Changes of tropomyosin isoforms during development of cross-fertilized sea urchin embryos

Changes of tropomyosin isoforms during development of the sea urchin, Hemicentrotus pulcherrimus , were investigated using two-dimensional urea-shift gel electrophoresis. Tropomyosin isoforms included in the embryos were gradually increased after 2 cell stage and retained at a constant level after gastrula stage. To detect the tropomyosin isoforms derived from zygotic genomes, embryos cross-fertilized between H. pulcherrimus and Pseudocentrotus depressus gametes were prepared. Since tropomyosin isoforms from H. pulcherrimus eggs and from P. depressus eggs could be distinguished from each other on a two-dimensional electrophoretic gel, the paternal isoforms of tropomyosin in the cross-fertilized embryos, which were not included endogenously in the egg, could be regarded as products derived from zygotic genomes. The paternal isoforms of tropomyosin were detected first at around the gastrula stage in embryos cross-fertilized between H. pulcherrimus sperm and P. depressus eggs and also in the reverse combination of the gamete species. Muscle tropomyosins derived from H. pulcherrimus and P. depressus genomes were similarly detected in cross-fertilized embryos at the pluteic stage when the muscle tropomyosin appeared in sea urchin embryos.     

Induction of the acrosome reaction on the surface of de-jellied sea urchin eggs

The vitelline coat of sea urchin eggs was disrupted by DTT and trypsin after removal of the jelly layer. Thereafter the percentage of acrosome reaction was determined and the fertilization rate was estimated, employing the treated eggs. Electron microscopical investigation of these eggs showed that the vitelline coat was disrupted but no morphological difference was observed between eggs treated with DTT and those treated with trypsin. However, the fertilizability of the eggs was markedly decreased by the treatment with trypsin. In contrast, DTT treatment did not affect the fertilizability of the eggs, indicating that some surface substance(s) necessary for fertilization which were not eliminated by DTT were digested by trypsin. At the same time, the percentage of acrosome reaction of supernumerary spermatozoa in the presence of variously treated eggs was estimated as an index of the acrosome reaction-inducing activity of the egg surface. The acrosome reaction of spermatozoa actually occurred at the surface of de-jellied and DTT-treated eggs. However, the eggs treated with trypsin lost the capacity to induce the acrosome reaction. The surface substance which induces the acrosome reaction and renders the eggs fertile was removed by trypsin and found in the supernatant fraction. The necessity of an acrosome reaction for fertilization was demonstrated by the fact that the low fertilizability of trypsin-treated eggs was brought back to the control level by insemination with spermatozoa previously treated with egg water to evoke the reaction of the acrosomes.     

Sperm proteasomes are responsible for the acrosome reaction and sperm penetration of the vitelline envelope during fertilization of the sea urchin Pseudocentrotus depressus

The roles of sperm proteasomes in fertilization were investigated in the sea urchin Pseudocentrotus depressus. Two proteasome inhibitors, MG-132 and MG-115, inhibited fertilization at 100 microM, whereas chymostatin and leupeptin showed no inhibition. Among three proteasome substrates, Z-Leu-Leu-Glu-MCA showed the strongest inhibition toward fertilization. MG-132 inhibited the egg-jelly-induced, but not ionomycin-induced, acrosome reaction. In addition, MG-132, but not E-64-d, inhibited fertilization of dejellied eggs by acrosome-reacted sperm. MG-132 showed no significant inhibition toward the binding of reacted sperm to the vitelline layer. Proteasomes were detected by Western blotting in the acrosomal contents, which are partially released upon exocytosis. We also found that the inhibition pattern of the caspase-like activity of the proteasome in the acrosomal contents by chymostatin and proteasome inhibitors coincided well with their inhibitory abilities toward fertilization. Furthermore, the vitelline layer of unfertilized eggs appears to be ubiquitinated as revealed by immunocytochemistry and Western blotting. Extracellular ATP, required for the degradation of ubiquitinated proteins by the proteasome, was also necessary for fertilization. These results indicate that the sperm proteasome plays a key role not only in the acrosome reaction but also in sperm penetration through the vitelline envelope, most probably as a lysin, during sea urchin fertilization.     

