Two essential processes in the formation of a dorsal axis during gastrulation ofCynops embryo

The isolated upper marginal zone from the initial stage ofCynops gastrulation is not yet determined to form the dorsal axis mesoderm: notochord and muscle. In this experiment, we will indicate where the dorsal mesoderm-inducing activity is localized in the very early gastrula, and what is an important event for specification of the dorsal axis mesoderm during gastrulation. Recombination experiments showed that dorsal mesoderm-inducing activity was localized definitively in the endodermal epithelium (EE) of the lower marginal zone, with a dorso-ventral gradient; and the EE itself differentiated into endodermal tissues, mainly pharyngeal endoderm. Nevertheless, when dorsal EE alone was transplanted into the ventral region, a secondary axis with dorsal mesoderm was barely formed. However, when dorsal EE was transplanted with the bottle cells which by themselves were incapable of mesoderm induction, a second axis with well-developed dorsal mesoderm was observed. When the animal half with the lower marginal zone was rotated 180° and recombined with the vegetal half, most of the rotated embryos formed only one dorsal axis at the primary blastopore side. The present results suggest that there are at least two essential processes in dorsal axis formation: mesoderm induction of the upper marginal zone by endodermal epithelium of the lower marginal zone, and dorsalization of the upper dorsal marginal zone evoked during involution.     

The Dorsalization of Spermann's Organizer Takes Place during Gastrulation in Xenopus laevis Embryos

Suramin, a polyanionic compound, which is thought to inhibit the binding of growth factors to their receptors, prevents the differentiation of the dorsal blastopore lip of early gastrulae into dorsal mesodermal structures as notochord and somites. Suramin treated blastopore lips form ventral mesodermal structures, mainly heart structures. Several cases showed rythmic contractions ("beating hearts"). Of special interest is the fact that blastopore lips isolated from middle gastrulae followed by suramin treatment differentiate in about 50% of the cases brain structures without the presence of notochord. These data suggest that suramin prevents the differentiation of the dorsal blastopore lip into notochord up to the early middle gastrula stage but no longer the formation of head mesoderm, which is the prequisite for the induction of archencephalic brain structures. Treated chordamesoderm with overlaying ectoderm from late gastrulae will differentiate as untreated controls, namely into dorsal axial structures like notochord, somites and brain structures. The results indicate that primarily a more general or ventral mesodermal signal is transferred from the dorsal vegetal blastomeres (Nieuwkoop center) to the dorsal marginal zone. The dorsalization, which enables the blastopore lip to differentiate into head mesoderm and notochord and in turn to acquire neuralizing activity, takes place during the early steps of gastrulation.     

Blastopore formation and dorsal mesoderm induction are independent events in early Cynops embryogenesis

The independent roles of blastopore formation and dorsal mesoderm induction in dorsal axis formation of the Cynops pyrrhogaster embryo were attempted to be clarified. The blastopore-forming (bottle) cells originated mainly from the progeny of the mid-dorsal C and/or D blastomeres of the 32-cell embryo, but were not defined to a fixed blastomere. It was confirmed that the isolated dorsal C and D blastomeres autonomously formed a blastopore. Ultraviolet-irradiated eggs formed an abnormal blastopore and then did not form a dorsal axis, although the lower dorsal marginal zone (LDMZ) still had dorsal mesoderm-inducing activity. Involution of the dorsal marginal zone was disturbed by the abnormal blastopore. These embryos were rescued by artificially facilitating involution of the dorsal marginal zone. Suramin-injected and nocodazole-treated blastulae did not have involution of the dorsal marginal zone, although the blastopore was formed. Neither embryos formed the dorsal axis. The dorsal mesoderm-inducing activity of the LDMZ in the nocodazole-treated gastrulae was still active. In contrast, the LDMZ of the suramin-injected embryos lost its dorsal mesoderm-inducing activity. bra expression was activated in the nocodazole-treated embryos but not in the suramin-injected embryos. The present study suggested that (i) the dorsal determinants consist of blastopore-forming and dorsal mesoderm-inducing factors, which are not always mutually dependent; (ii) both factors are activated during the late blastula stage; (iii) the dorsal marginal zone cannot specify to an organized notochord and muscle without the involution that blastopore formation leads to; and (iv) the localization of both factors in the same place is prerequisite for dorsal axis formation.     

