. However, the effect of C. scindens on PCa progression has not been determined. In this study, androgen-dependent PCa cells (LNCaP) were employed to investigate whether C. scindens-derived metabolites activate androgen receptor (AR), which is a pivotal step in the development of PCa. Results showed that cortisol metabolites derived from C. scindens-conditioned medium promoted proliferation and enhanced migration of PCa cells. Furthermore, cells treated with these metabolites presented activated AR and stimulated AR-regulated genes. These findings reveal that C. scindens has the potential to promote PCa progression via the activation of AR signaling. Further studies on the gut–prostate axis may help unravel an alternative source of androgen that triggers CRPC exacerbation.

Published

2023

7. Clostridium scindens secretome suppresses virulence gene expression of Clostridioides difficile in a bile acid-independent manner

Author

Carmen Saenz, Qing Fang, Thiyagarajan Gnanasekaran, Samuel Addison Jack Trammell, Jesse Arnold Buijink, Paola Pisano, Michael Wierer, Frédéric Moens, Bettina Lengger, Asker Brejnrod, and Manimozhiyan Arumugam

Subjects

Clostridioides difficile infection, Clostridium scindens, bile acids, secretome, Human Intestinal Microbial Ecosystem, gut microbiome, Microbiology, QR1-502

Abstract

ABSTRACT Clostridioides difficile infection (CDI) is a major health concern and one of the leading causes of hospital-acquired diarrhea in many countries. C. difficile infection is challenging to treat as C. difficile is resistant to multiple antibiotics. Alternative solutions are needed as conventional treatment with broad-spectrum antibiotics often leads to recurrent CDI. Recent studies have shown that specific microbiota-based therapeutics such as bile acids (BAs) are promising approaches to treat CDI. Clostridium scindens encodes the bile acid-induced (bai) operon that carries out 7-alpha-dehydroxylation of liver-derived primary BAs to secondary BAs. This biotransformation is thought to increase the antibacterial effects of BAs on C. difficile. Here, we used an automated multistage fermentor to study the antibacterial actions of C. scindens and BAs on C. difficile in the presence/absence of a gut microbial community derived from healthy human donor fecal microbiota. We observed that C. scindens inhibited C. difficile growth when the medium was supplemented with primary BAs. Transcriptomic analysis indicated upregulation of C. scindens bai operon and suppressed expression of C. difficile exotoxins that mediate CDI. We also observed BA-independent antibacterial activity of the secretome from C. scindens cultured overnight in a medium without supplementary primary BAs, which suppressed growth and exotoxin expression in C. difficile mono-culture. Further investigation of the molecular basis of our observation could lead to a more specific treatment for CDI than current approaches. IMPORTANCE There is an urgent need for new approaches to replace the available treatment options against Clostridioides difficile infection (CDI). Our novel work reports a bile acid-independent reduction of C. difficile growth and virulence gene expression by the secretome of Clostridium scindens. This potential treatment combined with other antimicrobial strategies could facilitate the development of alternative therapies in anticipation of CDI and in turn reduce the risk of antimicrobial resistance.

Published

2023

8. SIMMER employs similarity algorithms to accurately identify human gut microbiome species and enzymes capable of known chemical transformations

Author

Annamarie E Bustion, Renuka R Nayak, Ayushi Agrawal, Peter J Turnbaugh, and Katherine S Pollard

Subjects

microbiome metabolism, enzyme prediction, methotrexate, Clostridium scindens, Medicine, Science, Biology (General), QH301-705.5

Abstract

Bacteria within the gut microbiota possess the ability to metabolize a wide array of human drugs, foods, and toxins, but the responsible enzymes for these chemical events remain largely uncharacterized due to the time-consuming nature of current experimental approaches. Attempts have been made in the past to computationally predict which bacterial species and enzymes are responsible for chemical transformations in the gut environment, but with low accuracy due to minimal chemical representation and sequence similarity search schemes. Here, we present an in silico approach that employs chemical and protein Similarity algorithms that Identify MicrobioMe Enzymatic Reactions (SIMMER). We show that SIMMER accurately predicts the responsible species and enzymes for a queried reaction, unlike previous methods. We demonstrate SIMMER use cases in the context of drug metabolism by predicting previously uncharacterized enzymes for 88 drug transformations known to occur in the human gut. We validate these predictions on external datasets and provide an in vitro validation of SIMMER’s predictions for metabolism of methotrexate, an anti-arthritic drug. After demonstrating its utility and accuracy, we made SIMMER available as both a command-line and web tool, with flexible input and output options for determining chemical transformations within the human gut. We present SIMMER as a computational addition to the microbiome researcher’s toolbox, enabling them to make informed hypotheses before embarking on the lengthy laboratory experiments required to characterize novel bacterial enzymes that can alter human ingested compounds.

Published

2023

9. Membrane Vesicles Derived From Clostridium botulinum and Related Clostridial Species Induce Innate Immune Responses via MyD88/TRIF Signaling in vitro.

Author

Kobayashi, Nobuhide, Abe, Kimihiro, Akagi, Sachiyo, Kitamura, Mayu, Shiraishi, Yoshitake, Yamaguchi, Aki, Yutani, Masahiro, Amatsu, Sho, Matsumura, Takuhiro, Nomura, Nobuhiko, Ozaki, Noriyuki, Obana, Nozomu, and Fujinaga, Yukako

Subjects

CLOSTRIDIUM botulinum, IMMUNE response, BACTERIAL cell walls, BOTULINUM toxin, MYELOID differentiation factor 88, TOLL-like receptors, MACROPHAGE inflammatory proteins

Abstract

Clostridium botulinum produces botulinum neurotoxin complexes that cause botulism. Previous studies elucidated the molecular pathogenesis of botulinum neurotoxin complexes; however, it currently remains unclear whether other components of the bacterium affect host cells. Recent studies provided insights into the role of bacterial membrane vesicles (MVs) produced by some bacterial species in host immunity and pathology. We herein examined and compared the cellular effects of MVs isolated from four strains of C. botulinum with those of closely related Clostridium sporogenes and two strains of the symbiont Clostridium scindens. MVs derived from all strains induced inflammatory cytokine expression in intestinal epithelial and macrophage cell lines. Cytokine expression was dependent on myeloid differentiation primary response (MyD) 88 and TIR-domain-containing adapter-inducing interferon-β (TRIF), essential adaptors for toll-like receptors (TLRs), and TLR1/2/4. The inhibition of actin polymerization impeded the uptake of MVs in RAW264.7 cells, however, did not reduce the induction of cytokine expression. On the other hand, the inhibition of dynamin or phosphatidylinositol-3 kinase (PI3K) suppressed the induction of cytokine expression by MVs, suggesting the importance of these factors downstream of TLR signaling. MVs also induced expression of Reg3 family antimicrobial peptides via MyD88/TRIF signaling in primary cultured mouse small intestinal epithelial cells (IECs). The present results indicate that MVs from C. botulinum and related clostridial species induce host innate immune responses. [ABSTRACT FROM AUTHOR]

Published

2022

10. Membrane Vesicles Derived From Clostridium botulinum and Related Clostridial Species Induce Innate Immune Responses via MyD88/TRIF Signaling in vitro

Author

Nobuhide Kobayashi, Kimihiro Abe, Sachiyo Akagi, Mayu Kitamura, Yoshitake Shiraishi, Aki Yamaguchi, Masahiro Yutani, Sho Amatsu, Takuhiro Matsumura, Nobuhiko Nomura, Noriyuki Ozaki, Nozomu Obana, and Yukako Fujinaga

