Protein composition of the hyaline layer of sea urchin embryos and reaggregating cells

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.

Biochemical analysis of hyalin gelation: an essential step in the assembly of the sea urchin extraembryonic matrix, the hyaline layer

We have examined the effects of calcium and magnesium on both the structural characteristics and the self-association reaction of hyalin, a major protein component of the sea urchin extraembryonic matrix, the hyaline layer. In the absence of calcium, the circular dichroic spectrum revealed a protein possessing a high beta sheet content. The presence of increasing concentrations of calcium resulted in an increase in beta sheet content and a coincidental decrease in alpha helix. This effect occurred with an apparent dissociation constant (calcium) of 1.5mM. The calcium-induced structural change was potentiated by magnesium. Similar concentrations of calcium protected hyalin from digestion by trypsin and this effect was potentiated by magnesium. The thermal denaturation profile of hyalin was modulated by calcium. At a concentration of 3mM, calcium protected hyalin from thermal denaturation, an effect partially mimicked, but not potentiated, by magnesium. Calcium was also found to modulate both the intensity and the wavelength of maximal, endogenous tryptophan fluorescence. The effect of calcium on hyalin tertiary structure had a concentration dependence decidedly different from those reported above with an apparent dissociation constant of 0.18 mM. Collectively, these results delineate two distinct roles for calcium in modulating hyalin structure and allow us to define the pathway leading to hyalin-gel formation.

The apical lamina and its role in cell adhesion in sea urchin embryos

The hyaline layer (HL) is an extracellular matrix surrounding sea urchin embryos which has been implicated in a cell adhesion and morphogenesis. The apical lamina (AL) is a fibrous meshwork that remains after removal of hyalin from the HL and the fibropellins (FP) are glycoproteins thought to be the principal components of the AL. Using anti-FP antibodies (AL-1 and AL-2) we report immunoprecipitations and affinity purifications yield a high molecular weight complex comprised of the FP glycoproteins. The three components form a complex, stabilized by disulphide cross-linking and have stochiometric ratios of 2 FPIa molecules to 1 each of FPIb and FPIII. Pulse chase experiments indicate all 3 FP's are synthesized throughout development with peaks in synthesis during cleavage and a sustained peak beginning at hatching. Using immunogold and immunoperoxidase localization, the FP localize to a fibrillar complex forming the innermost layer of the HL. In cell adhesion experiments, cells adhere to affinity purified FP in a temperature, time and concentration dependent manner. Cell adhesion to Fp is about 70% of that seen when hyalin is used as a substrate. Pretreating with AL-1 and AL-2 reduces in vitro cell adhesion by about 65%. We conclude FP's form a fibrillar complex, which is synthesized throughout early development and functions, with other components of the HL, as a substrate for cell adhesion.

Hyalin, a sea urchin extraembryonic matrix protein: relationship between calcium binding and hyalin gelation

The protein hyalin, a major component of the sea urchin extraembryonic hyaline layer, was previously shown to undergo a Ca(2+)-induced self-association into large aggregates (gelation). This reaction represented a major step in assembly of the layer. In the experiments reported here, digestion with trypsin resulted in a rapid dissociation of hyalin into a mixture of peptides which retained the capacity to bind Ca2+. However, unlike intact hyalin, none of these peptides associated into large aggregates (gelation) in the presence of Ca2+, Mg2+, and NaCl. Loss of the ability to undergo gelation was not accompanied by any significant change in the content of acidic plus amide amino acid residues. Decreasing the pH to 5.6 resulted in a loss of 25% of hyalin's Ca(2+)-binding capacity but had no effect on the ability of the protein to undergo gelation. Peptide fragments were only partially effective at inhibiting hyalin gelation. Clearly, not all the Ca(2+)-binding sites were required for hyalin gelation and Ca2+ binding alone was insufficient to drive this reaction. In addition, hyalin appeared to possess two classes of protein-protein interaction domains, one of which was essential for gelation.

Protein-protein interactions and structural entities within the sea urchin extraembryonic matrix, the hyaline layer

We have investigated the effects of a variety of experimental conditions on the structural integrity of the sea urchin extraembryonic matrix, the hyaline layer. Removal of Ca2+ resulted in the quantitative release of hyalin from isolated layers. Protein gel blot analyses indicated that, in the absence of Ca2+, hyalin was also quantitatively released from the layers surrounding 1-h-old embryos. However, no other polypeptides of the hyaline layer were released in significant amounts. The layers remaining after removal of hyalin were refractory to digestion with proteinase K and dissociated only in the presence of chaotropes. These results provide insights into the structural organization within the hyaline layer as well as the role of the embryonic cell surface in maintaining the structural integrity of this extraembryonic matrix.

