The zona pellucida is an extracellular matrix consisting of three glycoproteins that surrounds mammalian eggs and mediates fertilization. The primary structures of mouse ZP1, ZP2, and ZP3 have been deduced from cDNA. Each has a predicted signal peptide and a transmembrane domain from which an ectodomain must be released. All three zona proteins undergo extensive coand post-translational modifications important for secretion and assembly of the zona matrix. In this report, native zonae pellucidae were isolated and structural features of individual zona proteins within the mixture were determined by high resolution electrospray mass spectrometry. Complete coverage of the primary structure of native ZP3, 96% of ZP2, and 56% of ZP1, the least abundant zona protein, was obtained. Partial disulfide bond assignments were made for each zona protein, and the size of the processed, native protein was determined. The N termini of ZP1 and ZP3, but not ZP2, were blocked by cyclization of glutamine to pyroglutamate. The C termini of ZP1, ZP2, and ZP3 lie upstream of a dibasic motif, which is part of, but distinct from, a proprotein convertase cleavage site. The zona proteins are highly glycosylated and 4/4 potential N-linkage sites on ZP1, 6/6 on ZP2, and 5/6 on ZP3 are occupied. Potential O-linked carbohydrate sites are more ubiquitous, but less utilized.The zona pellucida is an extracellular matrix surrounding mammalian eggs that functions in taxon-specific gamete binding, provides a post-fertilization block to polyspermy, and protects the developing pre-implantation embryo (1-3). The mouse zona pellucida (ZP) 1 is composed of three major glycoproteins (ZP1, ZP2, and ZP3) that are synthesized and secreted by oocytes during a 2-3 week growth period (4). The primary structures of ZP1 (623 amino acids), ZP2 (713 amino acids), and ZP3 (424 amino acids) have been deduced from cDNA (5-7). Each glycoprotein has a signal peptide directing it into a secretory pathway, a ϳ260 amino acid zona domain containing 8 conserved cysteine residues, and a transmembrane domain near the C terminus followed by a short cytoplasmic tail (8). The zona domain has been observed in multiple proteins (9) and has been implicated in the polymerization of extracellular matrices (10).During oocyte growth, ZP1, ZP2, and ZP3 traffick through the growing oocyte, and their ectodomains are released from a transmembrane domain at the surface of the cell (11, 12). A conserved hydrophobic patch upstream of the transmembrane domain is required for progression to the cell surface 2 and a consensus cleavage site (RX(K/R)R2) for the proprotein convertase furin is present upstream of the transmembrane domain. Although this site has been implicated in the release of the zona ectodomain (13-15), mutations (RNRR3 ANAA, or RNRR3 ANGE), do not prevent incorporation of reporter-ZP3 proteins into the zona pellucida in growing oocytes (12, 16) or transgenic mice (12) and secretion of recombinant human ZP3 with a similar mutation (RNRR3 ANAA) is not prevented (17).The three zo...
The zona pellucida surrounding ovulated mouse eggs contains three glycoproteins, two of which (ZP2 and ZP3) are reported sperm receptors. After fertilization, the zona pellucida is modified ad minimus by cleavage of ZP2, and sperm no longer bind. Crosstaxa sperm binding is limited among mammals, and human sperm do not bind to mouse eggs. Using transgenesis to replace mouse ZP2 and/or ZP3 with human homologs, mouse lines with human-mouse chimeric zonae pellucidae have been established. Unexpectedly, mouse, but not human, sperm bind to huZP2 and huZP2/huZP3 rescue eggs, eggs fertilized in vitro with mouse sperm progress to two-cell embryos, and rescue mice are fertile. Also unanticipated, human ZP2 remains uncleaved after fertilization, and mouse sperm continue to bind early rescue embryos. These observations are consistent with a model in which the supramolecular structure of the zona pellucida necessary for sperm binding is modulated by the cleavage status of ZP2.
