‘Endogenous yolk’ as the precursor of a possible fertilization envelope in a crab (Carcinus maenas)

After the egg attachment to a maternal ovigerous seta, the Carcinus maenas embryo is enclosed in a tripartite capsule. The innermost layer (envelope 2) which is also the main part of this capsule, is generally detected after egg-laying and is most probably closely related to the fecondation phenomenon. The precursor material of envelope 2, arising from the egg by a massive and very fast exocytosis process, appears as numerous ring-shaped granules. These granules, originated from numerous cortical vesicles perhaps intercommunicating with each others, are observed early in the ooplasm during oogenesis, These so-called ring-shaped granules seem very identical in form with the disc-shaped granules which are classically described as composing the endogenous or intracysternal yolk of many Decapoda crustacean oocytes. In view of our results the role of these granules, in endogenous yolk formation, is re-examined and discussed.     

Structure of the egg funiculus and deposition of embryonic envelopes in a crab

The newly laid egg of Carcinus maenas is attached to a maternal ovigerous seta by a funiculus which consists of the two superimposed vitelline envelopes 1a + 1b, highly stretched and concurrently showing important structural alterations. The funiculus is glued to the specialized seta merely owing to the strong adhesiveness of its external face comprising the outermost vitelline envelope 1a, without any added adhesive. The subjacent envelope 2, originated from the cortical reaction, is not involved in such a funiculus elaboration. In the course of the embryonic development, four new coatings are successively secreted from the ectodermal embryonic cells, underneath the (1a + 1b + 2) fertilization envelope or embryonic capsule. They will remain until hatching in this concentric order, thus giving evidence of successive embryonic moulting cycles, with apolysis but without exuviation. In addition, the successive secretory phases, regarding to the embryonic envelope elaborations, happen in presence of high concentrations of the ecdysteroid ponasterone A which might be involved consequently in such secretory processes.     

Fertilization in a crab: I. Early events in the ovary,and cytological aspects of the acrosome reaction and gamete contacts

Early events in fertilization were studied in Carcinus maenas by in vitro experiments and ultrastructural analysis; some were found to occur in the lumen of ripe ovaries. The acrosome reaction generally conformed to the usual Reptantia Decapoda pattern. However, a prominent membrane system continuous with the nuclear envelope and located close to the base of the acrosome tubule characterized the type of spermatozoon observed in Carcinus maenas. Such complex anatomical connections linking the three parts of the reacted spermatozoon (acrosome tubule, membrane system and nucleus envelope) may be significant in relation to the membrane system's contribution to the acrosome reaction. The outer layer of the everted acrosomal vesicle was found to comprise tubular elements ending in bell-shaped corpuscles, deeply interdigitated with the oolemma microvilli during the establishment of the initial contacts between the reacted spermatozoon and the egg plasma membrane. At the site of contact, the oolemma formed a minute fertilization cone, locally depressed by the acrosome tubule. During these early fertilization events, the nucleus, like the other spermatozoon components, was seen to penetrate the egg coatings first, and later to be located near the oolemma.     

Fine structure and secretion of the capsule enclosing the embryo in a crab (Carcinus maenas (L.))

Carcinus maenas oocyte is encased, at the end of viteilogenesis phase, by two superposed vitelline envelopes. If the outermost (envelope la) is relatively thin, the innermost (envelope 1b) is however five times much thicker. The envelope 1b, secreted mostly by the oocyte, contains proteinaceous material and a substance which strongly binds WGA. The 1b material deposition is completed when the oocyte nuclear apparatus still has the characteristics of a germinal vesicle. After the secretion phase and always at the ovarian level, envelope 1b material undergoes remarkable structural modifications. These last events occur while the oocyte nuclear apparatus is in the first meiotic metaphase stage. Later, after egg-laying, a new material appears below the two superimposed vitelline envelopes 1a and 1b. This new innermost material (envelope 2), observed as a very thick and homogeneous secretion, is secreted by the newly laid egg probably after fecondation. Envelope 2 material is wholly deposited in few hours and arises from vesicles of an oocytic origin. These three superimposed envelopes make up the embryo capsule of which the main part is constituted by envelope 2. This tripartite capsule will stay, surrounding the developmental stages, superimposed to newly secreted successive embryonic envelopes, up to the end of embryogenesis.     

