Wnt信号分子在神经管缺陷（NTD）发生过程中的表达及其可能的作用机制

目的探讨Wnt信号分子在神经胚形成和神经管缺陷（NTD）发生过程中的作用及其可能的分子调控机制。方法用Western blot方法半定量检测正常及NTD小鼠胚胎的脑泡及脊髓神经组织中Wnt信号分子的变化。采用流式细胞技术检测正常和神经管缺陷（NTD）胚胎脑泡及脊髓神经组织神经上皮细胞周期动力学的变化。结果与正常胚胎的脑泡及脊髓神经组织比较,NTD胚胎的脑泡及脊髓神经组织的β-catenin蛋白表达量明显减弱;而GSK-3β蛋白表达量明显增强。流式细胞仪的检测结果显示：与正常E10.5d胚胎脑泡及脊髓神经组织的神经上皮相比,神经管缺陷模型胚胎的脑泡及脊髓神经组织的神经上皮细胞处于G0/G1期的细胞百分比明显增高,而神经上皮细胞处于S期的细胞百分比则明显降低。结论神经管缺陷的发生与Wnt信号途径的变化是密切相关的,Wnt信号分子的变化可能正是神经管缺陷形成中细胞增殖抑制的相关分子机制。神经管上皮细胞的增殖抑制及凋亡可能是NTD发生的重要细胞基础。     

与神经管畸形相关的基因学研究进展

神经管畸形（neural tube defects,NTDs）是指由于在胚胎发育过程中,神经管闭合不全所引起的一组出生缺陷,包括无脑儿、脊柱裂、脑积水、脑或脑脊膜膨出等,其危害极大,严重影响患儿的生理发育和生活质量,给家庭和社会带来沉重的精神压力和经济负担。大多数研究认为神经管畸形是多因素多基因的遗传疾病,是遗传、环境、营养因素共同作用、交互影响的结果,目前还不能用一种单一原因解释该疾病的发生。本文主要从导致神经管畸形发生的叶酸代谢酶基因多态性、神经管形态学方面的相关基因研究等做一综述。     

胚胎神经管缺陷大鼠模型差异基因的表达

通过构建妊娠合并糖尿病诱发先天性神经管缺陷的SD大鼠模型, 与胚胎不伴有先天性神经管缺陷组大鼠和正常对照组大鼠胚胎进行研究, 提取卵黄囊细胞的mRNA, cDNA 基因芯片技术对表达差异基因进行检测, 应用特异性抗磷酸化抗体进行免疫共沉淀及Western blotting, 对卵黄囊细胞MAP Kinase信号途径蛋白激酶活性进行分析。在神经管缺陷大鼠胚胎卵黄囊细胞和对照组1 200个基因中, 共筛选出表达差异基因79个, 其中42个基因表达上调、37个基因表达下调。同时发现神经管缺陷胚胎卵黄囊细胞出现细胞凋亡特征性的DNA ladder(梯状电泳), 凋亡相关基因 caspase-3、Bax 高表达, 凋亡抑制基因 AKT活性明显受抑; 与正常对照组相比ERK1/2蛋白激酶活性显著下降、JNK1/2活性明显升高。因此, 认为妊娠合并糖尿病诱发胚胎先天性神经管缺陷的发生存在多种差异基因表达, 以及MAP Kinase、凋亡信号传导机制的共同作用。     

神经管畸形的表观遗传学研究进展

神经管畸形(neural tube defects,NTDs)是胚胎在早期发育过程中,由于神经管闭合不全或障碍引起的一组以脑和(或)脊髓发育异常为主的先天畸形。目前,对于神经管畸形的发病机制和病因没有明确的定论。很多因素参与神经管畸形的发生,主要涉及遗传、环境、以及二者的相互作用。遗传因素的研究主要着重于寻找神经管畸形的致病基因并进行基因功能缺陷研究,但是神经管畸形是多因素参与的结果,基因功能缺陷研究并不能完全解释其发病机制。基于目前的研究现状,近年来,环境因素通过调控表观遗传的修饰进而参与调节NTDs发生相关基因表达的研究逐渐受到重视。     

机械阻断神经管的闭合影响爪蟾神经管辐射状切入及神经嵴细胞定向迁移(英文)

