心管发生的分子机制

心管的发生是心脏发育早期最重要的事件之一.它由左右两团心脏前体细胞逐渐相互靠拢合并成一条位于腹侧正中的线性心管,然后再进行环化和房室化.心管发生的分子机制与两个方面有关:其一为心脏前体细胞的迁移,在斑马鱼中8个基因与之有关;其二为心管的装配,has等基因与之有关.     

人类心脏发育缺陷的分子机理

为了探索心脏发育的缺陷及遗传机制以及在分子水平上先天性心脏病的发生机理,概述了人类心脏发育缺陷的研究进展,包括人类心脏不对称发育、心脏发育缺陷和心脏缺陷的分子机理.     

纤毛与人体左右不对称发育研究进展

人体内脏器官在位置及形态上呈左右不对称分布。纤毛在左右不对称发育中发挥关键作用。目前已鉴定数十个不对称发育相关的人类疾病基因,这些基因大多涉及纤毛发生、运动以及Nodal-Pitx2信号传导过程。文中主要介绍了纤毛影响Nodal-Pitx2信号通路导致人体左右不对称发育的过程。此外还简要阐述了纤毛与先天性心脏病的关系以及左右不对称发育人类遗传学研究的最新发现。这些进展将有助于我们深入了解左右不对称发育分子机制以及纤毛与人类疾病的联系。     

心脏动脉极的形成

目前已发现与生心区形成心管这一过程有密切关系的关键基因和信号分子.对称的生心区后部促使心肌前体细胞形成心脏的流入区域或静脉极.最近在鸡和鼠胚胎中已经鉴定:心肌前体细胞群在咽中胚层中位于早期心管的前部.这种前部导致心脏的流出区域或动脉极处的心肌的产生.因此,脊椎动物的心脏起源于两种心肌前体细胞.这些细胞通过不同的基因程序有规律地出现.心区前部的发现对于解释突变鼠的心脏缺陷和研究人类先天性心脏病有非常重要的意义.     

两侧对称动物左右不对称发生机制研究进展

左右不对称是两侧对称动物的重要特征,其形成机制一直是发育生物学领域备受关注的科学问题之一。脊椎动物的左右不对称发生经过3个重要阶段：左右对称性的打破,左右不对称信号的建立和维持,以及左右不对称器官的形态发生。多数脊椎动物在胚胎发育阶段依赖纤毛产生定向液流打破胚胎的左右对称性,随后建立Nodal-Pitx2左右不对称信号,最后由Pitx2等基因指导左右不对称器官的形态发生过程。无脊椎动物中存在不依赖纤毛介导的Nodal-Pitx不对称信号表达机制,甚至具有完全独立的左右不对称发育机制。本文结合最新的左右不对称器官发育机制的研究进展,综述了脊椎动物和无脊椎动物胚胎左右不对称的发生过程及相关基因和信号通路,有助于深入理解左右不对称器官发育的过程,以期为追溯左右不对称器官发育机制的起源演化提供参考。     

斑马鱼charon基因的克隆、抗体制备及分析

斑马鱼charon基因位于1号染色体上,其成熟肽编码区含有731 bp,编码243个氨基酸.charon基因编码Cerberus/Dan家族的一种分泌因子,它与心脏的左右不对称发育有关.为进一步研究charon在心脏左右不对称发育中的功能,以斑马鱼为动物模型,利用RT-PCR的方法成功克隆了斑马鱼charon基因片段,...     

