Compatibility of chick embryo eye anlagen with the ectoderm of the early amphibian gastrula in vitro

Eye vesicles were isolated from the early chick embryos (stage 9+ after Hamburger and Hamilton, 1951) and combined with the Rana temporaria early gastrula ectoderm (EGE) in vitro. The tissues were jointly incubated in medium 199 diluted twice with deionized water at 22 +/- 1 degree for 7-8 days or the eye vesicles were removed from the EGE ectoderm within 16-18 h. At the joint long-term incubation of these tissues, a toxic effect of the chick embryonic tissues on the EGE cells was noted. In none of the experiments, the inducing effect of the eye vesicle on the EGE was found. Similar data were obtained when the EGE was jointly cultivated with the brain (stage 9-10) and retina (stage 15) of chick embryos. The brain of the chick embryos at stage 15 exerted a weak neuralizing effect on the EGE. In the control experiments, the eye vesicles explanted with the chick embryonic ectoderm remained viable till the end of cultivation but no lentoids formed in the ectoderm. The absence of lens-inducing effect at the joint cultivation of the chick embryonic eye vesicles with the EGE is considered as a result of disturbance of the synthesis or secretion of the corresponding agents rather than a sequence of the species "incompatibility" of the inductor and reacting tissue. Hence, the use of "xenogenic" tissue recombinants is not justified when analyzing the lens-inducing activity of the eye vesicles.     

Concentration dependence of inductive activity in the mixture of lens epithelium proteins

As shown elsewhere, the mixture of proteins secreted by lens epithelium cells in the process of microcultivation can selectively induce eye and forebrain tissues in the early gastrula ectoderm (Zemchikhina et al., 2000, 2003). In the present work, the dependence of inductive activity of this protein mixture on its concentration in culture solution has been studied. The test-system was the early gastrula ectoderm of Xenopus laevis frogs. The results of the experiments revealed no direct dependence of the spectrum of induced tissues on the concentration of the protein mixture. At a concentration of 0.5 mg/ml, brain appeared being accompanied by retina, pigmented epithelium, and lentoids, while at 0.031 mg/ml a perfect lens developed along with brain, retina and pigmented epithelium. At 0.125 mg/ml not only brain with accompanying structures but also muscle fibers were equally differentiated. These data suggest a new approach to the problem of dependence of the character of induction on the concentration of inducing factors, and they enable us to suppose that this dependence is not realized as a simple concentration dependence but may de determined by some adaptive, yet not elucidation processes.     

Distribution of differentiation potentials and the conditions for their realization in the amphibian neuroectoderm

The X. laevis neuroectoderm (NE) at the mid and late gastrula stages is capable to form mesoderm in vitro after its separation from mesoderm. This capacity is inherent in posterior 2/3 of NE underlied by axial mesoderm in the embryo and forming deuterencephalic and trunk regions of the brain in the normal development. The archencephalic 1/3 of NE of the late gastrula, underlied in the embryo by prechordal plate, is capable of differentiation into archencephalic regions of the brain, rather than into mesoderm. For the typical differentiation of archencephalic NE to be realized, it should be surrounded by the outer ectoderm layer. In the absence of the latter, the whole explant develops into retina and brain only. Inside the closed explants, ectomesenchyme and melanophores arise and the eye material is subdivided into retina and pigmented epithelium. The archencephalic NE, dissociated to individual cells and wrapped into epidermis, forms much more ectomesenchyme and melanophores than the usual NE explants.     

Inductive effect of the eye tissues of adult clawed toads on the gastrula ectoderm

The inducing influence of adult eye tissues on the early gastrula ectoderm was studied in vitro. Both retina and pigment epithelium induced in the early gastrula ectoderm similar spectra of cell types, including nervous tissue, retina, pigment epithelium, lentoids, ectomesenchyme, and melanophores. It is suggested that the correspondence of these cell types with those arising at a spontaneous transdifferentiation of the isolated retina and pigment epithelium cells in vitro or at the induction of the early gastrula ectoderma by archencephalic endomesoderm during the normal development can be accounted for by that in these eye cells molecular determinants appeared as a result of induction and maintaina the stability of their differentiation and their potencies to transdifferentiation in vitro being reproduced during the lifetime of these cells.     