神经管闭合缺陷 (NTDs)是一种严重的先天畸形疾病,在新生儿中有千分之一的发病率。神经管融合前后,多种组织参与形态发生运动。神经管一经融合,神经嵴细胞就会向背侧中线方向产生单极突出并向此方向迁移形成神经管的顶部。与此同时,神经管从腹侧开始发生辐射状切入以实现单层化。在此,我们在非洲爪蟾的移植体中机械阻断神经管的闭合以检测其细胞运动及随后的图式形成。结果显示神经管闭合缺陷的移植体不能形成单层化的神经管,并且神经嵴细胞滞留在侧面区域不能向背侧中线迁移,而对神经前体标记基因的检测显示神经管的背腹图式形成并未受到影响。以上结果表明神经管的融合对于辐射状切入和神经嵴细胞向背侧中线方向的迁移过程是必需的,而对于神经管的沿背腹轴方向的图式形成是非必需的。     

高温致神经管畸形过程中神经生长因子及其受体表达变化的观察

为进一步探讨高温致神经管畸形的机制, 本文利用我们已经建立的高温致神经管畸形金黄地鼠模型, 在神经管发育的不同阶段, 用免疫组织化学法检测了高温对神经管及其周围间充质中神经生长因子（Ｎｅｒｖｅ Ｇｒｏｗ ｔｈ Ｆａｃｔｏｒ, ＮＧＦ） 和ＮＧＦ受体 （ｔｒｋＡ） 表达的影响。结果显示： ＮＧＦ及其受体广泛分布于神经管及其周围间充质内, 并随胎龄增加而呈规律性变化, 高温处理后的胚胎神经管上皮及其周围间充质中ＮＧＦ及其受体的免疫组织化学反应不同程度的减弱。结果提示, 神经管ＮＧＦ及其受体的减少, 可能是高温致神经管畸形的一个重要因素     

基于群体转录组解析南荻局域适应的关键因子

选取有代表性的10个南荻（Miscanthus lutarioriparius L.Liu ex Renvoize&S.L.Chen）野生居群,以种群转录组数据为基础,对种群局部适应性的关键因子进行研究。首先利用SNP构建推断单倍型,分析环境间和推断单倍型间的差异表达基因,并将这类基因分为4类：仅受环境显著影响的基因（E）、仅受单倍型显著影响的基因（G）、受环境和单倍型相互作用显著影响的基因（G&E）以及非显著影响的基因。分析结果显示：G&E和E基因集在种群局域适应中发挥重要作用,前者的基因表达更容易受其它因素的影响,而后者相对较为稳定;前者中显著富集核糖体途径相关功能基因,后者中显著富集蛋白质折叠相关功能基因。这两类功能基因均参与响应外界压力,推测这些基因的差异表达主要受环境以及基因型和生长环境相互作用的影响。     

PAX3基因及其蛋白的生物信息学分析

目的：对PAX3基因和PAX3蛋白进行生物信息学分析,更多的了解该基因的相关信息,为进一步研究PAX3与神经管畸形的相关性研究提供基础。方法：运用生物信息学方法对PAX3基因的基因结构、单核苷酸多态性位点（SNP）、PAX3基因与其他基因的相互作用网络、PAX3蛋白结构域、蛋白二级结构、蛋白间相互作用网络、以及PAX3蛋白所调控和影响的靶基因进行分析。结果：PAX3基因有9中可变剪切形式,编码区存在14个SNP位点,其中错意突变13个,移码突变1个。PAX3蛋白由479个氨基酸组成,分子量52968Da,PAX3蛋白可能调控和影响151个靶基因的转录和表达,与PAX3基因存在相互作用的基因和与PAX3蛋白存在相互作用的蛋白多数与发育相关。结论：通过对PAX3基因和PAX3蛋白的生物信息学分析获得了其相应的分子生物学特征,为进一步研究提供基础。     

维甲酸致小鼠胚胎畸形发生过程中维甲酸受体α/β及β-catenin和caspase-3基因的表达变化

流行病学研究显示,在胚胎发育过程中摄入过多维甲酸可致各种发育缺陷,其中神经管畸形最为常见. 因此有必要探明维甲酸致各种发育缺陷的发生机制,以便为各种生长缺陷的预防和治疗提供实验依据. 用 RT-PCR 及蛋白质印迹技术,探测了过量维甲酸对昆明小鼠胚胎神经管中维甲酸受体α/β及β-catenin 和 caspase-3 基因表达的调整. 结果显示,在神经管闭合期过量维甲酸显著降低了维甲酸受体α/β及β-catenin 和 caspase-3 的基因表达,神经管闭合后,维甲酸受体β、β-catenin 及 caspase-3 的基因表达又出现了一个明显的回升过程. 提示,过量维甲酸改变了昆明小鼠胚胎神经管中维甲酸受体α/β及β-catenin 和 caspase-3 基因的正常时间表达模式,这种异常的基因表达模式可能参与了维甲酸致昆明小鼠胚胎畸形的发生机制.     

