Membrane depolarization facilitates sperm entry, large fertilization cone formation, and prolonged current responses in sea urchin oocytes

Depolarization of the sea urchin egg's membrane is required for two processes during fertilization: the entry of the fertilizing sperm and the block to polyspermy which prevents the entry of supernumerary sperm. In an immature sea urchin oocyte, the depolarization is very small in response to the attachment of a sperm. The purpose of this study was to determine whether the depolarization evoked by sperm attaching to an oocyte can facilitate sperm entry or induce the block to polyspermy. Individual oocytes of the sea urchin with diameters which ranged from 86 to 102% that of the average diameter for mature eggs from the same female were examined. The oocytes have a membrane potential of -73 +/- 6 mV (SD, n = 80) and a very low input resistance compared to that of mature eggs. Single sperm, following attachment to an oocyte, elicit a brief, small depolarization with a maximum amplitude of 8 +/- 1.4 mV (SE, n = 15), frequently followed by the formation of tiny filament-like fertilization cones, but the sperm fail to enter. If oocytes are voltage-clamped at membrane potentials more negative than -20 mV, following attachment of the sperm small transient inward currents occur, similar filament-like cones form, and the sperm do not enter. When many sperm attach to an oocyte which is not voltage clamped, the depolarizations sum to create a large depolarization with an amplitude of 60 to 80 mV, which shifts the oocyte's membrane potential to a value between -10 and +5 mV; more positive values are not attained. At such membrane potentials, whether the potential is maintained by the summed depolarizations of many attached sperm or by voltage clamp, large fertilization cones form, the sperm enter, and the oocytes can become highly polyspermic. In oocytes voltage clamped at +20 mV, however, both sperm entry and fertilization cone formation are suppressed. Therefore, both types of voltage-dependence for sperm entry are present in oocytes, although the depolarization caused by a single sperm is not large enough to permit its entry, nor is the depolarization caused by many sperm sufficient to prevent the entry of supernumerary sperm.     

Maturation and fertilization of the sea urchin oocyte: An electrophysiological study

Some electrical properties of the sea urchin oocyte during germinal vesicle breakdown (GVBD) and fertilization have been studied using two intracellular electrodes. Oocytes with distinct germinal vesicles have resting potentials of ?70 to ?90 mV and the specific membrane resistance may range from 3 to 10 kΩ·cm². Around rest the I–V relationship is concave toward the axis origin and the membrane is K⁺ selective. A second electrical state, of lower potential and higher resistance, preexists in the membrane. Following GVBD, the K⁺-selective system is lost and the oocyte attains the characteristics of the second state with a resting potential of ?10 to ?50 mV and specific membrane resistance of 10–50 kΩ·cm². At rest the I–V relationship tends to be convex toward the axis origin. The majority of sea urchin eggs (which have undergone GVBD and completed meiosis) have a resting state of ?10 to ?30 mV; 10–50 kΩ·cm². The I–V relationship around rest is convex toward the axis origin and the resting potential is sensitive to changes of Na⁺, Cl^?, and K⁺ in the external medium. There is probably no major change in the electrical properties of the oocyte during the completion of meiosis. A small percentage of eggs from suboptimal animals have high resting potentials of ?70 to ?90 mV and specific membrane resistance of 5–50 kΩ·cm². Such eggs have predominantly K⁺-selective membranes and we suggest that they are either underripe or aged. The first electrical event across the egg plasma membrane during fertilization is a step-like depolarization which occurs about 2 sec after the attachment of the fertilizing spermatozoon to the vitelline layer. There is no change—at the level of the light microscope—either in the egg surface or in the behavior of the spermatozoon until the second event, the fertilization potential (FP), is initiated 11 sec later. The cortical reaction occurs simultaneously with the FP and during the rising phase of the FP the spermatozoon stops gyrating around its point of attachment. Oocytes, which do not have cortical granules, upon insemination exhibit step events but no FP; in contrast artificially activated eggs, either spontaneous or induced by the ionophore A23187, give rise to only the FP. We suggest that the FP is the electrical result of the modification of the egg plasma membrane during cortical exocytosis.     