Fertilization in a Crab. III. Cytodifferentiation of vesicles enclosing ring-shaped elements involved in the cortical reaction

During the cortical reaction, Carcinus maenas eggs successively released a fine granular material and a massive amount of ring-shaped elements that subsequently formed most of the fertilization envelope. The ring-shaped elements came from egg cortical vesicles and, owing to their striking morphology, acted as naturally occurring markers in ultrathin sections, which permitted us to understand the pathway of their intracellular transport. In this respect it was established that the ring-shaped elements and their enclosing vesicles originated in the endoplasmic reticulum both in ripe oocytes and early fertilized eggs maintained under in vitro conditions. The intracellular transport pathway of the endoplasmic reticulum-derived vesicles seemed to bypass the Golgi apparatus. Accordingly, the ring-shaped elements appeared to be released by direct exocytosis from the endoplasmic reticulum system. Finally, a tentative scheme of oocytes functioning is suggested for crustacean decapods, based on the remarkable similarities between the structure and ER origin of the ring-shaped elements involved in the cortical reaction and the disc-shaped granules traditionally considered as endogenous yolk precursors. The scheme implies that the oocyte ER system might produce a precursor common to the cortical reaction exudate and to the endogenous yolk, in the form of the ring- or disc-shaped elements.     

Sea urchin embryo fertilization envelope: immunological evidence that soluble envelope proteins are derived from cortical granule secretions

Although structural studies support the hypothesis that the sea urchin embryo fertilization envelope is derived from the preexisting vitelline envelope template and structural proteins secreted during the cortical reaction, biochemical evidence is minimal. We used an immunological approach to determine the subcellular origin of proteins which were extracted from the fertilization envelope. Fertilization envelopes were isolated from Stronglyocentrotus purpuratus embryos 30 min postinsemination and extracted with 6.0 M urea-0.15 M 2-mercaptoethanol, pH 10.5, for 10 min at 80°C. Extracted proteins were exhaustively dialyzed against 0.015 M 2-mercaptoethanol-0.100 M Tris-HCl at pH 8.6 and mixed with Fruend's complete adjuvant prior to injection into female New Zealand white rabbits. The antiserum which was prepared contained antibodies to six major and two minor polypeptides in the soluble fertilization envelope fraction based on two-dimensional sodium dodecyl sulfate immunoelectrophoresis. Extracts of vitelline envelopes and extracts of unfertilized egg surfaces which are known to contain viteline envelope proteins did not form immunoprecipitates with antiserum against soluble fertilization envelope polypeptides. Extracts of isolated cortical granules and the secreted paracystalline protein fraction formed four and three immunoprecipitates, respectively, which showed complete identity with the soluble fertilization envelope polypeptides based on rocket-line immunoelectrophoresis. Two-dimensional sodium dodecyl sulfate immunoelectrophoresis of cortical granule extract and the secreted paracrystalline protein fraction showed a complex pattern of immunoprecipitates, but a major finding was that cortical granules contain a 193,000-dalton polypeptide which was not found in the paracrystalline protein fraction. These results suggest that proteolytic processing of a cortical granule precursor of the paracrystalline protein fraction occurs during fertilization and that not all of the cortical granule polypeptides are incorporated into the fertilization envelope by means of di- and trityrosine crosslinks with the vitelline envelope proteins.     

Electron microscopic study of the cortical reaction of an ophiuroid echinoderm.

