Role of cooperative cell movements and mechano-geometric constrains in patterning of axial rudiments in <Emphasis Type="Italic">Xenopus laevis</Emphasis> embryos

The role of cooperative cell movements has been explored in establishment of regular segregation of the marginal zone of Xenopus laevis embryos into the main axial rudiments: notochord, somites and neural tissue. For this purpose, the following operations were performed at the late blastula-early gastrula stages: (1) isolation of marginal zones, (2) addition of the ventral zone fragments to the marginal zones, (3) dissection of isolated marginal zones along either ventral (a) or dorsal (b) midlines, (4) immediate retransplantation of excised fragments of the suprablastoporal area to the same places without rotation or after 90° rotation, (5) Π-shaped separation of the suprablastoporal area either anteriorly or posteriorly. In experiments 1, 4, and 5, lateromedial convergent cell movements and differentiation of the axial rudiments were suppressed. In experiments 4 and 5, cell movements were reoriented ventrally, the entire embryo architecture was extensively reconstructed, and the axial rudiments were relocated to the blastopore lateral lips. In experiment 3, convergent cell movements were restored and oriented either towards the presumptive embryo midline (a), or in the perpendicular direction (b). In both cases, well developed axial rudiments elongated perpendicularly to cell convergences were formed. If the areas of axial rudiment formation were curved, mesodermal somites and neural tissue were always located on the convex (stretched) and concave (compressed) sides, respectively. We conclude that no stable prepatterning of the marginal zone takes place until at least the midgastrula stage. This prepatterning requires cooperative cell movements and associated mechano-geometric constrains.     

Spatial-temporal dynamics of morphogenetic blastoderm potencies in early embryogenesis of the loach

The degree of differentiation of axial structures (notochord, neuroectoderm, and somites) in 24-hour explants (a total of 380) of the loach embryonic blastoderm was determined on histological sections according to a developed scale of estimates. Before the beginning of epiboly, axial structures were formed only from fragments of the dorsal sector of the blastoderm marginal zone. Its other sectors acquired the capacity of forming axial structure only with the beginning of epiboly, as the germ ring was formed in the marginal zone, unlike the cells outside the germ ring. The degree of differentiation of axial structures in the dorsal sector of marginal zone increased reliably with the appearance of embryonic shield, i.e. area of the convergence of cell flows. Here, statistically significant regional differences in morphogenetic potencies of the marginal zone first appeared, which corresponded to the differences in prospective significance of its materials; notochord and neuroectoderm better differentiate from the dorsal sector material, while somites better differentiate from the ventral sector material. Thus, distribution of morphogenetic potencies reflects precisely the spatial-temporal dynamics of collective movement of the blastoderm cells during the normal course of morphogenesis.     

Spatial-temporal dynamics of morphogenetic blastoderm potencies in early embryogenesis of the loach

The degree of differentiation of axial structures (notochord, neuroectoderm, and somites) in 24-hour explants (a total of 380) of the loach embryonic blastoderm was determined on histological sections according to a developed scale of estimates. Before the beginning of epiboly, axial structures were formed only from fragments of the dorsal sector of the blastoderm marginal zone. Its other sectors acquired the capacity of forming axial structure only with the beginning of epiboly, as the germ ring was formed in the marginal zone, unlike the cells outside the germ ring. The degree of differentiation of axial structures in the dorsal sector of marginal zone increased reliably with the appearance of embryonic shield, i.e. area of the convergence of cell flows. Here, statistically significant regional differences in morphogenetic potencies of the marginal zone first appeared, which corresponded to the differences in prospective significance of its materials; notochord and neuroectoderm better differentiate from the dorsal sector material, while somites better differentiate from the ventral sector material. Thus, distribution of morphogenetic potencies reflects precisely the spatial-temporal dynamics of collective movement of the blastoderm cells during the normal course of morphogenesis.     