Inductive characteristics of proteins secreted by retinal cells

The studies of the development of eye rudiments and formation of adult eye tissues have always been among priorities in developmental biology and then in developmental genetics, which is associated with the peculiarities of the development and structure of the eye. In the late 80s, it was established by the group of developmental factors of the Institute of Gene Biology of RAS that many differentiated tissues are able to produce proteins causing homologous differentiations in polypotent cells of early gastrula ectoderm. The aim of our present study was isolation of proteins secreted by mammalian and fish retinal cells and determination of their inductive properties in early gastrula ectoderm of Xenopus laevis. The sets of proteins secreted by retina induce tissues homologous to the inducer, that is, neural tissue, brain, retina, pigmented epithelium, and also lenses and ear vesicles. The retinal inductive proteins retain their homologous inductive capacity after lyophilization. Biological testing shows that a total mixture of proteins secreted by retinal cells induces in polypotent gastrula ectoderm of X. laevis a narrower spectrum of tissues than the fractions obtained from this mixture. The above-outlined results obtained in thecourse of investigations of inductive peculiarities of retina and its fractions help in the elucidation of questions concerning embryonic induction and factors determining it, as well as questions concerning the maintenance of tissue specifity and regenerative capacity of the tissue studied.     

Water-soluble proteins in early amphibian embryos. III. Immunoelectrophoretic analysis of the antigenic changes in the ectoderm of the early gastrula and neural plate during development

20 water-soluble antigen have been identified with the help of rabbit antisera to extracts of the early gastrula ectoderm and neural plate in Rana temporaria. All of them were also found in the early blastula embryos and unfertilized eggs. The identified antigens are characterized by a definite embryospecificity. As the development proceeds, the concentration of these antigens in the embryonic tissues decreases until the complete disappearance of corresponding immunoelectrophoretic reactions. By this characteristic all antigens under study are subdivided into four groups: I--five antigens identified at the early developmental stages only (until hatching, stage 29); II--nine antigens present up to stages 33--35; III--three antigens followed up to stages 39--40 (well formed tadpole); IV--three antigens were found at all developmental stages under study up to stages 45--47. 11 out of 20 identified antigens have antigenic similarity with the proteins of blood serum of adult amphibians. Besides, the early gastrula ectoderm contains antigens similar with those of the brain of adult amphibians.     

Glycerol Phosphate Dehydrogenase in Developing Chick Retina and Brain

Abstract: The development of cytoplasmic glycerol phosphate dehydrogenase (GPDH) activity in chick neural retina is compared with that in brain. GPDH converts dihydroxyacetone phosphate to glycerol 3-phosphate, an intermediate in phospholipid synthesis. The enzyme is known to be under corticosteroid control in rat brain and spinal cord (but not muscle or liver) and in primary oligodendrocyte cultures. It has not been previously studied in the eye. In chick brain the GDPH specific activity rises fivefold from the early embryo to the adult, with nearly all the increase occurring between embryonic day 14 and hatching. This time course correlates well with the known maturation of chick adrenal cortex (which produces corticosteroids). On the other hand, in chick retina the GPDH specific activity remains at a low basal level throughout development. Furthermore, adult rat and beef retinas show much lower enzyme activity than do the corresponding brain tissues. GPDH can be induced precociously by hydrocortisone in embryonic chick brain from days 12 through 16, both in the intact embryo and in tissue culture; however, GPDH is not at all inducible in chick retina. The developmental increase in chick brain GPDH can be correlated qualitatively with myelin formation, as shown by luxol fast blue staining, whereas no myelin is seen in retina at any age. Our results are consistent with recent immunocytochemical studies demonstrating that GPDH in rat brain is associated with myelin-producing oligodendroglial cells, absent in retina. In comparison, another glial enzyme, glutamine synthetase (GS), known to be inducible in both chick brain and retina, is localized in brain astrocytes and retinal Müller cells.     

