Resolution and characterization of a major protein of the sea urchin hyaline layer

A major protein component of the gel-like, embryonic hyaline layer of Strongylocentrotus purpuratus has been purified and characterized. The protein retains the ability to form an insoluble gel in the presence of specific divalent cations, a property characteristic of the hyaline material. Using a light scattering assay developed to measure the initial rate of hyalin gelation, we have been able to show that calcium alone is capable of initiating this reaction but that calcium and magnesium are synergistic in their effect. In the absence of divalent cations, the major hyalin protein has a molecular weight of 9.2 +/- 0.5 X 10(5) and a sedimentation coefficient of 11.6 S; these and other data indicate that the protein assumes a very elongated, rod-like structure in solution. Smaller amounts of two additional proteins, 8.8 and 6.5 S, are present in the hyalin fraction when the jelly coat and vitelline layer are subjected to a more stringent acid treatment early in the isolation procedure.     

A calcium-insoluble 6.4 S protein derived from sea urchin cortical granule exudate

A major protein component of the sea urchin, Strongylocentrotus purpuratus, cortical granule exudate has been purified and characterized. In the absence of divalent cations, the native, soluble protein has a sedimentation coefficient at infinite dilution of 6.4 S and a molecular weight from sedimentation equilibrium measurements of 2.8 +/- 0.3 X 10(5). These and other data indicate that the protein assumes an elongated, rod-like structure in solution. The protein is greater than 95% homogeneous as judged by agarose- and sodium dodecyl sulfate-gel electrophoresis. In the latter experiments, the protein shows a relative molecular weight of 1.8 X 10(5) and is clearly distinct from the 11.6 S protein described earlier which shows two bands corresponding to 3.2 X 10(5) and 2.1 X 10(5). The 6.4 S protein is the major protein of the calcium-insoluble fraction of cortical granule exudate and contributes to the formation of the extracellular investments of the sea urchin embryo. Using a light-scattering assay, we show that the purified protein retains the ability to aggregate in the presence of divalent cations mirroring its assembly in vivo. Calcium ion alone is able to initiate this reaction and the rate of precipitation increases with calcium concentration. Magnesium alone is ineffective in this regard but, in combination, the two ions act synergistically. Strontium and barium can substitute for calcium, but higher concentrations of the former cations are required to produce an equivalent effect.     

CELL-BINDING SUBSTANCES IN SEA URCHIN EMBRYOS*

Properties of ovacquenin, a reaggregation-promoting substance from sea urchin embryos, were further studied and compared with those of hyalin, a calcium-insoluble protein of the hyaline layer surrounding the sea urchin embryo. Properties of hyalin were basically in agreement with previous reports, but differed in some aspects. Hyalin and ovacquenin were very similar in various aspects and were hard to distiguish generally, but they were separated by ammonium sulfate fractionation. Hyalin was precipitated at a low salt concentration, while ovacquenin remained soluble until the salt concentration exceeded half saturation. Therefore it was concluded that hyalin and ovacquenin are very much alike but distinct from each other. Probable relation of ovacquenin to hyalin was discussed.     

SOME PROPERTIES OF HYALIN : The Calcium-Insoluble Protein of the Hyaline Layer of the Sea Urchin Egg

The principal protein component of the hyaline layer of sea urchin eggs is the calcium-insoluble protein first described by Kane and Hersh. The protein hyalin is abnormally high in acidic amino acids, almost devoid of basic amino acids, and characteristically rich in valine and proline. Essentially all of the cysteine present is found in the disulfide form; no evidence points to intermolecular disulfide linkages. Hyalin from several species has a minimal subunit weight of about 100,000, though evidence exists for a particle three times this weight in urea or guanidine hydrochloride from one species. Optical rotatory dispersion measurements indicate no α-helix content, though the dispersion has unique characteristic features. Addition of small quantities of calcium causes hyalin to gel to a birefringent fibrous form. The fibrous, birefringent form of hyalin is rendered isotropic upon addition of EDTA, but the birefringence is restored with re-addition of divalent cation.     

