AI Article Synopsis
- A complex interplay of epigenetic factors governs the monoallelic expression of about 1% of genes in humans, known as genomic imprinting, which can impact fetal development if disrupted.
- In a study comparing normal placentas to those with severe growth restrictions, differential DNA methylation was found, with growth-restricted placentas showing a trend towards hypermethylation, particularly in introns without common sequence features.
- The research indicates that changes in methylation patterns occur broadly across genomic regions in growth-restricted placentas, emphasizing that observed patterns may relate more to gene length rather than specific biological significance.
Article Abstract
A complex network of epigenetic factors participates in regulating the monoallelic expression of a small subset of genes (~1%) in the human genome. This phenomenon goes under the definition of genomic imprinting, a parent-of-origin effect that, when altered during early embryogenesis, may influence fetal development into adulthood. Pertubations in genomic imprinting have been associated with placental and fetal growth restrictions. We analyzed the differential DNA methylation of all known imprinted genes on 10 appropriate-for-gestational-age, clinically normal, placentas and 7 severe intrauterine growth-restricted placentas. Samples were pooled according to the diagnosis and analyzed by methylated DNA immunoprecipitation (MeDIP) on a tiling microarray platform. The distribution of the differentially methylated regions (DMRs) identified in growth-restricted placentas showed a slight tendency toward hypermethylation. Imprinted genes not expressed in placenta showed a unique DMR profile with the fewest hyper- and hypomethylated DMRs. Promoter and CpG island DMRs were sporadic and randomly distributed. The vast majority of DMR identified (~99%) were mapped in introns, showing no common sequence features. Also, by using the more advanced array data mining softwares, no significant patterns emerged. In contrast, differential methylation showed a highly significant correlation with gene length. Overall these data suggest that differential methylation changes in growth-restricted placentas occur throughout the genomic regions, encompassing genes actively expressed in the placenta. These findings warrant caution in interpreting the significance of genes carrying clustered DMRs because the distribution of DMRs in a gene may be attributed as a function of its length rather than as a specific biological role.
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| http://dx.doi.org/10.1177/1933719111404611 | DOI Listing |
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