Does protein synthesis decline in lithium-treated sea urchin embryos because RNA synthesis is inhibited?

Vegetalization of sea urchin embryos by Li⁺ is characterized by rates of protein synthesis which are normal during cleavage, and decline after hatching. This paper tests the hypothesis that Li⁺ interferes with RNA synthesis during cleavage, resulting in the decline in protein synthesis at hatching when newly synthesized mRNA becomes critical for further normal development. Treatment with Li⁺ does cause a decline in the incorporation of [³H]guanosine into RNA. However, this decline could be accounted for by reduced uptake of the labeled precursor with a concomitant reduction in precursor pool specific activity. Therefore, reduced protein synthesis after hatching in Li⁺-treated embryos cannot be accounted for by a comparable reduction in RNA synthesis.     

Pulse treatment of sea urchin embryos with A23187 blocks their hatching out

Summary Pulse treatment of sea urchin embryos with 3 µM A23187 for 2 h at 20° C, starting from 3 to 6 h of development, prevented the embryos from hatching. Many embryos thus treated with A23187 produced mesenchyme cells and underwent gastrulation while still enclosed within the fertilization membrane. The pulse treatment in this pre-hatching period exerts markedly stronger inhibitory effects on hatching than on other events in early development. Treatment beginning at times earlier than 2 h and later than 8 h of development caused only a slight delay of hatching. The activity of hatching enzyme, known to increase between 6 and 8 h after fertilization, was quite low, if present at all, in embryos in which hatching was blocked by A23187. Hatching enzyme synthesis is probably blocked by the preceding pulse treatment. However, overall protein synthesis, estimated with methionine S 35 incorporation, was somewhat augmented in embryos by the pulse treatment. The blockage of hatching and the augmentation of overall protein synthesis by A23187 were appreciably reversed by procaine, tetracaine, ruthenium red or verapamil. Probably, an artificial Ca²⁺ signal induced by A23187 activates protein synthesis but blocks the induction of hatching enzyme synthesis.     

Sulfated mucopolysaccharide synthesis during the development of Rana pipiens

Sulfated mucopolysaccharide (MPS) synthesis during the development of Rana pipiens was studied autoradiographically and biochemically following injection of embryos with ³⁵S-sulfate. ³⁵S-sulfate incorporation can be detected in unfertilized and fertilized eggs. The sulfate-incorporating material accumulates along the periphery of yolk platelets of eggs. During cleavage, the ³⁵S-sulfate-incorporating material accumulates on cell surfaces as well as along the periphery of yolk platelets. Biochemical analysis utilizing the enzymes chondroitinase ABC and AC and nitrous acid degradation indicates that the MPS synthesized during cleavage is approximately 82% heparin and/or heparan sulfate and 18% chondroitin 4-sulfate. During gastrulation, a greatly enhanced incorporation of ³⁵S-sulfate is observed in the invaginating chordamesoderm and lateroventral mesoderm, and by the end of gastrulation enhanced incorporation can be detected in neural tissue. During this period, chondroitin 6-sulfate synthesis is initiated. Incorporation of ³⁵S-sulfate is observed in all tissues of the embryo from the beginning of neurulation through hatching. This ubiquitous incorporation is accompanied by an increase in the relative amount of chondroitin 6-sulfate synthesized. During the period following hatching, incorporation is suppressed in some tissues and enhanced in others so that by the late feeding tadpole stage a very high incorporation is observed only in cartilaginous tissue. These results indicate that sulfated MPS synthesis occurs in all stages of development of Rana pipiens, but that significant changes in the rate of synthesis occur in various cell types during gastrulation and after hatching. The ubiquity of sulfated MPS synthesis during the critical early stages of development and the changes in the pattern of synthesis in various cell types suggest that these molecules are involved in a number of embryonic processes.     

