The microbial metabolite urolithin A reduces
            <i>Clostridioides difficile</i>
            toxin expression and toxin-induced epithelial damage

Ghosh, Sweta; Erickson, Daniel; Chua, Michelle J.; Collins, James; Jala, Venkatakrishna Rao

doi:10.1128/msystems.01255-23

mSystems

2024

DOI: 10.1128/msystems.01255-23

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The microbial metabolite urolithin A reduces Clostridioides difficile toxin expression and toxin-induced epithelial damage

Sweta Ghosh,

Daniel Erickson,

Michelle J. Chua

et al.

Abstract: Clostridioides difficile is a Gram-positive, anaerobic, spore-forming bacterium responsible for antibiotic-associated pseudomembranous colitis. Clostridioides difficile infection (CDI) symptoms can range from diarrhea to life-threatening colon damage. Toxins produced by C. difficile (TcdA and TcdB) cause intestinal epithelial injury and lead to severe gut barrier dysfunction, stem cell damage, and impaired regeneration of the gut epithelium. Current t… Show more

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2024

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Cited by 3 publications

References 66 publications

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Design, Synthesis, and Anti‐Infective Effect Against Candida Albicans of a New Urolithin Derivative

Zhu,

Tang,

Zhou

et al. 2024

Chemistry & Biodiversity

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Deep mucosal and organ infections caused by the infestation of Candida albicans(C.albicans) in immunocompromised patients represent a significant cause of mortality in hospitalised patients. The rise in fungal resistance is a consequence of the overuse of antibiotics. Therefore, innovative immunostimulants must be developed to combat pathogenic fungal infections. We used urolithin A (UA), an intestinal metabolite rich in the naturally occurring polyphenolic antioxidants ellagic acid (EA) or ellagitannin (ET), as a lead compound for structural modification. Through liquid screening of 17 synthesized compounds, we discovered compound 1e effectively inhibited C.albicans biofilm formation, thereby reducing its virulence. Furthermore, it protects animals from severe infections by enhancing tolerance to infection by intestinal pathogens and reducing oxidative stress. Moreover, our findings indicate that compound 1e exerts its effects through the p38 mitogen‐activated protein kinase (MAPK) innate immune pathway, which is evolutionarily conserved. These observations not only enhance our comprehension of immune mechanisms but also provide a crucial foundation for the development of immune activators with the potential to resist pathogenic bacterial infections.

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Design, Synthesis, and Anti‐Infective Effect Against Candida Albicans of a New Urolithin Derivative

Zhu,

Tang,

Zhou

et al. 2024

Chemistry & Biodiversity

View full text Add to dashboard Cite

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Bile acids impact the microbiota, host, and C. difficile dynamics providing insight into mechanisms of efficacy of FMTs and microbiota-focused therapeutics

McMillan,

Theriot

2024

Gut Microbes

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Mice colonized with the defined microbial community OMM19.1 are susceptible to Clostridioides difficile infection without prior antibiotic treatment

Chua,

Collins

2024

mSphere

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Diverse gut microorganisms present in humans and mice are essential for the prevention of microbial pathogen colonization. However, antibiotic-induced dysbiosis of the gut microbiome reduces microbial diversity and allows Clostridioides difficile ( C. difficile ) to colonize the intestine. The Oligo-Mouse-Microbiota 19.1 (OMM19.1) is a synthetic community that consists of bacteria that are taxonomically and functionally designed to mimic the specific pathogen-free mouse gut microbiota. Here, we examined the susceptibility of OMM19.1 colonized mice to C. difficile infection (CDI) at a range of infectious doses (10 3 , 10 5 , and 10 7 spores) without prior antibiotic treatment. We found that mice colonized with OMM19.1 were susceptible to CDI regardless of the dose. The clinical scores increased with increasing C. difficile dosage. Infection with C. difficile was correlated with a significant increase in Ligilactobacillus murinus and Escherichia coli , while the relative abundance of Bacteroides caecimuris, Akkermansia muciniphila, Extibacter muris, and Turicimonas muris was significantly decreased following CDI. Our results demonstrate that the OMM19.1 community requires additional bacteria to enable C. difficile colonization resistance. IMPORTANCE The human gut microbiota consists of a wide range of microorganisms whose composition and function vary according to their location and have a significant impact on health and disease. The ability to generate and test the defined microbiota within gnotobiotic animal models is essential for determining the mechanisms responsible for colonization resistance. The exact mechanism(s) by which healthy microbiota prevents Clostridioides difficile infection is unknown, although competition for nutrients, active antagonism, production of inhibitory metabolites (such as secondary bile acids), and microbial manipulation of the immune system are all thought to play a role. Here, we colonized germ-free C57BL/6 mice with a synthetic bacterial community (OMM19.1) that mimics the specific pathogen-free mouse microbiota. Following breeding, to enable immune system development, F1 mice were infected with three different doses of C. difficile . Our research suggests that there are additional essential microbial functions that are absent from the current OMM19.1 model.

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The microbial metabolite urolithin A reduces Clostridioides difficile toxin expression and toxin-induced epithelial damage

Cited by 3 publications

References 66 publications

Design, Synthesis, and Anti‐Infective Effect Against Candida Albicans of a New Urolithin Derivative

Design, Synthesis, and Anti‐Infective Effect Against Candida Albicans of a New Urolithin Derivative

Bile acids impact the microbiota, host, and C. difficile dynamics providing insight into mechanisms of efficacy of FMTs and microbiota-focused therapeutics

Mice colonized with the defined microbial community OMM19.1 are susceptible to Clostridioides difficile infection without prior antibiotic treatment

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