<i>In vivo</i>commensal control of<i>Clostridioides difficile</i>virulence

Girinathan, Brintha P.; DiBenedetto, Nicholas; Worley, Jay N.; Peltier, Johann; Arrieta-Ortiz, Mario L.; Immanuel, Rupa; Lavin, Richard; Delaney, Mary L.; Cummins, Christopher K.; Hoffmann, Maria; Luo, Yan; Escalona, Narjol Gonzalez; Allard, Marc W.; Onderdonk, Andrew B.; Gerber, Georg K.; Sonenshein, Abraham L.; Baliga, Nitin S.; Dupuy, Bruno; Bry, Lynn

doi:10.1101/2020.01.04.894915

Cited by 13 publications

(30 citation statements)

References 107 publications

(82 reference statements)

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“…These findings were confirmed with the high levels of spore release in expanded populations of vegetative C. difficile when co-colonized with CSAR (22). Overall, this analysis suggested that the sporulation pathway is an indicator of C. difficile disease, reinforcing the Spo0A-mediated link between sporulation and toxin production recapitulated by the model (Fig.…”

Section: Egrin Uncovers Differentially Active Regulatory Network Dursupporting

confidence: 72%

“…Model predictions also illustrated C. difficile's predicted shift from carbohydrate utilization towards amino acid utilizing pathways in vivo, as shown by the enhanced set of 15 amino acids, including the preferred Stickland donor and acceptor amino acids (leucine and proline) known to support metabolism and growth(43,44,47). Notably, many of these amino acids show high abundance within the gut lumen in gnotobiotic and conventional colonization states that enhance C. difficile's capacity to colonize and expand(22).The Cdiff Web Portal, a resource for the C. difficile communityWe have released a new C. difficile Web Portal (http://networks.systemsbiology.net/cdiff-portal/)to provide a discovery and collaboration gateway for the C. difficile scientific community. The portal aims to accelerate the advancement of the science and understanding of C. difficile biology, gene regulation, and metabolism on its virulence.…”

mentioning

confidence: 89%

“…We also curated pathway annotations that were incorrectly designated using default KEGG annotations (61) File S1. Then, the transcriptome of C. difficile profiled from in vivo infections of specifically-colonized gnotobiotic mice (22) was mapped onto the icdf834 model using the GIMME algorithm (46). This resulted in a model with 665 active reactions, with no changes in the number of genes.…”

Section: Metabolic Model Refinement and Gene Essentiality Predictionmentioning

confidence: 99%

“…The C. difficile 630 (CD630) genome encodes 4,018 genes, with ~309 putative transcription factors (TFs; including sigma factors), 1,030 metabolic genes, and 1,330 genes (>30%) with unknown function (20,21). The ATCC43255 strain of C. difficile, which is used to generate symptomatic infections in mice, encodes 4,117 genes and ~327 TFs, of which ~97% are significantly orthologous to genes encoded in the CD630 strain (22). To address questions regarding the broader systems-level interplay among genes in colonization and infection, we used computational modeling and network inference algorithms to construct an Environment and Gene In addition to EGRIN, we have advanced a metabolic network model of C. difficile to understand how conditional regulation manifests physiologically, by adding reactions and associated genes supporting the exchange of nutrients required for growth in intestinal environments.…”

Section: Introductionmentioning

confidence: 99%

“…5C).We next extended and applied the model to predict C. difficile behaviors and gene essentiality in vivo. C. difficile transcriptomes from specifically-colonized gnotobiotic mice(22) were used as input into the GIMME algorithm(46). Analyses of expressed transcripts in vivo identified 665 active reactions(Fig.…”

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confidence: 99%

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Predictive regulatory and metabolic network models for systems analysis ofClostridioides difficile

Arrieta-Ortiz

Immanuel

Turkarslan

et al. 2020

Preprint

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Though Clostridioides difficile is among the most studied anaerobes, we know little about the systems level interplay of metabolism and regulation that underlies its ability to negotiate complex immune and commensal interactions while colonizing the human gut. We have compiled publicly available resources, generated through decades of work by the research community, into two models and a portal to support comprehensive systems analysis of C. difficile. First, by compiling a compendium of 148 transcriptomes from 11 studies we have generated an Environment and Gene Regulatory Influence Network (EGRIN) model that organizes 90% of all genes in the C. difficile genome into 297 high quality modules based on evidence for their conditional co-regulation by at least 120 transcription factors. EGRIN predictions, validated with independently-generated datasets, have recapitulated previously characterized C. difficile regulons of key transcriptional regulators, refined and extended membership of genes within regulons, and implicated new genes for sporulation, carbohydrate transport and metabolism. Findings further predict pathogen behaviors in in vivo colonization, and interactions with beneficial and detrimental commensals. Second, by advancing a constraints-based metabolic model, we have discovered that 15 amino acids, diverse carbohydrates, and 24 genes across glyoxylate, Wood-Ljungdahl, nucleotide, amino acid, and carbohydrate metabolism are essential to support growth of C. difficile within an intestinal environment. Models and supporting resources are accessible through an interactive web portal (http://networks.systemsbiology.net/cdiff-portal/) to support collaborative systems analyses of C. difficile.

