Starfish sperm-oocyte jelly binding triggers functional changes in cortical granules. A study using acid phosphatase and ruthenium red ultrastructural histochemistry

Starfish oocytes were examined before fertilization, immediately after insemination, and during the cortical reaction by means of acid phosphatase and ruthenium red ultrastructural histochemistry. Oocyte cortical granules are composed of a lamellar body and a surrounding matrix which is subdivided into dense and light portions. In unfertilized oocytes cortical granules are not stained by ruthenium red but show a weak acid phosphatase activity in the light portion of the granule matrix. Immediately after the adhesion of the spermatozoon to the oocyte jelly coat, the light matrix portion of cortical granules appears stained by ruthenium red and shows a strong acid phosphatase activity. During the cortical reaction, cortical granules are released into the perivitelline space and the lamellar body, surrounded by the stained matrix, fuses with the fertilization envelope. Our data suggest that membrane permeability changes and enzyme activation occur in the egg when the spermatozoon binds to the oocyte jelly coat.     

Perivitelline space of mammalian oocytes: extracellular matrix of unfertilized oocytes and formation of a cortical granule envelope following fertilization.

Extracellular matrices (ECM) present around unfertilized and fertilized mammalian oocytes were studied ultrastructurally in samples prepared in the presence of ruthenium red to facilitate stabilization of extracellular materials. Unfertilized mouse, hamster, and human oocytes have an ECM comprising granules and filaments in their perivitelline spaces (PVS). This matrix is more abundant in the human than in hamsters and mice. The granule/filament matrix appears identical to the matrix seen between cumulus and corona radiata cells following ruthenium red processing and previously shown to comprise protein and hyaluronic acid. By including ruthenium red during fixation, it is possible to demonstrate the existence of cortical granule exudate in the PVS of fertilized oocytes from hamsters, mice, and humans. Much of the cortical granule exudate is trapped in the PVS and forms a new coat around the fertilized oocyte. This material is particulate when stained with ruthenium red and appears to be uniformly dispersed around the entire oocyte surface. We refer to this new coat as the cortical granule envelope. This envelope is observed in the PVS of all developmental stages up to and including blastocysts in all three species. Following hatching of mouse and hamster blastocysts, the cortical granule envelope is no longer present. Possible functions of this envelope are discussed.     

Perivitelline space of marsupial oocytes: Extracellular matrix of the unfertilized oocyte and formation of a cortical granule envelope following the cortical reaction

The purpose of this study was to characterize the structure of the vestments surrounding unfertilized and cortical granule-reacted oocytes from a marsupial, the grey short-tailed opossum Monodelphis domestica and to determine if a cortical granule envelope (CGE) forms in the perivitelline space (PVS) following the cortical reaction. Unfertilized oocytes collected from mature ovarian follicles and oviducal oocytes that had undergone a cortical reaction were fixed for electron microscopy in the presence of ruthenium red which stabilizes extracellular matrices (ECM) and facilitates demonstration of a CGE. Unfertilized oocytes were surrounded by a zona pellucida and had a PVS which contained a thick ECM comprised of granules and filaments. This matrix appeared to attach to the oolemma and was structurally similar to matrices reported previously in the PVS of unfertilized oocytes from eutherian mammals and two other marsupials, the Virginia opossum and the fat-tailed dunnart. The cortex of unfertilized oocytes contained cortical granules which were absent in oocytes recovered from the oviducts of mated females. Oviducal oocytes which lacked cortical granules exhibited a new coat within the PVS between the zona pellucida and the tips of the oocyte microvilli. This coat, the CGE, appeared structurally similar to CGEs described previously around fertilized eutherian oocytes. The CGE of the grey short-tailed opossum is approximately 1 μm thick and is made up of numerous small dense granules. The coats of the opossum oocyte are compared to those present around other marsupial and eutherian oocytes. © 1995 Wiley-Liss, Inc.     

