A comparison of protein synthetic patterns in normal and animalized sea urchin embryos

Newly synthesized proteins from normal and animalized sea urchin embryos were compared by the technique of double labeling. Total embryonic protein was solubilized in SDS, urea, and 2-mercaptoethanol. The proteins were examined by coelectrophoresis on an SDS-polyacrylamide gel. The gels were sliced and the radioactivity determined. A standardized ratio of the isotopes served as the basis of comparison. A comparison of newly synthesized proteins from normal embryos 24 and 48 h old showed a shift from larger to smaller molecular weight proteins. Animalized embryos showed a similar shift. When normal and animalized embryos of the same ages were compared, differences were found. The differences were distributed over the entire range of molecular weights. These results show that although differences in protein synthesis between animalized and normal embryos are evident by 24 h, most of the changes in protein synthesis that occur in normal embryos are unaffected by animalization.     

A factor in sea urchin eggs inhibits transcription in isolated nuclei by sea urchin RNA polymerase III

Isolated nuclei from sea urchin embryos synthesize RNA at a rate comparable to other animal cell nuclei. All three RNA polymerases are active as judged by alpha-amanitin sensitivity and hybridization to specific cloned DNAs. Extracts were prepared from sea urchin eggs and embryos by extraction with 0.35 M KCl. None of the crude extracts had a large effect on total RNA synthesis. However, extracts from sea urchin eggs inhibited RNA polymerase III activity in nuclei from blastula and gastrula embryos. There was no effect on the synthesis of ribosomal RNA by RNA polymerase I or on the synthesis of two RNA polymerase II products, histone mRNA and the sea urchin analogue of U1 RNA. The inhibitor is present in two different species of sea urchin and has been 50-fold purified by diethylaminoethylcellulose and hydroxylapatite chromatography. The inhibitor is not present in extracts prepared from sea urchin blastula embryos.     

Inhibition of translation and modification of translation factors during apoptosis induced by the DNA-damaging agent MMS in sea urchin embryos

Translational control was investigated in sea urchin eggs and embryos in response to the DNA-damaging agent methyl methanesulfonate (MMS). We have shown in this report that exposure of sea urchin embryos to MMS induces drastic effects on protein synthesis activity, and on translation factors level, integrity and post-translational modifications. In response to the treatment of embryos by the DNA-damaging agent MMS, protein synthesis is inhibited independently of the translation inhibitor 4E-BP and in correlation with phosphorylation of the translation factor eIF2alpha subunit. Furthermore, a low molecular weight form of translation initiation factor eIF4G is detected correlatively with MMS-induced apoptosis. We propose that modifications of translation factors play an important role in protein synthesis modulation that occurs during DNA-damage induced apoptosis.     

Biogenesis of the mitochondrial ATPase from sea urchin embryos

The mitochondrial rutamycin-sensitive ATPase from sea urchin eggs was purified to homogeneity. The subunit structure of the enzyme was characterized by SDS-gel electrophoresis. Eight polypeptides were identified with molecular weights of 55,000, 52,000, 39,000, 31,000, 28,000, 23,000, 17,000 and 10,000. Developing sea urchin embryos were incubated with [2H]leucine in the presence of emetine preferentially to label mitochondrially made proteins. Under these conditions sea urchin mitochondria synthesize eight different polypeptides. Two of these proteins, with molecular weights of 31,000 and 23,000, co-purify with the ATPase. Antibody directed against the pure rutamycin-sensitive ATPase precipitated only these two proteins. Therefore, two of the eight sea urchin ATPase subunits appear to be made by mitochondria.     

Characterization of bep1 and bep4 antigens involved in cell interactions during Paracentrotus lividus development

We have identified and partially characterised two antigens, extracted with 3% butanol, from Paracentrotus lividus embryos dissociated at the blastula stage, and encoded by the cDNA clones previously described as bep1 and bep4 (bep-butanol extracted proteins). The cDNA fragments containing the specific central portions of bep1 and bep4 were expressed as MS2 polymerase fusion proteins in Escherichia coli. These two fusion proteins, called 1C1 (bep1) and 4A1 (bep4), were injected subcutaneously into rabbits and the corresponding polyclonal antibodies generated. Western blot analysis of proteins, extracted with 3% butanol, from sea urchin embryos at the blastula stage (b.e.p.), established that both antibodies recognize two 33 KDa proteins. Reducing and non-reducing electrophoretic conditions show that both antibodies against bep1 and bep4 related proteins react also with a protein band of a molecular weight 66 KDa, indicating that these two antigens probably exist as dimers. Immunolocalization with anti 1C1 and 4A1 antibodies shows the presence of the related antigens also on the cell surface. Fab fragments of the polyclonal antibodies against 1C1 and 4A1 inhibited reaggregation of sea urchin embryonic cells, dissociated from blastula stage embryos. This prevention of reaggregation indicates that these proteins probably play a role in cell interaction during sea urchin embryonic development.     

