Changes in chorion proteins induced by the exudate released from the egg cortex at the time of fertilization in the teleost, Oryzias latipes

The chorion of unfertilized medaka Oryzias latipes eggs consists of two major proteins (77–73 and 49 kDa) and a minor 150 kDa protein. Upon fertilization, these major chorion proteins are polymerized to insoluble high molecular weight proteins via the temporary formation of several new proteins (132, 114, 62 and 61 kDa). Increasing chorion toughness is closely related to the formation of high molecular weight proteins and the increasing insolubility of the chorion proteins. The changes in chorion proteins and hardening could be induced in vitro in isolated chorions by an egg exudate, which includes cortical alveolar contents. The effects of temperature and pH on the egg exudate-induced changes in chorion proteins were examined in the present study. The major proteins could be digested by proteolytic enzymes. The 49 kDa protein was PAS-positive. Analysis with polyclonal antibodies against the major proteins demonstrated that the temporarily formed 62 and 61 kDa proteins were derived from the 77–73 kDa protein and that higher molecular weight proteins, newly formed in the process of chorion hardening, contained the same epitopes as did the 77–73 and 49 kDa proteins. The results suggest that the changes in chorion proteins of the medaka egg at the time of fertilization can be induced by an enzyme(s) released from the egg cortex into the perivitelline space.     

Disappearance of cortical granules in rat ovum in vivo following fertilization

Electron microscopical studies of the rat ova were carried out to clarify the pattern of disappearance of cortical granules following fertilization. When the posterior cap of the head of a spermatozoon was attahced to the vitelline membrane, cortical granules located beneath this membrane fused with this membrane to be decomposed or broken. Then their contents were discharged into the perivitelline space. The disappearance of cortical granules seemed to have started in an area around the site of the vitelline membrane to which spermatozoon was attached and spread soon all over the vitellus.     

Ultrastructural changes during nuclear maturation in Bufo arenarum oocytes.

During progesterone-induced nuclear maturation the oocytes of Bufo arenarum undergo a series of nuclear and cytoplasmic changes. The breakdown of heterocellular communications between the follicular cell projections and the oocyte microvilli, and the consequent enlargement of the perivitelline space, were observed at the animal pole. The more evident cytoplasmic feature during nuclear maturation comprised the gathering of glycogen granules in clusters, some phagocytosed by empty vesicles. With respect to the location of these vesicles, some were observed in close proximity to the oolemma and others were freely suspended in the perivitelline space, extruded from the oocyte. Other visible events were the disruption of the annulate lamellae, the formation of an elaborate cortical endoplasmic reticulum and the rearrangement of the cortical granules in a monolayer immediately beneath the oolemma together with aggregates of endoplasmic reticulum cisternae. Our results show that during nuclear maturation the nuclear oocyte changes include a flattening of the spherical oocyte nucleus, its migration towards the surface of the animal pole, the disappearance of the nucleoli and the dissolution of the nuclear envelope.     

The swelling egg of the long rough dab, Hippoglossoides platessoides limandoides (Bloch)

The egg of Hippoglossoides platessoides limandoides swells when released into sea water. The swelling takes place entirely outside the ovoplasm and creates a large perivitelline space which can make up 85% of the total egg volume. Swelling occurs in both unfertilized and fertilized eggs although a small proportion of unfertilized eggs, believed not to have been activated, do not swell. Swelling is dependent upon the breakdown of cortical alveoli, together with an unusually soft and elastic chorion. The cortical alveoli, present in greater numbers than is usual in teleost eggs, release colloidal material when they break down on egg activation; adsorption of water by this material is responsible for the egg volume increase.     

FORMATION OF THE CORTICAL CONCAVITY AT FERTILIZATION IN THE SEA URCHIN EGG

During the initial stages of fertilization envelope elevation in eggs of Strongylocentrotus pur puratus and S. droebachiensis a large concavity of the egg cortex was observed in the light microscope. This concavity corresponded in shape and size with the elevating fertilization envelope. However, after the vitelline layers of eggs were disrupted and the eggs inseminated, the concavity failed to develop although the eggs were fertilized and developed normally. We propose that the concavity is formed owing to increased hydrostatic pressure within the perivitelline space. To further support this hypothesis we measured total egg protein secreted during fertilization, and found that 98% was retained within the perivitelline space. Furthermore, 80% of the total protein was contributed by the hyaline layer. Presumably, colloidal osmotic pressure and/or hydration of fertilization product, trapped beneath the fertilization envelope, is responsible for increased hydrostatic pressure within the perivitelline space, and therefore promotes not only fertilization envelope elevation, but the cortical concavity as well.     