Subjects

Clostridium botulinum, Clostridium sporogenes, Clostridium scindens, membrane vesicles, innate immunity, toll-like receptors, Microbiology, QR1-502

Abstract

Clostridium botulinum produces botulinum neurotoxin complexes that cause botulism. Previous studies elucidated the molecular pathogenesis of botulinum neurotoxin complexes; however, it currently remains unclear whether other components of the bacterium affect host cells. Recent studies provided insights into the role of bacterial membrane vesicles (MVs) produced by some bacterial species in host immunity and pathology. We herein examined and compared the cellular effects of MVs isolated from four strains of C. botulinum with those of closely related Clostridium sporogenes and two strains of the symbiont Clostridium scindens. MVs derived from all strains induced inflammatory cytokine expression in intestinal epithelial and macrophage cell lines. Cytokine expression was dependent on myeloid differentiation primary response (MyD) 88 and TIR-domain-containing adapter-inducing interferon-β (TRIF), essential adaptors for toll-like receptors (TLRs), and TLR1/2/4. The inhibition of actin polymerization impeded the uptake of MVs in RAW264.7 cells, however, did not reduce the induction of cytokine expression. On the other hand, the inhibition of dynamin or phosphatidylinositol-3 kinase (PI3K) suppressed the induction of cytokine expression by MVs, suggesting the importance of these factors downstream of TLR signaling. MVs also induced expression of Reg3 family antimicrobial peptides via MyD88/TRIF signaling in primary cultured mouse small intestinal epithelial cells (IECs). The present results indicate that MVs from C. botulinum and related clostridial species induce host innate immune responses.

Published

2022

11. Review: microbial transformations of human bile acids.

Author

Guzior, Douglas V. and Quinn, Robert A.

Subjects

BILE acids, CELLULAR signal transduction, DEHYDROGENATION, CIRRHOSIS of the liver, GUT microbiome

Abstract

Bile acids play key roles in gut metabolism, cell signaling, and microbiome composition. While the liver is responsible for the production of primary bile acids, microbes in the gut modify these compounds into myriad forms that greatly increase their diversity and biological function. Since the early 1960s, microbes have been known to transform human bile acids in four distinct ways: deconjugation of the amino acids glycine or taurine, and dehydroxylation, dehydrogenation, and epimerization of the cholesterol core. Alterations in the chemistry of these secondary bile acids have been linked to several diseases, such as cirrhosis, inflammatory bowel disease, and cancer. In addition to the previously known transformations, a recent study has shown that members of our gut microbiota are also able to conjugate amino acids to bile acids, representing a new set of "microbially conjugated bile acids." This new finding greatly influences the diversity of bile acids in the mammalian gut, but the effects on host physiology and microbial dynamics are mostly unknown. This review focuses on recent discoveries investigating microbial mechanisms of human bile acids and explores the chemical diversity that may exist in bile acid structures in light of the new discovery of microbial conjugations. 5Fy2KtZbjWrwhzxiWDK3TX Video Abstract [ABSTRACT FROM AUTHOR]

Published

2021

12. Conceptualizing the vertebrate sterolbiome.

Author

Ridlon, Jason M.

Subjects

*BIOCHEMISTRY, *MOLECULAR biology, *MICROBIAL genes, *BILE acids, *HOSTS (Biology), *STEROIDS

Abstract

Vertebrates synthesize a diverse set of steroids and bile acids that undergo bacterial biotransformations. The endocrine literature has principally focused on the biochemistry and molecular biology of host synthesis and tissue-specific metabolism of steroids. Host-associated microbiota possess a co-evolved set of steroid and bile acid modifying enzymes that match the majority of host peripheral biotransformations in addition to unique capabilities. The set of host associated microbial genes encoding enzymes involved in steroid transformations is known as the sterolbiome. This review focuses on the current knowledge of the sterolbiome as well as its importance in medicine and agriculture. [ABSTRACT FROM AUTHOR]

Published

2020

13. Clostridium scindens secretome suppresses virulence gene expression of Clostridioides difficile in a bile acid-independent manner

Author

Saenz, Carmen, Fang, Qing, Gnanasekaran, Thiyagarajan, Trammell, Samuel Addison Jack, Buijink, Jesse Arnold, Pisano, Paola, Wierer, Michael, Moens, Frédéric, Lengger, Bettina, Brejnrod, Asker, Arumugam, Manimozhiyan, Saenz, Carmen, Fang, Qing, Gnanasekaran, Thiyagarajan, Trammell, Samuel Addison Jack, Buijink, Jesse Arnold, Pisano, Paola, Wierer, Michael, Moens, Frédéric, Lengger, Bettina, Brejnrod, Asker, and Arumugam, Manimozhiyan

Abstract

Clostridioides difficile infection (CDI) is a major health concern and one of the leading causes of hospital-acquired diarrhea in many countries. C. difficile infection is challenging to treat as C. difficile is resistant to multiple antibiotics. Alternative solutions are needed as conventional treatment with broad-spectrum antibiotics often leads to recurrent CDI. Recent studies have shown that specific microbiota-based therapeutics such as bile acids (BAs) are promising approaches to treat CDI. Clostridium scindens encodes the bile acid-induced (bai) operon that carries out 7-alpha-dehydroxylation of liver-derived primary BAs to secondary BAs. This biotransformation is thought to increase the antibacterial effects of BAs on C. difficile. Here, we used an automated multistage fermentor to study the antibacterial actions of C. scindens and BAs on C. difficile in the presence/absence of a gut microbial community derived from healthy human donor fecal microbiota. We observed that C. scindens inhibited C. difficile growth when the medium was supplemented with primary BAs. Transcriptomic analysis indicated upregulation of C. scindens bai operon and suppressed expression of C. difficile exotoxins that mediate CDI. We also observed BA-independent antibacterial activity of the secretome from C. scindens cultured overnight in a medium without supplementary primary BAs, which suppressed growth and exotoxin expression in C. difficile mono-culture. Further investigation of the molecular basis of our observation could lead to a more specific treatment for CDI than current approaches.

Published

2023

14. Comparative Genomic and Physiological Analysis against Clostridium scindens Reveals Eubacterium sp. c-25 as an Atypical Deoxycholic Acid Producer of the Human Gut Microbiota

Author

Isaiah Song, Yasuhiro Gotoh, Yoshitoshi Ogura, Tetsuya Hayashi, Satoru Fukiya, and Atsushi Yokota

Subjects

secondary bile acid, deoxycholic acid, bai operon, gut microbiome, Clostridium scindens, Biology (General), QH301-705.5

Abstract

The human gut houses bile acid 7α-dehydroxylating bacteria that produce secondary bile acids such as deoxycholic acid (DCA) from host-derived bile acids through enzymes encoded by the bai operon. While recent metagenomic studies suggest that these bacteria are highly diverse and abundant, very few DCA producers have been identified. Here, we investigated the physiology and determined the complete genome sequence of Eubacterium sp. c-25, a DCA producer that was isolated from human feces in the 1980s. Culture experiments showed a preference for neutral to slightly alkaline pH in both growth and DCA production. Genomic analyses revealed that c-25 is phylogenetically distinct from known DCA producers and possesses a multi-cluster arrangement of predicted bile-acid inducible (bai) genes that is considerably different from the typical bai operon structure. This arrangement is also found in other intestinal bacterial species, possibly indicative of unconfirmed 7α-dehydroxylation capabilities. Functionality of the predicted bai genes was supported by the induced expression of baiB, baiCD, and baiH in the presence of cholic acid substrate. Taken together, Eubacterium sp. c-25 is an atypical DCA producer with a novel bai gene cluster structure that may represent an unexplored genotype of DCA producers in the human gut.