Soluble microtubule proteins of the sea urchin embryo: partial characterization of the proteins and behavior of the pool in early development

A partial characterization of the soluble microtubule proteins of sea urchin eggs and embryos is presented. Vinblastine precipitation yielded a pellet with a high colchicine binding activity. This precipitate when electrophoresed on an alkaline SDS/urea gel system yields two protein bands which correspond to molecular weights of 57,000 ± 2000 and 52,000 ± 2000. These values are very close to our values and to the published values for axonemal microtubule proteins. Electrophoresis of the vinblastine precipitated proteins on a neutral SDS system without urea yielded only one band with an apparent molecular weight of 52,000 ± 2000. The amino acid composition of the vinblastine-precipitated microtubule protein was determined to be similar to that of axonemal protein.The pool of microtubule proteins was found to remain constant in size throughout early development in both control and actinomycin-treated embryos. Soluble microtubule proteins comprise about 0.37% of the total protein of the sea urchin (Arbacia) egg. Approximately 20% of the total microtubule protein in the egg appears to be particle bound.     

Micromere Differentiation in the Sea Urchin Embryo: Two-Dimensional Gel Electrophoretic Analysis of Newly Synthesized Proteins

A method for large-scale culture of isolated blastomeres of sea urchin embryos in spinner flasks was developed. Micromeres and meso-, macromeres isolated from sea urchin embryos at the 16-cell stage were cultured by this method and the patterns of protein synthesis by their descendants were examined by two-dimensional gel electrophoresis of [³⁵S] methionine-labeled proteins. Six distinct proteins with molecular weights of 140–kDa, 105–kDa, 43–kDa, 32–kDa, and 28–kDa (two components) were specifically synthesized by differentiating micromeres. Quantitative analysis of the two-dimensional gel patterns demonstrated that all these proteins, except the 32–kDa protein, appeared at the time of ingression of primary mesenchyme cells (PMC's) in vivo , several hours earlier than the onset of spicule formation. The synthesis of 32–kDa protein was paralleled to active spicule formation and the uptake of Ca²⁺. Cell-free translation products directed by poly (A)⁺ RNAs isolated from descendant cells of micromeres and meso-, macromeres were compared by two-dimensional gel electrophoresis. Several spots specific to the micromere lineage were detected. However, none of them comigrated with the proteins synthesized specifically by the cultured micromeres. The results suggest that the expression of these proteins specific to differentiating micromeres may involve post-translational modification.     

The biochemical identification of fibronectin in the sea urchin embryo

We report the biochemical identification of fibronectin in the basal lamina of the sea urchin embryo. A. punctulata gastrula stage embryos were solubilized in Triton X-100 and the insoluble basal laminae extracted by incubation in buffer containing 8M urea, 2% 2-mercaptoethanol and 2% SDS. Extracted proteins were separated by SDS-PAGE, electrophoretically transferred to nitrocellulose filters and probed with monospecific antibodies directed against human plasma fibronectin (pFN). Incubation in 125I-labelled secondary antibody revealed a single band which co-migrates with human pFN at an apparent molecular weight of 220,000. This is the first direct biochemical demonstration of a fibronectin-like molecule in the sea urchin embryo which cross reacts with antibodies to vertebrate fibronectin.     

Cost of protein synthesis and energy allocation during development of antarctic sea urchin embryos and larvae

Cold environments represent a substantial volume of the biosphere. To study developmental physiology in subzero seawater temperatures typically found in the Southern Ocean, rates and costs of protein synthesis were measured in embryos and larvae of Sterechinus neumayeri, the Antarctic sea urchin. Our analysis of the "cost of living" in extreme cold for this species shows (1) that cost of protein synthesis is strikingly low during development, at 0.41 +/- 0.05 J (mg protein synthesized)(-1) (n = 16); (2) that synthesis cost is fixed and independent of synthesis rate; and (3) that a low synthesis cost permits high rates of protein turnover at -1 degrees C, at rates comparable to those of temperate species of sea urchin embryos developing at 15 degrees C. With a low synthesis cost, even at the highest synthesis rates measured (gastrulae), the proportion of total metabolism accounted for by protein synthesis in the Antarctic sea urchin was 54%-a value similar to that of temperate sea urchin embryos. In the Antarctic sea urchin, up to 87% of metabolic rate can be accounted for by the combined energy costs of protein synthesis and the sodium pump. We conclude that, in Antarctic sea urchin embryos, high rates of protein synthesis can be supported in extreme-cold environments while still maintaining low rates of respiration.     

