The electrical block to polyspermy induced by an intracellular Ca2+ increase at fertilization of the clawed frogs,Xenopus laevis and Xenopus tropicalis

Polyspermy blocking, to ensure monospermic fertilization, is necessary for normal diploid development in most animals. We have demonstrated here that monospermy in the clawed frog, Xenopus tropicalis, as well as in X. laevis, is ensured by a fast, electrical block to polyspermy on the egg plasma membrane after the entry of the first sperm, which is mediated by the positive‐going fertilization potential. An intracellular Ca²⁺ concentration ([Ca²⁺]_i) at the sperm entry site was propagated as a Ca²⁺ wave over the whole egg cytoplasm. In the X. tropicalis eggs fertilized in 10% Steinberg's solution, the positive‐going fertilization potential of +27 mV was generated by opening of Ca²⁺‐activated Cl^?‐channels (CaCCs). The fertilization was completely inhibited when the egg's membrane potential was clamped at +10 mV and 0 mV in X. tropicalis and X. laevis, respectively. In X. tropicalis, a small number of eggs were fertilized at 0 mV. In the eggs whose membrane potential was clamped below ?10 mV, a large increase in inward current, the fertilization current, was recorded and allowed polyspermy to occur. A small initial step‐like current (IS current) was observed at the beginning of the increase in the fertilization current. As the IS current was elicited soon after a small increase in [Ca²⁺]_i, this is probably mediated by the opening of CaCCs. This study not only characterized the fast and electrical polyspermy in X. tropicalis, but also explained that the initial phase of [Ca²⁺]_i increase causes IS current during the early phase of egg activation of Xenopus fertilization.     

Study of protein kinase C antagonists on cortical granule exocytosis and cell-cycle resumption in fertilized mouse eggs

Although pharmacological agonists of protein kinase C (PKC) stimulate some events of mammalian egg activation, including cortical granule (CG) exocytosis, it is not known if these events are dependent on PKC activation during the normal process of fertilization. In order to examine the potential role of PKC in CG exocytosis, this study investigated whether PKC agonists faithfully mimic CG release and whether PKC antagonists block fertilization-induced CG release in mature mouse eggs. Phorbol ester (TPA, 2.5 ng/ml) treatment resulted in an atypical pattern of CG release in which there was a greater net loss of CGs in the equatorial region of the egg than in the region opposite the spindle. This pattern also was in contrast to that during fertilization, in which CG release occurred randomly throughout the cortex. Fertilization experiments utilized two different PKC inhibitors, bisindolyl-maleimide (5 μM) and chelerytherine (0.8 μM), targeted to both the “conserved” substrate and ATP binding domains of PKC. Simultaneous use of both inhibitors at maximal concentrations (compatible with fertilization and above their IC₅₀S) resulted in no detectable inhibition of CG release in treated fertilized eggs compared to controls. In addition, no inhibition of anaphase onset was observed in treated fertilized eggs. Activity of the inhibitors was verified by demonstrating that they blocked the induction of CG loss by TPA. Moreover, 1 μM staurosporine, a potent but less specific antagonist of PKC, also did not block CG loss, whereas the metaphase-anaphase transition was temporarily inhibited. The results indicate that TPA does not faithfully mimic CG release in fertilized eggs, that a role for PKC in CG release at fertilization remains to be established, and that other calcium-dependent effectors may be involved in CG exocytosis. Mol Reprod Dev 46:216–226, 1997. © 1997 Wiley-Liss, Inc.     

The Ca increase by the sperm factor in physiologically polyspermic newt fertilization: Its signaling mechanism in egg cytoplasm and the species-specificity

The newt, Cynops pyrrhogaster, exhibits physiological polyspermic fertilization, in which several sperm enter an egg before egg activation. An intracellular Ca²⁺ increase occurs as a Ca²⁺ wave at each sperm entry site in the polyspermic egg. Some Ca²⁺ waves are preceded by a transient spike-like Ca²⁺ increase, probably caused by a tryptic protease in the sperm acrosome at the contact of sperm on the egg surface. The following Ca²⁺ wave was induced by a sperm factor derived from sperm cytoplasm after sperm–egg membrane fusion. The Ca²⁺ increase in the isolated, cell-free cytoplasm indicates that the endoplasmic reticulum is the major Ca²⁺ store for the Ca²⁺ wave. We previously demonstrated that citrate synthase in the sperm cytoplasm is a major sperm factor for egg activation in newt fertilization. In the present study, we found that the activation by the sperm factor as well as by fertilizing sperm was prevented by an inhibitor of citrate synthase, palmitoyl CoA, and that an injection of acetyl-CoA or oxaloacetate caused egg activation, indicating that the citrate synthase activity is necessary for egg activation at fertilization. In the frog, Xenopus laevis, which exhibits monospermic fertilization, we were unable to activate the eggs with either the homologous sperm extract or the Cynops sperm extract, indicating that Xenopus sperm lack the sperm factor for egg activation and that their eggs are insensitive to the newt sperm factor. The mechanism of egg activation in the monospermy of frog eggs is quite different from that in the physiological polyspermy of newt eggs.     

