Biological activity of vegetalizing and neuralizing inducing factors after binding to BAC-cellulose and CNBr-sepharose

Summary Covalent binding to bromoacetyl-cellulose inactivates the vegetalizing factor. The bound factor is however still able to form a complex with an inhibitor for the factor. Covalent binding to CNBr-Sepharose likewise inactivates the vegetalizing factor. The neuralizing factor on the other hand is not inactivated when covalently bound to CNBr-Sepharose. When a crude fraction which contains the neuralizng factor as well as the vegetalizing factor is bound to CNBr-Sepharose the vegetalizing activity is greatly decreased whereas the neuralizing activity is not reduced. This suggests that the mechanisms of action of the two factors are quite different. Whereas the vegetalizing factor must be incorporated into the cells, the neuralizing factor interacts with the plasma membrane of competent ectoderm cells.     

Embryonic induction and cation concentrations in amphibian embryos

Explanted ectoderm from early gastrulae of Triturus alpestris was treated with the Na-K ionophore gramicidin (10(-9) to 10(-5) M) and the Ca-ionophore A 23187 (10(-7) to 10(-5) M). The ectoderm developed almost exclusively to atypical epidermis as in the control explants. When the ectoderm was treated with ouabain (10(-4) M), intracellular Na+ increased about 4.4-fold and K+ was reduced by half. Mesenchyme cells in small number differentiated in about 40% of the ouabain-treated explants. The time course of total Na+ and K+ ion concentrations was measured over a period of 72 h in ectoderm of T. alpestris after induction with vegetalizing factor and in control explants. In the first 15 h after explantation, no significant differences between control and induced explants were found. Thereafter, the steady state concentration of K+ decreased in the induced explants, whereas the steady-state concentration of Na+ slightly increased. The membrane resting potential recorded intracellularly of ectoderm sandwiches from early gastrula stages was found to be -41.3 mV in control and -59.3 mV in induced explants. From the specific conductances and permeabilities of non-induced and induced cells it is concluded that the induction process leads to a differentiation of the cell membrane, which acquires the characteristics of ionic selectivity. Ectoderm from Ambystoma mexicanum forms neural or neuroid tissue, mesenchyme and melanophores after explantation in salt solution in up to 50% of the explants without any additions. Isolated Ambystoma ectoderm is therefore not suitable for test experiments.     

Formation of mesodermal pattern by secondary inducing interactions

Summary A highly purified vegetalizing factor induces endoderm preferentially in amphibian gastrula ectoderm. After combination of this factor with less pure fractions, a high percentage of trunks and tails with notochord and somites are induced. The induction of these mesodermal tissues depends on secondary factors which may act on plasma membrane receptors of the target cells. The secondary factors are probably proteins as they are inactivated by trypsin or cellulose-bound proteinase K. They are not inactivated by thioglycolic acid.The implication of these findings for tissue determination and differentiation in normal development in relation to the anlageplan for endoderm and mesodermal tissues is discussed.     

Change of the differentiation pattern of amphibian ectoderm after the increase of the initial cell mass

Summary Early amphibian gastrula ectoderm (Triturus alpestris) has been treated with vegetalizing factor. While normal sandwiches (animal caps of two eggs) differentiated mainly into endoderm derived tissues, giant-sandwiches (a combination of 8 animal caps) formed mesodermal and neural tissues in addition. The results support the interpretation that ectoderm will differentiate into endoderm derived tissues when all or nearly all cells are induced (presumably depending on certain threshold concentrations of the inducer). This is the case in the normal sandwich after treatment with high concentrations of vegetalizing factor for 24 h. However, in a giantsandwich it must be assumed that only the cells in the vicinity of the inducer will be triggered to differentiate into endoderm derived tissues. Mesodermal structures will be formed by secondary interactions between the induced ectoderm (endoderm) and non induced ectodermal cells. The induction of neural structures could be explained as a further interaction between mesodermalized and non induced ectodermal cells. This chain of events is compared with the steps of determination in normogenesis.     