SELECTIVE INHIBITION BY APHIDICOLIN OF THE ACTIVITY OF DNA POLYMERASE ALPHA LEADS TO BLOCKADE OF DNA SYNTHESIS AND CELL DIVISION IN SEA URCHIN EMBRYOS

Aphidicolin at 2 μg/ml caused 90% inhibition of mitotic cell division of sea urchin embryos at the I-cell stage. However, at 40 μg/ml it did not affect meiotic maturational divisions of starfish oocytes, which do not involve DNA replication. At 2 μg/ml it caused 90% inhibition of incorporation of tritiated thymidine into DNA of sea urchin embryos but did not affect protein or RNA synthesis even at a higher concentration. At 2 μg/ml it also caused 90% inhibition of the activity of DNA polymerase α, obtained from the nuclear fraction of sea urchin embryos, but did not affect the activity of DNA polymerase β or γ. These findings suggest that DNA polymerase α is responsible for replication of DNA in sea urchin embryos.     

Effect of reduced protein synthesis on the cell cycle in sea urchin embryos

We have reinvestigated the existence of cyclical fluctuations of protein synthesis and have examined the effects of reducing it in early embryos of the purple sea urchin, Strongylocentrotus purpuratus. The results show that protein synthesis increases linearly during the first 45-60 minutes after fertilization, then transiently decreases during mitosis, and rises again at first cleavage. Reducing protein synthesis of embryos to 35% its normal value only slightly affects the rate of progression through the cell cycle. It is also shown that the observed retardations of the cell cycle, under depressed protein synthesis, are attributable (by 80%) to a lengthening of the premitotic phase but also, to a lesser extent (20%), to a lengthening of the mitotic phase itself. These results suggest that mitotic proteins, in sea urchin embryos, are stable and little affected by an imposed decrease of protein synthesis during their accumulation phase. This analysis supports the view that specific mechanisms, other than decreased protein synthesis, need be turned on only at appropriate times during the cell cycle in order to explain the destruction or deactivation of mitotic proteins. Finally, a one-dimensional SDS-PAGE analysis of synthesized proteins, labeled with 35S-methionine, reveals the presence of a 50-kDa cyclin showing the expected characteristics of mitotic proteins deduced from our results.     

Re-examination of histone changes during development of newt embryos

Embryos of Triturus pyrrhogaster (BOIE) were labeled with Na₂¹⁴CO₃ and the incorporation of radioactivity into histone fractions was determined by the electrophoresis of the acid-soluble protein from isolated nuclei on a polyacrylamide gel with or without Triton X-100. The results supported the previous observation that the content of H1 histone might be low in blastulas and increased during development but they did not confirm the displacement of blastula H1 by other H1 molecular species in later embryos. The rate of H2b or H2a histone synthesis did not change much during development which contrasted sharply with the case of histone synthesis in sea urchin embryos. By changing the label duration or by culturing various durations after the label it was suggested that the histone fractions were synthesized or degraded as a set and any particular fraction that had a markedly long or short life could not be detected. The results were discussed in relation to the possible functions of H1 histone and to the histone synthesis in sea urchin embryos.     

Nucleic acid and histone synthesis by ethanol-treated cleavage-arrested sea urchin embryos

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.     

Immunohistochemical localization of a tenascin-like extracellular matrix protein in sea urchin embryos

Summary We have used polyclonal antisera raised against vertebrate tenascin to identify and localize tenascin-like proteins in the developing sea urchin. These antisera recognize high-molecular weight proteins on immunoblots of sea urchin embryo homogenates that are similar in size and appearance to tenascin from vertebrates. These proteins appear as a doublet with an apparent molecular weight of 150 kDa and a larger, broad band with an apparent molecular weight of 350 kDa. Whole mounts of sea urchin embryos and larvae were stained with one of these antisera. The anti-tenascin stained the surface of primary mesenchyme cells during their phase of active migration. This staining was sensitive to detergent, suggesting that the protein recognized by the antiserum was associated with the cell surface. During later stages of development, the bulk of the antitenascin staining was found dispersed throughout the blastocoel matrix, and was no longer sensitive to detergent. We conclude that sea urchins express tenascin-like proteins during early stages of development, and that these proteins may play a role associated with primary mesenchyme cell morphogenesis.     

