Seasonal variations in the production of the egg-jelly macromolecule,a fucose sulphate glycoconjugate,by the accessory cells in the ovary of the sea urchin Hemicentrotus pulcherrimus

In the sea urchin Hemicentrotus pulcherrimus, the egg-jelly macromolecule, a fucose sulphate glycoconjugate (FSG) that induces the acrosome reaction in spermatozoa, originates from the accessory cells in the ovary. In the present study we examined the seasonal variations in the distribution of FSG in the ovary by immunocytochemistry with a polyclonal antibody. An enzyme-linked immunosorbent assay indicated that FSG was present in supernatants of extracts of ovaries throughout the development of the ovary. However, the immunohistochemical study showed that there are marked seasonal changes in the distribution of FSG in ovaries. The polyclonal antibody reacted strongly with globules of accessory cells before the beginning of the breeding season (August to December). During the breeding season (February to April), the immunohistochemical reaction was found on the surface of oocytes but was weak in the accessory cells. At the ultrastructural level, the antibody reacted with globules of variable density in accessory cells. Intense immunolabelling was observed in the vacuole-like structures of the globules. Sometimes, products of the specific immunocytochemical reaction were found in the Golgi apparatus in these globules. Quantitative examination indicated that FSG was actively produced by the accessory cells from the late non-breeding season to the pre-breeding season. These results suggest that there are marked seasonal variations in the production of FSG by the accessory cells in the sea urchin ovary. These findings also provide new evidence that accessory cells exhibit dynamic changes during the reproductive process in the sea urchin.     

Effect of sulfated glycoconjugates on capacitation and the acrosome reaction of bovine and hamster spermatozoa

The effects of sulfated glycoconjugates on the preparation of mammalian sperm for fertilization were investigated. The three sulfated glycoconjugates tested were heparin, dextran sulfate, and the fucose sulfate glycoconjugate (FSG) from the sea urchin egg jelly coat. In vivo, FSG induces the acrosome reaction in sea urchin sperm. Bovine sperm were found to be capacitated by heparin and FSG as judged both by ability of lysophosphatidylcholine (LC) to induce an acrosome reaction and by ability to fertilize bovine oocytes in vitro. The mechanism by which heparin or FSG capacitated bovine sperm appeared similar, since glucose inhibited capacitation by both glycoconjugates. In contrast to effects on bovine sperm, heparin and FSG induced the acrosome reaction in capacitated hamster sperm. When hamster sperm were incubated under noncapacitating conditions, heparin had no effect on capacitation or the acrosome reaction. Three molecular weights (MW) of dextran sulfate (5,000, 8,000, 500,000) were found to capacitate bovine sperm as judged by the ability of LC to induce an acrosome reaction. Whereas bovine sperm incubated with 5,000 or 8,000 M W dextran sulfate fertilized more bovine oocytes than control sperm (P <0.05), sperm treated with 500,000 M W dextran sulfate failed to penetrate oocytes. The high-MW dextran sulfate appeared to interact with the zona pellucida and/or sperm to prevent sperm binding. Results suggest that sulfated glycoconjugates may prepare sperm for fertilization across a wide range of species.     

The jelly canal marker of polarity for sea urchin oocytes, eggs, and embryos

The jelly coat of a sea urchin egg possesses a narrow conical channel which identifies the animal pole. This rarely seen structure was first reported by Boveri in 1901 and is easily demonstrated by immersing freshly ovulated eggs into an ink suspension. The jelly canal, as this feature is called, fills with ink particles as the jelly swells. The jelly canal occurs on full-sized primary oocytes and unfertilized eggs. When filled with ink it serves as a useful marker of the animal pole during fertilization and early development when it is not otherwise visible. A common synonym for the jelly canal is ‘micropyle’, but this is a misnomer because sperm do not selectively pass through it for fertilization. The presence of the jelly canal on oocytes suggests how it might form and does not prove that the animal-vegetal polar axis in sea urchin eggs is defined before meiotic maturation.     

