Structural alteration of the target plasma membrane affects reception but not expression of the neural inductive signal

We have previously reported that incubation of presumptive neuroectoderm in a solution of lectin (soybean agglutinin or garden pea agglutinin at 50 micrograms ml-1, 30 min) prior to its association with blastoporal lip inhibits neural induction (Duprat et al., 1982). We have also shown that incubation of presumptive ectoderm immediately after its association with blastoporal lip does not prevent neural induction. The same pattern of fluorescence on the ectodermal surface was observed when incubation with lectin was carried out before or after association of ectoderm with blastoporal lip. Although a particular molecular organization of the plasma membrane of the target ectoderm appears to be essential for reception or initiation of neural induction, the subsequent transmission and expression of this neural information does not appear to be affected by structural modifications of the target membrane. Similar studies performed using the inducer Con A indicated that the experimentally induced signal differed from the natural one.     

From presumptive ectoderm to neural cells in an amphibian

As an immediate consequence of neural induction during gastrulation, some neuroectodermal cells acquire the ability to develop a number of specific neuronal and astroglial features, without requiring subsequent chordamesodermal cues. Thus, cholinergic, dopaminergic, noradrenergic, gabaergic, somatostatinergic, enkephalinergic, etc. traits are expressed in cultures of neural plate and neural fold isolated from amphibian late gastrulae immediately after induction and cultured in a defined medium. These results strongly suggest that at the late gastrula stage, the neural precursor population does not yet constitute a homogeneous set of cells. It was of interest to know the origin of this heterogeneity. Is it a direct result of the process of neural induction itself, stochastic phenomena being involved or not at the cellular level, or does it reflect a pre-existing heterogeneity in the presumptive ectoderm? At the early gastrula state, presumptive ectoderm can be neuralized consecutively to its dissociation into single cells. Using this experimental model, we have demonstrated by means of immunological probes that neuralized presumptive ectodermal cells, without any intervention of the chordamesoderm (natural inducing tissue), can develop autonomously into glial and neuronal lineages. These data suggest the existence of diverse predispositions of presumptive ectodermal cells. Competent ectoderm seems to be a heterogeneous structure with cells presenting distinct neural predispositions that can emerge as a consequence of a permissive inductive signal without real specificity (such as a target tissue dissociation). Moreover, such a differentiated neuronal population includes neurons of the GABAergic and enkephalinergic phenotypes but not of the cholinergic, catecholaminergic, somatostatinergic, etc. phenotypes. These data show that the developmental program of ectodermal cells induced without interaction with the chordamesoderm appears restricted compared to the naturally induced ectoderm. Experiments are now under way to analyze such sequential neural events.     

BRAIN INDUCTION IN VARIOUSLY AGED PRESUMPTIVE ECTODERMS BY HEAD ORGANIZER IN CYNOPS PYRRHOGASTER

Brain formation in variously aged presumptive ectoderms of Cynops pyrrhogaster under the influence of the head organizer was examined by the sandwich method. The head organizer was obtained from the middle portion of the archenteron roof at the slit-blastopore stage. The presumptive ectoderm was taken from 0- to 36-hr exogastrulae. Exogastrulae were prepared from the earliest gastrulae just before invagination (0-hr embryos). The presumptive neural plate overlying the archenteron roof used as organizer was cultivated in an envelope of belly ectoderm from an early neurula.
The following results were obtained: 1) Brain induction was almost entirely restricted to explants covered with 6-hr ectoderm and its frequency was low. 2) The presumptive neural plate above the head organizer was almost completely determined as neural tissues. 3) The head organizer showed a tendency to differentiate into more endodermal and less mesodermal tissues than those expected from its prospective fate.
Brain induction in normal development and the relationship between neural tissue formation in variously aged presumptive ectoderms and the time necessary for neural induction are discussed.     