Sea urchin morphogenesis and cell-hyalin adhesion are perturbed by a monoclonal antibody specific for hyalin

We have generated and characterized a monoclonal antibody (McA Tg-HYL) that recognizes sea urchin hyalin as evidenced by immunofluorescence staining of the hyaline layer (HL) and immunoblot staining of the hyalin protein band. On immunoblots of HL extracts only the hyalin protein reacted with McA Tg-HYL. Immunoprecipitates of radioactive proteins from embryos incubated with [35S]methionine yielded radioactive hyalin and 190, 140 and 105 x 10(3) Mr proteins associated with hyalin. McA Tg-HYL was generated against Tripneustes gratilla embryos but reacts with hyalin from the distantly related sea urchin species, Colobocentrotus atratus, Strongylocentrotus purpuratus, Arbacia punctulata, Lytechinus variegatus and Lytechinus pictus. Developing embryos of the above-mentioned six species were treated with McA Tg-HYL and did not gastrulate or form arms. Observations of treated embryos revealed areas of separation of the hyaline layer from the underlying embryonic cells, suggesting that McA Tg-HYL was interfering with binding of the cells to the HL. Using the centrifugation-based adhesion assay of McClay et al. (Proc. natn. Acad. Sci. U.S.A. 78, 4975-4979, 1981), Fab' fragments of McA Tg-HYL were found to inhibit cell-hyalin binding. McA Tg-HYL did not inhibit hyalin gelation in vitro or the reaggregation of dissociated blastula cells. We postulate that McA Tg-HYL recognizes an evolutionarily conserved hyalin domain involved in cell-hyalin binding and required for normal epithelial folding.     

Exogenous hyalin and sea urchin gastrulation. Part III: biological activity of hyalin isolated from Lytechinus pictus embryos

Hyalin is a large glycoprotein, consisting of the hyalin repeat domain and non-repeated regions, and is the major component of the hyaline layer in the early sea urchin embryo of Strongylocentrotus purpuratus. The hyalin repeat domain has been identified in proteins from organisms as diverse as bacteria, sea urchins, worms, flies, mice and humans. While the specific function of hyalin and the hyalin repeat domain is incompletely understood, many studies suggest that it has a functional role in adhesive interactions. In part I of this series, we showed that hyalin isolated from the sea urchin S. purpuratus blocked archenteron elongation and attachment to the blastocoel roof occurring during gastrulation in S. purpuratus embryos, (Razinia et al., 2007). The cellular interactions that occur in the sea urchin, recognized by the U.S. National Institutes of Health as a model system, may provide insights into adhesive interactions that occur in human health and disease. In part II of this series, we showed that S. purpuratus hyalin heterospecifically blocked archenteron-ectoderm interaction in Lytechinus pictus embryos (Alvarez et al., 2007). In the current study, we have isolated hyalin from the sea urchin L. pictus and demonstrated that L. pictus hyalin homospecifically blocks archenteron-ectoderm interaction, suggesting a general role for this glycoprotein in mediating a specific set of adhesive interactions. We also found one major difference in hyalin activity in the two sea urchin species involving hyalin influence on gastrulation invagination.     

Sea urchin egg hyaline layer: evidence for the localization of hyalin on the unfertilized egg surface

