THE FERTILIZING CAPACITY OF SEA URCHIN SPERM RAPIDLY DECREASES AFTER INDUCTION OF THE ACROSOME REACTION*

When immotile, flagella-less sperm were added to acid-dejellied eggs of Strongylocentrotus purpuratus 11% of the eggs fertilized. Addition of soluble egg jelly increased the percentage fertilization to 90.5. Over 50% of the sperm exposed to egg jelly had undergone the acrosome reaction compared to only 3–5% in the absence of jelly. Egg jelly was added to flagella-less sperm to induce the acrosome reaction and dejellied eggs added at various times thereafter. The fertilizing capacity of the sperm decreased with first order kinetics with 50% loss by 23 sec after induction of the acrosome reaction. Intact, motile sperm bind to formaldehyde-fixed eggs with maximum binding occurring 40 sec after sperm addition. After 40 sec the sperm begin to detach from the fixed eggs and by 240 sec none remain attached. Sperm detachment from fixed eggs and loss of fertilizing capacity after the acrosome reaction show a close temporal correlation.     

Reduction of the fertilizing capacity of sea urchin sperm by cannabinoids derived from marihuana. I. Inhibition of the acrosome reaction induced by egg jelly.

delta 9-Tetrahydrocannabinol (THC) and two other major cannabinoids derived from marihuana--cannabidiol (CBD) and cannabinol (CBN)--inhibit fertilization in the sea urchin Strongylocentrotus purpuratus by reducing the fertilizing capacity of sperm (Schuel et al., 1987). Sperm fertility depends on their motility and on their ability to undergo the acrosome reaction upon encountering the egg's jelly coat. Pretreatment of S. purpuratus sperm with THC prevents triggering of the acrosome reaction by solubilized egg jelly in a dose (0.1-100 microM) and time (0-5 min)-dependent manner. Induction of the acrosome reaction is inhibited in 88.9 +/- 2.3% of sperm pretreated with 100 microM THC for 5 min, while motility of THC-treated sperm is not reduced compared to solvent (vehicle) and seawater-treated controls. The acrosome reaction is inhibited 50% by pretreatment with 6.6 microM THC for 5 min and with 100 microM THC after 20.8 sec. CBN and CBD at comparable concentrations inhibit the acrosome reaction by egg jelly in a manner similar to THC. THC does not inhibit the acrosome reaction artificially induced by ionomycin, which promotes Ca2+ influx, and nigericin, which promotes K+ efflux. THC partially inhibits (20-30%) the acrosome reaction induced by A23187, which promotes Ca2+ influx, and NH4OH, which raises the internal pH of the sperm. Addition of monensin, which promotes Na+ influx to egg jelly or to A23187, does not overcome the THC inhibition. Inhibition of the egg jelly-induced acrosome reaction by THC produces a corresponding reduction in the fertilizing capacity of the sperm. The adverse effects of THC on the acrosome reaction and sperm fertility are reversible.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Egg water from the amphibian Bufo arenarum induces capacitation-like changes in homologous spermatozoa

Mammalian sperm acquire fertilizing capacity after residing in the female tract, where physiological changes named capacitation take place. In animals with external fertilization as amphibians, gamete interactions are first established between sperm and molecules of the egg jelly coat released into the medium. Since dejellied oocytes are not normally fertilized, the aim of this study was to determine if the jelly coat of the toad Bufo arenarum promotes a “capacitating” activity on homologous sperm. We found that sperm incubation in diffusible substances of the jelly coat (egg water) for 90-180 s is sufficient to render sperm transiently capable of fertilizing dejellied oocytes. The fertilizing state was correlated with an increase of protein tyrosine phosphorylation and a decrease of sperm cholesterol content. Inhibition of either the increase in tyrosine phosphorylation or cholesterol efflux affected the acquisition of fertilizing capacity. Phosphorylation and fertilization could be promoted with NaHCO₃ and also by addition of beta cyclodextrin. Moreover, sperm could gain the ability to fertilize dejellied oocytes in the presence of these compounds. These data indicate that sperm should undergo a series of molecular changes to gain fertilizing capacity; these changes are reminiscent of mammalian sperm capacitation and take place before the acrosome reaction.     