Fertilization of the starfish Astropecten aurantiacus

In the starfish Astropecten aurantiacus the acrosome reaction occurs when the spermatozoon contacts the outer surface of the jelly layer. A long thin acrosomal filament is extruded from the anterior region of the spermatozoon and establishes contact with the oocyte surface. This latter interaction initiates the movement of the spermatozoon to the oocyte surface, formation of the fertilization cone and the cortical reaction. The first detectable electrical change across the oocyte plasma membrane during interaction with the spermatozoon is the fertilization potential (FP) which occurs simultaneously with the cortical reaction. The FP is probably the electrical result of the modification of the oocyte plasma membrane during cortical exocytosis. There are no primary step-like depolarizations during fertilization of starfish oocytes, which contrasts with the situation in sea urchin eggs [see 13]. We suggest that the difference in electrical response to fertilization of starfish oocytes and sea urchin eggs may be attributed to the location of the acrosome reaction in these animals and not to their different meiotic states.     

The oocyte-cumulus complex: Ultrastructure of the extracellular components in hamsters and mice

To enhance preservation of the extracellular materials, we have fixed hamster and mouse oocyte cumulus complexes (OCC) for transmission electron microscopy in the presence of ruthenium red. Ruthenium red had four effects on the extracellular components of the freshly ovulated hamster OCC. It interacted with the surface of cumulus and corona radiata cells; it stabilized the extracellular matrix (ECM) that was comprised of granules and filaments; it produced moderate electron density and good structural definition in the zona pellucida, and it revealed occasional smalls granular depsits on the oolemma. The ECM observed between cells of the cumulus and corona radiata layers extended into the outer one third of the zona pellucida. The granule and filament matrix was removed from the cumulus layer, corona radiata, and pores of the zona pellucida by brief treatment with hyaluronidase. The extracellular components of oviducal OCC from hamsters and mice appeared similar to OCC removed from follicles of the hamster shortly before ovulation. However, oviducal OCC did show increased aggregation of granules in the ECM. In most cases where females had been mated and oocytes were fertilized, the extracellular components appeared similar to those seen in fresh OCC. Exceptions were noted in some oocytes that lacked cumulus and corona radiata cells. In these instances, the zona pellucida generally lacked the granule/filament matrix. After fertilization numerous small electrondense granules were noted in the perivitelline space. These were presumed to originate in the cortical granules and formed a new investing layer around the zygote. Our data suggest that the OCC becomes more difficult for a sperm to penetrate as it approaches the oocyte. The significance of these results is discussed with respect to sperm traffic in the OCC and the cortical reaction.     

Ultrastructure of opossum oocyte investing coats and their sensitivity to trypsin and hyaluronidase

Ovulated opossum oocytes are surrounded by a zona pellucida, but not by cumulus cells. Opossum sperm carry at least four acrosomal hydrolases (hyaluronidase, acrosin, N-acetylhexosaminidase, and arylsulfatase); the functions of these enzymes in opossum fertilization are uncertain. To identify possible substrates for these hydrolases, the ultrastructure of opossum oocytes was examined after fixation in the presence of ruthenium red which stabilizes extracellular matrices. This oocyte is unusual in having a wide perivitelline space containing a highly structured extracellular matrix (ECM). The ECM is comprised of granules and filaments, and it resembles matrices known to contain hyaluronic acid in other systems. Hydrolases, known to be present in opossum acrosomes, were tested for their effect on the ultrastructure of the zona pellucida and matrix of the perivitelline space. Trypsin dissolved the zona pellucida and decreased the size of the granules in the perivitelline space. Streptomyces hyaluronidase, which specifically attacks hyaluronic acid, removed only matrix filaments. Arylsulfatase, N-acetylhexosaminidase, and beta-glucuronidase did not affect the zona pellucida or ECM in our assay. These observations are consistent with the ideas that (1) opossum sperm must penetrate two oocyte investments, the zona pellucida and ECM of the perivitelline space; (2) the ECM contains hyaluronic acid (filaments) and protein (granules); (3) opossum sperm acrosin may function in penetration of the zona pellucida and ECM; and (4) opossum sperm hyaluronidase may function in penetration of the ECM by degrading hyaluronic acid (filaments). Dissolution of the granules and filaments from oocyte microvilli is probably necessary to permit close apposition and fusion of the sperm and oocyte membranes. The evolutionary significance of these results is discussed.     

