Fgf10导致Apert综合征小鼠模型骨骼和内脏缺陷的证据。

Evidence that Fgf10 contributes to the skeletal and visceral defects of an Apert syndrome mouse model.

作者信息

Hajihosseini Mohammad K, Duarte Raquel, Pegrum Jean, Donjacour Anne, Lana-Elola Eva, Rice David P, Sharpe James, Dickson Clive

机构信息

School of Biological Sciences, University of East Anglia, Norwich, United Kingdom.

出版信息

Dev Dyn. 2009 Feb;238(2):376-85. doi: 10.1002/dvdy.21648.

DOI:10.1002/dvdy.21648

PMID:18773495

Abstract

Apert syndrome (AS) is a severe congenital disease caused by mutations in fibroblast growth factor receptor-2 (FGFR2), and characterised by craniofacial, limb, visceral, and neural abnormalities. AS-type FGFR2 molecules exert a gain-of-function effect in a ligand-dependent manner, but the causative FGFs and their relative contribution to each of the abnormalities observed in AS remains unknown. We have generated mice that harbour an AS mutation but are deficient in or heterozygous for Fgf10. The genetic knockdown of Fgf10 can rescue the skeletal as well as some of the visceral defects observed in this AS model, and restore a near normal level of FgfR2 signaling involving an apparent switch between ERK(p44/p42) and p38 phosphorylation. Surprisingly, it can also yield de novo cleft palate and blind colon in a subset of the compound mutants. These findings strongly suggest that Fgf10 contributes to AS-like pathologies and highlight a complexity of Fgf10 function in different tissues.

摘要

阿佩尔综合征（AS）是一种由成纤维细胞生长因子受体-2（FGFR2）突变引起的严重先天性疾病，其特征为颅面、肢体、内脏和神经异常。AS型FGFR2分子以配体依赖的方式发挥功能获得效应，但导致AS的成纤维细胞生长因子（FGFs）及其对AS中观察到的每种异常的相对贡献仍不清楚。我们已经培育出携带AS突变但Fgf10基因缺失或为杂合子的小鼠。Fgf10基因的敲低可以挽救该AS模型中观察到的骨骼以及一些内脏缺陷，并恢复涉及ERK（p44/p42）和p38磷酸化明显转换的FgfR2信号传导的接近正常水平。令人惊讶的是，它还能在一部分复合突变体中产生新生腭裂和盲结肠。这些发现强烈表明Fgf10促成了AS样病理，并突出了Fgf10在不同组织中功能的复杂性。

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Fgf10导致Apert综合征小鼠模型骨骼和内脏缺陷的证据。

Evidence that Fgf10 contributes to the skeletal and visceral defects of an Apert syndrome mouse model.

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