Experimental reversal of the normal dorsal-ventral timing of blastopore formation does not reverse axis polarity in Xenopus laevis embryos

During gastrulation in Xenopus laevis, the dorsal lip of the blastopore normally appears before the ventral lip. Metabolic gradient models propose that the dorsal lip develops from the region of highest metabolic activity and somehow dominates other regions to prevent them from becoming dorsal. To test these ideas, I applied a temperature gradient of 12 degrees C across the embryo. Localized heating of the prospective ventral vegetal region from early in the first cleavage period until gastrulation causes the blastopore lip to form first by 2 hr at the prospective ventral meridian rather than at the prospective dorsal meridian. Despite this reversal of the timing of blastopore formation, gastrulation is completed, and the neural plate forms at its usual position on the prospective dorsal meridian. This demonstrates that the earliest gastrulating regions of the blastopore do not necessarily become dorsal, nor do they inhibit dorsal development by other regions. It is unlikely that axis polarity is based on regional differences in energy metabolism.     

Direct evidence of an essential role for extended involution in the specification of a dorsal marginal mesoderm during Cynops gastrulation

It has been indicated that specification of the dorsal marginal mesoderm of the Cynops gastrula is established by vertical interactions with other layers, which occur during its extended involution. In the present study, when the prospective notochordal area of the early gastrula was almost completely removed together with the dorsal mesoderm-inducing endoderm and most of the bottle cells, the D-less gastrulas still formed the dorsal axis with a well-differentiated notochord; in half of them, where the involution occurred bi-laterally, twin axes were observed. On the other hand, when the wound of a D-less gastrula was repaired by transplanting the ventral marginal zone and ectoderm, the formation of the dorsal axis was inhibited if the involution of the lateral marginal zone was prevented by the transplanted piece. The present study suggests that: (i) cells having dorsal mesoderm-forming potency distribute farther laterally than the fate map; and (ii) the extended involution plays an essential role in the specification of the dorsal marginal mesoderm, especially in notochordal differentiation in normal Cynops embryogenesis.     

Formation of the Neural Plate and the Mesoderm in Normally Developing Embryos of Xenopus laevis

Normally developing embryos of Xenopus were fixed at various stages between the blastula and early tail bud stage, and their serial sections were examined. The marginal belt of the blastula was characterized by abundance of cells with RNA-rich peripheral cytoplasm called mesoplasm. At the early gastrula stage, the marginal belt was folded into two layers giving rise to mesodermal material and marginal ectoderm. During gastrulation, the mesodermal material, which consisted of RNA-rich cells, spread to enclose the blastocoel and the endoderm, and a large part of it was shifted to the dorsal side of the embryo. It gradually established the mesodermal layer. The notochord was formed on the dorsal lip of the blastopore by involution, separately from preformed mesodermal material. The RNA-rich cells in the marginal ectoderm became columnar, forming a broad belt in the marginal zone. This belt was deformed and shifted to the dorsal side during gastrulation, eventually establishing the neural plate showing quantitative differentiation along the head-tail axis. Possible mechanisms involved in the formation of the neural plate and mesoderm were discussed with reference to the organizer and the mesoplasm.     

The restriction of the heart morphogenetic field in Xenopus laevis

We have examined the spatial restriction of heart-forming potency in Xenopus laevis embryos, using an assay system in which explants or explant recombinates are cultured in hanging drops and scored for the formation of a beating heart. At the end of neurulation at stage 20, the heart morphogenetic field, i.e., the area that is capable of heart formation when cultured in isolation, includes anterior ventral and ventrolateral mesoderm. This area of developmental potency does not extend into more posterior regions. Between postneurula stage 23 and the onset of heart morphogenesis at stage 28, the heart morphogenetic field becomes spatially restricted to the anterior ventral region. The restriction of the heart morphogenetic field during postneurula stages results from a loss of developmental potency in the lateral mesoderm, rather than from ventrally directed morphogenetic movements of the lateral mesoderm. This loss of potency is not due to the inhibition of heart formation by migrating neural crest cells. During postneurula stages, tissue interactions between the lateral mesoderm and the underlying anterior endoderm support the heart-forming potency in the lateral mesoderm. The lateral mesoderm loses the ability to respond to this tissue interaction by stages 27–28. We speculate that either formation of the third pharyngeal pouch during stages 23–27 or lateral inhibition by ventral mesoderm may contribute to the spatial restriction of the heart morphogenetic field.     

Suramin changes the fate of Spemann's organizer and prevents neural induction in Xenopus laevis.