The sea urchin embryo hyaline layer is an extracellular investment which develops within 20 min postinsemination of Strongylocentrotus purpuratus eggs and contains a single calcium-precipitable subunit termed hyalin. Other ultrastructural and biochemical studies have suggested that hyalin is localized in the cortical granules. We have examined the hypothesis that hyalin is a cell surface protein of the unfertilized egg using vectorial lactoperoxidase-catalyzed radioiodination. Extracts of labeled unfertilized eggs contained several labeled proteins, one of which was electrophoretically indistinguishable from authentic hyalin isolated by each of three different procedures. Pronase digestion of labeled unfertilized eggs removed 75% of the label, but the labeled hyalin-like molecule was still present in whole cell extracts. Upon insemination, pronase-digested, labeled eggs formed an apparently normal hyaline layer and whole cell extracts contained the labeled hyalin-like molecule. Denuded, labeled eggs were inseminated and the hyaline layer was selectively solubilized in calcium- and magnesium-free artificial seawater. Labeled hyalin was purified from this crude hyalin preparation to constant specific radioactivity and apparent homogeneity as shown by gel electrophoresis. These data strongly suggest that hyalin or a precursor is a cell surface protein of the unfertilized sea urchin egg.     

An ultrastructural immunocytochemical localization of hyalin in the sea urchin egg

The fertilized sea urchin egg is invested by the hyaline layer, a thick extracellular coat which is necessary for normal development. On the basis of ultrastructural studies and the fact that hyalin is released during the time of the cortical reaction, it has been generally accepted that hyalin is derived from the cortical granules. However, this has never been proven definitely, and recently, it has been reported that hyalin is a membrane and/or cell surface protein. To determine where hyalin is stored, we carried out an ultrastructural immunocytochemical localization of hyalin in the unfertilized egg. Hyalin purified from isolated hyaline layers was used to immunize rabbits. Antisera so obtained were shown to be hyalin specific following absorption with a combination of sea urchin proteins. Immunocytochemical localizations were carried out on sections of Epon-embedded material using protein A-coated gold particles as an antibody marker. Our results demonstrate that, prior to fertilization, hyalin is stored in the homogeneous component of the cortical granule in Strongylocentrotus droebachiensis and Strongylocentrotus purpuratus. Labeling of small cortical vesicles in both unfertilized and fertilized eggs, suggests that these vesicles may contain a secondary reservoir of hyalin.     

DEMONSTRATION AND PRELIMINARY CHARACTERIZATION OF REAGGREGATION-PROMOTING SUBSTANCES FROM EMBRYONIC SEA URCHIN CELLS

Morulae or early blastulae of sea urchins dissociate readily on treatment with isotonic urea containing EDTA. During dissociation a certain substance was extracted. This substance was found to accelerate reaggregation of dissociated cells. The manifestation of the reaggregation-accelerating activity of the substance requires rather complicated handling of divalent cations. On the basis of these findings, a working hypothesis on the mode of function of the substance is presented.
Some properties of the substance were investigated and were found to be very similar to those of hyalin, the calcium-insoluble protein of the hyaline layer surrounding the fertilized egg.     

Direct isolation of the hyaline layer protein released from the cortical granules of the sea urchin egg at fertilization

Treatment of the eggs of the sea urchin with a 1 M solution of glycerol at fertilization allows the recovery from this solution of the protein released from the cortical granules, including that which would normally give rise to the hyaline layer. The calcium-gelable protein previously extracted from whole eggs and from isolated cortical material was found to be present in the glycerol solution, confirming its localization in the cortical granules and its role in the hyaline layer. Quantitative measurements on the eggs of two Hawaiian species, Colobocentrotus atratus and Pseudoboletia indiana, which have the widest variation in the gel protein content, demonstrated that a proportionate amount of this material was released at fertilization in these species, which correlates with the thickness of the hyaline layer in the two cases. In addition, the calcium-insoluble fraction of Sakai can be extracted from these eggs after removal of the hyaline protein by glycerol, showing that this is a different material. A simple method for the separation of the hyaline protein from the calcium-insoluble fraction in solution is provided.     

