Changes in cortical granules during porcine oocyte maturation

The structure, number, and distribution of cortical granules in porcine oocytes during maturation induced by human chorionic gonadotrophin (HCG) are reported. The number of granules remained constant for 30 hr following HCG. Thereafter, there was an approximate doubling by 50 hr. At all times examined, a dark and light form were present. Up to 40 hr the latter predominated while at 50 hr there was a marked increase in the number of the former. Movement of cortical granules to the plasma membrane took place between 20 and 30 hr post-HCG. The changes in cortical granules are correlated with the capacity of the oocytes to undergo a block to polyspermy.     

Changes in the distribution of mouse oocyte cortical granules and ability to undergo the cortical reaction during gonadotropin-stimulated meiotic maturation and aging in vivo

Mouse oocyte cortical granule (CG) activation and distribution were investigated during in vivo meiotic maturation to determine the onset of competence to undergo the cortical reaction, which is considered responsible for the block to polyspermy. In the present study, the resumption of oocyte maturation was stimulated by hCG administration. Competence to undergo the cortical reaction (assessed with calcium ionophore A23187) was undetectable (0% loss) in germinal vesicle-stage oocytes 0.5 h after hCG administration. When germinal vesicle breakdown and metaphase I had taken place (3 and 7 h post hCG, respectively), approximately 30% CG loss was observed. Maximal (A23187-inducible) levels of CG loss, 67% and 72%, were present at 10 and 13 h, respectively, during metaphase II. Cortical granule distribution changed dramatically during metaphase I, polar body formation, metaphase II, and post-ovulatory aging in vivo. A stable metaphase II distribution was present from 13 to 18 h. After 24 and 32 h, 28% and 83% of the eggs, respectively, exhibited major alterations in the cortical distribution of CGs, some of which did not appear to be susceptible to release by A23187. These data support the hypothesis that just before ovulation the egg cortex completes the development of its normal structure and physiological competence, which are maintained for only a brief period of time afterward. The implications are discussed for normal fertilization and polyspermy in mammals, including humans.     

Precocious loss of cortical granules during mouse oocyte meiotic maturation and correlation with an egg-induced modification of the zona pellucida

Fertilization results in cortical granule exocytosis, which is thought to be involved in modifications of the zona pellucida that constitute the zona pellucida block to polyspermy. A previous report demonstrated that a decrease in the number of Lens culinaris agglutinin-staining granules, which are likely to be cortical granules, occurred during in vivo mouse oocyte maturation with arrest at metaphase II, as well as the formation of a cortical granule-free domain in the area of the metaphase II spindle (T. Ducibella, E. Anderson, D.F. Albertini, J. Aalberg, and S. Rangarajan, 1988, Dev. Biol. 130, 184-197). We extend these observations by reporting here that germinal vesicle-intact oocytes matured in vitro to metaphase II in either the absence or the presence of serum develop a cortical granule-free domain and have reduced numbers of cortical granules when compared to germinal vesicle-intact oocytes; these changes are similar to those of oocytes matured in vivo. The reduction in the number of cortical granules requires germinal vesicle breakdown, since it is prevented by dibutyryl cAMP, which inhibits germinal vesicle breakdown in vitro. The ability of oocytes to respond to the calcium ionophore A23187 with a reduction in the number of cortical granules is also associated with meiotic maturation and develops between 7 and 12 hr after initiation of maturation. The maturation-associated reduction in the number of cortical granules is likely to represent cortical granule exocytosis, since this reduction is accompanied by the formation of a cortical granule-free domain and a conversion of ZP2 to ZP2f when the oocytes are matured in vitro in serum-free medium; this zona pellucida modification occurs following fertilization and is thought to be due to cortical granule exocytosis. In contrast, the loss of cortical granules and development of the cortical granule-free domain of oocytes matured in vitro in the presence of serum is not accompanied by the modification of ZP2. The inhibitory effect of serum on the ZP2 modification may afford in vivo a physiological mechanism to prevent a precocious modification of the zona pellucida that could result in a premature block to polyspermy and hence inhibit fertilization.     

