Reactions of the sea urchin oocyte to foreign spermatozoa

Spermatozoa of the mussel Cyprina islandica and the nemertine Malacobdella grossa have been adddd to oocytes and mature eggs of the sea urchin Psammechinus miliaris. No spermatozoa were found to attach to the surface of the mature eggs which also remained unactivated throughout the experiments. Spermatozoa of both species were found to reach the oocyte surface and to become attached there. The interaction between egg and sperm was different in the two species and different from the situation of a sea urchin sperm on the sea urchin oocyte. The nemertine sperm was found to penetrate the cortex of the oocyte in a fashion resembling phagocytosis. The mussel sperm was partly surrounded by thin protrusions from the sea urchin oocyte which extended along a major portion of the sperm head.     

Isolation and characterization of a plasma membrane fraction from sea urchin sperm exhibiting species specific recognition of the egg surface

A method is described for isolating preparative quantities of plasma membranes from sea urchin sperm. The final membrane fraction is homogeneous by sucrose density sedimentation and is enriched in adenylate cyclase as well as in the four glycoproteins accessible to radioiodination of intact sperm. The electrophoretic profiles of sperm membranes from three sea urchin species are very similar. The membrane preparation consists primarily of sealed vesicles which release carboxyfluorescein when exposed to detergents or distilled water. Ninety-two percent of the 125I-labeled vesicle material binds to wheat germ lectin columns, suggesting a right-side-out orientation. The isolated sperm membrane vesicles exhibit species specific adhesion to the surfaces of sea urchin eggs; this adhesion is blocked by pretreatment of the vesicles with trypsin or egg jelly. This method will be useful for isolating biologically active sperm membrane components involved in sperm-egg recognition during fertilization.     

Studies of the mechanism of the electrical polyspermy block using voltage clamp during cross-species fertilization

Prevention of polyspermic fertilization in sea urchins (Jaffe, 1976, Nature (Lond.). 261:68-71) and the worm Urechis (Gould-Somero, Jaffe, and Holland, 1979, J. Cell Biol. 82:426-440) involves an electrically mediated fast block. The fertilizing sperm causes a positive shift in the egg's membrane potential; this fertilization potential prevents additional sperm entries. Since in Urechis the egg membrane potential required to prevent fertilization is more positive than in the sea urchin, we tested whether in a cross-species fertilization the blocking voltage is determined by the species of the egg or by the species of the sperm. With some sea urchin (Strongylocentrotus purpuratus) females, greater than or equal to 90% of the eggs were fertilized by Urechis sperm; a fertilization potential occurred, the fertilization envelope elevated, and sometimes decondensing Urechis sperm nuclei were found in the egg cytoplasm. After insemination of sea urchin eggs with Urechis sperm during voltage clamp at +50 mV, fertilization (fertilization envelope elevation) occurred in only nine of twenty trials, whereas, at +20 mV, fertilization occurred in ten of ten trials. With the same concentration of sea urchin sperm, fertilization of sea urchin eggs occurred, in only two of ten trials at +20 mV. These results indicate that the blocking voltage for fertilization in these crosses is determined by the sperm species, consistent with the hypothesis that the fertilization potential may block the translocation within the egg membrane of a positively charged component of the sperm.     

Physiological studies on the sperm surface component responsible for sperm-egg bonding in sea urchin fertilization : I. Effect of sperm-binding protein on the fertilizing capacity of sperm

When sea urchin sperm is pretreated with sperm-binding protein prepared from the vitelline membrane of eggs of homologous species, it loses its fertilizing capacity entirely without losing its motility. It is not affected at all by sperm-binding protein from heterologous species. Neither agglutination nor acrosome reaction is evoked by the pretreatment. It is suggested that the sea urchin spermatozoon has on the apical part of its head a component which is complementary to the sperm-binding protein of the egg, and that the observed loss of the fertilizing capacity is caused by antedated interaction of this component with sperm-binding protein added before insemination.     

