Cytoplasmic Influence on Lethality in Nucleocytoplasmic and Natural Hybrids between Bufo Calamita Laur and Bufo Bufo L. (Amphibia, Anura)

Nucleocytoplasmic interactions have been studied through nuclear and cytoplasmic grafts. Bufo bufo nuclei transplanted in Bufo calamita eggs provoked 95% lethality during gastrulation. Influence of the cytoplasm in such a nucleocytoplasmic incompatibility has been studied through cytoplasmic fractionation and grafting of the fractions obtained. Fractionation of egg cytoplasm gave three fundamental fractions: lipid, hyaline cytoplasm and vitellus. After injection of B. calamita fractions into B. bufo fertilized eggs, the hyaline cytoplasmic fraction provoked a gastrulation block in the same ratio (95%) as in the interspecific nuclear graft experiment. Influence of the hyaline cytoplasmic fractions of both species has been tested on nucleocytoplasmic and natural hybrid developments. The B. calamita hyaline cytoplasmic fraction provoked in each case a developmental block at the beginning of gastrulation. The B. bufo hyaline cytoplasmic fraction acts later at the yolk plug stage and in some cases partially corrects the developmental bolck or exogastrulation of young hybrid gastrula. It can be generalized that in both kinds of hybrids, the hyaline cytoplasmic fraction of B. calamita exerted a lethal effect on B. bufo nucleus.     

Inhibition of gastrulation in Xenopus embryos by an antibody against a cathepsin L-like protease

An antibody against cathepsin L-like protease (AACLP) was injected into one cell of 2-celled Xenopus embryos. The blastopores of AACLP-injected embryos either did not invaginate or failed to complete invagination. As a result of this failure to complete gastrulation, the body axes could not form normally and tail bud stage embryos were bent dorsally. Embryos injected with a control antibody (CA) developed normally through the tadpole stage. Mesodermal induction was not inhibited in embryos exhibiting this AACLP-induced gastrulation defect, but the mesodermal structure of these embryos was organized incorrectly due to the defective gastrulation during the early stages.     

Identification of novel genes affecting mesoderm formation and morphogenesis through an enhanced large scale functional screen in Xenopus

The formation of mesoderm is an important developmental process of vertebrate embryos, which can be broken down into several steps; mesoderm induction, patterning, morphogenesis and differentiation. Although mesoderm formation in Xenopus has been intensively studied, much remains to be learned about the molecular events responsible for each of these steps. Furthermore, the interplay between mesoderm induction, patterning and morphogenesis remains obscure. Here, we describe an enhanced functional screen in Xenopus designed for large-scale identification of genes controlling mesoderm formation. In order to improve the efficiency of the screen, we used a Xenopus tropicalis unique set of cDNAs, highly enriched in full-length clones. The screening strategy incorporates two mesodermal markers, Xbra and Xmyf-5, to assay for cell fate specification and patterning, respectively. In addition we looked for phenotypes that would suggest effects in morphogenesis, such as gastrulation defects and shortened anterior-posterior axis. Out of 1728 full-length clones we isolated 82 for their ability to alter the phenotype of tadpoles and/or the expression of Xbra and Xmyf-5. Many of the clones gave rise to similar misexpression phenotypes (synphenotypes) and many of the genes within each synphenotype group appeared to be involved in similar pathways. We determined the expression pattern of the 82 genes and found that most of the genes were regionalized and expressed in mesoderm. We expect that many of the genes identified in this screen will be important in mesoderm formation.     

