Structural characterization of fish egg vitelline envelope proteins by mass spectrometry

The extracellular coat, or vitelline envelope (VE), of rainbow trout (Oncorhynchus mykiss) eggs consists of three proteins, called VEalpha (M(r) approximately 52 kDa), VEbeta (M(r) approximately 48 kDa), and VEgamma (M(r) approximately 44 kDa). Each of these proteins is related to mammalian egg zona pellucida (ZP) glycoproteins ZP1-3 and possesses an N-terminal signal sequence, a ZP domain, and a protease cleavage site near the C-terminus. VEalpha and VEbeta also have a trefoil domain. All three proteins possess a relatively large number of cysteine residues (VEalpha, 18; VEbeta, 18; VEgamma, 12), of which 8 are present in the ZP domain and 6 are present in the trefoil domain of VEalpha and VEbeta. Here, several types of mass spectrometry were employed, together with gel electrophoresis of chemical and enzymatic digests, to identify intramolecular disulfide linkages, as well as the N- and C-terminal amino acids of VEalpha, VEbeta, and VEgamma. Additionally, these methods were used to characterize two high molecular weight proteins (HMWPs; M(r) > 110 kDa) of rainbow trout VEs that are heterodimers of individual VE proteins. These analyses have permitted assignment of disulfide linkages and identification of N- and C-terminal amino acids for the VE proteins and determination of the protein composition of two forms of HMWPs. These experiments provide important structural information about fish egg VE proteins and filaments and about structural relationships between extracellular coat proteins of mammalian and nonmammalian eggs.     

Purified trout egg vitelline envelope proteins VEbeta and VEgamma polymerize into homomeric fibrils from dimers in vitro

The rainbow trout egg vitelline envelope (VE) is composed of three proteins, called VEalpha ( approximately 58-60kDa Mr), VEbeta ( approximately 52kDa Mr), and VEgamma ( approximately 47kDa Mr). Each of these proteins is related to mouse egg zona pellucida (ZP) glycoproteins, called ZP1, ZP2, and ZP3, and possesses a ZP domain that has been implicated in the polymerization of the proteins into long, interconnected fibrils or filaments. Here, trout egg VEbeta and VEgamma were purified to homogeneity and analyzed under various experimental conditions (SDS-PAGE, Blue Native-(BN-)PAGE, size-exclusion chromatography, and transmission electron microscopy) to determine whether individual VE proteins would polymerize into fibrils in vitro. Such analyses revealed that in the presence of 6M urea each VE protein is present primarily as monomers and as small oligomers (dimers, tetramers, etc.). However, either a reduction in urea concentration or a complete removal of urea results in the polymerization of VEbeta and VEgamma dimers into very large oligomers. Mixtures of VEbeta and VEgamma also give rise to large oligomers. Under these conditions, VE proteins are visualized by transmission electron microscopy as aggregates of long fibrils, with each fibril composed of contiguous beads located periodically along the fibril. The relationship between the behavior of fish egg VE proteins and mouse ZP glycoproteins, as well as other ZP domain-containing proteins, is discussed.     

Mass spectrometric evidence that proteolytic processing of rainbow trout egg vitelline envelope proteins takes place on the egg