Fertilization of the starfish Astropecten aurantiacus

In the starfish Astropecten aurantiacus the acrosome reaction occurs when the spermatozoon contacts the outer surface of the jelly layer. A long thin acrosomal filament is extruded from the anterior region of the spermatozoon and establishes contact with the oocyte surface. This latter interaction initiates the movement of the spermatozoon to the oocyte surface, formation of the fertilization cone and the cortical reaction. The first detectable electrical change across the oocyte plasma membrane during interaction with the spermatozoon is the fertilization potential (FP) which occurs simultaneously with the cortical reaction. The FP is probably the electrical result of the modification of the oocyte plasma membrane during cortical exocytosis. There are no primary step-like depolarizations during fertilization of starfish oocytes, which contrasts with the situation in sea urchin eggs [see 13]. We suggest that the difference in electrical response to fertilization of starfish oocytes and sea urchin eggs may be attributed to the location of the acrosome reaction in these animals and not to their different meiotic states.     

Cortical granule-specific components are present within oocytes and accessory cells during sea urchin oogenesis

The coordinate expression of cortical granule-specific components in sea urchin oogenesis was studied using antibody probes. The components used to generate the organelle-specific antibodies included the whole cortical granule exudate, fertilization envelopes, hyalin, beta, 1-3,glucanase, and Ig8. Using immunolocalization techniques at both the light and electron microscopic levels, these molecules were found to be specific to cortical granules in three distinct cell types: developing oocytes, eggs, and accessory cells. In early oocytes, each of the cortical granule components are coordinately accumulated in the developing cortical granules dispersed throughout the cytoplasm. No other organelle within the developing oocytes or eggs contained detectable levels of any of these epitopes. In the somatic interstitial tissue of the ovary, cortical granule components also were accumulated specifically within cortical granule structures. Found only in select accessory cells, these cortical granules were indistinguishable in morphology and epitope composition from eggs and were contained within cytoplasmic aggregates termed mosaic globules. The mechanism of cortical granule concentration into mosaic globules is unknown, but this demonstration of common organelle constituents between oocytes and accessory cells may provide insight for such an understanding.     

Activation of phospholipase D by the fucose-sulfate glycoconjugate that induces an acrosome reaction in spermatozoa

We report for the first time that phospholipase D activity in sea urchin spermatozoa can be regulated by a component of egg jelly known to induce an acrosome reaction. The fucose-sulfate glycoconjugate (FSG) of egg jelly that induces an acrosome reaction in spermatozoa caused Ca2+-dependent increases in 1,2-diacylglycerol and phosphatidic acid. Diacylglycerol concentrations were increased 2-fold, and phosphatidic acid concentrations were elevated up to 10-fold 2 min after the addition of FSG to spermatozoa. FSG also caused increases in choline, but not in choline phosphate concentrations. Neither phosphorylation of diacylglycerol nor de novo synthesis from glycerol were significant routes of synthesis of phosphatidic acid during the acrosome reaction. When spermatozoa were incubated with FSG in the presence of ethanol, phosphatidylethanol was produced. As ethanol concentrations in the extracellular medium were increased from 0.1 to 2.5%, the amount of phosphatidylethanol increased, whereas phosphatidic acid concentrations decreased, suggesting a competitive transphosphatidylation reaction catalyzed by phospholipase D. Furthermore, when a phosphatidylcholine pool in spermatozoa was radiolabeled using [3H]1-O-alkyl-2-lyso-glycerol-3-phosphorylcholine, the subsequent addition of FSG caused a 4-fold accumulation of [3H]phosphatidic acid. FSG-induced elevations in [3H]phosphatidic acid were positively correlated with the percent of cells that had undergone an acrosome reaction.     

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.     

Selective transport and packaging of the major yolk protein in the sea urchin

The major yolk protein of sea urchins is an iron-binding, transferrin-like molecule that is made in the adult gut. Its final destination though is the developing oocytes that are embedded in somatic accessory cells and encompassed by two epithelial layers of the ovary. In this study, we address the dynamics of yolk transport, endocytosis, and packaging during the vitellogenic phase of oogenesis in the sea urchin by use of fluorescently labeled major yolk protein (MYP). Incorporation of MYP into the accessory cells of the ovary and its packaging into yolk platelets of developing oocytes is visualized in isolated oocytes, ovary explants, and in whole animals. When MYP is introduced into the coelom of adult females, it is first accumulated by the somatic cells of the ovarian capsule and is then transported to the oocytes and packaged into yolk platelets. This phenomenon is specific for MYP and accurately reflects the endogenous MYP packaging. We find that oocytes cultured in isolation are endocytically active and capable of selectively packaging MYP into yolk platelets. Furthermore, oocytes that packaged exogenous MYP are capable of in vitro maturation, fertilization, and early development, enabling an in vivo documentation of MYP utilization and yolk platelet dynamics. These results demonstrate that the endocytic uptake of yolk proteins in sea urchins does not require a signal from their surrounding epithelial cells and can occur autonomous of the ovary. In addition, these results demonstrate that the entire population of yolk platelets is competent to receive new yolk protein input, suggesting that they are all made simultaneously during oogenesis.     