Timing system for the start of gastrulation in the Xenopus embryo

This study examined which component of the egg, the nucleus or cytoplasm, is involved in the timing of the start of gastrulation in the Xenopus embryo, and when it starts to measure time. First, nuclei of cells of 256-cell stage embryos were transplanted to enucleated eggs 60 min after activation. These eggs showed first cleavage 20-30 min later than control eggs fertilized at the same time as the activation of recipient eggs, and started gastrulation 25-35 min later than control embryos (depending on the delay in the first cleavage). Second, eggs whose nuclei were temporarily isolated by the extrusion of the portion containing the nucleus out of the fertilization envelope showed first cleavage 60-90 min later than sibling control eggs, because of delayed introduction of the nucleus from the extruded portion. They started gastrulation 60-90 min later than sibling control embryos (depending on the delay in the first cleavage). The portion inside the envelope underwent two to three rounds of oscillation in cell cycle relevant activities before the first cleavage, while the portion outside underwent the same rounds of cleavage as the inside portion. From the present and previous results it is concluded that the putative timing system for the start of gastrulation in the Xenopus embryo, whether it consists of a single or of multiple clocks, starts measuring time at or around the first cleavage, and that the presence of both the nucleus and the cytoplasm in the same cell and occurrence of mitosis and/or cleavage there are indispensable for the timing system to work, although the role of the cytoplasm is superior to that of the nucleus.     

Implication of Cytoplasmic Factors in the Lethality of Bufonidae Nucleocytoplasmic Hybrids

The nucleocytoplasmic hybrid combination performed by nuclear graft between B. bufo nucleus and B. calamita egg is 95% lethal during gastrulation mostly at the young gastrula stage (75%) and to a lesser extent at the yolk plug stage (20%). The heterologous B. calamita cytoplasm was treated or fractioned by different techniques including centrifugation, nucleic acid extraction, ammonium sulfate treatment and heating.
The treated cytoplasmic fractions were injected in B. bufo fertilized eggs in order to check their influence on morphogenetic capacities of the B. bufo nucleus. Injection of hyaline cytoplasmic fraction obtained from B. calamita centrifuged eggs blocks the B. Bufo fertilized egg gastrulation in similar rates as in nucleocytoplasmic association performed by interspecific nuclear grafting. Gastrulation, however, is not affected by injection of total nucleic acids extracted from this hyaline fraction. The soluble cytoplasmic fraction obtained after 60% ammonium sulfate precipitation blocks the development at the beginning of gastrulation, this property being inactivated by heating for 5 min at 60°C. Supernatant from 70% ammonium sulfate precipitation blocks the development at the yolk plug stage and is inactivated by heating for 5 min at 80°C.
These experiments suggest that two distinct factors in B. calamita eggs are involved in developmental arrest of injected B. bufo fertilized eggs, these two factors respectively acting on the beginning and on the end of gastrulation.     

The ARID domain protein dril1 is necessary for TGF(beta) signaling in Xenopus embryos

ARID domain proteins are members of a highly conserved family involved in chromatin remodeling and cell-fate determination. Dril1 is the founding member of the ARID family and is involved in developmental processes in both Drosophila and Caenorhabditis elegans. We describe the first embryological characterization of this gene in chordates. Dril1 mRNA expression is spatiotemporally regulated and is detected in the involuting mesoderm during gastrulation. Inhibition of dril1 by either a morpholino or an engrailed repressor-dril1 DNA binding domain fusion construct inhibits gastrulation and perturbs induction of the zygotic mesodermal marker Xbra and the organizer markers chordin, noggin, and Xlim1. Xenopus tropicalis dril1 morphants also exhibit impaired gastrulation and axial deficiencies, which can be rescued by coinjection of Xenopus laevis dril1 mRNA. Loss of dril1 inhibits the response of animal caps to activin and secondary axis induction by smad2. Dril1 depletion in animal caps prevents both the smad2-mediated induction of dorsal mesodermal and endodermal markers and the induction of ventral mesoderm by smad1. Mesoderm induction by eFGF is uninhibited in dril1 morphant caps, reflecting pathway specificity for dril1. These experiments identify dril1 as a novel regulator of TGF(beta) signaling and a vital component of mesodermal patterning and embryonic morphogenesis.     

Expression of Brachyury-like T-box transcription factor, Xbra3 in Xenopus embryo

The Xenopus Brachyury-like Xbra3 gene is a novel T-box gene that is closely associated with Xenopus Brachyury. The expression pattern of Xbra3 during development is similar to that of Xbra. During gastrulation Xbra3 is expressed in the marginal zone, with a gradient of increasing expression from ventral to dorsal. In the early neurula stage Xbra3 is expressed in the notochord and posterior mesoderm, but by the tailbud stage its expression is restricted to the forming tailbud and the posterior portion of the notochord.     

eFGF regulates Xbra expression during Xenopus gastrulation.

