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.     

MAGNESIUM ION-REQUIRING STEP IN FERTILIZATION OF SEA URCHINS*

The magnesium ion-requiring step in fertilization of sea urchins was investigated. When eggs were inseminated in Mg-free sea water, several spermatozoa were found to bind to each egg surface with their reacted acrosomes without elevation of fertilization membrane. The number of binding jelly-treated spermatozoa to an egg did not differ regardless of the presence or virtual absence of magnesium ions. Although fertilization did not occur in Ca, Mg-deficient sea water (CM-deficient SW) even when jelly-treated spermatozoa were employed, some eggs could be fertilized by the addition of magnesium to the CM-deficient SW 60 sec after insemination, when jelly-treated spermatozoa had completely lost their fertilizing capacity in the CM-deficient SW. The acrosomal process of jelly-treated spermatozoa appeared to penetrate the vitelline layer in the CM-deficient SW. DTT- or pancreatin-treated eggs could not be fertilized in the virtual absence of magnesium. Re-fertilization using the fertilized eggs deprived of fertilization membrane did not occur under conditions of magnesium deficiency. These results suggest that external magnesium ions are indispensable at least for the fertilization process following penetration of the vitelline layer by the spermatozoa, such as fusion of the plasma membrane between an egg and a reacted spermatozoon, or the subsequent step(s) such as sperm penetration into egg interior and egg activation which precedes the cortical reaction.     

The effect of nicotine on sperm-Egg interaction in the sea urchin: Polyspermy and electrical events

We have studied some of the effects of nicotine on sea urchin eggs, spermatozoa, and their interaction using electrical recording techniques and fertilization-rate experiments. Pretreating eggs with nicotine enhances the fertilization rate, whereas this drug has an inhibitory effect on spermatozoa. Pulse-treated eggs or eggs fertilized in the presence of nicotine give rise to attenuated step depolarizations, which may be attributed to a decrease in membrane resistance (Rm) of the egg or, in the latter case, to an alteration to the spermatozoon. Concurrently, with the change in the step depolarization there is a reduction in amplitude of the fertilization potential (FP) suggesting that the cortical reaction is in some way altered. Nicotine has no effect on the Rm of fertilized eggs or oocytes, where there are no cortical granules. We suggest that nicotine alters the cortex of sea urchin eggs–possibly by causing a partial dissolution of cortical granules–which renders the eggs more receptive to spermatozoa. The reductions in amplitude of the step depolarization and the FP are consequences of this alteration.     

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.     

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.     

Propranolol induces polyspermy during sea urchin fertilization

Propranolol, a β-adrenergic receptor blocker, is found to induce polyspermy in sea urchin eggs. Unfertilized sea urchin eggs treated for 10 min with 50 μM of propranolol, and then inseminated, become polyspermic and show a fertilization envelope which is barely visible to the light microscope. Examination of treated eggs by transmission and scanning electron microscopy shows that the drug does not alter the cortex of the unfertilized egg. However, after insemination an incomplete cortical reaction occurs. This might well account for both polyspermy and the defective elevation of the fertilization envelope. Since the effects of the drug are reversed by simultaneous treatment with adrenalin, perhaps propranolol interferes with the monoaminergic system that has been proposed to be active. The involvement of the monoaminergic system in the fertilization process is present in the sea urchin egg. © 1996 Wiley-Liss, Inc.     

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.     

THE MEMBRANE CAPACITANCE OF THE SEA URCHIN EGG

1. The surface of the unfertilized sea urchin egg is folded and the folds are reversibly eliminated by exposing the egg to hypotonic sea water. If the plasma membrane is outside the layer of cortical granules, unfolding may explain why the membrane capacitance per unit area decreases (and does not increase) when a sea urchin egg is put into hypotonic sea water. 2. The degree of surface folding markedly increases after fertilization, which provides an explanation for the increase in membrane capacitance per unit area observed after fertilization. 3. The percentage reduction in membrane folding in fertilized eggs after immersion in hypotonic sea water is probably sufficient to explain the decrease in membrane capacitance per unit area observed in these conditions.     