The zona pellucida surrounding the egg and pre-implantation embryo is required for in vivo fertility and early development. Explanatory models of sperm -egg recognition need to take into account the ability of sperm to bind to ovulated eggs, but not to two-cell embryos. For the last two decades, investigators have sought to identify an individual protein or carbohydrate side chain as the 'sperm receptor'. However, recent genetic data in mice are more consistent with the three-dimensional structure of the zona pellucida, rather than a single protein (or carbohydrate), determining sperm binding. The mouse and human zonae pellucidae contain three glycoproteins (ZP1, ZP2, ZP3) and, following fertilization, ZP2 is proteolytically cleaved. The replacement of endogenous mouse proteins with human ZP2, ZP3 or both does not alter taxon specificity of sperm binding or prevent fertility. Surprisingly, human ZP2 is not cleaved following fertilization and intact ZP2 correlates with persistent sperm binding to two-cell embryos. Taken together, these data support a model in which the cleavage status of ZP2 modulates the three-dimensional structure of the zona pellucida and determines whether sperm bind (uncleaved) or do not (cleaved).
The specificity of sperm-egg recognition in mammals is mediated primarily by the zona pellucida surrounding ovulated eggs. Mouse sperm are quite promiscuous and bind to human eggs, but human spermatozoa will not bind to mouse eggs. The mouse zona pellucida contains three glycoproteins, ZP1, ZP2, and ZP3, which are conserved in rat and human. The recent observation that human zonae pellucidae contain a fourth protein raises the possibility that the presence of four zona proteins will support human sperm binding. Using mass spectrometry, four proteins that are similar in size and share 62-70% amino acid identity with human ZP1, ZP2, ZP3, and ZP4/ZPB were detected in rat zonae pellucidae. However, although mouse and rat spermatozoa bind to eggs from each rodent, human sperm bind to neither, and the presence of human follicular fluid did not alter the specificity of sperm binding. In addition, mutant mouse eggs lacking hybrid/complex N-glycans or deficient in Core 2 O-glycans were no more able to support human sperm binding than normal mouse eggs. These data suggest that the presence of four zona proteins are not sufficient to support human sperm binding to rodent eggs and that additional determinants must be responsible for taxon-specific fertilization among mammals.After passage through the lower female reproductive tract, mammalian spermatozoa fertilize ovulated eggs in the ampulla of the oviduct. A key event in successful fertilization is sperm binding to the surface of the extracellular zona pellucida that surrounds the egg. Following zona penetration and fusion with the egg plasma membrane, peripherally located cortical granules within the egg exocytose their contents, which modify the zona matrix such that sperm no longer bind. These events are carefully orchestrated to ensure that a single sperm fertilizes a single egg (1).Despite decades of investigation, the molecular basis of mammalian sperm-egg recognition remains controversial. Human sperm are particularly fastidious and bind to old world primate eggs but not to eggs of other species. In contrast, mouse sperm are quite promiscuous, binding with near universality to eggs from other mammalian orders (2). The mouse zona pellucida is composed of three major glycoproteins, ZP1, ZP2, and ZP3, one of which, ZP2, is proteolytically cleaved following fertilization (3). Mouse lines have been established that lack each of the zona proteins as well as lines in which human ZP2 and/or human ZP3 replace endogenous mouse proteins (4). Mice without ZP1 form a zona pellucida matrix to which mouse sperm bind and Zp1 null females are fertile, albeit with decreased fecundity (5). Mice in which endogenous proteins are replaced with human ZP2, human ZP3, or both are also fertile but do not support human sperm binding (6, 7). Thus, mouse ZP1 is not required for sperm-egg recognition, and human ZP2 and ZP3 are not sufficient to support human sperm binding.These results suggest that "humanized" zona matrices either lack a factor or contain a factor that prevents the binding of h...
