VEGETALIZATION OF SEA URCHIN LARVAE INDUCED WITH cAMP PHOSPHODIESTERASE INHIBITORS

Treatment of sea urchin embryos with cAMP phosphodiesterase (PDE)-inhibitors such as caffeine (4×10⁻³ M), theophylline (8×10⁻³M), or nicotinamide (10⁻²M), at the morula stage for only a couple of hours, yields vegetalized larvae. Most of the embryos treated with these reagents before the morula stage develop to blastulae filled with mcsenchyme-like cells. Almost all embryos at the blastula stage develop normally even if they are treated with a PDE-inhibitor for a considerable period. The rate of ³H-valine incorporation into protein in the morulae is reduced by caffeine and theophylline, but does not decrease in the presence of nicotinamide. Actinomycin D cancels the vegetalizing effect of PDE-inhibitors on the morulae.     

CANCELING EFFECT OF 2, 4-DINITROPHENOL ON THE VEGETALIZATION OF SEA URCHIN LARVAE INDUCED WITH CAFFEINE*

The treatment of the sea urchin morulae with both caffeine and 2, 4-dinitrophenol (DNP) for a couple of hours exerts no harmful effect on the development of sea urchin, whereas the tretment with caffeine alone yields vegetalized larvae. As long as the morulae are kept in the pressence of DNP alone, further development or the embryos is arrested, but the treated embryos develop normally after they are transferred into plain sea water. Hence, DNP is supposed to cancel vegetalizing effect of caffeine on the sea urchin morulae. When the embryos were kept in sea water containing respective radioactive precursors of macromolecules and caffeine, the radioactivity in the DNA fraction is slightly higher and those in the RNA and protein fraction are slightly lower than those of control ones (without the caffeine treatment). In the presence of DNP, the radioactivity in these macromolecules is very low in the caffeine-treated embroyos as well as in the control.     

Vegetalization of Sea Urchin Larvae Induced with Cycloheximide

The embryos, kept at 20°C for 3 hr–6 hr from the time of fertilization (at the morula stage), were cultured in sea water containing cycloheximide (10–16 mM) for successive 3 hr and then transferred to normal sea water. The embryos, thus treated, became vegetalized larvae. With the same treatment performed at a developmental stage prior to 3 hr of fertilization, most of embryos developed to small blastulae filled with mesenchyme-like cells. The treatment at a stage after 6 hr of fertilization yielded normal plutei. From the embryos exposed to both ¹⁴C-leucine and ³H-thymidine during the treatment, labelled chromatin was isolated. Only in the presumptive vegetalized embryos obtained by the cycloheximide treatment of morulae, ratio of ¹⁴C-radioactivity found in proteins of chromatin to ³H-radioactivity in DNA was markedly lower than that observed in chromatin from control embryos. The rate of ³H-radioactivity-decrease by DNase I treatment was higher in chromatin isolated from the presumptive regetalized embryos than that observed in chromatin isolated from control ones. Probable failure of chromatin structure formation, due to cycloheximide-inhibition of chromatin protein synthesis, seems to disturb the determination in the embryos at the morula stage, resulting in an induction of vegetalized embryos.     

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.     

Development of Sea Urchin Embryos in Artificial Sea Water Containing Br−in Place of Cl−

In artificial sea water in which the Cl⁻concentration was reduced to less than 10% of that in normal sea water by its replacement with Br⁻, sea urchin eggs were fertilized and developed into abnormal plutei following almost the same time schedule as in natural sea water. These embryos had poorly developed spicules, short pluteus arms, somewhat jagged embryo-walls and quasi-normal archenterons. Similar embryos were obtained in another artificial sea water in which 90% of the Cl⁻concentration in normal sea water was reduced by Br⁻and 10% by acetate. In artificial sea water, in which either 90% of the Cl⁻was replaced by Br⁻or 10% was replaced by acetate, embryos developed into plutei with quasi-normal spicules, pluteus arms and archenterons. These findings indicate that deficiency of Cl⁻results in somewhat abnormal sea urchin embryos. When cells derived from isolated micromeres, were cultured in these Cl⁻-deficient artificial sea waters, containing Br⁻in place of more than 70% of the normal Cl⁻concentration in sea water, spicule formation was strongly inhibited, but pseudopodial cables were well developed. Thus, external Cl⁻seems to be necessary for at least normal formation of spicule rods.     

