用实验方法反转原肠胚外胚层细胞的极性(英文)

过去的工作指出,在紧密连接形成的时候,紧密连接本身也经历了极性化的过程,而且这一过程在时间上和囊胚腔的出现和扩张是相互关连的。为了进一步探讨紧密连接的极性化和外胚层细胞极性之间的关系,进行了原肠胚外胚层细胞内外反转的实验,结合扫描和透射电镜的观察,指出反转后的外胚层细胞表面发生了明显的变化,在原来没有紧密连接的内层细胞的外缘形成了发育完善的紧密连接。内外反转的这一实验操作,使外胚层细胞和内外环境的关系发生了变化。很可能外胚层细胞的极性先发生了反转,然后影响紧密连接在新的向外的一极形成。     

Oral—aboral ectoderm differentiation of sea urchin embryos is disrupted in response to calcium ionophore

Intracellular signaling mediated by calcium ions has been implicated as important in controlling cell activity. The ability of calcium ionophore (A23187), which causes an increase in calcium ion concentration in the cytoplasm, to alter the pattern of differentiation of cells during sea urchin development was examined. The addition of A23187 to embryos for 3h during early cleavage causes dramatic changes in their development during gastrulation. Using tissue-specific cDNA probes and antibodies, it was shown that A23187 causes the disruption of oral–aboral ectoderm differentiation of sea urchin embryos. The critical period for A23187 to disturb the oral–aboral ectoderm differentiation is during the cleavage stage, and treatment of embryos with A23187 after that time has little effect. The A23187 does not affect the formation of the three germ layers. These results indicate that intracellular signals mediated by calcium ions may play a key role in establishment of the oralaboral axis during sea urchin development.     

Adaptation morphologique de l'acrorrhage chez Actinia equina L.

Résumé L'analyse ultra-structurale de l'acrorrhage d'Actinia equina L. a permis de montrer une adaptation histologique au décollement de l'ectoderme lors de la réponse de l'actinie à une agression. La zone basale et digitée des cellules ectodermiques est très vacuolisée. La turgescence de l'acrorrhage provoque une extension de la mésoglée; on observe un écartement des bases cellulaires et la rupture des vésicules facilite la séparation de l'ectoderme et de la mésoglée. Celle-ci a lieu après ancrage des nématocystes atriches dans les tissus de l'agresseur, et retrait de l'Actinie.

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Morphological adaptation of the acrorhagi of Actinia equina L.

Summary The ultrastructural analysis of the acrorhagi of Actinia equina reveals histological adaptations to the specific detachment of this brightly colored strip of ectoderm in case of being attached. The basal zone of the ectoderm cells is highly vacuolated. The turgidity of the acrorhagous provokes an extension of the mesoglea. The separation of the ectoderm is facilitated by rupture of the vacuoles and the specific arrangement of the filament containing branched bases of the cells. When the ectoderm, which contains numerous nematocysts, is fixed in the tissue of a agressor, this one detaches.

     

Dorsoventral differential distribution of collagen type XIV around the spinal cord is regulated by the ectoderm

Regional specification in the nervous system is a critical issue in nervous system morphogenesis. Along the dorsoventral axis of the spinal cord, ventral inductive signals of the notochord and floor plate, and dorsal ones of the epidermal ectoderm are essential. Collagen type XIV is uniquely distributed around the spinal cord with a gradient of dorsal high and ventral low at the early developmental stages of the chick embryo. In the present study it was found that collagen type XIV expression around the spinal cord was entirely regulated by the ectoderm and that even the ventralizing tissues, the notochord and floor plate, themselves could be influenced to express this molecule by the ectoderm.     

