Interspecies chimeric sperm lysins identify regions mediating species-specific recognition of the abalone egg vitelline envelope.

Abalone sperm lysin is a nonenzymatic, 16-kDa protein that creates a hole in the egg vitelline envelope (VE) through which the sperm swims to fuse with the egg. The dissolution of isolated VE by lysin is species specific. Interspecies comparisons show that the most divergent region of lysin is the N-terminal segment of residues 1-12 which is always species-unique. The C-terminus and three internal segments are moderately variable between species, but not species unique. Analysis of nucleotide substitutions shows that lysin evolves rapidly by positive Darwinian selection, suggesting that there is adaptive value in altering its amino acid sequence. The results reported here, in which segments of lysin were exchanged between two species, prove by direct experimentation that the interspecies variable termini play major roles in the species-specific recognition between sperm lysin and the egg VE.     

Crystal structure and subunit dynamics of the abalone sperm lysin dimer: egg envelopes dissociate dimers, the monomer is the active species

Lysin is a 16-kD acrosomal protein used by abalone spermatozoa to create a hole in the egg vitelline envelope (VE) by a nonenzymatic mechanism. The crystal structure of the lysin monomer is known at 1.9 A resolution. The surface of the molecule reveals two tracks of basic residues running the length of one surface of the molecule and a patch of solvent-exposed hydrophobic residues on the opposite surface. Here we report that lysin dimerizes via interaction of the hydrophobic patches of monomers. Triton X-100 dissociates the dimer. The crystal structure of the dimer is described at 2.75 A resolution. Fluorescence energy transfer experiments show that the dimer has an approximate KD of 1 microM and that monomers exchange rapidly between dimers. Addition of isolated egg VE dissociates dimers, implicating monomers as the active species in the dissolution reaction. This work represents the first step in the elucidation of the mechanism by which lysin enables abalone spermatozoa to create a hole in the egg envelope during fertilization.     

鲍配子识别蛋白的研究

配子相互作用的生化机制对于进一步阐明生殖过程具有重要作用,它是深入了解细胞内识别的理想体系。精卵细胞相互作用包括一系列的步骤,开始于精子与卵细胞外被的接触,终止于两性细胞的融合及精子核进入卵细胞质中,而精卵细胞的识别具有建立于各自性细胞表面成分基础上的种的特异性,鲍则是研究精卵识别的好材料。鲍精子在发生顶体反应时释放出两种蛋白质——细胞溶素(1ysin)和18ku糖蛋白(spl8),其中的细胞溶素与其卵黄膜上的受体紧密结合,并利用非酶反应在卵黄膜上穿一个小孔,整个精子则从此孔穿过卵黄膜与卵细胞融合;spl8释放后则覆盖到精子细胞膜表面,起到溶解卵细胞脂质体的作用,即spl8介导精、卵细胞膜的融合。鲍卵细胞膜上存在细胞溶素受体,它是大的不分支的糖蛋白分子,占据了卵黄膜30％的组分,可以专一性地与细胞溶素相结合。这些配子识别蛋白共同进化且速度很快,其中细胞溶素和18ku糖蛋白通过正向选择进化,而细胞溶素受体进行协同进化。     

The high resolution crystal structure of green abalone sperm lysin: implications for species-specific binding of the egg receptor

Abalone sperm lysin is a 16 kDa acrosomal protein used by sperm to create a hole in the egg vitelline envelope. Lysins from seven California abalone exhibit species-specificity in binding to their egg receptor, and range in sequence identity from 63 % to 90 %. The crystal structure of the sperm lysin dimer from Haliotis fulgens (green abalone) has been determined to 1.71 A by multiple isomorphous replacement. Comparisons with the structure of the lysin dimer from Haliotis rufescens (red abalone) reveal a similar overall fold and conservation of features contributing to lysin's amphipathic character. The two structures do, however, exhibit differences in surface residues and electrostatics. A large clustering of non-conserved surface residues around the waist and clefts of the dimer, and differences in charged residues around these regions, indicate areas of the molecule which may be involved in species-specific egg recognition.     

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.     

