RESUMO
Aim: Promoter methylation of LINE-1 may be affected by prematurity, but there is little evidence in the literature.Materials & methods: Blood from premature and full-term neonates on days 0, 5, 30 and 90 was analyzed for DNA methylation percentage in a promoter region of the LINE-1, after bisulfite conversion and pyrosequencing.Results: Premature infants, as a whole, showed significantly lower methylation percentage at birth, but this difference diminished over time. However, the subgroup of extremely premature (<28 weeks gestational age) had higher methylation percentages, similar to full-term newborns.Conclusion: This research underscores the critical role of prematurity on the methylation pattern of LINE-1. These findings underline the complexity of epigenetic regulation in prematurity and emphasize the need for further studies.
Premature birth can have significant effects on a baby's development and long-term health. This study investigates how being born prematurely affects a process called DNA methylation, which can influence how genes are turned on or off. Specifically, we examined the LINE-1 promoter, a frequently occurring region of DNA known for its role in regulating gene activity.We collected blood samples from both premature and full-term newborns at birth and at several points in the early months of life. Our findings showed that premature babies have lower levels of LINE-1 promoter methylation at birth compared with full-term babies. These differences in methylation could possibly affect the babies' development and health as they grow.Our research highlights the need for continued study in this area to explore how these epigenetic changes impact long-term health and to develop strategies to mitigate these effects.
RESUMO
Aim: To describe NR3C1 exon-1F methylation and cortisol levels in newborns. Materials & methods: Preterm ≤1500 g and full-term infants were included. Samples were collected at birth and at days 5, 30 and 90 (or at discharge). Results: 46 preterm and 49 full-term infants were included. Methylation was stable over time in full-term infants (p = 0.3116) but decreased in preterm infants (p = 0.0241). Preterm infants had higher cortisol levels on the fifth day, while full-term infants showed increasing levels (p = 0.0177) over time. Conclusion: Hypermethylated sites in NR3C1 at birth and higher cortisol levels on day 5 suggest that prematurity, reflecting prenatal stress, affects the epigenome. Methylation decrease over time in preterm infants suggests that postnatal factors may modify the epigenome, but their role needs to be clarified.
We investigated the methylation of a gene, NR3C1 exon-1F, and cortisol levels in newborns. DNA methylation is a biochemical process that can modify gene activity. In the case of this gene, higher methylation might be associated with higher cortisol levels. We studied 46 preterm infants (born weighing 1500 g or less) and 49 full-term infants. Our results revealed that the preterm infants had hypermethylation at birth and higher cortisol levels on day 5, but decreasing methylation and stable cortisol levels over time. Meanwhile, methylation remained stable and cortisol levels increased in full-term babies with time. These unexpected results suggest that prematurity can be associated with prenatal epigenetic changes in the NR3C1 gene, but postnatal factors may induce further modifications. More research is needed to understand these findings better.