Homoiogenetic Neural Induction in Xenopus Chimeric Explants

We previously raised monoclonal antibodies specific for epidermis (7) and neural tissue (8) of Xenopus for use as markers of tissue differentiation in induction experiments (8). Here we have used these monoclonal antibodies to examine homoiogenetic neural induction, by which cells induced to differentiate to neural tissues can in turn induce competent ectoderm to do the same. Presumptive anterior neural plate excised from late gastrulae of Xenopus laevis was conjugated with competent ectoderm from the initial gastrula of Xenopus borealis , either side by side or with their inner surfaces together. The chimeric explants enabled us to distinguish induced neural tissues from inducing neural tissues. In both types of explant, neural tissues identified by the neural tissue-specific antibody, NEU-1, were induced in the competent ectoderm by the presumptive anterior neural plate. The results suggest that homoiogenetic neural induction does occur in Xenopus embryos.     

Homeogenetic neural induction in Xenopus

Neural induction is known to involve an interaction of ectoderm with dorsal mesoderm during gastrulation, but several kinds of studies have argued that competent ectoderm can also be neutralized via an interaction with previously neuralized tissue, a process termed homeogenetic neural induction. Although homeogenetic neural induction has been proposed to play an important role in the normal induction of neural tissue, this process has not been subjected to detailed study using tissue recombinants and molecular markers. We have examined the question of homeogenetic neural induction in Xenopus embryos, both in transplant and recombinant experiments, using the expression of two neural antigens to assay the response. When ectoderm that is competent to be neuralized is transplanted to the region adjacent to the neural plate of early neurula embryos, it forms neural tissue, as assayed by staining with antibodies against the neural cell adhesion molecule, N-CAM. Transplants to the ventral region, far from the neural plate, do not express N-CAM, indicating that neuralization is not occurring as a result of the transplantation procedure itself. Because this response might be occurring as a result of interactions of ectoderm with either adjacent neural plate tissue, or with underlying dorsolateral mesoderm, recombinant experiments were performed to determine the source of the neuralizing signal. Ectoderm cultured in combination with neural plate tissue alone expresses neural markers, while ectoderm cultured in combination with dorsolateral mesoderm does not. We conclude that neural tissue can homeogenetically induce competent ectoderm to form neural tissue and argue that this induction occurs via planar signaling within the ectoderm, a mechanism that, in normal development, may be involved in interactions within presumptive neural ectoderm or in specifying structures that lie near the neural plate.     

EFFECT OF AGING ON NEURAL COMPETENCE OF PRESUMPTIVE ECTODERM, AND EFFECT OF AGED ECTODERM ON DIFFERENTIATION OF THE ORGANIZER IN CYNOPS PYRRHOGASTER II. ROLE OF EXTREME POSTERIOR OF THE ARCHENTERIC ROOF IN THE SLIT-BLASTOPORE STAGE IN NORMAL DEVELOPMENT

The effect of aging on the neural competence of the presumptive ectoderm in gastrulae of Cynops pyrrhogaster and the effect of aged ectoderm on differentiation of the extreme posterior of the archenteric roof in the slit-blastopore stage were examined by a sandwich method in which this organizer was wrapped in the presumptive ectoderm taken from the 0- to 42-hr aged exogastrulae. Vital staining showed that this organizer becomes mainly tail notochord. Therefore it should be called tail or trunk-tail organizer. In 0- to 18-hr explants, typical trunk-tail structures were formed. With further aging of the presumptive ectoderm, a decrease of spinal cord and muscle with a concomitant increase of mesenchyme and mesothelium was observed. In 36- (corresponding to the slit-blastopore-initial neural stage) and 42-hr explants, neural competence had disappeared markedly. The notochord appeared in all explants, indicating this organizer is more firmly determined than the uninvaginated dorsal lip in small yolk-plug stage. Conclusively, this organizer does not play an important role in the induction of the neural plate, but induces the tail in normal development.     

A monosaccharide is bound to the sodium pump alpha-subunit.