Concanavalin-binding proteins and cytokeratins in different tissues of the early amphibian gastrula (Rana temporaria, Xenopus laevis)]

Concanavalin A (con A), a lectin which specifically interacts with aD-mannose and aD-glucose, has a neutralizing effect on the explants of the early gastrula ectoderm of several amphibian species. Consequently, it was interesting to study con A-binding protein spectrum of the ectoderm and compare it to those of other early gastrula tissues. Animal pole ectoderm (APE), dorsal blastopore lip (DBL) and vegetal pole endoderm (VPE) were dissected from early gastrulae of Rana temporaria and Xenopus laevis. The extracts were subjected to SDS-PAGE with subsequent immunoelectroblotting on nitrocellulose membranes. The blots were sequentially treated with con A solution, horseradish peroxidase and diaminobenzidine. Spectra of the con A-binding glycoproteins were similar in APE, DBL and VPE of R. temporaria. Ten-twelve fractions with the molecular weight in the range from 30 to 150 kDa were stained in each blot. Fractions with the molecular weight of 150, 125, 104, 94 and 42 kDa showed more prominent lectin binding. Con A-binding protein spectra remained unchanged after freezing-thawing of the studied extracts, as well as after blots were treated with neuraminidase or sulphuric acid in order to remove sialic acid residues; the only exception was 42 kDa fraction. At the same time, a-methyl-D-mannoside pyranoside completely blocked con A binding by fractions of the studied extracts. In histological sections of R. temporaria early gastrula, all cells bound FITC-labelled con A. Similar data were obtained with tissues of X. laevis early gastrula. While electrophoretic pattern of X. laevis tissues drastically differed from that of R. temporaria, there were no significant differences between con A-binding protein spectra of X. laevis APE, DBL or VPE. Thus, all studied tissues of the amphibian early gastrula contain similar set of con A-binding proteins; however, only APE is capable of neutralization in response to con A action. These data favor our earlier assumption (see Mikha?lov et al., 1989) that con A reception and transmission of the corresponding signal do not determine the characteristics of the target cells response. APE, DBL and VPE extracts were assayed also for the presence of a protein similar to cytokeratin No. 8 characteristic of simple epithelia of mammals. Experiments were performed using immunoelectroblotting with monoclonal antibodies (mAB) against cytokeratin No. 8 from rat colon (mAB E2 and E7 kindly supplied by Dr. G. A. Bannikov). In R. temporaria embryos, cytokeratin 8 was detected in APE, but not in DBL or VPE. In X. laevis gastrulae all the tissues studied contained this cytokeratin.     

Ectopic induction of dorsal mesoderm by overexpression of Xwnt-8 elevates the neural competence of Xenopus ectoderm.

The ectoderm of early Xenopus gastrula is competent to become induced to neural tissue, but dorsal ectoderm is more neural competent than ventral ectoderm. It is a tenable, but as yet untested possibility that the higher neural competence of dorsal gastrula ectoderm is dependent on the presence of the dorsal mesoderm. To test this hypothesis we overexpressed Xwnt-8 in order to ectopically induce dorsal mesoderm in the ventral side of the embryo. We found that this elevated the level of neural competence of ventral ectoderm to that of dorsal ectoderm. The effect of Xwnt-8 on neural competence of ventral ectoderm was strictly correlated with its ability to enhance the amount of dorsal structures. The data indicate that the presence of dorsal mesoderm is a prerequisite for establishing the differences in neural competence between gastrula dorsal and ventral ectoderm.     

