Localization and developmental fate of ovoperoxidase and proteoliaisin, two proteins involved in fertilization envelope assembly

Fertilization of the sea urchin egg leads to the assembly of an extracellular matrix, the fertilization envelope. Ovoperoxidase, the enzyme implicated in hardening the fertilization envelope, is inserted into the assembling structure via a Ca2+-dependent interaction with the protein proteoliasin (P. Weidman and B. M. Shapiro, 1987, J. Cell Biol. 105, 561-567). In the present report, polyclonal antisera were raised to ovoperoxidase and proteoliasin (purified from eggs of Strongylocentrotus purpuratus) and characterized by Western blot analysis and an enzyme-linked immunoabsorbent assay (ELISA). By indirect immunofluorescence microscopy all cortical granules of unfertilized eggs, as well as the fertilization envelope, contained both proteoliasin and ovoperoxidase. At the ultrastructural level both proteins are localized to the electron-dense spiral lamellae of the cortical granules. Western blot analysis revealed that ovoperoxidase and proteoliasin persist in early embryos until hatching, but are absent from later developmental stages. Homogenates of eggs of several other echinoderm species (Strongylocentrotus droebachiensis, Strongylocentrotus franciscanus, Pisaster ochraceus, Dendraster excentricus, and Lytechinus pictus) also contain proteins antigenically similar to ovoperoxidase and proteoliaisin, indicating that many echinoderms utilize a similar strategy for assembly of the fertilization envelope. The results underline the need for postsecretory controls in the extracellular matrix modifications that accompany the cortical reaction.     

Regulation of extracellular matrix assembly: in vitro reconstitution of a partial fertilization envelope from isolated components

At fertilization, the glycocalyx (vitelline layer) of the sea urchin egg is transformed into an elevated fertilization envelope by the association of secreted peptides and the formation of intermolecular dityrosine bonds. Dityrosine cross-links are formed by a secreted ovoperoxidase that exists in a Ca2+-stabilized complex with proteoliaisin in the fertilization envelope. By using purified proteins, we now show that proteoliaisin is necessary and sufficient to link ovoperoxidase to the egg glycocalyx. Specifically, we have found that ovoperoxidase can associate with the vitelline layer only when complexed with proteoliaisin; proteoliaisin binds to the vitelline layer independently of its association with ovoperoxidase; proteolytic modification of the vitelline layer is not required for this interaction to occur; the binding of proteoliaisin to the vitelline layer is mediated by the synergistic action of the two major seawater divalent cations, Ca2+ and Mg2+; the number of proteoliaisin-binding sites on the vitelline layer of unfertilized eggs is equivalent to the amount of proteoliaisin secreted at fertilization; and the binding of ovoperoxidase to the vitelline layer, via proteoliaisin, permits the in vitro cross-linking of these two in vivo substrates. The association of purified ovoperoxidase and proteoliaisin with the vitelline layer of unfertilized eggs reconstitutes part of the morphogenesis of the fertilization envelope.     

Sea urchin embryo fertilization envelope: immunological evidence that soluble envelope proteins are derived from cortical granule secretions