The effects of N-cadherin misexpression on morphogenesis in Xenopus embryos

N-cadherin is a calcium-dependent, cell adhesion molecule that has been proposed to play a role in morphogenesis in vertebrate embryos. Throughout early neural development, N-cadherin is expressed during the morphogenetic changes that occur when ectoderm, in response to neural induction, forms a neural plate and tube. To study the role of N-cadherin in these processes, cDNA clones encoding Xenopus laevis N-cadherin were isolated and used to study the expression of N-cadherin in frog embryos. These studies showed that N-cadherin RNA is not expressed at detectable levels in early cleavage embryos or in isolated ectoderm in the absence of neural induction. However, N-cadherin RNA rapidly appeared in ectoderm exposed to a heterologous neural inducer, indicating that N-cadherin expression, as an early response to induction, precedes the morphogenetic events associated with early neural development. The role of N-cadherin in these morphogenetic events was studied by ectopically expressing N-cadherin in the ectoderm of embryos prior to induction. The ectopic expression of this protein in ectoderm led to the formation of cell boundaries and to severe morphological defects. These results are consistent with the hypothesis that the morphogenetic changes associated with early neural development are controlled, in part, by the induced expression of N-cadherin in the neural plate.     

Characterization of polyribosomes containing newly synthesized messenger RNA in preimplantation rabbit embryos

Conjugating cells of Stylonychia mytilus incorporate RNA precursors into RNA between 5–6 h after pairing. If RNA synthesis is inhibited during this period by Actinomycin D, the developmental processes are arrested immediately. After 6 h of pairing there is no detectable synthesis of RNA while protein synthesis continues for at least the next 33 h and during this time the cellular events leading to the macronuclear development are insensitive towards the action of actinomycin D. Treatment of live conjugating pairs (older than 6 h) with RNase solution digests the RNA of these cells and causes an immediate and irreversible arrest in development. On the other hand, a similar treatment of the vegetative cells, which show RNA synthesis, does not produce any irreversible effect. It is concluded that stable mRNA molecules are synthesized by the conjugants between 5–6 h following the onset of pairing.     

Effects of cordycepin on macromolecular synthesis and development in the preimplantation mouse embryo

Investigations were conducted to test the effects of cordycepin, a naturally-occurring analog of adenosine, on gene activity in preimplantation mouse embryos. Embryos were explanted into culture at the 2-cell, morula and blastocyst stages, and incubated in the absence or presence of cordycepin (5–100 μg/ml) to determine the effects of the drug on continued development and macromolecular synthesis. Cordycepin at concentrations exceeding 10 μg/ml caused a dose-responsive inhibition of cleavage and blastulation of embryos in culture. Exposure of morulae and blastocysts to cordycepin concentrations of 10–100 μg/ml produced a dose- and time-dependent suppression of RNA synthesis as measured by incorporation of [³H]uridine. Suppression in blastocyst-stage embryos was enhanced by preincubation, and reached 70% after 4 h at 100 μg/ml. Cordycepin (50–100 μg/ml) reduced synthesis of major RNA components detected by electrophoresis, blocked incorporation of radioactivity into fractions bound by olido(dT)-cellulose, and produced a time- and dose-dependent reduction of protein synthesis in blastocysts, causing a maximum inhibition of 25% after 4 h of preincubation at 50 μg/ml.     

THE SELECTIVE INTERRUPTION OF NUCLEOLAR RNA SYNTHESIS IN HELA CELLS BY CORDYCEPIN

Cordycepin is an analogue of adenosine lacking the 3'-OH. When incorporated into a growing RNA molecule, cordycepin prevents further elongation, thus producing a prematurely terminated RNA molecule. When HeLa cells are exposed to low concentrations of cordycepin, DNA and protein synthesis are unaffected during short exposure periods. The synthesis of completed ribosomal and ribosomal-precursor (45S) RNA is significantly depressed. Partially completed 45S ribosomal precursor molecules accumulate in the nucleolus. 18S ribosomal RNA can be cleaved from these incomplete precursors, while 32S ribosomal precursor cannot be produced from partially snythesized 45S molecules. The synthesis of transfer RNA is also reduced in the presence of cordycepin. The synthesis of the nuclear heterogeneous RNA species is unaffected by the drug while the cytoplasmic heterogeneous RNA is slightly reduced.     

