Regulation of heart size in Xenopus laevis

The region with the potential to form the heart has traditionally been called the heart field. This region can be approximated by, but is not identical to, the expression domain of the early cardiac gene Nkx2.5. The region expressing Nkx2.5 does not change in size, although there are major shape changes and a subdivision of the region into non-myogenic and myogenic lineages. Using a variety of embryo manipulations, we have sought to determine whether cellular interactions could change the size of the initial Nkx2.5-expressing region and thus change the size of the heart. We have shown that if the heart is isolated from the dorsal half of the embryo, the volume of tissue expressing myocardial differentiation markers increases, indicating that signals restricting the size of the heart come from the dorsal side. Despite the change in myocardial volume, the non-myogenic heart lineages are still present. The ability of dorsal tissues to restrict the size of the heart is further demonstrated by fusing two Xenopus embryos shortly after gastrulation, generating twinned embryos where the heart of one embryo would develop adjacent to different tissues of the second embryo. The final size of the differentiated heart was markedly reduced if it developed in close proximity to the dorso-anterior surface of the head but not if it developed adjacent to the flank or belly. In all cases, the manipulations that restricted the size of the myocardium also restricted the expression of Nkx2.5 and GATA-4, both key regulatory genes in the cardiogenic pathway. These results provide evidence for a model in which signals from dorso-anterior tissues restrict the size of the heart after gastrulation but before neural fold closure.     

Second heart field and the development of the outflow tract in human embryonic heart

The second heart field (SHF) is indicated to contribute to the embryonic heart development. However, less knowledge is available about SHF development of human embryo due to the difficulty of collecting embryos. In this study, serial sections of human embryos from Carnegie stage 10 (CS10) to CS16 were stained with antibodies against Islet‐1 (Isl‐1), Nkx2.5, GATA4, myosin heavy chain (MHC) and α‐smooth muscle actin (α‐SMA) to observe spatiotemporal distribution of SHF and its contribution to the development of the arterial pole of cardiac tube. Our findings suggest that during CS10 to CS12, SHF of the human embryo is composed of the bilateral pharyngeal mesenchyme, the central mesenchyme of the branchial arch and splanchnic mesoderm of the pericardial cavity dorsal wall. With development, SHF translocates and consists of ventral pharyngeal mesenchyme and dorsal wall of the pericardial cavity. Hence, the SHF of human embryo shows a dynamic spatiotemporal distribution pattern. The formation of the Isl‐1 positive condense cell prongs provides an explanation for the saddle structure formation at the distal pole of the outflow tract. In human embryo, the Isl‐1 positive cells of SHF may contribute to the formation of myocardial outflow tract (OFT) and the septum during different development stages.     

Dorsal and lateral fates in the mouse neural tube require the cell-autonomous activity of the open brain gene

The processes that specify early regional identity in dorsal and lateral regions of the mammalian neural tube are not well understood. The mouse open brain (opb) gene plays an essential role in dorsal neural patterning: in the caudal spinal cord of opb mutants, dorsal cell types are absent and markers of ventral fates, including Shh, expand into dorsal regions. Analysis of the opb mutant phenotype and of opb/opb <--> wild-type chimeric embryos reveals that early in neural development, the wild-type opb gene (opb(+)) is required cell autonomously for the expression of Pax7 in dorsal cells and Pax6 in lateral cells. Thus the opb(+) gene product acts intracellularly in the reception or interpretation of signals that determine cell types in the dorsal 80% of the neural tube. At later stages, the lack of opb(+) causes a non-cell-autonomous expansion of ventral cell types into dorsal regions of the neural tube, revealing that opb(+) controls the production of a diffusible molecule that defines the domain of Shh expression. The data indicate that opb(+) could act as either a novel component of a dorsalizing pathway or a novel intracellular negative regulator of the Shh signal transduction pathway.     