Although structural studies support the hypothesis that the sea urchin embryo fertilization envelope is derived from the preexisting vitelline envelope template and structural proteins secreted during the cortical reaction, biochemical evidence is minimal. We used an immunological approach to determine the subcellular origin of proteins which were extracted from the fertilization envelope. Fertilization envelopes were isolated from Stronglyocentrotus purpuratus embryos 30 min postinsemination and extracted with 6.0 M urea-0.15 M 2-mercaptoethanol, pH 10.5, for 10 min at 80°C. Extracted proteins were exhaustively dialyzed against 0.015 M 2-mercaptoethanol-0.100 M Tris-HCl at pH 8.6 and mixed with Fruend's complete adjuvant prior to injection into female New Zealand white rabbits. The antiserum which was prepared contained antibodies to six major and two minor polypeptides in the soluble fertilization envelope fraction based on two-dimensional sodium dodecyl sulfate immunoelectrophoresis. Extracts of vitelline envelopes and extracts of unfertilized egg surfaces which are known to contain viteline envelope proteins did not form immunoprecipitates with antiserum against soluble fertilization envelope polypeptides. Extracts of isolated cortical granules and the secreted paracystalline protein fraction formed four and three immunoprecipitates, respectively, which showed complete identity with the soluble fertilization envelope polypeptides based on rocket-line immunoelectrophoresis. Two-dimensional sodium dodecyl sulfate immunoelectrophoresis of cortical granule extract and the secreted paracrystalline protein fraction showed a complex pattern of immunoprecipitates, but a major finding was that cortical granules contain a 193,000-dalton polypeptide which was not found in the paracrystalline protein fraction. These results suggest that proteolytic processing of a cortical granule precursor of the paracrystalline protein fraction occurs during fertilization and that not all of the cortical granule polypeptides are incorporated into the fertilization envelope by means of di- and trityrosine crosslinks with the vitelline envelope proteins.     

Rearrangements of sea urchin egg cytoplasmic membrane domains at fertilization

Fertilization in the sea urchin is accompanied by rapid reorganization of the egg endoplasmic reticulum (ER). ER-derived vesicles contribute to one of three classes of membranes used in assembling the male pronuclear envelope in vitro. We provide here biochemical evidence for the rearrangement of sea urchin egg cytoplasmic membrane domains at fertilization up to the first mitosis, with respect to two nuclear envelope markers, lamin B and lamin B receptor (LBR), using purified vesicles prepared from homogenates fractionated by floatation on sucrose gradients. In unfertilized eggs, immunoprecipitation data indicate that most of lamin B and LBR are localized in the same vesicles but do not interact. By 3 min post-fertilization, both proteins are more widely distributed across the gradients and by 12 min most of lamin B and LBR are localized in vesicles of different densities. This partitioning is maintained throughout S phase. At mitosis, most lamin B and LBR remain in distinct vesicles, while a small proportion of lamin B and LBR, likely derived from the disassembled nuclear envelope, associate in a minor subset of vesicles. The results illustrate a dynamic reorganization of egg cytoplasmic membranes at fertilization, and the establishment of distinct membrane domains enriched in specific nuclear envelope markers during the first cell cycle of sea urchin development. Additionally, we demonstrate that male pro-nuclear membrane assembly occurs only when both cytosol and membranes originate from fertilized but not unfertilized eggs, suggesting that fertilization-induced membrane rearrangements contribute to the ability of the egg to assemble the male pronuclear envelope.     

SFE1, a constituent of the fertilization envelope in the sea urchin is made by oocytes and contains low-density lipoprotein-receptor-like repeats

At fertilization in most animals, cortical granules of the egg or oocyte secrete their contents, whose function it is to modify the extracellular matrix. This modified matrix then participates in the block to polyspermy and protection for early embryonic development. In the sea urchin, contents of the cortical granules are secreted within 30 sec of insemination. Several of these content proteins then bind to the nascent vitelline layer of the egg and lift off the cell surface to form a stable, impervious, fertilization envelope. At least six major proteins are present in the envelope, and recently we have identified cDNA clones of two, ovoperoxidase, and SFE9. Here we report on the identification and characterization of SFE1, a constituent of the fertilization envelope of the sea urchin Strongylocentrotus purpuratus, that has revealing characteristics of how the envelope might form and what protein interaction domains might predominate. We present the largest cDNA sequence we were able to identify representing approximately two thirds of the predicted protein coding region. The C-terminal half of the cognate SFE1 protein contains two different amino acid repeat motifs: a cysteine-rich (15%) motif of 40 amino acids that is tandemly repeated 22 times and is followed by a serine/threonine-rich (38%) repeat of 63 amino acids that is tandemly repeated 3.5 times. Surprisingly, just N-terminal to the cysteine-rich repeat region is a sequence of five repeats with similarity to repeats in another cortical granule protein, SFE9, and to the motif originally identified in the receptor of low-density lipoproteins, the LDLr motif. The amino acid composition deduced from the partial SFE1 cDNA is similar also to the composition of proteoliaisin, a protein thought to tether the ovoperoxidase to the vitelline layer of the egg and thereby sequester the crosslinking activity of the ovoperoxidase to a limited population of proteins in the fertilization envelope. However, by use of monoclonal and polyclonal antibodies to SFE1 and proteoliaisin, we show here that they are distinct gene products. We also show that SFE1 is packed selectively into the cortical granules and then is crosslinked into the fertilization envelope following fertilization. In situ RNA hybridization analysis shows that the mRNA of SFE1 (9 kilobases) is present in oocytes selectively and is turned over rapidly in the oocyte following germinal vesicle breakdown. Our findings suggest that the gene encoding this major product of the egg is activated concomitantly with the other cortical granule-specific products already identified, and that a common LDLr-like motif of the fertilization envelope may reveal a structural mechanism for protein interactions in its construction.     