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.     

CaMKII can participate in but is not sufficient for the establishment of the membrane block to polyspermy in mouse eggs

Fertilization triggers initiation of development and establishment of blocks on the egg coat and plasma membrane to prevent fertilization by multiple sperm (polyspermy). The mechanism(s) by which mammalian eggs establish the membrane block to polyspermy is largely unknown. Ca(2+)/calmodulin-dependent protein kinase II (CaMKII) appears to be the key regulator of several egg activation events (completion of meiosis, progression to embryonic interphase, recruitment of maternal mRNAs). Since sperm-induced increases in cytosolic Ca(2+) play a role in establishment of the membrane block to polyspermy in mouse eggs, we hypothesized that CaMKII was a Ca(2+)-dependent effector leading to this change in egg membrane function. To test this hypothesis, we modulated CaMKII activity in two ways: activating eggs parthenogenetically by introducing constitutively active CaMKIIalpha (CA-CaMKII) into unfertilized eggs, and inhibiting endogenous CaMKII in fertilized eggs with myristoylated autocamtide 2-related inhibitory peptide (myrAIP). We find that eggs treated with myrAIP establish a less effective membrane block to polyspermy than do control eggs, but that CA-CaMKII is not sufficient for membrane block establishment, despite the fact that CA-CaMKII-activated eggs undergo other egg activation events. This suggests that: (1) CaMKII activity contributes to the membrane block, but this not faithfully mimicked by CA-CaMKII and furthermore, other pathways, in addition to those activated by Ca(2+) and CaMKII, also participate in membrane block establishment; (2) CA-CaMKII has a range of effects as a parthenogenetic trigger of egg activation (high levels of cell cycle resumption, modest levels of cortical granule exocytosis, and no membrane block establishment).     

Activation of protein kinase C after fertilization is required for remodeling the mouse egg into the zygote

Fertilization of the mammalian egg initiates numerous biochemical and structural changes which remodel the egg into a single-celled zygote. To date, the most extensively studied phenomenon of fertilization in virtually all species has been the relationship between sperm penetration and the induction of the initial rise in intracellular-free calcium ([Ca²⁺]_i) concentration within the egg. In contrast, relatively few studies have focused on the biochemical events following this rise in calcium, and even fewer studies have directly linked the biochemical events to the structural changes which must ensue for proper development of the embryo. In this study, we exploited recently developed technologies to investigate the action of protein kinase C (PKC), a presumed downstream transducer of the initial rise in [Ca²⁺]_i, during fertilization and artificial activation with calcium ionophore or phorbol 12-myristate 13-acetate (PMA). The newly developed myristoylated PKC pseudosubstrate (myrPKCΨ) was used to specifically inhibit PKC, thereby averting the trauma of injecting the egg with nonmyristoylated PKCΨ. Following fertilization, eggs which were pretreated with myrPKCΨ were not capable of forming a second polar body and pronuclear formation was significantly inhibited. Spatial and temporal localization of PKC using confocal microscopy to visualize the PKC reporter dye, Rim-1, demonstrated localization of PKC to the lateral aspects of the forming second polar body after fertilization, or after artificial activation with calcium ionophore or PMA. In vivo biochemical analysis of eggs which were fertilized or artificially activated demonstrated that PKC activity rose at the same time (40 min) as the second polar body formed and then subsided over the next 5 hr post activation. From these data, we conclude that PKC plays an integral role in directing the transformation from egg to embryo. Mol. Reprod. Dev. 46:587–601, 1997. © 1997 Wiley-Liss, Inc.     

