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CCM通路基因之间的组合相互作用引发出血性中风。

Combinatorial interaction between CCM pathway genes precipitates hemorrhagic stroke.

作者信息

Gore Aniket V, Lampugnani Maria Grazia, Dye Louis, Dejana Elisabetta, Weinstein Brant M

机构信息

Laboratory of Molecular Genetics, Program in Genomics of Development, National Institute of Child Health and Human Development, NIH, Bethesda, MD 20892, USA.

出版信息

Dis Model Mech. 2008 Nov-Dec;1(4-5):275-81. doi: 10.1242/dmm.000513. Epub 2008 Oct 28.

DOI:10.1242/dmm.000513
PMID:19093037
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2590810/
Abstract

Intracranial hemorrhage (ICH) is a particularly severe form of stroke whose etiology remains poorly understood, with a highly variable appearance and onset of the disease (Felbor et al., 2006; Frizzell, 2005; Lucas et al., 2003). In humans, mutations in any one of three CCM genes causes an autosomal dominant genetic ICH disorder characterized by cerebral cavernous malformations (CCM). Recent evidence highlighting multiple interactions between the three CCM gene products and other proteins regulating endothelial junctional integrity suggests that minor deficits in these other proteins could potentially predispose to, or help to initiate, CCM, and that combinations of otherwise silent genetic deficits in both the CCM and interacting proteins might explain some of the variability in penetrance and expressivity of human ICH disorders. Here, we test this idea by combined knockdown of CCM pathway genes in zebrafish. Reducing the function of rap1b, which encodes a Ras GTPase effector protein for CCM1/Krit1, disrupts endothelial junctions in vivo and in vitro, showing it is a crucial player in the CCM pathway. Importantly, a minor reduction of Rap1b in combination with similar reductions in the products of other CCM pathway genes results in a high incidence of ICH. These findings support the idea that minor polygenic deficits in the CCM pathway can strongly synergize to initiate ICH.

摘要

颅内出血(ICH)是一种特别严重的中风形式,其病因仍知之甚少,疾病表现和发病情况高度可变(费尔博尔等人,2006年;弗里泽尔,2005年;卢卡斯等人,2003年)。在人类中,三个CCM基因中任何一个发生突变都会导致一种常染色体显性遗传的ICH疾病,其特征为脑海绵状血管畸形(CCM)。最近的证据突出了三种CCM基因产物与其他调节内皮细胞连接完整性的蛋白质之间的多种相互作用,这表明这些其他蛋白质的微小缺陷可能会使个体易患CCM或有助于引发CCM,而且CCM基因和相互作用蛋白质中原本沉默的基因缺陷组合可能解释了人类ICH疾病在遗传率和表现度方面的一些变异性。在此,我们通过在斑马鱼中联合敲低CCM通路基因来验证这一想法。降低rap1b的功能,rap1b编码一种针对CCM1/Krit1的Ras GTP酶效应蛋白,会在体内和体外破坏内皮细胞连接,表明它是CCM通路中的关键因子。重要的是,Rap1b的轻微减少与其他CCM通路基因产物的类似减少相结合,会导致ICH的高发病率。这些发现支持了这样一种观点,即CCM通路中的微小多基因缺陷可强烈协同作用引发ICH。

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