Isolation and effects of inducing factors secreted by the lens epithelium cells

Our previous studies showed that, unlike tissue extracts, the cells of living organs secrete substances capable of inducing the same organ rudiments in the early gastrula ectoderm (EGE). In this work, the molecular nature of these substances was studied. The porcine lens epithelium was chosen for the initial analysis. When cultivated, this epithelium secreted a mixture of proteins, which were separated by gel-filtration. Both the total protein mixture and its individual fractions were tested for their inducing capacity using the early gastrula ectoderm of Rana temporaria. Unexpected results were obtained, which indicated that (a) the mixture of native proteins secreted by lens epithelium has a selective inducing capacity differing from those of individual fractions isolated from this mixture and (b) each fraction has a specific effect, but all of them cause the induction of neural tissue or sensory organs. These results (obtained for the first time) suggest that the inducing capacity of individual protein fractions is wider than that of the total protein mixture secreted by lens epithelium. This fact raises a question concerning the relationships between the mechanisms underlying the corresponding inducing effects.     

The spatio-temporal distribution of single-stranded breaks in nuclear DNA in sections of clawed toad embryos during gastrulation and neurulation

Spatial and temporal pattern and quantities of nicks in nuclear DNA during gastrulation and neurulation was studied using nick-translation in sections of Xenopus laevis embryos. Specific changes in the number of nicks in different mesoderm and ectoderm regions were detected during embryogenesis. Dorso-ventral gradient of nuclear labelling was observed in mesoderm and inner ectoderm layer of early and middle gastrula. The gradient was inverted during transition from gastrula to neurula. At the same time dorso-ventral (in mesoderm) and ventro-dorsal (in outer ectoderm layer) gradients of nuclear labelling were increased. The intensity of nuclear labelling in all parts of embryo as a whole was remarkably higher during neurulation as compared with gastrulation. Dorso-ventral gradient of nuclear labelling was observed in mesoderm and ectoderm during neurulation. A connection between the nicks and differentiation status of the cells during early embryogenesis in amphibians is suggested.     

On the presence of a "particle-bound" neuraminidase in retina: a developmental study.

Neuraminidase activity was detected in chicken retina. A “particle-bound” neuraminidase was demonstrated in retina; however no “soluble” neuraminidase was present. For the endogenous “particle-bound” neuraminidase the pH optimum was 4.0 and the enzyme was stimulated by 0.15 % Triton X-100. Total activity measured in the presence of both endogenous and G_Dla (0.085 mM) substrates, reached a maximum at the same pH (4.0) in the presence of lower amounts of Triton X-100 (0.075–0.1 %). An excess of G_Dla inhibited the activity. Total and endogenous activity profiles of the “particle-bound” neuraminidase behaved similarly during chick retina ontogenesis; the activities were low during the early embryo period, reached maximum levels near hatching and remained stable throughout adulthood. In chicken retina, neuraminidase, which may take part in ganglioside catabolism, reached the maximum of activity when the retina was morphologically mature, while glycosyltransferases, implicated in the first steps of retinal ganglioside synthesis, are known to attain maximum levels of activity at an early stage of brain development.     

Electrophoretic study of water-soluble retinal proteins of chickens at early stages of embryogenesis]

The water-soluble proteins of chick retina were studied during the formation of eye cup and at the early stages of histological differentiation of retina by the micro-method of electrophoresis in 20% polyacrilamide gel. The retina of embryos at the stages under study contains a range of proteins forming over 20 fractions in electrophoresis. The most fractions are formed by the proteins which electrophoretic mobilities exceed that of serum albumin. The early stages of retina development are characterized by the definite changes in its protein composition. These changes manifest themselves in the disappearance of the most anodic fractions beginning from the stage of contact between the optic vesicle and presumptive lens ectoderm. During the subsequent development, these proteins are detected again in the retina, the corresponding anodic fractions being most distinct at the stage of completed eye cup. Their content in the retina decreases repeatedly with the beginning of histogenesis up to their complete disappearance.     

A novel homeobox gene expressed in the anterior neural plate of the Xenopus embryo.

