Dorsalization of mesoderm induction by lithium

Lithium dorsalizes the body plan of Xenopus embryos when administered at the 32-cell stage (K.R. Kao and R.P. Elinson, 1988, Dev. Biol. 127, 64-77). In this paper, we have attempted to determine the effects of lithium on mesoderm induction, in order to localize the target of action of lithium. In the 32-cell embryo, the vegetal-most tier 4 cells are able to induce dorsal development in the overlying, equatorial tier 3 cells (R.L. Gimlich and J.C. Gerhart, 1984, Dev. Biol. 104, 117-130). Our experiments show that microinjection of lithium into either tier 3 or tier 4 cells of ultraviolet-irradiated, dorsoanterior-deficient embryos rescues normal development. Lineage tracer studies show that only tier 3-injected cells contribute progeny to dorsal axial structures while tier 4-injected cells contribute progeny to endoderm. Sandwich explants between animal caps and ventral vegetal cells cause induction of large amounts of muscle in the explants if either caps or vegetal cells are pretreated with lithium. Similarly, fibroblast growth factor-mediated mesoderm induction is also modified by lithium so that muscle is induced instead of ventral mesoderm. We conclude that lithium dorsalizes the response of animal cells to mesoderm induction signals, while not acting directly as a mesoderm inducer itself. The target of action of lithium is likely the third tier of cells of the 32-cell embryo.     

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.     

Activation of muscle-specific actin genes in Xenopus development by an induction between animal and vegetal cells of a blastula

Muscle gene expression is induced a few hours after vegetal cells of a Xenopus blastula are placed in contact with animal cells that normally develop into epidermis and nerve cells. We have used a muscle-specific actin gene probe to determine the timing of gene activation in animal-vegetal conjugates. Muscle actin RNA is first transcribed in a minority of animal cells at a stage equivalent to late gastrula. The time of muscle gene activation is determined by the developmental stage of the responding (animal) cells, and not by the time when cells are first placed in contact. The minimal cell contact time required for induction is between 1 1/2 and 2 1/2 hr, and the minimal time for gene activation after induction is 5-7 hr.     

Ectopic mesodermal expression promoted by the eight-cell stage Bufo arenarum subequatorial cytoplasm

Mesodermal determinants were investigated by cytoplasmic transfer and blastomere isolation in the eight-cell stage of Bufo arenarum. Their existence was confirmed by assaying the subequatorial cytoplasm’s ability to respecify the developmental potency of animal quartets. The gray subequatorial cytoplasm, but not animal cytoplasm, is able to divert the ectodermal fate of animal quartets to several mesodermal components. The source of the transplanted cytoplasm was important in determining the category of the resulting structures. Ventral subequatorial cytoplasm from ventrovegetal blastomeres generated ventral derivatives, namely erythrocytes and mesenchyma. Dorsal subequatorial cytoplasm from dorsovegetal blastomeres produced dorsolateral derivatives, such as notochord, muscle, nephric tubules, and coelomic epithelium, including mesenchyma. On the other hand, transfer of vegetal pole cytoplasm to animal quartets resulted in the formation of groups of endoderm-like cells dispersed among epidermal cells. However, the presence of such cells did not cause any mesodermal induction. The present findings suggest the existence of cytoplasmic information responsible for mesodermal specification. The alternative hypothesis that animal blastomeres become mesoderm due to vegetal induction is questioned. Received: 9 October 1998 / Accepted: 10 March 1999     

A maternal mRNA localized to the vegetal hemisphere in Xenopus eggs codes for a growth factor related to TGF-beta

We report that Vg1, a maternal mRNA localized to the vegetal hemisphere of frog eggs, encodes a member of the transforming growth factor-beta (TGF-beta) family of proteins. Furthermore, we show that Vg1 mRNA is distributed to presumptive endodermal cells after fertilization. Previous studies had shown that the vegetal end of a frog egg produces a signal that induces the overlying animal pole cells to form mesodermal tissue. More recently it has been shown that fibroblast growth factor (FGF) and TGF-beta can participate in the induction of muscle. Together, these results lead us to propose that the formation of mesoderm during frog development is specified by the products of localized maternal mRNAs, including Vg1.     

