Project description:Gut microbiota and their metabolites influence host gene expression and physiological status through diverse mechanisms. Here we investigate how gut microbiota and their metabolites impact host's mRNA m6A epitranscriptome in various antibiotic-induced microbiota dysbiosis models. With multi-omics analysis, we find that the imbalance of gut microbiota can rewire host mRNA m6A epitranscriptomic profiles in brain, liver and intestine. We further explore the underlying mechanisms regulating host mRNA m6A methylome by depleting the microbiota with ampicillin. Metabolomic profiling shows that cholic acids are the main down-regulated metabolites with Firmicutes as the most significantly reduced genus in ampicillin-treated mice comparing to untreated mice. Fecal microbiota transplantations in germ-free mice and metabolites supplementations in cells verify that cholic acids are associated with host mRNA m6A epitranscriptomic rewiring. Collectively, this study employs an integrative multi-omics analysis to demonstrate the impact of gut microbiota dysbiosis on host mRNA m6A epitranscriptomic landscape via cholic acid metabolism.

Project description:Gut microbiota and their metabolites influence host gene expression and physiological status through diverse mechanisms. Here we investigate how gut microbiota and their metabolites impact host′s mRNA m6A epitranscriptome in various antibiotic-induced microbiota dysbiosis models. With multi-omics analysis, we find that the imbalance of gut microbiota can rewire host mRNA m6A epitranscriptomic profiles in brain, liver and intestine. We further explore the underlying mechanisms regulating host mRNA m6A methylome by depleting the microbiota with ampicillin. Metabolomic profiling shows that cholic acids are the main down-regulated metabolites with Firmicutes as the most significantly reduced genus in ampicillin-treated mice comparing to untreated mice. Fecal microbiota transplantations in germ-free mice and metabolites supplementations in cells verify that cholic acids are associated with host mRNA m6A epitranscriptomic rewiring. Collectively, this study employs an integrative multi-omics analysis to demonstrate the impact of gut microbiota dysbiosis on host mRNA m6A epitranscriptomic landscape via cholic acid metabolism.

Project description:To find the signalling pathway involved in WT/2D2 CD4+ gut T cell (CD4+ intraepithelial lymphocytes, CD4+IEL) differentiation, particulary to determine whether aryl hydrocarbon receptor (AHR) pathway is involved. Gene expression was analyzed ex vivo in CD4+ T cells that were sorted from Wild type-Gut / 2D2 mouse-Gut / Wild type-Spleen / 2D2 mouse-Spleen (N=3 per group). The genes highly expressed in WT/2D2 Gut compared to WT/2D2 Spleen were selected by k-means clustering. AHR pathway related genes (IPA software) were further selected.

Project description:Metabolites were extracted (aqueous & organic) from hamster tissues (liver, gut, and spleen) and were run through LC-MS, C8 in positive and negative mode.

Project description:Metabolites were extracted (aqueous & organic) from hamster tissues (liver, gut, and spleen) and were run through LC-MS, C8 in positive and negative mode.

Project description:Liver stage of malaria parasite exports SLTRiP and PB268 to the cytosol of parasite infected host cell. To know the host genes perturbed by WT-PBANKA, SLTRiP-KO and PB268-KO parasite growth, we did transcriptomic sequencing of infected host cells. We did mRNA sequencing of four samples for comparative analysis of WT and PB-knockout parasites infected host cells at 22 hours of post sporozoites infection.

Project description:Liver stage of malaria parasite exports SLTRiP and PB268 to the cytosol of parasite infected host cell. To know the host genes perturbed by WT-PBANKA, SLTRiP-KO and PB268-KO parasite growth, we did transcriptomic sequencing of infected host cells. We did mRNA sequencing of four samples for comparative analysis of WT and PB-knockout parasites infected host cells at 22 hours of post sporozoites infection. mRNA profiles of Plasmodium PBANKA, PBSLTRiP-KO, PB268-KO parasite infected and uninfected HepG2 cells after 22hrs of sporozoites infections were generated by deep sequencing using Illumina GAIIx.

Project description:The malaria parasite Plasmodium replicates and differentiates in red blood cells of its host. The erythropoietic niches (spleen and bone marrow) are important but poorly understood reservoirs of asexual replication and sexual development. We aimed to understand how the parasite adapts to its host organ and a host cell level. For this, we performed single-cell RNA-seq (scRNA-seq) analysis on host and parasite cells derived from spleen, blood and bone marrow. Organs were harvested from two infected and one uninfected mice and parasite cells were enriched to about 50% by flow sorting (infected samples only). To identify host cells by surface expression (CITE-seq), cells were stained with barcoded antibodies targeting CD44 and CD71. Droplet-based scRNA-seq of these samples was performed using 10X genomics technology and cDNA was sequenced on Illumina.

Project description:This experiment was investigating how gut commensal bacteria and intestinal inflammation affect miRNA expression. We analyzed miRNA expression of spleen and intestine from specific pathogen free (SPF) B6 mice, germ-free (GF) B6 mice, and IL-10 knockout mice which have severe colitis by microarray. Thus we have total 6 samples: GF spleen; GF intestines; SPF spleen; SPF intestine; IL-10 KO spleen and IL-10 KO intestine. We directly isolated RNA from whole spleens or intestines without any treatments, and then did microarray analysis.

Project description:BACKGROUND & AIMS: There is mounting evidence that microbes resident in the human intestine contribute to diverse alcohol-associated liver diseases (ALD) including the most deadly form known as alcoholic hepatitis (AH). However, mechanisms by which gut microbiota synergize with excessive alcohol intake to promote liver injury are poorly understood. Furthermore, whether drugs that selectively target gut microbial metabolism can improve ALD has never been tested. METHODS: We used liquid chromatography tandem mass spectrometry to quantify the levels of microbe and host choline co-metabolites in healthy controls and AH patients, and identified the metabolite trimethylamine (TMA) as a gut microbe-derived biomarker of AH. In subsequent studies, we treated mice with non-lethal mechanism-based bacterial choline TMA lyase inhibitors to blunt gut microbe-dependent production of TMA in the context of chronic ethanol administration. Indices of liver injury were quantified by complementary RNA sequencing, biochemical, and histological approaches. In addition, we examined the impact of ethanol consumption and TMA lyase inhibition on gut microbiome structure via 16S rRNA sequencing. RESULTS: We show the gut microbial choline metabolite trimethylamine (TMA) is elevated in AH patients, which is correlated with reduced hepatic expression of the TMA oxygenase flavin-containing monooxygenase 3 (FMO3). Provocatively, we find that small molecule inhibition of gut microbial choline TMA lyase activity protects mice from ethanol-induced liver injury. TMA lyase inhibitor-driven improvement in ethanol-induced liver injury is associated with distinct reorganization of the gut microbiome community and host liver transcriptome. CONCLUSIONS: The microbial metabolite TMA is a biomarker of AH, and blocking TMA production from gut microbes can blunt ALD in mice.