A mesoderm-inducing factor from a Xenopus laevis cell line

Summary We have compared the chemical properties and biological activities of the mesoderm-inducing factor that is secreted by the Xenopus XTC cell line with the vegetalizing factor from chicken embryos. The inducing activity of the factors was tested in different concentrations on totipotent ectoderm either by implantation into early gastrulae of Triturm alpestris or by application of solutions to isolated ectoderm of early gastrulae of Xenopus laevis. Both factors have similar properties. They are not irreversibly inactivated after treatment with 6 M urea or with phenol at 60° C. Reduction with thioglycolic acid inactivates the factors completely. The inducing activity of XTC-conditioned medium decreases only slightly after treatment with 50% formic acid. The apparent molecular mass and the isoelectric point of the factors are similar. The XTC factor was partially purified by size-exclusion and reversed-phase high-pressure liquid chromatography and by isoelectric focusing. The possible relationship of these factors to transforming growth factor is discussed.Dedicated to Prof. Dr. Sulo Toivonen on the occasion of his 80th birthday     

The inducing capacity of the presumptive endoderm of Xenopus laevis studied by transfilter experiments

Summary The inducing capacity of the vegetal hemisphere of early amphibian blastulae was studied by placing a Nucleopore filter (pore size 0.4 m) between isolated presumptive endoderm and animal (ectodermal) caps. The inducing effect was shown to traverse the Nucleopore membrane. The reacting ectoderm differentiated into mainly ventral mesodermal derivatives. Expiants consisting of five animal caps also formed dorsal mesodermal and neural structures. Those results together with data published elsewhere suggest that, in addition to a vegetalizing factor, different mesodermal factors must be taken into consideration for the induction of either the ventral or the dorsal mesodermal derivatives. The neural structures are thought to be induced by the primarily induced dorsal mesodermal tissue. Electron microscopic (TEM) examination did not reveal any cell processes in the pores of the filter. The results indicate that transmissible factors rather than signals via cytoplasmic contacts or gap junctions are responsible for the mesodermal induction of ectodermal cells. The data support the view that in normogenesis the mesoderm is determined by the transfer of inducing factors from vegetal blastomeres to cells of the marginal zone (presumptive mesodermal cells).     

Effect of concanavalin A and vegetalizing factor on the outer and inner ectoderm layers of early gastrulae of Xenopus laevis after treatment with cytochalasin B

Neural (archencephalic) structures have been evoked in the competent ectoderm (consisting of both ectodermal layers) of Xenopus laevis by treatment with Concanavalin A (Con A), which probably acts on the plasma membrane. The size of the neural structures is increased when the ectoderm is incubated in Cytochalasin B prior to the Con A treatment. The results indicate that Cytochalasin B could have an influence on the binding of Con A to receptors on the plasma membrane. On the other hand, Cytochalasin B seems to have an inhibitory effect on the action of the vegetalizing factor, which could be correlated with the decline of endocytotic processes and internalization. In further series, it could be shown that the isolated superficial ectoderm, in contrast to the inner ectoderm layer, does not react to Con A treatment with the differentiation of neural structures. Studies with FITC-Con A indicate that the marker binds less to the outer ectoderm than to the inner ectoderm layer. However, by xenoplastic combinations of the outer ectoderm layer of X. laevis as reacting tissue and chordamesoderm of Triturus vulgaris as inducer, it could be demonstrated that the superficial layer, which is normogenesis does not come into contact with the inducing chordamesoderm but forms the ependymal part of the brain only, is also able to form archencephalic brain structures under in vitro conditions.     

Inducing activity of subcellular fractions from amphibian embryos

Summary The homogenate from unfertilized eggs, gastrulae, neurulae and hatched embryos ofXenopus laevis was fractionated by differential centrifugation and subsequent repeated centrifugation on discontinuous sucrose gradients. A high archencephalic-neural inducing activity was found in RNP particles, which were released from the high-speed (microsomal) sediment by treatment with EDTA, and in a fraction of heterogeneous small vesicles. The highest archencephalic inducing activity was observed in RNP particles from unfertilized eggs and from gastrulae. RNP particles isolated from hatched embryos had a lower inducing activity. The neuralizing factor can be extracted from the small vesicles with pyrophosphate buffer at pH 8.6, but it is not solubilized with a non-ionic detergent (Triton X 100). The high-speed supernatant from the gastrula homogenate contains soluble neuralizing factor, whereas the supernatant from egg homogenate has a low inducing activity. The plasma membrane fraction (isolated from gastrulae) also has only a low inducing activity. The possible significance of the subcellular distribution of neuralizing factors for the transmission of neuralizing inducer from the mesoderm to competent gastrula ectoderm and the processing of signals which are generated on the plasma membrane of induced cells is discussed.     