Mechanism of univalent antisperm antibody inhibition of fertilization in the sea urchin, Arbacia punctulata

Univalent antisperm antibodies (IFab) markedly inhibited the fertilizing capacity of sperm when tested on intact, dejellied, and "demembranated" Arbacia punctulata eggs. Sperm motility and egg jelly penetration were not affected by IFab. Antifertilizin was excluded as the essential sperm antigen involved in the fertilization-inhibiting action. Sperm pretreated with IFab did not bind to the surfaces of either dejellied or demembranated eggs, whereas control globulin (CFab) and seawater-pretreated sperm bound to such eggs in high numbers. Electron microscopy showed that IFab-treated sperm failed to undergo the acrosome reaction. This excluded "bindin" as the essential antigen. Inhibition of fertilization by IFab was reversed or bypassed by artificial induction of the acrosome reaction with ionophore A23187. It is concluded that univalent antisperm antibody treatment inhibits the fertilizing capacity of sperm by preventing a sperm-egg interaction that results in the acrosome reaction; consequently, attachment of the sperm to the egg is prevented.     

Egg water from the amphibian Bufo arenarum modulates the ability of homologous sperm to undergo the acrosome reaction in the presence of the vitelline envelope

Sperm from the toad Bufo arenarum must penetrate the egg jelly before reaching the vitelline envelope (VE), where the acrosome reaction is triggered. When the jelly coat is removed, sperm still bind to the VE, but acrosomal exocytosis is not promoted. Our previous work demonstrated that diffusible substances of the jelly coat, termed "egg water" (EW), triggered capacitation-like changes in B. arenarum sperm, promoting the acquisition of a transient fertilizing capacity. In the present work, we correlated this fertilizing capacity with the ability of the sperm to undergo the acrosome reaction, further substantiating the role of the jelly coat in fertilization. When sperm were exposed to the VE, only those preincubated in EW for 5 or 8 min underwent an increase in the intracellular Ca(2+) concentration ([Ca(2+)](i)), which led to acrosomal exocytosis. Responsiveness to the VE was not acquired on preincubation in EW for 2 or 15 min or in Ringer solution regardless of the preincubation time. In contrast, depletion of intracellular Ca(2+) stores (induced by thapsigargin) promoted [Ca(2+)](i) rise and the acrosome reaction even in sperm that were not exposed to EW. Acrosomal exocytosis was blocked by the presence of Ca(2+) chelators independent of whether a physiological or pharmacological stimulus was used. However, Ni(2+) and mibefradil prevented [Ca(2+)](i) rise and the acrosome reaction of sperm exposed to the VE but not of sperm exposed to thapsigargin. These data suggest that the acrosomal responsiveness of B. arenarum sperm, present during a narrow period, is acquired during EW incubation and involves the modulation of a voltage-dependent Ca(2+) channel.     

Heavy metal chelators prolong motility and viability of sea urchin sperm by inhibiting spontaneous acrosome reactions

A variety of heavy metal chelating agents is known to prolong the fertilizing capacity and motility of sea urchin sperm. We report here that these agents maintain fertilizing capacity by preventing acrosome reactions which occur spontaneously after dilution of sperm into seawater. These chelating agents also inhibit acrosome reactions induced by high pH or egg jelly. Since induction of the acrosome reaction leads to steps that abolish motility, specifically a massive Ca2+ uptake and concomitant acidification of the cytoplasm, motility is prolonged by these chelators. These observations also suggest that heavy metals play a role in controlling the acrosome reaction in sea urchin sperm.     

Physiological inducers of the acrosome reaction

This article reviews recent studies on physiological inducers of the acrosome reaction in starfish. Upon encountering the jelly coat of eggs, starfish sperm undergo the acrosome reaction in response to a cooperation of three jelly components: a sulfated glycoprotein named acrosome reaction-inducing substance (ARIS), a group of steroidal saponins named Co-ARIS, and an oligopeptide presumably having an activity to increase the intracellular pH of sperm. ARIS induces the acrosome reaction in high Ca²⁺ or high pH sea water. In normal sea water, both ARIS and Co-ARIS are required for the induction. In addition to ARIS and Co-ARIS, a third jelly component, the oligopeptide, is necessary to mimic the full capacity of the jelly coat to induce the acrosome reaction. ARIS and Co-ARIS cooperatively increase the intracellular Ca²⁺ by stimulating Ca²⁺ channels, while the oligopeptide increases the intracellular pH by stimulating Na⁺/H⁺ exchange systems. When sperm meet the eggs, both changes are simultaneously achieved in them and thus they undergo the acrosome reaction.     

