Autonomous differentiation of dorsal axial structures from an animal cap cleavage stage blastomere in Xenopus

Dorsal or ventral blastomeres of the 16- and 32-cell stage animal hemisphere were labeled with a lineage dye and transplanted into the position of a ventral, vegetal midline blastomere. The donor blastomeres normally give rise to substantial amounts of head structures and central nervous system, whereas the blastomere which they replaced normally gives rise to trunk mesoderm and endoderm. The clones derived from the transplanted ventral blastomeres were found in tissues appropriate for their new position, whereas those derived from the transplanted dorsal blastomeres were found in tissues appropriate for their original position. The transplanted dorsal clones usually migrated into the host's primary axis (D1.1, 92%; D1.1.1, 69%; D1.1.2, 100%), and in many cases they also induced and populated a secondary axis (D1.1, 43%; D1.1.1, 67%; D1.1.2, 63%). Bilateral deletion of the dorsal blastomeres resulted in partial deficits of dorsal axial structures in the majority of cases, whereas deletions of ventral midline blastomeres did not. When the dorsal blastomeres were cultured as explants they elongated. Notochord and cement glands frequently differentiated in these explants. These studies show that the progeny of the dorsal, midline, animal blastomeres: (1) follow their normal lineage program to populate dorsal axial structures after the blastomere is transplanted to the opposite pole of the embryo; (2) induce and contribute to a secondary axis from their transplanted position in many embryos; (3) are important for the normal formation of the entire length of the dorsal axis; and (4) autonomously differentiate in the absence of exogenous growth factor signals. These data indicate that by the 16-cell stage, these blastomeres have received instructions regarding their fate, and they are intrinsically capable of carrying out some of their developmental program.     

Activin-like signal activates dorsal-specific maternal RNA between 8- and 16-cell stages of Xenopus

In many animals the dorsalventral axis forms by an initial localization of maternal molecules, which then regulate the spatial location of signals that directly influence the expression of axis-specific fates. Several recent studies have demonstrated that dorsal-animal blastomeres of the Xenopus morula (8–32 cells) are biased toward dorsal fates prior to mesoderm inductive signaling In this study we ask whether the dorsal bias is the result of autonomous expression of maternal molecules specifically localized within dorsal cells or of early activating signals. It was found that although 16-cell dorsal-animal blastomeres (D1.1) can differentiate into dorsal tissues when cultured alone, the 8-cell mothers (D1) can not. Likewise, although RNA extracted from D1.1 can induce an extra dorsal axis when injected into vegetal blastomeres, RNA extracted from D1 can not. However, D1 does express dorsal tissues if co-cultured with dorsal-vegetal cells or with culture medium containing a mixture of activins (PIF-medium). Furthermore, short-term culture of D1 in PIF-medium enables the D1 RNA to induce an ectopic dorsal axis. Ven ral-animal blastomeres also can express dorsal axial tissues when co-cultured with dorsal-vegetal blastomeres or in PIF-medium, but the RNA from the activin-treated ventral cells cannot induce ectopic dorsal axes. These studies demonstrate that there are maternal RNAs that, shortly after fertilization are present only in the dorsalanimal region. They do not act cell autonomously, but require an activin-like signal. These RNAs may function by increasing the responsiveness of dorsal-animal blastomeres to the mesoderm inductive signals present in both the morula and the blastula. © Wiley-Liss, Inc.     