The crystal structure of a fusagenic sperm protein reveals extreme surface properties

Sp18 is an 18 kDa protein that is released from abalone sperm during the acrosome reaction. It coats the acrosomal process where it is thought to mediate fusion between sperm and egg cell membranes. Sp18 is evolutionarily related to lysin, a 16 kDa abalone sperm protein that dissolves the vitelline envelope surrounding the egg. The two proteins were generated by gene duplication followed by rapid divergence by positive selection. Here, we present the crystal structure of green abalone sp18 resolved to 1.86 A. Sp18 is composed of a bundle of five alpha-helices with surface clusters of basic and hydrophobic residues, giving it a large dipole moment and making it extremely amphipathic. The large clusters of hydrophobic surface residues and domains of high positive electrostatic surface charge explain sp18's ability as a potent fusagen of liposomes. The overall fold of sp18 is similar to that of green abalone lysin; however, the surface features of the proteins are quite different, accounting for their different roles in fertilization. This is the first crystal structure of a protein implicated in sperm-egg fusion during animal fertilization.     

Rapid evolution of fertilization selectivity and lysin cDNA sequences in teguline gastropods.

Proteins mediating intercellular recognition face opposing selective forces as they evolve: purifying selection to maintain function, and diversifying selection to alter specificity. Lysin is a 16-kDa protein which enables sperm of free-spawning marine snails to make a hole in the vitelline layer (VE) surrounding conspecific eggs. Previous work on abalone (Haliotis spp.) has shown that positive selection promotes rapid interspecific divergence of lysin. Here, we present data on the specificity of VE dissolution by four species of teguline gastropods, along with lysin cDNA sequences. The teguline and abalone lineages diverged over 250 MYA. As in abalone, VE dissolution by lysin in tegulines is species-selective, and positive selection promotes rapid interspecific divergence over the entire mature protein. Nonsynonymous substitution rates, calculated using a mtCOI molecular clock calibrated by two Tegula species separated by the Isthmus of Panama, are high (> 25 substitutions per site per 10(9) years). However, the extensive replacements in teguline lysins are overwhelmingly conservative with respect to type, charge, and polarity of residues. Predictions of secondary structure suggest that the size and position of alpha-helices are also conserved, even through pairwise amino acid identities between Haliotis rufescens and the different tegulines are less than 15%.     

Role of oviductal pars recta extract on interspecific fertilization between anurans

During their journey through the oviductal pars recta, the vitelline envelope (VE) of Bufo arenarum oocytes encounter structural alterations that make them sensitive to attack by sperm lysin and thus to penetration by sperm cells. The role of pars recta (PR) on the specificity of fertilization between amphibians was analyzed by conditioning Bufo arenarum oocytes with either homologous PR extract (PRE) or Leptodactylus chaquencis PRE. The oocytes were thereafter exposed to sperm lysin preparations from both species. Lysis of the VE only took place when the oocytes were exposed to the homologous PRE. The pattern of protein composition of PRE of these species was strikingly different as shown by Coomassie blue staining of SDS-PAGE. Moreover, antibodies against PR fluid (PRF) of Bufo arenarum produced seven bands of immunoprecipitation in electrophoresed homologous PRE and only one faint band in Leptodactylus chaquencis PRE. Here we show that: (i) the biological activity of PR from Bufo arenarum and Leptodactylus chaquencis over the VE of Bufo arenarum oocytes is species-specific; (ii) this specificity seems to be based in differences in protein structure, which was indicated by the fact that proteins from PRE of Leptodactylus chaquencis and Bufo arenarum were antigenically distinct; (iii) the specificity was solely related to PR activity and not to sperm lysin activity since sperm lysin preparations from both species showed comparable activity.     

Speciation genes in free-spawning marine invertebrates

Research on speciation of marine organisms has lagged behind that of terrestrial ones, but the study of the evolution of molecules involved in the adhesion of gametes in free-spawning invertebrates is an exception. Here I review the function, species-specificity, and molecular variation of loci coding for bindin in sea urchins, lysin in abalone and their egg receptors, in an effort to assess the degree to which they contribute to the emergence of reproductive isolation during the speciation process. Bindin is a protein that mediates binding of the sperm to the vitelline envelope (VE) of the egg and the fusion of the gametes' membranes, whereas lysin is a protein involved only in binding to the VE. Both of these molecules are important in species recognition by the gametes, but they rarely constitute absolute blocks to interspecific hybridization. Intraspecific polymorphism is high in bindin, but low in lysin. Polymorphism in bindin is maintained by frequency-dependent selection due to sexual conflict arising from the danger of polyspermy under high densities of sperm. Monomorphism in lysin is the result of purifying selection arising from the need for species recognition. Interspecific divergence in lysin is due to strong positive selection, and the same is true for bindin of four out of seven genera of sea urchins studied to date. The differences between the sea urchin genera in the strength of selection can only partially be explained by the hypothesis of reinforcement. The egg receptor for lysin (VERL) is a glycoprotein with 22 repeats, 20 of which have evolved neutrally and homogenized by concerted evolution, whereas the first two repeats are under positive selection. Selection on lysin has been generated by the need to track changes in VERL, permitted by the redundant structure of this molecule. Both lysin and bindin are important in reproductive isolation, probably had a role in speciation, but it is hard to determine whether they meet the strictest criteria of "speciation loci," defined as genes whose differentiation has caused speciation.     