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.     

Acrosome reaction in sperm of the toad,bufo bufo japonicus

The acrosome in the sperm of the toad, Bufo bufo japonicus, consists of a membrane-limited acrosomal cap and a fibrous perforatorium. When sperm are incubated with the oviducal pars recta extract (PRE) for 30–60 min, the outer acrosomal membrane fuses with the overlying plasma membrane at several points with concomitant loss of the contents of the acrosomal cap. The inner acrosomal membrane thus exposed fuses with the plasma membrane at the caudal end of the acrosomal region. This PRE-induced acrosome reaction is completely inhibited by soybean trypsin inhibitor. Sperm found in the innermost jelly layer of inseminated eggs possess an intact acrosome, but those either passing through the vitelline coat or localizing in the perivitelline space are acrosome-reacted in the same manner as when treated with PRE. These observations, combined with recent evidence showing involvement of the pars recta substance in fertilization, indicate that the acrosome reaction occurring in a fertilizing sperm at or near the surface of the vitelline coat is a response to a substance that is derived from the pars recta and deposited in the vitelline coat.     

Effects of protease inhibitors on sperm-related events in sea urchin fertilization

Evidence for sperm-borne proteolytic enzymes exposed during the acrosome reaction in sea urchin sperm has been accumulating. To investigate the possible role(s) such enzymes have in fertilization, we studied the effects of several protease inhibitors on sperm-related events. Soybean trypsin inhibitor, Nα-p-tosyl-l-lysine, chloromethyl ketone, phenylmethylsulfonyl fluoride, and chymostatin neither reduced the number of acrosome reactions nor interfered with gamete binding. p-Nitrophenyl-p′-guanidinobenzoate caused sperm to fuse into irregular clumps, rendering them unable to fertilize eggs. However, l-1-tosylamide-2-phenylethyl chloromethyl ketone (TPCK), an inhibitor of chymotrypsin, prevented the acrosome reaction in Strongylocentrotus purpuratus, S. droebachiensis, and Lytechinus pictus. The effects of TPCK on sperm in subsequent steps of fertilization were also investigated. First, gamete binding assays were performed on fixed eggs. This precluded any effects TPCK might have had on egg-derived secretions (e.g., proteases). Binding of prereacted sperm occurred with both fixed and living eggs. However, fertilization of living eggs in the presence of TPCK was greatly reduced, even though sperm had been prereacted with egg jelly. Vitelline coats were then removed from eggs by trypsin treatment. Eggs in TPCK fertilized and developed normally after the above treatment. These observations are consistent with the hypothesis of a sperm protease participating in the acrosome reaction and the penetration of the egg vitelline coat in the sea urchin.     

Jelly coat and induction of the acrosome reaction in echinoid sperm

In a previous study we established that sperm from four species of echinoids differ in their specificity for induction of the acrosome reaction by heterotypic jelly coat and we presented evidence that there were only small compositional differences in the active component of the jelly coat, a polysaccharide composed of fucose sulfate units. In the current report we present additional studies related to the species specificity of jelly coat with respect to Ca²⁺ uptake (or exchange), which occurs concomitantly with the acrosome reaction, and activation of phospholipase activity, which appears to occur subsequent to the acrosome reaction. The specificity of jelly coat in inducing these processes is the same as that previously observed in induction of the acrosome reaction. Binding of jelly coat to sperm has been demonstrated, and has been shown to be species specific. This finding raises the possibility that a receptor for jelly coat exists on the surface of the sperm. Finally, based on chemical and physical-chemical studies, evidence is presented that establishes that, despite compositional similarities, the fucose sulfate polysaccharides from the four species of eggs differ in structure.     