Ultrastructural study of the hyaline layer of the starfish embryo, Pisaster ochraceus

The hyaline layer (HL) is a multilayered extracellular matrix (ECM) that coats the external surfaces of sea urchin and starfish embryos. It is thought to protect and lubricate the embryo, stabilize the blastomeres during morphogenesis, and regulate nutrient intake. Ultrastructural studies of chemically fixed embryos have shown the HL to consist of two to four sublayers. However, since chemical fixatives may cause collapse and alter the positions and antigenicity of the extracellular components, fixation methods that exclude chemicals may reveal a picture of the HL closer to what is present in vivo. Freeze substitution, a fixation method whereby tissues are rapidly frozen and dehydrated at low temperatures, has proved useful for fixing material rich in ECM. In this study, embryos of the starfish Pisaster ochraceus were fixed for microscopy using freeze substitution and three chemical methods in order to determine, as accurately as possible, the structure of the HL. Embryos appear to be best preserved by freeze substitution and demonstrate a HL consisting of at least six distinct sublayers. Based on staining with anionic dyes, most sublayers appear to contain glycosaminoglycans. Freeze substituted embryos, which were also stained with monoclonal antibodies raised against their ECM, revealed that some molecules are common to all six sublayers, whereas other molecules may be restricted to specific sublayers. This suggests that each sublayer could have a different function. Additional evidence suggests that microvillus associated bodies, present in other marine invertebrate embryos, may anchor the asteroid HL to the cell surface microvilli.

Storage, ultrastructural targeting and function of toposomes and hyalin in sea urchin embryogenesis

This study compares by immunogold labeling the ultrastructural localization of a hexameric 22S glycoprotein, called toposome, with that of hyalin in unfertilized eggs and cells of hatched sea urchin blastulae. Nearly all hyalin is present in the electron translucent compartment of the cortical granules and in the translucent non-cortical pigment granules. In the blastula both of these intracellular stores have vanished and hyalin now forms a broad band below the apical lamina. By contrast, in the egg toposomes are present on the surface, as well as stored in yolk granules and in the electron dense lamellar compartment of the cortical granules. In the hatched blastula, toposomes that have been modified by limited proteolysis in the yolk granules, are associated with the plasma membranes of all newly formed cells, while the toposomes originating from the cortical granules have been incorporated as unmodified 160 kDa polypeptides into an extracellular double layer enveloping the embryo on the outside of the hyaline layer. From evidence discussed in detail, we conclude that the extracellular toposomes rivet the apical lamina to the surface and underlying cytoskeleton of the microvilli, while the modified toposomes from the yolk granules are responsible for position specific intercellular adhesion as they are released to the surface of newly formed cells. We propose that all the material stored in yolk granules is utilized for the assembly of new membranes.

Elongated microvilli support the sea urchin embryo concentrically within the perivitelline space until hatching

The early sea urchin embryo is supported in a concentric position within the perivitelline space by elongated microvilli which are attached to the fertilization envelope by extracellular matrix fibers. This "attachment complex," of microvillus tip: extracellular matrix fibers: fertilization envelope, was revealed by two methods: the use of pronase or calcium-free sea water to dissolve the extracellular matrix fibers, thus causing the eggs to lose their concentric location, and the visualization of the "attachment complex" using video-enhanced differential interference contrast microscopy and transmission electron microscope images. The presence of the "attachment complex" helps in understanding two types of early developmental events: (1) the apparently continual change in microvillus length during cleavage stages which retains the embryos in their concentric position and (2) the hatching process.