Purification and Characterization of the Egg Jelly Macromolecules, Sialoglycoprotein and Fucose Sulfate Glycoconjugate, of the Sea Urchin Hemicentrotus Pulcherrimus

A sialoglycoprotein and a fucose sulfate glycoconjugate (FSG) were purified from egg jelly of the sea urchin Hemicentrotus pulcherrimus . Sialoglycoprotein which consisted of sialic acid (90%, w/w) and protein (10%, w/w) did not cause induction of the acrosome reaction and sperm isoagglutination. FSG which contained one mol sulfate/mol fucose possessed 2.0 times protein to fucose by weight. The proteins in intact FSG were separated to two major (258 kDa and 237 kDa) and one minor (120 kDa) proteins by SDS-polyacrylamide gel electrophoresis (SDS-PAGE) in the presence of 2-mercaptoethanol (2-ME) while the proteins could not be separated by HPLC in the presence of 0.1% SDS or SDS-PAGE without 2-ME. However, after carboxymethylation of FSG, two major (260 kDa and 240 kDa) proteins and two minor (140 kDa and 135 kDa) proteins were separated from the fucose sulfate moiety by HPLC in the presence of 0.1% SDS or SDS-PAGE without 2-ME. When FSG was first carboxymethylated with non-radioactive iodoacetic acid and then reduced with 2-ME and finally carboxymethylated with ¹⁴C-iodoacetic acid, the most of radioactivity was detected in 140 kDa and 135 kDa proteins. Carboxymethylted-FSG was less potent than intact FSG in induction of the acrosome reaction. Fucoidan, a fucose sulfate polymer, did not induce the acrosome reaction.     

Ovarian follicle growth in the catfish Iheringichthys labrosus (Siluriformes: Pimelodidae)

The morphofunctional organisation of the female reproductive system, the oocyte growth and the follicular envelope ultrastructure were studied by the first time in the catfish Iheringichthys labrosus from Upper Paraná River basin, Southeastern Brazil, in order to contribute to the knowledge of the reproductive behaviour strategies of this species. As in other Neotropical freshwater siluriforms, the ovaries are of the cystovarian type, the oocytes develop in an asynchronous pattern and mature oocytes are released in clusters in the ovarian lumen, being transported through the oviduct to the urogenital papilla. During the primary growth, nuclear material is transported to the ooplasm, forming the yolk nucleus, where proliferate membranous organelles. The onset of the zona radiata formation occurs during the late perionucleolar stage with the deposition of the outer layer. At the vitellogenic stage, this envelope reaches 6.35+/-0.84microm of thickness, being constituted by three distinct layers crossed by pore-canals containing oocyte and follicular cells processes. Cytochemical analyses evidence neutral glycoproteins in cortical alveoli, yolk globules and zona radiata. Follicular cells with squamous shape during the primary growth acquire synthetic activity at the secondary growth, reaching 37.82+/-4.72mum in height at the mature vitellogenic follicles. These cells accumulate sulphated polysaccharides in large electron-lucent vesicles during the vitellogenic stage which are possibly secreted to form a mucous coat at the egg surface. These evidences suggest that I. labrosus may have adhesive eggs as also detected in other Neotropical freshwater Siluriformes.     

Chemical characterization of the component of the jelly coat from sea urchin eggs responsible for induction of the acrosome reaction.

