Immunohistochemical localization of a tenascin-like extracellular matrix protein in sea urchin embryos

Summary We have used polyclonal antisera raised against vertebrate tenascin to identify and localize tenascin-like proteins in the developing sea urchin. These antisera recognize high-molecular weight proteins on immunoblots of sea urchin embryo homogenates that are similar in size and appearance to tenascin from vertebrates. These proteins appear as a doublet with an apparent molecular weight of 150 kDa and a larger, broad band with an apparent molecular weight of 350 kDa. Whole mounts of sea urchin embryos and larvae were stained with one of these antisera. The anti-tenascin stained the surface of primary mesenchyme cells during their phase of active migration. This staining was sensitive to detergent, suggesting that the protein recognized by the antiserum was associated with the cell surface. During later stages of development, the bulk of the antitenascin staining was found dispersed throughout the blastocoel matrix, and was no longer sensitive to detergent. We conclude that sea urchins express tenascin-like proteins during early stages of development, and that these proteins may play a role associated with primary mesenchyme cell morphogenesis.     

Micromere-specific cell surface proteins of 16-cell stage sea urchin embryos

Evidence is presented of cell-type specificity of surface proteins from the 16-cell stage sea urchin embryo. The protein composition of the micromere cell surface has been examined by 125I labelling of intact cells followed by SDS-PAGE. In Arbacia punctulata, four high molecular weight (HMW) proteins are detected on the surface of isolated micromeres--but not on mesomere-macromere fractions. In Strongylocentrotus droebachiensis, a micromere-specific protein of 133 K molecular weight (MW) was identified. This 133 K protein binds to wheat germ agglutinin (WGA) but not to concanavalin A (conA). Lectin binding was studied using a new technique. The procedure involves the separation, by SDS-PAGE, of iodinated cell-surface proteins followed by their electrophoretic transfer to lectin-coated nitrocellulose membranes. Using this procedure, cell-type-specific surface proteins which are also lectin-binding-specific, were detected.     

Cell adhesion during gastrulation : A new approach

In gastrulating sea urchin embryos, secondary mesenchyme cells at the tip of the advancing archenteron extend long narrow filopodia which probe the inner surface of the blastocoele wall, rejecting some surface contacts before adhering to other cells. After specific cell adhesions are made, contractions of the filopodia pull the leading tip of the archenteron to the opposite wall of the blastocoele with an accompanying elongation of the archenteron. A study was made of the biochemistry and morphology of the specific adhesions of filopodial extensions by injecting a variety of compounds into the blastocoele of living sea urchin gastrulae and observing their effects on filopodia and cell movements. A number of agents (proteases, lectins) caused specific filopodial detachment and subsequent archenteron regression. Fluorescein-conjugated lectins, including concanavalin A (conA) and wheat germ agglutinin (WGA) exhibited marked specificity of cell surface binding to specific regions (primary mesenchyme cells, blastocoele wall, etc.) of the embryo.     

Quantitative agglutination of specific populations of sea urchin embryo cells with concanavalin A

It has been demonstrated that specific changes in carbohydrate-containing cell surface lectin receptor sites occur with differentiation and maturation of sea urchin embryo cells. In this study, evidence is presented, using a quantitative electronic particle counter assay to measure agglutination, which indicates that concanavalin A (Con A) mediated agglutination of dissociated 32/64 cell sea urchin embryos differs dramatically with respect to specific cell populations. The migratory cell type, the micromere, is significantly more agglutinable with Con A than the other cell types and colchicine treatment markedly increases sea urchin embryo cell agglutinability. The results indicate that like many malignant cells which display extensive migratory behavior, specific migratory populations of embryonic cells are agglutinable with Con A. The results are discussed with respect to the possible nature of lectin receptor sites on specific populations of embryonic cells and the possible role of colchicine-sensitive structures in controlling the display patterns of these sites.     