U.V. Irradiation Inhibits The Electrical Block to Polyspermy in Echinoderms*

Oocytes of the sea urchin Sphaerechinus granularis and the startish Marthasterias glacialis have been submitted to U.V. irradiation before fertilization. This treatment significantly increased the incidence and severity of polyspermy in the sea urchin and was also found effective on starfish oocytes. These were found more resistant to damage than sea urchin eggs and U.V. irradiation did not affect either their response to the hormone l-methyladenine or the rate of elevation of the fertilization envelope, which assures the late and definitive block to polyspermy. Electrophysiological measurements performed on M. glacialis oocytes definitively demonstrate that U.V. irradiation completely inactivates voltage-dependent sodium channels, without altering the other main conductances, Cl^?, K⁺ or Ca²⁺. After such a treatment, the relative permeability of the membrane to Na⁺ as compared to K⁺ shifted from 0.019±0.003 to 0.003±0.002 and only the calcium component of the action potentials could be observed. However, a fertilization potential, preceded by small sperm induced steps, is still present in these conditions, although its peak and plateau level are greatly reduced. These new findings are discussed, which confirm the electrical nature of the fast block to polyspermy but question about the specificity of those sperm-gated channels which are supposed to trigger the fertilization potential.     

Mechanical stimulation by osmotic and hydrostatic pressure activates Drosophila oocytes in vitro in a calcium-dependent manner

Embryogenesis in vertebrates and marine invertebrates begins when a mature oocyte is fertilized, resulting in a rise in intracellular calcium (Ca²⁺) that activates development. Insect eggs activate without fertilization via an unknown signal imparted to the egg during ovulation or egg laying. One hypothesis for the activating signal is that deformation of eggs as they pass through a tight orifice provides a mechanical stimulus to trigger activation. Ovulation could produce two forms of mechanical stimulus: external pressure resulting from the passage of oocytes from the ovary into the narrow oviducts, and osmotic pressure caused by hydration-induced swelling of the oocyte within the oviducts. Ovulation could also trigger activation by placing the oocyte in a new environment that contains an activating substance, such as a particular ion. Here, we provide the first evidence that Drosophila oocytes require Ca²⁺ for activation, and that activation can be triggered in vitro by mechanical stimuli, specifically osmotic and hydrostatic pressure. Our results suggest that activation in Drosophila is triggered by a mechanosensitive process that allows external Ca²⁺ to enter the oocyte and drive the events of activation. This will allow exploitation of Drosophila genetics to dissect molecular pathways involving Ca²⁺ and the activation of development.     

Polyspermy block in jellyfish eggs: Collaborative controls by Ca and MAPK

Jellyfish eggs neither undergo apparent cortical reaction nor show any significant change in the membrane potential at fertilization, but nevertheless show monospermy. Utilizing the perfectly transparent eggs of the hydrozoan jellyfish Cytaeis uchidae, here we show that the polyspermy block is accomplished via a novel mechanism: a collaboration between Ca²⁺ and mitogen-activated protein kinase (MAPK). In Cytaeis, adhesion of a sperm to the animal pole surface of an egg was immediately followed by sperm–egg fusion and initiation of an intracellular Ca²⁺ rise from this site. The elevated Ca²⁺ levels lasted for several minutes following the sperm–egg fusion. The Ca²⁺ rise proved to be necessary and sufficient for a polyspermy block, as inhibiting a Ca²⁺ rise with EGTA promoted polyspermy, and conversely, triggering a Ca²⁺ rise by inositol 1,4,5-trisphosphate (IP₃) or excess K⁺ immediately abolished the egg’s capacity for sperm–egg fusion. A Ca²⁺ rise at fertilization or by artificial stimulations evoked dephosphorylation of MAPK in eggs. The eggs in which phosphorylated MAPK was maintained by injection of mRNA for MAPK kinase kinase (Mos), like intact eggs, exhibited a Ca²⁺ rise at fertilization or by IP₃ injection, and shut down the subsequent sperm–egg fusion. However, the Mos-expressing eggs became capable of accepting sperm following the arrest of Ca²⁺ rise. In contrast, addition of inhibitors of MAPK kinase (MEK) to unfertilized eggs caused MAPK dephosphorylation without elevating Ca²⁺ levels, and prevented sperm–egg fusion. Rephosphorylation of MAPK by injecting Mos mRNA after fertilization recovered sperm attraction, which is known to be another MAPK-dependent event, but did not permit subsequent sperm–egg fusion. Thus, it is possible that MAPK dephosphorylation irreversibly blocks sperm–egg fusion and reversibly suppresses sperm attraction. Collectively, our data suggest that both the fast and late mechanisms dependent on Ca²⁺ and MAPK, respectively, ensure a polyspermy block in jellyfish eggs.     