Published

2021

15. BaiJ and BaiB are key enzymes in the chenodeoxycholic acid 7α-dehydroxylation pathway in the gut microbe Clostridium scindens ATCC 35704.

Author

Meibom KL, Marion S, Volet C, Nass T, Vico-Oton E, Menin L, and Bernier-Latmani R

Subjects

Humans, Bile Acids and Salts metabolism, Clostridiales metabolism, Clostridium metabolism, Chenodeoxycholic Acid metabolism, Gastrointestinal Microbiome

Abstract

Bile acid transformation is a common gut microbiome activity that produces secondary bile acids, some of which are important for human health. One such process, 7α-dehydroxylation, converts the primary bile acids, cholic acid and chenodeoxycholic acid, to deoxycholic acid and lithocholic acid, respectively. This transformation requires a number of enzymes, generally encoded in a bile acid-inducible ( bai ) operon and consists of multiple steps. Some 7α-dehydroxylating bacteria also harbor additional genes that encode enzymes with potential roles in this pathway, but little is known about their functions. Here, we purified 11 enzymes originating either from the bai operon or encoded at other locations in the genome of Clostridium scindens strain ATCC 35704. Enzyme activity was probed in vitro under anoxic conditions to characterize the biochemical pathway of chenodeoxycholic acid 7α-dehydroxylation. We found that more than one combination of enzymes can support the process and that a set of five enzymes, including BaiJ that is encoded outside the bai operon, is sufficient to achieve the transformation. We found that BaiJ, an oxidoreductase, exhibits an activity that is not harbored by the homologous enzyme from another C. scindens strain. Furthermore, ligation of bile acids to coenzyme A (CoA) was shown to impact the product of the transformation. These results point to differences in the 7α-dehydroxylation pathway among microorganisms and the crucial role of CoA ligation in the process.

Published

2024

16. Clostridium scindens ATCC 35704: integration of nutritional requirements, the complete genome sequence, and global transcriptional responses to bile acids.

Author

Devendran, Saravanan, Shrestha, Rachana, Alves, João M.P., Wolf, Patricia G., Ly, Lindsey, Hernandez, Alvaro G., Méndez-García, Celia, Inboden, Ashley, Wiley, Jnai, Paul, Oindrila, Allen, Avery, Springer, Emily, Wright, Chris L., Fields, Christopher J., Daniel, Steven L., and Ridlon, Jason M.

Subjects

*BILE acids, *NUTRITIONAL requirements, *CHOLIC acid, *DEOXYCHOLIC acid, *NUCLEOTIDE sequencing, *TRYPTOPHAN

Abstract

In the human gut, Clostridium scindens ATCC 35704 is a predominant bacterium and one of the major bile acid 7α-dehydroxylating anaerobes. While this organism is well-studied relative to bile acid metabolism, little is known about the basic nutrition and physiology of C. scindens ATCC 35704. To determine the amino acid and vitamin requirements of C. scindens, the "leave one [amino acid group or vitamin] out" technique was used to eliminate the non-essential amino acids and vitamins. With this approach, the amino acid tryptophan and three vitamins (riboflavin, pantothenate, and pyridoxal) were found to be required for the growth of C. scindens. In the newly developed defined medium, C. scindens fermented glucose mainly to ethanol, acetate, formate, and H2. The genome of C. scindens ATCC 35704 was completed through PacBio sequencing. Pathway analysis of the genome sequence coupled with RNA-Seq analysis of gene expression under defined culture conditions revealed consistency with the growth requirements and end products of glucose metabolism. Induction with bile acids revealed complex and differential responses to cholic acid and deoxycholic acid, including the expression of potentially novel bile acid-inducible genes involved in cholic acid metabolism. Responses to toxic deoxycholic acid included expression of genes predicted to be involved in DNA repair, oxidative stress, cell wall maintenance/metabolism, chaperone synthesis, and down-regulation of one third of the genome. These analyses provide valuable insight into the overall biology of C. scindens which may be important in treatment of disease associated with increased colonic secondary bile acids. [ABSTRACT FROM AUTHOR]

Published

2019

17. Contribution of Inhibitory Metabolites and Competition for Nutrients to Colonization Resistance against Clostridioides difficile by Commensal Clostridium

Author

Amber D. Reed and Casey M. Theriot

Subjects

Clostridioides difficile, Clostridium scindens, secondary bile acids, deconjugation, dehydroxylation, epimerization, Biology (General), QH301-705.5

Abstract

Clostridioides difficile is an anaerobic pathogen that causes significant morbidity and mortality. Understanding the mechanisms of colonization resistance against C. difficile is important for elucidating the mechanisms by which C. difficile is able to colonize the gut after antibiotics. Commensal Clostridium play a key role in colonization resistance. They are able to modify bile acids which alter the C. difficile life cycle. Commensal Clostridium also produce other inhibitory metabolites including antimicrobials and short chain fatty acids. They also compete with C. difficile for vital nutrients such as proline. Understanding the mechanistic effects that these metabolites have on C. difficile and other gut pathogens is important for the development of new therapeutics against C. difficile infection (CDI), which are urgently needed.

Published

2021

18. Clostridium scindens secretome suppresses virulence gene expression of Clostridioides difficile in a bile acid-independent manner.

Author

Saenz C, Fang Q, Gnanasekaran T, Trammell SAJ, Buijink JA, Pisano P, Wierer M, Moens F, Lengger B, Brejnrod A, and Arumugam M

Abstract

Clostridioides difficile infection (CDI) is a major health concern and one of the leading causes of hospital-acquired diarrhea in many countries. C. difficile infection is challenging to treat as C. difficile is resistant to multiple antibiotics. Alternative solutions are needed as conventional treatment with broad-spectrum antibiotics often leads to recurrent CDI. Recent studies have shown that specific microbiota-based therapeutics such as bile acids (BAs) are promising approaches to treat CDI. Clostridium scindens encodes the bile acid-induced ( bai ) operon that carries out 7-alpha-dehydroxylation of liver-derived primary BAs to secondary BAs. This biotransformation is thought to increase the antibacterial effects of BAs on C. difficile . Here, we used an automated multistage fermentor to study the antibacterial actions of C. scindens and BAs on C. difficile in the presence/absence of a gut microbial community derived from healthy human donor fecal microbiota. We observed that C. scindens inhibited C. difficile growth when the medium was supplemented with primary BAs. Transcriptomic analysis indicated upregulation of C. scindens bai operon and suppressed expression of C. difficile exotoxins that mediate CDI. We also observed BA-independent antibacterial activity of the secretome from C. scinden s cultured overnight in a medium without supplementary primary BAs, which suppressed growth and exotoxin expression in C. difficile mono-culture. Further investigation of the molecular basis of our observation could lead to a more specific treatment for CDI than current approaches. IMPORTANCE There is an urgent need for new approaches to replace the available treatment options against Clostridioides difficile infection (CDI). Our novel work reports a bile acid-independent reduction of C. difficile growth and virulence gene expression by the secretome of Clostridium scindens . This potential treatment combined with other antimicrobial strategies could facilitate the development of alternative therapies in anticipation of CDI and in turn reduce the risk of antimicrobial resistance.

Published

2023

19. Complete genome sequence of the archetype bile acid 7α-dehydroxylating bacterium, Clostridium scindens VPI12708, isolated from human feces, circa 1980.