Concanavalin A inhibits the dispersion of the cortical granule contents of sand dollar eggs

Dendraster excentricus eggs fertilized in ConA (10 μg/ml) elevate vitelline layers and expel cortical granule contents into the perivitelline space. The granule material does not disperse but remains composed as discrete spheres. The elevated vitelline layer remains thin and weak. It is not a true fertilization membrane because it lacks the structural material supplied by the granules.     

Electron Microscopic Study of Development in a Sea Cucumber,Stichopus tremulus (Holothuroidea), from Unfertilized Egg through Hatched Blastula

In this, the first fine structural study of sea cucumber embryology, eggs and embryos of Stichopus tremulus developing at 7.5°C are described from spawning through hatched blastulae. Spawned eggs are at about first meiotic metaphase and are surrounded by a jelly layer that remains around the embryos until hatching. No vitelline coat can be demonstrated, but whether it is truly absent or removed by electron microscopic processing is not known. Insemination initiates a rapid cortical reaction, completed within 2 min., which involves a wave of cortical granule exocytosis and fertilization envelope formation. The compactly fibrous fertilization envelope is about 50 nm thick and appears to consist entirely of ejected cortical granule material (if one assumes that there is no vitelline coat). As the fertilization envelope elevates, no hyaline layer appears in the perivitelline space. The first and second polar bodies are emitted, respectively, at about 9 and 15 min. after insemination. The first seven or so cleavages are equal, radial, and occur approximately every 4 hr. The blastocoel opens up at the four-cell stage and, during the earlier cleavages, remains connected with the perivitelline space via numerous gaps between the roughly spherical blastomeres. At the 64-cell stage, these gaps begin to close as the blastomeres start to become cuboidal; in addition, an embryonic cuticle is produced on the apical surface of each blastomere. In embryos of several hundred cells, the blastomeres become associated apicolaterally by junctional complexes, each consisting of a zonula adherens and a septate junction. Several hours before hatching, a single cilium is produced at the apical surface of most blastomeres. At hatching (about 50 hr after insemination), the ciliated blastula leaves behind the fertilization envelope and jelly layer. Swimming blastulae soon begin to elongate in the animal-vegetal axis, and a basal lamina develops on blastomere surfaces facing the blastocoel. The discussion includes a fine structural comparison of egg coats among the five classes of the phylum Echinodermata.     

Localization of polysialoglycoprotein as a major glycoprotein component in cortical alveoli of the unfertilized eggs of Salmo gairdneri

Polysialoglycoprotein (PSGP, 200 kDa), first isolated by S. Inoue and M. Iwasaki in 1978 (Biochem. Biophys. Res. Commun. 83, 1018-1023) from unfertilized eggs of rainbow trout, has been shown to comprise a unique class of glycoproteins associated with the exocytosis of cortical alveoli. In 1986, 200-kDa PSGP was shown to undergo proteolytic depolymerization to 9-kDa PSGP on egg fertilization (activation) and there was an indication that 200-kDa PSGP may possibly be a component of cortical alveoli (J. Biol. Chem. 261, 5256-5261). In this paper we present evidence demonstrating that PSGP is actually a component of cortical alveolus. First, a cortical alveolus-rich fraction (CA fraction) was obtained by low-speed centrifugation of the homogenate of unfertilized eggs of rainbow trout. The 200-kDa PSGP was found to be a major component extractable with buffered saline from the CA fraction by chemical analysis of isolated materials. Treatment of the eggs to induce parthenogenetic activation resulted in all cases in the loss of both cortical alveoli and PSGP in the CA fraction. Second, perivitelline space fluid was isolated from the activated eggs of rainbow trout and analyzed, and 9-kDa PSGP was confirmed to be present as a major proteinaceous component. Third, following incubation of the eggs in water for activation, the time course of the appearance of 9-kDa PSGP and the breakdown of 200-kDa PSGP was observed. The formation of 9-kDa PSGP was detected in the eggs after 1 min of incubation and its level rose rapidly, attaining a maximum at 7 min after incubation. During this period, there was a concomitant fall in the level of 200-kDa PSGP. This formation and rapid increase in 9-kDa PSGP correspond directly to the time course of cortical alveolus exocytosis in activated chum salmon eggs recently studied by scanning electron microscopy.     

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.     

Time and process of sperm penetration into cumulus-free mouse eggs fertilized in vitro

Sperm penetration through the zona pellucida and fusion of the sperm head with the vitellus were observed continuously and filmed under phase optics in cumulus-free living mouse eggs inseminated in vitro with capacitated epididymal sperm. Most spermatozoa penetrated the zona pellucida, traversed the perivitelline space, and fused with the vitellus at an angle nearly perpendicular to the surface. The mean duration required for sperm to penetrate the zona pellucida was 20 minutes with a range of 15–26 minutes. Sperm traversed the perivitelline space in less than one second. The initial contact of sperm with the vitellus generally took place at the tip of the sperm head. When the tip of the sperm head contacted the vitellus there was an immediate reduction in the rate of flagellation, followed by the gradual sinking of the sperm head into the vitellus.     