Purification and characterization of proteoliaisin, a coordinating protein in fertilization envelope assembly

We report the purification and characterization of proteoliaisin, a protein that participates in the assembly of the sea urchin fertilization envelope. Proteoliaisin was purified from egg cortical granule exudate to greater than 99% homogeneity using chromatography on DEAE-Sepharose and on phenyl-Sepharose. Native proteoliaisin is a highly asymmetric protein (f/fo = 2.0) composed of a single Mr approximately 230,000 peptide. Its asymmetry was demonstrated both by analytical ultracentrifugation and by nondenaturing polyacrylamide gel electrophoresis, a novel analysis that detects molecular asymmetry in heterogeneous protein mixtures. Proteoliaisin is enriched in six amino acids: aspartic acid/asparagine, glutamic acid/glutamine, glycine, and cysteine, which account for over 50% of its mass. Nearly all of the cysteine residues are disulfide bonded. The protein contains a small proportion of aromatic amino acids with phenylalanine greater than tyrosine greater than tryptophan. At neutral pH its absorbance maximum is at 274.5 nm, with an extinction coefficient of 0.43 ml mg-1 cm-1. Proteoliaisin forms a 1:1 Ca2+-stabilized complex with ovoperoxidase, another component of the fertilization envelope, with Kd = 1.1 X 10(-6) M. Proteoliaisin, a constituent of the specialized echinoderm extracellular matrix called the fertilization envelope, has certain structural similarities to mammalian extracellular matrix proteins.     

Major components of a sea urchin block to polyspermy are structurally and functionally conserved

One sperm fusing with one egg is requisite for successful fertilization; additional sperm fusions are lethal to the embryo. Because sperm usually outnumber eggs, evolution has selected for mechanisms that prevent this polyspermy by immediately modifying the egg extracellular matrix. We focus here on the contribution of cortical granule contents in the sea urchin block to polyspermy to begin to understand how well this process is conserved. We identified each of the major constituents of the fertilization envelope in two species of seaurchins, Strongylocentrotus purpuratus and Lytechinus variegatus, that diverged 30 to 50 million years ago. Our results show that the five major structural components of the fertilization envelope, derived from the egg cortical granules, are semiconserved. Most of these orthologs share sequence identity and encode multiple low-density lipoprotein receptor type A repeats or CUB domains but at least two contain radically different carboxy-terminal repeats. Using a new association assay, we also show that these major structural components are functionally conserved during fertilization envelope construction. Thus, it seems that this population of female reproductive proteins has retained functional motifs while gaining significant sequence diversity-two opposing paths that may reflect cooperativity among the proteins that compose the fertilization envelope.     

