Mesoderm and Neural Inductions on Newt Ectoderm by Activin A

Mesoderm-inducing activity of human recombinant activin A was examined on presumptive ectoderm of the Japanese newt, Cynops pyrrhogaster , by using the animal cap assay, Activin A induced neural tissues and mesodermal tissues such as brain, neural tube, notochord, muscle, mesenchyme, coelomic epithelium and blood-like cells after 14 days cultivation. These tissues were induced by activin A at concentrations ranging from 0.5– 100 ng/ml. Dose-dependent inducing activity of activity A on newt ectoderm was slightly different from that on other animals, including Xenopus . Wide range of concentration of activin A (0.5– 100 ng/ml) could induce the neural tube, notochord, mesenchyme and coelomic epithelium on the newt ectoderm. Though the percentage of induced explants (two out of 23 explants, 8.7%) was low, the pulsating heart was induced. This paper showed first that activin could induce the mesodermal and neural tissues in newt presumptive ectoderm. Since activin homologues were present In Xenopus and chick embryos, it is likely that activin may be one of the natural inducers in a wide range of species.     

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.     

Ventral ectoderm of Xenopus forms neural tissue, including hindbrain, in response to activin.

The peptide growth factor Activin A has been shown to induce complete axial structures in explanted blastula animal caps. However, it is not understood how much this response to activin depends upon early signals that prepattern the ectoderm. We have therefore asked what tissues can be induced in blastula animal caps by activin in the absence of early dorsal signals. Using whole-mount in situ hybridization, we compare the expression of three neural markers, N-CAM, En-2 and Krox-20 in activin-treated ectoderm from control and ventralized embryos. In response to activin, both normal and ventralized animal caps frequently form neural tissue (and express N-CAM) and express the hindbrain marker Krox-20. However, the more anterior marker, En-2, is expressed in only a small fraction of normal animal caps and rarely in ventralized animal caps; the frequency of expression does not increase with higher doses of activin. In all cases En-2 and Krox-20 are expressed in coherent patches or stripes in the induced caps. Although mesoderm is induced in both control and ventralized animal caps, notochord is found in response to activin at moderate frequency in control caps, but rarely in ventralized animal caps. These results support the idea that in the absence of other signals, activin treatment elicits hindbrain but not notochord or anterior neural tissue; and thus, the anterior and dorsal extent of tissues formed in response to activin depends on a prior prepatterning or previous inductions.     

Dose and time-dependent mesoderm induction and outgrowth formation by activin A in Xenopus laevis.

We examined the quality of mesoderm induced by the action of activin A on the Xenopus presumptive ectoderm when various concentrations and treatment times were employed. The minimum concentration of activin A to induce mesodermal tissues was inversely proportional to its treatment time. The explants differentiated into different types of mesodermal tissues, from ventral-type to dorsal-type depending on the concentration of activin A and its treatment time. To confirm whether activin A has a role in establishing axial organization, activin A was injected into the blastocoel of late blastulae. About 70% of the injected embryos formed secondary tail-shaped outgrowths in which muscle and neural tube differentiated. The amount of activin A to form secondary outgrowths was 0.5-2.5 pg, roughly consistent with the amount estimated from in vitro experiments. As we have detected almost the same amount of activin homologue in the early embryos (Asashima et al., 1991a), we speculate that activin A may be the natural mesodermal inducer, and that it is responsible for establishing axial organization in the Xenopus embryo.     

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.     

Induction of cells expressing vascular endothelium markers from undifferentiated Xenopus presumptive ectoderm by co-treatment with activin and angiopoietin-2

Activin is a potent inducer of mesoderm in amphibian embryos. We previously reported that low concentrations of activin could induce the formation of blood cells from Xenopus explants (animal caps). Both hematopoietic and vascular endothelial cell lineages are believed to share a common precursor, termed hemangioblasts. In this study, we tried to induce differentiation of vascular endothelial cells in aggregates derived from Xenopus animal caps. Aggregates formed from cells that were co-treated with activin and angiopoietin-2 expressed the vascular endothelial markers, X-msr, Xtie2 and Xegfl7. However, none of these aggregates expressed the hematopoietic marker genes, globin alpha T3, alpha T5, alpha A or GATA-1. We used microarray analysis to compare the gene expression profiles of aggregates treated with activin alone or with activin and angiopoietin. The combination, but not activin alone, induced expression of vascular-related genes such as Xl-fli and VEGF. These results demonstrate that treatment of dissociated animal cap cells with activin and angiopoietin-2 can induce differentiation of endothelial cells, and provides a promising model system for the in vitro study of blood vessel induction in vertebrates.     

