Project description:Exposure to adverse early-life environment (AME) increases the incidence of developing adult-onset non-alcoholic fatty liver disease (NAFLD). DNA methylation has been postulated to link AME and late-onset diseases. The objective was to investigate whether and to what extent hepatic DNA methylome was perturbed prior to the development of NAFLD in offspring exposed to AME in mice. AME constituted maternal western diet and late-gestational stress. Male offspring livers at birth (d0) and weaning (d21) were used for evaluating DNA methylome and transcriptome using reduced representation of bisulfite sequencing and RNA-seq, respectively. We found AME caused 5,879 differentially methylated regions (DMRs) and zero differentially expressed gene (DEG) at d0, and 2,970 and 123, respectively at d21. Majority of the DMRs were distal from gene transcription start sites and did not correlate with DEGs. The DEGs at d21 were significantly en-riched in GO biological processes characteristic of liver metabolic functions. In conclusion, AME drove changes in hepatic DNA methylome which preceded perturbations in the hepatic metabolic transcriptome, which preceded the onset of NAFLD. We speculate that subtle impacts in dynamic enhancers lead to long-range regulatory changes that manifest over time as gene network alter-nations to increase the incidence of NAFLD later in life.

Project description:Purpose: RNAseq analysis of hPSC undergoing in vitro hepatic differentiation, to validate proper differentiation at different times of differentiation (D0 to D21)

Project description:The impact of healthy aging on molecular programming of immune cells is poorly understood. Here, we report comprehensive characterization of healthy aging in human classical monocytes, with a focus on epigenomic, transcriptomic, and proteomic alterations, as well as the corresponding proteomic and metabolomic data for plasma, using healthy cohorts of 20 young and 20 older males (~27 and ~64 years old on average). For each individual, we performed eRRBS-based DNA methylation profiling, which allowed us to identify a set of age-associated differentially methylated regions (DMRs) – a novel, cell-type specific signature of aging in DNA methylome. Hypermethylation events were associated with H3K27me3 in the CpG islands near promoters of lowly-expressed genes, while hypomethylated DMRs were enriched in H3K4me1 marked regions and associated with age-related increase of expression of the corresponding genes, providing a link between DNA methylation and age-associated transcriptional changes in primary human cells.

Project description:The regeneration of the airway mucociliary epithelium involves several sequential events including migration, proliferation, polarization and final differentiation (i.e ciliogenesis). We used microarrays to detail the global programme of gene expression that occurs during regeneration and ciliogenesis of the human airway mucociliary epithelium. The four time points of regeneration of the airway epithelium (ALI-D0 which corresponds to the end of proliferation step; ALI-D7 which corresponds to the polarization step; ALI-D14 which corresponds to the onset of ciliogenesis and ALI-D21 corresponding to the terminal differentiation step) for RNA extraction and hybridization on Affymetrix microarrays.

Project description:Background & Aims: Cirrhosis and liver cancer are potential outcomes of advanced nonalcoholic fatty liver disease (NAFLD). It is not clear what factors determine whether patients will develop advanced or mild NAFLD, limiting non-invasive diagnosis and treatment before clinical sequelae emerge. We investigated whether DNA methylation profiles can distinguish patients with mild disease from those with advanced NAFLD, and how these patterns are functionally related to hepatic gene expression. Methods: We collected frozen liver biopsies and clinical data from patients with biopsy-proven NAFLD (56 in the discovery cohort and 34 in the replication cohort). Samples were divided into groups based on histologic severity of fibrosis: F0?1 (mild) and F3?4 (advanced). DNA methylation profiles were determined and coupled with gene expression data from the same biopsies; differential methylation was validated in subsets of the discovery and replication cohorts. We then analyzed interactions between the methylome and transcriptome. Results: Clinical features did not differ between patients known to have mild or advanced fibrosis based on biopsy analysis. There were 69,247 differentially methylated CpG sites (76% hypomethylated, 24% hypermethylated) in patients with advanced vs mild NAFLD (P<.05). Methylation at FGFR2, MAT1A, and CASP1 was validated by bisulfite pyrosequencing and the findings were reproduced in the replication cohort. Methylation correlated with gene transcript levels for 7% of differentially methylated CpG sites, indicating that differential methylation contributes to differences in expression. In samples with advanced NAFLD, many tissue repair genes were hypomethylated and overexpressed, whereas genes in certain metabolic pathways, including 1-carbon metabolism, were hypermethylated and under-expressed. Conclusions: Functionally relevant differences in methylation can distinguish patients with advanced vs mild NAFLD. Altered methylation of genes that regulate processes such as steatohepatitis, fibrosis, and carcinogenesis indicate the role of DNA methylation in progression of NAFLD. Three technical replicates were included for quality control along with 35 mild NAFLD (33 unique samples) and 24 advanced NAFLD (23 unique sample). One sample per technical duplication was randomly included for a total of 56 NAFLD samples used for study.