Ultrastructural Observations on the Spermatozoon,Oocyte and Fertilization Process in Gonapodasmius,a Gonochoristic Trematode (Trematoda: Digenea: Didymozoidae)

Observations were performed in the uterus of a female Gonapodasmius sp., a gonochoristic didymozoid Trematode. The oocyte is a round cell 6 μm in diameter, which shows a ‘nucleolus-like cytoplasmic body’ and cortical granules. The spermatozoon is filiform, mobile and about 50 μm long. There is no acrosome. The anterior tip of the spermatozoon contains two centrioles made up of singlets and cortical microtubules with associated glycocalyx. The centrioles are continued as two axonemes of the classical 9 + ‘1’ pattern of flatworms, accompanied by a mitochondrion and a short row of cortical longitudinal microtubules. It is the posterior part of the sperm cell which contains the nucleus. At the outset of fertilization, the anterior part of the spermatozoon coils around the oocyte and penetrates it by lateral fusion. The posterior region of the spermatozoon, with the nucleus, is the last part to enter the oocyte, after passing through a perforation in the forming eggshell. The whole spermatozoon thus penetrates the female cell.     

Scanning electron microscopy: Identification of mast cells by indirect cathodoluminescence

Summary The epithelial tissues of the rabbit gall bladder reacted for acid mucosaccharides were studied with the electron microscope. A series of acid mucosaccharide-containing ultrastructures of the gall bladder epithelium were observed in specimens treated with dialyzed iron, colloidal thorium and ruthenium red. In the epithelium stained with dialyzed iron, reactive ultrastructures are not only extra- but intracellular; the surface coat of the plasma membrane, pinocytotic vesicles, granules of secretion and certain elements of the Golgi apparatus. In the epithelial tissues stained by colloidal thorium or ruthenium red, the surface coat of the plasma membrane is the only ultrastructure which is reacted positively for the acid mucosaccharide stains. The present images of ultrastructural elements containing acid mucosaccharides are taken to indicate a multiple function of the substances in rabbit gall bladder epithelium and are well correlated with the results of previous light and electron microscopic studies on the gall bladder epithelium of various vertebrate species.     

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.     

EFFECTS OF IONOPHORE A23187 ON OOCYTES OF COMANTHUS JAPONICA (ECHINODERMATA: CRINOIDEA)*

Micromolar amounts of divalent cation ionophore A23187 stimulate full grown (but unfertilizable) oocytes of Comanthus japonica to undergo a cortical reaction that is incomplete: first, cortical granule contents ejected at exocytosis do not coalesce but remain as individual blebs just outside the oocyte; and, second, about a fourth of the cortical granule population does not undergo exo-cytosis and remains in the cortical cytoplasm. Of the cortical granules remaining in the oocyte, some have unreacted contents and others have morphologically modified contents. Fine structures are compared among unreacted cortical granules, internally-reacted cortical granules, extracellular blebs of cortical granule material and normal fertilization membranes. The comparison strongly suggests that the outer dense layer and inner fibrous layer of the normal fertilization membrane are derived, respectively, from the dense patches and from the matrices of the cortical granules.     

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.     

Ultrastructural Observations on Fertilization in Dionchus remorae (Platyhelminthes,Monogenea, Dionchidae)

Ultrastructural observations are presented for some of the stages occurring during fertilization in Dionchus remorae (a gill parasite of Echeneis naucrates) and are believed to be the first published concerning a monogenean. Fertilized female germ cells were found in the ovary. Several loops of the spermatozoon were present within the oocyte cytoplasm; the sperm nucleus became electron lucent and the parallel peripheral doublets of the axonemes became increasingly divergent. The cortical granules in the oocyte were not released immediately after penetration by the spermatozoon. The homogeneity apparently found in the oocyte ultrastructure and process of fertilization in the monogeneans and digeneans contrasts with the variety that exists in their sperm ultrastructure.     