还原叶酸载体基因（RFC1）与神经管和颅面畸形病因学关系的研究进展

神经管畸形和颅面畸形是最常见的出生缺陷,由遗传和环境因素共同作用所致,大规模的人群流行病学研究已证实,叶酸能降低发生这类畸形的危险。叶酸缺乏是神经管和颅面畸形发生的主要环境因素,但其机制尚不清楚,通过对与叶酸代谢有关的还原叶酸载体（reduced folate carrier,RFC）的生化特点、生理功能、还原叶酸载体基因（RFC1）结构功能、调控、表达及其与叶酸水平和神经管颅面畸形的关系等研究进展进行综述,从而为神经管和颅面畸形的病因学研究提出可能的候选基因。 Abstract: Neural tube and craniofacial defects are common birth defects which are ascribed to the combination of genetic and environmental factors. The population epidemiological studies suggested that periconceptional use of multivitamins containing folic acid can reduce a woman’s risk of having a child with neural tube and craniofacial defects. It’s a major environmental factor that periconceptinal women with deficiency of folic acid may increase their risk for delivering babies with neural tube and craniofacial defects, but the mechanism by which folic acid facilitated this risk rediction is unknown. This paper reviews folate transport carrier, Reduced Folate Carrier(RFC)’s characteristics in biological chemistry, physiological function, the folate transport mechanism, structure, function, regulation and expression of reduced folate carrier gene(RFC1), and the relationship between RFC1 with plasm or erythrocyte folate level and neural tube defects, et al. It is suggested a etiologic hypothesis in investigation of candidate gene encoding specific folat-related pathways of neural tube and craniofacial defects.     

神经管畸形相关基因的研究进展

神经管畸形是由遗传和环境因素共同作用而导致的一种常见的出生缺陷。遗传因素中包括细胞增殖因子、转录因子及影响叶酸代谢的关键酶的基因。本文着重从动物模型和群体流行病学调查两方面,简述目前研究的热点基因及特定位点的遗传多态性与神经管畸形的关系,从而揭示多因素作用在神经管畸形病因学研究中的意义。 Progress in Researches on Neural Tube Defects Related the Genes QU Mei,LI Zhu Institute of Reproductive and Child Health of Peking University,National Reference Laboratory on Reproductive Health Research Ministry of Health,Beijing 100083,China Abstract:Neural tube defects are common birth defects which are ascribed to the combination of genetic and environmental factors.The genetic factors include cell growth factors,transformation factors and key enzymic genes involved in folate metabolism.This paper reviews the genes as focus of current investigantion and the relationship between the genetic polymorphism on the specific sites and neural tube defects based on animal model and population epidemiological study.It indicats that the multifactors play an important role in the etiology of neural tube defects. Key words：neural tube defects; genetic polymorphism     

Gene Expression Profiling Within the Developing Neural Tube

The developing mammalian nervous system is subject to devastating congenital malformations with clinical significance that extends into the billions of health care dollars annually worldwide. Neural tube defects (NTDs) are among the most common of all human congenital defects, yet their etiology remains poorly understood. This is largely due to the complexity of the genetic factors regulating the intricate events involved in neurulation. Using mouse model systems and the application of modern molecular biological technologies, we have recently gained a greater appreciation for the factors that not only regulate normal neural tube closure (NTC), but those genetic factors that predispose an embryo to significant birth defects such as anencephaly or spina bifida. We have selected prominent murine mutants, both spontaneous and genetically modified, as well as the use of teratogenic agents, to examine the impact of altering the normal pattern of gene expression in the developing neural tube.     

Genetic basis of neural tube defects. I. Regulatory genes for the neurulation process

Neural tube defects (NTD) together with cardiovascular system defects are the most common malformations in the Polish population (2.05-2.68/1000 newborns). They arise during early embryogenesis and are caused by an improper neural groove closure during the neurulation process. NTD can arise from the influence of specific environmental factors on the foetus. The genetic factor is also very important, because NTDs have multigenetic conditioning. It was suggested that genes connected with the regulation of neurulation could also be involved in NTD aetiology, especially when their deletion or modification leads to neural tube defects in the mouse model. Examples are genes from the PAX family, T (Brachyury), BRCA1 and PDGFRA genes.     