Suramin, a polyanionic compound, which has previously shown to dissociate platelet derived growth factor (PDGF) from its receptor, prevents the differentiation of neural (brain) structures of recombinants of dorsal blastopore lip (Spemann's organizer) and competent neuroectoderm. Furthermore, the suramin treatment changes the prospective differentiation pattern of isolated blastopore lip. While untreated dorsal blastopore lip will differentiate into dorsal mesodermal structures (notochord and somites), suramin treated dorsal blastopore lip will form ventral mesoderm structures, especially heart structures. The results are discussed in the context of the current opinion about the mode of action of different growth factor superfamilies.     

Bottle cell formation in relation to mesodermal patterning in the Xenopus embryo

The appearance of bottle cells at the dorsal vegetal/marginal boundary of Xenopus embryos marks the onset of blastopore formation. The conditions leading to this epithelial activity were investigated by inducing bottle cells ectopically in the animal region with VegT or different members of the transforming growth factor (TGF)-beta family. Morphological studies on the ectopic bottle cells indicate their close similarity to the endogenous bottle cells at the dorsal blastopore lip. The subepithelial cells of the induced animal region express mesodermal genes in a pattern reminiscent to that observed on the dorsal lip. Relating this expression pattern to the position of the ectopic bottle cells leads to the conclusion that bottle cells form in regions of high TGF-beta signalling. The specific inhibitory effects of cerberus on ectopically induced bottle cells revealed that nodal related growth factors are the intrinsic signals that elicit bottle cell formation in the normal embryo. In addition, fibroblast growth factor signalling is an essential precondition for this epithelial response as it is for mesoderm formation. We conclude that bottle cell formation in the epithelial layer of the gastrula is closely linked to mesodermal patterning in the subepithelial tissues.     

The restriction of the heart morphogenetic field in Xenopus laevis

We have examined the spatial restriction of heart-forming potency in Xenopus laevis embryos, using an assay system in which explants or explant recombinates are cultured in hanging drops and scored for the formation of a beating heart. At the end of neurulation at stage 20, the heart morphogenetic field, i.e., the area that is capable of heart formation when cultured in isolation, includes anterior ventral and ventrolateral mesoderm. This area of developmental potency does not extend into more posterior regions. Between postneurula stage 23 and the onset of heart morphogenesis at stage 28, the heart morphogenetic field becomes spatially restricted to the anterior ventral region. The restriction of the heart morphogenetic field during postneurula stages results from a loss of developmental potency in the lateral mesoderm, rather than from ventrally directed morphogenetic movements of the lateral mesoderm. This loss of potency is not due to the inhibition of heart formation by migrating neural crest cells. During postneurula stages, tissue interactions between the lateral mesoderm and the underlying anterior endoderm support the heart-forming potency in the lateral mesoderm. The lateral mesoderm loses the ability to respond to this tissue interaction by stages 27-28. We speculate that either formation of the third pharyngeal pouch during stages 23-27 or lateral inhibition by ventral mesoderm may contribute to the spatial restriction of the heart morphogenetic field.     

Amphibian embryos as a model system for organ engineering: in vitro induction and rescue of the heart anlage.

Beating hearts can be induced under in vitro conditions when the dorsal blastopore lip (including the zone of Spemann organizer) is treated with Suramin. In contrast, untreated organizer forms dorsal mesodermal derivatives as notochord and somites. When those in vitro produced heart precursor tissues are transplanted ectopically in the posterior trunk area of early larvae, secondary beating heart structures will be formed. Furthermore, the replacement of the heart primordium of the host embryo by heart tissue induced under in vitro conditions will result in the rescue of the heart anlage. This model could be a valuable tool for the study of the multi-step molecular mechanisms of heart structure induction under in vitro conditions and vasculogenesis after transplantation into the host embryo.     

Mechanisms of mesendoderm internalization in the Xenopus gastrula: lessons from the ventral side.

Two main processes are involved in driving ventral mesendoderm internalization in the Xenopus gastrula. First, vegetal rotation, an active movement of the vegetal cell mass, initiates gastrulation by rolling the peripheral blastocoel floor against the blastocoel roof. In this way, the leading edge of the internalized mesendoderm is established, that remains separated from the blastocoel roof by Brachet's cleft. Second, in a process of active involution, blastopore lip cells translocate on arc-like trails around the tip of Brachet's cleft. Hereby the lower, Xbra-negative part of the lip moves toward the interior, to contribute mainly to endoderm. In contrast, the upper, Xbra-expressing part moves toward the blastocoel roof-apposed surface of the involuted mesoderm, and eventually becomes inserted into this surface. Vegetal rotation and active mesoderm surface insertion persist over much of gastrulation ventrally. Both processes are also active dorsally. In fact, internalization processes generally spread from dorsal to ventral, though at different rates, which suggests that they are independently controlled. Ventrally and laterally, mesoderm occurs not only in the marginal zone, but also in the adjacent blastocoel roof. Such blastocoel roof mesoderm shares properties with the remaining, ectodermal roof, that are related to its function as substratum for mesendoderm migration. It repels involuted mesoderm, thus contributing to separation of cell layers, and it assembles a fibronectin matrix. These properties change as the blastocoel roof mesoderm moves into the blastopore lip during gastrulation.     