Role of mechano-dependent cell movements in the establishment of spatial organization of axial rudiments in <Emphasis Type="Italic">Xenopus laevis</Emphasis> embryos

Trajectories of individual cell movements and patterns of differentiation in the axial rudiments in suprablastoporal areas (SBA) in whole embryos of Xenopus laevis artificially stretched in the transverse direction up to 120–200% from the initial length at the early gastrula stage were mapped. We observed the impairment of anisotropic cell movements of longitudinal stretching and latero-medial convergence inherent for SBA. Axial rudiments occurred in all cases, but their location was completely impaired and dramatically different from the normal topology for moderate (120–140%) stretching. Stronger stretching caused a partial ordering of the whole axial complex and its reorientation toward stretching. We concluded that induction factors determine short-range order in their arrangement in SBA, whereas anisotropic cell movements in any direction are needed for long-range order. Moderate transverse stretching destroys normally oriented anisotropy, but it is not enough for establishment of the anisotropy oriented perpendicular to the normal. This explains the disorder at light stretching. The main conclusion of this study is that anisotropic tensions of embryonic tissues play role of long-range order parameters of cell differentiation.     

Relocations of cell convergence sites and formation of pharyngula-like shapes in mechanically relaxed <Emphasis Type="Italic">Xenopus</Emphasis> embryos

Influence of the relaxation of mechanical tensions upon collective cell movements, shape formation, and expression patterns of tissue-specific genes has been studied in Xenopus laevis embryos. We show that the local relaxation of tensile stresses within the suprablastoporal area (SBA) performed at the early-midgastrula stage leads to a complete arrest of normal convergent cell intercalation towards the dorsal midline. As a result, SBA either remains nondeformed or protrudes a strip of cells migrating ventralwards along one of the lateral lips of the opened blastopore. Already, few minutes later, the tissues in the ventral lip vicinity undergo abnormal transversal contraction/longitudinal extension resulting in the abnormal cell convergence toward ventral (rather than dorsal) embryo midline. Within a day, the dorsally relaxed embryos acquire pharyngula-like shapes and often possess tail-like protrusions. Their antero-posterior and dorso-ventral polarity, as well as expression patterns of pan-neural (Sox3), muscular cardiac actin, and forebrain (Otx2) genes substantially deviate from the normal ones. We suggest that normal gastrulation is permanently controlled by mechanical stresses within the blastopore circumference. The role of tissue tensions in regulating collective cell movements and creating pharyngula-like shapes are discussed.     

Dorsal and ventral cells of cleavage-stage Xenopus embryos show the same ability to induce notochord and somite formation

Cells in the dorsal marginal zone of the amphibian embryo acquire the potential for mesoderm formation during the first few hours following fertilization. An examination of those early cell interactions may therefore provide insight on the mechanisms important for organization of axial structures. The formation of mesoderm (notochord, somites, and pronephros) was studied by combining blastomeres from the animal pole region of Xenopus embryos (32- to 512-cell stages) with blastomeres from different regions of the vegetal hemisphere. The frequency of notochord and somite development was similar in combinations made with dorsal or ventral blastomeres, or with both. Our results show that during early cleavage stages the ventral half of the vegetal hemisphere has the potential to organize axial structures, a property previously believed to be limited to the dorsal region.     

Formation of the dorsal marginal zone in Xenopus laevis analyzed by time-lapse microscopic magnetic resonance imaging

The dorsal marginal zone (DMZ) of the amphibian embryo is a key embryonic region involved in body axis organization and neural induction. Using time-lapse microscopic magnetic resonance imaging (MRI), we follow the pregastrula movements that lead to the formation of the DMZ of the stage 10 Xenopus embryo. 2D and 3D MRI time-lapse series reveal that pregastrular movements change the tissue architecture of the DMZ at earlier stages and in a different fashion than previously appreciated. Beginning at stage 9, epiboly of the animal cap moves tissue into the dorsal but not into the ventral marginal zone, resulting in an asymmetry between the dorsal and the ventral sides. Time-lapse imaging of labeled blastomeres shows that the animal cap tissue moves into the superficial DMZ overlying the deeper mesendoderm of the DMZ. The shearing of superficial tissue over the deeper mesendoderm creates the radial/vertical arrangement of ectoderm outside of mesendoderm within the DMZ, which is independent of involution and prior to the formation of the dorsal blastoporal lip. This tilting of the DMZ is distinct from, but occurs synchronously with, the vegetal rotation of the vegetal cell mass [R., Winklbauer, M., Schürfeld (1999). "Vegetal rotation, a new gastrulation movement involved in the internalization of the mesoderm and endoderm in Xenopus." Development. 126, 3703-3713.]. We present a revised model of gastrulation movements in Xenopus laevis.     

