暴露于妊娠糖尿病会丰富人类羊水中免疫相关转录组和甲基化组的途径。

Exposure to Gestational Diabetes Enriches Immune-Related Pathways in the Transcriptome and Methylome of Human Amniocytes.

机构信息

Division of Endocrinology and Diabetes, Children's Hospital of Philadelphia, Philadelphia, Pennsylvania.

Department of Pediatrics, Perelman School of Medicine, University of Pennsylvania, Philadelphia, Pennsylvania.

出版信息

J Clin Endocrinol Metab. 2020 Oct 1;105(10):3250-64. doi: 10.1210/clinem/dgaa466.

DOI:10.1210/clinem/dgaa466

PMID:32687192

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7451504/

Abstract

CONTEXT

Gestational diabetes (GDM) has profound effects on the intrauterine metabolic milieu and is linked to obesity and diabetes in offspring, but the mechanisms driving these effects remain largely unknown. Alterations in DNA methylation and gene expression in amniocytes exposed to GDM in utero represent a potential mechanism leading to metabolic dysfunction later in life.

OBJECTIVE

To profile changes in genome-wide DNA methylation and expression in human amniocytes exposed to GDM.

DESIGN

A nested case-control study (n = 14 pairs) was performed in amniocytes matched for offspring sex, maternal race/ethnicity, maternal age, gestational age at amniocentesis, and gestational age at birth. Sex-specific genome-wide DNA methylation analysis and RNA-sequencing were completed and differentially methylated regions (DMRs) and gene expression changes were identified. Ingenuity pathway analysis identified biologically relevant pathways enriched after GDM exposure. In silico high-throughput chromosome conformation capture (Hi-C) analysis identified potential chromatin interactions with DMRs.

RESULTS

Expression of interferon-stimulated genes was increased in GDM amniocytes, accounting for 6 of the top 10 altered genes (q < 0.05). Enriched biological pathways in GDM amniocytes included pathways involving inflammation, the interferon response, fatty liver disease, monogenic diabetes, and atherosclerosis. Forty-two DMRs were identified in male GDM-exposed amniocytes and 20 in female amniocyte analysis (q < 0.05). Hi-C analysis identified interactions between DMRs and 11 genes with significant expression changes in male amniocytes and 9 in female amniocytes (P < .05).

CONCLUSION

In a unique repository of human amniocytes exposed to GDM in utero, transcriptome analysis identified enrichment of inflammation and interferon-related pathways and novel DMRs with potential distal regulatory functions.

摘要

背景

妊娠期糖尿病（GDM）对宫内代谢环境有深远影响，并与后代的肥胖和糖尿病有关，但导致这些影响的机制在很大程度上仍不清楚。在宫内暴露于 GDM 的羊水中，DNA 甲基化和基因表达的改变代表了导致生命后期代谢功能障碍的潜在机制。

目的

分析在宫内暴露于 GDM 的人类羊水中全基因组 DNA 甲基化和表达的变化。

设计

对羊水中的胎儿细胞进行了嵌套病例对照研究（n=14 对），这些细胞根据后代的性别、母亲的种族/民族、母亲的年龄、羊膜穿刺术时的妊娠周数和出生时的妊娠周数进行匹配。完成了性别的全基因组 DNA 甲基化分析和 RNA 测序，并确定了差异甲基化区域（DMR）和基因表达的变化。通过生物途径分析鉴定了 GDM 暴露后富含的生物学相关途径。在体高分辨率染色体构象捕获（Hi-C）分析中鉴定了与 DMR 相关的潜在染色质相互作用。

结果

GDM 胎儿细胞中干扰素刺激基因的表达增加，占前 10 个改变基因中的 6 个（q<0.05）。GDM 胎儿细胞中富集的生物学途径包括涉及炎症、干扰素反应、脂肪肝疾病、单基因糖尿病和动脉粥样硬化的途径。在男性 GDM 暴露的胎儿细胞中鉴定出 42 个 DMR，在女性胎儿细胞中鉴定出 20 个 DMR（q<0.05）。Hi-C 分析确定了男性胎儿细胞中 11 个基因的 DMR 之间的相互作用和 9 个基因的相互作用，这些基因的表达在女性胎儿细胞中发生了显著变化（P<0.05）。

结论

在一个独特的人类羊水中 GDM 暴露的储存库中，转录组分析鉴定出了炎症和干扰素相关途径的富集以及具有潜在远端调节功能的新 DMR。

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