Project description:Genetic variants in gene regulatory sequences can modify gene expression and mediate the molecular response to environmental stimuli. In addition, genotype–environment interactions (GxE) contribute to complex traits such as cardiovascular disease. Caffeine is the most widely consumed stimulant and is known to produce a vascular response. To investigate GxE for caffeine, we treated vascular endothelial cells with caffeine and used a massively parallel reporter assay to measure allelic effects on gene regulation for over 43,000 genetic variants. We identified 665 variants with allelic effects on gene regulation and 6 variants that regulate the gene expression response to caffeine (GxE, false discovery rate [FDR] < 5%). When overlapping our GxE results with expression quantitative trait loci colocalized with coronary artery disease and hypertension, we dissected their regulatory mechanisms and showed a modulatory role for caffeine. Our results demonstrate that massively parallel reporter assay is a powerful approach to identify and molecularly characterize GxE in the specific context of caffeine consumption.
Project description:Steady-state expression quantitative trait loci (eQTLs) explain only a fraction of disease-associated loci identified through genome-wide association studies (GWAS), while eQTLs involved in gene-by-environment (GxE) interactions have rarely been characterized in humans due to experimental challenges. Using a baboon model, we found hundreds of eQTLs that emerge in adipose, liver, and muscle after prolonged exposure to high dietary fat and cholesterol. Diet-responsive eQTLs exhibit genomic localization and genic features that are distinct from steady-state eQTLs. Furthermore, the human orthologs associated with diet-responsive eQTLs are enriched for GWAS genes associated with human metabolic traits, suggesting that context-responsive eQTLs with more complex regulatory effects are likely to explain GWAS hits that do not seem to overlap with standard eQTLs. Our results highlight the complexity of genetic regulatory effects and the potential of eQTLs with disease-relevant GxE interactions in enhancing the understanding of GWAS signals for human complex disease using nonhuman primate models.
Project description:Cancer is the most common disease around the world and colorectal cancer is the second most common cancer. The early diagnosis of colorectal cancer is difficult and relies on invasive diag-nostic tools such as colonoscopy and tissue biopsy. Other non-invasive techniques such as fecal occult blood screening test (FOBT) are less sensitive and accurate. The advantage of FOBT together with high throughput technology such as metabolomics could provide the advantages of non-invasive tool and the effectiveness of detecting novel colorectal cancer markers. In this way, this work focuses on the novelty of using FOBT as samples to perform metabolomics analysis and its application on colorectal cancer population.
Project description:This experiment was performed to compare and intend to acquire a genetic expression feature of signet ring cell carcinoma in colorectal cancer that is extremely rare histological type and also shows significantly worse prognosis compared with conventional histological type of the cancer.