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Section: Egrin Uncovers Differentially Active Regulatory Network Dursupporting

confidence: 72%

mentioning

confidence: 89%

Section: Metabolic Model Refinement and Gene Essentiality Predictionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

mentioning

confidence: 99%

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Predictive regulatory and metabolic network models for systems analysis ofClostridioides difficile

Arrieta-Ortiz

Immanuel

Turkarslan

et al. 2020

Preprint

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Metabolic adaption to extracellular pyruvate triggers biofilm formation in Clostridioides difficile

et al. 2021

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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. Deoxycholate 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 deoxycholate 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 deoxycholate. 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 deoxycholate. In the absence of deoxycholate, 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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In vivocommensal control ofClostridioides difficilevirulence

Girinathan

DiBenedetto

Worley

et al. 2020

Preprint

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We define multiple mechanisms by which commensals protect against or worsen Clostridioides difficile infection.Using a systems-level approach we show how two species of Clostridia with distinct metabolic capabilities modulate the pathogen's virulence to impact host survival. Gnotobiotic mice colonized with the amino acid fermenter Clostridium bifermentans survived infection, while colonization with the butyrate-producer, Clostridium sardiniense, more rapidly succumbed. Systematic in vivo analyses revealed how each commensal altered the pathogen's carbon source metabolism, cellular machinery, stress responses, and toxin production. Protective effects were replicated in infected conventional mice receiving C. bifermentans as an oral bacteriotherapeutic that prevented lethal infection. Leveraging a systematic and organism-level approach to host-commensalpathogen interactions in vivo, we lay the groundwork for mechanistically-informed therapies to treat and prevent this disease.Clostridioides difficile, the etiology of pseudomembranous colitis, causes substantantial morbidity, mortality and >$5 billion/year in US healthcare costs. Infections commonly arise after antibiotic disruption of the microbiota, allowing the pathogen to proliferate and release toxins that ADP ribosylate host rho GTPases (1, 2). In patients with recurrent C. difficile infections, fecal microbiota transplant (FMT) has become standard of care to reconstitute the microbiota and prevent recurrence. While intensive efforts to develop defined microbial replacements for FMT have been undertaken, relatively little is known about the molecular, metabolic, and microbiologic mechanisms by which specific members of the microbiota modulate the pathogen's virulence in vivo, information critical for therapeutics development (3,4). Given deaths in immunocompromised patients from drug-resistant pathogens in FMT preparations (5), therapies informed by molecular mechanisms of action among will enable options with improved safety and efficacy (6, 7).C. difficile's pathogenicity locus (PaLoc) contains the tcdA, tcdB and tcdE genes that encode the A and B toxins, and holin involved in toxin export, respectively. tcdR encodes a sigma factor specific for the toxin gene promoters, and the tcdC gene a TcdR anti-sigma factor (8-10). Multiple metabolic regulators influence PaLoc expression (11,12). In particular, C. difficile elaborates toxin under starvation conditions to extract nutrients from the host and promote the shedding of spores.C. difficile, like other cluster XI Clostridia, possesses diverse genetic machinery to utilize different carbon sources for energy and growth. In addition to carbohydrate fermentation, the pathogen uses Stickland fermentations, and Stickland-independent fermentations of other amino acids including threonine and cysteine (13), to extract energy from amino acids. The pathogen can ferment ethanolamine, extract electrons from primary bile salts, and undergo carbon fixation through the Wood-Ljungdhal pathway to generate acetate for metabolism...

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In vivocommensal control ofClostridioides difficilevirulence

Cited by 13 publications

References 107 publications

Predictive regulatory and metabolic network models for systems analysis ofClostridioides difficile

Predictive regulatory and metabolic network models for systems analysis ofClostridioides difficile

Metabolic adaption to extracellular pyruvate triggers biofilm formation in Clostridioides difficile

In vivocommensal control ofClostridioides difficilevirulence

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