raldh2基因阻抑导致斑马鱼心脏发育畸形的机制

目的通过显微注射吗啡啉修饰的反义寡核苷酸(MO)阻抑视黄醛脱氢酶2(raldh2)基因表达,探讨raldh2基因阻抑对斑马鱼胚胎心脏发育的影响及可能的分子机制。方法根据斑马鱼raldh2基因起始密码区域序列设计合成吗啡啉修饰的反义寡核苷酸,采用显微注射方法阻抑斑马鱼胚胎raldh2基因表达。构建raldh2-EG-FP重组质粒进一步验证MO的特异性和有效性。分析raldh2基因阻抑后对胚胎发育,尤其心脏表型和功能的影响。通过胚胎整体原位杂交,分析心脏相关nppa和tbx20基因表达模式以及raldh2阻抑后对其表达的影响。结果显微注射raldh2-MO能有效地特异地阻抑斑马鱼胚胎raldh2基因表达,raldh2-MO对胚胎发育影响呈剂量依赖性。raldh2基因阻抑可导致胚胎心脏发育畸形,干扰正常的房室分化和向右环化,导致房室瓣血液反流。与野生型胚胎比较,raldh2基因阻抑组胚胎心率和心室收缩分数降低(P<0.05),心功能受损。整体原位杂交结果显示raldh2基因阻抑后nppa基因表达改变,心室部位nppa表达清晰,而心房部位表达减弱。tbx20基因在心脏、运动神经元、顶盖及视网膜表达,raldh2基因阻抑后,tbx20表达下调,在心脏表达减弱,以心房和流出道部位更显著。结论 raldh2基因在心脏早期发育的多个环节发挥重要作用,影响房室分化、心管环化和心肌收缩等。在心脏发育过程中nppa和tbx20基因表达受到raldh2基因调控,可能参与RA信号缺乏导致心脏畸形的潜在分子机制。     

Nodal蛋白的表达、纯化及多克隆抗体制备

斑马鱼心脏发育模型中Nodal编码转录因子调节心脏的左右不对称发育,为了进一步研究Nodal信号途径在心脏发育中的调控作用和心脏疾病发生的分子机制,需要获得斑马鱼Nodal蛋白并制备其抗体.采用从斑马鱼心脏组织中提取RNA,通过反转录得到心脏组织各种表达基因的cDNA为模板,PCR扩增得到Nodal部分编码区序列,然后将其连接到pET-28a载体上获得原核表达.经酶切及测序鉴定后,转化Rosseta细菌,并用IPTG诱导表达融合蛋白,Ni-IDA凝胶柱亲和纯化,将纯化的融合蛋白免疫新西兰大白兔制备多克隆抗体,并用Western blotting检测抗体.获得了Nodal原核表达重组融合蛋白及高效价的特异性兔抗Nodal多克隆抗体,为Nodal功能的进一步研究奠定了基础.     

果蝇心脏发育基因调控的研究进展

果蝇心脏的发育是一个受到一系列基因共同调控的复杂过程,这些基因在脊椎动物和无脊椎动物果蝇中具有惊人的相似性,对于它们功能的研究将有助于揭示人类心脏发育的过程及分子控制机理.通过将果蝇作为一种重要的模式动物,对心脏发育基因调控的研究进展作一综述.     

心脏间隔的形成

心脏形态的建成包括了腔室的形成和间隔的形成两个部分,而心脏间隔的出现又使得心脏从单腔室器官发育成为四腔室的成熟器官.在人类心脏发育过程中,心脏间隔的发生是在胚胎发育的第4周至第7周,在这个过程中,心脏的袢环化以及腔室的逐渐建成,也促进了心脏间隔的形成.心肌层在房室腔的建成中充当了重要的角色,但是研究表明它在心脏间隔的发生中却没有起到实质性的作用,相反对于心外间充质组织,人们开始重新认识它在心脏间隔发生中的意义.     

The Rho kinase Rock2b establishes anteroposterior asymmetry of the ciliated Kupffer's vesicle in zebrafish