We show that, in addition to a role in mesoderm induction during blastula stages, FGF signalling plays an important role in maintaining the properties of the mesoderm in the gastrula of Xenopus laevis. eFGF is a maternally expressed secreted Xenopus FGF with potent mesoderm-inducing activity. However, it is most highly expressed in the mesoderm during gastrulation, suggesting a role after the period of mesoderm induction. eFGF is inhibited by the dominant negative FGF receptor. Embryos overexpressing the dominant negative receptor show a change of behaviour of the dorsal mesoderm such that it moves around the blastopore lip instead of elongating in an antero-posterior direction. In such embryos there is a reduction in Xbra expression during gastrulation. We show that during blastula stages eFGF and Xbra are able to activate the expression of each other, suggesting that they are components of an autocatalytic regulatory loop. Moreover, we show that Xbra expression in isolated gastrula mesoderm cells is maintained by eFGF, suggesting that eFGF continues to regulate the expression of Xbra in the blastopore region. In addition, overexpression of eFGF after the mid-blastula transition results in the up-regulation of Xbra expression during gastrula stages and causes suppression of the head and enlargement of the proctodeum, which is the converse of the posterior reductions of the FGF dominant negative receptor phenotype. These data suggest an important role for eFGF in regulating the expression of Xbra and for the eFGF-Xbra regulatory pathway in the control of mesodermal cell behaviour during gastrula stages.     

Genetic diagnosis of cytoplasmic male sterile cybrid plants of rice

Twelve Japanese rice cultivars were converted to CMS by asymmetric protoplast fusion with MTC-5A, the cytoplasm of which was derived from an indica rice, Chinsurah Boro II. With the exception of the cybrids that had a nucleus from Hoshiyutaka, most of these cybrid plants were sterile. The unique sequence downstream from the mitochondrial atp6 of MTC-5A was specifically amplified in the sterile cybrid plants by PCR. All progenies of the cybrid plants carrying this unique sequence were sterile. On the other hand, in some of the sterile cybrid plants in which the unique sequence was not amplified by PCR, fertility was recovered in their progenies. Somaclonal mutation may have caused sterility in these cybrids. Only the cybrid plants that had the unique sequence detected by PCR were CMS. Thus, the CMS plants can be selected rapidly and easily by PCR, at an early stage of plant regeneration. Soon after transplanting the regenerated plants to a green house, fertile cybrids and sterile cybrids produced by somaclonal mutation can be removed. These findings also show that the unique region downstream from atp6 is tightly linked with the CMS phenotype.     

Effect of egg composition on the developmental capacity of androgenetic mouse embryos.

Analysis of the developmental capacities of androgenetic and gynogenetic mouse embryos (bearing two paternal or two maternal pronuclei, respectively) revealed a defect in blastocyst formation of androgenetic, but not gynogenetic, embryos that was a function of the maternal genotype. Androgenetic embryos constructed using fertilized eggs from C57BL/6 or (B6D2)F1 mice developed to the blastocyst stage at frequencies similar to those previously reported, whereas androgenetic embryos constructed with fertilized eggs from DBA/2 mice developed poorly, the majority failing to progress beyond the 16-cell stage and unable to form a blastocoel-like cavity, regardless of whether the male pronuclei were of C57BL6 or DBA/2 origin. This impaired development was observed even in androgenetic embryos constructed by transplanting two male pronuclei from fertilized DBA/2 eggs to enucleated C57BL/6 eggs, indicating that the defect cannot be explained as the lack of some essential component in the DBA/2 cytoplasm that might otherwise compensate for androgeny. Rather, the DBA/2 egg cytoplasm apparently modifies the incoming male pronuclei differently than does C57BL/6 egg cytoplasm. Several specific alterations in the protein synthesis pattern of DBA/2 androgenones were observed that reflect a defect in the regulatory mechanisms that normally modulate the synthesis of these proteins between the 8-cell and blastocyst stages. These results are consistent with a model in which cytoplasmic factors present in the egg direct a strain-dependent modification of paternal genome function in response to epigenetic modifications (genomic imprinting) established during gametogenesis and indicate that preimplantation development can be affected by these modifications at both the morphological and biochemical levels.     