Polymorphism in abalone fertilization proteins is consistent with the neutral evolution of the egg's receptor for lysin (VERL) and positive darwinian selection of sperm lysin

The evolution of species-specific fertilization in free-spawning marine invertebrates is important for reproductive isolation and may contribute to speciation. The biochemistry and evolution of proteins mediating species-specific fertilization have been extensively studied in the abalone (genus Haliotis). The nonenzymatic sperm protein lysin creates a hole in the egg vitelline envelope by species-specifically binding to its egg receptor, VERL. The divergence of lysin is promoted by positive Darwinian selection. In contrast, the evolution of VERL does not depart from neutrality. Here, we cloned a novel nonrepetitive region of VERL and performed an intraspecific polymorphism survey for red (Haliotis rufescens) and pink (Haliotis corrugata) abalones to explore the evolutionary forces affecting VERL. Six statistical tests showed that the evolution of VERL did not depart from neutrality. Interestingly, there was a subdivision in the VERL sequences in the pink abalone and a lack of heterozygous individuals between groups, suggesting that the evolution of assortative mating may be in progress. These results are consistent with a model which posits that egg VERL is neutrally evolving, perhaps due to its repetitive structure, while sperm lysin is subjected to positive Darwinian selection to maintain efficient interaction of the two proteins during sperm competition.     

Abalone lysin: the dissolving and evolving sperm protein

Abalone sperm lysin is a non-enzymatic protein that creates a hole for sperm passage in the envelope surrounding the egg. Lysin exhibits species-specificity in making the hole and it evolves rapidly by positive selection. Our studies have focused on combining structural, biochemical, and evolutionary data to understand the mechanism of action and evolution of this remarkable protein. Currently, more is known about lysin than about any other protein involved in animal fertilization. We present an hypothesis to explain lysin's rapid evolution and the evolution of species-specific fertilization in this order of mollusks. We also propose a two-step model for lysin's action in which a dimer of lysin binds species-specifically to its glycoprotein receptor, and then monomerizes and binds the receptor in a non-species-specific manner. This experimental system yields data relevant to the general problem of molecular recognition between cell surfaces, and is also important to our thinking about how new species arise in the sea. BioEssays 23:95-103, 2001.     

The sequence of the Arbacia punctulata bindin cDNA and implications for the structural basis of species-specific sperm adhesion and fertilization

Bindin is the major protein component of the acrosome granule of sea urchin sperm which mediates the species-specific adhesion of sperm to the egg surface during fertilization. Bindin isolated from both Arbacia punctulata and Strongylocentrotus purpuratus sperm demonstrate a distinct adhesive preference for eggs of the same species although a significant amount of cross-species reactivity is observed. Here we describe the isolation and sequence of A. punctulata bindin cDNA clones and a comparison of the predicted protein sequence with the sequence previously reported for S. purpuratus bindin (Gao et al., 1986, Proc. Natl. Acad. Sci., USA 83, 8634-8638). Bindins from these genera show substantial sequence similarity in both the mature bindin domain and the probindin precursor region. The most striking identity is a region of 42 conserved amino acids in the central part of the mature bindins. This conserved domain may be responsible for conserved functions of bindin. Regions flanking this conserved element on both the amino and carboxyl side are more highly divergent, suggesting that they are responsible for the species-specific properties of bindin. The mature A. punctulata sequence contains a putative transmembrane segment between residues 431 and 451 that is absent from S. purpuratus bindin. This structural element may account for the previous observation that isolated A. punctulata bindin uniquely forms multilamellar structures reminiscent of lipid bilayers and binds significant amounts of phospholipid and detergent. The structure of this hydrophobic segment also displays a number of similarities to viral fusion peptides.     

