A possible maternal-effect mutant of Xenopus laevis: II. Studies of RNA synthesis in dissociated embryonic cells

Embryos from a female of Xenopus laevis (designated as no. 65) arrest development at gastrulation and are assumed to be ova-deficient mutant. We dissociated these embryos and studied RNA synthesis at different stages. The cells from the ova-deficient embryos reaggregated quite actively as wild-type embryo cells until the late gastrula stage. RNA synthesis was normal at the early blastula stage but greatly inhibited by the late blastula (stage 9.5) stage, when the synthesis of DNA and protein was still not inhibited appreciably. Thus, inhibition in RNA synthesis appears to be the first manifestation of the maternal defect that occurs before the gastrulation arrest.     

Possible role of the 38 kDa protein, lacking in the gastrula-arrested Xenopus mutant, in gastrulation

An acidic, 38 kDa protein that is present in Xenopus wild-type embryos has been previously shown to be lacking in gastrula-arrested mutant embryos. To gain understanding of the role of this protein, its spatio-temporal distribution and involvement in gastrulation was investigated using the monoclonal antibody (9D10) against it. The protein was prominent in the cortical cytoplasm of cells facing the outside in the animal hemisphere of embryos until the gastrula stage, and in ciliated epithelial cells of embryos at stages later than the late neurula. When the 9D10 antibody was injected into fertilized wild-type eggs, they cleaved normally, but most of them had arrested development, always at the early stage of gastrulation, as in the mutant embryos. In contrast, the majority of the control antibody-injected eggs gastrulated normally and developed further. Cytoskeletal F-actin, which was mainly observed in the area beneath the plasma membrane facing the outside of the epithelial layer of not only the dorsal involuting marginal zone but also the dorsal, vegetal cell mass of the control antibody-injected embryos at the early gastrula stage, was scarcely recognized in the corresponding area of the 9D10 antibody-injected embryos. It is likely that the paucity of the F-actin caused by the 9D10 antibody inhibition of the 38 kDa protein might lead to a failure of cell movement in gastrulation, resulting in developmental arrest.     

Involvement of differential gene expression and mRNA stability in the developmental regulation of the hsp 30 gene family in heat-shocked Xenopus laevis embryos

Four complete hsp 30 genes have been isolated from Xenopus laevis: hsp 30A, hsp 30B (a pseudogene), hsp 30C, and hsp 30D. The hsp 30A and hsp 30C genes are first heat inducible at the early tailbud stage, as determined by RNase protection and RT-PCR assays. In this study, we determined by RT-PCR that the hsp 30D gene was first heat inducible (33^oC for 1 h) at the mid-tailbud stage, approximately 1 day later in development than hsp 30A and hsp 30C. Furthermore, using Northern blot analysis, we detected the presence of very low levels of hsp 30 mRNA at the heat-shocked late blastula stage. The relative levels of these pre-tailbud (PTB) hsp 30 mRNAs increased at the gastrula and neurula stage followed by a dramatic enhancement in heat shocked tail-bud and tadpole stage embryos (50- to 100- fold relative to late blastula). Interestingly, treatment of blastula or gastrula embryos at high temperatures (37^oC for 1 h) or with the protein synthesis inhibitor, cycloheximide, followed by heat shock, led to enhanced accumulation of the pre-tailbud (PTB) hsp 30 mRNAs. hsp 70, hsp 87, and actin messages were not stabilized at high temperatures or by cycloheximide treatment. Finally, hsp 30D mRNA was not detected by RT-PCR analysis of cycloheximidetreated, heat-shocked blastula stage embryos, confirming that it is not a member of the PTB hsp 30 mRNAs. This study indicates that differential gene expression and mRNA stability are involved in the regulation of hsp 30 gene expression during early Xenopus laevis development. © 1995 Wiley-Liss, Inc.     