The ultrastructure of amphibian ectoderm treated with an inductor or actinomycin D

Summary Amphibian (Triturus alpestris) ectoderm was isolated and after 2–16 days in culture examined by electron microscopy. It has been shown that the ectoderm, formerly called undifferentiated ectoderm, forms in part ciliated epithelial cells, which cannot be distiguished from the cells of the epidermis, which has developed in situ (except for the alignment of the cells which depends on the mesenchyme underlying the epidermis). The ultrastructure of the cilia is similar to that of cilia of protozoa or sperms of insects or vertebrates. A zone at the periphery of the epidermal cells, free of yolk platelets, mitochondria and pigment granules (embryonic pigment) is observed after 4 days. This area is rich in vacuolous structures and basal bodies of the cilia.Ectoderm, which was treated with the vegetalizing factor differentiates into mesodermal and endodermal tissues. Cilia, as well as the characteristic peripheral zone, are not formed in the induced ectoderm.In ectoderm treated with actinomycin D (1 g/ml for 6 h) the differentiation of the peripheral zone and the cilia is delayed.

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Zusammenfassung Amphibien-(Triturus alpestris)-Ektoderm wurde isoliert und nach 2–16 Tagen elektronenmikroskopisch untersucht. Es konnte gezeigt werden, daß sich Ektoderm, früher oft als undifferenziertes Ektoderm bezeichnet, zu Epithelzellen differenziert, die zum Teil Cilien tragen. Diese Epithelzellen unterscheiden sich in ihrer Ultrastruktur nicht von Epidermiszellen, die sich in situ (also im Ganzkeim) entwickelt haben, lassen jedoch die typische flächige Anordnung der Epidermis vermissen. Die Cilien besitzen die gleiche Feinstruktur, wie sie bei Cilien der Protozoa oder Spermien von Insekten oder Wirbeltieren zu finden sind. Nach 4 Tagen Aufzucht bildet sich im Bereich der Peripherie der Epidermiszellen eine Zone aus, die frei ist von Dotterschollen, Mitochondrien und Embryonalpigment. Diese Zone ist reich an vacuolenähnlichen Strukturen und Basalkörpern der Cilien.Ektoderm, das mit vegetalisierendem (mesodermal/entodermal) induzierendem Faktor behandelt wurde, differenziert sich zu mesodermalen und entodermalen Geweben. Sowohl Cilien als auch die charakteristische periphere Zone werden in induziertem Gewebe nicht gebildet.In Ektoderm, das über 6 Std mit Aktinomycin D (1 g/ml) behandelt wurde, ist die Bildung der peripheren Zone und der Cilien verzögert.

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This investigation was supported by the Deutsche Forschungsgemeinschaft (Sonderforschungsbereich Embryonale Entwicklung und Differenzierung).

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I am very grateful to Prof. Dr. Dr. H. Tiedemann for stimulating discussions. Cordial thanks are due to Dr. Don Hendrick for correcting the English text.     

Alteration of cell adhesion system in amphibian ectoderm cells during primary embryonic induction: changes in reaggregation pattern of induced neurectoderm cells and ultrastructural features of the reaggregate

Summary Cell adhesion was studied during primary embryonic induction. The disaggregation rate and reaggregation patterns were analysed in the ectoderm cells of various developing Cynopus gastrulae and neurulae. The neurectoderm cells disaggregated more slowly with gastrulation, and the neural plate cells of early neurula showed a lesser capacity for disaggregation. Although no differences in reaggregation were found between dorsal and ventral ectoderm at the early gastrula stage, there were significant differences between the induced neurectoderm and the non-induced ventral epidermal cells at the late gastrula stage. Neural plate cells of the early neurula stage were seen to form a chain-like reaggregate, but the ventral epidermal cells of the same embryo formed a cluster-like spherical reaggregate. Scanning electron microscope observations of reaggregates also showed significant differences in adhesive properties between induced neurectoderm and non-induced epidermal cells. The adhesion field of the induced neurectoderm cells was smooth, differing from the distinct ridges of the non-induced epidermal cells. These results suggest that changes in the cell adhesion system, resulting in the formation of a columnar cell shape, may occur immediately after a neural-inducing action.     