Author

Olivos Caicedo KY, Fernandez-Materan FV, Hernandez AG, Daniel SL, Alves JMP, and Ridlon JM

Abstract

Clostridium scindens strain VPI12708 serves as model organism to study bile acid 7α-dehydroxylating pathways. The closed circular genome of C. scindens VPI12708 was obtained by PacBio sequencing. The genome is composed of 3,983,052 bp, with 47.59% G + C, and 3,707 coding DNA sequences are predicted., Competing Interests: The authors declare no conflict of interest.

Published

2023

20. Engineering a Cortisol Sensing Enteric Probiotic.

Author

Litteral V, Migliozzi R, Metzger D, McPherson C, and Saldanha R

Subjects

Humans, Engineering, Hydrocortisone, Escherichia coli

Abstract

Chronic stress can lead to prolonged adrenal gland secretion of cortisol, resulting in human ailments such as anxiety, post-traumatic stress disorder, metabolic syndrome, diabetes, immunosuppression, and cardiomyopathy. Real time monitoring of chronic increases in cortisol and intervening therapies to minimize the physiological effects of stress would be beneficial to prevent these endocrine related illnesses. Gut microbiota have shown the ability to secrete, respond, and even regulate endocrine hormones. One such microbe, Clostridium scindens , responds transcriptionally to cortisol. We engineered these cortisol responsive genetic elements from C. scindens into an enteric probiotic, E. coli Nissle 1917, to drive the expression of a fluorescent reporter allowing for the designing, testing, and building of a robust and physiologically relevant novel cortisol probiotic sensor. This smart probiotic was further engineered to be more sensitive and to respond to elevated cortisol by expressing tryptophan decarboxylase, thereby bestowing the ability to generate tryptamine and serotonin. Here we show that upon cortisol treatment the smart probiotic produces measurable amounts of tryptamine. Accumulated levels of these neuromodulators should improve mood, anxiety, and depression and drive down cortisol levels. Importantly, this work can serve as a model for the engineering of a sense-and-respond probiotic to modulate the gut-brain axis.

Published

2023

21. Metabolism of Oxo-Bile Acids and Characterization of Recombinant 12α-Hydroxysteroid Dehydrogenases from Bile Acid 7α-Dehydroxylating Human Gut Bacteria.

Author

Doden, Heidi, Sallam, Lina A., Devendran, Saravanan, Ly, Lindsey, Doden, Greta, Daniel, Steven L., Alves, João M. P., and Ridlon, Jason M.

Subjects

*HYDROXYSTEROID dehydrogenases, *DEHYDROGENASES, *BILE acids, *CLOSTRIDIUM, *HORMONES

Abstract

Bile acids are important cholesterol-derived nutrient signaling hormones, synthesized in the liver, that act as detergents to solubilize dietary lipids. Bile acid 7α-dehydroxylating gut bacteria generate the toxic bile acids deoxycholic acid and lithocholic acid from host bile acids. The ability of these bacteria to remove the 7-hydroxyl group is partially dependent on 7α-hydroxysteroid dehydrogenase (HSDH) activity, which reduces 7-oxo-bile acids generated by other gut bacteria. 3α-HSDH has an important enzymatic activity in the bile acid 7α-dehydroxylation pathway. 12α-HSDH activity has been reported for the low-activity bile acid 7α-dehydroxylating bacterium Clostridium leptum; however, this activity has not been reported for high-activity bile acid 7α-dehydroxylating bacteria, such as Clostridium scindens, Clostridium hylemonae, and Clostridium hiranonis. Here, we demonstrate that these strains express bile acid 12α-HSDH. The recombinant enzymes were characterized from each species and shown to preferentially reduce 12-oxolithocholic acid to deoxycholic acid, with low activity against 12-oxochenodeoxycholic acid and reduced activity when bile acids were conjugated to taurine or glycine. Phylogenetic analysis suggests that 12α-HSDH is widespread among Firmicutes, Actinobacteria in the Coriobacteriaceae family, and human gut Archaea. IMPORTANCE 12α-HSDH activity has been established in the medically important bile acid 7α-dehydroxylating bacteria C. scindens, C. hiranonis, and C. hylemonae. Experiments with recombinant 12α-HSDHs from these strains are consistent with culture-based experiments that show a robust preference for 12-oxolithocholic acid over 12-oxochenodeoxycholic acid. Phylogenetic analysis identified novel members of the gut microbiome encoding 12α-HSDH. Future reengineering of 12α-HSDH enzymes to preferentially oxidize cholic acid may provide a means to industrially produce the therapeutic bile acid ursodeoxycholic acid. In addition, a cholic acid-specific 12α-HSDH expressed in the gut may be useful for the reduction in deoxycholic acid concentration, a bile acid implicated in cancers of the gastrointestinal (GI) tract. [ABSTRACT FROM AUTHOR]

Published

2018

22. Review: microbial transformations of human bile acids

Author

Robert A. Quinn and Douglas V. Guzior

Subjects

Microbiology (medical), Taurine, medicine.drug_class, Review, Bile acid, Biology, Gut flora, digestive system, Microbiology, Bile Acids and Salts, Microbial ecology, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, medicine, Animals, Humans, Cholic acid, Microbiome, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, Clostridium scindens, Conjugation, Microbiota, QR100-130, Metabolism, biology.organism_classification, Inflammatory Bowel Diseases, Amino acid, Gastrointestinal Microbiome, Enterocloster bolteae, chemistry, Biochemistry, Glycine, 030211 gastroenterology & hepatology, Gut health

Abstract

Bile acids play key roles in gut metabolism, cell signaling, and microbiome composition. While the liver is responsible for the production of primary bile acids, microbes in the gut modify these compounds into myriad forms that greatly increase their diversity and biological function. Since the early 1960s, microbes have been known to transform human bile acids in four distinct ways: deconjugation of the amino acids glycine or taurine, and dehydroxylation, dehydrogenation, and epimerization of the cholesterol core. Alterations in the chemistry of these secondary bile acids have been linked to several diseases, such as cirrhosis, inflammatory bowel disease, and cancer. In addition to the previously known transformations, a recent study has shown that members of our gut microbiota are also able to conjugate amino acids to bile acids, representing a new set of “microbially conjugated bile acids.” This new finding greatly influences the diversity of bile acids in the mammalian gut, but the effects on host physiology and microbial dynamics are mostly unknown. This review focuses on recent discoveries investigating microbial mechanisms of human bile acids and explores the chemical diversity that may exist in bile acid structures in light of the new discovery of microbial conjugations. Video Abstract Electronic supplementary material The online version contains supplementary material available at 10.1186/s40168-021-01101-1.

Published

2021

23. SIMMER employs similarity algorithms to accurately identify human gut microbiome species and enzymes capable of known chemical transformations.

Author

Bustion AE, Nayak RR, Agrawal A, Turnbaugh PJ, and Pollard KS

Subjects

Humans, Bacteria metabolism, Food, Algorithms, Gastrointestinal Microbiome, Microbiota

Abstract

Bacteria within the gut microbiota possess the ability to metabolize a wide array of human drugs, foods, and toxins, but the responsible enzymes for these chemical events remain largely uncharacterized due to the time-consuming nature of current experimental approaches. Attempts have been made in the past to computationally predict which bacterial species and enzymes are responsible for chemical transformations in the gut environment, but with low accuracy due to minimal chemical representation and sequence similarity search schemes. Here, we present an in silico approach that employs chemical and protein S imilarity algorithms that I dentify M icrobio M e E nzymatic R eactions (SIMMER). We show that SIMMER accurately predicts the responsible species and enzymes for a queried reaction, unlike previous methods. We demonstrate SIMMER use cases in the context of drug metabolism by predicting previously uncharacterized enzymes for 88 drug transformations known to occur in the human gut. We validate these predictions on external datasets and provide an in vitro validation of SIMMER's predictions for metabolism of methotrexate, an anti-arthritic drug. After demonstrating its utility and accuracy, we made SIMMER available as both a command-line and web tool, with flexible input and output options for determining chemical transformations within the human gut. We present SIMMER as a computational addition to the microbiome researcher's toolbox, enabling them to make informed hypotheses before embarking on the lengthy laboratory experiments required to characterize novel bacterial enzymes that can alter human ingested compounds., Competing Interests: AB, RN, AA No competing interests declared, PT Reviewing editor, eLife, KP is a consultant for Phylagen Inc, (© 2023, Bustion et al.)