The rainbow trout egg vitelline envelope (VE) is constructed of three proteins, called VEalpha,VEbeta, and VEgamma, that are synthesized and secreted by the liver and transported in the bloodstream to the ovary, the site of VE assembly around eggs. All three proteins possess an N-terminal signal peptide, a zona pellucida domain, a consensus furin-like cleavage site (CFLCS) close to the C terminus, and a short propeptide downstream of the CFLCS. Proteolytic processing at the CFLCS results in loss of the short C-terminal propeptide from precursor proteins and enables incorporation of mature proteins into the VE. Here mass spectrometry (matrix-assisted laser desorption ionization time-of-flight-mass spectrometry and liquid chromatography-mass spectrometry with a micromass-quadrupole TOF hybrid mass and a QSTAR Pulsar i mass spectrometer) was employed with VE proteins isolated from rainbow trout eggs in a peptidomics-based approach to determine the following: 1) the C-terminal amino acid of mature, proteolytically processed VE proteins; 2) the cellular site of proteolytic processing at the CFLCS of VE precursor proteins; and 3) the relationship between proteolytic processing and limited covalent cross-linking of VE proteins. Peptides derived from the C-terminal region were found for all three VE proteins isolated from eggs, indicating that processing at the CFLCS occurs after the arrival of VE precursor proteins at the egg. Consistent with this conclusion, peptides containing an intact CFLCS were also found for all three VE proteins isolated from eggs. Furthermore, peptides derived from the C-terminal propeptides of VE protein heterodimers VEalpha-VEgamma and VEbeta-VEgamma were found, suggesting that a small amount of VE protein can be covalently cross-linked on eggs prior to proteolytic processing at the CFLCS. Collectively, these results provide important evidence about the process of VE formation in rainbow trout and other non-cyprinoid fish and allow comparisons to be made with the process of zona pellucida formation in mammals.     

Amyloid Properties of the Mouse Egg Zona Pellucida

The zona pellucida (ZP) surrounding the oocyte is an extracellular fibrillar matrix that plays critical roles during fertilization including species-specific gamete recognition and protection from polyspermy. The mouse ZP is composed of three proteins, ZP1, ZP2, and ZP3, all of which have a ZP polymerization domain that directs protein fibril formation and assembly into the three-dimensional ZP matrix. Egg coats surrounding oocytes in nonmammalian vertebrates and in invertebrates are also fibrillar matrices and are composed of ZP domain-containing proteins suggesting the basic structure and function of the ZP/egg coat is highly conserved. However, sequence similarity between ZP domains is low across species and thus the mechanism for the conservation of ZP/egg coat structure and its function is not known. Using approaches classically used to identify amyloid including conformation-dependent antibodies and dyes, X-ray diffraction, and negative stain electron microscopy, our studies suggest the mouse ZP is a functional amyloid. Amyloids are cross-β sheet fibrillar structures that, while typically associated with neurodegenerative and prion diseases in mammals, can also carry out functional roles in normal cells without resulting pathology. An analysis of the ZP domain from mouse ZP3 and ZP3 homologs from five additional taxa using the algorithm AmylPred 2 to identify amyloidogenic sites, revealed in all taxa a remarkable conservation of regions that were predicted to form amyloid. This included a conserved amyloidogenic region that localized to a stretch of hydrophobic amino acids previously shown in mouse ZP3 to be essential for fibril assembly. Similarly, a domain in the yeast protein α-agglutinin/Sag 1p, that possesses ZP domain-like features and which is essential for mating, also had sites that were predicted to be amyloidogenic including a hydrophobic stretch that appeared analogous to the critical site in mouse ZP3. Together, these studies suggest that amyloidogenesis may be a conserved mechanism for ZP structure and function across billions of years of evolution.     

Cloning and characterisation of a zona pellucida 3 cDNA from a marsupial, the brushtail possum Trichosurus vulpecula

The mammalian zona pellucida (ZP) is an extracellular glycoprotein coat that plays vital roles throughout fertilisation and preimplantation development. Like that of eutherian mammals the brushtail possum ZP is composed of three glycosylated proteins of 137 kDa, 92 kDa and 62 kDa. The 62 kDa protein is a ZP3 orthologue based on its nucleotide and deduced amino acid sequence. The brushtail possum ZP3 cDNA isolated in this study is 1305 nucleotides with an open reading frame encoding a 422 amino acid peptide of 45.7 kDa. Possum ZP3 has a 46% amino acid identity with eutherian ZP3 and shares similar structural characteristics including 12 conserved cysteine residues, N-linked glycosylation sites and hydrophobic regions. Like human and rabbit ZP1 an altered furin cleavage site upstream of the C-terminal hydrophobic domain also occurs in possum ZP3 (S-R-K-R), suggestive of processing by a furin-related endoprotease. Expression of brushtail possum ZP3 is limited to the ovary. Characterisation of brushtail possum ZP3 will enable examination of its functional role in marsupial fertilisation and its effectiveness as an immunocontraceptive agent.     

