15 research outputs found
The emerging landscape of dynamic DNA methylation in early childhood
Background: DNA methylation has been found to associate with disease, aging and environmental exposure, but it is unknown how genome, environment and disease influence DNA methylation dynamics in childhood. Results: By analysing 538 paired DNA blood samples from children at birth and at 4-5 years old and 726 paired samples from children at 4 and 8 years old from four European birth cohorts using the Illumina Infinium Human Methylation 450 k chip, we have identified 14,150 consistent age-differential methylation sites (a-DMSs) at epigenome-wide significance of rho <1.14x10(-7). Genes with an increase in age-differential methylation were enriched in pathways related to 'development', and were more often located in bivalent transcription start site (TSS) regions, which can silence or activate expression of developmental genes. Genes with a decrease in age-differential methylation were involved in cell signalling, and enriched on H3K27ac, which can predict developmental state. Maternal smoking tended to decrease methylation levels at the identified da-DMSs. We also found 101 a-DMSs (0.71%) that were regulated by genetic variants using cis-differential Methylation Quantitative Trait Locus (cis-dMeQTL) mapping. Moreover, a-DMS-associated genes during early development were significantly more likely to be linked with disease. Conclusion: Our study provides new insights into the dynamic epigenetic landscape of the first 8 years of life.Peer reviewe
DNA methylation in childhood asthma : an epigenome-wide meta-analysis
Background DNA methylation profiles associated with childhood asthma might provide novel insights into disease pathogenesis. We did an epigenome-wide association study to assess methylation profiles associated with childhood asthma. Methods We did a large-scale epigenome-wide association study (EWAS) within the Mechanisms of the Development of ALLergy (MeDALL) project. We examined epigenome-wide methylation using Illumina Infinium Human Methylation450 BeadChips (450K) in whole blood in 207 children with asthma and 610 controls at age 4-5 years, and 185 children with asthma and 546 controls at age 8 years using a cross-sectional case-control design. After identification of differentially methylated CpG sites in the discovery analysis, we did a validation study in children (4-16 years; 247 cases and 2949 controls) from six additional European cohorts and meta-analysed the results. We next investigated whether replicated CpG sites in cord blood predict later asthma in 1316 children. We subsequently investigated cell-type-specific methylation of the identified CpG sites in eosinophils and respiratory epithelial cells and their related gene-expression signatures. We studied cell-type specificity of the asthma association of the replicated CpG sites in 455 respiratory epithelial cell samples, collected by nasal brushing of 16-year-old children as well as in DNA isolated from blood eosinophils (16 with asthma, eight controls [age 2-56 years]) and compared this with whole-blood DNA samples of 74 individuals with asthma and 93 controls (age 1-79 years). Whole-blood transcriptional profiles associated with replicated CpG sites were annotated using RNA-seq data of subsets of peripheral blood mononuclear cells sorted by fluorescence-activated cell sorting. Findings 27 methylated CpG sites were identified in the discovery analysis. 14 of these CpG sites were replicated and passed genome-wide significance (p Interpretation Reduced whole-blood DNA methylation at 14 CpG sites acquired after birth was strongly associated with childhood asthma. These CpG sites and their associated transcriptional profiles indicate activation of eosinophils and cytotoxic T cells in childhood asthma. Our findings merit further investigations of the role of epigenetics in a clinical context.Peer reviewe
The emerging landscape of dynamic DNA methylation in early childhood
BACKGROUND: DNA methylation has been found to associate with
disease, aging and environmental exposure, but it is unknown how
genome, environment and disease influence DNA methylation
dynamics in childhood. RESULTS: By analysing 538 paired DNA
blood samples from children at birth and at 4-5 years old and
726 paired samples from children at 4 and 8 years old from four
European birth cohorts using the Illumina Infinium Human
Methylation 450 k chip, we have identified 14,150 consistent
age-differential methylation sites (a-DMSs) at epigenome-wide
significance of p < 1.14 x 10-7. Genes with an increase in
age-differential methylation were enriched in pathways related
to 'development', and were more often located in bivalent
transcription start site (TSS) regions, which can silence or
activate expression of developmental genes. Genes with a
decrease in age-differential methylation were involved in cell
signalling, and enriched on H3K27ac, which can predict
developmental state. Maternal smoking tended to decrease
methylation levels at the identified da-DMSs. We also found 101
a-DMSs (0.71%) that were regulated by genetic variants using
cis-differential Methylation Quantitative Trait Locus
(cis-dMeQTL) mapping. Moreover, a-DMS-associated genes during
early development were significantly more likely to be linked
with disease. CONCLUSION: Our study provides new insights into
the dynamic epigenetic landscape of the first 8 years of life
Additional file 1: Tables S1-S10. of The emerging landscape of dynamic DNA methylation in early childhood
(DOCX 1279 kb
Additional file 5: of The emerging landscape of dynamic DNA methylation in early childhood
List of age differential Methylation Quantitative Trait Locus in early childhood (XLSX 336 kb
Additional file 5: of The emerging landscape of dynamic DNA methylation in early childhood
List of age differential Methylation Quantitative Trait Locus in early childhood (XLSX 336 kb
Additional file 4: of The emerging landscape of dynamic DNA methylation in early childhood
Pathway analysis of age-differential methylation sites by gene network. (XLSX 3782 kb
Additional file 3: of The emerging landscape of dynamic DNA methylation in early childhood
Age-differential methylation sites in early childhood (XLSX 2094 kb
Shared DNA methylation signatures in childhood allergy: The MeDALL study
Background: Differential DNA methylation associated with allergy might provide novel insights into the shared or unique etiology of asthma, rhinitis, and eczema. Objective: We sought to identify DNA methylation profiles associated with childhood allergy. Methods: Within the European Mechanisms of the Development of Allergy (MeDALL) consortium, we performed an epigenome-wide association study of whole blood DNA methylation by using a cross-sectional design. Allergy was defined as having symptoms from at least 1 allergic disease (asthma, rhinitis, or eczema) and positive serum-specific IgE to common aeroallergens. The discovery study included 219 case patients and 417 controls at age 4 years and 228 case patients and 593 controls at age 8 years from 3 birth cohorts, with replication analyses in 325 case patients and 1111 controls. We performed additional analyses on 21 replicated sites in 785 case patients and 2124 controls by allergic symptoms only from 8 cohorts, 3 of which were not previously included in analyses. Results: We identified 80 differentially methylated CpG sites that showed a 1% to 3% methylation difference in the discovery phase, of which 21 (including 5 novel CpG sites) passed genome-wide significance after meta-analysis. All 21 CpG sites were also significantly differentially methylated with allergic symptoms and shared between asthma, rhinitis, and eczema. The 21 CpG sites mapped to relevant genes, including ACOT7, LMAN3, and CLDN23. All 21 CpG sties were differently methylated in asthma in isolated eosinophils, and 10 were replicated in respiratory epithelium. Conclusion: Reduced whole blood DNA methylation at 21 CpG sites was significantly associated with childhood allergy. The findings provide novel insights into the shared molecular mechanisms underlying asthma, rhinitis, and eczema