Regulation of diacylglycerol production and protein kinase C stimulation during sperm- and PLCzeta-mediated mouse egg activation

Background information. At fertilization in mammalian eggs, the sperm induces a series of Ca²⁺ oscillations via the production of inositol 1,4,5‐trisphosphate. Increased inositol 1,4,5‐trisphosphate production appears to be triggered by a sperm‐derived PLCζ (phospholipase C‐ζ) that enters the egg after gamete fusion. The specific phosphatidylinositol 4,5‐bisphosphate hydrolytic activity of PLCζ implies that DAG (diacylglycerol) production, and hence PKC (protein kinase C) stimulation, also occurs during mammalian egg fertilization. Fertilization‐mediated increase in PKC activity has been demonstrated; however, its precise role is unclear. Results. We investigated PLCζ‐ and fertilization‐mediated generation of DAG in mouse eggs by monitoring plasma‐membrane translocation of a fluorescent DAG‐specific reporter. Consistent plasma‐membrane DAG formation at fertilization, or after injection of physiological concentrations of PLCζ, was barely detectable. However, when PLCζ is overexpressed in eggs, significant plasma‐membrane DAG production occurs in concert with a series of unexpected secondary high‐frequency Ca²⁺ oscillations. We show that these secondary Ca²⁺ oscillations can be mimicked in a variety of situations by the stimulation of PKC and that they can be prevented by PKC inhibition. The way PKC leads to secondary Ca²⁺ oscillations appears to involve Ca²⁺ influx and the loading of thapsigargin‐sensitive Ca²⁺ stores. Conclusions. Our results suggest that overproduction of DAG in PLCζ‐injected eggs can lead to PKC‐mediated Ca²⁺ influx and subsequent overloading of Ca²⁺ stores. These results suggest that DAG generation in the plasma membrane of fertilizing mouse eggs is minimized since it can perturb egg Ca²⁺ homoeostasis via excessive Ca²⁺ influx.     

Translocation of the classic protein kinase C isoforms in porcine oocytes: implications of protein kinase C involvement in the regulation of nuclear activity and cortical granule exocytosis

Protein kinase C (PKC) is a family of Ser/Thr protein kinases categorized into three subfamilies: classical, novel, and atypical. The subcellular localization of classical PKCalpha, -betaI, and -gamma in the process of porcine oocyte maturation, fertilization, and parthenogenetic activation and their involvement in cortical granule (CG) exocytosis were investigated. The results of Western blot showed that PKCalpha, -betaI, and -gamma were expressed in the oocytes at the germinal vesicle (GV) and metaphase II (MII) stages. Confocal microscopy revealed that the three PKC isoforms were concentrated in the GV but evenly distributed in the cytoplasm of MII eggs. PKCalpha and -gamma were translocated to the plasma membrane soon after sperm penetration. cPKCs migrated into the pronucleus in fertilized eggs. Following treatment with a PKC activator, phorbol 12-myristate 13-acetate (PMA), CGs were released and PKCalpha and -gamma were translocated to the membrane. The CG exocytosis and PKC redistribution induced by PMA could be blocked by the PKC inhibitor staurosporine. Parthenogenetic stimulation with ionophore A23187 or electrical pulse also induced cPKC translocation and CG exocytosis. Eggs injected with PKCalpha isoform-specific antibody failed to undergo CG exocytosis after PMA treatment or fertilization. The results suggest that cPKCs, especially the alpha-isotype, regulate nuclear function and CG exocytosis in porcine eggs.     