Fertilization in crabs: IV. The fertilization potential consists of a sustained egg membrane hyperpolarization

The electrophysiological properties of immature and mature oocytes of two crabs were analyzed. Growing immature oocytes of Carcinus maenas and fully grown immature oocytes of Maia squinado had essentially K⁺ dependent resting potentials, Em, of ?61 ? 1 mV, n=19, and ?67.3 ± 0.5 mV, n=68, respectively. Fully grown immature oocytes of Carcinus maenas showed an Em of ?40 ± 1.5 mV, n=19, that was k⁺ and Cl^? dependent. In mature oocytes of both species, the plasma membrane became exclusively permeable to cl^? and the Em attained–41 ± 1 mV, n=49 and ?34 ± 1.5 mV, n=27 for Carcinus maenas and Maia squinado, respectively. After in vitro insemination, a dramatic increase in egg membrane permeability to K⁺ was observed. This instantaneously caused a sustained hyperpolarization constituting, for these crabs, the fertilization potential. We observed that concurrently with this electrical response to fertilization, sperm reinitiated the oocyte meiotic maturation previously arrested at the first metaphase. The triggering mechanism of the fertilization potential as well as the possible occurrence of a physiological polyspermy are discussed.     

Electrical characteristics of ascidian egg fragments

Fragments of ascidian eggs, but at random in any plane and ranging in size from 10 to 90% of the total egg volume, displayed the electrical characteristics of the intact egg, having a resting potential of -86 mV and giving rise to an action potential upon stimulation by electrical current injection. Following insemination, the fragments generated fertilization potentials, comparable to those of intact eggs, although the repolarization phase was shorter. Our data show that there are sufficient ion channels throughout the egg surface to generate action potentials and fertilization potentials in excised egg fragments, irrespective of their global origin. Furthermore, the fertilizing spermatozoon is capable of activating fertilization channels in areas of the egg plasma membrane not destined for sperm entry.     

NAADP and InsP3 play distinct roles at fertilization in starfish oocytes

NAADP participates in the response of starfish oocytes to sperm by triggering the fertilization potential (FP) through the activation of a Ca2+ current which depolarizes the membrane to the threshold of activation of the voltage-gated Ca2+ channels. The aim of this study was to investigate whether this Ca2+ influx is linked to the onset of the concomitant InsP3-mediated Ca2+ wave by simultaneously employing Ca2+ imaging and single-electrode intracellular recording techniques. In control oocytes, the sperm-induced membrane depolarization always preceded by a few seconds the onset of the Ca2+ wave. Strikingly, the self-desensitization of NAADP receptors either abolished the Ca2+ response or resulted in abnormal oocyte activation, i.e., the membrane depolarization followed the Ca2+ wave and the oocyte was polyspermic. The inhibition of InsP3 signaling only impaired the propagation of the Ca2+ wave and shortened the FP. The duration of FP was also reduced in low-Na+ sea water. Finally, uncaged InsP3 produced a Ca2+ increase, which depolarized the membrane upon the activation of a Ca2+-sensitive cation current. These results support the hypothesis that Ca2+ entry during the NAADP-triggered FP is required for the onset of the Ca2+ wave at fertilization. The InsP3-mediated Ca2+ wave, in turn, may interact with the NAADP-evoked depolarization by activating a Ca2+-dependent Na+ entry.     

An electrical block is required to prevent polyspermy in eggs fertilized by natural mating of Xenopus laevis

