In-utero exposure to maternal diabetes and DNA methylation alterations in the Next Generation birth cohort.

IF 4.4 2区医学 Q1 GENETICS & HEREDITY

Clinical Epigenetics Pub Date : 2025-10-03 DOI:10.1186/s13148-025-01972-3

Ola E Salama, Yash Rawal, Priscilla Irabor, Haziqa Kassim, Christy Pylypjuk, Elizabeth A C Sellers, Brandy A Wicklow, Meaghan J Jones

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Abstract

Introduction: The incidence of type 2 diabetes (T2D) in youth is increasing and in-utero exposure to maternal diabetes is a known risk factor, with higher risk associated with pregestational T2D exposure compared to gestational diabetes mellitus (GDM) exposure. We hypothesize this differential risk is reflected in DNA methylation (DNAm) changes induced by differential timing of in-utero exposure to maternal diabetes, and that exposure to diabetes throughout pregnancy (T2D) compared to exposure later in development (GDM), induces different DNAm signatures and different T2D risk to offspring. This study presents an epigenome-wide investigation of DNAm alterations associated with in-utero exposure to either maternal pregestational T2D or GDM, to determine if the timing of prenatal diabetes exposure differentially alters DNAm.

Methods: We performed an epigenome-wide analysis on cord blood from 99 newborns exposed to pregestational T2D, 70 newborns exposed to GDM, and 41 unexposed to diabetes in-utero from the Next Generation birth cohort. Associations were tested using multiple linear regression models while adjusting for sex, maternal age, BMI, smoking status, gestational age, cord blood cell type proportions and batch effects.

Results: We identified 27 differentially methylated sites associated with exposure to GDM, 27 sites associated with exposure to T2D, and 9 common sites associated with exposure to either GDM or T2D (adjusted p value < 0.05 and effect size estimate > 0.01). One site at CLDN15 and two unannotated sites were previously reported as associated with obesity. We also identified 87 differentially methylated regions (DMRs) associated with in-utero exposure to GDM and 69 DMRs associated with in-utero exposure to T2D. We identified 23 DMR sites that were previously associated with obesity, three with T2D and five with in-utero exposure to GDM. Furthermore, we identified six CpG sites in the PTPRN2 gene, a gene previously associated with DNAm differences in blood of youth with T2D from the same population.

Conclusion: Our findings support that in-utero exposure to maternal diabetes is associated with DNAm alterations in offspring. Moreover, the timing of maternal diabetes in-utero exposure (GDM or T2D) produces overlapping but distinct DNAm patterns, suggesting that the window of exposure to maternal diabetes produces different molecular modifications and may reflect, at least in part, the difference in risk for youth-onset T2D in offspring. We also identified sites in this study that have been previously associated with T2D or obesity, which may serve as potential early-life biomarkers of exposure and/or risk, warranting further investigation in longitudinal studies.

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在下一代出生队列中，子宫内暴露于母体糖尿病和DNA甲基化改变

2型糖尿病（T2D）在青少年中的发病率正在增加，宫内暴露于母体糖尿病是一个已知的危险因素，与妊娠期糖尿病（GDM）暴露相比，妊娠期暴露于T2D的风险更高。我们假设这种差异风险反映在子宫内暴露于母体糖尿病的不同时间所引起的DNA甲基化（DNAm）变化上，并且与发育后期暴露（GDM）相比，妊娠期间暴露于糖尿病（T2D）会诱导不同的DNAm特征和后代不同的T2D风险。本研究提出了一项全表观基因组范围的调查，研究DNAm改变与母体妊娠期T2D或GDM在子宫内暴露相关，以确定产前糖尿病暴露的时间是否会改变DNAm。方法：我们对来自下一代出生队列的99名妊娠期接触T2D的新生儿、70名妊娠期接触GDM的新生儿和41名子宫内未接触糖尿病的新生儿的脐带血进行了全表观基因组分析。在调整性别、母亲年龄、BMI、吸烟状况、胎龄、脐带血类型比例和批量效应的同时，使用多元线性回归模型检验相关性。结果：我们确定了27个与GDM暴露相关的差异甲基化位点，27个与T2D暴露相关的位点，以及9个与GDM或T2D暴露相关的常见位点（调整p值0.01）。CLDN15的一个位点和两个未注释的位点先前被报道与肥胖相关。我们还确定了87个差异甲基化区域（DMRs）与子宫内暴露于GDM相关，69个DMRs与子宫内暴露于T2D相关。我们确定了23个与肥胖有关的DMR位点，3个与T2D有关，5个与子宫内暴露于GDM有关。此外，我们在PTPRN2基因中发现了6个CpG位点，该基因先前与来自同一人群的T2D青年血液中的dna差异有关。结论：我们的研究结果支持子宫内暴露于母体糖尿病与后代dna改变有关。此外，母体糖尿病宫内暴露（GDM或T2D）的时间产生重叠但不同的DNAm模式，表明母体糖尿病暴露窗口产生不同的分子修饰，并可能至少部分反映后代年轻发病T2D风险的差异。我们还在本研究中确定了先前与T2D或肥胖相关的位点，这些位点可能作为潜在的早期暴露和/或风险的生物标志物，值得在纵向研究中进一步调查。

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来源期刊

Clinical Epigenetics ONCOLOGY-

自引率

5.30%

发文量

150

期刊介绍： Clinical Epigenetics, the official journal of the Clinical Epigenetics Society, is an open access, peer-reviewed journal that encompasses all aspects of epigenetic principles and mechanisms in relation to human disease, diagnosis and therapy. Clinical trials and research in disease model organisms are particularly welcome.