In Utero Life and Epigenetic Predisposition for Disease

Thornburg, Kent L.; Shannon, Jackilen; Thuillier, Philippe; Turker, Mitchell S.

doi:10.1016/b978-0-12-380864-6.00003-1

Cited by 77 publications

(61 citation statements)

References 98 publications

(112 reference statements)

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“…There is increasing evidence that "marked" regions of DNA can become "unmarked" under the influence of dietary nutrients. This gives hope for reversing propensities for metabolic disorders and other diseases that were acquired in the womb [101] . Experimental data in rodents and recent observations in humans suggest that epigenetic changes in regulatory and growth-related genes play a significant role in mediating the patho-physiological phenotypes derived from developmental programming [102,103] .…”

Section: Role Of Epigeneticsmentioning

confidence: 99%

Developmental programming of the metabolic syndrome - critical windows for intervention

Vickers

2011

WJG

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Metabolic disease results from a complex interaction of many factors, including genetic, physiological, behavioral and environmental influences. The recent rate at which these diseases have increased suggests that environmental and behavioral influences, rather than genetic causes, are fuelling the present epidemic. In this context, the developmental origins of health and disease hypothesis has highlighted the link between the periconceptual, fetal and early infant phases of life and the subsequent development of adult obesity and the metabolic syndrome. Although the mechanisms are yet to be fully elucidated, this programming was generally considered an irreversible change in developmental trajectory. Recent work in animal models suggests that developmental programming of metabolic disorders is potentially reversible by nutritional or targeted therapeutic interventions during the period of developmental plasticity. This review will discuss critical windows of developmental plasticity and possible avenues to ameliorate the development of postnatal metabolic disorders following an adverse early life environment.

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Section: Role Of Epigeneticsmentioning

confidence: 99%

Developmental programming of the metabolic syndrome - critical windows for intervention

Vickers

2011

WJG

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“…Although DNA methylation has traditionally been viewed as an epigenetic "silencing" mark, recent advances suggest that the impact of DNA methylation on gene expression depends more on the genomic location of the CpG site (7). An adverse intrauterine environment can modify placental epigenetic marks and gene expression profiles, resulting in fetal growth restraint (8)(9)(10). Differential patterns of placental and cord blood methylation and/or expression have been described in selected imprinted and nonimprinted genes (11,12) in heterogeneous populations, including preterm infants (11) and growth-restricted fetuses from pregnancies complicated by hypertension or preeclampsia (12).…”

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confidence: 99%

Placental and Cord Blood Methylation of Genes Involved in Energy Homeostasis: Association With Fetal Growth and Neonatal Body Composition

et al. 2016

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Low weight at birth is associated with subsequent susceptibility to diabetes. Epigenetic modulation is among the mechanisms potentially mediating this association. We performed a genome-wide DNA methylation analysis in placentas from term infants born appropriatefor-gestational-age (AGA) or small-for-gestational-age (SGA) to identify new genes related to fetal growth and neonatal body composition. Candidate genes were validated by bisulfite pyrosequencing (30 AGA, 21 SGA) and also analyzed in cord blood. Gene expression analyses were performed by RT-PCR. Neonatal body composition was assessed by dual X-ray absorptiometry at age 2 weeks. The ATG2B, NKX6.1, and SLC13A5 genes (respectively related to autophagy, b-cell development and function, and lipid metabolism) were hypermethylated in placenta and cord blood from SGA newborns, whereas GPR120 (related to free fatty acid regulation) was hypomethylated in placenta and hypermethylated in cord blood. Gene expression levels were opposite to methylation status, and both correlated with birth weight, circulating IGF-I, and total and abdominal fat at age 2 weeks. In conclusion, alterations in methylation and expression of genes involved in the regulation of energy homeostasis were found to relate to fetal growth and neonatal body composition and thus may be among the early mechanisms modulating later susceptibility to diabetes.

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“…В настоящее время представлены научные до-казательства того, что характер питания и опреде-ленные ингредиенты продуктов питания матери могут индуцировать эпигенетические изменения генома плода, детерминирующие развитие не-обратимых изменений его фенотипа [30,33,42]. Влияние питания матери на функционирование эпигенетических механизмов ребенка носит неод-нозначный характер.…”

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Вплив Екзогенних Факторів На Геномний Імпринтинг . 1. Вплив Дієти І Забезпеченості Мікронутрієнтами Матері На Геномний Імпринтинг Нащадків

Абатуров

Moroz

2021

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In Utero Life and Epigenetic Predisposition for Disease

Cited by 77 publications

References 98 publications

Developmental programming of the metabolic syndrome - critical windows for intervention

Developmental programming of the metabolic syndrome - critical windows for intervention

Placental and Cord Blood Methylation of Genes Involved in Energy Homeostasis: Association With Fetal Growth and Neonatal Body Composition

Вплив Екзогенних Факторів На Геномний Імпринтинг . 1. Вплив Дієти І Забезпеченості Мікронутрієнтами Матері На Геномний Імпринтинг Нащадків

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