Expression of Xenopus tropicalis noggin1 and noggin2 in early development: two noggin genes in a tetrapod

We report the identification of two distinct noggin genes in the tetrapod Xenopus tropicalis. Noggin functions to antagonize BMP signaling in many developmental contexts, and much work has explored its role in early vertebrate development. We have identified two noggin genes in the tropical clawed frog, X. tropicalis, a diploid anuran which is being explored for its potential as a genetic model system for early vertebrate development. Here we report the cloning and characterization of the Xenopus tropicalis noggin1 and noggin2 genes, which have distinct expression domains in the early embryo with one overlapping domain in the anterior neural tissue. X. tropicalis noggin1 expression is very similar to that of noggin in Xenopus laevis, with expression beginning in the blastula organizer region and continuing through gastrulation and neurulation in the organizer and notochord. Later, it is also expressed in the anterior neural ridge and subsequent forebrain; noggin1 is also expressed in the pharyngeal arches after neural tube closure. At the tadpole stage expression is maintained in the dorsal neural tube and is present in the otic vesicle. However, the expression of noggin2 is much more similar to the expression of noggin2 in D. rerio with expression in the forebrain, hindbrain, and somites, but unlike D. rerio, X. tropicalis noggin2 is expressed in the heart by stage 28. This work presents the first example of a tetrapod with at least two noggin genes.     

A novel gene, BENI is required for the convergent extension during Xenopus laevis gastrulation

Activin-like signaling plays an important role in early embryogenesis. Activin A, a TGF-beta family protein, induces mesodermal/endodermal tissues in animal cap assays. In a screen for genes expressed early after treatment with activin A, we isolated a novel gene, denoted as BENI (Brachyury Expression Nuclear Inhibitor). The BENI protein has a conserved domain at the N-terminus that contains a nuclear localization signal (NLS), and two other NLSs in the C-terminal domain. BENI mRNA was localized to the animal hemisphere at the gastrula stages and to ectoderm except for neural regions at stage 17; expression persisted until the tadpole stage. The overexpression of BENI caused gastrulation defects and inhibition of elongation of activin-treated animal caps with reduction of Xbra expression. Moreover, whole-mount in situ hybridization revealed reduced expression of Xbra in BENI mRNA-injected regions of gastrula embryos. Functional knockdown of BENI using an antisense morpholino oligonucleotide also resulted in an abnormal phenotype of embryos curling to the dorsal side, and excessive elongation of activin-treated animal caps without altered expression of mesodermal markers. These results suggested that BENI expression is regulated by activin-like signaling, and that this regulation is crucial for Xbra expression.     

Antisense inhibition of Xbrachyury impairs mesoderm formation in Xenopus embryos

Expression of the Xbrachyury (Xbra) gene was inhibited by antisense RNA synthesized in situ from an expression vector read by RNA polymerase III, injected into the fertilized egg or the 2-cell stage embryo of Xenopus laevis. Antisense-treated embryos had markedly reduced levels of Xbra mRNA and protein, and showed deficiencies in mesodermal derivatives and axis formation. In particular, organization of the posterior axis was affected, but often the anterior axis was also reduced. Some embryos failed to form mesoderm altogether and remained amorphous. The antisense effect is dose-dependent and may be "rescued" by overexpression of Xbra. In Xbra-deficient embryos, expression of several mesodermal genes (Xvent, pintallavis, Xlim, Xwnt-8 and noggin) was reduced to varying degrees, whereas goosecoid levels remained normal. The modified expression levels were partly normalized when Xbra deficiency was rescued. The observation that antisense inhibition yields slightly different phenotypes from dominant-negative inhibition suggests the recommendation of using several surrogate genetic approaches to determine the functional role of a gene in Xenopus development.     

