The vitelline envelope to fertilization envelope conversion in eggs of Xenopus laevis

Fertilization of the Xenopus laevis egg causes the conversion of the vitelline envelope to the fertilization envelope, a change reflected in the loss of sperm penetrability of the egg and the appearance of an electron-dense layer on the outer aspect of the fertilization envelope. As seen by one-dimensional gel electrophoresis, two components with molecular weights of 69,000 and 64,000 in the vitelline envelope were converted to 66,000 and 61,000 in the fertilization envelope. By two-dimensional gel electrophoresis, the components in the 69,000 and 64,000 molecular weight regions of the vitelline envelope were seen to shift to more basic isoelectric points upon conversion to the fertilization envelope. Peptide mapping by limited proteolysis suggested that the 69,000 and 64,000 molecular weight components shared the same polypeptide chains but the smaller glycoprotein lacked a carbohydrate side chain found on the larger species. Similar sites on each glycoprotein were affected when the vitelline envelope was converted to the fertilization envelope. No N-terminal amino acids could be identified on the envelope components, indicating that these glycoproteins have blocked N-termini. Ionophore A23187-activation of jellied eggs (but not dejellied eggs) caused the molecular weight changes in the absence of sperm. Thus, factors from the jelly and the cortical granules but not from sperm apparently are involved in the processing of the 69,000 and 64,000 molecular weight components.     

The vitelline envelope,chorion, and micropyle of Fundulus heteroclitus eggs

The architecture and transformation of the vitelline envelope of the developing oocyte into the chorion of the mature egg of Fundulus heteroclitus have been examined by scanning and transmission electron microscopy. The mature vitelline envelope is structurally complex and consists of about nine strata. The envelope is penetrated by pore canals that contain microvilli arising from the oocyte and macrovilli from follicle cells. During the envelope's transformation into the chorion, the pore canals are lost and the envelope becomes more fibrous and compact and its stratified nature less apparent. The micropyle, of pore, through which the sperm gains access to the enclosed egg is located at the bottom of a small funnel-shaped depression in the envelope. Internally, the micropyle opens on the apex of a cone-like elevation of the chorion. During the development of the envelope, structured chorionic fibrils, the components of which are presumed to be synthesized by the follicle cells, become attached to its surface. These chorionic fibrils are though to aid in the attachment of the egg to the substratum and perhaps to help prevent water loss during low tides when the egg may be exposed.     

cDNA cloning and sequence analysis of the Xenopus laevis egg envelope glycoprotein gp43

The glycoproteins of the Xenopus laevis egg envelope function in fertilization and development. As the unfertilizable coelomic egg transits the pars recta region of the oviduct, it is converted to a fertilizable egg by limited proteolysis of the envelope glycoprotein gp43 to gp41. This conversion is caused by an oviductally secreted serine active site protease, oviductin. We cloned a cDNA for gp43 from an oocyte cDNA library. The cDNA encoded a 454 amino acid protein homologous to the ZPC family of glycoproteins previously shown to be present in mammalian and fish egg envelopes. Conserved ZPC domains and motifs present in the Xenopus sequence included a signal peptide sequence, an N-linked glycosylation site, and 12 aligned Cys residues. In mammalian and Xenopus sequences, a furin-like (convertase) site and a C-terminal transmembrane domain were present reflecting the biosynthesis of ZPC in these species via the secretory glycoprotein pathway. However, fish envelope glycoproteins lack these sequences since they are synthesized via a different route (in the liver, transported to the ovary, and assembled into the egg envelope surrounding the oocyte). Consensus amino acid residues were identified by sequence comparisons of seven ZPC family members; 19% of the amino acid residues were invariant and 48% of the residues were identical in at least four of the seven sequences. The consensus sequence was used to make structure-fertilization function predictions for this phylogenetically conserved family of glycoproteins.     

