Ci-FoxA-a is the earliest zygotic determinant of the ascidian anterior ectoderm and directly activates Ci-sFRP1/5

This work focuses on the anteroposterior patterning of the ectoderm in the invertebrate chordate Ciona intestinalis. Previous work indicated that, by the eight-cell stage, the anterior and posterior animal blastomeres have acquired different properties, including a differential responsiveness to inducing signals from the underlying mesendoderm. Here, we investigated the molecular basis of this distinction. For this, we studied the regulation of the earliest marker specific for the anterior ectoderm, Ci-sFRP1/5, which is activated at the 64-cell stage. We first found that the activation of this marker in the anterior ectoderm does not involve communication with other lineages. We then identified, by phylogenetic footprinting and deletion analysis, a short conserved minimal enhancer driving the onset of expression of Ci-sFRP1/5. We showed that this enhancer was a direct target of the Ci-FoxA-a gene, a FoxA/HNF3 orthologue expressed in anterior ectodermal and mesendodermal lineages from the eight-cell stage. Gain- and loss-of-function experiments revealed that Ci-FoxA-a is necessary and sufficient within the ectoderm to impose an ectodermal anterior identity, and to repress the posterior programme. Thus, Ci-FoxA-a constitutes a major early zygotic anterior determinant for the ascidian ectoderm, acting autonomously in this territory, prior to the onset of vegetal inductions. Interestingly, while vertebrate FoxA2 are also involved in the regionalization of the ectoderm, they are thought to act during gastrulation to control, in the mesendoderm, the expression of organizer signals. We discuss the evolution of chordate ectodermal patterning in light of our findings.     

Neural tissue in ascidian embryos is induced by FGF9/16/20, acting via a combination of maternal GATA and Ets transcription factors

In chordates, formation of neural tissue from ectodermal cells requires an induction. The molecular nature of the inducer remains controversial in vertebrates. Here, using the early neural marker Otx as an entry point, we dissected the neural induction pathway in the simple embryos of Ciona intestinalis. We first isolated the regulatory element driving Otx expression in the prospective neural tissue, showed that this element directly responds to FGF signaling and that FGF9/16/20 acts as an endogenous neural inducer. Binding site analysis and gene loss of function established that FGF9/16/20 induces neural tissue in the ectoderm via a synergy between two maternal response factors. Ets1/2 mediates general FGF responsiveness, while the restricted activity of GATAa targets the neural program to the ectoderm. Thus, our study identifies an endogenous FGF neural inducer and its early downstream gene cascade. It also reveals a role for GATA factors in FGF signaling.     

Regulatory signals and signal molecules in early neurogenesis of Drosophila melanogaster

Summary The ectodermal germ layer of Drosophila melanogaster gives rise to two major cell lineages, the neural and the epidermal. Progenitor cells for each of these lineages arise from groups of cells, whose elements must decide between taking on either fate. Commitment of the progenitor cells to one of the developmental fates implies two factors. One is intrinsic to the ectodermal cells and determines a propensity to take on neural fate; this factor is probably represented by the products of the so-called proneural genes, which are differentially distributed throughout the ectoderm. The other factor in the cells' decision to adopt one of the two alternative fates is intercellular communication, which is mediated by the products of the so-called neurogenic genes. Two types of interactions, one inhibiting and the other stimulating neural development, have been inferred. We discuss here the assumed role of various neurogenic genes, in particular Notch and Delta, in these processes. Offprint requests to: J.A. Campos-Ortega     

Difference in the maternal and zygotic contributions of tumorhead on embryogenesis

Tumorhead (TH) is a maternally expressed gene in Xenopus laevis, that when overexpressed, increased proliferation of ectodermal derivatives and inhibited neural and epidermal differentiation. However, injection of anti-TH antibodies inhibited cleavage of all blastomeres, not only those contributing to the ectoderm. The injection of TH morpholino antisense oligonucleotide (TH-MO), which inhibits translation of TH mRNA, did not affect early cleavage but inhibited cell division in both the neural field and epidermis. This was accompanied by the inhibition of neural and epidermal markers. TH-MO did not affect the formation and differentiation of mesoderm and endoderm derivatives. Our overexpression and loss-of-function studies demonstrated that TH plays an important role in differentiation of the ectoderm by regulating cell proliferation. They also supported the conclusion that the maternal component of TH may affect the cell cycle in all cells, while the zygotic component has a germ layer-specific effect on the ectoderm.     