Expression of activins and TGF beta 1 and beta 2 RNAs in early postimplantation mouse embryos and uterine decidua.

The expression of the mesoderm inducing factors, activins and TGF beta s, was characterized in 5 1/2-9 1/2 day mouse embryos and implantation sites by in situ hybridization. Activin beta A RNA was not detected within the embryo, but is expressed in nearby decidual cells from 5 to 7 days. Thus activin A could play a role within the embyro during gastrulation. Activin beta A is also expressed in more mesometrially located decidual cells from 6 to 9 1/2 days. Activin beta B and inhibin alpha RNAs were not detected, while a control tissue was highly positive. TGF beta 1 is expressed in the secondary decidual zone and in developing endothelial cells in the decidua and embryo. TGF beta 2 is expressed in the mesometrial decidua at 6 1/2 days and in the midline of the cranial neural plate.     

Concentration-dependent inducing activity of activin A

Summary Human recombinant activin A, which is identical with erythroid differentiation factor (EDF), was tested for its mesoderm-inducing activity in concentrations from 0.3–50 ng/ml, using ectoderm of Xenopus late blastula (Stage 9) as the responding tissue. At a low concentration of activin A, blood-like cells, mesenchyme, and coelomic epithelium were induced; at a moderate concentration muscle and neural tissue, and at a high concentration notochord. Activin A thus induced all mesodermal tissues in a dose-dependent manner, such that a low dose induced ventral structures and a high dose induced dorsal structures. Activin may act as an intrinsic inducing molecule responsible for establishing the dorso-ventral axis in early Xenopus development. Offprint requests to: M. Asashima     

Should activin betaC be more than a fading snapshot in the activin/TGFbeta family album?

The activin growth factors consist of dimeric proteins made up of activin beta subunits and have been shown to be essential regulators of diverse systems in physiology. Four subunits are known to be expressed in mammalian cells: betaA, betaB, betaC, and betaE. Surprisingly, deletion of activin betaC and betaE subunits in vivo does not affect embryonic development or adult physiology which has led to the activin betaC and betaE subunits being regarded as non-essential and unimportant. The steady accumulation of circumstantial evidence to the contrary has led this lab to reassess the role of the activin betaC subunit. Activin betaC protein is expressed more widely than indicated by mRNA localisation. Experiments overexpressing activin betaC subunit or adding exogenous Activin C in vitro are contradictory but suggest roles for activin betaC in regulating Activin A action in apoptosis and homeostasis. Sequestration of betaA subunits by dimerisation with betaC subunits to form Activin AC represents an intracellular regulator of Activin A bioactivity. Activins play a pivotal role in normal physiology and carcinogenesis, so any molecule, such as the activin betaC subunit, that can affect activin action is potentially significant. Advancing our understanding of the physiological role of the activin betaC subunit requires new tools and reagents. Direct detection of the Activin AC dimer will be essential and will necessitate the purification of heteromeric Activin AC protein. In addition, there is a need for the development of an in vivo model of activin betaC subunit overexpression. With development of these tools, research into activin action in development and physiology can expand to include the less well understood members of the activin family such as activin betaC.     