Analysis of cytoskeletal and motility proteins in the sea urchin genome assembly

The sea urchin embryo is a classical model system for studying the role of the cytoskeleton in such events as fertilization, mitosis, cleavage, cell migration and gastrulation. We have conducted an analysis of gene models derived from the Strongylocentrotus purpuratus genome assembly and have gathered strong evidence for the existence of multiple gene families encoding cytoskeletal proteins and their regulators in sea urchin. While many cytoskeletal genes have been cloned from sea urchin with sequences already existing in public databases, genome analysis reveals a significantly higher degree of diversity within certain gene families. Furthermore, genes are described corresponding to homologs of cytoskeletal proteins not previously documented in sea urchins. To illustrate the varying degree of sequence diversity that exists within cytoskeletal gene families, we conducted an analysis of genes encoding actins, specific actin-binding proteins, myosins, tubulins, kinesins, dyneins, specific microtubule-associated proteins, and intermediate filaments. We conducted ontological analysis of select genes to better understand the relatedness of urchin cytoskeletal genes to those of other deuterostomes. We analyzed developmental expression (EST) data to confirm the existence of select gene models and to understand their differential expression during various stages of early development.     

Endo16, a lineage-specific protein of the sea urchin embryo, is first expressed just prior to gastrulation

We have isolated and characterized a new endoderm-specific gene, designated Endo16, from a sea urchin gastrula stage cDNA library. Northern blot analysis and in situ hybridization experiments indicate that this gene is first expressed in the vegetal plate, a group of endodermal and mesenchymal precursor cells that are poised to invaginate in the first movement of gastrulation. Expression becomes progressively restricted to a subset of endodermal cells as development proceeds. To study the Endo16 gene product, a polyclonal antiserum was raised against bacterially expressed Endo16 protein. Indirect immunofluorescence experiments in midgastrula stage embryos reveal that the Endo16 protein is localized to the surface of endoderm and secondary mesenchyme cells. In Western blot experiments, the antiserum detects a small set of high molecular weight proteins ranging from 180 to greater than 300 kDa. Analysis of the nucleotide-derived amino acid sequence from a partial Endo16 cDNA clone reveals a highly repetitive, extremely acidic protein segment that includes the Arg-Gly-Asp (RGD) tripeptide known to be important in cell binding domains of a number of extracellular proteins. Taken together, these data suggest that the Endo16 protein may be an adhesion molecule involved in gastrulation of the sea urchin embryo.     

Characterization of bep1 and bep4 antigens involved in cell interactions during Paracentrotus lividus development

We have identified and partially characterised two antigens, extracted with 3% butanol, from Paracentrotus lividus embryos dissociated at the blastula stage, and encoded by the cDNA clones previously described as bep1 and bep4 (bep-butanol extracted proteins). The cDNA fragments containing the specific central portions of bep1 and bep4 were expressed as MS2 polymerase fusion proteins in Escherichia coli. These two fusion proteins, called 1C1 (bep1) and 4A1 (bep4), were injected subcutaneously into rabbits and the corresponding polyclonal antibodies generated. Western blot analysis of proteins, extracted with 3% butanol, from sea urchin embryos at the blastula stage (b.e.p.), established that both antibodies recognize two 33 KDa proteins. Reducing and non-reducing electrophoretic conditions show that both antibodies against bep1 and bep4 related proteins react also with a protein band of a molecular weight 66 KDa, indicating that these two antigens probably exist as dimers. Immunolocalization with anti 1C1 and 4A1 antibodies shows the presence of the related antigens also on the cell surface. Fab fragments of the polyclonal antibodies against 1C1 and 4A1 inhibited reaggregation of sea urchin embryonic cells, dissociated from blastula stage embryos. This prevention of reaggregation indicates that these proteins probably play a role in cell interaction during sea urchin embryonic development.     