In 27% DeBoer's saline (DBS), which yields maximum fertility rates, Xenopus eggs fertilized in vitro are monospermic, regardless of sperm concentration. One block to polyspermy (the “slow” block), described previously, occurs at the fertilization envelope that is elevated in response to the cortical reaction. This paper describes properties of an earlier, “fast” block at the plasma membrane and evaluates the functional significance of the two blocks at physiological sperm concentrations in natural mating conditions. Unfertilized eggs have a resting membrane potential of ?19 mV in 27% DBS. Fertilization triggers a rapid depolarization to +8 mV (the fertilization potential, FP); the potential remains positive for ca. 15 min. Activation of eggs with the ionophore, A23187, produces a slower but similar depolarization (the activation potential, AP). As in other amphibian eggs, the FP appears to result from a net efflux of Cl^?, since the peak of the FP (or the AP in ionophore-activated eggs) decreases as the concentration of chloride salts in the medium is increased. In 67% DBS no FP or AP is observed; eggs fertilized in 67% DBS become polyspermic and average 2 sperm entry sites per egg. In the 5–37 mM range, I^? and Br^?, but not F^?, are more effective than Cl^? in producing polyspermy. In 20 mM NaI the plasma membrane hyperpolarizes in response to sperm or ionophore; 100% levels of polyspermy and an average of 14 sperm entry sites per egg are observed. NaI does not inhibit or retard elevation of the fertilization envelope; the cortical reaction and fertilization envelope are normal in transmission electron micrographs. In 67% DBS, which also inhibits the fast block, the slow block was estimated to become functional 6–8 min after insemination. Eggs fertilized by natural mating in 20 mM NaI exhibit polyspermy levels of 50–90% and average 5 sperm entry sites per egg. Since eggs become polyspermic when fertilized by natural mating under conditions that inhibit the fast, but not the slow, block to polyspermy, we conclude that the fast block is essential to the prevention of polyspermy at the sperm concentrations normally encountered by the egg.     

Fast polyspermy block and activation potential : Correlated changes during oocyte maturation of a starfish

Sperm entry into the oocyte of the starfish, Asterina pectinifera, was prevented when the membrane potential of the oocyte was held more positive than −10 to −5 mV, and multiple sperm entries were induced when the potential was held more negative. Based on this potential-dependent fertilization block mechanism, it was demonstrated that an activation potential (AVP) which is induced immediately after the attachment of the first sperm to the egg surface plays the role of a fast polyspermy block. The AVP-mediated polyspermy block mechanism develops as the oocyte matures and deteriorates as it ages. AVPs of mature oocytes exceeded −5 mV (the critical potential level for fertilization block) within 1 sec, and the potential stayed at +12 mV even after the initiation of fertilization membrane elevation. Consequently, the entry of a second sperm is prevented. In contrast, AVPs of overripe oocytes took about 15 sec to attain −5 mV, or they did not attain −5 mV at all. In overripe oocytes multiple sperm entries were associated with “step depolarization(s)” in the rising phase of the AVPs before membrane elevation took place. Immature oocytes generated AVPs associated with sperm entries, but without membrane elevation. AVPs in immature oocytes were characterized by the step depolarization(s) in the rising phase, and an AVP could be evoked again by a second insemination 20 min after the first insemination. These findings indicate that immature oocytes lack both fast and slow polyspermy block mechanisms.     

Fast polyspermy block and activation potential : Electrophysiological bases for their changes during oocyte maturation of a starfish

In the starfish oocyte, the activation potential (AVP) upon fertilization establishes a fast polyspermy block. In the present paper, factors affecting the peak level of the AVP were analyzed by comparing current-voltage relations of the oocyte membrane just before and after insemination at various maturation stages. These factors were: (1) conductance of the oocyte membrane before insemination; (2) magnitude of the conductance increase induced by sperm; and (3) equilibrium potential of the AVP. Mature oocytes showed extremely low membrane conductance before insemination, and this provided a more positive-going AVP establishing monospermy. Overmature oocytes before fertilization showed higher conductance than mature oocytes and usually became polyspermic upon insemination. Application of Ba²⁺ ions reduced the conductance of the unfertilized, overmature oocyte to a state similar to that of the mature oocyte. Correspondingly, Ba²⁺ reduced the probability of polyspermy in overmature oocytes. Old oocytes showed even higher conductance before insemination than overmature oocytes and, in addition, apparently showed a large negative value for the equilibrium potential of the AVP. In old oocytes, these two factors account for the small amplitude of the AVP, which allows multiple sperm entries. Furthermore, the magnitude of the conductance increase induced by sperm seemed to change during the maturation process.     