Pericardin,a Drosophila type IV collagen-like protein is involved in the morphogenesis and maintenance of the heart epithelium during dorsal ectoderm closure

The steps that lead to the formation of a single primitive heart tube are highly conserved in vertebrate and invertebrate embryos. Concerted migration of the two lateral cardiogenic regions of the mesoderm and endoderm (or ectoderm in invertebrates) is required for their fusion at the midline of the embryo. Morphogenetic signals are involved in this process and the extracellular matrix has been proposed to serve as a link between the two layers of cells. Pericardin (Prc), a novel Drosophila extracellular matrix protein is a good candidate to participate in heart tube formation. The protein has the hallmarks of a type IV collagen alpha-chain and is mainly expressed in the pericardial cells at the onset of dorsal closure. As dorsal closure progresses, Pericardin expression becomes concentrated at the basal surface of the cardioblasts and around the pericardial cells, in close proximity to the dorsal ectoderm. Pericardin is absent from the lumen of the dorsal vessel.Genetic evidence suggests that Prc promotes the proper migration and alignment of heart cells. Df(3)vin6 embryos, as well as embryos in which prc has been silenced via RNAi, exhibit similar and significant defects in the formation of the heart epithelium. In these embryos, the heart epithelium appears disorganized during its migration to the dorsal midline. By the end of embryonic development, cardial and pericardial cells are misaligned such that small clusters of both cell types appear in the heart; these clusters of cells are associated with holes in the walls of the heart. A prc transgene can partially rescue each of these phenotypes, suggesting that prc regulates these events. Our results support, for the first time, the function of a collagen-like protein in the coordinated migration of dorsal ectoderm and heart cells.     

A whole-mount immunocytochemical analysis of the expression of the intermediate filament protein vimentin in Xenopus

We have developed a whole-mount immunocytochemical method for Xenopus and used it to map the expression of the intermediate filament protein vimentin during early embryogenesis. We used two monoclonal antibodies, 14h7 and RV202. Both label vimentin filaments in Xenopus A6 cells, RV202 reacts specifically with vimentin (Mr, 55 x 10(3] on Western blots of A6 cells and embryos. 14h7 reacts with vimentin and a second, insoluble polypeptide of 57 x 10(3) Mr found in A6 cells. The 57 x 10(3) Mr polypeptide appears to be an intermediate filament protein immunochemically related to vimentin. In the whole-mount embryo, we first found vimentin at the time of neural tube closure (stage 19) in cells located at the lateral margins of the neural tube. By stage 26, these cells, which are presumably radial glia, are present along the entire length of the neural tube and in the tail bud. Cells in the optic vesicles express vimentin by stage 24. Vimentin-expressing mesenchymal cells appear on the surface of the somites at stage 22/23; these cells appear first on anterior somites and on progressively more posterior somites as development continues. Beginning at stage 24, vimentin appears in mesenchymal cells located ventral to the somites and associated with the pronephric ducts; these ventral cells first appear below the anterior somites and later appear below more posterior somites. The dorsal fin mesenchyme expresses vimentin at stage 26. In the head, both mesodermally-derived and neural-crest-derived mesenchymal tissues express vimentin by stage 26. These include the mesenchyme of the branchial arches, the mandibular arch, the corneal epithelium, the eye, the meninges and mesenchyme surrounding the otic vesicle. By stage 33, vimentin-expressing mesenchymal cells are present in the pericardial cavity and line the vitelline veins. Vimentin expression appears to be a marker for the differentiation of a subset of central nervous system cells and of head and body mesenchyme in the early Xenopus embryo.     

Nodal-related signals establish mesendodermal fate and trunk neural identity in zebrafish

The vertebrate body plan arises during gastrulation, when morphogenetic movements form the ectoderm, mesoderm, and endoderm. In zebrafish, mesoderm and endoderm derive from the marginal region of the late blastula, and cells located nearer the animal pole form the ectoderm [1]. Analysis in mouse, Xenopus, and zebrafish has demonstrated that Nodal-related proteins, a subclass of the TGF-beta superfamily, are essential for mesendoderm development [2], but previous mutational studies have not established whether Nodal-related signals control fate specification, morphogenetic movements, or survival of mesendodermal precursors. Here, we report that Nodal-related signals are required to allocate marginal cells to mesendodermal fates in the zebrafish embryo. In double mutants for the zebrafish nodal-related genes squint (sqt) and cyclops (cyc) [3] [4] [5], dorsal marginal cells adopt neural fates, whereas in wild-type embryos, cells at this position form endoderm and axial mesoderm. Involution movements characteristic of developing mesendoderm are also blocked in the absence of Nodal signaling. Because it has been proposed [6] that inhibition of Nodal-related signals promotes the development of anterior neural fates, we also examined anteroposterior organization of the neural tube in sqt;cyc mutants. Anterior trunk spinal cord is absent in sqt;cyc mutants, despite the presence of more anterior and posterior neural fates. These results demonstrate that nodal-related genes are required for the allocation of dorsal marginal cells to mesendodermal fates and for anteroposterior patterning of the neural tube.     