To obtain gene sequences controlling the early steps of amphibian neurogenesis, we have performed differential screening of a subtractive cDNA library prepared by a novel PCR-based method from a single presumptive neural plate of a Xenopus laevis late-gastrula embryo. As a result we have isolated a fragment of a novel homeobox gene (named XANF-1, for Xenopus anterior neural folds). This gene is expressed predominantly in the anterior part of the developing nervous system. Such preferential localization of XANF-1 mRNA is established from its initially homogenous distribution in ectoderm of early gastrula. This change in the expression pattern is conditioned by a differential influence of various mesoderm regions on ectoderm: anterior mesoderm activates XANF-1 expression in the overlying ectoderm, whereas posterior axial and ventral mesoderm areas inhibit it. The data obtained demonstrate for the first time that selection of genes for specific expression in the CNS of the early vertebrate embryo is affected not only by chordamesoderm (a neural inductor) but also by ventral mesoderm.     

Characterization of acidic and basic fibroblast growth factors in brain, retina and vitreous chick embryo

We have purified acidic and basic fibroblast growth factors (c-aFGF, c-bFGF) from 11 day-old chick embryo brain, retina and vitreous by heparin-Sepharose chromatography and reverse phase HPLC. The analysis of their biological activity as well as their molecular weight indicates that they were analogous to basic or acidic human and bovine FGF. The ratio of c-aFGF to c-bFGF activity depended of the tissue. In brain c-aFGF represented 66% of the total mitogenic activity retained on the heparin-sepharose column and c-bFGF 34% while retina contained 16% of c-aFGF and 84% of c-bFGF; vitreous 78% of c-aFGF and 22% of c-bFGF. Like human aFGF, Heparin stimulated purified c-aFGF mitogenic activity in the absence of serum but inhibited the activity of the retina acid soluble extract, in the presence of foetal calf serum (FCS). Thus, chick embryo and adult human acidic and basic FGF respectively share the same biochemical properties. Since there are no blood vessels in chick retina or vitreous, their presence in these tissues suggests that angiogenesis is not the only role of these growth factors.     

The ability of the epithelium of diencephalic origin to differentiate into cells of the ocular lens.

After the discovery that in adult salamanders following lentectomy a new, functional lens develops by transdifferentiation (cell-type conversion) of previously depigmented epithelial cells of the iris (Wolffian lens regeneration), this phenomenon has been intensively studied by various experimental approaches. During the last two decades it was shown that pleiomorphic aggregates of atypical lens cells (lentoids) differentiated in reaggregates of dissociated cells of the chick neural retina and in spread cell cultures of the pigmented epithelium of the iris and retina, of the neural retina and the pineal gland of the chick embryo. The neural retina of human fetuses and adults also displayed this capacity. We showed that lentoids developed at a low incidence in renal isografts of rat embryonic shields or isolated embryonic ectoderm and of lentectomized eyes of rat fetuses, as well as in organ cultures of rat embryonic shields in chemically defined media. The addition of transferrin significantly increased the incidence of differentiation of lentoids in explants. In both renal isografts and explants in vitro a continuous transformation of retinal epithelial cells into atypical lens cells was observed. In renal isografts lentoids were also observed to originate from the ependyma of the brain ventricle. All tissues having the capacity to convert into lens cells belong to the diencephalon in a broad sense. Evolutionary aspects of this feature are discussed.     

Refinement of gene expression patterns in the early Xenopus embryo

During blastula and gastrula stages of Xenopus development, cells become progressively and asynchronously committed to a particular germ layer. We have analysed the expression of genes normally expressed in ectoderm, mesoderm or endoderm in individual cells from early and late gastrula embryos, by both in situ hybridization and single-cell RT-PCR. We show that at early gastrula stages, individual cells in the same region may express markers of two or more germ layers, and 'rogue' cells that express a marker outside its canonical domain are also observed at these stages. However, by the late gastrula stage, individual cells express markers that are more characteristic of their position in the embryo, and 'rogue' cells are seen less frequently. These observations exemplify at the gene expression level the observation that cells of the early gastrula are less committed to one germ layer than are cells of the late gastrula embryo. Ectodermal cells induced to form mesendoderm by the addition of Activin respond by activating expression of different mesodermal and endodermal markers in the same cell, recapitulating the response of marginal zone cells in the embryo.     

Inhibition of chick embryo hepatic uroporphyrinogen decarboxylase by components of xenobiotic-treated chick embryo hepatocytes in culture. II.

