Electrical responses of eggs to acrosomal protein similar to those induced by sperm

Sperm MMP-2 is indispensable for fast electrical block to polyspermy at fertilization in Xenopus tropicalis

Sperm matrix metalloproteinase-2 (MMP-2) is necessary for frog fertilization. Monospermy is ensured by a fast, electrical block to polyspermy mediated by a positive fertilization potential. To determine the role of the MMP-2 hemopexin domain (HPX) in a fast block to polyspermy during fertilization of the frog, Xenopus tropicalis, we prepared mutant frogs deficient in mmp2 gene using the transcription activator-like effector nuclease method. mmp2 ΔHPX (-/-) sperm without MMP-2 protein were able to fertilize wild-type (WT; +/+) eggs. However, polyspermy occurred in some eggs. The mutant sperm generated a normal fertilization potential amounting to 10 mV, and were able to fertilize eggs at 10 mV, at which WT sperm never fertilized. Sensitivity during voltage-dependent fertilization decreased in mutant sperm. This study demonstrates for the first time that the genetic alteration of the MMP-2 molecule in sperm causes polyspermy during fertilization of a monospermic species. Our findings provide reliable evidence that sperm MMP-2 is indispensable for the fast, electrical block to polyspermy during Xenopus fertilization.

Defending the zygote: search for the ancestral animal block to polyspermy

Fertilization is the union of a single sperm and an egg, an event that results in a diploid embryo. Animals use many mechanisms to achieve this ratio; the most prevalent involves physically blocking the fusion of subsequent sperm. Selective pressures to maintain monospermy have resulted in an elaboration of diverse egg and sperm structures. The processes employed for monospermy are as diverse as the animals that result from this process. Yet, the fundamental molecular requirements for successful monospermic fertilization are similar, implying that animals may have a common ancestral block to polyspermy. Here, we explore this hypothesis, reviewing biochemical, molecular, and genetic discoveries that lend support to a common ancestral mechanism. We also consider the evolution of alternative or radical techniques, including physiological polyspermy, with respect to our ability to describe a parsimonious guide to fertilization.

The charged milieu: a major player in fertilization reactions

In previous studies, we have found that negatively charged, but not uncharged, amino acids and sugars block sea urchin fertilization. These studies were developed from modeling work in non-living systems using derivatized agarose beads that suggested that charge-charge bonding may control at least some adhesive interactions. In the present study, the effects of positively charged, negatively charged and uncharged molecules were examined in the sea urchin sperm-egg system in over 300 individual trials. The results indicate that depending on the specific molecules utilized, both sperm and egg are exquisitely sensitive to charged but not uncharged molecules and to pH changes in sea water caused by some of the charged molecules. It is shown that egg activation, as well as sperm motility and sperm-egg interactions, can be affected by charged molecules. One compound, fructose-1-phosphate blocked fertilization in S. purpuratus sea urchins but not in Lytechinus pictus sea urchins. These findings indicate that charge alone cannot explain all the results. In this case, the presence of a ketone instead of an aldehyde group indicates that species-specific components may control fertilization reactions. The present study is a comprehensive survey of the effects of charge, pH and molecular structure on the fertilization activation continuum in a model system of sea urchins.

Polyspermy prevention in marine invertebrates

In marine invertebrates, as in most other organisms, normal development requires that only one sperm nucleus joins with the egg nucleus at fertilization. The principal mechanisms employed are (1) prevention of sperm-egg plasma membrane fusion and (2) modifications of the egg extracellular coat to prevent sperm binding and/or penetration. In a third strategy, fertilization is polyspermic, but only one sperm nucleus fuses with the egg nucleus. Other factors such as gamete density during spawning, chemotaxis, and localized sites for sperm entry may also affect the numbers of sperm reaching the egg.

