Differences in abundance of individual RNAs in normal and animalized sea urchin embryos

A library of cDNA clones was constructed representing polysomal polyadenylated RNA of mesenchyme blastulae of Strongylocentrotus purpuratus. Using this library, we determined whether or not individual RNA species are associated with animalization of embryos by zinc ions. Clones corresponding to the most actively synthesized RNAs during the period just prior to the mesenchyme blastula stage were selected by screening colonies with in vivo-labeled RNA. The most abundant of these were chosen for further study. Individual RNA abundance was measured as percent of mass of total polyadenylated RNA by hybridizing cDNA exhaustively with cloned DNA on filters. The RNAs in the selected, cloned sequences were present in abundances of 0.01 to 1% of the mass of polyadenylated RNA. Changes in abundance of individual RNA species occurred during normal development and departures from these developmental changes occurred in the zinc-animalized embryos. Two RNA species, which normally increase 10-fold in abundance, are drastically repressed and at least one RNA species increases in abundance dramatically in the animalized embryos. These departures from the normal program of presumptive gene expression may furnish insights into changes in the normal processes of development.     

Animalizing ability of evans blue in embryos of Arbacia punctulata : Effect on multiple molecular forms of NAD- -malate dehydrogenase

Developing embryos of Arbacia punctulata were animalized by continuous exposure from the 2-cell stage to the polysulfonic acid dye, Evans Blue, at a concentration of 1/25000, or were radialized by exposure to this agent at a concentration of 1/200000. Cell fluid proteins, extracted from several stages in normal, animalized and radialized development, were separated by disc electrophoresis on polyacrylamide gels and NAD- -MDH activity was localized by suitable staining of the gels. Animalized embryos, which morphologically appear as hyperciliated blastulae, had NAD- -MDH patterns similar to the normal blastula stage and unlike their respective controls. In all stages of animalization, the normal reappearance of soluble isozyme (no. 4) was inhibited. Radialized embryos, which gastrulate and differentiate structures representative of all three germ layers, had patterns similar to controls. In all stages of animalization and radialization the most anodal, mitochondrial isozyme was apparently bound to Evans Blue. These results are discussed in terms of the animal-vegetal gradients of morphogenesis and oxidation-reduction.     

Some new observations on the animalization of the unfertilized sea urchin egg

The influence of bright daylight on the animalization of the unfertilized egg of Paracentrotus lividus by exposing it to SCN-ions in Ca⁺⁺-free sea water under aerobic conditions has been studied. The processes underlying animalization were decidedly inhibited by the light (Table I and II). It was found during the summer of 1948 that eggs taken from females from two different localities, Beclem and St. Efflam in the Roscoff area of Brittany, behaved very differently against the animalizing treatment, those from Beclem being easily animalized whereas those from St. Efflam were rather resistant. The proteins of the Beclem eggs turned out to be more soluble in icecooled 0.54 M. NaI than those of the St. Efflam eggs (Table V). In the cultures obtained from eggs not very resistant to the animalizing treatment, slightly animalized larvae were more frequent than in cultures with more resistant eggs.     

An altered series of ectodermal gene expressions accompanying the reversible suspension of differentiation in the zinc-animalized sea urchin embryo

Early stage treatment of the sea urchin embryo with zinc ions is known to prevent its gastrulation. The treated embryo, termed "animalized" and classically regarded as a permanent blastula with possibly exaggerated ectodermal differentiation, can be viewed, instead, as being in a state of reversibly suspended differentiation. This proposition is supported by the following observations: (1) An embryo exposed to Zn2+ through its blastula stages and resuspended in fresh sea water retains the simple blastula morphology for at least 4 days; however, if the Zn2+ is also depleted by a chelator during this period, development resumes and reaches the pluteus stage. (2) A suppression of ectodermal differentiation in the zinc-animalized embryo can be inferred from the blockage of the developmental initiation of Spec 1 and CyIIIa actin mRNA accumulation, since the genes encoding them are specifically expressed in differentiated (aboral) ectoderm. (3) Chelation allows the zinc-blocked accumulation of these ectodermal mRNAs to proceed. The later the treatment with chelator, the more slowly these mRNA accumulations resume, and the longer the interval between them and the subsequent morphological differentiation. (4) The enhancement of some early ectodermal functions in the zinc-animalized embryo is indicated by the increased concentrations of mRNAs, encoded by a set of genes, Blast j1 and Spec 3, that normally display peak levels in the blastula. The association of these genes with ectoderm is based on their being specifically expressed, albeit at low levels, in the pluteus ectoderm, and their being suppressed when presumptive ectoderm is made to differentiate as endoderm in the case of the embryo treated with lithium. The program of cell division in the zinc-animalized embryo remains essentially normal. Differentiation becomes reversibly suspended, with the enhancement of certain early mRNA expressions and the reversible suppression of certain late mRNA expressions, characteristic of differentiated tissues.     