Surface changes at fertilization: integration of sea urchin (Arbacia punctulata) sperm and oocyte plasma membranes

To examine the integration and fate of the sperm plasma membrane following its incorporation into the oocyte plasma membrane, we have fertilized sea urchin (Arbacia punctulata) gametes reciprocally labeled with cationized ferritin. When unlabeled oocytes were inseminated with labeled sperm, cationized ferritin acceptors moved laterally from the sperm plasma membrane into the fertilization cone and surrounding microvilli, mixing with components of the oocyte plasmalemma. Labeled oocytes inseminated with unlabeled sperm produced extremely large fertilization cones, completely devoid of cationized ferritin, while the remainder of the oocyte surface remained heavily labeled. Surface area measurements indicated that if all the sperm plasmalemma were utilized to delimit a fertilization cone it would provide less than 10% of the total surface membrane. Evidence is presented indicating that a principal source of membrane to the expanding fertilization cone of inseminated oocytes is from microvilli, i.e., microvilli are retracted to accommodate fertilization cone formation. Membrane delimiting the fertilization cone has a much lower affinity for agents (cationized ferritin and concanavalin A) that stain negatively charged and carbohydrate moieties compared to other regions of the oocyte surface. These ultrastructural observations indicate that significant rearrangements occur in the oocyte and sperm plasma membranes following gamete fusion which give rise to asymmetries in membrane topography; components of both membranes are redistributed within the bilayer adjacent to and delimiting the fertilization cone.     

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.     

Voltage Noise Changes during Monospermic and Polyspermic Fertilization of Mature Eggs of the Anuran, Rana temporaria

The electrical response of mature anuran eggs to the fertilizing sperm consists of a rapid depolarization and a decrease in resistance of the plasma membrane (fertilization potential) and serves as a fast block to polyspermy. We report here that the fertilization potential, previously thought to be the earliest electrical response of the egg, is preceded in Rana temporaria by changes in voltage noise. Voltage noise was recorded after insemination and compared in monospermic and NaI-induced polyspermic eggs. Fertilization potential in monospermic eggs arised at 1 min 45 sec to 2 min 15 sec after insemination, and that in NaI-induced polyspermic eggs did at 3 min to 3 min 30 sec after insemination. However, the increase in voltage noise was detected at the similar time (1–2 min 30 sec) after insemination in both the eggs. The duration of voltage noise increase before the fertilization potential was larger in polyspermic eggs (50–105 sec) than in monospermic eggs (10–40 sec). Polyspermic fertilization in Rana temporaria induced by NaI was checked by visualizing multiple sperm entry sites with the scanning microscope. The process of sperm entry and the development of the fertilization body are similar to those occurring with monospermic fertilization; furthermore all supernumerary sperm fuse only with the animal hemisphere of the egg. Although the physiological basis of the changes in voltage noise is unclear, these alterations appear to be the earliest electrical response to sperm yet reported.     

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.     

Sperm-activated currents in ascidian oocytes

Using patch electrodes and the whole-cell recording technique to study fertilization currents in ascidian oocytes under voltage clamp, this paper shows that between -85 and 0 mV the currents are inward with an initial peak ranging from 50 to 600 pA. Voltages more positive than 0 mV inhibit initiation of the fertilization current, but by allowing the oocyte to return briefly to its resting potential fertilization occurs and fertilization currents are outward at positive potentials. By comparison with previous single-channel work, a fertilizing spermatozoon opens about 300 large-conductance channels with zero reversal potential.     

An electrically mediated block to polyspermy in the primitive urodele Hynobius nebulosus and phylogenetic comparison with other amphibians

At fertilization, the egg of the primitive urodele, Hynobius nebulosus, produced a fertilization potential which rose from -12 to +47 mV. A similar activation potential was elicited by pricking with a needle, by applying A23187, or by electric shock. The potential change was mediated by an increased permeability to Cl-. Clamping the egg's membrane potential at +40 mV blocked fertilization, while clamping at +20 mV induced polyspermy. These results indicated the occurrence of an electrical polyspermy block, typical of anurans, but atypical of urodeles. Furthermore, Hynobius eggs fertilized by natural mating incorporated only one sperm nucleus, and experimentally polyspermic eggs underwent multipolar division. Accessory sperm did not degenerate in the egg cytoplasm, indicating lack of an intracellular polyspermy block. By comparison, fertilization of Bufo japonicus (anuran) was also voltage dependent, whereas that of Cynops pyrrhogaster (urodele) was voltage independent. Thus polyspermy prevention mechanisms in Hynobius closely resemble those of anuran amphibians and differ from those of higher urodeles.     