Published

2023

24. Functional Intestinal Bile Acid 7α-Dehydroxylation by Clostridium scindens Associated with Protection from Clostridium difficile Infection in a Gnotobiotic Mouse Model.

Author

Studer, Nicolas, Desharnais, Lyne, Beutler, Markus, Brugiroux, Sandrine, Terrazos, Miguel A., Menin, Laure, Schürch, Christian M., McCoy, Kathy D., Kuehne, Sarah A., Minton, Nigel P., Stecher, Bärbel, Bernier-Latmani, Rizlan, and Hapfelmeier, Siegfried

Subjects

BILE acids, LIPIDS, ANTI-infective agents, DEOXYCHOLIC acid, PATHOGENIC microorganisms

Abstract

Bile acids, important mediators of lipid absorption, also act as hormone-like regulators and as antimicrobial molecules. In all these functions their potency is modulated by a variety of chemical modifications catalyzed by bacteria of the healthy gut microbiota, generating a complex variety of secondary bile acids. Intestinal commensal organisms are well-adapted to normal concentrations of bile acids in the gut. In contrast, physiological concentrations of the various intestinal bile acid species play an important role in the resistance to intestinal colonization by pathogens such as Clostridium difficile. Antibiotic therapy can perturb the gut microbiota and thereby impair the production of protective secondary bile acids. The most important bile acid transformation is 7α-dehydroxylation, producing deoxycholic acid (DCA) and lithocholic acid (LCA). The enzymatic pathway carrying out 7α-dehydroxylation is restricted to a narrow phylogenetic group of commensal bacteria, the best-characterized of which is Clostridium scindens. Like many other intestinal commensal species, 7- dehydroxylating bacteria are understudied in vivo. Conventional animals contain variable and uncharacterized indigenous 7α-dehydroxylating organisms that cannot be selectively removed, making controlled colonization with a specific strain in the context of an undisturbed microbiota unfeasible. In the present study, we used a recently established, standardized gnotobiotic mouse model that is stably associated with a simplified murine 12-species "oligo-mouse microbiota" (Oligo-MM12). It is representative of the major murine intestinal bacterial phyla, but is deficient for 7α-dehydroxylation. We find that the Oligo-MM12 consortium carries out bile acid deconjugation, a prerequisite for 7α-dehydroxylation, and confers no resistance to C. difficile infection (CDI). Amendment of Oligo-MM12 with C. scindens normalized the large intestinal bile acid composition by reconstituting 7α-dehydroxylation. These changes had only minor effects on the composition of the native Oligo-MM12, but significantly decreased early large intestinal C. difficile colonization and pathogenesis. The delayed pathogenesis of C. difficile in C. scindens-colonized mice was associated with breakdown of cecal microbial bile acid transformation. [ABSTRACT FROM AUTHOR]

Published

2016

25. Clostridium scindens metabolites trigger prostate cancer progression through androgen receptor signaling.

Author

Bui NN, Li CY, Wang LY, Chen YA, Kao WH, Chou LF, Hsieh JT, Lin H, and Lai CH

Subjects

Male, Humans, Prostate metabolism, Androgens metabolism, Androgens pharmacology, Androgen Antagonists metabolism, Androgen Antagonists pharmacology, Hydrocortisone metabolism, Hydrocortisone pharmacology, Cell Line, Tumor, Receptors, Androgen genetics, Receptors, Androgen metabolism, Prostatic Neoplasms, Castration-Resistant genetics, Prostatic Neoplasms, Castration-Resistant metabolism

Abstract

Prostate cancer (PCa) is one of the most common malignancies in men; recently, PCa-related mortality has increased worldwide. Although androgen deprivation therapy (ADT) is the standard treatment for PCa, patients often develop aggressive castration-resistant PCa (CRPC), indicating the presence of an alternative source of androgen. Clostridium scindens is a member of the gut microbiota and can convert cortisol to 11β-hydroxyandrostenedione (11β-OHA), which is a potent androgen precursor. However, the effect of C. scindens on PCa progression has not been determined. In this study, androgen-dependent PCa cells (LNCaP) were employed to investigate whether C. scindens-derived metabolites activate androgen receptor (AR), which is a pivotal step in the development of PCa. Results showed that cortisol metabolites derived from C. scindens-conditioned medium promoted proliferation and enhanced migration of PCa cells. Furthermore, cells treated with these metabolites presented activated AR and stimulated AR-regulated genes. These findings reveal that C. scindens has the potential to promote PCa progression via the activation of AR signaling. Further studies on the gut-prostate axis may help unravel an alternative source of androgen that triggers CRPC exacerbation., Competing Interests: Conflicts of interest The authors report no conflict of interest., (Copyright © 2023. Published by Elsevier B.V.)

Published

2023

26. Comparative Genomic and Physiological Analysis against Clostridium scindens Reveals Eubacterium sp. c-25 as an Atypical Deoxycholic Acid Producer of the Human Gut Microbiota

Author

Song, Isaiah, Gotoh, Yasuhiro, Ogura, Yoshitoshi, Hayashi, Tetsuya, Fukiya, Satoru, Yokota, Atsushi, Song, Isaiah, Gotoh, Yasuhiro, Ogura, Yoshitoshi, Hayashi, Tetsuya, Fukiya, Satoru, and Yokota, Atsushi

Abstract

The human gut houses bile acid 7 alpha-dehydroxylating bacteria that produce secondary bile acids such as deoxycholic acid (DCA) from host-derived bile acids through enzymes encoded by the bai operon. While recent metagenomic studies suggest that these bacteria are highly diverse and abundant, very few DCA producers have been identified. Here, we investigated the physiology and determined the complete genome sequence of Eubacterium sp. c-25, a DCA producer that was isolated from human feces in the 1980s. Culture experiments showed a preference for neutral to slightly alkaline pH in both growth and DCA production. Genomic analyses revealed that c-25 is phylogenetically distinct from known DCA producers and possesses a multi-cluster arrangement of predicted bile-acid inducible (bai) genes that is considerably different from the typical bai operon structure. This arrangement is also found in other intestinal bacterial species, possibly indicative of unconfirmed 7 alpha-dehydroxylation capabilities. Functionality of the predicted bai genes was supported by the induced expression of baiB, baiCD, and baiH in the presence of cholic acid substrate. Taken together, Eubacterium sp. c-25 is an atypical DCA producer with a novel bai gene cluster structure that may represent an unexplored genotype of DCA producers in the human gut.

Published

2021

27. Do Primocolonizing Bacteria Enable Bacteroides thetaiotaomicron Intestinal Colonization Independently of the Capacity To Consume Oxygen?