In Vitro Control of the Embryonic Form of Xenopus laevis by Activin A: Time and Dose-Dependent Inducing Properties of Activin-Treated Ectoderm

The inducing properties of activin-treated ectoderm of Xenopus laevis were examined by the preculture and sandwich culture methods. Presumptive ectodermal sheets of the late blastula were treated with 10–100 ng/ml of activin A and precultured for 0–7 hr in Steinberg's solution. They were then sandwiched between two sheets of ectoderm from other late blastulae. Ectoderm precultured for a short term induced trunk-tail structures, whereas that precultured for a long term induced head structures in addition to trunk-tail structures. These time-dependent changes in inducing properties occurred more rapidly when the concentration of activin A was higher. These results suggest that the activin-treated ectoderm functioned as a "head organizer" or "trunk-tail organizer" depending upon the concentration of activin A and the duration of preculture.
To trace the cell lineage of the sandwich explants, activin-treated ectoderm labeled with fluorescein-dextran-amine (FDA) was used in this study. The explants sandwiching the long term-precultured ectoderm formed head structures equipped with non-labeled neural tissues (brain and eye) as well as FDA-labeled mesodermal tissues. These results suggest that the activin-treated ectoderm mainly differentiates into mesodermal tissues and induces neural tissues as the organizer does in normal development.     

Endodermal Nodal-related signals and mesoderm induction in Xenopus

In Xenopus, mesoderm induction by endoderm at the blastula stage is well documented, but the molecular nature of the endogenous inductive signals remains unknown. The carboxy-terminal fragment of Cerberus, designated Cer-S, provides a specific secreted antagonist of mesoderm-inducing Xenopus Nodal-Related (Xnr) factors. Cer-S does not inhibit signalling by other mesoderm inducers such as Activin, Derrière, Vg1 and BMP4, nor by the neural inducer Xnr3. In the present study we show that Cer-S blocks the induction of both dorsal and ventral mesoderm in animal-vegetal Nieuwkoop-type recombinants. During blastula stages Xnr1, Xnr2 and Xnr4 are expressed in a dorsal to ventral gradient in endodermal cells. Dose-response experiments using cer-S mRNA injections support the existence of an endogenous activity gradient of Xnrs. Xnr expression at blastula can be activated by the vegetal determinants VegT and Vg1 acting in synergy with dorsal (beta)-catenin. The data support a modified model for mesoderm induction in Xenopus, in which mesoderm induction is mediated by a gradient of multiple Nodal-related signals released by endoderm at the blastula stage.     

Translational control of activin in Xenopus laevis embryos

Activin is a potent mesoderm inducing factor present in embryos of Xenopus laevis. Recent evidence has implicated activin in the inhibition of neural development in addition to the well-established induction of mesoderm in ectodermal explants. These diverse effects are critically dependent on the concentration of activin yet little is known about the mechanisms regulating the level of activin in the embryo. We report that the 3′ untranslated region (3′ UTR) of activin βB mRNA inhibits the translation of activin in embryos. Microinjection of activin mRNA from which the 3′ UTR has been deleted is 8–10-fold more potent in inducing mesoderm than mRNA containing the 3′ UTR. Truncation of the 3′ UTR also leads to a marked enhancement of activin protein levels in embryos but has no effect when the truncated mRNA is translated in vitro. The 3′ UTR also confers translational inhibition on a heterologous mRNA. These data show that a maternal factor(s) present in X. laevis regulates the translation of injected activin βB mRNA. This factor(s) could be responsible for regulating the levels of endogenous activin βB protein during mesoderm induction and the specification of ectodermal derivatives such as neural and epidermal tissues. © 1995 Wiley-Liss, Inc.     

Regulated expression of the retinoblastoma gene product by fibroblast growth factor but not by activin during mesoderm induction in Xenopus