The role of micromere signaling in Notch activation and mesoderm specification during sea urchin embryogenesis.

In the sea urchin embryo, the micromeres act as a vegetal signaling center. These cells have been shown to induce endoderm; however, their role in mesoderm development has been less clear. We demonstrate that the micromeres play an important role in the induction of secondary mesenchyme cells (SMCs), possibly by activating the Notch signaling pathway. After removing the micromeres, we observed a significant delay in the formation of all mesodermal cell types examined. In addition, there was a marked reduction in the numbers of pigment cells, blastocoelar cells and cells expressing the SMC1 antigen, a marker for prospective SMCs. The development of skeletogenic cells and muscle cells, however, was not severely affected. Transplantation of micromeres to animal cells resulted in the induction of SMC1-positive cells, pigment cells, blastocoelar cells and muscle cells. The numbers of these cell types were less than those found in sham transplantation control embryos, suggesting that animal cells are less responsive to the micromere-derived signal than vegetal cells. Previous studies have demonstrated a role for Notch signaling in the development of SMCs. We show that the micromere-derived signal is necessary for the downregulation of the Notch protein, which is correlated with its activation, in prospective SMCs. We propose that the micromeres induce adjacent cells to form SMCs, possibly by presenting a ligand for the Notch receptor.     

Synergistic induction of mesoderm by FGF and TGF-beta and the identification of an mRNA coding for FGF in the early Xenopus embryo

The primary patterning event in early vertebrate development is the formation of the mesoderm and its subsequent induction of the neural tube. Classic experiments suggest that the vegetal region signals the animal hemisphere to diverge from the pathway of forming ectoderm to form mesoderm such as muscle. Here we show that bovine basic FGF has a limited capacity to induce muscle actin expression in animal hemisphere cells. This level of expression can be raised to levels normally induced in the embryo by another mammalian growth factor, TGF-beta, which by itself will not induce actin expression. We show that the Xenopus embryo contains an mRNA encoding a protein highly homologous to basic FGF. These results together with the identification of a maternal mRNA with strong homology to TGF-beta, suggest that molecules closely related to FGF and TGF-beta are the natural inducers of mesoderm in vertebrate development.     

Maternally localized germ plasm mRNAs and germ cell/stem cell formation in the cnidarian Clytia

The separation of the germ line from the soma is a classic concept in animal biology, and depending on species is thought to involve fate determination either by maternally localized germ plasm ("preformation" or "maternal inheritance") or by inductive signaling (classically termed "epigenesis" or "zygotic induction"). The latter mechanism is generally considered to operate in non-bilaterian organisms such as cnidarians and sponges, in which germ cell fate is determined at adult stages from multipotent stem cells. We have found in the hydrozoan cnidarian Clytia hemisphaerica that the multipotent "interstitial" cells (i-cells) in larvae and adult medusae, from which germ cells derive, express a set of conserved germ cell markers: Vasa, Nanos1, Piwi and PL10. In situ hybridization analyses unexpectedly revealed maternal mRNAs for all these genes highly concentrated in a germ plasm-like region at the egg animal pole and inherited by the i-cell lineage, strongly suggesting i-cell fate determination by inheritance of animal-localized factors. On the other hand, experimental tests showed that i-cells can form by epigenetic mechanisms in Clytia, since larvae derived from both animal and vegetal blastomeres separated during cleavage stages developed equivalent i-cell populations. Thus Clytia embryos appear to have maternal germ plasm inherited by i-cells but also the potential to form these cells by zygotic induction. Reassessment of available data indicates that maternally localized germ plasm molecular components were plausibly present in the common cnidarian/bilaterian ancestor, but that their role may not have been strictly deterministic.     

Animal-vegetal asymmetries influence the earliest steps in retina fate commitment in Xenopus.

