A radioautographic study of protein synthesis in loach blastoderm]

The dynamics of protein synthesis in the loach embryos has been studied by means of autoradiography at the stages of cleavage, blastula and gastrula. During the synchronous cleavage divisions, nuclear proteins are mainly synthesized. From the early blastula stage until the early gastrula stage, the intensity of nuclear protein synthesis increases 2.5 times whereas the intensity of cytoplasmic and total protein synthesis is low and relatively constant. After the onset of gastrulation the intensity of nuclear and cytoplasmic protein synthesis increases 3-4 times and at the late gastrula stage it decreases twice as compared with that at the midgastrula stage. During blastulation, no regional differences in the intensity of nuclear and cytoplasmic protein synthesis were found. With the onset of gastrulation, a vegeto-animal gradient of labeled aminoacid incorporation into nuclear and cytoplasmic proteins appears. During gastrulation, reliable differences were found between the intensity of labeled aminoacid incorporation into proteins of the cells of intact and dissociated blastoderms. During this period, the intensity of protein synthesis in embryonic shield is higher than that in the extraembryonic part of blastoderm.     

Effect of sodium selenite on RNA synthesis in loach embryos

The effects of sodium selenite on the ribonucleic acid synthesis in normal diploid embryos and isolated nuclei of the loach Misgurnus fossilis were studied. The relative rate of synthesis was determined from incorporation of [3H]uridine into the total RNA, taking into consideration the incorporation of the label into the total acid-soluble fraction and into phosphorylated derivatives of uridine. It was shown that sodium selenite inhibits the RNA synthesis in loach embryos at the gastrula stage. It was also found that sodium selenite exerts an inhibiting effect on the activity of form I of DNA-dependent RNA-polymerase in isolated loach nuclei without affecting the activity of the enzyme form II.     

Kinetics of the synthesis of nucleic acids in haploid and diploid loach embryos]

Al kinetic analysis of incorporation of the mixture of 3H-nucleosides in the nucleic acid fractions was carried out to examine the mechanisms of compensation of the genetic material deficiency. Both the haploid and diploid embryos of the loach (Misgurnus fossilis L.) were analyzed. When comparing the DNA and RNA syntheses, the level of phosphorylation (nucleotide pool) in the both genetic variants was under control. The rate of incorporation of the labelled nucleosides in DNA was shown to be higher in haploids at the early developmental stages than in diploids but later it became the same. The increased level of DNA replication in the early haploid embryos was due to the compensatory increase of the cell number in them as compared with the diploid ones. The rate of total RNA synthesis corrected by the differences in the rate of nucleoside phosphorylation varied directly with the degree of ploidy at the blastula stage; at the gastrula stage the value of RNA synthesis per haploid genome was compensated, and at the stage of organogenesis the production of total RNA, as calculated per cell, became in haploids even higher than in diploids. The data obtained suggest the essential changes in the patterns of RNA synthesis control during development.     

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.     

A cell-free assay system for the analysis of changes in RNA synthesis during the development of Xenopus laevis.

Conditions were established for the maximal synthesis of RNA by Xenopus cultured cell nuclei. These differed from those for mammalian nuclei in having a lower K⁺ optimum. The Xenopus nuclei showed all three RNA polymerase activities and processed rRNA to 28 S and 18 S species. Extracts of full-grown oocytes stimulated the rate of RNA synthesis 2.5-fold and caused it to continue linearly for at least 6 hr. This full effect could be produced by preincubation of the nuclei with oocyte extract, followed by their reisolation and assay under standard conditions, provided that the four ribonucleotide triphosphates were present during the preincubation. The stimulatory factor(s) were mainly present in the cytoplasm of the oocyte. They produced quantitatively identical stimulations of RNA synthesis in hamster nuclei. The overall stimulatory effect of cell extracts disappears in the egg, remains absent through cleavage, but reappears at the late blastula stage. This corresponds to the changes in RNA synthesis believed to occur in early development. The extracts affect polymerases I and III, but not II to a significant extent. They also stimulate the incorporation of [γ-³²P]ATP and GTP into RNA, though to a lesser extent than the incorporation of [³H]UTP. The egg extract inhibits γ-³²P incorporation. There therefore seems to be some effect on the initiation of new chain synthesis, but its magnitude is uncertain, and the effect could be indirect.     