Mechanodependent cell movements in the axial rudiments of <Emphasis Type="Italic">Xenopus</Emphasis> gastrulae

Sandwich explants of the suprablastoporal area of Xenopus early-mid gastrula and same stages of entire embryos were stretched with two needles perpendicular to the direction of natural elongation of the axial rudiments. The changes in the embryonic shape and histological structure were monitored as well as the arrangement of descendants of one of dorsal blastomers labeled with fluorescein-dextran at the 16-cell stage. A substantial fraction of stretched explants reoriented along the applied stretch direction. The arrangement dynamics of fluorescein-dextran-labeled cells and explant shape demonstrate that this is an active response based on convergent intercalation of cells induced by stretching. Stretched gastrulae demonstrated arrested gastrulation, dorsoventral extension of the blastopore, and ventral flow of labeled cells towards the lateral lips of the blastopore, which was also mediated by convergent intercalation and tensotaxis. The obtained data are discussed in terms of the hypothesis of mechanical stress hyper-restoration.     

The prickle-related gene in vertebrates is essential for gastrulation cell movements

Involving dynamic and coordinated cell movements that cause drastic changes in embryo shape, gastrulation is one of the most important processes of early development. Gastrulation proceeds by various types of cell movements, including convergence and extension, during which polarized axial mesodermal cells intercalate in radial and mediolateral directions and thus elongate the dorsal marginal zone along the anterior-posterior axis [1,2]. Recently, it was reported that a noncanonical Wnt signaling pathway, which is known to regulate planar cell polarity (PCP) in Drosophila [3,4], participates in the regulation of convergent extension movements in Xenopus as well as in the zebrafish embryo [5-8]. The Wnt5a/Wnt11 signal is mediated by members of the seven-pass transmembrane receptor Frizzled (Fz) and the signal transducer Dishevelled (Dsh) through the Dsh domains that are required for the PCP signal [6-8]. It has also been shown that the relocalization of Dsh to the cell membrane is required for convergent extension movements in Xenopus gastrulae. Although it appears that signaling via these components leads to the activation of JNK [9,10] and rearrangement of microtubules, the precise interplay among these intercellular components is largely unknown. In this study, we show that Xenopus prickle (Xpk), a Xenopus homolog of a Drosophila PCP gene [11-13], is an essential component for gastrulation cell movement. Both gain-of-function and loss-of-function of Xpk severely perturbed gastrulation and caused spina bifida embryos without affecting mesodermal differentiation. We also demonstrate that XPK binds to Xenopus Dsh as well as to JNK. This suggests that XPK plays a pivotal role in connecting Dsh function to JNK activation.     

The role of tensile fields and contact cell polarization in the morphogenesis of amphibian axial rudiments

Summary The role of stretching-generated tensile stresses upon the organization of axial rudiments have been studied. Pieces of the dorsal wall ofXenopus laevis andRana temporaria embryos at the late gastrula stage were rotated through 90°, transplanted into the field of neurulation tensions of another embryo and replaced by ventral tissues already insensitive to inductive influences. The axial rudiments which developed from rotated and transplanted dorsal tissues oped from rotated and transplanted dorsal tissues almost completely reorientated according to the tensile patterns in adjacent host tissues. Some of the donor cells changed their presumptive fates in accordance with their new positions in the host tensile field. Transplanted ventral tissues were involved in the morphogenetic movements specific for the dorsal regions and imitated some typical dorsal structures. In the regions without pronounced tensions the structure of transplanted axial rudiments was chaotic. It is suggested that the organization of the axial structures is established and maintained by tensile fields created by uniformly polarized cells. Cell polarization can be transmitted by contact from host to donor tissues. The specificity of this propagating process and its morphogenetical role is discussed.     

