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Boc 修饰 Cdo 突变小鼠的全前脑畸形谱。

Boc modifies the holoprosencephaly spectrum of Cdo mutant mice.

机构信息

Department of Developmental and Regenerative Biology, Mount Sinai School of Medicine, New York, NY 10029, USA.

出版信息

Dis Model Mech. 2011 May;4(3):368-80. doi: 10.1242/dmm.005744. Epub 2010 Dec 23.

DOI:10.1242/dmm.005744
PMID:21183473
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3097458/
Abstract

Holoprosencephaly (HPE) is caused by a failure to form the midline of the forebrain and/or midface. It is one of the most common human birth defects, but clinical expression is extremely variable. HPE is associated with mutations in the sonic hedgehog (SHH) pathway. Mice lacking the Shh pathway regulator Cdo (also called Cdon) display HPE with strain-dependent penetrance and expressivity, implicating silent modifier genes as one cause of the variability. However, the identities of potential HPE modifiers of this type are unknown. We report here that whereas mice lacking the Cdo paralog Boc do not have HPE, Cdo;Boc double mutants on a largely Cdo-resistant genetic background have lobar HPE with strong craniofacial anomalies and defects in Shh target gene expression in the developing forebrain. Boc is therefore a silent HPE modifier gene in mice. Furthermore, Cdo and Boc have specific, selective roles in Shh signaling in mammals, because Cdo;Boc double-mutant mice do not display the most severe HPE phenotype seen in Shh-null mice, nor do they have major defects in digit patterning or development of vertebrae, which are also Shh-dependent processes. This is in contrast to reported observations in Drosophila, where genetic removal of the Cdo and Boc orthologs Ihog and Boi results in a complete loss of response to the hedgehog ligand. Therefore, there is evolutionary divergence between mammals and insects in the requirement of the hedgehog pathway for Cdo/Ihog family members, with mammalian development involving additional factors and/or distinct mechanisms at this level of pathway regulation.

摘要

无脑回畸形(HPE)是由于前脑和/或中面部中线发育失败引起的。它是最常见的人类出生缺陷之一,但临床表现差异极大。HPE 与 sonic hedgehog(SHH)通路中的突变有关。缺乏 sonic hedgehog(SHH)通路调节因子 Cdo(也称为 Cdon)的小鼠表现出 HPE,其外显率和表现度具有菌株依赖性,表明沉默修饰基因是导致这种变异性的原因之一。然而,这种类型的潜在 HPE 修饰基因的身份尚不清楚。我们在这里报告,尽管缺乏 Cdo 旁系同源物 Boc 的小鼠没有 HPE,但在很大程度上对 Cdo 具有抗性的遗传背景下的 Cdo;Boc 双突变体具有叶状 HPE,具有强烈的颅面异常和发育中前脑 Shh 靶基因表达缺陷。因此,Boc 是小鼠中的沉默 HPE 修饰基因。此外,Cdo 和 Boc 在哺乳动物的 Shh 信号中具有特定的、选择性的作用,因为 Cdo;Boc 双突变体小鼠不会显示 Shh 缺失型小鼠中所见的最严重的 HPE 表型,也不会在指模式形成或脊椎骨发育中出现主要缺陷,这也是 Shh 依赖性过程。这与果蝇中的报道观察结果形成对比,在果蝇中,Cdo 和 Boc 同源物 Ihog 和 Boi 的遗传缺失导致对 hedgehog 配体的完全无反应。因此,在 hedgehog 通路对 Cdo/Ihog 家族成员的要求方面,哺乳动物和昆虫之间存在进化分歧,哺乳动物的发育涉及到该水平的通路调节中的其他因素和/或不同机制。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/7c09/3097458/852d2a974063/DMM005744F8.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/7c09/3097458/852d2a974063/DMM005744F8.jpg
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