An individual retina descends from a restricted and invariant group of nine animal blastomeres at the 32-cell stage. We tested which molecular signaling pathways are responsible for the competence of animal blastomeres to contribute to the retina. Inactivation of activin/Vg1 or fibroblast growth factor (FGF) signaling by expression of dominant-negative receptors does not prevent an animal blastomere from contributing to the retina. However, increasing bone morphogenetic protein (BMP) signaling in the retina-producing blastomeres significantly reduces their contribution. Conversely, reducing BMP signaling by expression of a dominant-negative BMP receptor or Noggin allows other animal blastomeres to contribute to the retina. Thus, the initial step in the retinal lineage is regulated by position within the BMP/Noggin field of epidermal versus neural induction. Vegetal tier blastomeres, in contrast, cannot contribute to the retina even when given access to the appropriate position and signaling fields by transplantation to the dorsal animal pole. We tested whether expression of molecules within the mesoderm inducing (activin, FGF), mesoderm-modifying (Wnt), or neural-inducing (BMP, Noggin) pathways impart a retinal fate on vegetal cell descendants. None of these, several of which induce secondary head structures, caused vegetal cells to contribute to retina. This was true even if the injected blastomeres were transplanted to the dorsal animal pole. Two pathways that specifically induce head tissues also were investigated. The simultaneous blockade of Wnt and BMP signaling, which results in the formation of a complete secondary axis with head and eyes, did not cause the vegetal clone to give rise to retina. However, Cerberus, a secreted protein that also induces an ectopic head with eyes, redirected vegetal progeny into the retina. These experiments indicate that vegetal blastomere incompetence to express a retinal fate is not due to a lack of components of known signaling pathways, but relies on a specific pathway of head induction.     

Determination and morphogenesis in the sea urchin embryo

The study of the sea urchin embryo has contributed importantly to our ideas about embryogenesis. This essay re-examines some issues where the concerns of classical experimental embryology and cell and molecular biology converge. The sea urchin egg has an inherent animal-vegetal polarity. An egg fragment that contains both animal and vegetal material will produce a fairly normal larva. However, it is not clear to what extent the oral-aboral axis is specified in embryos developing from meridional fragments. Newly available markers of the oral-aboral axis allow this issue to be settled. When equatorial halves, in which animal and vegetal hemispheres are separated, are allowed to develop, the animal half forms a ciliated hollow ball. The vegetal half, however, often forms a complete embryo. This result is not in accord with the double gradient model of animal and vegetal characteristics that has been used to interpret almost all defect, isolation and transplantation experiments using sea urchin embryos. The effects of agents used to animalize and vegetalize embryos are also due for re-examination. The classical animalizing agent, Zn2+, causes developmental arrest, not expression of animal characters. On the other hand, Li+, a vegetalizing agent, probably changes the determination of animal cells. The stability of these early determinative steps may be examined in dissociation-reaggregation experiments, but this technique has not been exploited extensively. The morphogenetic movements of primary mesenchyme are complex and involve a number of interactions. It is curious that primary mesenchyme is dispensable in skeleton formation since in embryos devoid of primary mesenchyme, the secondary mesenchyme cells will form skeletal elements. It is likely that during its differentiation the primary mesenchyme provides some of its own extracellular microenvironment in the form of collagen and proteoglycans. The detailed form of spicules made by primary mesenchyme is determined by cooperation between the epithelial body wall, the extracellular material and the inherent properties of primary mesenchyme cells. Gastrulation in sea urchins is a two-step process. The first invagination is a buckling, the mechanism of which is not understood. The secondary phase in which the archenteron elongates across the blastocoel is probably driven primarily by active cell repacking. The extracellular matrix is important for this repacking to occur, but the basis of the cellular-environmental interaction is not understood.(ABSTRACT TRUNCATED AT 400 WORDS)     

Interactions of different vegetal cells with mesomeres during early stages of sea urchin development

It has been known from results obtained in the classical experiments on sea urchin embryos that cell isolation and transplantation showed extensive interactions between the early blastomeres and/or their descendants. In the experiments reported here a systematic reexamination of recombination of mesomeres and their progeny (which come from the animal hemisphere) with various vegetal cells derived from blastomeres of the 32- and 64-cell stage was carried out. Cells were marked with lineage tracers to follow which cell gave rise to what structures, and newly available molecular markers have been used to analyze different structures characteristic of regional differentiation. Large micromeres form spicules and induce gut and pigment cells in mesomeres, conforming to previous results. Small micromeres, a cell type not heretofore examined, gave rise to no recognizable structure and had very limited ability to evoke poorly differentiated gut tissue in mesomeres. Macromeres and their descendants, Veg 1 and Veg 2, form primarily what their normal fate dictated, though both did have some capacity to form spicules, presumably by formation from secondary mesenchyme. Macromeres and their descendants were not potent inducers of vegetal structures in animal cells, but they suppress the latent ability of mesomeres to form vegetal structures. The results lead us to propose that the significant interactions during normal development may be principally suppressive effects of mesomeres on one another and of adjacent vegetal cells on mesomeres.     

