Calcium-dependent self-aggregation of toposome,a sea urchin embryo cell adhesion molecule

Summary— Sea urchin embryos can be easily dissociated into single cells by exposure to Ca²⁺- and Mg²⁺-free seawater. When transferred back to normal seawater, isolated cells spontaneously form aggregates capable of development. Here, the Ca²⁺-dependent self-aggregation of toposome, a 22S glycoprotein complex which mediates cell-cell adhesion in sea urchin embryos, has been investigated using the purified molecule. Results show that the 22S complex is completely converted to 15S particles by sedimentation on sucrose isokinetic gradients in the presence of EDTA. Reconstitution of the 22S complex is achieved by readdition of Ca²⁺. We propose that the 15S particle constitutes the toposome functional unit on the cell surface.     

Species-specific dissociation into single cells of live sea urchin embryos by fab against membrane components of Paracentrotus lividus and Arbacia lixula

The species and stage specificities of membrane components active in promoting reaggregation of cells dissociated from embryos of the two Mediterranean sea urchin species Paracentrotus lividus and Arbacia lixula have been examined. Membrane proteins extracted with butanol either from purified membranes or from dissociated cells without significant reduction of viability promoted reaggregation of both the homologous and heterologous species. Extracts from plutei and blastulae were equally effective in promoting reaggregation of blastula cells. By contrast, Fab's prepared from IgG raised against these extracts or purified membranes are strictly species specific because they prevent reaggregation of cells and actively dissociate live embryos of only the homologous species. No corresponding stage specificity of the Fab was observed: Fab against extracts from blastula embryos also caused dissociation of plutei. Antigenic analysis of the extracts by the Ouchterlony test revealed the presence of components specific for each species as well as others common to both.     

The color purple: analyzing alkaline phosphatase expression in experimentally manipulated sea urchin embryos in an undergraduate developmental biology course

In these laboratory exercises, developed for a sophomore/junior-level undergraduate course in Developmental Biology, students explore the processes of differentiation and morphogenesis in sea urchin embryos by monitoring the spatio-temporal expression pattern of the endoderm marker, alkaline phosphatase. Once students have determined the normal alkaline phosphatase expression pattern, they are asked to treat sea urchin embryos in some way that perturbs normal morphogenesis. Their task is to discover whether the chosen treatment perturbs both morphogenesis and differentiation of the gut or only morphogenesis. The ease with which sea urchin embryos can be cultured and manipulated provide the Developmental Biology instructor with a powerful system for inviting students to explore questions regarding differentiation and morphogenesis.     

A protein of the basal lamina of the sea urchin embryo

The purification, biochemical characterization and functional features of a novel extracellular matrix protein are described. This protein is a component of the basal lamina found in embryos from the sea urchin species Paracentrotus lividus and Hemicentrotus pulcherrimus . The protein has been named PI-200 K or Hp-200 K, respectively, because of the species from which it was isolated and its apparent molecular weight in SDS-PAGE under reducing conditions. It has been purified from unfertilized eggs where it is found packed within cytoplasmic granules, and has different binding affinities to type I collagen and heparin, as assessed by affinity chromatography columns. By indirect immunofluorescence experiments it was shown that, upon fertilization, the protein becomes extracellular, polarized at the basal surface of ectoderm cells, and on the surface of primary mesenchyme cells at the blastula and gastrula stages. The protein serves as an adhesive substrate, as shown by an in vitro binding assay where cells dissociated from blastula embryos were settled on 200K protein-coated substrates. To examine the involvement of the protein in morphogenesis of sea urchin embryo, early blastula embryos were microinjected with anti-200K Fab fragments and further development was followed. When control embryos reached the pluteus stage, microinjected embryos showed severe abnormalities in arms and skeleton elongation and patterning. On the basis of current results, it was proposed that 200K protein is involved in the regulation of sea urchin embryo skeletogenesis.     

Different aggregation properties of sea urchin embryonic cells at different developmental stages. I. Stage specificity of aggregation factors solubilized by butanol

Surface proteins solubilized with butanol from purified plasma membranes of sea urchin embryos at different developmental stages were tested for their aggregation promoting activity on dissociated cells. Cells used for the assays were obtained either from blastulae or from embryos at the 16 cell stage. Results show that a strong enhancement of cell aggregation was produced only when extracted proteins and dissociated cells were obtained from embryos at the same developmental stage.     

