Translocation of the classic protein kinase C isoforms in porcine oocytes: implications of protein kinase C involvement in the regulation of nuclear activity and cortical granule exocytosis

Protein kinase C (PKC) is a family of Ser/Thr protein kinases categorized into three subfamilies: classical, novel, and atypical. The subcellular localization of classical PKCalpha, -betaI, and -gamma in the process of porcine oocyte maturation, fertilization, and parthenogenetic activation and their involvement in cortical granule (CG) exocytosis were investigated. The results of Western blot showed that PKCalpha, -betaI, and -gamma were expressed in the oocytes at the germinal vesicle (GV) and metaphase II (MII) stages. Confocal microscopy revealed that the three PKC isoforms were concentrated in the GV but evenly distributed in the cytoplasm of MII eggs. PKCalpha and -gamma were translocated to the plasma membrane soon after sperm penetration. cPKCs migrated into the pronucleus in fertilized eggs. Following treatment with a PKC activator, phorbol 12-myristate 13-acetate (PMA), CGs were released and PKCalpha and -gamma were translocated to the membrane. The CG exocytosis and PKC redistribution induced by PMA could be blocked by the PKC inhibitor staurosporine. Parthenogenetic stimulation with ionophore A23187 or electrical pulse also induced cPKC translocation and CG exocytosis. Eggs injected with PKCalpha isoform-specific antibody failed to undergo CG exocytosis after PMA treatment or fertilization. The results suggest that cPKCs, especially the alpha-isotype, regulate nuclear function and CG exocytosis in porcine eggs.     

Plasma membrane block to sperm entry occurs in mouse eggs upon parthenogenetic activation

The ability of parthenogenetically activated mouse eggs to establish a plasma membrane (PM) block to sperm penetration was studied. Zona-free eggs preloaded with Hoechst 33342 were activated by exposure to ethanol or OAG (1-oleoyl-2-acetyl-sn-glycerol) and inseminated after different periods. Eggs challenged with sperm at 30- or 60-min postactivation displayed a fertilization frequency significantly lower than that of control eggs. Conversely, when insemination was carried out at 120-min postactivation, the proportion of fertilized eggs was equivalent to that observed in the control group. Moreover, we report that when the eggs were induced to resume meiosis without any notable loss of CGs (egg exposure to OAG at 100 μM external Ca²⁺ or to heat shock), a normal ability to be penetrated was recorded at 30-min postactivation. Similar behaviour was exhibited by eggs that underwent a CG exocytosis close to that triggered by sperm in absence of nuclear activation (microinjection of inositol 1,4,5-trisphosphate into the egg at 1 μM cytosolic concentration). Present data support the conclusion that parthenogenetically activated mouse eggs are capable of a transitory PM block response that requires both CG exocytosis and meiosis resumption to occur. © 1994 Wiley-Liss, Inc.     

A monoclonal antibody that recognizes mammalian cortical granules and a 32-kilodalton protein in mouse eggs

The fertilization-induced exocytosis of egg cortical granules (CGs) is responsible for a block to polyspermy, crucial to the viability of many species. The contents of mammalian CGs have been an elusive target for analysis because of picogram quantities of CG proteins. By using media enriched in secreted CG contents from calcium ionophore-induced eggs as an immunogen, a monoclonal antibody was raised that immunolocalized to structures in the mouse egg cortex with all the hallmarks of CGs. These structures were the correct size, absent from the region over the metaphase II spindle, and greatly reduced after fertilization. Double-labeling experiments confirmed that the antibody recognized the same population of CGs as those recognized by Lens culinaris agglutinin. On Western blots, the antibody primarily recognized a 32-kDa protein (and secondarily one at approximately 25 kDa) in mouse eggs. Analysis of biotin-labeled secreted proteins from activated eggs confirmed that CGs release only a small number of major proteins (45, 34, 32, 28, and approximately 20 kDa by SDS-PAGE). We therefore propose that the 32-kDa protein identified by this antibody is likely to correspond to the 32-kDa protein released from activated eggs and that it may be involved in the block to polyspermy. These methods should make it possible to generate additional antibodies to study the structure of CG components as well as their roles in the polyspermy block and CG biogenesis.     

