Leong Wan Y, Lim Zhi H, Korzh Vladimir, Pietri Thomas, Goh Eyleen L K
Program in Neuroscience and Behavioral Disorder, Duke-NUS Graduate Medical School, Singapore Singapore.
Institute of Molecular and Cell Biology, SingaporeSingapore; Department of Biological Sciences, National University of Singapore, SingaporeSingapore.
Front Cell Neurosci. 2015 Dec 21;9:481. doi: 10.3389/fncel.2015.00481. eCollection 2015.
Mutations in the gene encoding the MECP2 underlies Rett syndrome, a neurodevelopmental disorder in young females. Although reduced pain sensitivity in Rett syndrome patients and in partial MeCP2 deficient mice had been reported, these previous studies focused predominantly on motor impairments. Therefore, it is still unknown how MeCP2 is involved in these sensory defects. In addition, the human disease manifestations where males with mutations in MECP2 gene normally do not survive and females show typical neurological symptoms only after 18 months of age, is profoundly different in MeCP2-deficient mouse where all animals survived, and males but not females displayed Rett syndrome phenotypes at an early age. Thus, the mecp2-deficient zebrafish serves as an additional animal model to aid in deciphering the role and mechanisms of Mecp2 in neurodevelopment. Here, we used two independent methods of silencing expression of Mecp2 in zebrafish to uncover a novel role of Mecp2 in trigeminal ganglion sensory neurons during the embryonic development. mecp2-null mutation and morpholino-mediated silencing of Mecp2 in the zebrafish embryos resulted in defects in peripheral innervation of trigeminal sensory neurons and consequently affecting the sensory function. These defects were demonstrated to be dependent on the expression of Sema5b and Robo2. The expression of both proteins together could better overcome the defects caused by Mecp2 deficiency as compared to the expression of either Sema5b or Robo2 alone. Sema5b and Robo2 were downregulated upon Mecp2 silencing or in mecp2-null embryos, and Chromatin immunoprecipitation (ChIP) assay using antibody against Mecp2 was able to pull down specific regions of both Sema5b and Robo2 promoters, showing interaction between Mecp2 and the promoters of both genes. In addition, cell-specific expression of Mecp2 can overcome the innervation and sensory response defects in Mecp2 morphants indicating that these MeCP2-mediated defects are cell-autonomous. The sensory deficits caused by Mecp2 deficiency mirror the diminished sensory response observed in Rett syndrome patients. This suggests that zebrafish could be an unconventional but useful model for this disorder manifesting defects that are not easily studied in full using rodent models.
编码MECP2的基因突变是雷特综合征的病因,这是一种发生在年轻女性中的神经发育障碍。尽管已有报道称雷特综合征患者和部分MeCP2基因缺陷小鼠的痛觉敏感性降低,但这些先前的研究主要集中在运动障碍方面。因此,MeCP2如何参与这些感觉缺陷仍不清楚。此外,人类疾病表现为携带MECP2基因突变的男性通常无法存活,而女性仅在18个月大后才表现出典型的神经症状,这与MeCP2基因缺陷小鼠有很大不同,在该小鼠模型中所有动物都存活了下来,并且雄性而非雌性在幼年时就表现出雷特综合征表型。因此,Mecp2基因缺陷的斑马鱼可作为一种额外的动物模型,有助于阐明Mecp2在神经发育中的作用和机制。在此,我们使用两种独立的方法沉默斑马鱼中Mecp2的表达,以揭示Mecp2在胚胎发育过程中三叉神经节感觉神经元中的新作用。斑马鱼胚胎中Mecp2基因的无效突变和吗啉代介导的Mecp2沉默导致三叉神经感觉神经元的外周神经支配缺陷,进而影响感觉功能。这些缺陷被证明依赖于Sema5b和Robo2的表达。与单独表达Sema5b或Robo2相比,这两种蛋白共同表达能更好地克服由Mecp2缺陷引起的缺陷。在Mecp2沉默或Mecp2基因无效的胚胎中,Sema5b和Robo2表达下调,使用抗Mecp2抗体的染色质免疫沉淀(ChIP)分析能够沉淀Sema5b和Robo2启动子的特定区域,表明Mecp2与这两个基因的启动子之间存在相互作用。此外,Mecp2的细胞特异性表达可以克服Mecp2 morphants中的神经支配和感觉反应缺陷,这表明这些由MeCP2介导的缺陷是细胞自主性的。Mecp2缺陷引起的感觉缺陷反映了雷特综合征患者中观察到的感觉反应减弱。这表明斑马鱼可能是一种非传统但有用的该疾病模型,其表现出的缺陷在啮齿动物模型中不易全面研究。