Characterization of two zebrafish cDNA clones encoding egg envelope proteins ZP2 and ZP3.

Two zebrafish cDNA clones encoding homologs of mammalian zona pellucida proteins ZP2 and ZP3 were isolated from a whole adult cDNA library. The ZP2 clone encodes a protein of 428 amino acids. Unlike other teleost ZP2s that contain an N-terminal repetitive domain enriched with prolines and glutamines, the zebrafish ZP2 has no such repetitive domain. In the C-terminal non-repetitive domain, the zebrafish ZP2 shares 55-76% sequence identity with other teleost ZP2s. The ZP3 cDNA clone encodes a protein of 431 amino acids, which shares 61% sequence identity with a carp ZP3. Similar to mammalian ZP proteins, both zebrafish ZP2 and ZP3 contain several potential phosphorylation sites. However, unlike mammalian ZP proteins, both zebrafish ZP proteins contain almost no glycosylation site, which has been proposed to be important for interaction with sperm; thus, the ZP proteins may behave differently in mammals and teleosts. Northern blot analysis indicated that both zebrafish ZP2 and ZP3 mRNAs were expressed exclusively in the ovary and hence the ovary is likely the only site for ZP2 and ZP3 biosynthesis.     

The ZP domain is a conserved module for polymerization of extracellular proteins

Many eukaryotic extracellular proteins share a sequence of unknown function, called the zona pellucida (ZP) domain. Among these proteins are the mammalian sperm receptors ZP2 and ZP3, non-mammalian egg coat proteins, Tamm-Horsfall protein (THP), glycoprotein-2 (GP-2), alpha- and beta-tectorins, transforming growth factor (TGF)-beta receptor III and endoglin, DMBT-1 (deleted in malignant brain tumour-1), NompA (no-mechanoreceptor-potential-A), Dumpy and cuticlin-1 (refs 1,2). Here, we report that the ZP domain of ZP2, ZP3 and THP is responsible for polymerization of these proteins into filaments of similar supramolecular structure. Most ZP domain proteins are synthesized as precursors with carboxy-terminal transmembrane domains or glycosyl phosphatidylinositol (GPI) anchors. Our results demonstrate that the C-terminal transmembrane domain and short cytoplasmic tail of ZP2 and ZP3 are not required for secretion, but are essential for assembly. Finally, we suggest a molecular basis for dominant human hearing disorders caused by point mutations within the ZP domain of alpha-tectorin.     

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.     

Primary structure and developmental expression of Dp ZP2, a vitelline envelope glycoprotein homolog of mouse ZP2, in Discoglossus pictus, one of the oldest living Anuran species

A glycoprotein of the Xenopus vitelline envelope, gp 69/64, which mediates sperm binding, is closely related to the components of ZPA family, such as the mouse zona pellucida ZP2. To test the generality of these findings, we studied Discoglossus pictus, a species evolutionary distant from Xenopus and identified as a protein of 63 kDa in the vitelline envelope. Preliminary studies suggest that this protein may bind sperm at fertilization. We found that the 63-kDa protein is glycosylated and contains both N- and O-linked chains. We have cloned the cDNA encoding the Discoglossus protein of 63 kDa (Dp ZP2) by screening a Discoglossus cDNA library using Xenopus gp 69/64 cDNA as a probe. Analysis of the deduced sequence of Discoglossus protein revealed 48% identity with Xenopus gp 69/64 and 37-40% identity with mouse ZP2. The sequence conservation included a ZP domain, a potential furin cleavage site and a putative transmembrane domain. The N-terminus region of Dp ZP2 was 40% identical to the corresponding region of Xenopus gp 69/64 which has been shown to be essential for sperm binding to the VE. Although, as of yet, there is no evidence for sperm binding at the Dp ZP2 N-terminus, it is interesting that in this region three potential O-glycosylation sites are conserved in both species, in contrast to N-glycosylation sites. It was found that the Dp ZP2 mRNA is expressed in stage 1 oocytes and in the follicle cells surrounding the oocyte. Similarly, in Xenopus oocytes, the gp 69/64m RNA, was found in the oocytes, as well as in the somatic cells. Mol. Reprod. Dev. 59:133-143, 2001.     