Stage Specific Effects on Sea Urchin Embryogenesis of Zn2+, Li+, several Inhibitors of cAMP-Phosphodiesterase and Inhibitors of Protein Synthesis

Treatment of sea urchin embryos for 3 hr starting at the 16-64 cell stage with Li⁺ or 3-isobutyl-1-methylxanthine as well as with other inhibitors of cAMP-phosphodiesterase (PDE) and several inhibitors of protein synthesis, resulted in production of vegetalized embryos with a large exogut. However, the same treatment starting at other stages produced hardly any vegetalized embryos. The specific stage for these substances to cause vegetalization is probably the 16-64 cell stage. Treatment with Zn²⁺ between the times of fertilization and hatching, followed by culture in normal sea water produced animalized embryos with little if any archenteron, but the same treatment followed by culture with ethylenediamine-N, N'-diacetic acid (EDDA), a chelator of Zn²⁺, produced quasi-normal plutei. This chelator did not counteract the animalizing effect of Zn²⁺ when culture with EDDA was started at the post-gastrula stage. Treatment of embryos for a long period (1-3 days) starting at the blastula stage with Li⁺ and the inhibitors of PDE and protein synthesis, as well as with Zn²⁺, produced spherical embryos with little or no archenteron. The stages at which these substances produced abnormal embryos with a poor archenteron are post-hatching stages.     

Chromatin proteins from normal,vegetalized, and animalized sea urchin embryos

The chemical composition of the chromatin, the fractional content of histones and nonhistone chromatin proteins (NHP), and the biosynthesis of these proteins in normal, vegetalized, and animalized embryos of the sea urchin Strongylocentrotus droebachiensis at the blastula, mesenchyme blastula, and gastrula stages have been studied. The amount of the NHP in the chromatin from normal and vegetalized embryos increases during early embryonic development while that in animalized embryos remains without change at the mesenchyme blastula stage and then decreases. During development the histone content in all three cases slightly decreases. Polyacrylamide gel electrophoresis reveals that both fractional composition of histones and their biosynthesis in normal, vegetalized, and animalized embryos display no differences. During development, however, some changes occur, so that the relative amount of histones F1 and F2a2 increases, F2b decreases, while F3 and F2a1 remains constant. Histone F1 at the blastula stage consists of two subfractions while at the gastrula stage it consists of three subfractions. The histone F2a1 consists of one and two, respectively. Histone F3 at all stages is made up of three subfractions; histone F2b is made up of two; and the histone F2a2 is electrophoretically homogeneous. Specific radioactivity of the arginine-rich histones F3 and F2a1 tends to increase during development, while that of moderately lysine-rich histones F2b and F2a2 does not change, and that of the lysine-rich histone F1 decreases. The NHP in normal, vegetalized, and animalized embryos at different developmental stages consist of 17 fractions that can be separated by isoelectrofocusing within the 4.5-8.8 pH range. Quantitative changes have been observed in the fractions focused at pH 4.5-6.1 during development and in normal and modified embryos at the gastrula stage.     

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.     

Developmental time,cell lineage,and environment regulate the newly synthesized proteins in sea urchin embryos

Strongylocentrotus purpuratus embryos were fractionated into two cell populations of defined lineages at times corresponding to two critical developmental events: determination (16-cell stage) and early differentiation (mesenchyme blastula). The 16-cell stage blastomeres, labeled with [³⁵S]methionine, exhibited identical protein synthesis patterns by fluorography, and this pattern was not significantly altered by cell separation. In comparing the proteins of the mesenchyme blastula to the 16-cell stage, differences (increases and decreases) were seen by fluorography of newly synthesized proteins. The synthesis of 2.9% of the mesenchyme blastula proteins is specific to or enriched in primary mesenchyme cells and 8.2% is specific to or enriched in endoderm/ectoderm cells. Additionally, in contrast to the earlier stage, the pattern of protein synthesis in the mesenchyme blastula embryos is substantially altered by cell separation. The ability to alter protein synthesis in response to environmental factors may be a further demonstration of the differentiation of these cells.     