Surface biochemical changes accompanying primary infection with Rous sarcoma virus. I. Electrokinetic properties of cells and cell surface glycoprotein:glycosyl transferase activities

A special class of polysomes synthesizing tubulin was determined using embryos of the sea urchin, Hemicentrotus pulcherrimus. Three criteria were established for identification of polysomes carrying nascent tubulin, i.e., nascent tubulin on polysomes should have (i) colchicine binding activity, (ii) precipitability with vinblastine and (iii) coincidence in mobility by electrophoresis with tubulin. Two classes of polysomes had polypeptides which accorded with the three criteria. One was tetramers and the other was composed of 15–20 ribosomes. From data reported previously on the molecular weight and amino acid composition of completed microtubule proteins, it was suggested that the class of polysomes composed of 15–20 ribosomes constituted the polysome-synthesizing tubulin of sea urchin embryos. The nature of the nascent polypeptides carried by the tetramer polysomes having colchicine binding activity and precipitability with vinblastine could not be clarified.     

Cyclin: A protein specified by maternal mRNA in sea urchin eggs that is destroyed at each cleavage division

Cleavage in embryos of the sea urchin Arbacia punctulata consists of eight very rapid divisions that require continual protein synthesis to sustain them. This synthesis is programmed by stored maternal mRNAs, which code for three or four particularly abundant proteins whose synthesis is barely if at all detectable in the unfertilized egg. One of these proteins is destroyed every time the cells divide. Eggs of the sea urchin Lytechinus pictus and oocytes of the surf clam Spisula solidissima also contain proteins that only start to be made after fertilization and are destroyed at certain points in the cell division cycle. We propose to call these proteins the cyclins.     

Degradation of yolk proteins in sea urchin eggs and embryos

Yolk granules isolated from unfertilized and fertilized eggs of the sea urchins, Hemicentrotus pulcherrimus and Anthocidaris crassispina, were incubated in acidic media, and the protein components were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. By the incubation, a protein (molecular weight 180,000 in H. pulcherrimus and 178,000 in A. crassispina) most abundant in unfertilized eggs decreased, while proteins (molecular weight 61,000, 72,000, 94,000, 114,000 in H. pulcherrimus and 56,000, 70,000, 92,000, 112,000 in A. crassispina) dominant in developed embryos increased. Neither alkaline nor neutral condition resulted in such changes in the electrophoretic patterns of proteins as observed in acidic media. Experiments with various inhibitors of proteases suggested that thiol protease(s), such as cathepsin B, may be the most important enzyme(s) in the degradation of yolk proteins in embryogenesis of the sea urchin.     

The Effects of Chemical Animalizing and Vegetalizing Agents and of Cell Dissociation on the Synthesis of 5S RNA and Transfer RNA in Cleaving Sea Urchin Embryos

The effect of altering normal cell associations and interactions on the synthesis of 5S RNA and transfer RNA (tRNA) was studied in cleaving embryos of the sea urchin, Arbacia punctulata. Cell interactions were altered: (1) by culturing cleaving embryos in the animalizing agent, Evans Blue, and in the vegetalizing agent, Li⁺ as LiCl and (2) by culturing dissociated cells. Control and experimental embryos each were labeled from 3 h to 6 h post fertilization with [8-³H]-guanosine. Sixteen-cell embryos, whose GTP precursor pools had been preloaded, were dissociated, labeled and cultured under conditions which prevent reaggregation. Quantitative measurements of rates of accumulation of newly synthesized 5S RNA and tRNA showed that these rates are similar in cleaving sea urchin embryos and in corresponding embryos cultured in the presence of Evans Blue and of Li⁺. In addition, cells dissociated from cleavage embryos and maintained under conditions which prevent reaggregation retained the ability to synthesize 5S RNA and tRNA. These results suggest that normal cell associations and interactions are not necessary for the synthesis of 5S RNA and tRNA to occur in cleaving sea urchin embryos.     

MOLECULAR PROPERTIES AND DIFFERENTIATION OF ACETYLCHOLINESTERASE IN SEA URCHIN EMBRYOS*

The two molecular forms of acethylcholinesterase (EC 3.1.1.7) in sea urchin embryos were characterized by several physical methods. The sedimentation coefficients determined by sucrose gradient centrifugation are 7.6S and 10.6S. The Stokes radii determined by gel filtration are 65 Å and 91 Å. From these parameters, molecular weights were estimated as 190,000 and 380,000; the one is twice as large as the other. Both forms have similar electric property and buoyant density in a CsCl gradient. When the enzyme solution was concentrated, the 10.6S form became predominant. These results suggest that the two forms are monomer and dimer. The sea urchin enzymes resemble globular forms of acetylcholinesterase of the electric organ of fishes. The activity of the enzyme abruptly increases in post-gastrulation embryos. Inhibition of concomitant protein synthesis by a specific inhibitor, emetine, does not affect the increase in enzyme activity. The result suggests that post-translational processes may be involved in the differentiation of this enzyme in sea urchin development. The following sea urchins were used in the study: Strongylocentrotus purpuratus, Strongylocentrotus franciscanus, and Dendraster excentricus.     

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.