Protein kinase C is required for the disappearance of MPF upon artificial activation in mouse eggs

The aim of the present study was to investigate the implication of protein kinase C (PKC) in the mouse egg activation process. We used OAG (1-oleoyl-2-acetyl-sn-glycerol) as a PKC activator, calphostin C as a specific PKC inhibitor, and the calcium ionophore A23187 as a standard parthenogenetic agent. The exposure of zona-free eggs to 150 μM or 50 μM OAG for 10 min resulted in meiosis II completion in ∼80% of instances. By contrast, at a lower concentration (25 μM), the PKC stimulator was ineffective as parthenogenetic agent. Shortly after the application of 150 μM OAG, the cytosolic Ca²⁺ concentration ([Ca²⁺]_i) increased transiently in all the eggs examined, whereas after the addition of 50 μM OAG, [Ca²⁺]_i remained unchanged for at least 20 min. During this period, the activity of M-phase promoting factor (MPF) dramatically decreased and most of the eggs entered anaphase except when the PKC was inhibited by calphostin C. Similarly, MPF inactivation and meiosis resumption were prevented in calphostin C-loaded eggs following treatment with A23187, even though the ionophore-induced Ca²⁺ signalling was not affected. Taken together, our results indicate that stimulation of PKC is a sufficient and necessary event to induce meiosis resumption in mouse eggs and strongly suggest that, in this species, the mechanism by which a transient calcium burst triggers MPF inactivation involves a PKC-dependent pathway. Mol. Reprod. Dev. 48:292–299, 1997. © 1997 Wiley-Liss, Inc.     

Osmotrophy in fossil protoctists and early animals

Summary

The role of Ca²⁺ in activation and early development of locust eggs was examined through measurement of ooplasmic Ca²⁺ levels before and after fertilization, and through experimental activation of unfertilized eggs. Ooplasmic pCa (i.e. the negative logarithm of Ca²⁺ activity) measured in intact eggs decreased from 5.35 before fertilization, to 4.77 and 3.00 by 1 day and 3 days after fertilization, respectively. pCa was also determined for samples of ooplasm collected by rupturing eggs under paraffin oil. The pCa was 5.10 in ooplasm isolated from unfertilized eggs, and 3.84 in ooplasm collected from eggs within 4 h of fertilization. Ooplasmic pCa remained between 3.97 and 3.12 from 1–6 days after fertilization. Since a decline in pCa indicates an increase in ooplasmic Ca²⁺ activity, the data suggest that regulation of ooplasmic Ca²⁺ during post-fertilization development involves release of Ca²⁺ from internal stores. Experimental egg activation was examined in eggs dissected from the oviducts before fertilization and incubated on moist filter paper. Some eggs were first immersed in experimental solutions for 30–60 minutes before incubation. The presence of an embryo 2 or 4 days after fertilization or experimental treatment was used as an indicator of egg activation. Activation occurred in 92% and 12% of fertilized and untreated eggs, respectively. The percentage of unfertilized eggs which activated increased to 47% if eggs were soaked 30–60 minutes in physiological saline, and to as much as 65%-68% if eggs were injected with Ca²⁺ buffers or if a Ca²⁺ action potential was evoked. Up to 36% and 42% of unfertilized eggs activated after incubation in Ca²⁺-free salines or in the presence of the Ca²⁺-channel blocker Cd²⁺, respectively. Taken together, the results suggest that entry of external Ca²⁺ through voltage dependent channels increases the proportion of eggs which activate, but is not an absolute requirement for activation.     

Strontium supports capacitation and the acrosome reaction in mouse sperm and rapidly activates mouse eggs

Extracellular Ca²⁺ is required for capacitation and fertilization in the mouse, but very little is known about the ability of other divalent cations to substitute for Ca²⁺. In this study, Sr²⁺, Ba²⁺, and Mg²⁺ were evaluated for their ability to support capacitation, the acrosome reaction, hyperactivated motility, and fertilization. Ba²⁺ proved to be ineffective, but Mg²⁺-containing medium was able to support capacitation to a greater extent than unsupplemented Ca²⁺-deficient media; despite this, Ca²⁺ was required for fertilization. In contrast, Sr²⁺ proved capable of substituting for Ca²⁺ in all events. Furthermore, Sr²⁺-induced responses were indistinguishable from the corresponding Ca²⁺-induced ones: Sperm capacitated at the same rate and underwent the acrosome reaction to the same extent. However, demonstration of sperm:egg fusion in Sr²⁺ required the use of zona-free eggs. This was due not to the inability of the sperm to penetrate the zona but to the very rapid activation and cortical granule release by eggs in response to Sr²⁺. When zona-intact eggs were used, the block to polyspermy had been mounted by the time sperm had penetrated the zona. A 15 min exposure to Sr²⁺ was sufficient to block sperm fusion, but a longer exposure was required to ensure the resumption of meiosis in eggs; such a response was surprising in that the eggs were freshly ovulated and not susceptible to activation by many different treatments. Thus Sr²⁺ can profoundly affect both gametes in the mouse: It substitutes completely for Ca²⁺ in sperm responses and rapidly activates eggs, possibly by displacing Ca²⁺ from intracellular stores into the cytoplasm, where the Ca²⁺ can then trigger the various events of activation.     