In vitro incorporation of labelled amino acids into heart muscle ribosomes at early and late stages of compensatory heart hyperfunction]

The activity of a protein-synthesizing cell-free system from heart muscle was studied at early and late stages of compensatory heart hyperfunction. It was found that the incorporation of amino acids into heart ribosomes during 48 hours after the hyperfunction had been produced, increased by 30% as compared to the control. The incorporation of amino acids into heart ribosomes at the late stage of hyperfunction (after 6 months) was decreased by 46% as compared to the early stages. The addition of homologous tRNA to the cell-free system of protein synthesis under prolonged heart hyperfunction stimulated the incorporation of amino acids into the ribosomes by 40--50%.     

The detection and characteristics of substances with fibroblast growth factor properties in the cells of loach embryos]

The substances extracted and partially purified from embryos of the loach (Misgurnus fossilis L.) at the late blastula stage are shown to possess properties characteristic of the fibroblast growth factor (FGF): 1) they bind with Heparin-Sepharose; 2) induce DNA synthesis in mouse NIH-3T3 and Swiss-3T3 fibroblast cell lines and in the primary culture of human embryonic fibroblasts; 3) have an apparent molecular weight of 15-16 kDa (according to SDS-electrophoresis); and 4) show positive reaction with antibodies against bovine basic FGF.     

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.     

Morphogenesis and regulated gene activity are independent of DNA replication in Xenopus embryos.

Xenopus embryos were transferred into media containing aphidicolin at late blastula, mid-gastrula, and early neurula stages. In each case, embryos continued to differentiate in the absence of DNA replication. When the inhibitor was added at late blastula, embryos continued to develop for about 8 h. However, when aphidicolin was added at the early neurula stage, development could be seen for up to 40 h after addition. The influence of replication on embryonic gene activity was studied by RNA blot analysis. Of the genes we examined only histone gene expression was down regulated by the addition of aphidicolin. The expression of various embryo-specific genes was unaffected by the lack of DNA synthesis. Even after several hours of treatment with aphidicolin, replication-inhibited tailbud and tadpole stages showed the same levels of specific mRNAs as control embryos containing 4-5 times more DNA. We conclude that morphogenesis and embryo-specific gene activity are independent of both DNA replication and a precise amount of DNA per embryo.     

Cytophotometric and biochemical research on the amount of DNA in the nuclei of loach embryos injected with low-molecular RNA

The cell cycle structure in the cells of loach embryos at the early blastula stage (5 h of development at 21 degrees) is markedly altered under the influence of injection of homologous low molecular weight nuclear RNA and, as a result, the number of cells in G2-phase. The DNA amount in the embryo increases by 20%. At the midblastula stage (7 h) no increase in the number of cells in G2-phase was found.     

Incorporation of 13C,15N-labeled nucleosides and measurement of RNA synthesis and turnover in sea urchin embryos

The uptake of nucleosides into sea urchin embryos and their subsequent incorporation into RNA increases with increasing external nucleoside concentration. When embryos are incubated with high concentrations of ¹³C,¹⁵N-labeled nucleosides, newly synthesized RNA becomes sufficiently labeled with heavy isotope to be separated from unlabeled RNA on cesium formate equilibrium gradients. High concentrations of nucleosides do not affect development of embryos or rates of RNA synthesis. The extent of density-labeling of precursor pools increases with incubation time, and only levels off after many hours. During incubations with high concentrations of nucleosides, ATP pools expand up to twofold. Using density-labeling to circumvent precursor pool measurements, a method is presented to study the synthesis and decay of pulse-labeled RNA. The instantaneous rate of synthesis of total RNA at the blastula stage is 9.3 × 10^?15 mol of total nucleotide/embryo per minute and the average half-life of total RNA is 23 minutes.     