Jelly coat, a multicomponent extracellular matrix surrounding the sea urchin egg, induces the acrosome reaction in sperm. The jelly coats of the four species studied, Arbacia punctulata, Strongylocentrotus purpuratus, Strongylocentrotus drobachiensis, and Lytechinus variegatus, were found to be very similar in chemical composition. A sialoprotein (approximately 20% of the mass of the jelly coat) and a fucose sulfate polysaccharide (approximately 80%) are the major macromolecular components of the jelly coat. The acrosome reaction inducing capacity resides solely in the fucose sulfate polysaccharide. Induction of the acrosome reaction ranges from highly species specific to nonspecific. Thus, A. punctulata and S. drobachiensis sperm are induced to undergo the acrosome reaction only with their homologous jelly coat, while S. purpuratus sperm react equally well with homologous or L. variegatus jelly coat, but not with A. punctulata jelly coat. L. variegatus sperm seem to be relatively nonspecific in response. Species-specific induction of the acrosome reaction resides solely in the fucose sulfate polysaccharide, suggesting that there must be structural differences in this polysaccharide in the various species. Therefore, in some species, fertilization appears to involve sperm-egg recognition at the level of the jelly coat as well as at the level of sperm-egg receptors.     

Characterization and biological properties of L-HGP, a glycoprotein from the amphibian oviduct with acrosome-stabilizing effects

BACKGROUND INFORMATION: The role of the jelly coat that surrounds the amphibian oocytes has been widely discussed, but is poorly understood. The presence of the jelly coat is essential for fertilization. However, the structure and function of the molecules that comprise the jelly coat have not been thoroughly documented. L-HGP (low-molecular-mass highly glycosylated protein) is a highly glycosylated protein that is present in the jelly coat of the toad, Bufo arenarum, oocytes and diffuses to the surrounding media. L-HGP, when purified from egg water, protects the sperm acrosome from breakdown induced by hypotonic solutions. RESULTS: L-HGP is an acidic glycoprotein, formed by two different subunits, linked by disulphide bonds. We raised polyclonal antibodies in rabbits against the deglycosylated protein. We determined that L-HGP is secreted along the oviduct, being hence present in all the jelly layers. The molecular mass of L-HGP is higher in the most cephalic region of the oviduct. The lower-M(r) L-HGP isoform, produced in the caudal regions of the oviduct, presents an acrosome-protecting property. L-HGP is produced by secretory cells in the oviduct and is deposited on the cilia at the oviduct lumen. CONCLUSIONS: Biochemical characterization of L-HGP has been carried out. It is synthesized by secretory cells in the oviduct and, when secreted, is deposited over the ciliated surface of the cells. The lower-M(r) isoform, secreted by the caudal region of the oviduct, protects acrosome integrity. This isoform diffuses into the medium. The role of the higher-M(r) L-HGP isoform in fertilization remains unknown.     

A complex cortical reaction leads to formation of the fertilization envelope in the lobster,Homarus

We have examined the formation of the fertilization envelope in the lobsters Homarus americanus and H gammarus. Oocytes were fixed for electron microscopy either in the ovary or following extrusion from the gonopore. Mature ovarian oocytes are surrounded by a coat (envelope 1), which is comprised of small electron-dense granules and structures resembling “bottlebrushes.” At least part of this coat is synthesized by the follicle cells of the ovary. The cortex of ovarian oocytes contains four types of vesicles that we refer to as high-density vesicles (HDV), low-density vesicles (LDV), moderately dense vesicles (MDV), and ring vesicles (RV). Oocytes that were electrically extruded from the gonopore and fixed immediately had an envelope identical to that of ovarian oocytes. The cortex of gonopore oocytes contained the four types of vesicles found in ovarian oocytes. When unfertilized gonopore oocytes were allowed to incubate in sea water, the oocyte cortex appeared unaltered, but envelope 1 swelled and the bottlebrushes dispersed. When recently fertilized oocytes were fixed during natural spawning or following in-vitro fertilization, each type of vesicle was released in sequence from the cortex of the oocyte. The contents of the HDV and LDV appeared first in the perivitelline space, but their fate could not be determined at later times. The ring-shaped elements of the RV and the moderately electron-dense material of the MDV were released exocytotically somewhat later; these materials coalesced in the perivitelline space to form a new coat (envelope 2). Envelope 1 subsequently condensed to its original thickness and appeared firmly attached to envelope 2. Our results show that the fertilized lobster egg is surrounded by two discrete coats. The outer coat, which is formed in the ovary, undergoes a swelling/condensation cycle at spawning. The inner coat originates from a complex cortical reaction. Together these coats comprise the fertilization envelope of the lobster egg.     