Direct membrane retrieval into large vesicles after exocytosis in sea urchin eggs

At fertilization in sea urchin eggs, elevated cytosolic Ca2+ leads to the exocytosis of 15,000-18,000 1.3-microns-diam cortical secretory granules to form the fertilization envelope. Cortical granule exocytosis more than doubles the surface area of the egg. It is thought that much of the added membrane is retrieved by subsequent endocytosis. We have investigated how this is achieved by activating eggs in the presence of aqueous- and lipid-phase fluorescent dyes. We find rapid endocytosis of membrane into 1.5-microns-diam vesicles starting immediately after cortical granule exocytosis and persisting over the following 15 min. The magnitude of this membrane retrieval can compensate for the changes in the plasma membrane of the egg caused by exocytosis. This membrane retrieval is not stimulated by PMA treatment which activates the endocytosis of clathrin-coated vesicles. When eggs are treated with short wave-length ultraviolet light, cortical granule exocytosis still occurs, but granule cores fail to disperse. After egg activation, large vesicles containing semi-intact cortical granule protein cores are observed. These data together with experiments using sequential pulses of fluid-phase markers support the hypothesis that the bulk of membrane retrieval immediately after cortical granule exocytosis is achieved through direct retrieval into large endocytotic structures.     

Partially Fertilized Sea Urchin Eggs: An Electrophysiological and Morphological Study.

Propagation of the cortical reaction in sea urchin eggs may be interrupted by a mild heat shock. In such partially fertilized eggs three distinct cortical zones may be distinguished. First, an activated area where cortical granule exocytosis is complete, the fertilization membrane is elevated, and there is a cortical meshwork of polymerized actin. Second, at the antipode an area where the cortical granules are intact, actin is not polymerized, and the surface structure in general resembles that of the virgin egg. Between the two there is a transitional zone, some 10 to 20 μm wide, where a fraction of cortical granules have exocytosed, giving rise to isolated "blebs" of elevated fertilization membrane. Partially fertilized eggs have resting potentials ranging from −20 to −80 mV, and upon re-insemination give rise to step depolarizations indicating that spermatozoa may interact and possibly fuse with the "unactivated surface".     

Rearrangements of sea urchin egg cytoplasmic membrane domains at fertilization

Fertilization in the sea urchin is accompanied by rapid reorganization of the egg endoplasmic reticulum (ER). ER-derived vesicles contribute to one of three classes of membranes used in assembling the male pronuclear envelope in vitro. We provide here biochemical evidence for the rearrangement of sea urchin egg cytoplasmic membrane domains at fertilization up to the first mitosis, with respect to two nuclear envelope markers, lamin B and lamin B receptor (LBR), using purified vesicles prepared from homogenates fractionated by floatation on sucrose gradients. In unfertilized eggs, immunoprecipitation data indicate that most of lamin B and LBR are localized in the same vesicles but do not interact. By 3 min post-fertilization, both proteins are more widely distributed across the gradients and by 12 min most of lamin B and LBR are localized in vesicles of different densities. This partitioning is maintained throughout S phase. At mitosis, most lamin B and LBR remain in distinct vesicles, while a small proportion of lamin B and LBR, likely derived from the disassembled nuclear envelope, associate in a minor subset of vesicles. The results illustrate a dynamic reorganization of egg cytoplasmic membranes at fertilization, and the establishment of distinct membrane domains enriched in specific nuclear envelope markers during the first cell cycle of sea urchin development. Additionally, we demonstrate that male pro-nuclear membrane assembly occurs only when both cytosol and membranes originate from fertilized but not unfertilized eggs, suggesting that fertilization-induced membrane rearrangements contribute to the ability of the egg to assemble the male pronuclear envelope.     

Immunocytochemical localization of the 35-kDa sea urchin egg trypsin-like protease and its effects upon the egg surface

Trypsin-like protease in sea urchin eggs is thought to reside in cortical granules since it is secreted at fertilization and has been isolated with cortical granule fractions from unfertilized eggs. A 35-kDa serine protease has been purified from Strongylocentrotus purpuratus eggs by soybean trypsin inhibitor-affinity chromatography. For this report the protease was localized by immunocytochemistry before and after fertilization, and its potential biological activity was examined by application of the isolated enzyme to the unfertilized egg surface. The protease was localized on sections by immunofluorescence and immunoelectron microscopy, and was found to reside in the spiral lamellae of S. purpuratus cortical granules and in the electron-dense stellate core of Arbacia punctulata granules. At fertilization the enzyme is secreted into the perivitelline space and accumulates only very briefly between the hyaline layer and the nascent fertilization envelope. Shortly thereafter the enzyme is lost from the perivitelline space and immunological reactivity is no longer associated with the egg surface. The 35-kDa cortical granule protease has vitelline delaminase activity but does not appear to destroy vitelline envelope sperm receptors as judged by the fertility of protease-treated eggs.     