The vertebrate body plan features a consistent left-right (LR) asymmetry of internal organs. In several vertebrate embryos, motile cilia generate an asymmetric fluid flow that is necessary for normal LR development. However, the mechanisms involved in orienting LR asymmetric flow with previously established anteroposterior (AP) and dorsoventral (DV) axes remain poorly understood. In zebrafish, asymmetric flow is generated in Kupffer's vesicle (KV). The cellular architecture of KV is asymmetric along the AP axis, with more ciliated cells densely packed into the anterior region. Here, we identify a Rho kinase gene, rock2b, which is required for normal AP patterning of KV and subsequent LR development in the embryo. Antisense depletion of rock2b in the whole embryo or specifically in the KV cell lineage perturbed asymmetric gene expression in lateral plate mesoderm and disrupted organ LR asymmetries. Analyses of KV architecture demonstrated that rock2b knockdown altered the AP placement of ciliated cells without affecting cilia number or length. In control embryos, leftward flow across the anterior pole of KV was stronger than rightward flow at the posterior end, correlating with the normal AP asymmetric distribution of ciliated cells. By contrast, rock2b knockdown embryos with AP patterning defects in KV exhibited randomized flow direction and equal flow velocities in the anterior and posterior regions. Live imaging of Tg(dusp6:memGFP)(pt19) transgenic embryos that express GFP in KV cells revealed that rock2b regulates KV cell morphology. Our results suggest a link between AP patterning of the ciliated Kupffer's vesicle and LR patterning of the zebrafish embryo.     

Left-right development from embryos to brains

Bilateran animals have external bilateral symmetry along the dorsoventral (DV) and anteroposterior (AP) axes. Internal left-right asymmetries appear to be consistently aligned along the left-right (LR) axis with respect to the other axes. Left-right development is most apparent in the directional looping of the cardiac tube, the coiling and placement of the intestines, the positioning of internal organs such as liver, gallbladder, pancreas, and stomach. In addition, there are obvious morphological asymmetries in the brains of some vertebrates and functional left-right asymmetries in the activities of the brain, as assessed by psychological testing, MRI, and the analysis of lesions. There are several fundamental questions: What are the origins of the left-right axis, and are they highly conserved across metazoans? Once the left-right axis is established by the initial breaking of bilateral symmetry, what is the genetic pathway that perpetrates left-right development? What are the cellular and tissue mechanics that lead to morphogenesis during, for example, the looping of the cardiac tube, the coiling of the gut, or asymmetric brain development? Finally, do the asymmetric developmental pathways of each organ system take register from the same initial event that establishes the left-right axis, or are there separate mechanisms that orient heart, gut, and brain left-right asymmetry with respect to the DV and AP axes? These questions are beginning to be experimentally addressed, and papers in this issue of Developmental Genetics make contributions to several aspects in the burgeoning field of left-right development. Recent reviews have summarized the emerging genes and pathways in vertebrate left-right development [Wood, 1997; Harvey, 1998; Ramsdell and Yost, 1998]. Here, I give an overview of the contributions in this issue to the fundamental questions in left-right development. Dev. Genet. 23:159–163, 1998. © 1998 Wiley-Liss, Inc.     

Left-right asymmetry in the alimentary canal of the Drosophila embryo

In many animal groups, left-right (LR) asymmetry within the body is observed. The left and right sides of the body are generally defined with reference to the anterior-posterior (AP) and dorsal-ventral (DV) axes. In this study, we investigated whether LR asymmetry is solely dependent on the AP and DV polarities in Drosophila embryos. We focused on the proventriculus, a posterior part of the foregut, and the hindgut because LR asymmetry in these body parts is highly stable in normal embryos. In embryos with a fully reversed AP polarity, LR asymmetry in both the proventriculus and the hindgut was re-oriented in relation to the reversed AP polarity. This demonstrates that inversion of AP polarity does not affect LR asymmetry of these tissues, and implies that LR asymmetry is specified in relation to the AP and DV polarities. Our findings were not consistent with the alternative hypothesis that LR asymmetry is predetermined by maternal signals that localize asymmetrically along the LR axis in the oocyte and/or early embryo.     