The development of mouse oocyte cortical reaction competence is accompanied by major changes in cortical vesicles and not cortical granule depth

The basis for the incompetence of the cortical reaction in germinal vesicle stage (GV) mouse oocytes was studied by evaluating cortical granules (CGs) and vesicles in GV and mature oocyte cortices. Dark and light CGs had a similar mean distance of 0.4-0.6 micron from the plasma membrane for GV and mature cortices. The cortex of mature oocytes had a large population of membrane-bounded, 0.1-1.0 micron (diameter) vesicles. More than three times as many vesicles were observed in the CG domains of mature oocytes as were observed in GV oocytes. This lack of cortical vesicles (with their potential to store calcium) and not CG depth may account for cortical reaction incompetence in GV oocytes.     

Cytochemical localization of GalNAc and GalNAcβ1,4Galβ1,4 disaccharide in mouse zona pellucida

Carbohydrate residues contained in the zona pellucida play a key role in the process of sperm-egg interaction. In vitro fertilization experiments have shown that a specific monoclonal antibody against GalNAcş,4Galş,4 disaccharide inhibits fertilization in mice. In the present study, the ultrastructural cytochemical localization of GalNAc residues and the GalNAcş,4Galş,4 disaccharide was carried out in ovarian and postovulatory oocytes by using lectin-gold cytochemistry and immunocytochemistry. Plant lectins SBA and DBA showed an affinity for the entire zona pellucida matrix of ovarian oocytes throughout the follicular maturation; however, immunoreactivity for GalNAcş,4Galş,4 disaccharide was not detected in ovarian oocytes at the earliest stages of follicular development but was found to be associated with the inner region of the zona matrix at the trilaminar primary follicle stage. The Golgi apparatus, vesicular aggregates, and cortical granules of the oocyte were intensely labeled by SBA and DBA throughout follicular development. Immunoreactivity to GalNAcş,4Galş,4 disaccharide was first observed in the Golgi apparatus and vesicular aggregates in trilaminar primary follicles. No immunoreactivity was observed in the cortical granules. In postovulatory oocytes, results were similar to those observed in ovarian oocytes. Our results thus suggest that (1) GalNAcş,4Galş,4 disaccharide residues are present only in the inner region of the zona pellucida and, therefore, might be involved in sperm penetration through the zona pellucida, (2) the inner and outer regions of the zona pellucida contain different oligosaccharide chains, (3) the vesicular aggregates detected in the oocyte could represent an intermediate step in the secretory pathway of zona pellucida glycoproteins and might be involved in the formation of cortical granules.     

Fertilization envelope in diapause eggs of Pontella mediterranea (Crustacea, Copepoda).

The sequence and timing of morphological changes during envelope formation was followed in diapause eggs of Pontella mediterranea (Crustacea, Copepoda). The multilayer coat enveloping these eggs resulted from the exocytosis of 4 types of cortical vesicles that sequentially released their contents in the perivitelline space. These included small high-density vesicles (hDV) with electron-dense material, vesicles (V) with dense ring granules and a uniform matrix contained within the same compartment, large high-density (HDV) vesicles, and large moderately dense (MDV) vesicles. All of these cortical vesicles were present in newly spawned, fertilized eggs. Their exocytosis resulted from egg activation. One of these cortical vesicles (V) was similar in morphology to the intracisternal granules precursors of endogenous yolk. Intracisternal granules, characteristic of previtellogenic oocytes of many crustaceans, were present in previtellogenic oocytes of P. mediterranea but disappeared in later stages of oocyte development once yolk formation was completed. We discuss the role of cortical vesicles in the formation of the complex extracellular coat enveloping copepod diapause eggs.     