Synthesis of histone mRNA sequences in isolated nuclei of cleavage stage sea urchin embryos

A qualitative assay for detection of histone mRNA sequences in nuclear RNA was developed using actinomycin D-CsCl gradients to separate histone DNA from bulk DNA by differences in buoyant density. A significant amount of RNA synthesized in vitro in isolated nuclei from early blastula stage sea urchin embryos hybridized coincident with the histone DNA satellite, and this hybridization was competed out by unlabeled “9S” polysomal RNA purified from embryos at the same stage of development. The biogenesis of these histone mRNA sequences appeared similar as observed during in vivo and in vitro synthesis. Nuclear RNA from embryos pulse labeled in vivo was found to lack histone sequences, suggesting a rapid exit time for these sequences from the nucleus. Attempts to study the exit of histone sequences from isolated nuclei labeled in vitro also suggested a rapid exit time for histone sequences. The histone sequences were synthesized to a much lesser extent in isolated nuclei from late blastula stage embryos, as anticipated from the much reduced amount of histone mRNA labeled on polysomes at this stage.     

Determination of optimal conditions for physical and chemical inactivation of nuclei for obtaining haploid and anuclear loach (Misgurnus fossilis L.) embryos]

The doses of X-irradiation sufficient for obtained truly haploid and anuclear embryos of the loach were determined. Mitomycin C in concentrations arresting the development at the late blastula stage (100-500 mcg/ml) was tested for the purposes of chemical enucleation of embryos. The data obtained allowed to recommend the following doses of X-irradiation to obtained the 100% inactivation of one or both the paternal genomes and haploid and anuclear embryos of the loach: 40 kr for eggs and 60 kr for testes. Mitomycin in the concentrations tested did not cause the 100% enucleation of embryos.     

Overexpression of S-adenosylmethionine decarboxylase (SAMDC) activates the maternal program of apoptosis shortly after MBT in Xenopus embryos

Overexpression of S-adenosylmethionine decarboxylase (SAMDC) mRNA in 1- and 2-cell stage Xenopus embryos induces cell autonomous dissociation at the late blastula stage and developmental arrest at the early gastrula stage. The induction of cell dissociation took place "punctually" at the late blastula stage in the SAMDC-overexpressing cells, irrespective of the stage of the microinjection of SAMDC mRNA. When we examined the cells undergoing the dissociation, we found that they were TUNEL-positive and contained fragmented nuclei with condensed chromatin and fragmented DNA. Furthermore, by injecting Xenopus Bcl-2 mRNA together with SAMDC mRNA, we showed that SAMDC-overexpressing embryos are rescued completely by Bcl-2 and becometadpoles. These results indicatethat cell dissociation induced by SAMDC overexpression is due to apoptotic cell death. Since the level of S-adenosylmethionine (SAM) is greatly reduced in SAMDC-overexpressing embryos and this induces inhibition of protein synthesis accompanied by the inhibition of DNA and RNA syntheses, we conclude that deficiency in SAM induced by SAMDC overexpression activates the maternal program of apoptosis in Xenopus embryos at the late blastula stage, but not before. We propose that this mechanism serves as a surveillance mechanism to check and eliminate cells physiologically damaged during the cleavage stage.     

Synthesis and transport of various RNA species in developing embryos of Xenopus laevis.

Embryonic cells of Xenopus laevis were labeled for varying lengths of time, and their nuclear and cytoplasmic RNAs were analyzed, with the following results. (1) The synthesis of small nuclear RNAs (snRNAs) is detected from blastula stage on. (2) The initiation of 4 S and 5 S RNA syntheses occurs at blastula stage. However, while the former is transported into the cytoplasm immediately after its synthesis, the latter remains within the nucleus, until its transport starts later, concomitantly with that of 28 S rRNA. (3) As soon as “blastula” cells start to synthesize 40 S rRNA precursor at 5th hr of cultivation, 18 S rRNA is transported first; the transport of 28 S rRNA begins 2 hr later. (4) On a per-cell basis, poly(A)-RNA is synthesized in blastula stage at a much higher rate than in the later stages. About one-third of the total blastula poly(A)-RNA, and about one-fifth in the case of tailbud cells, is transported quickly into the cytoplasm. Then, it appears that the RNAs which are synthesized at early embryonic stages are transported to the cytoplasm without delays, except for 5 S RNA and snRNAs.     