POLARITIES, CELL DIFFERENTIATION AND PRIMARY INDUCTION IN THE AMPHIBIAN EMBRYO

1. Amphibian eggs are spherical, while the embryos are bilaterally symmetrical. The latter is manifested morphologically when gastrulation begins with the formation of the blastopore at a bilaterally symmetrical (vegetal-dorsal) location on the surface of the embryo. To account for this change in symmetry two polarities (vectors or axes) are required. These need not go through the centre, but if they do, one will go through two poles, called ‘animal’ and ‘vegetal’ in the amphibian embryo, and the other will pass through two points on opposite sides of the egg, one at the ‘dorsal’ and one at the ‘ventral’ side. Together these two polarities define a plane of bilateral symmetry. 2. It may be assumed that one polarity determines that gastrulation begins in the vegetal hemisphere, and the other that it begins at the dorsal side. 3. Judging from the distribution of pigment in the cortex of the egg and that of the yolk-hyaloplasm in the interior, an animal-vegetal polarity is already present in the unfertilized egg. That cytoplasmic components are actually part of the material substrate of this polarity is evident from the fact that the pattern of gastrulation may be upset if the distribution of yolk-hyaloplasm is deranged. 4. At fertilization the pigment border is raised at the side opposite the fertilizing sperm, giving rise to the ‘grey crescent’. The latter confers the first visible bilateral symmetry on the egg, and in fact it determines the presumptive median plane, for blastopore formation begins in the midline of the grey crescent. The dorso-ventral polarity imposed by the sperm is not irreversibly determined. By various experimental means, e.g. restriction of the oxygen supply, it may be inverted. 5. In order to understand the mechanism of the polarities it is necessary to study the processes on which the effects of the polarities are exerted, viz. the process of invagination associated with the formation of the blastopore. It has been known for a long time that at the bottom of the blastoporal groove are located some large flask-shaped cells, called ‘Ruffini's cells’. Various arguments can be mobilized to support the notion that these cells actually are engaged in pulling in the embryonic surface. 6. These cells are the first representatives of a cell type different from the spherical cells which are typical of the early embryo. It may therefore be presumed that Ruffini's cells are the products of the first cell differentiation occurring during amphibian embryogenesis. And it may further be assumed that the polarities somehow control this process. 7. A number of observations suggest that the animal-vegetal polarity is in direct control of the differentiation, ensuring that Ruffini's cells are formed only in the vegetal hemisphere. This point has been corroborated by isolating in cultures small aggregates from various regions of the blastula. When this is done it is found that the only path of differentiation available to animal cells is the formation of small spherical aggregates composed of a mixture of ciliated and non-ciliated cells. In contrast, in cultures of vegetal cells an outgrowth of cells occurs, and these cells share a number of properties with Ruffini's cells, and it is suggested that they are representatives of this cell type. 8. The formation of these cells is suppressed by inhibitors of RNA synthesis and by anaerobiosis induced by KCN. Since oxidative metabolism is apparently required for the differentiation of Ruffini's cells - gastrulation in the intact embryo is suppressed by anaerobiosis - a number of carbohydrate metabolites were scrutinized for their effect on the formation on Ruffini's cells. It was found that at 10 mm lactate completely suppresses their appearance, and indeed all the other cell differentiations that can otherwise be observed in our cell cultures. Since there is a very steep animal-vegetal cytoplasmic gradient in carbohydrate, the content being lowest at the vegetal pole, lactate might potentially be the agent of the animal-vegetal polarity, but there are a number of facts which do not readily support this idea. 9. If animal cells are explanted together with a few vegetal cells, some of the aggregates do not become ciliated, but rather exhibit an outgrowth similar to the one observed with vegetal cells. These animal cells have the same general shape as the vegetal Ruffini's cells, but they are smaller and more pigmented, typical ‘animal’ features. When the cultures are preserved, the cells undergo further differentiation, becoming either ‘mesenchyme’ cells, nerve cells, pigment cells and sometimes even muscle cells may be observed. In the normal embryo these differentiation patterns occur in that part of the animal hemisphere which becomes induced through contact with the vegetal material entering the blastocoel during gastrulation. Thus there is reason to assume that the induction occurring in our cultures is a miniature of the normal induction process. 