The apical lamina of the sea urchin embryo: Major glycoproteins associated with the hyaline layer

The hyaline layer (HL) surrounding the sea urchin blastula appears to dissolve in 1 M glycine. However, after this treatment, there persists over the surfaces of the blastomeres a layer of material, referred to here as the apical lamina (AL), that sloughs off as an adhesive convoluted bag upon gradual dissociation of the embryo. Isolated hyaline layers, referred to as HL-AL complexes, were analyzed by urea-SDS-polyacrylamide gel electrophoresis. A major protein of the HL-AL complex, hyalin, bands or precipitates in the stacking gel. Two other major proteins, both strongly PAS positive, migrate with apparent molecular weights of 175K and 145K daltons. As with intact embryos, the glycine wash removes the hyalin protein from the isolated HL-AL complex, leaving the undissolved AL which consists primarily of the 175K- and 145K-dalton proteins. The embryo's own perivitelline-localized cortical granule peroxidase heavily radioiodinates the proteins of the HL-AL complex, further verifying their apical, extracellular location. Unlike hyalin, the AL proteins do not precipitate with calcium ions. Compared to the entire HL-AL complex, the AL contains a greater percentage of carbohydrate. No sialic acid is associated with the HL-AL complex, but the AL contains some sulfate. In contrast to a published report based on ultrastructural staining, no biochemical evidence was found in this study for the presence of collagen or significant glycosaminoglycan within the HL-AL complex. No developmental differences were observed in AL proteins from 1-hr-old embryos compared to those from blastulae. However, there is evidence suggesting heterogeneity and developmental differences in hyalin. The possible organization of hyalin and the AL proteins into separate layers surrounding the embryo is discussed. The influence of the AL proteins in morphogenesis and cell adhesion is considered, and hypothetical roles attributed to the HL and hyalin are critically questioned.     

Relationship between p62 and p56, two proteins of the mammalian cortical granule envelope, and hyalin, the major component of the echinoderm hyaline layer, in hamsters

Mammalian cortical granules contain two polypeptides (p62 and p56) that are incorporated into the cortical granule envelope after fertilization and function in cleavage of the zygote and the preimplantation blastomeres. Since the echinoderm hyaline layer and mammalian cortical granule envelope are analogous, and since the hyaline layer protein, hyalin, functions in early echinoderm embryogenesis, this study was done to determine whether p62 and p56 and/or other components of the mammalian cortical granule envelope are related to hyalin. A polyclonal antibody (IL2) against purified S. purpuratus hyalin was shown by confocal scanning laser microscopy to bind to hamster cortical granules and to the cortical granule envelope of fertilized hamster oocytes and preimplantation embryos up to the blastocyst stage. In immunoblots, IL2 bound only to 62- and 56-kDa cortical granule proteins that were incorporated into the cortical granule envelope after fertilization. IL2 binding antigens appeared to be resynthesized by preimplantation embryos starting at the 2-cell stage of development. In vivo treatment of 2-cell-stage hamster embryos with IL2 inhibited blastomere cleavage, but treatment of morulae did not inhibit blastocyst implantation. These results support the idea that the mammalian cortical granule envelope proteins, p62/p56, share a common antigenic epitope(s) with echinoderm hyalin, and that p62/p56, like hyalin, play a role in early embryogenesis.     

Hyalin release during normal sea urchin development and its replacement after removal at fertilization

All stages of sea urchin embryos through pluteus can be dissociated to their component cells through the use of a 1 M solution of glycine containing EDTA, and a similar glycine solution can be used to prevent the formation of the fertilization membrane and remove the hyaline layer material released at fertilization. The protein hyalin, which makes up the bulk of the hyaline layer, can be recovered from these glycine solutions by calcium addition and quantitative agreement was found between the hyalin released at fertilization and the hyalin present at all later developmental stages. However, embryos stripped of their hyalin at fertilization often develop normally, which is unexpected in view of the apparent involvement of the hyaline layer in developmental mechanics. Such embryos are found to have regenerated an appreciable fraction of the hyalin removed at fertilization and this regeneration occurs at the time of blastulation. Thus the regeneration appears to be stimulated by hyaline layer removal at fertilization, but it does not take place until several hours later, at the time this layer has been postulated to play a role in development.     

Polypeptide composition and organization of the sea urchin extraembryonic hyaline layer.