Quantification and distribution of equine oocyte cortical granules during meiotic maturation and after activation

In vitro fertilization (IVF) is being routinely used in humans and several domestic species, however, limited success has been achieved in the horse. Although immature equine oocytes are capable of completing meiosis in vitro, subsequent fertilization, and embryonic development of those oocytes are questionable. The lack of development of these oocytes could be attributed to an impaired cytoplasmic maturation. In the horse, the study of oocyte cytoplasmic maturation and post-fertilization development has been hindered by the lack of progress in IVF. In mammalian oocytes, migration of cortical granules (CG) has been used as an important criterion to evaluate cytoplasmic maturation. The aim of this study was to describe and quantify the CG distribution of equine oocytes during in vitro meiotic maturation and to assess activation of oocytes with calcium ionophore based upon fluorescein isothiocyanate (FITC)-labeled Lens culinaris agglutinin (LCA) and laser confocal microscopy. The results of this study indicate that CG are distributed throughout the cytoplasm of oocytes at the germinal vesicle (GV) stage (immature). As maturation proceeds, a progressive centripetal migration of CG to the oocyte cortex occurs with the formation of a monolayer adjacent to the plasma membrane starting by the end of a 30 hr incubation period and increasing significantly after 36 hr. After activation, significant reduction in the number of CG was observed (P < 0.001) suggesting that oocytes cultured under the present conditions possess the ability to release CG in response to the elevation of intracellular free calcium.     

Ageing-induced changes in the cortical granules of mouse eggs

The cortical cytoplasm and cortical granules (CGs) of mouse oocytes were analysed by electron microscopy. Oocytes were collected soon and 20h after ovulation from adult young females (3-4 months old). In addition, gametes collected soon after ovulation from 12- to 14-month-old females were used. Ultrastructural analyses were undertaken using the conventional procedures and the alcoholic PTA method. PTA selectively stains the CGs indicating the presence of lysine-rich proteins in these granules. Oocytes from young females showed CGs as dense granules 300-500 nm in diameter linearly arranged under the oolemma. In oocytes recovered 20h after ovulation 24.31% of CGs appeared vacuolated and 38.40% internalized in the cytoplasm. In gametes collected from old females several changes were observed in the cortical cytoplasm: (a) CGs appeared concentrated in some areas while others regions were devoid of granules; (b) groups of CGs appeared internalized in the egg cytoplasm; (c) the CG contents had swollen and changed, showing dense and clear areas; (d) numerous dense structures and vesicles (lysosome-like vesicles) were present; (e) cytoplasmic fragmentation was frequently seen. Fragments contained CGs, dense structures and vacuoles. These changes are closely related to the low fertilization rates shown by these oocytes when they were used for in vitro fertilization procedures.     

Preantral intra-ovarian oocyte release in the white-footed mouse,Peromyscus leucopus

Summary Optical diffraction analysis was carried out on crystalline inclusions in the rough endoplasmic reticulum of the insulin and somatostatin cells in the islet organ of the hagfish. A striking difference in crystalline arrangement was observed between the inclusions of the insulin and somatostatin cells. The crystallographic arrangement of the inclusions observed in situ in the insulin cells differed from that previously found by means of X-ray diffraction analyses of hagfish insulin crystals formed in vitro.     

Immunocytochemical evidence suggesting heterogeneity in the population of sea urchin egg cortical granules

Unfertilized eggs of many species of animals contain cortical granules, which are specialized secretory granules that upon fertilization release their contents from the egg. The unfertilized eggs of the sea urchin, Strongylocentrotus purpuratus, contain cortical granules that all display an identical and elaborate internal morphology. It has been assumed that they all contain identical components. In this report we present immunocytochemical data which indicate that the cortical granule population of S. purpuratus eggs is heterogeneous. Two monoclonal antibodies are shown to react to the spiral lamellae region of approximately 20% of the cortical granules, implying that the contents of the reactive granules differ from the contents of the majority of the population. An egg protein of greater than 320 kDa is recognized by the antibody. These antibodies also stain a 130-kDa protein expressed on the surface of primary mesenchyme cells in later development. Both antibodies recognize a post-translational modification of this protein. This suggests that an antigenically similar epitope is present both on the 130-kDa primary mesenchyme cell-specific protein and in the cortical granules. To determine if the primary mesenchyme and cortical granule proteins are related, a fusion protein antibody specific for a region of the 130-kDa protein was used to stain unfertilized eggs. This antibody did not stain cortical granules. Thus, 20% of the cortical granules contain a molecule that has an epitope antigenically similar to the post-translational modification recognized in primary mesenchyme cells by the monoclonal antibodies.     