The spike component of the fertilization potential in the toad, Bufo japonicus: changes during meiotic maturation and absence during cross-fertilization

Immature oocytes of the toad, Bufo japonicus, inseminated between first- and second-meiotic metaphase, exhibited polyspermy. Monospermy occurred when the oocytes had reached second-meiotic metaphase. Electrical recording during insemination of the immature oocyte showed fast-rising and slow-rising spikes followed by a gradual shift to a positive membrane potential. The number of fast spikes in each oocyte corresponded well with the number of sperm observed in cytological sections. Mature oocytes elicited one fast spike followed by a rapid rise to a positive plateau. Ion-substitution experiments indicated that, like the plateau, the initial fast spike is mediated mainly by increased permeability of the oocyte plasma membrane to halides such as Cl- or I-. When inseminated with sperm of the newt, Cynops pyrrhogaster, mature Bufo oocytes exhibited polyspermy accompanied by a gradual hyperpolarization and a slowly developing positive plateau, without the fast spike that occurs in self-species fertilization. These results indicated that the spike component of the fertilization potential can be dissociated from the plateau component, and may be elicited by different mechanisms.     

The fast block against polyspermy in fucoid algae is an electrical block

Fertilization potentials in Pelvetia fastigiata, Fucus vesiculosus, and Fucus ceranoides were studied to examine whether eggs of fucoid algae have an electrical block against polyspermy. The resting potential of eggs of all species was about -60 mV, depolarizing, respectively, to -24 +/- 5 mV (SD, n = 9) for 7.5 +/- 2.1 (n = 8) min, -26 +/- 5 (n = 9) mV for 6.4 +/- 2.3 (n = 9) min, and -24 +/- 6 (n = 5) mV for 6.7 +/- 1.9 (n = 4) min. The depolarization was slower, and the fertilization potential was about 10 mV more negative in eggs of both F. vesiculosus and Pelvetia fertilized in 45-mM Na+ ASW; many of these eggs were polyspermic. Steady current was passed through unfertilized eggs of F. vesiculosus prior to insemination to test the potential dependence of fertilization. Eggs (n = 10) bound sperm at all potentials tested (-45 to -23 mV), but fertilization was prevented if eggs were held at potentials more positive than -45 to -37 mV. Eggs underwent a second depolarization if artificially hyperpolarized to potentials more negative than -50 mV immediately after the rise of a normal fertilization potential. Thus, fucoid eggs have an electrical fast block against polyspermy. Only in F. ceranoides does the formation of the cell wall after fertilization appear to be fast enough (i.e., 3-6 min postfertilization versus at 10-15 min in F. vesiculosus and P. fastigiata) to replace the fertilization potential as a polyspermy block. Nonfertilizing fucoid sperm swim away from the egg surface by 1-3 min after rise of the fertilization potential. This suggests that there is another "intermediate block" against polyspermy.     

Effect of methyl-beta-cyclodextrin treatment of pig spermatozoa on in vitro fertilization and embryo development in the absence or presence of caffeine

A series of experiments were carried out to develop a new method to reduce pig polyspermic fertilization and produce more normal embryos, in vitro. Experiment 1 determined the effect of methyl-beta-cyclodextrin (MCD) treatment during cryopreservation on sperm acrosome reaction and sperm fertilization. Compared to the non-MCD-treated control, MCD treatment increased the percentage of acrosome-reacted spermatozoa at thawing and 2h after incubation in fertilization medium (P<0.01). Treatment with MCD also increased (P<0.05) sperm-penetration rate, number of spermatozoa in oocytes, and fertilization efficiency in the caffeine-free fertilization medium. Experiment 2 was designed to examine the effect of withdrawal of caffeine (caffeine-free) from fertilization medium on fertilization parameters and early embryo development. Using MCD-treated spermatozoa, there was no difference in sperm-penetration rate, oocyte cleavage rate, and blastocyst formation rate between the caffeine-free and caffeine-supplemented groups. However, polyspermic fertilization rate was lower, and fertilization efficiency and blastocyst cell number were higher in the caffeine-free group compared to the caffeine-supplemented group (P<0.05). Experiment 3 studied the effect of caffeine and different concentrations of spermatozoa on fertilization parameters. Sperm-penetration rate did not differ between the caffeine-free and the caffeine-supplemented groups at different sperm concentrations. Caffeine and sperm concentration had an effect on the number of spermatozoa in oocytes and on the polyspermic fertilization rate (P<0.002). Caffeine also affected fertilization efficiency (P<0.05). In conclusion, treating spermatozoa with MCD and withdrawing caffeine from fertilization medium may provide a new method to produce a large number of normal embryos, in vitro.     

