Vegetalising factor extracted from the fish swimbladder and tested on presumptive ectoderm ofTriturus embryos

Summary Vegetalising factor was isolated from swimbladder of crusian carp (Carassius auratus) by solubilishing with 8 M urea the precipitate obtained after digesting the swimbladder with collagenase. The urea-soluble fraction vegetalised isolated presumptive ectoderm ofTriturus gastrula and produced both undifferentiated mesodermal and endodermal cells. Brief heating of the fraction changed its capacity to produce organised mesodermal tissues, such as notochord and somite, and the frequency of induction of undifferentiated cells was reduced. By inserting the urea-soluble fraction into the blastocoel of an early gastrula, embryos without epidermis were obtained. Some of the embryos consisted of undifferentiated mesodermal and endodermal cells, but in the remaining ones small fragments of notochord, small numbers of somites and pronephros developed, enclosed by endodermal cells.     

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.     

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.     

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.     

Endoderm differentiation and inductive effect of activin-treated ectoderm in Xenopus

When presumptive ectoderm is treated with high concentrations of activin A, it mainly differentiates into axial mesoderm (notochord, muscle) in Xenopus and into yolk-rich endodermal cells in newt (Cynops pyrrhogaster). Xenopus ectoderm consists of multiple layers, different from the single layer of Cynops ectoderm. This multilayer structure of Xenopus ectoderm may prevent complete treatment of activin A and subsequent whole differentiation into endoderm. In the present study, therefore, Xenopus ectoderm was separated into an outer layer and an inner layer, which were individually treated with a high concentration of activin A (100 ng/mL). Then the differentiation and inductive activity of these ectodermal cells were examined in explantation and transplantation experiments. In isolation culture, ectoderm treated with activin A formed endoderm. Ectodermal and mesodermal tissues were seldom found in these explants. The activin-treated ectoderm induced axial mesoderm and neural tissues, and differentiated into endoderm when it was sandwiched between two sheets of ectoderm or was transplanted into the ventral marginal zone of other blastulae. These findings suggest that Xenopus ectoderm treated with a high concentration of activin A forms endoderm and mimics the properties of the organizer as in Cynops.     

Mesoderm induction in Xenopus laevis: responding cells must be in contact for mesoderm formation but suppression of epidermal differentiation can occur in single cells

When Xenopus embryos are cultured in calcium- and magnesium-free medium (CMFM), the blastomeres lose adhesion but continue dividing to form a loose heap of cells. If divalent cations are restored at the early gastrula stage the cells re-adhere and eventually form muscle (a mesodermal cell type) as well as epidermis. If, however, the cells are dispersed during culture in CMFM, muscle does not form following reaggregation although epidermis does. This suggests that culturing blastomeres in a heap allows the transmission of mesoderm-induction signals from cell to cell while dispersion effectively dilutes the signal. In this paper, we have attempted to substitute for cell proximity by culturing dispersed blastomeres in XTC mesoderm-inducing factor (MIF). We find that dispersed cells do not respond to XTC-MIF by forming mesodermal cell types after reaggregation, but the factor does inhibit epidermal differentiation. One interpretation of this observation is that an early stage in mesoderm induction is the suppression of epidermal differentiation and that formation of mesoderm may require contact-mediated signals that are produced in response to XTC-MIF. We have gone on to study the suppression of epidermal differentiation in more detail. We find that this is a dose-dependent phenomenon that can occur in single cells in the absence of cell division. Animal pole blastomeres become more difficult to divert from epidermal differentiation at later stages of development and by stage 12 they are 'determined' to this fate. Fibroblast growth factor (FGF) also suppresses epidermal differentiation in isolated animal pole blastomeres and transforming growth factor-beta 1 acts synergistically with FGF in doing so.     

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.     

Transmission Problem in Primary Induction

It has been suggested that during the neuralization step of primary induction in the amphibian embryo the inductive signals are mediated from mesodermal cells to the responding competent neuroepithelium by means other than cell contacts. This idea corroborated by experiments in which the interacting tissues were separated by a Nuclepore filter with pores of 0.05 μm (series 1) or by a dialyzing membrane with pores of only 12,000 daltons (series 2). After 18–22 h exposure to mesoderm followed by 8–10 days' culture in isolation the ectodermal explants were neuralized in both series with about 80% differentiating into archencephalic structures. These results exclude the possibility of cell contact as a mediating mechanism in this step.
In a third series similar experiments were made using a special Nuclepore filter with dense pores of 0.6 μm and the exposure time was prolonged to 24 h. During subsequent culture in isolation the ectoderm was neuralized in every case, except forebrain, the ectoderm also differentiated in 25% to hindbrain and less frequently to spinal cord, myotomes, and in some cases even to notochord. The result is interpreted to mean that during the prolonged exposure the tissues have had time to age to an early neurula stage, and the ectodermal cells, after being neuralized, have had time to form cell contacts by cytoplasmic bridges through the pores resulting in the segregation of the preneuralized ectoderm into more caudal structures than the forebrain.     