Sperm tail entry into the mouse egg in vitro

Cumulus-free mouse eggs were placed on microscope slides and inseminated with capacitated mouse spermatozoa. Fertilization could then be observed through the phase contrast microscope and recorded by time-lapse cinematography. Following the penetration of the fertilizing spermatozoon through the zona pellucida and the fusion of the sperm head with the vitelline membrane, the entire sperm tail gradually entered the vitellus. The time required for tail incorporation into the vitellus as measured in 49 eggs varied from 3 h 3 min to 5 h 49 min, with a mean time of 4 h 23 min. When tail incorporation began, the greater part of the flagellum was still outside the zona pellucida; occasionally it slipped into the perivitelline space, but generally it remained outside the zona and shortened by degrees as incorporation proceeded. The motility of the fertilizing spermatozoon declined abruptly very soon after fusion of the sperm head with the vitellus and remained at a very low level during the 3–6 h required for tail incorporation. Sperm motility, therefore, does not appear to be the main determinant in tail incorporation and the primary mechanism responsible for it remains unclear. As the sperm tail slowly entered the vitellus, the second meiotic division was completed with concomitant extrusion of the second polar body. Key stages in second polar body formation were correlated with events in tail incorporation. Differences between fertilization in vitro and in vivo are discussed.     

A complex cortical reaction leads to formation of the fertilization envelope in the lobster,Homarus

We have examined the formation of the fertilization envelope in the lobsters Homarus americanus and H gammarus. Oocytes were fixed for electron microscopy either in the ovary or following extrusion from the gonopore. Mature ovarian oocytes are surrounded by a coat (envelope 1), which is comprised of small electron-dense granules and structures resembling “bottlebrushes.” At least part of this coat is synthesized by the follicle cells of the ovary. The cortex of ovarian oocytes contains four types of vesicles that we refer to as high-density vesicles (HDV), low-density vesicles (LDV), moderately dense vesicles (MDV), and ring vesicles (RV). Oocytes that were electrically extruded from the gonopore and fixed immediately had an envelope identical to that of ovarian oocytes. The cortex of gonopore oocytes contained the four types of vesicles found in ovarian oocytes. When unfertilized gonopore oocytes were allowed to incubate in sea water, the oocyte cortex appeared unaltered, but envelope 1 swelled and the bottlebrushes dispersed. When recently fertilized oocytes were fixed during natural spawning or following in-vitro fertilization, each type of vesicle was released in sequence from the cortex of the oocyte. The contents of the HDV and LDV appeared first in the perivitelline space, but their fate could not be determined at later times. The ring-shaped elements of the RV and the moderately electron-dense material of the MDV were released exocytotically somewhat later; these materials coalesced in the perivitelline space to form a new coat (envelope 2). Envelope 1 subsequently condensed to its original thickness and appeared firmly attached to envelope 2. Our results show that the fertilized lobster egg is surrounded by two discrete coats. The outer coat, which is formed in the ovary, undergoes a swelling/condensation cycle at spawning. The inner coat originates from a complex cortical reaction. Together these coats comprise the fertilization envelope of the lobster egg.     

Identification of cystatin as a component of carp chorion

An ovary-specific cystatin is immunocytochemically demonstrated to be localized in the chorions, cortical granules, and yolk granules of carp oocytes, as well as in the follicle cells surrounding oocytes. During cortical reaction, cystatin is exocytosed from cortical granules into the perivitelline space. In situ hybridization confirms that cystatin is synthesized by oocytes and follicle cells. Western blotting reveals that chorion cystatin appears in multiple bands of high molecular weight (from 65 kDa to larger than 200 kDa). No cystatin monomer of 14 kDa is found. These results indicate that chorion cystatin is conjugated with other chorion components. Two forms of conjugates are found. In one form, cystatin, ZP2, fibroin-like substance (FLS), and cathepsin-like substance (CLS) are conjugated, which is extracted by sodium dodecyl sulfate. In the other form, cystatin, FLS, and CLS are conjugated, which is extracted by guanidine thiocyanate (GTC). Most chorion cystatin of oocytes and ovulated eggs is solubilized by GTC, while a large amount of cystatin remains in the fertilization envelope of cortical reacted eggs after extraction by GTC. Mol. Reprod. Dev. 51:430–435, 1998. © 1998 Wiley-Liss, Inc.     

