Rational design of a microbial consortium of mucosal sugar utilizers reduces Clostridiodes difficile colonization

Pereira, Fátima C.; Wasmund, Kenneth; Cobankovic, Iva; Jehmlich, Nico; Herbold, Craig W.; Lee, Kang Soo; Szirányi, Barbara; Vesely, Cornelia; Decker, Thomas; Stocker, Roman; Warth, Benedikt; Bergen, Martin von; Wagner, Michael; Berry, David

doi:10.1038/s41467-020-18928-1

Cited by 189 publications

(171 citation statements)

References 82 publications

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“…Thus, we tested if mucus-derived sugars potentiate DOC-induced biofilm formation. Mucus is typically broken down into different hexose sugars including glucose, GlcNAc, fucose, Neu5Ac, galactose and N-acetylgalactosamine (GalNAc) and GlcNac and Neu5Ac acquisition is important for C. difficile growth in the intestinal tract (Ng et al, 2013; Pereira et al, 2020). We tested the effect of these sugars on biofilm formation.…”

Section: Resultsmentioning

confidence: 99%

“…Depending on the composition of the microbiota, C. difficile could encounter favourable conditions that would include sub-inhibitory concentrations of DOC, and availability of specific amino acids, mucus-derived sugars, and pyruvate (Abbas and Zackular, 2020; Girinathan et al, 2020; Pereira et al, 2020). Under these favourable conditions, sub-inhibitory concentration of DOC would trigger a metabolic adaptation in C. difficile to use the available metabolites produced by the microbiota.…”

Section: Discussionmentioning

confidence: 99%

“…GlcNac and Neu5Ac acquisition is important for C. difficile growth in the intestinal tract (Ng et al, 2013;Pereira et al, 2020). We tested the effect of these sugars on biofilm formation.…”

Section: Branched-chain Amino Acids and Mucus-derived Sugars Potentiamentioning

confidence: 99%

“…Once ingested from the surrounding environment or food, spores germinate in the ileum and then vegetative cells colonize the caecum (Crobach et al, 2018; Lim et al 2020). Successful colonization relies on the disruption of the host’s microbiota (Abbas and Zackular, 2020; Ghimire et al 2020; Girinathan et al, 2020; Pereira et al, 2020). The microbiota protects against C. difficile infection by producing metabolites including deoxycholic acid (DOC) and short chain fatty acids (SCFA) (Buffie et al, 2015; Studer et al 2016; McDonald et al, 2018; Sobach et al 2018; Seekatz et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

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Metabolic adaption to extracellular pyruvate triggers biofilm formation inClostridioides difficile

Tremblay

Durand

Hamiot

et al. 2021

Preprint

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Clostridioides difficile infections are associated with gut microbiome dysbiosis and are the leading cause of hospital acquired diarrhoea. The infectious process is strongly influenced by the microbiota and successful infection relies on the absence of specific microbiota-produced metabolites. Deoxycholic acid (DOC) and short chain fatty acids are microbiota-produced metabolites that limit the growth of C. difficile and protect the host against this infection. In a previous study, we showed that DOC causes C. difficile to form strongly adherent biofilms after 48 h. Here, our objectives were to identify and characterize key molecules and events required for biofilm formation in the presence of DOC. We applied time-course transcriptomics and genetics to identify sigma factors, metabolic processes and type IV pili that drive biofilm formation. These analyses revealed that extracellular pyruvate induces biofilm formation in the presence of DOC. In the absence of DOC, pyruvate supplementation was sufficient to induce biofilm formation in a process that was dependent on pyruvate uptake by the membrane protein CstA. In the context of the human gut, microbiota-generated pyruvate is a metabolite that limits pathogen colonization. Taken together our results suggest that pyruvate-induced biofilm formation might act as a key process driving C. difficile persistence in the gut.

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Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

“…GlcNac and Neu5Ac acquisition is important for C. difficile growth in the intestinal tract (Ng et al, 2013;Pereira et al, 2020). We tested the effect of these sugars on biofilm formation.…”

Section: Branched-chain Amino Acids and Mucus-derived Sugars Potentiamentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Metabolic adaption to extracellular pyruvate triggers biofilm formation inClostridioides difficile

Tremblay

Durand

Hamiot

et al. 2021

Preprint

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“…Although carbohydrates-metabolism has been exhaustively studied in different microorganisms, including gut ones, and there is enough genomic information (both from individual microorganisms and metagenomics studies) confirming that gut microorganisms possess the necessary enzymatic tools to metabolize different NSPs, it is not known which of these organisms are indeed capable of such metabolizing jobs within the complex context of natural gut communities and if metabolic pathways, capabilities and preferences determined in vitro will be replicated inside the gut. A sophisticated and targeted-approach was recently employed to reveal microbes within the mouse complex gut community with the capacity to utilize mucosal sugars 86 . Similar studies are needed to exploit specific NSP-microbiota interactions in aquaculture fish to fully unveil the underlying mechanisms determining the fate of specific NSP and its effect on fish performance, fish health and nutrient digestibility 39 .…”