Injection of a sperm extract triggers egg activation in the newt Cynops pyrrhogaster

Unfertilized eggs of the newt Cynops pyrrhogaster are arrested at the second meiotic metaphase. The primary signal for egg activation is a transient increase in [Ca2+](i), which is triggered by the fertilizing sperm and propagates over the egg cortex as a Ca2+ wave. We injected an extract of Cynops sperm (SE) into unfertilized eggs and induced a wave-like [Ca2+](i) increase which resulted in activation and resumption of meiosis. The SE-injected eggs showed degradation of cyclin B1 and DNA replication. When SE was boiled or treated with proteinase K before injection, it was unable to cause egg activation. Preinjection of Ca2+ -chelator BAPTA before SE injection inhibited egg activation. These results indicate that a heat-labile and proteinaceous factor in the sperm cytoplasm induces a transient increase in [Ca2+](i) which is required for egg activation. Injection of IP3 into unfertilized eggs caused an increase in [Ca2+](i) and egg activation, but injection of cADP-ribose did not. These results support the hypothesis that Ca2+ release at fertilization occurs via IP3 receptors.

Sperm extract injection into ascidian eggs signals Ca(2+) release by the same pathway as fertilization

Injection of eggs of various species with an extract of sperm cytoplasm stimulates intracellular Ca(2+) release that is spatially and temporally like that occurring at fertilization, suggesting that Ca(2+) release at fertilization may be initiated by a soluble factor from the sperm. Here we investigate whether the signalling pathway that leads to Ca(2+) release in response to sperm extract injection requires the same signal transduction molecules as are required at fertilization. Eggs of the ascidian Ciona intestinalis were injected with the Src-homology 2 domains of phospholipase C gamma or of the Src family kinase Fyn (which act as specific dominant negative inhibitors of the activation of these enzymes), and the effects on Ca(2+) release at fertilization or in response to injection of a sperm extract were compared. Our findings indicate that both fertilization and sperm extract injection initiate Ca(2+) release by a pathway requiring phospholipase C gamma and a Src family kinase. These results support the hypothesis that, in ascidians, a soluble factor from the sperm cytoplasm initiates Ca(2+) release at fertilization, and indicate that the activating factor from the sperm may be a regulator, directly or indirectly, of a Src family kinase in the egg.

Voltage-dependent activation of frog eggs by a sperm surface disintegrin peptide

Fertilin, a sperm protein of the metalloprotease/disintegrin/cysteine-rich (MDC) family, plays a critical role in sperm-egg binding in mammals. Peptides corresponding to the disintegrin domain of fertilin and antibodies against fertilin have been shown to inhibit mammalian sperm-egg binding and fusion. A protein from the same family, xMDC16, was recently cloned from frog (Xenopus laevis) testis and was found to be involved in frog sperm-egg binding. Here we report that xMDC16 is localized predominantly on the posterior surface of egg jelly-activated sperm, and peptides from the disintegrin domain of this protein activate eggs when applied near the egg surface. Egg activation was dependent on (1) specific amino acid residues (KTX); (2) the presence of divalent cations, but not external Ca2+ alone; and (3) voltage across the egg plasma membrane. This is the first demonstration of egg activation in vertebrates by the surface application of a peptide derived from a sperm surface protein, supporting a model for egg activation that involves a signal transducing receptor for sperm in the egg's plasma membrane.

Molecular mechanisms of sperm-egg interactions and egg activation

The binding of acrosome reacted mammalian sperm to the egg plasma membrane initiates a series of signaling events in the egg, termed "egg activation", which lead to the completion of meiosis II and the initiation of a mitotic cell cycle. Many of these signaling events have characteristics of classical signal transduction events in somatic cells. Currently, there are two hypotheses for how sperm-induced egg activation is initiated. In the "receptor" hypothesis, the fertilizing sperm interacts with a specific egg surface receptor, and this interaction leads to signal transduction and effector activation. In the "fusion" hypothesis it is postulated that following fusion of the sperm and egg plasma membranes a soluble sperm-derived factor enters the egg's cytoplasm and activates pathways leading to egg activation. This chapter will provide an overview of the processes of cell-cell interaction and signal transduction leading to mammalian egg activation. It will concentrate on specific molecules proposed to be involved in sperm-egg interaction, signal transduction and effector mechanisms involved in egg activation, and a discussion of sperm-associated factors that have been implicated in egg activation.