Sea urchin sperm head plasma membranes: characteristics and egg jelly induced Ca2+ and Na+ uptake

Sea urchin sperm respond to egg factors with changes in the ionic permeability of their plasma membrane. It has been previously shown that plasma membranes isolated preferentially from sea urchin sperm flagella respond to egg jelly increasing their Ca2+ and Na+ uptake (Darszon et al. (1984) Eur. J. Biochem. 144, 515-522). However, the egg jelly induced acrosome reaction occurs in the sperm head, and there is evidence for an heterogeneous distribution of plasma membrane components within the various regions of this cell. We here report a method for purifying sperm head membranes using positively charged beads according to Jacobson (1977) Biochim. Biophys. Acta 471, 331-335). Under the transmission electron microscope these membranes appeared homogeneous and apparently free of internal membranes. The yield of the preparation was 0.9% of the total protein in the sperm homogenate. The preparation contained less than 5% of the mitochondrial marker cytochrome oxidase, and 10% of the total DNA/mg protein. Surface labeling with 125I indicated a 2.5-3-fold enrichment in specific activity of the head membranes with respect to whole sperm. The SDS band pattern and the lipid composition of this preparation were different from those of isolated flagellar membranes. Phosphatidylcholine was higher in the head membranes, while phosphatidylserine and phosphatidylethanolamine were lower. The head membranes displayed a 1.7-2.3-fold higher Ca2+-ATPase activity and a 2.5-fold lower Na+/K+-ATPase activity, than the flagellar membranes. These results are consistent with a heterogeneous distribution of membrane components along the sea urchin sperm plasma membranes. Isolated head membranes sonicated in the presence of soybean phospholipid liposomes responded to egg jelly with a species-specific increase in Ca2+ and Na+ uptake. As in whole sperm, Ca2+ uptake was inhibited by the Ca2+ channel blocker nisoldipine. A close analog of this compound, [3H]nitrendipine, binds with high affinity to head membranes in a saturable, reversible manner, showing a Kd and Bmax of 31 nM and 5.3 pmol/mg protein, respectively.     

Fertilization induced changes in sea urchin sperm: mitochondrial deformation and phosphatidylserine exposure

This study demonstrates that the single mitochondrion of the sea urchin sperm undergoes a shape change at fertilization that is linked to respiration. The mitochondrion swells and shifts to the lateral side of the sperm head on contact with the homologous egg jelly or egg surface; Mg(2+)- or Na(+)-free seawater or respiratory inhibitors also induce this change. During the mitochondrial deformation, the sperm decreases the rate of oxygen consumption and their redox-state of cytochromes is disrupted b-c(1)/c. Simultaneously, the adenine nucleotides content changes precipitously. This suggests that mitochondrial morphology is strongly associated with respiratory activities in the sea urchin sperm. These changes in mitochondrial morphology and function are similar to the mitochondrial changes in apoptotic cells such as swelling, decrease in its membrane potential, and release of cytochrome c. In apoptotic cells, the exposure of phosphatidylserine from the inner to outer leaflet of the plasma membrane is one of prominence phenomena. This change was visualized by staining the sea urchin sperm with Annexin V-Fluorescein. It is possible that mitochondrial deformation is an initial sign of sperm destruction, which like as apoptotic cells.     

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.     

A study of factors involved in induction of the acrosomal reaction in sperm of the sea urchin, Arbacia punctulata.

Several factors involved in induction of the acrosomal reaction in sperm of the sea urchin, Arbacia punctulata, have been investigated quantitatively using a simple substrate film technique to monitor extension of the acrosomal process by electron microscopy. Verification of typical acrosomal process formation has been accomplished using thin sections. Sperm were found to undergo the acrosomal reaction in artificial sea water in the absence of egg jelly coat at pH values above 9.6. In the presence of egg jelly a high percentage of sperm react at pH 8.6. At this pH, the fraction of sperm that undergo the acrosomal reaction is directly proportional to the concentration of egg jelly. The Ca²⁺ ionophore A23187 induces the acrosomal reaction in the absence of egg jelly at pH 8.6. The proportion of sperm that react is dependent on the concentration of ionophore and on the concentration of Ca²⁺ in the medium. Pretreatment of sperm with low levels of La³⁺ ion, which is known to be a Ca²⁺ ion antagonist, results in inhibition of egg jelly induction of the acrosomal reaction. These findings suggest that there are marked similarities between the acrosomal reaction in sea urchin sperm and membrane fusion dependent secretory processes in other cell types.     

