Mar Lynn, Rivkin Elena, Kim Dennis Y, Yu Joanna Y, Cordes Sabine P
Samuel Lunenfeld Research Institute, Mount Sinai Hospital, Toronto, Ontario, M5G 1X5, Canada.
J Neurosci. 2005 Dec 14;25(50):11787-95. doi: 10.1523/JNEUROSCI.3813-05.2005.
Cranial motor and sensory nerves arise stereotypically in the embryonic hindbrain, act as sensitive indicators of general and region-specific neuronal development, and are directly or indirectly affected in many human disorders, particularly craniofacial syndromes. The molecular genetic hierarchies that regulate cranial nerve development are mostly unknown. Here, we describe the first mouse genetic screen that has used direct immunohistochemical visualization methods to systematically identify genetic loci required for cranial nerve development. After screening 40 pedigrees, we recovered seven new neurodevelopmental mutations. Two mutations model human genetic syndromes. Mutation 7-1 causes facial nerve anomalies and a reduced lower jaw, and is located in a region of conserved synteny with an interval associated with the micrognathia and mental retardation of human cri-du-chat syndrome. Mutation 22-1 is in the Pax3 gene and, thus, models human Waardenburg syndrome. Three mutations cause global axon guidance deficits: one interferes with initial motor axon extension from the neural tube, another causes overall axon defasciculation, and the third affects general choice point selection. Another two mutations affect the oculomotor nerve specifically. Oculomotor nerve development, which is disrupted by six mutations, appears particularly sensitive to genetic perturbations. Phenotypic comparisons of these mutants identifies a "transition zone" that oculomotor axons enter after initial outgrowth and in which new factors govern additional progress. The number of interesting neurodevelopmental mutants revealed by this small-scale screen underscores the promise of similar focused genetic screens to contribute significantly to our understanding of cranial nerve development and human craniofacial syndromes.
颅运动神经和感觉神经在胚胎后脑以固定模式产生,是整体和区域特异性神经元发育的敏感指标,并且在许多人类疾病,尤其是颅面部综合征中受到直接或间接影响。调节颅神经发育的分子遗传层级大多未知。在此,我们描述了首个利用直接免疫组化可视化方法系统鉴定颅神经发育所需基因位点的小鼠遗传筛选。在筛选40个家系后,我们发现了7个新的神经发育突变。其中两个突变模拟人类遗传综合征。突变7-1导致面神经异常和下颌缩小,位于与人类猫叫综合征的小颌畸形和智力迟钝相关区间具有保守同线性的区域。突变22-1位于Pax3基因中,因此模拟人类瓦登伯革氏综合征。三个突变导致整体轴突导向缺陷:一个干扰运动轴突从神经管的初始延伸,另一个导致轴突整体解束,第三个影响一般选择点的选择。另外两个突变特异性影响动眼神经。动眼神经发育受到6个突变的干扰,似乎对基因扰动特别敏感。这些突变体的表型比较确定了一个“过渡区”,动眼神经轴突在初始生长后进入该区域,其中新的因子控制进一步的发育进程。这个小规模筛选揭示的有趣神经发育突变体数量强调了类似的聚焦遗传筛选有望为我们理解颅神经发育和人类颅面部综合征做出重大贡献。