FGF10 Signaling Enhances Epicardial Cell Expansion during Neonatal Mouse Heart Repair.

Nicole Rubin, Ali Darehzereshki, Saverio Bellusci, Vesa Kaartinen, Ching Ling Lien
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Abstract

Unlike zebrafish and newt hearts, mammalian hearts have limited capacity to regenerate. Upon injury or disease, the adult mammalian hearts form a fibrotic scar. Recently, it was shown that neonatal mouse hearts can regenerate similarly to adult zebrafish hearts. However, this capacity quickly decreases after postnatal day 7 (P7). Understanding the molecular mechanisms underlying neonatal heart regeneration might lead to therapeutic approaches for regenerating adult mammalian hearts. In this study, we utilized an inducible transgenic mouse model to determine the effects of FGF10 growth factor over expression on neonatal mouse heart regeneration/repair. Over expression of FGF10 in myocardium enhanced the expansion of Wt1 positive epicardial cells at 21 days after heart injury through increased proliferation. However, this expansion of epicardial cells did not lead to increased epithelial-to-mesenchymal transition or affect fibroblast formation or fibrosis, as seen by vimentin expression, after heart injury. Furthermore, neither continuous nor transient expression of FGF10 did not affect scar thickness or length after heart injury in neonatal hearts. Our results suggest that FGF10 can regulate epicardial cell expansion of neonatal mouse hearts after injury; however, FGF10 alone is not sufficient to cause beneficial effects on heart repair.

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在新生小鼠心脏修复过程中,FGF10 信号可促进心外膜细胞扩张
与斑马鱼和蝾螈的心脏不同,哺乳动物心脏的再生能力有限。受伤或患病后,成年哺乳动物的心脏会形成纤维化疤痕。最近的研究表明,新生小鼠心脏的再生能力与成年斑马鱼心脏相似。然而,这种能力在出生后第 7 天(P7)后迅速下降。了解新生儿心脏再生的分子机制可能有助于找到再生成年哺乳动物心脏的治疗方法。在本研究中,我们利用诱导转基因小鼠模型来确定 FGF10 生长因子过度表达对新生小鼠心脏再生/修复的影响。在心肌中过度表达 FGF10 会在心脏损伤后 21 天通过增殖增强 Wt1 阳性心外膜细胞的扩增。然而,心外膜细胞的扩增并没有导致上皮细胞向间质转化的增加,也没有影响成纤维细胞的形成或纤维化(如波形蛋白的表达)。此外,FGF10 的持续或瞬时表达都不会影响新生儿心脏损伤后的瘢痕厚度或长度。我们的研究结果表明,FGF10 能调节新生小鼠心脏损伤后心外膜细胞的扩增;但仅靠 FGF10 并不足以对心脏修复产生有益影响。
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