Histone variants and chromatin structure during sea urchin development

At the late blastula stage of sea urchin development a changeover of histone synthesis and chromatin composition takes place. Synthesis of the early histone variants declines while another set, the late histone variants, begins to be detected. During subsequent development the late histones accumulate steadily. In the 9-day larva only late histone variants are detectable. Micrococcal nuclease acts differentially on early and late nuclei. There is a depressed release of acid-soluble DNA when chromatin containing the late histones is digested. Nucleosomal repeat lengths change systematically and in parallel with the changing histone composition. Blastula and preblastula chromatin have a significantly shorter major repeat length than does the chromatin of 9-, 11-, and 16-day larvae. Intermediate stages of development have chromatin with intermediate periodicities. These differences are observed when the determinations are made under denaturing conditions of electrophoresis. Repeat lengths were found to be independent of the extent of digestion at all stages examined except the pluteus, in which there is an increase of the apparent repeat length as digestion proceeds. Pancreatic DNase I digests nuclei from blastulae and 9-day larvae similarly. Changes in the histone composition of chromatin, in nuclease accessibility of chromatin, and in nucleosomal repeat length are all very closely correlated, implying that there are underlying causal relationships.     

Phosphorylation of nonhistone chromatin proteins during sea urchin development

The phosphorylation of nonhistone chromatin proteins during development was studied in the sea urchin, $\text{Strongylocentrotus purpuratus}$. The rate of phosphorylation was found to be maximal during gastrula, slightly lower during prism and almost 70% lower in pluteus stage embryos. Analysis of the phosphorylated nonhistone chromatin proteins by SDS-acrylamide gel electrophoresis showed significant variations in the labeling pattern during different stages of development. A specific protein which is actively phosphorylated during gastrula and prism stages is nearly absent from the pluteus stage.     

Automated sequential affinity chromatography of sea urchin embryo DNA binding proteins.

An automated method of running a tandem sequence of oligonucleotide affinity columns was used to purify factors that interact specifically with cis-regulatory sites of the CyIIIa cytoskeletal actin gene of the sea urchin embryo (Strongylocentrotus purpuratus). The method allows quantitative enrichment in a single chromatographic run of up to 12 different sequence-specific DNA binding proteins, each of which may then be readily purified to homogeneity by methods such as preparative gel electrophoresis. The affinity chromatography and identification of six different CyIIIa-regulatory factors is described, and the general utility of the method is discussed.     

Membrane formation and membrane contacts during the development of the sea urchin embryo

Summary Sea urchin embryos, 8-cell stage to pluteus stage, fixed in osmium tetroxide and embedded in Epon 812 were observed by electron microscopy. At no point in the development were syncytial junctions between the embryonic cells found. During the cleavage stages the membrane contact was closer than in later stages. In early blastula stages intercellular clefts appeared which in the gastrula stage demarcate every cell. At the same time a ringshaped desmosome structure develops at the outer cell surface. In the pluteus stage a closer cell contact is re-established. With proceeding embryogenesis endoplasmic membranes will attach to the cell membrane. These membrane structures may even be of nuclear origin. Gradually, long protrusions, vesicles and lamellae begin to be formed from the nuclear membrane. The commencement of this nuclear activity coincides in time with the formation of nucleoli. At cell division the new cell membrane seemed to arise partly independently of the cleavage furrow from a system of cytoplasmic vesicles.The investigation was facilitated by grants from the Nordic Insulin Foundation.I am indebted to Dr. Torsten Olsson and Miss Brita Nilsson for procuring the material and to Mrs. Mariann Carleson for technical aid.     

Metabolic interconversion of dolichol and dolichyl phosphate during development of the sea urchin embryo

The in vivo and in vitro synthesis and turnover of dolichol and dolichyl phosphate have been studied over the course of early development in sea urchin embryos. Synthesis of dolichol and dolichyl phosphate was studied in vivo and in vitro using [3H]acetate and [14C] isopentenylpyrophosphate, respectively, as precursors. Both the in vivo and in vitro results indicate that the principal labeled end product of de novo synthesis is the free alcohol, and that this alcohol is subsequently phosphorylated to produce dolichyl phosphate. The presence of 30 microM compactin inhibits the de novo synthesis of dolichol from [3H]acetate by greater than 90%, but has no effect on the incorporation of 32Pi into dolichyl phosphate for more than 6 h, thus suggesting that during this time interval the major source of dolichyl phosphate is preformed dolichol. The rate of turnover of the [3H]acetate-labeled polyisoprenoid backbone of dolichyl phosphate is very slow (t1/2 = 40-70 h). In contrast, the rate of loss of the [32P]phosphate headgroup is more rapid (t1/2 = 5.7-7.7 h) and increases over the course of development. Finally, dolichyl phosphate phosphatase activity has been measured in vitro. The activity of this enzyme, which can be distinguished from phosphatidic acid phosphatase, was found to increase as a function of development, in qualitative agreement with the increased turnover of 32P from dolichyl phosphate observed in vivo. These results suggest that the phosphate moiety of dolichyl phosphate is in a dynamic state, and that dolichol kinase and dolichyl phosphate phosphatase play key roles in regulating the cellular level of dolichyl phosphate.     