 The retinoblastoma (RB) gene is a tumor suppressor gene that plays an important role in cell cycle arrest and in the terminal differentiation of skeletal myoblasts. Differentiation into muscle occurs in Xenopus embryo explants during mesoderm induction by fibroblast growth factor (FGF) or activin A. We examined expression of the RB gene product (pRB) during mesoderm induction in vivo and in vitro. We show that hypo- and hyper-phosphorylated forms of pRB are present during early development and that expression of both forms increases significantly during the blastula stage, concomitant with mesoderm induction. Further investigation revealed that pRB is enriched in the presumptive mesoderm of the blastula stage embryo. In animal cap explants induced by Xenopus bFGF (XbFGF), pRB expression levels increased approximately tenfold while no increase was observed in explants induced by activin. However, when explants were induced by XbFGF in the presence of sodium orthovanadate, a compound previously shown to synergize with FGF to produce more dorsal ”activin-like” inductions than FGF alone, only a slight increase in pRB expression was observed. Furthermore, upregulation of pRB during mesoderm induction in vitro displayed an inverse correlation with expression of XFKH1, a marker for notochord. These results suggest that pRB may be important for patterning along the dorsoventral axis. Received: 22 February 1996 / Accepted: 20 September 1996     

Interaction of Wnt and activin in dorsal mesoderm induction in Xenopus.

Both the activin and Wnt families of peptide growth factors are capable of inducing dorsal mesoderm in Xenopus embryos. Presumptive ventral ectoderm cells isolated from embryos injected with Xwnt8 mRNA were cultured in the presence of activin A to study the possible interactions between these two classes of signaling proteins. We find that overexpression of Xwnt8 RNA alters the response of ventral ectoderm to activin such that ventral explants differentiate dorsoanterior structures including notochord and eyes. This response is similar to the response of dorsal ectoderm to activin alone. When embryos are irradiated with uv light to inhibit dorsal axis formation, ectodermal explants differentiate notochord when they are induced by a combination of both signaling factors, but not when cells receive only one inducing signal (activin or Xwnt8). This result is further supported by the observation that goosecoid (gsc) mRNA, an early marker for dorsal mesoderm, is expressed in these explants only when they are injected with Xwnt8 mRNA followed by exposure to activin. Early morphogenetic movements of the induced cells and activation of muscle-specific actin and Brachyury (Xbra) genes also reveal a cooperation of activin A and Xwnt8 in mesoderm induction.     

Regulation of prostate branching morphogenesis by activin A and follistatin

Ventral prostate development occurs by branching morphogenesis and is an androgen-dependent process modulated by growth factors. Many growth factors have been implicated in branching morphogenesis including activins (dimers of beta(A) and beta(B) subunits); activin A inhibited branching of lung and kidney in vitro. Our aim was to examine the role of activins on prostatic development in vitro and their localization in vivo. Organ culture of day 0 rat ventral prostates for 6 days with activin A (+/- testosterone) inhibited prostatic branching and growth without increasing apoptosis. The activin-binding protein follistatin increased branching in vitro in the absence (but not presence) of testosterone, suggesting endogenous activins may reduce prostatic branching morphogenesis. In vivo, inhibin alpha subunit was not expressed until puberty, therefore inhibins (dimers of alpha and beta subunits) are not involved in prostatic development. Activin beta(A) was immunolocalized to developing prostatic epithelium and mesenchymal aggregates at ductal tips. Activin beta(B) immunoreactivity was weak during development, but was upregulated in prostatic epithelium during puberty. Activin receptors were expressed throughout the prostatic epithelium. Follistatin mRNA and protein were expressed throughout the prostatic epithelium. The in vitro evidence that activin and follistatin have opposing effects on ductal branching suggests a role for activin as a negative regulator of prostatic ductal branching morphogenesis.     

Activin/EDF as an inhibitor of neural differentiation

Activin/EDG, a stimulator of the secretion of follicle stimulating hormone (FSH) from pituitary gland and an inducer of erythroid differentiation for Friend leukemia cells, has since been implicated in a variety of biological roles. Here, we show some novel effects of activin on murine embryonal carcinoma cells (EC cells). First, activin acts as a growth factor on undifferentiated P19 cells, a well characterized EC cell line for the study of mammalian development. Second, activin inhibits the retinoic acid (RA) induced differentiation of P19 cells to neurons and glial cells. The inhibitory effect of activin on neural differentiation, which has yet to be proved in other physiological peptides, is confirmed also on the differentiation of various neuroblastoma cell lines. Our results suggest a possible role of activin as a negative regulator of neural differentiation in mammalian development.