Long-Term Changes in the Gonad Condition of the Sea Urchin Strongylocentrotus intermediusfrom Alekseev Bight (Amurskii Bay) under Polluted Conditions

The gonad condition of the sea urchin Strongylocentrotus intermediuscollected in August 1997 at two stations in Peter the Great Bay was examined. One of the stations was located in a polluted area (Alekseev Bight, Popov Island) and the other, in a relatively clean area (the Verkhovskii Islands). The results were compared with analogous data for 1984, 1985, and 1989. In 1997, the gonad condition of sea urchins inhabiting the two areas differed significantly. The mean value of the gonad index (GI) for sea urchins from Alekseev Bight was less than half and the maturity index was about twice that of sea urchins from the Verkhovskii Islands. The GI of sea urchins from Alekseev Bight decreased by a factor of 1.5 between 1984 and 1997. Pronounced histopathological changes were found in sea urchin gonads at this station: granular and hydropic dystrophy of oocytes, resorption and a sharp decrease in the number of gametes (in about 20% of the sea urchins, hardly any gametes were found in the gonads), changes in the morphology of accessory cells (hypertrophy, atrophy, and necrosis), and accumulation of lipofuscin in the cytoplasm of accessory cells and oocytes, in the hemal sinuses and mesentery. The suppressed gonad condition of the sea urchin S. intermediusin Alekseev Bight may be a consequence of the unfavorable environmental situation that formed in the bight in the 1980s–1990s. The main negative factor is anthropogenic pollution of Amurskii Bay.     

Biochemical Studies on the Acrosome Reaction of the Starfish, Asterias Amurensis I. Factors Participating in the Acrosome Reaction

In contrast with the case in sea urchin sperm, in starfish the acrosome reaction is not spontaneously induced by simply increasing the extracellular Ca²⁺ concentration or pH. At higher pHs, starfish sperm undergo morphological changes accompanied by exocytosis of the acrosomal vacuole, but they do not form acrosomal filaments. Nomarski-microscopic observation confirmed that spermatozoa undergo the acrosome reaction within the jelly coat. Acrosome reaction-inducing substance, a glycoprotein from the egg jelly, required a diffusible cofactor(s) present in the egg jelly for full activity. Several lines of evidence showed that this diffusible factor(s) is not merely Ca²⁺.     

Immunohistochemical localization of glutamate decarboxylase in the rat oviduct and ovary: Further evidence for non-neural GABA systems

Summary The distribution of L-glutamate decarboxylase (GAD), a major biosynthetic enzyme for gamma-aminobutyric acid (GABA), was examined in the oviduct and ovary of the rat by means of an immunohistochemical technique. The polyclonal antiserum raised against brain GAD showed specific immunoreaction in some non-neuronal elements of the sex organs. In the oviduct, the inner layer of the mucosa was predominantly labelled. The selective distribution of GAD immunoreactivity in epithelial cells of the oviduct is consistent with former findings for GABA-like immunoreactivity in the same organ, indicating that the GAD-catalyzed reaction may be a major biosynthetic pathway for GABA even in these cells. In the ovary, vacuole-like formations within the follicular fluid and oocytes showed intense, specific staining. The occurrence of GAD immunoreactivity inside developing ovarian follicles including the oocyte may suggest a role for GABA related to follicular development and certain functions concerning the ovum.     

Ovarian maturation and oogenesis in the blue swimmer crab,Portunus pelagicus (Decapoda: Portunidae)

The study was aimed at understanding the process of reproduction and the changes happening in the ovary of Portunus pelagicus during maturation, which would be useful for its broodstock development for hatchery purposes. For that, tissue samples from different regions of the ovary at various stages of maturation were subjected to light and electron microscopy, and based on the changes revealed and the differences in ovarian morphology, the ovary was divided into five stages such as immature (previtellogenic oocytes), early maturing (early vitellogenic oocytes), late maturing (late vitellogenic oocytes), mature (vitellogenic oocytes), and spent (resorbing oocytes). The ovarian wall comprised of an outermost thin pavement epithelium, a middle layer of connective tissue, and an innermost layer of germinal epithelium. The oocytes matured as they moved from the centrally placed germinal zone toward the ovarian wall. The peripheral arrangement of nucleolar materials and the high incidence of cell organelles during the initial stages indicated vitellogenesis I. Movement of follicle cells toward oocytes in the early maturing stage and low incidence of mitochondria and endoplasmic reticulum in the ooplasm during late vitellogenic stage marked the commencement and end of vitellogenesis II, respectively. Yolk granules at various stages of development were seen in the ooplasm from late vitellogenic stage onwards. The spent ovary had an area with resorbing oocytes and empty follicle cells denoting the end of one reproductive cycle and another area with oogonial cells and previtellogenic oocytes indicating the beginning of the next.     