Author

Sylvie Rabot, David Halpern, Thierry Meylheuc, Mélanie Guillemet, Aurélie Derré-Bobillot, Alexandra Gruss, Claire Morvan, MICrobiologie de l'ALImentation au Service de la Santé (MICALIS), AgroParisTech-Université Paris-Saclay-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), Pathogénèse des Bactéries Anaérobies / Pathogenesis of Bacterial Anaerobes (PBA (U-Pasteur_6)), Institut Pasteur [Paris] (IP)-Centre National de la Recherche Scientifique (CNRS)-Université Paris Cité (UPCité), and ANR-11-IDEX-0003,IPS,Idex Paris-Saclay(2011)

Subjects

Aerobic bacteria, [SDV]Life Sciences [q-bio], germfree mice, Biology, medicine.disease_cause, Microbiology, Mice, 03 medical and health sciences, Escherichia coli, medicine, Animals, Humans, Bacteroides, Colonization, intestine, Molecular Biology, 030304 developmental biology, Mice, Inbred BALB C, 0303 health sciences, Microbial Viability, Clostridium scindens, Bacteria, 030306 microbiology, primocolonization, food and beverages, Obligate anaerobe, Opinion/Hypothesis, biology.organism_classification, QR1-502, Aerobiosis, Specific Pathogen-Free Organisms, Intestines, Bacteroides thetaiotaomicron, [Clostridium] scindens, oxygen

Abstract

Aerobic bacteria are frequent primocolonizers of the human naive intestine. Their generally accepted role is to eliminate oxygen, which would allow colonization by anaerobes that subsequently dominate bacterial gut populations., Aerobic bacteria are frequent primocolonizers of the human naive intestine. Their generally accepted role is to eliminate oxygen, which would allow colonization by anaerobes that subsequently dominate bacterial gut populations. In this hypothesis-based study, we revisited this dogma experimentally in a germfree mouse model as a mimic of the germfree newborn. We varied conditions leading to the establishment of the dominant intestinal anaerobe Bacteroides thetaiotaomicron. Two variables were introduced: Bacteroides inoculum size and preestablishment by bacteria capable or not of consuming oxygen. High Bacteroides inoculum size enabled its primocolonization. At low inocula, we show that bacterial preestablishment was decisive for subsequent Bacteroides colonization. However, even non-oxygen-respiring bacteria, a hemA Escherichia coli mutant and the intestinal obligate anaerobe Clostridium scindens, facilitated Bacteroides establishment. These findings, which are supported by recent reports, revise the long-held assumption that oxygen scavenging is the main role for aerobic primocolonizing bacteria. Instead, we suggest that better survival of aerobic bacteria ex vivo during vectorization between hosts could be a reason for their frequent primocolonization.

Published

2021

28. Biogeography and biochemistry of bile acid 7-dehydroxylation in the mammalian gut

Author

Marion, Solenne Anne Marie, Bernier-Latmani, Rizlan, and Meibom, Karin Lederballe

Subjects

bile acids, bai operon, Clostridium scindens, bile acid 7-dehydroxylation, bile acid signalling, NanoSIMS, vertical pathway, metaproteomic, hydroxysteroid dehydrogenases, 12-oxoLCA

Abstract

Bile acids (BAs) are small molecules synthesized by the host and chemically modified by the microorganisms inhabiting the intestinal tract. The microbial transformation of BAs in the gut is critical to BA-mediated signaling as it modifies their amount and affinity for specific BA receptors. Bile acid 7-dehydroxylating bacteria are intestinal commensals of particular importance as they catalyze the dehydroxylation of liver-derived (primary) bile acids at the C7 position (i.e., 7-dehydroxylation) and produce secondary bile acids. One of the major receptors for secondary BAs is Takeda G-protein receptor 5 (TGR5), and it is associated with regulation of energy expenditure and glucose management, protection from liver steatosis and inflammation. In addition, 7-dehydroxylated bile acids are also associated with protection from infection by specific intestinal pathogens (i.e., Clostridioides difficile). Thus, through their action on primary BAs, 7-dehydroxylating (7-DH-ing) bacteria play an important role in health promotion and in the functioning of major physiological processes in the body such as insulin secretion, thermogenesis and immune responses. Despite these potentially important roles in the mammalian host, bile acid 7-dehydroxylating bacteria are poorly studied and much remains to be deciphered regarding their metabolism, diversity, abundance in the gut, and colonization dynamics in the host. Here, we use Clostridium scindens, as model organism to study bile acid 7-dehydroxylation in vitro and in gnotobiotic mice. We found that C. scindens metabolize only human primary bile acids (CA and CDCA). We uncovered the formation of a novel intermediate during CA 7-dehydroxylation by C. scindens in vitro: 12-oxoLCA. In vivo, using NanoSIMS and metabolomic analysis, we demonstrated that the large intestine constitutes C. scindens primary ecological niche in gnotobiotic mice. Following up on the discovery of the 12oxoLCA, we hypothesized the existence of another 7-dehydroxylation pathway for cholic acid. We postulated that it may involve the B and C rings of the steroid structure and may entail the oxidation/reduction of the C12- hydroxyl group. Thus, it was dubbed the putative vertical pathway. Conducting in vitro enzymatic assays with purified enzymes, we confirmed the existence of this novel vertical biosynthetic 7-dehydroxylation pathway for cholic acid, the most abundant primary bile acid in humans, and identified the core of enzymes necessary and sufficient for CA 7-dehydroxylation. Furthermore, we used a coupled metabolomic and metaproteomic approach to probe in vivo activity of the gut microbial community in a gnotobiotic mouse model. Additionnally, we also considered the bile acid profile in mice with more complex microbiota or with no microbiota. By comparing the bile acid profile of the different mice models along with expression of key genes of bile acid synthesis, we emphasized the profound influence of the gut microbial community on BA pool homeostasis. Altogether, our data provides a significant contribution to our collective understanding of the microbiology of bile acid 7-dehydroxylating bacteria, a group of gut commensals highly relevant to host health but that remains poorly characterized. The discovery of a novel 7-dehydroxylation pathway is a major scientific achievement of this thesis.

Published

2020

29. Comparative Genomic and Physiological Analysis against Clostridium scindens Reveals Eubacterium sp. c-25 as an Atypical Deoxycholic Acid Producer of the Human Gut Microbiota

Author

Yasuhiro Gotoh, Atsushi Yokota, Yoshitoshi Ogura, Isaiah Song, Satoru Fukiya, and Tetsuya Hayashi

Subjects

Microbiology (medical), QH301-705.5, Operon, medicine.drug_class, gut microbiome, Microbiology, Article, chemistry.chemical_compound, Virology, Gene cluster, medicine, secondary bile acid, Biology (General), Human feces, bai operon, Clostridium scindens, biology, Bile acid, Deoxycholic acid, Cholic acid, biology.organism_classification, chemistry, [Clostridium] scindens, Biochemistry, deoxycholic acid, Bacteria

Abstract

The human gut houses bile acid 7α-dehydroxylating bacteria that produce secondary bile acids such as deoxycholic acid (DCA) from host-derived bile acids through enzymes encoded by the bai operon. While recent metagenomic studies suggest that these bacteria are highly diverse and abundant, very few DCA producers have been identified. Here, we investigated the physiology and determined the complete genome sequence of Eubacterium sp. c-25, a DCA producer that was isolated from human feces in the 1980s. Culture experiments showed a preference for neutral to slightly alkaline pH in both growth and DCA production. Genomic analyses revealed that c-25 is phylogenetically distinct from known DCA producers and possesses a multi-cluster arrangement of predicted bile-acid inducible (bai) genes that is considerably different from the typical bai operon structure. This arrangement is also found in other intestinal bacterial species, possibly indicative of unconfirmed 7α-dehydroxylation capabilities. Functionality of the predicted bai genes was supported by the induced expression of baiB, baiCD, and baiH in the presence of cholic acid substrate. Taken together, Eubacterium sp. c-25 is an atypical DCA producer with a novel bai gene cluster structure that may represent an unexplored genotype of DCA producers in the human gut.