In vitro pancreas formation from Xenopus ectoderm treated with activin and retinoic acid

In the present study, isolated presumptive ectoderm from Xenopus blastula was treated with activin and retinoic acid to induce differentiation into pancreas. The presumptive ectoderm region of the blastula consists of undifferentiated cells and is fated to become epidermis and neural tissue in normal development. When the region is isolated and cultured in vitro, it develops into atypical epidermis. Isolated presumptive ectoderm was treated with activin and retinoic acid. The ectoderm frequently differentiated into pancreas-like structures accompanied by an intestinal epithelium-like structure. Sections of the explants viewed using light and electron microscopy showed some cells clustered and forming an acinus-like structure, including secretory granules. The pancreas-specific molecular markers insulin and XIHbox8 were also expressed in the treated explants. The pancreatic hormones, insulin and glucagon, were detected in the explants using immunohistochemistry. Therefore, sequential treatment with activin and retinoic acid can induce presumptive ectoderm to differentiate into a morphological and functional pancreas in vitro. When ectoderm was immediately treated with retinoic acid after treatment with activin, well-differentiated pronephric tubules were seen in a few of the differentiated pancreases. Treatment with retinoic acid 3-5 h after activin treatment induced frequent pancreatic differentiation. When the time lag was longer than 15h, the explants developed into axial mesoderm and pharynx. The present study provides an effective system for analyzing pancreas differentiation in vertebrate development.     

Cell sorting during the regeneration of Hydra from reaggregated cells.

The role of cell sorting in the reorganization of Hydra cell reaggregates was studied. We quantitatively labeled ectodermal and endodermal cells by incubating whole animals in fluorescent beads or by injecting the beads into the gastric cavity. Beads were stably incorporated into the cells by phagocytosis. Our data show that dramatic cell sorting processes drive the formation of ectoderm and endoderm within the first 12 hr of reaggregation. After the ectoderm is established, no further rearrangement could be observed. We also tested the ability of cells to sort out with respect to their original position in Hydra by dissociating labeled apical and basal pieces of Hydra and measuring the clumping of labeled cells during reorganization. There was no increase in the clumping of cells during reorganization indicating that cell sorting is not involved in the formation of early activation centers. There was also no preferential incorporation of apically derived (presumptive head) tissue into tentacles that subsequently formed, indicating that after dissociation into single cells there is no predisposition of erstwhile presumptive head tissue to form heads.     

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).     

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.     

Bidirectional induction toward paraxial mesodermal derivatives from mouse ES cells in chemically defined medium

Embryonic stem cells (ESCs) are a renewable cell source of tissue for regenerative therapies. The addition of bone morphogenetic protein 4 (BMP4) to serum-free ESC cultures can induce primitive streak-like mesodermal cells. In differentiated mouse ESCs, platelet-derived growth factor receptor-α (PDGFR-α) and E-cadherin (ECD) are useful markers to distinguish between paraxial mesodermal progenitor cells and undifferentiated and endodermal cells, respectively. Here, we demonstrate methods for BMP4-mediated induction of paraxial mesodermal progenitors using PDGFR-α and ECD as markers for purification and characterization. Serum-free monolayers of ESCs cultured with BMP4 could efficiently promote paraxial mesodermal differentiation akin to embryonic mesodermal development. BMP4 treatment alone induced paraxial mesodermal progenitors that could differentiate into osteochondrogenic cells in vitro and in vivo. Furthermore, early removal of BMP4 followed by lithium chloride (LiCl) promoted the differentiation to myogenic progenitor cells. These myogenic progenitors were able to differentiate further in vitro into mature skeletal muscle cells. Thus, we successfully induced the efficient bidirectional differentiation of mouse ESCs toward osteochondrogenic and myogenic cell types using chemically defined conditions.     