The egg coats of an ophiuroid echinoderm (Ophiopholis aculeata) are described by electron microscopy before and after fertilization. The unfertilized egg is closely invested by a vitelline coat about 40 A thick, and the peripheral cytoplasm is crowded with cortical granules five or six deep. During the cortical reaction, which rapidly follows insemination, exocytosis of cortical granules takes place. Some of the cortical granule material is evidently added to the vitelline coat to form a composite structure, the fertilization envelope, which is made up of a 400 A thick middle layer separating inner and outer dense layers, each about 50 A thick. The elevation of the fertilization envelope from the egg surface creates a perivitelline space in which the hyaline layer soon forms. The hyaline layer is about 2 micron thick, finely granular, and apparently derived from cortical granule material. The extracellular layers of the early developmental stages of ophiuroids and echinoids are quite similar in comparison to those of asteroids; this finding helps support Hyman's argument that the ophiuroids are more closely related to the echinoids than to the asteroids.     

Binding of antibiotics to glycoproteins of the vitelline and fertilization envelopes of cherry salmon eggs

The binding of antibiotics (gentamicin, oleandomycin and chloramphenicol) to vitelline and fertilization envelopes and their extracts was investigated by immunohistochemical and immunocytochemical techniques and immunoblot analysis using mature and artificially activated eggs of the fish Oncorhynchus masou. Binding of antibiotics was detected in the vitelline and fertilization envelope outermost layers, the fertilization envelope inner surface and cortical alveolus exudates, with differences in immunoreactive intensity and deposition. The fertilization envelope outermost layer had the capacity to bind much greater amounts of the antibiotics than the vitelline envelope outermost layer. The greater capacity was caused by the deposition of cortical alveolus exudates, which were known to be responsible for functional roles of protection against bacteria, fungi and noxious materials. Treatment of the vitelline and fertilization envelopes with neuraminidase markedly reduced the binding of gentamicin and chloramphenicol but slightly increased that of oleandomycin; binding of the latter to the vitelline and fertilization envelope outermost layers was considerably reduced after treatment with alpha-fucosidase. Treatment of the two envelopes with alpha-mannosidase, beta-galactosidase or beta-SdD-glucosaminidase did not cause any alteration in immunoreactive intensity or number of immunoreactive deposits. Immunoblot analysis of the vitelline or fertilization envelope extracts indicated that many of the antibiotic-binding substances were glycoproteins, and several major bands were bound by all three antibiotics. These results suggest that the vitelline or fertilization envelopes may have the ability to protect the egg itself, or the embryo, respectively, by trapping antibiotics, and the trapping may be related to the presence of carbohydrate moieties, such as sialyl or fucosyl residues. This revised version was published online in November 2006 with corrections to the Cover Date.     

Fertilization in a chiton: Acrosome-mediated sperm-egg fusion

Contrary to the widely accepted view that chiton sperm lack acrosomes and that fertilization in this group occurs via a micropyle, we demonstrate here that fertilization in Tonicella lineata occurs by acrosome-mediated sperm-egg fusion. The acrosome is a small vesicle containing two granules located at the tip of the sperm. The eggs have an elaborate hull (=chorion), which is formed into cupules that remain covered by follicle cells until maturity. When dissected ripe eggs were exposed to sperm in vitro, the sperm were attracted only to open cupules, inside which they swam through one of seven channels to the base where they penetrated the hull. The acrosome fired on contact with, or in, the hull, and during passage through it the apical granule was exhausted while the basal granule was exposed. If sperm contacted follicle cells between the cupules the acrosome did not react. The vitelline layer beneath the hull contains pores arranged in a regular pattern. Embedded in the base of each pore is an egg microvillus. Having penetrated the hull the sperm anterior filament located a pore and fused with the tip of the egg microvillus projecting into it. This created a membranous tube, through which the sperm nucleus was injected into the egg. The egg membrane appeared to be raised up into a small fertilization cone around the penetrating sperm, the vitelline layer became slightly elevated, and some cortical granules were released by exocytosis.     