Determination and morphogenesis in the sea urchin embryo

The study of the sea urchin embryo has contributed importantly to our ideas about embryogenesis. This essay re-examines some issues where the concerns of classical experimental embryology and cell and molecular biology converge. The sea urchin egg has an inherent animal-vegetal polarity. An egg fragment that contains both animal and vegetal material will produce a fairly normal larva. However, it is not clear to what extent the oral-aboral axis is specified in embryos developing from meridional fragments. Newly available markers of the oral-aboral axis allow this issue to be settled. When equatorial halves, in which animal and vegetal hemispheres are separated, are allowed to develop, the animal half forms a ciliated hollow ball. The vegetal half, however, often forms a complete embryo. This result is not in accord with the double gradient model of animal and vegetal characteristics that has been used to interpret almost all defect, isolation and transplantation experiments using sea urchin embryos. The effects of agents used to animalize and vegetalize embryos are also due for re-examination. The classical animalizing agent, Zn2+, causes developmental arrest, not expression of animal characters. On the other hand, Li+, a vegetalizing agent, probably changes the determination of animal cells. The stability of these early determinative steps may be examined in dissociation-reaggregation experiments, but this technique has not been exploited extensively. The morphogenetic movements of primary mesenchyme are complex and involve a number of interactions. It is curious that primary mesenchyme is dispensable in skeleton formation since in embryos devoid of primary mesenchyme, the secondary mesenchyme cells will form skeletal elements. It is likely that during its differentiation the primary mesenchyme provides some of its own extracellular microenvironment in the form of collagen and proteoglycans. The detailed form of spicules made by primary mesenchyme is determined by cooperation between the epithelial body wall, the extracellular material and the inherent properties of primary mesenchyme cells. Gastrulation in sea urchins is a two-step process. The first invagination is a buckling, the mechanism of which is not understood. The secondary phase in which the archenteron elongates across the blastocoel is probably driven primarily by active cell repacking. The extracellular matrix is important for this repacking to occur, but the basis of the cellular-environmental interaction is not understood.(ABSTRACT TRUNCATED AT 400 WORDS)     

Gastrulation in the sea urchin embryo requires the deposition of crosslinked collagen within the extracellular matrix

This study demonstrates that a collagenous extracellular matrix (ECM) is necessary for gastrulation in the sea urchin embryo. The approach taken was to disrupt collagen processing with two types of agents (a lathyritic agent, beta-aminopropionitrile (BAPN), and three types of proline analogs: dehydroproline, cis-OH-proline, and azetidine carboxylic acid) and to assess the effect on embryogenesis by morphological, immunological, and biochemical criteria. Embryos chronically exposed to either of the agents following fertilization displayed no detectable developmental abnormalities before the mesenchyme blastula stage. These embryos, however, did not gastrulate nor differentiate any further and remained at the mesenchyme blastula stage for at least 36 hr. Upon removal of the agents, the embryos resumed a normal developmental schedule and formed pluteus larvae that were indistinguishable from control embryos. By immunofluorescence studies with monospecific antibodies to type I and type IV collagens it is seen that the lathyritic agent BAPN reduces the accumulation of collagens within the ECM. This effect is confirmed and quantitated by use of an ELISA and by a biochemical determination of OH-proline. When the agents are removed from the inhibited embryos, collagen deposition returns to normal, coincident with gastrulation. Western-blot analysis, using monospecific antibodies to collagen, demonstrates that the effect of the lathyritic agent is to reduce the stability of the extracellular collagen by inhibiting the intra- and intermolecular crosslinking of collagen molecules. BAPN exhibits a dose-dependent effect on morphogenesis, but has no effect on respiration nor on protein synthesis of the embryos throughout development. Although the lathyritic agent affects collagen deposition, it is shown to not affect the expression of other molecules of the ECM, nor that of several cell surface molecules. However, a cell surface molecule that is expressed specifically in the endoderm, termed Endo 1, is not expressed in the inhibited embryos. Endo 1 is expressed after removal of the lathyritic agent and its appearance is coincident with gastrulation in the recovered embryos. These results suggest that a collagenous ECM is important for gastrulation and subsequent differentiation in the sea urchin, but not for earlier developmental processes. In addition, the dependence of Endo 1 expression on the collagenous ECM raises the possibility that this cell surface molecule is in some way regulated by interactions of the presumptive endodermal cells with the ECM.     

