High level of γH2AX phosphorylation in the cord-blood cells of large-for-gestational-age (LGA) newborns.

Newborns can experience adverse effects as a consequence of maternal or in utero exposure, altered growth of the fetus, or placental dysfunctions. Accurate characterization of gestational age allows monitoring of fetal growth, identification of deviations from the normal growth trajectory, and classification of babies as adapted, small, or large for gestational age (AGA, SGA, or LGA). The aim of this work was to evaluate nuclear and oxidative damage in umbilical cord-blood cells of newborns (sampled at birth), by applying the γH2AX assay and the fluorescent probe BODIPY581/591 C11, to detect DNA DSB and cell membrane oxidation, respectively. No statistically significant differences were observed in the proportion of oxidized cord-blood cells among the groups of newborns, although the LGA group showed the highest value. With regard to genome damage, elevated levels of γH2AX foci were detected in the cell nuclei from LGA newborns as compared to AGA or SGA babies, whose values did not differ from each other. Considering that the observed DNA damage, although still repairable, can represent a risk factor for obesity, metabolic diseases, or other pathologies, monitoring genome and cell integrity at birth can provide useful information for prevention of diseases later in life.

Role of oxidative stress, genome damage and DNA methylation as determinants of pathological conditions in the newborn: an overview from conception to early neonatal stage.

Increasing evidence suggests that early-life events can predispose the newborn to a variety of health issues in later life. In adverse pre- and perinatal conditions, oxidative stress appears to play an important role in the development of future pathological outcomes. From a molecular point of view, oxidative stress can result in genome damage and changes in DNA methylation that can in turn prime pathogenic mechanisms. Interestingly, both alterations have been related to a reciprocal regulation of oxidative stress. The aim of this review is to give a brief overview of the complex relationship linking oxidative stress to DNA damage and methylation and to go through the different sources of exposure that a neonate can encounter in utero or shortly after birth. In this context, the setup of methodologies to monitor the extent of oxidative stress, genomic damage and instability or the presence of altered methylation patterns contributes to the understanding on how the complex events occurring in early life can lead to either a healthy status or a pathological condition.