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.     

Active reinforcement of externally imposed folding in amphibians embryonic tissues

Although the folding of epithelial layers is one of the most common morphogenetic events, the underlying mechanisms of this process are still poorly understood. We aimed to determine whether an artificial bending of an embryonic cell sheet, which normally remains flat, is reinforced and stabilized by intrinsic cell transformations. We observed both reinforcement and stabilization in double explants of blastocoel roof tissue from Xenopus early gastrula embryos. The reinforcement of artificial bending occurred over the course of a few hours and was driven by the gradual apical constriction and radial elongation of previously compressed cells situated at the bending arch of the concave layer of explant. Apical constriction was associated with actomyosin contraction and endocytosis-mediated engulfing of the apical cell membranes. Cooperative apical constrictions of the concave layer of cells produced a tensile force that extended over the entire surface of the explant and correlated with apical contraction of the concave side cells. In the explants taken from the anterior regions of the embryo, this reinforcement was more stable and the bending better expressed than in those taken from suprablastoporal areas. The morphogenetic role of cell responses to the bending force is discussed.     

Actomyosin contractility and microtubules drive apical constriction in Xenopus bottle cells

Cell shape changes are critical for morphogenetic events such as gastrulation, neurulation, and organogenesis. However, the cell biology driving cell shape changes is poorly understood, especially in vertebrates. The beginning of Xenopus laevis gastrulation is marked by the apical constriction of bottle cells in the dorsal marginal zone, which bends the tissue and creates a crevice at the blastopore lip. We found that bottle cells contribute significantly to gastrulation, as their shape change can generate the force required for initial blastopore formation. As actin and myosin are often implicated in contraction, we examined their localization and function in bottle cells. F-actin and activated myosin accumulate apically in bottle cells, and actin and myosin inhibitors either prevent or severely perturb bottle cell formation, showing that actomyosin contractility is required for apical constriction. Microtubules were localized in apicobasally directed arrays in bottle cells, emanating from the apical surface. Surprisingly, apical constriction was inhibited in the presence of nocodazole but not taxol, suggesting that intact, but not dynamic, microtubules are required for apical constriction. Our results indicate that actomyosin contractility is required for bottle cell morphogenesis and further suggest a novel and unpredicted role for microtubules during apical constriction.     

Two-step induction of primitive erythrocytes in Xenopus laevis embryos: signals from the vegetal endoderm and the overlying ectoderm

Primitive blood cells differentiate from the ventral mesoderm blood islands in Xenopus embryos. In order to determine the tissue interactions that propagate blood formation in early embryogenesis, we used embryos that had the ventral cytoplasm removed. These embryos gastrulated normally, formed a mesodermal layer and lacked axial structures, but displayed a marked enhancement of alpha-globin expression. Early ventral markers, such as msx-1, vent-1 and vent-2 were highly expressed at the gastrula stage, while a dorsal marker, goosecoid, was diminished. Several lines of experimental evidence demonstrate the critical role of animal pole-derived ectoderm in blood cell formation: 1) Mesoderm derived from dorsal blastomeres injected with beta-galactosidase mRNA (as a lineage tracer) expressed alpha-globin when interfaced with an animal pole-derived ectodermal layer; 2) Embryos in which the animal pole tissue had been removed by dissection at the blastula stage failed to express alpha-globin; 3) Exogastrulated embryos that lacked an interaction between the mesodermal and ectodermal layers failed to form blood cells, while muscle cells were observed in these embryos. Using dominant-negative forms of the BMP-4 and ALK-4 receptors, we showed that activin and BMP-4 signaling is necessary for blood cell differentiation in ventral marginal zone explants, while FGF signaling is not essential. In ventralized embryos, inactivation of the BMP-4 signal within a localized area of the ectoderm led to suppression of globin expression in the adjacent mesoderm layer, but inactivation of the activin signal did not have this effect. These observations suggest that mesodermal cells, derived from a default pathway that is induced by the activin signal, need an additional BMP-4-dependent factor from the overlying ectoderm for further differentiation into a blood cell lineage.     