Behaviour of the vitelline envelope in Bufo arenarum oocytes matured in vitro in blockade to polyspermy

During activation of amphibian eggs, cortical granule exocytosis causes elaborate ultrastructural changes in the vitelline envelope. These changes involve modifications in the structure of the vitelline envelope and formation of a fertilization envelope (FE) that can no longer be penetrated by sperm. In Bufo arenarum, as the egg traverses the oviduct, the vitelline envelope is altered by a trypsin-like protease secreted by the oviduct, which induces an increased susceptibility of the vitelline envelope to sperm lysins. Full-grown oocytes of B. arenarum, matured in vitro by progesterone, are polyspermic, although cortical granule exocytosis seems to occur within a normal chronological sequence. These oocytes can be fertilized with or without trypsin treatment, suggesting that the vitelline envelope is totally sperm-permeable. Vitelline envelopes without trypsin treatment cannot retain either gp90 or gp96. This suggests that these glycoproteins are involved in the block to polyspermy and that trypsin treatment of matured in vitro oocytes before insemination is necessary to enable vitelline envelopes to block polyspermy. The loss of the binding capacity in vitelline envelopes isolated from B. arenarum oocytes matured in vitro with trypsin treatment and activated by electric shock suggests that previous trypsin treatment is a necessary step for sperm block to occur. When in vitro matured oocytes were incubated with the product of cortical granules obtained from in vitro matured oocytes (vCGP), vitelline envelopes with trypsin treatment were able to block sperm entry. These oocytes exhibited the characteristic signs of activation. These results support the idea that B. arenarum oocytes can be activated by external stimuli and suggest the presence of unknown oocyte surface receptors linked to the activation machinery in response to fertilization. Electrophoretic profiles obtained by SDS-PAGE of solubilized vitelline envelopes from oocytes matured in vitro revealed the conversion of gp40 (in vitro matured oocytes, without trypsin treatment) to gp38 (ascribable to trypsin activity or cortical granule product activity, CGP) and the conversion of gp70 to gp68 (ascribable to trypsin activity plus CGP activity). Taking into account that only the vitelline envelopes of in vitro matured oocytes with trypsin treatment and activated can block sperm entry, we may suggest that the conversion of gp70 to gp68 is related to the changes associated with sperm binding.     

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

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

On the contents of the cortical granules from Xenopus laevis eggs

The extruded contents of the cortical granules in eggs of Xenopus laevis were solubilized by exposure to divalent metal ion chelators. Chelator extraction of cortical granule (CG) material from intact fertilized or artificially activated eggs was quantitated by fluorescence spectroscopy. The isolated fertilization envelope, formed upon interaction between CG material and the preexisting vitelline envelope, was also subject to extraction. An ultrastructural analysis revealed that chelator exposure resulted in the disruption of the structural integrity of the CG-derived F-component of the fertilization envelope. CG material was isolated from Xenopus ova by three procedures: (1) extrusion from artificially activated, dejellied eggs; (2) extraction of intact, fertilized eggs; and (3) extraction of isolated fertilization envelopes. Only 4–5% of the CG protein recovered by extrusion or by extraction of the intact fertilized egg could be associated with the isolated fertilization envelopes. One predominant polypeptide fraction with an identical relative mobility was demonstrated in all CG preparations upon polyacrylamide gel electrophoresis in SDS. Polymeric forms of CG protein were detected in chelator extracted preparations. The presence of an intact jelly coat during CG breakdown was a prerequisite to the transformation of the vitelline envelope to a fertilization envelope with altered physicochemical characteristics. Further, the CG-derived F-component of the fertilization envelope did not appear to play a critical role in determining the physicochemical properties of the fertilization envelope.     

