Project description:To determine whether diet-induced changes in gut microbiota modified intestinal immune cell gene expression, we analyzed the transcriptome of CD4 T lymphocytes isolated from the lamina propria of the small intestine from mice fed with different diets.
Project description:Dietary lipids and gut microbiota may both influence adipose tissue physiology. By feeding conventional and germ-free mice high fat diets with different lipid compositon we aimed to investigate how dietary lipids and the gut microbiota interact to influence inflammation and metabolism in the liver Wild-type C57Bl/6 male mice 11 weeks of age were fed isocaloric diets (45% kcal fat) with either menhaden fish oil (Research Diets, D05122102) or lard (Research Diets, D10011202) for 11 weeks. Liver samples were harvested at the end of the experiment and analyzed by microarray.
Project description:Dietary lipids and gut microbiota may both influence adipose tissue physiology. By feeding conventional and germ-free mice high fat diets with different lipid compositon we aimed to investigate how dietary lipids and the gut microbiota interact to influence inflammation and metabolism in epididymal adipiose tissue (EWAT) Wild-type C57Bl/6 male mice 11 weeks of age were fed isocaloric diets (45% kcal fat) with either menhaden fish oil (Research Diets, D05122102) or lard (Research Diets, D10011202) for 11 weeks. Epididymal WAT samples were harvested at the end of the experiment and analyzed by microarray.
Project description:In this study, mice were colonized from birth on with the minimal microbiota Oligo-MM with or without the addition of Extibacter muris. Extibacter muris is known to metabolize cholic acid to deoxycholic acid via 7α-dehydroxylation. The impact of Extibacter muris colonization on the liver proteome of mice under different diets was investigated using untargeted proteomics.
Project description:Feces samples from pigs with two different diets were analysed. Proteins from the microbiota was extracted and analysed by LC-MS/MS. Differences along the time and between the diets were observed.
Project description:Dietary lipids and gut microbiota may both influence adipose tissue physiology. By feeding conventional and germ-free mice high fat diets with different lipid compositon we aimed to investigate how dietary lipids and the gut microbiota interact to influence inflammation and metabolism in the liver
Project description:Dietary lipids and gut microbiota may both influence adipose tissue physiology. By feeding conventional and germ-free mice high fat diets with different lipid compositon we aimed to investigate how dietary lipids and the gut microbiota interact to influence inflammation and metabolism in epididymal adipiose tissue (EWAT)
Project description:To elucidate alterations in intestinal cell types under chronic stress, we conducted scRNA-seq analysis of intestinal crypts from NT and ES models. After that, we found that significant changes in ISCs in the ES group compared to the NT group. To validate the functional roles of ISCs, we performed RNA-seq of ISCs under different treatment conditions, we identified Chrm3-dependent differential genes between NT and ES groups, particularly noting downregulated genes associated with stemness and proliferation (e.g., Olfm4, Lgr5, and Mcm4), and upregulated genes linked to aging and calcium signaling pathways (e.g., Cdkn1a, Orai1, and Chp2), which contribute to ISC aging. These findings provided mechanistic insights into targeting these pathways to enhance intestinal function and integrity. Furthermore, to assess the impact of stress-induced changes in microbiota composition on ISC stemness, we synchronized microbiota between NT and ES groups through co-housing conditions and employed 16S rDNA sequencing. This analysis aimed to ascertain the possibility that changes in the microbiota composition whether contribute to the decline in ISC stemness under stress conditions. scRNA-seq of crypts were used to to characterize the diversity of cell lines under chronic stress. RNA-seq of ISC in Chrm3Lgr5+/+ and Chrm3Lgr5-/- mice from NT and ES mice were taken to delineate altered pathways and the mechanisms underlying ISC changes in ES model. 16S rDNA-seq (available in PRJNA1090629) were employed to confirm microbiota synchronization between NT and ES groups under co-housing conditions.