Inductive interactions required for mesodermal differentiation in Bufo arenarum gastrulae

 Dorso-marginal epithelium, a distinct crescent-shaped region in the early gastrula of Bufo arenarum, appears after involution as a narrow dorso-median strip of archenteric endoderm close to the notochord. In explant cultures, this layer showed an extreme dorsalizing activity, promoting the formation of notochordal structures from ventro-mesodermal cells. In the presence of ectoderm, this inductive activity was expanded resulting in a wide range of dorso-lateral components such as notochord, muscle, nephric tubules, mesothelium and mesenchyme. The mesodermal origin of these derivatives was confirmed by the use of FDA (fluorescein-dextran-amine)-labelled explants. Extensive mesodermal development in cultures seems to require cell contacts between the inner aspect of the dorso-marginal epithelium and mesodermal cells. When such contacts were prevented, cultures would only differentiate erythrocytes as a result of a purely ectodermal stimulus. Bisection of the dorso-marginal epithelium in whole embryos resulted in the development of a duplicated set of axial structures, clearly showing the role of the epithelium as a dorsal organizer. Received: 30 July 1996 / Accepted: 20 February 1997     

Autonomous mesoderm formation in blastocoelic roof explants from inverted Xenopus embryos.

Xenopus eggs, artificially fertilized, were prevented from undergoing equilibrium rotation by incubation in medium containing ficoll. Three orientations were selected: normal, with animal pole uppermost; inverted, with vegetal pole away from gravity; and an off-axis orientation, with embryos tilted approximately 90 degrees from the animal-vegetal axis. At blastula stage 8, cells forming the blastocoelic roof were cultured in isolation as explants. These cells are normally fated to from epidermis ventrally and neural derivatives dorsally. Unexpectedly, in the fragments originating from inverted or 90 degrees-off-axis embryos, axial structures were found: notochord, somites, neural cells, cement glands, and sometimes sensory organs. Inverted eggs could be exploited in studies of mesodermal specification.     

Retinoic acid-mediated patterning of the pre-pancreatic endoderm in Xenopus operates via direct and indirect mechanisms

Early patterning of the endoderm as a prerequisite for pancreas specification involves retinoic acid (RA) as a critical signalling molecule in gastrula stage Xenopus embryos. In extension of our previous studies, we made systematic use of early embryonic endodermal and mesodermal explants. We find RA to be sufficient to induce pancreas-specific gene expression in dorsal but not ventral endoderm. The differential expression of retinoic acid receptors (RARs) in gastrula stage endoderm is important for the distinct responsiveness of dorsal versus ventral explants. Furthermore, BMP signalling, that is repressed dorsally, prevents the formation of pancreatic precursor cells in the ventral endoderm of gastrula stage Xenopus embryos. An additional requirement for mesoderm suggests the production of one or more further pancreas inducing signals by this tissue. Finally, recombination of manipulated early embryonic explants, and also inhibition of RA activity in whole embryos, reveal that RA signalling, as it is relevant for pancreas development, operates simultaneously on both mesodermal and endodermal germ layers.     

The involvement of lethal giant larvae and Wnt signaling in bottle cell formation in Xenopus embryos

Lethal giant larvae (Lgl) plays a critical role in establishment of cell polarity in epithelial cells. While Frizzled/Dsh signaling has been implicated in the regulation of the localization and activity of Lgl, it remains unclear whether specific Wnt ligands are involved. Here we show that Wnt5a triggers the release of Lgl from the cell cortex into the cytoplasm with the concomitant decrease in Lgl stability. The observed changes in Lgl localization were independent of atypical PKC (aPKC), which is known to influence Lgl distribution. In ectodermal cells, both Wnt5a and Lgl triggered morphological and molecular changes characteristic of apical constriction, whereas depletion of their functions prevented endogenous and ectopic bottle cell formation. Furthermore, Lgl RNA partially rescued bottle cell formation in embryos injected with a dominant negative Wnt5a construct. These results suggest a molecular link between Wnt5a and Lgl that is essential for apical constriction during vertebrate gastrulation.     

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.     

An ECM substratum allows mouse mesodermal cells isolated from the primitive streak to exhibit motility similar to that inside the embryo and reveals a deficiency in the T/T mutant cells