Effects of ethanol on the primitive streak stage mouse embryo

Recent studies of mouse models have suggested that malformations associated with the fetal alcohol syndrome (FAS) are caused by the effects of ethanol on early embryos during gastrulation and neurulation. A study of Xenopus laevis embryos showed that exposure of gastrula stage amphibian embryos to ethanol inhibits migration of the mesodermal cells, causes formation of small neural plates, and subsequently causes hypoplastic craniofacial malformations in tadpoles. We now report effects of ethanol on the primitive streak stage mouse embryos. An ethanol solution (25%) was injected intraperitonealy twice into mice of 6.5-7.0 days of pregnancy at a dose of 0.015 ml/gm of body weight. Histological and morphometric examinations of 7.5-day embryos, 20 hr after the second injection, showed that the epiblast layer was disorganized and shrunk with formation of many blebs. In addition, formation of the mesodermal cell layer was retarded in the ethanol-treated embryos, suggesting that exposure of gastrula stage embryos to ethanol causes similar abnormalities in mouse and Xenopus embryos. These results suggest that the inhibition of the morphogenetic movements during gastrulation may be the primary effect of ethanol in causing major craniofacial malformations of FAS.     

Activation of muscle-specific actin genes in Xenopus development by an induction between animal and vegetal cells of a blastula

Muscle gene expression is induced a few hours after vegetal cells of a Xenopus blastula are placed in contact with animal cells that normally develop into epidermis and nerve cells. We have used a muscle-specific actin gene probe to determine the timing of gene activation in animal-vegetal conjugates. Muscle actin RNA is first transcribed in a minority of animal cells at a stage equivalent to late gastrula. The time of muscle gene activation is determined by the developmental stage of the responding (animal) cells, and not by the time when cells are first placed in contact. The minimal cell contact time required for induction is between 1 1/2 and 2 1/2 hr, and the minimal time for gene activation after induction is 5-7 hr.     

The Effect of Actinomycin D and Cycloheximide on the Dedifferentiation of Cotyledon in Phaseolus radiatus L. and Its Nucleic Acid and Protein

Calli were induced from cotyledon segment of mung bean (Phaseolus radiatus L.) in Miller medium supplemented with NAA 4 mg/l, kinetin 10 mg/L. The callus formation was completely prevented by the addition of actinomycin D 15 μg/mL or cyclo- heximidc 0.5 μg/mL at 0 hour. The inhibitory effect of actinomycin D or cycloheximide was increased with the increment of concentration but decreased when the inhibitory agents were added a few hours later. If actinomycin D or cycloheximide was added at 24 hour culture it inhibits neither the induction of callus formation nor the proliferation. The content of RNA, DNA and protein were determined. RNA in each segment increased obviously in the early stage of callus formation, but DNA and protein increased slightly afterward. It is suggested that a large increase of RNA is the characteristic of dedifferentiation of cotyledon in P. radiatus. In addition, it has also been shown that an actinomycin D or cycloheximide-sensitive process in the early stage of dedifferentiation is crucial for the callus formation. Both RNA and protein synthesis are required for the initiation of dedifferentiation.     

Correlation between the cell cycle in the neurectoderm and differentiation during the early development of Xenopus laevis. 2 Inhibition of DNA synthesis and mitosis during gastrulation

The hypothesis that cell differentiation during primary induction may be coupled with a 'quantal' cell cycle in the presumptive neurectoderm is considered. Embryos of Xenopus laevis were incubated with fluorodeoxyuridine or mitomycin C during gastrulation or neurulation. Embryos treated during the gastrula stage developed abnormalities of the brain but not of other tissues. This is seen as lending support to the idea that the wave of DNA synthesis and mitosis in the presumptive neurectoderm during gastrulation is an important event in the process of primary induction.     

VegT activation of Sox17 at the midblastula transition alters the response to nodal signals in the vegetal endoderm domain

