Free radical processes in the embryogenesis of Anura]

The localization of free radical processes and changes in their level during the common frog development have been studied by means of grafted copolymerisation and autoradiography. The maps of distribution of relative concentrations of free radicals were obtained for the beginning of cleavage, blastula, gastrula and neurula. The distinct regionalization was found in the beginning of cleavage: the concentration of the free radicals in the cortical layer and dorsal half of embryo is lower than in the central area and ventral half, resp. At the early blastula stage this regionalization is preserved in its general features. The region of embryo characterized by active free radical processes corresponds to the presumptive endo- and mesoderm in the period of inductive interaction. The possible participation of regional changes in oxidative metabolism in the fertilized egg in the determination of cytoplasmic localization of morphogenetic potencies is discussed. At the later stages there were variations observed in free radicals concentration, which are discussed as being related to the determination and morphogenesis of some rudiments of embryo. A local rise of free radicals concentration was also found out in the eye rudiment just before the onset of its components differentiation.     

Multiple extracellular activities in Drosophila egg perivitelline fluid are required for establishment of embryonic dorsal-ventral polarity.

Twelve maternal effect genes (the dorsal group and cactus) are required for the establishment of the embryonic dorsal-ventral axis in the Drosophila embryo. Embryonic dorsal-ventral polarity is defined within the perivitelline compartment surrounding the embryo by the ventral formation of a ligand for the Toll receptor. Here, by transplantation of perivitelline fluid we demonstrate the presence of three separate activities present in the perivitelline fluid that can restore dorsal-ventral polarity to mutant easter, snake, and sp?tzle embryos, respectively. These activities are not capable of defining the polarity of the dorsal-ventral axis; instead they restore structures according to the intrinsic dorsal-ventral polarity of the mutant embryos. They appear to be involved in the ventral formation of a ligand for the Toll protein. This process requires serine proteolytic activity; the injection of serine protease inhibitors into the perivitelline space of wild-type embryos results in the formation of dorsalized embryos.     

Induction of dorsal and ventral mesoderm by ectopically expressed Xenopus basic fibroblast growth factor.

Peptide growth factors from the fibroblast growth factor (FGF) and transforming growth factor-beta families are likely regulators of mesoderm formation in the early Xenopus embryo. Although basic FGF is found in the Xenopus embryo at the correct time and at sufficient concentrations to suggest that it is the FGF-type inducer, the lack of a secretory signal sequence in the basic FGF peptide has raised questions as to its role in the inductive process. We show here that Xenopus basic FGF can ectopically induce mesoderm when translated from injected synthetic RNA within the cells of a Xenopus embryo. Basic FGF produced in this manner is able to induce the formation of both dorsal and ventral mesoderm with the type of mesoderm formed dependent on the inherent dorsal-ventral polarity of the animal hemisphere. Surprisingly, although Xenopus basic FGF produced from the injected mRNA has a potent mesodermalizing effect on animal hemisphere cells, virtually no phenotypic effect is observed with intact embryos. These results suggest that the role of Xenopus basic FGF is to specify the size of the marginal zone, and synergistically with a dorsally localized prepatterning signal, to initially establish the dorsal-ventral axis of the mesoderm.     

The Maternal Maverick/GDF15-like TGF-β Ligand Panda Directs Dorsal-Ventral Axis Formation by Restricting Nodal Expression in the Sea Urchin Embryo

Specification of the dorsal-ventral axis in the highly regulative sea urchin embryo critically relies on the zygotic expression of nodal, but whether maternal factors provide the initial spatial cue to orient this axis is not known. Although redox gradients have been proposed to entrain the dorsal-ventral axis by acting upstream of nodal, manipulating the activity of redox gradients only has modest consequences, suggesting that other factors are responsible for orienting nodal expression and defining the dorsal-ventral axis. Here we uncover the function of Panda, a maternally provided transforming growth factor beta (TGF-β) ligand that requires the activin receptor-like kinases (Alk) Alk3/6 and Alk1/2 receptors to break the radial symmetry of the embryo and orient the dorsal-ventral axis by restricting nodal expression. We found that the double inhibition of the bone morphogenetic protein (BMP) type I receptors Alk3/6 and Alk1/2 causes a phenotype dramatically more severe than the BMP2/4 loss-of-function phenotype, leading to extreme ventralization of the embryo through massive ectopic expression of nodal, suggesting that an unidentified signal acting through BMP type I receptors cooperates with BMP2/4 to restrict nodal expression. We identified this ligand as the product of maternal Panda mRNA. Double inactivation of panda and bmp2/4 led to extreme ventralization, mimicking the phenotype caused by inactivation of the two BMP receptors. Inhibition of maternal panda mRNA translation disrupted the early spatial restriction of nodal, leading to persistent massive ectopic expression of nodal on the dorsal side despite the presence of Lefty. Phylogenetic analysis indicates that Panda is not a prototypical BMP ligand but a member of a subfamily of TGF-β distantly related to Inhibins, Lefty, and TGF-β that includes Maverick from Drosophila and GDF15 from vertebrates. Indeed, overexpression of Panda does not appear to directly or strongly activate phosphoSmad1/5/8 signaling, suggesting that although this TGF-β may require Alk1/2 and/or Alk3/6 to antagonize nodal expression, it may do so by sequestering a factor essential for Nodal signaling, by activating a non-Smad pathway downstream of the type I receptors, or by activating extremely low levels of pSmad1/5/8. We provide evidence that, although panda mRNA is broadly distributed in the early embryo, local expression of panda mRNA efficiently orients the dorsal-ventral axis and that Panda activity is required locally in the early embryo to specify this axis. Taken together, these findings demonstrate that maternal panda mRNA is both necessary and sufficient to orient the dorsal-ventral axis. These results therefore provide evidence that in the highly regulative sea urchin embryo, the activity of spatially restricted maternal factors regulates patterning along the dorsal-ventral axis.     

