Advances in understanding the molecular causes of diabetes-induced birth defects.

Mary R Loeken
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引用次数: 103

Abstract

Objective: To review the current understanding of the molecular causes of birth defects resulting from diabetic pregnancy, with a focus on neural tube defects.

Methods: A mouse model of diabetic pregnancy is described, in which embryo gene expression associated with neural tube defects is examined. Chemical, physiologic, or genetic manipulations are employed to elucidate critical pathways affected by increased glucose metabolism, and how abnormal gene expression disrupts neural tube closure.

Results: Increased glucose delivery to embryos, or activation of pathways that are stimulated by high glucose, such as the hexosamine biosynthetic pathway or hypoxia, increase oxidative stress in embryos, inhibit expression of Pax3, a gene that encodes a transcription factor that is required for neural tube closure, and increase neural tube defects. Conversely, blocking these pathways, or providing the antioxidants, reduced glutathione or vitamin E, suppress the adverse effects of excess glucose. Pax3 decreases steady-state levels of the p53 tumor-suppressor protein, such that when Pax3 is deficient, p53 protein increases, leading to increased neuroepithelial apoptosis prior to completion of neural tube closure. Embryos that lack both functional Pax3 protein and p53 do not display neuroepithelial apoptosis or neural tube defects.

Conclusions: Excess glucose metabolism by embryos resulting from maternal hyperglycemia disturbs a complex network of biochemical pathways, leading to oxidative stress. Oxidative stress inhibits expression of genes, such as Pax3, which control essential developmental processes. Pax3 protein is required during neural tube development to suppress p53-dependent cell death and consequent abortion of neural tube closure, but is not required to control expression of genes that direct neural tube closure. Impaired embryo gene expression resulting from oxidative stress, and consequent apoptosis or disturbed organogenesis, may be a general mechanism to explain diabetic embryopathy.

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糖尿病所致出生缺陷的分子成因研究进展。
目的:综述目前对糖尿病妊娠所致出生缺陷的分子原因的认识,重点介绍神经管缺陷。方法:建立糖尿病妊娠小鼠模型,检测胚胎与神经管缺陷相关的基因表达。利用化学、生理或基因操作来阐明受葡萄糖代谢增加影响的关键途径,以及异常基因表达如何破坏神经管闭合。结果:胚胎的葡萄糖输送增加,或高葡萄糖刺激的途径(如已糖胺生物合成途径或缺氧)的激活,增加胚胎的氧化应激,抑制Pax3基因的表达,Pax3基因编码神经管闭合所需的转录因子,增加神经管缺陷。相反,阻断这些途径,或提供抗氧化剂,还原性谷胱甘肽或维生素E,可以抑制过量葡萄糖的不利影响。Pax3降低p53肿瘤抑制蛋白的稳态水平,因此当Pax3缺乏时,p53蛋白增加,导致神经管闭合完成前神经上皮细胞凋亡增加。缺乏功能性Pax3蛋白和p53的胚胎不会表现出神经上皮细胞凋亡或神经管缺陷。结论:母体高血糖引起的胚胎葡萄糖代谢过剩扰乱了复杂的生化通路网络,导致氧化应激。氧化应激抑制基因的表达,如Pax3,控制重要的发育过程。在神经管发育过程中,Pax3蛋白是抑制p53依赖性细胞死亡和神经管闭合流产所必需的,但不需要控制指导神经管闭合的基因表达。氧化应激导致的胚胎基因表达受损,以及随之而来的细胞凋亡或器官发生紊乱,可能是糖尿病胚胎病的一般机制。
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