Histones and histone synthesis in sea urchin development

Histones are synthesized and become a part of the chromatin as early as the first cleavage in sea urchins. Reproducible changes in relative amounts of individual histone fractions synthesized are observed during development. A new and electrophoretically distinct very lysine rich fraction appears at hatching in Arbacia and in the early gastrula of Lytechinus. When RNA synthesis is blocked by actinomycin D, maternal mRNA alone can direct a quantitatively and qualitatively changing pattern of histone synthesis as cleavage proceeds. Inhibition of DNA synthesis by hydroxyurea reduces synthesis of histones; the arginine-rich histones are more severely affected than the lysine-rich ones.     

Polar lobe specific regulation of translation in embryos of Ilyanassa obsoleta.

Comparisons of the patterns of synthesis of ¹⁴C-labeled proteins of normal embryos of Ilyanassa with the patterns of synthesis of ³H-labeled proteins of embryos from which the polar lobes had been removed at the trefoil stage were made by coelectrophoresis on polyacrylamide disc gels. Controls utilizing biochemical and morphological markers were performed to assure that normal and delobed embryos were developing at equivalent rates. The expression of significant differences in the patterns of protein synthesis were found between normal and delobed embryos, and these differences were not dependent upon concomitant RNA synthesis. These differences were observable as early as after only 24 hr of development, although organogenesis does not begin until much later in development. Therefore, the observed differences probably reflect determininative events. The results support the hypothesis that the developmental determinants of the polar lobe may include specific, preformed mRNA sequences, or specific regulators of translation.     

Embryonic staging series for the beach spawning, terrestrially incubating California grunion Leuresthes tenuiswith comparisons to other Atherinomorpha

California grunion Leuresthes tenuis synchronize spawning with tidal cycles, so the embryos incubate in a terrestrial environment, delay hatching until cued by a specific environmental trigger, and may extend incubation for up to an additional four weeks. These adaptations, however, do not appear to alter the morphology or sequence of early developmental stages as compared to other Atherinomorph fishes in the Orders Beloniformes and Cyprinodontiformes. Embryonic development is described in a series of 30 stages based on morphology observed by light microscopy. Stages are placed in five periods: zygote and cleavage, blastula, gastrula, segmentation and organogenesis, and hatching competence. Embryos from a southern population of L. tenuis in Los Angeles are compared with embryos found >560 km north in San Francisco Bay. Northern L. tenuis embryos developed more slowly at several stages than southern embryos and reached hatching competence later, but both locations maintained synchrony with the tidal cycle for both spawning and hatching. The variation in rates of development and stage at hatching readiness are forms of developmental heterochrony that may be associated with evolutionary adaptation or morphological plasticity within this highly successful clade.     

Development of preimplantation rabbit embryos in vivo and in vitro

Qualitative patterns of protein synthesis in preimplantation rabbit embryos grown in vivo and in vitro were examined by SDS polyacrylamide gel electrophoresis followed by autoradiography. The results demonstrate that (1) most qualitative changes in the pattern of protein synthesis occur during cleavage, (2) the blastocyst period of development is characterized by a remarkably uniform and constant pattern of protein synthesis, and (3) the qualitative pattern of protein synthesis in embryos cultured in vitro from the 1-cell to the blastocyst stage is essentially identical to the pattern of protein synthesis in embryos grown to a comparable stage in vivo.These results indicate that no “special” maternal factors, such as uterine proteins, are required in vitro either for the qualitative changes in the pattern of protein synthesis during cleavage, or for the initial expression of a pattern of protein synthesis characteristic of the entire blastocyst period. From these studies we conclude that, once fertilized, the rabbit egg proceeds through cleavage and blastocyst formation on its own endogenous developmental program.     