Sea urchin sperm cation-selective channels directly modulated by cAMP

Components of the sea urchin outer egg jelly layer such as speract drastically change second messenger levels and membrane permeability in sperm. Ion channels are deeply involved in the sperm-egg dialogue in sea urchin and other species. Yet, due to the small size of sperm, studies of ion channels and their modulation by second messengers in sperm are scarce. In this report we offer the first direct evidence that cation-selective channels upwardly regulated by cAMP operate in sea urchin sperm. Due to their poor selectivity among monovalent cations, channel activation in seawater could contribute to sperm membrane repolarization during the speract response.     

A third sea urchin sperm receptor for egg jelly module protein, suREJ2, concentrates in the plasma membrane over the sperm mitochondrion

Sea urchin spermatozoa are model cells for studying signal transduction events underlying flagellar motility and the acrosome reaction. We previously described the sea urchin sperm receptor for egg jelly 1 (suREJ1) which consists of 1450 amino acids, has one transmembrane segment and binds to the fucose sulfate polymer of egg jelly to induce the sperm acrosome reaction. We also cloned suREJ3 which consists of 2681 amino acids and has 11 putative transmembrane segments. Both these proteins localize to the plasma membrane over the acrosomal vesicle. While cloning suREJ1, we found suREJ2, which consists of 1472 amino acids, has two transmembrane segments and is present in the entire sperm plasma membrane, but is concentrated over the sperm mitochondrion. Experimental evidence suggests that, unlike suREJ1 and suREJ3, suREJ2 does not project extracellularly from the plasma membrane, but is an intracellular plasma membrane protein. All three sea urchin sperm REJ proteins possess a protein module of > 900 amino acids, termed 'the REJ module', that is shared by the human autosomal dominant polycystic kidney disease protein, polycystin-1, and PKDREJ, a testis-specific protein in mammals whose function is unknown. In the present study, we describe the sequence, domain structure and localization of suREJ2 and speculate on its possible function.     

A reevaluation of the fertilizin hypothesis of sperm agglutination and the description of a novel form of sperm adhesion

The classical isoagglutination of sea urchin sperm by egg jelly is not an agglutination of cells, as proposed by the fertilizin-antifertilizin hypothesis. Sperm motility is required to obtain the isoagglutination of Strongylocentrotus purpuratus sperm, and the sperm do not adhere to each other in the isoagglutination clusters, which cannot be fixed for microscopy and which disperse rapidly into individual cells when sperm motility is inhibited. These observations suggest that isoagglutination is the swarming of freely moving sperm to a common focus and is quite distinct from the agglutination of sperm by known crosslinking agents (antibodies or lectins).A previously unrecognized form of sperm agglutination is described which follows induction of an acrosome reaction by egg jelly, ammonia, or the ionophore A23187 in a suspension of sea urchin or sand dollar sperm. The sperm form rosettes of up to 100 cells in which the newly extended acrosomal processes adhere to each other. Rosettes can form containing sperm of different species, in which the acrosomal processes adhere without species preference.As observed by transmission electron microscopy, the acrosomal process of Lytechinus pictus sperm consists of an acrosomal tubule covered by a sheath of extracellular material. Rosette formation results from attachment between the extracellular materials of adjacent sperm.Less frequently, the acrosomal process of one sperm adheres to the midpiece of another by fusion of the acrosomal tubule and midpiece plasma membranes.     

ELECTRON MICROSCOPE STUDIES OF EARLY STAGES OF SPERM PENETRATION IN HYDROIDES HEXAGONUS (ANNELIDA) AND SACCOGLOSSUS KOWALEVSKII (ENTEROPNEUSTA)