Calcium-mediated release of glucanase activity from cortical granules of sea urchin eggs

Confluent monolayers of sea urchin eggs were bonded to culture dishes coated with protamine sulfate. The cytoplasm was then sheared away by a jet of isosmotic buffer. About 326,000 circular fragments of individual egg cortices (430 micrograms protein) remained bound to each dish. The fragments are composed of cortical granules (CG), plasma membrane, and vitelline layer. A single dish contains 7.7 X 10(8) CG and is referred to as a CG lawn (CGL). Ca2+-EGTA buffers of estimated free-Ca2+ concentrations (0.06-25.7 microM) were applied to CGL and samples removed and assayed for the CG marker enzyme exo-beta (1 leads to 3)-glucanohydrolase (glucanase). Estimated free-Ca2+ concentrations above 2.75 microM caused the total release of the glucanase to the supernatant within 4 min. The half-maximal rate of appearance of glucanase occurred in 2.5 microM Ca2+. At all Ca2+ concentrations tested, the appearance of enzyme activity exhibited sigmoidal kinetics. The visual disappearance of CG correlated with the appearance of glucanase in the Ca2+ buffer. In response to Ca2+ the CG probably lyse, fuse with adjacent CG, or fuse with the underlying plasma membrane. The calmodulin antagonist trifluoperazine inhibited Ca2+-mediated glucanase release from CGL (I50 8 microM). The sensitivity of the CGL to Ca2+ in the 1-10 microM range is rapidly lost during incubation of CGL in the isolation buffer. ATP and low temperature retard the rate of loss of Ca2+ sensitivity. These secretory granules are a model for studying the mechanism of Ca2+-induced secretion. In addition, they contain structural proteins and enzymes which function in the fertilization process. CGL preparations should be useful in studies dealing with the processing of CG components after their release in response to micromolar concentrations of Ca2+.     

A C-type lectin associated and translocated with cortical granules during oocyte maturation and egg fertilization in fish

Oocyte maturation and egg fertilization in both vertebrates and invertebrates are marked by orchestrated cytoplasmic translocation of secretory vesicles known as cortical granules. It is thought that such redistribution of cellular content is critical for asymmetrical cell division during early development, but the mechanism and regulation of the process is poorly understood. Here we report the identification, purification and cDNA cloning of a C-type lectin from oocytes of a freshwater fish species gibel carp (Carassius auratus gibelio). The purified protein has been demonstrated to have lectin activity and to be a Ca(2+)-dependent C-type lectin by hemagglutination activity assay. Immunocytochemistry revealed that the lectin is associated with cortical granules, gradually translocated to the cell surface during oocyte maturation, and discharged to the egg envelope upon fertilization. Interestingly, the lectin becomes phosphorylated on threonine residues upon induction of exocytosis by fertilization and returns to its original state after morula stage of embryonic development, suggesting that this posttranslational modification may represent a critical molecular switch for early embryonic development.     

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.     

Distribution of prepubertal and adult goat oocyte cortical granules during meiotic maturation and fertilisation: ultrastructural and cytochemical study

The aim of this study was evaluate cortical granule (CG) distribution during in vitro maturation (IVM) and fertilisation of prepubertal goat oocytes compared to CG distribution of ovulated and in vitro fertilised oocytes from adult goats. Oocytes from prepubertal goats were recovered from a slaughterhouse and were matured in M199 with hormones and serum for 27 hr. Ovulated oocytes were collected from gonadotrophin treated Murciana goats. Frozen-thawed spermatozoa were selected by centrifugation in percoll gradient and were capacitated in DMH with 20% steer serum for 1 hr. Ovulated and IVM-oocytes were inseminated in DMH medium with steer serum and calcium lactate for 20 hr. Oocytes and presumptive zygotes were stained with FITC-LCA (Lens culinaris agglutinin labelled with fluorescein isothiocyanate) and observed under a confocal laser scanning microscope. Ultrastructure morphology of oocytes and presumptive zygotes were analysed by transmission electron microscopy (TEM). Prepubertal goat oocytes at germinal vesicle stage show a homogeneous CG distribution in the cytoplasm. IVM-oocytes at Metaphase II (MII) and ovulated oocytes presented CGs located in the cortex with the formation of a monolayer beneath to the plasma membrane. At 20 hr postinsemination (hpi), zygotes from IVM-oocytes showed a complete CG exocytosis whereas zygotes from ovulated oocytes presented aggregates of CGs located at the cortical region. Images by TEM detected that CGs were more electrodense and compacts in oocytes from prepubertal than from adult goats.     