A novel protein for Ca2+ signaling at fertilization

At fertilization in all species studied the sperm activates the egg by causing an increase in the level of cytoplasmic free Ca2+ concentration. It is still not established how the sperm causes the changes in Ca2+ in the egg, which in the majority of eggs is due to release from internal stores. Current hypotheses about the signaling molecules involved in fertilization are confounded by the fact that for many eggs the fertilization-associated Ca2+ increase is readily mimicked by parthenogenetic activating agents. One exception to this is found for mammalian eggs where there are a series of Ca2+ oscillations observed at fertilization that have distinct characteristics. In this context we discuss three different theories of how sperm trigger Ca2+ release in eggs. We present the case that the sperm mediates its Ca2+ mobilization effects after gamete membrane fusion by introducing a specific protein into the egg cytoplasm. Our argument is based upon the fact that only the mammalian sperm protein factor can trigger a pattern of Ca2+ oscillations that is similar to that induced by the sperm in mammalian eggs. The sperm factor activity is correlated with a novel signaling protein that we have called oscillin and which may mediate Ca2+ release via a novel mechanism.

The intracellular calcium increase at fertilization in Urechis caupo oocytes: activation without waves

The intracellular Ca2+ (Cai) increase at fertilization of the marine worm Urechis caupo (Echiura) was studied with conventional and confocal epifluorescence microscopy in oocytes microinjected with calcium green dextran or dually labeled with the calcium-insensitive dye tetramethylrhodamine dextran. Calcium green fluorescence was also measured with a photomultiplier system while the oocyte membrane potential was recorded and manipulated. The results show that Cai rises simultaneously around the oocyte cortex and peaks slightly later in the nucleoplasm. The Cai rise coincides with the initiation of the fertilization potential and we conclude that it is due primarily to external Ca2+ entering through the voltage-gated Ca2+ action potential channels that open during the fertilization potential because: (1) current clamping the oocyte membrane potential to positive values in the absence of sperm produces a similar Cai increase, (2) external Ca2+ is required, (3) and the confocal images are consistent with this mechanism. External application of sperm acrosomal peptide (P23) also caused a Cai increase that was inhibited in the presence of CoCl2. Cai and pHi (measured with BCECF dextran) were manipulated in experiments employing microinjection of BAPTA (to chelate Cai), external application of NH4Cl (to increase pHi) and CoCl2 (to block Ca2+ channels), and fertilization of eggs in pH 7 seawater (Cai increase without pHi increase). The results showed that increases in both Cai and pHi are required for GVBD; neither alone is sufficient. However, although nuclear and cytoplasmic Ca2+ levels tended to parallel each other in oocytes fertilized at pH 7, and during the initial Cai response in oocytes fertilized at pH 8, there was a disproportionate fluorescence increase in the nucleoplasm of the latter prior to GVBD which could not be explained by any artifact we tested, suggesting there may be a selective increase in nuclear Ca2+ associated with GVBD. Finally, electrophysiological experiments with BAPTA-injected oocytes showed that the opening of the fertilization potential Na+ channels was Ca2+-independent, (although they did not close at the normal time). These and earlier results suggest that Urechis sperm may activate oocytes by interacting directly with the Na+ channels or associated receptors.

Parthenogenesis in Urechis caupo (Echiura). II. Role of intracellular pH in parthenogenesis induction

A peptide (P23) isolated from sperm acrosomal protein initiates development in eggs of the marine worm Urechis caupo. We have shown previously that eggs exposed to P23 for > or = 3 min complete meiosis but fail to cleave. However, a brief (1.5-2 min) exposure to P23 at pH 8, followed by either acidification of the seawater of pH 7 or dilution of P23 at pH 8 causes germinal vesicle breakdown (GVBD), but eggs fail to complete meiosis and many then later advance to mitosis. In the present study we investigated the hypothesis that partial activation leading to parthenogenesis occurs when there is a partial intracellular alkalinization. Measurements with the fluorescent pH indicator bis(carboxyethyl)-carboxyfluorescein (BCECF) showed that P23 induces a pHi increase similar to that occurring during fertilization and the parthenogenesis-inducing treatments interrupt this rise in pHi. In eggs exposed to P23 for > 3 min the pHi increase was 0.31-0.49 units, slightly higher than in fertilized eggs. In partially activated eggs exposed to P23 for 1.5-2 min at pH 8, pHi began to rise but then returned to control values or remained only partially elevated (< 0.2 pH units average increase). Electrophysiological measurements revealed that removal of P23 during the first few minutes of exposure caused the activation potential to terminate and experiments with [14C]-P23 confirmed that dilution results in a rapid unbinding of P23 from eggs. If proton export is driven by membrane potential as well as the pH gradient, these results explain why dilution of P23 at pH 8 also interrupts the pHi increase.