Formation and cellular structure of the lines of tension in the axial rudimenta of amphibian embryos]

The lines of mechanical tension (cross-lines) in axial rudiments of the amphibian embryo represent bands of polarized cells. They form in the inner layers of the rudiments as separate bundles of polarized cell which, then, merge, attain the external surface and gather in lengthy planes (cross-planes) and, later, degrade. The primary inductor induces the formation of cross-lines in the ventral ectoderm of the early gastrula. The growth of cross-lines in considered as one of the types of contact cells polarization. The morphogenetic role of contact polarization is discussed. The connection between the subsequent tension patterns is based on the fact that the lines of exit of the cross-planes on the surface of the embryo coincide with the direction of the previously established tensions.     

Calcium signaling during convergent extension in Xenopus

BACKGROUND: During Xenopus gastrulation, cell intercalation drives convergent extension of dorsal tissues. This process requires the coordination of motility throughout a large population of cells. The signaling mechanisms that regulate these movements in space and time remain poorly understood. RESULTS: To investigate the potential contribution of calcium signaling to the control of morphogenetic movements, we visualized calcium dynamics during convergent extension using a calcium-sensitive fluorescent dye and a novel confocal microscopy system. We found that dramatic intercellular waves of calcium mobilization occurred in cells undergoing convergent extension in explants of gastrulating Xenopus embryos. These waves arose stochastically with respect to timing and position within the dorsal tissues. Waves propagated quickly and were often accompanied by a wave of contraction within the tissue. Calcium waves were not observed in explants of the ventral marginal zone or prospective epidermis. Pharmacological depletion of intracellular calcium stores abolished the calcium dynamics and also inhibited convergent extension without affecting cell fate. These data indicate that calcium signaling plays a direct role in the coordination of convergent extension cell movements. CONCLUSIONS: The data presented here indicate that intercellular calcium signaling plays an important role in vertebrate convergent extension. We suggest that calcium waves may represent a widely used mechanism by which large groups of cells can coordinate complex cell movements.     

Localization and induction in early development of Xenopus

Our experimental results, as well as those of others, lead us to suggest the following steps in the dorsalization and axialization of the Xenopus egg and embryo: the sperm aster determines the direction of rotation of the cortex relative to the deeper cytoplasm (endoplasm); the rotation of the cortex activates latent dorsalizing-axializing agents in the vegetal hemisphere. The extent of rotation determines the amount of activation. The direction of rotation determines the location of the activated agents. The activated agents determine the level of mesoderm-inducing activity of the vegetal cells cleaved from that cytoplasmic region. The level of inducing activity determines at least the time at which marginal zone cells will begin gastrulation movements. The time of its initiation of gastrulation may determine how anterior and dorsal a particular marginal zone cell can become.     

The epithelium of the dorsal marginal zone of Xenopus has organizer properties.

We have investigated the properties of the epithelial layer of the dorsal marginal zone (DMZ) of the Xenopus laevis early gastrula and found that it has inductive properties similar to those of the entire Spemann organizer. When grafts of the epithelial layer of the DMZ of early gastrulae labelled with fluorescein dextran were transplanted to the ventral sides of unlabelled host embryos, they induced secondary axes composed of notochord, somites and posterior neural tube. The organizer epithelium rescued embryos ventralized by UV irradiation, inducing notochord, somites and posterior neural tube in these embryos, while over 90% of ventralized controls showed no such structures. Combinations of organizer epithelium and ventral marginal zone (VMZ) in explants of the early gastrula resulted in convergence, extension and differentiation of dorsal mesodermal tissues, whereas similar recombinants of nonorganizer epithelium and the VMZ did none of these things. In all cases, the axial structures forming in response to epithelial grafts were composed of labelled graft and unlabelled host cells, indicating an induction by the organizer epithelium of dorsal, axial morphogenesis and tissue differentiation among mesodermal cells that otherwise showed non-axial development. Serial sectioning and scanning electron microscopy of control grafts shows that the epithelial organizer effect occurs in the absence of contaminating deep cells adhering to the epithelial grafts. However, labelled organizer epithelium grafted to the superficial cell layer contributed cells to deep mesodermal tissues, and organizer epithelium developed into mesodermal tissues when deliberately grafted into the deep region. This shows that these prospective endodermal epithelial cells are able to contribute to mesodermal, mesenchymal tissues when they move or are moved into the deep environment. These results suggest that in normal development, the endodermal epithelium may influence some aspects of the cell motility underlying the mediolateral intercalation (see Shih, J. and Keller, R. (1992) Development 116, 901-914), as well as the tissue differentiation of mesodermal cells. These results have implications for the analysis of mesoderm induction and for analysis of variations in the differentiation and morphogenetic function of the marginal zone in different species of amphibians.     