A hatching enzyme substrate in the Xenopus laevis egg envelope is a high molecular weight ZPA homolog

The Xenopus laevis egg envelope is composed of six or more glycoproteins, three of which have been cloned and identified as the mammalian homologs ZPA (ZP2), ZPB (ZP1) and ZPC (ZP3). The remaining glycoproteins are a triplet of high molecular weight components that are selectively hydrolyzed by the hatching enzyme. We have isolated one of these proteins and cloned its cDNA. The mRNA for the protein was found to be expressed only in early stage oocytes, as are other envelope components. From the deduced amino acid sequence, it was indicated to be a secreted glycoprotein with a characteristic ZP domain in the C-terminal half of the molecule. The N-terminal half was unrelated to any known glycoprotein. Comparative sequence analysis of the ZP domain indicated that it was derived from an ancestor of ZPA and ZPB, with the greatest identity to ZPA. This envelope component has been designated ZPAX.     

The coelomic envelope of Xenopus laevis eggs: a quick-freeze, deep-etch analysis

The extracellular matrix of Xenopus laevis oocytes was analyzed before and after meiotic maturation using quick-freeze, deep-etch, rotary-shadow electron microscopy. The perivitelline space (PS) of the meiotically immature oocyte contains a filamentous network which connects microvilli (MV) and follicle cell macrovilli to the folded oocyte surface below. The envelope overlying the PS is composed of bundles of large fibers which course between the tips of the MV. Spaces between these bundles contain smaller fibrils which secure the egg envelope to the microvillar tips. Meiotic maturation is accompanied by flattening of the oocyte plasma membrane, formation of an orderly array of MV, and elevation of the egg envelope. In the coelomic eggs, the reorganized envelope is composed of loosely bundled large fibers which course above the microvillar tips rather than between them. The spaces between these bundles contain small fibers similar to those seen in the meiotically immature oocyte. This reorganized envelope, however, will not bind sperm; further modifications must transpire during passage through the oviduct to render it sperm receptive.     

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.     

Identification and characterization of a unique Xenopus laevis egg envelope component,ZPD

We report the identification of a previously undetected Xenopus laevis egg envelope component discovered through cloning experiments. A cDNA sequence was found that represented a mature protein of 32 kDa. Peptide antibodies were generated to probe for the protein in egg envelope samples and reactivity was found to a glycoprotein of approximately 80 kDa. When deglycosylated egg envelope samples were probed, a 32 kDa protein was labeled, confirming the size of the translated cDNA sequence. A BLAST analysis showed that it is most closely related (34% amino acid identity) to the ZP domains of mammalian tectorin, uromodulin and ZPA. From a dendrogram of known egg envelope glycoproteins, the new glycoprotein was shown to be unique among egg envelope components and was designated ZPD. A similar glycoprotein was identified by immunocrossreactivity in Xenopus tropicalis and Xenopus borealis egg envelopes.     

Characterization of the vitelline envelope of the sea urchin Strongylocentrotus purpuratus

The vitelline envelope (VE) is an extremely thin, acellular, proteinaceous coat that surrounds the extracellular surface of sea urchin eggs. Despite previous studies on VE composition, structure and function, our understanding of the envelope is still incomplete at the molecular level. We have isolated VE components from intact, unfertilized Strongylocentrotus purpuratus eggs by reduction with alkaline dithiothreitol-sea water solutions and have characterized the macromolecules by SDS-PAGE. There were eight major glycoprotein bands, including two high molecular weight components at 265 and 300 kDa, and several minor components. We have revealed, by lectin blot analysis, that most components contain mannose, while a subset of glycoproteins contain fucose and N -acetylglucosamine; galactose and sialic acid were also detected. The components in the VE preparations were compared with cell surface complex preparations by immunoblot analysis, using antisera against a VE preparation, a 305 kDa electrophoretically purified VE glycoprotein and an extracellular portion of the sea urchin egg recombinant 350 kDa sperm receptor. Serum against the recombinant sperm receptor reacted with a component of ∼350 kDa on blots, but did not react with the 300 kDa component found in VE preparations. Therefore, we suggest these two glycoproteins are not the same.     