The Tegula tango: a coevolutionary dance of interacting, positively selected sperm and egg proteins

Reproductive proteins commonly show signs of rapid divergence driven by positive selection. The mechanisms driving these changes have remained ambiguous in part because interacting male and female proteins have rarely been examined. We isolate an egg protein the vitelline envelope receptor for lysin (VERL) from Tegula, a genus of free-spawning marine snails. Like VERL from abalone, Tegula VERL is a major component of the VE surrounding the egg, includes a conserved zona pellucida (ZP) domain at its C-terminus, and possesses a unique, negatively charged domain of about 150 amino acids implicated in interactions with the positively charged lysin. Unlike for abalone VERL, where this unique VERL domain occurs in a tandem array of 22 repeats, Tegula VERL has just one such domain. Interspecific comparisons show that both lysin and the VERL domain diverge via positive selection, whereas the ZP domain evolves neutrally. Rates of nonsynonymous substitution are correlated between lysin and the VERL domain, consistent with sexual antagonism, although lineage-specific effects, perhaps owing to different ecologies, may alter the relative evolutionary rates of sperm- and egg-borne proteins.     

Positive selection in the carbohydrate recognition domains of sea urchin sperm receptor for egg jelly (suREJ) proteins

A wealth of evidence shows that protein-carbohydrate recognition mediates the steps of gamete interaction during fertilization. Carbohydrate-recognition domains (CRDs) comprise a large family of ancient protein modules of approximately 120 amino acids, having the same protein fold, that bind terminal sugar residues on glycoproteins and polysaccharides. Sea urchin sperm express three suREJ (sea urchin receptor for egg jelly) proteins on their plasma membranes. suREJ1 has two CRDs, whereas suREJ2 and suREJ3 both have one CRD. suREJ1 binds the fucose sulfate polymer (FSP) of egg jelly to induce the sperm acrosome reaction. The structure of FSP is species specific. Therefore, the suREJ1 CRDs could encode molecular recognition between sperm and egg underlying the species-specific induction of the acrosome reaction. The functions of suREJ2 and suREJ3 have not been explored, but suREJ3 is exclusively localized on the plasma membrane over the sperm acrosomal vesicle and is physically associated with sea urchin polycystin-2, a known cation channel. An evolutionary analysis of these four CRDs was performed for six sea urchin species. Phylogenetic analysis shows that these CRDs were already differentiated in the common ancestor of these six sea urchins. The CRD phylogeny agrees with previous work on these species based on one nuclear gene and several mitochondrial genes. Maximum likelihood shows that positive selection acts on these four CRDs. Threading the suREJ CRDs onto the prototypic CRD crystal structure shows that many of the sites under positive selection are on extended loops, which are involved in saccharide binding. This is the first demonstration of positive selection in CRDs and is another example of positive selection acting on the evolution of gamete-recognition proteins.     

Amino acid sequence of an egg-lysin protein from abalone spermatozoa that solubilizes the vitelline layer

Spermatozoa of the California red abalone (Haliotis rufescens; Phylum Mollusca, order Archeogastropoda) possess an acrosomal protein that dissolves the egg vitelline layer during fertilization. Evidence strongly suggests that the dissolution mechanism is a stoichiometric, nonenzymatic process that depends on the hydrophobic nature of the sperm protein which should therefore be termed an egg-lysin. Here we report the complete amino acid sequence of this unique protein. Peptides obtained by cyanogen bromide cleavage and trypsin and V8 protease digestions were isolated and subjected to automated Edman degradation. Seven unique CNBr fragments accounted for the intact lysin and the proteolytically derived peptides were used to establish the order of these fragments. The protein is composed of 134 amino acids and contains 36 charged amino acids. The majority of these occur at distances of 2 or 3 residues from each other. A stretch of 41 amino acids contains 10 positively charged amino acids and no negatively charged residue. Model building experiments demonstrated that the charged residues that may occur in alpha-helical regions of the protein would occupy one-half of the circumference of such helices. The other half would display predominantly hydrophobic residues. This arrangement of the charged and hydrophobic residues may account for the biological properties of the lysin.     