Embryonic vascular development: immunohistochemical identification of the origin and subsequent morphogenesis of the major vessel primordia in quail embryos

The development of the embryonic vasculature is examined here using a monoclonal antibody, QH-1, capable of labelling the presumptive endothelial cells of Japanese quail embryos. Antibody labelling is first seen within the embryo proper at the 1-somite stage. Scattered labelling of single cells appears ventral to the somites and at the lateral edges of the anterior intestinal portal. The dorsal aorta soon forms a continuous cord at the ventrolateral edge of the somites and continues into the head to fuse with the ventral aorta forming the first aortic arch by the 6-somite stage. The rudiments of the endocardium fuse at the midline above the anterior intestinal portal by the 3-somite stage and the ventral aorta extends craniad. Intersomitic arteries begin to sprout off of the dorsal aorta at the 7-somite stage. The posterior cardinal vein forms from single cells which segregate from somatic mesoderm at the 7-somite stage to form a loose plexus which moves mediad and wraps around the developing Wolffian duct in later stages. These studies suggest two modes of origin of embryonic blood vessels. The dorsal aortae and cardinal veins apparently arise in situ by the local segregation of presumptive endothelial cells from the mesoderm. The intersomitic arteries, vertebral arteries and cephalic vasculature arise by sprouts from these early vessel rudiments. There also seems to be some cell migration in the morphogenesis of endocardium, ventral aorta and aortic arches. The extent of presumptive endothelial migration in these cases, however, needs to be clarified by microsurgical intervention.     

Change of Rat Embryos from a Ventrally Concave U-Shape to a Ventrally Convex C-Shape

In an early stage of development in murine embryos, axial rotation occurs and the body axis changes from a ventrally concave U-shape to a ventrally convex C-shape. In this study, axial rotation in Sprague-Dawley rat embryos occurred in about 5 h in vitro (from 27 h to 32 h in cultures of head-fold stage embryos). In sagittal sections, the somites in the mid-region of the body changed from a trapezoidal shape with a short dorsal side and long ventral side to the reverse trapezoidal shape with a long dorsal side and a short ventral side. The dorsal part of these somites acquired the ability to react with actin-specific antibody and developed into dermatome. On treatment with 0.1 μg/ml cytochalasin D during this 5 h period, embryos became ventrally concave with two lordosis bends. The somites in the bends had a short dorsal side, which did not show any evidence of dermatome or intense immunocytochemical staining. These results suggest that the increase in length of the dorsal side of the somites is a cause of the axial rotation and that the organization of actin filaments plays an important role in the conformational change of the somites.     

Ventral axial organs regulate expression of myotomal Fgf-8 that influences rib development

Fgf-8 encodes a secreted signaling molecule mediating key roles in embryonic patterning. This study analyzes the expression pattern, regulation, and function of this growth factor in the paraxial mesoderm of the avian embryo. In the mature somite, expression of Fgf-8 is restricted to a subpopulation of myotome cells, comprising most, but not all, epaxial and hypaxial muscle precursors. Following ablation of the notochord and floor plate, Fgf-8 expression is not activated in the somites, in either the epaxial or the hypaxial domain, while ablation of the dorsal neural tube does not affect Fgf-8 expression in paraxial mesoderm. Contrary to the view that hypaxial muscle precursors are independent of regulatory influences from axial structures, these findings provide the first evidence for a regulatory influence of ventral, but not dorsal axial structures on the hypaxial muscle domain. Sonic hedgehog can substitute for the ventral neural tube and notochord in the initiation of Fgf-8 expression in the myotome. It is also shown that Fgf-8 protein leads to an increase in sclerotomal cell proliferation and enhances rib cartilage development in mature somites, whereas inhibition of Fgf signaling by SU 5402 causes deletions in developing ribs. These observations demonstrate: (1) a regulatory influence of the ventral axial organs on the hypaxial muscle compartment; (2) regulation of epaxial and hypaxial expression of Fgf-8 by Sonic hedgehog; and (3) independent regulation of Fgf-8 and MyoD in the hypaxial myotome by ventral axial organs. It is postulated that the notochord and ventral neural tube influence hypaxial expression of Fgf-8 in the myotome and that, in turn, Fgf-8 has a functional role in rib formation.     