Membrane currents in the oocyte of the toad Bufo arenarum

The amphibian oocyte cell model is widely used for heterologous expression of ionic channels and receptors. Little is known, however, about the physiology of oocyte cell models other than Xenopus laevis. In this study, the two-electrode voltage clamp technique was used to assess the most common electrical patterns of oocytes of the South American toad Bufo arenarum. Basal membrane resistance, resting potential, and ionic currents were determined in this cell model. The oocyte transmembrane resistance was 0.35 M(Omega), and the resting potential in normal saline was about -33 mV with a range between -20 mV and -50 mV. This is, to our knowledge, the first attempt to begin an understanding of the ion transport mechanisms of Bufo arenarum oocytes. This cell model may provide a viable alternative to the expression of ion channels, in particular those endogenously observed in Xenopus laevis oocytes.     

A fast block to polyspermy in frogs mediated by changes in the membrane potential

The role of the egg membrane potential in the prevention of polyspermy in Rana pipiens was studied with intracellular microelectrodes and ion-substituted media. At fertilization, the egg membrane potential shifts from a resting value of ?28 to +8 mV in a single step of less than 1 sec. A second, slower shift reaches a maximum amplitude of +17 mV; the membrane potential is positive for a total of 21 min. When the membrane potential of unfertilized eggs exposed to sperm was held at +1 to +22 mV for 30 min by injecting current through a second intracellular electrode, the initiation of the first cleavage furrow was delayed about 20 min, suggesting that the eggs were not fertilized while the membrane potential was positive. Injection of a similar amount of current after fertilization did not delay cleavage. Furthermore, fertilization in ion-substituted media suggests a correlation between the maximum amplitude of the positive-going shift and the incidence of polyspermy. Up to 25% of eggs were polyspermic when inseminated in the presence of NaI, and the maximum amplitude was reduced to ?20 mV when eggs were fertilized in 40 mM NaI. In contrast, fertilization in 40 mM NaCl reduced the maximum amplitude only to +6 mV, and produced no polyspermy. In solutions of NaBr, intermediate effects on the membrane potential and polyspermy were seen. Comparable results were obtained with the toad, Bufo americanus. We conclude that the membrane potential shift prevents polyspermy.     

Fertilization potential and polyspermy prevention in the egg of the nemertean, Cerebratulus lacteus

We investigated the electrical properties of the egg of the nemertean worm Cerebratulus, and found evidence that an electrically-mediated polyspermy block operates for a period of about 1 hr after fertilization. At fertilization, in natural or artificial sea water, the membrane potential shifts from its resting level of about -66 mV to a peak of about +43 mV, and in most cases remains greater than 0 mV for more than 1 hr. The average potential during the first 30 min is +22 +/- 8 mV (SD, n = 12). When the external Na+ concentration is reduced from 486 to 51 mM (choline substituted) the fertilization potential amplitude is reduced; the average potential during the first 30 min is -27 +/- 21 mV (SD, n = 5). Eggs inseminated in 51 mM Na+ sea water become polyspermic, indicating that polyspermy prevention depends on an electrically-mediated mechanism. The electrical block is required for about 60 min, since transfer to 51 mM Na+ sea water during this period results in polyspermy. During the first hour following fertilization, the egg is also developing a permanent, nonelectrical block; the degree of polyspermy which results upon transfer to low Na+ sea water decreases progressively with time. The permanent block appears to be at the level of the egg plasma membrane or glycocalyx, since the egg envelope is not a barrier to sperm penetration, nor does its removal induce polyspermy. Electron micrographs show no obvious changes in the morphology of the extracellular layers, plasma membrane or cortex of the egg after fertilization.