HSP90 function is required for morphogenesis in ascidian and echinoid embryos

Treatment of embryos of the ascidians Boltenia villosa and Cnemidocarpa finmarkiensis and the sea urchin Strongylocentrotus purpuratus with the anti-HSP90 drugs geldanamycin and radicicol caused morphogenetic arrest. All embryonic stages during which obvious morphogenesis was observed were sensitive to treatment, including formation of the sea urchin blastular epithelium. Arrested embryos were viable for many hours to days post-treatment, indicating a low general toxicity of these drugs. Morphogenetic movements including gastrulation and migration (but not ingression) of sea urchin primary and secondary mesenchyme cells were arrested 8-10 h after treatment began. Cell division and developmentally regulated expression of some genes continued after morphogenesis was arrested. Anti-HSP90 drugs cause selective inactivation or degradation of proteins with which the protein chaperone HSP90 interacts. Therefore, morphogenetic arrest subsequent to the disruption of HSP90 function may result from the reduction in concentration, or activity, of client proteins required for morphogenetic movements of cells. The use of these drugs may provide a means to identify novel activities or proteins involved in morphogenesis.     

Microplate assay for quantifying developmental morphologies: effects of exogenous hyalin on sea urchin gastrulation

It is often difficult to determine the effects of various substances on the development of the sea urchin embryo due to the lack of appropriate quantitative microassays. Here, a microplate assay has been developed for quantitatively evaluating the effects of substances, such as hyalin, on living sea urchin embryos. Hyalin (330 kDa) is a major constituent of the sea urchin hyaline layer, an extracellular matrix that develops 20 min postinsemination. Function of the hyaline layer and its major constituent, is the adhesion of cells during morphogenesis. Using wide-mouthed pipette tips, 25 microl of 24-h Strongylocentrotus purpuratus embryos were transferred to each well of a 96-well polystyrene flat-bottom microplate yielding about 12 embryos per well. Specific concentrations of purified hyalin diluted in low calcium seawater were added to the wells containing the embryos, which were then incubated for 24 h at 15 degree C. The hyalin-treated and control samples were observed live and after fixation with 10% formaldehyde using a Zeiss Axiolab photomicroscope. The small number of embryos in each well allowed quantification of the developmental effects of the added media. Specific archenteron morphologies-attached, unattached, no invagination and exogastrula-were scored and a dose-dependent response curve was generated. Hyalin at high concentrations blocked invagination. At low concentrations, it inhibited archenteron elongation/attachment to the blastocoel roof. While many studies have implicated hyalin in a variety of interactions during morphogenesis, we are not aware of any past studies that have quantitatively examined the effects of exogenous hyalin on specific gastrulation events in whole embryos.     

Immunocytochemical evidence for the presence of two domains in the plasma membrane of sea urchin blastomeres

Summary The blastomeres of sea urchin embryos have two surface regions with different properties. Numerous microvilli are present in the apical surface region, while the baso-lateral surface region, either on adjoining adjacent cells or facing the blastocoel, is smooth. When blastomeres are isolated from embryos and stained with fluorescein-isothiocyanate-labelled anti-(egg surface) antibody (anti-ES) prepared against membranes isolated from fertilized eggs, the apical microvillous region fluoresces while the smooth region does not [Yazaki I (1984) Acta Embryol Morphol Exp 5∶3–22]. In order to study quantitatively the ‘bindability’ of the membrane in the two regions to anti-ES, immunoelectron microscopy was used. Blastomeres isolated from embryos ofHemicentrotus pulcherrimus at the eight-cell stage were treated with rabbit anti-ES serum or pre-immune serum and then with ferritin-conjugated goat anti-(rabbit IgG) for 10 min at 0°C, mainly before fixation. About 10 times (maximally 45 times) more ferritin particles were counted per contour length in the microvillous surface region than in the smooth surface region. These results suggest that the membrane of the blastomeres of sea urchin embryos is a mosaic of two different membrane territories: one represented by the microvillous surface originating from the unfertilized egg, which binds anti-ES, the other by the smooth surface newly organized after the first cleavage, which does not react with anti-ES. The mechanism of segregation of the membrane into these two regions is discussed.     