Analysis of vitelline envelope synthesis and composition during early oocyte development in gilthead seabream (Sparus aurata)

The oocyte vitelline envelope (VE) of gilthead seabream is composed of four known zona pellucida (ZP) proteins, ZPBa, ZPBb, ZPC, and ZPX. We have previously shown that the gilthead seabream ZP proteins are differentially transcribed in liver and ovary, with the expression in liver being under estrogenic control. However, although mRNA was found in both liver and ovary, only low ZPBa protein levels were detected in liver and plasma. Using isoform-specific ZP antibodies we show that ZPBa and ZPX translation products are present in the cytosol of stage I and II oocytes. In addition, the zpBa and zpX mRNAs were detected in early developing oocytes. During oocyte growth (vitellogenesis), the VE increased in thickness (>10 microm), and we show that the four ZP isoforms are present in different regions of the VE. ZPX was detected closest to the oocyte plasma membrane while the intermediate region was composed of ZPBa, ZPBb, and ZPC. At the outer layer, only ZPC was detected. When oocytes reach the fully grown stage they resume meiosis and hydration. As the oocyte expands, thinning to 4 microm, the VE acquire a striped and compact appearance at the electron microscopy level. This study provides further evidence for the oocyte origin of some ZP proteins in the gilthead seabream and suggests that the ZP proteins are differentially distributed within the VE.     

Adaptive Evolution in an Avian Reproductive Protein: ZP3

Proteins involved in reproduction appear to be evolving adaptively across taxa. This rapid evolution is thought to be the result of forces involved in sexual selection. One of the most often suggested of these forces is sexual conflict involving sperm competition and polyspermy avoidance. Bird species offer a unique opportunity to test this hypothesis since the avian egg coat tolerates physiological polyspermy, or the penetration of multiple sperm during fertilization, without negative effects on later development. Despite this, and the extensive amount of data gathered on sexual selection in birds, there are limited studies on the patterns of evolution of avian reproductive proteins. Here we present an analysis of the pattern of evolution of Zona Pellucida 3 (ZP3), a protein present on the avian egg coat. We found that, across several galliform and a single anseriform species, ZP3 appears to be diverging by positive adaptive evolution. In an exploratory analysis of portions of the gene in Callipepla californica we also found evidence of a selective sweep at the putative sperm binding region of the protein. In sum, ZP3 in birds, like reproductive proteins in other species, appears to be adaptively evolving. This result suggests that polyspermy avoidance is not sufficient to explain positive Darwinian selection in reproductive proteins across taxonomic groups. Clearly, the inclusion of bird species in the study of reproductive proteins across taxa promises to add greatly to the discussion of the factors driving the widespread phenomenon of adaptive evolution in reproductive proteins. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Cloning, sequencing and site of origin of the rat sperm receptor protein, ZP3