Dibutyryl cyclic AMP decreases capacitation time in vitro in mouse spermatozoa

Epididymal mouse sperm suspensions were preincubated for various times in medium containing glucose and/or dibutyryl cyclic AMP and then assessed for fertilizing ability in vitro, loss of the acrosome and motility changes. Capacitation time was significantly reduced by exposure to glucose and 0.1 mM-dbcAMP for 30 min as evidenced by early and synchronous fertilization of eggs, compared with glucose alone. Although this was accompanied by a precocious development of whiplash motility, the rate of acrosome loss in isolated sperm suspensions was not accelerated by the presence of exogenous cyclic nucleotide. Exposure of spermatozoa to 1 mM-dbcAMP in the presence of glucose resulted in very poor fertilization, but the effect could be prevented by withholding glucose until eggs were introduced; this may be due to free butyrate in the system since the inclusion of 1 mM-butyrate in glucose-containing medium had a similar inhibitory effect. Although cyclic nucleotide supported the acrosome reaction but not motility changes, no fertilization was obtained unless zonae were removed, when a low level of fertilization (30%) was observed. Both whiplash motility and acrosome loss are thus obligatory for sperm penetration of the zona and glycolytic metabolism supports both changes, perhaps by promoting endogenous generation of cyclic AMP to act as an intermediary in these two distinct phenomena.     

Difference of fertilizing capacity between testicular sperm and vas deferens sperm in Cynops pyrrhogaster

The fertilizing capacity was compared between testicular and vas deferens sperm in Cynops pyrrhogaster. The testicular sperm was not capable of fertilizing jelly eggs. In contrast, the vas deferens sperm was already capable of fertilizing the newt jelly eggs. There was no inhibitory factor for fertilizing jelly eggs in the testis. These results suggest that the testicular sperm is immature as to the fertilizing capacity. The testicular sperm gained the fertilizing capacity for the jelly eggs by treatment with Holtfreter's solution or 1/20 strength Holtfreter's solution. The treatment may promote the step of maturation to achieve the fertilizing capacity. The treated testicular sperm did not fertilize dejellied eggs, although vas deferens sperm fertilized dejellied eggs. Therefore, the maturation state of the treated testicular sperm is different from that of vas deferens sperm. Newt sperm may be matured within the vas deferens, as the newt does not have an organ like the mammalian epididymis.     

Studies on the specificity of sperm binding in echinoderm fertilization

Using gametes from the sea urchins Arbacia punctulata and Strongylocentrotus purpuratus, we have evaluated the role of the acrosome reaction and the sperm-egg binding process in the block to interspecific fertilization among echinoids. The results indicate that sperm preinduced to undergo the acrosomal reaction by two different methods still bind to homologous eggs in a species specific manner. These results, taken in conjunction with an earlier study on species specificity of jelly coat induction of the acrosomal reaction (SeGall and Lennarz 1978), indicate that both the acrosome reaction and the sperm binding process contribute to the species specificity of fertilization in S. purpuratus and A. punctulata.     

The outermost layer of egg-jelly is crucial to successful fertilization in the newt, Cynops pyrrhogaster

The significance of egg-jelly layers in internal fertilization was evaluated in the newt, Cynops pyrrhogaster. In this species, six egg-jelly layers, J1, J2, J3, J4, J5 and the outermost J6 layers, are accumulated on the surface of the fertilizable eggs in pars convoluta of the oviduct. When a large number of sperm (about 6 x 10(5)) were placed on eggs having different numbers of jelly layers, all the eggs were fully fertilized, although many of the eggs developed abnormally. Upon insemination using about 600 sperm, only eggs with the full set of jelly layers were fertilized at a high rate with normal development. Since around 300 (the range of 48-1,192) sperm were observed on and in the egg-jelly in naturally spawned eggs, we conclude that the J6 layer must be present on the outermost surface of the egg-jelly for successful internal fertilization of the newt. Previous studies have suggested that the J6 layer is a prerequisite for the initiation of sperm motility and the acrosome reaction. In the present study, the fertilization rate decreased in eggs with a full set of jelly layers when inseminated using acrosome-reacted and motile sperm. However, the fertilization rate was high when motile sperm with intact acrosome was used. These results suggest that induction of the sperm acrosome reaction in the J6 layer is an important step in the internal fertilization of the newt.     

When do sperm of the sea urchin,Pseudocentrotus depressus,undergo the acrosome reaction at fertilization?