The oligomeric integrity of toposome is essential for its morphogenetic function

Sea urchin embryos are uniquely suitable for the study of morphogenetic cell interactions. Efforts to identify the molecules responsible for morphogenetic cell adhesion led to the isolation of a 22S glycoprotein complex from Paracentrotus lividus sea urchin embryo, that has been called toposome. The biological activity of toposome in mediating cellular adhesion has been fully documented. Its function in determining positional guidance during the development of the sea urchin embryo has been proposed. Here studies on the molecular structure of toposome are reported showing that, under non-reducing conditions, it is resolved in sodium dodecyl sulphate polyacrylamide gel electrophoresis (SDS-PAGE) in a major band with an apparent molecular weight of 260 kDa, a doublet of 180-160 kDa and a lower band of 80 kDa. Digestion with EndoH endoglycosidase reduced the molecular sizes of the bands of 10%, 20% and 40%, respectively. In order to establish if the oligomeric integrity of toposome was essential for its function, the biological activity of each subunit on cells dissociated from sea urchin blastula embryos was tested. The resulting swimming embryoids were lacking skeleton, while reaggregating cells supplemented with native toposome developed into pluteus-like structures with skeletal elements.     

Exogenous hyalin and sea urchin gastrulation, Part II: hyalin, an interspecies cell adhesion molecule.

The 330 kDa fibrillar glycoprotein hyalin is a well known component of the sea urchin embryo extracellular hyaline layer. Only recently, the main component of hyalin, the hyalin repeat domain, has been identified in organisms as widely divergent as bacteria and humans using the GenBank database and therefore its possible function has garnered a great deal of interest. In the sea urchin, hyalin serves as an adhesive substrate in the developing embryo and we have recently shown that exogenously added purified hyalin from Strongylocentrotus purpuratus embryos blocks a model cellular interaction in these embryos, archenteron elongation/attachment to the blastocoel roof. It is important to demonstrate the generality of this result by observing if hyalin from one species of sea urchin blocks archenteron elongation/attachment in another species. Here we show in three repeated experiments, with 30 replicate samples for each condition, that the same concentration of S. purpuratus hyalin (57 microg/ml) that blocked the interaction in living S. purpuratus embryos blocked the same interaction in living Lytechinus pictus embryos. These results correspond with the known crossreactivity of antibody against S. purpuratus hyalin with L. pictus hyalin. We propose that hyalin-hyalin receptor binding may mediate this adhesive interaction. The use of a microplate assay that allows precise quantification of developmental effects should help facilitate identification of the function of hyalin in organisms as divergent as bacteria and humans.     

Role of syndecan in the elongation of postoral arms in sea urchin larvae

Ac-SYN is the core protein of a cell surface proteoglycan of the sea urchin Anthocidaris crassispina. To examine the functions of Ac-SYN, embryos were cultured in the presence of affinity-purified antibody against Ac-SYN. At the late pluteus stage, severe inhibition of elongation of the postoral arms was seen in treated embryos compared with control embryos. Blastocoeleic microinjection of the antibody did not affect morphogenesis. The relationship between the number of cells in the postoral arms and the length of the postoral rods was investigated in normal embryos. This showed that postoral arm elongation has two phases: the first phase accompanies the increase in cell numbers while the second does not. The syndecan antibody inhibited the increase in cell numbers in the postoral arms. Furthermore, in the treated embryos, cell numbers continued to increase normally until 31 h post fertilization (hpf), while cell division stopped after 31 hpf. These results suggest that Ac-SYN participates in postoral arm formation via cell division in sea urchin embryos.     

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.     

Expression of univin, a TGF-beta growth factor, requires ectoderm-ECM interaction and promotes skeletal growth in the sea urchin embryo

Pl-nectin is an ECM protein located on the apical surface of ectoderm cells of Paracentrotus lividus sea urchin embryo. Inhibition of ECM-ectoderm cell interaction by the addition of McAb to Pl-nectin to the culture causes a dramatic impairment of skeletogenesis, offering a good model for the study of factor(s) involved in skeleton elongation and patterning. We showed that skeleton deficiency was not due to a reduction in the number of PMCs ingressing the blastocoel, but it was correlated with a reduction in the number of Pl-SM30-expressing PMCs. Here, we provide evidence on the involvement of growth factor(s) in skeleton morphogenesis. Skeleton-defective embryos showed a strong reduction in the levels of expression of Pl-univin, a growth factor of the TGF-beta superfamily, which was correlated with an equivalent strong reduction in the levels of Pl-SM30. In contrast, expression levels of Pl-BMP5-7 remained low and constant in both skeleton-defective and normal embryos. Microinjection of horse serum in the blastocoelic cavity of embryos cultured in the presence of the antibody rescued skeleton development. Finally, we found that misexpression of univin is also sufficient to rescue defects in skeleton elongation and SM30 expression caused by McAb to Pl-nectin, suggesting a key role for univin or closely related factor in sea urchin skeleton morphogenesis.     

