Ionel Sandovici, Olatejumoye Knee, Jorge Lopez-Tello, Norman Shreeve, Abigail L Fowden, Amanda N Sferruzzi-Perri, Miguel Constância
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引用次数: 0
摘要
胎盘是母体和胎儿之间的守门人,通过调整其结构和功能来支持胎儿的最佳生长。目前还缺乏探索胎盘适应性以支持遗传性矮小胎儿发育的研究。在这里,我们利用一种通过在上胚层中缺失胰岛素样生长因子2(Igf2)而导致胎儿生长受损的小鼠模型,评估了妊娠晚期胎盘的营养传递和脐动脉(UA)血流。在胚胎发育到第 15.5 天时,我们观察到葡萄糖和 A 系统氨基酸(通过使用 3H-MeG 和 14C-MeAIB)的跨胎盘通量下降,与胎儿大小的减小成正比,而脐动脉血流正常。然而,在E18.5时,两种示踪剂的跨胎盘通量都不成比例地减少,同时伴有UA血流减弱。雌性胎儿的胎儿-胎盘生长和营养传递受到的影响更大。因此,降低胎儿遗传生长需求会损害胎盘血流和营养运输的适应性,而这种适应性通常支持胎儿在妊娠晚期的快速生长。这些发现对我们理解胎儿生长受限妊娠的病理生理学具有重要意义。
A genetically small fetus impairs placental adaptations near term.
The placenta is a gatekeeper between the mother and fetus, adapting its structure and functions to support optimal fetal growth. Studies exploring adaptations of placentae that support the development of genetically small fetuses are lacking. Here, using a mouse model of impaired fetal growth, achieved by deleting insulin-like growth factor 2 (Igf2) in the epiblast, we assessed placental nutrient transfer and umbilical artery (UA) blood flow during late gestation. At embryonic day (E) 15.5, we observed a decline in the trans-placental flux of glucose and system A amino acids (by using 3H-MeG and 14C-MeAIB), proportionate to the diminished fetal size, whereas UA blood flow was normal. However, at E18.5, the trans-placental flux of both tracers was disproportionately decreased and accompanied by blunted UA blood flow. Feto-placental growth and nutrient transfer were more impaired in female conceptuses. Thus, reducing the fetal genetic demand for growth impairs the adaptations in placental blood flow and nutrient transport that normally support the fast fetal growth during late gestation. These findings have important implications for our understanding of the pathophysiology of pregnancies afflicted by fetal growth restriction.
期刊介绍:
Disease Models & Mechanisms (DMM) is an online Open Access journal focusing on the use of model systems to better understand, diagnose and treat human disease.