Latrunculin inhibits the microfilament-mediated processes during fertilization, cleavage and early development in sea urchins and mice

Latrunculin A, a marine toxin from a Red Sea sponge, is a potent inhibitor of the microfilament-mediated processes of fertilization and early development in sea urchins and in mice. Sperm from sea urchins, but not those from Limulus or mice, were affected by latrunculin, and fertilization in both sea urchins and in mice was arrested but at different stages. Sea urchin sperm treated with 2.6 microM latrunculin are unable to assemble acrosomal processes and their ability to fertilize eggs is impaired. The unwinding of the Limulus sperm acrosomal process occurs in the presence of latrunculin. Treated mouse sperm are able to fertilize mouse oocytes in vitro, suggesting that microfilaments may not be required in this mammalian sperm. In sea urchin eggs, sperm incorporation, microvillar elongation and cytokinesis are inhibited. Microtubule-mediated motility occurs normally. 20 nM latrunculin prevents the morphogenetic movements during gastrulation. It reduces the viscosity of actin gels from sea urchin egg homogenates. In unfertilized mouse oocytes, it prevents the colcemid-induced dispersion of the meiotic chromosomes; accumulations of cortical actin are noted adjacent to the scattered chromosomes. Sperm incorporation during mouse fertilization in vitro is unaffected suggesting that sperm entry may occur independent of microfilament activity in mammals. However, the apposition of the pronuclei at the center of the egg cytoplasm does not occur, providing evidence that cytoplasmic microfilaments may be required for the motions leading to pronuclear union during mouse fertilization. It inhibits the second polar body formation and cytokinesis. These results indicate that latrunculin is a potent inhibitor of microfilament-mediated processes in sperm, eggs and embryos, and that it may prove to be a powerful new drug for exploring the cellular behavior of microfilaments in the maintenance of cell shape and during motility.     

Peptides from sperm acrosomal protein that initiate egg development

How sperm initiate egg development is being investigated with gametes of the marine worm Urechis. Sperm acrosomal protein, previously shown to activate eggs (Gould et al., 1986, Dev. Biol. 117, 306-318; Gould and Stephano, 1987, Science 235, 1654-1656), was enzymatically cleaved into soluble peptide fragments. When this mixture was added to eggs they activated, and parthenogenetic cleavage often occurred. An active peptide (P23) was purified from the mixture and its sequence was determined to be Val-Ala-Lys-Lys-Pro-Lys. Synthetic peptide had the same biological activity. P23 induced eggs to undergo the complete sequence of changes that normally follows fertilization, including the fertilization potential, completion of meiosis, and DNA replication. When a sperm centrosome was introduced into eggs by prefertilization without activation, and the eggs were subsequently activated by P23, they developed normally to trochophore larvae (the contribution of another sperm component is not ruled out by this experiment). P23 covalently coupled to bovine serum albumin also activated eggs, showing that it acted on the external surface of the egg. The peptide did not activate sea urchin eggs, but did cause oyster eggs to undergo germinal vesicle breakdown.     

Role of calcium influx during the latent period in sea urchin fertilization

After ∼7–40 s following gamete fusion, a steadily increasing fraction of a sea urchin's zygotes initiate an activating calcium wave. The fertilization membrane then rises, the cell cycle resumes and development begins. This study focuses on the so-called latent period that occurs between the time that gamete fusion occurs and the initiation of the activating calcium wave. We inhibited calcium influx during this period by adding lanthanum or by reducing external calcium with a buffer at various time points after insemination. Both of these treatments blocked the activation of eggs that had not yet started a wave at the time of treatment. This indicates that an influx of calcium is needed during the latent period to induce egg activation. These results support the sperm conduit model of egg activation in the sea urchin, where calcium flows from the sea through the fused sperms' acrosomal process into a cortical region of the eggs' endoplasmic reticulum.     

False fertilization in sea urchin eggs induced by diabolin, a 120K kelp protein

A 120K lectin-like protein was isolated from the kelp Laminaria diabolica (Oni-kombu), with a unique activity to induce false fertilization specifically in the eggs of the sea urchin Hemicentrotus pulcherrimus. The protein designated as "diabolin" rendered the unfertilized egg forms and elevated the fertilization envelope without insemination at 18 nM half-maximally. Those eggs with elevated fertilization envelopes, however, could not enter into normal cleavage or further development, and hence the proliferation of the sea urchin was hindered. Diabolin, thus, by its unique defense mechanism protects the kelp from the predator sea urchin. It was partially sequenced and found to have the highest homology with phytoene dehydrogenase from the plant virus Erwinia uredovora. A question was left to be solved as to how the kelp on the southeast coast of Hokkaido Island could develop the defense mechanism against the sea urchin on Honshu Island separated by Tsugaru Straits.     