A variety of xenobiotics, viz., 3,3',4,4'-tetrachlorobiphenyl (TCBP), sodium phenobarbital (PB), 3,5-diethoxycarbonyl-2, 4,6-trimethylpyridine (OX-DDC), and nifedipine, cause a decrease in uroporphyrinogen decarboxylase (UROG-D) activity, accompanied by uroporphyrin accumulation, in chick embryo hepatocytes in culture. In this study the activity of 17-day-old chick embryo hepatic UROG-D was determined by measuring the conversion of pentacarboxylporphyrinogen I to coproporphyrinogen I, and it was shown that a UROG-D inhibitor, previously reported to accumulate in TCBP-treated and PB-treated chick embryo hepatocytes in culture, also accumulates in OX-DDC-treated and nifedipine-treated chick embryo hepatocytes in culture. It was concluded that the accumulation of a UROG-D inhibitor provides an explanation for the UROG-D inhibition observed in this culture system with xenobiotics that cause uroporphyrin accumulation. Studies of the UROG-D inhibitory fraction isolated from the 10,000 x g, 40,000 x g, and 100,000 x g supernatant fractions of cultured chick embryo hepatocyte homogenate led to the conclusion that the UROG-D inhibitor is derived from a soluble component of the homogenate.     

Brain-derived proteins that rescue spinal motoneurons from cell death in the chick embryo: Comparisons with target-derived and recombinant factors

Spinal motoneurons that normally die during early development can be rescued by a variety of purified growth or neurotrophic factors and target tissue extracts. There is also indirect evidence that brain or supraspinal afferent input may influence lumbar motoneuron survival during development and that this effect may be mediated by central nervous system–derived trophic agents. This report examines the biological and biochemical properties of motoneuron survival activity obtained from extracts of the embryonic chick brain. Treatment with an ammonium sulfate (25% to 75%) fraction of embryonic day 16 (E16) or E10 brain extracts rescued many spinal motoneurons that otherwise die during the normal period of cell death in vivo (E6 to E10). The same fractions also enhanced lumbar motoneuron survival following deafferentation. There were both similarities and differences between the active fractions derived from brain extracts (BEX) when compared with extracts derived from target muscles (MEX) or with purified neurotrophic factors. Survival activity from E10 BEX was as effective in promoting motoneuron survival as E10 MEX and more effective than astrocyte-conditioned media. Unlike MEX, the active fractions from BEX also rescued placode-derived nodose ganglion cells. In addition, unlike nerve growth factor and brain-derived neurotrophic factor, active BEX fractions did not rescue neural crest-derived dorsal root ganglion cells or sympathetic ganglion neurons. Interestingly, among many cranial motor and other brainstem nuclei examined, only the survival of motoneurons from the abducens nucleus was enhanced by BEX. Active proteins obtained from BEX were further separated by gel filtration chromatography and by preparative isolelectric focusing techniques. Activity was recovered in a basic (pI8) and an acidic (pI5) small molecular weight protein fraction (20 kD or less). The specific activity of the basic fraction was increased ×66 when compared with the specific activity of crude BEX, and the basic fraction had a slightly higher specific activity than the acidic fraction. The biological and biochemical properties of these fractions are discussed in the context of known neurotrophic factors and their effects on normal and lesion-induced motoneuron death during development. © 1995 John Wiley & Sons, Inc.     

The development of nervous tissue to experimental manipulation in vitro (author's transl)

Explants of nervous tissue (CNS: hippocampus from fetal rats, telencephalon and PNS: ganglion trigeminale from chick embryos) were cultivated in maximow chambers. Biological extracts (brain and embryo extract) or chemical agents (aminoacid mixtures and peptides with known sequence of amino acids) were tested. Biological extracts and aminoacid mixtures stimulated the differentiation in PNS and CNS cultures. A stimulating effect of peptides seems to exist only on PNS explants. The fundamental importance of suitable reference systems, parameters, optimal concentrations and periods of application of effective substances for the evaluation of the results is discussed.