Nucleic Acid and Histone Synthesis by Ethanol-Treated Cleavage-Arrested Sea Urchin Embryos

Abstract. It has been found that fertilized sea urchin eggs prevented from normal cleavage by solutions of isosmotic ethanol in sea water are able to complete some cellular and molecular aspects of the normal developmental program that are observed in control cultures. In both treated and control cultures, the type of RNA transcribed changes at 24 h (early gastrula) in favor of higher molecular weight rRNA. Ultrastructural studies reveal the presence of nucleoli in ethanol-treated as well as control embryos. The type of H1 histone synthesized also shifts at 24 h in favor of a higher molecular weight H1 in both ethanol-treated and control embryos. Replication of DNA proceeds at a slower rate in ethanol-treated embryos than in controls, resulting in DNA/embryo values in ethanol which are 20–30% of control values after 24 h. The results relate to the problem of differentiation without cleavage, and the role of normal partitioning, cell-cell interaction, and DNA synthesis in triggering the sequence of events in the developmental program.     

The program of protein synthesis during the development of the micromere-primary mesenchyme cell line in the sea urchin embryo

Changes in the pattern of protein synthesis were analyzed during the in vitro development of the micromere-primary mesenchyme cell line of the sea urchin embryo. Micromeres were isolated and cultured from 16-cell stage embryos, and primary mesenchyme cells were isolated and cultured from early gastrulae. Both cell isolates developed normally in culture with about the same timing as their in situ counterparts in control embryos. Newly synthesized proteins were labeled with [³H]valine at several stages of development and were analyzed by two-dimensional polyacrylamide gel electrophoresis and fluorgraphy. The electrophoretic pattern of labeled proteins changed dramatically during development. More than half of the analyzed proteins underwent qualitative or quantitative changes in their relative rates of valine incorporation and these changes were highly specific to this cell line. Almost all of the changes were initiated prior to gastrulation and many prior to hatching. The highest frequency of changes in the micromere pattern of protein synthesis occurred between hatching and the start of gastrulation. This peak of activity coincided with the normal time of ingression of the primary mesenchyme and preceded the differentiation of spicules by more than 30 hr. Most of the observed changes were characterized as either decreases in the synthesis of proteins that showed maximum incorporation at the 16-cell stage or increases in the synthesis of proteins that showed maxima in the fully differentiated cells. Very few proteins exhibited transient synthetic maxima at intermediate stages. Thus, the program of protein synthesis associated with the development of micromeres consists largely of a switch in emphasis from early to late proteins, with the primary time of switching being between hatching and the onset of gastrulation.     

Changes in the synthesis and intracellular localization of nuclear proteins during embryogenesis in the sea urchin Strongylocentrotus purpuratus

A rapid, gentle technique is described for the isolation of nuclei from sea urchin embryos. Using this technique, we have analyzed the synthesis and accumulation of nonhistone nuclear proteins during sea urchin development by two-dimensional gel electrophoresis. Most nuclear proteins fall into one of three patterns of synthesis, which are distinguished by maximal rates of accumulation at early (prior to hatching blastula), middle (hatching blastula/gastrula), or late (prism/pluteus) stages of development. Over 60% of observed nuclear proteins undergo apparent qualitative changes in synthesis and accumulation between the 64-cell and pluteus stages. Most of these changes represent appearances of new proteins. A large number of qualitative changes occur very early in development; the period of greatest change is between the 64-cell and 200-cell stages. Over half of the proteins which first appear in the nucleus subsequent to the 64-cell stage are synthesized at stages prior to the time of their initial appearance in nuclei, but are excluded from nuclei for some time.     

Developmentally regulated proteolytic processing of a yolk glycoprotein complex in embryos of the sea urchin,Strongylocentrotus purpuratus

We have isolated a yolk glycoprotein complex from eggs and early embryos of the sea urchin, Strongylocentrotus purpuratus. Sodium dodecyl sulfate polyacrylamide gel electrophoresis of these complexes and peptide mapping of their individual glycoprotein components indicate that developmental stage-specific changes in molecular composition of the complex are due to proteolytic processing events. Our data revealed that a 180 kDa glycoprotein of the egg complex is separated by a single proteolytic cleavage into intermediate glycoproteins of 115 and 76 kDa early in development. By the hatched blastula stage, each of these intermediate glycoproteins has been further processed to lower molecular weight forms: the 115 kDa protein is proteolytically clipped to a 84 kDa form, perhaps through 110 and 105 kDa intermediaries, while the 76 kDa molecule is directly processed to a 65 kDa form.     