Study of larval and adult skeletogenic cells in developing sea urchin larvae

The larval skeleton of sea urchin embryos is formed by primary mesenchyme cells (PMCs). Thereafter, the larvae start feeding and additional arms develop. An adult rudiment that contains spines, tube feet, tests, and other parts of the adult body is formed in the eight-armed larva. The cellular mechanism of the later skeletogenesis and the lineage of the adult skeletogenic cells are not known. In this study, the morphogenesis of larval and adult skeletons during larval development of the sea urchin Hemicentrotus pulcherrimus was investigated by immunostaining cells with PMC-specific monoclonal antibodies, which are useful markers of skeletogenic cells. All spicules and the associated cells in the later larvae were stained with the antibodies. We could observe the initiation of skeletal morphogenesis at each developmental stage and visualize the cellular basis of skeleton formation in whole-mount embryos that possessed an intact morphology. There were some similarities between PMCs and the later skeletogenic cells. Both had a rounded shape with some filopodia, and the antigen expression started just before overt spicule formation. In the later-stage embryos, cells with filopodia and faint antigen expression were observed migrating in the blastocoel or aggregating in the presumptive location of new skeletogenesis.     

Septate junctions mediate the barrier to paracellular permeability in sea urchin embryos

In sea urchin embryos, blastula formation occurs between the seventh and tenth cleavage and is associated with changes in the permeability properties of the epithelium although the structures responsible for mediating these changes are not known. Tight junctions regulate the barrier to paracellular permeability in chordate epithelia; however, the sea urchin blastula epithelium lacks tight junctions and instead possesses septate junctions. Septate junctions are unique to non-chordate invertebrate cell layers and have a characteristic ladder-like appearance whereby adjacent cells are connected by septa. To determine the function of septate junctions in sea urchin embryos, the permeability characteristics of the embryonic sea urchin epithelia were assessed. First, the developmental stage at which a barrier to paracellular permeability arises was examined and found to be in place after the eighth cleavage division. The mature blastula epithelium is impermeable to macromolecules; however, brief depletion of divalent cations renders the epithelium permeable. The ability of the blastula epithelium to recover from depletion of divalent cations and re-establish a barrier to paracellular permeability using fluorescently labelled lectins was also examined. Finally, septate junction structure was examined in embryos in which the permeability status of the epithelium was known. The results provide evidence that septate junctions mediate the barrier to paracellular permeability in sea urchin embryos.     

Alteration of sea urchin embryo cell surface properties by mycostatin, a sterol binding antibiotic

Sea urchin embryos incubated in sea water containing mycostatin (MST), a polyene antibiotic, dissociate into single cells. Reaggregation of dissociated sea urchin embryo cells, and uptake of labeled precursors by these cells are also greatly inhibited although O₂ consumption is only slightly affected by this compound. It is known that mycostatin binds primarily to membrane sterols and affects only cells containing membrane sterols. Sea urchin cell membranes contain sterols. The effects of mycostatin on cell adhesion, reaggregation, and permeability seen in this study may be a result of an interaction with cell membrane sterols or sterol-associated molecules.     

The sea urchin multicatalytic protease: purification, biochemical analysis, subcellular distribution, and relationship to snRNPs