Fertilization Induces a Transient Exposure of Phosphatidylserine in Mouse Eggs

Phosphatidylserine (PS) is normally localized to the inner leaflet of the plasma membrane and the requirement of PS translocation to the outer leaflet in cellular processes other than apoptosis has been demonstrated recently. In this work we investigated the occurrence of PS mobilization in mouse eggs, which express flippase Atp8a1 and scramblases Plscr1 and 3, as determined by RT-PCR; these enzyme are responsible for PS distribution in cell membranes. We find a dramatic increase in binding of flouresceinated-Annexin-V, which specifically binds to PS, following fertilization or parthenogenetic activation induced by SrCl₂ treatment. This increase was not observed when eggs were first treated with BAPTA-AM, indicating that an increase in intracellular Ca²⁺ concentration was required for PS exposure. Fluorescence was observed over the entire egg surface with the exception of the regions overlying the meiotic spindle and sperm entry site. PS exposure was also observed in activated eggs obtained from CaMKIIγ null females, which are unable to exit metaphase II arrest despite displaying Ca²⁺ spikes. In contrast, PS exposure was not observed in TPEN-activated eggs, which exit metaphase II arrest in the absence of Ca²⁺ release. PS exposure was also observed when eggs were activated with ethanol but not with a Ca²⁺ ionophore, suggesting that the Ca²⁺ source and concentration are relevant for PS exposure. Last, treatment with cytochalasin D, which disrupts microfilaments, or jasplakinolide, which stabilizes microfilaments, prior to egg activation showed that PS externalization is an actin-dependent process. Thus, the Ca²⁺ rise during egg activation results in a transient exposure of PS in fertilized eggs that is not associated with apoptosis.     

Plasma membrane block to sperm entry occurs in mouse eggs upon parthenogenetic activation

The ability of parthenogenetically activated mouse eggs to establish a plasma membrane (PM) block to sperm penetration was studied. Zona-free eggs preloaded with Hoechst 33342 were activated by exposure to ethanol or OAG (1-oleoyl-2-acetyl-sn-glycerol) and inseminated after different periods. Eggs challenged with sperm at 30- or 60-min postactivation displayed a fertilization frequency significantly lower than that of control eggs. Conversely, when insemination was carried out at 120-min postactivation, the proportion of fertilized eggs was equivalent to that observed in the control group. Moreover, we report that when the eggs were induced to resume meiosis without any notable loss of CGs (egg exposure to OAG at 100 μM external Ca²⁺ or to heat shock), a normal ability to be penetrated was recorded at 30-min postactivation. Similar behaviour was exhibited by eggs that underwent a CG exocytosis close to that triggered by sperm in absence of nuclear activation (microinjection of inositol 1,4,5-trisphosphate into the egg at 1 μM cytosolic concentration). Present data support the conclusion that parthenogenetically activated mouse eggs are capable of a transitory PM block response that requires both CG exocytosis and meiosis resumption to occur. © 1994 Wiley-Liss, Inc.     

Initiation of the activation potential by an increase in intracellular calcium in eggs of the frog,Rana pipiens

The membrane potential of the frog egg undergoes a transient positive shift at fertilization which is a block to polyspermy. This paper addresses the question of how a sperm elicits this “fertilization potential.” Iontophoretic injection of Ca²⁺ activates Rana pipiens eggs to develop and initiates a transient, positive-going shift in the membrane potential (the activation potential) which is like the sperm-induced fertilization potential in amplitude, duration, and Cl^? dependence. Activation potentials are elicited by Ca² injection into both animal and vegetal regions of the egg, but the rate of the initial depolarization is much less when Ca²⁺ is injected into the vegetal region. Injections of K⁺, Na⁺, Cl^?, or Mg²⁺ do not result in activation potentials, but the Ca²⁺ analogs, Sr²⁺ and Ba²⁺, can substitute for Ca²⁺. Treatment of eggs with the divalent cation ionophore, A23187, also initiates a transient, positive-going depolarization. Because injection of Ca²⁺ is sufficient to elicit a response almost identical to a fertilization potential, the ion transport mechanisms necessary to produce a fertilization potential must preexist in the unfertilized eggs; the sperm contributes only the stimulus to activate these mechanisms. The results reported here suggest that the stimulus may be a rise in free Ca²⁺.     