LOCALIZATION AND SEGREGATION OF MATERNAL RNA'S DURING EARLY CLEAVAGE OF XENOPUS LAEVIS EMBRYOS

The localization and segregation of maternal RNA's during early cleavage of Xenopus laevis embryos were studied. Blastomeres and hemispheres of eggs and early embryos were separated manually and the amounts of ribosomal RNA and poly(A) ⁺RNA extracted from each blastomere and hemisphere were determined by optical density measurement and by ³H-poly(U) hybridization, respectively. It was found that both kinds of the maternal RNA's were more abundant (two-thirds of the total) in the animal hemisphere (cells), while they were evenly distributed between the dorsal and ventral halves. This pattern of localization remained unchanged from the egg to the blastula stage, indicating that these maternal RNA's were segregated into blastomeres quite simply by cell division. Gel electrophoresis showed that the size distributions of poly(A) ⁺RNA and poly(A) sequences obtained from different blastomeres of 8-cell embryos did not differ greatly. It was also found that cytoplasmic polyadenylation of maternal RNA, which occurs during early cleavage and blastulation, took place equally in all regions of the cleaving embryos, suggesting no regional difference in the localization of maternally inherited nonpolyadenylated RNA. These observations are discussed in relation to previous findings on differences along the animal-vegetal and dorsal-ventral axes of the early amphibian embryo.     

Primitive and definitive blood share a common origin in Xenopus: a comparison of lineage techniques used to construct fate maps

Primitive blood constitutes the ventralmost mesoderm in amphibians, and its cleavage-stage origin reveals important clues about the orientation of the dorsal/ventral axis in the embryo. In recent years, investigators employing various lineage-labeling strategies have reported disparate results for the origin of primitive blood in Xenopus [W. D. Tracey, Jr., M. E. Pepling, G. H. Thomsen, and J. P. Gergen (1998). Development 125, 1371-1380; M. C. Lane W. C. Smith (1999). Development 126, 423-434; K. R. Mills, D. Kruep, and M. S. Saha (1999). Dev. Biol. 209, 352-368; A. Ciau-Uitz, M. Walmsley, and R. Patient (2000). Cell 102, 787-796]. These discrepancies must be resolved in order to elucidate early embryonic patterning mechanisms in vivo. We directly compared two of the techniques used to determine the origin of the ventral blood islands and primitive blood, injection of either beta-galactosidase mRNA or conjugated dextrans, by coinjecting both tracers simultaneously into individual blastomeres in cleavage-stage embryos. We find that dextrans label progeny efficiently, while beta-galactosidase activity is not present in many of the progeny of an injected blastomere, suggesting that mRNA fails to diffuse throughout a blastomere. This result demonstrates that beta-galactosidase mRNA fails to meet the criterion for a true lineage label, namely efficient detection of the progeny of a blastomere, and raises questions about interpretations based on mapping the ventral blood islands using Lac Z mRNA as a tracer. We examined the origins of the ventral blood islands and primitive blood from the vegetal region of the marginal zone in regularly cleaving embryos by coinjecting both reporters into C-tier blastomeres. Our results demonstrate that both the ventral blood islands and primitive blood routinely arise from all C-tier blastomeres. Our data, in combination with published mapping results for the dorsal aorta, demonstrate that primitive and definitive blood do not have separate origins at the 32-cell stage in Xenopus. In addition, these results support a proposal to align the dorsal/ventral axis of the mesendoderm with the animal/vegetal axis in pregastrula Xenopus.     

Induction of dorsal and ventral mesoderm by ectopically expressed Xenopus basic fibroblast growth factor.

Peptide growth factors from the fibroblast growth factor (FGF) and transforming growth factor-beta families are likely regulators of mesoderm formation in the early Xenopus embryo. Although basic FGF is found in the Xenopus embryo at the correct time and at sufficient concentrations to suggest that it is the FGF-type inducer, the lack of a secretory signal sequence in the basic FGF peptide has raised questions as to its role in the inductive process. We show here that Xenopus basic FGF can ectopically induce mesoderm when translated from injected synthetic RNA within the cells of a Xenopus embryo. Basic FGF produced in this manner is able to induce the formation of both dorsal and ventral mesoderm with the type of mesoderm formed dependent on the inherent dorsal-ventral polarity of the animal hemisphere. Surprisingly, although Xenopus basic FGF produced from the injected mRNA has a potent mesodermalizing effect on animal hemisphere cells, virtually no phenotypic effect is observed with intact embryos. These results suggest that the role of Xenopus basic FGF is to specify the size of the marginal zone, and synergistically with a dorsally localized prepatterning signal, to initially establish the dorsal-ventral axis of the mesoderm.     