Interaction of induced and uninduced cells during primary induction

Summary UsingTriturus pyrrhogaster embryos, the effects of uninduced cells on the differentiation of induced cells were investigated. The inducing stimulus was given to the presumptive ectoderm of early gastrulae by treatment with protein sooution from guinea pig bone-marrow. Mesodermal induction was evoked in the ectodermal explants. After the treatment, some of the ectodermal explants were cut into pieces 1/8 of their original size and combined with untreated presumptive ectoderm. Mesodermal tissues were differentiated in the combined explants too, but the mesodermal tissues evoked in these combined ectodermal explants were different in their regional characters from these in uncombined explants; dorsal structures, such as notochrod and muscle, were observed predominatly in the latter, whereas the dominant structures observed in the former were ventral ones, such as mesothelium and mesenchyme. The shifting of the regional characters in the combined explants was regarded as the result of an unknown effect from the uninduced cells.     

Excitability changes of presumptive ectoderm following mesodermal induction

Dissociated ectodermal cells of the early newt gastrula which have been treated with CMF (Ca-Mg-free saline) for 5 hr differentiate into muscle cells when cultured in HFCS (heated fetal calf serum) for up to 9-12 days. Similarly dissociated cells placed into FCS (fetal calf serum) culture differentiate into epidermis. Differences in cell-cluster formation have been found between HFCS and FCS in early cell cultures (6 hr), and membrane excitability phenomena associated with the differentiation of these clusters into the muscle cells or epidermal cells have been investigated, respectively. The HFCS cultures consist of cell clusters which have few of microvilli at their surfaces and which form loose contacts by means of lamellipodia. FCS cultures consist of cell clusters which have numerous microvilli at their surfaces and which make tight contacts between cells by means of ridge-structure precursors. The different reaggregation pattern of dissociated ectoderm cells in HFCS reflects changes in the cell membrane surface induced by HFCS. The sequential genesis of action potentials in cells destined to form muscle cells in HFCS is very similar to those produced by somitic muscle cells in vivo and their ionic dependence for generating action potentials is related to epidermal action potentials in vitro (FCS).     

Effects of puromycin and cycloheximide on properties of cells from Xenopus laevis early embryos

The effects have been studied of puromycin and cycloheximide on the reaggregation of ectoderm cells dissociated from Xenopus laevis blastulae. Puromycin or cycloheximide can inhibit reaggregation, suggesting that cell reassociation is dependent upon protein synthesis. If the cells are allowed a 3 h 'recovery' period in culture medium following dissociation, before being exposed to either puromycin or cycloheximide, higher concentrations of the inhibitors are required to prevent cell aggregation, suggesting that significant synthesis of the proteins required for reaggregation occurs in the 3 h immediately following dissociation. Lower concentrations of puromycin permit cell reaggregation but reduce the normal formation of cilia. The effects have also been observed of puromycin on the scanning electron microscopical appearance of Xenopus blastula ectoderm cells cultured singly in vitro. Puromycin reduces the normal formation of pseudopodia, suggesting that puromycin might inhibit reaggregation partly by inhibiting cell movement. Puromycin also produces some elongated cells, possibly by inhibition of cytokinesis.     

Induction of proopiomelanocortin mRNA expression in animal caps of Xenopus laevis embryos

To convert animal pole cells of a frog embryo from an ectodermal fate into a neural one, inductive signals are necessary. The alkalizing agent NH4Cl induces the expression of several anterior brain markers and the early pituitary marker XANF-2 in Xenopus animal caps. Here it is demonstrated that NH4Cl also induced proopiomelanocortin (POMC)-expressing cells (the first fully differentiated pituitary cell type) in stage 9 and 10 Xenopus animal caps, and that all-trans retinoic acid, a posteriorizing agent, was able to block this induction when it was administered within 2 h after the start of NH4Cl incubation. Thus, after 2 h, the fate of Xenopus animal cap cells was determined. Microinjection of ribonucleic acid (RNA) encoding noggin, an endogenous neural inducer, led to the induction of POMC gene expression in animal caps of stage 10 embryos, suggesting that noggin represents a candidate mesodermal signal leading to the POMC messenger (m) RNA producing cell type in uncommitted ectoderm. Hence, an alkalizing agent and a neural inducer can generate a fully differentiated POMC cell lineage from Xenopus animal caps.     

The epithelium of the dorsal marginal zone of Xenopus has organizer properties.

