Quantitative Imaging of Gut Microbiota Spatial Organization

Earle, Kristen A.; Billings, Gabriel; Sigal, Michael; Lichtman, Joshua S.; Hansson, Gunnar C.; Elias, Joshua E.; Amieva, Manuel R.; Huang, Kerwyn Casey; Sonnenburg, Justin L.

doi:10.1016/j.chom.2015.09.002

Cited by 375 publications

(347 citation statements)

References 33 publications

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“…These differences could be explained by AMP being differentially expressed in physiological conditions along the SI (66), and thus respond differentially with respect to microbiota modulation. Moreover, it was recently shown that elimination of the microbiota-accessible carbohydrates, which are highly represented in dietary fibers and used as substrate by intestinal bacteria, induces a shift of the microbiota toward mucus-consuming bacteria and consequently results in closer proximity of bacteria with the epithelium (67). However, no data are actually available concerning the impact on the spatial distribution of microbiota of missing microbiotaaccessible carbohydrates in the small intestine.…”

Section: Discussionmentioning

confidence: 91%

“…In our model collapse of the mucus barrier could favor the emergence of such bacteria able to use it as substrate, or diet-mediated increase in this species may further participate in the alteration of the mucus barrier (67,73). Interestingly, the treatment of HF-fed mice with rosiglitazone was able to restore the spatial distribution of the ileal microbiota but not the composition compared with SD-fed mice, indicating that biochemical parameters, such as electrolytes and mucus releases, play pivotal roles in maintaining microbiota at a distance from the epithelium, but diet composition determine the microbiota composition (67). Other bacterial species were affected under HF diet, such as SFB.…”

Section: Discussionmentioning

confidence: 99%

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High-fat diet modifies the PPAR-γ pathway leading to disruption of microbial and physiological ecosystem in murine small intestine

Tomas

Mulet

Saffarian

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

192

137

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Diet is among the most important factors contributing to intestinal homeostasis, and basic functions performed by the small intestine need to be tightly preserved to maintain health. Little is known about the direct impact of high-fat (HF) diet on small-intestinal mucosal defenses and spatial distribution of the microbiota during the early phase of its administration. We observed that only 30 d after HF diet initiation, the intervillous zone of the ileum—which is usually described as free of bacteria—became occupied by a dense microbiota. In addition to affecting its spatial distribution, HF diet also drastically affected microbiota composition with a profile characterized by the expansion of Firmicutes (appearance of Erysipelotrichi), Proteobacteria (Desulfovibrionales) and Verrucomicrobia, and decrease of Bacteroidetes (family S24-7) and Candidatus arthromitus. A decrease in antimicrobial peptide expression was predominantly observed in the ileum where bacterial density appeared highest. In addition, HF diet increased intestinal permeability and decreased cystic fibrosis transmembrane conductance regulator (Cftr) and the Na-K-2Cl cotransporter 1 (Nkcc1) gene and protein expressions, leading to a decrease in ileal secretion of chloride, likely responsible for massive alteration in mucus phenotype. This complex phenotype triggered by HF diet at the interface between the microbiota and the mucosal surface was reversed when the diet was switched back to standard composition or when mice were treated for 1 wk with rosiglitazone, a specific agonist of peroxisome proliferator-activated receptor-γ (PPAR-γ). Moreover, weaker expression of antimicrobial peptide-encoding genes and intervillous bacterial colonization were observed in Ppar-γ–deficient mice, highlighting the major role of lipids in modulation of mucosal immune defenses.