Spatially regulated translation in embryos: asymmetric expression of maternal Wnt-11 along the dorsal-ventral axis in Xenopus.

Transition from symmetry to asymmetry is a central theme in cell and developmental biology. In Xenopus embryos, dorsal-ventral asymmetry is initiated by a microtubule-dependent cytoplasmic rotation during the first cell cycle after fertilization. Here we show that the cytoplasmic rotation initiates differential cytoplasmic polyadenylation of maternal Xwnt-11 RNA, encoding a member of the Wnt family of cell-cell signaling factors. Translational regulation of Xwnt-11 mRNA along the dorsal-ventral axis results in asymmetric accumulation of Xwnt-11 protein. These results demonstrate spatially regulated translation of a maternal cell-signaling factor along the vertebrate dorsal-ventral axis and represent a novel mechanism for Wnt gene regulation. Spatial regulation of maternal RNA translation, which has been established in invertebrates, appears to be an evolutionarily conserved mechanism in the generation of intracellular asymmetry and the consequential formation of the multicellular body pattern.     

The first cleavage furrow demarcates the dorsal-ventral axis in Xenopus embryos

To determine the relationship between the first cleavage furrow and the dorsal-ventral axis of the Xenopus embryo, a heritable intracellular marker was injected into one blastomere at the two-cell stage. Embryos were selected in which the cleavage furrow bisected the crescent-shaped region of pale pigmentation or in which it formed 45-90 degrees from this region. This region, which is located in the animal hemisphere of the Xenopus embryo, meets the criteria of the grey crescent as defined in other amphibian species. At tailbud stages the interface between the labeled and unlabeled halves was always coincident with the midsagittal plane. This correlation shows that the first cleavage furrow demarcates the dorsal-ventral axis. The labeling pattern was the same whether the first cleavage furrow bisected the region of pale pigmentation or whether it formed 90 degrees from it. However, when this region was bisected (70% of embryos) it always was located on the dorsal side of the embryo. Thus the region of pale pigmentation indicates the dorsal side of the embryo only when it is bisected by the first cleavage furrow.     

Heat-Induced Reversal of Dorsal-Ventral Polarity in Xenopus Eggs

Heat-treatment of fertilized Xenopus laevis eggs at 30°C induced; 1. conspicuous concentration of the pigment toward the sperm entry point (SEP), 2. eccentric first cleavage furrow formation, and 3. reversal of the dorsal-ventral polarity of the embryos. The optimal treatment was for 2.5 min applied at 20 min postfertilization (p.f.). The rotation movement of the Nile-blue stained spots in the vegetal hemisphere of the heated eggs accurately located the future dorsal midline as in untreated embryos (ref. 22). Exposure of eggs to D₂O also reversed the dorsal-ventral polarity of the embryo suggesting that stabilization of microtubules is involved in the dorsal-ventral axis reversal.     

LOCALIZATION AND SEGREGATION OF MATERNAL RNA'S DURING EARLY CLEAVAGE OF XENOPUS LAEVIS EMBRYOS

The localization and segregation of maternal RNA's during early cleavage of Xenopus laevis embryos were studied. Blastomeres and hemispheres of eggs and early embryos were separated manually and the amounts of ribosomal RNA and poly(A) ⁺RNA extracted from each blastomere and hemisphere were determined by optical density measurement and by ³H-poly(U) hybridization, respectively. It was found that both kinds of the maternal RNA's were more abundant (two-thirds of the total) in the animal hemisphere (cells), while they were evenly distributed between the dorsal and ventral halves. This pattern of localization remained unchanged from the egg to the blastula stage, indicating that these maternal RNA's were segregated into blastomeres quite simply by cell division. Gel electrophoresis showed that the size distributions of poly(A) ⁺RNA and poly(A) sequences obtained from different blastomeres of 8-cell embryos did not differ greatly. It was also found that cytoplasmic polyadenylation of maternal RNA, which occurs during early cleavage and blastulation, took place equally in all regions of the cleaving embryos, suggesting no regional difference in the localization of maternally inherited nonpolyadenylated RNA. These observations are discussed in relation to previous findings on differences along the animal-vegetal and dorsal-ventral axes of the early amphibian embryo.     