We have recently reported that the Na pump alpha-subunit has cytosolic-oriented oligosaccharides which were sensitive to cleavage by an enzyme specific for hydrolysis of N-linked glycans [Pedemonte et al. (1990) Proc. Natl. Acad. Sci. U.S.A. 87, 9789-9793]. We now describe experiments that characterize the saccharides and further substantiate our previous findings. Bovine milk galactosyltransferase has been used in conjunction with radiolabeled UDP-galactose to label N-acetylglucosamine residues on the protein. The Na pump alpha-subunit contains some O-linked carbohydrates; however, the bulk (> 80%) of the radioactivity was found in oligosaccharides sensitive to peptide:N-glycosidase F degradation but not to alkaline hydrolysis. Alkaline hydrolysis produced degradation of the protein, and the [3H]Gal radiolabeled carbohydrates remained bound to peptides and were released by subsequent peptide N-glycosidase F treatment. The exogenously galactosylated sugars cleaved by the glycosidase were analyzed by liquid chromatography and had elution volumes identical to a galactose-N-acetylglucosamine disaccharide standard. Since the galactose was exogenously added, we propose that the N-linked glycans on the alpha-subunit of the Na pump are composed of a single sugar residue, which is probably N-acetylglucosamine.     

Homoiogenetic Neural Inducing Activity of the Presumptive Neural Plate of Xenopus Laevis

Heteroplastic combinations were made between Xenopus laevis presumptive neural plate and competent ectoderm of Xenopus borealis . Primarily induced presumptive neural plate cells ( Xenopus laevis ) can easily be distinguished from Xenopus borealis cells by specific quinacrine fluorescence of the nuclei. It was clearly shown that presumptive neural plate, which has primarily been induced by the underlying chordamesoderm exerts homoiogenetic inducing activity on competent ectoderm. The inducing activity is increased in pieces of presumptive neural plates, when the superficial layer has been removed from the adjacent deep layers. The enhancement can be explained by the fact that the removal of the superficial layer acting as barrier allows the inducing stimulus to be easily propagated from the apical (distal) side of the deep layers of the presumptive neural plate.     

Expression of the guanine nucleotide-binding protein Go correlates with the state of neural competence in the amphibian embryo

The nucleotide-binding protein Go is a transducing molecule closely associated with neural structures in vertebrates. Because of the potential importance of molecules of this type during the first step of neurogenesis, we have investigated the kinetics of expression of Go in the amphibian (Pleurodeles waltl) embryo, focusing our attention on the stages corresponding to the acquisition of neural competence by presumptive ectoderm and to the process of neural induction. Using affinity-purified IgGs directed against the alpha subunit of Go, Go-like immunoreaction (GoLI) is first detected at the midblastula stage in some animal cap (future ectodermal) cells just before they have attained competence to be neuralized. At the early gastrula stage, GoLI is almost exclusively expressed by neural-competent tissue as a whole, with no obvious difference between the dorsal (prospective neural) and the ventral (prospective epidermal) ectoderm. The expression of GoLI is therefore related to the state of competence of the tissue rather than to its fate. At the early neurula stage, immediately following neural induction, the expression of GoLI persists essentially in that part of ectoderm that has been diverted from epidermal differentiation towards the neural pathway; in the ventral ectoderm, as neural competence is lost GoLI disappears. Furthermore, in the neurectoderm, only approximately 70% of the cells conserve GoLI, demonstrating that immediately following neural induction the population of neurectodermal cells is not homogeneous.     

DIFFERENTIATION OF PARTIALLY MESODERMALIZED ECTODERM; HOMOIOGENETIC AND HETEROGENETIC INDUCTION BY PRIMARILY INDUCED PART OF THE ECTODERM

Using embryos of the Japanese newt, Cynops pyrrhogaster , homoiogenetic and heterogenetic induction were investigated in the partially mesodermaelzed presumptive ectoderm. Half of the isolated presumptive ectoderm was placed in contact with the swimbladder of the crucian carp, Carasius auratus , for 15 or 60 min, while the other half was stained with Nile blue sulfate at the same time. The distribution of the stained cells in the tissues evoked in the explants was examined after cultivation for 10 days.
Some mesodermal tissues were composed of both stained and unstained cells. This indicates homoiogenetic induction by the primarily induced part of the ectoderm on the other half. The neural and epidermal tissues in the explants were composed of stained cells only, except in one case. We conclude that the neural tissues are derived from cells not placed in contact with the swimbladder and that they are induced by the primarily induced part of the ectoderm.     