10. Just as in the sea-urchin embryo, the animal cells in amphibia may become ‘vegetalized’ by addition of Li⁺ to the culture medium. 11. For various reasons it is likely that Ruffini's cells contain heparan sulphate, and in the belief that this substance might be the inductor proper, its effect was tested on animal cells. It turned out that in a concentration of 0·1 ppm it can alter the differentiation pattern of these cells, and we suggest that heparan sulphate, for the time being, is the most likely candidate for the role of primary inductor in the amphibian embryo. 12. The edges of the blastoporal groove, and hence the formation of Ruffini's cells, proceeds gradually around the circumference of the embryo. The effect of the dorso-ventral polarity therefore appears to be concerned with the time at which the cells undergo differentiation, imposing a spatial and a temporal gradient on this phenomenon. The second overt manifestation of the dorso-ventral polarity, next to the formation of the grey crescent, concerns the size of the embryonic cells, the dorsal ones being always smaller than the ventral. This fact suggests the possibility that the polarity may exert its effect by interfering with the process of cell division. 13. The cell divisions in the early embryo are distinguished by being synchronous; all cells are either undergoing mitosis or they are in interphase. The duration of the latter is typically very short. After a certain number of cell divisions, around 10, when the embryos are in the mid-blastula stage, the synchrony is gradually lost, while the interphase becomes considerably prolonged. This peculiar behaviour suggests that the cytoplasm of the early embryonic cells contain some factor which ensures the synchrony. The well-known presence in the early embryo of deoxyriboside-containing material, in an amount corresponding roughly to the total amount of DNA residing in the cell nuclei after 10 cell divisions hinted that deoxyribosides might indeed be the ‘synchrony factor’. 14. This idea was tested first on intact embryos. An excess of deoxyribonucleotides was injected into very early embryos. The result was developmental arrest at a pregastrula stage (no Ruffini's cells formed) in a large percentage of embryos. However, the number of cells was greater than in the controls, and the rate of cell division higher, indicating a delay in the transition to synchrony, thus supporting the proposed mechanism. Furthermore, the deoxynucleotides inhibited cell differentiation and an explanation of this was found in the fact that they also strongly inhibited RNA synthesis. 15. The studies were extended to cell cultures. It was found that deoxyribosides inhibit the differentiation of animal as well as vegetal cells; instead, the cells go on dividing at least for another two rounds. The utilization of added deoxyribosides does not demonstrate that the endogenous substances are similarly utilized. That they are, was indicated by the following experiment: In the presence of cytosine arabinoside, an inhibitor of DNA synthesis de novo, the explanted cells go on dividing an unknown number of times, and then they, animal as well as vegetal cells, undergo differentiation. But in either case these cells are larger (about four times) than the controls. This result suggests that in the experimental cultures the cells go on dividing as long as the cytoplasmic deoxyribosides last and then stop, while the controls synthesize their own DNA for two rounds of division before they undergo differentiation. 16. It is now possible to suggest a mechanism for the dorso-ventral polarity. First it affects the cell size such that the dorsal cells are the smallest. If the cytoplasmic deoxyribosides are evenly distributed at the outset, then small cells must be nearer exhaustion than large ones. A dorso-ventral gradient in cell sue will therefore automatically imply a dorso-ventral gradient in the time at which the cells reach the state in which they can undergo differentiation.     