Comparison of polyadenylic acid and oligouridylic acid messenger RNA associated proteins

Various subclasses of messenger ribonucleoprotein particles were prepared from free cytoplasmic and polysome fractions of rat liver on the basis of the homopolymeric content of the constituent RNA's. Two major proteins were evident in the free cytoplasmic preparations: the poly(A)-binding protein was the major constituent of polyadenylated components and a 60 kilodalton protein was the major protein in oligouridylated components. In addition to the poly(A)-binding protein, the polysome fractions contained a 74 kilodalton protein that was present in all subclasses of particles. With both free cytoplasmic and polysome preparations, chromatography on columns of poly(U)-sepharose separated poly-adenylated mRNP's largely on the basis of the length of the poly(A) tract; mRNP's containing short poly(A) tracts (fragment distribution centered on 34 residues) were not retained by the columns, presumably because of the interaction of the poly(A) with poly(A)-binding protein.     

Establishment of dorsal-ventral polarity in the Drosophila embryo: the induction of polarity by the Toll gene product

Drosophila females that lack Toll gene activity produce dorsalized embryos, in which all embryonic cells behave like the dorsal cells of the wild-type embryo. Injection of wild-type cytoplasm into young Toll- embryos restores their ability to produce a normal dorsal-ventral pattern in a position-dependent manner. No matter where the cytoplasm is injected relative to the dorsal-ventral axis of the egg shell, the position of the injected cytoplasm defines the ventralmost part of the rescued pattern. Although injection of wild-type cytoplasm into mutants at six other dorsal-group loci also restores the ability to produce lateral and ventral structures, only Toll- embryos lack any residual dorsal-ventral polarity. Experiments suggest that the activity of the Toll product is normally regulated by other dorsal-group genes and that the function of the Toll product is to provide the source for a morphogen gradient in the dorsal-ventral axis of the wild-type embryo.     

F-Actin is a marker of dorsal induction in earlyPatella embryos

Summary The dorsal-ventral axis inPatella vulgata embryos is established at the 32-cell stage by an inductive interaction between the animal micromeres and one vegetal macromere. This vegetal macromere, once induced, is called the 3D macromere, and marks the future dorsal side of the embryo. We examined the pattern of filamentous (F) actin in such embryos using fluorescent phalloidin and found that this dorsal 3D macromere contains more F-actin than the remainder of the cells. In addition, only one of its two daughter cells, i.e. the 4D macromere, retains this higher density. In embryos in which the establishment of the dorsal-ventral axis has been experimentally inhibited via treatment with monensin, such differences in F-actin were not found. These results suggest that the appearance of an increased density of F-actin in the dorsal 3D and 4D macromeres of normal embryos requires the inductive interactions that establish the dorsal-ventral axis. We therefore conclude that F-actin is an early marker for dorsal induction in thePatella embryo.     

Relocalization of the dorsal protein from the cytoplasm to the nucleus correlates with its function

dorsal is one of the maternally active dorsal-ventral polarity genes of Drosophila and is homologous to the vertebrate proto-oncogene c-rel. In wild-type embryos, the dorsal protein is found in the cytoplasm during cleavage. After the nuclei migrate to the periphery of the embryo, a ventral-to-dorsal gradient of nuclear dorsal protein is established. The formation of the nuclear gradient is disrupted in mutant embryos from other maternally active dorsal-ventral polarity genes: in dorsalized embryos only cytoplasmic protein is observed, while in ventralized embryos the nuclear gradient is shifted dorsally. My findings suggest that nuclear localization is critical for dorsal to function as a morphogen and that the distribution of the dorsal protein determines cell fate along the dorsal-ventral axis.     

Gastrulation defective, a complement factor C2/B-like protease, interprets a ventral prepattern in Drosophila

gastrulation defective (gd) encodes a serine protease required for specification of dorsal-ventral cell fates during Drosophila embryogenesis. Using RNA microinjection, I show that wild-type gd RNA can restore ventrolateral pattern elements with correct polarity with respect to egg shape in embryos lacking gd function. While low RNA concentrations restore ventrolateral pattern elements, higher concentrations ventralize the embryo. Gastrulation defective concentration has a rate-limiting effect on the domain of high Dorsal concentration but little effect upon the slope of the gradient. In embryos from pipe-null females, much higher RNA concentrations generate an ectopic axis oriented with respect to the site of injection. The data suggest that the Dorsal gradient is not directly determined by asymmetric cues in the eggshell but arises de novo within the perivitelline space as a consequence of self-regulatory properties of the protease cascade. A homology to the mammalian complement factors C2 and B is also described.     