Formation and structure of the fertilization envelope in Xenopus laevis

This paper reports the morphological events that occur when the vitelline envelope (VE) of an unfertilized egg of Xenopus laevis is transformed into the fertilization envelope (FE) surrounding the zygote. The VE is about 1 μm thick and is composed of an interlacing network of small filaments. The FE is constructed from the VE plus an electron-dense layer (fertilization layer), about 2–6 μm thick, on the outer surface of the VE, i.e., at the interface between the VE and the innermost jelly-coat layer. The fertilization layer is a stable component of the FE and is not removed by mercaptan solutions used to dejelly eggs. The events of FE formation were observed in the light and electron microscopes after dejellied eggs were activated by pricking. The FE is established when material from the cortical granules is extruded into the perivitelline space. The cortical granule material passes through the VE as the envelope lifts away from the egg surface. Some cortical granule material deposits in the interstices of the VE, but most of it forms the fertilization layer on the outer surface of the envelope. The cortical reaction is completed about 8–9 min after addition of sperm when eggs are fertilized in vitro.     

Fertilization in Oikopleura dioica (Tunicata,Appendicularia): Acrosome reaction,cortical reaction and sperm-egg fusion

Summary Fine structural changes in the egg and sperm are described during gamete interaction in Oikopleura dioica, an appendicularian tunicate. The unfertilized egg has a vitelline layer 80 nm thick and a perivitelline space about 5 m wide. In the peripheral cytoplasm are a few cortical granules 0.6×0.7 m in diameter and areas rich in parallel cisternae of rough endoplasmic reticulum alternating with areas rich in long mitochondria. In the deeper cytoplasm the predominant organelles are multivesicular bodies. From 25 s to 60 s after insemination, the egg transiently elongates, although with no obvious cytoplasmic rearrangement, and the egg surface becomes bumpy. During this interval sperm enter the egg, and the cortical granules undergo exocytosis. After expulsion into the perivitelline space, the cortical granule contents do not appear to change their shape or blend with the vitelline layer, which neither elevates further nor loses its ability to bind sperm. On encountering the egg, the sperm undergoes an acrosome reaction involving exocytosis of the acrosome and production of an acrosomal tubule. The acrosomal contents bind the sperm to the vitelline layer, and the posterior portion of the acrosomal membrane and the anterior portion of the nuclear envelope evaginate together to form an acrosomal tubule, which fuses with the egg plasma membrane to form a fertilization cone. By 45 s after insemination, the sperm nucleus, centriole, mitochondrion and at least the anterior portion of the axoneme are within the fertilization cone. By 60 s sperm entry is complete. In having eggs with a cortical reaction and sperm with an acrosome reaction, O. dioica resembles echinoderms and enteropneusts and differs markedly from ascidian tunicates, which lack both these features. The relatively unmodified pattern of gamete interaction in O. dioica in comparison with the highly modified pattern in ascidians is difficult to reconcile with the neoteny theory that appendicularians have evolved via ascidian ancestors. The present results are more consistent with the idea that an appendicularian-like ancestor gave rise to ascidians.     

Isolation and biological activity of the proteases released by sea urchin eggs following fertilization.

The protease activity released from sea urchin egg cortical granules into the surrounding seawater at fertilization is involved in vitelline layer elevation and the block to polyspermy. The cortical granule protease components were isolated by isoelectric precipitation and affinity chromatography on p-aminobenzamidine-Sepharose columns. Elution profiles from affinity columns suggested heterogeneity of the proteases, and polyacrylamide-gel electrofocusing of affinity-purified preparations established the presence of two proteins. Dramatically different biological activities were resolved by affinity chromatography. Early-eluting fractions of low specific activity delaminated the vitelline layer from the egg plasma membrane; this activity is termed vitelline delaminase. Late-eluting fractions of high specific activity modified the egg vitelline layer surface such that sperm could not bind or fertilize them; this activity is referred to as sperm receptor hydrolase. The biological activities of the sea urchin proteases are apparently the result of limited action on the vitelline layer, unlike bovine trypsin which simply digests the vitelline layer. The cortical granule proteases lost biological specificity when stored at 0°C at pH 8.0. Esterase activity increased, and the preparation acquired the ability to digest the vitelline layer. Increase of the esterase activity in protease preparations was prevented by storage at low pH.The molecular weight of both enzymes was estimated by sucrose gradient centrifugation to be 47,000, whereas multiple components with molecular weights between 10⁵ and 10⁶ were demonstrated by gel filtration.     

