Embryonic development of the sea bass Dicentrarchus labrax

The embryonic development of the sea bass Dicentrarchus labrax during the endotrophic period is discussed. An 8 cells stage, not reported for other studied species, results from two rapid successive cleavages. Blastula occurs at the eighth division when the embryo is made of 128 cells. During gastrulation, the infolded blastoderm creates the endomesoblastic layer. The Kupffer??s vesicle is reported to drive the left/right patterning of brain, heart and digestive tract. Heart formation starts at 8 pairs of somites, differentiation of myotomes and sclerotomes starts at the stage 18 pairs of somites; main parts of the digestive tract are entirely formed at 25 pairs of somites. At 28 pairs of somites, a rectal region is detected, however, the digestive tube is closed at both ends, the jaw appears the fourth day after hatching, but the mouth is not opened before the fifth day. Although cardiac beating and blood circulation are observed, gills are not reported in newly hatched individuals; eye melanization appears concomitant with exotrophic behavior.     

Effects of mycostatin in sea urchin development

Summary Sea urchin development is inhibited in the presence of mycostatin, a fungicidal antibiotic believed to alter cell membranes. Pretreatment of eggs inhibits fertilization inL. pictus, but not inS. purpuratus. The doses resulting in abnormal development inS. purpuratus increase as the treatment is started later in development. AH tissues are sensitive to mycostatin at high concentrations, but the endodermal and mesenchyme derivatives are most sensitive at lower concentrations. The results suggest the heterogeneity of cell membranes and also indicate that membranes change with time of development.This work was supported by San Fernando Valley State College Foundation Grants No 4.267.01, No 4.268.05.     

Apoptosis: focus on sea urchin development

It has been proposed that the apoptosis is an essential requirement for the evolution of all animals, in fact the apoptotic program is highly conserved from nematodes to mammals. Throughout development, apoptosis is employed by multicellular organisms to eliminate damaged or unnecessary cells. Here, we will discuss both developmental programmed cell death (PCD) under normal conditions and stress induced apoptosis, in sea urchin embryos. Sea urchin represent an excellent model system for studying embryogenesis and cellular processes involved in metamorphosis. PCD plays an essential role in sculpting and remodelling the embryos and larvae undergoing metamorphosis. Moreover, this marine organism directly interacts with its environment, and is susceptible to effects of several aquatic contaminants. Apoptosis can be adopted as a defence mechanism against any environmental chemical, physical and mechanical stress, for removing irreversibly damaged cells. This review, while not comprehensive in its reporting, aims to provide an overview of current knowledge on mechanisms to regulate physiological and the induced apoptotic program in sea urchin embryos.     

Cell type specification during sea urchin development

Recent discoveries indicate that cell lineages and fates play a key role in the establishment of spatially restricted gene expression during sea urchin development. Unique sets of founder cells generate five territories of gene expression by means of an invariant pattern of complete cleavage. Cell lineage analysis demonstrates that the second embryonic axis, the oral-aboral axis, is specified with reference to the first cleavage plane. In the undisturbed embryo, clones that contribute to one territory or another begin to appear at the third cleavage, and founder cell segregation to all five territories is completed by the sixth cleavage. Founder cell segregation is a key feature of mechanisms that establish the spatially defined gene activity of sea urchin embryogenesis.     

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.     

Intracellular pH controls the development of new potassium conductance after fertilization of the sea urchin egg

Fertilization of the sea urchin egg leads to a sequence of changes at the egg surface and the interior cytoplasm. Among these changes are the transient elevation of internal calcium levels, alkalization of the cytoplasm and development of new K⁺-conductance. In the series of experiments reported here, we separate the effects on potassium activation of the calcium release and the rise in the intracellular pH. The development of new K⁺-conductance was dependent on alkalization of the egg cytoplasm, and not on a rise of internal calcium levels. The effects of 2,4-dinitrophenol, N-ethylmalemide, antimycin A and oligomycin suggest that the maintenance of the alkaline internal pH of fertilized eggs appears to be dependent on membrane ATPase activity.     

The fate of the small micromeres in sea urchin development

We show that in sea urchin embryos, the daughter cells of the small micromeres become part of the coelomic sacs, in contrast to the long-held view that these sacs are purely of macromere origin. In addition, after prolonged mitotic quiescence, and following their incorporation into the coelomic sacs, these cells resume dividing, contrary to the previous view that they do not divide. Since coelomic sac cells give rise to much of the adult urchin, our results indicate that the small micromeres are founders of cell lineages involved in the formation of adult tissues. The setting aside of these cells in a nondividing state may be analogous to a phenomenon in Drosophila development, in which primordial imaginal and germ cells divide approximately once after the blastoderm stage and do not resume dividing until the larval stage.     

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.     

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.     

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.