Relation between nuclear envelope and nuclear lamina in nuclear assembly in vitro

Xenopus laevis egg extracts cell-free nuclear assembly system was used as an experimental model to study the process of nuclear lamina assembly in nuclear reconstitution in vitro. The experimental results showed that lamin was involved in the nuclear assembly in vitro. The assembly of nuclear lamina was preceded by the assembly of nuclear matrix, and probably, inner nuclear matrix assembly provided the basis for nuclear lamina assembly. Inhibition of normal assembly of nuclear lamina, by preincubating egg extracts cell-free system with anti-lamin antibodies, resulted in abnormal assembly of nuclear envelope, suggesting that nuclear envelope assembly is closely associated with nuclear lamina assembly.     

Characterization of the membrane binding and fusion events during nuclear envelope assembly using purified components

At the end of mitosis membrane vesicles are targeted to the surface of chromatin and fuse to form a continuous nuclear envelope. To investigate the molecular mechanisms underlying these steps in nuclear envelope assembly, we have developed a defined cell-free system in which the binding and fusion steps in nuclear envelope assembly can be examined separately. We have found that extensively boiled Xenopus egg extracts efficiently promote the decondensation of demembranated Xenopus sperm chromatin. When isolated membranes are added to this decondensed chromatin a specific subfraction of membrane vesicles (approximately 70 nM in diameter) bind to the chromatin, but these vesicles do not fuse to each other. Vesicle binding is independent of ATP and insensitive to N-ethylmalamide. Quantitative analysis of these sites by EM suggests that there is at least one vesicle binding site per 100 kb of chromosomal DNA. We show by tryptic digestion that vesicle-chromatin association requires proteins on both the vesicle and on the chromatin. In addition, we show that the vesicles bound under these conditions will fuse into an intact nuclear envelope when incubated with the soluble fraction of a Xenopus egg nuclear assembly extract. With respect to vesicle fusion, we have found that vesicles prebound to chromatin will fuse to each other when ATP and GTP are present in the boiled extract. These results indicate that nuclear envelope assembly is mediated by a subset of approximately 70-nM-diam vesicles which bind to chromatin sites spaced 100 kb apart and that fusion of these vesicles is regulated by membrane-associated GTP-binding proteins.     

Intermolecular cross-linking of vitelline envelope polypeptides predominates in the hardened sea urchin fertilization envelope

At fertilization, the sea urchin egg vitelline envelope (VE) elevates, and a subset of released cortical granule proteins, paracrystalline protein fraction (PCF), associates with the VE to form the fertilization envelope (FE). Cortical granule peroxidase cross-links FE polypeptides by phenolic coupling of tyrosyl residues. We have used an immunological approach to determine which polypeptides are linked together in the hardened FE of Strongylocentrotus purpuratus. Soluble polypeptides were extracted from hardened FEs, and antibodies were prepared in rabbits against the insoluble envelope matrix (FE ghost). Whole immune serum and purified IgGs each reacted with FE ghosts when using an enzyme-linked immunosorbent assay. VEs isolated by means of three published procedures cross-reacted with the immune serum and purified IgGs. Soluble FE polypeptides also cross-reacted with whole immune serum and IgGs owing to the presence of VE polypeptides. Hyalin, a protein not found in FEs, and PCF did not cross-react with antiserum against FE ghosts. To determine which VE polypeptides were cross-linked in the hardened FE, VE polypeptides were immunoblotted by using antiserum against FE ghosts. Most of the VE polypeptides that ranged from 68,000 to 283,000 molecular weight cross-reacted with the antibody.     

FORMATION OF THE CORTICAL CONCAVITY AT FERTILIZATION IN THE SEA URCHIN EGG

During the initial stages of fertilization envelope elevation in eggs of Strongylocentrotus pur puratus and S. droebachiensis a large concavity of the egg cortex was observed in the light microscope. This concavity corresponded in shape and size with the elevating fertilization envelope. However, after the vitelline layers of eggs were disrupted and the eggs inseminated, the concavity failed to develop although the eggs were fertilized and developed normally. We propose that the concavity is formed owing to increased hydrostatic pressure within the perivitelline space. To further support this hypothesis we measured total egg protein secreted during fertilization, and found that 98% was retained within the perivitelline space. Furthermore, 80% of the total protein was contributed by the hyaline layer. Presumably, colloidal osmotic pressure and/or hydration of fertilization product, trapped beneath the fertilization envelope, is responsible for increased hydrostatic pressure within the perivitelline space, and therefore promotes not only fertilization envelope elevation, but the cortical concavity as well.     