Cholinergic regulation of the sea urchin embryonic and larval development

Choline esters of polyenoic fatty acids block cleavage divisions of sea urchins and evoke the formation of one-cell multinuclear embryos. If the fatty acids AA-Ch or DHA-Ch are added at the mid or late blastula stage, many cells are extruded, forming extra-embryonic cell clusters near the animal pole of embryos or larvae. Both effects are prevented by dimethylaminoethyl esters of polyenoic fatty acids (AA-DMAE or DHA-DMAE) or their 5-hydroxytryptamides. Nicotinic acetylcholine receptor antagonists, imechine, d-tubocurarine or QX-222 provide partial protection against AA-Ch or DHA-Ch. The organophosphate pesticide, chlorpyrifos, or a combination of (-)-nicotine + phorbol 12-myristate 13-acetate, also evoke the mass extrusion of transformed embryonic cells at the animal pole of larvae. These effects are similarly antagonized by AA-DMAE, DHA-DMAE, or fatty acids 5-hydroxytryptamides. Taking together, these results suggest that AA-Ch and DHA-Ch act on sea urchin embryos and larvae as agonists of acetylcholine receptors, whereas AA-DMAE and DHA-DMAE act as antagonists. The ability of fatty acids 5-hydroxytryptamides to prevent the effects of AA-Ch or DHA-Ch may be due to restoration of the normal dynamic balance of cholinergic and serotonergic signaling during cleavage divisions and gastrulation.     

Acetylation of proteins in the course of sea urchin development

Acetate incorporation into proteins including acidic proteins and basic proteins was studied by introduction of isotopically labeled precursors during sea urchin development. At pregastrulational stages, the acetate incorporation exhibited relatively low activities, whereas a remarked enhancement was apparently observed at gastrula stage and more advanced stages. Although some amount of exogenous acetate might be metabolically converted to amino acids, the acetate incorporation into proteins appeared to be mainly attributed to acetylation of proteins that should be coupled with peptide synthesis, as indicated by the incorporation occurring on peptide-synthesizing polysomes and strong inhibition of it by administration of puromycin.     

Loss of yolk platelets and yolk glycoproteins during larval development of the sea urchin embryo

The fate of the yolk platelets and their constituent yolk glycoproteins was studied in Strongylocentrotus purpuratus eggs and embryos cultured through the larval stage. Previous studies have shown that the yolk glycoproteins undergo limited proteolysis during early embryonic development. We present evidence that the yolk glycoproteins stored in the yolk platelets exist as large, disulfide-linked complexes that are maintained even after limited proteolysis have occurred. We provide additional evidence that acidification of the yolk platelet may activate a latent thiol protease in the yolk platelet that is capable of correctly processing the major yolk glycoprotein into the smaller yolk glycoproteins. Because we previously showed that these yolk glycoproteins are not catabolized during early embryonic development, it was of interest to study their fate during larval development. Using a specific polyclonal antibody to a yolk glycoprotein, we found that both yolk glycoproteins and the yolk platelets disappeared in feeding, Day 7, larval stage embryos, but that starvation did not significantly affect the levels of the yolk glycoproteins. We also found that the yolk glycoproteins reappeared in 30-day-old premetamorphosis larvae.     

Mathematical model for early development of the sea urchin embryo

In Xenopus and Drosophila, the nucleocytoplasmic ratio controls many aspects of cell-cycle remodeling during the transitory period that leads from fast and synchronous cell divisions of early development to the slow, carefully regulated growth and divisions of somatic cells. After the fifth cleavage in sea urchin embryos, there are four populations of differently sized blastomeres, whose interdivision times are inversely related to size. The inverse relation suggests nucleocytoplasmic control of cell division during sea urchin development as well. To investigate this possibility, we developed a mathematical model based on molecular interactions underlying early embryonic cell-cycle control. Introducing the nucleocytoplasmic ratio explicitly into the molecular mechanism, we are able to reproduce many physiological features of sea urchin development.     

Changes of cell and embryo volume during development of vitelline membrane-free sea urchin embryos

The rearing in large batches of sea urchin embryos stripped of their fertilization membranes is described. The developmental stages are electronically characterized and compared with untreated, coated embryos. The volumes of disaggregated cells from early stages are determined. The total number of cells per embryo can be evaluated reliably. The conclusions drawn from the volume distribution curves—such as the volume increase of fertilized eggs preceding the first cleavage, the constancy of the embryo volume between the first and fifth cleavage and the constancy of the cellular volumes from the onset of the blastula stage around 15 h up to 30 h are discussed.     

Non-histone chromatin proteins from the sea urchin Strongylocentrotus droebachiensis sperm and embryo

Non-histone chromatin proteins (NHP) from sperm and gastrula of the sea urchin Strongylocentrotus droebachiensis have been studied. The results obtained show that the total amount of the NHP in the sperm chromatin is one-sixth of that in the gastrula chromatin. Certain notable differences in the electrophoretic banding patterns of the NHP have also been observed. SDS polyacrylamide gel electrophoresis of NHP revealed one major specific component of molecular weight 17000 in the sperm chromatin and three major specific fractions with molecular weights 14000; 15000 and 35000 in gastrula chromatin. Furthermore, the gastrula chromatin NHP contains about ten minor specific fractions in the molecular weight range 25 000 to 65 000. The relevance of these results to the control of gene activity is discussed.     

Cell junctions during the early development of the sea urchin embryo (Paracentrotus lividus)

Thin sections, lanthanum tracer and the freeze-fracture technique revealed the presence of different types of cell junctions in early sea urchin (Paracentrotus lividus) embryos. During the first four cleavage cycles, which are characterized by synchrony of cell division, sister blastomeres were connected only by intercellular bridges, formed as a result of incomplete cytokinesis; no trace of other junctions was found at these stages. From the 16-cell stage onwards, septate junctions and gap junctions began to appear between blastomeres. It is postulated that cell-cell interactions may provide a mechanism for the propagation of signals necessary for the coordination of cell proliferation and differentiation.