Developmentally regulated expression and functional role of alpha 7 integrin in the chick embryo

Integrin alpha 7 beta 1 is a specific cellular receptor for laminin. In the present work, we studied the distribution pattern of the alpha 7 subunit by immunofluorescence and immunoprecipitation and the role of the integrin by blocking antibodies in early chick embryos. alpha 7 immunoreactivity was first detectable in the neural plate during neural furrow formation (stage HH5, early neurula, Hamburger & Hamilton 1951) and its expression was upregulated in the neural folds during primary neurulation. The alpha 7 expression domain spanned the entire neural tube by stage HH8 (4 somites), and was then downregulated and confined to the neuroepithelial cells in the germinal region near the lumen and the ventrolateral margins of the neural tube in embryos by the onset of stage HH17 (29 somites). Expression of alpha 7 in the neural tube was transient suggesting that alpha 7 functions during neural tube closure and axon guidance and may not be required for neuronal differentiation or for the maintenance of the differentiated cell types. alpha 7 immunoreactivity was strong in the newly formed epithelial somites, although this expression was restricted only to the myotome in the mature somites. The most intense alpha 7 immunoreactivity was detectable in the paired heart primordia and the endoderm apposing the heart primordia in embryos at stage HH8. In the developing heart, alpha 7 immunoreactivity was: (i) intense in the myocardium; (ii) milder in the endocardial cushions of the ventricle; (iii) intense in the sinus venosus; (iv) distinct in the associated blood vessels; and (v) undetectable in the dorsal mesocardium of embryos at stage HH17. Inhibition of function of alpha 7 by blocking antibodies showed that alpha 7 integrin-laminin signaling may play a critical role in tissue organization of the neural plate and neural tube closure, in tissue morphogenesis of the heart tube but not in the directional migration of pre-cardiac cells, and in somite epithelialization but not in segment formation in presomitic mesoderm. In embryos treated with alpha 7 antibody, the formation of median somites in place of a notochord was intriguing and suggested that alpha 7 integrin-laminin signaling may have played a role in segment re-specification in the mesoderm.     

Positive and Negative Regulation of the Differentiation of Ventral Mesoderm for Erythrocytes in Xenopus laevis

To elucidate the mechanism of determination and regulation of hemopoiesis in the early Xenopus embryo, explants of dorsal and ventral mesoderm from various stage embryos were cultured alone or combined with various tissues derived from the same stage embryo. Western blot analysis of larvae-specific globin expression using monoclonal antibody L5.41 revealed that extensive erythropoiesis occurred in the explants of ventral mesoderm from st. 22 tailbud embryo, but not in those of dorsal mesoderm. Experiments using combined explants at this stage demonstrated that the in vitro differentiation of erythrocytes in the ventral mesoderm could be completely inhibited by the dorsal tissue, including neural tube, notochord, and somite mesoderm, but not by other mesoderms, gut endoderm, or forebrain. Subsequent explant studies showed that the notochord alone is sufficient for this inhibition. Furthermore, the ventral mesoderm explant from the st. 10⁺ early gastrula embryo was not able to differentiate into erythroid cells. However, small amounts of globin were expressed if ventral mesoderm of this stage was combined with animal pole cells which were mainly differentiated to epidermis. This stimulation was enhanced when both tissues were excised together without separation, while none of the other parts of st. 10⁺ embryo had this stimulatory effect. These observations found in the combined explants suggest that in vivo interactions between the ventral mesoderm and adjacent tissues are important for normal development of erythroid precursor cells.     