Coordinated regulation of the dorsal‐ventral and anterior‐posterior patterning of Xenopus embryos by the BTB/POZ zinc finger protein Zbtb14

During early vertebrate embryogenesis, bone morphogenetic proteins (BMPs) belonging to the transforming growth factor‐β (TGF‐β) family of growth factors play a central role in dorsal–ventral (DV) patterning of embryos, while other growth factors such as Wnt and fibroblast growth factor (FGF) family members regulate formation of the anterior–posterior (AP) axis. Although the establishment of body plan is thought to require coordinated formation of the DV and AP axes, the mechanistic details underlying this coordination are not well understood. Here, we show that a Xenopus homologue of zbtb14 plays an essential role in the regulation of both DV and AP patterning during early Xenopus development. We show that overexpression of Zbtb14 promotes neural induction and inhibits epidermal differentiation, thereby regulating DV patterning. In addition, Zbtb14 promotes the formation of posterior neural tissue and suppresses anterior neural development. Consistent with this, knock‐down experiments show that Zbtb14 is required for neural development, especially for the formation of posterior neural tissues. Mechanistically, Zbtb14 reduces the levels of phosphorylated Smad1/5/8 to suppress BMP signaling and induces an accumulation of β‐Catenin to promote Wnt signaling. Collectively, these results suggest that Zbtb14 plays a crucial role in the formation of DV and AP axes by regulating both the BMP and Wnt signaling pathways during early Xenopus embryogenesis.     

D-JNK signaling in visceral muscle cells controls the laterality of the Drosophila gut

Although bilateral animals appear to have left-right (LR) symmetry from the outside, their internal organs often show directional and stereotypical LR asymmetry. The mechanisms by which the LR axis is established in vertebrates have been extensively studied. However, how each organ develops its LR asymmetric morphology with respect to the LR axis is still unclear. Here, we showed that Drosophila Jun N-terminal kinase (D-JNK) signaling is involved in the LR asymmetric looping of the anterior-midgut (AMG) in Drosophila. Mutant embryos of puckered (puc), which encodes a D-JNK phosphatase, showed random laterality of the AMG. Directional LR looping of the AMG required D-JNK signaling to be down-regulated by puc in the trunk visceral mesoderm. Not only the down-regulation, but also the activation of D-JNK signaling was required for the LR asymmetric looping. We also found that the LR asymmetric cell rearrangement in the circular visceral muscle (CVM) was regulated by D-JNK signaling and required for the LR asymmetric looping of the AMG. Rac1, a Rho family small GTPase, augmented D-JNK signaling in this process. Our results also suggest that a basic mechanism for eliciting LR asymmetric gut looping may be conserved between vertebrates and invertebrates.     

Wnt3a links left-right determination with segmentation and anteroposterior axis elongation

The alignment of the left-right (LR) body axis relative to the anteroposterior (AP) and dorsoventral (DV) axes is central to the organization of the vertebrate body plan and is controlled by the node/organizer. Somitogenesis plays a key role in embryo morphogenesis as a principal component of AP elongation. How morphogenesis is coupled to axis specification is not well understood. We demonstrate that Wnt3a is required for LR asymmetry. Wnt3a activates the Delta/Notch pathway to regulate perinodal expression of the left determinant Nodal, while simultaneously controlling the segmentation clock and the molecular oscillations of the Wnt/beta-catenin and Notch pathways. We provide evidence that Wnt3a, expressed in the primitive streak and dorsal posterior node, acts as a long-range signaling molecule, directly regulating target gene expression throughout the node and presomitic mesoderm. Wnt3a may also modulate the symmetry-breaking activity of mechanosensory cilia in the node. Thus, Wnt3a links the segmentation clock and AP axis elongation with key left-determining events, suggesting that Wnt3a is an integral component of the trunk organizer.     

Patterning and morphogenesis of the vertebrate inner ear

The positional cues for formation of individual inner ear components are dependent on pre-established axial information conferred by inductive signals from tissues surrounding the developing inner ear. This review summarizes some of the known molecular pathways involved in establishing the three axes of the inner ear, anterior-posterior (AP), dorsal-ventral (DV) and medial-lateral (ML). Signals required to establish the AP axis of the inner ear are not known, but they do not appear to be derived from the hindbrain. In contrast, the hindbrain is essential for establishing the DV axis of the inner ear by providing inductive signals such as Wnts and Sonic hedgehog. Signaling from the hindbrain is also required for the formation of the ML axis, whereas formation of the lateral wall of the otocyst may be a result of first establishing both the AP and DV axes. In addition, this review addresses how genes induced within the otic epithelium as a result of axial specification continue to mediate inner ear morphogenesis.