We have investigated the properties of the epithelial layer of the dorsal marginal zone (DMZ) of the Xenopus laevis early gastrula and found that it has inductive properties similar to those of the entire Spemann organizer. When grafts of the epithelial layer of the DMZ of early gastrulae labelled with fluorescein dextran were transplanted to the ventral sides of unlabelled host embryos, they induced secondary axes composed of notochord, somites and posterior neural tube. The organizer epithelium rescued embryos ventralized by UV irradiation, inducing notochord, somites and posterior neural tube in these embryos, while over 90% of ventralized controls showed no such structures. Combinations of organizer epithelium and ventral marginal zone (VMZ) in explants of the early gastrula resulted in convergence, extension and differentiation of dorsal mesodermal tissues, whereas similar recombinants of nonorganizer epithelium and the VMZ did none of these things. In all cases, the axial structures forming in response to epithelial grafts were composed of labelled graft and unlabelled host cells, indicating an induction by the organizer epithelium of dorsal, axial morphogenesis and tissue differentiation among mesodermal cells that otherwise showed non-axial development. Serial sectioning and scanning electron microscopy of control grafts shows that the epithelial organizer effect occurs in the absence of contaminating deep cells adhering to the epithelial grafts. However, labelled organizer epithelium grafted to the superficial cell layer contributed cells to deep mesodermal tissues, and organizer epithelium developed into mesodermal tissues when deliberately grafted into the deep region. This shows that these prospective endodermal epithelial cells are able to contribute to mesodermal, mesenchymal tissues when they move or are moved into the deep environment. These results suggest that in normal development, the endodermal epithelium may influence some aspects of the cell motility underlying the mediolateral intercalation (see Shih, J. and Keller, R. (1992) Development 116, 901-914), as well as the tissue differentiation of mesodermal cells. These results have implications for the analysis of mesoderm induction and for analysis of variations in the differentiation and morphogenetic function of the marginal zone in different species of amphibians.     

Hematopoietic progenitors express embryonic stem cell and germ layer genes

Cell therapy for tissue regeneration requires cells with high self-renewal potential and with the capacity to differentiate into multiple differentiated cell lineages, like embryonic stem cells (ESCs) and adult somatic cells induced to pluripotency (iPSCs) by genetic manipulation. Here we report that normal adult mammalian bone marrow contains cells, with the cell surface antigen CD34, that naturally express genes characteristic of ESCs and required to generate iPSCs. In addition, these CD34+ cells spontaneously express, without genetic manipulation, genes characteristic of the three embryonic germ layers: ectoderm, mesoderm and endoderm. In addition to the neural lineage genes we previously reported in these CD34+ cells, we found that they express genes of the mesodermal cardiac muscle lineage and of the endodermal pancreatic lineage as well as intestinal lineage genes. Thus, these normal cells in the adult spontaneously exhibit characteristics of embryonic-like stem cells.     

An SEM study of cellular morphology,contact, and arrangement,as related to gastrulation inXenopus laevis

Summary Cellular morphology, contact, and arrangement in the late blastula and in various stages of gastrulation ofXenopus were examined by SEM of specimens dissected after fixation or fractured in amyl acetate. The prospective ectoderm of the blastocoel roof consists of several layers of interdigitating cells connected by numerous small protrusions which may function in the decrease in number of cell layers observed during ectodermal epiboly. During gastrulation, prospective mesoderm is regionally differentiated by cellular morphology and arrangement into preinvolution mesoderm, the mesodermal involution zone, and involuted mesoderm. The involuted anterodorsal (head), lateral, and ventral mesoderm consists of a stream of loosely-packed, irregularly shaped cells having large extensions of the cell body attached locally to other cells by small protrusions. Involuted posterodorsal mesoderm (chordamesoderm) consists of elongated cells arranged in palisade fashion and connected by similar protrusions. Involuted mesodermal cells in all regions are attached to the overlying prospective ectodermal cells by numerous small protrusions along the entire interface between the two cell layers. Suprablastoporal endodermal cells involute as an epithelial sheet, changing in shape in the process, to form the roof of the archenteron. Bottle cell morphology, arrangement, and position with respect to the mesodermal cell stream is described. Evidence presented here and elsewhere suggests that involution of mesoderm and of the archenteron roof inXenopus is dependent primarily upon the relative movement of the mesodermal cell stream and of the overlying ectoderm.