Abnormal fatty acid metabolism and availability are landmarks of metabolic diseases, which in turn are associated with aberrant DNA methylation profiles. To understand the role of fatty acids in disease epigenetics, we sought DNA methylation profiles specifically induced by arachidonic (AA) or oleic acid (OA) in cultured cells and compared those with published profiles of normal and diseased tissues. THP-1 monocytes were stimulated with AA or OA and analyzed using Infinium HumanMethylation450 BeadChip (Illumina) and Human Exon 1.0 ST array (Affymetrix). Data were corroborated in mouse embryonic fibroblasts. Comparisons with publicly available data were conducted by standard bioinformatics. AA and OA elicited a complex response marked by a general DNA hypermethylation and hypomethylation in the 1-200 μM range, respectively, with a maximal differential response at the 100 μM dose. The divergent response to AA and OA was prominent within the gene body of target genes, where it correlated positively with transcription. AA-induced DNA methylation profiles were similar to the corresponding profiles described for palmitic acid, atherosclerosis, diabetes, obesity, and autism, but relatively dissimilar from OA-induced profiles. Furthermore, human atherosclerosis grade-associated DNA methylation profiles were significantly enriched in AA-induced profiles. Biochemical evidence pointed to β-oxidation, PPAR-α, and sirtuin 1 as important mediators of AA-induced DNA methylation changes. In conclusion, AA and OA exert distinct effects on the DNA methylome. The observation that AA may contribute to shape the epigenome of important metabolic diseases, supports and expands current diet-based therapeutic and preventive efforts.
Alterations in birth weight impact postnatal outcome and adult metabolic health. Therefore, fetal growth regulation is crucial for preventing chronic metabolic diseases. Leptin has been suggested to play an important role in placental and fetal growth, albeit its specific mechanisms of action have not been elucidated. The aim of this study was to analyze leptin concentrations in placenta, cord blood, and maternal blood of SGA, AGA, and LGA (small, adequate and large for gestational age, respectively) newborns, as well as placental leptin receptor (LEPRa and LEPRb) protein expression. We performed a cross-sectional comparative study in 3 groups of healthy mothers and their term newborns at delivery (SGA, AGA, and LGA, n=20 per group). Placental, maternal blood, and cord blood leptin content were measured by ELISA. Placental LEPRa and LEPRb protein expression were determined by Western Blot. Maternal leptin concentrations correlated positively with maternal weight before and at the end of gestation, without differences between groups. Cord leptin is higher in LGA and lower in SGA, whereas placental leptin is higher in SGA. Placental leptin was inversely correlated with placental weight, independently from maternal weight and gestational age. Both LEPRa and LEPRb expression are lower in SGA, while LEPRa positively correlated with placental weight and birthweight. The current findings indicate that placental leptin and its receptors are differentially expressed in SGA, AGA, and LGA newborns. We suggest that placental leptin and LEPR protein expression may influence placental growth and thus, birth weight.
We interpreted these findings to indicate that diminished body weight in newborns induce different adaptive signals, some of them mediated by IGF-1/IGFBP-3, ghrelin or by IGFBP-1. This regulation is congruent with the proposed role of ghrelin to adaptation to under-nutrition favouring lipid accumulation. CONCyTEG grant number 05-16-K117-028.
Pediatrics and Neonatology (2019) 60, 564e569 than neonates with a faecal sIgA level increment 0.45 mg/dl. No adverse effects were found after probiotics use. Conclusions: No difference between strains of probiotics used was found on NEC incidence or in the increase of faecal sIgA levels. Faecal sIgA levels were positively related to gestational age and body weight in very low preterm infants. ClinicalTrials.gov/NCT02245815.
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