The protein composition and organization of the sea urchin extraembryonic hyaline layer was examined. Hyalin and a polypeptide of 45 kilodaltons (kDa) were present in hyaline layers isolated from 1-h-old embryos through to the pluteus larva stage. In contrast, several polypeptide species ranging in size from 175 to 32 kDa either decreased in amount or disappeared from the layer as embryonic development proceeded. Concomitant with the changes in composition, hyaline layers became progressively more refractory to dissolution by washing in Ca2+, Mg2(+)-free seawater. Incubation of intact layers, isolated from 1-h-old embryos, with proteinase K resulted in the selective digestion of hyalin and was accompanied by release of the 45-kDa polypeptide from the layers. Washing intact layers in 20 mM Tris (pH 8.0) also resulted in the selective removal of hyalin and the 45-kDa polypeptide. The Ca2(+)-precipitable protein hyalin, alone among the hyaline layer polypeptides, bound the Ca2(+)-antagonist ruthenium red. These results suggest a structural organization within the hyaline layer that is both heterogenous and dynamic throughout embryonic development.     

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.     

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.     

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.     

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.     

Tissue-specific, temporal changes in cell adhesion to echinonectin in the sea urchin embryo.

Echinonectin is a dimeric, glycoprotein found in the hyaline layer of the developing sea urchin embryo. It was found that echinonectin supports adhesion of embryonic cells in vitro. Previous studies have shown that the protein hyalin also supports adhesion. The purpose of this study was to examine the specificity of cell-echinonectin interactions during sea urchin development. Primary mesenchyme cells (PMCs) ingress into the blastocoel during gastrulation. In the process the PMCs lose contact with the hyaline layer. It was found experimentally that differentiating PMCs decreased their adhesion to hyalin at the time of ingression. It was of interest, therefore, to determine whether there was a coordinate loss of adhesion to echinonectin at ingression as well. When cell-echinonectin interactions were quantified using a centrifugal force-based adhesion assay, it was shown that micromeres adhered well to echinonectin. At the time of ingression, PMCs displayed reduced adhesion to echinonectin just as had been found when hyalin was tested as a substrate. There was no change in adhesion of presumptive ectoderm or endoderm to echinonectin over the same time period. Early in gastrulation presumptive ectoderm and endoderm adhered to echinonectin only half as strongly as to equimolar concentrations of hyalin. After gastrulation endoderm cells were observed to retain the same relative affinity to hyalin and echinonectin, while ectoderm cells became equally adhesive for both hyalin and echinonectin. Quantitatively, this represents an overall increase in the affinity of ectodermal cells for echinonectin. Adhesion to combined substrata of echinonectin and hyalin was reduced but not abolished by monoclonal antibodies specific for echinonectin. The antibodies did not cross-react with hyalin. We conclude that both echinonectin and hyalin independently act as adhesive substrata for the developing sea urchin embryo. PMCs lose an affinity for echinonectin and ectodermal cells later increase their affinity for this substrate.     

The sea urchin extraembryonic hyaline layer: Ionic parameters controlling the hyalin gelation reaction

• 1.1. As reported previously (Robinson, 1988) the Ca²⁺-induced self-association reaction of the protein hyalin, purified from the sea urchin extraembryonic hyaline layer, was modulated by both Mg²⁺ and NaCl.
• 2.2. In the presence of 400 mM NaCl the apparent dissociation constant (Ca²⁺) decreased five-fold from 4.8 ± 1.1 mM in the absence to 0.9 ± 0.5 mM in the presence of 20 mM Mg²⁺.
• 3.3. The potentiating effect of Mg²⁺ occurred with an apparent dissociation constant (Mg²⁺) of 4.6 ± 0.5mM.
• 4.4. In the absence of Ca²⁺ or NaCl hyalin dissociated from isolated hyaline layers indicating that the behavior of hyalin within the layer is predictable from results obtained with the purified protein.