Early tissue interactions leading to embryonic lens formation in Xenopus laevis

Our previous research has demonstrated that lens induction in Xenopus laevis requires inductive interactions prior to contact with the optic vesicle, which classically had been thought to be the major lens inductor. The importance of these early interactions has been verified by demonstrating that lens ectoderm is specified by the time it comes into contact with the optic vesicle. It has been argued that the tissues which underlie the presumptive lens ectoderm during gastrulation and neurulation, dorsolateral endoderm and mesoderm, are the primary early inductors. We show here, however, that these tissues alone cannot elicit lens formation in Xenopus ectoderm. Evidence is presented that presumptive anterior neural plate tissue (which includes the early eye rudiment) is an essential early lens inductor in Xenopus. The presence of dorsolateral mesoderm appears to enhance this response. These findings support a model in which an essential inductive signal passes through the plane of ectoderm during gastrula and early neurula stages from presumptive anterior neural tissue to the presumptive lens ectoderm. Since there is evidence for such interactions within a tissue layer in mesodermal and neural induction as well, this may be a general feature of the initial stages of determination of many tissues.     

Modulation of neural commitment by changes in target cell contacts in Pleurodeles waltl

In amphibian development, neural structures arise from the presumptive ectoderm at the gastrula stage by an inductive interaction with the chordamesoderm. It has been previously reported that early gastrula presumptive ectoderm can be neuralized when it is dissociated into single cells. A similar result is reported here with regard to Pleurodeles waltl presumptive ectoderm. Using this experimental model system we demonstrate: first, that neuronal and glial lineages can be specified from the presumptive ectoderm without any intervention of the natural inducing tissue; and second, that whereas rupture of cell-cell contacts evoked neural induction, dissociation immediately followed by reaggregation reduces the neuralizing response, pointing toward an active role played by cell-cell contacts of presumptive ectodermal cells in the modulation of neural commitment.     

Characterization of carbohydrates using highly fluorescent 2-aminobenzoic acid tag following gel electrophoresis of glycoproteins.

Application of the most sensitive fluorescent label 2-aminobenzoic acid (anthranilic acid, AA) for characterization of carbohydrates from the glycoproteins ( approximately 15 pmol) separated by polyacrylamide gel electrophoresis is described. AA label is used for the determination of both monosaccharide composition and oligosaccharide map. For the monosaccharide determination, bands containing the glycoprotein of interest are excised from the polyvinylidene fluoride (PVDF) membrane blots, hydrolyzed in 20% trifluoroacetic acid, derivatized, and analyzed by C-18 reversed-phase high-performance liquid chromatography. For the oligosaccharide mapping, bands were digested with peptide N-glycosidase F (PNGase F) in order to release the N-linked oligosaccharides, derivatized, and analyzed by normal-phase anion-exchange chromatography. For convenience, the PNGase F digestion was performed in 1:100 diluted ammonium hydroxide overnight. The oligosaccharide yield from ammonium hydroxide-PNGase F digestion was better or equal to all the other reported procedures, and the presumed "oligosaccharide-amine" product formed in the reaction mixture did not interfere with labeling of the oligosaccharides under the conditions used for derivatization. Sequencing of oligosaccharides can be performed using the same mapping method following treatment with an array of glycosidases. In addition, the mapping method is useful for determining the relative and simultaneous distribution of sialic acid and fucose.     

Cell Contacts Between Chorda-Mesoderm and the Overlaying Neuroectoderm (Presumptive Central Nervous System) During the Period of Primary Embryonic Induction in Amphibians

Using transmission and scanning electron microscopy we were able to show that during primary embryonic induction in amphibians ( Triturus alpestris ) the interspace between the inducing chorda-mesoderm and the reacting ectoderm (presumptive medullary plate) of mid-gastrula stages is traversed by cell projections starting from cells of both tissue layers. In addition intimate membrane contacts between the main bodies of the ectodermal and chorda-mesodermal cells could be observed.
It could be ruled out that cytoplasmic bridges (anastomosis) exist between cells of inducing chorda-mesoderm and reacting ectoderm, which would allow a free transfer of inducing substances without passing through membranes, as Eakin and Lehmann [1] have postulated. The possible role of cell to cell contact for neural induction is emphasized.     