Microfolds in the suprablastoporal zone of the frog gastrula and their relationship to the geometry and mechanics of gastrulation

Spatial distribution and orientation of microfolds arising during invagination of the outer layer of suprablastoporal zone into the blastopore dorsal lip and changes of the lip shape were studied in Rana ridibunda embryos using statistical analysis of a normal individual variability. Active invagination of the cells into the lip correlated with deviation of the orientation of microfolds from the normal in the points of their intersection with the zone of dorsal lip inflection and their orientation is normalized upon transition of the cells across the inflection zone. Frequency distribution of the angle of microfold deviation from the normal is close to the exponential and, therefore, the angle of deviation is an analog of the potential energy of cells-components of the microfold: the bigger the deviation angle, the higher the potential energy. The minimum potential energy is observed at the normal orientation of microfolds, i.e., when it coincides with the radius of the dorsal lip curvature at the point of intersection with the microfold. The following mechanism of dorsal lip formation has been proposed: equatorial contraction of cells upon their invagination into the dorsal lip causes deviation of cell flux orientation from the normal orientation and the normal orientation is restored through an increase in the local curvature of dorsal lip. When the orientation of cell fluxes is normalized, invagination of cells in the dorsal lip ceases. The wave of normalization overtakes the wave of cell invagination into the dorsal lip at the lip angle length 120 degrees. At this moment, the archenteron roof is mechanically detached from the superficial cells of the suprablastoporal zone and lateral blastopore lips and this determines separation of the presumptive notochord.     

Determinants of Early Amphibian Development

The animal-vegetal organization of the amphibian egg may originatefrom the axis of organelles and cytoskeletal elements establishedin the oocyte as it divides from the oogonium. Along this axis,cytoplasmic materials are localized during oogenesis: yolk platelets,for example, are translocated toward the vegetal pole, increasingtheir amount and size in that region. In the first cell cycleafter fertilization, the egg cortex rotates 30° relativeto the cytoplasmic core, modifying animal-vegetal organization.The direction of this rotation, biased by the point of spermentry, defines the site of development of anatomical structuresof the dorsal midline of the embryo. As its immediate effect,rotation activates the cytoplasm of a subregion of the vegetalhemisphere, causing cells cleaved from this subregion to bemore effective than other vegetal parts in inducing marginalzone cells to initiate gastrulation movements. The most stronglyinduced part of the marginal zone begins gastrulation first(the dorsal lip of the blastopore) and proceeds through a seriesof cell interactions leading to its determination as the anteriordorsal mesoderm of the embryo. If these cell movements are inhibitedin the gastrula stage, or if vegetal induction is inhibitedin the blastula stage, or if cortical rotation is inhibitedin the first cell cycle after fertilization, the embryo alwaysfails to develop dorsal structures of the anterior end of itsbody axis; the more inhibition, the more posterior is the levelof truncation, until a radial ventralized embryo develops, derivedfrom the animal-vegetal organization of the oocyte.     

Spemann's organizer--it's origin and derivatives (cellular-tissue and molecular-genetic aspects)