Relation between nuclear envelope and nuclear lamina in nuclear assemblyin vitro

Xenopus laevis egg extracts cell-free nuclear assembly system was used as an experimental model to study the process of nuclear lamina assembly in nuclear reconstitutionin vitro. The experimental results showed that lamin was involved in the nuclear assemblyin vitro. The assembly of nuclear lamina was preceded by the assembly of nuclear matrix, and probably, inner nuclear matrix assembly provided the basis for nuclear lamina assembly. Inhibition of normal assembly of nuclear Iknina, by preincubating egg extracts cell-free system with anti-lamin antibodies, resulted in abnormal assembly of nuclear envelope, suggesting that nuclear envelope assembly is closely associated with nuclear lamina assembly.     

Relation between nuclear envelope and nuclear lamina in nuclear assembly in vitro

Xenopus laevis egg extracts cell-free nuclear assembly system was used as an experimental model to study the process of nuclear lamina assembly in nuclear reconstitutionin vitro. The experimental results showed that lamin was involved in the nuclear assemblyin vitro. The assembly of nuclear lamina was preceded by the assembly of nuclear matrix, and probably, inner nuclear matrix assembly provided the basis for nuclear lamina assembly. Inhibition of normal assembly of nuclear Iknina, by preincubating egg extracts cell-free system with anti-lamin antibodies, resulted in abnormal assembly of nuclear envelope, suggesting that nuclear envelope assembly is closely associated with nuclear lamina assembly. Project supported by the National Natural Science Foundation of China.     

Sperm binding and fertilization envelope formation in a cell surface complex isolated from sea urchin eggs

An isolated surface complex consisting of the vitelline layer, plasma membrane, and attached secretory vesicles has been examined for its ability to bind sperm and to form the fertilization envelope. Isolated surface complexes (or intact eggs) fixed in glutaraldehyde and then washed in artificial sea water are capable of binding sperm in a species-specific manner. Sperm which bind to the isolated surface complex exhibit the acrosomal process only when they are associated with the exterior surface (vitelline layer) of the complex. Upon resuspension of the unfixed surface complex in artificial sea water, a limiting envelope is formed which, based on examination of thin sections and negatively stained surface preparations, is structurally similar to the fertilization envelope formed by the fertilized egg. These results suggest that the isolated egg surface complex retains the sperm receptor, as well as integrated functions for the secretion of components involved in assembly of the fertilization envelope.     

Sea urchin fertilization envelope: Uncoupling of cortical granule exocytosis from envelope assembly and isolation of an envelope intermediate from Strongylocentrotus purpuratus embryos

The sea urchin fertilization envelope (FE) is an extraembryonic coat which develops from the egg vitelline envelope (VE) and the secreted paracrystalline protein fraction of the cortical granules at fertilization. The FE undergoes further developmental changes postinsemination which are characterized by changes in envelope permeability, solubility in reducing and denaturing solvents, and morphology. We have developed a procedure to uncouple cortical granule exocytosis from assembly of the paracrystalline protein fraction onto the VE template. Egg suspensions were inseminated in normal seawater and diluted into Ca²⁺- and Mg²⁺-free seawater at 15 sec postinsemination. Phase-contrast and electron microscopic observations showed that the embryos formed a normally elevated, extremely thin envelope through which the cortical granule exudate permeated. Secretion studies showed that eggs which were diluted into divalent ion-free seawater postinsemination secreted as much protein into the surrounding seawater as eggs which had their VEs removed prior to the experiment. We have termed the envelope elevated in divalent ion-free seawater the VE1 and we believe that it is the VE structural component of the FE based on its thickness and morphology. VE1s were isolated by gentle physical means and the preparations appeared to be greater than 80% pure based on radioactive mixing experiments and on malate dehydrogenase and glucose-6-phosphate dehydrogenase marker studies. VE1s were at least 80% soluble based on extraction of radioiodinated preparations with reducing and denaturing solvents. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of VE1s showed eight major polypeptides which ranged from 30,500 to 270,000 in molecular weight.     