Identification and cloning of localized maternal RNAs from Xenopus eggs

A central question in developmental biology is to explain how cells in different regions of an embryo acquire different developmental fates. We have begun to address this question by investigating whether specific RNAs are localized within a frog egg. Differential screening of a cDNA library shows that most maternal RNAs are uniformly distributed along the animal-vegetal axis. However, we find that a rare class of maternal RNAs is localized. cDNA clones of four localized RNAs have been characterized. Three of these cDNAs are derived from maternal RNAs that are concentrated in the animal hemisphere of unfertilized eggs and remain localized through the early blastula stage. One cDNA is derived from a maternal RNA found almost exclusively in the vegetal hemisphere at both stages. These studies show that some informational molecules, specifically RNAs, are localized in eggs and are inherited by particular blastomeres.     

Onset of competence to respond to activin A in isolated eight-cell stage Xenopus animal blastomeres

Single animal hemisphere blastomeres isolated from the eight-cell stage Xenopus embryos differentiate into mesoderm when treated with activin A, whereas when cultured without activin they form atypical epidermis. The mesoderm tissue induced by activin is different between dorsal and ventral blastomeres. In the present study, the duration and timing of activin treatment was varied, in order to identify the critical stage when animal blastomeres acquire competence to respond to activin A. It was shown that the critical time was 45 min after blastomere isolation, which corresponds approximately to NF stage 6 (32-cell stage) of normal development. The competence gradually increased during the morula stages.     

Pattern regulation in defect embryos of Xenopus laevis

Defect embryos of 24 series were prepared by removing increasing numbers of blastomeres from an 8-cell embryo of Xenopus laevis. They were cultured and their development was examined macroscopically when controls reached a tailbud stage or later. Results show that most of defect embryos of 12 series develop normally, and some of them become normal frogs. Each of these defect embryos contain at least two animal blastomeres, one dorsal, and one ventral blastomere of the vegetal hemisphere. This suggests that a set of these four blastomeres of the three types is essential for complete pattern regulation.     

The first cleavage furrow demarcates the dorsal-ventral axis in Xenopus embryos

To determine the relationship between the first cleavage furrow and the dorsal-ventral axis of the Xenopus embryo, a heritable intracellular marker was injected into one blastomere at the two-cell stage. Embryos were selected in which the cleavage furrow bisected the crescent-shaped region of pale pigmentation or in which it formed 45-90 degrees from this region. This region, which is located in the animal hemisphere of the Xenopus embryo, meets the criteria of the grey crescent as defined in other amphibian species. At tailbud stages the interface between the labeled and unlabeled halves was always coincident with the midsagittal plane. This correlation shows that the first cleavage furrow demarcates the dorsal-ventral axis. The labeling pattern was the same whether the first cleavage furrow bisected the region of pale pigmentation or whether it formed 90 degrees from it. However, when this region was bisected (70% of embryos) it always was located on the dorsal side of the embryo. Thus the region of pale pigmentation indicates the dorsal side of the embryo only when it is bisected by the first cleavage furrow.     

Distinct effects of ectopic expression of Wnt-1, activin B, and bFGF on gap junctional permeability in 32-cell Xenopus embryos.

A polarity in gap junctional permeability normally exists in 32-cell stage Xenopus embryos, in that dorsal cells are relatively more coupled than ventral cells, as measured by transfer of Lucifer yellow dye. The current study extends our analysis of whether gap junctional permeability at this stage can be modulated by secreted factors, and whether the polarity in gap junctional permeability correlates with the effects of ectopic expression of these secreted factors on the subsequent phenotype of the developing embryo. Following ectopic expression of activin B or Wnt-1, but not bFGF, the transfer of Lucifer yellow between ventral animal pole cells is detected in a greater percentage of 32-cell stage embryos. This increased incidence of dye transfer between ventral cells correlates with axial duplications later in development. However, there are differences in the extent of Lucifer yellow transfer between animal and vegetal hemisphere blastomeres which is dependent on whether activin B or Wnt-1 RNA had previously been injected. These results suggest that enhanced gap junctional permeability between ventral cells of 32-cell Xenopus embryos correlates with subsequent defects in the dorsoventral axis, although there are at present no direct data demonstrating a role for gap junctions in establishment or maintenance of this axis. Moreover, while both activin B and bFGF are mesoderm-inducing growth factors, only activin B has effects on gap junctional permeability in 32-cell embryos following ectopic expression, demonstrating an interesting difference in physiological responses to expression of these factors.     