Cytochemical studies on the protamine-type protein transition in sperm nuclei after fertilization and the early embryonic histones of Urechis caupo.

Cytochemical staining characteristics of nuclear histones during postfertilization maturation division and various early embryonic stages in Urechis have been studied. The transition of protamine-type protein to adult histones in the sperm nucleus is accomplished by 15 min after entrance into the egg cytoplasm. Newly synthesized egg proteins migrate into enlarging male and female pronuclei after this transition, followed by pronuclear DNA synthesis and fusion. The shift from protamine-type protein to adult histones, which occurs in the absence of RNA synthesis during the postfertilization maturation division of the egg, may be one of the processes involved in the normal structural reorganization of chromosomes. Such a reorganization is likely to be a prerequisite for chromosome replication and mitosis. No qualitative differences are detected in the stainability of histones of unfertilized eggs and embryos at the cleavage and later stages of development.     

The antioxidant epigallocatechin gallate (EGCG) moderates the deleterious effects of maternal hyperthermia on follicle-enclosed oocytes in mice

Hyperthermia-induced oxidative stress is one of the mechanisms suggested to underlie loss of developmental competence in mouse embryos. In this study, we examined whether pretreatment with the antioxidant epigallocatechin gallate (EGCG) can alleviate the negative effects of hyperthermia on developmental competence of the ovarian pool of oocytes and improve embryonic development. Female mice (CB6F1) were synchronized (eCG+hCG) and injected with 0.4ml EGCG (100mg/kg body weight) or with saline. Both EGCG- and saline-treated mice were exposed to heat stress (HS; 40 degrees C, 65% RH) or kept under normothermal conditions (Control; 22 degrees C, 45% RH). In vivo-derived zygotes were recovered 20h after hCG administration and cultured in vitro. Maternal hyperthermia attenuated embryonic cleavage rate in association with further disruption in embryonic early cleavage and subsequently, with embryonic development. While pretreatment with EGCG did not affect the proportion of zygotes that cleaved to the two-cell stage, it appeared to moderate the effect of hyperthermia on both cleavage timing and developmental rate, as reflected by an increased rate of early cleaved embryos and blastocyst formation. Blastocyst developmental competence was also improved, as indicated by the increased total cell number and percentage of embryos that underwent hatching, in association with reduced apoptotic status, as reflected by the percentage of TUNEL-positive cells and intensity of caspase activity for the HS-EGCG embryos vs. HS-saline ones. In summary, while hyperthermia disrupts the competence of the follicle-enclosed oocyte, in vivo administration of the antioxidant EGCG improves developmental competence and the quality of the embryos that develop from these oocytes.     

Proteinbiosynthesen in dormanten und nachgereiften embryonen und samen von Agrostemma githago

Seed germination of Agrostemma githago is prevented by inhibitors of protein and RNA synthesis. Thus protein as well as RNA synthesis are essential prerequisites for germination. Early protein synthesis of Agrostemnia embryos can be completely inhibited by cycloheximide and cordycepin. During the aging of seeds there is a considerable decrease in germination capacity and protein synthesis. In dormant and afterripened embryos of Agrostemma githago¹⁴C-leucine and ¹⁴C-uracil are incorporated in protein and RNA respectively with nearly the same intensity, whereas RNA and protein synthesis of dormant seeds and embryos starts earlier than in those subjected to afterripening. ³H-uracil-labelled RNA from dormant and afterripened embryos are able to hybridize on oligo-dT-cellulose to the same extent. There is a similarity in the protein pattern of dormant and afterripened embryos revealed by electrophoresis in polyacrylamide gels of double-labelled proteins. According to these results dormancy of Agrostemma githago is not caused by a general but by a specific metabolic block.