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.     

INHIBITION OF RESPIRATION IN SEA URCHIN SPERMATOZOA FOLLOWIGN INTERACTION WITH FIXED UNFERTILIZED EGGS

The respiratory rate of spermatozoa of the sea urchin, Pseudocentrotus depressus and Hemicentrotus pulcherrimus , became quite low and spermatozoa was immotile, after sperm suspension containing glutaraldehyde-fixed eggs of homologous species was stirred at 20°C for 15 min. The respiratory rate of fresh spermatozoa, introduced to the suspension of immotile spermatozoa thus obtained, was also reduced markedly. The respiration of fresh spermatozoa was not inhibited by adding them to suspension of intact or acrosome reacted spermatozoa. A heat stable and non-dialyzable substance, which inhibited sperm respiration, was removed from the fixed eggs by vigorously stirring the egg suspension for 10 min, when unfertilized eggs were fixed with insufficient amount of glutaraldehyde (10 ml of 1% glutaraldehyde solution to 1 ml egg pellet).     

Two pathways from glycogen to glucose-6-phosphate in sea urchin eggs with special reference to the difference between the species in the contribution ratio of each pathway

In the unfertilized eggs of the sea urchins, Anthocidaris crassispina, Pseudocentrotus depressus, Hemicentrotus pulcherrimus, Mespilia globulus, Temnopleurus toreumaticus, Toxopeneustes pileolus, and Clypeaster japonicus, the activities of phosphorylase [EC 2.4.1.1], phosphoglucomutase [EC 2.7.5.1], exo-l,4-α-glucosidase [EC 3.2.1.3], and hexokinase [EC 2.7.1.1] are very similar. In all species, only phosphorylase activity is higher in fertilized eggs than in unfertilized eggs. The concentrations of glycogen, glucose, GIP, G6P, ATP, ADP, and Pi; the products and substrates in reactions catalyzed by these enzymes, were measured in these eggs. Based on the concentrations of these compounds in the eggs, it is assumed that G6P is produced by the combined action of glucosidase and hexokinase in all species examined, and that it is also produced in the reaction catalyzed by phosphorylase and phosphoglucomutase in all species except A crassispina and P depressus. Glycogen was found both in supernatant and in precipitate fractions, which were obtained by adding perchloric acid. Glycogen in the precipitate seems to be protein-bound. Whole glycogen level in the eggs is almost the same in all species examined, but the level of acid-soluble glycogen, as well as GIP, is markedly lower in the eggs of A crassispina and P depressus than in the eggs of other species examined. Protein-bound glycogen is utilized by glucosidase activity but not by phosphorylase activity, in contrast to acid-soluble glycogen, which is utilized by both enzyme activities. Hence, it is assumed that the failure of G6P production by phosphorylase and phosphoglucomutase-in A crassispina and P depressus eggs is due to a low level of acid-soluble glycogen in these eggs.     

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.     

Inhibition of sea urchin fertilization by jaspisin, a specific inhibitor of matrix metalloendoproteinase

Jaspisin, originally isolated from a marine sponge as an inhibitor of the hatching of the sea urchin (Hemicentrotus pulcherrimus) embryo, causes inhibition of sea urchin fertilization. Electron microscopic examination revealed that the acrosome reaction was induced in jaspisin-treated sperm when they were incubated with an intact egg. The acrosome-reacted sperm bound to the vitelline layer by the acrosomal material surrounding the acrosomal process. However, fusion of the acrosomal process and the egg plasma membrane failed to take place. Membrane potential changes were monitored using eggs preloaded with a membrane potential-sensitive fluorochrome, di-8-ANEPPS. Depolarization of the membrane potential, normally observed in the fertilized egg was not observed in the egg inseminated in the presence of jaspisin, indicating the absence of electrical continuity between the jaspisin-treated egg and sperm. Jaspisin inhibited the activities of matrix metallo-endoproteinase members but not of other types of proteinases. These results provide strong, albeit indirect, evidence that a matrix metallo-endoproteinase(s) is involved in the process of gamete fusion during sea urchin fertilization.     