Myosin-1c couples assembling actin to membranes to drive compensatory endocytosis

Compensatory endocytosis follows regulated exocytosis in cells ranging from eggs to neurons, but the means by which it is accomplished are unclear. In Xenopus eggs, compensatory endocytosis is driven by dynamic coats of assembling actin that surround and compress exocytosing cortical granules (CGs). We have identified Xenopus laevis myosin-1c (XlMyo1c) as a myosin that is upregulated by polyadenylation during meiotic maturation, the developmental interval that prepares eggs for fertilization and regulated CG exocytosis. Upon calcium-induced exocytosis, XlMyo1c is recruited to exocytosing CG membranes where actin coats then assemble. When XlMyo1c function is disrupted, actin coats assemble, but dynamic actin filaments are uncoupled from the exocytosing CG membranes such that coats do not compress, and compensatory endocytosis fails. Remarkably, there is also an increase in polymerized actin at membranes throughout the cell. We conclude that XlMyo1c couples polymerizing actin to membranes and so mediates force production during compensatory endocytosis.     

Multiple myosins are required to coordinate actin assembly with coat compression during compensatory endocytosis

Actin is involved in endocytosis in organisms ranging from yeast to mammals. In activated Xenopus eggs, exocytosing cortical granules (CGs) are surrounded by actin "coats," which compress the exocytosing compartments, resulting in compensatory endocytosis. Here, we examined the roles of two myosins in actin coat compression. Myosin-2 is recruited to exocytosing CGs late in coat compression. Inhibition of myosin-2 slows coat compression without affecting actin assembly. This differs from phenotype induced by inhibition of actin assembly, where exocytosing CGs are trapped at the plasma membrane (PM) completely. Thus, coat compression is likely driven in part by actin assembly itself, but it requires myosin-2 for efficient completion. In contrast to myosin-2, the long-tailed myosin-1e is recruited to exocytosing CGs immediately after egg activation. Perturbation of myosin-1e results in partial actin coat assembly and induces CG collapse into the PM. Intriguingly, simultaneous inhibition of actin assembly and myosin-1e prevents CG collapse. Together, the results show that myosin-1e and myosin-2 are part of an intricate machinery that coordinates coat compression at exocytosing CGs.     

Evidence for direct membrane retrieval following cortical granule exocytosis in Xenopus oocytes and eggs

Rapid exocytosis is typically followed by rapid resorption of exocytosed membrane; however, whether membrane retrieval occurs via indirect endocytosis of numerous small vesicles or direct resealing of the original, larger exocytotic vesicles is controversial. Here we show that cortical granule (CG) exocytosis in Xenopus oocytes and eggs is followed by rapid formation of endosomes as large as the CGs. Large endosomes are translucent, and their formation has the same developmental and pharmacological profile as CG exocytosis. Time course analyses show that large endosomes are not derived from small endosomes. Large endosome formation is triggered by stimuli that do not trigger increases in intracellular-free calcium and is insensitive to perturbation of microtubules by treatment with nocodazole. Perturbation of the f-actin cytoskeleton with latrunculin, however, sharply reduces large endosome formation. We conclude that CG membrane is directly retrieved in Xenopus oocytes and eggs and suggest that this retrieval is not directly dependent on an increase in intracellular-free calcium, but is dependent on the actin cytoskeleton.     

Incompetence of preovulatory mouse oocytes to undergo cortical granule exocytosis following induced calcium oscillations

Immature oocytes of many species are incompetent to undergo cortical granule (CG) exocytosis upon fertilization. In mouse eggs, CG exocytosis is dependent primarily on an inositol 1,4,5-trisphosphate (IP3)-mediated elevation of intracellular calcium ([Ca2+]i). While deficiencies upstream of [Ca2+]i release are known, this study examined whether downstream deficiencies also contribute to the incompetence of preovulatory mouse oocytes to release CGs. The experimental strategy was to bypass upstream deficiencies by inducing normal, fertilization-like [Ca2+]i oscillations in fully grown, germinal vesicle (GV) stage oocytes and determine if the extent of CG exocytosis was restored to levels observed in mature, metaphase II (MII)-stage eggs. Because IP3 does not stimulate a normal Ca2+ response in GV-stage oocytes, three alternate methods were used to induce oscillations: thimerosal treatment, electroporation, and sperm factor injection. Long-lasting oscillations from thimerosal treatment resulted in 64 and 10% mean CG release at the MII and GV stages, respectively (P < 0.001). Three electrical pulses induced mean [Ca2+]i elevations of approximately 730 and 650 nM in MII- and GV-stage oocytes, respectively, and 31% CG release in MII-stage eggs and 9% in GV-stage oocytes (P < 0.001). Sperm factor microinjection resulted in 86% CG release in MII-stage eggs, while similarly treated GV-stage oocytes exhibited < 1% CG release (P < 0.001). Taken together, these results demonstrate a deficiency downstream of [Ca2+]i release which is developmentally regulated in the 12 h prior to ovulation.     