Positive selection is a general phenomenon in the evolution of abalone sperm lysin

Lysin is a 16kDa acrosomal protein used by abalone sperm to create a hole in the egg vitelline envelope (VE). The interaction of lysin with the VE is species-selective and is one step in the multistep fertilization process that restricts heterospecific (cross-species) fertilization. For this reason, the evolution of lysin could play a role in establishing prezygotic reproductive isolation between species. Previously, we sequenced sperm lysin cDNAs from seven California abalone species and showed that positive Darwinian selection promotes their divergence. In this paper an additional 13 lysin sequences are presented representing species from Japan, Taiwan, Australia, New Zealand, South Africa, and Europe. The total of 20 sequences represents the most extensive analysis of a fertilization protein to date. The phylogenetic analysis divides the sequences into two major clades, one composed of species from the northern Pacific (California and Japan) and the other composed of species from other parts of the world. Analysis of nucleotide substitution demonstrates that positive selection is a general process in the evolution of this fertilization protein. Analysis of nucleotide and codon usage bias shows that neither parameter can account for the robust data supporting positive selection. The selection pressure responsible for the positive selection on lysin remains unknown.      

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.     

Identification of the ZPC oligosaccharide ligand involved in sperm binding and the glycan structures of Xenopus laevis vitelline envelope glycoproteins

The Xenopus laevis egg vitelline envelope is composed of five glycoproteins (ZPA, ZPB, ZPC, ZPD, and ZPX). As shown previously, ZPC is the primary ligand for sperm binding to the egg envelope, and this binding involves the oligosaccharide moieties of the glycoprotein (Biol. Reprod., 62:766-774, 2000). To understand the molecular mechanism of sperm-egg envelope binding, we characterized the N-linked glycans of the vitelline envelope (VE) glycoproteins. The N-linked glycans of the VE were composed predominantly of a heterogeneous mixture of high-mannose (5-9) and neutral, complex oligosaccharides primarily derived from ZPC (the dominant glycoprotein). However, the ZPA N-linked glycans were composed of acidic-complex and high-mannose oligosaccharides, ZPX had only high-mannose oligosaccharides, and ZPB lacked N-linked oligosaccharides. The consensus sequence for N-linked glycosylation at the evolutionarily conserved residue N113 of the ZPC protein sequence was glycosylated solely with high-mannose oligosaccharides. This conserved glycosylation site may be of importance to the three-dimensional structure of the ZPC glycoproteins. One of the complex oligosaccharides of ZPC possessed terminal beta-N-acetyl-glucosamine residues. The same ZPC oligosaccharide species isolated from the activated egg envelopes lacked terminal beta-N-acetyl-glucosamine residues. We previously showed that the cortical granules contain beta-N-acetyl-glucosaminidase (J. Exp. Zool., 235:335-340, 1985). We propose that an alteration in the oligosaccharide structure of ZPC by glucosaminidase released from the cortical granule reaction is responsible for the loss of sperm binding ligand activity at fertilization.     

Bindin,a multifunctional sperm ligand and the evolution of new species

Sea urchin sperm species-specifically adhere to the egg surface during fertilization. The protein which mediates this adhesion is known as bindin and cDNAs have recently been cloned and sequenced from several different species. Bindin proteins contain a highly conserved central domain flanked by much more highly divergent amino- and carboxyl-terminal domains. Investigations of the structure and function relationships indicate that the conserved domains may participate in membrane fusion and sulfated fucan binding activities, which may be conserved functions of bindin. The species-specific adhesion activity appears to be duplicated in both the amino- and carboxyl-terminal domain and may correspond to repeated sequence motifs found in these domains. The duplication of these sequence motifs and the redundancy of the adhesive domains may be important for the molecular mechanism of bindin evolution during speciation.     

The amino terminal sequence of sea urchin sperm histone H1 and its phosphorylation by egg cytosol

1. The amino acid sequence of the first 34 residues of sperm histone H1 (SpH1) from Strongylocentrotus purpuratus shows striking similarity with sequences from three South African species. 2. Five contiguous repeats of the tetrapeptide SPBB (where B is R or K) occur between positions 10 and 29. 3. SpH1 was phosphorylated in vitro using egg cytosol as the source of protein kinase and approximately 4.2 mol phosphate were incorporated per mol H1. 4. Sequences of five phosphopeptides of SpH1 show the egg possesses protein kinase activity capable of phosphorylating multiple seryl residues including SPBB in the NH2-, and BBSP in the COOH-end of the protein.