Sperm-binding proteins

Gamete recognition and binding are mediated by specific proteins on the surface of the sperm and egg. Identification and characterization of some of these proteins from several model systems, particularly mouse and sea urchin, have focused interest on the general properties and functions of gamete recognition proteins. Sperm-binding proteins located in egg extracellular coats as well as sperm-binding proteins that are localized to the egg plasma membrane are presented in the context of their structure and function in gamete binding. Unifying and disparate characteristics are discussed in light of the diverse biology of fertilization among species. Outstanding questions, alternative mechanisms and models, and strategies for future work are presented.

Tyrosine phosphorylation of the egg receptor for sperm at fertilization

Gamete interaction triggers a variety of responses within the egg, collectively referred to as egg activation. In addition to the hallmarks of calcium release and fertilization envelope elevation, there are cytoskeletal rearrangements, protein tyrosine phosphorylation, and an increase in pH, among others. The ultimate goal of these concerted activation events is entry of the newly fertilized egg into the cell cycle. However, the molecular mechanisms which promote downstream cell activation events remain poorly understood. One model suggests that sperm deliver an "activating factor" upon fusion with the egg plasma membrane, while a second model proposes that the egg receptor for sperm transduces a signal that mediates a cascade of subsequent events. It also is possible that multiple pathways are activated. As a first step toward testing the hypothesis of receptor-mediated signal transduction, we have investigated the tyrosine phosphorylation state of the sea urchin egg receptor for sperm using specific antibodies. The present work indicates that the sperm receptor is phosphorylated by an egg cortical tyrosine kinase in response to sperm or purified ligand (bindin) binding. Maximal phosphorylation was reached within 20 sec. These data support the hypothesis that the sperm receptor is a gamete recognition protein which responds to ligand binding and focus attention on the question of the role of this tyrosine phosphorylation signal in egg activation.

Receptor-mediated signal transduction and egg activation

Egg activation at fertilisation is composed of a complex, choreographed series of events, the initiation of which still is not understood. Two major hypotheses have emerged as explanations for the mechanism of egg activation (reviewed by Nuccitelli, 1991; Whitaker & Swann, 1993). The first holds that the sperm delivers an ‘activating factor’ (e.g. inositol trisphosphate, calcium, or a protein) that diffuses into the egg cytoplasm after gamete fusion. The second hypothesis holds that sperm bind to receptors spanning the egg plasma membrane which then transduce a signal to second messenger enzymes. We present here the evidence for receptor-mediated signal transduction in egg activation at fertilisation. By ‘receptor’ we mean only molecules that bind an extra-membrane ligand and which transduce a signal to molecules residing on the cytoplasmic side of the egg membrane. It is critical to be aware that several alternative activating mechanisms are not mutually exclusive and that species differences may exist. In fact, as more has been learnt about the molecules involved in gamete recognition and binding and of the signalling pathways in the egg, it seems likely that multiple pathways exist to trigger complete egg activation.

A putative ATP-activated Na+ channel involved in sperm-induced fertilization

Extracellular application of adenosine triphosphate (ATP) to defolliculated Xenopus laevis oocytes activated a saturating inward current with a maximal amplitude E(max) of 2.4 +/- 0.2 microamperes and an apparent Michaelis constant of 197.6 micromolar. The current was carried predominantly by sodium ions and potently inhibited by amiloride, guanosine triphosphate (GTP), and its nonhydrolyzable analogs guanosine 5'-[beta,gamma-imido]triphosphate (GppNHp) and guanosine 5'-O-(3-thiotriphosphate). Likewise, in vitro fertilization using mature eggs and Xenopus sperm was inhibited by amiloride, GTP, and GppNHp. Hence, an ATP receptor on the egg membrane may be the recipient target for ATP originating in sperm, suggesting that an ATP-induced increase in sodium permeability mediates the initial sperm to egg signal in the fertilization process.