Some more speract derivatives associated with eggs of sea urchins, Pseudocentrotus depressus, Strongylocentrotus purpuratus, Hemicentrotus pulcherrimus and Anthocidaris crassispina

1. Fourteen peptides were isolated from the egg jelly of sea urchins, Pseudocentrotus depressus, Strongylocentrotus purpuratus, Hemicentrotus pulcherrimus and Anthocidaris crassispina and their amino acid sequences were determined. 2. The peptides stimulated H. pulcherrimus sperm respiration one half-maximally at about 8-60 pM. 3. Addition of speract to intact spermatozoa of P. depressus, H. pulcherrimus and A. crassispina resulted in the appearance of a newly stained protein (Mr 128,000 for P. depressus, Mr 128,000 for H. pulcherrimus and Mr 131,000 for A. crassispina) on sodium dodecyl sulfate-polyacrylamide gels.     

Structural features of the abalone egg extracellular matrix and its role in gamete interaction during fertilization

Abalone eggs are surrounded by a complex extracellular coat that contains three distinct elements: the jelly layer, the vitelline envelope, and the egg surface coat. In this study we used light and electron microscopy to describe these three elements in the red abalone (Haliotis rufescens) and ascribe function to each based on their interactions with sperm. The jelly coat is a spongy matrix that lies at the outermost margin of the egg and consists of variably sized fibers. Sperm pass through this layer with their acrosomes intact and then go on to bind to the vitelline envelope. The vitelline envelope is a multilamellar fibrous layer that appears to trigger the acrosome reaction after sperm binding. Next, sperm release lysin from their acrosomal granules, a nonenzymatic protein that dissolves a hole in the vitelline envelope through which the sperm swims. Sperm then contact the egg surface coat, a network of uniformly sized filaments lying directly above the egg plasma membrane. This layer mediates attachment of sperm, via their acrosomal process, to the egg surface. © 1995 Wiley-Liss, Inc.     

Blocks to polyspermy in Chaetopterus

Blocks to polyspermy may act either at the level of the egg plasma membrane to prevent gamete fusion or at the level of egg surface coats to prevent gamete attachment. The present study was undertaken to determine what type(s) of block(s) to polyspermy exist in Chaetopterus. The results showed the existence of both types. A rapid block acts at the plasma membrane level based on independence from detectable changes in the vitelline layer and is dependent on external sodium ions. A vitelline layer block had been predicted on morphological evidence and is supported here by demonstrating an increase in polyspermy following chemical disruption of the vitelline layer. However, the vitelline layer of the fertilized egg retained its ability to initiate the acrosome reaction in sperm and attach sperm which had undergone the acrosome reaction. The vitelline layer block resulted from the retraction of egg microvilli from the vitelline layer, and not from elevation of the vitelline layer per se. Thus the vitelline layer of the fertilized egg could be involved in preventing sperm penetration into the egg without being altered structurally or functionally.     

External calcium ions are requisite for fertilization of sea urchin eggs by spermatozoa with reacted acrosomes

That a small amount of external calcium ions is requisite for the fertilization by spermatozoa with reacted acrosomes was found by some simple experiments using jelly-treated sperm of the sea urchin, Hemicentrotus pulcherrimus. When eggs were inseminated with the jelly-treated sperm in artificial seawaters containing calcium at various concentrations, the percentage of fertilization decreased concomitant with the reduction in the amount of external calcium ions, 50% at 40 μM calcium and almost 0% at less than 10 μM. On the other hand, it was observed that both the morphology of the reacted acrosome and the binding capacity of the jelly-treated spermatozoa to eggs were not influenced by the calcium deficiency. These results suggest that external calcium ions are indispensable even for the fertilization processes following sperm binding to eggs after the acrosome reaction, such as penetration of reacted spermatozoa through vitelline layer and/or membrane fusion between egg and spermatozoon.     

