Metabolomics,Unknown,Transcriptomics,Genomics,Proteomics

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In utero caffeine exposure alters DNA methylation patterns in adult hearts

ABSTRACT: Our previous research demonstrated that caffeine exposure on embryonic day (E) 8.5 increased body weight, altered cardiac morphology and function in adult male mice. However, these adverse effects were not observed in adenosine A1 receptor knockout (A1AR-/-) mice. Our hypothesis is that A1AR action mediates changes in DNA methylation patterns in mice exposed in utero to caffeine and that these changes in methylation lead to long-term effects in adult mice. To test this hypothesis, DNA Methylation 2.1M Deluxe Promoter Arrays (NimbleGen) were used to examine the methylation patterns of DNA isolated from adult left ventricles of the A1AR knockout line exposed to 20 mg/kg caffeine at E8.5 in utero. In A1AR+/+ mice, 4,896 hypermethylated and 2,823 hypomethylated regions were discovered in the left ventricles of the caffeine group compared to the normal saline group. In A1AR-/- mice, 1,024 hypermethylated and 1,757 hypomethylated regions were found in the caffeine group. The differentially methylated regions (DMRs) in the caffeine treated A1AR+/+ hearts mapped to 6,148 genes, 4,853 promoters, 4,111 primary transcripts, 816 CpG islands, and 98 miRNAs. Functional annotation clustering of genes revealed that many genes were involved in the development of hypertrophic cardiomyopathy and other heart diseases, which may explain our earlier findings of thickening of the left ventricular wall after in utero caffeine treatment. The methylation changes in several DMRs, mef2c, ins2, tnnt2, and myh6, were validated by bisulfite sequencing. In summary, in utero caffeine exposure caused DNA methylation changes in adult left ventricles and that these changes may be mediated by A1ARs. Pregnant mice were injected at embryonic day 8.5 with 0.9% NaCl (vehicle) or 20 mg/kg caffeine in vehicle i.p. Pups were born and raised until 8-10 weeks of age. Analysis was performed on the following groups vehicle A1AR+/+ (veh+/+), vehicle A1AR-/- (veh-/-), caffeine A1AR+/+ (caff+/+), and caffeine A1AR-/- (caff-/-). Genomic DNA from left ventricles of adult male mice was used. Two biological replicates were measured for each group.

ORGANISM(S): Mus musculus

SUBMITTER: Xiefan Fang

PROVIDER: E-GEOD-43030 | biostudies-arrayexpress |

REPOSITORIES: biostudies-arrayexpress

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Project description:Purpose: This study aimed to identify differentially expressed genes including alternative splice variants in embryonic ventricles following in utero caffeine treatment. Methods: Pregnant CD-1 mice were injected with 20 mg/kg of caffeine or vehicle control daily from embryonic day (E) 6.5-9.5. On E10.5, total RNA was isolated from embryonic ventricles and used for transcriptomic RNA sequencing with Illumina HiSeq 2000 (1X75bp). RNA-seq reads were aligned to the mouse genome (build mm10) with the Tophat for Illumina tool in the PSU galaxy platform. Counting and annotation of RNA-seq reads as well as alternative splicing analysis were performed with Partek Genomics Suite version 6.11. Differential expression of gene and transcript reads between treatments was analyzed with R package EdgeR. Genes/transcripts with false discovery rate (FDR) less than 0.05 and absolute fold change greater than 1.5 were considered as significant. Differentially expressed genes were defined as genes with altered expression at either gene or transcript level. Unique differentially expressed genes were identified by combining the results from annotations with the RefSeq Transcripts (2013-05-10) or Ensembl Transcripts release 71 databases. Results: Differential expression analysis revealed that 59 genes and 451 transcripts were significantly up-regulated, and 65 genes and 398 transcripts were down-regulated by prenatal caffeine treatment (fold change >1.5 or <-1.5; p-value with FDR<0.05). In total, 900 unique genes were identified to have altered expression either at the gene or transcription level. Further analysis with Partek GS revealed that 183 genes had abnormal alternative splicing at the exon level after in utero caffeine treatment. Conclusions: In utero caffeine exposure caused gene expression changes in embryonic ventricles and these changes may lead to long-term effects on cardiac morphology and function. mRNA profiles in E10.5 heart ventricles treated with caffeine were generated by deep sequencing (n=2 for vehicle, n=3 for caffeine), using Illumina HiSeq 2000.

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In utero caffeine exposure alters DNA methylation patterns in adult hearts

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