Sulfated polysaccharides and cell differentiation in the sea urchin embryo

The synthesis of sulfated polysaccharides during the embryonic development of Paracentrotus lividus has been investigated by incorporation of radioactive sulfate, glucose, glucosamine and fucose. The following substances become labelled: fucan sulfate (approximately 60%), heparan sulfate (approximately 20%) and dermatan sulfate (approximately 20%), and possibly a very slight amount of chondroitin sulfate. In animalized and vegetalized embryos, the rate of incorporation is significantly reduced, and furthermore dermatan sulfate is almost absent in animalized embryos. It is concluded that this substance is associated with the differentiation of vegetative cells, possibly the mesenchyme cells.     

Stimulation of Protein Synthesis in the Mitochondria of Sea Urchin Embryos before Gastrulation

A transient increase in protein synthesis was observed in mitochondria at the mesenchyme blastula stage of sea urchin ( Hemicentrotus pulcherrimus ) embryos. This stimulated activity was inhibited by chloramphenicol but not by cycloheximide. Reconstituting experiments in which poly U-dependent protein synthesis was carried out showed the mitochondrial peptide elongation factor to be essential for increasing the protein synthetic activity in mesenchyme blastula, but aminoacyl tRNA synthetase and ribosome fraction containing initiation factor not to be involved in this increase. These findings are discussed in relation to the differentiation of embryos at the gastrulation stage.     

Acid mucopolysaccharide metabolism, the cell surface, and primary mesenchyme cell activity in the sea urchin embryo

The relationship between ³⁵SO₄ incorporation into acid mucopolysaccharides and the appearance and activity of the primary mesenchyme cells has been studied in the sea urchin, Lytechinus pictus. The ratio of the uptake of ³⁵SO₄ to its incorporation into cetylpyridinium chloride precipitable material varies over a wide range during early development, with the smallest ratio, therefore the greatest sulfation activity, being found at the early mesenchyme blastula stage. The types of mucopolysaccharides produced have not been identified, but are heterogeneous. At the mesenchyme blastula stage nearly 90% of the polysaccharides produced become sulfated. When embryos develop in sulfate-free sea water to the mesenchyme blastula stage there is a 70% decrease in the incorporation of ³H-acetate into polysaccharides and a 13-fold decrease in the ratio of sulfated to nonsulfated polysaccharides produced. Embryos raised in sulfate-free sea water develop normally to the mesenchyme blastula stage at which time there is an accumulation in the blastocoel of primary mesenchyme cells that do not migrate. The surface of the primary mesenchyme cells of sulfate-deficient embryos has a smooth appearance in the scanning electron microscope, while the surface of these cells in control embryos is rough, possibly reflecting the presence of an extracellular coat. It is suggested that there is a correlation between sulfated polysaccharide synthesis, cell surface morphology and cell movement.     

An acid extract from dissociation medium of sea urchin embryos, induces mesenchyme differentiation.

When material extracted by 1 M acetic acid from the dissociation medium of sea urchin embryos is added at low concentrations to isolated primary mesenchyme cells, it induces skeletogenesis. The same material added to dissociated blastula cells, or to embryos at the blastula stage, stimulates skeleton formation and pigment cell differentiation. On dissociated cells, it also increases cell reaggregation, thymidine incorporation and survival. On embryos, it induces exogastrulation and appearance of extraembryonic pigment cells. The activity of the extract is resistant to raised temperatures and partially to tryptic digestion but is abolished by trypsin treatment followed by heating. The active fraction does not readily filter through Amicon XM-50 and is retarded by column chromatography on Bio-Gel P-60.     

Changes in cell surface charges during differentiation of isolated micromeres and mesomeres from sea urchin embryos

Changes in the negative surface charge were observed by cell electrophoresis during the differentiation of micromeres and mesomeres isolated from 16-cell-stage sea urchin embryos. Micromeres and mesomeres were separated by a sucrose density gradient column and were cultured in normal seawater. An isolated micromere developed to a cell aggregate, and, at the mesenchyme-blastula stage of control, the aggregate began to scatter into single cells. These processes are quite similar to those of the primary mesenchyme cells in situ. An isolated mesomere, on the other hand, developed into an ectodermal vesicle. At desired stages of development, the cell aggregates which derived from single blastomeres were dissociated into single cells, and their electrophoretic mobilities were measured. It was found that the electrophoretic mobility of the micromere- and mesomere-derived cells concomitantly increased from the early blastula stage up to the early mesenchyme stage. In contrast with the mesomere-derived cells, however, the micromere-derived cells showed another increase in electrophoretic mobility when the cells began to migrate as primary mesenchyme cells. These results show that a correlation exists between the increase in cell surface negative charge and the migration of the primary mesenchyme cells.