Ectodermal factor restricts mesoderm differentiation by inhibiting p53

During gastrulation of the amphibian embryo, specification of the three germ layers, endo-, ecto-, and mesoderm, is regulated by maternal and zygotic mechanisms. Although it is known that mesoderm specification requires the cooperation between TGF-beta signaling and p53 activity and requires maternal factors, essential zygotic factors have been elusive. Here, we report that the Zn-finger protein XFDL156 is an ectodermal, zygotic factor that suppresses mesodermal differentiation. XFDL156 overexpression suppresses mesodermal markers, and its depletion induces aberrant mesodermal differentiation in the presumptive ectoderm. Furthermore, we find that XFDL156 and its mammalian homologs interact with the C-terminal regulatory region of p53, thereby inhibiting p53 target gene induction and mesodermal differentiation. Thus, XFDL156 actively restricts mesodermal differentiation in the presumptive ectoderm by controlling the spatiotemporal responsiveness to p53.     

Different spatial distribution of mRNAs for activin receptors (type IIA and IIB) and follistatin in developing embryos of Xenopus laevis

Spatial distribution of mRNAs for activin receptors and follistatin was studied by Northern blot hybridization using RNAs from different parts of dissected Xenopus embryos. mRNAs of two activin receptors (type IIA and IIB) occurred uniformly in pre-gastrular embryos, but occurred in larger amounts in ectoderm (in gastrulae), neural plate (in neurulae) and anterior (head) regions (in tailbud embryos) than in other embryonic regions. By contrast, follistatin mRNA appeared almost exclusively in the dorsal mesoderm including invaginating organizer region at the gastrula stage, in notochord and in dorsal ectoderm at the neurula stage, then in anterior part at the tailbud stage. The localized patterns of the distribution of these mRNAs may be due to the regionally different zygotic expression of genes in embryos at later stages. From the relatively widespread pattern of distribution of their mRNAs, we assume that both type IIA and type IIB activin receptors have broad functions in ectodermal and neural differentiation. On the other hand, follistatin mRNA showed quite a restricted pattern of expression, and therefore, we assume that follistatin may have functions more specifically related to the sites of expression of its mRNA. Thus, follistatin may be involved in the differentiation of notochord itself and/or directly be responsible for organizer functions such as neural induction and subsequent differentiation of induced neural tissues at the gastrula and later stages.     

Identification and characterization of Xenopus kctd15, an ectodermal gene repressed by the FGF pathway

The FGF pathway regulates a variety of developmental processes in animals through activation and/or repression of numerous target genes. Here we have identified a Xenopus homolog of potassium channel tetramerization domain containing 15 (KCTD15) as an FGF-repressed gene. Kctd15 expression is first detected at the gastrula stage and gradually increases until the tadpole stage. Whole-mount in situ hybridization reveals that the spatial expression of kctd15 is tightly regulated during early embryogenesis. While kctd15 is uniformly expressed throughout the presumptive ectoderm at the early gastrula stage, its expression becomes restricted to the non-neural ectoderm and is excluded from the neural plate at the early neurula stage. At the mid-neurula stage, kctd15 shows a more restricted distribution pattern in regions that are located at the anterior, lateral or medial edge of the neural fold, including the preplacodal ectoderm, the craniofacial neural crest and the prospective roof plate. At the tailbud stage, kctd15 expression is mainly detected in neural crest- or placode-derived tissues that are located around the eye, including the mandibular arch, trigeminal ganglia and the olfactory placode. FGF represses kctd15 expression in ectodermal explants, and the inhibition of FGF receptor with a chemical compound dramatically expands the region expressing kctd15 in whole embryos. Dorsal depletion of kctd15 in Xenopus embryos leads to bent axes with reduced head structures, defective eyes and abnormal somites, while ventral depletion causes defects in ventral and caudal morphologies. These results suggest that kctd15 is an FGF-repressed ectodermal gene required for both dorsal and ventral development.     