Refertilization in eggs of the sea urchin Strongylocentrotus purpuratus

To determine the role of the sea urchin egg plasma membrane in the species-specificity of fertilization, the ability of denuded activated eggs to be heterospecifically refertilized was determined. Our initial studies included evaluating the effectiveness of three commonly used methods of vitelline envelope (VE) removal using indirect immunofluorescence microscopy with antibodies directed against the VE. Unfertilized Strongylocentrotus purpuratus eggs were extracted with 0.01 M dithiothreitol (DTT) for 3 min or digested with 1.0 mg/ml pronase for 1 hr. Eggs were also fertilized, then diluted into a divalent-free medium to produce thin, elevated envelopes (VE*s) that were mechanically removed by sieving the eggs through nylon mesh. We found that both DTT extraction and pronase digestion were not completely effective in VE removal, and mechanical removal methods gave rise to a mixed population of eggs, those that had their VEs removed and those with a collapsed envelope that was not detectable at the light microscope level. Therefore, a new method of VE removal was developed. Eggs with VE*s were prepared followed by treatment with 0.01 M DTT to solubilize the envelopes. Nearly 100% of the denuded activated eggs incorporated one or more homologous and heterologous sperm, suggesting that the egg plasma membrane does not function in determining the species-specificity of fertilization.     

Cryopreservation of sperm of Xenopus laevis and Xenopus tropicalis

Now that transgenic strains of Xenopus laevis and X. tropicalis can be generated efficiently and with genomic sequence resources available for X. tropicalis, early amphibian development can be studied using integrated biochemical and genetic approaches. However, housing large numbers of animals generated during genetic screens or produced as novel transgenic lines presents a considerable challenge. We describe a method for cryopreserving Xenopus sperm that should facilitate low maintenance, long-term storage of male gametes. By optimising the cryoprotectant, the rates of cooling and thawing, and conditions for fertilisation, sperm from the equivalent of one-eighth of a X. laevis testis or of two X. tropicalis testes have been cryopreserved and used to fertilise eggs of both species after thawing. Sperm undergo a substantial loss of viability during a freeze-thaw cycle, but sufficient survive to fertilise eggs. Gametes of mutagenised frogs are being stored in connection with a screen for developmental mutations.     

Sperm surface heparin/heparan sulfate is responsible for sperm binding to the uterine envelope in the newt, Cynops pyrrhogaster

The sperm-binding properties of egg envelopes are investigated in the newt, Cynops pyrrhogaster. Sperm binding was only seen on the uterine envelope when acrosome-reacted sperm were inseminated. No acrosome-intact sperm bound to the envelopes. By scanning electron microscopic observation, acrosome-reacted sperm were revealed to bind to a seat-like structure present on the surface of the uterine envelope. Sperm binding to the uterine envelope was inhibited by treatment of eggs with heparin or heparan sulfate, or treatment of acrosome-reacted sperm with heparinase prior to insemination. A molecule with a molecular mass of 75 kDa was purified from the uterine envelope by affinity chromatography with heparin-Sepharose. These results indicated that sperm binding was mediated by heparin-like molecules expressed on the surface of acrosome-reacted sperm and the 75 kDa molecule was present as a constituent of uterine envelopes.     

Fertilization envelope assembly in sea urchin eggs inseminated in Cl− deficient sea water: I. Morphological effects

Elevation and hardening of the fertilization envelope (FE) occur within 15 min following insemination of the sea urchin egg. When chloride ions were replaced in the media with various anion substitutes, including methyl sulfonate, nitrates, bromide, and isethionate, the fertilization envelope failed to harden and collapsed back to the surface of the egg of Lytechinus variegatus, L. pictus, and Strongylocentrotus purpuratus. At the light microscopy level, the collapse of the envelope was accompanied by a decrease in birefringence, compared with controls. When examined with electron microscopy, the FEs of eggs inseminated in reduced Cl^? solutions failed to transform from an amorphous layer into the more robust laminar structure observed around eggs incubated in normal sea water. Furthermore, in the case of S. purpuratus, the I-T transformation of the FE did not occur. When transfer of the inseminated eggs from the Cl^?-deficient sea water to normal sea water was carried out before 10 min elapsed, the envelope did not collapse, and the birefringence of the envelope was similar to that of controls. Partial envelope collapse was also observed in a dose-dependent manner, varying with the concentration of the Cl^? in the sea water solution. The results suggest that lack of Cl^? in the media may interfere with proper fertilization envelope assembly. Possible mechanisms, including proper incorporation of the cortical granule exudate into the nascent envelope structure, are discussed.     