The ZP3 gene encodes for a zona glycoprotein that serves as both a cell-specific binding site for capacitated spermatozoa and an inducer of acrosomal exocytosis during fertilisation. In this study we have determined the nucleotide sequence of rat ZP3 (accession no. Y10823), predicted primary amino acid structure and determined the cellular origin of this molecule within the ovary. Rat ZP3 was found to have an open reading frame of 1272 nucleotides encoding a polypeptide chain of 424 amino acids that was expressed exclusively by the actively growing oocyte population. Rat ZP3 exhibited 91%, 78% and 66% identity with the mouse, hamster and human homologues, respectively. Key features of mouse ZP3, including the number and location of cysteine and proline residues and N-linked glycosylation sites, were also conserved in the rat homologue. The putative O-linked glycosylation sites, a series of serine residues at ZP3(329-334), were also conserved in rat and mouse ZP3, although immediately downstream of this site the amino acid sequences deviated over a short stretch of amino acids. The hydropathicity profile revealed two hydrophobic domains. The first was associated with a putative N-terminal signal sequence which is unusual in the rat in possessing a proline residue at the -1 position relative to the signal cleavage site, a feature it shares with human and marmoset ZP3 but not mouse. The second hydrophobic domain was observed at the C-terminus downstream of a TGF-beta type III receptor domain that appears to be common to all ZP3 sequences examined to date.     

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.     

A structural view of egg coat architecture and function in fertilization

Species-restricted interaction between gametes at the beginning of fertilization is mediated by the extracellular coat of the egg, a matrix of cross-linked glycoprotein filaments called the zona pellucida (ZP) in mammals and the vitelline envelope in nonmammals. All egg coat subunits contain a conserved protein-protein interaction module-the "ZP domain"-that allows them to polymerize upon dissociation of a C-terminal propeptide containing an external hydrophobic patch (EHP). Recently, the first crystal structures of a ZP domain protein, sperm receptor ZP subunit zona pellucida glycoprotein 3 (ZP3), have been reported, giving a glimpse of the structural organization of the ZP at the atomic level and the molecular basis of gamete recognition in vertebrates. The ZP module is divided in two related immunoglobulin-like domains, ZP-N and ZP-C, that contain characteristic disulfide bond patterns and, in the case of ZP-C, also incorporate the EHP. This segment lies at the interface between the two domains, which are connected by a long loop carrying a conserved O-glycan important for binding to sperm in vitro. The structures explain several apparently contradictory observations by reconciling the variable disulfide bond patterns found in different homologues of ZP3 as well as the multiple ZP3 determinants alternatively involved in gamete interaction. These findings have implications for our understanding of ZP subunit biogenesis; egg coat assembly, architecture, and interaction with sperm; structural rearrangements leading to postfertilization hardening of the ZP and the block to sperm binding; and the evolutionary origin of egg coats.     

Full-length sequence of VERL,the egg vitelline envelope receptor for abalone sperm lysin

Abalone sperm use 16 kDa lysin to create a hole in the egg vitelline envelope (VE) by a species-specific, nonenzymatic mechanism. To create the hole, lysin binds tightly to VERL (the VE receptor for lysin), a giant, unbranched glycoprotein comprising 30% of the VE. Binding of lysin to VERL causes the VERL molecules to lose cohesion and splay apart creating the hole. Lysin and VERL represent a cognate pair of gamete recognition proteins, one male the other female, which mediate fertilization. The coevolution of such cognate pairs may underlie the establishment of species-specific fertilization which could be a component of the mechanism to achieve reproductive isolation and hence new species. Here we present the full-length cDNA sequence (11,166 bp) of VERL from the red abalone (Haliotis rufescens). There are 42 amino acids from the start Met residue to the beginning of the first 'VERL repeat'. Most of VERL (9981 bp; 89.4%) consists of 22 tandem repeats of a approximately 153 amino acid sequence that is predicted to be beta-sheet. The last VERL repeat is followed by 353 non-repeat amino acid residues containing a furin cleavage site (RTRR), a ZP domain and a hydrophobic COOH-terminus with a 3' UTR of only 10 nucleotides. VERL repeats 3-22 have been subjected to concerted evolution and consequently have almost identical sequences. Curiously, comparisons of repeats from other species shows that repeats 1 and 2 of red abalone VERL have not been subjected to concerted evolution since the divergence of the red species from the other six California species.