Regional expression, pattern and timing of convergence and extension during gastrulation of Xenopus laevis

We show with time-lapse micrography that narrowing in the circumblastoporal dimension (convergence) and lengthening in the animal-vegetal dimension (extension) of the involuting marginal zone (IMZ) and the noninvoluting marginal zone (NIMZ) are the major tissue movements driving blastopore closure and involution of the IMZ during gastrulation in the South African clawed frog, Xenopus laevis. Analysis of blastopore closure shows that the degree of convergence is uniform from dorsal to ventral sides, whereas the degree of extension is greater on the dorsal side of the gastrula. Explants of the gastrula show simultaneous convergence and extension in the dorsal IMZ and NIMZ. In both regions, convergence and extension are most pronounced at their common boundary, and decrease in both animal and vegetal directions. Convergent extension is autonomous to the IMZ and begins at stage 10.5, after the IMZ has involuted. In contrast, expression of convergent extension in the NIMZ appears to be dependent on basal contact with chordamesoderm or with itself. The degree of extension decreases progressively in lateral and ventral sectors. Isolated ventral sectors show convergence without a corresponding degree of extension, perhaps reflecting the transient convergence and thickening that occurs in this region of the intact embryo. We present a detailed mechanism of how these processes are integrated with others to produce gastrulation. The significance of the regional expression of convergence and extension in Xenopus is discussed and compared to gastrulation in other amphibians.     

Xenopus p21-activated kinase 5 regulates blastomeres' adhesive properties during convergent extension movements

The p21-activated kinase (PAK) proteins regulate many cellular events including cell cycle progression, cell death and survival, and cytoskeleton rearrangements. We previously identified X-PAK5 that binds the actin and microtubule networks, and could potentially regulate their coordinated dynamics during cell motility. In this study, we investigated the functional importance of this kinase during gastrulation in Xenopus. X-PAK5 is mainly expressed in regions of the embryo that undergo extensive cell movements during gastrula such as the animal hemisphere and the marginal zone. Expression of a kinase-dead mutant inhibits convergent extension movements in whole embryos and in activin-treated animal cap by modifying behavior of cells. This phenotype is rescued in embryo by adding back X-PAK5 catalytic activity. The active kinase decreases cell adhesiveness when expressed in animal hemisphere and inhibits the calcium-dependent reassociation of cells, while dead X-PAK5 kinase localizes to cell-cell junctions and increases cell adhesion. In addition, endogenous X-PAK5 colocalizes with adherens junction proteins and its activity is regulated by extracellular calcium. Taken together, our results suggest that X-PAK5 regulates convergent extension movements in vivo by modulating the calcium-mediated cell-cell adhesion.     

Demonstration of neural induction using nuclear markers inXenopus

Summary Two nuclear markers were used to investigate the origin of cells in secondary embryos ofXenopus induced by dorsal lip transplants, and to determine the ability of the chordomesoderm to direct cells to change their fates.³H-thymidine was used to label cells transplanted between individualX. laevis embryos, and nuclear quinacrine fluorescence was used to distinguishX. borealis tissues transplanted toX. laevis hosts. In the first set of experiments, dorsal lip tissue (also known as the dorsal marginal zone; DMZ) was transplanted to the ventral marginal zone (VMZ) of host embryos. The marginal zone is the toroid of presumptive mesodermal cells which involutes during gastrulation. Examination of the secondary embryos resulting from these grafts revealed that their notochords were derived almost exclusively from transplanted cells whereas their nervous systems and somites were composed almost entirely of host cells. Next, the nuclear markers were used to show the normal fates of the tissue of the ventral equatorial region immediately above the VMZ by orthotopic grafting. This tissue was found to give rise to structures in the ventral posterior portions of the tailbud embryo. Finally, the same ventral tissue was labeled and transplanted to the dorsal equatorial region above the DMZ. As a result, it was induced to change its fate and become neural. These results lend unequivocal support to Spemann's theory of neural induction which has recently been questioned.