Involvement of carbohydrate moieties of the toad egg vitelline coat in binding with fertilizing sperm

Vitelline coats (VC) were isolated from the eggs of Bufo japonicus , and were added with sperm in reconstituted salt solution, which mimics the physiological role of jelly envelopes, to determine the rates of sperm binding per unit area (0.2 mm²) of VC. The rate of sperm binding to VC from uterine eggs was high, but was low to VC from coelomic eggs and eggs activated in 1/20 De Boer's solution (DB) and moderately low to VC from eggs activated in DB. The binding rate increased when VC from coelomic eggs were treated with extracts of the pars recta portion of the oviduct. The sperm that bound to VC were not acrosome-reacted and their binding to VC required both a low salinity, assuring motility of sperm, and sufficiently high levels of Ca²⁺ and Mg²⁺. The rate of sperm binding was reduced by either coexisting solubilized VC materials, periodate-oxidation of VC or the pretreatment of VC with Fab fragments of anti-VC antibodies, which reacted mostly to carbohydrate residues of VC glycoproteins. Sperm-VC binding assays in combination with gel-filtrated VC components revealed that the fractions containing 36–39 kDa components were most effective both in inhibiting the binding and in neutralizing the antibody induced inhibition of binding. These results indicate that carbohydrate moieties in 36–39 kDa glycoproteins of VC, exposed as a result of hydrolysis by the oviducal pars recta protease, are involved in binding with fertilizing sperm.     

Analysis of a sperm surface molecule that binds to a vitelline envelope component of Xenopus laevis eggs

To analyze sperm surface molecules involved in sperm–egg envelope binding in Xenopus laevis, heat‐solubilized vitelline envelope (VE) dot blotted onto a polyvinylidene difluoride (PVDF) sheet was incubated with a detergent extract of sperm plasma membrane (SP‐ML). The membrane components bound to the VE were detected using an antibody library against sperm plasma membrane components, and a hybridoma clone producing a monoclonal antibody (mAb) 16A2A7 was identified. This mAb was used in a Far Western blotting experiment in which VE was separated by electrophoresis, and then transferred to a PVDF strip that was incubated with SP‐ML. It was found that SP‐ML binds to the VE component gp37 (Xenopus homolog of mammalian ZP1). The antigens reactive to mAb 16A2A7 showed apparent molecular weights of 65–130 and 20–30 kDa, and were distributed relatively evenly over the entire sperm surface. Periodate oxidation revealed that both the pertinent epitope on the sperm surface and the ligands of VE gp37 were sugar moieties. VE gp37 was exposed on the VE surface, and the mAb 16A2A7 dose‐dependently inhibited sperm binding to VE. The sperm membrane molecules reactive with mAb 16A2A7 also reacted with mAb 2A3D9, which is known to recognize the glycoprotein SGP in the sperm plasma membrane and is involved in interactions with the egg plasma membrane, indicating that the sperm membrane glycoprotein has a bifunctional role in Xenopus fertilization. Mol. Reprod. Dev. 77: 728–735, 2010. © 2010 Wiley‐Liss, Inc.     

Fertilization of newt coelomic eggs in the absence of jelly envelope material

Summary Fertilization ofCynops pyrrhogaster (Japanese newt) coelomic eggs was studied in the absence of jelly envelope material or synthetic high polymer. An undiluted sperm fluid from the vas deferens fertilized coelomic eggs in the absence of the jelly envelope material or synthetic high polymer. The fertilized eggs developed beyond gastrulae and formed tail bud embryos. These results indicate that the fertilization process does not depend upon the presence of jelly envelope material or synthetic high polymer and that the sperms within the vas deferens are already capable of fertilizing the eggs inC. pyrrhogaster. The sperm suspension in Holtfreter's balanced salt solution (H-sperm) fertilized the coelomic eggs without the jelly envelope material or synthetic high polymer. These eggs had been suspended in Holtfreter's balanced salt solution (H) or in 1/20 strength H (1/20 H) prior to insemination (H-eggs or 1/20 H-eggs). In contrast, the sperm suspension in 1/20 H (1/20 H-sperm) did not fertilize 1/20 H-eggs, but dit H-eggs. In the latter case, H surrounding the eggs may affect sperms, allowing them to be fertilized. The 1/20 H-sperms regained their ability to fertilize 1/20 H-eggs on re-exposure to H. The 1/20 H-sperm also fertilized jelly eggs. The results of the dejellied egg experiment showed the same pattern. These results indicate that the sperms within the vas deferens lose their capacity to fertilize 1/20 H-eggs on exposure to low ionic strength solution (1/20 H); this capacity is restored by exposure to high ionic strength solution (H) or to jelly envelope.     