ADP-Ribosylation of Histones in Nuclei Isolated from Embryos of the Sea Urchin, Hemicentrotus pulcherrimus

Two-dimensional electrophoresis (2D-PAGE) of a histone fraction isolated from nuclei of embryos of the sea urchin Hemicentrotus pulcherrimus exhibited almost all histone species at all stages examined. At the gastrula stage, a spot of H1A became evident and three spots closely associated with one another were found in place of a single spot of H2A.1. In the histone fraction isolated from [adenylate-³²P] NAD⁺-treated nuclei of all stages examined, autoradiograms of 2D-PAGE exhibited spots of mono [ADP-ribosyl] ated H1 and polymodified H2B.2, H3.1, H3.3 and H4 but did not show ADP-ribosylated H2A.1, H2A.2 or H2B.1. Poly [ADP-ribosyl] ated H3.2, found in morulae, was not detectable in blastulae and gastrulae. Treatment with dimethylsulfate, known to activate ADP-ribosylation in other cell types, induced poly [ADP-ribosyl] ation of H2A.2 and H2B.1 in embryos at all stages examined, and also polymodification of H3.2 in gastrulae. ADP-ribosylation of H1, H2B.2, H3.1 and H3.3 was hardly affected by dimethylsulfate treatment, though modification of H4 was blocked by this treatment. Probably, strong regulation of ADP-ribosyltransferase reactions causes failures of modification of H2A.2 and H2B.1 throughout early development and also of H3.2 at the gastrula stage. Regulation of histone ADP-ribosylation is thought to alter chromatin structures and the rate of gene expression, contributing to cell differentiation.     

Sea urchin sperm DNP. I. Chemical composition and template properties of DNP

Electrophoretic mobility, amino acid composition and salt dissociation of histones isolated from sperm of sea urchin Strongylocentrotus intermedius and calf thymus cells were studied. The special arginine-rich histone fraction (I) has been observed in sea urchin sperm chromatin, this fraction being absent in calf thymus chromatin. Dissociation of lysine-containing histone fractions from sea urchin chromatin occured in the range of 0.7 to 1.0 M NaCl concentrations. H1 of calf thymus chromatin was totally extracted with 0.6 M NaCl. In the course of a further increase of salt concentrations (up to 1.5 M NaCl) a practically total extraction of histones from sperm chromatin was observed, while about 20% of proteins remained bound to DNA in thymus chromatin after extraction with 2.0 M NaCl. The template activity of non-extracted DNP preparations from urchin sperm was equal to 2-3% of that of totally deproteinized DNA. The template activity of DNP gradually increased at protein extraction from DNP preparations. The hybridization capacity of RNA transcribed on partially dehistonized DNP templates in vitro also increased.     

MORPHOGENETIC SUBSTANCES FOUND IN THE EMBRYOS OF SEA URCHIN, WITH SPECIAL REFERENCE TO THE ANTI-VEGETALIZING SUBSTANCE

When sea urchin embryos up to the 2-cell stage are treated with 5 × 10⁻³ M chloramphenicol for a short period, small blastulae filled with mesenchyme-like cells (type A) are formed. If a homogenate of the embryos up to the 2-cell stage is introduced just after the chloramphenicol treatment, almost all embryos developed to normal plutei. Chloramphenicol treatment, started at the 8 ∽ 32-cell stages, induces vegetalized larvae (type B), and presumptive vegetalized ones develop normally after treatment with a homogenate of the embryos at the 16 ∽ 64-cell stages. If embryos are treated in the same manner at 7 hr after insemination, abnormal embryos which seem to be bipolar ones (type C) are observed at 40 hr after the treatment. These also develop normally, if a homogenate of embryos at the stages from unfertilized egg to gastrula is added to them at the end of the chloramphenicol treatment. The substances having these activities are named morphogenetic substances α, β and γ, respectively. The morphogenetic substance β (anti-vegetalizing substance) is heat stable and its molecular weight is less than 10,000.     

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.     