The mesodermal cell layer is created by ingression and migration of the cells from the primitive streak region in mouse embryos on day 7 of pregnancy. In order to study the mechanisms of mesodermal cell migration during development, the mesodermal cells isolated from the primitive streak were cultured on various substrata, and cell behaviour and motility were analysed with a time-lapse video system. The mesodermal cells on the surface of extracellular matrix (ECM)-coated dishes (ECM produced by bovine corneal endothelial cells) showed extensive migration at a mean rate of approx. 50 micron h-1. They also showed frequent cell division and exhibited contact paralysis of lamellipodia and contact inhibition of movement. On plastic or glass surfaces, however, the mesodermal cells became more flattened and less motile (approx. 20-30 micron h-1). Cell shape and mean rate of movement on the ECM were very similar to those in situ, as investigated in a previous study (Nakatsuji, Snow & Wylie, 1986). Therefore, this culture condition could provide a useful experimental system for analysing the cellular basis of normal and abnormal morphogenetic movements in mouse embryos. Employing such a culture system, we studied motility of the mesodermal cells from embryos homozygous for Brachyury (T) mutation, which are lethal at the midgestation stage in utero. Histological observations have suggested that anomalous morphogenesis of the T/T embryos may be brought about by defects in migration of the mesodermal cells derived from the primitive streak. When mesodermal cells from the primitive streak of the T/T mutant embryos on days 8-9 were cultured on the ECM substratum, mean rate of cell migration was significantly reduced compared to cells from normal embryos. Results support the idea of retarded migration by the mutant mesodermal cells as an important factor causing abnormalities in morphogenesis.     

Mediolateral cell intercalation in the dorsal, axial mesoderm of Xenopus laevis

The pattern of mediolateral cell intercalation in mesodermal tissues during gastrulation and neurulation of Xenopus laevis was determined by tracing cells labeled with fluorescein dextran amine (FDA). Patches of the involuting marginal zone (IMZ) of early gastrula stage embryos, labeled by injection of FDA at the one-cell stage, were grafted to the corresponding regions of unlabeled host embryos. The host embryos were fixed at several stages, serially sectioned, and examined with fluorescence microscopy and three-dimensional reconstruction. Patterns of mixing of labeled and unlabeled cells show that mediolateral cell intercalation occurs in the posterior, dorsal mesoderm as this region undergoes convergent extension and differentiates into somites and notochord. In contrast, it does not occur in any dorsoventral sector of the anterior, leading edge of the mesodermal mantle. These results, taken with other evidence, suggest that the mesoderm of Xenopus consists of two subpopulations, each with a characteristic morphogenetic movement, cell behavior, and tissue fate. The migrating mesoderm (1) does not show convergent extension; (2) migrates and spreads on the blastocoel roof; (3) is dependent on this substratum for its morphogenesis; (4) shows little mediolateral intercalation; (5) consists of the anterior, early-involuting region of the mesodermal mantle; and (6) differentiates into head, heart, blood island, and lateral body wall mesoderm. The extending mesoderm (1) shows convergent extension; (2) is independent of the blastocoel roof in its morphogenesis; (3) shows extensive mediolateral intercalation; (4) consists of the posterior, late-involuting parts of the mesodermal mantle; and (5) differentiates into somite and notochord.     

Exogenous tenascin inhibits mesodermal cell migration during amphibian gastrulation.

We have used amphibian gastrulation as a model system to study the action of the extracellular matrix (ECM) glycoprotein tenascin on mesodermal cell migration. Tenascin function was assayed in vitro during spreading of isolated cells from the dorsal marginal zone (DMZ) and during cell migration from DMZ explants. Plastic coated with bovine fibronectin or gastrula ECM was used as a substratum. In both cases, tenascin added to the medium inhibited spreading and migration of mesodermal cells. In addition, a substratum coated with a mixture of fibronectin and tenascin was found to prevent mesodermal cell migration. Tenascin was also microinjected into the blastocoel cavity of living embryos at the late blastula stage. This led to a complete arrest of gastrulation in more than 80% of the cases. Scanning electron microscopy of fractures from arrested gastrulae showed that mesodermal cell migration was blocked. Similar injection experiments carried out at the middle gastrula stage demonstrated that tenascin is able to inhibit cell migration after cells have already contacted the ECM. Mesodermal cell migration in the presence of tenascin could be restored in vitro and in vivo by the monoclonal antibody mAb Tn68 which is known to mask a cell binding site of the molecule. Finally, tenascin microinjected into the blastocoel of blastula or gastrula stage embryos bound within 15 min to the ECM fibrils at all the stages studied. Our results show that exogenous tenascin can be incorporated into embryonic ECM and interferes in vivo with the interactions of cells with a fibronectin-rich matrix.     