Boundaries and functional domains in the animal/vegetal axis of Xenopus gastrula mesoderm

Patterning of the Xenopus gastrula marginal zone in the axis running equatorially from the Spemann organizer-the so--called "dorsal/ventral axis"--has been extensively studied. It is now evident that patterning in the animal/vegetal axis also needs to be taken into consideration. We have shown that an animal/vegetal pattern is apparent in the marginal zone by midgastrulation in the polarized expression domains of Xenopus brachyury (Xbra) and Xenopus nodal-related factor 2 (Xnr2). In this report, we have followed cells expressing Xbra in the presumptive trunk and tail at the gastrula stage, and find that they fate to presumptive somite, but not to ventrolateral mesoderm of the tailbud embryo. From this, we speculate that the boundary between the Xbra- and Xnr2-expressing cells at gastrula corresponds to a future tissue boundary. In further experiments, we show that the level of mitogen-activated protein kinase (MAPK) activation is polarized along the animal/vegetal axis, with the Xnr2-expressing cells in the vegetal marginal zone having no detectable activated MAPK. We show that inhibition of MAPK activation in Xenopus animal caps results in the conversion of Xnr2 from a dorsal mesoderm inducer to a ventral mesoderm inducer, supporting a role for Xnr2 in induction of ventral mesoderm.     

16细胞期爪蟾胚胎背方与腹方裂球的发育能力

在两栖类爪蟾胚胎发育中,由受精引起的皮层转动造成了受精卵的背腹极性。为了研究受精卵细胞质的不均一分布对胚胎体轴形成的影响,我们进行了16细胞期动物极背、腹方裂球的外植和异位移植实验。16细胞期的动物极背方裂球在外植和移植到腹方位置后都表现出背方特征,如外植块培养到原肠中期时伸长,背方裂球在移植到腹方后引发第二体轴等;而16细胞期动物极腹方裂球移植到背方后其发育命运则遵循背方裂球的命运,参与背方结构的形成。我们认为在16细胞期,动物极背、腹方的裂球由于包含着不同的卵质,因而在发育能力上已经具有背、腹的差异。     

Secretion and mesoderm-inducing activity of the TGF-beta-related domain of Xenopus Vg1.

Vg1 is a maternal mRNA localized to the vegetal hemisphere of Xenopus embryos during blastula stages, a region responsible for the induction of mesoderm in the adjacent marginal zone. Its homology to the transforming growth factor-beta family, which includes several proteins with mesoderm-inducing activity, suggests a role for Vg1 as an endogenous mesoderm-inducing factor. However, expression of Vg1 protein in the animal hemisphere, following injection of synthetic mRNA, has no effect on development, and isolated animal caps are not mesodermalized. It is shown that Vg1 protein fails to form dimers and is not processed to release the putative bioactive domain. Furthermore it is shown that the N-terminal signal peptide of Vg1 is not cleaved following translocation into the ER, which may explain the failure of this protein to dimerize. To explore the role of Vg1 in amphibian development, a fusion protein has been made of the preproregion of Xenopus bone morphogenetic protein-4 and the putative bioactive C-terminal domain of Vg1. This fusion protein forms dimers and the C-terminal domain of Vg1 is secreted. Injection of this construct into Xenopus embryos induces the formation of a second dorsal axis and isolated animal caps are mesodermalized. The results are consistent with a role for Vg1 in mesoderm induction during Xenopus development.     

