Epigenetic modulation of the IGF2/H19imprinted domain in human embryonic and extra-embryonic compartments and its possible role in fetal growth restriction

Genomic imprinting, resulting in parent-of-origin-dependent gene expression, is mainly achieved by DNA methylation. IGF2and H19, belonging to the same cluster of imprinted genes and regulated by ICR1, DMR2 and H19promoter elements, play a major role in fetal/placental growth. Using quantitative approaches, we explored the epigenetic modulation of IGF2/H19during human development in 60 normal and 66 idiopathic IUGR (Intrauterine Growth Restriction) pregnancies, studying embryonic (cord blood) and extraembryonic (placenta and umbilical cord) tissues. We found ICR1 normal methylation levels (~50%) and H19 promoter/DMR2 hypomethylation in extra-embryonic tissues. In contrast, in embryonic samples the three loci displayed normal methylation values comparable to those in postnatal blood. This feature is stably maintained throughout gestation and does not vary in IUGR cases. We reported asymmetric allelic expression of H19and IGF2 as a common feature in pre- and post-natal tissues, independent of H19 promoter and DMR2 methylation levels. In addition, we excluded in IUGR posttranscriptional IGF2 interference possibly related to miRNA 483-3p (IGF2, intron 2) expression defects. Through LINE1 methylation analysis, we observed a methylation gradient with increasing methylation from pre- to post-natal life. The involvement of UPD (Uniparental Disomy) in IUGR aetiology was excluded. Our data indicate that: i) ICR1 3 methylation status is a necessary and sufficient condition to drive the imprinting of IGF2and H19present in embryonic as well as in extra-embryonic tissues; ii) hypomethylation of H19 promoter and DMR2 does not influence the expression pattern of IGF2and H19; iii) there is a gradient of global methylation, increasing from extra-embryonic to embryonic and adult tissues. Finally, because of placental hypomethylation, cautions should be exercised in diagnosis of imprinting diseases using chorionic villi.