Published

2021

30. Isolation and 16S ribosomal RNA gene sequence-based identification of Clostridium scindens from an intra-abdominal abscess

Author

Elsayed, Sameer and Zhang, Kunyan

Subjects

*CLOSTRIDIUM, *NUCLEIC acids, *RNA, *BIOMOLECULES

Abstract

Abstract: Clostridium scindens has not been previously associated with human infection. We describe a case of an adolescent female with Crohn''s disease presenting with a post-surgical intra-abdominal abscess from which this organism was isolated in pure culture. This is the first documented report of human infection caused by this micro-organism. [Copyright &y& Elsevier]

Published

2006

31. Contribution of Inhibitory Metabolites and Competition for Nutrients to Colonization Resistance against Clostridioides difficile by Commensal Clostridium

Author

Casey M. Theriot and A. D. Reed

Subjects

0301 basic medicine, Microbiology (medical), medicine.drug_class, media_common.quotation_subject, short-chain fatty acids, 030106 microbiology, Antibiotics, Review, Colonisation resistance, deconjugation, Microbiology, Clostridioides difficile, Competition (biology), 03 medical and health sciences, Clostridium, Nutrient, epimerization, Virology, medicine, hydroxyproline, proline, lcsh:QH301-705.5, Pathogen, media_common, Clostridium scindens, biology, secondary bile acids, Antimicrobial, biology.organism_classification, 030104 developmental biology, lcsh:Biology (General), [Clostridium] scindens, dehydroxylation

Abstract

Clostridioides difficile is an anaerobic pathogen that causes significant morbidity and mortality. Understanding the mechanisms of colonization resistance against C. difficile is important for elucidating the mechanisms by which C. difficile is able to colonize the gut after antibiotics. Commensal Clostridium play a key role in colonization resistance. They are able to modify bile acids which alter the C. difficile life cycle. Commensal Clostridium also produce other inhibitory metabolites including antimicrobials and short chain fatty acids. They also compete with C. difficile for vital nutrients such as proline. Understanding the mechanistic effects that these metabolites have on C. difficile and other gut pathogens is important for the development of new therapeutics against C. difficile infection (CDI), which are urgently needed.

Published

2021

32. Comparative Genomic and Physiological Analysis against Clostridium scindens Reveals Eubacterium sp. c-25 as an Atypical Deoxycholic Acid Producer of the Human Gut Microbiota.

Author

Song I, Gotoh Y, Ogura Y, Hayashi T, Fukiya S, and Yokota A

Abstract

The human gut houses bile acid 7α-dehydroxylating bacteria that produce secondary bile acids such as deoxycholic acid (DCA) from host-derived bile acids through enzymes encoded by the bai operon. While recent metagenomic studies suggest that these bacteria are highly diverse and abundant, very few DCA producers have been identified. Here, we investigated the physiology and determined the complete genome sequence of Eubacterium sp. c-25, a DCA producer that was isolated from human feces in the 1980s. Culture experiments showed a preference for neutral to slightly alkaline pH in both growth and DCA production. Genomic analyses revealed that c-25 is phylogenetically distinct from known DCA producers and possesses a multi-cluster arrangement of predicted bile-acid inducible ( bai ) genes that is considerably different from the typical bai operon structure. This arrangement is also found in other intestinal bacterial species, possibly indicative of unconfirmed 7α-dehydroxylation capabilities. Functionality of the predicted bai genes was supported by the induced expression of baiB , baiCD , and baiH in the presence of cholic acid substrate. Taken together, Eubacterium sp. c-25 is an atypical DCA producer with a novel bai gene cluster structure that may represent an unexplored genotype of DCA producers in the human gut.

Published

2021

33. Contribution of Inhibitory Metabolites and Competition for Nutrients to Colonization Resistance against Clostridioides difficile by Commensal Clostridium.

Author

Reed, Amber D., Theriot, Casey M., and Parkar, Shanthi G.

Subjects

CLOSTRIDIOIDES difficile, METABOLITES, BILE acids, SHORT-chain fatty acids, FATTY acids, CLOSTRIDIUM acetobutylicum, CLOSTRIDIA

Abstract

Clostridioides difficile is an anaerobic pathogen that causes significant morbidity and mortality. Understanding the mechanisms of colonization resistance against C. difficile is important for elucidating the mechanisms by which C. difficile is able to colonize the gut after antibiotics. Commensal Clostridium play a key role in colonization resistance. They are able to modify bile acids which alter the C. difficile life cycle. Commensal Clostridium also produce other inhibitory metabolites including antimicrobials and short chain fatty acids. They also compete with C. difficile for vital nutrients such as proline. Understanding the mechanistic effects that these metabolites have on C. difficile and other gut pathogens is important for the development of new therapeutics against C. difficile infection (CDI), which are urgently needed. [ABSTRACT FROM AUTHOR]

Published

2021

34. Overview of Clostridium difficile Infection: Life Cycle, Epidemiology, Antimicrobial Resistance and Treatment

Author

Aristides L. Mendes, Mónica Serrano, Adriano O. Henriques, Mónica Oleastro, and Joana Isidro

Subjects

Spores, 0301 basic medicine, medicine.medical_specialty, Epidemiology, medicine.drug_class, Fidaxomycin, 030106 microbiology, Antibiotics, Drug Resistance, Drug resistance, Biology, Microbiology, 03 medical and health sciences, Antibiotic resistance, medicine, Clostridium difficile Infection, Clostridium difficile, Clostridium Scindens, 3. Good health, Infecções Gastrointestinais, 030104 developmental biology, [Clostridium] scindens, Beta-lactam Antibiotics, Beta lactam antibiotics

Abstract

The use of antimicrobial agents and acquired resistances explains in part the emergence and spreading of epidemic strains of Clostridium difficile. Continued use of antimicrobial therapy still represents an acute danger in triggering the emergence and spreading of new resistant and multiresistant strains including against first line antibiotics. We examine the pathway of peptidoglycan synthesis in this organism and associated resistances, as well as resistance to other classes of antibiotics. The life-cycle of C. difficile involves growth, spore formation and germination. Spores endow the organism with a formidable capacity of persistence in the environment and in the host, resistance, dissemination and infectious potential. Highly resistant spores produced by antibiotic resistant/multiresistant strains may be one of the most serious challenges we face in what concerns the containment of C. difficile. Finally, we review recent developments in treatment and prevention of C. difficile infection. info:eu-repo/semantics/publishedVersion

Published

2017

35. Do Primocolonizing Bacteria Enable Bacteroides thetaiotaomicron Intestinal Colonization Independently of the Capacity To Consume Oxygen?