Time course of cortical and zona reactions of pig oocytes upon intracellular calcium increase induced by thimerosal

Our previous study indicated that thimerosal is one of the most effective artificial activators to mimic sperm-induced increases in the intracellular free calcium concentration ([Ca2+]i) and other activation events in pig oocytes (Macháty et al., 1997). The present study was conducted to examine the temporal relationship between intracellular calcium transients, cortical granule (CG) exocytosis and the zona reaction induced by thimerosal. When pig oocytes matured in vitro were exposed to 200 microM thimerosal the first intracellular calcium transient, with a mean peak ratio of 4.97 +/- 1.14, was observed 509.64 +/- 122.03 s after addition of thimerosal. The density of CGs fell significantly from 63.3 +/- 11.7 CGs/100 micron 2 of cortex in control oocytes to 25.7 +/- 19.2 CGs/100 micron 2 of cortex (59.4% release) at 2 min after the first intracellular calcium transient. At 5 min after the calcium transient the residual CG density had been reduced to 10.7 +/- 10.4 CGs/100 micron 2 of cortex (83.1% release). This degree of CG exocytosis was the same as that in oocytes penetrated by sperm (9.5 +/- 5.1 CGs/100 micron 2 of cortex). No further decrease in residual CG density was observed at 10 min (10.3 +/- 14.8 CGs/100 micron 2 of cortex). Whereas 77.4% (120/155) of control oocytes were penetrated by spermatozoa only 1.4% (2/144) of thimerosal-treated oocytes were penetrated. Further experimental results obtained by in vitro fertilisation of oocytes with preincubated (capacitated) spermatozoa suggested that the zona block to sperm penetration in thimerosal-treated oocytes occurred within 35 min after CG exocytosis and 40 min after the first calcium transient. These results indicate that polyspermic penetration of pig oocytes inseminated in vitro is not due to delayed or incomplete CG exocytosis but more likely to a delayed zona reaction and/or simultaneous sperm penetration.     

Chromatin-mediated cortical granule redistribution is responsible for the formation of the cortical granule-free domain in mouse eggs

A cortical granule-free domain (CGFD) overlies the metaphase chromatin in fully mature mouse eggs. Although a chromatin-induced localized release of cortical granules (CG) during maturation is thought to be a major contributing factor to its formation, there are indications that CG redistribution may also be involved in generating the CGFD. We performed experiments to determine the relative contributions of CG exocytosis and redistribution in generating the CGFD. We found that the CGFD-inducing activity was not specific to female germ cell chromatin and was heat stable but sensitive to DNase and protease treatment. Surprisingly, chelation of egg intracellular Ca(2+) levels did not prevent CGFD formation in response to microinjection of exogenous chromatin, suggesting that development of the CGFD was not a result of CG exocytosis. This finding was confirmed by the lack of CG exudate on the plasma membrane surface of the injected eggs and the absence of conversion of ZP2 to ZP2(f) during formation of the new CGFD. Moreover, clamping intracellular Ca(2+) did not prevent the formation of the CGFD during oocyte maturation, but did inhibit the maturation-associated release of CGs between metaphase I and II. Results of these experiments suggest that CG redistribution is the dominant factor in formation of the CGFD.     

Study of protein kinase C antagonists on cortical granule exocytosis and cell-cycle resumption in fertilized mouse eggs