Extracellular matrix of sea urchin and other marine invertebrate embryos

The extracellular matrix surrounding the sea urchin embryo (outer ECM) contains fibers and granules of various sizes which are organized in recognizable patterns as shown by ultrastructural studies, particularly stereoimaging techniques. The use of the ruthenium red method for retaining and staining the ECM, with modifications of the Luft (Anatomical Record 171:347-368, 1971) method for invertebrate embryos, allows for the clarification of certain structures, particularly fiber compaction in the interzonal region, and microvillus-associated bodies. The inner ECM in the sea urchin embryo includes the basal lamina and blastocoel matrix. Stereoimages show that the fibers which are loosely distributed in the blastocoel matrix become compacted around the periphery of the blastocoel to form the basal lamina. The ruthenium red method was also used on a number of marine invertebrate embryos and larvae, representing different phyla, to facilitate comparisons between their surface coats. The similarities observed in the specimens shown suggest that ECMs are widely found on marine invertebrate eggs, embryos, and larvae, and that they resemble vertebrate ECMs and may, therefore, have similar functions.

Developmentally regulated proteolytic processing of a yolk glycoprotein complex in embryos of the sea urchin, Strongylocentrotus purpuratus

We have isolated a yolk glycoprotein complex from eggs and early embryos of the sea urchin, Strongylocentrotus purpuratus. Sodium dodecyl sulfate polyacrylamide gel electrophoresis of these complexes and peptide mapping of their individual glycoprotein components indicate that developmental stage-specific changes in molecular composition of the complex are due to proteolytic processing events. Our data revealed that a 180 kDa glycoprotein of the egg complex is separated by a single proteolytic cleavage into intermediate glycoproteins of 115 and 76 kDa early in development. By the hatched blastula stage, each of these intermediate glycoproteins has been further processed to lower molecular weight forms: the 115 kDa protein is proteolytically clipped to a 84 kDa form, perhaps through 110 and 105 kDa intermediaries, while the 76 kDa molecule is directly processed to a 65 kDa form.

Echinonectin: a new embryonic substrate adhesion protein

An extracellular matrix molecule has been purified from sea urchin (Lytechinus variegatus) embryos. Based on its functional properties and on its origin, this glycoprotein has been given the name "echinonectin." Echinonectin is a 230-kD dimer with a unique bow tie shape when viewed by electron microscopy. The molecule is 12 nm long, 8 nm wide at the ends, and narrows to approximately 4 nm at the middle. It is composed of two 116-kD U-shaped subunits that are attached to each other by disulfide bonds at their respective apices. Polyclonal antibodies were used to localize echinonectin in paraffin-embedded, sectioned specimens by indirect immunofluorescence. The protein is stored in vesicles or granules in unfertilized eggs, is released after fertilization, and later becomes localized on the apical surface of ectoderm cells in the embryo. When used as a substrate in a quantitative in vitro assay, echinonectin is highly effective as an adhesive substrate for dissociated embryonic cells. Because of the quantity, pattern of appearance, distribution, and adhesive characteristics of this protein, we suggest that echinonectin serves as a substrate adhesion molecule during sea urchin development.

Roles for Ca2+, Mg2+ and NaCl in modulating the self-association reaction of hyalin, a major protein component of the sea-urchin extraembryonic hyaline layer

The self-association reaction of hyalin, a major protein component of the sea-urchin extraembryonic hyaline layer, was examined. Concentrations of Ca2+ below 1 mM had little effect on the hyalin gelation reaction, but higher concentrations of the cation induced protein aggregation. Quantitative aggregate formation required a Ca2+ concentration in excess of 10 mM. This reaction was modulated by both NaCl and Mg2+. The effectiveness of Ca2+ in inducing hyalin gelation was markedly enhanced in the presence of 500 mM-NaCl, the concentration found in sea water. Similarly, 20 mM-Mg2+ also enhanced Ca2+-induced hyalin gelation. Neither NaCl nor Mg2+ alone induced hyalin gelation. Concentrations of Ca2+ as low as 1 mM effectively protected hyalin from tryptic digestion both in the presence and in the absence of 500 mM-NaCl. The latter result suggested that, although higher concentrations of Ca2+ were required to induce the hyalin gelation reaction, lower concentrations of the cation could mediate a protein-protein interaction in an NaCl-independent fashion. These results identify the parameters that modulate hyalin self-association, a reaction that is essential for hyaline-layer assembly around the developing sea-urchin embryo.