Cell contacts between chorda-mesoderm and the overlaying neuroectoderm (presumptive central nervous system) during the period of primary embryonic induction in amphibians.

Using transmission and scanning electron microscopy we were able to show that during primary embryonic induction in amphibians (Triturus alpestris) the interspace between the inducing chorda-mesoderm and the reacting ectoderm (presumptive medullary plate) of mid-gastrula stages is traversed by cell projections starting from cells of both tissue layers. In addition intimate membrane contacts between the main bodies of the ectodermal and chorda-mesodermal cells could be observed. It could be ruled out that cytoplasmic bridges (anastomosis) exist between cells of inducing chorda-mesoderm and reacting ectoderm, which would allow a free transfer of inducing substances without passing through membranes, as Eakin and Lehmann [1] have postulated. The possible role of cell to cell contact for neural induction is emphasized.     

Neural-inducing activity and glycoprotein synthesis of newly mesodermalized ectoderm in the newtCynops (Amphibia)

Summary An artificially mesodermalized ectoderm (mE) shows the same properties as the organizer: chordamesoderm formation and neural induction. The neural-inducing activity of the mE was inhibited by treatment with protein synthesis inhibitors (cycloheximide and puromycin) and a specific inhibitor of protein glycosylation (tunicamycin). These antibiotics also inhibited chordamesoderm differentiaton, especiallly that of notochord. Newly synthesized proteins of the mE were compared with those of presumptive ectoderm (pE) using two-dimensional PAGE. There were differences in relative amounts of many protein spots. These results suggest that neural-inducing activity is related to glycoproteins synthesized during the early phase of mesodermalization.     

A re-examination of lens induction in chicken embryos: in vitro studies of early tissue interactions

Early studies on lens induction suggested that the optic vesicle, the precursor of the retina, was the primary inducer of the lens; however, more recent experiments with amphibians establish an important role for earlier inductive interactions between anterior neural plate and adjacent presumptive lens ectoderm in lens formation. We report here experiments assessing key inductive interactions in chicken embryos to see if features of amphibian systems are conserved in birds. We first examined the issue of specification of head ectoderm for a lens fate. A large region of head ectoderm, in addition to the presumptive lens ectoderm, is specified for a lens fate before the time of neural tube closure, well before the optic vesicle first contacts the presumptive lens ectoderm. This positive lens response was observed in cultures grown in a wide range of culture media. We also tested whether the optic vesicle can induce lenses in recombinant cultures with ectoderm and find that, at least with the ectodermal tissues we examined, it generally cannot induce a lens response. Finally, we addressed how lens potential is suppressed in non-lens head ectoderm and show an inhibitory role for head mesenchyme. This mesenchyme is infiltrated by neural crest cells in most regions of the head. Taken together, these results suggest that, as in amphibians, the optic vesicle cannot be solely responsible for lens induction in chicken embryos; other tissue interactions must send early signals required for lens specification, while inhibitory interactions from mesenchyme suppress lens-forming ability outside of the lens area.     

Mesodermalizing Factors in Fetal Calf Serum

The inducing activities of fetal calf serum (FCS) and fetal calf serum heated for a short time (HFCS) were tested with early gastrula presumptive ectoderm of the newt, Cynops pyrrhogaster as a reactor. Inducing activity was measured by sitting-drop culture of pieces of ectoderm before and after treatment with Ca, Mg-free solution (CMF) in culture medium contained FCS or HFCS (10–50%) as inductor. Results showed that FCS did not induce mesodermalization of ectoderm, before or after treatment with CMF, and that HFCS induced mesodermalization only of ectoderm treated with CMF. The treated ectoderm cells differentiated into mesoderm cells such as muscle and notochord. The induction increased with increase in the duration of CMF treatment and with the concentration of HFCS in the medium. This indicates that FCS changes into mesodermalizing material when heated for a short time and that mesodermal induction by HFCS depends on some effect of CMF on presumptive ectoderm. Since CMF was found to be a neuralizing factor, activation of presumptive ectoderm with a neuralizing factor is probably a prerequisite for mesodermal induction with HFCS.