Amino acid transport and protein synthesis in induced ectoderm of amphibian embryos

Summary Isolated gastrula ectoderm ofTriturus alpestris orAmbystoma mexicanum was induced by the vegetalizing factor. Protein synthesis in the induced and uninduced control explants was measured by double labelling with³H-and¹⁴C-amino acids after different periods of cultivation. Slight differences were observed in the pattern of nuclear proteins after 12 h of cultivation and in the pattern of cytoplasmic proteins after 48 h of cultivation.The uptake of leucine started to increase in induced explants after 48 h of cultivation and after 96 h was about 50 times greater than in uninduced control explants. The uptake is reduced under partially anaerobic conditions. Ouabain inhibits the uptake by about 50%.     

Effects of Inducers on Inner and Outer Gastrula Ectoderm Layers of Xenopus laevis

Abstract. Gastrula ectoderm, isolated from Xenopus laevis , was cultured in Holtfreter solution or modified Leibovitz medium (L-15) by the sandwich-method with or without inducer. The ectoderm (SD cell layers) consists of two cell sheets, representing a superficial (S) and a deep (D) layer. In the L-15 medium rather than in Holtfreter solution, the two cell layers separate out into distinct cell masses. This difference in cell affinity under certain experimental conditions could indicate that the deep layer contains endodermal cells. However, an endodermal character of the deep layer can be ruled out by induction experiments with vegetalizing factor or dorsal blastopore lip as inducers. Under the influence of vegetalizing factor the outer as well as the inner ectoderm layer differentiated into mesodermal derivatives such as notochord and somites. The results of the experiments with dorsal blastopore lip as inducer indicate that both inner and outer ectoderm layers are responsive to the neural stimulus. The lower neural competence of the outer ectoderm layer observed by several authors in normogenesis is discussed with regard to the hypothesis about short distance diffusion of the neuralizing factor and/or close cell-to-cell contact between inducing tissue and ectodermal target cells.     

Biological activity of the vegetalizing factor: Decrease after coupling to polysaccharide matrix and enzymatic recovery of active factor

Summary The inducing activity of the vegetalizing factor decreases after covalent coupling to CNBr-Sepharose with reduced binding capacity. The residual inducing activity is probably due to the release of a small amount of the factor from Sepharose beads. Covalent coupling to activated CH-Sepharose completely inactivated the vegetalizing factor, whereas the neuralizing factor retained its full activity. The biological activity was also very much reduced when the vegetalizing factor was bound to Sephadex beads, a derivative of dextran. Fully active factor was recovered after enzymatic degradation of the dextran matrix with dextranase. The experiments suggest that the neuralizing factor acts on the cell surface of ectoderm cells, whereas the vegetalizing factor must probably be internalized to become biologically active.     

Influence of cyclic nucleotides on amphibian ectoderm

Summary Isolated amphibian (Triturus alpestris) gastrula ectoderm was treated with cyclic nucleotides for 24 h and cultured up to 12 days. Explants treated with$cyclic N⁶-Monobutyryl-adenosine-35-monophosphate, cyclic Dibutyryladenosine-35-monophosphate and cyclic Dibutyrylguanosine-35-monophosphate in a concentration of 10^–3 and 10^–5 M did not differentiate into mesoderm- or endoderm-derived tissues. The number of explants with small neural and neuroid structures did not exceed the percentage found in the control series. Inductions could also not be obtained when ectoderm was dissociated prior to the treatment with cyclic nucleotides, or when theophylline (which inhibits phosphodiesterase) was added to the culture medium. The results are discussed with regard to the possible mode of action of the vegetalizing factor.     