Relationship between nuclear DNA synthesis and centrosome reproduction in sea urchin eggs

The importance of nuclear DNA synthesis for the doubling, or reproduction, of centrosomes in cells that are not growth-limited, such as sea urchin eggs, has not been clearly defined. Studies of enucleated, fertilized eggs show that nuclear activities are not required at each cell cycle for the normal reproduction of the complete centrosome. However, other studies report that the inhibition of nuclear DNA synthesis in intact eggs by the drug aphidicolin prevents centrosome reproduction and entry into mitosis as seen by nuclear envelope breakdown. To resolve this paradox, we systematically characterized the effect of aphidicolin on cell division in eggs from three species of sea urchins. Eggs were continuously treated with 5 or 10 micrograms/ml aphidicolin starting 5 min after fertilization. This blocked total incorporation of 3H-thymidine into DNA by at least 90%, as previously reported. We found that the sperm aster always doubles prior to first mitosis. Over a period of several hours, the centrosomes reproduce in the normal 2-4-8-16 fashion, with a period that is longer and more variable than normal. In every culture, a variable percentage of the eggs undergoes nuclear envelope breakdown. Once broken down, the nuclear envelope never visibly reforms even though centrosomes continue to double. Fluorescent labeling of DNA revealed that the chromatin does not condense into discrete chromosomes. Whether or not the nuclear envelope breaks down, the chromatin appears as an amorphous mass of fibers stretched between first two and then four asters. Later, the nuclear envelope/chromatin loses its association with some or all centrosomes. Our results were the same for all eggs at both drug concentrations. Thus, nuclear DNA synthesis is not required for centrosome reproduction in sea urchin eggs.     

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.     

Nucleosomal structure of sea urchin and starfish sperm chromatin. Histone H2B is possibly involved in determining the length of linker DNA.

Comparison has been made between sea urchin and starfish sperm chromatin. The only protein by which chromatins from these sources differ significantly is histone H2B. Sea urchin sperm H2B is known to contain an elongated N-terminal region enriched in Arg. Analysis of the micrococcal nuclease digests of sea urchin and starfish nuclei in one- and two-dimensional electrophoresis has shown that sperm chromatin of both animals consists of repeated units similar in general features to those of rat thymus or liver. However, DNA repeat length in chromatin of sea urchin sperm (237 bp) is higher than that of starfish sperm (224 bp), while the core DNA length does not differ and is the same as in the chromatin of rat liver or thymus. A suggestion has been made that the N-terminal region of histone H2B is associated with the linker DNA and is responsible for the increased length of sea urchin linker DNA.     

Novel form of DNA polymerase alpha associated with DNA primase activity of vertebrates. Detection with mouse stimulating factor

With a specific stimulating factor of mouse DNA replicase for its detection, a novel form of DNA polymerase alpha (DNA replicase) associated with DNA primase activity was partially purified from several vertebrates, i.e. the cherry salmon Oncorhyncus masou, the frog Xenopus laevis, the chick, and human (HeLa cells). Activity similar to DNA replicase was also partially purified from embryos of the sea urchin Anthocidaris crassispina. In all vertebrates examined, two forms of DNA polymerase alpha were separated by chromatography on ion-exchange columns; one form (DNA replicase) was associated with DNA primase activity and could utilize unprimed single-stranded DNAs as template, and the other could not utilize unprimed single-stranded DNAs. The sedimentation coefficient of the former, the novel form, obtained from each vertebrate in a glycerol gradient at high ionic strength was slightly larger than that of the other form which had no primase activity, except in the case of chick embryos where the sedimentation coefficients of the two forms were almost the same. The initiator RNA synthesized with the DNA primase activity associated with DNA replicase obtained from salmon, chick, HeLa cells, and sea urchin was 8 to 10 nucleotides long. The stimulating factor obtained from Ehrlich ascites cells has been found to stimulate both the activities of DNA primase and DNA polymerase in DNA replicase obtained from all the vertebrates examined, when unprimed single-stranded DNA was used as template, while the factor failed to stimulate both the activities of the enzyme of sea urchin embryos. This factor thus should be an effective tool in studies on the mechanism of vertebrate DNA replication.     

Isolation and characterization of developmentally regulated sea urchin U2 snRNA genes

Genes encoding the U2 snRNA have been isolated from the sea urchins, Strongylocentrotus purpuratus and Lytechinus variegatus. Representatives of tandemly repeated gene sets have been isolated from both sea urchin species and a unique U2 gene has also been isolated from L. variegatus. The sequence of the U2 snRNA encoded by the tandemly repeated genes differs in two nucleotides between S. purpuratus and L. variegatus. The unique U2 gene from L. variegatus encodes the same U2 RNA as the tandemly repeated genes. There is a change in the U2 genes expressed between morula and pluteus embryos as judged by a change in the U2 RNA sequence in S. purpuratus embryos. The tandemly repeated genes were expressed at a higher rate in blastula than in gastrula stage relative to the single-copy gene, when the two genes were injected into sea urchin zygotes.     