The biology and dynamics of mammalian cortical granules

Cortical granules are membrane bound organelles located in the cortex of unfertilized oocytes. Following fertilization, cortical granules undergo exocytosis to release their contents into the perivitelline space. This secretory process, which is calcium dependent and SNARE protein-mediated pathway, is known as the cortical reaction. After exocytosis, the released cortical granule proteins are responsible for blocking polyspermy by modifying the oocytes' extracellular matrices, such as the zona pellucida in mammals. Mammalian cortical granules range in size from 0.2 um to 0.6 um in diameter and different from most other regulatory secretory organelles in that they are not renewed once released. These granules are only synthesized in female germ cells and transform an egg upon sperm entry; therefore, this unique cellular structure has inherent interest for our understanding of the biology of fertilization. Cortical granules are long thought to be static and awaiting in the cortex of unfertilized oocytes to be stimulated undergoing exocytosis upon gamete fusion. Not till recently, the dynamic nature of cortical granules is appreciated and understood. The latest studies of mammalian cortical granules document that this organelle is not only biochemically heterogeneous, but also displays complex distribution during oocyte development. Interestingly, some cortical granules undergo exocytosis prior to fertilization; and a number of granule components function beyond the time of fertilization in regulating embryonic cleavage and preimplantation development, demonstrating their functional significance in fertilization as well as early embryonic development. The following review will present studies that investigate the biology of cortical granules and will also discuss new findings that uncover the dynamic aspect of this organelle in mammals.     

Ultrastructural characterization by ruthenium red of the surface of the fat globule membrane of human and rat milk with data on carbohydrates of fractions of rat milk

The fat globules of the cream fractions of human and rat milk were stained with ruthenium red. Under the electron microscope, discrete granules and an amorphous coat of lesser density are seen at the surface of the milk fat globules. Since ruthenium red binds anionic groups selectively, it is probable that the granules contain the greatest concentration of these groups. The cream fraction of rat milk contains hexoses, hexosamines, methylpentoses and sialic acid. Methylpentoses and hexosamines are significantly enriched in the cream fraction. It is concluded that the finding of a surface coat in milk fat globules is in keeping with the Bargmann-Knoop model and suggests a distinct mechanism for carrying certain complex carbohydrates in milk. The role of the negative charges at the outer surface of the membrane coat is maintaining fat globules in suspension and in binding certain cations such as calcium is suggested.     

Plasminogen activator activity in cortical granules of bovine oocytes during in vitro maturation

In this study, we provide evidence that plasminogen activator of tissue-type (t-PA), at least, is present in extracts of bovine oocyte cortical granules, and that its activity varies significantly with the duration of oocyte in vitro maturation. Cortical granules were collected from bovine oocytes by means of micromanipulation, after 0, 12, or 24 h of IVM. Our results show that plasminogen activator activity of cortical granule extracts was significantly higher after 24 h of IVM than after 12 h of IVM or before IVM. This activity was apparently due, at least partly, to tissue-type plasminogen activator as shown immunologically. No evidence was found for the presence of urokinase-type plasminogen activator, plasminogen activator inhibitors or plasmin inhibitors in bovine oocyte cortical granule extracts. Our findings further support the hypothesis that t-PA activity of oocyte origin may have a role in oocyte maturation or fertilization, as well as in post-fertilization events, such as cortical reaction and formation of the zona block to polyspermy.     

Oocyte differentiation in Urechis caupo (Echiura): a fine structural study.

The fine structure of oocytes of Urechis caupo is described for seven arbitrary stages ranging from the smallest oocytes (7 mum in diameter) in the coelom to the mature oocytes (115 mum in diameter) in the storage organs. Although most types of cytoplasmic organelles accumulate more or less continuously, yolk granules do not appear until oocytes reach a diameter of 35 mum, and there is stage-specific synthesis of cortical granules in 60-80 mum oocytes. In the nucleus a single nucleolus first appears when an oocyte is 15 mum in diameter. Then a nucleolus satellite, which is about 3 mum in diameter, forms in 30 mum oocytes; this nucleolus satellite later (60-70 mum oocytes) becomes surrounded by 750 nm dense spherical bodies. Large (2-4 mum in diameter) juxtachromosomal spherules occur only in the nuclei of mature oocytes. Microvilli become progressively more numerous and longer until the oocyte reaches a diameter of 90 mum; their tips project 1 mum beyond the fibrous surface coat, which is 2 mum thick when well developed. Near the end of oocyte growth, the microvilli retract into the surface coat leaving their pinched-off tips adhering to the outside of the coat.