Members of the SNARE hypothesis are associated with cortical granule exocytosis in the sea urchin egg

Cortical granule exocytosis is important for the block to polyspermy at fertilization in the eggs of most vertebrates and many invertebrates. Cortical granules are poised at the cell surface and exocytose in response to sperm stimulation. Following exocytosis, the cortical granule contents modify the extracellular environment of the egg, the major result of which is to block additional sperm binding. Here we show that proteins homologous to members of the SNARE hypothesis—a molecular model designed to explain the trafficking, docking, and exocytosis of vesicles in the secretory compartment—are present in eggs at the right time and place to be involved in the regulation of cortical granule exocytosis. Using polymerase chain reaction (PCR) screens we have found homologues of synaptobrevin/VAMP, syntaxin, synaptotagmin, and rab3. Antibodies generated to fusion proteins or to synthetic peptides encoded by the cloned cDNAs were used in an immunofluorescence assay to show that each of the cognate proteins are present in the cortex of the egg. A synaptobrevin/VAMP homologue appears to be specifically associated with the membrane of cortical granules before fertilization and, following cortical granule exocytosis, is incorporated into the plasma membrane of the zygote. A rab3 homologue is also associated with cortical granules specifically but, following fertilization, the protein reassociates with different, yet undefined, vesicles throughout the cytoplasm of the zygote. Homologues of synaptotagmin and syntaxin are also present at the egg cortex but, in contrast to rab3 and VAMP, appear to be associated with the plasma membrane. Following fertilization, syntaxin and tagmin remain associated with the plasma membrane and are more readily immunolabeled, presumably due to an increased accessibility of the antibodies to the target protein domains. We also show by immunoblotting experiments that the cognate proteins are of the sizes predicted for these homologues. These results suggest that at least some steps in the biology of cortical granules may be mediated by SNARE homologues, and this finding, along with the unique biology of cortical granules, should facilitate examination of specific events of the fertilization reaction and the mechanism of stimulus-dependent exocytosis. Mol. Reprod. Dev. 48:106–118, 1997. © 1997 Wiley-Liss, Inc.     

Hatching envelope formation in shrimp (Sicyonia ingentis) ova: Origin and sequential exocytosis of cortical vesicles

The ova of Sicyonia ingentis lack cortical vesicles at the time of spawning. Within 30 min post-spawning, two populations of cortical vesicles are organized in the ooplasm which, during cortical vesicle exocytosis (cortical reaction), successively release two morphologically different exudates. The first type of cortical vesicles (dense vesicles) appears to be derived from the Golgi complexes after spawning. The second type (the ring vesicles) is formed by the fusion of asternal elements which contain loosely packed ring-shaped structures that are present in the unactivated ova. During exocytosis of the dense vesicles an electron dense material is released which coalesces with the surface coat of the ovum to form a thin hatching envelope which eventually lifts from the ovum's surface. Subsequent to the formation of the thin hatching envelope, the ring vesicles undergo exocytosis resulting in an accumulation of ring-shaped structures in the perivitelline space. These structures coalesce and form an electron translucent layer on the inner surface of the thin elevated envelope to form the thickened hatching envelope. The formation of the cortical vesicles, their exocytosis and the elaboration of the hatching envelope are normally completed within 40-45 min after spawning.     

