BIOMAT Database Logo BIOMAT Database Logo

A single cell survey of the microbial impacts on the mouse small intestinal epithelium. 2022

Derek K L Tsang, and Ryan J Wang, and Oliver De Sa, and Arshad Ayyaz, and Elisabeth G Foerster, and Giuliano Bayer, and Shawn Goyal, and Daniel Trcka, and Bibaswan Ghoshal, and Jeffrey L Wrana, and Stephen E Girardin, and Dana J Philpott
Department of Immunology, University of Toronto, Toronto, Ontario, Canada.

The small intestinal epithelial barrier inputs signals from the gut microbiota in order to balance physiological inflammation and tolerance, and to promote homeostasis. Understanding the dynamic relationship between microbes and intestinal epithelial cells has been a challenge given the cellular heterogeneity associated with the epithelium and the inherent difficulty of isolating and identifying individual cell types. Here, we used single-cell RNA sequencing of small intestinal epithelial cells from germ-free and specific pathogen-free mice to study microbe-epithelium crosstalk at the single-cell resolution. The presence of microbiota did not impact overall cellular composition of the epithelium, except for an increase in Paneth cell numbers. Contrary to expectations, pattern recognition receptors and their adaptors were not induced by the microbiota but showed concentrated expression in a small proportion of epithelial cell subsets. The presence of the microbiota induced the expression of host defense- and glycosylation-associated genes in distinct epithelial cell compartments. Moreover, the microbiota altered the metabolic gene expression profile of epithelial cells, consequently inducing mTOR signaling thereby suggesting microbe-derived metabolites directly activate and regulate mTOR signaling. Altogether, these findings present a resource of the homeostatic transcriptional and cellular impact of the microbiota on the small intestinal epithelium.

UI MeSH Term Description Entries
D007413 Intestinal Mucosa Lining of the INTESTINES, consisting of an inner EPITHELIUM, a middle LAMINA PROPRIA, and an outer MUSCULARIS MUCOSAE. In the SMALL INTESTINE, the mucosa is characterized by a series of folds and abundance of absorptive cells (ENTEROCYTES) with MICROVILLI. Intestinal Epithelium,Intestinal Glands,Epithelium, Intestinal,Gland, Intestinal,Glands, Intestinal,Intestinal Gland,Mucosa, Intestinal
D007421 Intestine, Small The portion of the GASTROINTESTINAL TRACT between the PYLORUS of the STOMACH and the ILEOCECAL VALVE of the LARGE INTESTINE. It is divisible into three portions: the DUODENUM, the JEJUNUM, and the ILEUM. Small Intestine,Intestines, Small,Small Intestines
D000069196 Gastrointestinal Microbiome All of the microbial organisms that naturally exist within the GASTROINTESTINAL TRACT. Enteric Bacteria,Gastric Microbiome,Gastrointestinal Flora,Gastrointestinal Microbial Community,Gastrointestinal Microbiota,Gastrointestinal Microflora,Gut Flora,Gut Microbiome,Gut Microbiota,Gut Microflora,Intestinal Flora,Intestinal Microbiome,Intestinal Microbiota,Intestinal Microflora,Bacteria, Enteric,Flora, Gastrointestinal,Flora, Gut,Flora, Intestinal,Gastric Microbiomes,Gastrointestinal Microbial Communities,Gastrointestinal Microbiomes,Gastrointestinal Microbiotas,Gut Microbiomes,Gut Microbiotas,Intestinal Microbiomes,Intestinal Microbiotas,Microbial Community, Gastrointestinal,Microbiome, Gastric,Microbiome, Gastrointestinal,Microbiome, Gut,Microbiome, Intestinal,Microbiota, Gastrointestinal,Microbiota, Gut,Microbiota, Intestinal,Microflora, Gastrointestinal,Microflora, Gut,Microflora, Intestinal
D000818 Animals Unicellular or multicellular, heterotrophic organisms, that have sensation and the power of voluntary movement. Under the older five kingdom paradigm, Animalia was one of the kingdoms. Under the modern three domain model, Animalia represents one of the many groups in the domain EUKARYOTA. Animal,Metazoa,Animalia
D051379 Mice The common name for the genus Mus. Mice, House,Mus,Mus musculus,Mice, Laboratory,Mouse,Mouse, House,Mouse, Laboratory,Mouse, Swiss,Mus domesticus,Mus musculus domesticus,Swiss Mice,House Mice,House Mouse,Laboratory Mice,Laboratory Mouse,Mice, Swiss,Swiss Mouse,domesticus, Mus musculus
D058570 TOR Serine-Threonine Kinases A serine threonine kinase that controls a wide range of growth-related cellular processes. The protein is referred to as the target of RAPAMYCIN due to the discovery that SIROLIMUS (commonly known as rapamycin) forms an inhibitory complex with TACROLIMUS BINDING PROTEIN 1A that blocks the action of its enzymatic activity. TOR Kinase,TOR Kinases,TOR Serine-Threonine Kinase,Target of Rapamycin Protein,mTOR Serine-Threonine Kinase,mTOR Serine-Threonine Kinases,FK506 Binding Protein 12-Rapamycin Associated Protein 1,FKBP12-Rapamycin Associated Protein,FKBP12-Rapamycin Complex-Associated Protein,Mammalian Target of Rapamycin,Mechanistic Target of Rapamycin Protein,RAFT-1 Protein,Rapamycin Target Protein,Target of Rapamycin Proteins,mTOR Protein,FK506 Binding Protein 12 Rapamycin Associated Protein 1,FKBP12 Rapamycin Associated Protein,FKBP12 Rapamycin Complex Associated Protein,Kinase, TOR,Kinase, TOR Serine-Threonine,Kinase, mTOR Serine-Threonine,Kinases, TOR Serine-Threonine,Kinases, mTOR Serine-Threonine,Protein Target, Rapamycin,Protein, RAFT-1,Protein, mTOR,RAFT 1 Protein,Rapamycin Protein Target,Serine-Threonine Kinase, TOR,Serine-Threonine Kinase, mTOR,Serine-Threonine Kinases, TOR,Serine-Threonine Kinases, mTOR,TOR Serine Threonine Kinase,TOR Serine Threonine Kinases,mTOR Serine Threonine Kinase,mTOR Serine Threonine Kinases
D019879 Paneth Cells Differentiated epithelial cells of the INTESTINAL MUCOSA, found in the basal part of the intestinal crypts of Lieberkuhn. Paneth cells secrete GROWTH FACTORS, digestive enzymes such as LYSOZYME and antimicrobial peptides such as cryptdins (ALPHA-DEFENSINS) into the crypt lumen. Paneth Cell,Cell, Paneth,Cells, Paneth