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Section: Discussionmentioning

confidence: 91%

Section: Discussionmentioning

confidence: 99%

High-fat diet modifies the PPAR-γ pathway leading to disruption of microbial and physiological ecosystem in murine small intestine

Tomas

Mulet

Saffarian

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

192

137

View full text Add to dashboard Cite

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“…Mucus acts to protect the gut epithelium from mechanical stress, to lubricate the intestine to ease transit of digested material, and to prevent the translocation of harmful substances. A study comparing a standard rodent diet (fiber from wheat, corn, and oats comprising 4.3% of the diet by weight) with a diet devoid of any fiber showed that mice fed the fiber-deficient diet had a thinner mucus layer, thus allowing microbes to come in closer proximity to the gut epithelium (61). Without sufficient amounts of DF in the gut, bacteria may degrade the host mucus layer in order to provide themselves with the substrates necessary to survive, thus breaking down one of the host's physical barriers.…”

Section: Impact Of Df On the Gut The Gatekeeper Of The Bodymentioning

confidence: 99%

Impact of Dietary Fibers on Nutrient Management and Detoxification Organs: Gut, Liver, and Kidneys

Kieffer

Martin

Adams

2016

Advances in Nutrition

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Increased dietary fiber (DF) intake elicits a wide range of physiologic effects, not just locally in the gut, but systemically. DFs can greatly alter the gut milieu by affecting the gut microbiome, which in turn influences the gut barrier, gastrointestinal immune and endocrine responses, and nitrogen cycling and microbial metabolism. These gut-associated changes can then alter the physiology and biochemistry of the body's other main nutrient management and detoxification organs, the liver and kidneys. The molecular mechanisms by which DF alters the physiology of the gut, liver, and kidneys is likely through gut-localized events (i.e., bacterial nitrogen metabolism, microbe-microbe, and microbe-host cell interactions) coupled with specific factors that emanate from the gut in response to DF, which signal to or affect the physiology of the liver and kidneys. The latter may include microbe-derived xenometabolites, peptides, or bioactive food components made available by gut microbes, inflammation signals, and gut hormones. The intent of this review is to summarize how DF alters the gut milieu to specifically affect intestinal, liver, and kidney functions and to discuss the potential local and systemic signaling networks that are involved. Adv Nutr 2016;7:1111-21.

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“…Some biofilms are beneficial to human health, for example as part of the healthy gut and skin microbiota (5,6) or in wastewater treatment systems (7). Other biofilms, however, cause serious problems in oral hygiene, chronic infections, and prosthetic contamination (8)(9)(10) and act as fouling agents in industrial flow systems (11).…”

mentioning

confidence: 99%

Architectural transitions in Vibrio cholerae biofilms at single-cell resolution

Drescher

Dunkel

Nadell

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

181

205

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Many bacterial species colonize surfaces and form dense 3D structures, known as biofilms, which are highly tolerant to antibiotics and constitute one of the major forms of bacterial biomass on Earth. Bacterial biofilms display remarkable changes during their development from initial attachment to maturity, yet the cellular architecture that gives rise to collective biofilm morphology during growth is largely unknown. Here, we use high-resolution optical microscopy to image all individual cells in Vibrio cholerae biofilms at different stages of development, including colonies that range in size from 2 to 4,500 cells. From these data, we extracted the precise 3D cellular arrangements, cell shapes, sizes, and global morphological features during biofilm growth on submerged glass substrates under flow. We discovered several critical transitions of the internal and external biofilm architectures that separate the major phases of V. cholerae biofilm growth. Optical imaging of biofilms with single-cell resolution provides a new window into biofilm formation that will prove invaluable to understanding the mechanics underlying biofilm development.biofilm | community | self-organization | emergent order | nematic order

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Quantitative Imaging of Gut Microbiota Spatial Organization

Cited by 375 publications

References 33 publications

High-fat diet modifies the PPAR-γ pathway leading to disruption of microbial and physiological ecosystem in murine small intestine

High-fat diet modifies the PPAR-γ pathway leading to disruption of microbial and physiological ecosystem in murine small intestine

Impact of Dietary Fibers on Nutrient Management and Detoxification Organs: Gut, Liver, and Kidneys

Architectural transitions in Vibrio cholerae biofilms at single-cell resolution

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