LvNotch signaling mediates secondary mesenchyme specification in the sea urchin embryo

Cell-cell interactions are thought to regulate the differential specification of secondary mesenchyme cells (SMCs) and endoderm in the sea urchin embryo. The molecular bases of these interactions, however, are unknown. We have previously shown that the sea urchin homologue of the LIN-12/Notch receptor, LvNotch, displays dynamic patterns of expression within both the presumptive SMCs and endoderm during the blastula stage, the time at which these two cell types are thought to be differentially specified (Sherwood, D. R. and McClay, D. R. (1997) Development 124, 3363-3374). The LIN-12/Notch signaling pathway has been shown to mediate the segregation of numerous cell types in both invertebrate and vertebrate embryos. To directly examine whether LvNotch signaling has a role in the differential specification of SMCs and endoderm, we have overexpressed activated and dominant negative forms of LvNotch during early sea urchin development. We show that activation of LvNotch signaling increases SMC specification, while loss or reduction of LvNotch signaling eliminates or significantly decreases SMC specification. Furthermore, results from a mosaic analysis of LvNotch function as well as endogenous LvNotch expression strongly suggest that LvNotch signaling acts autonomously within the presumptive SMCs to mediate SMC specification. Finally, we demonstrate that the expansion of SMCs seen with activation of LvNotch signaling comes at the expense of presumptive endoderm cells, while loss of SMC specification results in the endoderm expanding into territory where SMCs usually arise. Taken together, these results offer compelling evidence that LvNotch signaling directly specifies the SMC fate, and that this signaling is critical for the differential specification of SMCs and endoderm in the sea urchin embryo.     

Introduction to the Symposium and Studies on the Surfaces of Separated and Synchronized Tumor and Embryonic Cell Populations

Tumor and embryonic cell surfaces are examined in this symposiumwith respect to their roles in cell-cell interactions and inearly development and malignancy. Three sets of studies havebeen recently performed in my laboratory to help elucidate thenature of tumor and embryonic cell surfaces and the means bywhich these cells adhere to each other. We separated an in vivo129/J ascites mouse teratoma into specific subpopuladons ofcells by velocity sedimentation in shallow density gradients.The teratoma consistently separated into two major populations:"large" and "small" cells. Only the large cells displayed "malignant-like"surface characteristics in terms of their agglutinability withcarbohydrate binding lectins. The teratoma cells were also synchronizedin culture with thymidine plus colcemid. In these synchronizedcultures, cellular adhesiveness and glutamine synthetase specificactivity displayed oscillatory patterns with peaks of glutaminesynthetase specific activity occurring just prior to peaks ofadhesivenesss. Also, both glutamine synthetase specific activityand cellular adhesiveness were enhanced by two compounds: actinomycinD and hydrocortisone. Based upon previous work that implicatesL-glutamine in intercellular adhesion, it is not unreasonableto speculate that glutamine synthetase specific activity andcellular adhesiveness may be causally related. The problem ofaltered tumor cell adhesiveness is important because it seems,in part, to be responsible for tumor spread. Finally, the seaurchin embryo system was utilized to identify specific cellsurface carbohydrates that may be involved in intercellularadhesion. In 15 separate experiments with each sugar and with15 different saccharides, D-galactose and N-acetyl-D-galactosaminewere the best inhibitors of rotation-medicated reaggregationof 24-hr sea urchin embryo cells dissociated by removal of divalentcations. ß-galactosidase also inhibited reaggregationof these cells. These results implicate galactopyranosyl-likeresidues in the adhesion of 24-hr sea urchin embryo cells witheach other.     

Polyadenylation of nascent RNA during the embryogenesis of Ilyanassa obsoleta.

It has been demonstrated that specific changes in carbohydrate-containing cell surface lectin receptor sites occur with differentiation and maturation of sea urchin embryo cells. In this study, evidence is presented, using a quantitative electronic particle counter assay to measure agglutination, which indicates that concanavalin A (Con A) mediated agglutination of dissociated $\text{32}\text{64}$ cell sea urchin embryos differs dramatically with respect to specific cell populations. The migratory cell type, the micromere, is significantly more agglutinable with Con A than the other cell types and colchicine treatment markedly increases sea urchin embryo cell agglutinability. The results indicate that like many malignant cells which display extensive migratory behavior, specific migratory populations of embryonic cells are agglutinable with Con A. The results are discussed with respect to the possible nature of lectin receptor sites on specific populations of embryonic cells and the possible role of colchicine-sensitive structures in controlling the display patterns of these sites.     