Related Publications

Derek K L Tsang, and Ryan J Wang, and Oliver De Sa, and Arshad Ayyaz, and Elisabeth G Foerster, and Giuliano Bayer, and Shawn Goyal, and Daniel Trcka, and Bibaswan Ghoshal, and Jeffrey L Wrana, and Stephen E Girardin, and Dana J Philpott
A single-cell survey of the small intestinal epithelium.
November 2017, Nature,
Derek K L Tsang, and Ryan J Wang, and Oliver De Sa, and Arshad Ayyaz, and Elisabeth G Foerster, and Giuliano Bayer, and Shawn Goyal, and Daniel Trcka, and Bibaswan Ghoshal, and Jeffrey L Wrana, and Stephen E Girardin, and Dana J Philpott
Effects of single-dose partial-body x-irradiation on cell proliferation in the mouse small intestinal epithelium.
January 1974, Radiation research,
Derek K L Tsang, and Ryan J Wang, and Oliver De Sa, and Arshad Ayyaz, and Elisabeth G Foerster, and Giuliano Bayer, and Shawn Goyal, and Daniel Trcka, and Bibaswan Ghoshal, and Jeffrey L Wrana, and Stephen E Girardin, and Dana J Philpott
The crypt cycle in mouse small intestinal epithelium.
December 1994, Journal of cell science,
Derek K L Tsang, and Ryan J Wang, and Oliver De Sa, and Arshad Ayyaz, and Elisabeth G Foerster, and Giuliano Bayer, and Shawn Goyal, and Daniel Trcka, and Bibaswan Ghoshal, and Jeffrey L Wrana, and Stephen E Girardin, and Dana J Philpott
Neurogenin 3 and the enteroendocrine cell lineage in the adult mouse small intestinal epithelium.
December 2006, Developmental biology,
Derek K L Tsang, and Ryan J Wang, and Oliver De Sa, and Arshad Ayyaz, and Elisabeth G Foerster, and Giuliano Bayer, and Shawn Goyal, and Daniel Trcka, and Bibaswan Ghoshal, and Jeffrey L Wrana, and Stephen E Girardin, and Dana J Philpott
Detailed survey of an in vitro intestinal epithelium model by single-cell transcriptomics.
April 2024, iScience,
Derek K L Tsang, and Ryan J Wang, and Oliver De Sa, and Arshad Ayyaz, and Elisabeth G Foerster, and Giuliano Bayer, and Shawn Goyal, and Daniel Trcka, and Bibaswan Ghoshal, and Jeffrey L Wrana, and Stephen E Girardin, and Dana J Philpott
Single-Cell Transcriptional Profiling of the Intestinal Epithelium.
January 2020, Methods in molecular biology (Clifton, N.J.),
Derek K L Tsang, and Ryan J Wang, and Oliver De Sa, and Arshad Ayyaz, and Elisabeth G Foerster, and Giuliano Bayer, and Shawn Goyal, and Daniel Trcka, and Bibaswan Ghoshal, and Jeffrey L Wrana, and Stephen E Girardin, and Dana J Philpott
Use of a mouse chimaeric model to study cell migration patterns in the small intestinal epithelium.
May 1985, Cell and tissue kinetics,
Derek K L Tsang, and Ryan J Wang, and Oliver De Sa, and Arshad Ayyaz, and Elisabeth G Foerster, and Giuliano Bayer, and Shawn Goyal, and Daniel Trcka, and Bibaswan Ghoshal, and Jeffrey L Wrana, and Stephen E Girardin, and Dana J Philpott
Cell population kinetics in the intestinal epithelium of the mouse.
June 1959, Experimental cell research,
Derek K L Tsang, and Ryan J Wang, and Oliver De Sa, and Arshad Ayyaz, and Elisabeth G Foerster, and Giuliano Bayer, and Shawn Goyal, and Daniel Trcka, and Bibaswan Ghoshal, and Jeffrey L Wrana, and Stephen E Girardin, and Dana J Philpott
Transcriptional Integration of Distinct Microbial and Nutritional Signals by the Small Intestinal Epithelium.
January 2022, Cellular and molecular gastroenterology and hepatology,
Derek K L Tsang, and Ryan J Wang, and Oliver De Sa, and Arshad Ayyaz, and Elisabeth G Foerster, and Giuliano Bayer, and Shawn Goyal, and Daniel Trcka, and Bibaswan Ghoshal, and Jeffrey L Wrana, and Stephen E Girardin, and Dana J Philpott
Effects of 30% intestinal resection on whole population cell kinetics of mouse intestinal epithelium.
May 1986, The Anatomical record,
Copied contents to your clipboard!