We have purified and extensively characterized a 19-S particle from sea urchin eggs. This particle is the sea urchin homologue of the "prosome", a particle originally identified in duck erythroblasts. We now show that these sea urchin prosomes contain multiple proteolytic activities. As shown for analogous particles from other cells, these particles hydrolyze synthetic substrates containing neutral hydrophobic or basic amino acids at the carboxy terminus of the synthetic peptides. They contain 16-20 small proteins ranging in molecular weight from 20,000 to 32,000. Peptide mapping shows that most of the polypeptides are unique, however, three exist in two isoelectric forms. We have investigated the possible function of the sea urchin multicatalytic proteases (MCPs) by determining their subcellular distribution, their relationship to egg snRNPs, and their possible role in translational repression. There are almost as many MCPs (2 x 10(8] as ribosomes (6.6 x 10(8] or mRNPs (1.8 x 10(7] per egg. This suggests that like ribosomes, the MCPs are stored in the egg for use during later development. We find that a substantial proportion of egg MCPs move into nuclei by the late blastula stage. Using a specific antibody against one of the sea urchin MCP proteins and antibodies against U1-U6, La, and Ro RNPs, we show that the sea urchin particle is distinct from these RNPs, although the anti-U1-U6 RNP antibody cross-reacts with a single MCP protein. In addition, the sea urchin MCP appears to be associated with a large structure in the cytoplasm of unfertilized eggs and is released under the same conditions that activate egg mRNPs in vitro.     

DNA Polymerase Potentials of Sea Urchin Embryos

THE possible involvement of RNA-instructed DNA polymerase in differentiation has been proposed by Temin¹. Here we present evidence that partially purified polymerase fractions prepared from 16-cell sea urchin embryos, which can undergo normal development through gastrulation, are able to support RNA-directed, as well as the expected DNA-directed, DNA synthesis. The results reported lead us to suggest that the observed RNA-instructed DNA synthesis may be mediated by polymerases other than that responsible for DNA-dependent DNA synthesis.     

Glycoprotein synthesis in developing sea urchin embryos

Surface membrane glycoproteins have been postulated in many mammalian cells to be involved in external surface membrane functions such as cell adhesion, cell-cell recognition, and cell movement. In developing echinoderm embryos, cell adhesion, recognition, and movement of individual cell types have been attributed to differences in the external surface membranes of these cells. Results reported here suggest that the three cell types of 16-cell sea urchin embryos have a mechanism that could establish differences in the carbohydrate portion of glycoproteins located in the external surface membrane. The results demonstrate 1) that glycoproteins are synthesized during early sea urchin development and 2) that slightly different rates of glycoprotein synthesis exist for the three types of blastomeres from 16-cell sea urchin embryos.     

Receptor activity of rotavirus nonstructural glycoprotein NS28.

Rotavirus morphogenesis involves the budding of subviral particles through the rough endoplasmic reticulum (RER) membrane of infected cells. During this process, particles acquire the outer capsid proteins and a transient envelope. Previous immunocytochemical and biochemical studies have suggested that a rotavirus nonstructural glycoprotein, NS28, encoded by genome segment 10, is a transmembrane RER protein and that about 10,000 Mr of its carboxy terminus is exposed on the cytoplasmic side of the RER. We have used in vitro binding experiments to examine whether NS28 serves as a receptor that binds subviral particles and mediates the budding process. Specific binding was observed between purified simian rotavirus SA11 single-shelled particles and RER membranes from SA11-infected monkey kidney cells and from SA11 gene 10 baculovirus recombinant-infected insect cells. Membranes from insect cells synthesizing VP1, VP4, NS53, VP6, VP7, or NS26 did not possess binding activity. Comparison of the binding of single-shelled particles to microsomes from infected monkey kidney cells and from insect cells indicated that a membrane-associated component(s) from SA11-infected monkey kidney cells interfered with binding. Direct evidence showing the interaction of NS28 and its nonglycosylated 20,000-Mr precursor expressed in rabbit reticulocyte lysates and single-shelled particles was obtained by cosedimentation of preformed receptor-ligand complexes through sucrose gradients. The domain on NS28 responsible for binding also was characterized. Reduced binding of single-shelled particles to membranes was seen with membranes treated with (i) a monoclonal antibody previously shown to interact with the C terminus of NS28, (ii) proteases known to cleave the C terminus of NS28, and (iii) the Enzymobead reagent. VP6 on single-shelled particles was suggested to interact with NS28 because (i) a monoclonal antibody to the subgroup I epitope on VP6 reduced particle binding, (ii) a purified polyclonal antiserum raised against recombinant baculovirus-produced VP6 reduced ligand binding, and (iii) a monoclonal antibody to a conserved epitope on VP6 augmented ligand binding. These experimental data provide support for the hypothesized receptor role of NS28 before the budding stage of rotavirus morphogenesis.