THE ORIGIN OF ECHINOID HATCHING ENZYME MESSENGER RNA*

To determine if echinoid hatching enzyme messenger RNA is newly synthesized from embryonic chromatin or is a maternal mRNA stored in the unfertilized egg, hybrid andromerogones have been constructed containing a sea urchin (Strongylocentrotus purpuratus) genome in sand dollar (Dendraster excentricus) cytoplasm. Such hybrid andromerogones developed at a normal rate to the blastula stage but failed to hatch. Diploid hybrids or merogones containing at least one complement of sand dollar genome hatched on the normal maternal schedule. Since the sea urchin hatching enzyme is not able to digest the sand dollar fertilization membrane, this failure to hatch is evidence that new mRNA synthesis from embryonic chromatin is required before hatching enzyme can be synthesized.     

Animalizing Effect of A23187 on Sea Urchin Embryos

Pulse treatment of sea urchin embryos with 3 μM A23187 for 2 hr starting at a stage in initial 10 hr period of development at 20°C, followed by a culture in normal sea water up to the pluteus corresponding stage (45 hr after fertilization), yielded many large exogastrulae with thin embryo walls. The pulse treatment starting at a time between 10 and 13 hr after fertilization yielded considerable number of large prisms and gastrulae having thin embryo walls. Probably, the pulse treatment exerts stimulating effects on ectodermal cell determination in whole span of pre-hatching period to produce animalized embryos. On the other hand, pulse treatment with A23187 in pre-hatching period exerts stage-specific effects on gut formation. Embryos, thus treated for 2 hr starting at stages between 3 and 5 hr after fertilization, produced quite small exoguts but those treated at stages between 7 and 8 hr formed well developed and long exoguts. In embryos treated at the other stages than above, guts or exoguts were almost the same in their size to those in normal ones. These effects of A23187 on morphogenesis were canceled by procaine, tetracaine and ruthenium red. Probably, artificial Ca²⁺signal induced by A23187 alters the determination of cell fates, programmed in pre-hatching period.     

Behavior of M-phase synchronized blastomeres after nuclear transfer in cattle

M-phase synchronized bovine blastomeres were used to study the effect of nuclear-cytoplasmic synchronization on the developmental potential after nuclear transfer (NT). The capacity of nocodazole and benomyl to reversibly synchronize blastomeres from embryos in M-phase was evaluated. Nocodazole reversibly arrested bovine embryos at the studied stages and induced high rates of M-phases in morulae and compact morulae. In contrast, benomyl was less efficient than nocodazole to synchronize in M-phase. After transfer of an M-phase blastomere, premature chromatin condensation was the prevalent finding 1 hr post-fusion (hpf). Condensed chromosomes non-arranged in the equatorial plate (1-3 hpf) that acquired an organized structure over time (3-7 hpf) were subsequently observed. Anaphase-telophase structures were predominantly recorded at 4-9 hpf. About 50% of the embryos activated at both 3-4 and 6-7 hpf extruded a polar body-like structure 5 hr after activation, but this was not observed in embryos activated immediately after fusion. A significantly lower activation rate was observed for oocytes activated 3-4 hpf compared to those activated 6-7 hpf. However, the ability to undergo first cleavage was significantly lower in the latter group. Reconstructed embryos activated immediately after fusion showed no difference in the rate of activation compared to those activated 6-7 hpf, although the cleavage rate was higher. DNA synthesis was observed at a significantly higher rate in embryos activated both immediately and 3-4 hpf that did not extrude a PB-like structure than in those activated 3-4 hpf that extruded a polar body-like structure. Under the conditions tested M-phase donor cells cannot be properly remodeled after NT in cattle to trigger normal embryonic development. Our observations of chromatin structures together with DNA synthesis suggest that the failure in the development may be due to improper chromatin remodeling of mitotic nuclei after NT, which may result in chromosomal abnormalities incompatible with normal embryo development.     

Sequence complexity of heterogeneous nuclear RNA in sea urchin embryos.

The sequence complexity of heterogeneous nuclear RNA is sea urchin gastrulas was measured by RNA-driven hybridization reactions with nonrepetitive sea urchin DNA. 28.5% of the sequence complexity of the genome is represented in the nuclear RNA. This amounts to 1.74 X 10(8) nucleotides of diverse sequence, more than 10 times the nucleotide complexity of the polysomal messenger RNA extracted from sea urchin embryos at the same stage. The complex set of nuclear RNA sequences driving this hybridization reaction was shown to be the same as the rapidly labeled hnRNA, using pulse-labeled nuclear RNA as driver.