Biochemical and morphological changes in the chorion of the carp (Cyprinus carpio) oocyte, following the cortical reaction

Following oviposition and/or fertilization in fieshwater, the soft vitelline membrane surrounding the carp oocyte elevates and becomes tough (fertilization envelope). We have studied the biochemical (protease digestion) and morphological (analysis scanning electron microscopy) changes associated with this transformation. The vitelline envelope is easily digested by most proteolytic enzymes; following elevation, the chorion becomes very resistant to proteolyse. This chorion is much thinner and smoother than the vitelline membrane, but retains a characteristic porous appearance. These results are compared with previous observations obtained by transmission electron microscopy and are discussed in relation to the blockage to polyspermy.     

Mammalian cortical granules: Contents,fate, and function

Recent studies have extended our knowledge regarding the contents of mammalian cortical granules (CG) and their function in postfertilization events. Cytochemical staining has demonstrated the presence of carbohydrates within mammalian CG, and lectin-binding studies have shown that these carbohydrates include α-Dmannose, α-D-GalNAc, and galactose residues in the hamster, α-D-mannose in the mouse and cat, and β-D-Gal(1,3)-D-GalNAc in the pig. Following fertilization and artificial activation, mannosylated material is released from CG and can be found on the oolemma and within the perivitelline space (PVS) of hamster oocytes. Fertilized or artificially activated rabbit, mouse, and human oocytes also release mannosylated, fucosylated and sialylated, and fucosylated material, respectively, which localizes to the oolemma. These glycosylated materials are probably of CG origin, although they have not been directly localized to the CG in rabbit, mice, and humans. The function(s) of the glycosylated material released from mammalian oocytes is not known, although it may participate in blocking polyspermy at the level of the plasma membrane, PVS, and/or zona pellucida (ZP), or it may facilitate preimplantation embryonic development. Proteinases, including tissue plasminogen activator, are also released from mammalian oocytes following fertilization and artificial activation, suggesting that they are of CG origin. These proteinases modify the ZP such that it is no longer receptive to sperm, and some proteinases have been suggested to bring about ZP hardening (an increased resistance to denaturing agents) by an unknown mechanism. Mouse ZP may also be hardened by an ovoperoxidase (cross-links tyrosine residues) cytochemically identified in mouse CG and CG exudate. The phenomena of ZP hardening in mammalian zygotes is not well understood but is likely to function in blocking polyspermic penetration of the ZP and/or in protecting embryos during preimplantation development. Recently, a 75 kD protein (p75) has been immunocytochemically localized to mouse CG and to the PVS of fertilized oocytes and two-cell embryos. The identity and function of p75 remains to be determined. Heparin binding placental protein may also be a CG component, since it is released from hamster oocytes following fertilization. It has not, however, been directly demonstrated to be a CG component, and its functions in fertilization and/or early embryonic development have yet to be defined. © 1994 Wiley-Liss, Inc.     

Temporal pattern of synthesis of the mouse cortical granule protein, p75, during oocyte growth and maturation.

We previously demonstrated that a protein of M(r) 75,000 (p75) is localized to cortical granules (CGs) in mouse oocytes and eggs and is released upon activation or fertilization of eggs (K.E. Pierce, M. C. Siebert, G. S. Kopf, R. M. Schultz, and P. G. Calarco, 1990, Dev. Biol. 141, 381-392). To examine the temporal pattern of synthesis of p75 during the early stages of CG formation, growing oocytes, which were isolated from juvenile mice, were incubated for 4 hr in medium containing [35S]methionine, and radiolabeled proteins were immunoprecipitated using an antiserum that detects p75. Synthesis of p75 is detected at low levels in the smallest oocytes examined (less than 20 microns). Synthesis of p75 relative to total protein synthesis increases about 12-fold during oocyte growth from the 20-40 microns size and then remains constant throughout the remaining period of oocyte growth (40-70 microns). In the fully grown, germinal vesicle (GV)-intact oocyte (70-80 microns), immunoprecipitated p75 comprises approximately 1.5% of the total amount of radiolabeled protein. Three hours after the transfer of these oocytes to a medium that supports resumption of meiosis and GV breakdown in vitro, oocytes subjected to a 1-hr labeling pulse display a 35% decrease in the relative level of p75 synthesis. By 15 hr of maturation, p75 synthesis was reduced to 14% of that in the fully grown, GV-intact oocyte and this is similar to the level of p75 synthesis in ovulated eggs. The level of p75 synthesis following in vitro translation of total egg RNA is only 38% lower than that obtained from total oocyte RNA. In addition, synthesis of p75 is observed following in vitro translation of oocyte, but not egg, poly(A)+ RNA. These results are consistent with p75 synthesis during oocyte maturation being under translational control.     