The fertilization potential and associated membrane potential oscillations during the resumption of meiosis in the egg of the ascidian Phallusia mammillata

The fertilization potential in Phallusia mammillata consisted of an initial rapid depolarization. This initial sperm-triggered depolarization was followed by a phase of membrane depolarization which was of either long or short duration, depending on the eggs. When of long duration, the phase of membrane depolarization was divided into two periods: the first one began with a plateau (Em = +20.2 +/- 1.1 mV; duration = 1.7 +/- 0.14 min) which was followed by a series of membrane potential oscillations (n = 3.1 +/- 0.25) lasting 2.4 +/- 0.2 min. The second period also began as a plateau (Em = approximately 0 mV; duration = 3.40 +/- 0.20 min) which was followed by a series of oscillations (n = 11.5 +/- 0.5) lasting 11.8 +/- 0.6 min, followed by a membrane repolarization. The second series of oscillations often continued rising from the resting potential value. In the eggs displaying a short duration of membrane depolarization, the second period of depolarization was shortened (lasting only 3.5 +/- 0.5 min) since it lacked the second plateau. In addition it displayed a smaller number of oscillations (n = 4.7 +/- 0.6). As a consequence of this shortening, the membrane repolarized sooner. After repolarization, the membrane displayed several potential oscillations that started from the repolarization level. Regardless of the length of the depolarized plateau phases, the total number of membrane oscillations and the time period during which they occurred were constant. Eggs displaying a long depolarization phase had 15.9 +/- 0.6 oscillations in a 19.5 +/- 0.6 min interval, while eggs having a short depolarization phase had 16.0 +/- 0.8 oscillations in a 18.1 +/- 0.3 min interval. The time period during which the potential oscillations occurred corresponded remarkably well with the time of the meiotic divisions: the formation of the first polar body was detected about 80 sec after the end of the first series of oscillations; the second polar body was extruded about 85 sec after the last membrane oscillation occurred.

Fusion of membranes during fertilization. Increases of the sea urchin egg's membrane capacitance and membrane conductance at the site of contact with the sperm

The early events of fertilization that precede and cause activation of an egg have not been fully elucidated. The earliest electrophysiological change in the sea urchin egg is a sperm-evoked increase of the egg's membrane conductance. The resulting depolarization facilitates entry of the fertilizing sperm and precludes the entry of supernumerary sperm. The sequence of the increase in the egg's membrane conductance, gamete membrane fusion, egg activation, and sperm entry, including causal relationships between these events, are not known. This study reports the use of whole egg voltage clamp and loose patch clamp to monitor simultaneously changes of membrane conductance and capacitance at the site of sperm-egg contact. Measurements were made during sperm-egg interactions where sperm entry readily proceeded or was precluded by maintaining the egg's membrane potential either at large, negative values or at positive values. Whenever the sperm evoked an increase of the egg's membrane conductance, that increase initiated abruptly, was localized to the site of sperm attachment, and was accompanied by a simultaneous abrupt increase of the membrane capacitance. This increase of capacitance indicated the establishment of electrical continuity between gametes (possibly fusion of the gametes' plasma membranes). If sperm entry was blocked by large negative membrane potentials, the capacitance cut off rapidly and simultaneously with a decrease of the membrane conductance, indicating that electrical continuity between gametes was disrupted. When sperm entry was precluded by positive membrane potentials, neither conductance nor capacitance increased, indicating that sperm entry was halted before the fusion of membranes. A second, smooth increase of capacitance was associated with the exocytosis of cortical granules near the sperm in eggs that were activated. Electrical continuity between the gametes always preceded activation of the egg, but transient electrical continuity between the gametes alone was not always sufficient to induce activation.