A regulatory domain that directs lineage-specific expression of a skeletal matrix protein gene in the sea urchin embryo

DNA sequences derived from the 5' region of a gene coding for the 50-kD skeletal matrix protein (SM50) of sea urchin embryo spicules were linked to the CAT reporter gene and injected into unfertilized eggs. CAT mRNA and enzyme were synthesized from these fusion constructs in embryos derived from these eggs, and in situ hybridization with a CAT antisense RNA probe demonstrated that expression is confined to skeletogenic mesenchyme cells. A mean of 5.5 of the 32-blastula-stage skeletogenic mesenchyme cells displayed CAT mRNA (range 1-15), a result consistent with earlier measurements indicating that incorporation of the exogenous injected DNA probably occurs in a single blastomere during early cleavage. In vitro mutagenesis and deletion experiments showed that CAT enzyme activity in the transgenic embryos is enhanced 34-fold by decreasing the number of SM50 amino acids at the amino-terminus of the fusion protein from 43 to 4. cis-regulatory sequences that are sufficient to promote lineage-specific spatial expression in the embryo are located between -440 and +120 with respect to the transcriptional initiation site.

Role of calcium in stabilizing the structure of hyalin, a major protein component of the sea urchin extraembryonic hyaline layer

The interactions of NaCl and CaCl2 with the sea urchin embryo coat protein hyalin were investigated. Endogenous protein tryptophan fluorescence was enhanced by almost 45% in the presence of 200mM NaCl while 1mM CaCl2 reversed this effect and brought the intensity of fluorescence back close to that of the native protein. Half-maximal concentrations of 53 and 0.32mM were determined for NaCl and Ca+2, respectively. Hyalin conformation, as measured by circular dichroic spectroscopy, was altered by NaCl and CaCl2 in a fashion parallel to the effects of these salts on tryptophan fluorescence. Sodium chloride disrupted hyalin secondary structure while CaCl2 affected the return of hyalin to its native conformation. The interactions of NaCl and CaCl2 with hyalin were not modulated by MgCl2. These results suggest a role for CaCl2 in stabilizing hyalin against the disruptive effects of the high concentration of NaCl present in sea water.

Storage and mobilization of extracellular matrix proteins during sea urchin development

After fertilization, sea urchin embryos surround themselves with an extracellular matrix, or hyaline layer, to which cells adhere during early development. Hyalin, the major protein component of the hyaline layer has been isolated and partially characterized in several laboratories. Although other proteins are present in the hyaline layer, little is known about their origin, distribution, or functions. The present report characterizes a set of hyaline layer proteins that are secreted after fertilization from a class of vesicles that are distinct from cortical granules. The group of proteins in these vesicles were identified by a monoclonal antibody (8d11) which recognizes a carbohydrate epitope common to each of these molecules. 8d11 polypeptides range in molecular weight from 105 to 225 kDa. Oogonia and oocytes in early stages of vitellogenesis do not express the antigen. The proteins are first observed by immunofluorescence during oogenesis as a peripheral band in mid-vitellogenic oocytes. Following germinal vesicle breakdown 8d11 moves to be distributed evenly throughout the cytoplasm. The proteins are transported to the egg surface by a cytochalasin-sensitive mechanism after fertilization, and secreted predominately within the first 30 min of development. 8d11 proteins are depleted in areas of cell contact during early embryogenesis, and become concentrated on the apical surface of ectoderm cells where they are assembled into high-molecular-weight aggregates. Three of the molecules in this group may be proteins previously described as "apical lamina" proteins. These observations provide evidence of a third pathway (cortical granules and basal lamina granules being the other two) for synthesis, storage, and exocytosis of matrix proteins that are release after fertilization.

Dissociation of cells from sea urchin embryos alters the synthesis of actins and other proteins

The effects of altered cellular microenvironments on patterns of protein synthesis at various periods during sea urchin development were quantitated by comparing the relative incorporation of [35S]methionine into selected polypeptides of intact embryos and cells dissociated from them. The effects of increasing times of reassociation were also determined. Quantitative, but not qualitative, differences in incorporation were noted. Actins, as well as heterogeneous acidic polypeptides with an Mr of about 80 kDa, showed increased incorporation in dissociated cells labeled at the time control embryos were recently hatched blastulae. Labeling of another acidic group of polypeptides with an Mr of about 100 kDa was decreased. Possible mechanisms regulating these shifts in incorporation were investigated by the use of inhibitors. The dissociation-triggered changes were insensitive to actinomycin D, cordycepin, dibutyryl cAMP, 3-isobutyl-1-methylxanthine, and trifluoperazine; however, the latter two stimulated incorporation into some polypeptides in intact blastulae. Age-dependent shifts in incorporation were also detected in both intact embryos and dissociated/reassociating cells.

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.