Myocardial cell relationships during morphogenesis in normal and cardiac lethal mutant axolotls, Ambystoma mexicanum

Sarcomere formation has been shown to be deficient in the myocardium of axolotl embryos homozygous for the recessive cardiac lethal gene c. We examined the developing hearts of normal and cardiac mutant embryos from tailbud stage 33 to posthatching stage 43 by scanning electron microscopy in order to determine whether that deficiency has any effect on heart morphogenesis. Specifically, we investigated the relationships of myocardial cells during the formation of the heart tube (stage 33), the initiation of dextral looping (stages 34-36), and the subsequent flexure of the elongating heart (stages 38-43). In addition, we compared the morphogenetic events in the axolotl to the published accounts of comparable stages in the chick embryo. In the axolotl (stage 33), changes in cell shape and orientation accompany the closure of the myocardial trough to form the tubular heart. The ventral mesocardium persists longer in the axolotl embryo than in the chick and appears to contribute to the asymmetry of dextral looping (stages 34-36) in two ways. First, as a persisting structure it places constraints on the simple elongation of the heart tube and the ability of the heart to bend. Second, after it is resorbed, the ventral myocardial cells that contributed to it are identifiable by their orientation, which is orthogonal to adjacent cells: a potential source of shearing effects. Cardiac lethal mutant embryos behave identically during these events, indicating that functional sarcomeres are not necessary to these processes. The absence of dynamic apical myocardial membrane changes, characteristic of the chick embryo (Hamburger and Hamilton stages 9-11), suggests that sudden hydration of the cardiac jelly is less likely to be a major factor in axolotl cardiac morphogenesis. Subsequent flexure (stages 38-43) of the axolotl heart is the same in normal and cardiac lethal mutant embryos as the myocardial tube lengthens within the confines of a pericardial cavity of fixed length. However, the cardiac mutant begins to exhibit abnormalities at this time. The lack of trabeculation (normally beginning at stage 37) in the mutant ventricle is evident at the same time as an increase in myocardial surface area, manifest in extra bends of the heart tube at stage 39. Nonbeating mutant hearts (stage 41) have an abnormally large diameter in the atrioventricular region, possibly the result of the accumulation of ascites fluid. In addition, mutant myocardial cells have a larger apical surface area compared to normals.     

Epaxial-adaxial-hypaxial regionalisation of the vertebrate somite: evidence for a somitic organiser and a mirror-image duplication

During vertebrate neural tube formation, the initially lateral borders between the neural and epidermal ectoderm fuse to form the definitive dorsal region of the embryo, while the initially dorsally located notochord-floor plate complex is being internalised. Along the definitive dorso-ventral body axis, one can distinguish an epaxial (dorsal to the notochord) and a hypaxial (ventral to the notochord) body region. The mesodermal somites on both sides of the notochord and neural tube give rise to the trunk skeleton and skeletal muscle. Muscle forms from the somite-derived dermomyotomes and myotomes that elongate dorsally and ventrally. Based on gene expression patterns and comparative embryology, it is proposed here that the epaxial (dermo)myotome region in amniote embryos is subdivided into a dorsalmost and a centrally intercalated subregion. The intercalated subregion abuts to the hypaxial (dermo)myotome region that elongates ventrally via the hypaxial somitic bud. The dorsalmost subregion elongates towards the dorsal neural tube and is proposed to derive from an epaxial somitic bud. The dorsalmost and hypaxial somite derivatives share specific gene expression patterns which are distinct from those of the intercalated somite derivatives. The intercalated somite derivatives develop adaxially, i.e. at the level of the notochord-floor plate complex. Thus, the dorsalmost and intercalated (dermo)myotome subregions may be influenced preferentially by signals from the dorsal neural tube and from the notochord-floor plate complex, respectively. These (dermo)myotome subregions are sharply delimited from each other by molecular boundary markers, including Engrailed and Wnts. It thus appears that the molecular network that polarises borders in Drosophila and vertebrate embryogenesis is redeployed during subregionalisation of the (dermo)myotome. It is proposed here that cells within the amniote (dermo)myotome establish polarised borders with organising capacity, and that the epaxial somitic bud represents a mirror-image duplication of the hypaxial somitic bud along such a border. The resulting epaxial-intercalated/adaxial-hypaxial regionalisation of somite derivatives is conserved in vertebrates although the differentiation of sclerotome and myotome starts heterochronically in embryos of different vertebrate groups.     