Activation of mitochondrial DNA synthesis during loach embryogenesis

Mitochondria isolated from unfertilized loach (Misgurnus fossilis) eggs incorporate 3H-dTTP at a low rate (0,01 pmoles 3H-dTTP-mg of mitochondrial protein/1 hr incubation). After fertilization the rate of 3H-dTTP incorporation into DNA of mitochondria isolated from embryos of different developmental stages increases exponentially, doubling each 7 hours, and attains the maximum to 35 hour of development. This stage corresponds to the beginning of movement. DNA synthesis in mitochondria from unfertilized eggs resembles repair; as early as 6 hours after fertilization the labeling pattern of mt-DNA is of replicative type. This replicative type of labeling is observed throughout all early development. Activation of mt-DNA biosynthesis in the course of early development is not accompanied by any changes of DNA polymerase activity in mitochondrial extracts or in mitochondrial lysates.     

Synthesis of sulfate donor in developing sea urchin embryos

In sea urchin embryos, synthesis of the sulfate donor, 3′-phosphoadenosine-5′-phosphosulfate (PAPS) begins in late blastula stage, which is a critical stage with respect to the need for sulfate ions. The formation of PAPS is insensitive to actinomycin D but sensitive to puromycin; this suggests the possibility that the PAPS synthesizing system has been maternally programmed during oogenesis. Thiocyanate inhibits the incorporation of sulfate into PAPS.     

Changes in the representation of repeating DNA sequences in nuclear RNAs of early loach embryos

The hybridization kinetics of nuclear RNAs of loach embryos labelled with [3H]uridine for 1 hour with DNA excess shows that during embryogenesis (from the blastula to the gastrula stage) the number of newly formed RNA molecules transcribed from repeating DNA sequences in considerably reduced. This occurs both in the RNA fraction extracted from the nuclei with phenol pH 7.7 and having a low sedimentation coefficient and a low degree of polyadenylation, and in the RNA fraction extracted with phenol pH 9.0 having a higher sedimentation coefficient and a higher degree of polyadenylation.     

Synthesis and turnover of late H2B histone mRNA in developing embryos of the sea urchin, Strongylocentrotus purpuratus

In sea urchins, "early" histone proteins are synthesized during cleavage and blastula formation, "late" histone proteins in subsequent stages of development. To understand the molecular mechanisms responsible for this ontogenic switch in histone subtype synthesis, we determined the absolute amounts, rates of synthesis, and rates of turnover of late H2b histone mRNAs during development. We showed previously that late H2b mRNA comprises several mRNA isotypes. In this study, we used both a class-specific DNA probe to measure the amounts of the late H2b mRNA isotypes collectively, and a gene-specific probe to measure amounts of a particular late H2b mRNA encoded by a gene known as L1. We found that the amount of late H2b mRNA increased dramatically from 85,000 molecules per embryo in the 16-hr blastula to a peak of 670,000 molecules per embryo in the 24-hr mesenchyme blastula, and fell to 380,000 molecules per embryo in the 72-hr pluteus larva. The L1 late H2b mRNA achieved its maximum abundance earlier than the late H2b mRNA class as a whole, reaching a peak of 34% of total late H2b in the 14-hr blastula and declining to 7% in the pluteus larva. Measurements of the rate of incorporation of [3H]uridine into late class H2b mRNA, performed by a novel in vivo isotope incorporation method, enabled us to calculate both synthesis rates and half-lives of late H2b mRNA during development. These calculations showed (1) that the increase in late H2b mRNA level between 16 and 24 hr postfertilization is regulated primarily if not entirely at the level of mRNA synthesis; and (2) that the half-life of late H2b mRNA is comparatively short, around 20 min, at all stages examined.