INDUCTION OF THE ACROSOME REACTION ON THE EGG SURFACE OF DE-JELLIED SEA URCHIN EGGS BEFORE AND AFTER FERTILIZATION*

The capacity of the surface of sea urchin eggs to induce the acrosome reaction was assayed by estimating the rate of acrosome reaction of supernumerary spermatozoa in the presence of variously treated eggs before and after fertilization. DTT-disruption of the vitelline coat did not eliminate the acrosome reaction-inducing capacity. This capacity was retained after fertilization in eggs of both H. pulcherrimus and A. crassispina. The acrosome reaction-inducing capacity of the eggs was markedly decreased by treatment with trypsin. The low capacity of the trypsin-treated eggs was maintained after fertilization in H. pulcherrimus, but in A. crassispina the capacity returned to the pre-trypsin treatment level after fertilization. Fertilized eggs from which the fertilization membrane was mechanically removed retained the inducing capacity to a considerable extent, independent of the presence or absence of the hyaline layer, but the capacity diminished rapidly as cleavage proceeded. It was concluded from these data that the acrosome reaction of spermatozoa actually occurred at the surface of de-jellied eggs and that the inducing substance resides in the plasma membrane in addition to the fertilization membrane. A chemical difference between the inducing substance of egg surface and jelly substance is discussed.     

Studies on the interactions of sperm with the surface of the sea urchin egg

We have examined the relationship between sperm adhesion and fertilization in the cross species insemination of Arbacia punctulata eggs by Strongylocentrotus purpuratus sperm. As previously reported (Kinsey et al., 1980) the addition of S. purpuratus egg jelly results in induction of the acrosome reaction in sperm and significant numbers of S. purpuratus sperm adhere to A. punctulata eggs. However, in the absence of S. purpuratus egg jelly, S. purpuratus sperm fail to bind to A. punctulata eggs. Although at least 200 S. purpuratus sperm bind to an A. punctulata egg in the presence of S. purpuratus jelly, less than 8% of the eggs are fertilized. The adhesion of S. purpuratus sperm meets the same functional criteria as homologous A. punctulata sperm-egg adhesion. Electron microscopy shows that S. purpuratus sperm that have undergone the acrosome reaction adhere to A. punctulata eggs by their bindin-coated acrosomal process in a manner that is morphologically identical to that observed with homologous A. punctulata sperm. We have also compared the ability of S. purpuratus and A. punctulata sperm to fuse and fertilize with A. punctulata eggs after removal of the vitelline layer. Using high levels of sperm of either species, heterologous as well as homologous fertilization is readily detectable. Under these conditions, where stable binding is not demonstrable, there is no difference in the ability of S. purpuratus and A. punctulata sperm to fertilize A. punctulata eggs. These observations suggest that the failure of S. purpuratus sperm to fertilize A. punctulata eggs under normal conditions may be due to their inability to penetrate the vitelline layer so that they can fuse with the egg plasma membrane. In relation to the possible mechanism of vitelline layer penetration, we have also investigated the mode of action of chymostatin, an inhibitor of chymotrypsin that has been reported to inhibit fertilization of sea urchin eggs (Hoshi et al., 1979). Our findings suggest that the fertilization inhibitory activity of chymostatin is not related to its antichymotrypsin activity. Rather, it appears that this inhibition is due to the induction of an abnormal acrosome reaction in sperm that precludes formation of the acrosome process.     