Endogenous angiotensin II receptors in Xenopus oocytes and eggs

Angiotensin II (AII) induced strongly desensitizing oscillatory Cl- inward currents in both follicle-enclosed and collagenase-treated Xenopus oocytes. The AII response was abolished by EGTA and attenuated by pertussis toxin. Treatment of oocytes with collagenase transiently reduced both the ratio of oocytes responsive to AII and the amplitude of AII responses, followed by restoration to original levels in 3-4 days. The response to adrenaline, which is mediated by endogenous beta-adrenoceptors in follicle cells, however, was irreversibly abolished by collagenase treatment. These results suggest that endogenous current-mediating AII receptors in oocytes are coupled with phosphatidylinositol hydrolysis and localized in the oocyte or in a cellular structure distinct from that for endogenous beta-adrenoceptors. Progesterone-matured Xenopus eggs also responded to AII, and this AII-induced depolarization resembled the fertilization potential in the eggs, suggesting a possible role of AII receptors in processes of fertilization or growth of the eggs.

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.

High concentration of inositol 1,4,5-trisphosphate in sea urchin sperm

We measured inositol 1,4,5-trisphosphate (InsP3) content of sea urchin gametes by using a specific protein binding assay, and found that a spermatozoon contains 4 x 10(-19) to 1 x 10(-18) moles of InsP3 before the acrosome reaction. Since the acrosome reaction has previously been shown to increase the InsP3 content of sperm severalfold, our measurement indicates that a spermatozoon contains at least 2 x 10(-18) moles of InsP3 at fertilization, corresponding to a concentration in the spermatozoon of about 1 mM. The threshold for activation of eggs by injection of InsP3 dissolved in a much larger volume of solution has been found to be about 3 x 10(-18) moles, corresponding to a concentration in the injectate of 1 microM. This suggests that sea urchin sperm may contain enough InsP3 to activate eggs. With an electroporation method, we also showed that sperm extract acts on eggs only from inside, consistent with a primary messenger role for InsP3.

Activation of mammalian oocytes by a factor obtained from rabbit sperm

In this study a fraction was prepared from rabbit sperm that activated rabbit and mouse oocytes following injection into the cytoplasm. The sperm factor activated oocytes exhibited cortical granule exocytosis, pronuclear formation, and cleavage. The sperm factor was soluble in aqueous solution and was not active extracellularly. Unlike most artificial activation methods that are only effective with aged oocytes, the sperm factor activated recently ovulated oocytes. The factor appears to be a protein or associated with a protein but not an acrosomal protein. Fractions from both mouse and bull sperm did not activate rabbit or mouse oocytes. Their inactivity may be owing to the techniques used to recover the fractions or differences between species in sperm morphology and fertilization processes. These observations support the hypothesis that oocyte activation is induced by a factor within sperm that is released into the cytoplasm of the oocyte at the time of sperm-oocyte fusion.

Voltage clamp studies of fertilization in sea urchin eggs. II. Current patterns in relation to sperm entry, nonentry, and activation

Following attachment of a sperm to the surface of a sea urchin egg clamped at a membrane potential (Vm) more positive than +17 mV, no changes in membrane conductance can be detected, the sperm does not enter egg, and no morphological changes can be detected. At Vm from +17 to -100 mV three characteristically different types of current profiles are observed: Type I are activation currents in eggs penetrated by a sperm. These have three phases, which occur in all eggs clamped at Vm from +17 to -20 mV and in decreasing percentages at clamped Vm more negative than -20 mV (to -75 mV). Complete fertilization envelopes are elevated, relatively large mound-shaped fertilization cones form, and the eggs develop to normal embryos. Type II are sperm transient currents in eggs not penetrated by a sperm, the eggs otherwise remaining in the unfertilized state. These transients are simpler and shorter than type I currents, and are observed only at clamped Vm more negative than -20 mV. Type III are modified activation currents in eggs not penetrated by a sperm. These have three phases, are observed only at clamped Vm more negative than -20 mV, and are the only type of activation current seen at clamped Vm more negative than -75 mV. Complete fertilization envelopes are elevated, the fertilization cones are small and filament-like, and the eggs fail to cleave. We conclude that (a) the sperm transient currents (type II) and phase 1 of the activation currents (type I and III) are similar events generated by a sperm-initiated localized conductance increase, (b) the abrupt decrease of current which terminates the sperm transients and phase 1 of type III currents results from a turnoff of the sperm-induced conductance increase and signals that the sperm will not enter the egg, and (c) the occurrence of phase 2 during an electrophysiological response induced by a sperm indicates that the egg is activating.