Although pharmacological agonists of protein kinase C (PKC) stimulate some events of mammalian egg activation, including cortical granule (CG) exocytosis, it is not known if these events are dependent on PKC activation during the normal process of fertilization. In order to examine the potential role of PKC in CG exocytosis, this study investigated whether PKC agonists faithfully mimic CG release and whether PKC antagonists block fertilization-induced CG release in mature mouse eggs. Phorbol ester (TPA, 2.5 ng/ml) treatment resulted in an atypical pattern of CG release in which there was a greater net loss of CGs in the equatorial region of the egg than in the region opposite the spindle. This pattern also was in contrast to that during fertilization, in which CG release occurred randomly throughout the cortex. Fertilization experiments utilized two different PKC inhibitors, bisindolyl-maleimide (5 μM) and chelerytherine (0.8 μM), targeted to both the “conserved” substrate and ATP binding domains of PKC. Simultaneous use of both inhibitors at maximal concentrations (compatible with fertilization and above their IC₅₀S) resulted in no detectable inhibition of CG release in treated fertilized eggs compared to controls. In addition, no inhibition of anaphase onset was observed in treated fertilized eggs. Activity of the inhibitors was verified by demonstrating that they blocked the induction of CG loss by TPA. Moreover, 1 μM staurosporine, a potent but less specific antagonist of PKC, also did not block CG loss, whereas the metaphase-anaphase transition was temporarily inhibited. The results indicate that TPA does not faithfully mimic CG release in fertilized eggs, that a role for PKC in CG release at fertilization remains to be established, and that other calcium-dependent effectors may be involved in CG exocytosis. Mol Reprod Dev 46:216–226, 1997. © 1997 Wiley-Liss, Inc.     

Quantitative studies of changes in cortical granule number and distribution in the mouse oocyte during meiotic maturation

Cortical granules (CGs) undergo a substantial change in distribution in the mouse oocyte cortex during meiotic maturation. In order to determine the mechanism of their change in distribution near the time of ovulation, CG density, total number per oocyte, and domain areas were quantitated. CGs were visualized microscopically by Lens culinaris agglutinin-biotin and Texas red-strepavidin fluorescence as well as by electron microscopy. Immature germinal vesicle stage (GV) oocytes from adult mice had a continuous cortical localization with some interior granules. Mature oocytes had an asymmetric cortical distribution with a CG-free domain, overlying the meiosis II metaphase spindle, occupying 40% of the cortex. The mean CG densities of the granule-occupied cortex of mature oocytes and the entire cortex of GV oocytes were 43 and 34 CGs/100 micron 2, respectively. The mean total numbers of CGs/oocyte were 4127 (mature) and 7440 (GV), and staining was absent in fertilized oocytes with two pronuclei. Calcium ionophore (A23187)-activated mature oocytes had a mean total number of 1235 CGs, some of which may have been in the process of exocytosis. The first polar body had few CGs, and thus was unlikely to account for the difference in CG number between GV and mature oocytes. The smaller total number and higher density of CGs in mature mouse oocytes suggests that both exocytosis and redistribution are plausible mechanisms for the development of the CG-free domain. Prefertilization exocytosis could account for the locus of sperm penetration which others have reported to occur in the hemisphere opposite the meiotic spindle in the mouse.     

Analysis of zona pellucida modifications due to cortical granule exocytosis in single porcine oocytes, using enhanced chemiluminescence

The present study was carried out to determine whether modification of zona pellucida (ZP) of a single oocyte following the cortical granule (CG) exocytosis induced by electrical stimulation could be analyzed using enhanced chemiluminescent (ECL) detection of the biotinylated ZP in a porcine oocyte. When a biotinylated ZP derived from a single oocyte matured in vitro was subjected to SDS-PAGE, 3 major bands (ZP1, ZP2 and ZP3) were observed following ECL detection. In these oocytes, CGs staining with fluorescein isothiocyanate (FITC)-labeled peanut agglutinin (FITC-PNA) had formed a monolayer underlying the plasma membrane. Electrical stimulation to induce artificial activation caused a decline in the fluorescent intensity of the CGs with a concomitant decrease in the amounts of ZP1 and ZP2 bands. However, the mobility changes of ZP1 and ZP2 on SDS-PAGE were not found under the inhibitory condition of the CG exocytosis in which oocytes were treated with ethylene glycol-bis(beta-aminoethyl ether) N, N, N',N'-tetraacetic acid (EGTA) or 1, 2-bis(2-aminophenoxy)ethane-N, N, N', N'-tetraacetic acid tetrakis(acetoxymethyl) ester (BAPTA/AM). In addition, when a time-dependent decrease in amounts of ZP1 and ZP2 bands on SDS-PAGE was observed in a single oocyte during activation, a maximum decrease in these bands was detected in oocytes incubated for at least 3.5 h after electrical stimulation. These results show that the method employed, ECL detection of the biotinylated ZP of a single oocyte, is a valuable tool for the analysis of ZP modification resulting from a decrease in amounts of ZP1 and ZP2 glycoproteins in combination with exocytosis of CGs, and that the prolonged period after activation is required for complete ZP modification in porcine 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.     