Section: Discussionmentioning

confidence: 99%

Gut microbiota dynamics in carnivorous European seabass (Dicentrarchus labrax) fed plant-based diets

Serra

Oliva-Teles

Enes

et al. 2021

Sci Rep

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A healthy gastrointestinal microbiota is essential for host fitness, and strongly modulated by host diet. In aquaculture, a current challenge is to feed carnivorous fish with plant-feedstuffs in substitution of fish meal, an unsustainable commodity. Plants have a limited nutritive value due to the presence of non-starch polysaccharides (NSP) which are not metabolized by fish. In this work we assessed the effects of NSP-enriched diets on European seabass gut microbiota and evaluate the selective pressure of plant feedstuffs towards gut microbes with NSP-hydrolytic potential, i.e. capable to convert indigestible dietary constituents in fish metabolites. Triplicate groups of European seabass juveniles were fed a fish meal-based diet (control) or three plant-based diets (SBM, soybean meal; RSM, rapeseed meal; SFM, sunflower meal) for 6 weeks, before recovering intestinal samples for microbiota analysis, using the Illumina’s MiSeq platform. Plant-based diets impacted differently digesta and mucosal microbiota. A decrease (p = 0.020) on species richness, accompanied by a decline on the relative abundance of specific phyla such as Acidobacteria (p = 0.030), was observed in digesta samples of SBM and RSM experimental fish, but no effects were seen in mucosa-associated microbiota. Plant-based diets favored the Firmicutes (p = 0.01), in particular the Bacillaceae (p = 0.017) and Clostridiaceae (p = 0.007), two bacterial families known to harbor carbohydrate active enzymes and thus putatively more prone to grow in high NSP environments. Overall, bacterial gut communities of European seabass respond to plant-feedstuffs with adjustments in the presence of transient microorganisms (allochthonous) with carbohydrolytic potential, while maintaining a balanced core (autochthonous) microbiota.

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Specific Localization and Quantification of the Oligo‐Mouse‐Microbiota (OMM¹²) by Fluorescence In Situ Hybridization (FISH)

Brugiroux

Berry

Ring³

et al. 2022

Current Protocols

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The oligo‐mouse‐microbiota (OMM12) is a widely used syncom that colonizes gnotobiotic mice in a stable manner. It provides several fundamental functions to its murine host, including colonization resistance against enteric pathogens. Here, we designed and validated specific fluorescence in situ hybridization (FISH) probes to detect and quantify OMM12 strains on intestinal tissue cross sections. 16S rRNA‒specific probes were designed, and specificity was validated on fixed pure cultures. A hybridization protocol was optimized for sensitive detection of the individual bacterial cells in cryosections. Using this method, we showed that the intestinal mucosal niche of Akkermansia muciniphila can be influenced by global gut microbial community context. © 2022 The Authors. Current Protocols published by Wiley Periodicals LLC. Basic Protocol: Localization and quantification of OMM12 single strains in mouse cecum cross section Support Protocol: Establishment of specific FISH probe set for OMM12 syncom

show abstract

Rational design of a microbial consortium of mucosal sugar utilizers reduces Clostridiodes difficile colonization

Cited by 189 publications

References 82 publications

Metabolic adaption to extracellular pyruvate triggers biofilm formation inClostridioides difficile

Metabolic adaption to extracellular pyruvate triggers biofilm formation inClostridioides difficile

Gut microbiota dynamics in carnivorous European seabass (Dicentrarchus labrax) fed plant-based diets

Specific Localization and Quantification of the Oligo‐Mouse‐Microbiota (OMM¹²) by Fluorescence In Situ Hybridization (FISH)

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Rational design of a microbial consortium of mucosal sugar utilizers reduces Clostridiodes difficile colonization

Cited by 189 publications

References 82 publications

Metabolic adaption to extracellular pyruvate triggers biofilm formation inClostridioides difficile

Metabolic adaption to extracellular pyruvate triggers biofilm formation inClostridioides difficile

Gut microbiota dynamics in carnivorous European seabass (Dicentrarchus labrax) fed plant-based diets

Specific Localization and Quantification of the Oligo‐Mouse‐Microbiota (OMM12) by Fluorescence In Situ Hybridization (FISH)

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Product

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Specific Localization and Quantification of the Oligo‐Mouse‐Microbiota (OMM¹²) by Fluorescence In Situ Hybridization (FISH)