Nuclear beta-catenin-dependent Wnt8 signaling in vegetal cells of the early sea urchin embryo regulates gastrulation and differentiation of endoderm and mesodermal cell lineages

The entry of beta-catenin into vegetal cell nuclei beginning at the 16-cell stage is one of the earliest known molecular asymmetries seen along the animal-vegetal axis in the sea urchin embryo. Nuclear beta-catenin activates a vegetal signaling cascade that mediates micromere specification and specification of the endomesoderm in the remaining cells of the vegetal half of the embryo. Only a few potential target genes of nuclear beta-catenin have been functionally analyzed in the sea urchin embryo. Here, we show that SpWnt8, a Wnt8 homolog from Strongylocentrotus purpuratus, is zygotically activated specifically in 16-cell-stage micromeres in a nuclear beta-catenin-dependent manner, and its expression remains restricted to the micromeres until the 60-cell stage. At the late 60-cell stage nuclear beta-catenin-dependent SpWnt8 expression expands to the veg2 cell tier. SpWnt8 is the only signaling molecule thus far identified with expression localized to the 16-60-cell stage micromeres and the veg2 tier. Overexpression of SpWnt8 by mRNA microinjection produced embryos with multiple invagination sites and showed that, consistent with its localization, SpWnt8 is a strong inducer of endoderm. Blocking SpWnt8 function using SpWnt8 morpholino antisense oligonucleotides produced embryos that formed micromeres that could transmit the early endomesoderm-inducing signal, but these cells failed to differentiate as primary mesenchyme cells. SpWnt8-morpholino embryos also did not form endoderm, or secondary mesenchyme-derived pigment and muscle cells, indicating a role for SpWnt8 in gastrulation and in the differentiation of endomesodermal lineages. These results establish SpWnt8 as a critical component of the endomesoderm regulatory network in the sea urchin embryo.     

The nodal target gene Xmenf is a component of an FGF-independent pathway of ventral mesoderm induction in Xenopus

The interplay of fibroblast growth factor (FGF) and nodal signaling in the Xenopus gastrula marginal zone specifies distinct populations of presumptive mesodermal cells. Cells in the vegetal marginal zone, making up the presumptive leading edge mesoderm, are exposed to nodal signaling, as evidenced by SMAD2 activation, but do not appear to be exposed to FGF signaling, as evidenced by the lack of MAP kinase (MAPK) activation. However, in the animal marginal zone, activation of both SMAD2 and MAPK occurs. The differential activation of these two signaling pathways in the marginal zone results in the vegetal and animal marginal zones expressing different genes at gastrulation, and subsequently having different fates, with the vegetal marginal zone contributing to ventral mesoderm (e.g. ventral blood island) and the animal marginal zone giving rise to dorsal fates (e.g. notochord and somite). We report here the cloning of a cDNA encoding a novel nuclear protein, Xmenf, that is expressed in the vegetal marginal zone. The expression of Xmenf is induced by nodal signaling and negatively regulated by FGF signaling. Results from animal cap studies indicate that Xmenf plays a role in the pathway of ventral mesoderm induction in the vegetal marginal zone.     

Brain induction in ascidian embryos is dependent on juxtaposition of FGF9/16/20-producing and -receiving cells

Coordinated regulation of inductive events, both spatially and temporally, during animal development ensures that tissues are induced at their specific positions within the embryo. The ascidian brain is induced in cells at the anterior edge of the animal hemisphere by fibroblast growth factor (FGF) signals secreted from vegetal cells. To clarify how this process is spatially regulated, we first identified the sources of the FGF signal by examining the expression of brain markers Hr-Otx and Hr-ETR-1 in embryos in which FGF signaling is locally inhibited by injecting individual blastomeres with morpholino oligonucleotide against Hr-FGF9/16/20, which encodes an endogenous brain inducer. The blastomeres identified as the inducing sources are A5.1 and A5.2 at the 16-cell stage and A6.2 and A6.4 at the 24-cell stage, which are juxtaposed with brain precursors at the anterior periphery of the embryo at the respective stages. We also showed that all the cells of the animal hemisphere are capable of expressing Hr-Otx in response to the FGF signal. These results suggest that the position of inducers, rather than competence, plays an important role in determining which animal cells are induced to become brain tissues during ascidian embryogenesis. This situation in brain induction contrasts with that in mesoderm induction, where the positions at which the notochord and mesenchyme are induced are determined mainly by intrinsic competence factors that are inherited by signal-receiving cells.