Sea urchin arylsulfatase,an extracellular matrix component,is involved in gastrulation during embryogenesis

Arylsulfatases (Arses) have been regarded as lysosomal enzymes because of their hydrolytic activities on synthetic aromatic substrates and their lysosomal localization of their enzymatic activities. Using sea urchin embryos, we previously demonstrated that the bulk of Hemicentrotus Ars (HpArs) does not exhibit enzyme activity and is located on the apical surface of the epithelial cells co-localizing with sulfated polysaccharides. Here we show that HpArs strongly binds to sulfated polysaccharides and that repression of the synthesis by HpArs-morpholino results in retardation of gastrulation in the sea urchin embryo. Accumulation of HpArs protein and sulfated polysaccharides on the apical surface of the epithelial cells in sea urchin larvae is repressed by treatment with β-aminopropionitrile (BAPN), suggesting that deposition of HpArs and sulfated polysaccharides is dependent on the crosslinking of proteins such as collagen-like molecules. We suggest that HpArs functions by binding to components of the extracellular matrix.     

Transient appearance of Strongylocentrotus purpuratus Otx in micromere nuclei: Cytoplasmic retention of SpOtx possibly mediated through an α-actinin interaction

At the 16-cell stage, the sea urchin embryo is partitioned along the animal-vegetal axis into eight mesomeres, four macromeres, and four micromeres. The micromeres, unlike the other blastomeres, are autonomously specified to produce skeletogenic mesenchymal cells and are also required to induce the vegetal-plate territory. A long-held belief is that micromeres inherit localized maternal determinants that endow them with their cell autonomous behavior and inducing capabilities. Here, we present evidence that an orthodenticle-related protein, SpOtx appears transiently in nuclei of micromeres but not in nuclei of mesomeres and macromeres. At later stages of development, SpOtx was translocated into nuclei of all cells. To address the possibility that SpOtx was retained In the cytoplasm at early developmental stages we searched for cytoplasmic proteins that interact with SpOtx. A proline-rich region of SpOtx resembling an SH3-binding domain was used to screen an embryo cDNA expression library, and a cDNA clone was isolated and shown to be α-actinin. A yeast two-hybrid analysis showed a specific interaction between the proline-rich region of SpOtx and a putative SH3 domain of the sea urchin α-actinin. Because micromeres lack an actin-based cytoskeleton, the results suggested that, at the vegetal pole of the 16-cell stage embryo, SpOtx was translocated into micromere nuclei, whereas in other blastomeres SpOtx was actively retained in the cytoplasm by binding to α-actinin. The transient appearance of SpOtx in micromere nuclei may be associated with the specification of micromere cell fate. © 1996 Wiley-Liss, Inc.     

Changing localizations of site-specific surface antigens during sea urchin spermiogenesis

Whole mount preparations of dissociated testicular cells from the sea urchin, Strongylocentrotus purpuratus, were exposed to monoclonal antibodies (mAbs) directed against sperm surface proteins. Indirect immunofluorescence microscopy and Western immunoblot analysis show that mAb J18/29 binds to the entire surface of the mature spermatozoon and membrane proteins ranging in relative molecular masses from 25 to 340 kDa. MAb J18/2 binds to the acrosomal and tail regions of the mature spermatozoon and mainly to a 210-kDa membrane protein. MAb J17/30 binds to the midpiece and tail regions and monospecifically to a 60-kDa membrane protein. MAb J16/33 binds specifically to the sperm midpiece but does not bind to Western immunoblots of sperm membrane proteins. With the exception of J16/33, which shows a punctate binding pattern, all of these mAbs show uniform binding over the entire surface of the early spermatid. This uniform and complete surface binding is observed through all stages of spermiogenesis for mAb J18/29. By the midspermatid stage, when tail formation first begins, but before the nucleus condenses and the cytoplasm decreases in volume, localized binding patterns of mAbs J17/30 and J16/33 become evident. Localized binding of mAb J18/2 is not observed until the late spermatid stage. These results show that the sea urchin sperm surface is composed of at least four different domains and provide the first insight into differentiation of the cell surface during sea urchin spermatogenesis.     

