In women at risk of gestational diabetes mellitus, a low-GI diet influences offspring birth weight, birth length, and arterial wall thickness in early childhood, but not adiposity or growth trajectory during the first year of life. This trial was registered at anzctr.org.au as ACTRN12610000681055.
Birth weight is associated with cardiovascular disease, with those at both ends of the spectrum at increased risk. However, birth weight is a crude surrogate of fetal growth. Measures of body composition may more accurately identify high risk infants. We aimed to determine whether aortic wall thickening, cardiac autonomic control, and cardiac structure/function differ in newborns with high or low body fatness compared to those with average body fatness. 189 healthy singleton term born neonates were recruited and stratified by body fat percentiles (sex and gestation-specific). Infants with low body fat had higher aortic intima-media thickness (43 µm (95% confidence interval (CI) 7, 78), p = 0.02), lower heart rate variability (log total power, −0.5 (95% CI −0.8, −0.1), p = 0.008), and thicker ventricular walls (posterior wall thickness, 3.1 mm (95% CI 1.6, 4.6), p < 0.001) compared to infants with average body fatness. Infants with high body fat showed no differences in aortic intima-media thickness (−2 µm (95% CI −37, 33), p = 0.91) or cardiac structure compared to average body fatness, although stroke volume (−0.3 mL/kg (95% CI −0.6, −0.0), p = 0.003) and heart rate variability were lower (log total power, −0.8 (95% CI −1.1, −0.5), p < 0.001). The non-linear association of body fatness with heart rate variability was independent of birth weight. Infants born with low or high body fat have altered markers of cardiovascular health. Assessment of body fatness alongside birth weight may assist in identifying high risk individuals.
Background Epigenetic aging is associated with higher risk of cardiovascular disease, cancer, and all-cause mortality and may be a mechanistic link between early-life exposures, such as maternal dietary characteristics during pregnancy, and risk of adult disease. Objectives We sought to determine the early-life risk factors for newborn epigenetic aging, specifically maternal dietary macronutrient intake, and whether epigenetic aging is associated with cardiovascular health markers in the newborn. Methods Epigenetic age acceleration of 169 newborns was measured from saliva using the Horvath age calculator. Maternal diet during pregnancy was assessed using food-frequency questionnaires. Results Newborns with positive age acceleration were more likely to be female and have greater body fatness. Maternal intakes of saturated fat [6.2 wk epigenetic age acceleration (95% CI: 1.0, 11.3) per 5% of energy; P = 0.02] and monounsaturated fat [12.4 wk (95% CI: 4.2, 20.5) per 5% of energy; P = 0.003] were associated with higher epigenetic age acceleration in the newborn. The strongest association of individual fatty acids were for palmitoleic acid (25.3 wk; 95% CI: 11.4, 39.2; P = 0.0004), oleic acid (2.2 wk; 95% CI: 0.8, 3.6; P = 0.002), and palmitic acid (2.9 wk; 95% CI: 1.0, 4.9; P = 0.004) per 1% of energy intake. Vitamin D supplementation was associated with lower epigenetic age acceleration (−8.1 wk; 95% CI: −14.5, −1.7; P = 0.01). Epigenetic age acceleration was associated with aortic intima-media thickness in preterm infants [1.0 µm (95% CI: 0.2, 1.8) per week of epigenetic age acceleration; P = 0.01], but not among those born at term (P = 0.78). Epigenetic age acceleration was not associated with heart rate variability in either preterm or term born infants (both P > 0.2). Conclusions This study provides evidence of maternal dietary characteristics that are associated with epigenetic aging in the offspring. Prospective intervention studies are required to determine whether such associations are causal.
Iron accumulation causes cell death and disrupts tissue functions, which necessitates chelation therapy to reduce iron overload. However, clinical utilization of deferoxamine (DFO), an iron chelator, has been documented to give rise to systemic adverse effects, including ocular toxicity. This study provided the pathogenic and molecular basis for DFO‐related retinopathy and identified retinal pigment epithelium (RPE) as the target tissue in DFO‐related retinopathy. Our modeling demonstrated the susceptibility of RPE to DFO compared with the neuroretina. Intriguingly, we established upregulation of hypoxia inducible factor (HIF) 2α and mitochondrial deficit as the most prominent pathogenesis underlying the RPE atrophy. Moreover, suppressing hyperactivity of HIF2α and preserving mitochondrial dysfunction by α‐ketoglutarate (AKG) protects the RPE against lesions both in vitro and in vivo. This supported our observation that AKG supplementation alleviates visual impairment in a patient undergoing DFO‐chelation therapy. Overall, our study established a significant role of iron deficiency in initiating DFO‐related RPE atrophy. Inhibiting HIF2α and rescuing mitochondrial function by AKG protect RPE cells and can potentially ameliorate patients' visual function.
Background:The FGF receptors (FGFRs) regulate pleiotropic (diverse) cellular responses. Results: Serine 779 phosphorylation of FGFR1 and 2 by PKC⑀ promotes maximal Ras/MAPK signaling and neuronal differentiation. Conclusion:The FGFRs quantitatively control signal transduction via receptor serine phosphorylation. Significance: Receptor tyrosine kinases couple to specific downstream signaling pathways via phosphoserine docking sites to control pleiotropic cellular responses.
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