Dorsalization of the neural tube by Xenopus tiarin, a novel patterning factor secreted by the flanking nonneural head ectoderm

We have isolated a novel secreted dorsalizing factor of the neural tube, Xenopus Tiarin, which belongs to the olfactomedin-related family. Tiarin expression starts at the late gastrula stage in the nonneural ectoderm adjacent to the anterior neural plate. Overexpression of Tiarin in the embryo causes expansion of dorsal neural markers and suppression of ventral markers. In the eye-forming field, Tiarin overexpression induces the retinal markers and represses optic stalk markers. Tiarin directly dorsalizes neural tissues in the absence of mesodermal tissues and antagonizes the ventralizing activity of Sonic hedghog (Shh). Unlike BMP4, another dorsalizing factor, Tiarin does not display antineuralizing activity on the ectoderm or mesoderm-ventralizing activity. These findings show that Tiarin is a novel patterning signal candidate acting in the specification of the dorsal neural tube.     

Cell lineage analysis of neural induction: origins of cells forming the induced nervous system

Horseradish peroxidase (HRP) was used as an intracellular lineage tracer in two experiments designed to reveal the sites of origin of cells that formed the duplicate embryo which developed in relation to an organizer grafted in the ventral marginal zone (VMZ) of Xenopus laevis embryos. In the first experiment a dorsal blastoporal lip fully labeled with HRP was grafted in the VMZ of an unlabeled embryo at the beginning of gastrulation. This resulted in development of a second embryo in which labeled cells, of graft origin, formed the notochord, and parts of the somites, endoderm, and neural tube. The second experiment was designed to show the sites of origin of the host's cells that formed parts of the induced embryo. HRP was injected into individual blastomeres in a series of Xenopus embryos at the 32-cell stage and each embryo received an unlabeled organizer graft in the VMZ at the beginning of gastrulation. In these embryos the lineages that contributed to the host's primary neural tube did not contribute any cells to the induced neural tube. All the cells in the induced neural tube which originated from the host were descendants of ventral blastomeres that did not contribute to the neural tube normally. This shows that the second neural tube is formed as a result of the action of the organizer on cells in its immediate vicinity which would not normally have entered neural pathways of differentiation.     

低氧对斑马鱼胚胎心脏和血管发育及相关基因表达的影响

研究以斑马鱼(Danio rerio)为研究模型,选择心脏和血管荧光标记的2个品系斑马鱼为实验材料,设定低氧和常氧2种水体溶氧条件,用荧光显微镜检测低氧胁迫对胚胎形态结构、心脏和血管外部形态、心率、胚胎躯干部主要血管形成的影响.研究发现低氧导致胚胎存活率低于常氧.低氧不仅滞后胚胎发育,而且造成胚胎形态异常.低氧胁迫后斑...     

Reduction of XNkx2-10 expression leads to anterior defects and malformation of the embryonic heart

Normal vertebrate heart development depends upon the expression of homeodomain containing proteins related to the Drosophila gene, tinman. In Xenopus laevis, three such genes have been identified in regions that will eventually give rise to the heart, XNkx2-3, XNkx2-5 and XNkx2-10. Although the expression domains of all three overlap in early development, distinctive differences have been noted. By the time the heart tube forms, there is little XNkx2-10 mRNA detected by in situ analysis in the embryonic heart while both XNkx2-3 and XNkx2-5 are clearly present. In addition, unlike XNkx2-3 and XNkx2-5, injection of XNkx2-10 mRNA does not increase the size of the embryonic heart. We have reexamined the expression and potential role of XNkx2-10 in development via oligonucleotide-mediated reduction of XNkx2-10 protein expression. We find that a decrease in XNkx2-10 leads to a broad spectrum of developmental abnormalities including a reduction in heart size. We conclude that XNkx2-10, like XNkx2-3 and XNkx2-5, is necessary for normal Xenopus heart development.