多能性转录因子OCT4和SOX2在体外发育的小鼠2-细胞胚胎的表达与定位

为探讨多能性转录因子OCT4和SOX2在昆明小鼠(Mus musculus)2-细胞胚胎发育过程中与2-细胞胚胎阻滞发生的相关性,本研究应用实时荧光定量PCR技术检测了小鼠卵母细胞及在M16培养液中培养的不同发育阶段体外受精胚Oct4和Sox2基因的表达,并利用实时荧光定量PCR和免疫荧光技术比较了2-细胞胚、2-细胞阻滞胚和4-细胞胚的OCT4和SOX2的表达与定位。采用ANOVA对实验所得的数据进行分析,P0.05被认为是具有显著性差异。研究结果显示,2-细胞胚只有24.8%发育成4-细胞胚,75.2%的2-细胞胚发生了阻滞。Sox2和Oct4的m RNA在MⅡ期卵母细胞、原核胚、2-细胞胚、4-细胞胚、桑椹胚和囊胚中都有表达。Oct4 m RNA的表达水平在4-细胞胚显著高于2-细胞胚和2-细胞阻滞胚(P0.05),Sox2 m RNA的表达水平在2-细胞胚显著高于2-细胞阻滞胚和4-细胞胚(P0.05),而后两者之间没有差异(P0.05)。OCT4蛋白在2-细胞胚和4-细胞胚中与核共定位,但在2-细胞阻滞胚中弥散存在于胞质中。SOX2蛋白在以上3类胚胎中始终定位于细胞核。上述结果提示,转录因子OCT4和SOX2的表达和定位与小鼠2-细胞胚胎发育阻滞相关,母源性SOX2表达的维持对胚胎合子基因组激活(ZGA)的发生具有重要作用,母源性OCT4的异常定位可能影响了合子基因组激活相关基因的激活,而合子中Oct4的表达影响合子基因组激活后胚胎的发育。     

Modulation of neural commitment by changes in target cell contacts in Pleurodeles waltl

In amphibian development, neural structures arise from the presumptive ectoderm at the gastrula stage by an inductive interaction with the chordamesoderm. It has been previously reported that early gastrula presumptive ectoderm can be neuralized when it is dissociated into single cells. A similar result is reported here with regard to Pleurodeles waltl presumptive ectoderm. Using this experimental model system we demonstrate: first, that neuronal and glial lineages can be specified from the presumptive ectoderm without any intervention of the natural inducing tissue; and second, that whereas rupture of cell-cell contacts evoked neural induction, dissociation immediately followed by reaggregation reduces the neuralizing response, pointing toward an active role played by cell-cell contacts of presumptive ectodermal cells in the modulation of neural commitment.     

Nervous systems of the sea anemone Nematostella vectensis are generated by ectoderm and endoderm and shaped by distinct mechanisms

As a sister group to Bilateria, Cnidaria is important for understanding early nervous system evolution. Here we examine neural development in the anthozoan cnidarian Nematostella vectensis in order to better understand whether similar developmental mechanisms are utilized to establish the strikingly different overall organization of bilaterian and cnidarian nervous systems. We generated a neuron-specific transgenic NvElav1 reporter line of N. vectensis and used it in combination with immunohistochemistry against neuropeptides, in situ hybridization and confocal microscopy to analyze nervous system formation in this cnidarian model organism in detail. We show that the development of neurons commences in the ectoderm during gastrulation and involves interkinetic nuclear migration. Transplantation experiments reveal that sensory and ganglion cells are autonomously generated by the ectoderm. In contrast to bilaterians, neurons are also generated throughout the endoderm during planula stages. Morpholino-mediated gene knockdown shows that the development of a subset of ectodermal neurons requires NvElav1, the ortholog to bilaterian neural elav1 genes. The orientation of ectodermal neurites changes during planula development from longitudinal (in early-born neurons) to transverse (in late-born neurons), whereas endodermal neurites can grow in both orientations at any stage. Our findings imply that elav1-dependent ectodermal neurogenesis evolved prior to the divergence of Cnidaria and Bilateria. Moreover, they suggest that, in contrast to bilaterians, almost the entire ectoderm and endoderm of the body column of Nematostella planulae have neurogenic potential and that the establishment of connectivity in its seemingly simple nervous system involves multiple neurite guidance systems.