Mastoparan induces Ca2+-independent cortical granule exocytosis in sea urchin eggs

In most species, cortical granule exocytosis is characteristic of egg activation by sperm. It is a Ca(2+)-mediated event which results in elevation of the vitelline coat to block permanently the polyspermy at fertilization. We examined the effect of mastoparan, an activator of G-proteins, on the sea urchin egg activation. Mastoparan was able to induce, in a concentration-dependent manner, the egg cortical granule exocytosis; mastoparan-17, an inactive analogue of mastoparan, had no effect. Mastoparan, but not sperm, induced cortical granule exocytosis in eggs preloaded with BAPTA, a Ca(2+) chelator. In isolated egg cortical lawns, which are vitelline layers and membrane fragments with endogenously docked cortical granules, mastoparan induced cortical granule fusion in a Ca(2+)-independent manner. By contrast, mastoparan-17 did not trigger fusion. We conclude that in sea urchin eggs mastoparan stimulates exocytosis at a Ca(2+)-independent late site of the signaling pathway that culminates in cortical granule discharge.     

The GTP-binding protein RhoA localizes to the cortical granules of Strongylocentrotus purpuratas sea urchin egg and is secreted during fertilization

The sea urchin egg has thousands of secretory vesicles known as cortical granules. Upon fertilization, these vesicles undergo a Ca2+-dependent exocytosis. G-protein-linked mechanisms may take place during the egg activation. In somatic cells from mammals, GTP-binding proteins of the Rho family regulate a number of cellular processes, including organization of the actin cytoskeleton. We report here that a crude membrane fraction from homogenates of Strongylocentrotus purpuratus sea urchin eggs, incubated with C3 (which ADP-ribosylates specifically Rho proteins) and [32P]NAD, displayed an [32P]ADP-ribosylated protein of 25 kDa that had the following characteristics: i) identical electrophoretic mobility in SDS-PAGE gels as the [32P]ADP-ribosylated Rho from sea urchin sperm; ii) identical mobility in isoelectro focusing gels as human RhoA; iii) positive cross-reactivity by immunoblotting with an antibody against mammalian RhoA. Thus, unfertilized S. purpuratus eggs contain a mammalian RhoA-like protein. Immunocytochemical analyses indicated that RhoA was localized preferentially to the cortical granules; this was confirmed by experiments of [32P]ADP-ribosylation with C3 in isolated cortical granules. Rho was secreted and retained in the fertilization membrane after insemination or activation with A23187. It was observed that the Rho protein present in the sea urchin sperm acrosome was also secreted during the exocytotic acrosome reaction. Thus, Rho could participate in those processes related to the cortical granules, i.e., in the Ca2+-regulated exocytosis or actin reorganization that accompany the egg activation.     

Benzohydroxamic acid induces polyspermic fertilization in the sea urchin Arbacia punctulata

Benzohydroxamic acid (BHA) is a competitive inhibitor of the sea urchin sperm peroxidase. We now report that addition of BHA to fertilization cultures of Arbacia punctulata promotes polyspermy. This effect is dose and sperm density dependent. The cortical reaction (elevation of the fertilization envelope) is not retarded by BHA. BHA must be added to the cultures before the eggs complete the cortical reaction at 60 sec post insemination in order to induce polyspermy. Since sea urchin eggs release H2O2 during the cortical reaction at fertilization, these findings support our hypothesis that the sperm peroxidase has a functional role in helping to prevent polyspermy.     

Sperm binding and fertilization envelope formation in a cell surface complex isolated from sea urchin eggs

An isolated surface complex consisting of the vitelline layer, plasma membrane, and attached secretory vesicles has been examined for its ability to bind sperm and to form the fertilization envelope. Isolated surface complexes (or intact eggs) fixed in glutaraldehyde and then washed in artificial sea water are capable of binding sperm in a species-specific manner. Sperm which bind to the isolated surface complex exhibit the acrosomal process only when they are associated with the exterior surface (vitelline layer) of the complex. Upon resuspension of the unfixed surface complex in artificial sea water, a limiting envelope is formed which, based on examination of thin sections and negatively stained surface preparations, is structurally similar to the fertilization envelope formed by the fertilized egg. These results suggest that the isolated egg surface complex retains the sperm receptor, as well as integrated functions for the secretion of components involved in assembly of the fertilization envelope.