Progressive determination of cell fates along the dorsoventral axis in the sea urchin Heliocidaris erythrogramma

In the direct-developing sea urchin Heliocidaris erythrogramma the first cleavage division bisects the dorsoventral axis of the developing embryo along a frontal plane. In the two-celled embryo one of the blastomeres, the ventral cell (V), gives rise to all pigmented mesenchyme, as well as to the vestibule of the echinus rudiment. Upon isolation, however, the dorsal blastomere (D) displays some regulation, and is able to form a small number of pigmented mesenchyme cells and even a vestibule. We have examined the spatial and temporal determination of cell fates along the dorsoventral axis during subsequent development. We demonstrate that the dorsoventral axis is resident within both cells of the two-celled embryo, but only the ventral pole of this axis has a rigidly fixed identity this early in development. The polarity of this axis remains the same in half-embryos developing from isolated ventral (V) blastomeres, but it can flip 180° in half-embryos developing from isolated dorsal (D) blastomeres. We find that cell fates are progressively determined along the dorsoventral axis up to the time of gastrulation. The ability of dorsal half-embryos to differentiate ventral cell fates diminishes as they are isolated at progressively later stages of development. These results suggest that the determination of cell fates along the dorsoventral axis in H. erythrogramma is regulated via inductive interactions organized by cells within the ventral half of the embryo.     

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.     

Pre-MBT patterning of early gene regulation in Xenopus: the role of the cortical rotation and mesoderm induction

Patterning events that occur before the mid-blastula transition (MBT) and that organize the spatial pattern of gene expression in the animal hemisphere have been analyzed in Xenopus embryos. We present evidence that genes that play a role in dorsoventral specification display different modes of activation. Using early blastomere explants (16–128-cell stage) cultured until gastrula stages, we demonstrate by RT-PCR analysis that the expression of goosecoid (gsc), wnt-8 and brachyury (bra) is dependent on mesoderm induction. In contrast, nodal-related 3 (nr3) and siamois (sia) are expressed in a manner that is independent of mesoderm induction, however their spatially correct activation does require cortical rotation. The pattern of sia and nr3 expression reveals that the animal half of the 16-cell embryo is already distinctly polarized along the dorsoventral axis as a result of rearrangement of the egg structure during cortical rotation. Similar to the antagonistic activity between the ventral and the dorsal mesoderm, the ventral animal blastomeres can attenuate the expression of nr3 and sia in dorsal animal blastomeres. Our data suggest that no Nieuwkoop center activity at the blastula stage is required for the activation of nr3 and sia in vivo.     

Intrinsic chiral properties of the Xenopus egg cortex: an early indicator of left-right asymmetry?

Vertebrate embryos define an anatomic plane of bilateral symmetry by establishing rudimentary anteroposterior and dorsoventral (DV) axes. A left-right (LR) axis also emerges, presaging eventual morphological asymmetries of the heart and other viscera. In the radially symmetric egg of Xenopus laevis, the earliest steps in DV axis determination are driven by microtubule-dependent localization of maternal components toward the prospective dorsal side. LR axis determination is linked in time to this DV-determining process, but the earliest steps are unclear. Significantly, no cytoskeletal polarization has been identified in early embryos capable of lateral displacement of maternal components. Cleaving Xenopus embryos and parthenogenetically activated eggs treated with 2,3-butanedione monoxime (BDM) undergo a dramatic large-scale torsion, with the cortex of the animal hemisphere shearing in an exclusively counterclockwise direction past the vegetal cortex. Long actin fibers develop in a shear zone paralleling the equator. Drug experiments indicate that the actin is not organized by microtubules, and depends on the reorganization of preexisting f-actin fibers rather than new actin polymerization. The invariant chirality of this drug response suggests a maternally inherited, microfilament-dependent organization within the egg cortex that could play an early role in LR axis determination during the first cell cycle. Consistent with this hypothesis, brief disruption of cortical actin during the first cell cycle randomizes the LR orientation of tadpole heart and gut.