Jelly coats of the sea urchin, Pseudocentrotus depressus, were stripped off the eggs, and the eggs were “inseminated.” After penetration through the isolated jelly hull, sperm swarmed in the cavity previously occupied by the egg. Electron microscopic examination could not detect any sperm with reacted acrosome. Observation was also made of the sperm penetrating through the intact jelly coat-egg complex. Although a number of sperm were examined in ultrathin sections, only those attached to the vitelline layer had undergone the acrosome reaction; those sperm embedded in jelly but not attached to the vitelline layer had not undergone the acrosome reaction. The sequence of events in fertilization of this species and of other echinoids is discussed.     

Induction of the Acrosome Reaction of Hemicentrotus pulcherrimus Spermatozoa by the Egg Jelly Molecules, Fucose-Rich Glycoconjugate and Spem-Activating Peptide I

A fucose-rich glycoconjugate (FRG) was isolated from egg jelly of the sea urchin Hemicentrotus pulcherrimus by gel filtration. FRG induced the acrosome reaction in H. pulcherrimus spermatozoa in a concentration-dependent manner, although it showed about half the activity of the original unfractionated jelly. Synthetic sperm-activating peptide I (SAP-I: Gly-Phe-Asp-Leu-Asn-Gly-Gly-Gly-Val-Gly) increased the rate of the acrosome reaction induced by FRG; the maximal rate of the acrosome reaction with FRG and SAP-I being that of the unfractionated jelly. The half-maximal increase in induction of the acrosome reaction by SAP-I with FRG occurred at 4 × 10⁻¹⁰ M SAP-I, which was almost the same concentration inducing half-maximal stimulation of sperm respiration. Pronase digestion of FRG resulted in an 50% decrease in induction of the acrosome reaction and also in the elevation of cAMP in sperm. Some reagents (monensin and 3-isobutyl-1-methylxanthine) which increase intracellular pH, Ca²⁺ and cyclic nucleotides also increased the rates of the acrosome reaction induced by FRG or pronase-digested FRG. However, the rates did not reach those with FRG or pronase-digested FRG with SAP-I. These results indicate that SAP-I promotes induction of the acrosome reaction by acting as a specific co-factor of FRG.     

Sperm-egg interaction in the painted frog (Discoglossus pictus): An ultrastructural study

The ultrastructure of sperm changes and penetration in the egg was studied in the anuran Discoglossus pictus, whose sperm have an acrosome cap with a typical tip, the apical rod. The first stage of the sperm apical rod and acrosome reaction (AR) consists in vesiculation between the plasma membrane and the outer acrosome membrane. The two components of the acrosome cap are released in sequence. The innermost component (component B) is dispersed first. The next acrosome change is the dispersal of the outermost acrosome content (component A). At 30 sec postinsemination, when the loss of component B is first observed, holes are seen in the innermost jelly coat (J1), surrounding the penetrating sperm. Therefore, this acrosome constituent might be related to penetration through the innermost egg investments. At 1 min postinsemination, during sperm penetration into the egg, a halo of finely granular material is observed around the inner acrosome membrane of the spermatozoon, suggesting a role for component A at this stage of penetration. Gamete-binding and fusion take place between D1 (the egg-specific site for sperm interaction) and the perpendicularly oriented sperm. Spermatozoa visualized at their initial interaction (15 sec postinsemination) with the oolemma are undergoing vesiculation. The first interaction is likely to occur between the D1 glycocalyx and the plasma membrane of the hybrid vesicles surrounding the apical rod. As fusion is observed between the internal acrosome membrane and the oolemma, it can be postulated that gametic interaction might be followed by fusion of the latter with the apical rod internal membrane that extends posteriorly into the inner acrosome membrane. Insemination of the outermost jelly layer (J3) dissected out of the egg, and observations of the ultrastructural changes of spermatozoa in this coat, indicate that J3 rather than the vitelline coat (VC) induces the AR. Interestingly, at the late postinsemination stage, VC fibrils are seen crosslinking the inner acrosome membrane. The role of this binding is here discussed. Mol. Reprod. Dev. 47:323–333, 1997. © 1997 Wiley-Liss, Inc.     

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.