Development of white spruce somatic embryos: II. Continual shoot meristem development during germination

Summary This study compares the development of shoot apical meristems of white spruce somatic and zygotic embryos during germination. In mature somatic embryos, the functional part of the shoot apical meristem was bi-layered. After partial drying, a normal shoot meristem was formed from these two cell layers during germination. Other cells within the meristem were vacuolated and separated by intercellular air spaces. In the absence of the partial drying treatment, somatic embryos enlarged in size primarily due to vacuolation of cells and the formation of large intercellular air spaces. A majority of these somatic embryos failed to form a functional shoot apical meristem. Compared with somatic embryos, the shoot apical meristem of a mature zygotic embryo was well organized with a densely cytoplasmic apical layer. The cells within the meristem were tightly packed. Judging from the cell profiles during germination, all cells within the meristem of the zygotic embryo took part in the formation of the vegetative shoot apical meristem.     

An in vitro Analogue of Early Chick Limb Bud Outgrowth

Our culture system appears to represent an in vitro analogue of early chick limb morphogenesis. Organized mesodermal cell accumulations resembling limb buds were derived from a monolayer of limb mesoderm cells when covered by limb ectoderm which included the apical ectodermal ridge (AER). The ridge retained its normal configuration when grown over a limb mesoderm monolayer and the mesoderm cells accumulated under the ridge to form a multilayered structure (10–25 cells in thickness) with the characteristic shape of a limb bud. Ectoderm which did not include the ridge failed to promote the formation of limb-like mesodermal accumulations thus the action of the ridge appears to be specific. The AER-elicited expression of mesodermal cell behaviour leading to early limb outgrowth is discussed in terms of possible morphogenetic mechanisms involved i.e. differential mitosis, cell migration, changes in cell shape and especially the adhesive properties of the cells.     

Cellular changes in early development of regenerating thin cell layer-explants of rapeseed analyzed by light and electron microscopy

Cellular changes in thin cell layer (TCL) explants of stem origin of Brassica napus L. cv. Vega were studied from 0 to 15 day by light and transmission electron microscopy. Apical and basal ends of the old explants were analysed separately. Quantitative and qualitative analyses showed that during the first culture day the parenchyma cells enlarged significantly as did the cytoplasm/vacuole ratio. The cytoplasm contained increased rough endoplasmic reticulum (RER), polysomes and dictyosomes associated with both coated and uncoated vesicles. The cell enlargement continued during the first 5 days of culture. The structural organization of the cell wall became somewhat loose and inhomogeneous. Parenchyma in the basal end divided frequently, resulting in several centres of division, while cell division in apical cells was less frequent and cells there remained enlarged. Starch accumulation started on the first day and increased until the third day. i. e. until cell divisions became more frequent. The starch content of dividing cells gradually decreased and starch was almost totally lacking in 15-day-old explants. Starch grains remained numerous, however, in the large non-dividing apical cells, except in those cells adjacent to the medium. Cell divisions started close to medium in explants containing vascular tissue, but closer to the epidermis in the explants without vascular tissue.
The results show how rapid (one day) striking changes in the cells take place and suggest that optimal hormone concentration and intertissue relations between epidermis and parenchyma and between parenchyma and vascular tissues as well as intercellular relations among parenchyma cells determine the first cell division sites and planes in the explants. Although the cells change from elongated to spheroid, their original polarity remains as evidenced by the formation of more numerous basal shoot primordia than in apical shoot primordia.     

A Possibility of an in Vitro Differentiation of Primordial Germ Cells (PGCs) from Blastomeres Containing "Germinal Plasm" of Early Cleavage Stage in Xenopus laevis

The blastomeres containing the "germinal plasm" were isolated from 32-cell stage Xenopus embryos and cultured in vitro for various periods of time till the control embryos developed to stage 28, 33/34, 40 and 45, respectively. The cells containing the plasm in the 'stage-28', '33/34' and '40' explants were similar in external shape, and in distribution in the spherical endodermal cell mass to the presumptive primordial germ cells (pPGCs) in normal embryos of the corresponding stages. In addition, the cells in explants as well as the pPGCs were separated by a large intercellular space from the surrounding endodermal cells. The change in proportion of the compact or the loosely structured germinal granules and the irregularly shaped-stringlike bodies (ISBs) occurred in the cells of the explants with the prolongation of the culture period. In the cells of the 'stage-45' explant as well as in the PGCs of normal stage-45 tadpoles the ISBs and "granular materials" replace those germinal granules. These facts lead to the conclusion that the change of the germinal granules through the ISBs, to the "granular materials", noticed in the normal course of differentiation of pPGCs into PGCs (see (1)), also takes place in the cells of the explants during the culture. Therefore, it is likely that the cells in the explants are genuine pPGCs or PGCs. This is the first demonstration of a possibility of the in vitro differentiation of PGCs from the blastomeres containing the "germinal plasm" of early cleavage stage.