Induction of mesodermal tissues by acidic and basic heparin binding growth factors

The inducing activity of two heparin binding growth factors HBGF-1 (prostate epithelial cell growth factor; acidic pI) and HBGF-2 (fibroblast growth factor; basic pI) from bovine brain has been tested on totipotent ectoderm from early amphibian (Xenopus laevis, Ambystoma mexicanum) embryos. Both factors induced, at high concentrations, mostly compact spheres surrounded by a non-epidermal epithelium. When the concentration or time of incubation was reduced, large muscle inductions frequently organized as somites were formed besides endothelial vesicles, mesenchyme and smaller areas of intestine-like epithelium. Further reduction of the concentrations or the time of incubation led to an increase in size and number of endothelium-lined vesicles and of mesenchyme, whereas the induction of muscle decreased. At still lower concentrations the overall rate of inductions decreased. The relationship of the growth factors to the vegetalizing factor from chicken embryos, dilution of which shows a similar shift in induced organs, is discussed. The present and previous experiments suggest that different mesodermal and endodermal tissues are induced by secondary interactions in which additional factors are involved. The induced organs derive from dorsal as well as from ventral mesoderm.     

The membranes of slowly drought-stressed wheat seedlings: a freeze-fracture study

Seedlings of Triticum aestivum L. cv. Neepawa were slowly drought-stressed by witholding water after sowing in pots. Leaf extension stopped during development of the third leaf. Damage was assessed by rewatering the pots and measuring regrowth; 1–5 d after growth stopped, rewatering induced significant regrowth within several hours; 6–13 d after growth stopped, regrowth was delayed; from 14 d after growth stopped, no regrowth occurred after rewatering. Leaf bases were excised from the drought-stressed seedlings during this period of increasing damage, and were freeze-etched.Intramembranous particles (IMP) were evenly scattered in the plasma membrane in those plants which regrew immediately after rewatering. In the plants which regrew after a delay or which did not regrow on rewatering, there were patches without IMP in plasma membrane, nuclear envelope, and other membranes. Plasma membrane, nuclear envelope and possibly other membranes were sometimes partly replaced by vesicles, possibly formed from the original membrane. Such vesiculation occurred in a few cells in plants which survived the stress with a delayed regrowth, and was commoner in the plants which did not recover. The results support the idea that slow drought induces IMP-free patches in membranes including the plasma membrane, this induces membrane reorganisation including vesiculation of membranes and coagulation of protoplasm, and that these are expressed as delayed or failed regrowth. Some IMP-free patches in the plasma membrane had a faint ordered sub-structure, possibly a hexagonal lipid phase. Such patches were infrequent and IMP sometimes occurred in areas of plasma membrane having an apparently similar sub-structure. Thus the IMP-free patches could not be explained by a lamellar-hexagonal phase transition. As the stress became damaging, vesicles and endoplasmic reticulum accumulated immediately next to the plasma membrane. Mainly during the early period of damaging stress (6–10 d after growth stopped), depressions, invaginations, and rarer lesions occurred in the plasma membrane, sometimes associated with some of the IMP-free patches. In the same period, many nuclear envelopes had exceptionally large nuclear pores.Abbreviations E exoplasmic - IMP intramembranous particles - P protoplasmic     

Head and trunk-tail organizing effects of the gastrula ectoderm of Cynops pyrrhogaster after treatment with activin A

Differentiation tendency and the inducing ability of the presumptive ectoderm of newt early gastrulae were examined after treatment with activin A at a high concentration (100 ng/ml). The activin-treated ectoderm differentiated preferentially into yolk-rich endodermal cells. Combination explants consisting of three pieces of activin-treated ectoderm formed neural tissues and axial mesoderm along with endodermal cells. However, the neural tissue was poorly organized and never showed any central nervous system characteristics. When the activin-treated ectoderm was sandwiched between two sheets of untreated ectoderm, the sandwich explants differentiated into trunk-tail or head structures depending on the duration of preculture of activin-treated ectoderm in Holtfreter's solution. Short-term (0–5 h) precultured ectoderm induced trunk-tail structures accompanied by axial organs, alimentary canal and beating heart. The arrangement of the explant tissues and organs was similar to that of normal embryos. However, archencephalic structures, such as forebrain and eye, were lacking or deficient. On the other hand, long-term (10–25 h) precultured ectoderm induced archencephalic structures in addition to axial organs. Lineage analysis of the sandwich explants using fluorescent dyes revealed that the activin-treated ectoderm mainly differentiated into endodermal cells and induced axial mesoderm and central nervous system in the untreated ectoderm. These results suggest that activin A is one of the substances involved in triggering endodermal differentiation and that the presumptive ectoderm induced to form endoderm displays trunk-tail organizer or head organizer effects, depending on the duration of preculture.     