Monoclonal antibodies to the sea urchin egg vitelline layer inhibit fertilization by blocking sperm adhesion

Thirty-one mouse hybridomas were produced against the vitelline layer (VL) of the egg of the sea urchin S. purpuratus. Ascites fluids of eight of the 31 bound to the VL surface in the high ionic strength conditions of sea water. Binding was specific to the VL, since immunofluorescence showed that the antibodies elevated from the egg surface with the fertilization envelope after activation with ionophore A23187. Antibody binding was strictly species-specific, the eggs of L. pictus showing no reaction. An immunoperoxidase surface-binding assay showed a wide range in the amount of each monoclonal antibody binding to the VL surface at saturation. All eight monoclonals inhibit fertilization by inhibiting the binding of sperm to the VL. None of the eight ascites fluids reacted with egg jelly. The inhibition of fertilization correlates positively with amount of antibody binding the egg surface. In contrast to the effects of polyclonal rabbit antisera raised against whole eggs or egg cortices, these eight monoclonal antibodies to the VL do not induce the wrinkling of the egg, the cortical granule reaction, the centering of pronuclei, or any other visual indication of metabolic activation.     

Involvement of an acrosin-like enzyme in the acrosome reaction of sea urchin sperm

Extracts of the jelly coat of eggs of several marine invertebrates are known to induce in homologous sperm morphological changes known as the acrosome reaction. When sperm of the sea urchin Strongylocentrotus purpuratus are treated with low concentrations (0.2 μg fucose/ml) of egg jelly coat or 30 mM CaCl₂ in artificial seawater the acrosome reaction does not occur. However, either of these treatments causes the exposure of an acrosin-like enzyme to exogenous substrate and inhibitors. Subsequent addition of jelly coat to 3.7 μg fucose/ml to sperm in this “initial stage” induces the acrosome reaction (as judged by the appearance of an acrosomal filament). This concentration is also effective for untreated sperm. If inhibitors of the enzyme (diisopropylphosphofluoridate or phenylmethanesulfonyl fluoride) are added to sperm in the initial stage, no acrosomal filaments are observed when the high concentration of jelly coat is added. Whether other morphological changes occur in these sperm has not been examined. If phenylmethanesulfonyl fluoride is added 4 sec after the jelly coat, the acrosomal filaments are observed, but the sperm still fail to fertilize eggs. These results suggest a dual role for the acrosin-like enzyme(s), first in the mechanism of the acrosomal filament formation and then in a subsequent event in the fertilization process.     

The structure of sulfated polysaccharides ensures a carbohydrate-based mechanism for species recognition during sea urchin fertilization

The evolution of barriers to inter-specific hybridization is a crucial step in the fertilization of free spawning marine invertebrates. In sea urchins, molecular recognition between sperm and egg ensures species recognition. Here we review the sulfated polysaccharide-based mechanism of sperm-egg recognition in this model organism. The jelly surrounding sea urchin eggs is not a simple accessory structure; it is molecularly complex and intimately involved in gamete recognition. It contains sulfated polysaccharides, sialoglycans and peptides. The sulfated polysaccharides have unique structures, composed of repetitive units of alpha-L-fucose or alpha-L-galactose, which differ among species in the sulfation pattern and/or the position of the glycosidic linkage. The egg jelly sulfated polysaccharides show species-specificity in inducing the sperm acrosome reaction, which is regulated by the structure of the saccharide chain and its sulfation pattern. Other components of the egg jelly do not possess acrosome reaction inducing activity, but sialoglycans act in synergy with the sulfated polysaccharide, potentiating its activity. The system we describe establishes a new view of cell-cell interaction in the sea urchin model system. Here, structural changes in egg jelly polysaccharides modulate cell-cell recognition and species-specificity leading to exocytosis of the acrosome. Therefore, sulfated polysaccharides, in addition to their known functions as growth factors, coagulation factors and selectin binding partners, also function in fertilization. The differentiation of these molecules may play a role in sea urchin speciation.