RELATION BETWEEN THE ACROSOME REACTION AND FERTILIZATION IN THE SEA URCHIN. II. FERTILIZATION IN ACIDIFIED SEA WATER WITH EGG-WATER-TREATED SPERMATOZOA*

Fertilization of sea urchin eggs fails to occur at a pH lower than 6.5. Analytical studies on this problem were made with Hemicentrotus pulcherrimus, Anthocidaris crassispina and Pseudocentrotus depressus. If the spermatozoa have been pretreated with egg water, eggs can be fertilized even at pH 6.5 and 6.0. The acrosome reaction is inhibited at a pH lower than 6.5. Intact spermatozoa fail to adhere to the fixed eggs in acidified sea water, whereas egg-water-treated spermatozoa adhere even at pH 6.5 and 6.0. From these results we infer that the failure of fertilization at pH 6.5–6.0 is caused by non-occurrence of the acrosome reaction, and that fertilization reactions other than the acrosome reaction, such as the binding and fusion of the gametes, are not inhibited in this range of pH. At pH 5.5, the spermatozoa become inert and fertilization is inhibited or suppressed, even though egg-water-treated spermatozoa are employed.     

The Chaetopterus vitelline envelope is not necessary for the gamete interactions that lead to fertilization

It has been recently shown that, in several genera of annelids, including Chaetopterus, fertilizing sperm attach to and fuse with egg microvilli which penetrate the vitelline envelope. This suggests that the annelid vitelline envelope may have no direct or obligatory role in normal fertilization. The present study was undertaken to investigate the involvement of the vitelline envelope in fertilization in Chaetopterus experimentally, by examining the fertilization of vitelline envelope-free eggs quantitatively and qualitatively. Brief exposure of the eggs to isotonic sucrose-EDTA removed the vitelline envelope as determined by both phase-contrast and electron microscopy, rendered the eggs more sensitive to polyspermy and substantially reduced the binding of supernumerary sperm to eggs but did not decrease fertilizability as determined by sperm dilution assay and did not make the eggs more sensitive to cross-fertilization. The events of fertilization were examined by electron microscopy and found to be very similar in vitelline envelope-free eggs to those in intact eggs. We conclude that the vitelline envelope in Chaetopterus has binding sites for sperm but that it has no obligatory role in fertilization and is primarily involved in the prevention of polyspermy.     

Multiple molecular forms of acid nitrophenyl phosphatase in sea urchin eggs and embryos

Acid nitrophenyl phosphatases from sea urchin eggs and embryos were investigated by gel filtration. Four different forms were found in Hemicentrotus pulcherrimus, and three forms in Anthocidaris crassispina and Pseudocentrotus depressus. The first and second forms (designated AcP-1 and AcP-2) had the highest activity in the range of pH 5.6–6.0. The third (designated AcP-3) had an apparent optimum pH between pH 4.3 and 4.8, and the fourth (designated AcP-4) showed the maximum activity at pH 3.0. AcP-1 was much more thermolabile than AcP-2 and AcP-3 at 56°C. NaF inhibited AcP-2, AcP-3, and AcP-4 but not AcP-1. AcP-1, AcP-2, and AcP-3 were observed in the three species, whereas AcP-4 was not detected in A. crassispina and P. depressus. AcP-1, AcP-2, and AcP-3 were separted by gel filtration. AcP-1 and AcP-2 of A. crassispina and H. pulcherrimus were studied in developing embryos. The behavior of these forms in gel filtration changed during development, from unfertilized eggs to the pluteus stage.     