In 1924 H. Spemann and H. Mangold discovered that a piece of the dorsal lip of a blastopore from Triturus cristatus, after transplantation to the ventral side of another embryo, was able to cause the neighbouring tissues to change their fate and participate in the formation of a new embryo. The dorsal lip was termed "the organizer". Since then, for as long as 75 years, attempts have been made to establish the intimate mechanisms of the organizer activity. However, no real advance was achieved in their understanding. Within the last 15 years, genetic and molecular techniques have been vastly improved, to help in tracing the fate of many cell lineages, and in compiling more exactly the fate maps for different parts of the embryo. Using these data, I have attempted to trace the fate of Spemann's organizer after the early gastrula stage. Analysis of data on inductive abilities of the organizer cells, on the use of markers, and on the observation of expression of specific genes allowed to conclude that Spemann's organizer in amphibia and its homologues in other vertebrates too are heterogeneous: they are composed of distinct cell populations able to induce primarity the development of either the head or trunk parts of the embryo. These population, determined to become the head of the trunk organizers still at the blastula stage, may be located either in the single continuous cell layer (as in amphibia and birds) or separated among different tissue germs (as in mammals). When the dorsal-ventral orientation of the embryo is established and the organizer is switched on the very early invaginating cells of the dorsal blastopore lip (in the case of amphibia) move in advance of the entire invaginating mesoderm and by the end of gastrulation occupy the place just in front of the notochord. It is supposed that the early dorsal lip and the prechordal mesoderm (PCM) are one and the same cell population, i.e. during gastrulation Spemann's organizer transfers from the lip of blastopore to the prechordal zone. The PCM seems to play an exclusive role in the formation of a head in vertebrate, because some mutations in genes expressed in the PCM result in the entire head deletion. It is supposed that spreading of differentiating signals from the PCM occurs along the main body axis in both caudal and rostral directions. After the main body plan formation the PCM is replaced by adenohypophysis. This conclusion is drawn not only from the same topology of both these structures, but also from the similarities of a set of specific genetical markers expressed in these, that makes it possible to suppose the existence of deep connections and succession between them. The adenohypophysis seems to arise directly from the PCM, or cells of the ectoderm influenced by the PCM may be subsequently transformed into humoral cells of adenohypophysis. In this interpretation, adenohypophysis and the much earlier established PCM may be considered as derivatives of Spemann's organizer. This inference is supported by the fact that all the three above structures first originate in vertebrates only.     

Regional specification within the mesoderm of early embryos of Xenopus laevis

We have further analysed the roles of mesoderm induction and dorsalization in the formation of a regionally specified mesoderm in early embryos of Xenopus laevis. First, we have examined the regional specificity of mesoderm induction by isolating single blastomeres from the vegetalmost tier of the 32-cell embryo and combining each with a lineage-labelled (FDA) animal blastomere tier. Whereas dorsovegetal (D1) blastomeres induce 'dorsal-type' mesoderm (notochord and muscle), laterovegetal and ventrovegetal blastomeres (D2-4) induce either 'intermediate-type' (muscle, mesothelium, mesenchyme and blood) or 'ventral-type' (mesothelium, mesenchyme and blood) mesoderm. No significant difference in inductive specificity between blastomeres D2, 3 and 4 could be detected. We also show that laterovegetal and ventrovegetal blastomeres from early cleavage stages can have a dorsal inductive potency partially activated by operative procedures, resulting in the induction of intermediate-type mesoderm. Second, we have determined the state of specification of ventral blastomeres by isolating and culturing them in vitro between the 4-cell stage and the early gastrula stage. The majority of isolates from the ventral half of the embryo gave extreme ventral types of differentiation at all stages tested. Although a minority of cases formed intermediate-type and dorsal-type mesoderms we believe these to result from either errors in our assessment of the prospective DV axis or from an enhancement, provoked by microsurgery, of some dorsal inductive specificity. The results of induction and isolation experiments suggest that only two states of specification exist in the mesoderm of the pregastrula embryo, a dorsal type and a ventral type. Finally we have made a comprehensive series of combinations between different regions of the marginal zone using FDA to distinguish the components. We show that, in combination with dorsal-type mesoderm, ventral-type mesoderm becomes dorsalized to the level of intermediate-type mesoderm. Dorsal-type mesoderm is not ventralized in these combinations. Dorsalizing activity is confined to a restricted sector of the dorsal marginal zone, it is wider than the prospective notochord and seems to be graded from a high point at the dorsal midline. The results of these experiments strengthen the case for the three-signal model proposed previously, i.e. dorsal and ventral mesoderm inductions followed by dorsalization, as the simplest explanation capable of accounting for regional specification within the mesoderm of early Xenopus embryos.     

The anterior heart-forming field: voyage to the arterial pole of the heart

Studies of vertebrate heart development have identified key genes and signalling molecules involved in the formation of a myocardial tube from paired heart-forming fields in splanchnic mesoderm. The posterior region of the paired heart-forming fields subsequently contributes myocardial precursor cells to the inflow region or venous pole of the heart. Recently, a population of myocardial precursor cells in chick and mouse embryos has been identified in pharyngeal mesoderm anterior to the early heart tube. This anterior heart-forming field gives rise to myocardium of the outflow region or arterial pole of the heart. The amniote heart is therefore derived from two myocardial precursor cell populations, which appear to be regulated by distinct genetic programmes. Discovery of the anterior heart-forming field has important implications for the interpretation of cardiac defects in mouse mutants and for the study of human congenital heart disease.