1. The early events of sperm entry in Saccoglossus and Hydroides are described and examined in relation to present knowledge of the acrosome reaction and of egg membrane lysins. In Saccoglossus and several other species these events occur in two phases. First. The acrosome filament of the spermatozoön spans the egg membrane barriers, reaches the reactive egg protoplasm, and causes the egg to begin its fertilization reaction. Second. The filament and its connected sperm head move through the egg membrane barriers and enter the egg proper. The first phase is completed in a matter of seconds but the second phase usually requires several minutes. 2. The peripheral areas of the eggs of the two species differ as seen in sections. In Hydroides, but not in Saccoglossus, the vitelline membrane is bounded by a distinct outer border layer of small concentrically differentiated bodies and penetrated by microvilli from the egg. 3. The acrosome filament, seen in the living condition as a delicate thread in Hydroides and as an exceedingly tenuous thread in Saccoglossus, appears to be tubular in both species when seen in electron micrographs of thin sections. 4. The acrosomal region of Hydroides appears to consist of two components—a peripheral one, which may collapse during the acrosome reaction, and a central one related to the acrosome filament. 5. Deliberately induced polyspermic material was used to increase the probability of finding examples of sperm penetration in thin sections. 6. As seen in sections, areas of low electron density, interpreted as spaces or pits from which the material of the membrane is absent, surround the attached or penetrating spermatozoa. (a) In Hydroides the spaces vary greatly in many characteristics including shape, position in the membrane, and size with relation to the enclosed sperm head. In one specimen a portion of the membrane is missing from border to border; no spermatozoön is seen but immediately beneath the space is the apex of a fertilization cone. (b) In every case in which a determination could be made, the spermatozoön in the membrane has undergone its acrosome reaction. (c) In Saccoglossus some pits are found with which several spermatozoa are associated. Generally, where the spermatozoa are more numerous the pit is larger. (d) Pits similar to those seen in Saccoglossus sections are observed in living eggs. They remain in Membrane I after sperm entry. (e) From the above and other considerations it is suggested that the pits and spaces are formed by local action of a lysin or lysins emanating from the individual spermatozoön at the site of sperm entry. 7. It is considered that the suggested lysin would participate in sperm entry by eroding the membrane barrier in the vicinity of the sperm head, thus permitting the sperm head to pass through the membrane. Since the acrosome filament much earlier stimulates the egg's initial fertilization response, this lysin would facilitate the second phase of the early events of sperm entry.     

Induction of cross-fertilization between sea urchin eggs and starfish sperm by polyethylene glycol treatment

Cross-fertilization between sea urchin eggs (Strongylocentrotus nudus) and starfish sperm (Asterina pectinifera) was induced by treatment with polyethylene glycol (PEG). Without treatment with PEG, the denuded egg surface (jelly coat- and vitelline coat-free) engulfed the head of acrosome-reacted sperm; however, sperm penetration did not occur [Kyozuka and Osanai, 1988]. When these eggs were exposed briefly to PEG (molecular weight 3,000) in seawater, the sperm entered the egg by membrane fusion. Cortical granules were discharged, and embryogenesis began following sperm penetration. PEG did not induce parthenogenesis in Strongylocentrotus eggs. Egg activation is thus closely linked with gamete membrane fusion.     

Morphology of gametes in sea urchins from Peter The Great Bay,Sea of Japan

The fine structure of the gametes in six sea urchin species of the Sea of Japan was studied. The sperm in Strongylocentrotus nudus, S. intermedius, Echinocardium cordatum, Scaphechinus mirabilis, Sc. griseus and Echinarachnius parma are species-specific. The conical head and symmetrically disposed ring-shape mitochondrion are common to regular sea urchin sperm cells. S. nudus is characterized by the bulb-shaped head of the sperm; S. intermedius, by a bullet-shaped one. The sperm spearhead and small amount of post-acrosome material are common to irregular sea urchins; the sperm width: length ratio varies for different species, with the highest for Sc. mirabilis. The sperm of Sc. griseus is characterized by two lipid drops in the middle part of sperm. Asymmetrical mitochondrion disposal is usual for E. parma. Actin filaments are found in the postacrosome material in the sperm of heart-shaped sea urchins. The differences in the fine structure of sperm in cosmopolitan species Ech. cordatum inhabiting the Sea of Japan and coastal areas of the Northeast Atlantic may bear record to the complex existence of species Ech. cordatum. The fine structure of sperm is unique for each of the studied families, Strongylocentrotidae, Scutellidae, and Loveniidae. The eggs of all the species are characterized by vitelline and jelly-like membranes. The vitelline membrane is formed by cytoplasm protrusions; the area between them is filled with fibrillar material. The jelly-like membrane is formed by fibrillar material associated with apical parts of microvilli of the vitelline membrane. The irregular sea urchins Sc. griseus, Sc. mirabilis and E. parma are characterized by chromatophores situated in the jelly-like membrane, with the highest abundance in Sc. mirabilis.     

