Elucidating cytosine modification differences between human populations can enhance our understanding of ethnic specificity in complex traits. In this study, cytosine modification levels in 133 HapMap lymphoblastoid cell lines derived from individuals of European or African ancestry were profiled using the Illumina HumanMethylation450 BeadChip. Approximately 13% of the analyzed CpG sites showed differential modification between the two populations at a false discovery rate of 1%. The CpG sites with greater modification levels in European descent were enriched in the proximal regulatory regions, while those greater in African descent were biased toward gene bodies. More than half of the detected population-specific cytosine modifications could be explained primarily by local genetic variation. In addition, a substantial proportion of local modification quantitative trait loci exhibited population-specific effects, suggesting that genetic epistasis and/or genotype · environment interactions could be common. Distinct correlations were observed between gene expression levels and cytosine modifications in proximal regions and gene bodies, suggesting epigenetic regulation of interindividual expression variation. Furthermore, quantitative trait loci associated with population-specific modifications can be colocalized with expression quantitative trait loci and single nucleotide polymorphisms previously identified for complex traits with known racial disparities. Our findings revealed abundant population-specific cytosine modifications and the underlying genetic basis, as well as the relatively independent contribution of genetic and epigenetic variations to population differences in gene expression.
DNA methylation is a covalent cytosine modification that occurs at the C-5 position of cytosines at CpG dinucleotides and is dispersed unevenly over the genome (Bird 2002). Interindividual variation in cytosine modifications can be affected by both the stable underlying genetic sequence and dynamic environmental influences (Flanagan et al. 2006;Bock et al. 2008). Cytosine modifications are known to play an important role in the regulation of gene expression, with promoter methylation acting to silence gene expression (Grewal and Moazed 2003). Previous studies of human variation in gene expression have shown that differential gene expression can influence a variety of complex traits, including susceptibilities to common diseases and variation in drug response (Schadt et al. 2005;Emilsson et al. 2008;Cookson et al. 2009).The lymphoblastoid cell lines (LCLs) from the International HapMap Project (HapMap 2003;HapMap 2005) have been used recently for investigating within-and betweenpopulation differences in promoter methylation (Bell et al. 2011;Fraser et al. 2012). Furthermore, previous work from our group and others has demonstrated that common genetic variants and microRNAs contributed to the variation in gene expression between LCLs derived from individuals of We reasoned that an evaluation of the natural variation ...
Interindividual variation in cytosine modifications could contribute to heterogeneity in disease risks and other complex traits. We assessed the genetic architecture of cytosine modifications at 283,540 CpG sites in lymphoblastoid cell lines (LCLs) derived from independent samples of European and African descent. Our study suggests that cytosine modification variation was primarily controlled in local by single major modification quantitative trait locus (mQTL) and additional minor loci. Local genetic epistasis was detectable for a small proportion of CpG sites, which were enriched by more than 9-fold for CpG sites mapped to population-specific mQTL. Genetically dependent CpG sites whose modification levels negatively (repressive sites) or positively (facilitative sites) correlated with gene expression levels significantly co-localized with transcription factor binding, with the repressive sites predominantly associated with active promoters whereas the facilitative sites rarely at active promoters. Genetically independent repressive or facilitative sites preferentially modulated gene expression variation by influencing local chromatin accessibility, with the facilitative sites primarily antagonizing H3K27me3 and H3K9me3 deposition. In comparison with expression quantitative trait loci (eQTL), mQTL detected from LCLs were enriched in associations for a broader range of disease categories including chronic inflammatory, autoimmune and psychiatric disorders, suggesting that cytosine modification variation, while possesses a degree of cell linage specificity, is more stably inherited over development than gene expression variation. About 11% of unique single-nucleotide polymorphisms reported in the Genome-Wide Association Study Catalog were annotated, 78% as mQTL and 31% as eQTL in LCLs, which covered 37% of the investigated diseases/traits and provided insights to the biological mechanisms.
Background: MicroRNA-138 deregulation is a common event in cancer. Results: Our study describes a microRNA regulatory module consisting of tumor suppressor miR-138 and proto-oncogene FOSL1.
Conclusion:The deregulation of miR-138-FOSL1 regulatory module may play an important role in cancer initiation and progression. Significance: Our results suggest that microRNAs target both canonical and non-canonical targeting sites located in all areas of mRNA molecules.
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