Cloning of rainbow trout egg envelope proteins: members of a unique group of structural proteins

All vertebrate eggs are surrounded by an extracellular envelope that protects the egg and is vital for a successful fertilization. The terminology and functions of the egg envelope vary in different vertebrate groups, but the envelope itself is consistently composed of a few major proteins that are deposited around the oocyte during oocyte growth. Here, we describe the deduced amino acid sequences and tissue expression patterns of the three major egg envelope proteins for rainbow trout (Oncorhynchus mykiss). All three vitelline envelope proteins (VEPs) are expressed in the livers of both male and female fish, with higher expression in females. In addition, VEPgamma mRNA is also detected in the female gonads. To our knowledge, this is the first time that expression of a VEP protein gene has been demonstrated to occur in more than one organ. Sequence comparison reveals that all three VEP proteins share distinct homology with their amphibian, avian, and mammalian counterparts. Whereas mammalian zona pellucida protein 3 isoforms contain two conserved serines needed for sperm binding, these are not conserved in teleost species, in which sperm entry is restricted to the micropyle. Besides the difference in VEPgamma sperm-binding function, the high sequence homology suggests that the egg envelope proteins from these distinct vertebrate groups share a common ancestry and form a unique group of structural proteins.     

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.     

Xenopus laevis egg jelly contains small proteins that are essential to fertilization.

The eggs of Xenopus laevis are surrounded by investment layers of egg jelly that interact with the sperm immediately prior to fertilization. Components of these egg jelly layers are necessary for the fertilization of the egg by incoming sperm. Eggs which are stripped of their jelly layers are refractile to fertilization by sperm, but the addition of solubilized jelly promotes fertilization. We have shown previously that the egg jelly layers are composed of a fibrous network of glycoconjugates which loosely hold smaller diffusible components. Extracts of these diffusible components were prepared by incubation of freshly ovulated eggs in high-salt buffers for 12 h at 4 degrees C. This diffusible component extract, when incubated with sperm, promoted the sperm's ability to fertilize dejellied eggs in a dose-dependent manner. In contrast, the high-molecular-weight "structural" glycoconjugates of jelly that remain after extraction of the diffusible components did not increase fertilization efficiency of dejellied eggs nor did nonspecific proteins, carbohydrate polymers, or organic polymers. The diffusible components, analyzed by SDS-PAGE, consisted of a mixture of proteins from 4 to 180 kDa. The protein responsible for fertilization rescue appeared to be <50 kDa and appeared to self-aggregate or to bind to larger proteins. This protein component was required during sperm binding to the egg, its action required an intact egg vitelline envelope, and its action was independent of large soluble polymers such as Ficoll.     

Free-radical crosslinking of specific proteins alters the function of the egg extracellular matrix at fertilization

All animal embryos begin development by modifying the egg extracellular matrix. This protein-rich matrix protects against polyspermy, microbes and mechanical stress via enzyme-dependent transformations that alter the organization of its constituents. Using the sea urchin fertilization envelope, a well-defined extracellular structure formed within minutes of fertilization, we examine the mechanisms whereby limited permeability is established within this matrix. We find that the fertilization envelope acquires a barrier filtration of 40,000 daltons within minutes of insemination via a peroxidase-dependent mechanism, with dynamics that parallel requisite production of hydrogen peroxide by the zygote. To identify the molecular targets of this free-radical modification, we developed an in vivo technique to label and isolate the modified matrix components for mass spectrometry. This method revealed that four of the six major extracellular matrix components are selectively crosslinked, discriminating even sibling proteins from the same gene. Thus, specific free-radical chemistry is essential for establishing the embryonic microenvironment of early development.