Author

Halpern D, Morvan C, Derré-Bobillot A, Meylheuc T, Guillemet M, Rabot S, and Gruss A

Subjects

Aerobiosis, Animals, Bacteria classification, Humans, Mice, Mice, Inbred BALB C, Microbial Viability, Specific Pathogen-Free Organisms, Bacteria metabolism, Bacteroides thetaiotaomicron physiology, Intestines microbiology, Oxygen metabolism

Abstract

Aerobic bacteria are frequent primocolonizers of the human naive intestine. Their generally accepted role is to eliminate oxygen, which would allow colonization by anaerobes that subsequently dominate bacterial gut populations. In this hypothesis-based study, we revisited this dogma experimentally in a germfree mouse model as a mimic of the germfree newborn. We varied conditions leading to the establishment of the dominant intestinal anaerobe Bacteroides thetaiotaomicron Two variables were introduced: Bacteroides inoculum size and preestablishment by bacteria capable or not of consuming oxygen. High Bacteroides inoculum size enabled its primocolonization. At low inocula, we show that bacterial preestablishment was decisive for subsequent Bacteroides colonization. However, even non-oxygen-respiring bacteria, a hemA Escherichia coli mutant and the intestinal obligate anaerobe Clostridium scindens , facilitated Bacteroides establishment. These findings, which are supported by recent reports, revise the long-held assumption that oxygen scavenging is the main role for aerobic primocolonizing bacteria. Instead, we suggest that better survival of aerobic bacteria ex vivo during vectorization between hosts could be a reason for their frequent primocolonization., (Copyright © 2021 Halpern et al.)

Published

2021

36. Bile Acid 7α-Dehydroxylating Gut Bacteria Secrete Antibiotics that Inhibit Clostridium difficile: Role of Secondary Bile Acids.

Author

Kang, Jason D., Myers, Christopher J., Harris, Spencer C., Kakiyama, Genta, Lee, In-Kyoung, Yun, Bong-Sik, Matsuzaki, Keiichi, Furukawa, Megumi, Min, Hae-Ki, Bajaj, Jasmohan S., Zhou, Huiping, and Hylemon, Phillip B.

Subjects

*BILE acids, *GUT microbiome, *CLOSTRIDIOIDES difficile, *BIOTRANSFORMATION (Metabolism), *ANTIBIOTICS assay, *LITHOCHOLIC acid

Abstract

Summary Clostridium scindens biotransforms primary bile acids into secondary bile acids, and is correlated with inhibition of Clostridium difficile growth in vivo. The aim of the current study was to determine how C. scindens regulates C. difficile growth in vitro and if these interactions might relate to the regulation of gut microbiome structure in vivo. The bile acid 7α-dehydroxylating gut bacteria, C. scindens and C. sordellii , were found to secrete the tryptophan-derived antibiotics, 1-acetyl-β-carboline and turbomycin A, respectively. Both antibiotics inhibited growth of C. difficile and other gut bacteria. The secondary bile acids, deoxycholic acid and lithocholic acid, but not cholic acid, enhanced the inhibitory activity of these antibiotics. These antibiotics appear to inhibit cell division of C. difficile. The results help explain how endogenously synthesized antibiotics and secondary bile acids may regulate C. difficile growth and the structure of the gut microbiome in health and disease. Graphical Abstract Highlights • Bile acid 7α-dehydroxylating gut bacteria secrete tryptophan-derived antibiotics • Secondary bile acid enhanced the activity of these antibiotics • Tryptophan-derived antibiotics appear to inhibit the division septum of bacteria • Clostridium difficile secretes proline-based cyclic dipeptides Kang et al. describe the discovery of tryptophan-derived antibiotics secreted by specific gut bacteria that inhibit C. difficile, a bacterial pathogen causing diarrhea and colitis. These results help explain why antibiotic treatment, which disrupts the normal protective gut microbiota, allows C. difficile to colonize the colon and cause disease. [ABSTRACT FROM AUTHOR]

Published

2019

37. [原著］Production of bacteriocins by Clostridium scindens and some of their properties

Author

Takamine, Fusae, Imamura, Teisuke, and Laboratory of Microbiology, School of Health Sciences, Faculty of Medicine, University of the Ryukyus

Subjects

Clostridium scindens, bacteriocin, bacteriocin production, food and beverages, bacteria, anaerobes, biochemical phenomena, metabolism, and nutrition, bacteriocin susceptibility

Abstract

Twenty-three strains of Clostridium scindens isolated from 11 human feces samples and one reference strain were examined for both bacteriocin production and bacteriocin susceptibility. Out of these, 10 strains were found to produce bacteriocins, and another 10 strains were sensitive to the bacteriocins. The bacteriocin-producing strains were resistant to their own bacteriocin as well as bacteriocin produced by other strains. Six strains were sensitive to all tested bacteriocins. Four of the strains tested were insensitive to all bacteriocins and produced no bactenocin. The physicochemical properties of three bacteriocins produced by strains O-51, Y-1113 and O-161 were similar, and were mitomycin C inducible, trypsin resistant and heat-labile. Sensitivity to the bacteriocins was confined to other strains of C. scindens, Eubacterium species VPl 12708, Eubacterium species strains C-25 and Peptostreptococcus anaerobius PL-9; the other gram-positive and gram-negative bacteria tested for sensitivity were not affected by the bactenocins. Crude bacteriocins killed sensitive cells rapidly but cell lysis did not appear to be involved

Published

2001

38. Characterization of a Novel D-tagatose 3-Epimerase from Clostridium scindens ATCC 35704

Author

Mu, Wanmeng, Chu, Feifei, and Jiang, Bo

Published

2010

39. Functional intestinal bile acid 7-alpha-dehydroxylation by Clostridium scindens associated with protection from C. difficile infection in a gnotobiotic mouse model

Author

Studer, Nicolas, Desharnais, Lyne, Beutler, Markus, Brurigoux, Sandrine, Terrazos, Miguel, Menin, Laure, McCoy, Kathy D., Minton, Nigel, Stecher, Bärbel, Bernier-Latmani, Rizlan, and Hapfelmeier, Siegfried

Subjects

intestinal infection, Clostridium scindens, Clostridium difficile infection (CDI), gut microbiota, gnotobiotic mouse model, secondary bile acids, Clostridium difficile, digestive system, 7 alpha-dehydroxylation

Abstract

Bile acids, important mediators of lipid absorption, also act as hormone-like regulators and as antimicrobial molecules. In all these functions their potency is modulated by a variety of chemical modifications catalyzed by bacteria of the healthy gut microbiota, generating a complex variety of secondary bile acids. Intestinal commensal organisms are well adapted to normal concentrations of bile acids in the gut. In contrast, physiological concentrations of the various intestinal bile acid species play an important role in the resistance to intestinal colonization by pathogens such as Clostridium difficile. Antibiotic therapy can perturb the gut microbiota and thereby impair the production of protective secondary bile acids. The most important bile acid transformation is 7 alpha-dehydroxylation, producing deoxycholic acid (DCA) and lithocholic acid (LCA). The enzymatic pathway carrying out 7 alpha-dehydroxylation is restricted to a narrow phylogenetic group of commensal bacteria, the best-characterized of which is Clostridium scindens. Like many other intestinal commensal species, 7 alpha-dehydroxylating bacteria are understudied in vivo. Conventional animals contain variable and uncharacterized indigenous 7 alpha-dehydroxylating organisms that cannot be selectively removed, making controlled colonization with a specific strain in the context of an undisturbed microbiota unfeasible. In the present study, we used a recently established, standardized gnotobiotic mouse model that is stably associated with a simplified murine 12-species "oligo-mouse microbiota" (Oligo-MM12). It is representative of the major murine intestinal bacterial phyla, but is deficient for 7 alpha-dehydroxylation. We find that the Oligo-MM12 consortium carries out bile acid deconjugation, a prerequisite for 7 alpha-dehydroxylation, and confers no resistance to C. difficile infection (CDI). Amendment of Oligo-MM12 with C. scindens normalized the large intestinal bile acid composition by reconstituting Ty-dehydroxylation. These changes had only minor effects on the composition of the native Oligo-MM12, but significantly decreased early large intestinal C. difficile colonization and pathogenesis. The delayed pathogenesis of C. difficile in C. scindens-colonized mice was associated with breakdown of cecal microbial bile acid transformation.