The hardening effect of dimethylsulphoxide on the mouse zona pellucida requires the presence of an oocyte and is associated with a reduction in the number of cortical granules present

When mouse ovulated oocytes were exposed to 1.5 M-dimethylsulphoxide (DMSO) the resultant hardening of the zona pellucida was not a direct effect but required the presence of an oocyte. The hardening of the zona pellucida when zonae used were aged in vitro was also dependent upon the presence of the oocyte. Protocols of DMSO exposure that induce zona-hardening also caused depletion of the numbers of cortical granules underlying the oocyte surface, whereas protocols without effect on the zona did not reduce significantly the cortical granule count. It is proposed that the effects of DMSO may be mediated by a release of cortical granule contents.     

Development of the competence of bovine oocytes to release cortical granules and block polyspermy after meiotic maturation

Bovine immature oocytes do not have the ability to block polyspermic penetration. The present study was conducted to determine whether this is correlated to cortical granule (CG) distribution and the competence of oocytes to release CG upon sperm penetration, and whether the ability of bovine oocytes to release CG develops during in vitro maturation. Fluorescein isothiocyanate-conjugated Lens culinaris agglutinin was used for detecting CG in immature and mature oocytes before and after sperm penetration and electric stimulation. The labeled oocytes were examined with laser confocal and fluorescent microscopes. The results show that CG exist as clusters in all immature oocytes. The CG were not released from immature oocytes exposed to electric pulse or penetrated by spermatozoa, resulting in 94% of oocytes being polyspermic. When immature oocytes were cultured for 22h in vitro , 81% extruded the first polar body and reached metaphase II. In mature oocytes, 25% of oocytes showed CG clusters, 42% and 33% of oocytes showed partial and complete CG dispersion, respectively. When mature oocytes were inseminated in vitro , only 15% of oocytes were polyspermic. Cortical granule exocytosis occurred in 97% of oocytes after sperm penetration and 84% of oocytes released all of the CG 18 h after insemination. Electric pulse induced all of the mature oocytes to release CG but only 55% released all of their CG 18 h post stimulation. These results indicate that polyspermy in immature bovine oocytes is the result of the complete failure of the oocyte to release CG after sperm penetration. Bovine oocytes became competent to release CG by sperm penetration and electric stimulation after meiotic maturation. These results provide evidence that CG exocytosis plays an important role(s) in the establishment of the block to polyspermy in bovine oocytes.     

Biochemical heterogeneity of mitochondria]

Rat liver mitochondria were fractionated on the basis of their sedimentation coefficients in the gradient of ficoll. The fractions ("heavy", "middle" and "light" mitochondria) were heterogeneous with regard to the content of protein, DNA, cytochrome a + a3 and respiratory activity. Heterogeneity of mitochondria did not result from the damage or microsomal and lysosomal contamination. The biosynthesis of DNA, RNA and proteins in the different fractions of mitochondria was studied. In vivo incorporation of radioactive precursor into RNA was highest in the fractions of "middle" mitochondria, whereas in vitro the "heavy" mitochondria showed maximum activity in the synthesis of RNA. In vitro DNA synthes was maximum in the fractions of "heavy" mitochondria, protein synthesis in "heavy" and "light" mitochondria. Activity of the synthesis of RNA, DNA and proteins in vitro depends on the content of DNA and cytochrome a + a3 in the different fractions of mitochondria. It is supposed that heterogeneity of mitochondria may be connected with their biogenesis.