Studies on fertilization in the teleost. I. Dynamic responses of fertilized medaka eggs

In order to understand the mechanisms of fertilization in the teleost, the movements of the egg cortex, cytoplasmic inclusions and pronuclei were observed in detail in fertilized medaka Oryzias latipes eggs. The first cortical contraction occurred toward the animal pole region following the onset of exocytosis of cortical alveoli. The cortical contraction caused movement of oil droplets toward the animal pole where the germinal vesicle had broken down during oocyte maturation. The movement of oil droplets toward the animal pole region was frequently twisted in the right or left direction. The direction of the twisting movement has been correlated with the unilateral bending of non-attaching filaments on the chorion. The female pronucleus, which approached the male pronucleus from the vicinity of the second polar body, took a course to the right, left or straight along the s-p axis connecting the male pronucleus and the second polar body. The course of approach by the female pronucleus correlated with the bending direction of the non-attaching filaments that had been determined by rotation of the oocyte around the animal–vegetal axis during oogenesis. The first cleavage furrow also very frequently coincided with the axis. These observations suggest that dynamic responses of medaka eggs from fertilization to the first cleavage reflect the architecture dynamically constructed during oogenesis.     

Fine structural investigation of the insemination response in Urechis caupo.

Electron microscopy of Urechis eggs revealed no changes in the egg cortex or investing layers until 4 min after insemination at 172C. From 4 min to about 30 min after insemination the surface coat gradually elevates, widening the perivitelline space. During this period, microvilli separate from the tightly woven layer of the surface coat, fibrogranular aggregates resembling surface coat material appear in the perivitelline space, and some cortical granules are extruded from the egg cortex into cytoplasmic processes. There is no statistically significant decrease in the number of cortical granules remaining in the egg surface during the first 95 min after insemination; many cortical granules persist in postgastrulae. Most of the cortical granules remain in fertilized eggs after removal of the surface coat with glucose-EGTA. We found no morphological correlates of the polyspermy block which is established within 1 min of insemination (Paul, 1975).     

金鱼精子入卵过程的扫描电镜观察

本文采用扫描电镜观察了金鱼(Carassius auratus)卵壳膜(chorion)表面结构和精子入卵过程。在壳膜的卵膜孔(micropyle)区有5—10条沟和嵴。位于精孔管下面,卵的质膜为一束较长的微绒毛组成的精子穿入部(sperm entry site)。授精5s,精子头的顶部已附着于精子穿入部,随即两者的质膜发生融合,而围于精子头部四周的微绒毛迅速伸长形成一受精锥,它不断将精子头部包裹。授精110s,精子的头部和颈部已完全进入卵内,受精锥本身也渐趋消失,但精子尾部仍平躺于卵的表面。皮层小泡是在授精30s后才开始破裂并释放其内含物,导致卵子表面呈蜂窝状,并在无膜内表面附着了大量球状物。     

Exocytosis of cortical granules from activated oocytes of the toad,Bufo arenarum

Summary Observation of the cortical region of oocytes of Bufo arenarum by transmission electron microscopy reveals modifications on their surface and in the contents of the cortical granules (CG) during activation. In non-activated oocytes only amorphous cortical granules (ACG) can be observed. Activated oocytes display ACG, intermediate cortical granules containing both amorphous and membranous material (ICG), and a third type containing only membranous material (MCG). During exocytosis, CG release their contents into the perivitelline space, where the amorphous and membranous materials are found. The three types of CG found during oocyte activation suggest transformation of ACG to MCG and indicate that the different components of the cortical granules, when released into the perivitelline space, might play different roles in prevention of polyspermy.Members of the Scientific Research Career of CONICET, R. Argentina.     

SCANNING ELECTRON MICROSCOPIC STUDY ON THE SURFACE CHANGE OF EGGS OF THE TELEOST, ORYZIAS LATIPES, AT THE TIME OF FERTILIZATION

The surface change of the egg of the teleost, Oryzias latipes , during fertilization was observed with a scanning electron microscope. The microvilli of the outer surface of the unfertilized egg show a slight difference in density between the animal and vegetal pole areas. In the initial step of the breakdown of cortical alveoli (CA), several small holes or gapes are formed at the apical part of the CA membrane, becoming a large aperture from which the alveolar contents are discharged. The formation of microvilli is observed on the inner surface of the exposed cavity left by the CA, starting from the periphery of the aperture and propagating throughout the whole inner surface in accompaniment with the release of the alveolar contents. After the completion of CA breakdown, the CA membrane cannot be distinguished from the original egg plasma membrane.     

A cortical granule-specific enzyme,B-1,3-glucanase,in sea urchin eggs

The ultrastructural localization of B-1,3-glucanase in three species of sea urchin eggs was determined using a monospecific antibody in an electronmicroscopic immunogold procedure. In all three species, Lytechinus variegatus, Strongylocentrotus purpuratus, and Arbacia punctulata, B-1,3-glucanase was localized specifically to the cortical granules. No other organelle within the egg contained significant label. During the fertilization reaction, B-1,3-glucanase was released from cortical granules into the perivitelline space and became associated with the hyaline layer. No significant label was found in association with the fertilization envelope.     

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.