Calcium ultrastructural localization in Xenopus laevis eggs following activation by pricking or by calcium ionophore A 23187

In the egg of Xenopus laevis a cortical network of smooth endoplasmic reticulum (SER) surrounds and interconnects each cortical granule (CG) (Campanella and Andreuccetti, '77). This network is a possible intracellular site of calcium storage to be called into action for CG exocytosis. In our experiments, Xenopus eggs, unfertilized or activated by pricking or by calcium ionophore A 23187, have been fixed in osmium-pyroantimonate for calcium localization. Our data show that deposits can be detected only in activated eggs. The calcium chelator edetate (EGTA) and x-ray microprobe analysis demonstrate that they contain calcium. Deposits are found on liposomes and on all intraovular cytomembranes, which therefore appear to be possible sites of calcium sequestration. In the case of ionophore-activated eggs, deposits are detectable independently of the presence of extracellular calcium. These data show that in Xenopus at activation an intracellular liberation of calcium occurs similar to that described in other species. Furthermore, the fact that antimony deposits are observed only after activation makes Xenopus eggs appropriate material in which to follow the temporal and spatial sequence of appearance of the deposits during the early stages of activation. Our results show that antimony deposits appear first in SER vesicles between the plasma membrane and CGs and then spread to the rest of the egg cytomembranes. These data corroborate our hypothesis that in Xenopus the cortical SER network is the first intracellular site where calcium is released at activation. The possible mechanism of calcium release and propagation along the egg cortex is discussed.     

SNAP-25 is essential for cortical granule exocytosis in mouse eggs

Synaptosome-associated protein of 25 kDa (SNAP-25) has beenshown to play an important role inCa²⁺-dependent exocytosis inneurons and endocrine cells. During fertilization, sperm-egg fusioninduces cytosolic Ca²⁺mobilization and subsequentlyCa²⁺-dependent cortical granule(CG) exocytosis in eggs. However, it is not yet clear whether SNAP-25is involved in this process. In this study, we determined theexpression and function of SNAP-25 in mouse eggs. mRNA and SNAP-25 weredetected in metaphase II (MII) mouse eggs by RT-PCR and immunoblotanalysis, respectively. Next, to determine the function of SNAP-25, weevaluated the change in CG exocytosis with a membrane dye,tetramethylammonium-1,6-diphenyl-1,3,5-hexatriene, after microinjectionof a botulinum neurotoxin A (BoNT/A), which selectively cleaves SNAP-25in MII eggs. Sperm-induced CG exocytosis was significantly inhibited inthe BoNT/A-treated eggs. The inhibition was attenuated by coinjectionof SNAP-25. These results suggest that SNAP-25 may be involved inCa²⁺-dependent CG exocytosisduring fertilization in mouse eggs.

     

Compensatory endocytosis occurs after cortical granule exocytosis in mouse eggs

Compensatory endocytosis (CE) is one of the primary mechanisms through which cells maintain their surface area after exocytosis. Considering that in eggs massive exocytosis of cortical granules (CG) takes place after fertilization, the aim of this study was to evaluate the occurrence of CE following cortical exocytosis in mouse eggs. For this purpose, we developed a pulse-chase assay to detect CG membrane internalization. Results showed internalized labeling in SrCl₂-activated and fertilized eggs when chasing at 37°C, but not at a nonpermissive temperature (4°C). The use of kinase and calcineurin inhibitors led us to conclude that this internal labeling corresponded to CE. Further experiments showed that CE in mouse eggs is dependent on actin dynamics and dynamin activity, and could be associated with a transient exposure of phosphatidylserine. Finally, CE was impaired in A23187 ionophore-activated eggs, highlighting once again the mechanistic differences between the activation methods. Altogether, these results demonstrate for the first time that egg activation triggers CE in mouse eggs after exocytosis of CG, probably as a plasma membrane homeostasis mechanism.     

Identification of a translocation deficiency in cortical granule secretion in preovulatory mouse oocytes.