Electron Microscopic Observations on the Cortical Reaction of the Brittle-Star Amphipholis kochii Lütken, with Special Reference to its Vitelline Coat Modification as Revealed by the Surface Replica Method

This paper describes the fine structural changes of the egg of the brittle-star Amphipholis kochii Lütken during the cortical reaction. The vitelline coat is 20 nm thick, when Ruthenium Red stain is used, and consists of a dense network of fibers. The cortical granules are large, 1.5–2.0 μm in diameter, and exist in several layers in the egg cortex, unlike the monolayer arrangement found in many other animals. The contents of the cortical granules are clearly distinguished into two components: peripheral fibrous (PF) material and central fibrous (CF) material that consists of two components differing in electron density. The PF material is densely stained by periodic acid-chromic acid-silver methenamine stain, while the CF material is stained little if at all by this technique. The vitelline coat and some PF materials form the fertilization membrane, which is about 40 nm thick and consists of three layers; the outer and the inner layer of the fertilization membrane each have a trilaminated structure. The vitelline coat substances are probably located in the upper part of the fertilization membrane. The hyaline layer, 7–8 μm thick, consists mainly of CF materials. These observations on the morphology of the ophiuroid egg are discussed in comparison with those on other echinoderms, especially echinoids and asteroids.     

Induction of calcium-dependent, localized cortical granule breakdown in sea-urchin eggs by voltage pulsation

A technique that employs a high-voltage pulses to produce pores in cell membranes (Kinosita and Tsong (1977) Proc. Natl. Acad. Sci. U.S.A. 74, 1923) has been used to investigate the role of Ca²⁺ in the early events of activation of sea-urchin eggs. Exposure of eggs to a voltage pulse of 1 kV/cm for 100 μs resulted in localized exocytosis of the contents of cortical granules and development of a partial fertilization envelope. This effect was triggered by entrance of Ca²⁺ through the voltage-induced pores. In a medium containing 100 μM Ca²⁺ and ⁴⁵Ca²⁺ tracer, the voltage-treated eggs admitted 3.6±0.3 fmol Ca²⁺/egg within a few seconds. Untreated eggs took up only 1.0±0.2 fmol/egg after minutes of incubation. Furthermore, depletion of Ca²⁺ or the presence of EGTA in the external medium prevented elevation of the fertilization envelope by the voltage pulsation. Delay in Ca²⁺ addition after the voltage pulsation reduced the fraction of eggs that developed partial fertilization envelope. Loss of essential cytoplasmic components during the delay period is judged unlikely, since these eggs were viable, could form partial fertilization envelopes if re-pulsed in the presence of Ca²⁺, and could develop to normal blastula stage embryos upon fertilization with sperm. Thus, we interpret this effect as due to a resealing of pores; the half-life of pores being 20 s. The elevation of partial fertilization envelopes occured only at the loci facing the anode, and multiple pulses with mixing resulted in the formation of multiple fertilization envelopes. These envelopes were stable for up to several hours; further propagation (wave spreading) was not observed. The above results indicate that a primary reaction in the sequence of steps in fertilization envelope formation involves Ca²⁺ to trigger cortical granule breakdown and formation of the fertilization envelope.     

THE SURFACE EVENTS AT FERTILIZATION OF THE SEA URCHIN EGG I. EVENTS ON THE SURFACE OF THE VITELLINE COAT1

Sperm-egg interaction during normal fertilization in the sea urchins, Strongylocentrotus intermedius and Hemicentrotus pulcherrimus, was studied by scanning and transmission electron microscopy. Several seconds after insemination, acrosome-reacted spermatozoa were found attached to the surface of the vitelline coat on each egg. Soon, several bulges of the vitelline coat appeared surrounding the fertilizing spermatozoon. These bulges then spread over the surface increasing in number, while they became fewer and disappeared around the sperm head. Thin sections of the bulging areas revealed discharging cortical granules. As the bulging vitelline coat was elevated, the sperm head was incorporated into the perivitelline space, passing through a small hole in the coat that resulted from penetration of the sperm acrosomal process immediately before fusion of the gametes. When the spermatozoon disappeared beneath the fertilization membrane, a hole was left in the membrane and the cortical reaction had finished on the other hemispheric surface. Mechanical removal of the membrane at that time exposed a spermatozoon protruding perpendicularly from the egg plasma membrane surface. The anterior tip of the sperm head was smoothly connected with the egg surface, and neither microvillous projections nor cytoplasmic covering of the egg cytoplasm could be found around the spermatozoon.