A cytoplasmic determinant for dorsal axis formation in an early embryo of Xenopus laevis

In Xenopus laevis, dorsal cells that arise at the future dorsal side of an early cleaving embryo have already acquired the ability to cause axis formation. Since the distribution of cytoplasmic components is markedly heterogeneous in an egg and embryo, it has been supposed that the dorsal cells are endowed with the activity to form axial structures by inheriting a unique cytoplasmic component or components localized in the dorsal region of an egg or embryo. However, there has been no direct evidence for this. To examine the activity of the cytoplasm of dorsal cells, we injected cytoplasm (dorsal cytoplasm) from dorsal vegetal cells of a Xenopus 16-cell embryo into ventral vegetal cells of a simultaneous recipient. The cytoplasm caused secondary axis formation in 42% of recipients. Histological examination revealed that well-developed secondary axes included notochord, as well as a neural tube and somites. However, injection of cytoplasm of ventral vegetal cells never caused secondary axis and most recipients became normal tailbud embryos. Furthermore, about two-thirds of ventral isolated halves injected with dorsal cytoplasm formed axial structures. These results show that dorsal, but not ventral, cytoplasm contains the component or components responsible for axis formation. This can be the first step towards identifying the molecular basis of dorsal axis formation.     

Structure of a bacterial photosynthetic membrane: integrity of reaction centers following proteolysis and detergent solubilization

cDNAs were molecularly cloned for proteins specifically expressed in embryo as well as in a chemically induced rat pancreatic B cell tumor in which virally related oncogenes such as v-myc, v-src, v-yes, v-mos and v-kis were previously demonstrated not to be expressed. A plasmid cDNA library consisting of 48,000 independent colonies was constructed from poly(A) containing cytoplasmic RNA isolated from 12 day rat embryo. The library was screened by hybridization with 32p-labelled cDNA synthesized from poly(A) containing RNA of rat pancreatic B cell tumor or normal islet B cells. Two clones were obtained which showed a clearly positive reaction only with tumor probe. Nucleotide sequence of one of them harboring insert of 615 nucleotides was determined and its amino acid sequence of 119 residues was deduced, which showed that the protein encoded by this mRNA is highly basic, basic residues/acidic residues being 1.63.     

Interaction among GSK-3, GBP, axin, and APC in Xenopus axis specification

Glycogen synthase kinase 3 (GSK-3) is a constitutively active kinase that negatively regulates its substrates, one of which is beta-catenin, a downstream effector of the Wnt signaling pathway that is required for dorsal-ventral axis specification in the Xenopus embryo. GSK-3 activity is regulated through the opposing activities of multiple proteins. Axin, GSK-3, and beta-catenin form a complex that promotes the GSK-3-mediated phosphorylation and subsequent degradation of beta-catenin. Adenomatous polyposis coli (APC) joins the complex and downregulates beta-catenin in mammalian cells, but its role in Xenopus is less clear. In contrast, GBP, which is required for axis formation in Xenopus, binds and inhibits GSK-3. We show here that GSK-3 binding protein (GBP) inhibits GSK-3, in part, by preventing Axin from binding GSK-3. Similarly, we present evidence that a dominant-negative GSK-3 mutant, which causes the same effects as GBP, keeps endogenous GSK-3 from binding to Axin. We show that GBP also functions by preventing the GSK-3-mediated phosphorylation of a protein substrate without eliminating its catalytic activity. Finally, we show that the previously demonstrated axis-inducing property of overexpressed APC is attributable to its ability to stabilize cytoplasmic beta-catenin levels, demonstrating that APC is impinging upon the canonical Wnt pathway in this model system. These results contribute to our growing understanding of how GSK-3 regulation in the early embryo leads to regional differences in beta-catenin levels and establishment of the dorsal axis.     

Dorsal ventral polarity and pattern formation in the Drosophila embryo

The establishment of polarity along the dorsal-ventral axis of the Drosophila embryo requires the graded distribution of the dorsal morphogen. Several maternal genes are responsible for the formation of the gradient and their products act in an ordered series of events that begins during oogenesis and involves two different cell types, the oocyte and the follicle cells. The last step in the series results in selective nuclear localization of dorsal proteins, dorsal is thought to regulate the expression of zygotic genes in a concentration dependent way. The zygotic genes determine cell fates in specific regions of the embryo and direct other genes involved in the processes of differentiation.