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:Nonalcoholic fatty liver disease represents a spectrum of pathology that ranges from benign steatosis to potentially-progressive steatohepatitis and affects more than 30% of US adults. Advanced NAFLD is associated with increased morbidity and mortality from cirrhosis, primary liver cancer, cardiovascular disease and extrahepatic cancers. Accurate identification of patients at risk for advanced NAFLD is challenging. The aims of this study were to define the liver gene expression patterns that distinguish mild from advanced NAFLD and to develop a gene expression profile associated with advanced NAFLD. We analyzed total RNA from 72 patients with NAFLD (40 with mild NAFLD, fibrosis stage 0-1 and 32 with advanced NAFLD, fibrosis stage 3-4) and developed a gene profile associated with advanced NAFLD. This dataset is part of the TransQST collection.

Project description:We investigated the hepatic transcriptome of 58 biopsy-proven NAFLD patients at multiple stages of the disease (NAFL, NASH with mild fibrosis, NASH with advanced fibrosis) with the aim of describing the pathophysiological events driving the development and progression of NASH.

Project description:The aim of this study is to compare mild and advanced liver fibrosis gene expression profiling and to identify novel markers of fibrosis progression. By transcriptome analysis with a cDNA array virtually covering every transcript in liver, we compared transcript levels in mild (F1 Metavir score) and advanced (F4 Metavir score) fibrosis. A stringent selection identified a list of 16 transcripts which completely separated the 2 groups of patients (8 F1 and 8 F4). We report that dysregulations at the transcriptional level do exist between mild fibrosis (F1) and advanced fibrosis (F4). Keywords: fibrosis stage-dependent analysis Fibrosis samples were analyzed for 16 patients : 8 mild fibrosis (F1-1 to F1-8) and 8 advanced fibrosis (F4-1 to F4-8). All data in the current study were obtained from 3 separate hybridizations per RNA sample.

Project description:We hypothesized that DNA methylation patterns may contribute to the development of active pulmonary tuberculosis (TB). Illumina’s DNA methylation 450 K assay was used to identify differentially methylated loci (DML) in a discovery cohort of 12 active pulmonary TB patients and 6 healthy subjects (HS). DNA methylation levels were validated in an independent cohort of 64 TB patients and 24 HS. Microarray analysis identified 1028 DMLs in TB patients versus HS, and 3747 DMLs in TB patients after versus before anti-TB treatment, while autophagy was the most enriched signaling pathway. In the validation cohort, PARP9 and miR505 genes were hypomethylated in the TB patients versus HS, while RASGRP4 and GNG12 genes were hypermethylated, with the former two further hypomethylated in those with delayed sputum conversion, systemic symptoms, or far advanced lesions. MRPS18B and RPTOR genes were hypomethylated in TB patients with pleural involvement. RASGRP4 gene hypermethylation and RPTOR gene down-regulation were associated with high mycobacterial burden. TB patients with WIPI2/GNG12 hypermethylation or MRPS18B/FOXO3 hypomethylation had lower one-year survival. In vitro ESAT6 and CFP10 stimuli of THP-1 cells resulted in DNA de-methylation changes of the PARP9, RASGRP4, WIPI2, and FOXO3 genes. In conclusions, aberrant DNA methylation over the PARP9/miR505/RASGRP4/GNG12 genes may contribute to the development of active pulmonary TB disease and its clinical phenotypes, while aberrant DNA methylation over the WIPI2/GNG12/MARPS18B/FOXO3 genes may constitute a determinant of long-term outcomes.

Project description:Nonalcoholic fatty liver disease represents a spectrum of pathology that ranges from benign steatosis to potentially-progressive steatohepatitis and affects more than 30% of US adults. Advanced NAFLD is associated with increased morbidity and mortality from cirrhosis, primary liver cancer, cardiovascular disease and extrahepatic cancers. Accurate identification of patients at risk for advanced NAFLD is challenging. The aims of this study were to define the liver gene expression patterns that distinguish mild from advanced NAFLD and to develop a gene expression profile associated with advanced NAFLD.

Project description:Nonalcoholic fatty liver disease (NAFLD) is the most common liver disease worldwide. Nonalcoholic steatohepatitis (NASH), the progressive form of NAFLD, and advanced fibrosis are associated with poor outcomes but their molecular pathogenesis is not fully elucidated. Global RNA sequencing of snap frozen liver tissue from 98 patients with biopsy-proven NAFLD was performed. Unsupervised hierarchical clustering well-distinguished NASH from NAFL, and NASH patients exhibited molecular abnormalities reflecting their pathological features. Transcriptomic analysis identified multiple secreted proteins upregulated in NASH and/or advanced fibrosis

Project description:The aim of this study is to compare mild and advanced liver fibrosis gene expression profiling and to identify novel markers of fibrosis progression. By transcriptome analysis with a cDNA array virtually covering every transcript in liver, we compared transcript levels in mild (F1 Metavir score) and advanced (F4 Metavir score) fibrosis. A stringent selection identified a list of 16 transcripts which completely separated the 2 groups of patients (8 F1 and 8 F4). We report that dysregulations at the transcriptional level do exist between mild fibrosis (F1) and advanced fibrosis (F4). Keywords: fibrosis stage-dependent analysis

Project description:Mild vs advanced liver fibrosis

Project description:Non-alcoholic Fatty Liver Disease (NAFLD) is the most common type of chronic liver disease in children. The mechanisms that drive NAFLD disease progression in this specific patient population remains poorly defined. In this study, we gathered liver biopsy samples from a multiethnic cohort (71% Hispanic) of pediatric NAFLD patients (n=52, mean age=13.6 years) plus healthy liver controls (n=5). We analyzed transcriptomic changes associated with NAFLD disease progression using high-throughput RNA-sequencing. Unsupervised clustering as well as pairwise transcriptome comparison distinguished NAFLD from healthy livers. We identified perturbations in calcium and insulin/glucose signaling occurring early in NAFLD disease, prior to the presence of histopathologic evidence of advanced disease. Transcriptomic comparisons between low and advanced fibrosis identified a 25-gene signature associated with pediatric fibrotic liver progression. We also identified expression of the IGFBP gene family (1/2/3/7) as correlating with disease progression and it has the potential to be used as a peripheral biomarker in NAFLD. Comparing our dataset with publicly available adult transcriptomic data, we identified similarities and differences in pathway enrichment and gene expression profiles between adult and pediatric NAFLD patients. Regulation of genes including IL32, IGFBP1, IGFBP2, IGFBP7 was consistently found in both NAFLD populations, while IGFBP3 was specific to pediatric NAFLD. Conclusions: This paper expands our knowledge on the molecular mechanisms driving NAFLD and fibrosis in the pediatric population and aids future biomarker and therapeutics discovery.