The vegetalizing factor from chicken embryos: its EDF (activin A)-like activity

The erythroid differentiation capacity of the HPLC-purified mesoderm- and endoderm-inducing vegetalizing factor from chicken embryos and of recombinant erythroid differentiation factor (EDF = activin A), an evolutionary highly conserved member of the TGF-beta protein superfamily have been compared. Both factors stimulate the synthesis of hemoglobin in erythroleukemia cells in the same concentration range. The EDF-activity of the mesoderm-inducing HPLC-fractions is inhibited by follistatin, an EDF-binding protein. The factor induces in ectoderm of Triturus taeniatus all kinds of mesodermal organs. The wide spectrum of organs is very likely to be induced by secondary interactions. At higher concentration (15 ng/ml), notochord- and endoderm-like tissues are induced in a high percentage.     

Lectin binding by microvillous membranes and coated-pit regions of human syncytial trophoblast

Summary The distribution of saccharides on the microvillous membrane of the human syncytial trophoblast was investigated using ferritin conjugates of four lectins: concanavalin A (specific for -d-manno- and -d-glucopyranosyl residues), wheatgerm agglutinin (specific forN-acetylglucosamine),Limulus polyphemus lectin (specific forN-acetylneuraminic acid), andLotus tetragonolobus lectin (specific for -l-fucose). Concanavalin A and wheatgerm agglutinin (WGA) reacted strongly with the surface membrane and ferritin deposits were also observed in coated pit regions of the membrane. Lectins fromL. polyphemus andL. tetragonolobus, however, reacted only weakly with the microvillous border and neither reacted with coated pits.Enhanced agglutinability of trophoblast cells in comparison with other foetal cells from the same conceptus was seen with WGA. This agglutination was inhibited by addition of acetylglucosamine or by a solubilized membrane fraction which was bound by a column of WGA-Sepharose. The membrane fraction which did not bind to the column did not inhibit agglutination. Electrophoresis of the WGA-bound membrane proteins revealed six subunits, the major band having an apparent mol. wt. of 55 000. A protein of this mol. wt was also seen in coated vesicles isolated from equivalent human placentae.     

The presence of heat-labile factors interfering with binding analysis of fibrinogen with ferritin in horse plasma

Background

Horse fibrinogen has been identified as a plasma specific ferritin-binding protein. There are two ways in the binding of ferritin-binding protein with ferritin: one is direct binding and the other is indirect binding which is heme-mediated. The aim of this study was to analyze the binding between horse fibrinogen and ferritin.

Findings

Although fibrinogen in horse plasma did not show the binding to ferritin coated on the plate wells, after following heat-treatment (60°C, 30 min) of horse plasma, plasma fibrinogen as well as purified horse fibrinogen bound to plates coated with horse spleen ferritin, but not with its apoferritin which lost heme as well as iron after the treatment of reducing reagent. Binding of purified or plasma fibrinogen to ferritin was inhibited by hemin and Sn-protoporphyrin IX (Sn-PPIX), but not by PPIX or Zn-PPIX.

Conclusions

Heat-treatment of horse plasma enabled plasma fibrinogen to bind to plate well coated with holo-ferritin. From the binding analysis of fibrinogen and ferritin, it is suggested that horse fibrinogen recognized iron or tin in complexed with the heme- or the hemin-ring, and also suggest that some fibrinogens circulate in the form of a complex with ferritin and/or heat-labile factors which inhibit the binding of fibrinogen with ferritin.