Bioelectric responses of sea urchin eggs inseminated with oyster spermatozoa: a sperm evoked potential without egg activation

Multiple oyster spermatozoa can enter sea urchin eggs with or often without fertilization membrane formation (Osanai and Kyozuka, 1982). In the present work, electrical responses of sea urchin (Temnopleurus hardwicki) eggs inseminated with oyster (Crassostrea gigas) sperm were examined and correlated to the failure of monospermy and egg activation. With diluted sperm, a transient depolarization of the membrane with a constant pattern appeared repeatedly and discretely, and the depolarizations (sperm evoked potentials, SEPs) were not associated with fertilization membrane elevation. With dense sperm, the SEPs occurred consecutively, and sometimes an assembled consecutive depolarization was followed by an activation potential associated with cortical granule discharge. When the membrane potential was artificially held at positive levels, the frequency of SEPs was strongly suppressed but not completely blocked. The present results indicate that an individual heterologous spermatozoon neither produces a depolarization sufficient to block additional sperm entry, nor stimulates egg activation, and that simultaneous entries of multiple heterologous spermatozoa, as possibly reflected by the assembled consecutive depolarizations, induce cortical granule discharge and egg activation.     

Studies on fertilization in the ascidians : II. Lectin binding to the gametes of ciona intestinalis

In the present work we have compared the binding of fluorescein-conjugated lectins (concanavalin A (ConA), wheat germ agglutinin (WGA), fucose binding protein (FBP) and soybean agglutinin (SBA)) to the sperm surface and to the egg and its envelopes of Ciona intestinalis. Only WGA is bound to the follicle cells: yet this lectin has no binding sites on the sperm surface. Both ConA and FBP are bound by the chorion, the oolemma and the sperm surface. However, while ConA reacts only with the sperm head, FBP is bound both to the head and to the flagellum. Experiments on the effect of ConA and FBP on the fertilization reaction have been carried out. The role of the lectin-binding sites that are shared by the surfaces of both gametes is discussed in connection with the nature of the sperm-binding sites.     

The involvement of O-linked oligosaccharide chains of the sea urchin egg receptor for sperm in fertilization

Recent investigations on the sea urchin egg receptor for spermhave led to its sequencing and the demonstration that it isa 350 kDa glycoprotein. In the current study, the N- and O-linkedoligosaccharide chains were cleaved from the protein fractionatedon concanavalin A-agarose. The putative O-linked oligosaccharidechains that did not bind to the lectin were further fractionatedby anion-exchange chromatography. Using a competition bioassaythat measured the ability of these oligosaccharide chains toinhibit fertilization, it was found that the N-linked chainswere devoid of inhibitory activity. Rather, the inhibitory activitywas localized to the O-linked chains, with the most highly charged,sulphated chains showing the highest inhibitory activity. Thebioactive oligosaccharides were labelled by reduction and assayedfor binding to sperm. The results of the binding assay, coupledwith the fertilization bioassay, indicate that the oligosaccharidesinhibit fertilization by binding to acrosome-reacted sperm.The bioactive oligosaccharide lacked species specificity infertilization bioassays, unlike the intact receptor and a recombinantaglyco protein containing only the extracellular domain of thereceptor. Since previous work showed that the recombinant proteininhibits fertilization species specifically and binds to acrosome-reactedsperm, a two-step model of sperm-egg interaction is proposed.The first step is postulated to be a low-affinity ionic interactionof the sulphated O-linked oligosaccharide chains of the receptorwith sperm that is not species specific. This is followed bya high affinity, species-specific interaction of the sperm withone or more binding sits on the polypeptide chain of the receptor. fertilization oligosaccharide receptor sea urchin egg sea urchin sperm     

An intermediate state of fertilization involved in internalization of sperm components