Two-dimensional gel analysis of the fate of oocyte nuclear proteins in the development of Xenopus laevis

The amphibian oocyte nucleus is thought to provide a maternal store of protein required in embryogenesis. The fate of germinal vesicle proteins has been studied by comparing polypeptide patterns of oocytes, embryos, and several adult organs of Xenopus laevis on two-dimensional gels. A combination of silver staining and fluorography of radiolabeled protein on gels was used to analyze maternal and newly synthesized polypeptides in embryogenesis. Comparison of protein patterns was facilitated and corroborated by application of monoclonal antibodies against several germinal vesicle proteins. These were characterized by immunoblotting from two-dimensional gels, and polypeptides of identical structure were recognized in oocyte nuclei, embryos, and tadpoles. The following conclusions were drawn: (1) Almost all prevalent germinal vesicle proteins can be continuously traced in embryos up to swimming tadpole stages, although their patterns of new synthesis are greatly different, some are not radiolabeled in the embryo but solely provided by the maternal store. (2) Many of the polypeptides occurring in oocyte nuclei are also found in one or several organs of the adult. (3) Tissue specificities of germinal vesicle proteins, previously detected by immunocytochemistry with monoclonal antibodies, could be confirmed by independent biochemical methods. (4) As has been previously shown by immunohistological methods, oocyte nuclear antigens are shed into the cytoplasm of the maturing egg, and are reaccumulated in the nuclei of the embryonic cells, each at a characteristic developmental stage. These shifts between intracellular compartments are not accompanied by a change of the covalent structure of the antigen.     

Appearance and Distribution of RNA-Rich Cytoplasms in the Embryo of Xenopus laevis during Early Development

The occurrence of the dorsal yolk-free cytoplasm in the fertilized egg of Xenopus was re-examined, and the appearance and the distribution of RNA-rich cytoplasms in Xenopus embryos during early development were examined with their paraffin sections. The results show that the dorsal yolk-free cytoplasm does not occur solely in the dorsal part of the embryo but is continuous to similar cytoplasmic mass in the central and the ventral part. The whole mass of this continuous cytoplasm is denoted here as the mesoplasm. The locations of the mesoplasm in the embryo can be traced by its high RNA content during cleavage and blastulation. The cells endowed with the mesoplasm constitute a broad band about the equator of the blastula. At the lower edge of this band, the blastopore lip is formed during gastrulation. Another mass of yolk-poor and RNA-rich cytoplasm becomes distinct around every nucleus in the stage 4 embryo and is denoted here as the nucleophilic plasm. This plasm is diminished at every nuclear division and disappears in the stage 10 embryo. Origins and roles of the mesoplasm and the nucleophilic plasm were discussed and a mechanism of blastulation was suggested.     

Xoom is maternally stored and functions as a transmembrane protein for gastrulation movement in Xenopus embryos

Xoom has been identified as a novel gene that plays an important role in gastrulation of Xenopus laevis embryo. Although Xoom is actively transcribed during oogenesis, distribution and function of its translation product have not yet been clarified. In the present study, the polyclonal antibody raised against Xoom was generated to investigate a behavior of Xoom protein. Anti-Xoom antibodies revealed that there are two forms of Xoom protein in Xenopus embryos: (i) a 45 kDa soluble cytoplasmic form; and (ii) a 44 kDa membrane-associated form. Two forms of Xoom protein were ubiquitously detected from unfertilized egg to tadpole stage, with a qualitative peak during blastula and gastrula stages. Immunohistochemical examination showed that Xoom protein is maternally stored in the animal subcortical layer and divided into presumptive ectodermal cells during cleavage stages. Enzymatic digestion of membrane protein and immunologic detection of Xoom showed that Xoom exists as a membrane-associated protein. To examine a function of Xoom protein, anti-Xoom antibodies were injected into blastocoele of stage 7 blastula embryo. Anti-Xoom antibodies caused gastrulation defect in a dose- dependent manner. These results suggest that maternally prepared Xoom protein is involved in gastrulation movement on ectodermal cells.