Fertilization events induced by neurotransmitters after injection of mRNA in Xenopus eggs

Fertilization initiates in the egg a dramatic increase in intracellular calcium that opens ion channels and causes exocytosis. To explore the possibility that these events might involve a receptor-mediated pathway, receptors for serotonin or acetylcholine (M1 muscarinic) were expressed in the Xenopus egg; serotonin or acetylcholine then could initiate a series of responses similar to those normally initiated by sperm. Thus, there may be an endogenous receptor in the egg membrane that is activated by sperm, and the serotonin or M1 muscarinic receptor may replace the sperm receptor in this pathway.

Dynamic changes in plasma membrane properties of Semliki Forest virus infected cells related to cell fusion

The mechanism of the processes leading to membrane fusion is as yet unknown. In this report we demonstrate that changes in membrane potential and potassium fluxes correlate with Semliki Forest virus induced cell-cell fusion at mildly acidic pH. The changes observed occur only at pH's below 6.2 corresponding to values required to trigger the fusion process. A possible role of these alterations of the plasma membrane related to membrane fusion phenomena is discussed.

Isolation and partial characterization of an ion channel protein from human sperm membranes

Human sperm cells were fractionated and plasma membrane proteins were separated by molecular gel sieving chromatography (Sephacryl S-200 followed by HPLC). A pore-forming protein was extracted from sperm cell membranes. The partially purified protein migrated with Mr 100,000-110,000, as determined by molecular sieving gel chromatography, and with a Mr 90,000 when analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis under reducing conditions. The channel activity was also extracted with Triton X-114, suggesting a hydrophobic nature for this protein. This protein was incorporated into planar lipid bilayers, resulting in the formation of voltage-dependent ion channels. Single channel fluctuations of 130 pS/unit in 0.1 M NaCl were resolved; however, channels preferentially aggregated in triplets having an open state life-time that persisted for several seconds. The channels studied here were more selective for monovalent cations than anions, but also showed some permeability to anions and larger electrolytes, suggesting a large functional pore diameter. The role of this sperm channel in normal sperm physiology and/or fertilization is presently unclear.

Increase in intracellular calcium induced by the polycation-coated latex bead, a stimulus that causes postsynaptic-type differentiation in cultured Xenopus muscle cells

The polycation-coated latex bead is a potent stimulus for the induction of postsynaptic-type differentiation in cultured Xenopus myotomal muscle cells. Specializations characteristic of the neuromuscular junction, such as clusters of acetylcholine receptors and other postsynaptic-specific proteins, develop at the bead-muscle contact. Previous studies have shown that a deprivation of extracellular calcium inhibits the effect of the beads in causing the development of these specializations. This suggests that an increase in intracellular Ca2+ is a necessary condition for the development of this specialization. In this study, we tested whether an increase in intracellular calcium is observable upon the bead-muscle contact. The measurement was carried out on cells loaded with the fluorescent calcium indicator fura-2 AM by digitized video microscopy. When polycation-coated beads were added to cells, an increase in intracellular calcium concentration in the range of 5 to 57% of the resting level was observed within 10 sec after bead-muscle contact. Afterward, the calcium level gradually returned to the resting level with a time course of about 3 min. Uncoated beads, which do not induce the formation of acetylcholine receptor clustering, failed to elicit this calcium transient. Removal of extracellular calcium as well as blocking calcium channels with 50 microM verapamil also suppressed this transient induced by the polycation-coated beads. Both treatments are known to suppress the formation of receptor clusters by these beads. These results suggest that the polycation-coated beads cause an influx of calcium by increasing the membrane conductance to this ion. This process may underlie the signaling of the postsynaptic differentiation.