Elf5 regulation in the trophectoderm

Mouse Elf5 is expressed exclusively in the trophectoderm from the late blastocyst stage to postgastrulation. We demonstrate here that the proximal promoter is used for trophectoderm expression but is not sufficient on its own. In transgenic assays, deletion of a differentially methylated region (DMR) within the promoter has no effect on the activation and maintenance of trophectoderm expression and does not result in ectopic activity. Two redundant enhancers drive Elf5 expression to the extraembryonic ectoderm and ectoplacental cone. The enhancers, located in the 5′ half of intron 1 and 3′ half of intron 2, require the presence of 1.8 kbp, although not the DMR, of the endogenous proximal promoter for optimal activity. These trophectoderm enhancers are mouse specific. A cattle Elf5 BAC reporter transgene is not expressed in mouse trophectoderm although it is expressed in skin, a known foetal domain of mouse Elf5 expression. The established importance of Elf5 for mouse trophectoderm at pre- and perigastrulation stages is not a conserved mammalian feature as Elf5 expression localises to embryonic as opposed to trophectodermal ectoderm in cattle.     

Salivary gland stem cells: A review of development,regeneration and cancer

Salivary glands are responsible for maintaining the health of the oral cavity and are routinely damaged by therapeutic radiation for head and neck cancer as well as by autoimmune diseases such as Sjögren's syndrome. Regenerative approaches based on the reactivation of endogenous stem cells or the transplant of exogenous stem cells hold substantial promise in restoring the structure and function of these organs to improve patient quality of life. However, these approaches have been hampered by a lack of knowledge on the identity of salivary stem cell populations and their regulators. In this review we discuss our current knowledge on salivary stem cells and their regulators during organ development, homeostasis and regeneration. As increasing evidence in other systems suggests that progenitor cells may be a source of cancer, we also review whether these same salivary stem cells may also be cancer initiating cells.     

Specific induction of cranial placode cells from Xenopus ectoderm by modulating the levels of BMP,Wnt, and FGF signaling

The neural–epidermal boundary tissues include the neural crest and preplacodal ectoderm (PPE) as primordial constituents. The PPE region is essential for the development of various sensory and endocrine organs, such as the anterior lobe of the pituitary, olfactory epithelium, lens, trigeminal ganglion, and otic vesicles. During gastrulation, a neural region is induced in ectodermal cells that interacts with mesendodermal tissue and responds to several secreted factors. Among them, inhibition of bone morphogenetic protein (BMP) in the presumptive neuroectoderm is essential for the induction of neural regions, and formation of a Wnt and fibroblast growth factor (FGF) signaling gradient along the midline determines anterior–posterior patterning. In this study, we attempted to specifically induce PPE cells from undifferentiated Xenopus cells by regulating BMP, Wnt, and FGF signaling. We showed that the proper level of BMP inhibition with an injection of truncated BMP receptor or treatment with a chemical antagonist triggered the expression of PPE genes. In addition, by varying the amount of injected chordin, we optimized specific expression of the PPE genes. PPE gene expression is increased by adding an appropriate dose of an FGF receptor antagonist. Furthermore, co‐injection with either wnt8 or the Wnt inhibitor dkk‐1 altered the expression levels of several region‐specific genes according to the injected dose. We specifically induced PPE cell differentiation in animal cap cells from early‐stage Xenopus embryos by modulating BMP, Wnt, and FGF signaling. This is not the first research on placode induction, but our simple method could potentially be applied to mammalian stem cell systems. genesis 53:652–659, 2015. © 2015 Wiley Periodicals, Inc.     

Cell proliferation in ectodermal explants from Xenopus embryos

Summary Dissociated prospective ectoderm cells from Xenopus laevis embryos divide autonomously up to the 17th division cycle of the embryo. To examine the requirements for the further proliferation of these cells, the continuation of cell division in compact ectodermal explants beyond the 17th division cycle has been studied. Such explants develop into aggregates of epidermal cells, as can be shown immunohistochemically with an anti-serum against Xenopus epidermal cytokeratin. Cell division in these explants is comparable to the in vivo proliferation rate at least during the first 24 h of cultivation, that is, well beyond the 17th division cycle. Thus, epidermal cells are provided with all the factors necessary for continued proliferation, but these can be effective only when the cells form tight aggregates. The long-term changes in cell number are complex. Mitotic figures are present until the explants disintegrate after 3–4 days. However, the total cell number per explant does not increase during later development. The production of cells by mitotic divisions is likely to be countered by the loss of cells due to cell death, which is indicated by the presence of pyknotic nuclei.