In Xenopus, the prospective endoderm and mesoderm are localized to discrete, adjacent domains at the beginning of gastrulation, and this is made evident by the expression of Sox17 in vegetal blastomeres and Brachyury (Xbra) in marginal blastomeres. Here, we examine the regulation of Sox17alpha expression and the role of Sox17alpha in establishing the vegetal endodermal gene expression domain. Injection of specific inhibitors of VegT or Nodal resulted in a loss of Sox17alpha expression in the gastrula. However, the onset of Sox17alpha expression at the midblastula transition was dependent on VegT, but not on Nodal function, indicating that Sox17alpha expression is initiated by VegT and then maintained by Nodal signals. Consistent with these results, VegT, but not Xenopus Nodal-related-1 (Xnr1), can activate Sox17alpha expression at the midblastula stage in animal explants. In addition, VegT activates Sox17alpha in the presence of cycloheximide or a Nodal antagonist, suggesting that Sox17alpha is an immediate-early target of VegT in vegetal blastomeres. Given that Nodal signals are necessary and sufficient for both mesodermal and endodermal gene expression, we propose that VegT activation of Sox17alpha at the midblastula transition prevents mesodermal gene expression in response to Nodal signals, thus establishing the vegetal endodermal gene expression domain. Supporting this idea, Sox17alpha misexpression in the marginal zone inhibits the expression of multiple mesodermal genes. Furthermore, in animal explants, Sox17alpha prevents the induction of Xbra and MyoD, but not Sox17beta or Mixer, in response to Xnr1. Therefore, VegT activation of Sox17alpha plays an important role in establishing a region of endoderm-specific gene expression in vegetal blastomeres.     

RNA synthesis in nuclei isolated from early embryos of Xenopus laevis.

1. Rates of RNA synthesis in isolated Xenopus embryo nuclei decrease from blastula through gastrula and neurula stages to hatching tadpoles. 2. In blastula and gastrula nuclei, net synthesis of RNA continues for over 30 min, both in the presence of KCl at 0.4 M and in its absence. In nuclei from later stages, net synthesis continues for only about 10 min in the absence of KCl. 3. At low ionic strength, RNA synthesis in all nuclei is greater with optimum Mg-2+ (6 mM) than with optimum Mn-2+ (1 mM). At high ionic strength the reverse is true. 4. An unusual feature, which gradually disappears as development proceeds, is that curves relating RNA synthesis to KCl concentration show a peak at 0.1 M KCl. In blastula nuclei, RNA synthesis is more rapid at 0.1 M KCl than at 0.4 M. 5. This peak at low ionic strength is not observed in the presence of the initiation inhibitor rifamycin AF/013. It is concluded that the peak arises from initiation of RNA synthesis by an excess of RNA polymerases bound non-specifically to the isolated nuclei. The residual synthesis, representing elongation of chains that were initiated in vivo, still declines as development progresses. 6. In blastula nuclei, over half of the RNA synthesis is effected by polymerase II (inhibited by alpha-amanitin), the proportion remaining roughly constant with increasing ionic strength. In neurula nuclei, the proportion rises from about one-half to three-quarters. The initiation-dependent peak in blastula and gastrula nuclei is contributed by both alpha-amanitin-sensitive and alpha-amanitin-resistant enzymes.     

Xoom is required for epibolic movement of animal ectodermal cells in Xenopus laevis gastrulation

Gastrulation is the most dynamic cell movement and initiates the body plan in amphibian development. In contrast to numerous molecular studies on mesodermal induction, the driving force of gastrulation is as yet poorly understood. A novel transmembrane protein, Xoom, was previously reported, which is required for Xenopus gastrulation. In the present study, the role of Xoom during Xenopus gastrulation was further examined in detail. Overexpression and misexpression of Xoom induced overproduction of Xoom protein, but not a changed phenotype. However, Xoom antisense ribonucleic acid (RNA) injection reduced the Xoom protein and caused gastrulation defects without any influence on the involution and translation levels of mesodermal marker genes. Normal migrating activity of dorsal mesodermal cells was recognized in the antisense RNA-injected explant. Morphological examination using artificial exogastrulation showed that convergent extension of mesodermal cells occurred normally, but the ectodermal cell layer significantly shrank in the antisense RNA-injected embryo. Comparison of cell shape among various experimental conditions showed that inhibition of cell spreading occurs specifically in the outer ectodermal layer of the antisense RNA-injected embryo. Cytochemical examination indicated disorganization of F-actin in the ectodermal cells of the antisense RNA-injected embryo. These results suggest that Xoom plays an important role in the epibolic movement of ectodermal cells through some regulation of actin filament organization.