Investigating trophoblast invasion and angiogenesis expression changes in a caloric deficient mouse model of fetal growth restriction

IF 2.5 3区生物学 Q3 REPRODUCTIVE BIOLOGY

Reproductive biology Pub Date : 2026-06-01 Epub Date: 2026-01-22 DOI:10.1016/j.repbio.2026.101179

James R. Bardill , Caitlin R. Eason , Holly Wood , Courtney Breckenfelder , Lauren T. Gallagher , Madison Crew , Anis Karimpour-Fard , Carmen C. Sucharov , Theresa L. Powell , Clyde J. Wright , S.Christopher Derderian

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引用次数: 0

Abstract

Fetal growth restriction (FGR) is a severe pregnancy complication often caused by placental insufficiency. Proper trophoblast invasion is essential for placental development and function, ensuring adequate nutrient and oxygen supply to the developing fetus. Dysregulation impairs placental perfusion, leading to FGR. This study uses a calorie-restricted mouse model to investigate genes/molecular mechanisms regulating trophoblast invasion across gestational timepoints. Pregnant mice received either a standard or 50 % calorie-restricted diet from E8.5. Placentas and invasion sites were analyzed at E10.5, E12.5, E14.5, E16.5, and E17.5. mRNA sequencing and RT/qPCR examined trophoblast invasion-related genes (Mmp2, Mmp9, Efna1, Rac1, Rras, Ascl2, Tfap2c, Prl7b1) and angiogenesis genes (Vegfa, Vegfb, Pdgf, Akt3). Immunohistochemistry of trophoblast cells (cytokeratin 8, CK8) and endothelial cell markers (endomucin, CD31, CCD105, VEGFR2) was performed. Statistical analysis used Student’s t-test. Caloric restriction significantly reduced fetal/placental weights from E12.5, with persistent growth restriction at E16.5, and E17.5. IHC at E17.5 showed reduced decidual depth, trophoblast invasion distance, and trophoblast quantity within the decidua. This impaired growth was accompanied by reduced expression of trophoblast invasion genes (Mmp2, Mmp9, Efna1, Rac1, Rras, Ascl2, Tfap2c, Prl7b1) in FGR placentas, with a reduction in CK8 trophoblast staining. Angiogenesis reduction in FGR was demonstrated with reduced Vegfa, Vegfb, and Akt3 and supported by reduced CD31, CD105, and VEGF2 endothelial cell markers A caloric-restriction mouse model replicates key FGR pathophysiology, including reduced fetal/placental growth, downregulation of trophoblast invasion genes, impaired trophoblast invasion into the decidua, and reduced placenta angiogenesis. These findings offer molecular insights into placental insufficiency that merits further exploration regarding FGR pathogenesis.

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研究滋养细胞侵袭和血管生成表达在胎儿生长受限的热量缺乏小鼠模型中的变化

胎儿生长受限（FGR）是一种严重的妊娠并发症，通常由胎盘功能不全引起。适当的滋养细胞侵袭对胎盘的发育和功能至关重要，确保发育中的胎儿有足够的营养和氧气供应。失调损害胎盘灌注，导致FGR。本研究使用限制热量的小鼠模型来研究在妊娠时间点调节滋养细胞侵袭的基因/分子机制。怀孕的小鼠从E8.5中获得标准或50% %卡路里限制饮食。在E10.5、E12.5、E14.5、E16.5和E17.5时分析胎盘和侵犯部位。mRNA测序和RT/qPCR检测滋养细胞侵袭相关基因（Mmp2、Mmp9、Efna1、Rac1、Rras、Ascl2、Tfap2c、Prl7b1）和血管生成基因（Vegfa、Vegfb、Pdgf、Akt3）。对滋养细胞（细胞角蛋白8，CK8）和内皮细胞标志物（内啡肽，CD31, CCD105, VEGFR2）进行免疫组化。统计分析采用学生t检验。从E12.5开始，热量限制显著降低了胎儿/胎盘重量，在E16.5和E17.5持续限制生长。E17.5时的免疫组化显示蜕膜深度、滋养细胞侵袭距离和蜕膜内滋养细胞数量减少。这种生长受损伴随着滋养层侵袭基因（Mmp2、Mmp9、Efna1、Rac1、Rras、Ascl2、Tfap2c、Prl7b1）在FGR胎盘中的表达减少，CK8滋养层染色减少。通过vegf、Vegfb和Akt3的减少，以及CD31、CD105和VEGF2内皮细胞标记物的减少，可以证明FGR中血管生成的减少。热量限制小鼠模型复制了FGR的关键病理生理，包括胎儿/胎盘生长减少，滋养细胞侵袭基因下调，滋养细胞侵袭蜕膜受损，胎盘血管生成减少。这些发现为胎盘功能不全提供了分子视角，值得进一步探索FGR的发病机制。

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来源期刊

Reproductive biology 生物-生殖生物学

CiteScore

3.90

自引率

0.00%

发文量

审稿时长

29 days

期刊介绍： An official journal of the Society for Biology of Reproduction and the Institute of Animal Reproduction and Food Research of Polish Academy of Sciences in Olsztyn, Poland. Reproductive Biology is an international, peer-reviewed journal covering all aspects of reproduction in vertebrates. The journal invites original research papers, short communications, review articles and commentaries dealing with reproductive physiology, endocrinology, immunology, molecular and cellular biology, receptor studies, animal breeding as well as andrology, embryology, infertility, assisted reproduction and contraception. Papers from both basic and clinical research will be considered.