The Parkes Lecture. Zona pellucida glycoprotein mZP3: a versatile player during mammalian fertilization

All mammalian eggs are surrounded by a relatively thick extracellular coat, the zona pellucida (ZP), which facilitates fertilization of eggs by a single spermatozoon. The mouse egg ZP is constructed of only three glycoproteins, termed mZP1-3. Each of these glycoproteins consists of a unique polypeptide that is heterogeneously glycosylated with both asparagine-(N-)linked and serine/threonine-(O-)linked oligosaccharides. Polypeptides of ZP glycoproteins are highly conserved among mammalian species and are similar to polypeptides of egg vitelline envelope glycoproteins of fish, birds and amphibians. One of the mouse ZP glycoproteins, mZP3, serves as both a receptor for spermatozoa and an inducer of the acrosome reaction during fertilization. Free-swimming acrosome-intact spermatozoa recognize and bind to certain serine-(O-)linked oligosaccharides located close to the carboxy terminus of mZP3 polypeptide and, after binding, undergo the acrosome reaction (cellular exocytosis). In this review, in addition to the background information presented, results of recent experiments using homologous recombination to produce mZP3 null mice and site-directed mutagenesis to inactivate mZP3 as a sperm receptor and inducer of the acrosome reaction are presented and discussed.     

Ascidian sperm lysin system

Fertilization is a precisely controlled process involving many gamete molecules in sperm binding to and penetration through the extracellular matrix of the egg. After sperm bind to the extracellular matrix (vitelline coat), they undergo the acrosome reaction which exposes and partially releases a lytic agent called "lysin" to digest the vitelline coat for the sperm penetration. The vitelline coat sperm lysin is generally a protease in deuterostomes. The molecular mechanism of the actual degradation of the vitelline coat, however, remains poorly understood. In order to understand the lysin system, we have been studying the fertilization mechanism in ascidians (Urochordata) because we can obtain large quantities of gametes which are readily fertilized in the laboratory. Whereas ascidians are hermaphrodites, which release sperm and eggs simultaneously, many ascidians, including Halocynthia roretzi, are strictly self-sterile. Therefore, after sperm recognize the vitelline coat as nonself, the sperm lysin system is thought to be activated. We revealed that two sperm trypsin-like proteases, acrosin and spermosin, the latter of which is a novel sperm protease with thrombin-like substrate specificity, are essential for fertilization in H. roretzi. These molecules contain motifs involved in binding to the vitelline coat. We found that the proteasome rather than trypsin-like proteases has a direct lytic activity toward the vitelline coat. The target for the ascidian lysin was found to be a 70-kDa vitelline coat component called HrVC70, which is made up of 12 EGF-like repeats. In addition to the proteasome system, the ubiquitination system toward the HrVC70 was found to be necessary for ascidian fertilization. In this review, I describe recent progress on the structures and roles in fertilization of the two trypsin-like proteases, acrosin and spermosin, and also on the novel extracellular ubiquitin-proteasome system, which plays an essential role in the degradation of the ascidian vitelline coat.     

Egg jelly of the newt, Cynops pyrrhogaster contains a factor essential for sperm binding to the vitelline envelope

The acrosome reaction of newt sperm is induced at the surface of egg jelly and the acrosome-reacted sperm acquire the ability to bind to the vitelline envelope. However, because the substance that induces the acrosome reaction has not been identified, the mechanism by which the acrosome-reacted sperm bind to the vitelline envelope remains unclear. We found here that a Dolichos biforus agglutinin (DBA) specifically mimicked the acrosome reaction immediately upon its addition in the presence of milimolar level Ca(2+). Fluorescein isothiocyanate-labeled DBA bound specifically to the acrosomal cap of the intact sperm in the presence of a Ca(2+)-chelating agent, EDTA, suggesting that binding of DBA to the native receptor for the egg jelly substance on the acrosomal region took the place of the egg jelly substance-induced acrosome reaction. In contrast, the sperm that had been acrosome reacted by DBA treatment did not bind to the vitelline envelope of the egg whose jelly layers were removed. Subsequent addition of jelly extract caused the sperm binding to vitelline envelope, indicating that the egg jelly of the newt contains substances that are involved in not only inducing the acrosome reaction but also binding to the vitelline envelope. This is the first demonstration of the involvement of egg jelly substance in the binding of acrosome-reacted sperm to the vitelline envelope.