Preovulatory, germinal vesicle (GV)-stage mouse oocytes are unable to undergo normal cortical granule (CG) secretion. Full secretory competence is observed by metaphase II (MII) of meiosis and involves the development of calcium response mechanisms. To identify the deficient or inhibited step in CG secretion, preovulatory GV-stage oocytes were stimulated and tested for their ability to undergo translocation, docking, and/or fusion. The mean CG distance to the plasma membrane was not reduced in fertilized or sperm fraction-injected, GV-stage oocytes relative to that in control GV-stage oocytes. In addition, analysis of individual CG distances to the plasma membrane indicated no subpopulation of CGs competent to translocate. Further analysis demonstrated that secretory incompetence likely is not due to a lack of proximity of CGs to the egg's primary calcium store, the endoplasmic reticulum. Calcium/calmodulin-dependent protein kinase II (CaMKII), which is reportedly involved in secretory granule translocation and secretion in many cells, including eggs, was investigated. A 60-kDa CaMKII isoform detected by Western blot analysis increased 150% during oocyte maturation. The CaMKII activity assays indicated that MII-stage eggs correspondingly have 110% more maximal activity than GV-stage oocytes. These data demonstrate that the primary secretory deficiency is due to a failure of CG translocation, and that a maturation-associated increase in CaMKII correlates with the acquisition of secretory competence and the ability of the egg to undergo normal activation.     

Cellular and molecular mechanisms mediating the effects of polychlorinated biphenyls on oocyte developmental competence in cattle.

Polychlorinated biphenyls (PCBs) can interfere with normal reproductive functions acting as endocrine disruptors. Aroclor-1254 (A-1254), is a pool of more than 60 congeners used for in vitro studies because its composition is representative of PCBs environmental pollution. We previously demonstrated that the exposure of bovine oocytes to A-1254 during in vitro maturation (IVM) was detrimental not only to the maturation process but also induced a significant increase of polyspermy and a reduction of developmental competence. Therefore, we investigated whether A-1254 acts on two processes that occur during IVM and may be related with its negative effects: maternal mRNA polyadenylation and cortical granules (CGs) migration and exocytosis. Bovine cumulus-oocyte complexes (COCs) were exposed to 0.1 microg/ml of A-1254 during IVM, a level of exposure known to affect oocyte maturation, fertilization, and developmental competence. Oocyte exposure to A-1254 altered the poly(A) tail length of 5 out of 10 genes examined. PCBs effect on mRNA polyadenylation was different depending on the gene considered and resulted either in a shorter or in a longer poly(A) tail. At the end of maturation, Aroclor treated oocytes presented clustered CG in a significantly higher percentage than the control group. In addition, CG exocytosis after 8 hr of fertilization occurred at significantly lower extent in zygotes derived from the exposed group compared to control. Our results indicated that the lower developmental competence of oocytes exposed to PCBs during IVM can be related to the interaction of these contaminants with mechanisms regulating maternal mRNA storage in the ooplasm and normal CGs function.     

Activation of protein kinase C induces cortical granule exocytosis in a Ca2+-independent manner, but not the resumption of cell cycle in porcine eggs

The effects of protein kinase C (PKC) activation on meiotic resumption and cortical granule (CG) exocytosis as well as its dependence on Ca²⁺ in porcine eggs matured in vitro were studied. Cortical granule release was judged by both confocal laser microscopy after the eggs were labeled with fluorescein isothiocyanate-peanut agglutinin (FITC-PNA) and electron microscopy. Meiotic resumption and pronuclear formation were observed after eggs were stained with acetic orcein. When eggs were treated with PKC activators, 1-oleyl-2-acetyl-glycerol (OAG) or phorbol 12-myristate 13-acetate (PMA), the pronuclear formation percentage was significantly lower than that of Ca²⁺ ionophore A23187-treated group, but not statistically different from that in negative control group (P > 0.05), and most of the eggs were still arrested at metaphase II stage, suggesting that PKC activation does not induce the resumption of meiosis and pronuclear formation. In contrast, PKC activation induced 89.1% to 100% of the eggs completely or partially released their CG in different groups, not statistically different from A23187-treated group, and this effect could be overcome by PKC inhibition. When the intracellular free Ca²⁺ was chelated with acetoxymethal ester form of 1,2-bis(0-aminophenoxy)-ethane-N,N,N',N'-tetraacetic acid (BAPTA-AM), and then treated with PMA or OAG in Ca²⁺-free medium, the proportions of eggs with CG release were 90.9% and 78.1%, respectively, not statistically different from the above-treated groups, suggesting that CG exocytosis induced by PKC activation is independent of Ca²⁺ rise. The results indicate that different events of porcine egg activation may be uncoupled from one another.