Ca2+-independent form of protein kinase C may regulate Na+ transport across frog skin

Summary Activators of protein kinase C (PKC) stimulate Na^– transport (J _Na) across frog skin. We have examined the effect of Ca²⁺ on PKC stimulation ofJ _Na. Both the phorbol ester 12-O-tetradecanoylglycerol (DiC₈) were used as PKC activators. Blocking Ca²⁺ entry into the cytosol (either from external or internal stores) reduced the subsequent natriferic effect of the PKC activators. This negative interaction did not simply reflect saturation of activation of the apical Na⁺ channels, since the stimulations produced by blocking Ca²⁺ entry and adding cyclic AMP were simply additive.The Ca²⁺ dependence of the natriferic effect could have reflected either a direct action of cytosolic Ca²⁺ on PKC or an indirect action on the final receptor site (the Na⁺ channel). To distinguish between these possibilities, the TPA- and phospholipid-dependent kinase activity of broken-cell preparations was assayed. The kinase activity was not stimulated by physiological levels of Ca²⁺, and in fact was inhibited at millimolar concentrations of Ca²⁺.We conclude that the effects of Ca²⁺ on the natriferic response to PKC activators are indirect. Reducing cytosolic uptake of Ca²⁺ may have stimulated Na⁺ transport by a chemical modification of the apical channels observed in other tight epithelia. The usual stimulation of Na⁺ transport produced by PKC activators in frog skin may reflect the operation of a nonconventional form of PKC. This enzyme is Ca²⁺ independent and seems related to thenPKC or PKC observed in other systems.     

Premature cortical granule loss does not prevent sperm penetration of mouse eggs.

The role of cortical granules in the mouse egg's plasmalemma block to polyspermy was investigated by examining the effect of premature granule loss on egg fertility. Granule loss, quantitated by transmission electron microscopic examination, was induced in zona-free eggs by exposure to the divalent cation ionophore, A23187, or by mechanical removal of zonae. Egg exposure to ionophore led to the loss of approximately 50% of the egg's complement of granules in the absence of nuclear activation (parthenogenesis), while complete cortical granule loss accompanied the parthenogenetic activation seen in a limited population of mechanically stimulated eggs. Aged eggs underwent nuclear activation without a dramatic reduction in granule complements. The fertility of treated zona-free eggs was identical to that of controls, as measured by the percentage of eggs penetrated and by the mean number of sperm recovered per egg. Moreover, both ionophore-treated and aged eggs subsequently underwent a normal sperm-induced block response. Exposure of zona-intact eggs to ionophore was also without effect on egg fertility. These results indicate that cortical granules are not involved in the plasmalemma block to polyspermy in the mouse.     

Intracellular pH and intracellular free calcium responses to protein kinase C activators and inhibitors in Xenopus eggs.

Cell activation during fertilization of the egg of Xenopus laevis is accompanied by various metabolic changes, including a permanent increase in intracellular pH (pHi) and a transient increase in intracellular free calcium activity ([Ca2+]i). Recently, it has been proposed that protein kinase C (PKC) is an integral component of the Xenopus fertilization pathway (Bement and Capco, J. Cell Biol. 108, 885-892, 1989). Indeed, activators of PKC trigger cortical granule exocytosis and cortical contraction, two events of egg activation, without, however, releasing the cell cycle arrest (blocked in second metaphase of meiosis). In the egg of Xenopus, exocytosis as well as cell cycle reinitiation are supposed to be triggered by the intracellular Ca2+ transient. We report here that PKC activators do not induce the intracellular Ca2+ transient, or the activation-associated increase in pHi. These results suggest that the ionic responses to egg activation in Xenopus do not appear to depend on the activation of PKC. In addition, in eggs already pretreated with phorbol esters, those artificial activators that act by releasing Ca2+ intracellularly, triggered a diminished increase in pHi. Finally, sphingosine and staurosporine, two potent inhibitors of PKC, were found to trigger egg activation, suggesting that a decrease in PKC activity might be an essential event in the release of the metaphase block, in agreement with recent findings on the release of the prophase block in Xenopus oocytes (Varnold and Smith, Development 109, 597-604, 1990).