A systems‐based approach to investigate dose‐ and time‐dependent methylmercury‐induced gene expression response in C57BL/6 mouse embryos undergoing neurulation

BACKGROUND: Aberrations during neurulation due to genetic and/or environmental factors underlie a variety of adverse developmental outcomes, including neural tube defects (NTDs). Methylmercury (MeHg) is a developmental neurotoxicant and teratogen that perturbs a wide range of biological processes/pathways in animal models, including those involved in early gestation (e.g., cell cycle, cell differentiation). Yet, the relationship between these MeHg‐linked effects and changes in gestational development remains unresolved. Specifically, current information lacks mechanistic comparisons across dose or time for MeHg exposure during neurulation. These detailed investigations are crucial for identifying sensitive indicators of toxicity and for risk assessment applications. METHODS: Using a systems‐based toxicogenomic approach, we examined dose‐ and time‐dependent effects of MeHg on gene expression in C57BL/6 mouse embryos during cranial neural tube closure, assessing for significantly altered genes and associated Gene Ontology (GO) biological processes. Using the GO‐based application GO‐Quant, we quantitatively assessed dose‐ and time‐dependent effects on gene expression within enriched GO biological processes impacted by MeHg. RESULTS: We observed MeHg to significantly alter expression of 883 genes, including several genes (e.g., Vangl2, Celsr1, Ptk7, Twist, Tcf7) previously characterized to be crucial for neural tube development. Significantly altered genes were associated with development cell adhesion, cell cycle, and cell differentiation–related GO biological processes. CONCLUSIONS: Our results suggest that MeHg‐induced impacts within these biological processes during gestational development may underlie MeHg‐induced teratogenic and neurodevelopmental toxicity outcomes. Birth Defects Res (Part B) 89:188–200, 2010. © 2010 Wiley‐Liss, Inc.     

Roles of planar cell polarity pathways in the development of neutral tube defects

Neural tube defects (NTDs) are the second most common birth defect in humans. Despite many advances in the understanding of NTDs and the identification of many genes related to NTDs, the fundamental etiology for the majority of cases of NTDs remains unclear. Planar cell polarity (PCP) signaling pathway, which is important for polarized cell movement (such as cell migration) and organ morphogenesis through the activation of cytoskeletal pathways, has been shown to play multiple roles during neural tube closure. The disrupted function of PCP pathway is connected with some NTDs. Here, we summarize our current understanding of how PCP factors affect the pathogenesis of NTDs.     

The emerging role of epigenetic mechanisms in the etiology of neural tube defects

The molecular requirements for neural tube closure are complex. This is illustrated by the occurrence of neural tube defects (NTDs) in many genetic mouse mutants, which implicate a variety of genes, pathways and cellular functions. NTDs are also prevalent birth defects in humans, affecting around 1 per 1,000 pregnancies worldwide. In humans the causation is thought to involve the interplay of fetal genes and the effect of environmental factors. Recent studies on the etiology of human NTDs, as well as analysis of mouse models, have raised the question of the possible involvement of epigenetic factors in determining susceptibility. A consideration of potential causative factors in human NTDs must now include both alterations in the regulation of gene expression, through mutation of promoter or regulatory elements and the additional analysis of epigenetic regulation. Alterations in the epigenetic status can be directly modified by various environmental insults or maternal dietary factors.Key words: neural tube defects, diet, folic acid, epigenome, epigenetic regulation, methylation, chromatin, histones, acetylation     

The emerging role of epigenetic mechanisms in the etiology of neural tube defects

The molecular requirements for neural tube closure are complex. This is illustrated by the occurrence of neural tube defects (NTDs) in many genetic mouse mutants, which implicate a variety of genes, pathways and cellular functions. NTDs are also prevalent birth defects in humans, affecting around 1 per 1000 pregnancies worldwide. In humans the causation is thought to involve the interplay of fetal genes and the effect of environmental factors. Recent studies on the aetiology of human NTDs, as well as analysis of mouse models, have raised the question of the possible involvement of epigenetic factors in determining susceptibility. A consideration of potential causative factors in human NTDs must now include both alterations in the regulation of gene expression, through mutation of promoter or regulatory elements, and the additional analysis of epigenetic regulation. Alterations in the epigenetic status can be directly modified by various environmental insults or maternal dietary factors.