Recent studies have extended our knowledge regarding the contents of mammalian cortical granules (CG) and their function in postfertilization events. Cytochemical staining has demonstrated the presence of carbohydrates within mammalian CG, and lectin-binding studies have shown that these carbohydrates include a-Dmannose, a-D-GalNAc, and galactose residues in the hamster, a-D-mannose in the mouse and cat, and P-D-Gal(l,3)-D-GalNAc in the pig. Following fertilization and artificial activation, mannosylated material is released from CG and can be found on the oolemma and within the perivitelline space (PVS) of hamster oocytes. Fertilized or artificially activated rabbit, mouse, and human oocytes also release mannosylated, fucosylated and sialylated, and fucosylated material, respectively, which localizes to the oolemma. These glycosylated materials are probably of CG origin, although they have not been directly localized to the CG in rabbit, mice, and humans. The function(s) of the glycosylated material released from mammalian oocytes is not known, although it may participate in blocking polyspermy at the level of the plasma membrane, PVS, and/or zona pellucida (ZP), or it may facilitate preimplantation embryonic development. Proteinases, including tissue plasminogen activator, are also released from mammalian oocytes following fertilization and artificial activation, suggesting that they are of CG origin. These proteinases modify the ZP such that it is no longer receptive to sperm, and some proteinases have been suggested to bring about ZP hardening (an increased resistance to denaturing agents) by an unknown mechanism. Mouse ZP may also be hardened by an ovoperoxidase (cross-links tyrosine residues) cytochemically identified in mouse CG and CG exudate. The phenomena of ZP hardening in mammalian zygotes is not well understood but is likely to function in blocking polyspermic penetration of the ZP and/or in protecting embryos during preirnplantation development. Recently, a 75 kD protein (p75) has been immunocytochemically localized to mouse CG and to the PVS of fertilized oocytes and two-cell embryos. The identity and function of p75 remains to be determined. Heparin binding placental protein may also be a CG component, since it is released from hamster oocytes following fertilization. It has not, however, been directly demonstrated to be a CG component, and its functions in 0 1994 WILEY-LISS, INC.fertilization and/or early embryonic development have yet to be defined. 0 1994 Wlley-Llss, Inc.
The zona pellucida is an extracellular matrix that mediates taxon-specific fertilization in which human sperm will not bind to mouse eggs. The mouse zona pellucida is composed of three glycoproteins (ZP1, ZP2, ZP3). The primary structure of each has been deduced from the cDNA nucleic acid sequence, and each has been analyzed by mass spectrometry. However, determination of the secondary structure and processing of the human zona proteins have been hampered by the paucity of biological material. To investigate if taxon-specific sperm-egg recognition was ascribable to structural differences in a zona protein required for matrix formation, recombinant human ZP3 was expressed in CHO-Lec3.2.8.1 cells and compared to mouse ZP3. With nearly complete coverage, LC-QTOF mass spectrometry was used to determine the cleavage of an N-terminal signal peptide (amino acids 1-22) and the release of secreted ZP3 from a C-terminal transmembrane domain (amino acids 379-424). The resultant N-terminal glutamine was cyclized to pyroglutamate (pyrGln(23)), and several C-terminal peptides were detected, including one ending at Asn(350). The disulfide bond linkages of eight cysteine residues in the conserved zona domain were ascertained (Cys(46)/Cys(140), Cys(78)/Cys(99), Cys(217)/Cys(282), Cys(239)/Cys(300)), but the precise linkage of two additional disulfide bonds was indeterminate due to clustering of the remaining four cysteine residues (Cys(319), Cys(321), Cys(322), Cys(327)). Three of the four potential N-linked oligosaccharide binding sites (Asn(125), Asn(147), Asn(272)) were occupied, and clusters of O-glycans were observed within two regions, amino acids 156-173 and 260-281. Taken together, these data indicate that human and mouse ZP3 proteins are quite similar, and alternative explanations of taxon-specific sperm binding warrant exploration.
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