The pathway of sperm entry during sea urchin fertilization was analyzed by using sperm covalently labeled with fluorescent and radioactive tracers. Sperm that have been covalently labeled on their surfaces with fluorescein isothiocyanate (FITC) or a radioactive congener, diiodofluorescein isothiocyanate (¹²⁵IFC), transfer labeled components to the egg that persist throughout early development. In order to study the transfer of sperm components and their fate after fertilization, cytochalasin B-dependent inhibition of fertilization, previously shown to permit the cortical reaction of sea urchin eggs but block sperm pronuclear incorporation, was investigated. Under certain conditions cytochalasin B or D (CB or CD) results in about half of the activated eggs having both the sperm nucleus and the fluorescently labeled sperm components arrested apparently at the level of the egg plasma membrane. This arrest of internalization was reversed by removal of CB or CD, and the sperm derivatives entered the egg. When sperm were labeled noncovalently with ethidium bromide or rhodamine 123, fluorescence was transferred to the egg in the cytochalasin-inhibited state in a fashion similar to that found in normal fertilization; in both cases the sperm fluorescence disappeared within a few minutes of fertilization, due to the repartitioning of the noncovalent dyes into the egg cytoplasm. It is concluded that cytochalasin arrests fertilization at an intermediate step in which the sperm has fused with the egg to achieve cytoplasmic continuity, but in which the subsequent internalization of sperm components is inhibited. After removal of cytochalasins the fluorescent sperm components move from the egg surface to an internal site, a process that can be monitored by time-lapse video microscopy with an image intensifier to permit extended observations of sperm fluorescence. The cytoplasmic location of labeled sperm components was substantiated by autoradiography of early embryos fertilized with ¹²⁵IFC-labeled sperm; transfer of sperm components to an internal site was seen after fertilization of either sea urchin or mouse eggs. Taken together, the data suggest that the fate of the labeled sperm surface components, as well as that of the sperm nucleus, is to be transferred to the egg cytoplasm, and that this transfer is mediated by the actin-dependent cytoskeleton of the egg.     

Stoichiometry of phosphate loss from sea urchin sperm guanylate cyclase during fertilization

Spermatozoa of the sea urchin Arbacia punctulata possess a phosphorylated guanylate cyclase as a major glycoprotein of the flagellar plasma membrane. When sperm cells contact the jelly layer surrounding the egg, the peptide "resact" binds the sperm cell surface and triggers the dephosphorylation of the cyclase. A large decrease in cyclase activity accompanies dephosphorylation. Before treatment of sperm cells with egg jelly the enzyme contains 17.95 +/- 1.24 moles phosphate per mole cyclase. After treatment of sperm cells with egg jelly this number decreases to 2.57 +/- 0.42. Based on a molecular weight of 137,250 for the peptide chain, approximately 15 phosphate groups are lost per molecule of guanylate cyclase at fertilization.     

Species-specific sperm adhesion in sea urchins. A quantitative investigation of bindin- mediated egg agglutination

Bindin, a protein component of the acrosomal vesicle of sea urchin sperm, has been isolated from Arbacia punctulata and strongylocentrous purpuratus. Using this isolated bindin, we have devised a quantitative assay for bindin-mediated egg agglutination and compared the agglutination of bindin eggs from A. puntulata and S. purpuratus. Bindin- mediated agglutination is species –specific in both species, although a measurable degree of heterotypic interaction is observed. Homotypic bindin-egg interactions differ significantly from heterotypic interactions both in the extent of agglutination and the size of the resulting aggregates. We also provide direct evidence that bindin particles agglutinate eggs by adhering to the surfaces of adjacent eggs. Although the A. punctulata bindin preparation displays the same functional properties and consists of one major polypeptide of the same apparent molecular weight as S. purpuratus bindin, its morphology is very different. Unlike the spherical aggregates observed with S. purpuratus bindin, A punctulata bindin exists as lamellar vesicles and binds significant amounts of phospholipids and Triton X-100, suggesting that it may be tightly associated with the acrosomal membrane. Having defined a number of the basic parameters of bindin-mediated agglutination, we examined the effect of a number of saccharides and glycopeptides on bindin-mediated egg agglutination. Carbohydrate-containing components derived from the egg cell surface by proteolysis were found to inhibit bindin-mediated egg agglutination at low concentrations, but this inhibition is not species specific.