Plasma membrane proteins of embryo cells of various sea urchin species and hybrid embryo]

Differences are observed in plasma membrane proteins of S. intermedius and S. droebachiensis sea urchin embryo cells isolated at middle blastula stage by means of acrylamide-gel electrophoresis in presence of SDS, urea or non-ionic detergents--Triton X-100 or Brij 35. Electrophoretic mobilities of plasma membrane proteins of sea urchin hybrid embryo malemale S. intermedius X femalefemale S. droebachiensis were identical with electrophoretic mobilities of plasma membrane proteins of maternal species S. droebachiensis. Three sea urchin embryo species under study had just the same biosynthesis of plasma membrane proteins at middle blastula stage detected by 14C-aminoacids pulse-labeling followed by membrane isolation, electrophoresis and gel-autoradiography.     

Inhibition by aphidicolin of cell cycle progression and DNA replication in sea urchin embryos.

We have recently found that aphidicolin, a tetracyclic diterpene-tetraol produced by several fungi, blocks DNA synthesis of sea urchin embryos by interfering with the activity of DNA polyermase alpha. These cells fail to proliferate in the presence of aphidicolin. In continuation of these studies, we determined the drug-sensitive stage in the first cell cycle of the sea urchin Clypeaster japonicus embryo. In continuous exposure to aphidicolin (2 micrograms/ml) from five minutes after fertilization, mitotic division of the embryo was completely suppressed. Embryos were exposed to the drug at progressively later intervals and their capability for cytokinesis was examined. Evidence was thereby obtained that aphidicolin acts at the S-period to inhibit DNA synthesis resulting in developmental arrest of the embryo.     

Protease-insensitive sea urchin embryo cell adhesions become protease sensitive in the presence of azide or cytochalasin B

To understand the nature of the cell adhesions that must be modified during sea urchin embryo primary mesenchyme formation, we are studying the adhesive components of the hatched blastula stage embryo of Strongylocentrotus purpuratus. Pronase treatment conditions have been defined that leave the cells intact and able to recover from the effects of the protease upon its removal. Under these conditions, adhesion of the cells to tissue culture plates is totally eliminated, but cell-cell adhesion formation is only partially inhibited. Analysis of iodinated cell surface proteins indicates that most are affected by thepronase. Further studies of pronase effects found that sodium azide-treated cells are slightly adhesive and that pronase treatment of azidc-treated cells totally eliminates cell-cell adhesions.     

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.     

Effects of retinoic acid and dimethylsulfoxide on the morphogenesis of the sea urchin embryo

Sea urchin embryos of the species Paracentrotus lividus were treated continuously with different concentrations of all-trans retinoic acid (RA) or dimethylsulfoxide (DMSO) at different developmental stages. A delay in embryonic development was observed when embryos were cultured in the presence of 2x10^?5 M RA, between 1 and 12 hours of development. Hence, at 48 hours of development, while control embryos had reached the pluteus stage, RA-treated embryos were at the prism stage. At 72 hours of development RA-treated embryos recovered and continued normal development reaching the pluteus stage. No effect was observed when treatment was performed before 1 hour or after 12 hours of developmet. DMSO treatment had no effect on normal sea urchin embryo development, although we observed that pigment cells, clearly visible at the pluteus stage, become visible earlier with respect to control embryos. This report confirms the advantages that the sea urchin embryo offers for the study of problems in cellular and developmental biology.