Incorporation of mouse zona pellucida proteins into the envelope of Xenopus laevis oocytes

 All vertebrate eggs have extracellular matrices, referred to as the zona pellucida in Mus musculus and the vitelline envelope in Xenopus laevis. The mouse zona, composed of three sulfated glycoproteins (ZP1, ZP2, ZP3), is critical for fertilization and early development, and mice lacking a zona pellucida produce no live offspring. The primary structures of mouse ZP1 (623 amino acids), ZP2 (713 amino acids) and ZP3 (424 amino acids) have been deduced from full-length cDNAs, but posttranslational modifications result in mature zona proteins with molecular masses of 200–180 kDa, 140–120 kDa, and 83 kDa, respectively. The vitelline envelope forms a similar structure around Xenopus eggs and contains three glycoproteins that are structurally related (39–48% amino acid similarity) to the three mouse zona proteins. To investigate whether the structural semblances are sufficient to allow incorporation of the mouse zona proteins into the Xenopus vitelline envelope, capped synthetic mRNAs encoding ZP1, ZP2, and ZP3 proteins were injected into the cytoplasm of stage VI Xenopus oocytes. After 20 h of incubation the oocytes were harvested, and posttranslationally modified zona proteins were detected with monoclonal antibodies specific to mouse ZP1, ZP2, and ZP3. The oocytes were imaged with confocal microscopy to detect individual zona proteins in the extracellular matrix of the oocytes, and this localization was confirmed biochemically. Thus the mouse zona proteins appear to have been sufficiently conserved through 350 million years of evolution to be incorporated into the extracellular envelope surrounding Xenopus eggs. Received: 5 January 1999 / Accepted: 12 February 1999     

Nuclear assembly of purified Crythecodinium cohnii chromosomes in cell—free extracts of Xenopus laevis eggs

Incubation of dinoflagellate Crythecodinium cohnii chromosomes in cytoplasmic extracts of unfertilized Xenopus laevis eggs resulted in chromosomes decondensation and recondensation,nuclear envelope assembly,and nuclear reconstitution.Dinoflagellate Crythecodinium cohnii is a kind of primitive eukaryote which possesses numerous permanently condensed chromosomes and discontinuous double-layered nuclear membrane throughout the cell cycle.The assembled nuclei,being surrounded by a continuous double membrane containing nuclear pores and the uniformly dispersed chromatin fibers are morphologically distinguishable from that of Dinoflagellate Crythecodinium cohnii.However,incubation of dinoflagellate Cyrthecodinium cohnii chromosomes in the extracts from dinoflagellate Crythecodinium cohnii cells does not induce nuclear reconstitution.     

Oviducal pars recta-induced degradation of vitelline coat proteins in relation to acquisition of fertilizability of toad eggs

In the toad Bufo bufo japonicus the vitelline coat (VC) of the uterine egg (UEVC) is more readily lysed by the sperm lysin than the VC of coelomic egg (CEVC). Fluorometric determinations of released proteins after incubation of the VC with the sperm lysin in vitro revealed that the CEVC is not completely refractory to the lysin but increases in susceptibility after treatment with a pars recta extract (PRE). Experiments employing isolated pars recta granules showed that both this increase of VC susceptibility and the acquisition of egg fertilizability are ascribable to the contents of the granules. SDS-PAGE analyses of VC proteins revealed that in comparison with CEVC, UEVC lacks 40–52K proteins concomitant with the increased stainability of 39K protein and the appearance of 36K protein. These changes in SDS-PAGE profiles were observed either in oviducal eggs after passage through the pars recta or in coelomic eggs treated with PRE but were inhibited when coelomic eggs were treated with PRE containing soybean trypsin inhibitor (SBTI) and leupeptin. Likewise, the acquisition of fertilizability by treatment of coelomic egg with PRE was inhibited by SBTI. Dejellied uterine eggs were successfully fertilized when pretreated with trypsin inhibitors before insemination but were not fertilized when pre-treated with concanavalin A. We propose that the hydrolytic degradation of certain VC proteins due to the tryptic activity of pars recta granules renders the VC susceptible to the sperm lysin, so that the eggs are made receptive to a fertilizing sperm.