Project description:DNA methylation is critical for development and is strongly associated with gene regulation. Variation in the DNA methylome between closely related species may reveal unique functional adaptation. We have implemented a novel inter-primate DNA methylation genome-wide analysis between human, chimpanzee and rhesus macaque to identify human species-specific Differentially Methylated Regions (human s-DMRs) in orthologous loci. We analysed the peripheral blood cell DNA methylomes of these primates and identified 22,758 hypomethylated and 15,858 hypermethylated human s-DMRs. These s-DMRs are globally enriched within weak promoter, enhancer and transcribed regions via comparison with ChromHMM segmentation. Human s-DMRs, (both hypo- and hypermethylated) are found to be more prevalent in CpG Island shores than within the islands themselves (?2 P = 1.80 x 10-32). Examining human-specific Transcription Factor Binding Site motif change within CpG islands, we show gain and loss, in hypomethylated and hypermethylated s-DMRs, respectively, of CTCF motifs. Epigenetically the most divergent human-specific locus was the immunological Leukotriene B4 receptor (LTB4R, aka BLT1 receptor), due to collocating hypomethylated s-DMRs within the promoter CpG island and shore, as well as inverse increased gene body methylation. This gene is vital in host immune responses and associated with the pathogenesis of a wide range of human inflammatory diseases. This finding was supported by additional neutrophil-only DNA methylome and lymphoblastoid H3K4me3 chromatin comparative data. Functional investigation of the consequences of these epigenetic differences identified this receptor to have increased expression, and have a higher response to the LTB4 ligand in human versus rhesus macaque peripheral blood mononuclear cells. This result further emphasises the exclusive nature of the human immunological system, its divergent adaptation even from closely related primates, and the power of comparative epigenomics to identify and understand human uniqueness. DNA methylome analysis of pooled Human, Chimpanzee and Macaque

Project description:Investigate the genome-wide DNA methylation and gene expression changes during human embryonic stem cell differentiation. hESCs (H1 and H13) DNA samples for 3 different differentian stage (D0, undifferentiated;D21, 21 days after undirected differentiation; D90, 90 days after undirected differentiation); two-color experiment, paired comparison (differentiated vs undifferentiated; A & B: two biological replicates). Differentian-stage variation in methylation profiling of human DNA samples were detected by MSAM. 2µg of DNA was serially digested with SmaI and XmaI followed by an adaptor ligation and adaptor mediated PCR amplification. Analysis of differentian-stage variation in gene expression of human mRNA samples were implementd following standard Agilent protocol.

Project description:Non-alcoholic fatty liver (NAFL) has the potential to progress to non-alcoholic steatohepatitis (NASH) or to promote type 2 diabetes mellitus (T2DM). However, NASH and T2DM do not always develop coordinately. We established rat models of NAFL, NASH, and NAFL + T2DM to recapitulate different phenotypes associated with NAFLD and its progression. Microarrays were used to identify hepatic gene expression changes in each of these models. The goal is to identify a predictor of different NAFLD progressions. Non-alcoholic fatty liver disease (NAFLD) is recognized as a low-grade systemic inflammatory state with both hepatic and extra-hepatic manifestations. We aimed to identify common key regulators and adaptive pathways in different NAFLD phenotypes. NAFL, NASH and NAFL+T2DM rat models were used to represent simple fatty liver, fatty liver with severe hepatic manifestations, and fatty liver with severe metabolic manifestations, respectively. We applied microarray analysis to characterize the key regulators and adaptive pathways in different NAFLD phenotypes. There are 12 samples in our study which belonged to 4 groups, and each group contains 3 different samples.

Project description:Molecular and cellular mechanisms causing the onset and progression of non-alcoholic fatty liver disease (NAFLD), non-alcoholic steatohepatitis (NASH), and HCC remain poorly understood. Here we show that myeloid-cell-specific heterozygous deletion of Ncoa5 (Ncoa5ΔM/+) sufficiently causes the development of NAFLD/NASH and HCC in male mice. The platelet factor 4 (PF4) overexpressed by Ncoa5ΔM/+ intrahepatic macrophages is identified as a potent mediator to trigger lipid accumulation in hepatocytes by inducing expression of genes promoting lipogenesis. Enrichment score of the gene expression signature derived from Ncoa5ΔM/+ hepatic macrophages correlated with unfavorable clinical parameters of NAFLD patients. Moreover, in HCC patients, the high PF4 expression correlated with poor overall survival and increased infiltrations of M2 macrophages, exhausted CD8 T cells, and MDSCs in HCCs. Our results reveal a novel macrophage-underlying mechanism for the onset of NAFLD and NASH-related HCC and suggest that NCOA5-PF4 axis is a potential target for therapeutic inhibition of NAFLD/NASH progression.

Project description:Perfluoroalkyl substances (PFASs) are a family of toxicants universally detected in human serum and known to cause dyslipidemia in animals and humans. Non-alcoholic fatty liver disease (NAFLD) is most prevalent form of liver disease in the United States and has been rising in global prevalence over recent years. This study explored diet-PFAS interactions and their potential role in the increasing global incidence of NAFLD. Male C57BL/6 mice were fed with either a low-fat diet (10% kcal from fat) or a moderately high fat diet (45% kcal from fat) with or without perfluorooctanesulfonic acid (PFOS) or perfluorononanoic acid (PFNA) at a low dose of 0.0003% w/w in feed for 12 weeks. Livers were excised for histology and quantification of PFASs and lipids. Proteomics and transcriptomics were utilized to conduct mechanistic pathway exploration. In a high fat diet, PFOS and PFNA protected against the onset of hepatic lipid accumulation and inflammatory progression. Genes and proteins related to lipid metabolism, synthesis, transport, and storage were modulated by PFAS exposure and further impacted by the presence of dietary fat. When combined with a high fat diet, low dose PFOS and PFNA are protective against the onset of NAFLD suggesting that dietary fat impacts the behavior of PFASs in vivo. Furthermore, both dietary fat content and the chemical functional head group exerted significant influence on tissue partitioning and the resulting hepatic biochemical signature.